linux/drivers/gpu/host1x/cdma.c
Linus Torvalds a13de74e47 IOMMU Updates for Linux v6.3:
Including:
 
 	- Consolidate iommu_map/unmap functions. There have been
 	  blocking and atomic variants so far, but that was problematic
 	  as this approach does not scale with required new variants
 	  which just differ in the GFP flags used.
 	  So Jason consolidated this back into single functions that
 	  take a GFP parameter. This has the potential to cause
 	  conflicts with other trees, as they introduce new call-sites
 	  for the changed functions. I offered them to pull in the
 	  branch containing these changes and resolve it, but I am not
 	  sure everyone did that. The conflicts this caused with
 	  upstream up to v6.2-rc8 are resolved in the final merge
 	  commit.
 
 	- Retire the detach_dev() call-back in iommu_ops
 
 	- Arm SMMU updates from Will:
 	  - Device-tree binding updates:
 	    * Cater for three power domains on SM6375
 	    * Document existing compatible strings for Qualcomm SoCs
 	    * Tighten up clocks description for platform-specific compatible strings
 	  - Enable Qualcomm workarounds for some additional platforms that need them
 
 	- Intel VT-d updates from Lu Baolu:
 	  - Add Intel IOMMU performance monitoring support
 	  - Set No Execute Enable bit in PASID table entry
 	  - Two performance optimizations
 	  - Fix PASID directory pointer coherency
 	  - Fix missed rollbacks in error path
 	  - Cleanups
 
 	- Apple t8110 DART support
 
 	- Exynos IOMMU:
 	  - Implement better fault handling
 	  - Error handling fixes
 
 	- Renesas IPMMU:
 	  - Add device tree bindings for r8a779g0
 
 	- AMD IOMMU:
 	  - Various fixes for handling on SNP-enabled systems and
 	    handling of faults with unknown request-ids
 	  - Cleanups and other small fixes
 
 	- Various other smaller fixes and cleanups
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Merge tag 'iommu-updates-v6.3' of git://git.kernel.org/pub/scm/linux/kernel/git/joro/iommu

Pull iommu updates from Joerg Roedel:

 - Consolidate iommu_map/unmap functions.

   There have been blocking and atomic variants so far, but that was
   problematic as this approach does not scale with required new
   variants which just differ in the GFP flags used. So Jason
   consolidated this back into single functions that take a GFP
   parameter.

 - Retire the detach_dev() call-back in iommu_ops

 - Arm SMMU updates from Will:
     - Device-tree binding updates:
         - Cater for three power domains on SM6375
         - Document existing compatible strings for Qualcomm SoCs
         - Tighten up clocks description for platform-specific
           compatible strings
     - Enable Qualcomm workarounds for some additional platforms that
       need them

 - Intel VT-d updates from Lu Baolu:
     - Add Intel IOMMU performance monitoring support
     - Set No Execute Enable bit in PASID table entry
     - Two performance optimizations
     - Fix PASID directory pointer coherency
     - Fix missed rollbacks in error path
     - Cleanups

 - Apple t8110 DART support

 - Exynos IOMMU:
     - Implement better fault handling
     - Error handling fixes

 - Renesas IPMMU:
     - Add device tree bindings for r8a779g0

 - AMD IOMMU:
     - Various fixes for handling on SNP-enabled systems and
       handling of faults with unknown request-ids
     - Cleanups and other small fixes

