546 lines
14 KiB
C
546 lines
14 KiB
C
/*
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* Copyright (c) 2019 Intel Corporation
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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#include <zephyr/sys/sys_heap.h>
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#include <zephyr/sys/util.h>
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#include <zephyr/sys/heap_listener.h>
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#include <zephyr/kernel.h>
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#include <string.h>
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#include "heap.h"
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#ifdef CONFIG_MSAN
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#include <sanitizer/msan_interface.h>
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#endif
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#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
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static inline void increase_allocated_bytes(struct z_heap *h, size_t num_bytes)
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{
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h->allocated_bytes += num_bytes;
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h->max_allocated_bytes = MAX(h->max_allocated_bytes, h->allocated_bytes);
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}
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#endif
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static void *chunk_mem(struct z_heap *h, chunkid_t c)
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{
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chunk_unit_t *buf = chunk_buf(h);
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uint8_t *ret = ((uint8_t *)&buf[c]) + chunk_header_bytes(h);
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CHECK(!(((uintptr_t)ret) & (big_heap(h) ? 7 : 3)));
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return ret;
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}
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static void free_list_remove_bidx(struct z_heap *h, chunkid_t c, int bidx)
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{
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struct z_heap_bucket *b = &h->buckets[bidx];
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CHECK(!chunk_used(h, c));
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CHECK(b->next != 0);
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CHECK(h->avail_buckets & BIT(bidx));
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if (next_free_chunk(h, c) == c) {
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/* this is the last chunk */
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h->avail_buckets &= ~BIT(bidx);
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b->next = 0;
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} else {
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chunkid_t first = prev_free_chunk(h, c),
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second = next_free_chunk(h, c);
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b->next = second;
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set_next_free_chunk(h, first, second);
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set_prev_free_chunk(h, second, first);
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}
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#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
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h->free_bytes -= chunksz_to_bytes(h, chunk_size(h, c));
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#endif
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}
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static void free_list_remove(struct z_heap *h, chunkid_t c)
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{
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if (!solo_free_header(h, c)) {
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int bidx = bucket_idx(h, chunk_size(h, c));
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free_list_remove_bidx(h, c, bidx);
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}
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}
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static void free_list_add_bidx(struct z_heap *h, chunkid_t c, int bidx)
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{
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struct z_heap_bucket *b = &h->buckets[bidx];
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if (b->next == 0U) {
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CHECK((h->avail_buckets & BIT(bidx)) == 0);
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/* Empty list, first item */
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h->avail_buckets |= BIT(bidx);
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b->next = c;
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set_prev_free_chunk(h, c, c);
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set_next_free_chunk(h, c, c);
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} else {
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CHECK(h->avail_buckets & BIT(bidx));
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/* Insert before (!) the "next" pointer */
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chunkid_t second = b->next;
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chunkid_t first = prev_free_chunk(h, second);
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set_prev_free_chunk(h, c, first);
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set_next_free_chunk(h, c, second);
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set_next_free_chunk(h, first, c);
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set_prev_free_chunk(h, second, c);
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}
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#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
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h->free_bytes += chunksz_to_bytes(h, chunk_size(h, c));
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#endif
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}
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static void free_list_add(struct z_heap *h, chunkid_t c)
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{
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if (!solo_free_header(h, c)) {
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int bidx = bucket_idx(h, chunk_size(h, c));
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free_list_add_bidx(h, c, bidx);
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}
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}
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/* Splits a chunk "lc" into a left chunk and a right chunk at "rc".
