qemu/util/qht.c
Emilio G. Cota fe9959a275 qsp: QEMU's Synchronization Profiler
The goal of this module is to profile synchronization primitives (i.e.
mutexes, recursive mutexes and condition variables) so that scalability
issues can be quickly diagnosed.

Sync primitives are profiled by QSP based on the vaddr of the object accessed
as well as the call site (file:line_nr). That means the same object called
from two different call sites will be tracked in separate entries, which
might be reported together or separately (see subsequent commit on
call site coalescing).

Some perf numbers:

Host: Intel(R) Core(TM) i7-6700K CPU @ 4.00GHz
Command: taskset -c 0 tests/atomic_add-bench -d 5 -m

- Before: 54.80 Mops/s
- After:  54.75 Mops/s

That is, a negligible slowdown due to the now indirect call to
qemu_mutex_lock. Note that using a branch instead of an indirect
call introduces a more severe slowdown (53.65 Mops/s, i.e. 2% slowdown).

Enabling the profiler (with -p, added in this series) is more interesting:

- No profiling: 54.75 Mops/s
- W/ profiling: 12.53 Mops/s

That is, a 4.36X slowdown.

We can break down this slowdown by removing the get_clock calls or
the entry lookup:

- No profiling:     54.75 Mops/s
- W/o get_clock:    25.37 Mops/s
- W/o entry lookup: 19.30 Mops/s
- W/ profiling:     12.53 Mops/s

Signed-off-by: Emilio G. Cota <cota@braap.org>
Signed-off-by: Paolo Bonzini <pbonzini@redhat.com>
2018-08-23 18:46:25 +02:00

