cpython/Objects/mimalloc/page.c

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/*----------------------------------------------------------------------------
Copyright (c) 2018-2020, Microsoft Research, Daan Leijen
This is free software; you can redistribute it and/or modify it under the
terms of the MIT license. A copy of the license can be found in the file
"LICENSE" at the root of this distribution.
-----------------------------------------------------------------------------*/
/* -----------------------------------------------------------
The core of the allocator. Every segment contains
pages of a certain block size. The main function
exported is `mi_malloc_generic`.
----------------------------------------------------------- */
#include "mimalloc.h"
#include "mimalloc/internal.h"
#include "mimalloc/atomic.h"
/* -----------------------------------------------------------
Definition of page queues for each block size
----------------------------------------------------------- */
#define MI_IN_PAGE_C
#include "page-queue.c"
#undef MI_IN_PAGE_C
/* -----------------------------------------------------------
Page helpers
----------------------------------------------------------- */
// Index a block in a page
static inline mi_block_t* mi_page_block_at(const mi_page_t* page, void* page_start, size_t block_size, size_t i) {
MI_UNUSED(page);
mi_assert_internal(page != NULL);
mi_assert_internal(i <= page->reserved);
return (mi_block_t*)((uint8_t*)page_start + (i * block_size));
}
static void mi_page_init(mi_heap_t* heap, mi_page_t* page, size_t size, mi_tld_t* tld);
static void mi_page_extend_free(mi_heap_t* heap, mi_page_t* page, mi_tld_t* tld);
#if (MI_DEBUG>=3)
static size_t mi_page_list_count(mi_page_t* page, mi_block_t* head) {
size_t count = 0;
while (head != NULL) {
mi_assert_internal(page == _mi_ptr_page(head));
count++;
head = mi_block_next(page, head);
}
return count;
}
/*
// Start of the page available memory
static inline uint8_t* mi_page_area(const mi_page_t* page) {
return _mi_page_start(_mi_page_segment(page), page, NULL);
}
*/
static bool mi_page_list_is_valid(mi_page_t* page, mi_block_t* p) {
size_t psize;
uint8_t* page_area = _mi_page_start(_mi_page_segment(page), page, &psize);
mi_block_t* start = (mi_block_t*)page_area;
mi_block_t* end = (mi_block_t*)(page_area + psize);
while(p != NULL) {
if (p < start || p >= end) return false;
p = mi_block_next(page, p);
}
#if MI_DEBUG>3 // generally too expensive to check this
if (page->free_is_zero) {
const size_t ubsize = mi_page_usable_block_size(page);
for (mi_block_t* block = page->free; block != NULL; block = mi_block_next(page, block)) {
mi_assert_expensive(mi_mem_is_zero(block + 1, ubsize - sizeof(mi_block_t)));
}
}
#endif
return true;
}
static bool mi_page_is_valid_init(mi_page_t* page) {
mi_assert_internal(page->xblock_size > 0);
mi_assert_internal(page->used <= page->capacity);
mi_assert_internal(page->capacity <= page->reserved);
mi_segment_t* segment = _mi_page_segment(page);
uint8_t* start = _mi_page_start(segment,page,NULL);
mi_assert_internal(start == _mi_segment_page_start(segment,page,NULL));
//const size_t bsize = mi_page_block_size(page);
//mi_assert_internal(start + page->capacity*page->block_size == page->top);
mi_assert_internal(mi_page_list_is_valid(page,page->free));
mi_assert_internal(mi_page_list_is_valid(page,page->local_free));
#if MI_DEBUG>3 // generally too expensive to check this
if (page->free_is_zero) {
const size_t ubsize = mi_page_usable_block_size(page);
for(mi_block_t* block = page->free; block != NULL; block = mi_block_next(page,block)) {
mi_assert_expensive(mi_mem_is_zero(block + 1, ubsize - sizeof(mi_block_t)));
}
}
#endif
#if !MI_TRACK_ENABLED && !MI_TSAN
mi_block_t* tfree = mi_page_thread_free(page);
mi_assert_internal(mi_page_list_is_valid(page, tfree));
//size_t tfree_count = mi_page_list_count(page, tfree);
//mi_assert_internal(tfree_count <= page->thread_freed + 1);
#endif
size_t free_count = mi_page_list_count(page, page->free) + mi_page_list_count(page, page->local_free);
mi_assert_internal(page->used + free_count == page->capacity);
return true;
}
extern bool _mi_process_is_initialized; // has mi_process_init been called?
