OpenSolaris_b135/lib/libc/port/gen/malloc.c
/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright 2008 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
/* Copyright (c) 1988 AT&T */
/* All Rights Reserved */
#pragma ident "%Z%%M% %I% %E% SMI"
/*
* Memory management: malloc(), realloc(), free().
*
* The following #-parameters may be redefined:
* SEGMENTED: if defined, memory requests are assumed to be
* non-contiguous across calls of GETCORE's.
* GETCORE: a function to get more core memory. If not SEGMENTED,
* GETCORE(0) is assumed to return the next available
* address. Default is 'sbrk'.
* ERRCORE: the error code as returned by GETCORE.
* Default is (char *)(-1).
* CORESIZE: a desired unit (measured in bytes) to be used
* with GETCORE. Default is (1024*ALIGN).
*
* This algorithm is based on a best fit strategy with lists of
* free elts maintained in a self-adjusting binary tree. Each list
* contains all elts of the same size. The tree is ordered by size.
* For results on self-adjusting trees, see the paper:
* Self-Adjusting Binary Trees,
* DD Sleator & RE Tarjan, JACM 1985.
*
* The header of a block contains the size of the data part in bytes.
* Since the size of a block is 0%4, the low two bits of the header
* are free and used as follows:
*
* BIT0: 1 for busy (block is in use), 0 for free.
* BIT1: if the block is busy, this bit is 1 if the
* preceding block in contiguous memory is free.
* Otherwise, it is always 0.
*/
#include "lint.h"
#include "mallint.h"
#include "mtlib.h"
/*
* Some abusers of the system (notably java1.2) acquire __malloc_lock
* in order to prevent threads from holding it while they are being
* suspended via thr_suspend() or thr_suspend_allmutators().
* This never worked when alternate malloc() libraries were used
* because they don't use __malloc_lock for their locking strategy.
* We leave __malloc_lock as an external variable to satisfy these
* old programs, but we define a new lock, private to libc, to do the
* real locking: libc_malloc_lock. This puts libc's malloc() package
* on the same footing as all other malloc packages.
*/
mutex_t __malloc_lock = DEFAULTMUTEX;
mutex_t libc_malloc_lock = DEFAULTMUTEX;
static TREE *Root, /* root of the free tree */
*Bottom, /* the last free chunk in the arena */
*_morecore(size_t); /* function to get more core */
static char *Baddr; /* current high address of the arena */
static char *Lfree; /* last freed block with data intact */
static void t_delete(TREE *);
static void t_splay(TREE *);
static void realfree(void *);
static void cleanfree(void *);
static void *_malloc_unlocked(size_t);
#define FREESIZE (1<<5) /* size for preserving free blocks until next malloc */
#define FREEMASK FREESIZE-1
static void *flist[FREESIZE]; /* list of blocks to be freed on next malloc */
static int freeidx; /* index of free blocks in flist % FREESIZE */
/*
* Interfaces used only by atfork_init() functions.
*/
void
malloc_locks(void)
{
(void) mutex_lock(&libc_malloc_lock);
}
void
malloc_unlocks(void)
{
(void) mutex_unlock(&libc_malloc_lock);
}
/*
* Allocation of small blocks
*/
static TREE *List[MINSIZE/WORDSIZE-1]; /* lists of small blocks */
