blob: 2c864c5714c2f3765aa3f75838ffc489c5fab8d3 [file] [log] [blame]
/*
* Copyright 2012-2015 Samy Al Bahra.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#define CK_HT_IM
#include <ck_ht.h>
/*
* This implementation borrows several techniques from Josh Dybnis's
* nbds library which can be found at http://code.google.com/p/nbds
*
* This release currently only includes support for 64-bit platforms.
* We can address 32-bit platforms in a future release.
*/
#include <ck_cc.h>
#include <ck_md.h>
#include <ck_pr.h>
#include <ck_stdint.h>
#include <ck_stdbool.h>
#include <ck_string.h>
#include "ck_ht_hash.h"
#include "ck_internal.h"
#ifndef CK_HT_BUCKET_LENGTH
#ifdef CK_HT_PP
#define CK_HT_BUCKET_SHIFT 2ULL
#else
#define CK_HT_BUCKET_SHIFT 1ULL
#endif
#define CK_HT_BUCKET_LENGTH (1U << CK_HT_BUCKET_SHIFT)
#define CK_HT_BUCKET_MASK (CK_HT_BUCKET_LENGTH - 1)
#endif
#ifndef CK_HT_PROBE_DEFAULT
#define CK_HT_PROBE_DEFAULT 64ULL
#endif
#if defined(CK_F_PR_LOAD_8) && defined(CK_F_PR_STORE_8)
#define CK_HT_WORD uint8_t
#define CK_HT_WORD_MAX UINT8_MAX
#define CK_HT_STORE(x, y) ck_pr_store_8(x, y)
#define CK_HT_LOAD(x) ck_pr_load_8(x)
#elif defined(CK_F_PR_LOAD_16) && defined(CK_F_PR_STORE_16)
#define CK_HT_WORD uint16_t
#define CK_HT_WORD_MAX UINT16_MAX
#define CK_HT_STORE(x, y) ck_pr_store_16(x, y)
#define CK_HT_LOAD(x) ck_pr_load_16(x)
#elif defined(CK_F_PR_LOAD_32) && defined(CK_F_PR_STORE_32)
#define CK_HT_WORD uint32_t
#define CK_HT_WORD_MAX UINT32_MAX
#define CK_HT_STORE(x, y) ck_pr_store_32(x, y)
#define CK_HT_LOAD(x) ck_pr_load_32(x)
#else
#error "ck_ht is not supported on your platform."
#endif
struct ck_ht_map {
unsigned int mode;
CK_HT_TYPE deletions;
CK_HT_TYPE probe_maximum;
CK_HT_TYPE probe_length;
CK_HT_TYPE probe_limit;
CK_HT_TYPE size;
CK_HT_TYPE n_entries;
CK_HT_TYPE mask;
CK_HT_TYPE capacity;
CK_HT_TYPE step;
CK_HT_WORD *probe_bound;
struct ck_ht_entry *entries;
};
void
ck_ht_stat(struct ck_ht *table,
struct ck_ht_stat *st)
{
struct ck_ht_map *map = table->map;
st->n_entries = map->n_entries;
st->probe_maximum = map->probe_maximum;
return;
}
void
ck_ht_hash(struct ck_ht_hash *h,
struct ck_ht *table,
const void *key,
uint16_t key_length)
{
table->h(h, key, key_length, table->seed);
return;
}
void
ck_ht_hash_direct(struct ck_ht_hash *h,
struct ck_ht *table,
uintptr_t key)
{
ck_ht_hash(h, table, &key, sizeof(key));
return;
}
static void
ck_ht_hash_wrapper(struct ck_ht_hash *h,
const void *key,
size_t length,
uint64_t seed)
{
h->value = (unsigned long)MurmurHash64A(key, length, seed);
return;
}
static struct ck_ht_map *
ck_ht_map_create(struct ck_ht *table, CK_HT_TYPE entries)
{
struct ck_ht_map *map;
CK_HT_TYPE size;
uintptr_t prefix;
uint32_t n_entries;
n_entries = ck_internal_power_2(entries);
if (n_entries < CK_HT_BUCKET_LENGTH)
n_entries = CK_HT_BUCKET_LENGTH;
size = sizeof(struct ck_ht_map) +
(sizeof(struct ck_ht_entry) * n_entries + CK_MD_CACHELINE - 1);
if (table->mode & CK_HT_WORKLOAD_DELETE) {
prefix = sizeof(CK_HT_WORD) * n_entries;
size += prefix;
} else {
prefix = 0;
}
map = table->m->malloc(size);
if (map == NULL)
return NULL;
map->mode = table->mode;