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* Leaves both chunks marked "free"
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*/
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static void split_chunks(struct z_heap *h, chunkid_t lc, chunkid_t rc)
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{
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CHECK(rc > lc);
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CHECK(rc - lc < chunk_size(h, lc));
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chunksz_t sz0 = chunk_size(h, lc);
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chunksz_t lsz = rc - lc;
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chunksz_t rsz = sz0 - lsz;
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set_chunk_size(h, lc, lsz);
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set_chunk_size(h, rc, rsz);
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set_left_chunk_size(h, rc, lsz);
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set_left_chunk_size(h, right_chunk(h, rc), rsz);
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}
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/* Does not modify free list */
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static void merge_chunks(struct z_heap *h, chunkid_t lc, chunkid_t rc)
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{
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chunksz_t newsz = chunk_size(h, lc) + chunk_size(h, rc);
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set_chunk_size(h, lc, newsz);
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set_left_chunk_size(h, right_chunk(h, rc), newsz);
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}
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static void free_chunk(struct z_heap *h, chunkid_t c)
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{
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/* Merge with free right chunk? */
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if (!chunk_used(h, right_chunk(h, c))) {
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free_list_remove(h, right_chunk(h, c));
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merge_chunks(h, c, right_chunk(h, c));
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}
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/* Merge with free left chunk? */
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if (!chunk_used(h, left_chunk(h, c))) {
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free_list_remove(h, left_chunk(h, c));
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merge_chunks(h, left_chunk(h, c), c);
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c = left_chunk(h, c);
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}
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free_list_add(h, c);
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}
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/*
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* Return the closest chunk ID corresponding to given memory pointer.
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* Here "closest" is only meaningful in the context of sys_heap_aligned_alloc()
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* where wanted alignment might not always correspond to a chunk header
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* boundary.
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*/
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static chunkid_t mem_to_chunkid(struct z_heap *h, void *p)
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{
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uint8_t *mem = p, *base = (uint8_t *)chunk_buf(h);
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return (mem - chunk_header_bytes(h) - base) / CHUNK_UNIT;
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}
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void sys_heap_free(struct sys_heap *heap, void *mem)
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{
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if (mem == NULL) {
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return; /* ISO C free() semantics */
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}
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struct z_heap *h = heap->heap;
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chunkid_t c = mem_to_chunkid(h, mem);
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/*
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* This should catch many double-free cases.
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* This is cheap enough so let's do it all the time.
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*/
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__ASSERT(chunk_used(h, c),
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"unexpected heap state (double-free?) for memory at %p", mem);
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/*
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* It is easy to catch many common memory overflow cases with
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* a quick check on this and next chunk header fields that are
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* immediately before and after the freed memory.
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*/
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__ASSERT(left_chunk(h, right_chunk(h, c)) == c,
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"corrupted heap bounds (buffer overflow?) for memory at %p",
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mem);
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set_chunk_used(h, c, false);
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#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
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h->allocated_bytes -= chunksz_to_bytes(h, chunk_size(h, c));
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#endif
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#ifdef CONFIG_SYS_HEAP_LISTENER
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heap_listener_notify_free(HEAP_ID_FROM_POINTER(heap), mem,
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chunksz_to_bytes(h, chunk_size(h, c)));
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#endif
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free_chunk(h, c);
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}
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size_t sys_heap_usable_size(struct sys_heap *heap, void *mem)
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{
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struct z_heap *h = heap->heap;
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chunkid_t c = mem_to_chunkid(h, mem);
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size_t addr = (size_t)mem;
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size_t chunk_base = (size_t)&chunk_buf(h)[c];
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size_t chunk_sz = chunk_size(h, c) * CHUNK_UNIT;
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return chunk_sz - (addr - chunk_base);
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}
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static chunkid_t alloc_chunk(struct z_heap *h, chunksz_t sz)
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{
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int bi = bucket_idx(h, sz);
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struct z_heap_bucket *b = &h->buckets[bi];
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CHECK(bi <= bucket_idx(h, h->end_chunk));
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/* First try a bounded count of items from the minimal bucket
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* size. These may not fit, trying (e.g.) three means that
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* (assuming that chunk sizes are evenly distributed[1]) we
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* have a 7/8 chance of finding a match, thus keeping the
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* number of such blocks consumed by allocation higher than
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* the number of smaller blocks created by fragmenting larger
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* ones.