892 lines
25 KiB
C

/*
* qht.c - QEMU Hash Table, designed to scale for read-mostly workloads.
*
* Copyright (C) 2016, Emilio G. Cota <cota@braap.org>
*
* License: GNU GPL, version 2 or later.
* See the COPYING file in the top-level directory.
*
* Assumptions:
* - NULL cannot be inserted/removed as a pointer value.
* - Trying to insert an already-existing hash-pointer pair is OK. However,
* it is not OK to insert into the same hash table different hash-pointer
* pairs that have the same pointer value, but not the hashes.
* - Lookups are performed under an RCU read-critical section; removals
* must wait for a grace period to elapse before freeing removed objects.
*
* Features:
* - Reads (i.e. lookups and iterators) can be concurrent with other reads.
* Lookups that are concurrent with writes to the same bucket will retry
* via a seqlock; iterators acquire all bucket locks and therefore can be
* concurrent with lookups and are serialized wrt writers.
* - Writes (i.e. insertions/removals) can be concurrent with writes to
* different buckets; writes to the same bucket are serialized through a lock.
* - Optional auto-resizing: the hash table resizes up if the load surpasses
* a certain threshold. Resizing is done concurrently with readers; writes
* are serialized with the resize operation.
*
* The key structure is the bucket, which is cacheline-sized. Buckets
* contain a few hash values and pointers; the u32 hash values are stored in
* full so that resizing is fast. Having this structure instead of directly
* chaining items has two advantages:
* - Failed lookups fail fast, and touch a minimum number of cache lines.
* - Resizing the hash table with concurrent lookups is easy.
*
* There are two types of buckets:
* 1. "head" buckets are the ones allocated in the array of buckets in qht_map.
* 2. all "non-head" buckets (i.e. all others) are members of a chain that
* starts from a head bucket.
* Note that the seqlock and spinlock of a head bucket applies to all buckets
* chained to it; these two fields are unused in non-head buckets.
*
* On removals, we move the last valid item in the chain to the position of the
* just-removed entry. This makes lookups slightly faster, since the moment an
* invalid entry is found, the (failed) lookup is over.
*
* Resizing is done by taking all bucket spinlocks (so that no other writers can
* race with us) and then copying all entries into a new hash map. Then, the
* ht->map pointer is set, and the old map is freed once no RCU readers can see
* it anymore.
*
* Writers check for concurrent resizes by comparing ht->map before and after
* acquiring their bucket lock. If they don't match, a resize has occured
* while the bucket spinlock was being acquired.
*
* Related Work:
* - Idea of cacheline-sized buckets with full hashes taken from:
* David, Guerraoui & Trigonakis, "Asynchronized Concurrency:
* The Secret to Scaling Concurrent Search Data Structures", ASPLOS'15.
* - Why not RCU-based hash tables? They would allow us to get rid of the
* seqlock, but resizing would take forever since RCU read critical
* sections in QEMU take quite a long time.
* More info on relativistic hash tables:
* + Triplett, McKenney & Walpole, "Resizable, Scalable, Concurrent Hash
* Tables via Relativistic Programming", USENIX ATC'11.
* + Corbet, "Relativistic hash tables, part 1: Algorithms", @ lwn.net, 2014.
* https://lwn.net/Articles/612021/
*/
#include "qemu/osdep.h"
#include "qemu/qht.h"
#include "qemu/atomic.h"
#include "qemu/rcu.h"
//#define QHT_DEBUG
/*
* We want to avoid false sharing of cache lines. Most systems have 64-byte
