server-skynet-source-3rd-je.../src/psset.c

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#include "jemalloc/internal/jemalloc_preamble.h"
#include "jemalloc/internal/jemalloc_internal_includes.h"
#include "jemalloc/internal/psset.h"
#include "jemalloc/internal/flat_bitmap.h"
static const bitmap_info_t psset_bitmap_info =
BITMAP_INFO_INITIALIZER(PSSET_NPSIZES);
void
psset_init(psset_t *psset) {
for (unsigned i = 0; i < PSSET_NPSIZES; i++) {
edata_age_heap_new(&psset->pageslabs[i]);
}
bitmap_init(psset->bitmap, &psset_bitmap_info, /* fill */ true);
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psset->full_slab_stats.npageslabs = 0;
psset->full_slab_stats.nactive = 0;
psset->full_slab_stats.ninactive = 0;
for (unsigned i = 0; i < PSSET_NPSIZES; i++) {
psset->slab_stats[i].npageslabs = 0;
psset->slab_stats[i].nactive = 0;
psset->slab_stats[i].ninactive = 0;
}
psset->age_counter = 0;
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}
/*
* The stats maintenance strategy is simple, but not necessarily obvious.
* edata_nfree and the bitmap must remain consistent at all times. If they
* change while an edata is within an edata_heap (or full), then the associated
* stats bin (or the full bin) must also change. If they change while not in a
* bin (say, in between extraction and reinsertion), then the bin stats need not
* change. If a pageslab is removed from a bin (or becomes nonfull), it should
* no longer contribute to that bin's stats (or the full stats). These help
* ensure we don't miss any heap modification operations.
*/
JEMALLOC_ALWAYS_INLINE void
psset_bin_stats_adjust(psset_bin_stats_t *binstats, edata_t *ps, bool inc) {
size_t mul = inc ? (size_t)1 : (size_t)-1;
size_t npages = edata_size_get(ps) >> LG_PAGE;
size_t ninactive = edata_nfree_get(ps);
size_t nactive = npages - ninactive;
binstats->npageslabs += mul * 1;
binstats->nactive += mul * nactive;
binstats->ninactive += mul * ninactive;
}
static void
psset_edata_heap_remove(psset_t *psset, pszind_t pind, edata_t *ps) {
edata_age_heap_remove(&psset->pageslabs[pind], ps);
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psset_bin_stats_adjust(&psset->slab_stats[pind], ps, /* inc */ false);
}
static void
psset_edata_heap_insert(psset_t *psset, pszind_t pind, edata_t *ps) {
edata_age_heap_insert(&psset->pageslabs[pind], ps);
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psset_bin_stats_adjust(&psset->slab_stats[pind], ps, /* inc */ true);
}
JEMALLOC_ALWAYS_INLINE void
psset_assert_ps_consistent(edata_t *ps) {
assert(fb_urange_longest(edata_slab_data_get(ps)->bitmap,
edata_size_get(ps) >> LG_PAGE) == edata_longest_free_range_get(ps));
}
/*
* Similar to PAC's extent_recycle_extract. Out of all the pageslabs in the
* set, picks one that can satisfy the allocation and remove it from the set.
*/
static edata_t *
psset_recycle_extract(psset_t *psset, size_t size) {
pszind_t min_pind = sz_psz2ind(sz_psz_quantize_ceil(size));
pszind_t pind = (pszind_t)bitmap_ffu(psset->bitmap, &psset_bitmap_info,
(size_t)min_pind);
if (pind == PSSET_NPSIZES) {
return NULL;
}
edata_t *ps = edata_age_heap_first(&psset->pageslabs[pind]);
if (ps == NULL) {
return NULL;
}
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psset_edata_heap_remove(psset, pind, ps);
if (edata_age_heap_empty(&psset->pageslabs[pind])) {
bitmap_set(psset->bitmap, &psset_bitmap_info, pind);
}
psset_assert_ps_consistent(ps);
return ps;
}
static void
psset_insert(psset_t *psset, edata_t *ps, size_t largest_range) {
psset_assert_ps_consistent(ps);
pszind_t pind = sz_psz2ind(sz_psz_quantize_floor(
largest_range << LG_PAGE));
assert(pind < PSSET_NPSIZES);
if (edata_age_heap_empty(&psset->pageslabs[pind])) {
bitmap_unset(psset->bitmap, &psset_bitmap_info, (size_t)pind);
}
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psset_edata_heap_insert(psset, pind, ps);
}
/*
* Given a pageslab ps and an edata to allocate size bytes from, initializes the
* edata with a range in the pageslab, and puts ps back in the set.