 - Various other smaller fixes and cleanups

* tag 'iommu-updates-v6.3' of git://git.kernel.org/pub/scm/linux/kernel/git/joro/iommu: (71 commits)
  iommu/amd: Skip attach device domain is same as new domain
  iommu: Attach device group to old domain in error path
  iommu/vt-d: Allow to use flush-queue when first level is default
  iommu/vt-d: Fix PASID directory pointer coherency
  iommu/vt-d: Avoid superfluous IOTLB tracking in lazy mode
  iommu/vt-d: Fix error handling in sva enable/disable paths
  iommu/amd: Improve page fault error reporting
  iommu/amd: Do not identity map v2 capable device when snp is enabled
  iommu: Fix error unwind in iommu_group_alloc()
  iommu/of: mark an unused function as __maybe_unused
  iommu: dart: DART_T8110_ERROR range should be 0 to 5
  iommu/vt-d: Enable IOMMU perfmon support
  iommu/vt-d: Add IOMMU perfmon overflow handler support
  iommu/vt-d: Support cpumask for IOMMU perfmon
  iommu/vt-d: Add IOMMU perfmon support
  iommu/vt-d: Support Enhanced Command Interface
  iommu/vt-d: Retrieve IOMMU perfmon capability information
  iommu/vt-d: Support size of the register set in DRHD
  iommu/vt-d: Set No Execute Enable bit in PASID table entry
  iommu/vt-d: Remove sva from intel_svm_dev
  ...
2023-02-24 13:40:13 -08:00

