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linux-next/drivers/md/raid5-cache.c

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raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
/*
* Copyright (C) 2015 Shaohua Li <shli@fb.com>
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
* Copyright (C) 2016 Song Liu <songliubraving@fb.com>
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
*/
#include <linux/kernel.h>
#include <linux/wait.h>
#include <linux/blkdev.h>
#include <linux/slab.h>
#include <linux/raid/md_p.h>
#include <linux/crc32c.h>
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
#include <linux/random.h>
#include <linux/kthread.h>
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
#include <linux/types.h>
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
#include "md.h"
#include "raid5.h"
#include "md-bitmap.h"
#include "raid5-log.h"
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
/*
* metadata/data stored in disk with 4k size unit (a block) regardless
* underneath hardware sector size. only works with PAGE_SIZE == 4096
*/
#define BLOCK_SECTORS (8)
#define BLOCK_SECTOR_SHIFT (3)
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
/*
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
* log->max_free_space is min(1/4 disk size, 10G reclaimable space).
*
* In write through mode, the reclaim runs every log->max_free_space.
* This can prevent the recovery scans for too long
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
*/
#define RECLAIM_MAX_FREE_SPACE (10 * 1024 * 1024 * 2) /* sector */
#define RECLAIM_MAX_FREE_SPACE_SHIFT (2)
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
/* wake up reclaim thread periodically */
#define R5C_RECLAIM_WAKEUP_INTERVAL (30 * HZ)
/* start flush with these full stripes */
#define R5C_FULL_STRIPE_FLUSH_BATCH(conf) (conf->max_nr_stripes / 4)
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
/* reclaim stripes in groups */
#define R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2)
/*
* We only need 2 bios per I/O unit to make progress, but ensure we
* have a few more available to not get too tight.
*/
#define R5L_POOL_SIZE 4
static char *r5c_journal_mode_str[] = {"write-through",
"write-back"};
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
/*
* raid5 cache state machine
*
* With the RAID cache, each stripe works in two phases:
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
* - caching phase
* - writing-out phase
*
* These two phases are controlled by bit STRIPE_R5C_CACHING:
* if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase
* if STRIPE_R5C_CACHING == 1, the stripe is in caching phase
*
* When there is no journal, or the journal is in write-through mode,
* the stripe is always in writing-out phase.
*
* For write-back journal, the stripe is sent to caching phase on write
* (r5c_try_caching_write). r5c_make_stripe_write_out() kicks off
* the write-out phase by clearing STRIPE_R5C_CACHING.
*
* Stripes in caching phase do not write the raid disks. Instead, all
* writes are committed from the log device. Therefore, a stripe in
* caching phase handles writes as:
* - write to log device
* - return IO
*
* Stripes in writing-out phase handle writes as:
* - calculate parity
* - write pending data and parity to journal
* - write data and parity to raid disks
* - return IO for pending writes
*/
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
struct r5l_log {
struct md_rdev *rdev;
u32 uuid_checksum;
sector_t device_size; /* log device size, round to
* BLOCK_SECTORS */
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
sector_t max_free_space; /* reclaim run if free space is at
* this size */
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
sector_t last_checkpoint; /* log tail. where recovery scan
* starts from */
u64 last_cp_seq; /* log tail sequence */
sector_t log_start; /* log head. where new data appends */
u64 seq; /* log head sequence */
sector_t next_checkpoint;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
struct mutex io_mutex;
struct r5l_io_unit *current_io; /* current io_unit accepting new data */
spinlock_t io_list_lock;
struct list_head running_ios; /* io_units which are still running,
* and have not yet been completely
* written to the log */
struct list_head io_end_ios; /* io_units which have been completely
* written to the log but not yet written
* to the RAID */
struct list_head flushing_ios; /* io_units which are waiting for log
* cache flush */
struct list_head finished_ios; /* io_units which settle down in log disk */
struct bio flush_bio;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
struct list_head no_mem_stripes; /* pending stripes, -ENOMEM */
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
struct kmem_cache *io_kc;
mempool_t *io_pool;
struct bio_set *bs;
mempool_t *meta_pool;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
struct md_thread *reclaim_thread;
unsigned long reclaim_target; /* number of space that need to be
* reclaimed. if it's 0, reclaim spaces
* used by io_units which are in
* IO_UNIT_STRIPE_END state (eg, reclaim
* dones't wait for specific io_unit
* switching to IO_UNIT_STRIPE_END
* state) */
wait_queue_head_t iounit_wait;
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
struct list_head no_space_stripes; /* pending stripes, log has no space */
spinlock_t no_space_stripes_lock;
bool need_cache_flush;
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
/* for r5c_cache */
enum r5c_journal_mode r5c_journal_mode;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
/* all stripes in r5cache, in the order of seq at sh->log_start */
struct list_head stripe_in_journal_list;
spinlock_t stripe_in_journal_lock;
atomic_t stripe_in_journal_count;
/* to submit async io_units, to fulfill ordering of flush */
struct work_struct deferred_io_work;
/* to disable write back during in degraded mode */
struct work_struct disable_writeback_work;
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
/* to for chunk_aligned_read in writeback mode, details below */
spinlock_t tree_lock;
struct radix_tree_root big_stripe_tree;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
};
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
/*
* Enable chunk_aligned_read() with write back cache.
*
* Each chunk may contain more than one stripe (for example, a 256kB
* chunk contains 64 4kB-page, so this chunk contain 64 stripes). For
* chunk_aligned_read, these stripes are grouped into one "big_stripe".
* For each big_stripe, we count how many stripes of this big_stripe
* are in the write back cache. These data are tracked in a radix tree
* (big_stripe_tree). We use radix_tree item pointer as the counter.
* r5c_tree_index() is used to calculate keys for the radix tree.
*
* chunk_aligned_read() calls r5c_big_stripe_cached() to look up
* big_stripe of each chunk in the tree. If this big_stripe is in the
* tree, chunk_aligned_read() aborts. This look up is protected by
* rcu_read_lock().
*
* It is necessary to remember whether a stripe is counted in
* big_stripe_tree. Instead of adding new flag, we reuses existing flags:
* STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these
* two flags are set, the stripe is counted in big_stripe_tree. This
* requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to
* r5c_try_caching_write(); and moving clear_bit of
* STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to
* r5c_finish_stripe_write_out().
*/
/*
* radix tree requests lowest 2 bits of data pointer to be 2b'00.
* So it is necessary to left shift the counter by 2 bits before using it
* as data pointer of the tree.
*/
#define R5C_RADIX_COUNT_SHIFT 2
/*
* calculate key for big_stripe_tree
*
* sect: align_bi->bi_iter.bi_sector or sh->sector
*/
static inline sector_t r5c_tree_index(struct r5conf *conf,
sector_t sect)
{
sector_t offset;
offset = sector_div(sect, conf->chunk_sectors);
return sect;
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
/*
* an IO range starts from a meta data block and end at the next meta data
* block. The io unit's the meta data block tracks data/parity followed it. io
* unit is written to log disk with normal write, as we always flush log disk
* first and then start move data to raid disks, there is no requirement to
* write io unit with FLUSH/FUA
*/
struct r5l_io_unit {
struct r5l_log *log;
struct page *meta_page; /* store meta block */
int meta_offset; /* current offset in meta_page */
struct bio *current_bio;/* current_bio accepting new data */
atomic_t pending_stripe;/* how many stripes not flushed to raid */
u64 seq; /* seq number of the metablock */
sector_t log_start; /* where the io_unit starts */
sector_t log_end; /* where the io_unit ends */
struct list_head log_sibling; /* log->running_ios */
struct list_head stripe_list; /* stripes added to the io_unit */
int state;
bool need_split_bio;
struct bio *split_bio;
unsigned int has_flush:1; /* include flush request */
unsigned int has_fua:1; /* include fua request */
unsigned int has_null_flush:1; /* include null flush request */
unsigned int has_flush_payload:1; /* include flush payload */
/*
* io isn't sent yet, flush/fua request can only be submitted till it's
* the first IO in running_ios list
*/
unsigned int io_deferred:1;
struct bio_list flush_barriers; /* size == 0 flush bios */
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
};
/* r5l_io_unit state */
enum r5l_io_unit_state {
IO_UNIT_RUNNING = 0, /* accepting new IO */
IO_UNIT_IO_START = 1, /* io_unit bio start writing to log,
* don't accepting new bio */
IO_UNIT_IO_END = 2, /* io_unit bio finish writing to log */
IO_UNIT_STRIPE_END = 3, /* stripes data finished writing to raid */
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
};
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
bool r5c_is_writeback(struct r5l_log *log)
{
return (log != NULL &&
log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_BACK);
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
static sector_t r5l_ring_add(struct r5l_log *log, sector_t start, sector_t inc)
{
start += inc;
if (start >= log->device_size)
start = start - log->device_size;
return start;
}
static sector_t r5l_ring_distance(struct r5l_log *log, sector_t start,
sector_t end)
{
if (end >= start)
return end - start;
else
return end + log->device_size - start;
}
static bool r5l_has_free_space(struct r5l_log *log, sector_t size)
{
sector_t used_size;
used_size = r5l_ring_distance(log, log->last_checkpoint,
log->log_start);
return log->device_size > used_size + size;
}
static void __r5l_set_io_unit_state(struct r5l_io_unit *io,
enum r5l_io_unit_state state)
{
if (WARN_ON(io->state >= state))
return;
io->state = state;
}
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
static void
r5c_return_dev_pending_writes(struct r5conf *conf, struct r5dev *dev)
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
{
struct bio *wbi, *wbi2;
wbi = dev->written;
dev->written = NULL;
while (wbi && wbi->bi_iter.bi_sector <
dev->sector + STRIPE_SECTORS) {
wbi2 = r5_next_bio(wbi, dev->sector);
md_write_end(conf->mddev);
bio_endio(wbi);
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
wbi = wbi2;
}
}
void r5c_handle_cached_data_endio(struct r5conf *conf,
struct stripe_head *sh, int disks)
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
{
int i;
for (i = sh->disks; i--; ) {
if (sh->dev[i].written) {
set_bit(R5_UPTODATE, &sh->dev[i].flags);
r5c_return_dev_pending_writes(conf, &sh->dev[i]);
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
bitmap_endwrite(conf->mddev->bitmap, sh->sector,
STRIPE_SECTORS,
!test_bit(STRIPE_DEGRADED, &sh->state),
0);
}
}
}
void r5l_wake_reclaim(struct r5l_log *log, sector_t space);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
/* Check whether we should flush some stripes to free up stripe cache */
void r5c_check_stripe_cache_usage(struct r5conf *conf)
{
int total_cached;
if (!r5c_is_writeback(conf->log))
return;
total_cached = atomic_read(&conf->r5c_cached_partial_stripes) +
atomic_read(&conf->r5c_cached_full_stripes);
/*
* The following condition is true for either of the following:
* - stripe cache pressure high:
* total_cached > 3/4 min_nr_stripes ||
* empty_inactive_list_nr > 0
* - stripe cache pressure moderate:
* total_cached > 1/2 min_nr_stripes
*/
if (total_cached > conf->min_nr_stripes * 1 / 2 ||
atomic_read(&conf->empty_inactive_list_nr) > 0)
r5l_wake_reclaim(conf->log, 0);
}
/*
* flush cache when there are R5C_FULL_STRIPE_FLUSH_BATCH or more full
* stripes in the cache
*/
void r5c_check_cached_full_stripe(struct r5conf *conf)
{
if (!r5c_is_writeback(conf->log))
return;
/*
* wake up reclaim for R5C_FULL_STRIPE_FLUSH_BATCH cached stripes
* or a full stripe (chunk size / 4k stripes).
*/
if (atomic_read(&conf->r5c_cached_full_stripes) >=
min(R5C_FULL_STRIPE_FLUSH_BATCH(conf),
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
conf->chunk_sectors >> STRIPE_SHIFT))
r5l_wake_reclaim(conf->log, 0);
}
/*
* Total log space (in sectors) needed to flush all data in cache
*
* To avoid deadlock due to log space, it is necessary to reserve log
* space to flush critical stripes (stripes that occupying log space near
* last_checkpoint). This function helps check how much log space is
* required to flush all cached stripes.
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
*
* To reduce log space requirements, two mechanisms are used to give cache
* flush higher priorities:
* 1. In handle_stripe_dirtying() and schedule_reconstruction(),
* stripes ALREADY in journal can be flushed w/o pending writes;
* 2. In r5l_write_stripe() and r5c_cache_data(), stripes NOT in journal
* can be delayed (r5l_add_no_space_stripe).
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
*
* In cache flush, the stripe goes through 1 and then 2. For a stripe that
* already passed 1, flushing it requires at most (conf->max_degraded + 1)
* pages of journal space. For stripes that has not passed 1, flushing it
* requires (conf->raid_disks + 1) pages of journal space. There are at
* most (conf->group_cnt + 1) stripe that passed 1. So total journal space
* required to flush all cached stripes (in pages) is:
*
* (stripe_in_journal_count - group_cnt - 1) * (max_degraded + 1) +
* (group_cnt + 1) * (raid_disks + 1)
* or
* (stripe_in_journal_count) * (max_degraded + 1) +
* (group_cnt + 1) * (raid_disks - max_degraded)
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
*/
static sector_t r5c_log_required_to_flush_cache(struct r5conf *conf)
{
struct r5l_log *log = conf->log;
if (!r5c_is_writeback(log))
return 0;
return BLOCK_SECTORS *
((conf->max_degraded + 1) * atomic_read(&log->stripe_in_journal_count) +
(conf->raid_disks - conf->max_degraded) * (conf->group_cnt + 1));
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
}
/*
* evaluate log space usage and update R5C_LOG_TIGHT and R5C_LOG_CRITICAL
*
* R5C_LOG_TIGHT is set when free space on the log device is less than 3x of
* reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log
* device is less than 2x of reclaim_required_space.
*/
static inline void r5c_update_log_state(struct r5l_log *log)
{
struct r5conf *conf = log->rdev->mddev->private;
sector_t free_space;
sector_t reclaim_space;
bool wake_reclaim = false;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (!r5c_is_writeback(log))
return;
free_space = r5l_ring_distance(log, log->log_start,
log->last_checkpoint);
reclaim_space = r5c_log_required_to_flush_cache(conf);
if (free_space < 2 * reclaim_space)
set_bit(R5C_LOG_CRITICAL, &conf->cache_state);
else {
if (test_bit(R5C_LOG_CRITICAL, &conf->cache_state))
wake_reclaim = true;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
clear_bit(R5C_LOG_CRITICAL, &conf->cache_state);
}
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (free_space < 3 * reclaim_space)
set_bit(R5C_LOG_TIGHT, &conf->cache_state);
else
clear_bit(R5C_LOG_TIGHT, &conf->cache_state);
if (wake_reclaim)
r5l_wake_reclaim(log, 0);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
}
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
/*
* Put the stripe into writing-out phase by clearing STRIPE_R5C_CACHING.