bool _mi_page_is_valid(mi_page_t* page) {
mi_assert_internal(mi_page_is_valid_init(page));
#if MI_SECURE
mi_assert_internal(page->keys[0] != 0);
#endif
if (mi_page_heap(page)!=NULL) {
mi_segment_t* segment = _mi_page_segment(page);
mi_assert_internal(!_mi_process_is_initialized || segment->thread_id==0 || segment->thread_id == mi_page_heap(page)->thread_id);
#if MI_HUGE_PAGE_ABANDON
if (segment->kind != MI_SEGMENT_HUGE)
#endif
{
mi_page_queue_t* pq = mi_page_queue_of(page);
mi_assert_internal(mi_page_queue_contains(pq, page));
mi_assert_internal(pq->block_size==mi_page_block_size(page) || mi_page_block_size(page) > MI_MEDIUM_OBJ_SIZE_MAX || mi_page_is_in_full(page));
mi_assert_internal(mi_heap_contains_queue(mi_page_heap(page),pq));
}
}
return true;
}
#endif
void _mi_page_use_delayed_free(mi_page_t* page, mi_delayed_t delay, bool override_never) {
while (!_mi_page_try_use_delayed_free(page, delay, override_never)) {
mi_atomic_yield();
}
}
bool _mi_page_try_use_delayed_free(mi_page_t* page, mi_delayed_t delay, bool override_never) {
mi_thread_free_t tfreex;
mi_delayed_t old_delay;
mi_thread_free_t tfree;
size_t yield_count = 0;
do {
tfree = mi_atomic_load_acquire(&page->xthread_free); // note: must acquire as we can break/repeat this loop and not do a CAS;
tfreex = mi_tf_set_delayed(tfree, delay);
old_delay = mi_tf_delayed(tfree);
if mi_unlikely(old_delay == MI_DELAYED_FREEING) {
if (yield_count >= 4) return false; // give up after 4 tries
yield_count++;
mi_atomic_yield(); // delay until outstanding MI_DELAYED_FREEING are done.
// tfree = mi_tf_set_delayed(tfree, MI_NO_DELAYED_FREE); // will cause CAS to busy fail
}
else if (delay == old_delay) {
break; // avoid atomic operation if already equal
}
else if (!override_never && old_delay == MI_NEVER_DELAYED_FREE) {
break; // leave never-delayed flag set
}
} while ((old_delay == MI_DELAYED_FREEING) ||
!mi_atomic_cas_weak_release(&page->xthread_free, &tfree, tfreex));
return true; // success
}
/* -----------------------------------------------------------
Page collect the `local_free` and `thread_free` lists
----------------------------------------------------------- */
// Collect the local `thread_free` list using an atomic exchange.
// Note: The exchange must be done atomically as this is used right after
// moving to the full list in `mi_page_collect_ex` and we need to
// ensure that there was no race where the page became unfull just before the move.
static void _mi_page_thread_free_collect(mi_page_t* page)
{
mi_block_t* head;
mi_thread_free_t tfreex;
mi_thread_free_t tfree = mi_atomic_load_relaxed(&page->xthread_free);
do {
head = mi_tf_block(tfree);
tfreex = mi_tf_set_block(tfree,NULL);
} while (!mi_atomic_cas_weak_acq_rel(&page->xthread_free, &tfree, tfreex));
// return if the list is empty
if (head == NULL) return;
// find the tail -- also to get a proper count (without data races)
uint32_t max_count = page->capacity; // cannot collect more than capacity
uint32_t count = 1;
mi_block_t* tail = head;
mi_block_t* next;
while ((next = mi_block_next(page,tail)) != NULL && count <= max_count) {
count++;
tail = next;
}
// if `count > max_count` there was a memory corruption (possibly infinite list due to double multi-threaded free)
if (count > max_count) {
_mi_error_message(EFAULT, "corrupted thread-free list\n");
return; // the thread-free items cannot be freed
}
// and append the current local free list
mi_block_set_next(page,tail, page->local_free);
page->local_free = head;
// update counts now
page->used -= count;
}
void _mi_page_free_collect(mi_page_t* page, bool force) {
mi_assert_internal(page!=NULL);
// collect the thread free list
if (force || mi_page_thread_free(page) != NULL) { // quick test to avoid an atomic operation
_mi_page_thread_free_collect(page);
}
// and the local free list
if (page->local_free != NULL) {
// any previous QSBR goals are no longer valid because we reused the page
_PyMem_mi_page_clear_qsbr(page);
if mi_likely(page->free == NULL) {
// usual case
page->free = page->local_free;
page->local_free = NULL;
page->free_is_zero = false;
}
else if (force) {
// append -- only on shutdown (force) as this is a linear operation
mi_block_t* tail = page->local_free;
mi_block_t* next;
while ((next = mi_block_next(page, tail)) != NULL) {
tail = next;
}
mi_block_set_next(page, tail, page->free);
page->free = page->local_free;
page->local_free = NULL;
page->free_is_zero = false;
}
}
mi_assert_internal(!force || page->local_free == NULL);
}
/* -----------------------------------------------------------
Page fresh and retire
----------------------------------------------------------- */
// called from segments when reclaiming abandoned pages
void _mi_page_reclaim(mi_heap_t* heap, mi_page_t* page) {
mi_assert_expensive(mi_page_is_valid_init(page));
mi_assert_internal(mi_page_heap(page) == heap);
mi_assert_internal(mi_page_thread_free_flag(page) != MI_NEVER_DELAYED_FREE);
#if MI_HUGE_PAGE_ABANDON
mi_assert_internal(_mi_page_segment(page)->kind != MI_SEGMENT_HUGE);
#endif
// TODO: push on full queue immediately if it is full?