*/
static void
psset_ps_alloc_insert(psset_t *psset, edata_t *ps, edata_t *r_edata,
size_t size) {
size_t start = 0;
/*
* These are dead stores, but the compiler will issue warnings on them
* since it can't tell statically that found is always true below.
*/
size_t begin = 0;
size_t len = 0;
fb_group_t *ps_fb = edata_slab_data_get(ps)->bitmap;
size_t npages = size >> LG_PAGE;
size_t ps_npages = edata_size_get(ps) >> LG_PAGE;
size_t largest_unchosen_range = 0;
while (true) {
bool found = fb_urange_iter(ps_fb, ps_npages, start, &begin,
&len);
/*
* A precondition to this function is that ps must be able to
* serve the allocation.
*/
assert(found);
if (len >= npages) {
/*
* We use first-fit within the page slabs; this gives
* bounded worst-case fragmentation within a slab. It's
* not necessarily right; we could experiment with
* various other options.
*/
break;
}
if (len > largest_unchosen_range) {
largest_unchosen_range = len;
}
start = begin + len;
}
uintptr_t addr = (uintptr_t)edata_base_get(ps) + begin * PAGE;
edata_init(r_edata, edata_arena_ind_get(r_edata), (void *)addr, size,
/* slab */ false, SC_NSIZES, /* sn */ 0, extent_state_active,
/* zeroed */ false, /* committed */ true, EXTENT_PAI_HPA,
EXTENT_NOT_HEAD);
edata_ps_set(r_edata, ps);
fb_set_range(ps_fb, ps_npages, begin, npages);
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edata_nfree_set(ps, (uint32_t)(edata_nfree_get(ps) - npages));
/* The pageslab isn't in a bin, so no bin stats need to change. */
/*
* OK, we've got to put the pageslab back. First we have to figure out
* where, though; we've only checked run sizes before the pageslab we
* picked. We also need to look for ones after the one we picked. Note
* that we want begin + npages as the start position, not begin + len;
* we might not have used the whole range.
*
* TODO: With a little bit more care, we can guarantee that the longest
* free range field in the edata is accurate upon entry, and avoid doing
* this check in the case where we're allocating from some smaller run.