* cache lines so we go with it for simplicity.
*
* Note that systems with smaller cache lines will be fine (the struct is
* almost 64-bytes); systems with larger cache lines might suffer from
* some false sharing.
*/
#define QHT_BUCKET_ALIGN 64
/* define these to keep sizeof(qht_bucket) within QHT_BUCKET_ALIGN */
#if HOST_LONG_BITS == 32
#define QHT_BUCKET_ENTRIES 6
#else /* 64-bit */
#define QHT_BUCKET_ENTRIES 4
#endif
/*
* Do _not_ use qemu_mutex_[try]lock directly! Use these macros, otherwise
* the profiler (QSP) will deadlock.
*/
static inline void qht_lock(struct qht *ht)
{
if (ht->mode & QHT_MODE_RAW_MUTEXES) {
qemu_mutex_lock__raw(&ht->lock);
} else {
qemu_mutex_lock(&ht->lock);
}
}
static inline int qht_trylock(struct qht *ht)
{
if (ht->mode & QHT_MODE_RAW_MUTEXES) {
return qemu_mutex_trylock__raw(&(ht)->lock);
}
return qemu_mutex_trylock(&(ht)->lock);
}
/* this inline is not really necessary, but it helps keep code consistent */
static inline void qht_unlock(struct qht *ht)
{
qemu_mutex_unlock(&ht->lock);
}
/*
* Note: reading partially-updated pointers in @pointers could lead to
* segfaults. We thus access them with atomic_read/set; this guarantees
* that the compiler makes all those accesses atomic. We also need the
* volatile-like behavior in atomic_read, since otherwise the compiler
* might refetch the pointer.
* atomic_read's are of course not necessary when the bucket lock is held.
*
* If both ht->lock and b->lock are grabbed, ht->lock should always
* be grabbed first.
*/
struct qht_bucket {
QemuSpin lock;
QemuSeqLock sequence;
uint32_t hashes[QHT_BUCKET_ENTRIES];
void *pointers[QHT_BUCKET_ENTRIES];
struct qht_bucket *next;
} QEMU_ALIGNED(QHT_BUCKET_ALIGN);
QEMU_BUILD_BUG_ON(sizeof(struct qht_bucket) > QHT_BUCKET_ALIGN);
/**
* struct qht_map - structure to track an array of buckets
* @rcu: used by RCU. Keep it as the top field in the struct to help valgrind
* find the whole struct.
* @buckets: array of head buckets. It is constant once the map is created.
* @n_buckets: number of head buckets. It is constant once the map is created.
* @n_added_buckets: number of added (i.e. "non-head") buckets
* @n_added_buckets_threshold: threshold to trigger an upward resize once the
* number of added buckets surpasses it.
*
* Buckets are tracked in what we call a "map", i.e. this structure.
*/
struct qht_map {
struct rcu_head rcu;
struct qht_bucket *buckets;
size_t n_buckets;
size_t n_added_buckets;
size_t n_added_buckets_threshold;
};
/* trigger a resize when n_added_buckets > n_buckets / div */
#define QHT_NR_ADDED_BUCKETS_THRESHOLD_DIV 8
static void qht_do_resize_reset(struct qht *ht, struct qht_map *new,
bool reset);
static void qht_grow_maybe(struct qht *ht);
#ifdef QHT_DEBUG
#define qht_debug_assert(X) do { assert(X); } while (0)
static void qht_bucket_debug__locked(struct qht_bucket *b)
{
bool seen_empty = false;
bool corrupt = false;
int i;
do {
for (i = 0; i < QHT_BUCKET_ENTRIES; i++) {
if (b->pointers[i] == NULL) {
seen_empty = true;
continue;
}
if (seen_empty) {
fprintf(stderr, "%s: b: %p, pos: %i, hash: 0x%x, p: %p\n",
__func__, b, i, b->hashes[i], b->pointers[i]);
corrupt = true;
}
}
b = b->next;
} while (b);
qht_debug_assert(!corrupt);
}
static void qht_map_debug__all_locked(struct qht_map *map)
{
int i;
for (i = 0; i < map->n_buckets; i++) {
qht_bucket_debug__locked(&map->buckets[i]);
}
}
#else
#define qht_debug_assert(X) do { (void)(X); } while (0)
static inline void qht_bucket_debug__locked(struct qht_bucket *b)
{ }
static inline void qht_map_debug__all_locked(struct qht_map *map)
{ }
#endif /* QHT_DEBUG */