mi_page_queue_t* pq = mi_page_queue(heap, mi_page_block_size(page));
mi_page_queue_push(heap, pq, page);
_PyMem_mi_page_reclaimed(page);
mi_assert_expensive(_mi_page_is_valid(page));
}
// allocate a fresh page from a segment
static mi_page_t* mi_page_fresh_alloc(mi_heap_t* heap, mi_page_queue_t* pq, size_t block_size, size_t page_alignment) {
#if !MI_HUGE_PAGE_ABANDON
mi_assert_internal(pq != NULL);
mi_assert_internal(mi_heap_contains_queue(heap, pq));
mi_assert_internal(page_alignment > 0 || block_size > MI_MEDIUM_OBJ_SIZE_MAX || block_size == pq->block_size);
#endif
mi_page_t* page = _mi_segment_page_alloc(heap, block_size, page_alignment, &heap->tld->segments, &heap->tld->os);
if (page == NULL) {
// this may be out-of-memory, or an abandoned page was reclaimed (and in our queue)
return NULL;
}
mi_assert_internal(page_alignment >0 || block_size > MI_MEDIUM_OBJ_SIZE_MAX || _mi_page_segment(page)->kind != MI_SEGMENT_HUGE);
mi_assert_internal(pq!=NULL || page->xblock_size != 0);
mi_assert_internal(pq!=NULL || mi_page_block_size(page) >= block_size);
// a fresh page was found, initialize it
const size_t full_block_size = ((pq == NULL || mi_page_queue_is_huge(pq)) ? mi_page_block_size(page) : block_size); // see also: mi_segment_huge_page_alloc
mi_assert_internal(full_block_size >= block_size);
mi_page_init(heap, page, full_block_size, heap->tld);
mi_heap_stat_increase(heap, pages, 1);
if (pq != NULL) { mi_page_queue_push(heap, pq, page); }
mi_assert_expensive(_mi_page_is_valid(page));
return page;
}
// Get a fresh page to use
static mi_page_t* mi_page_fresh(mi_heap_t* heap, mi_page_queue_t* pq) {
mi_assert_internal(mi_heap_contains_queue(heap, pq));
mi_page_t* page = mi_page_fresh_alloc(heap, pq, pq->block_size, 0);
if (page==NULL) return NULL;
mi_assert_internal(pq->block_size==mi_page_block_size(page));
mi_assert_internal(pq==mi_page_queue(heap, mi_page_block_size(page)));
return page;
}
/* -----------------------------------------------------------
Do any delayed frees
(put there by other threads if they deallocated in a full page)
----------------------------------------------------------- */
void _mi_heap_delayed_free_all(mi_heap_t* heap) {
while (!_mi_heap_delayed_free_partial(heap)) {
mi_atomic_yield();
}
}
// returns true if all delayed frees were processed
bool _mi_heap_delayed_free_partial(mi_heap_t* heap) {
// take over the list (note: no atomic exchange since it is often NULL)
mi_block_t* block = mi_atomic_load_ptr_relaxed(mi_block_t, &heap->thread_delayed_free);
while (block != NULL && !mi_atomic_cas_ptr_weak_acq_rel(mi_block_t, &heap->thread_delayed_free, &block, NULL)) { /* nothing */ };
bool all_freed = true;
// and free them all
while(block != NULL) {
mi_block_t* next = mi_block_nextx(heap,block, heap->keys);
// use internal free instead of regular one to keep stats etc correct
if (!_mi_free_delayed_block(block)) {
// we might already start delayed freeing while another thread has not yet
// reset the delayed_freeing flag; in that case delay it further by reinserting the current block
// into the delayed free list
all_freed = false;
mi_block_t* dfree = mi_atomic_load_ptr_relaxed(mi_block_t, &heap->thread_delayed_free);
do {
mi_block_set_nextx(heap, block, dfree, heap->keys);
} while (!mi_atomic_cas_ptr_weak_release(mi_block_t,&heap->thread_delayed_free, &dfree, block));
}
block = next;
}
return all_freed;
}
/* -----------------------------------------------------------
Unfull, abandon, free and retire
----------------------------------------------------------- */
// Move a page from the full list back to a regular list
void _mi_page_unfull(mi_page_t* page) {
mi_assert_internal(page != NULL);
mi_assert_expensive(_mi_page_is_valid(page));
mi_assert_internal(mi_page_is_in_full(page));
if (!mi_page_is_in_full(page)) return;
mi_heap_t* heap = mi_page_heap(page);
mi_page_queue_t* pqfull = &heap->pages[MI_BIN_FULL];
mi_page_set_in_full(page, false); // to get the right queue
mi_page_queue_t* pq = mi_heap_page_queue_of(heap, page);
mi_page_set_in_full(page, true);
mi_page_queue_enqueue_from(pq, pqfull, page);
}
static void mi_page_to_full(mi_page_t* page, mi_page_queue_t* pq) {
mi_assert_internal(pq == mi_page_queue_of(page));
mi_assert_internal(!mi_page_immediate_available(page));
mi_assert_internal(!mi_page_is_in_full(page));
if (mi_page_is_in_full(page)) return;
mi_page_queue_enqueue_from(&mi_page_heap(page)->pages[MI_BIN_FULL], pq, page);
_mi_page_free_collect(page,false); // try to collect right away in case another thread freed just before MI_USE_DELAYED_FREE was set
}
// Abandon a page with used blocks at the end of a thread.