* This function should only be called in write-back mode.
*/
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
void r5c_make_stripe_write_out(struct stripe_head *sh)
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
{
struct r5conf *conf = sh->raid_conf;
struct r5l_log *log = conf->log;
BUG_ON(!r5c_is_writeback(log));
WARN_ON(!test_bit(STRIPE_R5C_CACHING, &sh->state));
clear_bit(STRIPE_R5C_CACHING, &sh->state);
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
if (!test_and_set_bit(STRIPE_PREREAD_ACTIVE, &sh->state))
atomic_inc(&conf->preread_active_stripes);
}
static void r5c_handle_data_cached(struct stripe_head *sh)
{
int i;
for (i = sh->disks; i--; )
if (test_and_clear_bit(R5_Wantwrite, &sh->dev[i].flags)) {
set_bit(R5_InJournal, &sh->dev[i].flags);
clear_bit(R5_LOCKED, &sh->dev[i].flags);
}
clear_bit(STRIPE_LOG_TRAPPED, &sh->state);
}
/*
* this journal write must contain full parity,
* it may also contain some data pages
*/
static void r5c_handle_parity_cached(struct stripe_head *sh)
{
int i;
for (i = sh->disks; i--; )
if (test_bit(R5_InJournal, &sh->dev[i].flags))
set_bit(R5_Wantwrite, &sh->dev[i].flags);
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
}
/*
* Setting proper flags after writing (or flushing) data and/or parity to the
* log device. This is called from r5l_log_endio() or r5l_log_flush_endio().
*/
static void r5c_finish_cache_stripe(struct stripe_head *sh)
{
struct r5l_log *log = sh->raid_conf->log;
if (log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_THROUGH) {
BUG_ON(test_bit(STRIPE_R5C_CACHING, &sh->state));
/*
* Set R5_InJournal for parity dev[pd_idx]. This means
* all data AND parity in the journal. For RAID 6, it is
* NOT necessary to set the flag for dev[qd_idx], as the
* two parities are written out together.
*/
set_bit(R5_InJournal, &sh->dev[sh->pd_idx].flags);
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
} else if (test_bit(STRIPE_R5C_CACHING, &sh->state)) {
r5c_handle_data_cached(sh);
} else {
r5c_handle_parity_cached(sh);
set_bit(R5_InJournal, &sh->dev[sh->pd_idx].flags);
}
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
}
static void r5l_io_run_stripes(struct r5l_io_unit *io)
{
struct stripe_head *sh, *next;
list_for_each_entry_safe(sh, next, &io->stripe_list, log_list) {
list_del_init(&sh->log_list);
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
r5c_finish_cache_stripe(sh);
set_bit(STRIPE_HANDLE, &sh->state);
raid5_release_stripe(sh);
}
}
static void r5l_log_run_stripes(struct r5l_log *log)
{
struct r5l_io_unit *io, *next;
assert_spin_locked(&log->io_list_lock);
list_for_each_entry_safe(io, next, &log->running_ios, log_sibling) {
/* don't change list order */
if (io->state < IO_UNIT_IO_END)
break;
list_move_tail(&io->log_sibling, &log->finished_ios);
r5l_io_run_stripes(io);
}
}
static void r5l_move_to_end_ios(struct r5l_log *log)
{
struct r5l_io_unit *io, *next;
assert_spin_locked(&log->io_list_lock);
list_for_each_entry_safe(io, next, &log->running_ios, log_sibling) {
/* don't change list order */
if (io->state < IO_UNIT_IO_END)
break;
list_move_tail(&io->log_sibling, &log->io_end_ios);
}
}
static void __r5l_stripe_write_finished(struct r5l_io_unit *io);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
static void r5l_log_endio(struct bio *bio)
{
struct r5l_io_unit *io = bio->bi_private;
struct r5l_io_unit *io_deferred;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
struct r5l_log *log = io->log;
unsigned long flags;
bool has_null_flush;
bool has_flush_payload;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
if (bio->bi_status)
md_error(log->rdev->mddev, log->rdev);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
bio_put(bio);
mempool_free(io->meta_page, log->meta_pool);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
spin_lock_irqsave(&log->io_list_lock, flags);
__r5l_set_io_unit_state(io, IO_UNIT_IO_END);
/*
* if the io doesn't not have null_flush or flush payload,
* it is not safe to access it after releasing io_list_lock.
* Therefore, it is necessary to check the condition with
* the lock held.
*/
has_null_flush = io->has_null_flush;
has_flush_payload = io->has_flush_payload;
if (log->need_cache_flush && !list_empty(&io->stripe_list))
r5l_move_to_end_ios(log);
else
r5l_log_run_stripes(log);
if (!list_empty(&log->running_ios)) {
/*
* FLUSH/FUA io_unit is deferred because of ordering, now we
* can dispatch it
*/
io_deferred = list_first_entry(&log->running_ios,
struct r5l_io_unit, log_sibling);
if (io_deferred->io_deferred)
schedule_work(&log->deferred_io_work);
}
spin_unlock_irqrestore(&log->io_list_lock, flags);
if (log->need_cache_flush)
md_wakeup_thread(log->rdev->mddev->thread);
/* finish flush only io_unit and PAYLOAD_FLUSH only io_unit */
if (has_null_flush) {
struct bio *bi;
WARN_ON(bio_list_empty(&io->flush_barriers));
while ((bi = bio_list_pop(&io->flush_barriers)) != NULL) {
bio_endio(bi);
if (atomic_dec_and_test(&io->pending_stripe)) {
__r5l_stripe_write_finished(io);
return;
}
}
}
/* decrease pending_stripe for flush payload */
if (has_flush_payload)
if (atomic_dec_and_test(&io->pending_stripe))
__r5l_stripe_write_finished(io);
}
static void r5l_do_submit_io(struct r5l_log *log, struct r5l_io_unit *io)
{
unsigned long flags;
spin_lock_irqsave(&log->io_list_lock, flags);
__r5l_set_io_unit_state(io, IO_UNIT_IO_START);
spin_unlock_irqrestore(&log->io_list_lock, flags);
/*
* In case of journal device failures, submit_bio will get error
* and calls endio, then active stripes will continue write
* process. Therefore, it is not necessary to check Faulty bit
* of journal device here.
*
* We can't check split_bio after current_bio is submitted. If
* io->split_bio is null, after current_bio is submitted, current_bio
* might already be completed and the io_unit is freed. We submit
* split_bio first to avoid the issue.
*/
if (io->split_bio) {
if (io->has_flush)
io->split_bio->bi_opf |= REQ_PREFLUSH;
if (io->has_fua)
io->split_bio->bi_opf |= REQ_FUA;
submit_bio(io->split_bio);
}
if (io->has_flush)
2016-12-14 04:40:15 +08:00
io->current_bio->bi_opf |= REQ_PREFLUSH;
if (io->has_fua)
2016-12-14 04:40:15 +08:00
io->current_bio->bi_opf |= REQ_FUA;
submit_bio(io->current_bio);
}
/* deferred io_unit will be dispatched here */
static void r5l_submit_io_async(struct work_struct *work)
{
struct r5l_log *log = container_of(work, struct r5l_log,
deferred_io_work);
struct r5l_io_unit *io = NULL;
unsigned long flags;
spin_lock_irqsave(&log->io_list_lock, flags);
if (!list_empty(&log->running_ios)) {
io = list_first_entry(&log->running_ios, struct r5l_io_unit,
log_sibling);
if (!io->io_deferred)
io = NULL;
else
io->io_deferred = 0;
}
spin_unlock_irqrestore(&log->io_list_lock, flags);
if (io)
r5l_do_submit_io(log, io);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
static void r5c_disable_writeback_async(struct work_struct *work)
{
struct r5l_log *log = container_of(work, struct r5l_log,
disable_writeback_work);
struct mddev *mddev = log->rdev->mddev;
struct r5conf *conf = mddev->private;
int locked = 0;
if (log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_THROUGH)
return;
pr_info("md/raid:%s: Disabling writeback cache for degraded array.\n",
mdname(mddev));
/* wait superblock change before suspend */
wait_event(mddev->sb_wait,
conf->log == NULL ||
(!test_bit(MD_SB_CHANGE_PENDING, &mddev->sb_flags) &&
(locked = mddev_trylock(mddev))));
if (locked) {
mddev_suspend(mddev);
log->r5c_journal_mode = R5C_JOURNAL_MODE_WRITE_THROUGH;
mddev_resume(mddev);
mddev_unlock(mddev);
}
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
static void r5l_submit_current_io(struct r5l_log *log)
{
struct r5l_io_unit *io = log->current_io;
struct bio *bio;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
struct r5l_meta_block *block;
unsigned long flags;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
u32 crc;
bool do_submit = true;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
if (!io)
return;
block = page_address(io->meta_page);
block->meta_size = cpu_to_le32(io->meta_offset);
crc = crc32c_le(log->uuid_checksum, block, PAGE_SIZE);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
block->checksum = cpu_to_le32(crc);
bio = io->current_bio;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
log->current_io = NULL;
spin_lock_irqsave(&log->io_list_lock, flags);
if (io->has_flush || io->has_fua) {
if (io != list_first_entry(&log->running_ios,
struct r5l_io_unit, log_sibling)) {
io->io_deferred = 1;
do_submit = false;
}
}
spin_unlock_irqrestore(&log->io_list_lock, flags);
if (do_submit)
r5l_do_submit_io(log, io);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
static struct bio *r5l_bio_alloc(struct r5l_log *log)
{
struct bio *bio = bio_alloc_bioset(GFP_NOIO, BIO_MAX_PAGES, log->bs);
bio_set_op_attrs(bio, REQ_OP_WRITE, 0);
bio_set_dev(bio, log->rdev->bdev);
bio->bi_iter.bi_sector = log->rdev->data_offset + log->log_start;
return bio;
}
static void r5_reserve_log_entry(struct r5l_log *log, struct r5l_io_unit *io)
{
log->log_start = r5l_ring_add(log, log->log_start, BLOCK_SECTORS);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
r5c_update_log_state(log);
/*
* If we filled up the log device start from the beginning again,
* which will require a new bio.
*
* Note: for this to work properly the log size needs to me a multiple
* of BLOCK_SECTORS.
*/
if (log->log_start == 0)
io->need_split_bio = true;
io->log_end = log->log_start;
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
static struct r5l_io_unit *r5l_new_meta(struct r5l_log *log)
{
struct r5l_io_unit *io;
struct r5l_meta_block *block;
io = mempool_alloc(log->io_pool, GFP_ATOMIC);
if (!io)
return NULL;
memset(io, 0, sizeof(*io));
io->log = log;
INIT_LIST_HEAD(&io->log_sibling);
INIT_LIST_HEAD(&io->stripe_list);
bio_list_init(&io->flush_barriers);
io->state = IO_UNIT_RUNNING;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
io->meta_page = mempool_alloc(log->meta_pool, GFP_NOIO);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
block = page_address(io->meta_page);
clear_page(block);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
block->magic = cpu_to_le32(R5LOG_MAGIC);
block->version = R5LOG_VERSION;
block->seq = cpu_to_le64(log->seq);
block->position = cpu_to_le64(log->log_start);
io->log_start = log->log_start;
io->meta_offset = sizeof(struct r5l_meta_block);
io->seq = log->seq++;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
io->current_bio = r5l_bio_alloc(log);
io->current_bio->bi_end_io = r5l_log_endio;
io->current_bio->bi_private = io;
bio_add_page(io->current_bio, io->meta_page, PAGE_SIZE, 0);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
r5_reserve_log_entry(log, io);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
spin_lock_irq(&log->io_list_lock);
list_add_tail(&io->log_sibling, &log->running_ios);
spin_unlock_irq(&log->io_list_lock);
return io;
}
static int r5l_get_meta(struct r5l_log *log, unsigned int payload_size)
{
if (log->current_io &&
log->current_io->meta_offset + payload_size > PAGE_SIZE)
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
r5l_submit_current_io(log);
if (!log->current_io) {
log->current_io = r5l_new_meta(log);
if (!log->current_io)
return -ENOMEM;
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
return 0;
}
static void r5l_append_payload_meta(struct r5l_log *log, u16 type,
sector_t location,
u32 checksum1, u32 checksum2,
bool checksum2_valid)
{
struct r5l_io_unit *io = log->current_io;
struct r5l_payload_data_parity *payload;
payload = page_address(io->meta_page) + io->meta_offset;
payload->header.type = cpu_to_le16(type);
payload->header.flags = cpu_to_le16(0);
payload->size = cpu_to_le32((1 + !!checksum2_valid) <<
(PAGE_SHIFT - 9));
payload->location = cpu_to_le64(location);
payload->checksum[0] = cpu_to_le32(checksum1);
if (checksum2_valid)
payload->checksum[1] = cpu_to_le32(checksum2);
io->meta_offset += sizeof(struct r5l_payload_data_parity) +
sizeof(__le32) * (1 + !!checksum2_valid);
}
static void r5l_append_payload_page(struct r5l_log *log, struct page *page)
{
struct r5l_io_unit *io = log->current_io;
if (io->need_split_bio) {
BUG_ON(io->split_bio);
io->split_bio = io->current_bio;
io->current_bio = r5l_bio_alloc(log);
bio_chain(io->current_bio, io->split_bio);
io->need_split_bio = false;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
if (!bio_add_page(io->current_bio, page, PAGE_SIZE, 0))
BUG();
r5_reserve_log_entry(log, io);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
static void r5l_append_flush_payload(struct r5l_log *log, sector_t sect)
{
struct mddev *mddev = log->rdev->mddev;
struct r5conf *conf = mddev->private;
struct r5l_io_unit *io;
struct r5l_payload_flush *payload;
int meta_size;
/*
* payload_flush requires extra writes to the journal.