static inline size_t qht_elems_to_buckets(size_t n_elems)
{
return pow2ceil(n_elems / QHT_BUCKET_ENTRIES);
}
static inline void qht_head_init(struct qht_bucket *b)
{
memset(b, 0, sizeof(*b));
qemu_spin_init(&b->lock);
seqlock_init(&b->sequence);
}
static inline
struct qht_bucket *qht_map_to_bucket(struct qht_map *map, uint32_t hash)
{
return &map->buckets[hash & (map->n_buckets - 1)];
}
/* acquire all bucket locks from a map */
static void qht_map_lock_buckets(struct qht_map *map)
{
size_t i;
for (i = 0; i < map->n_buckets; i++) {
struct qht_bucket *b = &map->buckets[i];
qemu_spin_lock(&b->lock);
}
}
static void qht_map_unlock_buckets(struct qht_map *map)
{
size_t i;
for (i = 0; i < map->n_buckets; i++) {
struct qht_bucket *b = &map->buckets[i];
qemu_spin_unlock(&b->lock);
}
}
/*
* Call with at least a bucket lock held.
* @map should be the value read before acquiring the lock (or locks).
*/
static inline bool qht_map_is_stale__locked(struct qht *ht, struct qht_map *map)
{
return map != ht->map;
}
/*
* Grab all bucket locks, and set @pmap after making sure the map isn't stale.
*
* Pairs with qht_map_unlock_buckets(), hence the pass-by-reference.
*
* Note: callers cannot have ht->lock held.
*/
static inline
void qht_map_lock_buckets__no_stale(struct qht *ht, struct qht_map **pmap)
{
struct qht_map *map;
map = atomic_rcu_read(&ht->map);
qht_map_lock_buckets(map);
if (likely(!qht_map_is_stale__locked(ht, map))) {
*pmap = map;
return;
}
qht_map_unlock_buckets(map);
/* we raced with a resize; acquire ht->lock to see the updated ht->map */
qht_lock(ht);
map = ht->map;
qht_map_lock_buckets(map);
qht_unlock(ht);
*pmap = map;
return;
}
/*
* Get a head bucket and lock it, making sure its parent map is not stale.
* @pmap is filled with a pointer to the bucket's parent map.
*
* Unlock with qemu_spin_unlock(&b->lock).
*
* Note: callers cannot have ht->lock held.
*/
static inline
struct qht_bucket *qht_bucket_lock__no_stale(struct qht *ht, uint32_t hash,
struct qht_map **pmap)
{
struct qht_bucket *b;
struct qht_map *map;
map = atomic_rcu_read(&ht->map);
b = qht_map_to_bucket(map, hash);
qemu_spin_lock(&b->lock);
if (likely(!qht_map_is_stale__locked(ht, map))) {
*pmap = map;
return b;
}
qemu_spin_unlock(&b->lock);
/* we raced with a resize; acquire ht->lock to see the updated ht->map */
qht_lock(ht);
map = ht->map;
b = qht_map_to_bucket(map, hash);
qemu_spin_lock(&b->lock);
qht_unlock(ht);
*pmap = map;
return b;
}
static inline bool qht_map_needs_resize(struct qht_map *map)
{
return atomic_read(&map->n_added_buckets) > map->n_added_buckets_threshold;
}
static inline void qht_chain_destroy(struct qht_bucket *head)
{
struct qht_bucket *curr = head->next;
struct qht_bucket *prev;
while (curr) {
prev = curr;
curr = curr->next;
qemu_vfree(prev);
}
}
/* pass only an orphan map */
static void qht_map_destroy(struct qht_map *map)
{
size_t i;
for (i = 0; i < map->n_buckets; i++) {
qht_chain_destroy(&map->buckets[i]);
}
qemu_vfree(map->buckets);
g_free(map);
}
static struct qht_map *qht_map_create(size_t n_buckets)
{
struct qht_map *map;
size_t i;
map = g_malloc(sizeof(*map));
map->n_buckets = n_buckets;
map->n_added_buckets = 0;
map->n_added_buckets_threshold = n_buckets /
QHT_NR_ADDED_BUCKETS_THRESHOLD_DIV;
/* let tiny hash tables to at least add one non-head bucket */
if (unlikely(map->n_added_buckets_threshold == 0)) {
map->n_added_buckets_threshold = 1;
}
map->buckets = qemu_memalign(QHT_BUCKET_ALIGN,
sizeof(*map->buckets) * n_buckets);
for (i = 0; i < n_buckets; i++) {
qht_head_init(&map->buckets[i]);
}
return map;
}
void qht_init(struct qht *ht, qht_cmp_func_t cmp, size_t n_elems,
