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Add rtree lookup path caching.

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rtree-based extent lookups remain more expensive than chunk-based run
lookups, but with this optimization the fast path slowdown is ~3 CPU
cycles per metadata lookup (on Intel Core i7-4980HQ), versus ~11 cycles
prior.  The path caching speedup tends to degrade gracefully unless
allocated memory is spread far apart (as is the case when using a
mixture of sbrk() and mmap()).
This commit is contained in:
Jason Evans 2016-06-02 18:43:10 -07:00
parent 7be2ebc23f
commit 6f29a83924
7 changed files with 267 additions and 94 deletions
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5
include/jemalloc/internal/extent.h
View File

@ -181,8 +181,11 @@ void extent_ring_remove(extent_t *extent);
JEMALLOC_INLINE extent_t *
extent_lookup(tsdn_t *tsdn, const void *ptr, bool dependent)
{
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
return (rtree_read(tsdn, &extents_rtree, (uintptr_t)ptr, dependent));
return (rtree_read(tsdn, &extents_rtree, rtree_ctx, (uintptr_t)ptr,
dependent));
}
JEMALLOC_INLINE arena_t *

5
include/jemalloc/internal/private_symbols.txt
View File

@ -399,6 +399,7 @@ rtree_child_read
rtree_child_read_hard
rtree_child_tryread
rtree_clear
rtree_ctx_start_level
rtree_delete
rtree_elm_acquire
rtree_elm_lookup
@ -502,6 +503,9 @@ tsd_nominal
tsd_prof_tdata_get
tsd_prof_tdata_set
tsd_prof_tdatap_get
tsd_rtree_ctx_get
tsd_rtree_ctx_set
tsd_rtree_ctxp_get
tsd_rtree_elm_witnesses_get
tsd_rtree_elm_witnesses_set
tsd_rtree_elm_witnessesp_get
@ -529,6 +533,7 @@ tsd_witnesses_set
tsd_witnessesp_get
tsdn_fetch
tsdn_null
tsdn_rtree_ctx
tsdn_tsd
witness_assert_lockless
witness_assert_not_owner

181
include/jemalloc/internal/rtree.h
View File

@ -10,6 +10,7 @@ typedef struct rtree_elm_s rtree_elm_t;
typedef struct rtree_elm_witness_s rtree_elm_witness_t;
typedef struct rtree_elm_witness_tsd_s rtree_elm_witness_tsd_t;
typedef struct rtree_level_s rtree_level_t;
typedef struct rtree_ctx_s rtree_ctx_t;
typedef struct rtree_s rtree_t;
/*
@ -25,6 +26,13 @@ typedef struct rtree_s rtree_t;
/* Used for two-stage lock-free node initialization. */
#define RTREE_NODE_INITIALIZING ((rtree_elm_t *)0x1)
#define RTREE_CTX_INITIALIZER { \
false, \
0, \
0, \
{NULL /* C initializes all trailing elements to NULL. */} \
}
/*
* Maximum number of concurrently acquired elements per thread. This controls
* how many witness_t structures are embedded in tsd. Ideally rtree_elm_t would
@ -78,9 +86,9 @@ struct rtree_level_s {
*
* Suppose keys comprise 48 bits, and LG_RTREE_BITS_PER_LEVEL is 4.
* This results in a 3-level tree, and the leftmost leaf can be directly
* accessed via subtrees[2], the subtree prefixed by 0x0000 (excluding
* 0x00000000) can be accessed via subtrees[1], and the remainder of the
* tree can be accessed via subtrees[0].
* accessed via levels[2], the subtree prefixed by 0x0000 (excluding
* 0x00000000) can be accessed via levels[1], and the remainder of the
* tree can be accessed via levels[0].
*
* levels[0] : [<unused> | 0x0001******** | 0x0002******** | ...]
*
@ -90,7 +98,7 @@ struct rtree_level_s {
*
* This has practical implications on x64, which currently uses only the
* lower 47 bits of virtual address space in userland, thus leaving
* subtrees[0] unused and avoiding a level of tree traversal.
* levels[0] unused and avoiding a level of tree traversal.
*/
union {
void *subtree_pun;
@ -105,13 +113,31 @@ struct rtree_level_s {
unsigned cumbits;
};
struct rtree_ctx_s {
/* If false, key/elms have not yet been initialized by a lookup. */
bool valid;
/* Key that corresponds to the tree path recorded in elms. */
uintptr_t key;
/* Memoized rtree_start_level(key). */
unsigned start_level;
/*
* A path through rtree, driven by key. Only elements that could
* actually be used for subsequent lookups are initialized, i.e. if
* start_level = rtree_start_level(key) is non-zero, the first
* start_level elements are uninitialized. The last element contains a
* pointer to the leaf node element that corresponds to key, so that
* exact matches require no tree node offset computation.