694 lines
16 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* Tegra host1x Command DMA
*
* Copyright (c) 2010-2013, NVIDIA Corporation.
*/
#include <asm/cacheflush.h>
#include <linux/device.h>
#include <linux/dma-mapping.h>
#include <linux/host1x.h>
#include <linux/interrupt.h>
#include <linux/kernel.h>
#include <linux/kfifo.h>
#include <linux/slab.h>
#include <trace/events/host1x.h>
#include "cdma.h"
#include "channel.h"
#include "dev.h"
#include "debug.h"
#include "job.h"
/*
* push_buffer
*
* The push buffer is a circular array of words to be fetched by command DMA.
* Note that it works slightly differently to the sync queue; fence == pos
* means that the push buffer is full, not empty.
*/
/*
* Typically the commands written into the push buffer are a pair of words. We
* use slots to represent each of these pairs and to simplify things. Note the
* strange number of slots allocated here. 512 slots will fit exactly within a
* single memory page. We also need one additional word at the end of the push
* buffer for the RESTART opcode that will instruct the CDMA to jump back to
* the beginning of the push buffer. With 512 slots, this means that we'll use
* 2 memory pages and waste 4092 bytes of the second page that will never be
* used.
*/
#define HOST1X_PUSHBUFFER_SLOTS 511
/*
* Clean up push buffer resources
*/
static void host1x_pushbuffer_destroy(struct push_buffer *pb)
{
struct host1x_cdma *cdma = pb_to_cdma(pb);
struct host1x *host1x = cdma_to_host1x(cdma);
if (!pb->mapped)
return;
if (host1x->domain) {
iommu_unmap(host1x->domain, pb->dma, pb->alloc_size);
free_iova(&host1x->iova, iova_pfn(&host1x->iova, pb->dma));
}
dma_free_wc(host1x->dev, pb->alloc_size, pb->mapped, pb->phys);
pb->mapped = NULL;
pb->phys = 0;
}
/*
* Init push buffer resources
*/
static int host1x_pushbuffer_init(struct push_buffer *pb)
{
struct host1x_cdma *cdma = pb_to_cdma(pb);
struct host1x *host1x = cdma_to_host1x(cdma);
struct iova *alloc;
u32 size;
int err;
pb->mapped = NULL;
pb->phys = 0;
pb->size = HOST1X_PUSHBUFFER_SLOTS * 8;
size = pb->size + 4;
/* initialize buffer pointers */
pb->fence = pb->size - 8;
pb->pos = 0;
if (host1x->domain) {
unsigned long shift;
size = iova_align(&host1x->iova, size);
pb->mapped = dma_alloc_wc(host1x->dev, size, &pb->phys,
GFP_KERNEL);
if (!pb->mapped)
return -ENOMEM;
shift = iova_shift(&host1x->iova);
alloc = alloc_iova(&host1x->iova, size >> shift,
host1x->iova_end >> shift, true);
if (!alloc) {
err = -ENOMEM;
goto iommu_free_mem;
}
pb->dma = iova_dma_addr(&host1x->iova, alloc);
err = iommu_map(host1x->domain, pb->dma, pb->phys, size,
IOMMU_READ, GFP_KERNEL);
if (err)
goto iommu_free_iova;
} else {
pb->mapped = dma_alloc_wc(host1x->dev, size, &pb->phys,
GFP_KERNEL);
if (!pb->mapped)
return -ENOMEM;
pb->dma = pb->phys;
}
pb->alloc_size = size;
host1x_hw_pushbuffer_init(host1x, pb);
return 0;
iommu_free_iova:
__free_iova(&host1x->iova, alloc);
iommu_free_mem:
dma_free_wc(host1x->dev, size, pb->mapped, pb->phys);
return err;
}
/*
* Push two words to the push buffer
* Caller must ensure push buffer is not full
*/
static void host1x_pushbuffer_push(struct push_buffer *pb, u32 op1, u32 op2)
{
u32 *p = (u32 *)((void *)pb->mapped + pb->pos);
WARN_ON(pb->pos == pb->fence);
*(p++) = op1;
*(p++) = op2;
pb->pos += 8;
if (pb->pos >= pb->size)
pb->pos -= pb->size;
}
/*
* Pop a number of two word slots from the push buffer
* Caller must ensure push buffer is not empty
*/
static void host1x_pushbuffer_pop(struct push_buffer *pb, unsigned int slots)
{
/* Advance the next write position */
pb->fence += slots * 8;
if (pb->fence >= pb->size)
pb->fence -= pb->size;
}
/*
* Return the number of two word slots free in the push buffer
*/
static u32 host1x_pushbuffer_space(struct push_buffer *pb)
{
unsigned int fence = pb->fence;
if (pb->fence < pb->pos)
fence += pb->size;
return (fence - pb->pos) / 8;
}
/*
* Sleep (if necessary) until the requested event happens
* - CDMA_EVENT_SYNC_QUEUE_EMPTY : sync queue is completely empty.
