/*
ChibiOS/RT - Copyright (C) 2006,2007,2008,2009,2010,
2011,2012 Giovanni Di Sirio.
This file is part of ChibiOS/RT.
ChibiOS/RT is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
ChibiOS/RT is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see .
---
A special exception to the GPL can be applied should you wish to distribute
a combined work that includes ChibiOS/RT, without being obliged to provide
the source code for any proprietary components. See the file exception.txt
for full details of how and when the exception can be applied.
*/
/**
* @file chheap.c
* @brief Heaps code.
*
* @addtogroup heaps
* @details Heap Allocator related APIs.
*
Operation mode
* The heap allocator implements a first-fit strategy and its APIs
* are functionally equivalent to the usual @p malloc() and @p free()
* library functions. The main difference is that the OS heap APIs
* are guaranteed to be thread safe.
* By enabling the @p CH_USE_MALLOC_HEAP option the heap manager
* will use the runtime-provided @p malloc() and @p free() as
* back end for the heap APIs instead of the system provided
* allocator.
* @pre In order to use the heap APIs the @p CH_USE_HEAP option must
* be enabled in @p chconf.h.
* @{
*/
#include "ch.h"
#if CH_USE_HEAP || defined(__DOXYGEN__)
#if !CH_USE_MALLOC_HEAP || defined(__DOXYGEN__)
/*
* Defaults on the best synchronization mechanism available.
*/
#if CH_USE_MUTEXES || defined(__DOXYGEN__)
#define H_LOCK(h) chMtxLock(&(h)->h_mtx)
#define H_UNLOCK(h) chMtxUnlock()
#else
#define H_LOCK(h) chSemWait(&(h)->h_sem)
#define H_UNLOCK(h) chSemSignal(&(h)->h_sem)
#endif
/**
* @brief Default heap descriptor.
*/
static MemoryHeap default_heap;
/**
* @brief Initializes the default heap.
*
* @notapi
*/
void _heap_init(void) {
default_heap.h_provider = chCoreAlloc;
default_heap.h_free.h.u.next = (union heap_header *)NULL;
default_heap.h_free.h.size = 0;
#if CH_USE_MUTEXES || defined(__DOXYGEN__)
chMtxInit(&default_heap.h_mtx);
#else
chSemInit(&default_heap.h_sem, 1);
#endif
}
/**
* @brief Initializes a memory heap from a static memory area.
* @pre Both the heap buffer base and the heap size must be aligned to
* the @p stkalign_t type size.
* @pre In order to use this function the option @p CH_USE_MALLOC_HEAP
* must be disabled.
*
* @param[out] heapp pointer to the memory heap descriptor to be initialized
* @param[in] buf heap buffer base
* @param[in] size heap size
*
* @init
*/
void chHeapInit(MemoryHeap *heapp, void *buf, size_t size) {
union heap_header *hp;
chDbgCheck(MEM_IS_ALIGNED(buf) && MEM_IS_ALIGNED(size), "chHeapInit");
heapp->h_provider = (memgetfunc_t)NULL;
heapp->h_free.h.u.next = hp = buf;
heapp->h_free.h.size = 0;
hp->h.u.next = NULL;
hp->h.size = size - sizeof(union heap_header);
#if CH_USE_MUTEXES || defined(__DOXYGEN__)
chMtxInit(&heapp->h_mtx);
#else
chSemInit(&heapp->h_sem, 1);
#endif
}
/**
* @brief Allocates a block of memory from the heap by using the first-fit
* algorithm.
* @details The allocated block is guaranteed to be properly aligned for a
* pointer data type (@p stkalign_t).
*
* @param[in] heapp pointer to a heap descriptor or @p NULL in order to
* access the default heap.
* @param[in] size the size of the block to be allocated. Note that the
* allocated block may be a bit bigger than the requested
* size for alignment and fragmentation reasons.
* @return A pointer to the allocated block.
* @retval NULL if the block cannot be allocated.
*
* @api
*/
void *chHeapAlloc(MemoryHeap *heapp, size_t size) {
union heap_header *qp, *hp, *fp;
if (heapp == NULL)
heapp = &default_heap;
size = MEM_ALIGN_NEXT(size);
qp = &heapp->h_free;
H_LOCK(heapp);
while (qp->h.u.next != NULL) {
hp = qp->h.u.next;
if (hp->h.size >= size) {
if (hp->h.size < size + sizeof(union heap_header)) {
/* Gets the whole block even if it is slightly bigger than the
requested size because the fragment would be too small to be
useful.*/
qp->h.u.next = hp->h.u.next;
}
else {
/* Block bigger enough, must split it.*/
fp = (void *)((uint8_t *)(hp) + sizeof(union heap_header) + size);
fp->h.u.next = hp->h.u.next;
fp->h.size = hp->h.size - sizeof(union heap_header) - size;
qp->h.u.next = fp;
hp->h.size = size;
}
hp->h.u.heap = heapp;
H_UNLOCK(heapp);
return (void *)(hp + 1);
}
qp = hp;
}
H_UNLOCK(heapp);
/* More memory is required, tries to get it from the associated provider
else fails.*/
if (heapp->h_provider) {
hp = heapp->h_provider(size + sizeof(union heap_header));
if (hp != NULL) {
hp->h.u.heap = heapp;
hp->h.size = size;
hp++;
return (void *)hp;
}
}
return NULL;
}
#define LIMIT(p) (union heap_header *)((uint8_t *)(p) + \
sizeof(union heap_header) + \
(p)->h.size)
/**
* @brief Frees a previously allocated memory block.