static void *
_smalloc(size_t size)
{
TREE *tp;
size_t i;
ASSERT(size % WORDSIZE == 0);
/* want to return a unique pointer on malloc(0) */
if (size == 0)
size = WORDSIZE;
/* list to use */
i = size / WORDSIZE - 1;
if (List[i] == NULL) {
TREE *np;
int n;
/* number of blocks to get at one time */
#define NPS (WORDSIZE*8)
ASSERT((size + WORDSIZE) * NPS >= MINSIZE);
/* get NPS of these block types */
if ((List[i] = _malloc_unlocked((size + WORDSIZE) * NPS)) == 0)
return (0);
/* make them into a link list */
for (n = 0, np = List[i]; n < NPS; ++n) {
tp = np;
SIZE(tp) = size;
np = NEXT(tp);
AFTER(tp) = np;
}
AFTER(tp) = NULL;
}
/* allocate from the head of the queue */
tp = List[i];
List[i] = AFTER(tp);
SETBIT0(SIZE(tp));
return (DATA(tp));
}
void *
malloc(size_t size)
{
void *ret;
if (!primary_link_map) {
errno = ENOTSUP;
return (NULL);
}
assert_no_libc_locks_held();
(void) mutex_lock(&libc_malloc_lock);
ret = _malloc_unlocked(size);
(void) mutex_unlock(&libc_malloc_lock);
return (ret);
}
static void *
_malloc_unlocked(size_t size)
{
size_t n;
TREE *tp, *sp;
size_t o_bit1;
COUNT(nmalloc);
ASSERT(WORDSIZE == ALIGN);
/* check for size that could overflow calculations */
if (size > MAX_MALLOC) {
errno = ENOMEM;
return (NULL);
}
/* make sure that size is 0 mod ALIGN */
ROUND(size);
/* see if the last free block can be used */
if (Lfree) {
sp = BLOCK(Lfree);
n = SIZE(sp);
CLRBITS01(n);
if (n == size) {
/*
* exact match, use it as is
*/
freeidx = (freeidx + FREESIZE - 1) &
FREEMASK; /* 1 back */
flist[freeidx] = Lfree = NULL;
return (DATA(sp));
} else if (size >= MINSIZE && n > size) {
/*
* got a big enough piece
*/
freeidx = (freeidx + FREESIZE - 1) &
FREEMASK; /* 1 back */
flist[freeidx] = Lfree = NULL;
o_bit1 = SIZE(sp) & BIT1;
SIZE(sp) = n;
goto leftover;
}
}
o_bit1 = 0;
/* perform free's of space since last malloc */
cleanfree(NULL);
/* small blocks */
if (size < MINSIZE)
return (_smalloc(size));
/* search for an elt of the right size */
sp = NULL;
n = 0;
if (Root) {
tp = Root;
for (;;) {
/* branch left */
if (SIZE(tp) >= size) {
if (n == 0 || n >= SIZE(tp)) {
sp = tp;
n = SIZE(tp);
}
if (LEFT(tp))
tp = LEFT(tp);
else
break;
} else { /* branch right */
if (RIGHT(tp))
tp = RIGHT(tp);
else
break;
}
}
if (sp) {
t_delete(sp);
} else if (tp != Root) {
/* make the searched-to element the root */
t_splay(tp);
Root = tp;
}
}
/* if found none fitted in the tree */
if (!sp) {
if (Bottom && size <= SIZE(Bottom)) {
sp = Bottom;
CLRBITS01(SIZE(sp));
} else if ((sp = _morecore(size)) == NULL) /* no more memory */
return (NULL);
}
/* tell the forward neighbor that we're busy */
CLRBIT1(SIZE(NEXT(sp)));
ASSERT(ISBIT0(SIZE(NEXT(sp))));
leftover:
/* if the leftover is enough for a new free piece */
if ((n = (SIZE(sp) - size)) >= MINSIZE + WORDSIZE) {
n -= WORDSIZE;
SIZE(sp) = size;
tp = NEXT(sp);
SIZE(tp) = n|BIT0;
realfree(DATA(tp));
} else if (BOTTOM(sp))
Bottom = NULL;
/* return the allocated space */
SIZE(sp) |= BIT0 | o_bit1;
return (DATA(sp));
}
/*
* realloc().
*
* If the block size is increasing, we try forward merging first.
* This is not best-fit but it avoids some data recopying.
