HardenedBSD/gnu/lib/libmalloc/malloc.c
Rich Murphey adb52cac6c merge free.c realloc.c into malloc.c so that all three are linked in
if any are referenced.

libc's malloc.o contains malloc(), free() and realloc().  And libc
refers to realloc which will cause the linker to pull in redundant
malloc() and free() definitions from malloc.o if it isn't already
linked in from GNU malloc.  Rich
1993-10-19 18:22:37 +00:00

623 lines
17 KiB
C

/* Memory allocator `malloc'.
Copyright 1990, 1991, 1992, 1993 Free Software Foundation
Written May 1989 by Mike Haertel.
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Library General Public License as
published by the Free Software Foundation; either version 2 of the
License, or (at your option) any later version.
This library 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
Library General Public License for more details.
You should have received a copy of the GNU Library General Public
License along with this library; see the file COPYING.LIB. If
not, write to the Free Software Foundation, Inc., 675 Mass Ave,
Cambridge, MA 02139, USA.
The author may be reached (Email) at the address mike@ai.mit.edu,
or (US mail) as Mike Haertel c/o Free Software Foundation. */
#ifndef _MALLOC_INTERNAL
#define _MALLOC_INTERNAL
#include <malloc.h>
#endif
/* How to really get more memory. */
__ptr_t (*__morecore) __P ((ptrdiff_t __size)) = __default_morecore;
/* Debugging hook for `malloc'. */
__ptr_t (*__malloc_hook) __P ((size_t __size));
/* Pointer to the base of the first block. */
char *_heapbase;
/* Block information table. Allocated with align/__free (not malloc/free). */
malloc_info *_heapinfo;
/* Number of info entries. */
static size_t heapsize;
/* Search index in the info table. */
size_t _heapindex;
/* Limit of valid info table indices. */
size_t _heaplimit;
/* Free lists for each fragment size. */
struct list _fraghead[BLOCKLOG];
/* Instrumentation. */
size_t _chunks_used;
size_t _bytes_used;
size_t _chunks_free;
size_t _bytes_free;
/* Are you experienced? */
int __malloc_initialized;
void (*__after_morecore_hook) __P ((void));
/* Aligned allocation. */
static __ptr_t align __P ((size_t));
static __ptr_t
align (size)
size_t size;
{
__ptr_t result;
unsigned long int adj;
result = (*__morecore) (size);
adj = (unsigned long int) ((unsigned long int) ((char *) result -
(char *) NULL)) % BLOCKSIZE;
if (adj != 0)
{
adj = BLOCKSIZE - adj;
(void) (*__morecore) (adj);
result = (char *) result + adj;
}
if (__after_morecore_hook)
(*__after_morecore_hook) ();
return result;
}
/* Set everything up and remember that we have. */
static int initialize __P ((void));
static int
initialize ()
{
heapsize = HEAP / BLOCKSIZE;
_heapinfo = (malloc_info *) align (heapsize * sizeof (malloc_info));
if (_heapinfo == NULL)
return 0;
memset (_heapinfo, 0, heapsize * sizeof (malloc_info));
_heapinfo[0].free.size = 0;
_heapinfo[0].free.next = _heapinfo[0].free.prev = 0;
_heapindex = 0;
_heapbase = (char *) _heapinfo;
__malloc_initialized = 1;
return 1;
}
/* Get neatly aligned memory, initializing or
growing the heap info table as necessary. */
static __ptr_t morecore __P ((size_t));
static __ptr_t
morecore (size)
size_t size;
{
__ptr_t result;
malloc_info *newinfo, *oldinfo;
size_t newsize;
result = align (size);
if (result == NULL)
return NULL;
/* Check if we need to grow the info table. */
if ((size_t) BLOCK ((char *) result + size) > heapsize)
{
newsize = heapsize;
while ((size_t) BLOCK ((char *) result + size) > newsize)
newsize *= 2;
newinfo = (malloc_info *) align (newsize * sizeof (malloc_info));
if (newinfo == NULL)
{
(*__morecore) (-size);
return NULL;
}
memset (newinfo, 0, newsize * sizeof (malloc_info));
memcpy (newinfo, _heapinfo, heapsize * sizeof (malloc_info));
oldinfo = _heapinfo;
newinfo[BLOCK (oldinfo)].busy.type = 0;
newinfo[BLOCK (oldinfo)].busy.info.size
= BLOCKIFY (heapsize * sizeof (malloc_info));
_heapinfo = newinfo;
_free_internal (oldinfo);
heapsize = newsize;
}
_heaplimit = BLOCK ((char *) result + size);
return result;
}
/* Allocate memory from the heap. */
__ptr_t
malloc (size)
size_t size;
{
__ptr_t result;
size_t block, blocks, lastblocks, start;
register size_t i;
struct list *next;
/* ANSI C allows `malloc (0)' to either return NULL, or to return a
valid address you can realloc and free (though not dereference).