map->size = size;
map->probe_limit = ck_internal_max_64(n_entries >>
(CK_HT_BUCKET_SHIFT + 2), CK_HT_PROBE_DEFAULT);
map->deletions = 0;
map->probe_maximum = 0;
map->capacity = n_entries;
map->step = ck_internal_bsf_64(map->capacity);
map->mask = map->capacity - 1;
map->n_entries = 0;
map->entries = (struct ck_ht_entry *)(((uintptr_t)&map[1] + prefix +
CK_MD_CACHELINE - 1) & ~(CK_MD_CACHELINE - 1));
if (table->mode & CK_HT_WORKLOAD_DELETE) {
map->probe_bound = (CK_HT_WORD *)&map[1];
memset(map->probe_bound, 0, prefix);
} else {
map->probe_bound = NULL;
}
memset(map->entries, 0, sizeof(struct ck_ht_entry) * n_entries);
ck_pr_fence_store();
return map;
}
static inline void
ck_ht_map_bound_set(struct ck_ht_map *m,
struct ck_ht_hash h,
CK_HT_TYPE n_probes)
{
CK_HT_TYPE offset = h.value & m->mask;
if (n_probes > m->probe_maximum)
CK_HT_TYPE_STORE(&m->probe_maximum, n_probes);
if (m->probe_bound != NULL && m->probe_bound[offset] < n_probes) {
if (n_probes >= CK_HT_WORD_MAX)
n_probes = CK_HT_WORD_MAX;
CK_HT_STORE(&m->probe_bound[offset], n_probes);
ck_pr_fence_store();
}
return;
}
static inline CK_HT_TYPE
ck_ht_map_bound_get(struct ck_ht_map *m, struct ck_ht_hash h)
{
CK_HT_TYPE offset = h.value & m->mask;
CK_HT_TYPE r = CK_HT_WORD_MAX;
if (m->probe_bound != NULL) {
r = CK_HT_LOAD(&m->probe_bound[offset]);
if (r == CK_HT_WORD_MAX)
r = CK_HT_TYPE_LOAD(&m->probe_maximum);
} else {
r = CK_HT_TYPE_LOAD(&m->probe_maximum);
}
return r;
}
static void
ck_ht_map_destroy(struct ck_malloc *m, struct ck_ht_map *map, bool defer)
{
m->free(map, map->size, defer);
return;
}
static inline size_t
ck_ht_map_probe_next(struct ck_ht_map *map, size_t offset, ck_ht_hash_t h, size_t probes)
{
ck_ht_hash_t r;
size_t stride;
unsigned long level = (unsigned long)probes >> CK_HT_BUCKET_SHIFT;
r.value = (h.value >> map->step) >> level;
stride = (r.value & ~CK_HT_BUCKET_MASK) << 1
| (r.value & CK_HT_BUCKET_MASK);
return (offset + level +
(stride | CK_HT_BUCKET_LENGTH)) & map->mask;
}
bool
ck_ht_init(struct ck_ht *table,
unsigned int mode,
ck_ht_hash_cb_t *h,
struct ck_malloc *m,
CK_HT_TYPE entries,
uint64_t seed)
{
if (m == NULL || m->malloc == NULL || m->free == NULL)
return false;
table->m = m;
table->mode = mode;
table->seed = seed;
if (h == NULL) {
table->h = ck_ht_hash_wrapper;
} else {
table->h = h;
}
table->map = ck_ht_map_create(table, entries);
return table->map != NULL;
}
static struct ck_ht_entry *
ck_ht_map_probe_wr(struct ck_ht_map *map,
ck_ht_hash_t h,
ck_ht_entry_t *snapshot,
ck_ht_entry_t **available,
const void *key,
uint16_t key_length,
CK_HT_TYPE *probe_limit,
CK_HT_TYPE *probe_wr)
{
struct ck_ht_entry *bucket, *cursor;
struct ck_ht_entry *first = NULL;
size_t offset, i, j;
CK_HT_TYPE probes = 0;
CK_HT_TYPE limit;
if (probe_limit == NULL) {
limit = ck_ht_map_bound_get(map, h);
} else {
limit = CK_HT_TYPE_MAX;
}
offset = h.value & map->mask;
for (i = 0; i < map->probe_limit; i++) {
/*
* Probe on a complete cache line first. Scan forward and wrap around to
* the beginning of the cache line. Only when the complete cache line has
* been scanned do we move on to the next row.