*/
void *
realloc(void *old, size_t size)
{
TREE *tp, *np;
size_t ts;
char *new;
if (!primary_link_map) {
errno = ENOTSUP;
return (NULL);
}
assert_no_libc_locks_held();
COUNT(nrealloc);
/* check for size that could overflow calculations */
if (size > MAX_MALLOC) {
errno = ENOMEM;
return (NULL);
}
/* pointer to the block */
(void) mutex_lock(&libc_malloc_lock);
if (old == NULL) {
new = _malloc_unlocked(size);
(void) mutex_unlock(&libc_malloc_lock);
return (new);
}
/* perform free's of space since last malloc */
cleanfree(old);
/* make sure that size is 0 mod ALIGN */
ROUND(size);
tp = BLOCK(old);
ts = SIZE(tp);
/* if the block was freed, data has been destroyed. */
if (!ISBIT0(ts)) {
(void) mutex_unlock(&libc_malloc_lock);
return (NULL);
}
/* nothing to do */
CLRBITS01(SIZE(tp));
if (size == SIZE(tp)) {
SIZE(tp) = ts;
(void) mutex_unlock(&libc_malloc_lock);
return (old);
}
/* special cases involving small blocks */
if (size < MINSIZE || SIZE(tp) < MINSIZE) {
/* free is size is zero */
if (size == 0) {
SETOLD01(SIZE(tp), ts);
_free_unlocked(old);
(void) mutex_unlock(&libc_malloc_lock);
return (NULL);
} else {
goto call_malloc;
}
}
/* block is increasing in size, try merging the next block */
if (size > SIZE(tp)) {
np = NEXT(tp);
if (!ISBIT0(SIZE(np))) {
ASSERT(SIZE(np) >= MINSIZE);
ASSERT(!ISBIT1(SIZE(np)));
SIZE(tp) += SIZE(np) + WORDSIZE;
if (np != Bottom)
t_delete(np);
else
Bottom = NULL;
CLRBIT1(SIZE(NEXT(np)));
}
#ifndef SEGMENTED
/* not enough & at TRUE end of memory, try extending core */
if (size > SIZE(tp) && BOTTOM(tp) && GETCORE(0) == Baddr) {
Bottom = tp;
if ((tp = _morecore(size)) == NULL) {
tp = Bottom;
Bottom = NULL;
}
}
#endif
}
/* got enough space to use */
if (size <= SIZE(tp)) {
size_t n;
chop_big:
if ((n = (SIZE(tp) - size)) >= MINSIZE + WORDSIZE) {
n -= WORDSIZE;
SIZE(tp) = size;
np = NEXT(tp);
SIZE(np) = n|BIT0;
realfree(DATA(np));
} else if (BOTTOM(tp))
Bottom = NULL;
/* the previous block may be free */
SETOLD01(SIZE(tp), ts);
(void) mutex_unlock(&libc_malloc_lock);
return (old);
}
/* call malloc to get a new block */
call_malloc:
SETOLD01(SIZE(tp), ts);
if ((new = _malloc_unlocked(size)) != NULL) {
CLRBITS01(ts);
if (ts > size)
ts = size;
MEMCOPY(new, old, ts);
_free_unlocked(old);
(void) mutex_unlock(&libc_malloc_lock);
return (new);
}
/*
* Attempt special case recovery allocations since malloc() failed:
*
* 1. size <= SIZE(tp) < MINSIZE
* Simply return the existing block
* 2. SIZE(tp) < size < MINSIZE
* malloc() may have failed to allocate the chunk of
* small blocks. Try asking for MINSIZE bytes.
* 3. size < MINSIZE <= SIZE(tp)
* malloc() may have failed as with 2. Change to
* MINSIZE allocation which is taken from the beginning
* of the current block.
* 4. MINSIZE <= SIZE(tp) < size
* If the previous block is free and the combination of
* these two blocks has at least size bytes, then merge
* the two blocks copying the existing contents backwards.
*/
CLRBITS01(SIZE(tp));
if (SIZE(tp) < MINSIZE) {
if (size < SIZE(tp)) { /* case 1. */
SETOLD01(SIZE(tp), ts);
(void) mutex_unlock(&libc_malloc_lock);
return (old);
} else if (size < MINSIZE) { /* case 2. */
size = MINSIZE;
goto call_malloc;
}
} else if (size < MINSIZE) { /* case 3. */
size = MINSIZE;
goto chop_big;
} else if (ISBIT1(ts) &&
(SIZE(np = LAST(tp)) + SIZE(tp) + WORDSIZE) >= size) {
ASSERT(!ISBIT0(SIZE(np)));
t_delete(np);
SIZE(np) += SIZE(tp) + WORDSIZE;
/*
* Since the copy may overlap, use memmove() if available.
* Otherwise, copy by hand.
*/
(void) memmove(DATA(np), old, SIZE(tp));
old = DATA(np);
tp = np;
CLRBIT1(ts);
goto chop_big;
}
SETOLD01(SIZE(tp), ts);
(void) mutex_unlock(&libc_malloc_lock);
return (NULL);
}
/*
* realfree().
*
* Coalescing of adjacent free blocks is done first.
