mirror of
https://github.com/espressif/esp-idf.git
synced 2024-10-05 20:47:46 -04:00
42447ccf12
This commit fixes the missing tracing on all heap_caps_xx_prefer and heap_caps_xx_aligned functions.
458 lines
13 KiB
C
458 lines
13 KiB
C
/*
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* SPDX-FileCopyrightText: 2015-2024 Espressif Systems (Shanghai) CO LTD
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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#include <stdbool.h>
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#include <string.h>
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#include <assert.h>
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#include <stdio.h>
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#include <sys/param.h>
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#include "esp_attr.h"
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#include "esp_heap_caps.h"
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#include "multi_heap.h"
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#include "esp_log.h"
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#include "heap_private.h"
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#include "esp_system.h"
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/*
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This file, combined with a region allocator that supports multiple heaps, solves the problem that the ESP32 has RAM
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that's slightly heterogeneous. Some RAM can be byte-accessed, some allows only 32-bit accesses, some can execute memory,
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some can be remapped by the MMU to only be accessed by a certain PID etc. In order to allow the most flexible memory
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allocation possible, this code makes it possible to request memory that has certain capabilities. The code will then use
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its knowledge of how the memory is configured along with a priority scheme to allocate that memory in the most sane way
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possible. This should optimize the amount of RAM accessible to the code without hardwiring addresses.
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*/
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static esp_alloc_failed_hook_t alloc_failed_callback;
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#ifdef CONFIG_HEAP_ABORT_WHEN_ALLOCATION_FAILS
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HEAP_IRAM_ATTR static void hex_to_str(char buf[8], uint32_t n)
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{
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for (int i = 0; i < 8; i++) {
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uint8_t b4 = (n >> (28 - i * 4)) & 0b1111;
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buf[i] = b4 <= 9 ? '0' + b4 : 'a' + b4 - 10;
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}
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}
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HEAP_IRAM_ATTR static void fmt_abort_str(char dest[48], size_t size, uint32_t caps)
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{
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char sSize[8];
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char sCaps[8];
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hex_to_str(sSize, size);
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hex_to_str(sCaps, caps);
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memcpy(dest, "Mem alloc fail. size 0x00000000 caps 0x00000000", 48);
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memcpy(dest + 23, sSize, 8);
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memcpy(dest + 39, sCaps, 8);
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}
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#endif
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HEAP_IRAM_ATTR NOINLINE_ATTR static void heap_caps_alloc_failed(size_t requested_size, uint32_t caps, const char *function_name)
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{
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if (alloc_failed_callback) {
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alloc_failed_callback(requested_size, caps, function_name);
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}
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#ifdef CONFIG_HEAP_ABORT_WHEN_ALLOCATION_FAILS
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char buf[48];
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fmt_abort_str(buf, requested_size, caps);
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esp_system_abort(buf);
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#endif
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}
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esp_err_t heap_caps_register_failed_alloc_callback(esp_alloc_failed_hook_t callback)
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{
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if (callback == NULL) {
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return ESP_ERR_INVALID_ARG;
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}
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alloc_failed_callback = callback;
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return ESP_OK;
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}
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bool heap_caps_match(const heap_t *heap, uint32_t caps)
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{
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return heap->heap != NULL && ((get_all_caps(heap) & caps) == caps);
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}
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/*
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Routine to allocate a bit of memory with certain capabilities. caps is a bitfield of MALLOC_CAP_* bits.
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*/
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HEAP_IRAM_ATTR void *heap_caps_malloc( size_t size, uint32_t caps)
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{
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void* ptr = heap_caps_malloc_base(size, caps);
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if (!ptr && size > 0){
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heap_caps_alloc_failed(size, caps, __func__);
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}
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return ptr;
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}
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#define MALLOC_DISABLE_EXTERNAL_ALLOCS -1
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//Dual-use: -1 (=MALLOC_DISABLE_EXTERNAL_ALLOCS) disables allocations in external memory, >=0 sets the limit for allocations preferring internal memory.