It turns out that some extant code (sunrpc, at least Ultrix's version)
expects `malloc (0)' to return non-NULL and breaks otherwise.
Be compatible. */
#if 0
if (size == 0)
return NULL;
#endif
if (__malloc_hook != NULL)
return (*__malloc_hook) (size);
if (!__malloc_initialized)
if (!initialize ())
return NULL;
if (size < sizeof (struct list))
size = sizeof (struct list);
/* Determine the allocation policy based on the request size. */
if (size <= BLOCKSIZE / 2)
{
/* Small allocation to receive a fragment of a block.
Determine the logarithm to base two of the fragment size. */
register size_t log = 1;
--size;
while ((size /= 2) != 0)
++log;
/* Look in the fragment lists for a
free fragment of the desired size. */
next = _fraghead[log].next;
if (next != NULL)
{
/* There are free fragments of this size.
Pop a fragment out of the fragment list and return it.
Update the block's nfree and first counters. */
result = (__ptr_t) next;
next->prev->next = next->next;
if (next->next != NULL)
next->next->prev = next->prev;
block = BLOCK (result);
if (--_heapinfo[block].busy.info.frag.nfree != 0)
_heapinfo[block].busy.info.frag.first = (unsigned long int)
((unsigned long int) ((char *) next->next - (char *) NULL)
% BLOCKSIZE) >> log;
/* Update the statistics. */
++_chunks_used;
_bytes_used += 1 << log;
--_chunks_free;
_bytes_free -= 1 << log;
}
else
{
/* No free fragments of the desired size, so get a new block
and break it into fragments, returning the first. */
result = malloc (BLOCKSIZE);
if (result == NULL)
return NULL;
/* Link all fragments but the first into the free list. */
for (i = 1; i < (size_t) (BLOCKSIZE >> log); ++i)
{
next = (struct list *) ((char *) result + (i << log));
next->next = _fraghead[log].next;
next->prev = &_fraghead[log];
next->prev->next = next;
if (next->next != NULL)
next->next->prev = next;
}
/* Initialize the nfree and first counters for this block. */
block = BLOCK (result);
_heapinfo[block].busy.type = log;
_heapinfo[block].busy.info.frag.nfree = i - 1;
_heapinfo[block].busy.info.frag.first = i - 1;
_chunks_free += (BLOCKSIZE >> log) - 1;
_bytes_free += BLOCKSIZE - (1 << log);
_bytes_used -= BLOCKSIZE - (1 << log);
}
}
else
{
/* Large allocation to receive one or more blocks.
Search the free list in a circle starting at the last place visited.
If we loop completely around without finding a large enough
space we will have to get more memory from the system. */
blocks = BLOCKIFY (size);
start = block = _heapindex;
while (_heapinfo[block].free.size < blocks)
{
block = _heapinfo[block].free.next;
if (block == start)
{
/* Need to get more from the system. Check to see if
the new core will be contiguous with the final free
block; if so we don't need to get as much. */
block = _heapinfo[0].free.prev;
lastblocks = _heapinfo[block].free.size;
if (_heaplimit != 0 && block + lastblocks == _heaplimit &&
(*__morecore) (0) == ADDRESS (block + lastblocks) &&
(morecore ((blocks - lastblocks) * BLOCKSIZE)) != NULL)
{
_heapinfo[block].free.size = blocks;
_bytes_free += (blocks - lastblocks) * BLOCKSIZE;
continue;
}
result = morecore (blocks * BLOCKSIZE);
if (result == NULL)
return NULL;
block = BLOCK (result);
_heapinfo[block].busy.type = 0;
_heapinfo[block].busy.info.size = blocks;
++_chunks_used;
_bytes_used += blocks * BLOCKSIZE;
return result;
}
}
/* At this point we have found a suitable free list entry.