* Then, the new free block is leaf-inserted into the free tree
* without splaying. This strategy does not guarantee the amortized
* O(nlogn) behaviour for the insert/delete/find set of operations
* on the tree. In practice, however, free is much more infrequent
* than malloc/realloc and the tree searches performed by these
* functions adequately keep the tree in balance.
*/
static void
realfree(void *old)
{
TREE *tp, *sp, *np;
size_t ts, size;
COUNT(nfree);
/* pointer to the block */
tp = BLOCK(old);
ts = SIZE(tp);
if (!ISBIT0(ts))
return;
CLRBITS01(SIZE(tp));
/* small block, put it in the right linked list */
if (SIZE(tp) < MINSIZE) {
ASSERT(SIZE(tp) / WORDSIZE >= 1);
ts = SIZE(tp) / WORDSIZE - 1;
AFTER(tp) = List[ts];
List[ts] = tp;
return;
}
/* see if coalescing with next block is warranted */
np = NEXT(tp);
if (!ISBIT0(SIZE(np))) {
if (np != Bottom)
t_delete(np);
SIZE(tp) += SIZE(np) + WORDSIZE;
}
/* the same with the preceding block */
if (ISBIT1(ts)) {
np = LAST(tp);
ASSERT(!ISBIT0(SIZE(np)));
ASSERT(np != Bottom);
t_delete(np);
SIZE(np) += SIZE(tp) + WORDSIZE;
tp = np;
}
/* initialize tree info */
PARENT(tp) = LEFT(tp) = RIGHT(tp) = LINKFOR(tp) = NULL;
/* the last word of the block contains self's address */
*(SELFP(tp)) = tp;
/* set bottom block, or insert in the free tree */
if (BOTTOM(tp))
Bottom = tp;
else {
/* search for the place to insert */
if (Root) {
size = SIZE(tp);
np = Root;
for (;;) {
if (SIZE(np) > size) {
if (LEFT(np))
np = LEFT(np);
else {
LEFT(np) = tp;
PARENT(tp) = np;
break;
}
} else if (SIZE(np) < size) {
if (RIGHT(np))
np = RIGHT(np);
else {
RIGHT(np) = tp;
PARENT(tp) = np;
break;
}
} else {
if ((sp = PARENT(np)) != NULL) {
if (np == LEFT(sp))
LEFT(sp) = tp;
else
RIGHT(sp) = tp;
PARENT(tp) = sp;
} else
Root = tp;
/* insert to head of list */
if ((sp = LEFT(np)) != NULL)
PARENT(sp) = tp;
LEFT(tp) = sp;
if ((sp = RIGHT(np)) != NULL)
PARENT(sp) = tp;
RIGHT(tp) = sp;
/* doubly link list */
LINKFOR(tp) = np;
LINKBAK(np) = tp;
SETNOTREE(np);
break;
}
}
} else
Root = tp;
}
/* tell next block that this one is free */
SETBIT1(SIZE(NEXT(tp)));
ASSERT(ISBIT0(SIZE(NEXT(tp))));
}
/*
* Get more core. Gaps in memory are noted as busy blocks.
*/
static TREE *
_morecore(size_t size)
{
TREE *tp;
ssize_t n, offset;
char *addr;
ssize_t nsize;
/* compute new amount of memory to get */
tp = Bottom;
n = (ssize_t)size + 2 * WORDSIZE;
addr = GETCORE(0);
if (addr == ERRCORE)
return (NULL);
/* need to pad size out so that addr is aligned */
if ((((uintptr_t)addr) % ALIGN) != 0)
offset = ALIGN - (uintptr_t)addr % ALIGN;
else
offset = 0;
#ifndef SEGMENTED
/* if not segmented memory, what we need may be smaller */
if (addr == Baddr) {
n -= WORDSIZE;
if (tp != NULL)
n -= SIZE(tp);
}
#endif
/* get a multiple of CORESIZE */
n = ((n - 1) / CORESIZE + 1) * CORESIZE;
nsize = n + offset;
/* check if nsize request could overflow in GETCORE */
if ((size_t)nsize > MAX_MALLOC - (uintptr_t)addr) {
errno = ENOMEM;
return (NULL);
}
if ((size_t)nsize <= MAX_GETCORE) {
if (GETCORE(nsize) == ERRCORE)
return (NULL);
} else {
intptr_t delta;
/*
* the value required is too big for GETCORE() to deal with
* in one go, so use GETCORE() at most 2 times instead.