// Note: only call if it is ensured that no references exist from
// the `page->heap->thread_delayed_free` into this page.
// Currently only called through `mi_heap_collect_ex` which ensures this.
void _mi_page_abandon(mi_page_t* page, mi_page_queue_t* pq) {
mi_assert_internal(page != NULL);
mi_assert_expensive(_mi_page_is_valid(page));
mi_assert_internal(pq == mi_page_queue_of(page));
mi_assert_internal(mi_page_heap(page) != NULL);
mi_heap_t* pheap = mi_page_heap(page);
#ifdef Py_GIL_DISABLED
if (page->qsbr_node.next != NULL) {
// remove from QSBR queue, but keep the goal
llist_remove(&page->qsbr_node);
}
#endif
// remove from our page list
mi_segments_tld_t* segments_tld = &pheap->tld->segments;
mi_page_queue_remove(pq, page);
// page is no longer associated with our heap
mi_assert_internal(mi_page_thread_free_flag(page)==MI_NEVER_DELAYED_FREE);
mi_page_set_heap(page, NULL);
#if (MI_DEBUG>1) && !MI_TRACK_ENABLED
// check there are no references left..
for (mi_block_t* block = (mi_block_t*)pheap->thread_delayed_free; block != NULL; block = mi_block_nextx(pheap, block, pheap->keys)) {
mi_assert_internal(_mi_ptr_page(block) != page);
}
#endif
// and abandon it
mi_assert_internal(mi_page_heap(page) == NULL);
_mi_segment_page_abandon(page,segments_tld);
}
// Free a page with no more free blocks
void _mi_page_free(mi_page_t* page, mi_page_queue_t* pq, bool force) {
mi_assert_internal(page != NULL);
mi_assert_expensive(_mi_page_is_valid(page));
mi_assert_internal(pq == mi_page_queue_of(page));
mi_assert_internal(mi_page_all_free(page));
mi_assert_internal(mi_page_thread_free_flag(page)!=MI_DELAYED_FREEING);
// no more aligned blocks in here
mi_page_set_has_aligned(page, false);
mi_heap_t* heap = mi_page_heap(page);
#ifdef Py_GIL_DISABLED
mi_assert_internal(page->qsbr_goal == 0);
mi_assert_internal(page->qsbr_node.next == NULL);
#endif
// remove from the page list
// (no need to do _mi_heap_delayed_free first as all blocks are already free)
mi_segments_tld_t* segments_tld = &heap->tld->segments;
mi_page_queue_remove(pq, page);
// and free it
mi_page_set_heap(page,NULL);
_mi_segment_page_free(page, force, segments_tld);
}
// Retire parameters
#define MI_MAX_RETIRE_SIZE (MI_MEDIUM_OBJ_SIZE_MAX)
#define MI_RETIRE_CYCLES (16)
// Retire a page with no more used blocks
// Important to not retire too quickly though as new
// allocations might coming.
// Note: called from `mi_free` and benchmarks often
// trigger this due to freeing everything and then
// allocating again so careful when changing this.
void _mi_page_retire(mi_page_t* page) mi_attr_noexcept {
mi_assert_internal(page != NULL);
mi_assert_expensive(_mi_page_is_valid(page));
mi_assert_internal(mi_page_all_free(page));
mi_page_set_has_aligned(page, false);
// any previous QSBR goals are no longer valid because we reused the page
_PyMem_mi_page_clear_qsbr(page);
// don't retire too often..
// (or we end up retiring and re-allocating most of the time)
// NOTE: refine this more: we should not retire if this
// is the only page left with free blocks. It is not clear
// how to check this efficiently though...
// for now, we don't retire if it is the only page left of this size class.
mi_page_queue_t* pq = mi_page_queue_of(page);
if mi_likely(page->xblock_size <= MI_MAX_RETIRE_SIZE && !mi_page_queue_is_special(pq)) { // not too large && not full or huge queue?
if (pq->last==page && pq->first==page) { // the only page in the queue?
mi_stat_counter_increase(_mi_stats_main.page_no_retire,1);
page->retire_expire = 1 + (page->xblock_size <= MI_SMALL_OBJ_SIZE_MAX ? MI_RETIRE_CYCLES : MI_RETIRE_CYCLES/4);
mi_heap_t* heap = mi_page_heap(page);
mi_assert_internal(pq >= heap->pages);
const size_t index = pq - heap->pages;
mi_assert_internal(index < MI_BIN_FULL && index < MI_BIN_HUGE);
if (index < heap->page_retired_min) heap->page_retired_min = index;
if (index > heap->page_retired_max) heap->page_retired_max = index;
mi_assert_internal(mi_page_all_free(page));
return; // don't free after all
}
}
_PyMem_mi_page_maybe_free(page, pq, false);
}
// free retired pages: we don't need to look at the entire queues
// since we only retire pages that are at the head position in a queue.