* - Returns 1
* - CDMA_EVENT_PUSH_BUFFER_SPACE : there is space in the push buffer
* - Return the amount of space (> 0)
* Must be called with the cdma lock held.
*/
unsigned int host1x_cdma_wait_locked(struct host1x_cdma *cdma,
enum cdma_event event)
{
for (;;) {
struct push_buffer *pb = &cdma->push_buffer;
unsigned int space;
switch (event) {
case CDMA_EVENT_SYNC_QUEUE_EMPTY:
space = list_empty(&cdma->sync_queue) ? 1 : 0;
break;
case CDMA_EVENT_PUSH_BUFFER_SPACE:
space = host1x_pushbuffer_space(pb);
break;
default:
WARN_ON(1);
return -EINVAL;
}
if (space)
return space;
trace_host1x_wait_cdma(dev_name(cdma_to_channel(cdma)->dev),
event);
/* If somebody has managed to already start waiting, yield */
if (cdma->event != CDMA_EVENT_NONE) {
mutex_unlock(&cdma->lock);
schedule();
mutex_lock(&cdma->lock);
continue;
}
cdma->event = event;
mutex_unlock(&cdma->lock);
wait_for_completion(&cdma->complete);
mutex_lock(&cdma->lock);
}
return 0;
}
/*
* Sleep (if necessary) until the push buffer has enough free space.
*
* Must be called with the cdma lock held.
*/
static int host1x_cdma_wait_pushbuffer_space(struct host1x *host1x,
struct host1x_cdma *cdma,
unsigned int needed)
{
while (true) {
struct push_buffer *pb = &cdma->push_buffer;
unsigned int space;
space = host1x_pushbuffer_space(pb);
if (space >= needed)
break;
trace_host1x_wait_cdma(dev_name(cdma_to_channel(cdma)->dev),
CDMA_EVENT_PUSH_BUFFER_SPACE);
host1x_hw_cdma_flush(host1x, cdma);
/* If somebody has managed to already start waiting, yield */
if (cdma->event != CDMA_EVENT_NONE) {
mutex_unlock(&cdma->lock);
schedule();
mutex_lock(&cdma->lock);
continue;
}
cdma->event = CDMA_EVENT_PUSH_BUFFER_SPACE;
mutex_unlock(&cdma->lock);
wait_for_completion(&cdma->complete);
mutex_lock(&cdma->lock);
}
return 0;
}
/*
* Start timer that tracks the time spent by the job.
* Must be called with the cdma lock held.
*/
static void cdma_start_timer_locked(struct host1x_cdma *cdma,
struct host1x_job *job)
{
if (cdma->timeout.client) {
/* timer already started */
return;
}
cdma->timeout.client = job->client;
cdma->timeout.syncpt = job->syncpt;
cdma->timeout.syncpt_val = job->syncpt_end;
cdma->timeout.start_ktime = ktime_get();
schedule_delayed_work(&cdma->timeout.wq,
msecs_to_jiffies(job->timeout));
}
/*
* Stop timer when a buffer submission completes.
* Must be called with the cdma lock held.
*/
static void stop_cdma_timer_locked(struct host1x_cdma *cdma)
{
cancel_delayed_work(&cdma->timeout.wq);
cdma->timeout.client = NULL;
}
/*
* For all sync queue entries that have already finished according to the
* current sync point registers:
* - unpin & unref their mems
* - pop their push buffer slots
* - remove them from the sync queue
* This is normally called from the host code's worker thread, but can be
* called manually if necessary.
* Must be called with the cdma lock held.
*/
static void update_cdma_locked(struct host1x_cdma *cdma)
{
bool signal = false;
struct host1x_job *job, *n;
/*
* Walk the sync queue, reading the sync point registers as necessary,
* to consume as many sync queue entries as possible without blocking
*/
list_for_each_entry_safe(job, n, &cdma->sync_queue, list) {
struct host1x_syncpt *sp = job->syncpt;
/* Check whether this syncpt has completed, and bail if not */
if (!host1x_syncpt_is_expired(sp, job->syncpt_end) &&
!job->cancelled) {
/* Start timer on next pending syncpt */
if (job->timeout)
cdma_start_timer_locked(cdma, job);
break;
}
/* Cancel timeout, when a buffer completes */
if (cdma->timeout.client)
stop_cdma_timer_locked(cdma);
/* Unpin the memory */
host1x_job_unpin(job);
/* Pop push buffer slots */
if (job->num_slots) {
struct push_buffer *pb = &cdma->push_buffer;
host1x_pushbuffer_pop(pb, job->num_slots);
if (cdma->event == CDMA_EVENT_PUSH_BUFFER_SPACE)
signal = true;
}
list_del(&job->list);
host1x_job_put(job);
}
if (cdma->event == CDMA_EVENT_SYNC_QUEUE_EMPTY &&
list_empty(&cdma->sync_queue))
signal = true;