*/
rtree_elm_t *elms[RTREE_HEIGHT_MAX + 1];
};
struct rtree_s {
unsigned height;
/*
* Precomputed table used to convert from the number of leading 0 key
* bits to which subtree level to start at.
*/
unsigned start_level[RTREE_HEIGHT_MAX];
unsigned start_level[RTREE_HEIGHT_MAX + 1];
rtree_level_t levels[RTREE_HEIGHT_MAX];
};
@ -143,7 +169,9 @@ void rtree_elm_witness_release(tsdn_t *tsdn, const rtree_t *rtree,
#ifdef JEMALLOC_H_INLINES
#ifndef JEMALLOC_ENABLE_INLINE
unsigned rtree_start_level(rtree_t *rtree, uintptr_t key);
unsigned rtree_start_level(const rtree_t *rtree, uintptr_t key);
unsigned rtree_ctx_start_level(const rtree_t *rtree,
const rtree_ctx_t *rtree_ctx, uintptr_t key);
uintptr_t rtree_subkey(rtree_t *rtree, uintptr_t key, unsigned level);
bool rtree_node_valid(rtree_elm_t *node);
@ -156,33 +184,55 @@ rtree_elm_t *rtree_subtree_tryread(rtree_t *rtree, unsigned level,
bool dependent);
rtree_elm_t *rtree_subtree_read(tsdn_t *tsdn, rtree_t *rtree,
unsigned level, bool dependent);
rtree_elm_t *rtree_elm_lookup(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key,
bool dependent, bool init_missing);
rtree_elm_t *rtree_elm_lookup(tsdn_t *tsdn, rtree_t *rtree,
rtree_ctx_t *rtree_ctx, uintptr_t key, bool dependent, bool init_missing);
bool rtree_write(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key,
const extent_t *extent);
extent_t *rtree_read(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key,
bool dependent);
rtree_elm_t *rtree_elm_acquire(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key,
bool dependent, bool init_missing);
bool rtree_write(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, const extent_t *extent);
extent_t *rtree_read(tsdn_t *tsdn, rtree_t *rtree,
rtree_ctx_t *rtree_ctx, uintptr_t key, bool dependent);
rtree_elm_t *rtree_elm_acquire(tsdn_t *tsdn, rtree_t *rtree,
rtree_ctx_t *rtree_ctx, uintptr_t key, bool dependent, bool init_missing);
extent_t *rtree_elm_read_acquired(tsdn_t *tsdn, const rtree_t *rtree,
rtree_elm_t *elm);
void rtree_elm_write_acquired(tsdn_t *tsdn, const rtree_t *rtree,
rtree_elm_t *elm, const extent_t *extent);
void rtree_elm_release(tsdn_t *tsdn, const rtree_t *rtree, rtree_elm_t *elm);
void rtree_clear(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key);
void rtree_clear(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key);
#endif
#if (defined(JEMALLOC_ENABLE_INLINE) || defined(JEMALLOC_RTREE_C_))
JEMALLOC_ALWAYS_INLINE unsigned
rtree_start_level(rtree_t *rtree, uintptr_t key)
rtree_start_level(const rtree_t *rtree, uintptr_t key)
{
unsigned start_level;
if (unlikely(key == 0))
return (rtree->height - 1);
start_level = rtree->start_level[lg_floor(key) >>
start_level = rtree->start_level[(lg_floor(key) + 1) >>
LG_RTREE_BITS_PER_LEVEL];
assert(start_level < rtree->height);
return (start_level);
}
JEMALLOC_ALWAYS_INLINE unsigned
rtree_ctx_start_level(const rtree_t *rtree, const rtree_ctx_t *rtree_ctx,
uintptr_t key)
{
unsigned start_level;
uintptr_t key_diff;
/* Compute the difference between old and new lookup keys. */
key_diff = key ^ rtree_ctx->key;
assert(key_diff != 0); /* Handled in rtree_elm_lookup(). */
/*
* Compute the last traversal path element at which the keys' paths
* are the same.
