nuttx/mm/tlsf/mm_tlsf.c

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/****************************************************************************
* mm/tlsf/mm_tlsf.c
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership. The
* ASF licenses this file to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance with the
* License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
* License for the specific language governing permissions and limitations
* under the License.
*
****************************************************************************/
/****************************************************************************
* Included Files
****************************************************************************/
#include <nuttx/config.h>
#include <unistd.h>
#include <errno.h>
#include <assert.h>
#include <debug.h>
#include <execinfo.h>
#include <sched.h>
#include <stdio.h>
#include <string.h>
#include <sys/param.h>
#include <nuttx/arch.h>
#include <nuttx/fs/procfs.h>
#include <nuttx/mutex.h>
#include <nuttx/mm/mm.h>
#include <nuttx/mm/kasan.h>
#include <nuttx/mm/mempool.h>
#include <nuttx/sched_note.h>
#include "tlsf/tlsf.h"
/****************************************************************************
* Pre-processor Definitions
****************************************************************************/
#if CONFIG_MM_HEAP_MEMPOOL_THRESHOLD > 0
# define MEMPOOL_NPOOLS (CONFIG_MM_HEAP_MEMPOOL_THRESHOLD / tlsf_align_size())
#endif
/****************************************************************************
* Private Types
****************************************************************************/
struct mm_delaynode_s
{
FAR struct mm_delaynode_s *flink;
};
struct mm_heap_s
{
/* Mutually exclusive access to this data set is enforced with
* the following un-named mutex.
*/
mutex_t mm_lock;
/* This is the size of the heap provided to mm */
size_t mm_heapsize;
/* This is the heap maximum used memory size */
size_t mm_maxused;
/* This is the current used size of the heap */
size_t mm_curused;
/* This is the first and last of the heap */
FAR void *mm_heapstart[CONFIG_MM_REGIONS];
FAR void *mm_heapend[CONFIG_MM_REGIONS];
#if CONFIG_MM_REGIONS > 1
int mm_nregions;
#endif
tlsf_t mm_tlsf; /* The tlfs context */
/* The is a multiple mempool of the heap */
#ifdef CONFIG_MM_HEAP_MEMPOOL
size_t mm_threshold;
FAR struct mempool_multiple_s *mm_mpool;
#endif
/* Free delay list, for some situation can't do free immediately */
struct mm_delaynode_s *mm_delaylist[CONFIG_SMP_NCPUS];
#if CONFIG_MM_FREE_DELAYCOUNT_MAX > 0
size_t mm_delaycount[CONFIG_SMP_NCPUS];
#endif
#if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_MEMINFO)
struct procfs_meminfo_entry_s mm_procfs;
#endif
};
#if CONFIG_MM_BACKTRACE >= 0
struct memdump_backtrace_s
{
pid_t pid; /* The pid for caller */
unsigned long seqno; /* The sequence of memory malloc */
#if CONFIG_MM_BACKTRACE > 0
FAR void *backtrace[CONFIG_MM_BACKTRACE]; /* The backtrace buffer for caller */
#endif
};
#endif
struct mm_mallinfo_handler_s
{
FAR const struct malltask *task;
FAR struct mallinfo_task *info;
};
/****************************************************************************
* Private Function Prototypes
****************************************************************************/
static void mm_delayfree(struct mm_heap_s *heap, void *mem, bool delay);
/****************************************************************************
* Private Functions
****************************************************************************/
#if CONFIG_MM_BACKTRACE >= 0
/****************************************************************************
* Name: memdump_backtrace
****************************************************************************/
static void memdump_backtrace(FAR struct mm_heap_s *heap,
FAR struct memdump_backtrace_s *buf)
{
# if CONFIG_MM_BACKTRACE > 0
FAR struct tcb_s *tcb;
# endif
buf->pid = _SCHED_GETTID();
buf->seqno = g_mm_seqno++;
# if CONFIG_MM_BACKTRACE > 0
tcb = nxsched_get_tcb(buf->pid);
if (heap->mm_procfs.backtrace ||
(tcb && tcb->flags & TCB_FLAG_HEAP_DUMP))
{
int ret = sched_backtrace(buf->pid, buf->backtrace,
CONFIG_MM_BACKTRACE,
CONFIG_MM_BACKTRACE_SKIP);
if (ret < CONFIG_MM_BACKTRACE)
{
buf->backtrace[ret] = NULL;
}
}
# endif
}
#endif
/****************************************************************************
* Name: add_delaylist
****************************************************************************/
static void add_delaylist(FAR struct mm_heap_s *heap, FAR void *mem)
{
#if defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__)
FAR struct mm_delaynode_s *tmp = mem;
irqstate_t flags;
/* Delay the deallocation until a more appropriate time. */
flags = up_irq_save();
tmp->flink = heap->mm_delaylist[this_cpu()];
heap->mm_delaylist[this_cpu()] = tmp;
#if CONFIG_MM_FREE_DELAYCOUNT_MAX > 0
heap->mm_delaycount[this_cpu()]++;
#endif
up_irq_restore(flags);
#endif
}
/****************************************************************************
* Name: free_delaylist
****************************************************************************/
static bool free_delaylist(FAR struct mm_heap_s *heap, bool force)
{
bool ret = false;
#if defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__)
FAR struct mm_delaynode_s *tmp;
irqstate_t flags;
/* Move the delay list to local */
flags = up_irq_save();
tmp = heap->mm_delaylist[this_cpu()];
#if CONFIG_MM_FREE_DELAYCOUNT_MAX > 0
if (tmp == NULL ||
(!force &&
heap->mm_delaycount[this_cpu()] < CONFIG_MM_FREE_DELAYCOUNT_MAX))
{
up_irq_restore(flags);
return false;
}
heap->mm_delaycount[this_cpu()] = 0;
#endif
heap->mm_delaylist[this_cpu()] = NULL;
up_irq_restore(flags);
/* Test if the delayed is empty */
ret = tmp != NULL;
while (tmp)
{
FAR void *address;
/* Get the first delayed deallocation */
address = tmp;
tmp = tmp->flink;
/* The address should always be non-NULL since that was checked in the
* 'while' condition above.