* To avoid handling the extra IO in quiesce, just skip
* flush_payload
*/
if (conf->quiesce)
return;
mutex_lock(&log->io_mutex);
meta_size = sizeof(struct r5l_payload_flush) + sizeof(__le64);
if (r5l_get_meta(log, meta_size)) {
mutex_unlock(&log->io_mutex);
return;
}
/* current implementation is one stripe per flush payload */
io = log->current_io;
payload = page_address(io->meta_page) + io->meta_offset;
payload->header.type = cpu_to_le16(R5LOG_PAYLOAD_FLUSH);
payload->header.flags = cpu_to_le16(0);
payload->size = cpu_to_le32(sizeof(__le64));
payload->flush_stripes[0] = cpu_to_le64(sect);
io->meta_offset += meta_size;
/* multiple flush payloads count as one pending_stripe */
if (!io->has_flush_payload) {
io->has_flush_payload = 1;
atomic_inc(&io->pending_stripe);
}
mutex_unlock(&log->io_mutex);
}
static int r5l_log_stripe(struct r5l_log *log, struct stripe_head *sh,
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
int data_pages, int parity_pages)
{
int i;
int meta_size;
int ret;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
struct r5l_io_unit *io;
meta_size =
((sizeof(struct r5l_payload_data_parity) + sizeof(__le32))
* data_pages) +
sizeof(struct r5l_payload_data_parity) +
sizeof(__le32) * parity_pages;
ret = r5l_get_meta(log, meta_size);
if (ret)
return ret;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
io = log->current_io;
if (test_and_clear_bit(STRIPE_R5C_PREFLUSH, &sh->state))
io->has_flush = 1;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
for (i = 0; i < sh->disks; i++) {
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
if (!test_bit(R5_Wantwrite, &sh->dev[i].flags) ||
test_bit(R5_InJournal, &sh->dev[i].flags))
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
continue;
if (i == sh->pd_idx || i == sh->qd_idx)
continue;
if (test_bit(R5_WantFUA, &sh->dev[i].flags) &&
log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_BACK) {
io->has_fua = 1;
/*
* we need to flush journal to make sure recovery can
* reach the data with fua flag
*/
io->has_flush = 1;
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
r5l_append_payload_meta(log, R5LOG_PAYLOAD_DATA,
raid5_compute_blocknr(sh, i, 0),
sh->dev[i].log_checksum, 0, false);
r5l_append_payload_page(log, sh->dev[i].page);
}
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
if (parity_pages == 2) {
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
r5l_append_payload_meta(log, R5LOG_PAYLOAD_PARITY,
sh->sector, sh->dev[sh->pd_idx].log_checksum,
sh->dev[sh->qd_idx].log_checksum, true);
r5l_append_payload_page(log, sh->dev[sh->pd_idx].page);
r5l_append_payload_page(log, sh->dev[sh->qd_idx].page);
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
} else if (parity_pages == 1) {
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
r5l_append_payload_meta(log, R5LOG_PAYLOAD_PARITY,
sh->sector, sh->dev[sh->pd_idx].log_checksum,
0, false);
r5l_append_payload_page(log, sh->dev[sh->pd_idx].page);
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
} else /* Just writing data, not parity, in caching phase */
BUG_ON(parity_pages != 0);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
list_add_tail(&sh->log_list, &io->stripe_list);
atomic_inc(&io->pending_stripe);
sh->log_io = io;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_THROUGH)
return 0;
if (sh->log_start == MaxSector) {
BUG_ON(!list_empty(&sh->r5c));
sh->log_start = io->log_start;
spin_lock_irq(&log->stripe_in_journal_lock);
list_add_tail(&sh->r5c,
&log->stripe_in_journal_list);
spin_unlock_irq(&log->stripe_in_journal_lock);
atomic_inc(&log->stripe_in_journal_count);
}
return 0;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
/* add stripe to no_space_stripes, and then wake up reclaim */
static inline void r5l_add_no_space_stripe(struct r5l_log *log,
struct stripe_head *sh)
{
spin_lock(&log->no_space_stripes_lock);
list_add_tail(&sh->log_list, &log->no_space_stripes);
spin_unlock(&log->no_space_stripes_lock);
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
/*
* running in raid5d, where reclaim could wait for raid5d too (when it flushes
* data from log to raid disks), so we shouldn't wait for reclaim here
*/
int r5l_write_stripe(struct r5l_log *log, struct stripe_head *sh)
{
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
struct r5conf *conf = sh->raid_conf;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
int write_disks = 0;
int data_pages, parity_pages;
int reserve;
int i;
int ret = 0;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
bool wake_reclaim = false;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
if (!log)
return -EAGAIN;
/* Don't support stripe batch */
if (sh->log_io || !test_bit(R5_Wantwrite, &sh->dev[sh->pd_idx].flags) ||
test_bit(STRIPE_SYNCING, &sh->state)) {
/* the stripe is written to log, we start writing it to raid */
clear_bit(STRIPE_LOG_TRAPPED, &sh->state);
return -EAGAIN;
}
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
WARN_ON(test_bit(STRIPE_R5C_CACHING, &sh->state));
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
for (i = 0; i < sh->disks; i++) {
void *addr;
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
if (!test_bit(R5_Wantwrite, &sh->dev[i].flags) ||
test_bit(R5_InJournal, &sh->dev[i].flags))
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
continue;
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
write_disks++;
/* checksum is already calculated in last run */
if (test_bit(STRIPE_LOG_TRAPPED, &sh->state))
continue;
addr = kmap_atomic(sh->dev[i].page);
sh->dev[i].log_checksum = crc32c_le(log->uuid_checksum,
addr, PAGE_SIZE);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
kunmap_atomic(addr);
}
parity_pages = 1 + !!(sh->qd_idx >= 0);
data_pages = write_disks - parity_pages;
set_bit(STRIPE_LOG_TRAPPED, &sh->state);
/*
* The stripe must enter state machine again to finish the write, so
* don't delay.
*/
clear_bit(STRIPE_DELAYED, &sh->state);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
atomic_inc(&sh->count);
mutex_lock(&log->io_mutex);
/* meta + data */
reserve = (1 + write_disks) << (PAGE_SHIFT - 9);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_THROUGH) {
if (!r5l_has_free_space(log, reserve)) {
r5l_add_no_space_stripe(log, sh);
wake_reclaim = true;
} else {
ret = r5l_log_stripe(log, sh, data_pages, parity_pages);
if (ret) {
spin_lock_irq(&log->io_list_lock);
list_add_tail(&sh->log_list,
&log->no_mem_stripes);
spin_unlock_irq(&log->io_list_lock);
}
}
} else { /* R5C_JOURNAL_MODE_WRITE_BACK */
/*
* log space critical, do not process stripes that are
* not in cache yet (sh->log_start == MaxSector).
*/
if (test_bit(R5C_LOG_CRITICAL, &conf->cache_state) &&
sh->log_start == MaxSector) {
r5l_add_no_space_stripe(log, sh);
wake_reclaim = true;
reserve = 0;
} else if (!r5l_has_free_space(log, reserve)) {
if (sh->log_start == log->last_checkpoint)
BUG();
else
r5l_add_no_space_stripe(log, sh);
} else {
ret = r5l_log_stripe(log, sh, data_pages, parity_pages);
if (ret) {
spin_lock_irq(&log->io_list_lock);
list_add_tail(&sh->log_list,
&log->no_mem_stripes);
spin_unlock_irq(&log->io_list_lock);
}
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
mutex_unlock(&log->io_mutex);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (wake_reclaim)
r5l_wake_reclaim(log, reserve);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
return 0;
}
void r5l_write_stripe_run(struct r5l_log *log)
{
if (!log)
return;
mutex_lock(&log->io_mutex);
r5l_submit_current_io(log);
mutex_unlock(&log->io_mutex);
}
int r5l_handle_flush_request(struct r5l_log *log, struct bio *bio)
{
if (!log)
return -ENODEV;
if (log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_THROUGH) {
/*
* in write through (journal only)
* we flush log disk cache first, then write stripe data to
* raid disks. So if bio is finished, the log disk cache is
* flushed already. The recovery guarantees we can recovery
* the bio from log disk, so we don't need to flush again
*/
if (bio->bi_iter.bi_size == 0) {
bio_endio(bio);
return 0;
}
bio->bi_opf &= ~REQ_PREFLUSH;
} else {
/* write back (with cache) */
if (bio->bi_iter.bi_size == 0) {
mutex_lock(&log->io_mutex);
r5l_get_meta(log, 0);
bio_list_add(&log->current_io->flush_barriers, bio);
log->current_io->has_flush = 1;
log->current_io->has_null_flush = 1;
atomic_inc(&log->current_io->pending_stripe);
r5l_submit_current_io(log);
mutex_unlock(&log->io_mutex);
return 0;
}
}
return -EAGAIN;
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
/* This will run after log space is reclaimed */
static void r5l_run_no_space_stripes(struct r5l_log *log)
{
struct stripe_head *sh;
spin_lock(&log->no_space_stripes_lock);
while (!list_empty(&log->no_space_stripes)) {
sh = list_first_entry(&log->no_space_stripes,
struct stripe_head, log_list);
list_del_init(&sh->log_list);
set_bit(STRIPE_HANDLE, &sh->state);
raid5_release_stripe(sh);
}
spin_unlock(&log->no_space_stripes_lock);
}
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
/*
* calculate new last_checkpoint
* for write through mode, returns log->next_checkpoint
* for write back, returns log_start of first sh in stripe_in_journal_list
*/
static sector_t r5c_calculate_new_cp(struct r5conf *conf)
{
struct stripe_head *sh;
struct r5l_log *log = conf->log;
sector_t new_cp;
unsigned long flags;
if (log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_THROUGH)
return log->next_checkpoint;
spin_lock_irqsave(&log->stripe_in_journal_lock, flags);
if (list_empty(&conf->log->stripe_in_journal_list)) {
/* all stripes flushed */
spin_unlock_irqrestore(&log->stripe_in_journal_lock, flags);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
return log->next_checkpoint;
}
sh = list_first_entry(&conf->log->stripe_in_journal_list,
struct stripe_head, r5c);
new_cp = sh->log_start;
spin_unlock_irqrestore(&log->stripe_in_journal_lock, flags);
return new_cp;
}
static sector_t r5l_reclaimable_space(struct r5l_log *log)
{
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
struct r5conf *conf = log->rdev->mddev->private;
return r5l_ring_distance(log, log->last_checkpoint,
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
r5c_calculate_new_cp(conf));
}
static void r5l_run_no_mem_stripe(struct r5l_log *log)
{
struct stripe_head *sh;
assert_spin_locked(&log->io_list_lock);
if (!list_empty(&log->no_mem_stripes)) {
sh = list_first_entry(&log->no_mem_stripes,
struct stripe_head, log_list);
list_del_init(&sh->log_list);
set_bit(STRIPE_HANDLE, &sh->state);
raid5_release_stripe(sh);
}
}
static bool r5l_complete_finished_ios(struct r5l_log *log)
{
struct r5l_io_unit *io, *next;
bool found = false;
assert_spin_locked(&log->io_list_lock);
list_for_each_entry_safe(io, next, &log->finished_ios, log_sibling) {
/* don't change list order */
if (io->state < IO_UNIT_STRIPE_END)
break;
log->next_checkpoint = io->log_start;
list_del(&io->log_sibling);
mempool_free(io, log->io_pool);
r5l_run_no_mem_stripe(log);
found = true;
}
return found;
}
static void __r5l_stripe_write_finished(struct r5l_io_unit *io)
{
struct r5l_log *log = io->log;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
struct r5conf *conf = log->rdev->mddev->private;
unsigned long flags;
spin_lock_irqsave(&log->io_list_lock, flags);
__r5l_set_io_unit_state(io, IO_UNIT_STRIPE_END);
if (!r5l_complete_finished_ios(log)) {
spin_unlock_irqrestore(&log->io_list_lock, flags);
return;
}
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (r5l_reclaimable_space(log) > log->max_free_space ||
test_bit(R5C_LOG_TIGHT, &conf->cache_state))
r5l_wake_reclaim(log, 0);
spin_unlock_irqrestore(&log->io_list_lock, flags);
wake_up(&log->iounit_wait);
}
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
void r5l_stripe_write_finished(struct stripe_head *sh)
{
struct r5l_io_unit *io;
io = sh->log_io;
sh->log_io = NULL;
if (io && atomic_dec_and_test(&io->pending_stripe))
__r5l_stripe_write_finished(io);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
}
static void r5l_log_flush_endio(struct bio *bio)
{
struct r5l_log *log = container_of(bio, struct r5l_log,
flush_bio);
unsigned long flags;
struct r5l_io_unit *io;
if (bio->bi_status)
md_error(log->rdev->mddev, log->rdev);
spin_lock_irqsave(&log->io_list_lock, flags);
list_for_each_entry(io, &log->flushing_ios, log_sibling)
r5l_io_run_stripes(io);
list_splice_tail_init(&log->flushing_ios, &log->finished_ios);
spin_unlock_irqrestore(&log->io_list_lock, flags);
}
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
/*
* Starting dispatch IO to raid.
* io_unit(meta) consists of a log. There is one situation we want to avoid. A
* broken meta in the middle of a log causes recovery can't find meta at the
* head of log. If operations require meta at the head persistent in log, we
* must make sure meta before it persistent in log too. A case is:
*
* stripe data/parity is in log, we start write stripe to raid disks. stripe
* data/parity must be persistent in log before we do the write to raid disks.
*
* The solution is we restrictly maintain io_unit list order. In this case, we
* only write stripes of an io_unit to raid disks till the io_unit is the first
* one whose data/parity is in log.
*/
void r5l_flush_stripe_to_raid(struct r5l_log *log)
{
bool do_flush;
if (!log || !log->need_cache_flush)
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
return;
spin_lock_irq(&log->io_list_lock);
/* flush bio is running */
if (!list_empty(&log->flushing_ios)) {
spin_unlock_irq(&log->io_list_lock);
return;
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
}
list_splice_tail_init(&log->io_end_ios, &log->flushing_ios);
do_flush = !list_empty(&log->flushing_ios);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
spin_unlock_irq(&log->io_list_lock);
if (!do_flush)
return;
bio_reset(&log->flush_bio);
bio_set_dev(&log->flush_bio, log->rdev->bdev);
log->flush_bio.bi_end_io = r5l_log_flush_endio;
log->flush_bio.bi_opf = REQ_OP_WRITE | REQ_PREFLUSH;
submit_bio(&log->flush_bio);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
}
static void r5l_write_super(struct r5l_log *log, sector_t cp);
static void r5l_write_super_and_discard_space(struct r5l_log *log,
sector_t end)
{
struct block_device *bdev = log->rdev->bdev;
struct mddev *mddev;
r5l_write_super(log, end);
if (!blk_queue_discard(bdev_get_queue(bdev)))
return;
mddev = log->rdev->mddev;
/*
* Discard could zero data, so before discard we must make sure
* superblock is updated to new log tail. Updating superblock (either
* directly call md_update_sb() or depend on md thread) must hold
* reconfig mutex. On the other hand, raid5_quiesce is called with
* reconfig_mutex hold. The first step of raid5_quiesce() is waitting
* for all IO finish, hence waitting for reclaim thread, while reclaim
* thread is calling this function and waitting for reconfig mutex. So
* there is a deadlock. We workaround this issue with a trylock.
* FIXME: we could miss discard if we can't take reconfig mutex
*/
set_mask_bits(&mddev->sb_flags, 0,
BIT(MD_SB_CHANGE_DEVS) | BIT(MD_SB_CHANGE_PENDING));
if (!mddev_trylock(mddev))
return;
md_update_sb(mddev, 1);
mddev_unlock(mddev);
/* discard IO error really doesn't matter, ignore it */
if (log->last_checkpoint < end) {
blkdev_issue_discard(bdev,
log->last_checkpoint + log->rdev->data_offset,
end - log->last_checkpoint, GFP_NOIO, 0);
} else {
blkdev_issue_discard(bdev,
log->last_checkpoint + log->rdev->data_offset,
log->device_size - log->last_checkpoint,
GFP_NOIO, 0);
blkdev_issue_discard(bdev, log->rdev->data_offset, end,
GFP_NOIO, 0);
}
}
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
/*
* r5c_flush_stripe moves stripe from cached list to handle_list. When called,
* the stripe must be on r5c_cached_full_stripes or r5c_cached_partial_stripes.