*/
start_level = rtree->start_level[(lg_floor(key_diff) + 1) >>
LG_RTREE_BITS_PER_LEVEL];
assert(start_level < rtree->height);
return (start_level);
@ -291,8 +341,8 @@ rtree_subtree_read(tsdn_t *tsdn, rtree_t *rtree, unsigned level, bool dependent)
}
JEMALLOC_ALWAYS_INLINE rtree_elm_t *
rtree_elm_lookup(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key, bool dependent,
bool init_missing)
rtree_elm_lookup(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, bool dependent, bool init_missing)
{
uintptr_t subkey;
unsigned start_level;
@ -300,35 +350,95 @@ rtree_elm_lookup(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key, bool dependent,
assert(!dependent || !init_missing);
start_level = rtree_start_level(rtree, key);
if (dependent || init_missing) {
if (likely(rtree_ctx->valid)) {
if (key == rtree_ctx->key)
return (rtree_ctx->elms[rtree->height]);
else {
unsigned no_ctx_start_level =
rtree_start_level(rtree, key);
unsigned ctx_start_level;
if (likely(no_ctx_start_level <=
rtree_ctx->start_level && (ctx_start_level =
rtree_ctx_start_level(rtree, rtree_ctx,
key)) >= rtree_ctx->start_level)) {
start_level = ctx_start_level;
node = rtree_ctx->elms[ctx_start_level];
} else {
start_level = no_ctx_start_level;
node = init_missing ?
rtree_subtree_read(tsdn, rtree,
no_ctx_start_level, dependent) :
rtree_subtree_tryread(rtree,
no_ctx_start_level, dependent);
rtree_ctx->start_level =
no_ctx_start_level;
rtree_ctx->elms[no_ctx_start_level] =
node;
}
}
} else {
unsigned no_ctx_start_level = rtree_start_level(rtree,
key);
start_level = no_ctx_start_level;
node = init_missing ? rtree_subtree_read(tsdn, rtree,
no_ctx_start_level, dependent) :
rtree_subtree_tryread(rtree, no_ctx_start_level,
dependent);
rtree_ctx->valid = true;
rtree_ctx->start_level = no_ctx_start_level;
rtree_ctx->elms[no_ctx_start_level] = node;
}
rtree_ctx->key = key;
} else {
start_level = rtree_start_level(rtree, key);
node = init_missing ? rtree_subtree_read(tsdn, rtree,
start_level, dependent) : rtree_subtree_tryread(rtree,
start_level, dependent);
}
node = init_missing ? rtree_subtree_read(tsdn, rtree, start_level,
dependent) : rtree_subtree_tryread(rtree, start_level, dependent);
#define RTREE_GET_BIAS (RTREE_HEIGHT_MAX - rtree->height)
switch (start_level + RTREE_GET_BIAS) {
#define RTREE_GET_SUBTREE(level) \
case level: \
assert(level < (RTREE_HEIGHT_MAX-1)); \
if (!dependent && unlikely(!rtree_node_valid(node))) \
if (!dependent && unlikely(!rtree_node_valid(node))) { \
if (init_missing) \
rtree_ctx->valid = false; \
return (NULL); \
} \
subkey = rtree_subkey(rtree, key, level - \
RTREE_GET_BIAS); \
node = init_missing ? rtree_child_read(tsdn, rtree, \
&node[subkey], level - RTREE_GET_BIAS, dependent) : \
rtree_child_tryread(&node[subkey], dependent); \
if (dependent || init_missing) { \
rtree_ctx->elms[level - RTREE_GET_BIAS + 1] = \
node; \
} \
/* Fall through. */
#define RTREE_GET_LEAF(level) \
case level: \
assert(level == (RTREE_HEIGHT_MAX-1)); \
if (!dependent && unlikely(!rtree_node_valid(node))) \
if (!dependent && unlikely(!rtree_node_valid(node))) { \
if (init_missing) \
rtree_ctx->valid = false; \
return (NULL); \
} \
subkey = rtree_subkey(rtree, key, level - \
RTREE_GET_BIAS); \
/* \
* node is a leaf, so it contains values rather than \
* child pointers. \
*/ \
return (&node[subkey]);
node = &node[subkey]; \
if (dependent || init_missing) { \