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static int malloc_alwaysinternal_limit=MALLOC_DISABLE_EXTERNAL_ALLOCS;
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void heap_caps_malloc_extmem_enable(size_t limit)
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{
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malloc_alwaysinternal_limit=limit;
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}
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/*
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Default memory allocation implementation. Should return standard 8-bit memory. malloc() essentially resolves to this function.
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*/
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HEAP_IRAM_ATTR void *heap_caps_malloc_default( size_t size )
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{
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if (malloc_alwaysinternal_limit==MALLOC_DISABLE_EXTERNAL_ALLOCS) {
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return heap_caps_malloc( size, MALLOC_CAP_DEFAULT | MALLOC_CAP_INTERNAL);
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} else {
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// use heap_caps_malloc_base() since we'll
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// check for allocation failure ourselves
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void *r;
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if (size <= (size_t)malloc_alwaysinternal_limit) {
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r=heap_caps_malloc_base( size, MALLOC_CAP_DEFAULT | MALLOC_CAP_INTERNAL );
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} else {
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r=heap_caps_malloc_base( size, MALLOC_CAP_DEFAULT | MALLOC_CAP_SPIRAM );
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}
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if (r==NULL && size > 0) {
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//try again while being less picky
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r=heap_caps_malloc_base( size, MALLOC_CAP_DEFAULT );
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}
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// allocation failure?
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if (r==NULL && size > 0){
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heap_caps_alloc_failed(size, MALLOC_CAP_DEFAULT, __func__);
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}
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return r;
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}
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}
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/*
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Same for realloc()
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Note: keep the logic in here the same as in heap_caps_malloc_default (or merge the two as soon as this gets more complex...)
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*/
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HEAP_IRAM_ATTR void *heap_caps_realloc_default( void *ptr, size_t size )
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{
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if (malloc_alwaysinternal_limit==MALLOC_DISABLE_EXTERNAL_ALLOCS) {
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return heap_caps_realloc( ptr, size, MALLOC_CAP_DEFAULT | MALLOC_CAP_INTERNAL );
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} else {
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// We use heap_caps_realloc_base() since we'll
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// handle allocation failure ourselves
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void *r;
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if (size <= (size_t)malloc_alwaysinternal_limit) {
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r=heap_caps_realloc_base( ptr, size, MALLOC_CAP_DEFAULT | MALLOC_CAP_INTERNAL);
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} else {
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r=heap_caps_realloc_base( ptr, size, MALLOC_CAP_DEFAULT | MALLOC_CAP_SPIRAM);
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}
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if (r==NULL && size>0) {
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//We needed to allocate memory, but we didn't. Try again while being less picky.
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r=heap_caps_realloc_base( ptr, size, MALLOC_CAP_DEFAULT);
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}
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// allocation failure?
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if (r==NULL && size>0){
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heap_caps_alloc_failed(size, MALLOC_CAP_DEFAULT, __func__);
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}
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return r;
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}
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}
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/*
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Memory allocation as preference in decreasing order.
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*/
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HEAP_IRAM_ATTR void *heap_caps_malloc_prefer( size_t size, size_t num, ... )
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{
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va_list argp;
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va_start( argp, num );
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void *r = NULL;
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uint32_t caps = MALLOC_CAP_DEFAULT;
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while (num--) {
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caps = va_arg( argp, uint32_t );
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r = heap_caps_malloc_base( size, caps );
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if (r != NULL || size == 0) {
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break;
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}
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}
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if (r == NULL && size > 0){
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heap_caps_alloc_failed(size, caps, __func__);
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}
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va_end( argp );
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return r;
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}
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/*
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Memory reallocation as preference in decreasing order.