Figure out how to remove what we need from the list. */
result = ADDRESS (block);
if (_heapinfo[block].free.size > blocks)
{
/* The block we found has a bit left over,
so relink the tail end back into the free list. */
_heapinfo[block + blocks].free.size
= _heapinfo[block].free.size - blocks;
_heapinfo[block + blocks].free.next
= _heapinfo[block].free.next;
_heapinfo[block + blocks].free.prev
= _heapinfo[block].free.prev;
_heapinfo[_heapinfo[block].free.prev].free.next
= _heapinfo[_heapinfo[block].free.next].free.prev
= _heapindex = block + blocks;
}
else
{
/* The block exactly matches our requirements,
so just remove it from the list. */
_heapinfo[_heapinfo[block].free.next].free.prev
= _heapinfo[block].free.prev;
_heapinfo[_heapinfo[block].free.prev].free.next
= _heapindex = _heapinfo[block].free.next;
--_chunks_free;
}
_heapinfo[block].busy.type = 0;
_heapinfo[block].busy.info.size = blocks;
++_chunks_used;
_bytes_used += blocks * BLOCKSIZE;
_bytes_free -= blocks * BLOCKSIZE;
}
return result;
}
#define min(A, B) ((A) < (B) ? (A) : (B))
/* Debugging hook for realloc. */
__ptr_t (*__realloc_hook) __P ((__ptr_t __ptr, size_t __size));
/* 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. This module has incestuous knowledge of the
internals of both free and malloc. */
__ptr_t
realloc (ptr, size)
__ptr_t ptr;
size_t size;
{
__ptr_t result;
int type;
size_t block, blocks, oldlimit;
if (size == 0)
{
free (ptr);
return malloc (0);
}
else if (ptr == NULL)
return malloc (size);
if (__realloc_hook != NULL)
return (*__realloc_hook) (ptr, size);
block = BLOCK (ptr);
type = _heapinfo[block].busy.type;
switch (type)
{
case 0:
/* Maybe reallocate a large block to a small fragment. */
if (size <= BLOCKSIZE / 2)
{
result = malloc (size);
if (result != NULL)
{
memcpy (result, ptr, size);
free (ptr);
return result;
}
}
/* 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 (ADDRESS (block + blocks));
result = ptr;
}
else if (blocks == _heapinfo[block].busy.info.size)
/* No size change necessary. */
result = ptr;
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 (ptr);
_heaplimit = oldlimit;
result = malloc (size);
if (result == NULL)
{
/* 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)
(void) malloc (blocks * BLOCKSIZE);
else
{
__ptr_t previous = malloc ((block - _heapindex) * BLOCKSIZE);
(void) malloc (blocks * BLOCKSIZE);
free (previous);
}
return NULL;
}
if (ptr != result)
memmove (result, ptr, blocks * BLOCKSIZE);
}
break;
default:
/* Old size is a fragment; type is logarithm
to base two of the fragment size. */
if (size > (size_t) (1 << (type - 1)) && size <= (size_t) (1 << type))
/* The new size is the same kind of fragment. */
result = ptr;
else
{
/* The new size is different; allocate a new space,
and copy the lesser of the new size and the old. */
result = malloc (size);
if (result == NULL)
return NULL;
memcpy (result, ptr, min (size, (size_t) 1 << type));
free (ptr);
}
break;
}
return result;
}
/* Debugging hook for free. */
void (*__free_hook) __P ((__ptr_t __ptr));
/* List of blocks allocated by memalign. */
struct alignlist *_aligned_blocks = NULL;
/* Return memory to the heap.
Like `free' but don't call a __free_hook if there is one. */
void
_free_internal (ptr)
__ptr_t ptr;
{
int type;
size_t block, blocks;
register size_t i;
struct list *prev, *next;
block = BLOCK (ptr);
type = _heapinfo[block].busy.type;
switch (type)
{
case 0:
/* Get as many statistics as early as we can. */
--_chunks_used;
_bytes_used -= _heapinfo[block].busy.info.size * BLOCKSIZE;
_bytes_free += _heapinfo[block].busy.info.size * BLOCKSIZE;
/* Find the free cluster previous to this one in the free list.