unsigned int mode)
{
struct qht_map *map;
size_t n_buckets = qht_elems_to_buckets(n_elems);
g_assert(cmp);
ht->cmp = cmp;
ht->mode = mode;
qemu_mutex_init(&ht->lock);
map = qht_map_create(n_buckets);
atomic_rcu_set(&ht->map, map);
}
/* call only when there are no readers/writers left */
void qht_destroy(struct qht *ht)
{
qht_map_destroy(ht->map);
memset(ht, 0, sizeof(*ht));
}
static void qht_bucket_reset__locked(struct qht_bucket *head)
{
struct qht_bucket *b = head;
int i;
seqlock_write_begin(&head->sequence);
do {
for (i = 0; i < QHT_BUCKET_ENTRIES; i++) {
if (b->pointers[i] == NULL) {
goto done;
}
atomic_set(&b->hashes[i], 0);
atomic_set(&b->pointers[i], NULL);
}
b = b->next;
} while (b);
done:
seqlock_write_end(&head->sequence);
}
/* call with all bucket locks held */
static void qht_map_reset__all_locked(struct qht_map *map)
{
size_t i;
for (i = 0; i < map->n_buckets; i++) {
qht_bucket_reset__locked(&map->buckets[i]);
}
qht_map_debug__all_locked(map);
}
void qht_reset(struct qht *ht)
{
struct qht_map *map;
qht_map_lock_buckets__no_stale(ht, &map);
qht_map_reset__all_locked(map);
qht_map_unlock_buckets(map);
}
static inline void qht_do_resize(struct qht *ht, struct qht_map *new)
{
qht_do_resize_reset(ht, new, false);
}
static inline void qht_do_resize_and_reset(struct qht *ht, struct qht_map *new)
{
qht_do_resize_reset(ht, new, true);
}
bool qht_reset_size(struct qht *ht, size_t n_elems)
{
struct qht_map *new = NULL;
struct qht_map *map;
size_t n_buckets;
n_buckets = qht_elems_to_buckets(n_elems);
qht_lock(ht);
map = ht->map;
if (n_buckets != map->n_buckets) {
new = qht_map_create(n_buckets);
}
qht_do_resize_and_reset(ht, new);
qht_unlock(ht);
return !!new;
}
static inline
void *qht_do_lookup(struct qht_bucket *head, qht_lookup_func_t func,
const void *userp, uint32_t hash)
{
struct qht_bucket *b = head;
int i;
do {
for (i = 0; i < QHT_BUCKET_ENTRIES; i++) {
if (atomic_read(&b->hashes[i]) == hash) {
/* The pointer is dereferenced before seqlock_read_retry,
* so (unlike qht_insert__locked) we need to use
* atomic_rcu_read here.
*/
void *p = atomic_rcu_read(&b->pointers[i]);
if (likely(p) && likely(func(p, userp))) {
return p;
}
}
}
b = atomic_rcu_read(&b->next);
} while (b);
return NULL;
}
static __attribute__((noinline))
void *qht_lookup__slowpath(struct qht_bucket *b, qht_lookup_func_t func,
const void *userp, uint32_t hash)
{
unsigned int version;
void *ret;
do {
version = seqlock_read_begin(&b->sequence);
ret = qht_do_lookup(b, func, userp, hash);
} while (seqlock_read_retry(&b->sequence, version));
return ret;
}
void *qht_lookup_custom(struct qht *ht, const void *userp, uint32_t hash,
qht_lookup_func_t func)
{
struct qht_bucket *b;
struct qht_map *map;
unsigned int version;
void *ret;
map = atomic_rcu_read(&ht->map);
b = qht_map_to_bucket(map, hash);
version = seqlock_read_begin(&b->sequence);
ret = qht_do_lookup(b, func, userp, hash);
if (likely(!seqlock_read_retry(&b->sequence, version))) {
return ret;
}
/*
* Removing the do/while from the fastpath gives a 4% perf. increase when
* running a 100%-lookup microbenchmark.
*/
return qht_lookup__slowpath(b, func, userp, hash);
}
void *qht_lookup(struct qht *ht, const void *userp, uint32_t hash)
{
return qht_lookup_custom(ht, userp, hash, ht->cmp);
}
/* call with head->lock held */
static void *qht_insert__locked(struct qht *ht, struct qht_map *map,
struct qht_bucket *head, void *p, uint32_t hash,
bool *needs_resize)
{
struct qht_bucket *b = head;
struct qht_bucket *prev = NULL;
struct qht_bucket *new = NULL;
int i;
do {
for (i = 0; i < QHT_BUCKET_ENTRIES; i++) {