*/
mm_delayfree(heap, address, false);
}
#endif
return ret;
}
#if defined(CONFIG_MM_HEAP_MEMPOOL) && CONFIG_MM_BACKTRACE >= 0
/****************************************************************************
* Name: mempool_memalign
*
* Description:
* This function call mm_memalign and set mm_backtrace pid to free pid
* avoid repeated calculation.
****************************************************************************/
static FAR void *mempool_memalign(FAR void *arg, size_t alignment,
size_t size)
{
FAR struct memdump_backtrace_s *buf;
FAR void *ret;
ret = mm_memalign(arg, alignment, size);
if (ret)
{
buf = ret + mm_malloc_size(arg, ret);
buf->pid = PID_MM_MEMPOOL;
}
return ret;
}
#else
# define mempool_memalign mm_memalign
#endif
/****************************************************************************
* Name: mallinfo_handler
****************************************************************************/
static void mallinfo_handler(FAR void *ptr, size_t size, int used,
FAR void *user)
{
FAR struct mallinfo *info = user;
if (!used)
{
info->ordblks++;
info->fordblks += size;
if (size > info->mxordblk)
{
info->mxordblk = size;
}
}
else
{
info->aordblks++;
}
}
/****************************************************************************
* Name: mallinfo_task_handler
****************************************************************************/
static void mallinfo_task_handler(FAR void *ptr, size_t size, int used,
FAR void *user)
{
FAR struct mm_mallinfo_handler_s *handler = user;
FAR const struct malltask *task = handler->task;
FAR struct mallinfo_task *info = handler->info;
if (used)
{
#if CONFIG_MM_BACKTRACE < 0
if (task->pid == PID_MM_ALLOC)
{
info->aordblks++;
info->uordblks += size;
}
#else
FAR struct memdump_backtrace_s *buf =
ptr + size - sizeof(struct memdump_backtrace_s);
if ((MM_DUMP_ASSIGN(task->pid, buf->pid) ||
MM_DUMP_ALLOC(task->pid, buf->pid) ||
MM_DUMP_LEAK(task->pid, buf->pid)) &&
buf->seqno >= task->seqmin && buf->seqno <= task->seqmax)
{
info->aordblks++;
info->uordblks += size;
}
#endif
}
else if (task->pid == PID_MM_FREE)
{
info->aordblks++;
info->uordblks += size;
}
}
/****************************************************************************
* Name: mm_lock
*
* Description:
* Take the MM mutex. This may be called from the OS in certain conditions
* when it is impossible to wait on a mutex:
* 1.The idle process performs the memory corruption check.
* 2.The task/thread free the memory in the exiting process.
*
* Input Parameters:
* heap - heap instance want to take mutex
*
* Returned Value:
* 0 if the lock can be taken, otherwise negative errno.
*
****************************************************************************/
static int mm_lock(FAR struct mm_heap_s *heap)
{
#if defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__)
/* Check current environment */
if (up_interrupt_context())
{
#if !defined(CONFIG_SMP)
/* Check the mutex value, if held by someone, then return false.
* Or, touch the heap internal data directly.
*/
return nxmutex_is_locked(&heap->mm_lock) ? -EAGAIN : 0;
#else
/* Can't take mutex in SMP interrupt handler */
return -EAGAIN;
#endif
}
else
#endif
/* _SCHED_GETTID() returns the task ID of the task at the head of the
* ready-to-run task list. mm_lock() may be called during context
* switches. There are certain situations during context switching when
* the OS data structures are in flux and then can't be freed immediately
* (e.g. the running thread stack).
*
* This is handled by _SCHED_GETTID() to return the special value
* -ESRCH to indicate this special situation.
*/
if (_SCHED_GETTID() < 0)
{
return -ESRCH;
}
else
{
return nxmutex_lock(&heap->mm_lock);
}
}
/****************************************************************************
* Name: mm_unlock
*
* Description:
* Release the MM mutex when it is not longer needed.
*
****************************************************************************/
static void mm_unlock(FAR struct mm_heap_s *heap)
{
#if defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__)
if (up_interrupt_context())
{
return;
}
#endif
DEBUGVERIFY(nxmutex_unlock(&heap->mm_lock));
}
/****************************************************************************
* Name: memdump_handler
****************************************************************************/
static void memdump_handler(FAR void *ptr, size_t size, int used,
FAR void *user)
{
FAR const struct mm_memdump_s *dump = user;
if (used)
{
#if CONFIG_MM_BACKTRACE < 0
if (dump->pid == PID_MM_ALLOC)
{
syslog(LOG_INFO, "%12zu%*p\n", size, BACKTRACE_PTR_FMT_WIDTH, ptr);
}
#elif CONFIG_MM_BACKTRACE == 0
FAR struct memdump_backtrace_s *buf =
ptr + size - sizeof(struct memdump_backtrace_s);
if ((MM_DUMP_ASSIGN(dump->pid, buf->pid) ||
MM_DUMP_ALLOC(dump->pid, buf->pid) ||
MM_DUMP_LEAK(dump->pid, buf->pid)) &&
buf->seqno >= dump->seqmin && buf->seqno <= dump->seqmax)
{
syslog(LOG_INFO, "%6d%12zu%12lu%*p\n",
buf->pid, size, buf->seqno, BACKTRACE_PTR_FMT_WIDTH, ptr);
}
#else
FAR struct memdump_backtrace_s *buf =
ptr + size - sizeof(struct memdump_backtrace_s);
if ((MM_DUMP_ASSIGN(dump->pid, buf->pid) ||
MM_DUMP_ALLOC(dump->pid, buf->pid) ||
MM_DUMP_LEAK(dump->pid, buf->pid)) &&
buf->seqno >= dump->seqmin && buf->seqno <= dump->seqmax)
{
char tmp[BACKTRACE_BUFFER_SIZE(CONFIG_MM_BACKTRACE)];
backtrace_format(tmp, sizeof(tmp), buf->backtrace,
CONFIG_MM_BACKTRACE);
syslog(LOG_INFO, "%6d%12zu%12lu%*p %s\n",
buf->pid, size, buf->seqno, BACKTRACE_PTR_FMT_WIDTH,
ptr, tmp);
}
#endif
}
else if (dump->pid == PID_MM_FREE)
{
syslog(LOG_INFO, "%12zu%*p\n", size, BACKTRACE_PTR_FMT_WIDTH, ptr);
}
}
/****************************************************************************
* Name: mm_delayfree
*
* Description:
* Delay free memory if `delay` is true, otherwise free it immediately.