rtree_ctx->elms[level - RTREE_GET_BIAS + 1] = \
node; \
} \
return (node);
#if RTREE_HEIGHT_MAX > 1
RTREE_GET_SUBTREE(0)
#endif
@ -387,14 +497,15 @@ rtree_elm_lookup(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key, bool dependent,
}
JEMALLOC_INLINE bool
rtree_write(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key, const extent_t *extent)
rtree_write(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, uintptr_t key,
const extent_t *extent)
{
rtree_elm_t *elm;
assert(extent != NULL); /* Use rtree_clear() for this case. */
assert(((uintptr_t)extent & (uintptr_t)0x1) == (uintptr_t)0x0);
elm = rtree_elm_lookup(tsdn, rtree, key, false, true);
elm = rtree_elm_lookup(tsdn, rtree, rtree_ctx, key, false, true);
if (elm == NULL)
return (true);
assert(rtree_elm_read(elm, false) == NULL);
@ -404,11 +515,12 @@ rtree_write(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key, const extent_t *extent)
}
JEMALLOC_ALWAYS_INLINE extent_t *
rtree_read(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key, bool dependent)
rtree_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, uintptr_t key,
bool dependent)
{
rtree_elm_t *elm;
elm = rtree_elm_lookup(tsdn, rtree, key, dependent, false);
elm = rtree_elm_lookup(tsdn, rtree, rtree_ctx, key, dependent, false);
if (elm == NULL)
return (NULL);
@ -416,12 +528,13 @@ rtree_read(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key, bool dependent)
}
JEMALLOC_INLINE rtree_elm_t *
rtree_elm_acquire(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key, bool dependent,
bool init_missing)
rtree_elm_acquire(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, bool dependent, bool init_missing)
{
rtree_elm_t *elm;
elm = rtree_elm_lookup(tsdn, rtree, key, dependent, init_missing);
elm = rtree_elm_lookup(tsdn, rtree, rtree_ctx, key, dependent,
init_missing);
if (!dependent && elm == NULL)
return (NULL);
{
@ -481,11 +594,11 @@ rtree_elm_release(tsdn_t *tsdn, const rtree_t *rtree, rtree_elm_t *elm)
}
JEMALLOC_INLINE void
rtree_clear(tsdn_t *tsdn, rtree_t *rtree, uintptr_t key)
rtree_clear(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, uintptr_t key)
{
rtree_elm_t *elm;
elm = rtree_elm_acquire(tsdn, rtree, key, true, false);
elm = rtree_elm_acquire(tsdn, rtree, rtree_ctx, key, true, false);
rtree_elm_write_acquired(tsdn, rtree, elm, NULL);
rtree_elm_release(tsdn, rtree, elm);
}

19
include/jemalloc/internal/tsd.h
View File

@ -572,6 +572,7 @@ struct tsd_init_head_s {
O(narenas_tdata, unsigned, no) \
O(arenas_tdata_bypass, bool, no) \
O(tcache_enabled, tcache_enabled_t, no) \
O(rtree_ctx, rtree_ctx_t, no) \
O(witnesses, witness_list_t, yes) \
O(rtree_elm_witnesses, rtree_elm_witness_tsd_t,no) \
O(witness_fork, bool, no) \
@ -588,6 +589,7 @@ struct tsd_init_head_s {
0, \
false, \
tcache_enabled_default, \
RTREE_CTX_INITIALIZER, \
ql_head_initializer(witnesses), \
RTREE_ELM_WITNESS_TSD_INITIALIZER, \
false \
@ -651,6 +653,7 @@ MALLOC_TSD
tsdn_t *tsdn_fetch(void);
bool tsdn_null(const tsdn_t *tsdn);
tsd_t *tsdn_tsd(tsdn_t *tsdn);
rtree_ctx_t *tsdn_rtree_ctx(tsdn_t *tsdn, rtree_ctx_t *fallback);
#endif
#if (defined(JEMALLOC_ENABLE_INLINE) || defined(JEMALLOC_TSD_C_))
@ -741,6 +744,22 @@ tsdn_tsd(tsdn_t *tsdn)
return (&tsdn->tsd);
}
JEMALLOC_ALWAYS_INLINE rtree_ctx_t *
tsdn_rtree_ctx(tsdn_t *tsdn, rtree_ctx_t *fallback)
{
/*
* If tsd cannot be accessed, initialize the fallback rtree_ctx and
* return a pointer to it.