*/
bucket = (void *)((uintptr_t)(map->entries + offset) &
~(CK_MD_CACHELINE - 1));
for (j = 0; j < CK_HT_BUCKET_LENGTH; j++) {
uint16_t k;
if (probes++ > limit)
break;
cursor = bucket + ((j + offset) & (CK_HT_BUCKET_LENGTH - 1));
/*
* It is probably worth it to encapsulate probe state
* in order to prevent a complete reprobe sequence in
* the case of intermittent writers.
*/
if (cursor->key == CK_HT_KEY_TOMBSTONE) {
if (first == NULL) {
first = cursor;
*probe_wr = probes;
}
continue;
}
if (cursor->key == CK_HT_KEY_EMPTY)
goto leave;
if (cursor->key == (uintptr_t)key)
goto leave;
if (map->mode & CK_HT_MODE_BYTESTRING) {
void *pointer;
/*
* Check memoized portion of hash value before
* expensive full-length comparison.
*/
k = ck_ht_entry_key_length(cursor);
if (k != key_length)
continue;
#ifdef CK_HT_PP
if ((cursor->value >> CK_MD_VMA_BITS) != ((h.value >> 32) & CK_HT_KEY_MASK))
continue;
#else
if (cursor->hash != h.value)
continue;
#endif
pointer = ck_ht_entry_key(cursor);
if (memcmp(pointer, key, key_length) == 0)
goto leave;
}
}
offset = ck_ht_map_probe_next(map, offset, h, probes);
}
cursor = NULL;
leave:
if (probe_limit != NULL) {
*probe_limit = probes;
} else if (first == NULL) {
*probe_wr = probes;
}
*available = first;
if (cursor != NULL) {
*snapshot = *cursor;
}
return cursor;
}
bool
ck_ht_gc(struct ck_ht *ht, unsigned long cycles, unsigned long seed)
{
CK_HT_WORD *bounds = NULL;
struct ck_ht_map *map = ht->map;
CK_HT_TYPE maximum, i;
CK_HT_TYPE size = 0;
if (map->n_entries == 0) {
CK_HT_TYPE_STORE(&map->probe_maximum, 0);
if (map->probe_bound != NULL)
memset(map->probe_bound, 0, sizeof(CK_HT_WORD) * map->capacity);
return true;
}
if (cycles == 0) {
maximum = 0;
if (map->probe_bound != NULL) {
size = sizeof(CK_HT_WORD) * map->capacity;
bounds = ht->m->malloc(size);
if (bounds == NULL)
return false;
memset(bounds, 0, size);
}
} else {
maximum = map->probe_maximum;
}
for (i = 0; i < map->capacity; i++) {
struct ck_ht_entry *entry, *priority, snapshot;
struct ck_ht_hash h;
CK_HT_TYPE probes_wr;
CK_HT_TYPE offset;
entry = &map->entries[(i + seed) & map->mask];
if (entry->key == CK_HT_KEY_EMPTY ||
entry->key == CK_HT_KEY_TOMBSTONE) {
continue;
}
if (ht->mode & CK_HT_MODE_BYTESTRING) {
#ifndef CK_HT_PP
h.value = entry->hash;
#else
ht->h(&h, ck_ht_entry_key(entry), ck_ht_entry_key_length(entry),
ht->seed);
#endif
entry = ck_ht_map_probe_wr(map, h, &snapshot, &priority,
ck_ht_entry_key(entry),
ck_ht_entry_key_length(entry),
NULL, &probes_wr);
} else {
#ifndef CK_HT_PP
h.value = entry->hash;
#else
ht->h(&h, &entry->key, sizeof(entry->key), ht->seed);
#endif
entry = ck_ht_map_probe_wr(map, h, &snapshot, &priority,
(void *)entry->key,
sizeof(entry->key),
NULL, &probes_wr);
}
offset = h.value & map->mask;
if (priority != NULL) {
CK_HT_TYPE_STORE(&map->deletions, map->deletions + 1);
ck_pr_fence_store();
#ifndef CK_HT_PP
CK_HT_TYPE_STORE(&priority->key_length, entry->key_length);
CK_HT_TYPE_STORE(&priority->hash, entry->hash);