*
****************************************************************************/
static void mm_delayfree(FAR struct mm_heap_s *heap, FAR void *mem,
bool delay)
{
if (mm_lock(heap) == 0)
{
size_t size = mm_malloc_size(heap, mem);
#ifdef CONFIG_MM_FILL_ALLOCATIONS
memset(mem, MM_FREE_MAGIC, size);
#endif
kasan_poison(mem, size);
/* Pass, return to the tlsf pool */
if (delay)
{
add_delaylist(heap, mem);
}
else
{
/* Update heap statistics */
heap->mm_curused -= size;
sched_note_heap(NOTE_HEAP_FREE, heap, mem, size, heap->mm_curused);
tlsf_free(heap->mm_tlsf, mem);
}
mm_unlock(heap);
}
else
{
/* Add to the delay list(see the comment in mm_lock) */
add_delaylist(heap, mem);
}
}
/****************************************************************************
* Public Functions
****************************************************************************/
/****************************************************************************
* Name: mm_addregion
*
* Description:
* This function adds a region of contiguous memory to the selected heap.
*
* Input Parameters:
* heap - The selected heap
* heapstart - Start of the heap region
* heapsize - Size of the heap region
*
* Returned Value:
* None
*
* Assumptions:
*
****************************************************************************/
void mm_addregion(FAR struct mm_heap_s *heap, FAR void *heapstart,
size_t heapsize)
{
#if CONFIG_MM_REGIONS > 1
int idx;
idx = heap->mm_nregions;
/* Writing past CONFIG_MM_REGIONS would have catastrophic consequences */
DEBUGASSERT(idx < CONFIG_MM_REGIONS);
if (idx >= CONFIG_MM_REGIONS)
{
return;
}
#else
# define idx 0
#endif
#ifdef CONFIG_MM_FILL_ALLOCATIONS
/* Use the fill value to mark uninitialized user memory */
memset(heapstart, 0xcc, heapsize);
#endif
/* Register to KASan for access check */
kasan_register(heapstart, &heapsize);
DEBUGVERIFY(mm_lock(heap));
minfo("Region %d: base=%p size=%zu\n", idx + 1, heapstart, heapsize);
/* Add the size of this region to the total size of the heap */
heap->mm_heapsize += heapsize;
/* Save the start and end of the heap */
heap->mm_heapstart[idx] = heapstart;
heap->mm_heapend[idx] = heapstart + heapsize;
#undef idx
#if CONFIG_MM_REGIONS > 1
heap->mm_nregions++;
#endif
/* Add memory to the tlsf pool */
tlsf_add_pool(heap->mm_tlsf, heapstart, heapsize);
mm_unlock(heap);
sched_note_heap(NOTE_HEAP_ADD, heap, heapstart, heapsize,
heap->mm_curused);
}
/****************************************************************************
* Name: mm_brkaddr
*
* Description:
* Return the break address of a heap region. Zero is returned if the
* memory region is not initialized.
*
****************************************************************************/
FAR void *mm_brkaddr(FAR struct mm_heap_s *heap, int region)
{
#if CONFIG_MM_REGIONS > 1
DEBUGASSERT(region >= 0 && region < heap->mm_nregions);
#else
DEBUGASSERT(region == 0);
#endif
return heap->mm_heapend[region];
}
/****************************************************************************
* Name: mm_calloc
*
* Descriptor:
* mm_calloc() calculates the size of the allocation and calls mm_zalloc()
*
****************************************************************************/
FAR void *mm_calloc(FAR struct mm_heap_s *heap, size_t n, size_t elem_size)
{
mm: memory allocations return valid pointer when request 0 size This change introduce 2 items: 1. If the size of the space requested is 0, the behavior is implementation-defined: either a null pointer shall be returned, or the behavior shall be as if the size were some non-zero value, except that the behavior is undefined if the returned pointer is used to access an object. Change the behavior to be similar to Linux and Android and allocates an object of a minimum size instead of returning null pointer. https://pubs.opengroup.org/onlinepubs/9699919799/functions/malloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/calloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html 2. The description of realloc() has been modified from previous versions of this standard to align with the ISO/IEC 9899:1999 standard. Previous versions explicitly permitted a call to realloc (p, 0) to free the space pointed to by p and return a null pointer. While this behavior could be interpreted as permitted by this version of the standard, the C language committee have indicated that this interpretation is incorrect. Applications should assume that if realloc() returns a null pointer, the space pointed to by p has not been freed. Since this could lead to double-frees, implementations should also set errno if a null pointer actually indicates a failure, and applications should only free the space if errno was changed. Do not free memory of zero-length reallocation is requested https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html Co-authored-by: fangxinyong <fangxinyong@xiaomi.com> Signed-off-by: Petro Karashchenko <petro.karashchenko@gmail.com>
2023-05-02 14:58:22 +02:00
FAR void *mem = NULL;
mm: memory allocations return valid pointer when request 0 size This change introduce 2 items: 1. If the size of the space requested is 0, the behavior is implementation-defined: either a null pointer shall be returned, or the behavior shall be as if the size were some non-zero value, except that the behavior is undefined if the returned pointer is used to access an object. Change the behavior to be similar to Linux and Android and allocates an object of a minimum size instead of returning null pointer. https://pubs.opengroup.org/onlinepubs/9699919799/functions/malloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/calloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html 2. The description of realloc() has been modified from previous versions of this standard to align with the ISO/IEC 9899:1999 standard. Previous versions explicitly permitted a call to realloc (p, 0) to free the space pointed to by p and return a null pointer. While this behavior could be interpreted as permitted by this version of the standard, the C language committee have indicated that this interpretation is incorrect. Applications should assume that if realloc() returns a null pointer, the space pointed to by p has not been freed. Since this could lead to double-frees, implementations should also set errno if a null pointer actually indicates a failure, and applications should only free the space if errno was changed. Do not free memory of zero-length reallocation is requested https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html Co-authored-by: fangxinyong <fangxinyong@xiaomi.com> Signed-off-by: Petro Karashchenko <petro.karashchenko@gmail.com>
2023-05-02 14:58:22 +02:00
/* Verify input parameters
*
* elem_size or n is zero treats as valid input.