*/
if (unlikely(tsdn_null(tsdn))) {
static const rtree_ctx_t rtree_ctx = RTREE_CTX_INITIALIZER;
memcpy(fallback, &rtree_ctx, sizeof(rtree_ctx_t));
return (fallback);
}
return (tsd_rtree_ctxp_get(tsdn_tsd(tsdn)));
}
#endif
#endif /* JEMALLOC_H_INLINES */

65
src/extent.c
View File

@ -259,18 +259,19 @@ extent_heaps_remove(extent_heap_t extent_heaps[NPSIZES], extent_t *extent)
}
static bool
extent_rtree_acquire(tsdn_t *tsdn, const extent_t *extent, bool dependent,
bool init_missing, rtree_elm_t **r_elm_a, rtree_elm_t **r_elm_b)
extent_rtree_acquire(tsdn_t *tsdn, rtree_ctx_t *rtree_ctx,
const extent_t *extent, bool dependent, bool init_missing,
rtree_elm_t **r_elm_a, rtree_elm_t **r_elm_b)
{
*r_elm_a = rtree_elm_acquire(tsdn, &extents_rtree,
*r_elm_a = rtree_elm_acquire(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)extent_base_get(extent), dependent, init_missing);
if (!dependent && *r_elm_a == NULL)
return (true);
assert(*r_elm_a != NULL);
if (extent_size_get(extent) > PAGE) {
*r_elm_b = rtree_elm_acquire(tsdn, &extents_rtree,
*r_elm_b = rtree_elm_acquire(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)extent_last_get(extent), dependent,
init_missing);
if (!dependent && *r_elm_b == NULL)
@ -302,14 +303,15 @@ extent_rtree_release(tsdn_t *tsdn, rtree_elm_t *elm_a, rtree_elm_t *elm_b)
}
static void
extent_interior_register(tsdn_t *tsdn, const extent_t *extent)
extent_interior_register(tsdn_t *tsdn, rtree_ctx_t *rtree_ctx,
const extent_t *extent)
{
size_t i;
assert(extent_slab_get(extent));
for (i = 1; i < (extent_size_get(extent) >> LG_PAGE) - 1; i++) {
rtree_write(tsdn, &extents_rtree,
rtree_write(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)extent_base_get(extent) + (uintptr_t)(i <<
LG_PAGE), extent);
}
@ -318,13 +320,16 @@ extent_interior_register(tsdn_t *tsdn, const extent_t *extent)
static bool
extent_register(tsdn_t *tsdn, const extent_t *extent)
{
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
rtree_elm_t *elm_a, *elm_b;
if (extent_rtree_acquire(tsdn, extent, false, true, &elm_a, &elm_b))
if (extent_rtree_acquire(tsdn, rtree_ctx, extent, false, true, &elm_a,
&elm_b))
return (true);
extent_rtree_write_acquired(tsdn, elm_a, elm_b, extent);
if (extent_slab_get(extent))
extent_interior_register(tsdn, extent);
extent_interior_register(tsdn, rtree_ctx, extent);
extent_rtree_release(tsdn, elm_a, elm_b);
if (config_prof && opt_prof && extent_active_get(extent)) {
@ -347,14 +352,15 @@ extent_register(tsdn_t *tsdn, const extent_t *extent)
}
static void
extent_interior_deregister(tsdn_t *tsdn, const extent_t *extent)
extent_interior_deregister(tsdn_t *tsdn, rtree_ctx_t *rtree_ctx,
const extent_t *extent)
{
size_t i;
assert(extent_slab_get(extent));
for (i = 1; i < (extent_size_get(extent) >> LG_PAGE) - 1; i++) {
rtree_clear(tsdn, &extents_rtree,
rtree_clear(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)extent_base_get(extent) + (uintptr_t)(i <<
LG_PAGE));
}
@ -363,12 +369,15 @@ extent_interior_deregister(tsdn_t *tsdn, const extent_t *extent)
static void
extent_deregister(tsdn_t *tsdn, const extent_t *extent)
{
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
rtree_elm_t *elm_a, *elm_b;
extent_rtree_acquire(tsdn, extent, true, false, &elm_a, &elm_b);
extent_rtree_acquire(tsdn, rtree_ctx, extent, true, false, &elm_a,
&elm_b);
extent_rtree_write_acquired(tsdn, elm_a, elm_b, NULL);
if (extent_slab_get(extent))
extent_interior_deregister(tsdn, extent);
extent_interior_deregister(tsdn, rtree_ctx, extent);
extent_rtree_release(tsdn, elm_a, elm_b);
if (config_prof && opt_prof && extent_active_get(extent)) {
@ -422,6 +431,8 @@ extent_recycle(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
bool slab)
{
extent_t *extent;
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