Start searching at the last block referenced; this may benefit
programs with locality of allocation. */
i = _heapindex;
if (i > block)
while (i > block)
i = _heapinfo[i].free.prev;
else
{
do
i = _heapinfo[i].free.next;
while (i > 0 && i < block);
i = _heapinfo[i].free.prev;
}
/* Determine how to link this block into the free list. */
if (block == i + _heapinfo[i].free.size)
{
/* Coalesce this block with its predecessor. */
_heapinfo[i].free.size += _heapinfo[block].busy.info.size;
block = i;
}
else
{
/* Really link this block back into the free list. */
_heapinfo[block].free.size = _heapinfo[block].busy.info.size;
_heapinfo[block].free.next = _heapinfo[i].free.next;
_heapinfo[block].free.prev = i;
_heapinfo[i].free.next = block;
_heapinfo[_heapinfo[block].free.next].free.prev = block;
++_chunks_free;
}
/* Now that the block is linked in, see if we can coalesce it
with its successor (by deleting its successor from the list
and adding in its size). */
if (block + _heapinfo[block].free.size == _heapinfo[block].free.next)
{
_heapinfo[block].free.size
+= _heapinfo[_heapinfo[block].free.next].free.size;
_heapinfo[block].free.next
= _heapinfo[_heapinfo[block].free.next].free.next;
_heapinfo[_heapinfo[block].free.next].free.prev = block;
--_chunks_free;
}
/* Now see if we can return stuff to the system. */
blocks = _heapinfo[block].free.size;
if (blocks >= FINAL_FREE_BLOCKS && block + blocks == _heaplimit
&& (*__morecore) (0) == ADDRESS (block + blocks))
{
register size_t bytes = blocks * BLOCKSIZE;
_heaplimit -= blocks;
(*__morecore) (-bytes);
_heapinfo[_heapinfo[block].free.prev].free.next
= _heapinfo[block].free.next;
_heapinfo[_heapinfo[block].free.next].free.prev
= _heapinfo[block].free.prev;
block = _heapinfo[block].free.prev;
--_chunks_free;
_bytes_free -= bytes;
}
/* Set the next search to begin at this block. */
_heapindex = block;
break;
default:
/* Do some of the statistics. */
--_chunks_used;
_bytes_used -= 1 << type;
++_chunks_free;
_bytes_free += 1 << type;
/* Get the address of the first free fragment in this block. */
prev = (struct list *) ((char *) ADDRESS (block) +
(_heapinfo[block].busy.info.frag.first << type));
if (_heapinfo[block].busy.info.frag.nfree == (BLOCKSIZE >> type) - 1)
{
/* If all fragments of this block are free, remove them
from the fragment list and free the whole block. */
next = prev;
for (i = 1; i < (size_t) (BLOCKSIZE >> type); ++i)
next = next->next;
prev->prev->next = next;
if (next != NULL)
next->prev = prev->prev;
_heapinfo[block].busy.type = 0;
_heapinfo[block].busy.info.size = 1;
/* Keep the statistics accurate. */
++_chunks_used;
_bytes_used += BLOCKSIZE;
_chunks_free -= BLOCKSIZE >> type;
_bytes_free -= BLOCKSIZE;
free (ADDRESS (block));
}
else if (_heapinfo[block].busy.info.frag.nfree != 0)
{
/* If some fragments of this block are free, link this
fragment into the fragment list after the first free
fragment of this block. */
next = (struct list *) ptr;
next->next = prev->next;
next->prev = prev;
prev->next = next;
if (next->next != NULL)
next->next->prev = next;
++_heapinfo[block].busy.info.frag.nfree;
}
else
{
/* No fragments of this block are free, so link this
fragment into the fragment list and announce that
it is the first free fragment of this block. */
prev = (struct list *) ptr;
_heapinfo[block].busy.info.frag.nfree = 1;
_heapinfo[block].busy.info.frag.first = (unsigned long int)
((unsigned long int) ((char *) ptr - (char *) NULL)
% BLOCKSIZE >> type);
prev->next = _fraghead[type].next;
prev->prev = &_fraghead[type];
prev->prev->next = prev;
if (prev->next != NULL)
prev->next->prev = prev;
}
break;
}
}
/* Return memory to the heap. */
void
free (ptr)
__ptr_t ptr;
{
register struct alignlist *l;
if (ptr == NULL)
return;
for (l = _aligned_blocks; l != NULL; l = l->next)
if (l->aligned == ptr)
{
l->aligned = NULL; /* Mark the slot in the list as free. */
ptr = l->exact;
break;
}
if (__free_hook != NULL)
(*__free_hook) (ptr);
else
_free_internal (ptr);
}