void _mi_heap_collect_retired(mi_heap_t* heap, bool force) {
size_t min = MI_BIN_FULL;
size_t max = 0;
for(size_t bin = heap->page_retired_min; bin <= heap->page_retired_max; bin++) {
mi_page_queue_t* pq = &heap->pages[bin];
mi_page_t* page = pq->first;
if (page != NULL && page->retire_expire != 0) {
if (mi_page_all_free(page)) {
page->retire_expire--;
if (force || page->retire_expire == 0) {
#ifdef Py_GIL_DISABLED
mi_assert_internal(page->qsbr_goal == 0);
#endif
_PyMem_mi_page_maybe_free(page, pq, force);
}
else {
// keep retired, update min/max
if (bin < min) min = bin;
if (bin > max) max = bin;
}
}
else {
page->retire_expire = 0;
}
}
}
heap->page_retired_min = min;
heap->page_retired_max = max;
}
/* -----------------------------------------------------------
Initialize the initial free list in a page.
In secure mode we initialize a randomized list by
alternating between slices.
----------------------------------------------------------- */
#define MI_MAX_SLICE_SHIFT (6) // at most 64 slices
#define MI_MAX_SLICES (1UL << MI_MAX_SLICE_SHIFT)
#define MI_MIN_SLICES (2)
static void mi_page_free_list_extend_secure(mi_heap_t* const heap, mi_page_t* const page, const size_t bsize, const size_t extend, mi_stats_t* const stats) {
MI_UNUSED(stats);
#if (MI_SECURE<=2)
mi_assert_internal(page->free == NULL);
mi_assert_internal(page->local_free == NULL);
#endif
mi_assert_internal(page->capacity + extend <= page->reserved);
mi_assert_internal(bsize == mi_page_block_size(page));
void* const page_area = _mi_page_start(_mi_page_segment(page), page, NULL);
// initialize a randomized free list
// set up `slice_count` slices to alternate between
size_t shift = MI_MAX_SLICE_SHIFT;
while ((extend >> shift) == 0) {
shift--;
}
const size_t slice_count = (size_t)1U << shift;
const size_t slice_extend = extend / slice_count;
mi_assert_internal(slice_extend >= 1);
mi_block_t* blocks[MI_MAX_SLICES]; // current start of the slice
size_t counts[MI_MAX_SLICES]; // available objects in the slice
for (size_t i = 0; i < slice_count; i++) {
blocks[i] = mi_page_block_at(page, page_area, bsize, page->capacity + i*slice_extend);
counts[i] = slice_extend;
}
counts[slice_count-1] += (extend % slice_count); // final slice holds the modulus too (todo: distribute evenly?)
// and initialize the free list by randomly threading through them
// set up first element
const uintptr_t r = _mi_heap_random_next(heap);
size_t current = r % slice_count;
counts[current]--;
mi_block_t* const free_start = blocks[current];
// and iterate through the rest; use `random_shuffle` for performance
uintptr_t rnd = _mi_random_shuffle(r|1); // ensure not 0
for (size_t i = 1; i < extend; i++) {
// call random_shuffle only every INTPTR_SIZE rounds
const size_t round = i%MI_INTPTR_SIZE;
if (round == 0) rnd = _mi_random_shuffle(rnd);
// select a random next slice index
size_t next = ((rnd >> 8*round) & (slice_count-1));
while (counts[next]==0) { // ensure it still has space
next++;
if (next==slice_count) next = 0;
}
// and link the current block to it
counts[next]--;
mi_block_t* const block = blocks[current];
blocks[current] = (mi_block_t*)((uint8_t*)block + bsize); // bump to the following block
mi_block_set_next(page, block, blocks[next]); // and set next; note: we may have `current == next`
current = next;
}
// prepend to the free list (usually NULL)
mi_block_set_next(page, blocks[current], page->free); // end of the list
page->free = free_start;
}
static mi_decl_noinline void mi_page_free_list_extend( mi_page_t* const page, const size_t bsize, const size_t extend, mi_stats_t* const stats)
{
MI_UNUSED(stats);
#if (MI_SECURE <= 2)
mi_assert_internal(page->free == NULL);
mi_assert_internal(page->local_free == NULL);
#endif
mi_assert_internal(page->capacity + extend <= page->reserved);
mi_assert_internal(bsize == mi_page_block_size(page));
void* const page_area = _mi_page_start(_mi_page_segment(page), page, NULL );
mi_block_t* const start = mi_page_block_at(page, page_area, bsize, page->capacity);
// initialize a sequential free list
mi_block_t* const last = mi_page_block_at(page, page_area, bsize, page->capacity + extend - 1);
mi_block_t* block = start;
while(block <= last) {
mi_block_t* next = (mi_block_t*)((uint8_t*)block + bsize);
mi_block_set_next(page,block,next);
block = next;
}
// prepend to free list (usually `NULL`)
mi_block_set_next(page, last, page->free);
page->free = start;
}
/* -----------------------------------------------------------
Page initialize and extend the capacity
----------------------------------------------------------- */
#define MI_MAX_EXTEND_SIZE (4*1024) // heuristic, one OS page seems to work well.