size_t size, alloc_size, leadsize, trailsize;
assert(new_addr == NULL || !slab);
@ -437,7 +448,7 @@ extent_recycle(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
if (new_addr != NULL) {
rtree_elm_t *elm;
elm = rtree_elm_acquire(tsdn, &extents_rtree,
elm = rtree_elm_acquire(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)new_addr, false, false);
if (elm != NULL) {
extent = rtree_elm_read_acquired(tsdn, &extents_rtree,
@ -515,7 +526,7 @@ extent_recycle(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
extent_active_set(extent, true);
if (slab) {
extent_slab_set(extent, slab);
extent_interior_register(tsdn, extent);
extent_interior_register(tsdn, rtree_ctx, extent);
}
malloc_mutex_unlock(tsdn, &arena->extents_mtx);
@ -731,6 +742,8 @@ extent_record(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
extent_heap_t extent_heaps[NPSIZES], bool cache, extent_t *extent)
{
extent_t *prev, *next;
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
assert(!cache || !extent_zeroed_get(extent));
@ -741,7 +754,7 @@ extent_record(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
extent_active_set(extent, false);
extent_zeroed_set(extent, !cache && extent_zeroed_get(extent));
if (extent_slab_get(extent)) {
extent_interior_deregister(tsdn, extent);
extent_interior_deregister(tsdn, rtree_ctx, extent);
extent_slab_set(extent, false);
}
@ -750,7 +763,7 @@ extent_record(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
arena_extent_cache_maybe_insert(arena, extent, cache);
/* Try to coalesce forward. */
next = rtree_read(tsdn, &extents_rtree,
next = rtree_read(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)extent_past_get(extent), false);
if (next != NULL) {
extent_try_coalesce(tsdn, arena, extent_hooks, extent, next,
@ -758,7 +771,7 @@ extent_record(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
}
/* Try to coalesce backward. */
prev = rtree_read(tsdn, &extents_rtree,
prev = rtree_read(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)extent_before_get(extent), false);
if (prev != NULL) {
extent_try_coalesce(tsdn, arena, extent_hooks, prev, extent,
@ -910,6 +923,8 @@ extent_split_wrapper(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
size_t usize_b)
{
extent_t *trail;
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
rtree_elm_t *lead_elm_a, *lead_elm_b, *trail_elm_a, *trail_elm_b;
assert(extent_size_get(extent) == size_a + size_b);
@ -928,8 +943,8 @@ extent_split_wrapper(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
extent_zeroed_get(extent), extent_committed_get(extent),
extent_slab_get(extent));
if (extent_rtree_acquire(tsdn, &lead, false, true, &lead_elm_a,
&lead_elm_b))
if (extent_rtree_acquire(tsdn, rtree_ctx, &lead, false, true,
&lead_elm_a, &lead_elm_b))
goto label_error_b;
}
@ -937,8 +952,8 @@ extent_split_wrapper(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
size_a), size_b, usize_b, extent_active_get(extent),
extent_zeroed_get(extent), extent_committed_get(extent),
extent_slab_get(extent));
if (extent_rtree_acquire(tsdn, trail, false, true, &trail_elm_a,
&trail_elm_b))
if (extent_rtree_acquire(tsdn, rtree_ctx, trail, false, true,
&trail_elm_a, &trail_elm_b))
goto label_error_c;
if (extent_hooks->split(extent_base_get(extent), size_a + size_b,
@ -985,6 +1000,8 @@ bool
extent_merge_wrapper(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
extent_t *a, extent_t *b)
{
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
rtree_elm_t *a_elm_a, *a_elm_b, *b_elm_a, *b_elm_b;
extent_hooks_assure_initialized(tsdn, arena, extent_hooks);
@ -998,8 +1015,10 @@ extent_merge_wrapper(tsdn_t *tsdn, arena_t *arena, extent_hooks_t *extent_hooks,
* owned, so the following code uses decomposed helper functions rather
* than extent_{,de}register() to do things in the right order.