if (signal) {
cdma->event = CDMA_EVENT_NONE;
complete(&cdma->complete);
}
}
void host1x_cdma_update_sync_queue(struct host1x_cdma *cdma,
struct device *dev)
{
struct host1x *host1x = cdma_to_host1x(cdma);
u32 restart_addr, syncpt_incrs, syncpt_val;
struct host1x_job *job, *next_job = NULL;
syncpt_val = host1x_syncpt_load(cdma->timeout.syncpt);
dev_dbg(dev, "%s: starting cleanup (thresh %d)\n",
__func__, syncpt_val);
/*
* Move the sync_queue read pointer to the first entry that hasn't
* completed based on the current HW syncpt value. It's likely there
* won't be any (i.e. we're still at the head), but covers the case
* where a syncpt incr happens just prior/during the teardown.
*/
dev_dbg(dev, "%s: skip completed buffers still in sync_queue\n",
__func__);
list_for_each_entry(job, &cdma->sync_queue, list) {
if (syncpt_val < job->syncpt_end) {
if (!list_is_last(&job->list, &cdma->sync_queue))
next_job = list_next_entry(job, list);
goto syncpt_incr;
}
host1x_job_dump(dev, job);
}
/* all jobs have been completed */
job = NULL;
syncpt_incr:
/*
* Increment with CPU the remaining syncpts of a partially executed job.
*
* CDMA will continue execution starting with the next job or will get
* into idle state.
*/
if (next_job)
restart_addr = next_job->first_get;
else
restart_addr = cdma->last_pos;
if (!job)
goto resume;
/* do CPU increments for the remaining syncpts */
if (job->syncpt_recovery) {
dev_dbg(dev, "%s: perform CPU incr on pending buffers\n",
__func__);
/* won't need a timeout when replayed */
job->timeout = 0;
syncpt_incrs = job->syncpt_end - syncpt_val;
dev_dbg(dev, "%s: CPU incr (%d)\n", __func__, syncpt_incrs);
host1x_job_dump(dev, job);
/* safe to use CPU to incr syncpts */
host1x_hw_cdma_timeout_cpu_incr(host1x, cdma, job->first_get,
syncpt_incrs, job->syncpt_end,
job->num_slots);
dev_dbg(dev, "%s: finished sync_queue modification\n",
__func__);
} else {
struct host1x_job *failed_job = job;
host1x_job_dump(dev, job);
host1x_syncpt_set_locked(job->syncpt);
failed_job->cancelled = true;
list_for_each_entry_continue(job, &cdma->sync_queue, list) {
unsigned int i;
if (job->syncpt != failed_job->syncpt)
continue;
for (i = 0; i < job->num_slots; i++) {
unsigned int slot = (job->first_get/8 + i) %
HOST1X_PUSHBUFFER_SLOTS;
u32 *mapped = cdma->push_buffer.mapped;
/*
* Overwrite opcodes with 0 word writes
* to offset 0xbad. This does nothing but
* has a easily detected signature in debug
* traces.
*
* On systems with MLOCK enforcement enabled,
* the above 0 word writes would fall foul of
* the enforcement. As such, in the first slot
* put a RESTART_W opcode to the beginning
* of the next job. We don't use this for older
* chips since those only support the RESTART
* opcode with inconvenient alignment requirements.
*/
if (i == 0 && host1x->info->has_wide_gather) {
unsigned int next_job = (job->first_get/8 + job->num_slots)
% HOST1X_PUSHBUFFER_SLOTS;
mapped[2*slot+0] = (0xd << 28) | (next_job * 2);
mapped[2*slot+1] = 0x0;
} else {
mapped[2*slot+0] = 0x1bad0000;
mapped[2*slot+1] = 0x1bad0000;
}
}
job->cancelled = true;
}
wmb();
update_cdma_locked(cdma);
}
resume:
/* roll back DMAGET and start up channel again */
host1x_hw_cdma_resume(host1x, cdma, restart_addr);
}
static void cdma_update_work(struct work_struct *work)
{
struct host1x_cdma *cdma = container_of(work, struct host1x_cdma, update_work);
mutex_lock(&cdma->lock);
update_cdma_locked(cdma);
mutex_unlock(&cdma->lock);
}
/*
* Create a cdma
*/
int host1x_cdma_init(struct host1x_cdma *cdma)
{
int err;
mutex_init(&cdma->lock);
init_completion(&cdma->complete);
INIT_WORK(&cdma->update_work, cdma_update_work);
INIT_LIST_HEAD(&cdma->sync_queue);
cdma->event = CDMA_EVENT_NONE;
cdma->running = false;
cdma->torndown = false;
err = host1x_pushbuffer_init(&cdma->push_buffer);
if (err)
return err;
return 0;
}
/*
* Destroy a cdma
*/
int host1x_cdma_deinit(struct host1x_cdma *cdma)
{
struct push_buffer *pb = &cdma->push_buffer;
struct host1x *host1x = cdma_to_host1x(cdma);