*
* Assure that the following multiplication cannot overflow the size_t
* type, i.e., that: SIZE_MAX >= n * elem_size
*
* Refer to SEI CERT C Coding Standard.
*/
mm: memory allocations return valid pointer when request 0 size This change introduce 2 items: 1. If the size of the space requested is 0, the behavior is implementation-defined: either a null pointer shall be returned, or the behavior shall be as if the size were some non-zero value, except that the behavior is undefined if the returned pointer is used to access an object. Change the behavior to be similar to Linux and Android and allocates an object of a minimum size instead of returning null pointer. https://pubs.opengroup.org/onlinepubs/9699919799/functions/malloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/calloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html 2. The description of realloc() has been modified from previous versions of this standard to align with the ISO/IEC 9899:1999 standard. Previous versions explicitly permitted a call to realloc (p, 0) to free the space pointed to by p and return a null pointer. While this behavior could be interpreted as permitted by this version of the standard, the C language committee have indicated that this interpretation is incorrect. Applications should assume that if realloc() returns a null pointer, the space pointed to by p has not been freed. Since this could lead to double-frees, implementations should also set errno if a null pointer actually indicates a failure, and applications should only free the space if errno was changed. Do not free memory of zero-length reallocation is requested https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html Co-authored-by: fangxinyong <fangxinyong@xiaomi.com> Signed-off-by: Petro Karashchenko <petro.karashchenko@gmail.com>
2023-05-02 14:58:22 +02:00
if (elem_size == 0 || n <= (SIZE_MAX / elem_size))
{
mm: memory allocations return valid pointer when request 0 size This change introduce 2 items: 1. If the size of the space requested is 0, the behavior is implementation-defined: either a null pointer shall be returned, or the behavior shall be as if the size were some non-zero value, except that the behavior is undefined if the returned pointer is used to access an object. Change the behavior to be similar to Linux and Android and allocates an object of a minimum size instead of returning null pointer. https://pubs.opengroup.org/onlinepubs/9699919799/functions/malloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/calloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html 2. The description of realloc() has been modified from previous versions of this standard to align with the ISO/IEC 9899:1999 standard. Previous versions explicitly permitted a call to realloc (p, 0) to free the space pointed to by p and return a null pointer. While this behavior could be interpreted as permitted by this version of the standard, the C language committee have indicated that this interpretation is incorrect. Applications should assume that if realloc() returns a null pointer, the space pointed to by p has not been freed. Since this could lead to double-frees, implementations should also set errno if a null pointer actually indicates a failure, and applications should only free the space if errno was changed. Do not free memory of zero-length reallocation is requested https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html Co-authored-by: fangxinyong <fangxinyong@xiaomi.com> Signed-off-by: Petro Karashchenko <petro.karashchenko@gmail.com>
2023-05-02 14:58:22 +02:00
mem = mm_zalloc(heap, n * elem_size);
}
mm: memory allocations return valid pointer when request 0 size This change introduce 2 items: 1. If the size of the space requested is 0, the behavior is implementation-defined: either a null pointer shall be returned, or the behavior shall be as if the size were some non-zero value, except that the behavior is undefined if the returned pointer is used to access an object. Change the behavior to be similar to Linux and Android and allocates an object of a minimum size instead of returning null pointer. https://pubs.opengroup.org/onlinepubs/9699919799/functions/malloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/calloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html 2. The description of realloc() has been modified from previous versions of this standard to align with the ISO/IEC 9899:1999 standard. Previous versions explicitly permitted a call to realloc (p, 0) to free the space pointed to by p and return a null pointer. While this behavior could be interpreted as permitted by this version of the standard, the C language committee have indicated that this interpretation is incorrect. Applications should assume that if realloc() returns a null pointer, the space pointed to by p has not been freed. Since this could lead to double-frees, implementations should also set errno if a null pointer actually indicates a failure, and applications should only free the space if errno was changed. Do not free memory of zero-length reallocation is requested https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html Co-authored-by: fangxinyong <fangxinyong@xiaomi.com> Signed-off-by: Petro Karashchenko <petro.karashchenko@gmail.com>
2023-05-02 14:58:22 +02:00
return mem;
}
#ifdef CONFIG_DEBUG_MM
/****************************************************************************
* Name: mm_checkcorruption
*
* Description:
* mm_checkcorruption is used to check whether memory heap is normal.
*
****************************************************************************/
void mm_checkcorruption(FAR struct mm_heap_s *heap)
{
#if CONFIG_MM_REGIONS > 1
int region;
#else
# define region 0
#endif
/* Visit each region */
#if CONFIG_MM_REGIONS > 1
for (region = 0; region < heap->mm_nregions; region++)
#endif
{
/* Retake the mutex for each region to reduce latencies */
if (mm_lock(heap) < 0)
{
return;
}
/* Check tlsf control block in the first pass */
if (region == 0)
{
tlsf_check(heap->mm_tlsf);
}
/* Check tlsf pool in each iteration temporarily */
tlsf_check_pool(heap->mm_heapstart[region]);
/* Release the mutex */
mm_unlock(heap);
}
#undef region
}
#endif
/****************************************************************************
* Name: mm_extend
*
* Description:
* Extend a heap region by add a block of (virtually) contiguous memory
* to the end of the heap.
*
****************************************************************************/
void mm_extend(FAR struct mm_heap_s *heap, FAR void *mem, size_t size,
int region)
{
size_t oldsize;
/* Make sure that we were passed valid parameters */
#if CONFIG_MM_REGIONS > 1
DEBUGASSERT(region >= 0 && region < heap->mm_nregions);
#else
DEBUGASSERT(region == 0);
#endif
DEBUGASSERT(mem == heap->mm_heapend[region]);
/* Take the memory manager mutex */
DEBUGVERIFY(mm_lock(heap));
/* Extend the tlsf pool */
oldsize = heap->mm_heapend[region] - heap->mm_heapstart[region];
tlsf_extend_pool(heap->mm_tlsf, heap->mm_heapstart[region], oldsize, size);
/* Save the new size */
heap->mm_heapsize += size;
heap->mm_heapend[region] += size;
mm_unlock(heap);
}
/****************************************************************************
* Name: mm_free
*
* Description:
* Returns a chunk of memory to the list of free nodes, merging with
* adjacent free chunks if possible.