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*/
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HEAP_IRAM_ATTR void *heap_caps_realloc_prefer( void *ptr, size_t size, size_t num, ... )
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{
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va_list argp;
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va_start( argp, num );
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void *r = NULL;
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uint32_t caps = MALLOC_CAP_DEFAULT;
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while (num--) {
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caps = va_arg( argp, uint32_t );
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r = heap_caps_realloc_base( ptr, size, caps );
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if (r != NULL || size == 0) {
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break;
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}
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}
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if (r == NULL && size > 0){
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heap_caps_alloc_failed(size, caps, __func__);
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}
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va_end( argp );
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return r;
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}
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/*
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Memory callocation as preference in decreasing order.
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*/
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HEAP_IRAM_ATTR void *heap_caps_calloc_prefer( size_t n, size_t size, size_t num, ... )
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{
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va_list argp;
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va_start( argp, num );
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void *r = NULL;
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uint32_t caps = MALLOC_CAP_DEFAULT;
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while (num--) {
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caps = va_arg( argp, uint32_t );
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r = heap_caps_calloc_base( n, size, caps );
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if (r != NULL || size == 0){
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break;
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}
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}
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if (r == NULL && size > 0){
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heap_caps_alloc_failed(size, caps, __func__);
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}
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va_end( argp );
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return r;
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}
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HEAP_IRAM_ATTR void *heap_caps_realloc( void *ptr, size_t size, uint32_t caps)
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{
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ptr = heap_caps_realloc_base(ptr, size, caps);
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if (ptr == NULL && size > 0){
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heap_caps_alloc_failed(size, caps, __func__);
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}
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return ptr;
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}
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HEAP_IRAM_ATTR void *heap_caps_calloc( size_t n, size_t size, uint32_t caps)
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{
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void* ptr = heap_caps_calloc_base(n, size, caps);
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if (!ptr && size > 0){
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heap_caps_alloc_failed(n * size, caps, __func__);
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}
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return ptr;
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}
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size_t heap_caps_get_total_size(uint32_t caps)
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{
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size_t total_size = 0;
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heap_t *heap;
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SLIST_FOREACH(heap, ®istered_heaps, next) {
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if (heap_caps_match(heap, caps)) {
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total_size += (heap->end - heap->start);
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}
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}
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return total_size;
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}
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size_t heap_caps_get_free_size( uint32_t caps )
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{
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size_t ret = 0;
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heap_t *heap;
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SLIST_FOREACH(heap, ®istered_heaps, next) {
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if (heap_caps_match(heap, caps)) {
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ret += multi_heap_free_size(heap->heap);
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}
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}
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return ret;
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}
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size_t heap_caps_get_minimum_free_size( uint32_t caps )
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{
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size_t ret = 0;
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heap_t *heap;
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SLIST_FOREACH(heap, ®istered_heaps, next) {
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if (heap_caps_match(heap, caps)) {
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ret += multi_heap_minimum_free_size(heap->heap);
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}
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}
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return ret;
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}
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size_t heap_caps_get_largest_free_block( uint32_t caps )
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{
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multi_heap_info_t info;
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heap_caps_get_info(&info, caps);
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return info.largest_free_block;
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}
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void heap_caps_get_info( multi_heap_info_t *info, uint32_t caps )
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{
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memset(info, 0, sizeof(multi_heap_info_t));
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heap_t *heap;
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SLIST_FOREACH(heap, ®istered_heaps, next) {
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if (heap_caps_match(heap, caps)) {
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multi_heap_info_t hinfo;
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multi_heap_get_info(heap->heap, &hinfo);
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info->total_free_bytes += hinfo.total_free_bytes;
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info->total_allocated_bytes += hinfo.total_allocated_bytes;
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info->largest_free_block = MAX(info->largest_free_block,
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hinfo.largest_free_block);
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info->minimum_free_bytes += hinfo.minimum_free_bytes;
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info->allocated_blocks += hinfo.allocated_blocks;
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info->free_blocks += hinfo.free_blocks;
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info->total_blocks += hinfo.total_blocks;
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}
