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/* malloc.c - C standard library routine.
Copyright (c) 1989, 1993 Michael J. Haertel
You may redistribute this library under the terms of the
GNU Library General Public License (version 2 or any later
version) as published by the Free Software Foundation.
THIS SOFTWARE IS PROVIDED "AS IS" WITHOUT ANY EXPRESS OR IMPLIED
WARRANTY. IN PARTICULAR, THE AUTHOR MAKES NO REPRESENTATION OR
WARRANTY OF ANY KIND CONCERNING THE MERCHANTABILITY OF THIS
SOFTWARE OR ITS FITNESS FOR ANY PARTICULAR PURPOSE. */
#define _GNU_SOURCE
#include <features.h>
#include <limits.h>
#include <stddef.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <errno.h>
#include "malloc.h"
#ifdef __UCLIBC_HAS_THREADS__
#include <pthread.h>
extern pthread_mutex_t __malloclock;
# define LOCK __pthread_mutex_lock(&__malloclock)
# define UNLOCK __pthread_mutex_unlock(&__malloclock);
#else
# define LOCK
# define UNLOCK
#endif
/* Resize the given region to the new size, returning a pointer
to the (possibly moved) region. This is optimized for speed;
some benchmarks seem to indicate that greater compactness is
achieved by unconditionally allocating and copying to a
new region. */
void * realloc (void *ptr, size_t size)
{
void *result, *previous;
size_t block, blocks, type;
size_t oldlimit;
if (!ptr)
return malloc(size);
if (!size) {
LOCK;
__free_unlocked(ptr);
result = __malloc_unlocked(0);
goto alldone;
}
LOCK;
block = BLOCK(ptr);
switch (type = _heapinfo[block].busy.type) {
case 0:
/* Maybe reallocate a large block to a small fragment. */
if (size <= BLOCKSIZE / 2) {
if ((result = __malloc_unlocked(size)) != NULL) {
memcpy(result, ptr, size);
__free_unlocked(ptr);
}
goto alldone;
}
/* The new size is a large allocation as well; see if
we can hold it in place. */
blocks = BLOCKIFY(size);
if (blocks < _heapinfo[block].busy.info.size) {
/* The new size is smaller; return excess memory
to the free list. */
_heapinfo[block + blocks].busy.type = 0;
_heapinfo[block + blocks].busy.info.size
= _heapinfo[block].busy.info.size - blocks;
_heapinfo[block].busy.info.size = blocks;
__free_unlocked(ADDRESS(block + blocks));
result = ptr;
goto alldone;
} else if (blocks == _heapinfo[block].busy.info.size) {
/* No size change necessary. */
result = ptr;
goto alldone;
} else {
/* Won't fit, so allocate a new region that will. Free
the old region first in case there is sufficient adjacent
free space to grow without moving. */
blocks = _heapinfo[block].busy.info.size;
/* Prevent free from actually returning memory to the system. */
oldlimit = _heaplimit;
_heaplimit = 0;
__free_unlocked(ptr);
_heaplimit = oldlimit;
result = __malloc_unlocked(size);
if (!result) {
/* Now we're really in trouble. We have to unfree
the thing we just freed. Unfortunately it might
have been coalesced with its neighbors. */
if (_heapindex == block)
__malloc_unlocked(blocks * BLOCKSIZE);
else {
previous = __malloc_unlocked((block - _heapindex) * BLOCKSIZE);
__malloc_unlocked(blocks * BLOCKSIZE);
__free_unlocked(previous);
}
goto oom;
}
if (ptr != result)
memmove(result, ptr, blocks * BLOCKSIZE);
goto alldone;
}
break;
default:
/* Old size is a fragment; type is logarithm to base two of
the fragment size. */
if ((size > 1 << (type - 1)) && (size <= 1 << type)) {
/* New size is the same kind of fragment. */
result = ptr;
goto alldone;
}
else {
/* New size is different; allocate a new space, and copy
the lesser of the new size and the old. */
result = __malloc_unlocked(size);
if (!result) {
goto oom;
}
memcpy(result, ptr, MIN(size, (size_t)(1 << type)));
__free_unlocked(ptr);
goto alldone;
}
break;
}
alldone:
UNLOCK;
return result;
oom:
UNLOCK;
__set_errno(ENOMEM);
return NULL;
}
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