*
****************************************************************************/
void mm_free(FAR struct mm_heap_s *heap, FAR void *mem)
{
minfo("Freeing %p\n", mem);
/* Protect against attempts to free a NULL reference */
if (mem == NULL)
{
return;
}
DEBUGASSERT(mm_heapmember(heap, mem));
#ifdef CONFIG_MM_HEAP_MEMPOOL
if (heap->mm_mpool)
{
if (mempool_multiple_free(heap->mm_mpool, mem) >= 0)
{
return;
}
}
#endif
mm_delayfree(heap, mem, CONFIG_MM_FREE_DELAYCOUNT_MAX > 0);
}
/****************************************************************************
* Name: mm_heapmember
*
* Description:
* Check if an address lies in the heap.
*
* Parameters:
* heap - The heap to check
* mem - The address to check
*
* Return Value:
* true if the address is a member of the heap. false if not
* not. If the address is not a member of the heap, then it
* must be a member of the user-space heap (unchecked)
*
****************************************************************************/
bool mm_heapmember(FAR struct mm_heap_s *heap, FAR void *mem)
{
#if CONFIG_MM_REGIONS > 1
int i;
/* A valid address from the heap for this region would have to lie
* between the region's two guard nodes.
*/
for (i = 0; i < heap->mm_nregions; i++)
{
if (mem >= heap->mm_heapstart[i] &&
mem < heap->mm_heapend[i])
{
return true;
}
}
/* The address does not like any any region assigned to the heap */
return false;
#else
/* A valid address from the heap would have to lie between the
* two guard nodes.
*/
if (mem >= heap->mm_heapstart[0] &&
mem < heap->mm_heapend[0])
{
return true;
}
/* Otherwise, the address does not lie in the heap */
return false;
#endif
}
/****************************************************************************
* Name: mm_initialize
*
* Description:
* Initialize the selected heap data structures, providing the initial
* heap region.
*
* Input Parameters:
* heap - The selected heap
* heapstart - Start of the initial heap region
* heapsize - Size of the initial heap region
*
* Returned Value:
* None
*
* Assumptions:
*
****************************************************************************/
FAR struct mm_heap_s *mm_initialize(FAR const char *name,
FAR void *heapstart, size_t heapsize)
{
FAR struct mm_heap_s *heap;
minfo("Heap: name=%s start=%p size=%zu\n", name, heapstart, heapsize);
/* Reserve a block space for mm_heap_s context */
DEBUGASSERT(heapsize > sizeof(struct mm_heap_s));
heap = (FAR struct mm_heap_s *)heapstart;
memset(heap, 0, sizeof(struct mm_heap_s));
heapstart += sizeof(struct mm_heap_s);
heapsize -= sizeof(struct mm_heap_s);
/* Allocate and create TLSF context */
DEBUGASSERT(heapsize > tlsf_size());
heap->mm_tlsf = tlsf_create(heapstart);
heapstart += tlsf_size();
heapsize -= tlsf_size();
/* Initialize the malloc mutex (to support one-at-
* a-time access to private data sets).
*/
nxmutex_init(&heap->mm_lock);
/* Add the initial region of memory to the heap */
mm_addregion(heap, heapstart, heapsize);
#if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_MEMINFO)
#if defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__)
heap->mm_procfs.name = name;
heap->mm_procfs.heap = heap;
# ifdef CONFIG_MM_BACKTRACE_DEFAULT
heap->mm_procfs.backtrace = true;
# endif
procfs_register_meminfo(&heap->mm_procfs);
#endif
#endif
return heap;
}
#ifdef CONFIG_MM_HEAP_MEMPOOL
FAR struct mm_heap_s *
mm_initialize_pool(FAR const char *name,
FAR void *heap_start, size_t heap_size,
FAR const struct mempool_init_s *init)
{
FAR struct mm_heap_s *heap;
#if CONFIG_MM_HEAP_MEMPOOL_THRESHOLD > 0
size_t poolsize[MEMPOOL_NPOOLS];
struct mempool_init_s def;
if (init == NULL)
{
/* Initialize the multiple mempool default parameter */
int i;
for (i = 0; i < MEMPOOL_NPOOLS; i++)
{
poolsize[i] = (i + 1) * tlsf_align_size();
}
def.poolsize = poolsize;
def.npools = MEMPOOL_NPOOLS;
def.threshold = CONFIG_MM_HEAP_MEMPOOL_THRESHOLD;
def.chunksize = CONFIG_MM_HEAP_MEMPOOL_CHUNK_SIZE;
def.expandsize = CONFIG_MM_HEAP_MEMPOOL_EXPAND_SIZE;
def.dict_expendsize = CONFIG_MM_HEAP_MEMPOOL_DICTIONARY_EXPAND_SIZE;
init = &def;
}
#endif
heap = mm_initialize(name, heap_start, heap_size);
/* Initialize the multiple mempool in heap */
if (init != NULL && init->poolsize != NULL && init->npools != 0)
{
heap->mm_threshold = init->threshold;
heap->mm_mpool = mempool_multiple_init(name, init->poolsize,
init->npools,
(mempool_multiple_alloc_t)mempool_memalign,
(mempool_multiple_alloc_size_t)mm_malloc_size,
(mempool_multiple_free_t)mm_free, heap,
init->chunksize, init->expandsize,
init->dict_expendsize);
}
return heap;
}
#endif
/****************************************************************************
* Name: mm_mallinfo
*
* Description:
* mallinfo returns a copy of updated current heap information.