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*
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* [1] In practice, they are never evenly distributed, of
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* course. But even in pathological situations we still
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* maintain our constant time performance and at worst see
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* fragmentation waste of the order of the block allocated
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* only.
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*/
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if (b->next != 0U) {
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chunkid_t first = b->next;
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int i = CONFIG_SYS_HEAP_ALLOC_LOOPS;
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do {
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chunkid_t c = b->next;
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if (chunk_size(h, c) >= sz) {
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free_list_remove_bidx(h, c, bi);
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return c;
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}
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b->next = next_free_chunk(h, c);
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CHECK(b->next != 0);
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} while (--i && b->next != first);
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}
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/* Otherwise pick the smallest non-empty bucket guaranteed to
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* fit and use that unconditionally.
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*/
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uint32_t bmask = h->avail_buckets & ~BIT_MASK(bi + 1);
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if (bmask != 0U) {
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int minbucket = __builtin_ctz(bmask);
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chunkid_t c = h->buckets[minbucket].next;
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free_list_remove_bidx(h, c, minbucket);
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CHECK(chunk_size(h, c) >= sz);
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return c;
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}
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return 0;
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}
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void *sys_heap_alloc(struct sys_heap *heap, size_t bytes)
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{
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struct z_heap *h = heap->heap;
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void *mem;
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if ((bytes == 0U) || size_too_big(h, bytes)) {
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return NULL;
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}
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chunksz_t chunk_sz = bytes_to_chunksz(h, bytes);
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chunkid_t c = alloc_chunk(h, chunk_sz);
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if (c == 0U) {
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return NULL;
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}
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/* Split off remainder if any */
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if (chunk_size(h, c) > chunk_sz) {
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split_chunks(h, c, c + chunk_sz);
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free_list_add(h, c + chunk_sz);
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}
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set_chunk_used(h, c, true);
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mem = chunk_mem(h, c);
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#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
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increase_allocated_bytes(h, chunksz_to_bytes(h, chunk_size(h, c)));
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#endif
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#ifdef CONFIG_SYS_HEAP_LISTENER
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heap_listener_notify_alloc(HEAP_ID_FROM_POINTER(heap), mem,
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chunksz_to_bytes(h, chunk_size(h, c)));
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#endif
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IF_ENABLED(CONFIG_MSAN, (__msan_allocated_memory(mem, bytes)));
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return mem;
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}
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void *sys_heap_aligned_alloc(struct sys_heap *heap, size_t align, size_t bytes)
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{
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struct z_heap *h = heap->heap;
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size_t gap, rew;
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/*
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* Split align and rewind values (if any).
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* We allow for one bit of rewind in addition to the alignment
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* value to efficiently accommodate z_heap_aligned_alloc().
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* So if e.g. align = 0x28 (32 | 8) this means we align to a 32-byte
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* boundary and then rewind 8 bytes.
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*/
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rew = align & -align;
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if (align != rew) {
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align -= rew;
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gap = MIN(rew, chunk_header_bytes(h));
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} else {
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if (align <= chunk_header_bytes(h)) {
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return sys_heap_alloc(heap, bytes);
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}
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rew = 0;
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gap = chunk_header_bytes(h);
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}
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__ASSERT((align & (align - 1)) == 0, "align must be a power of 2");
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if ((bytes == 0) || size_too_big(h, bytes)) {
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return NULL;
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}
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/*
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* Find a free block that is guaranteed to fit.
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* We over-allocate to account for alignment and then free
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* the extra allocations afterwards.