#if (MI_SECURE>0)
#define MI_MIN_EXTEND (8*MI_SECURE) // extend at least by this many
#else
#define MI_MIN_EXTEND (4)
#endif
// Extend the capacity (up to reserved) by initializing a free list
// We do at most `MI_MAX_EXTEND` to avoid touching too much memory
// Note: we also experimented with "bump" allocation on the first
// allocations but this did not speed up any benchmark (due to an
// extra test in malloc? or cache effects?)
static void mi_page_extend_free(mi_heap_t* heap, mi_page_t* page, mi_tld_t* tld) {
MI_UNUSED(tld);
mi_assert_expensive(mi_page_is_valid_init(page));
#if (MI_SECURE<=2)
mi_assert(page->free == NULL);
mi_assert(page->local_free == NULL);
if (page->free != NULL) return;
#endif
if (page->capacity >= page->reserved) return;
size_t page_size;
_mi_page_start(_mi_page_segment(page), page, &page_size);
mi_stat_counter_increase(tld->stats.pages_extended, 1);
// calculate the extend count
const size_t bsize = (page->xblock_size < MI_HUGE_BLOCK_SIZE ? page->xblock_size : page_size);
size_t extend = page->reserved - page->capacity;
mi_assert_internal(extend > 0);
size_t max_extend = (bsize >= MI_MAX_EXTEND_SIZE ? MI_MIN_EXTEND : MI_MAX_EXTEND_SIZE/(uint32_t)bsize);
if (max_extend < MI_MIN_EXTEND) { max_extend = MI_MIN_EXTEND; }
mi_assert_internal(max_extend > 0);
if (extend > max_extend) {
// ensure we don't touch memory beyond the page to reduce page commit.
// the `lean` benchmark tests this. Going from 1 to 8 increases rss by 50%.
extend = max_extend;
}
mi_assert_internal(extend > 0 && extend + page->capacity <= page->reserved);
mi_assert_internal(extend < (1UL<<16));
// and append the extend the free list
if (extend < MI_MIN_SLICES || MI_SECURE==0) { //!mi_option_is_enabled(mi_option_secure)) {
mi_page_free_list_extend(page, bsize, extend, &tld->stats );
}
else {
mi_page_free_list_extend_secure(heap, page, bsize, extend, &tld->stats);
}
// enable the new free list
page->capacity += (uint16_t)extend;
mi_stat_increase(tld->stats.page_committed, extend * bsize);
mi_assert_expensive(mi_page_is_valid_init(page));
}
// Initialize a fresh page
static void mi_page_init(mi_heap_t* heap, mi_page_t* page, size_t block_size, mi_tld_t* tld) {
mi_assert(page != NULL);
mi_segment_t* segment = _mi_page_segment(page);
mi_assert(segment != NULL);
mi_assert_internal(block_size > 0);
// set fields
mi_page_set_heap(page, heap);
page->tag = heap->tag;
page->use_qsbr = heap->page_use_qsbr;
page->debug_offset = heap->debug_offset;
page->xblock_size = (block_size < MI_HUGE_BLOCK_SIZE ? (uint32_t)block_size : MI_HUGE_BLOCK_SIZE); // initialize before _mi_segment_page_start
size_t page_size;
const void* page_start = _mi_segment_page_start(segment, page, &page_size);
MI_UNUSED(page_start);
mi_track_mem_noaccess(page_start,page_size);
mi_assert_internal(mi_page_block_size(page) <= page_size);
mi_assert_internal(page_size <= page->slice_count*MI_SEGMENT_SLICE_SIZE);
mi_assert_internal(page_size / block_size < (1L<<16));
page->reserved = (uint16_t)(page_size / block_size);
mi_assert_internal(page->reserved > 0);
#if (MI_PADDING || MI_ENCODE_FREELIST)
page->keys[0] = _mi_heap_random_next(heap);
page->keys[1] = _mi_heap_random_next(heap);
#endif
page->free_is_zero = page->is_zero_init;
#if MI_DEBUG>2
if (page->is_zero_init) {
mi_track_mem_defined(page_start, page_size);
mi_assert_expensive(mi_mem_is_zero(page_start, page_size));
}
#endif
mi_assert_internal(page->is_committed);
mi_assert_internal(page->capacity == 0);
mi_assert_internal(page->free == NULL);
mi_assert_internal(page->used == 0);
mi_assert_internal(page->xthread_free == 0);
mi_assert_internal(page->next == NULL);
mi_assert_internal(page->prev == NULL);
#ifdef Py_GIL_DISABLED
mi_assert_internal(page->qsbr_goal == 0);
mi_assert_internal(page->qsbr_node.next == NULL);
#endif
mi_assert_internal(page->retire_expire == 0);
mi_assert_internal(!mi_page_has_aligned(page));
#if (MI_PADDING || MI_ENCODE_FREELIST)
mi_assert_internal(page->keys[0] != 0);
mi_assert_internal(page->keys[1] != 0);
#endif
mi_assert_expensive(mi_page_is_valid_init(page));
// initialize an initial free list
mi_page_extend_free(heap,page,tld);
mi_assert(mi_page_immediate_available(page));
}
/* -----------------------------------------------------------
Find pages with free blocks
-------------------------------------------------------------*/
// Find a page with free blocks of `page->block_size`.