*
****************************************************************************/
struct mallinfo mm_mallinfo(FAR struct mm_heap_s *heap)
{
struct mallinfo info;
#ifdef CONFIG_MM_HEAP_MEMPOOL
struct mallinfo poolinfo;
#endif
#if CONFIG_MM_REGIONS > 1
int region;
#else
# define region 0
#endif
memset(&info, 0, sizeof(struct mallinfo));
/* Visit each region */
#if CONFIG_MM_REGIONS > 1
for (region = 0; region < heap->mm_nregions; region++)
#endif
{
/* Retake the mutex for each region to reduce latencies */
DEBUGVERIFY(mm_lock(heap));
tlsf_walk_pool(heap->mm_heapstart[region],
mallinfo_handler, &info);
mm_unlock(heap);
}
#undef region
info.arena = heap->mm_heapsize;
info.uordblks = info.arena - info.fordblks;
info.usmblks = heap->mm_maxused;
#ifdef CONFIG_MM_HEAP_MEMPOOL
poolinfo = mempool_multiple_mallinfo(heap->mm_mpool);
info.uordblks -= poolinfo.fordblks;
info.fordblks += poolinfo.fordblks;
#endif
return info;
}
struct mallinfo_task mm_mallinfo_task(FAR struct mm_heap_s *heap,
FAR const struct malltask *task)
{
struct mm_mallinfo_handler_s handle;
struct mallinfo_task info =
{
0, 0
};
#if CONFIG_MM_REGIONS > 1
int region;
#else
#define region 0
#endif
#ifdef CONFIG_MM_HEAP_MEMPOOL
info = mempool_multiple_info_task(heap->mm_mpool, task);
#endif
handle.task = task;
handle.info = &info;
#if CONFIG_MM_REGIONS > 1
for (region = 0; region < heap->mm_nregions; region++)
#endif
{
/* Retake the mutex for each region to reduce latencies */
DEBUGVERIFY(mm_lock(heap));
tlsf_walk_pool(heap->mm_heapstart[region],
mallinfo_task_handler, &handle);
mm_unlock(heap);
}
#undef region
return info;
}
/****************************************************************************
* Name: mm_memdump
*
* Description:
* mm_memdump returns a memory info about specified pid of task/thread.
* if pid equals -1, this function will dump all allocated node and output
* backtrace for every allocated node for this heap, if pid equals -2, this
* function will dump all free node for this heap, and if pid is greater
* than or equal to 0, will dump pid allocated node and output backtrace.
****************************************************************************/
void mm_memdump(FAR struct mm_heap_s *heap,
FAR const struct mm_memdump_s *dump)
{
#if CONFIG_MM_REGIONS > 1
int region;
#else
# define region 0
#endif
struct mallinfo_task info;
if (dump->pid >= PID_MM_ALLOC)
{
syslog(LOG_INFO, "Dump all used memory node info:\n");
#if CONFIG_MM_BACKTRACE < 0
syslog(LOG_INFO, "%12s%*s\n", "Size", BACKTRACE_PTR_FMT_WIDTH,
"Address");
#else
syslog(LOG_INFO, "%6s%12s%12s%*s %s\n", "PID", "Size", "Sequence",
BACKTRACE_PTR_FMT_WIDTH, "Address", "Backtrace");
#endif
}
else
{
syslog(LOG_INFO, "Dump all free memory node info:\n");
syslog(LOG_INFO, "%12s%*s\n", "Size", BACKTRACE_PTR_FMT_WIDTH,
"Address");
}
#ifdef CONFIG_MM_HEAP_MEMPOOL
mempool_multiple_memdump(heap->mm_mpool, dump);
#endif
#if CONFIG_MM_REGIONS > 1
for (region = 0; region < heap->mm_nregions; region++)
#endif
{
DEBUGVERIFY(mm_lock(heap));
tlsf_walk_pool(heap->mm_heapstart[region],
memdump_handler, (FAR void *)dump);
mm_unlock(heap);
}
#undef region
info = mm_mallinfo_task(heap, dump);
syslog(LOG_INFO, "%12s%12s\n", "Total Blks", "Total Size");
syslog(LOG_INFO, "%12d%12d\n", info.aordblks, info.uordblks);
}
/****************************************************************************
* Name: mm_malloc_size
****************************************************************************/
size_t mm_malloc_size(FAR struct mm_heap_s *heap, FAR void *mem)
{
#ifdef CONFIG_MM_HEAP_MEMPOOL
if (heap->mm_mpool)
{
ssize_t size = mempool_multiple_alloc_size(heap->mm_mpool, mem);
if (size >= 0)
{
return size;
}
}
#endif
#if CONFIG_MM_BACKTRACE >= 0
return tlsf_block_size(mem) - sizeof(struct memdump_backtrace_s);
#else
return tlsf_block_size(mem);
#endif
}
/****************************************************************************
* Name: mm_malloc
*
* Description:
* Find the smallest chunk that satisfies the request. Take the memory from
* that chunk, save the remaining, smaller chunk (if any).
*
* 8-byte alignment of the allocated data is assured.
*
****************************************************************************/
FAR void *mm_malloc(FAR struct mm_heap_s *heap, size_t size)
{
size_t nodesize;
FAR void *ret;
mm: memory allocations return valid pointer when request 0 size This change introduce 2 items: 1. If the size of the space requested is 0, the behavior is implementation-defined: either a null pointer shall be returned, or the behavior shall be as if the size were some non-zero value, except that the behavior is undefined if the returned pointer is used to access an object. Change the behavior to be similar to Linux and Android and allocates an object of a minimum size instead of returning null pointer. https://pubs.opengroup.org/onlinepubs/9699919799/functions/malloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/calloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html 2. The description of realloc() has been modified from previous versions of this standard to align with the ISO/IEC 9899:1999 standard. Previous versions explicitly permitted a call to realloc (p, 0) to free the space pointed to by p and return a null pointer. While this behavior could be interpreted as permitted by this version of the standard, the C language committee have indicated that this interpretation is incorrect. Applications should assume that if realloc() returns a null pointer, the space pointed to by p has not been freed. Since this could lead to double-frees, implementations should also set errno if a null pointer actually indicates a failure, and applications should only free the space if errno was changed. Do not free memory of zero-length reallocation is requested https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html Co-authored-by: fangxinyong <fangxinyong@xiaomi.com> Signed-off-by: Petro Karashchenko <petro.karashchenko@gmail.com>
2023-05-02 14:58:22 +02:00
/* In case of zero-length allocations allocate the minimum size object */
if (size < 1)
{
size = 1;
}
#ifdef CONFIG_MM_HEAP_MEMPOOL
if (heap->mm_mpool)
{
ret = mempool_multiple_alloc(heap->mm_mpool, size);
if (ret != NULL)
{
return ret;
}
}
#endif
/* Free the delay list first */
free_delaylist(heap, false);
/* Allocate from the tlsf pool */
DEBUGVERIFY(mm_lock(heap));
#if CONFIG_MM_BACKTRACE >= 0
ret = tlsf_malloc(heap->mm_tlsf, size +
sizeof(struct memdump_backtrace_s));
#else
ret = tlsf_malloc(heap->mm_tlsf, size);
#endif
nodesize = mm_malloc_size(heap, ret);
heap->mm_curused += nodesize;
if (heap->mm_curused > heap->mm_maxused)
{
heap->mm_maxused = heap->mm_curused;
}
mm_unlock(heap);
if (ret)
{
#if CONFIG_MM_BACKTRACE >= 0
FAR struct memdump_backtrace_s *buf = ret + nodesize;
memdump_backtrace(heap, buf);
#endif
ret = kasan_unpoison(ret, nodesize);
sched_note_heap(NOTE_HEAP_ALLOC, heap, ret, nodesize,
heap->mm_curused);
#ifdef CONFIG_MM_FILL_ALLOCATIONS
memset(ret, 0xaa, nodesize);
#endif
}
#if CONFIG_MM_FREE_DELAYCOUNT_MAX > 0
/* Try again after free delay list */
else if (free_delaylist(heap, true))
{
return mm_malloc(heap, size);
}
#endif
return ret;
}
/****************************************************************************
* Name: mm_memalign
*
* Description:
* memalign requests more than enough space from malloc, finds a region
* within that chunk that meets the alignment request and then frees any
* leading or trailing space.