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*/
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chunksz_t padded_sz = bytes_to_chunksz(h, bytes + align - gap);
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chunkid_t c0 = alloc_chunk(h, padded_sz);
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if (c0 == 0) {
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return NULL;
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}
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uint8_t *mem = chunk_mem(h, c0);
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/* Align allocated memory */
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mem = (uint8_t *) ROUND_UP(mem + rew, align) - rew;
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chunk_unit_t *end = (chunk_unit_t *) ROUND_UP(mem + bytes, CHUNK_UNIT);
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/* Get corresponding chunks */
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chunkid_t c = mem_to_chunkid(h, mem);
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chunkid_t c_end = end - chunk_buf(h);
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CHECK(c >= c0 && c < c_end && c_end <= c0 + padded_sz);
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/* Split and free unused prefix */
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if (c > c0) {
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split_chunks(h, c0, c);
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free_list_add(h, c0);
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}
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/* Split and free unused suffix */
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if (right_chunk(h, c) > c_end) {
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split_chunks(h, c, c_end);
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free_list_add(h, c_end);
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}
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set_chunk_used(h, c, true);
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#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
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increase_allocated_bytes(h, chunksz_to_bytes(h, chunk_size(h, c)));
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#endif
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#ifdef CONFIG_SYS_HEAP_LISTENER
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heap_listener_notify_alloc(HEAP_ID_FROM_POINTER(heap), mem,
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chunksz_to_bytes(h, chunk_size(h, c)));
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#endif
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IF_ENABLED(CONFIG_MSAN, (__msan_allocated_memory(mem, bytes)));
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return mem;
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}
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void *sys_heap_aligned_realloc(struct sys_heap *heap, void *ptr,
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size_t align, size_t bytes)
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{
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struct z_heap *h = heap->heap;
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/* special realloc semantics */
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if (ptr == NULL) {
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return sys_heap_aligned_alloc(heap, align, bytes);
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}
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if (bytes == 0) {
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sys_heap_free(heap, ptr);
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return NULL;
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}
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__ASSERT((align & (align - 1)) == 0, "align must be a power of 2");
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if (size_too_big(h, bytes)) {
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return NULL;
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}
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chunkid_t c = mem_to_chunkid(h, ptr);
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chunkid_t rc = right_chunk(h, c);
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size_t align_gap = (uint8_t *)ptr - (uint8_t *)chunk_mem(h, c);
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chunksz_t chunks_need = bytes_to_chunksz(h, bytes + align_gap);
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if (align && ((uintptr_t)ptr & (align - 1))) {
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/* ptr is not sufficiently aligned */
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} else if (chunk_size(h, c) == chunks_need) {
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/* We're good already */
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return ptr;
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} else if (chunk_size(h, c) > chunks_need) {
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/* Shrink in place, split off and free unused suffix */
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#ifdef CONFIG_SYS_HEAP_LISTENER
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size_t bytes_freed = chunksz_to_bytes(h, chunk_size(h, c));
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#endif
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#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
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h->allocated_bytes -=
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(chunk_size(h, c) - chunks_need) * CHUNK_UNIT;
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#endif
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split_chunks(h, c, c + chunks_need);
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set_chunk_used(h, c, true);
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free_chunk(h, c + chunks_need);
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#ifdef CONFIG_SYS_HEAP_LISTENER
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heap_listener_notify_alloc(HEAP_ID_FROM_POINTER(heap), ptr,
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chunksz_to_bytes(h, chunk_size(h, c)));
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heap_listener_notify_free(HEAP_ID_FROM_POINTER(heap), ptr,
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bytes_freed);
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#endif
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return ptr;
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} else if (!chunk_used(h, rc) &&
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(chunk_size(h, c) + chunk_size(h, rc) >= chunks_need)) {
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/* Expand: split the right chunk and append */
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chunksz_t split_size = chunks_need - chunk_size(h, c);
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#ifdef CONFIG_SYS_HEAP_LISTENER
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size_t bytes_freed = chunksz_to_bytes(h, chunk_size(h, c));
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#endif
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#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
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increase_allocated_bytes(h, split_size * CHUNK_UNIT);
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#endif
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free_list_remove(h, rc);
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if (split_size < chunk_size(h, rc)) {
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split_chunks(h, rc, rc + split_size);
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free_list_add(h, rc + split_size);
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}
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merge_chunks(h, c, rc);
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set_chunk_used(h, c, true);
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#ifdef CONFIG_SYS_HEAP_LISTENER
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heap_listener_notify_alloc(HEAP_ID_FROM_POINTER(heap), ptr,
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chunksz_to_bytes(h, chunk_size(h, c)));
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heap_listener_notify_free(HEAP_ID_FROM_POINTER(heap), ptr,
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bytes_freed);
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#endif
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return ptr;
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} else {
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;
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}
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/*
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* Fallback: allocate and copy
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*
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* Note for heap listener notification:
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* The calls to allocation and free functions generate
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* notification already, so there is no need to those here.