*
* must hold conf->device_lock
*/
static void r5c_flush_stripe(struct r5conf *conf, struct stripe_head *sh)
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
{
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
BUG_ON(list_empty(&sh->lru));
BUG_ON(!test_bit(STRIPE_R5C_CACHING, &sh->state));
BUG_ON(test_bit(STRIPE_HANDLE, &sh->state));
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
/*
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
* The stripe is not ON_RELEASE_LIST, so it is safe to call
* raid5_release_stripe() while holding conf->device_lock
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
*/
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
BUG_ON(test_bit(STRIPE_ON_RELEASE_LIST, &sh->state));
assert_spin_locked(&conf->device_lock);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
list_del_init(&sh->lru);
atomic_inc(&sh->count);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
set_bit(STRIPE_HANDLE, &sh->state);
atomic_inc(&conf->active_stripes);
r5c_make_stripe_write_out(sh);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
if (test_bit(STRIPE_R5C_PARTIAL_STRIPE, &sh->state))
atomic_inc(&conf->r5c_flushing_partial_stripes);
else
atomic_inc(&conf->r5c_flushing_full_stripes);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
raid5_release_stripe(sh);
}
/*
* if num == 0, flush all full stripes
* if num > 0, flush all full stripes. If less than num full stripes are
* flushed, flush some partial stripes until totally num stripes are
* flushed or there is no more cached stripes.
*/
void r5c_flush_cache(struct r5conf *conf, int num)
{
int count;
struct stripe_head *sh, *next;
assert_spin_locked(&conf->device_lock);
if (!conf->log)
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
return;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
count = 0;
list_for_each_entry_safe(sh, next, &conf->r5c_full_stripe_list, lru) {
r5c_flush_stripe(conf, sh);
count++;
}
if (count >= num)
return;
list_for_each_entry_safe(sh, next,
&conf->r5c_partial_stripe_list, lru) {
r5c_flush_stripe(conf, sh);
if (++count >= num)
break;
}
}
static void r5c_do_reclaim(struct r5conf *conf)
{
struct r5l_log *log = conf->log;
struct stripe_head *sh;
int count = 0;
unsigned long flags;
int total_cached;
int stripes_to_flush;
int flushing_partial, flushing_full;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (!r5c_is_writeback(log))
return;
flushing_partial = atomic_read(&conf->r5c_flushing_partial_stripes);
flushing_full = atomic_read(&conf->r5c_flushing_full_stripes);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
total_cached = atomic_read(&conf->r5c_cached_partial_stripes) +
atomic_read(&conf->r5c_cached_full_stripes) -
flushing_full - flushing_partial;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (total_cached > conf->min_nr_stripes * 3 / 4 ||
atomic_read(&conf->empty_inactive_list_nr) > 0)
/*
* if stripe cache pressure high, flush all full stripes and
* some partial stripes
*/
stripes_to_flush = R5C_RECLAIM_STRIPE_GROUP;
else if (total_cached > conf->min_nr_stripes * 1 / 2 ||
atomic_read(&conf->r5c_cached_full_stripes) - flushing_full >
R5C_FULL_STRIPE_FLUSH_BATCH(conf))
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
/*
* if stripe cache pressure moderate, or if there is many full
* stripes,flush all full stripes
*/
stripes_to_flush = 0;
else
/* no need to flush */
stripes_to_flush = -1;
if (stripes_to_flush >= 0) {
spin_lock_irqsave(&conf->device_lock, flags);
r5c_flush_cache(conf, stripes_to_flush);
spin_unlock_irqrestore(&conf->device_lock, flags);
}
/* if log space is tight, flush stripes on stripe_in_journal_list */
if (test_bit(R5C_LOG_TIGHT, &conf->cache_state)) {
spin_lock_irqsave(&log->stripe_in_journal_lock, flags);
spin_lock(&conf->device_lock);
list_for_each_entry(sh, &log->stripe_in_journal_list, r5c) {
/*
* stripes on stripe_in_journal_list could be in any
* state of the stripe_cache state machine. In this
* case, we only want to flush stripe on
* r5c_cached_full/partial_stripes. The following
* condition makes sure the stripe is on one of the
* two lists.
*/
if (!list_empty(&sh->lru) &&
!test_bit(STRIPE_HANDLE, &sh->state) &&
atomic_read(&sh->count) == 0) {
r5c_flush_stripe(conf, sh);
if (count++ >= R5C_RECLAIM_STRIPE_GROUP)
break;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
}
}
spin_unlock(&conf->device_lock);
spin_unlock_irqrestore(&log->stripe_in_journal_lock, flags);
}
if (!test_bit(R5C_LOG_CRITICAL, &conf->cache_state))
r5l_run_no_space_stripes(log);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
md_wakeup_thread(conf->mddev->thread);
}
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
static void r5l_do_reclaim(struct r5l_log *log)
{
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
struct r5conf *conf = log->rdev->mddev->private;
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
sector_t reclaim_target = xchg(&log->reclaim_target, 0);
sector_t reclaimable;
sector_t next_checkpoint;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
bool write_super;
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
spin_lock_irq(&log->io_list_lock);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
write_super = r5l_reclaimable_space(log) > log->max_free_space ||
reclaim_target != 0 || !list_empty(&log->no_space_stripes);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
/*
* move proper io_unit to reclaim list. We should not change the order.
* reclaimable/unreclaimable io_unit can be mixed in the list, we
* shouldn't reuse space of an unreclaimable io_unit
*/
while (1) {
reclaimable = r5l_reclaimable_space(log);
if (reclaimable >= reclaim_target ||
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
(list_empty(&log->running_ios) &&
list_empty(&log->io_end_ios) &&
list_empty(&log->flushing_ios) &&
list_empty(&log->finished_ios)))
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
break;
md_wakeup_thread(log->rdev->mddev->thread);
wait_event_lock_irq(log->iounit_wait,
r5l_reclaimable_space(log) > reclaimable,
log->io_list_lock);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
}
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
next_checkpoint = r5c_calculate_new_cp(conf);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
spin_unlock_irq(&log->io_list_lock);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (reclaimable == 0 || !write_super)
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
return;
/*
* write_super will flush cache of each raid disk. We must write super
* here, because the log area might be reused soon and we don't want to
* confuse recovery
*/
r5l_write_super_and_discard_space(log, next_checkpoint);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
mutex_lock(&log->io_mutex);
log->last_checkpoint = next_checkpoint;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
r5c_update_log_state(log);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
mutex_unlock(&log->io_mutex);
r5l_run_no_space_stripes(log);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
}
static void r5l_reclaim_thread(struct md_thread *thread)
{
struct mddev *mddev = thread->mddev;
struct r5conf *conf = mddev->private;
struct r5l_log *log = conf->log;
if (!log)
return;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
r5c_do_reclaim(conf);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
r5l_do_reclaim(log);
}
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
void r5l_wake_reclaim(struct r5l_log *log, sector_t space)
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
{
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
unsigned long target;
unsigned long new = (unsigned long)space; /* overflow in theory */
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (!log)
return;
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
do {
target = log->reclaim_target;
if (new < target)
return;
} while (cmpxchg(&log->reclaim_target, target, new) != target);
md_wakeup_thread(log->reclaim_thread);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
void r5l_quiesce(struct r5l_log *log, int quiesce)
{
struct mddev *mddev;
if (!log)
return;
if (quiesce) {
/* make sure r5l_write_super_and_discard_space exits */
mddev = log->rdev->mddev;
wake_up(&mddev->sb_wait);
kthread_park(log->reclaim_thread->tsk);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
r5l_wake_reclaim(log, MaxSector);
r5l_do_reclaim(log);
} else
kthread_unpark(log->reclaim_thread->tsk);
}
bool r5l_log_disk_error(struct r5conf *conf)
{
struct r5l_log *log;
bool ret;
/* don't allow write if journal disk is missing */
rcu_read_lock();
log = rcu_dereference(conf->log);
if (!log)
ret = test_bit(MD_HAS_JOURNAL, &conf->mddev->flags);
else
ret = test_bit(Faulty, &log->rdev->flags);
rcu_read_unlock();
return ret;
}
#define R5L_RECOVERY_PAGE_POOL_SIZE 256
struct r5l_recovery_ctx {
struct page *meta_page; /* current meta */
sector_t meta_total_blocks; /* total size of current meta and data */
sector_t pos; /* recovery position */
u64 seq; /* recovery position seq */
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
int data_parity_stripes; /* number of data_parity stripes */
int data_only_stripes; /* number of data_only stripes */
struct list_head cached_list;
/*
* read ahead page pool (ra_pool)
* in recovery, log is read sequentially. It is not efficient to
* read every page with sync_page_io(). The read ahead page pool
* reads multiple pages with one IO, so further log read can
* just copy data from the pool.
*/
struct page *ra_pool[R5L_RECOVERY_PAGE_POOL_SIZE];
sector_t pool_offset; /* offset of first page in the pool */
int total_pages; /* total allocated pages */
int valid_pages; /* pages with valid data */
struct bio *ra_bio; /* bio to do the read ahead */
};
static int r5l_recovery_allocate_ra_pool(struct r5l_log *log,
struct r5l_recovery_ctx *ctx)
{
struct page *page;
ctx->ra_bio = bio_alloc_bioset(GFP_KERNEL, BIO_MAX_PAGES, log->bs);
if (!ctx->ra_bio)
return -ENOMEM;
ctx->valid_pages = 0;
ctx->total_pages = 0;
while (ctx->total_pages < R5L_RECOVERY_PAGE_POOL_SIZE) {
page = alloc_page(GFP_KERNEL);
if (!page)
break;
ctx->ra_pool[ctx->total_pages] = page;
ctx->total_pages += 1;
}
if (ctx->total_pages == 0) {
bio_put(ctx->ra_bio);
return -ENOMEM;
}
ctx->pool_offset = 0;
return 0;
}
static void r5l_recovery_free_ra_pool(struct r5l_log *log,
struct r5l_recovery_ctx *ctx)
{
int i;
for (i = 0; i < ctx->total_pages; ++i)
put_page(ctx->ra_pool[i]);
bio_put(ctx->ra_bio);
}
/*
* fetch ctx->valid_pages pages from offset
* In normal cases, ctx->valid_pages == ctx->total_pages after the call.
* However, if the offset is close to the end of the journal device,
* ctx->valid_pages could be smaller than ctx->total_pages
*/
static int r5l_recovery_fetch_ra_pool(struct r5l_log *log,
struct r5l_recovery_ctx *ctx,
sector_t offset)
{
bio_reset(ctx->ra_bio);
bio_set_dev(ctx->ra_bio, log->rdev->bdev);
bio_set_op_attrs(ctx->ra_bio, REQ_OP_READ, 0);
ctx->ra_bio->bi_iter.bi_sector = log->rdev->data_offset + offset;
ctx->valid_pages = 0;
ctx->pool_offset = offset;
while (ctx->valid_pages < ctx->total_pages) {
bio_add_page(ctx->ra_bio,
ctx->ra_pool[ctx->valid_pages], PAGE_SIZE, 0);
ctx->valid_pages += 1;
offset = r5l_ring_add(log, offset, BLOCK_SECTORS);
if (offset == 0) /* reached end of the device */
break;
}
return submit_bio_wait(ctx->ra_bio);
}
/*
* try read a page from the read ahead page pool, if the page is not in the
* pool, call r5l_recovery_fetch_ra_pool
*/
static int r5l_recovery_read_page(struct r5l_log *log,
struct r5l_recovery_ctx *ctx,
struct page *page,
sector_t offset)
{
int ret;
if (offset < ctx->pool_offset ||
offset >= ctx->pool_offset + ctx->valid_pages * BLOCK_SECTORS) {
ret = r5l_recovery_fetch_ra_pool(log, ctx, offset);
if (ret)
return ret;
}
BUG_ON(offset < ctx->pool_offset ||
offset >= ctx->pool_offset + ctx->valid_pages * BLOCK_SECTORS);
memcpy(page_address(page),
page_address(ctx->ra_pool[(offset - ctx->pool_offset) >>
BLOCK_SECTOR_SHIFT]),
PAGE_SIZE);
return 0;
}
static int r5l_recovery_read_meta_block(struct r5l_log *log,
struct r5l_recovery_ctx *ctx)
{
struct page *page = ctx->meta_page;
struct r5l_meta_block *mb;
u32 crc, stored_crc;
int ret;
ret = r5l_recovery_read_page(log, ctx, page, ctx->pos);
if (ret != 0)
return ret;
mb = page_address(page);
stored_crc = le32_to_cpu(mb->checksum);
mb->checksum = 0;
if (le32_to_cpu(mb->magic) != R5LOG_MAGIC ||
le64_to_cpu(mb->seq) != ctx->seq ||
mb->version != R5LOG_VERSION ||
le64_to_cpu(mb->position) != ctx->pos)
return -EINVAL;
crc = crc32c_le(log->uuid_checksum, mb, PAGE_SIZE);
if (stored_crc != crc)
return -EINVAL;
if (le32_to_cpu(mb->meta_size) > PAGE_SIZE)
return -EINVAL;
ctx->meta_total_blocks = BLOCK_SECTORS;
return 0;
}
static void
r5l_recovery_create_empty_meta_block(struct r5l_log *log,
struct page *page,
sector_t pos, u64 seq)
{
struct r5l_meta_block *mb;
mb = page_address(page);
clear_page(mb);
mb->magic = cpu_to_le32(R5LOG_MAGIC);
mb->version = R5LOG_VERSION;
mb->meta_size = cpu_to_le32(sizeof(struct r5l_meta_block));
mb->seq = cpu_to_le64(seq);
mb->position = cpu_to_le64(pos);
}
static int r5l_log_write_empty_meta_block(struct r5l_log *log, sector_t pos,
u64 seq)
{
struct page *page;
struct r5l_meta_block *mb;
page = alloc_page(GFP_KERNEL);
if (!page)
return -ENOMEM;
r5l_recovery_create_empty_meta_block(log, page, pos, seq);
mb = page_address(page);
mb->checksum = cpu_to_le32(crc32c_le(log->uuid_checksum,
mb, PAGE_SIZE));
if (!sync_page_io(log->rdev, pos, PAGE_SIZE, page, REQ_OP_WRITE,
REQ_SYNC | REQ_FUA, false)) {
__free_page(page);
return -EIO;
}
__free_page(page);
return 0;
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
/*
* r5l_recovery_load_data and r5l_recovery_load_parity uses flag R5_Wantwrite
* to mark valid (potentially not flushed) data in the journal.