*/
start = begin + npages;
while (start < ps_npages) {
bool found = fb_urange_iter(ps_fb, ps_npages, start, &begin,
&len);
if (!found) {
break;
}
if (len > largest_unchosen_range) {
largest_unchosen_range = len;
}
start = begin + len;
}
edata_longest_free_range_set(ps, (uint32_t)largest_unchosen_range);
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if (largest_unchosen_range == 0) {
psset_bin_stats_adjust(&psset->full_slab_stats, ps,
/* inc */ true);
} else {
psset_insert(psset, ps, largest_unchosen_range);
}
}
bool
psset_alloc_reuse(psset_t *psset, edata_t *r_edata, size_t size) {
edata_t *ps = psset_recycle_extract(psset, size);
if (ps == NULL) {
return true;
}
psset_ps_alloc_insert(psset, ps, r_edata, size);
return false;
}
void
psset_alloc_new(psset_t *psset, edata_t *ps, edata_t *r_edata, size_t size) {
fb_group_t *ps_fb = edata_slab_data_get(ps)->bitmap;
size_t ps_npages = edata_size_get(ps) >> LG_PAGE;
assert(fb_empty(ps_fb, ps_npages));
assert(ps_npages >= (size >> LG_PAGE));
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edata_nfree_set(ps, (uint32_t)ps_npages);
edata_age_set(ps, psset->age_counter);
psset->age_counter++;
psset_ps_alloc_insert(psset, ps, r_edata, size);
}
edata_t *
psset_dalloc(psset_t *psset, edata_t *edata) {
assert(edata_pai_get(edata) == EXTENT_PAI_HPA);
assert(edata_ps_get(edata) != NULL);
edata_t *ps = edata_ps_get(edata);
fb_group_t *ps_fb = edata_slab_data_get(ps)->bitmap;
size_t ps_old_longest_free_range = edata_longest_free_range_get(ps);
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pszind_t old_pind = SC_NPSIZES;
if (ps_old_longest_free_range != 0) {
old_pind = sz_psz2ind(sz_psz_quantize_floor(
ps_old_longest_free_range << LG_PAGE));
}
size_t ps_npages = edata_size_get(ps) >> LG_PAGE;
size_t begin =
((uintptr_t)edata_base_get(edata) - (uintptr_t)edata_base_get(ps))
>> LG_PAGE;
size_t len = edata_size_get(edata) >> LG_PAGE;
fb_unset_range(ps_fb, ps_npages, begin, len);
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if (ps_old_longest_free_range == 0) {
/* We were in the (imaginary) full bin; update stats for it. */
psset_bin_stats_adjust(&psset->full_slab_stats, ps,
/* inc */ false);
} else {
/*
* The edata is still in the bin, need to update its
* contribution.
*/
psset->slab_stats[old_pind].nactive -= len;
psset->slab_stats[old_pind].ninactive += len;
}
/*
* Note that we want to do this after the stats updates, since if it was
* full it psset_bin_stats_adjust would have looked at the old version.
*/
edata_nfree_set(ps, (uint32_t)(edata_nfree_get(ps) + len));
/* We might have just created a new, larger range. */
size_t new_begin = (size_t)(fb_fls(ps_fb, ps_npages, begin) + 1);
size_t new_end = fb_ffs(ps_fb, ps_npages, begin + len - 1);
size_t new_range_len = new_end - new_begin;
/*
* If the new free range is no longer than the previous longest one,
* then the pageslab is non-empty and doesn't need to change bins.
* We're done, and don't need to return a pageslab to evict.
*/
if (new_range_len <= ps_old_longest_free_range) {
return NULL;
}
/*
* Otherwise, it might need to get evicted from the set, or change its
* bin.
*/
edata_longest_free_range_set(ps, (uint32_t)new_range_len);
/*
* If it was previously non-full, then it's in some (possibly now
* incorrect) bin already; remove it.
*
* TODO: We bailed out early above if we didn't expand the longest free
* range, which should avoid a lot of redundant remove/reinserts in the
* same bin. But it doesn't eliminate all of them; it's possible that
* we decreased the longest free range length, but only slightly, and
* not enough to change our pszind. We could check that more precisely.
* (Or, ideally, size class dequantization will happen at some point,
* and the issue becomes moot).
*/
if (ps_old_longest_free_range > 0) {
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psset_edata_heap_remove(psset, old_pind, ps);
if (edata_age_heap_empty(&psset->pageslabs[old_pind])) {
bitmap_set(psset->bitmap, &psset_bitmap_info,
(size_t)old_pind);
}
}
/* If the pageslab is empty, it gets evicted from the set. */
if (new_range_len == ps_npages) {
return ps;
}
/* Otherwise, it gets reinserted. */
pszind_t new_pind = sz_psz2ind(sz_psz_quantize_floor(
new_range_len << LG_PAGE));
if (edata_age_heap_empty(&psset->pageslabs[new_pind])) {
bitmap_unset(psset->bitmap, &psset_bitmap_info,
(size_t)new_pind);
}
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psset_edata_heap_insert(psset, new_pind, ps);
return NULL;
}