#endif
ck_pr_store_ptr_unsafe(&priority->value, (void *)entry->value);
ck_pr_fence_store();
ck_pr_store_ptr_unsafe(&priority->key, (void *)entry->key);
ck_pr_fence_store();
CK_HT_TYPE_STORE(&map->deletions, map->deletions + 1);
ck_pr_fence_store();
ck_pr_store_ptr_unsafe(&entry->key, (void *)CK_HT_KEY_TOMBSTONE);
ck_pr_fence_store();
}
if (cycles == 0) {
if (probes_wr > maximum)
maximum = probes_wr;
if (probes_wr >= CK_HT_WORD_MAX)
probes_wr = CK_HT_WORD_MAX;
if (bounds != NULL && probes_wr > bounds[offset])
bounds[offset] = probes_wr;
} else if (--cycles == 0)
break;
}
if (maximum != map->probe_maximum)
CK_HT_TYPE_STORE(&map->probe_maximum, maximum);
if (bounds != NULL) {
for (i = 0; i < map->capacity; i++)
CK_HT_STORE(&map->probe_bound[i], bounds[i]);
ht->m->free(bounds, size, false);
}
return true;
}
static struct ck_ht_entry *
ck_ht_map_probe_rd(struct ck_ht_map *map,
ck_ht_hash_t h,
ck_ht_entry_t *snapshot,
const void *key,
uint16_t key_length)
{
struct ck_ht_entry *bucket, *cursor;
size_t offset, i, j;
CK_HT_TYPE probes = 0;
CK_HT_TYPE probe_maximum;
#ifndef CK_HT_PP
CK_HT_TYPE d = 0;
CK_HT_TYPE d_prime = 0;
retry:
#endif
probe_maximum = ck_ht_map_bound_get(map, h);
offset = h.value & map->mask;
for (i = 0; i < map->probe_limit; i++) {
/*
* Probe on a complete cache line first. Scan forward and wrap around to
* the beginning of the cache line. Only when the complete cache line has
* been scanned do we move on to the next row.
*/
bucket = (void *)((uintptr_t)(map->entries + offset) &
~(CK_MD_CACHELINE - 1));
for (j = 0; j < CK_HT_BUCKET_LENGTH; j++) {
uint16_t k;
if (probes++ > probe_maximum)
return NULL;
cursor = bucket + ((j + offset) & (CK_HT_BUCKET_LENGTH - 1));
#ifdef CK_HT_PP
snapshot->key = (uintptr_t)ck_pr_load_ptr(&cursor->key);
ck_pr_fence_load();
snapshot->value = (uintptr_t)ck_pr_load_ptr(&cursor->value);
#else
d = CK_HT_TYPE_LOAD(&map->deletions);
snapshot->key = (uintptr_t)ck_pr_load_ptr(&cursor->key);
ck_pr_fence_load();
snapshot->key_length = CK_HT_TYPE_LOAD(&cursor->key_length);
snapshot->hash = CK_HT_TYPE_LOAD(&cursor->hash);
snapshot->value = (uintptr_t)ck_pr_load_ptr(&cursor->value);
#endif
/*
* It is probably worth it to encapsulate probe state
* in order to prevent a complete reprobe sequence in
* the case of intermittent writers.
*/
if (snapshot->key == CK_HT_KEY_TOMBSTONE)
continue;
if (snapshot->key == CK_HT_KEY_EMPTY)
goto leave;
if (snapshot->key == (uintptr_t)key)
goto leave;
if (map->mode & CK_HT_MODE_BYTESTRING) {
void *pointer;
/*
* Check memoized portion of hash value before
* expensive full-length comparison.
*/
k = ck_ht_entry_key_length(snapshot);
if (k != key_length)
continue;
#ifdef CK_HT_PP
if ((snapshot->value >> CK_MD_VMA_BITS) != ((h.value >> 32) & CK_HT_KEY_MASK))
continue;
#else
if (snapshot->hash != h.value)
continue;
d_prime = CK_HT_TYPE_LOAD(&map->deletions);
/*
* It is possible that the slot was
* replaced, initiate a re-probe.