*
* @param[in] p pointer to the memory block to be freed
*
* @api
*/
void chHeapFree(void *p) {
union heap_header *qp, *hp;
MemoryHeap *heapp;
chDbgCheck(p != NULL, "chHeapFree");
hp = (union heap_header *)p - 1;
heapp = hp->h.u.heap;
qp = &heapp->h_free;
H_LOCK(heapp);
while (TRUE) {
chDbgAssert((hp < qp) || (hp >= LIMIT(qp)),
"chHeapFree(), #1",
"within free block");
if (((qp == &heapp->h_free) || (hp > qp)) &&
((qp->h.u.next == NULL) || (hp < qp->h.u.next))) {
/* Insertion after qp.*/
hp->h.u.next = qp->h.u.next;
qp->h.u.next = hp;
/* Verifies if the newly inserted block should be merged.*/
if (LIMIT(hp) == hp->h.u.next) {
/* Merge with the next block.*/
hp->h.size += hp->h.u.next->h.size + sizeof(union heap_header);
hp->h.u.next = hp->h.u.next->h.u.next;
}
if ((LIMIT(qp) == hp)) {
/* Merge with the previous block.*/
qp->h.size += hp->h.size + sizeof(union heap_header);
qp->h.u.next = hp->h.u.next;
}
break;
}
qp = qp->h.u.next;
}
H_UNLOCK(heapp);
return;
}
/**
* @brief Reports the heap status.
* @note This function is meant to be used in the test suite, it should
* not be really useful for the application code.
* @note This function is not implemented when the @p CH_USE_MALLOC_HEAP
* configuration option is used (it always returns zero).
*
* @param[in] heapp pointer to a heap descriptor or @p NULL in order to
* access the default heap.
* @param[in] sizep pointer to a variable that will receive the total
* fragmented free space
* @return The number of fragments in the heap.
*
* @api
*/
size_t chHeapStatus(MemoryHeap *heapp, size_t *sizep) {
union heap_header *qp;
size_t n, sz;
if (heapp == NULL)
heapp = &default_heap;
H_LOCK(heapp);
sz = 0;
for (n = 0, qp = &heapp->h_free; qp->h.u.next; n++, qp = qp->h.u.next)
sz += qp->h.u.next->h.size;
if (sizep)
*sizep = sz;
H_UNLOCK(heapp);
return n;
}
/**
* @brief Reports the min/max size of fragments on heap.
* @note This function is not implemented when the @p CH_USE_MALLOC_HEAP
* configuration option is used (it always returns zero).
*
* @param[in] heapp pointer to a heap descriptor or @p NULL in order to
* access the default heap.
* @param[in] min pointer to a variable that will receive the min free fragmented size
* @param[in] max pointer to a variable that will receive the max free fragmented size
* @return The number of fragments in the heap.
*
* @api
*/
void chHeapMaxMinFraq(MemoryHeap *heapp, size_t *min, size_t *max) {
union heap_header *qp;
size_t n, sz;
*min = 0;
*max = 0;
if (heapp == NULL)
heapp = &default_heap;
H_LOCK(heapp);
for (n = 0, qp = &heapp->h_free; qp->h.u.next; n++, qp = qp->h.u.next){
sz = qp->h.u.next->h.size;
if(*min>sz)
*min = sz;
if(*max
#if CH_USE_MUTEXES
#define H_LOCK() chMtxLock(&hmtx)
#define H_UNLOCK() chMtxUnlock()
static Mutex hmtx;
#elif CH_USE_SEMAPHORES
#define H_LOCK() chSemWait(&hsem)
#define H_UNLOCK() chSemSignal(&hsem)
static Semaphore hsem;
#endif
void _heap_init(void) {
#if CH_USE_MUTEXES
chMtxInit(&hmtx);
#else
chSemInit(&hsem, 1);
#endif
}
void *chHeapAlloc(MemoryHeap *heapp, size_t size) {
void *p;
chDbgCheck(heapp == NULL, "chHeapAlloc");
H_LOCK();
p = malloc(size);
H_UNLOCK();
return p;
}
void chHeapFree(void *p) {
chDbgCheck(p != NULL, "chHeapFree");
H_LOCK();
free(p);
H_UNLOCK();
}
size_t chHeapStatus(MemoryHeap *heapp, size_t *sizep) {
chDbgCheck(heapp == NULL, "chHeapStatus");
if (sizep)
*sizep = 0;
return 0;
}
#endif /* CH_USE_MALLOC_HEAP */
#endif /* CH_USE_HEAP */
/** @} */