static mi_page_t* mi_page_queue_find_free_ex(mi_heap_t* heap, mi_page_queue_t* pq, bool first_try)
{
// search through the pages in "next fit" order
#if MI_STAT
size_t count = 0;
#endif
mi_page_t* page = pq->first;
while (page != NULL)
{
mi_page_t* next = page->next; // remember next
#if MI_STAT
count++;
#endif
// 0. collect freed blocks by us and other threads
_mi_page_free_collect(page, false);
// 1. if the page contains free blocks, we are done
if (mi_page_immediate_available(page)) {
break; // pick this one
}
// 2. Try to extend
if (page->capacity < page->reserved) {
mi_page_extend_free(heap, page, heap->tld);
mi_assert_internal(mi_page_immediate_available(page));
break;
}
// 3. If the page is completely full, move it to the `mi_pages_full`
// queue so we don't visit long-lived pages too often.
mi_assert_internal(!mi_page_is_in_full(page) && !mi_page_immediate_available(page));
mi_page_to_full(page, pq);
page = next;
} // for each page
mi_heap_stat_counter_increase(heap, searches, count);
if (page == NULL) {
_PyMem_mi_heap_collect_qsbr(heap); // some pages might be safe to free now
_mi_heap_collect_retired(heap, false); // perhaps make a page available?
page = mi_page_fresh(heap, pq);
if (page == NULL && first_try) {
// out-of-memory _or_ an abandoned page with free blocks was reclaimed, try once again
page = mi_page_queue_find_free_ex(heap, pq, false);
}
}
else {
mi_assert(pq->first == page);
page->retire_expire = 0;
_PyMem_mi_page_clear_qsbr(page);
}
mi_assert_internal(page == NULL || mi_page_immediate_available(page));
return page;
}
// Find a page with free blocks of `size`.
static inline mi_page_t* mi_find_free_page(mi_heap_t* heap, size_t size) {
mi_page_queue_t* pq = mi_page_queue(heap,size);
mi_page_t* page = pq->first;
if (page != NULL) {
#if (MI_SECURE>=3) // in secure mode, we extend half the time to increase randomness
if (page->capacity < page->reserved && ((_mi_heap_random_next(heap) & 1) == 1)) {
mi_page_extend_free(heap, page, heap->tld);
mi_assert_internal(mi_page_immediate_available(page));
}
else
#endif
{
_mi_page_free_collect(page,false);
}
if (mi_page_immediate_available(page)) {
page->retire_expire = 0;
_PyMem_mi_page_clear_qsbr(page);
return page; // fast path
}
}
return mi_page_queue_find_free_ex(heap, pq, true);
}
/* -----------------------------------------------------------
Users can register a deferred free function called
when the `free` list is empty. Since the `local_free`
is separate this is deterministically called after
a certain number of allocations.
----------------------------------------------------------- */
static mi_deferred_free_fun* volatile deferred_free = NULL;
static _Atomic(void*) deferred_arg; // = NULL
void _mi_deferred_free(mi_heap_t* heap, bool force) {
heap->tld->heartbeat++;
if (deferred_free != NULL && !heap->tld->recurse) {
heap->tld->recurse = true;
deferred_free(force, heap->tld->heartbeat, mi_atomic_load_ptr_relaxed(void,&deferred_arg));
heap->tld->recurse = false;
}
}
void mi_register_deferred_free(mi_deferred_free_fun* fn, void* arg) mi_attr_noexcept {
deferred_free = fn;
mi_atomic_store_ptr_release(void,&deferred_arg, arg);
}
/* -----------------------------------------------------------
General allocation
----------------------------------------------------------- */
// Large and huge page allocation.
// Huge pages are allocated directly without being in a queue.
// Because huge pages contain just one block, and the segment contains
// just that page, we always treat them as abandoned and any thread
// that frees the block can free the whole page and segment directly.