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}
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}
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void heap_caps_print_heap_info( uint32_t caps )
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{
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multi_heap_info_t info;
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printf("Heap summary for capabilities 0x%08"PRIX32":\n", caps);
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heap_t *heap;
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SLIST_FOREACH(heap, ®istered_heaps, next) {
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if (heap_caps_match(heap, caps)) {
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multi_heap_get_info(heap->heap, &info);
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printf(" At 0x%08x len %d free %d allocated %d min_free %d\n",
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heap->start, heap->end - heap->start, info.total_free_bytes, info.total_allocated_bytes, info.minimum_free_bytes);
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printf(" largest_free_block %d alloc_blocks %d free_blocks %d total_blocks %d\n",
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info.largest_free_block, info.allocated_blocks,
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info.free_blocks, info.total_blocks);
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}
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}
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printf(" Totals:\n");
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heap_caps_get_info(&info, caps);
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printf(" free %d allocated %d min_free %d largest_free_block %d\n", info.total_free_bytes, info.total_allocated_bytes, info.minimum_free_bytes, info.largest_free_block);
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}
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bool heap_caps_check_integrity(uint32_t caps, bool print_errors)
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{
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bool all_heaps = caps & MALLOC_CAP_INVALID;
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bool valid = true;
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heap_t *heap;
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SLIST_FOREACH(heap, ®istered_heaps, next) {
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if (heap->heap != NULL
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&& (all_heaps || (get_all_caps(heap) & caps) == caps)) {
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valid = multi_heap_check(heap->heap, print_errors) && valid;
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}
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}
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return valid;
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}
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bool heap_caps_check_integrity_all(bool print_errors)
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{
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return heap_caps_check_integrity(MALLOC_CAP_INVALID, print_errors);
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}
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bool heap_caps_check_integrity_addr(intptr_t addr, bool print_errors)
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{
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heap_t *heap = find_containing_heap((void *)addr);
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if (heap == NULL) {
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return false;
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}
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return multi_heap_check(heap->heap, print_errors);
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}
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void heap_caps_dump(uint32_t caps)
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{
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bool all_heaps = caps & MALLOC_CAP_INVALID;
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heap_t *heap;
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SLIST_FOREACH(heap, ®istered_heaps, next) {
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if (heap->heap != NULL
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&& (all_heaps || (get_all_caps(heap) & caps) == caps)) {
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multi_heap_dump(heap->heap);
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}
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}
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}
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void heap_caps_dump_all(void)
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{
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heap_caps_dump(MALLOC_CAP_INVALID);
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}
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size_t heap_caps_get_allocated_size( void *ptr )
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{
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heap_t *heap = find_containing_heap(ptr);
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assert(heap);
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size_t size = multi_heap_get_allocated_size(heap->heap, ptr);
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return size;
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}
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HEAP_IRAM_ATTR void *heap_caps_aligned_alloc(size_t alignment, size_t size, uint32_t caps)
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{
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if(!alignment) {
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return NULL;
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}
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//Alignment must be a power of two:
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if((alignment & (alignment - 1)) != 0) {
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return NULL;
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}
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if (size == 0) {
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return NULL;
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}
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if (size > HEAP_SIZE_MAX) {
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// Avoids int overflow when adding small numbers to size, or
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// calculating 'end' from start+size, by limiting 'size' to the possible range
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heap_caps_alloc_failed(size, caps, __func__);
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return NULL;
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}
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void *ret = heap_caps_aligned_alloc_base(alignment, size, caps);
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if (ret == NULL) {
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heap_caps_alloc_failed(size, caps, __func__);
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}
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return ret;
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}
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HEAP_IRAM_ATTR void heap_caps_aligned_free(void *ptr)
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{
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heap_caps_free(ptr);
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}
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void *heap_caps_aligned_calloc(size_t alignment, size_t n, size_t size, uint32_t caps)
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{
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size_t size_bytes;
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if (__builtin_mul_overflow(n, size, &size_bytes)) {
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return NULL;
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}
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void *ptr = heap_caps_aligned_alloc(alignment,size_bytes, caps);
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if(ptr != NULL) {
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memset(ptr, 0, size_bytes);
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}
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return ptr;
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}
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