*/
if (d != d_prime)
goto retry;
#endif
pointer = ck_ht_entry_key(snapshot);
if (memcmp(pointer, key, key_length) == 0)
goto leave;
}
}
offset = ck_ht_map_probe_next(map, offset, h, probes);
}
return NULL;
leave:
return cursor;
}
CK_HT_TYPE
ck_ht_count(struct ck_ht *table)
{
struct ck_ht_map *map = ck_pr_load_ptr(&table->map);
return CK_HT_TYPE_LOAD(&map->n_entries);
}
bool
ck_ht_next(struct ck_ht *table,
struct ck_ht_iterator *i,
struct ck_ht_entry **entry)
{
struct ck_ht_map *map = table->map;
uintptr_t key;
if (i->offset >= map->capacity)
return false;
do {
key = map->entries[i->offset].key;
if (key != CK_HT_KEY_EMPTY && key != CK_HT_KEY_TOMBSTONE)
break;
} while (++i->offset < map->capacity);
if (i->offset >= map->capacity)
return false;
*entry = map->entries + i->offset++;
return true;
}
bool
ck_ht_reset_size_spmc(struct ck_ht *table, CK_HT_TYPE size)
{
struct ck_ht_map *map, *update;
map = table->map;
update = ck_ht_map_create(table, size);
if (update == NULL)
return false;
ck_pr_store_ptr_unsafe(&table->map, update);
ck_ht_map_destroy(table->m, map, true);
return true;
}
bool
ck_ht_reset_spmc(struct ck_ht *table)
{
struct ck_ht_map *map = table->map;
return ck_ht_reset_size_spmc(table, map->capacity);
}
bool
ck_ht_grow_spmc(struct ck_ht *table, CK_HT_TYPE capacity)
{
struct ck_ht_map *map, *update;
struct ck_ht_entry *bucket, *previous;
struct ck_ht_hash h;
size_t k, i, j, offset;
CK_HT_TYPE probes;
restart:
map = table->map;
if (map->capacity >= capacity)
return false;
update = ck_ht_map_create(table, capacity);
if (update == NULL)
return false;
for (k = 0; k < map->capacity; k++) {
previous = &map->entries[k];
if (previous->key == CK_HT_KEY_EMPTY || previous->key == CK_HT_KEY_TOMBSTONE)
continue;
if (table->mode & CK_HT_MODE_BYTESTRING) {
#ifdef CK_HT_PP
void *key;
uint16_t key_length;
key = ck_ht_entry_key(previous);
key_length = ck_ht_entry_key_length(previous);
#endif
#ifndef CK_HT_PP
h.value = previous->hash;
#else
table->h(&h, key, key_length, table->seed);
#endif
} else {
#ifndef CK_HT_PP
h.value = previous->hash;
#else
table->h(&h, &previous->key, sizeof(previous->key), table->seed);
#endif
}
offset = h.value & update->mask;
probes = 0;
for (i = 0; i < update->probe_limit; i++) {
bucket = (void *)((uintptr_t)(update->entries + offset) & ~(CK_MD_CACHELINE - 1));
for (j = 0; j < CK_HT_BUCKET_LENGTH; j++) {
struct ck_ht_entry *cursor = bucket + ((j + offset) & (CK_HT_BUCKET_LENGTH - 1));
probes++;
if (CK_CC_LIKELY(cursor->key == CK_HT_KEY_EMPTY)) {
*cursor = *previous;
update->n_entries++;
ck_ht_map_bound_set(update, h, probes);
break;
}
}
if (j < CK_HT_BUCKET_LENGTH)
break;
offset = ck_ht_map_probe_next(update, offset, h, probes);
}
if (i == update->probe_limit) {
/*
* We have hit the probe limit, the map needs to be even
* larger.