*
* We already verified checksum in r5l_recovery_verify_data_checksum_for_mb,
* so there should not be any mismatch here.
*/
static void r5l_recovery_load_data(struct r5l_log *log,
struct stripe_head *sh,
struct r5l_recovery_ctx *ctx,
struct r5l_payload_data_parity *payload,
sector_t log_offset)
{
struct mddev *mddev = log->rdev->mddev;
struct r5conf *conf = mddev->private;
int dd_idx;
raid5_compute_sector(conf,
le64_to_cpu(payload->location), 0,
&dd_idx, sh);
r5l_recovery_read_page(log, ctx, sh->dev[dd_idx].page, log_offset);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
sh->dev[dd_idx].log_checksum =
le32_to_cpu(payload->checksum[0]);
ctx->meta_total_blocks += BLOCK_SECTORS;
set_bit(R5_Wantwrite, &sh->dev[dd_idx].flags);
set_bit(STRIPE_R5C_CACHING, &sh->state);
}
static void r5l_recovery_load_parity(struct r5l_log *log,
struct stripe_head *sh,
struct r5l_recovery_ctx *ctx,
struct r5l_payload_data_parity *payload,
sector_t log_offset)
{
struct mddev *mddev = log->rdev->mddev;
struct r5conf *conf = mddev->private;
ctx->meta_total_blocks += BLOCK_SECTORS * conf->max_degraded;
r5l_recovery_read_page(log, ctx, sh->dev[sh->pd_idx].page, log_offset);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
sh->dev[sh->pd_idx].log_checksum =
le32_to_cpu(payload->checksum[0]);
set_bit(R5_Wantwrite, &sh->dev[sh->pd_idx].flags);
if (sh->qd_idx >= 0) {
r5l_recovery_read_page(
log, ctx, sh->dev[sh->qd_idx].page,
r5l_ring_add(log, log_offset, BLOCK_SECTORS));
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
sh->dev[sh->qd_idx].log_checksum =
le32_to_cpu(payload->checksum[1]);
set_bit(R5_Wantwrite, &sh->dev[sh->qd_idx].flags);
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
clear_bit(STRIPE_R5C_CACHING, &sh->state);
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
static void r5l_recovery_reset_stripe(struct stripe_head *sh)
{
int i;
sh->state = 0;
sh->log_start = MaxSector;
for (i = sh->disks; i--; )
sh->dev[i].flags = 0;
}
static void
r5l_recovery_replay_one_stripe(struct r5conf *conf,
struct stripe_head *sh,
struct r5l_recovery_ctx *ctx)
{
struct md_rdev *rdev, *rrdev;
int disk_index;
int data_count = 0;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
for (disk_index = 0; disk_index < sh->disks; disk_index++) {
if (!test_bit(R5_Wantwrite, &sh->dev[disk_index].flags))
continue;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
if (disk_index == sh->qd_idx || disk_index == sh->pd_idx)
continue;
data_count++;
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
/*
* stripes that only have parity must have been flushed
* before the crash that we are now recovering from, so
* there is nothing more to recovery.
*/
if (data_count == 0)
goto out;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
for (disk_index = 0; disk_index < sh->disks; disk_index++) {
if (!test_bit(R5_Wantwrite, &sh->dev[disk_index].flags))
continue;
/* in case device is broken */
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
rcu_read_lock();
rdev = rcu_dereference(conf->disks[disk_index].rdev);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
if (rdev) {
atomic_inc(&rdev->nr_pending);
rcu_read_unlock();
sync_page_io(rdev, sh->sector, PAGE_SIZE,
sh->dev[disk_index].page, REQ_OP_WRITE, 0,
false);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
rdev_dec_pending(rdev, rdev->mddev);
rcu_read_lock();
}
rrdev = rcu_dereference(conf->disks[disk_index].replacement);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
if (rrdev) {
atomic_inc(&rrdev->nr_pending);
rcu_read_unlock();
sync_page_io(rrdev, sh->sector, PAGE_SIZE,
sh->dev[disk_index].page, REQ_OP_WRITE, 0,
false);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
rdev_dec_pending(rrdev, rrdev->mddev);
rcu_read_lock();
}
rcu_read_unlock();
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
ctx->data_parity_stripes++;
out:
r5l_recovery_reset_stripe(sh);
}
static struct stripe_head *
r5c_recovery_alloc_stripe(struct r5conf *conf,
sector_t stripe_sect)
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
{
struct stripe_head *sh;
sh = raid5_get_active_stripe(conf, stripe_sect, 0, 1, 0);
if (!sh)
return NULL; /* no more stripe available */
r5l_recovery_reset_stripe(sh);
return sh;
}
static struct stripe_head *
r5c_recovery_lookup_stripe(struct list_head *list, sector_t sect)
{
struct stripe_head *sh;
list_for_each_entry(sh, list, lru)
if (sh->sector == sect)
return sh;
return NULL;
}
static void
r5c_recovery_drop_stripes(struct list_head *cached_stripe_list,
struct r5l_recovery_ctx *ctx)
{
struct stripe_head *sh, *next;
list_for_each_entry_safe(sh, next, cached_stripe_list, lru) {
r5l_recovery_reset_stripe(sh);
list_del_init(&sh->lru);
raid5_release_stripe(sh);
}
}
static void
r5c_recovery_replay_stripes(struct list_head *cached_stripe_list,
struct r5l_recovery_ctx *ctx)
{
struct stripe_head *sh, *next;
list_for_each_entry_safe(sh, next, cached_stripe_list, lru)
if (!test_bit(STRIPE_R5C_CACHING, &sh->state)) {
r5l_recovery_replay_one_stripe(sh->raid_conf, sh, ctx);
list_del_init(&sh->lru);
raid5_release_stripe(sh);
}
}
/* if matches return 0; otherwise return -EINVAL */
static int
r5l_recovery_verify_data_checksum(struct r5l_log *log,
struct r5l_recovery_ctx *ctx,
struct page *page,
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
sector_t log_offset, __le32 log_checksum)
{
void *addr;
u32 checksum;
r5l_recovery_read_page(log, ctx, page, log_offset);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
addr = kmap_atomic(page);
checksum = crc32c_le(log->uuid_checksum, addr, PAGE_SIZE);
kunmap_atomic(addr);
return (le32_to_cpu(log_checksum) == checksum) ? 0 : -EINVAL;
}
/*
* before loading data to stripe cache, we need verify checksum for all data,
* if there is mismatch for any data page, we drop all data in the mata block
*/
static int
r5l_recovery_verify_data_checksum_for_mb(struct r5l_log *log,
struct r5l_recovery_ctx *ctx)
{
struct mddev *mddev = log->rdev->mddev;
struct r5conf *conf = mddev->private;
struct r5l_meta_block *mb = page_address(ctx->meta_page);
sector_t mb_offset = sizeof(struct r5l_meta_block);
sector_t log_offset = r5l_ring_add(log, ctx->pos, BLOCK_SECTORS);
struct page *page;
struct r5l_payload_data_parity *payload;
struct r5l_payload_flush *payload_flush;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
page = alloc_page(GFP_KERNEL);
if (!page)
return -ENOMEM;
while (mb_offset < le32_to_cpu(mb->meta_size)) {
payload = (void *)mb + mb_offset;
payload_flush = (void *)mb + mb_offset;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
if (le16_to_cpu(payload->header.type) == R5LOG_PAYLOAD_DATA) {
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
if (r5l_recovery_verify_data_checksum(
log, ctx, page, log_offset,
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
payload->checksum[0]) < 0)
goto mismatch;
} else if (le16_to_cpu(payload->header.type) == R5LOG_PAYLOAD_PARITY) {
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
if (r5l_recovery_verify_data_checksum(
log, ctx, page, log_offset,
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
payload->checksum[0]) < 0)
goto mismatch;
if (conf->max_degraded == 2 && /* q for RAID 6 */
r5l_recovery_verify_data_checksum(
log, ctx, page,
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
r5l_ring_add(log, log_offset,
BLOCK_SECTORS),
payload->checksum[1]) < 0)
goto mismatch;
} else if (le16_to_cpu(payload->header.type) == R5LOG_PAYLOAD_FLUSH) {
/* nothing to do for R5LOG_PAYLOAD_FLUSH here */
} else /* not R5LOG_PAYLOAD_DATA/PARITY/FLUSH */
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
goto mismatch;
if (le16_to_cpu(payload->header.type) == R5LOG_PAYLOAD_FLUSH) {
mb_offset += sizeof(struct r5l_payload_flush) +
le32_to_cpu(payload_flush->size);
} else {
/* DATA or PARITY payload */
log_offset = r5l_ring_add(log, log_offset,
le32_to_cpu(payload->size));
mb_offset += sizeof(struct r5l_payload_data_parity) +
sizeof(__le32) *
(le32_to_cpu(payload->size) >> (PAGE_SHIFT - 9));
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
}
put_page(page);
return 0;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
mismatch:
put_page(page);
return -EINVAL;
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
/*
* Analyze all data/parity pages in one meta block
* Returns:
* 0 for success
* -EINVAL for unknown playload type
* -EAGAIN for checksum mismatch of data page
* -ENOMEM for run out of memory (alloc_page failed or run out of stripes)
*/
static int
r5c_recovery_analyze_meta_block(struct r5l_log *log,
struct r5l_recovery_ctx *ctx,
struct list_head *cached_stripe_list)
{
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
struct mddev *mddev = log->rdev->mddev;
struct r5conf *conf = mddev->private;
struct r5l_meta_block *mb;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
struct r5l_payload_data_parity *payload;
struct r5l_payload_flush *payload_flush;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
int mb_offset;
sector_t log_offset;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
sector_t stripe_sect;
struct stripe_head *sh;
int ret;
/*
* for mismatch in data blocks, we will drop all data in this mb, but
* we will still read next mb for other data with FLUSH flag, as
* io_unit could finish out of order.
*/
ret = r5l_recovery_verify_data_checksum_for_mb(log, ctx);
if (ret == -EINVAL)
return -EAGAIN;
else if (ret)
return ret; /* -ENOMEM duo to alloc_page() failed */
mb = page_address(ctx->meta_page);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
mb_offset = sizeof(struct r5l_meta_block);
log_offset = r5l_ring_add(log, ctx->pos, BLOCK_SECTORS);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
while (mb_offset < le32_to_cpu(mb->meta_size)) {
int dd;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
payload = (void *)mb + mb_offset;
payload_flush = (void *)mb + mb_offset;
if (le16_to_cpu(payload->header.type) == R5LOG_PAYLOAD_FLUSH) {
int i, count;
count = le32_to_cpu(payload_flush->size) / sizeof(__le64);
for (i = 0; i < count; ++i) {
stripe_sect = le64_to_cpu(payload_flush->flush_stripes[i]);
sh = r5c_recovery_lookup_stripe(cached_stripe_list,
stripe_sect);
if (sh) {
WARN_ON(test_bit(STRIPE_R5C_CACHING, &sh->state));
r5l_recovery_reset_stripe(sh);
list_del_init(&sh->lru);
raid5_release_stripe(sh);
}
}
mb_offset += sizeof(struct r5l_payload_flush) +
le32_to_cpu(payload_flush->size);
continue;
}
/* DATA or PARITY payload */
stripe_sect = (le16_to_cpu(payload->header.type) == R5LOG_PAYLOAD_DATA) ?
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
raid5_compute_sector(
conf, le64_to_cpu(payload->location), 0, &dd,
NULL)
: le64_to_cpu(payload->location);
sh = r5c_recovery_lookup_stripe(cached_stripe_list,
stripe_sect);
if (!sh) {
sh = r5c_recovery_alloc_stripe(conf, stripe_sect);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
/*
* cannot get stripe from raid5_get_active_stripe
* try replay some stripes
*/
if (!sh) {
r5c_recovery_replay_stripes(
cached_stripe_list, ctx);
sh = r5c_recovery_alloc_stripe(
conf, stripe_sect);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
}
if (!sh) {
pr_debug("md/raid:%s: Increasing stripe cache size to %d to recovery data on journal.\n",
mdname(mddev),
conf->min_nr_stripes * 2);
raid5_set_cache_size(mddev,
conf->min_nr_stripes * 2);
sh = r5c_recovery_alloc_stripe(conf,
stripe_sect);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
}
if (!sh) {
pr_err("md/raid:%s: Cannot get enough stripes due to memory pressure. Recovery failed.\n",
mdname(mddev));
return -ENOMEM;
}
list_add_tail(&sh->lru, cached_stripe_list);
}
if (le16_to_cpu(payload->header.type) == R5LOG_PAYLOAD_DATA) {
if (!test_bit(STRIPE_R5C_CACHING, &sh->state) &&
test_bit(R5_Wantwrite, &sh->dev[sh->pd_idx].flags)) {
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
r5l_recovery_replay_one_stripe(conf, sh, ctx);
list_move_tail(&sh->lru, cached_stripe_list);
}
r5l_recovery_load_data(log, sh, ctx, payload,
log_offset);
} else if (le16_to_cpu(payload->header.type) == R5LOG_PAYLOAD_PARITY)
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
r5l_recovery_load_parity(log, sh, ctx, payload,
log_offset);
else
return -EINVAL;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
log_offset = r5l_ring_add(log, log_offset,
le32_to_cpu(payload->size));
mb_offset += sizeof(struct r5l_payload_data_parity) +
sizeof(__le32) *
(le32_to_cpu(payload->size) >> (PAGE_SHIFT - 9));
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
return 0;
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
/*
* Load the stripe into cache. The stripe will be written out later by
* the stripe cache state machine.
*/
static void r5c_recovery_load_one_stripe(struct r5l_log *log,
struct stripe_head *sh)
{
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
struct r5dev *dev;
int i;
for (i = sh->disks; i--; ) {
dev = sh->dev + i;
if (test_and_clear_bit(R5_Wantwrite, &dev->flags)) {
set_bit(R5_InJournal, &dev->flags);
set_bit(R5_UPTODATE, &dev->flags);
}
}
}
/*
* Scan through the log for all to-be-flushed data
*
* For stripes with data and parity, namely Data-Parity stripe
* (STRIPE_R5C_CACHING == 0), we simply replay all the writes.
*
* For stripes with only data, namely Data-Only stripe
* (STRIPE_R5C_CACHING == 1), we load them to stripe cache state machine.
*
* For a stripe, if we see data after parity, we should discard all previous
* data and parity for this stripe, as these data are already flushed to
* the array.
*
* At the end of the scan, we return the new journal_tail, which points to
* first data-only stripe on the journal device, or next invalid meta block.