*/
extent_rtree_acquire(tsdn, a, true, false, &a_elm_a, &a_elm_b);
extent_rtree_acquire(tsdn, b, true, false, &b_elm_a, &b_elm_b);
extent_rtree_acquire(tsdn, rtree_ctx, a, true, false, &a_elm_a,
&a_elm_b);
extent_rtree_acquire(tsdn, rtree_ctx, b, true, false, &b_elm_a,
&b_elm_b);
if (a_elm_b != NULL) {
rtree_elm_write_acquired(tsdn, &extents_rtree, a_elm_b, NULL);

3
src/rtree.c
View File

@ -52,11 +52,12 @@ rtree_new(rtree_t *rtree, unsigned bits)
rtree->levels[height-1].cumbits = bits;
}
/* Compute lookup table to be used by rtree_start_level(). */
/* Compute lookup table to be used by rtree_[ctx_]start_level(). */
for (i = 0; i < RTREE_HEIGHT_MAX; i++) {
rtree->start_level[i] = hmin(RTREE_HEIGHT_MAX - 1 - i, height -
1);
}
rtree->start_level[RTREE_HEIGHT_MAX] = 0;
return (false);
}

83
test/unit/rtree.c
View File

@ -40,10 +40,11 @@ TEST_BEGIN(test_rtree_read_empty)
for (i = 1; i <= (sizeof(uintptr_t) << 3); i++) {
rtree_t rtree;
rtree_ctx_t rtree_ctx = RTREE_CTX_INITIALIZER;
test_rtree = &rtree;
assert_false(rtree_new(&rtree, i),
"Unexpected rtree_new() failure");
assert_ptr_null(rtree_read(tsdn, &rtree, 0, false),
assert_ptr_null(rtree_read(tsdn, &rtree, &rtree_ctx, 0, false),
"rtree_read() should return NULL for empty tree");
rtree_delete(tsdn, &rtree);
test_rtree = NULL;
@ -66,7 +67,8 @@ static void *
thd_start(void *varg)
{
thd_start_arg_t *arg = (thd_start_arg_t *)varg;
sfmt_t *sfmt;
rtree_ctx_t rtree_ctx = RTREE_CTX_INITIALIZER;
sfmt_t *sfmt;
extent_t *extent;
tsdn_t *tsdn;
unsigned i;
@ -81,21 +83,22 @@ thd_start(void *varg)
if (i % 2 == 0) {
rtree_elm_t *elm;
elm = rtree_elm_acquire(tsdn, &arg->rtree, key, false,
true);
elm = rtree_elm_acquire(tsdn, &arg->rtree, &rtree_ctx,
key, false, true);
assert_ptr_not_null(elm,
"Unexpected rtree_elm_acquire() failure");
rtree_elm_write_acquired(tsdn, &arg->rtree, elm, extent);
rtree_elm_write_acquired(tsdn, &arg->rtree, elm,
extent);
rtree_elm_release(tsdn, &arg->rtree, elm);
elm = rtree_elm_acquire(tsdn, &arg->rtree, key, true,
false);
elm = rtree_elm_acquire(tsdn, &arg->rtree, &rtree_ctx,
key, true, false);
assert_ptr_not_null(elm,
"Unexpected rtree_elm_acquire() failure");
rtree_elm_read_acquired(tsdn, &arg->rtree, elm);
rtree_elm_release(tsdn, &arg->rtree, elm);
} else
rtree_read(tsdn, &arg->rtree, key, false);
rtree_read(tsdn, &arg->rtree, &rtree_ctx, key, false);
}
free(extent);
@ -145,19 +148,22 @@ TEST_BEGIN(test_rtree_extrema)
for (i = 1; i <= (sizeof(uintptr_t) << 3); i++) {
rtree_t rtree;
rtree_ctx_t rtree_ctx = RTREE_CTX_INITIALIZER;
test_rtree = &rtree;
assert_false(rtree_new(&rtree, i),
"Unexpected rtree_new() failure");
assert_false(rtree_write(tsdn, &rtree, 0, &extent_a),
"Unexpected rtree_write() failure, i=%u", i);
assert_ptr_eq(rtree_read(tsdn, &rtree, 0, true), &extent_a,
assert_false(rtree_write(tsdn, &rtree, &rtree_ctx, 0,
&extent_a), "Unexpected rtree_write() failure, i=%u", i);
assert_ptr_eq(rtree_read(tsdn, &rtree, &rtree_ctx, 0, true),
&extent_a,
"rtree_read() should return previously set value, i=%u", i);
assert_false(rtree_write(tsdn, &rtree, ~((uintptr_t)0),
&extent_b), "Unexpected rtree_write() failure, i=%u", i);
assert_ptr_eq(rtree_read(tsdn, &rtree, ~((uintptr_t)0), true),
&extent_b,
assert_false(rtree_write(tsdn, &rtree, &rtree_ctx,