* Argument to GETCORE() must be multiple of ALIGN.
* If not, GETCORE(-MAX_GETCORE) will not return brk point
* to previous value, but will be ALIGN more.
* This would leave a small hole.
*/
delta = MAX_GETCORE;
while (delta > 0) {
if (GETCORE(delta) == ERRCORE) {
if (addr != GETCORE(0))
(void) GETCORE(-MAX_GETCORE);
return (NULL);
}
nsize -= MAX_GETCORE;
delta = nsize;
}
}
/* contiguous memory */
if (addr == Baddr) {
ASSERT(offset == 0);
if (tp) {
addr = (char *)tp;
n += SIZE(tp) + 2 * WORDSIZE;
} else {
addr = Baddr - WORDSIZE;
n += WORDSIZE;
}
} else
addr += offset;
/* new bottom address */
Baddr = addr + n;
/* new bottom block */
tp = (TREE *)(uintptr_t)addr;
SIZE(tp) = n - 2 * WORDSIZE;
ASSERT((SIZE(tp) % ALIGN) == 0);
/* reserved the last word to head any noncontiguous memory */
SETBIT0(SIZE(NEXT(tp)));
/* non-contiguous memory, free old bottom block */
if (Bottom && Bottom != tp) {
SETBIT0(SIZE(Bottom));
realfree(DATA(Bottom));
}
return (tp);
}
/*
* Tree rotation functions (BU: bottom-up, TD: top-down)
*/
#define LEFT1(x, y) \
if ((RIGHT(x) = LEFT(y)) != NULL) PARENT(RIGHT(x)) = x;\
if ((PARENT(y) = PARENT(x)) != NULL)\
if (LEFT(PARENT(x)) == x) LEFT(PARENT(y)) = y;\
else RIGHT(PARENT(y)) = y;\
LEFT(y) = x; PARENT(x) = y
#define RIGHT1(x, y) \
if ((LEFT(x) = RIGHT(y)) != NULL) PARENT(LEFT(x)) = x;\
if ((PARENT(y) = PARENT(x)) != NULL)\
if (LEFT(PARENT(x)) == x) LEFT(PARENT(y)) = y;\
else RIGHT(PARENT(y)) = y;\
RIGHT(y) = x; PARENT(x) = y
#define BULEFT2(x, y, z) \
if ((RIGHT(x) = LEFT(y)) != NULL) PARENT(RIGHT(x)) = x;\
if ((RIGHT(y) = LEFT(z)) != NULL) PARENT(RIGHT(y)) = y;\
if ((PARENT(z) = PARENT(x)) != NULL)\
if (LEFT(PARENT(x)) == x) LEFT(PARENT(z)) = z;\
else RIGHT(PARENT(z)) = z;\
LEFT(z) = y; PARENT(y) = z; LEFT(y) = x; PARENT(x) = y
#define BURIGHT2(x, y, z) \
if ((LEFT(x) = RIGHT(y)) != NULL) PARENT(LEFT(x)) = x;\
if ((LEFT(y) = RIGHT(z)) != NULL) PARENT(LEFT(y)) = y;\
if ((PARENT(z) = PARENT(x)) != NULL)\
if (LEFT(PARENT(x)) == x) LEFT(PARENT(z)) = z;\
else RIGHT(PARENT(z)) = z;\
RIGHT(z) = y; PARENT(y) = z; RIGHT(y) = x; PARENT(x) = y
#define TDLEFT2(x, y, z) \
if ((RIGHT(y) = LEFT(z)) != NULL) PARENT(RIGHT(y)) = y;\
if ((PARENT(z) = PARENT(x)) != NULL)\
if (LEFT(PARENT(x)) == x) LEFT(PARENT(z)) = z;\
else RIGHT(PARENT(z)) = z;\
PARENT(x) = z; LEFT(z) = x;
#define TDRIGHT2(x, y, z) \
if ((LEFT(y) = RIGHT(z)) != NULL) PARENT(LEFT(y)) = y;\
if ((PARENT(z) = PARENT(x)) != NULL)\
if (LEFT(PARENT(x)) == x) LEFT(PARENT(z)) = z;\
else RIGHT(PARENT(z)) = z;\
PARENT(x) = z; RIGHT(z) = x;
/*
* Delete a tree element
*/
static void
t_delete(TREE *op)
{
TREE *tp, *sp, *gp;
/* if this is a non-tree node */
if (ISNOTREE(op)) {
tp = LINKBAK(op);
if ((sp = LINKFOR(op)) != NULL)
LINKBAK(sp) = tp;
LINKFOR(tp) = sp;
return;
}
/* make op the root of the tree */
if (PARENT(op))
t_splay(op);
/* if this is the start of a list */
if ((tp = LINKFOR(op)) != NULL) {