*/
static int r5c_recovery_flush_log(struct r5l_log *log,
struct r5l_recovery_ctx *ctx)
{
struct stripe_head *sh;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
int ret = 0;
/* scan through the log */
while (1) {
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
if (r5l_recovery_read_meta_block(log, ctx))
break;
ret = r5c_recovery_analyze_meta_block(log, ctx,
&ctx->cached_list);
/*
* -EAGAIN means mismatch in data block, in this case, we still
* try scan the next metablock
*/
if (ret && ret != -EAGAIN)
break; /* ret == -EINVAL or -ENOMEM */
ctx->seq++;
ctx->pos = r5l_ring_add(log, ctx->pos, ctx->meta_total_blocks);
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
if (ret == -ENOMEM) {
r5c_recovery_drop_stripes(&ctx->cached_list, ctx);
return ret;
}
/* replay data-parity stripes */
r5c_recovery_replay_stripes(&ctx->cached_list, ctx);
/* load data-only stripes to stripe cache */
list_for_each_entry(sh, &ctx->cached_list, lru) {
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
WARN_ON(!test_bit(STRIPE_R5C_CACHING, &sh->state));
r5c_recovery_load_one_stripe(log, sh);
ctx->data_only_stripes++;
}
return 0;
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
/*
* we did a recovery. Now ctx.pos points to an invalid meta block. New
* log will start here. but we can't let superblock point to last valid
* meta block. The log might looks like:
* | meta 1| meta 2| meta 3|
* meta 1 is valid, meta 2 is invalid. meta 3 could be valid. If
* superblock points to meta 1, we write a new valid meta 2n. if crash
* happens again, new recovery will start from meta 1. Since meta 2n is
* valid now, recovery will think meta 3 is valid, which is wrong.
* The solution is we create a new meta in meta2 with its seq == meta
* 1's seq + 10000 and let superblock points to meta2. The same recovery
* will not think meta 3 is a valid meta, because its seq doesn't match
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
*/
/*
* Before recovery, the log looks like the following
*
* ---------------------------------------------
* | valid log | invalid log |
* ---------------------------------------------
* ^
* |- log->last_checkpoint
* |- log->last_cp_seq
*
* Now we scan through the log until we see invalid entry
*
* ---------------------------------------------
* | valid log | invalid log |
* ---------------------------------------------
* ^ ^
* |- log->last_checkpoint |- ctx->pos
* |- log->last_cp_seq |- ctx->seq
*
* From this point, we need to increase seq number by 10 to avoid
* confusing next recovery.
*
* ---------------------------------------------
* | valid log | invalid log |
* ---------------------------------------------
* ^ ^
* |- log->last_checkpoint |- ctx->pos+1
* |- log->last_cp_seq |- ctx->seq+10001
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
*
* However, it is not safe to start the state machine yet, because data only
* parities are not yet secured in RAID. To save these data only parities, we
* rewrite them from seq+11.
*
* -----------------------------------------------------------------
* | valid log | data only stripes | invalid log |
* -----------------------------------------------------------------
* ^ ^
* |- log->last_checkpoint |- ctx->pos+n
* |- log->last_cp_seq |- ctx->seq+10000+n
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
*
* If failure happens again during this process, the recovery can safe start
* again from log->last_checkpoint.
*
* Once data only stripes are rewritten to journal, we move log_tail
*
* -----------------------------------------------------------------
* | old log | data only stripes | invalid log |
* -----------------------------------------------------------------
* ^ ^
* |- log->last_checkpoint |- ctx->pos+n
* |- log->last_cp_seq |- ctx->seq+10000+n
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
*
* Then we can safely start the state machine. If failure happens from this
* point on, the recovery will start from new log->last_checkpoint.
*/
static int
r5c_recovery_rewrite_data_only_stripes(struct r5l_log *log,
struct r5l_recovery_ctx *ctx)
{
struct stripe_head *sh;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
struct mddev *mddev = log->rdev->mddev;
struct page *page;
sector_t next_checkpoint = MaxSector;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
page = alloc_page(GFP_KERNEL);
if (!page) {
pr_err("md/raid:%s: cannot allocate memory to rewrite data only stripes\n",
mdname(mddev));
return -ENOMEM;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
}
WARN_ON(list_empty(&ctx->cached_list));
list_for_each_entry(sh, &ctx->cached_list, lru) {
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
struct r5l_meta_block *mb;
int i;
int offset;
sector_t write_pos;
WARN_ON(!test_bit(STRIPE_R5C_CACHING, &sh->state));
r5l_recovery_create_empty_meta_block(log, page,
ctx->pos, ctx->seq);
mb = page_address(page);
offset = le32_to_cpu(mb->meta_size);
write_pos = r5l_ring_add(log, ctx->pos, BLOCK_SECTORS);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
for (i = sh->disks; i--; ) {
struct r5dev *dev = &sh->dev[i];
struct r5l_payload_data_parity *payload;
void *addr;
if (test_bit(R5_InJournal, &dev->flags)) {
payload = (void *)mb + offset;
payload->header.type = cpu_to_le16(
R5LOG_PAYLOAD_DATA);
payload->size = cpu_to_le32(BLOCK_SECTORS);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
payload->location = cpu_to_le64(
raid5_compute_blocknr(sh, i, 0));
addr = kmap_atomic(dev->page);
payload->checksum[0] = cpu_to_le32(
crc32c_le(log->uuid_checksum, addr,
PAGE_SIZE));
kunmap_atomic(addr);
sync_page_io(log->rdev, write_pos, PAGE_SIZE,
dev->page, REQ_OP_WRITE, 0, false);
write_pos = r5l_ring_add(log, write_pos,
BLOCK_SECTORS);
offset += sizeof(__le32) +
sizeof(struct r5l_payload_data_parity);
}
}
mb->meta_size = cpu_to_le32(offset);
mb->checksum = cpu_to_le32(crc32c_le(log->uuid_checksum,
mb, PAGE_SIZE));
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
sync_page_io(log->rdev, ctx->pos, PAGE_SIZE, page,
REQ_OP_WRITE, REQ_SYNC | REQ_FUA, false);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
sh->log_start = ctx->pos;
list_add_tail(&sh->r5c, &log->stripe_in_journal_list);
atomic_inc(&log->stripe_in_journal_count);
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
ctx->pos = write_pos;
ctx->seq += 1;
next_checkpoint = sh->log_start;
}
log->next_checkpoint = next_checkpoint;
__free_page(page);
return 0;
}
static void r5c_recovery_flush_data_only_stripes(struct r5l_log *log,
struct r5l_recovery_ctx *ctx)
{
struct mddev *mddev = log->rdev->mddev;
struct r5conf *conf = mddev->private;
struct stripe_head *sh, *next;
if (ctx->data_only_stripes == 0)
return;
log->r5c_journal_mode = R5C_JOURNAL_MODE_WRITE_BACK;
list_for_each_entry_safe(sh, next, &ctx->cached_list, lru) {
r5c_make_stripe_write_out(sh);
set_bit(STRIPE_HANDLE, &sh->state);
list_del_init(&sh->lru);
raid5_release_stripe(sh);
}
md_wakeup_thread(conf->mddev->thread);
/* reuse conf->wait_for_quiescent in recovery */
wait_event(conf->wait_for_quiescent,
atomic_read(&conf->active_stripes) == 0);
log->r5c_journal_mode = R5C_JOURNAL_MODE_WRITE_THROUGH;
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
static int r5l_recovery_log(struct r5l_log *log)
{
struct mddev *mddev = log->rdev->mddev;
struct r5l_recovery_ctx *ctx;
int ret;
sector_t pos;
ctx = kzalloc(sizeof(*ctx), GFP_KERNEL);
if (!ctx)
return -ENOMEM;
ctx->pos = log->last_checkpoint;
ctx->seq = log->last_cp_seq;
INIT_LIST_HEAD(&ctx->cached_list);
ctx->meta_page = alloc_page(GFP_KERNEL);
if (!ctx->meta_page) {
ret = -ENOMEM;
goto meta_page;
}
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
if (r5l_recovery_allocate_ra_pool(log, ctx) != 0) {
ret = -ENOMEM;
goto ra_pool;
}
ret = r5c_recovery_flush_log(log, ctx);
if (ret)
goto error;
pos = ctx->pos;
ctx->seq += 10000;
if ((ctx->data_only_stripes == 0) && (ctx->data_parity_stripes == 0))
pr_debug("md/raid:%s: starting from clean shutdown\n",
mdname(mddev));
else
pr_debug("md/raid:%s: recovering %d data-only stripes and %d data-parity stripes\n",
mdname(mddev), ctx->data_only_stripes,
ctx->data_parity_stripes);
if (ctx->data_only_stripes == 0) {
log->next_checkpoint = ctx->pos;
r5l_log_write_empty_meta_block(log, ctx->pos, ctx->seq++);
ctx->pos = r5l_ring_add(log, ctx->pos, BLOCK_SECTORS);
} else if (r5c_recovery_rewrite_data_only_stripes(log, ctx)) {
pr_err("md/raid:%s: failed to rewrite stripes to journal\n",
mdname(mddev));
ret = -EIO;
goto error;
md/r5cache: r5cache recovery: part 1 Recovery of write-back cache has different logic to write-through only cache. Specifically, for write-back cache, the recovery need to scan through all active journal entries before flushing data out. Therefore, large portion of the recovery logic is rewritten here. To make the diffs cleaner, we split the rewrite as follows: 1. In this patch, we: - add new data to r5l_recovery_ctx - add new functions to recovery write-back cache The new functions are not used in this patch, so this patch does not change the behavior of recovery. 2. In next patch, we: - modify main recovery procedure r5l_recovery_log() to call new functions - remove old functions With cache feature, there are 2 different scenarios of recovery: 1. Data-Parity stripe: a stripe with complete parity in journal. 2. Data-Only stripe: a stripe with only data in journal (or partial parity). The code differentiate Data-Parity stripe from Data-Only stripe with flag STRIPE_R5C_CACHING. For Data-Parity stripes, we use the same procedure as raid5 journal, where all the data and parity are replayed to the RAID devices. For Data-Only strips, we need to finish complete calculate parity and finish the full reconstruct write or RMW write. For simplicity, in the recovery, we load the stripe to stripe cache. Once the array is started, the stripe cache state machine will handle these stripes through normal write path. r5c_recovery_flush_log contains the main procedure of recovery. The recovery code first scans through the journal and loads data to stripe cache. The code keeps tracks of all these stripes in a list (use sh->lru and ctx->cached_list), stripes in the list are organized in the order of its first appearance on the journal. During the scan, the recovery code assesses each stripe as Data-Parity or Data-Only. During scan, the array may run out of stripe cache. In these cases, the recovery code will also call raid5_set_cache_size to increase stripe cache size. If the array still runs out of stripe cache because there isn't enough memory, the array will not assemble. At the end of scan, the recovery code replays all Data-Parity stripes, and sets proper states for Data-Only stripes. The recovery code also increases seq number by 10 and rewrites all Data-Only stripes to journal. This is to avoid confusion after repeated crashes. More details is explained in raid5-cache.c before r5c_recovery_rewrite_data_only_stripes(). Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:43 +08:00
}
log->log_start = ctx->pos;
log->seq = ctx->seq;
log->last_checkpoint = pos;
r5l_write_super(log, pos);
r5c_recovery_flush_data_only_stripes(log, ctx);
ret = 0;
error:
r5l_recovery_free_ra_pool(log, ctx);
ra_pool:
__free_page(ctx->meta_page);
meta_page:
kfree(ctx);
return ret;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
static void r5l_write_super(struct r5l_log *log, sector_t cp)
{
struct mddev *mddev = log->rdev->mddev;
log->rdev->journal_tail = cp;
set_bit(MD_SB_CHANGE_DEVS, &mddev->sb_flags);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
static ssize_t r5c_journal_mode_show(struct mddev *mddev, char *page)
{
struct r5conf *conf;
int ret;
ret = mddev_lock(mddev);
if (ret)
return ret;
conf = mddev->private;
if (!conf || !conf->log) {
mddev_unlock(mddev);
return 0;
}
switch (conf->log->r5c_journal_mode) {
case R5C_JOURNAL_MODE_WRITE_THROUGH:
ret = snprintf(
page, PAGE_SIZE, "[%s] %s\n",
r5c_journal_mode_str[R5C_JOURNAL_MODE_WRITE_THROUGH],
r5c_journal_mode_str[R5C_JOURNAL_MODE_WRITE_BACK]);
break;
case R5C_JOURNAL_MODE_WRITE_BACK:
ret = snprintf(
page, PAGE_SIZE, "%s [%s]\n",
r5c_journal_mode_str[R5C_JOURNAL_MODE_WRITE_THROUGH],
r5c_journal_mode_str[R5C_JOURNAL_MODE_WRITE_BACK]);
break;
default:
ret = 0;
}
mddev_unlock(mddev);
return ret;
}
/*
* Set journal cache mode on @mddev (external API initially needed by dm-raid).
*
* @mode as defined in 'enum r5c_journal_mode'.
*
*/
int r5c_journal_mode_set(struct mddev *mddev, int mode)
{
struct r5conf *conf;
int err;
if (mode < R5C_JOURNAL_MODE_WRITE_THROUGH ||
mode > R5C_JOURNAL_MODE_WRITE_BACK)
return -EINVAL;
err = mddev_lock(mddev);
if (err)
return err;
conf = mddev->private;
if (!conf || !conf->log) {
mddev_unlock(mddev);
return -ENODEV;
}
if (raid5_calc_degraded(conf) > 0 &&
mode == R5C_JOURNAL_MODE_WRITE_BACK) {
mddev_unlock(mddev);
return -EINVAL;
}
mddev_suspend(mddev);
conf->log->r5c_journal_mode = mode;
mddev_resume(mddev);
mddev_unlock(mddev);
pr_debug("md/raid:%s: setting r5c cache mode to %d: %s\n",
mdname(mddev), mode, r5c_journal_mode_str[mode]);
return 0;
}
EXPORT_SYMBOL(r5c_journal_mode_set);
static ssize_t r5c_journal_mode_store(struct mddev *mddev,
const char *page, size_t length)
{
int mode = ARRAY_SIZE(r5c_journal_mode_str);
size_t len = length;
if (len < 2)
return -EINVAL;
if (page[len - 1] == '\n')
len--;
while (mode--)
if (strlen(r5c_journal_mode_str[mode]) == len &&
!strncmp(page, r5c_journal_mode_str[mode], len))
break;
return r5c_journal_mode_set(mddev, mode) ?: length;
}
struct md_sysfs_entry
r5c_journal_mode = __ATTR(journal_mode, 0644,
r5c_journal_mode_show, r5c_journal_mode_store);
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
/*
* Try handle write operation in caching phase. This function should only
* be called in write-back mode.
*
* If all outstanding writes can be handled in caching phase, returns 0
* If writes requires write-out phase, call r5c_make_stripe_write_out()
* and returns -EAGAIN
*/
int r5c_try_caching_write(struct r5conf *conf,
struct stripe_head *sh,
struct stripe_head_state *s,
int disks)
{
struct r5l_log *log = conf->log;
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
int i;
struct r5dev *dev;
int to_cache = 0;
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
void **pslot;
sector_t tree_index;
int ret;
uintptr_t refcount;
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
BUG_ON(!r5c_is_writeback(log));
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
if (!test_bit(STRIPE_R5C_CACHING, &sh->state)) {
/*
* There are two different scenarios here:
* 1. The stripe has some data cached, and it is sent to
* write-out phase for reclaim
* 2. The stripe is clean, and this is the first write
*
* For 1, return -EAGAIN, so we continue with
* handle_stripe_dirtying().