if (cdma->running) {
pr_warn("%s: CDMA still running\n", __func__);
return -EBUSY;
}
host1x_pushbuffer_destroy(pb);
host1x_hw_cdma_timeout_destroy(host1x, cdma);
return 0;
}
/*
* Begin a cdma submit
*/
int host1x_cdma_begin(struct host1x_cdma *cdma, struct host1x_job *job)
{
struct host1x *host1x = cdma_to_host1x(cdma);
mutex_lock(&cdma->lock);
/*
* Check if syncpoint was locked due to previous job timeout.
* This needs to be done within the cdma lock to avoid a race
* with the timeout handler.
*/
if (job->syncpt->locked) {
mutex_unlock(&cdma->lock);
return -EPERM;
}
if (job->timeout) {
/* init state on first submit with timeout value */
if (!cdma->timeout.initialized) {
int err;
err = host1x_hw_cdma_timeout_init(host1x, cdma);
if (err) {
mutex_unlock(&cdma->lock);
return err;
}
}
}
if (!cdma->running)
host1x_hw_cdma_start(host1x, cdma);
cdma->slots_free = 0;
cdma->slots_used = 0;
cdma->first_get = cdma->push_buffer.pos;
trace_host1x_cdma_begin(dev_name(job->channel->dev));
return 0;
}
/*
* Push two words into a push buffer slot
* Blocks as necessary if the push buffer is full.
*/
void host1x_cdma_push(struct host1x_cdma *cdma, u32 op1, u32 op2)
{
struct host1x *host1x = cdma_to_host1x(cdma);
struct push_buffer *pb = &cdma->push_buffer;
u32 slots_free = cdma->slots_free;
if (host1x_debug_trace_cmdbuf)
trace_host1x_cdma_push(dev_name(cdma_to_channel(cdma)->dev),
op1, op2);
if (slots_free == 0) {
host1x_hw_cdma_flush(host1x, cdma);
slots_free = host1x_cdma_wait_locked(cdma,
CDMA_EVENT_PUSH_BUFFER_SPACE);
}
cdma->slots_free = slots_free - 1;
cdma->slots_used++;
host1x_pushbuffer_push(pb, op1, op2);
}
/*
* Push four words into two consecutive push buffer slots. Note that extra
* care needs to be taken not to split the two slots across the end of the
* push buffer. Otherwise the RESTART opcode at the end of the push buffer
* that ensures processing will restart at the beginning will break up the
* four words.
*
* Blocks as necessary if the push buffer is full.
*/
void host1x_cdma_push_wide(struct host1x_cdma *cdma, u32 op1, u32 op2,
u32 op3, u32 op4)
{
struct host1x_channel *channel = cdma_to_channel(cdma);
struct host1x *host1x = cdma_to_host1x(cdma);
struct push_buffer *pb = &cdma->push_buffer;
unsigned int space = cdma->slots_free;
unsigned int needed = 2, extra = 0;
if (host1x_debug_trace_cmdbuf)
trace_host1x_cdma_push_wide(dev_name(channel->dev), op1, op2,
op3, op4);
/* compute number of extra slots needed for padding */
if (pb->pos + 16 > pb->size) {
extra = (pb->size - pb->pos) / 8;
needed += extra;
}
host1x_cdma_wait_pushbuffer_space(host1x, cdma, needed);
space = host1x_pushbuffer_space(pb);
cdma->slots_free = space - needed;
cdma->slots_used += needed;
if (extra > 0) {
/*
* If there isn't enough space at the tail of the pushbuffer,
* insert a RESTART(0) here to go back to the beginning.
* The code above adjusted the indexes appropriately.
*/
host1x_pushbuffer_push(pb, (0x5 << 28), 0xdead0000);
}
host1x_pushbuffer_push(pb, op1, op2);
host1x_pushbuffer_push(pb, op3, op4);
}
/*
* End a cdma submit
* Kick off DMA, add job to the sync queue, and a number of slots to be freed
* from the pushbuffer. The handles for a submit must all be pinned at the same
* time, but they can be unpinned in smaller chunks.
*/
void host1x_cdma_end(struct host1x_cdma *cdma,
struct host1x_job *job)
{
struct host1x *host1x = cdma_to_host1x(cdma);
bool idle = list_empty(&cdma->sync_queue);
host1x_hw_cdma_flush(host1x, cdma);
job->first_get = cdma->first_get;
job->num_slots = cdma->slots_used;
host1x_job_get(job);
list_add_tail(&job->list, &cdma->sync_queue);
/* start timer on idle -> active transitions */
if (job->timeout && idle)
cdma_start_timer_locked(cdma, job);
trace_host1x_cdma_end(dev_name(job->channel->dev));
mutex_unlock(&cdma->lock);
}
/*
* Update cdma state according to current sync point values
*/
void host1x_cdma_update(struct host1x_cdma *cdma)
{
schedule_work(&cdma->update_work);
}