*
* The alignment argument must be a power of two (not checked). 8-byte
* alignment is guaranteed by normal malloc calls.
*
****************************************************************************/
FAR void *mm_memalign(FAR struct mm_heap_s *heap, size_t alignment,
size_t size)
{
size_t nodesize;
FAR void *ret;
#ifdef CONFIG_MM_HEAP_MEMPOOL
if (heap->mm_mpool)
{
ret = mempool_multiple_memalign(heap->mm_mpool, alignment, size);
if (ret != NULL)
{
return ret;
}
}
#endif
/* Free the delay list first */
free_delaylist(heap, false);
/* Allocate from the tlsf pool */
DEBUGVERIFY(mm_lock(heap));
#if CONFIG_MM_BACKTRACE >= 0
ret = tlsf_memalign(heap->mm_tlsf, alignment, size +
sizeof(struct memdump_backtrace_s));
#else
ret = tlsf_memalign(heap->mm_tlsf, alignment, size);
#endif
nodesize = mm_malloc_size(heap, ret);
heap->mm_curused += nodesize;
if (heap->mm_curused > heap->mm_maxused)
{
heap->mm_maxused = heap->mm_curused;
}
mm_unlock(heap);
if (ret)
{
#if CONFIG_MM_BACKTRACE >= 0
FAR struct memdump_backtrace_s *buf = ret + nodesize;
memdump_backtrace(heap, buf);
#endif
ret = kasan_unpoison(ret, nodesize);
sched_note_heap(NOTE_HEAP_ALLOC, heap, ret, nodesize,
heap->mm_curused);
}
#if CONFIG_MM_FREE_DELAYCOUNT_MAX > 0
/* Try again after free delay list */
else if (free_delaylist(heap, true))
{
return mm_memalign(heap, alignment, size);
}
#endif
return ret;
}
/****************************************************************************
* Name: mm_realloc
*
* Description:
* If the reallocation is for less space, then:
*
* (1) the current allocation is reduced in size
* (2) the remainder at the end of the allocation is returned to the
* free list.
*
* If the request is for more space and the current allocation can be
* extended, it will be extended by:
*
* (1) Taking the additional space from the following free chunk, or
* (2) Taking the additional space from the preceding free chunk.
* (3) Or both
*
* If the request is for more space but the current chunk cannot be
* extended, then malloc a new buffer, copy the data into the new buffer,
* and free the old buffer.
*
****************************************************************************/
FAR void *mm_realloc(FAR struct mm_heap_s *heap, FAR void *oldmem,
size_t size)
{
FAR void *newmem;
size_t oldsize;
size_t newsize;
mm: memory allocations return valid pointer when request 0 size This change introduce 2 items: 1. If the size of the space requested is 0, the behavior is implementation-defined: either a null pointer shall be returned, or the behavior shall be as if the size were some non-zero value, except that the behavior is undefined if the returned pointer is used to access an object. Change the behavior to be similar to Linux and Android and allocates an object of a minimum size instead of returning null pointer. https://pubs.opengroup.org/onlinepubs/9699919799/functions/malloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/calloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html 2. The description of realloc() has been modified from previous versions of this standard to align with the ISO/IEC 9899:1999 standard. Previous versions explicitly permitted a call to realloc (p, 0) to free the space pointed to by p and return a null pointer. While this behavior could be interpreted as permitted by this version of the standard, the C language committee have indicated that this interpretation is incorrect. Applications should assume that if realloc() returns a null pointer, the space pointed to by p has not been freed. Since this could lead to double-frees, implementations should also set errno if a null pointer actually indicates a failure, and applications should only free the space if errno was changed. Do not free memory of zero-length reallocation is requested https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html Co-authored-by: fangxinyong <fangxinyong@xiaomi.com> Signed-off-by: Petro Karashchenko <petro.karashchenko@gmail.com>
2023-05-02 14:58:22 +02:00
/* If oldmem is NULL, then realloc is equivalent to malloc */
if (oldmem == NULL)
{
return mm_malloc(heap, size);
}
mm: memory allocations return valid pointer when request 0 size This change introduce 2 items: 1. If the size of the space requested is 0, the behavior is implementation-defined: either a null pointer shall be returned, or the behavior shall be as if the size were some non-zero value, except that the behavior is undefined if the returned pointer is used to access an object. Change the behavior to be similar to Linux and Android and allocates an object of a minimum size instead of returning null pointer. https://pubs.opengroup.org/onlinepubs/9699919799/functions/malloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/calloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html 2. The description of realloc() has been modified from previous versions of this standard to align with the ISO/IEC 9899:1999 standard. Previous versions explicitly permitted a call to realloc (p, 0) to free the space pointed to by p and return a null pointer. While this behavior could be interpreted as permitted by this version of the standard, the C language committee have indicated that this interpretation is incorrect. Applications should assume that if realloc() returns a null pointer, the space pointed to by p has not been freed. Since this could lead to double-frees, implementations should also set errno if a null pointer actually indicates a failure, and applications should only free the space if errno was changed. Do not free memory of zero-length reallocation is requested https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html Co-authored-by: fangxinyong <fangxinyong@xiaomi.com> Signed-off-by: Petro Karashchenko <petro.karashchenko@gmail.com>
2023-05-02 14:58:22 +02:00
/* If size is zero, reallocate to the minim size object, so