*
* For 2, set STRIPE_R5C_CACHING and continue with caching
* write.
*/
/* case 1: anything injournal or anything in written */
if (s->injournal > 0 || s->written > 0)
return -EAGAIN;
/* case 2 */
set_bit(STRIPE_R5C_CACHING, &sh->state);
}
/*
* When run in degraded mode, array is set to write-through mode.
* This check helps drain pending write safely in the transition to
* write-through mode.
*
* When a stripe is syncing, the write is also handled in write
* through mode.
*/
if (s->failed || test_bit(STRIPE_SYNCING, &sh->state)) {
r5c_make_stripe_write_out(sh);
return -EAGAIN;
}
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
for (i = disks; i--; ) {
dev = &sh->dev[i];
/* if non-overwrite, use writing-out phase */
if (dev->towrite && !test_bit(R5_OVERWRITE, &dev->flags) &&
!test_bit(R5_InJournal, &dev->flags)) {
r5c_make_stripe_write_out(sh);
return -EAGAIN;
}
}
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
/* if the stripe is not counted in big_stripe_tree, add it now */
if (!test_bit(STRIPE_R5C_PARTIAL_STRIPE, &sh->state) &&
!test_bit(STRIPE_R5C_FULL_STRIPE, &sh->state)) {
tree_index = r5c_tree_index(conf, sh->sector);
spin_lock(&log->tree_lock);
pslot = radix_tree_lookup_slot(&log->big_stripe_tree,
tree_index);
if (pslot) {
refcount = (uintptr_t)radix_tree_deref_slot_protected(
pslot, &log->tree_lock) >>
R5C_RADIX_COUNT_SHIFT;
radix_tree_replace_slot(
&log->big_stripe_tree, pslot,
(void *)((refcount + 1) << R5C_RADIX_COUNT_SHIFT));
} else {
/*
* this radix_tree_insert can fail safely, so no
* need to call radix_tree_preload()
*/
ret = radix_tree_insert(
&log->big_stripe_tree, tree_index,
(void *)(1 << R5C_RADIX_COUNT_SHIFT));
if (ret) {
spin_unlock(&log->tree_lock);
r5c_make_stripe_write_out(sh);
return -EAGAIN;
}
}
spin_unlock(&log->tree_lock);
/*
* set STRIPE_R5C_PARTIAL_STRIPE, this shows the stripe is
* counted in the radix tree
*/
set_bit(STRIPE_R5C_PARTIAL_STRIPE, &sh->state);
atomic_inc(&conf->r5c_cached_partial_stripes);
}
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
for (i = disks; i--; ) {
dev = &sh->dev[i];
if (dev->towrite) {
set_bit(R5_Wantwrite, &dev->flags);
set_bit(R5_Wantdrain, &dev->flags);
set_bit(R5_LOCKED, &dev->flags);
to_cache++;
}
}
if (to_cache) {
set_bit(STRIPE_OP_BIODRAIN, &s->ops_request);
/*
* set STRIPE_LOG_TRAPPED, which triggers r5c_cache_data()
* in ops_run_io(). STRIPE_LOG_TRAPPED will be cleared in
* r5c_handle_data_cached()
*/
set_bit(STRIPE_LOG_TRAPPED, &sh->state);
}
return 0;
}
/*
* free extra pages (orig_page) we allocated for prexor
*/
void r5c_release_extra_page(struct stripe_head *sh)
{
struct r5conf *conf = sh->raid_conf;
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
int i;
bool using_disk_info_extra_page;
using_disk_info_extra_page =
sh->dev[0].orig_page == conf->disks[0].extra_page;
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
for (i = sh->disks; i--; )
if (sh->dev[i].page != sh->dev[i].orig_page) {
struct page *p = sh->dev[i].orig_page;
sh->dev[i].orig_page = sh->dev[i].page;
clear_bit(R5_OrigPageUPTDODATE, &sh->dev[i].flags);
if (!using_disk_info_extra_page)
put_page(p);
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
}
if (using_disk_info_extra_page) {
clear_bit(R5C_EXTRA_PAGE_IN_USE, &conf->cache_state);
md_wakeup_thread(conf->mddev->thread);
}
}
void r5c_use_extra_page(struct stripe_head *sh)
{
struct r5conf *conf = sh->raid_conf;
int i;
struct r5dev *dev;
for (i = sh->disks; i--; ) {
dev = &sh->dev[i];
if (dev->orig_page != dev->page)
put_page(dev->orig_page);
dev->orig_page = conf->disks[i].extra_page;
}
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
}
/*
* clean up the stripe (clear R5_InJournal for dev[pd_idx] etc.) after the
* stripe is committed to RAID disks.
*/
void r5c_finish_stripe_write_out(struct r5conf *conf,
struct stripe_head *sh,
struct stripe_head_state *s)
{
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
struct r5l_log *log = conf->log;
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
int i;
int do_wakeup = 0;
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
sector_t tree_index;
void **pslot;
uintptr_t refcount;
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
if (!log || !test_bit(R5_InJournal, &sh->dev[sh->pd_idx].flags))
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
return;
WARN_ON(test_bit(STRIPE_R5C_CACHING, &sh->state));
clear_bit(R5_InJournal, &sh->dev[sh->pd_idx].flags);
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
if (log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_THROUGH)
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
return;
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
for (i = sh->disks; i--; ) {
clear_bit(R5_InJournal, &sh->dev[i].flags);
if (test_and_clear_bit(R5_Overlap, &sh->dev[i].flags))
do_wakeup = 1;
}
/*
* analyse_stripe() runs before r5c_finish_stripe_write_out(),
* We updated R5_InJournal, so we also update s->injournal.
*/
s->injournal = 0;
if (test_and_clear_bit(STRIPE_FULL_WRITE, &sh->state))
if (atomic_dec_and_test(&conf->pending_full_writes))
md_wakeup_thread(conf->mddev->thread);
if (do_wakeup)
wake_up(&conf->wait_for_overlap);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
spin_lock_irq(&log->stripe_in_journal_lock);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
list_del_init(&sh->r5c);
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
spin_unlock_irq(&log->stripe_in_journal_lock);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
sh->log_start = MaxSector;
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
atomic_dec(&log->stripe_in_journal_count);
r5c_update_log_state(log);
/* stop counting this stripe in big_stripe_tree */
if (test_bit(STRIPE_R5C_PARTIAL_STRIPE, &sh->state) ||
test_bit(STRIPE_R5C_FULL_STRIPE, &sh->state)) {
tree_index = r5c_tree_index(conf, sh->sector);
spin_lock(&log->tree_lock);
pslot = radix_tree_lookup_slot(&log->big_stripe_tree,
tree_index);
BUG_ON(pslot == NULL);
refcount = (uintptr_t)radix_tree_deref_slot_protected(
pslot, &log->tree_lock) >>
R5C_RADIX_COUNT_SHIFT;
if (refcount == 1)
radix_tree_delete(&log->big_stripe_tree, tree_index);
else
radix_tree_replace_slot(
&log->big_stripe_tree, pslot,
(void *)((refcount - 1) << R5C_RADIX_COUNT_SHIFT));
spin_unlock(&log->tree_lock);
}
if (test_and_clear_bit(STRIPE_R5C_PARTIAL_STRIPE, &sh->state)) {
BUG_ON(atomic_read(&conf->r5c_cached_partial_stripes) == 0);
atomic_dec(&conf->r5c_flushing_partial_stripes);
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
atomic_dec(&conf->r5c_cached_partial_stripes);
}
if (test_and_clear_bit(STRIPE_R5C_FULL_STRIPE, &sh->state)) {
BUG_ON(atomic_read(&conf->r5c_cached_full_stripes) == 0);
atomic_dec(&conf->r5c_flushing_full_stripes);
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
atomic_dec(&conf->r5c_cached_full_stripes);
}
r5l_append_flush_payload(log, sh->sector);
/* stripe is flused to raid disks, we can do resync now */
if (test_bit(STRIPE_SYNC_REQUESTED, &sh->state))
set_bit(STRIPE_HANDLE, &sh->state);
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
}
int r5c_cache_data(struct r5l_log *log, struct stripe_head *sh)
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
{
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
struct r5conf *conf = sh->raid_conf;
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
int pages = 0;
int reserve;
int i;
int ret = 0;
BUG_ON(!log);
for (i = 0; i < sh->disks; i++) {
void *addr;
if (!test_bit(R5_Wantwrite, &sh->dev[i].flags))
continue;
addr = kmap_atomic(sh->dev[i].page);
sh->dev[i].log_checksum = crc32c_le(log->uuid_checksum,
addr, PAGE_SIZE);
kunmap_atomic(addr);
pages++;
}
WARN_ON(pages == 0);
/*
* The stripe must enter state machine again to call endio, so
* don't delay.
*/
clear_bit(STRIPE_DELAYED, &sh->state);
atomic_inc(&sh->count);
mutex_lock(&log->io_mutex);
/* meta + data */
reserve = (1 + pages) << (PAGE_SHIFT - 9);
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
if (test_bit(R5C_LOG_CRITICAL, &conf->cache_state) &&
sh->log_start == MaxSector)
r5l_add_no_space_stripe(log, sh);
else if (!r5l_has_free_space(log, reserve)) {
if (sh->log_start == log->last_checkpoint)
BUG();
else
r5l_add_no_space_stripe(log, sh);
md/r5cache: caching phase of r5cache As described in previous patch, write back cache operates in two phases: caching and writing-out. The caching phase works as: 1. write data to journal (r5c_handle_stripe_dirtying, r5c_cache_data) 2. call bio_endio (r5c_handle_data_cached, r5c_return_dev_pending_writes). Then the writing-out phase is as: 1. Mark the stripe as write-out (r5c_make_stripe_write_out) 2. Calcualte parity (reconstruct or RMW) 3. Write parity (and maybe some other data) to journal device 4. Write data and parity to RAID disks This patch implements caching phase. The cache is integrated with stripe cache of raid456. It leverages code of r5l_log to write data to journal device. Writing-out phase of the cache is implemented in the next patch. With r5cache, write operation does not wait for parity calculation and write out, so the write latency is lower (1 write to journal device vs. read and then write to raid disks). Also, r5cache will reduce RAID overhead (multipile IO due to read-modify-write of parity) and provide more opportunities of full stripe writes. This patch adds 2 flags to stripe_head.state: - STRIPE_R5C_PARTIAL_STRIPE, - STRIPE_R5C_FULL_STRIPE, Instead of inactive_list, stripes with cached data are tracked in r5conf->r5c_full_stripe_list and r5conf->r5c_partial_stripe_list. STRIPE_R5C_FULL_STRIPE and STRIPE_R5C_PARTIAL_STRIPE are flags for stripes in these lists. Note: stripes in r5c_full/partial_stripe_list are not considered as "active". For RMW, the code allocates an extra page for each data block being updated. This is stored in r5dev->orig_page and the old data is read into it. Then the prexor calculation subtracts ->orig_page from the parity block, and the reconstruct calculation adds the ->page data back into the parity block. r5cache naturally excludes SkipCopy. When the array has write back cache, async_copy_data() will not skip copy. There are some known limitations of the cache implementation: 1. Write cache only covers full page writes (R5_OVERWRITE). Writes of smaller granularity are write through. 2. Only one log io (sh->log_io) for each stripe at anytime. Later writes for the same stripe have to wait. This can be improved by moving log_io to r5dev. 3. With writeback cache, read path must enter state machine, which is a significant bottleneck for some workloads. 4. There is no per stripe checkpoint (with r5l_payload_flush) in the log, so recovery code has to replay more than necessary data (sometimes all the log from last_checkpoint). This reduces availability of the array. This patch includes a fix proposed by ZhengYuan Liu <liuzhengyuan@kylinos.cn> Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:39 +08:00
} else {
ret = r5l_log_stripe(log, sh, pages, 0);
if (ret) {
spin_lock_irq(&log->io_list_lock);
list_add_tail(&sh->log_list, &log->no_mem_stripes);
spin_unlock_irq(&log->io_list_lock);
}
}
mutex_unlock(&log->io_mutex);
return 0;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
}
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
/* check whether this big stripe is in write back cache. */
bool r5c_big_stripe_cached(struct r5conf *conf, sector_t sect)
{
struct r5l_log *log = conf->log;
sector_t tree_index;
void *slot;
if (!log)
return false;
WARN_ON_ONCE(!rcu_read_lock_held());
tree_index = r5c_tree_index(conf, sect);
slot = radix_tree_lookup(&log->big_stripe_tree, tree_index);
return slot != NULL;
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
static int r5l_load_log(struct r5l_log *log)
{
struct md_rdev *rdev = log->rdev;
struct page *page;
struct r5l_meta_block *mb;
sector_t cp = log->rdev->journal_tail;
u32 stored_crc, expected_crc;
bool create_super = false;
int ret = 0;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
/* Make sure it's valid */
if (cp >= rdev->sectors || round_down(cp, BLOCK_SECTORS) != cp)
cp = 0;
page = alloc_page(GFP_KERNEL);
if (!page)
return -ENOMEM;
if (!sync_page_io(rdev, cp, PAGE_SIZE, page, REQ_OP_READ, 0, false)) {
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
ret = -EIO;
goto ioerr;
}
mb = page_address(page);
if (le32_to_cpu(mb->magic) != R5LOG_MAGIC ||
mb->version != R5LOG_VERSION) {
create_super = true;
goto create;
}
stored_crc = le32_to_cpu(mb->checksum);
mb->checksum = 0;
expected_crc = crc32c_le(log->uuid_checksum, mb, PAGE_SIZE);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
if (stored_crc != expected_crc) {
create_super = true;
goto create;
}
if (le64_to_cpu(mb->position) != cp) {
create_super = true;
goto create;
}
create:
if (create_super) {
log->last_cp_seq = prandom_u32();
cp = 0;
r5l_log_write_empty_meta_block(log, cp, log->last_cp_seq);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
/*
* Make sure super points to correct address. Log might have
* data very soon. If super hasn't correct log tail address,
* recovery can't find the log
*/
r5l_write_super(log, cp);
} else
log->last_cp_seq = le64_to_cpu(mb->seq);
log->device_size = round_down(rdev->sectors, BLOCK_SECTORS);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
log->max_free_space = log->device_size >> RECLAIM_MAX_FREE_SPACE_SHIFT;
if (log->max_free_space > RECLAIM_MAX_FREE_SPACE)
log->max_free_space = RECLAIM_MAX_FREE_SPACE;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
log->last_checkpoint = cp;
__free_page(page);
if (create_super) {
log->log_start = r5l_ring_add(log, cp, BLOCK_SECTORS);
log->seq = log->last_cp_seq + 1;
log->next_checkpoint = cp;
} else
ret = r5l_recovery_log(log);
r5c_update_log_state(log);
return ret;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
ioerr:
__free_page(page);
return ret;
}
void r5c_update_on_rdev_error(struct mddev *mddev, struct md_rdev *rdev)
{
struct r5conf *conf = mddev->private;
struct r5l_log *log = conf->log;
if (!log)
return;
if ((raid5_calc_degraded(conf) > 0 ||
test_bit(Journal, &rdev->flags)) &&
conf->log->r5c_journal_mode == R5C_JOURNAL_MODE_WRITE_BACK)
schedule_work(&log->disable_writeback_work);
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
int r5l_init_log(struct r5conf *conf, struct md_rdev *rdev)
{
struct request_queue *q = bdev_get_queue(rdev->bdev);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
struct r5l_log *log;
char b[BDEVNAME_SIZE];
pr_debug("md/raid:%s: using device %s as journal\n",
mdname(conf->mddev), bdevname(rdev->bdev, b));
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
if (PAGE_SIZE != 4096)
return -EINVAL;
/*
* The PAGE_SIZE must be big enough to hold 1 r5l_meta_block and
* raid_disks r5l_payload_data_parity.