~((uintptr_t)0), &extent_b),
"Unexpected rtree_write() failure, i=%u", i);
assert_ptr_eq(rtree_read(tsdn, &rtree, &rtree_ctx,
~((uintptr_t)0), true), &extent_b,
"rtree_read() should return previously set value, i=%u", i);
rtree_delete(tsdn, &rtree);
@ -178,27 +184,30 @@ TEST_BEGIN(test_rtree_bits)
(((uintptr_t)1) << (sizeof(uintptr_t)*8-i)) - 1};
extent_t extent;
rtree_t rtree;
rtree_ctx_t rtree_ctx = RTREE_CTX_INITIALIZER;
test_rtree = &rtree;
assert_false(rtree_new(&rtree, i),
"Unexpected rtree_new() failure");
for (j = 0; j < sizeof(keys)/sizeof(uintptr_t); j++) {
assert_false(rtree_write(tsdn, &rtree, keys[j],
&extent), "Unexpected rtree_write() failure");
assert_false(rtree_write(tsdn, &rtree, &rtree_ctx,
keys[j], &extent),
"Unexpected rtree_write() failure");
for (k = 0; k < sizeof(keys)/sizeof(uintptr_t); k++) {
assert_ptr_eq(rtree_read(tsdn, &rtree, keys[k],
true), &extent, "rtree_read() should "
"return previously set value and ignore "
"insignificant key bits; i=%u, j=%u, k=%u, "
"set key=%#"FMTxPTR", get key=%#"FMTxPTR, i,
j, k, keys[j], keys[k]);
assert_ptr_eq(rtree_read(tsdn, &rtree,
&rtree_ctx, keys[k], true), &extent,
"rtree_read() should return previously set "
"value and ignore insignificant key bits; "
"i=%u, j=%u, k=%u, set key=%#"FMTxPTR", "
"get key=%#"FMTxPTR, i, j, k, keys[j],
keys[k]);
}
assert_ptr_null(rtree_read(tsdn, &rtree,
assert_ptr_null(rtree_read(tsdn, &rtree, &rtree_ctx,
(((uintptr_t)1) << (sizeof(uintptr_t)*8-i)), false),
"Only leftmost rtree leaf should be set; "
"i=%u, j=%u", i, j);
rtree_clear(tsdn, &rtree, keys[j]);
rtree_clear(tsdn, &rtree, &rtree_ctx, keys[j]);
}
rtree_delete(tsdn, &rtree);
@ -222,6 +231,7 @@ TEST_BEGIN(test_rtree_random)
extent_t extent;
unsigned j;
rtree_t rtree;
rtree_ctx_t rtree_ctx = RTREE_CTX_INITIALIZER;
rtree_elm_t *elm;
test_rtree = &rtree;
@ -230,29 +240,32 @@ TEST_BEGIN(test_rtree_random)
for (j = 0; j < NSET; j++) {
keys[j] = (uintptr_t)gen_rand64(sfmt);
elm = rtree_elm_acquire(tsdn, &rtree, keys[j], false,
true);
elm = rtree_elm_acquire(tsdn, &rtree, &rtree_ctx,
keys[j], false, true);
assert_ptr_not_null(elm,
"Unexpected rtree_elm_acquire() failure");
rtree_elm_write_acquired(tsdn, &rtree, elm, &extent);
rtree_elm_release(tsdn, &rtree, elm);
assert_ptr_eq(rtree_read(tsdn, &rtree, keys[j], true),
&extent,
assert_ptr_eq(rtree_read(tsdn, &rtree, &rtree_ctx,
keys[j], true), &extent,
"rtree_read() should return previously set value");
}
for (j = 0; j < NSET; j++) {
assert_ptr_eq(rtree_read(tsdn, &rtree, keys[j], true),
&extent, "rtree_read() should return previously "
"set value, j=%u", j);
assert_ptr_eq(rtree_read(tsdn, &rtree, &rtree_ctx,
keys[j], true), &extent,
"rtree_read() should return previously set value, "
"j=%u", j);
}
for (j = 0; j < NSET; j++) {
rtree_clear(tsdn, &rtree, keys[j]);
assert_ptr_null(rtree_read(tsdn, &rtree, keys[j], true),
rtree_clear(tsdn, &rtree, &rtree_ctx, keys[j]);
assert_ptr_null(rtree_read(tsdn, &rtree, &rtree_ctx,
keys[j], true),
"rtree_read() should return previously set value");
}
for (j = 0; j < NSET; j++) {
assert_ptr_null(rtree_read(tsdn, &rtree, keys[j], true),
assert_ptr_null(rtree_read(tsdn, &rtree, &rtree_ctx,
keys[j], true),
"rtree_read() should return previously set value");
}