PARENT(tp) = NULL;
if ((sp = LEFT(op)) != NULL)
PARENT(sp) = tp;
LEFT(tp) = sp;
if ((sp = RIGHT(op)) != NULL)
PARENT(sp) = tp;
RIGHT(tp) = sp;
Root = tp;
return;
}
/* if op has a non-null left subtree */
if ((tp = LEFT(op)) != NULL) {
PARENT(tp) = NULL;
if (RIGHT(op)) {
/* make the right-end of the left subtree its root */
while ((sp = RIGHT(tp)) != NULL) {
if ((gp = RIGHT(sp)) != NULL) {
TDLEFT2(tp, sp, gp);
tp = gp;
} else {
LEFT1(tp, sp);
tp = sp;
}
}
/* hook the right subtree of op to the above elt */
RIGHT(tp) = RIGHT(op);
PARENT(RIGHT(tp)) = tp;
}
} else if ((tp = RIGHT(op)) != NULL) /* no left subtree */
PARENT(tp) = NULL;
Root = tp;
}
/*
* Bottom up splaying (simple version).
* The basic idea is to roughly cut in half the
* path from Root to tp and make tp the new root.
*/
static void
t_splay(TREE *tp)
{
TREE *pp, *gp;
/* iterate until tp is the root */
while ((pp = PARENT(tp)) != NULL) {
/* grandparent of tp */
gp = PARENT(pp);
/* x is a left child */
if (LEFT(pp) == tp) {
if (gp && LEFT(gp) == pp) {
BURIGHT2(gp, pp, tp);
} else {
RIGHT1(pp, tp);
}
} else {
ASSERT(RIGHT(pp) == tp);
if (gp && RIGHT(gp) == pp) {
BULEFT2(gp, pp, tp);
} else {
LEFT1(pp, tp);
}
}
}
}
/*
* free().
* Performs a delayed free of the block pointed to
* by old. The pointer to old is saved on a list, flist,
* until the next malloc or realloc. At that time, all the
* blocks pointed to in flist are actually freed via
* realfree(). This allows the contents of free blocks to
* remain undisturbed until the next malloc or realloc.
*/
void
free(void *old)
{
if (!primary_link_map) {
errno = ENOTSUP;
return;
}
assert_no_libc_locks_held();
(void) mutex_lock(&libc_malloc_lock);
_free_unlocked(old);
(void) mutex_unlock(&libc_malloc_lock);
}
void
_free_unlocked(void *old)
{
int i;
if (old == NULL)
return;
/*
* Make sure the same data block is not freed twice.
* 3 cases are checked. It returns immediately if either
* one of the conditions is true.
* 1. Last freed.
* 2. Not in use or freed already.
* 3. In the free list.
*/
if (old == Lfree)
return;
if (!ISBIT0(SIZE(BLOCK(old))))
return;
for (i = 0; i < freeidx; i++)
if (old == flist[i])
return;
if (flist[freeidx] != NULL)
realfree(flist[freeidx]);
flist[freeidx] = Lfree = old;
freeidx = (freeidx + 1) & FREEMASK; /* one forward */
}
/*
* cleanfree() frees all the blocks pointed to be flist.
*
* realloc() should work if it is called with a pointer
* to a block that was freed since the last call to malloc() or
* realloc(). If cleanfree() is called from realloc(), ptr
* is set to the old block and that block should not be
* freed since it is actually being reallocated.
*/
static void
cleanfree(void *ptr)
{
char **flp;
flp = (char **)&(flist[freeidx]);
for (;;) {
if (flp == (char **)&(flist[0]))
flp = (char **)&(flist[FREESIZE]);
if (*--flp == NULL)
break;
if (*flp != ptr)
realfree(*flp);
*flp = NULL;
}
freeidx = 0;
Lfree = NULL;
}