if (b->pointers[i]) {
if (unlikely(b->hashes[i] == hash &&
ht->cmp(b->pointers[i], p))) {
return b->pointers[i];
}
} else {
goto found;
}
}
prev = b;
b = b->next;
} while (b);
b = qemu_memalign(QHT_BUCKET_ALIGN, sizeof(*b));
memset(b, 0, sizeof(*b));
new = b;
i = 0;
atomic_inc(&map->n_added_buckets);
if (unlikely(qht_map_needs_resize(map)) && needs_resize) {
*needs_resize = true;
}
found:
/* found an empty key: acquire the seqlock and write */
seqlock_write_begin(&head->sequence);
if (new) {
atomic_rcu_set(&prev->next, b);
}
/* smp_wmb() implicit in seqlock_write_begin. */
atomic_set(&b->hashes[i], hash);
atomic_set(&b->pointers[i], p);
seqlock_write_end(&head->sequence);
return NULL;
}
static __attribute__((noinline)) void qht_grow_maybe(struct qht *ht)
{
struct qht_map *map;
/*
* If the lock is taken it probably means there's an ongoing resize,
* so bail out.
*/
if (qht_trylock(ht)) {
return;
}
map = ht->map;
/* another thread might have just performed the resize we were after */
if (qht_map_needs_resize(map)) {
struct qht_map *new = qht_map_create(map->n_buckets * 2);
qht_do_resize(ht, new);
}
qht_unlock(ht);
}
bool qht_insert(struct qht *ht, void *p, uint32_t hash, void **existing)
{
struct qht_bucket *b;
struct qht_map *map;
bool needs_resize = false;
void *prev;
/* NULL pointers are not supported */
qht_debug_assert(p);
b = qht_bucket_lock__no_stale(ht, hash, &map);
prev = qht_insert__locked(ht, map, b, p, hash, &needs_resize);
qht_bucket_debug__locked(b);
qemu_spin_unlock(&b->lock);
if (unlikely(needs_resize) && ht->mode & QHT_MODE_AUTO_RESIZE) {
qht_grow_maybe(ht);
}
if (likely(prev == NULL)) {
return true;
}
if (existing) {
*existing = prev;
}
return false;
}
static inline bool qht_entry_is_last(struct qht_bucket *b, int pos)
{
if (pos == QHT_BUCKET_ENTRIES - 1) {
if (b->next == NULL) {
return true;
}
return b->next->pointers[0] == NULL;
}
return b->pointers[pos + 1] == NULL;
}
static void
qht_entry_move(struct qht_bucket *to, int i, struct qht_bucket *from, int j)
{
qht_debug_assert(!(to == from && i == j));
qht_debug_assert(to->pointers[i]);
qht_debug_assert(from->pointers[j]);
atomic_set(&to->hashes[i], from->hashes[j]);
atomic_set(&to->pointers[i], from->pointers[j]);
atomic_set(&from->hashes[j], 0);
atomic_set(&from->pointers[j], NULL);
}
/*
* Find the last valid entry in @head, and swap it with @orig[pos], which has
* just been invalidated.
*/
static inline void qht_bucket_remove_entry(struct qht_bucket *orig, int pos)
{
struct qht_bucket *b = orig;
struct qht_bucket *prev = NULL;
int i;
if (qht_entry_is_last(orig, pos)) {
orig->hashes[pos] = 0;
atomic_set(&orig->pointers[pos], NULL);
return;
}
do {
for (i = 0; i < QHT_BUCKET_ENTRIES; i++) {
if (b->pointers[i]) {
continue;
}
if (i > 0) {
return qht_entry_move(orig, pos, b, i - 1);
}
qht_debug_assert(prev);
return qht_entry_move(orig, pos, prev, QHT_BUCKET_ENTRIES - 1);
}
prev = b;
b = b->next;
} while (b);
/* no free entries other than orig[pos], so swap it with the last one */
qht_entry_move(orig, pos, prev, QHT_BUCKET_ENTRIES - 1);
}
/* call with b->lock held */
static inline
bool qht_remove__locked(struct qht_map *map, struct qht_bucket *head,
const void *p, uint32_t hash)
{
struct qht_bucket *b = head;
int i;
do {
for (i = 0; i < QHT_BUCKET_ENTRIES; i++) {
void *q = b->pointers[i];
if (unlikely(q == NULL)) {
return false;
}
if (q == p) {
qht_debug_assert(b->hashes[i] == hash);
seqlock_write_begin(&head->sequence);
qht_bucket_remove_entry(b, i);
seqlock_write_end(&head->sequence);
return true;
}
}
b = b->next;
} while (b);
return false;
}