// Huge pages are also use if the requested alignment is very large (> MI_ALIGNMENT_MAX).
static mi_page_t* mi_large_huge_page_alloc(mi_heap_t* heap, size_t size, size_t page_alignment) {
size_t block_size = _mi_os_good_alloc_size(size);
mi_assert_internal(mi_bin(block_size) == MI_BIN_HUGE || page_alignment > 0);
bool is_huge = (block_size > MI_LARGE_OBJ_SIZE_MAX || page_alignment > 0);
#if MI_HUGE_PAGE_ABANDON
mi_page_queue_t* pq = (is_huge ? NULL : mi_page_queue(heap, block_size));
#else
mi_page_queue_t* pq = mi_page_queue(heap, is_huge ? MI_HUGE_BLOCK_SIZE : block_size); // not block_size as that can be low if the page_alignment > 0
mi_assert_internal(!is_huge || mi_page_queue_is_huge(pq));
#endif
mi_page_t* page = mi_page_fresh_alloc(heap, pq, block_size, page_alignment);
if (page != NULL) {
mi_assert_internal(mi_page_immediate_available(page));
if (is_huge) {
mi_assert_internal(_mi_page_segment(page)->kind == MI_SEGMENT_HUGE);
mi_assert_internal(_mi_page_segment(page)->used==1);
#if MI_HUGE_PAGE_ABANDON
mi_assert_internal(_mi_page_segment(page)->thread_id==0); // abandoned, not in the huge queue
mi_page_set_heap(page, NULL);
#endif
}
else {
mi_assert_internal(_mi_page_segment(page)->kind != MI_SEGMENT_HUGE);
}
const size_t bsize = mi_page_usable_block_size(page); // note: not `mi_page_block_size` to account for padding
if (bsize <= MI_LARGE_OBJ_SIZE_MAX) {
mi_heap_stat_increase(heap, large, bsize);
mi_heap_stat_counter_increase(heap, large_count, 1);
}
else {
mi_heap_stat_increase(heap, huge, bsize);
mi_heap_stat_counter_increase(heap, huge_count, 1);
}
}
return page;
}
// Allocate a page
// Note: in debug mode the size includes MI_PADDING_SIZE and might have overflowed.
static mi_page_t* mi_find_page(mi_heap_t* heap, size_t size, size_t huge_alignment) mi_attr_noexcept {
// huge allocation?
const size_t req_size = size - MI_PADDING_SIZE; // correct for padding_size in case of an overflow on `size`
if mi_unlikely(req_size > (MI_MEDIUM_OBJ_SIZE_MAX - MI_PADDING_SIZE) || huge_alignment > 0) {
if mi_unlikely(req_size > PTRDIFF_MAX) { // we don't allocate more than PTRDIFF_MAX (see <https://sourceware.org/ml/libc-announce/2019/msg00001.html>)
_mi_error_message(EOVERFLOW, "allocation request is too large (%zu bytes)\n", req_size);
return NULL;
}
else {
_PyMem_mi_heap_collect_qsbr(heap);
return mi_large_huge_page_alloc(heap,size,huge_alignment);
}
}
else {
// otherwise find a page with free blocks in our size segregated queues
#if MI_PADDING
mi_assert_internal(size >= MI_PADDING_SIZE);
#endif
return mi_find_free_page(heap, size);
}
}
// Generic allocation routine if the fast path (`alloc.c:mi_page_malloc`) does not succeed.
// Note: in debug mode the size includes MI_PADDING_SIZE and might have overflowed.
// The `huge_alignment` is normally 0 but is set to a multiple of MI_SEGMENT_SIZE for
// very large requested alignments in which case we use a huge segment.
void* _mi_malloc_generic(mi_heap_t* heap, size_t size, bool zero, size_t huge_alignment) mi_attr_noexcept
{
mi_assert_internal(heap != NULL);
// initialize if necessary
if mi_unlikely(!mi_heap_is_initialized(heap)) {
heap = mi_heap_get_default(); // calls mi_thread_init
if mi_unlikely(!mi_heap_is_initialized(heap)) { return NULL; }
}
mi_assert_internal(mi_heap_is_initialized(heap));
// call potential deferred free routines
_mi_deferred_free(heap, false);
// free delayed frees from other threads (but skip contended ones)
_mi_heap_delayed_free_partial(heap);
// find (or allocate) a page of the right size
mi_page_t* page = mi_find_page(heap, size, huge_alignment);
if mi_unlikely(page == NULL) { // first time out of memory, try to collect and retry the allocation once more
mi_heap_collect(heap, true /* force */);
page = mi_find_page(heap, size, huge_alignment);
}
if mi_unlikely(page == NULL) { // out of memory
const size_t req_size = size - MI_PADDING_SIZE; // correct for padding_size in case of an overflow on `size`
_mi_error_message(ENOMEM, "unable to allocate memory (%zu bytes)\n", req_size);
return NULL;
}
mi_assert_internal(mi_page_immediate_available(page));
mi_assert_internal(mi_page_block_size(page) >= size);
// and try again, this time succeeding! (i.e. this should never recurse through _mi_page_malloc)
if mi_unlikely(zero && page->xblock_size == 0) {
// note: we cannot call _mi_page_malloc with zeroing for huge blocks; we zero it afterwards in that case.
void* p = _mi_page_malloc(heap, page, size, false);
mi_assert_internal(p != NULL);
_mi_memzero_aligned(p, mi_page_usable_block_size(page));
return p;
}
else {
return _mi_page_malloc(heap, page, size, zero);
}
}