*/
ck_ht_map_destroy(table->m, update, false);
capacity <<= 1;
goto restart;
}
}
ck_pr_fence_store();
ck_pr_store_ptr_unsafe(&table->map, update);
ck_ht_map_destroy(table->m, map, true);
return true;
}
bool
ck_ht_remove_spmc(struct ck_ht *table,
ck_ht_hash_t h,
ck_ht_entry_t *entry)
{
struct ck_ht_map *map;
struct ck_ht_entry *candidate, snapshot;
map = table->map;
if (table->mode & CK_HT_MODE_BYTESTRING) {
candidate = ck_ht_map_probe_rd(map, h, &snapshot,
ck_ht_entry_key(entry),
ck_ht_entry_key_length(entry));
} else {
candidate = ck_ht_map_probe_rd(map, h, &snapshot,
(void *)entry->key,
sizeof(entry->key));
}
/* No matching entry was found. */
if (candidate == NULL || snapshot.key == CK_HT_KEY_EMPTY)
return false;
*entry = snapshot;
ck_pr_store_ptr_unsafe(&candidate->key, (void *)CK_HT_KEY_TOMBSTONE);
ck_pr_fence_store();
CK_HT_TYPE_STORE(&map->n_entries, map->n_entries - 1);
return true;
}
bool
ck_ht_get_spmc(struct ck_ht *table,
ck_ht_hash_t h,
ck_ht_entry_t *entry)
{
struct ck_ht_entry *candidate, snapshot;
struct ck_ht_map *map;
CK_HT_TYPE d, d_prime;
restart:
map = ck_pr_load_ptr(&table->map);
/*
* Platforms that cannot read key and key_length atomically must reprobe
* on the scan of any single entry.
*/
d = CK_HT_TYPE_LOAD(&map->deletions);
if (table->mode & CK_HT_MODE_BYTESTRING) {
candidate = ck_ht_map_probe_rd(map, h, &snapshot,
ck_ht_entry_key(entry), ck_ht_entry_key_length(entry));
} else {
candidate = ck_ht_map_probe_rd(map, h, &snapshot,
(void *)entry->key, sizeof(entry->key));
}
d_prime = CK_HT_TYPE_LOAD(&map->deletions);
if (d != d_prime) {
/*
* It is possible we have read (K, V'). Only valid states are
* (K, V), (K', V') and (T, V). Restart load operation in face
* of concurrent deletions or replacements.
*/
goto restart;
}
if (candidate == NULL || snapshot.key == CK_HT_KEY_EMPTY)
return false;
*entry = snapshot;
return true;
}
bool
ck_ht_set_spmc(struct ck_ht *table,
ck_ht_hash_t h,
ck_ht_entry_t *entry)
{
struct ck_ht_entry snapshot, *candidate, *priority;
struct ck_ht_map *map;
CK_HT_TYPE probes, probes_wr;
bool empty = false;
for (;;) {
map = table->map;
if (table->mode & CK_HT_MODE_BYTESTRING) {
candidate = ck_ht_map_probe_wr(map, h, &snapshot, &priority,
ck_ht_entry_key(entry),
ck_ht_entry_key_length(entry),
&probes, &probes_wr);
} else {
candidate = ck_ht_map_probe_wr(map, h, &snapshot, &priority,
(void *)entry->key,
sizeof(entry->key),
&probes, &probes_wr);
}
if (priority != NULL) {
probes = probes_wr;
break;
}
if (candidate != NULL)
break;
if (ck_ht_grow_spmc(table, map->capacity << 1) == false)
return false;
}
if (candidate == NULL) {
candidate = priority;
empty = true;
}
if (candidate->key != CK_HT_KEY_EMPTY &&
priority != NULL && candidate != priority) {
/*
* Entry is moved into another position in probe sequence.
* We avoid a state of (K, B) (where [K, B] -> [K', B]) by
* guaranteeing a forced reprobe before transitioning from K to
* T. (K, B) implies (K, B, D') so we will reprobe successfully
* from this transient state.
*/
probes = probes_wr;
#ifndef CK_HT_PP
CK_HT_TYPE_STORE(&priority->key_length, entry->key_length);
CK_HT_TYPE_STORE(&priority->hash, entry->hash);
#endif
/*
* Readers must observe version counter change before they
* observe re-use. If they observe re-use, it is at most
* a tombstone.
*/
if (priority->value == CK_HT_KEY_TOMBSTONE) {
CK_HT_TYPE_STORE(&map->deletions, map->deletions + 1);
ck_pr_fence_store();
}
ck_pr_store_ptr_unsafe(&priority->value, (void *)entry->value);
ck_pr_fence_store();
ck_pr_store_ptr_unsafe(&priority->key, (void *)entry->key);
ck_pr_fence_store();
/*
* Make sure that readers who observe the tombstone would
* also observe counter change.