bool qht_remove(struct qht *ht, const void *p, uint32_t hash)
{
struct qht_bucket *b;
struct qht_map *map;
bool ret;
/* NULL pointers are not supported */
qht_debug_assert(p);
b = qht_bucket_lock__no_stale(ht, hash, &map);
ret = qht_remove__locked(map, b, p, hash);
qht_bucket_debug__locked(b);
qemu_spin_unlock(&b->lock);
return ret;
}
static inline void qht_bucket_iter(struct qht *ht, struct qht_bucket *b,
qht_iter_func_t func, void *userp)
{
int i;
do {
for (i = 0; i < QHT_BUCKET_ENTRIES; i++) {
if (b->pointers[i] == NULL) {
return;
}
func(ht, b->pointers[i], b->hashes[i], userp);
}
b = b->next;
} while (b);
}
/* call with all of the map's locks held */
static inline void qht_map_iter__all_locked(struct qht *ht, struct qht_map *map,
qht_iter_func_t func, void *userp)
{
size_t i;
for (i = 0; i < map->n_buckets; i++) {
qht_bucket_iter(ht, &map->buckets[i], func, userp);
}
}
void qht_iter(struct qht *ht, qht_iter_func_t func, void *userp)
{
struct qht_map *map;
map = atomic_rcu_read(&ht->map);
qht_map_lock_buckets(map);
/* Note: ht here is merely for carrying ht->mode; ht->map won't be read */
qht_map_iter__all_locked(ht, map, func, userp);
qht_map_unlock_buckets(map);
}
static void qht_map_copy(struct qht *ht, void *p, uint32_t hash, void *userp)
{
struct qht_map *new = userp;
struct qht_bucket *b = qht_map_to_bucket(new, hash);
/* no need to acquire b->lock because no thread has seen this map yet */
qht_insert__locked(ht, new, b, p, hash, NULL);
}
/*
* Atomically perform a resize and/or reset.
* Call with ht->lock held.
*/
static void qht_do_resize_reset(struct qht *ht, struct qht_map *new, bool reset)
{
struct qht_map *old;
old = ht->map;
qht_map_lock_buckets(old);
if (reset) {
qht_map_reset__all_locked(old);
}
if (new == NULL) {
qht_map_unlock_buckets(old);
return;
}
g_assert(new->n_buckets != old->n_buckets);
qht_map_iter__all_locked(ht, old, qht_map_copy, new);
qht_map_debug__all_locked(new);
atomic_rcu_set(&ht->map, new);
qht_map_unlock_buckets(old);
call_rcu(old, qht_map_destroy, rcu);
}
bool qht_resize(struct qht *ht, size_t n_elems)
{
size_t n_buckets = qht_elems_to_buckets(n_elems);
size_t ret = false;
qht_lock(ht);
if (n_buckets != ht->map->n_buckets) {
struct qht_map *new;
new = qht_map_create(n_buckets);
qht_do_resize(ht, new);
ret = true;
}
qht_unlock(ht);
return ret;
}
/* pass @stats to qht_statistics_destroy() when done */
void qht_statistics_init(struct qht *ht, struct qht_stats *stats)
{
struct qht_map *map;
int i;
map = atomic_rcu_read(&ht->map);
stats->used_head_buckets = 0;
stats->entries = 0;
qdist_init(&stats->chain);
qdist_init(&stats->occupancy);
/* bail out if the qht has not yet been initialized */
if (unlikely(map == NULL)) {
stats->head_buckets = 0;
return;
}
stats->head_buckets = map->n_buckets;
for (i = 0; i < map->n_buckets; i++) {
struct qht_bucket *head = &map->buckets[i];
struct qht_bucket *b;
unsigned int version;
size_t buckets;
size_t entries;
int j;
do {
version = seqlock_read_begin(&head->sequence);
buckets = 0;
entries = 0;
b = head;
do {
for (j = 0; j < QHT_BUCKET_ENTRIES; j++) {
if (atomic_read(&b->pointers[j]) == NULL) {
break;
}
entries++;
}
buckets++;
b = atomic_rcu_read(&b->next);
} while (b);
} while (seqlock_read_retry(&head->sequence, version));
if (entries) {
qdist_inc(&stats->chain, buckets);
qdist_inc(&stats->occupancy,
(double)entries / QHT_BUCKET_ENTRIES / buckets);
stats->used_head_buckets++;
stats->entries += entries;
} else {
qdist_inc(&stats->occupancy, 0);
}
}
}
void qht_statistics_destroy(struct qht_stats *stats)
{
qdist_destroy(&stats->occupancy);
qdist_destroy(&stats->chain);
}