*
* Write journal and cache does not work for very big array
* (raid_disks > 203)
*/
if (sizeof(struct r5l_meta_block) +
((sizeof(struct r5l_payload_data_parity) + sizeof(__le32)) *
conf->raid_disks) > PAGE_SIZE) {
pr_err("md/raid:%s: write journal/cache doesn't work for array with %d disks\n",
mdname(conf->mddev), conf->raid_disks);
return -EINVAL;
}
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
log = kzalloc(sizeof(*log), GFP_KERNEL);
if (!log)
return -ENOMEM;
log->rdev = rdev;
log->need_cache_flush = test_bit(QUEUE_FLAG_WC, &q->queue_flags) != 0;
log->uuid_checksum = crc32c_le(~0, rdev->mddev->uuid,
sizeof(rdev->mddev->uuid));
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
mutex_init(&log->io_mutex);
spin_lock_init(&log->io_list_lock);
INIT_LIST_HEAD(&log->running_ios);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
INIT_LIST_HEAD(&log->io_end_ios);
INIT_LIST_HEAD(&log->flushing_ios);
INIT_LIST_HEAD(&log->finished_ios);
bio_init(&log->flush_bio, NULL, 0);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
log->io_kc = KMEM_CACHE(r5l_io_unit, 0);
if (!log->io_kc)
goto io_kc;
log->io_pool = mempool_create_slab_pool(R5L_POOL_SIZE, log->io_kc);
if (!log->io_pool)
goto io_pool;
log->bs = bioset_create(R5L_POOL_SIZE, 0, BIOSET_NEED_BVECS);
if (!log->bs)
goto io_bs;
log->meta_pool = mempool_create_page_pool(R5L_POOL_SIZE, 0);
if (!log->meta_pool)
goto out_mempool;
md/r5cache: enable chunk_aligned_read with write back cache Chunk aligned read significantly reduces CPU usage of raid456. However, it is not safe to fully bypass the write back cache. This patch enables chunk aligned read with write back cache. For chunk aligned read, we track stripes in write back cache at a bigger granularity, "big_stripe". Each chunk may contain more than one stripe (for example, a 256kB chunk contains 64 4kB-page, so this chunk contain 64 stripes). For chunk_aligned_read, these stripes are grouped into one big_stripe, so we only need one lookup for the whole chunk. For each big_stripe, struct big_stripe_info tracks how many stripes of this big_stripe are in the write back cache. We count how many stripes of this big_stripe are in the write back cache. These counters are tracked in a radix tree (big_stripe_tree). r5c_tree_index() is used to calculate keys for the radix tree. chunk_aligned_read() calls r5c_big_stripe_cached() to look up big_stripe of each chunk in the tree. If this big_stripe is in the tree, chunk_aligned_read() aborts. This look up is protected by rcu_read_lock(). It is necessary to remember whether a stripe is counted in big_stripe_tree. Instead of adding new flag, we reuses existing flags: STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE. If either of these two flags are set, the stripe is counted in big_stripe_tree. This requires moving set_bit(STRIPE_R5C_PARTIAL_STRIPE) to r5c_try_caching_write(); and moving clear_bit of STRIPE_R5C_PARTIAL_STRIPE and STRIPE_R5C_FULL_STRIPE to r5c_finish_stripe_write_out(). Signed-off-by: Song Liu <songliubraving@fb.com> Reviewed-by: NeilBrown <neilb@suse.com> Signed-off-by: Shaohua Li <shli@fb.com>
2017-01-12 05:39:14 +08:00
spin_lock_init(&log->tree_lock);
INIT_RADIX_TREE(&log->big_stripe_tree, GFP_NOWAIT | __GFP_NOWARN);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
log->reclaim_thread = md_register_thread(r5l_reclaim_thread,
log->rdev->mddev, "reclaim");
if (!log->reclaim_thread)
goto reclaim_thread;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
log->reclaim_thread->timeout = R5C_RECLAIM_WAKEUP_INTERVAL;
init_waitqueue_head(&log->iounit_wait);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
INIT_LIST_HEAD(&log->no_mem_stripes);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
INIT_LIST_HEAD(&log->no_space_stripes);
spin_lock_init(&log->no_space_stripes_lock);
INIT_WORK(&log->deferred_io_work, r5l_submit_io_async);
INIT_WORK(&log->disable_writeback_work, r5c_disable_writeback_async);
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
log->r5c_journal_mode = R5C_JOURNAL_MODE_WRITE_THROUGH;
md/r5cache: write-out phase and reclaim support There are two limited resources, stripe cache and journal disk space. For better performance, we priotize reclaim of full stripe writes. To free up more journal space, we free earliest data on the journal. In current implementation, reclaim happens when: 1. Periodically (every R5C_RECLAIM_WAKEUP_INTERVAL, 30 seconds) reclaim if there is no reclaim in the past 5 seconds. 2. when there are R5C_FULL_STRIPE_FLUSH_BATCH (256) cached full stripes, or cached stripes is enough for a full stripe (chunk size / 4k) (r5c_check_cached_full_stripe) 3. when there is pressure on stripe cache (r5c_check_stripe_cache_usage) 4. when there is pressure on journal space (r5l_write_stripe, r5c_cache_data) r5c_do_reclaim() contains new logic of reclaim. For stripe cache: When stripe cache pressure is high (more than 3/4 stripes are cached, or there is empty inactive lists), flush all full stripe. If fewer than R5C_RECLAIM_STRIPE_GROUP (NR_STRIPE_HASH_LOCKS * 2) full stripes are flushed, flush some paritial stripes. When stripe cache pressure is moderate (1/2 to 3/4 of stripes are cached), flush all full stripes. For log space: To avoid deadlock due to log space, we need to reserve enough space to flush cached data. The size of required log space depends on total number of cached stripes (stripe_in_journal_count). In current implementation, the writing-out phase automatically include pending data writes with parity writes (similar to write through case). Therefore, we need up to (conf->raid_disks + 1) pages for each cached stripe (1 page for meta data, raid_disks pages for all data and parity). r5c_log_required_to_flush_cache() calculates log space required to flush cache. In the following, we refer to the space calculated by r5c_log_required_to_flush_cache() as reclaim_required_space. Two flags are added to r5conf->cache_state: R5C_LOG_TIGHT and R5C_LOG_CRITICAL. R5C_LOG_TIGHT is set when free space on the log device is less than 3x of reclaim_required_space. R5C_LOG_CRITICAL is set when free space on the log device is less than 2x of reclaim_required_space. r5c_cache keeps all data in cache (not fully committed to RAID) in a list (stripe_in_journal_list). These stripes are in the order of their first appearance on the journal. So the log tail (last_checkpoint) should point to the journal_start of the first item in the list. When R5C_LOG_TIGHT is set, r5l_reclaim_thread starts flushing out stripes at the head of stripe_in_journal. When R5C_LOG_CRITICAL is set, the state machine only writes data that are already in the log device (in stripe_in_journal_list). This patch includes a fix to improve performance by Shaohua Li <shli@fb.com>. Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:40 +08:00
INIT_LIST_HEAD(&log->stripe_in_journal_list);
spin_lock_init(&log->stripe_in_journal_lock);
atomic_set(&log->stripe_in_journal_count, 0);
md/r5cache: State machine for raid5-cache write back mode This patch adds state machine for raid5-cache. With log device, the raid456 array could operate in two different modes (r5c_journal_mode): - write-back (R5C_MODE_WRITE_BACK) - write-through (R5C_MODE_WRITE_THROUGH) Existing code of raid5-cache only has write-through mode. For write-back cache, it is necessary to extend the state machine. With write-back cache, every stripe could operate in two different phases: - caching - writing-out In caching phase, the stripe handles writes as: - write to journal - return IO In writing-out phase, the stripe behaviors as a stripe in write through mode R5C_MODE_WRITE_THROUGH. STRIPE_R5C_CACHING is added to sh->state to differentiate caching and writing-out phase. Please note: this is a "no-op" patch for raid5-cache write-through mode. The following detailed explanation is copied from the raid5-cache.c: /* * raid5 cache state machine * * With rhe RAID cache, each stripe works in two phases: * - caching phase * - writing-out phase * * These two phases are controlled by bit STRIPE_R5C_CACHING: * if STRIPE_R5C_CACHING == 0, the stripe is in writing-out phase * if STRIPE_R5C_CACHING == 1, the stripe is in caching phase * * When there is no journal, or the journal is in write-through mode, * the stripe is always in writing-out phase. * * For write-back journal, the stripe is sent to caching phase on write * (r5c_handle_stripe_dirtying). r5c_make_stripe_write_out() kicks off * the write-out phase by clearing STRIPE_R5C_CACHING. * * Stripes in caching phase do not write the raid disks. Instead, all * writes are committed from the log device. Therefore, a stripe in * caching phase handles writes as: * - write to log device * - return IO * * Stripes in writing-out phase handle writes as: * - calculate parity * - write pending data and parity to journal * - write data and parity to raid disks * - return IO for pending writes */ Signed-off-by: Song Liu <songliubraving@fb.com> Signed-off-by: Shaohua Li <shli@fb.com>
2016-11-18 07:24:38 +08:00
rcu_assign_pointer(conf->log, log);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
if (r5l_load_log(log))
goto error;
set_bit(MD_HAS_JOURNAL, &conf->mddev->flags);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
return 0;
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
error:
rcu_assign_pointer(conf->log, NULL);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
md_unregister_thread(&log->reclaim_thread);
reclaim_thread:
mempool_destroy(log->meta_pool);
out_mempool:
bioset_free(log->bs);
io_bs:
mempool_destroy(log->io_pool);
io_pool:
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
kmem_cache_destroy(log->io_kc);
io_kc:
kfree(log);
return -EINVAL;
}
void r5l_exit_log(struct r5conf *conf)
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
{
struct r5l_log *log = conf->log;
conf->log = NULL;
synchronize_rcu();
/* Ensure disable_writeback_work wakes up and exits */
wake_up(&conf->mddev->sb_wait);
flush_work(&log->disable_writeback_work);
raid5: log reclaim support This is the reclaim support for raid5 log. A stripe write will have following steps: 1. reconstruct the stripe, read data/calculate parity. ops_run_io prepares to write data/parity to raid disks 2. hijack ops_run_io. stripe data/parity is appending to log disk 3. flush log disk cache 4. ops_run_io run again and do normal operation. stripe data/parity is written in raid array disks. raid core can return io to upper layer. 5. flush cache of all raid array disks 6. update super block 7. log disk space used by the stripe can be reused In practice, several stripes consist of an io_unit and we will batch several io_unit in different steps, but the whole process doesn't change. It's possible io return just after data/parity hit log disk, but then read IO will need read from log disk. For simplicity, IO return happens at step 4, where read IO can directly read from raid disks. Currently reclaim run if there is specific reclaimable space (1/4 disk size or 10G) or we are out of space. Reclaim is just to free log disk spaces, it doesn't impact data consistency. The size based force reclaim is to make sure log isn't too big, so recovery doesn't scan log too much. Recovery make sure raid disks and log disk have the same data of a stripe. If crash happens before 4, recovery might/might not recovery stripe's data/parity depending on if data/parity and its checksum matches. In either case, this doesn't change the syntax of an IO write. After step 3, stripe is guaranteed recoverable, because stripe's data/parity is persistent in log disk. In some cases, log disk content and raid disks content of a stripe are the same, but recovery will still copy log disk content to raid disks, this doesn't impact data consistency. space reuse happens after superblock update and cache flush. There is one situation we want to avoid. A broken meta in the middle of a log causes recovery can't find meta at the head of log. If operations require meta at the head persistent in log, we must make sure meta before it persistent in log too. The case is stripe data/parity is in log and we start write stripe to raid disks (before step 4). stripe data/parity must be persistent in log before we do the write to raid disks. The solution is we restrictly maintain io_unit list order. In this case, we only write stripes of an io_unit to raid disks till the io_unit is the first one whose data/parity is in log. The io_unit list order is important for other cases too. For example, some io_unit are reclaimable and others not. They can be mixed in the list, we shouldn't reuse space of an unreclaimable io_unit. Includes fixes to problems which were... Reported-by: kbuild test robot <fengguang.wu@intel.com> Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:32:00 +08:00
md_unregister_thread(&log->reclaim_thread);
mempool_destroy(log->meta_pool);
bioset_free(log->bs);
mempool_destroy(log->io_pool);
raid5: add basic stripe log This introduces a simple log for raid5. Data/parity writing to raid array first writes to the log, then write to raid array disks. If crash happens, we can recovery data from the log. This can speed up raid resync and fix write hole issue. The log structure is pretty simple. Data/meta data is stored in block unit, which is 4k generally. It has only one type of meta data block. The meta data block can track 3 types of data, stripe data, stripe parity and flush block. MD superblock will point to the last valid meta data block. Each meta data block has checksum/seq number, so recovery can scan the log correctly. We store a checksum of stripe data/parity to the metadata block, so meta data and stripe data/parity can be written to log disk together. otherwise, meta data write must wait till stripe data/parity is finished. For stripe data, meta data block will record stripe data sector and size. Currently the size is always 4k. This meta data record can be made simpler if we just fix write hole (eg, we can record data of a stripe's different disks together), but this format can be extended to support caching in the future, which must record data address/size. For stripe parity, meta data block will record stripe sector. It's size should be 4k (for raid5) or 8k (for raid6). We always store p parity first. This format should work for caching too. flush block indicates a stripe is in raid array disks. Fixing write hole doesn't need this type of meta data, it's for caching extension. Signed-off-by: Shaohua Li <shli@fb.com> Signed-off-by: NeilBrown <neilb@suse.com>
2015-08-14 05:31:59 +08:00
kmem_cache_destroy(log->io_kc);
kfree(log);
}