*/
CK_HT_TYPE_STORE(&map->deletions, map->deletions + 1);
ck_pr_fence_store();
ck_pr_store_ptr_unsafe(&candidate->key, (void *)CK_HT_KEY_TOMBSTONE);
ck_pr_fence_store();
} else {
/*
* In this case we are inserting a new entry or replacing
* an existing entry. Yes, this can be combined into above branch,
* but isn't because you are actually looking at dying code
* (ck_ht is effectively deprecated and is being replaced soon).
*/
bool replace = candidate->key != CK_HT_KEY_EMPTY &&
candidate->key != CK_HT_KEY_TOMBSTONE;
if (priority != NULL) {
if (priority->key == CK_HT_KEY_TOMBSTONE) {
CK_HT_TYPE_STORE(&map->deletions, map->deletions + 1);
ck_pr_fence_store();
}
candidate = priority;
probes = probes_wr;
}
#ifdef CK_HT_PP
ck_pr_store_ptr_unsafe(&candidate->value, (void *)entry->value);
ck_pr_fence_store();
ck_pr_store_ptr_unsafe(&candidate->key, (void *)entry->key);
#else
CK_HT_TYPE_STORE(&candidate->key_length, entry->key_length);
CK_HT_TYPE_STORE(&candidate->hash, entry->hash);
ck_pr_store_ptr_unsafe(&candidate->value, (void *)entry->value);
ck_pr_fence_store();
ck_pr_store_ptr_unsafe(&candidate->key, (void *)entry->key);
#endif
/*
* If we are insert a new entry then increment number
* of entries associated with map.
*/
if (replace == false)
CK_HT_TYPE_STORE(&map->n_entries, map->n_entries + 1);
}
ck_ht_map_bound_set(map, h, probes);
/* Enforce a load factor of 0.5. */
if (map->n_entries * 2 > map->capacity)
ck_ht_grow_spmc(table, map->capacity << 1);
if (empty == true) {
entry->key = CK_HT_KEY_EMPTY;
} else {
*entry = snapshot;
}
return true;
}
bool
ck_ht_put_spmc(struct ck_ht *table,
ck_ht_hash_t h,
ck_ht_entry_t *entry)
{
struct ck_ht_entry snapshot, *candidate, *priority;
struct ck_ht_map *map;
CK_HT_TYPE probes, probes_wr;
for (;;) {
map = table->map;
if (table->mode & CK_HT_MODE_BYTESTRING) {
candidate = ck_ht_map_probe_wr(map, h, &snapshot, &priority,
ck_ht_entry_key(entry),
ck_ht_entry_key_length(entry),
&probes, &probes_wr);
} else {
candidate = ck_ht_map_probe_wr(map, h, &snapshot, &priority,
(void *)entry->key,
sizeof(entry->key),
&probes, &probes_wr);
}
if (candidate != NULL || priority != NULL)
break;
if (ck_ht_grow_spmc(table, map->capacity << 1) == false)
return false;
}
if (priority != NULL) {
/* Version counter is updated before re-use. */
CK_HT_TYPE_STORE(&map->deletions, map->deletions + 1);
ck_pr_fence_store();
/* Re-use tombstone if one was found. */
candidate = priority;
probes = probes_wr;
} else if (candidate->key != CK_HT_KEY_EMPTY &&
candidate->key != CK_HT_KEY_TOMBSTONE) {
/*
* If the snapshot key is non-empty and the value field is not
* a tombstone then an identical key was found. As store does
* not implement replacement, we will fail.
*/
return false;
}
ck_ht_map_bound_set(map, h, probes);
#ifdef CK_HT_PP
ck_pr_store_ptr_unsafe(&candidate->value, (void *)entry->value);
ck_pr_fence_store();
ck_pr_store_ptr_unsafe(&candidate->key, (void *)entry->key);
#else
CK_HT_TYPE_STORE(&candidate->key_length, entry->key_length);
CK_HT_TYPE_STORE(&candidate->hash, entry->hash);
ck_pr_store_ptr_unsafe(&candidate->value, (void *)entry->value);
ck_pr_fence_store();
ck_pr_store_ptr_unsafe(&candidate->key, (void *)entry->key);
#endif
CK_HT_TYPE_STORE(&map->n_entries, map->n_entries + 1);
/* Enforce a load factor of 0.5. */
if (map->n_entries * 2 > map->capacity)
ck_ht_grow_spmc(table, map->capacity << 1);
return true;
}
void
ck_ht_destroy(struct ck_ht *table)
{
ck_ht_map_destroy(table->m, table->map, false);
return;
}