* the memory pointed by oldmem is freed
*/
if (size < 1)
{
mm: memory allocations return valid pointer when request 0 size This change introduce 2 items: 1. If the size of the space requested is 0, the behavior is implementation-defined: either a null pointer shall be returned, or the behavior shall be as if the size were some non-zero value, except that the behavior is undefined if the returned pointer is used to access an object. Change the behavior to be similar to Linux and Android and allocates an object of a minimum size instead of returning null pointer. https://pubs.opengroup.org/onlinepubs/9699919799/functions/malloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/calloc.html https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html 2. The description of realloc() has been modified from previous versions of this standard to align with the ISO/IEC 9899:1999 standard. Previous versions explicitly permitted a call to realloc (p, 0) to free the space pointed to by p and return a null pointer. While this behavior could be interpreted as permitted by this version of the standard, the C language committee have indicated that this interpretation is incorrect. Applications should assume that if realloc() returns a null pointer, the space pointed to by p has not been freed. Since this could lead to double-frees, implementations should also set errno if a null pointer actually indicates a failure, and applications should only free the space if errno was changed. Do not free memory of zero-length reallocation is requested https://pubs.opengroup.org/onlinepubs/9699919799/functions/realloc.html Co-authored-by: fangxinyong <fangxinyong@xiaomi.com> Signed-off-by: Petro Karashchenko <petro.karashchenko@gmail.com>
2023-05-02 14:58:22 +02:00
size = 1;
}
#ifdef CONFIG_MM_HEAP_MEMPOOL
if (heap->mm_mpool)
{
newmem = mempool_multiple_realloc(heap->mm_mpool, oldmem, size);
if (newmem != NULL)
{
return newmem;
}
else if (size <= heap->mm_threshold ||
mempool_multiple_alloc_size(heap->mm_mpool, oldmem) >= 0)
{
newmem = mm_malloc(heap, size);
if (newmem != 0)
{
memcpy(newmem, oldmem, size);
mm_free(heap, oldmem);
return newmem;
}
}
}
#endif
#ifdef CONFIG_MM_KASAN
newmem = mm_malloc(heap, size);
if (newmem)
{
if (size > mm_malloc_size(heap, oldmem))
{
size = mm_malloc_size(heap, oldmem);
}
memcpy(newmem, oldmem, size);
mm_free(heap, oldmem);
}
#else
/* Free the delay list first */
free_delaylist(heap, false);
/* Allocate from the tlsf pool */
DEBUGVERIFY(mm_lock(heap));
oldsize = mm_malloc_size(heap, oldmem);
heap->mm_curused -= oldsize;
#if CONFIG_MM_BACKTRACE >= 0
newmem = tlsf_realloc(heap->mm_tlsf, oldmem, size +
sizeof(struct memdump_backtrace_s));
#else
newmem = tlsf_realloc(heap->mm_tlsf, oldmem, size);
#endif
newsize = mm_malloc_size(heap, newmem);
heap->mm_curused += newmem ? newsize : oldsize;
if (heap->mm_curused > heap->mm_maxused)
{
heap->mm_maxused = heap->mm_curused;
}
mm_unlock(heap);
if (newmem)
{
#if CONFIG_MM_BACKTRACE >= 0
FAR struct memdump_backtrace_s *buf = newmem + newsize;
memdump_backtrace(heap, buf);
#endif
sched_note_heap(NOTE_HEAP_FREE, heap, oldmem, oldsize,
heap->mm_curused - newsize);
sched_note_heap(NOTE_HEAP_ALLOC, heap, newmem, newsize,
heap->mm_curused);
}
#if CONFIG_MM_FREE_DELAYCOUNT_MAX > 0
/* Try again after free delay list */
else if (free_delaylist(heap, true))
{
return mm_realloc(heap, oldmem, size);
}
#endif
#endif
return newmem;
}
/****************************************************************************
* Name: mm_uninitialize
*
* Description:
* Uninitialize the selected heap data structures.
*
* Input Parameters:
* heap - The heap to uninitialize
*
* Returned Value:
* None
*
****************************************************************************/
void mm_uninitialize(FAR struct mm_heap_s *heap)
{
int i;
#ifdef CONFIG_MM_HEAP_MEMPOOL
mempool_multiple_deinit(heap->mm_mpool);
#endif
for (i = 0; i < CONFIG_MM_REGIONS; i++)
{
kasan_unregister(heap->mm_heapstart[i]);
sched_note_heap(NOTE_HEAP_REMOVE, heap, heap->mm_heapstart[i],
(uintptr_t)heap->mm_heapend[i] -
(uintptr_t)heap->mm_heapstart[i], heap->mm_curused);
}
#if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_MEMINFO)
# if defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__)
procfs_unregister_meminfo(&heap->mm_procfs);
# endif
#endif
nxmutex_destroy(&heap->mm_lock);
tlsf_destroy(&heap->mm_tlsf);
}
/****************************************************************************
* Name: mm_zalloc
*
* Description:
* mm_zalloc calls mm_malloc, then zeroes out the allocated chunk.
*
****************************************************************************/
FAR void *mm_zalloc(FAR struct mm_heap_s *heap, size_t size)
{
FAR void *alloc = mm_malloc(heap, size);
if (alloc)
{
memset(alloc, 0, size);
}
return alloc;
}
/****************************************************************************
* Name: mm_free_delaylist
*
* Description:
* force freeing the delaylist of this heap.
*
****************************************************************************/
void mm_free_delaylist(FAR struct mm_heap_s *heap)
{
if (heap)
{
free_delaylist(heap, true);
}
}
/****************************************************************************
* Name: mm_heapfree
*
* Description:
* Return the total free size (in bytes) in the heap
*
****************************************************************************/
size_t mm_heapfree(FAR struct mm_heap_s *heap)
{
return heap->mm_heapsize - heap->mm_curused;
}
/****************************************************************************
* Name: mm_heapfree_largest
*
* Description:
* Return the largest chunk of contiguous memory in the heap
*
****************************************************************************/
size_t mm_heapfree_largest(FAR struct mm_heap_s *heap)
{
return SIZE_MAX;
}