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*/
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void *ptr2 = sys_heap_aligned_alloc(heap, align, bytes);
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if (ptr2 != NULL) {
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size_t prev_size = chunksz_to_bytes(h, chunk_size(h, c)) - align_gap;
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memcpy(ptr2, ptr, MIN(prev_size, bytes));
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sys_heap_free(heap, ptr);
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}
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return ptr2;
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}
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void sys_heap_init(struct sys_heap *heap, void *mem, size_t bytes)
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{
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IF_ENABLED(CONFIG_MSAN, (__sanitizer_dtor_callback(mem, bytes)));
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if (IS_ENABLED(CONFIG_SYS_HEAP_SMALL_ONLY)) {
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/* Must fit in a 15 bit count of HUNK_UNIT */
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__ASSERT(bytes / CHUNK_UNIT <= 0x7fffU, "heap size is too big");
|
|
} else {
|
|
/* Must fit in a 31 bit count of HUNK_UNIT */
|
|
__ASSERT(bytes / CHUNK_UNIT <= 0x7fffffffU, "heap size is too big");
|
|
}
|
|
|
|
/* Reserve the end marker chunk's header */
|
|
__ASSERT(bytes > heap_footer_bytes(bytes), "heap size is too small");
|
|
bytes -= heap_footer_bytes(bytes);
|
|
|
|
/* Round the start up, the end down */
|
|
uintptr_t addr = ROUND_UP(mem, CHUNK_UNIT);
|
|
uintptr_t end = ROUND_DOWN((uint8_t *)mem + bytes, CHUNK_UNIT);
|
|
chunksz_t heap_sz = (end - addr) / CHUNK_UNIT;
|
|
|
|
CHECK(end > addr);
|
|
__ASSERT(heap_sz > chunksz(sizeof(struct z_heap)), "heap size is too small");
|
|
|
|
struct z_heap *h = (struct z_heap *)addr;
|
|
heap->heap = h;
|
|
h->end_chunk = heap_sz;
|
|
h->avail_buckets = 0;
|
|
|
|
#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
|
|
h->free_bytes = 0;
|
|
h->allocated_bytes = 0;
|
|
h->max_allocated_bytes = 0;
|
|
#endif
|
|
|
|
int nb_buckets = bucket_idx(h, heap_sz) + 1;
|
|
chunksz_t chunk0_size = chunksz(sizeof(struct z_heap) +
|
|
nb_buckets * sizeof(struct z_heap_bucket));
|
|
|
|
__ASSERT(chunk0_size + min_chunk_size(h) <= heap_sz, "heap size is too small");
|
|
|
|
for (int i = 0; i < nb_buckets; i++) {
|
|
h->buckets[i].next = 0;
|
|
}
|
|
|
|
/* chunk containing our struct z_heap */
|
|
set_chunk_size(h, 0, chunk0_size);
|
|
set_left_chunk_size(h, 0, 0);
|
|
set_chunk_used(h, 0, true);
|
|
|
|
/* chunk containing the free heap */
|
|
set_chunk_size(h, chunk0_size, heap_sz - chunk0_size);
|
|
set_left_chunk_size(h, chunk0_size, chunk0_size);
|
|
|
|
/* the end marker chunk */
|
|
set_chunk_size(h, heap_sz, 0);
|
|
set_left_chunk_size(h, heap_sz, heap_sz - chunk0_size);
|
|
set_chunk_used(h, heap_sz, true);
|
|
|
|
free_list_add(h, chunk0_size);
|
|
}
|