From 35d29fcb08fadaf006561a058746b0fce76a6a74 Mon Sep 17 00:00:00 2001 From: Eric Andersen Date: Thu, 18 Jul 2002 15:00:07 +0000 Subject: Miles Bader implemented a new mmap based malloc which is much smarter than the old "malloc-simple", and actually works, unlike the old "malloc". So kill the old "malloc-simple" and the old "malloc" and replace them with Miles' new malloc implementation. Update Config files to match. Thanks Miles! --- libc/stdlib/malloc/malloc.c | 961 +++++--------------------------------------- 1 file changed, 94 insertions(+), 867 deletions(-) (limited to 'libc/stdlib/malloc/malloc.c') diff --git a/libc/stdlib/malloc/malloc.c b/libc/stdlib/malloc/malloc.c index 9a3bbb332..317b10840 100644 --- a/libc/stdlib/malloc/malloc.c +++ b/libc/stdlib/malloc/malloc.c @@ -1,880 +1,107 @@ /* - malloc - heap manager based on heavy use of virtual memory management. - Copyright (C) 1998 Valery Shchedrin - - 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; if not, write to the Free - Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, - MA 02111-1307, USA - - Public Functions: - - void *malloc(size_t size); - - Allocates `size` bytes - returns NULL if no free memory available - - void *calloc(size_t unit, size_t quantity); - - Allocates `quantity*unit` zeroed bytes via internal malloc call - - void *realloc(void *ptr, size_t size); - - Reallocates already allocated block `ptr`, if `ptr` is not valid block - then it works as malloc. NULL is returned if no free memory available - - void *_realloc_no_move(void *ptr, size_t size); - - Reallocates already allocated block `ptr`, if `ptr` is not valid block - or if reallocation can't be done with shrinking/expanding already - allocated block NULL is returned - - void free(void *ptr); - - Frees already allocated block, if `ptr` is incorrect one nothing will - happen. -*/ - -/* - * Manuel Novoa III Jan 2001 + * libc/stdlib/malloc-zarg/malloc.c -- malloc function + * + * Copyright (C) 2002 NEC Corporation + * Copyright (C) 2002 Miles Bader * - * Modified to decrease object sizes. - * Broke into independent object files. - * Converted INIT_BLOCK() and FREE_MEM_DEL_BLOCK() from macros to functions. + * This file is subject to the terms and conditions of the GNU Lesser + * General Public License. See the file COPYING.LIB in the main + * directory of this archive for more details. + * + * Written by Miles Bader */ -#include -#ifndef _XOPEN_SOURCE -#define _XOPEN_SOURCE -#endif -#include -#include -#include -#include -#include -#include +#include #include -#include -#include "malloc.h" -#include - -#define M_DOTRIMMING 1 -#define M_MULTITHREADED 0 - -#define VALLOC_MSTART ((void*)0x1c000000) -#define LARGE_MSTART ((void*)0x19000000) -#define HUNK_MSTART ((void*)0x18000000) -#define HUNK_MSIZE M_PAGESIZE -#define HUNK_ID 0x99171713 - -/* alignment of allocations > HUNK_THRESHOLD */ -#define MALLOC_ALIGN 4 - -/* allocations < HUNK_THRESHOLD will not be aligned */ -#define HUNK_THRESHOLD 4 - -/*up to HUNK_MAXSIZE blocks will be joined together to decrease memory waste*/ -#define HUNK_MAXSIZE 128 - -/* returns value not less than size, aligned to MALLOC_ALIGN */ -#define ALIGN(size) (((size)+(MALLOC_ALIGN)-1)&(~((MALLOC_ALIGN)-1))) - -/* aligns s or p to page boundaries */ -#define PAGE_ALIGN(s) (((s)+M_PAGESIZE-1)&(~(M_PAGESIZE-1))) -#define PAGE_ALIGNP(p) ((char*)PAGE_ALIGN((unsigned)(p))) -#define PAGE_DOWNALIGNP(p) ((char*)(((unsigned)(p))&(~(M_PAGESIZE-1)))) - -/* returns v * 2 for your machine (speed-up) */ -#define MUL2(v) ((v)*2) - -/* does v *= 8 for your machine (speed-up) */ -#define EMUL8(v) v*=8 - -/* does v/8 for your machind (speed-up) */ -#define DIV8(v) ((v)/8) - -#if M_MULTITHREADED -#error This version does not support threads -#else -typedef int mutex_t; - -#define mutex_lock(x) -#define mutex_unlock(x) -#define mutex_init(x) -#define MUTEX_INITIALIZER 0 -//static mutex_t malloc_lock = MUTEX_INITIALIZER; -#endif - -extern int __malloc_initialized; - -#ifdef L__malloc_init -int __malloc_initialized = -1; - - /* -1 == uninitialized, 0 == initializing, 1 == initialized */ -#endif - -#ifndef MAP_FAILED -#define MAP_FAILED ((void*)-1) -#endif - -#if defined(MAP_ANONYMOUS) && !defined(MAP_ANON) -#define MAP_ANON MAP_ANONYMOUS -#endif - -#ifndef NULL -#define NULL ((void*)0) -#endif - -/* guess pagesize */ -#define M_PAGESIZE getpagesize() - -/* HUNK MANAGER */ - -typedef struct Hunk_s Hunk_t; - -struct Hunk_s { /* Hunked block - 8 byte overhead */ - int id; /* unique id */ - unsigned int total:12, used:12, size:8; - Hunk_t *next; /* next free in __free_h */ -}; - -#define usagemap(h) (((unsigned char *)(h))+sizeof(Hunk_t)) -#define hunk_ptr(h) (((char*)(h))+sizeof(Hunk_t)+ALIGN(DIV8(h->total+7))) -#define hunk(h) ((Hunk_t*)(h)) - -extern Hunk_t *__free_h[HUNK_MAXSIZE + 1]; -extern int __total_h[HUNK_MAXSIZE + 1]; - -#ifdef L__malloc_init -Hunk_t *__free_h[HUNK_MAXSIZE + 1]; /* free hash */ -int __total_h[HUNK_MAXSIZE + 1]; /* Hunk_t's `total` member */ -#endif - -extern void *__hunk_alloc(int size); - -#ifdef L_malloc -/* __hunk_alloc allocates <= HUNK_MAXSIZE blocks */ -void *__hunk_alloc(int size) -{ - Hunk_t *p; - unsigned long *cpl; - int i, c; - - // if (size >= HUNK_THRESHOLD) - size = ALIGN(size); - - /* Look for already allocated hunkblocks */ - if ((p = __free_h[size]) == NULL) { - if ( - (p = - (Hunk_t *) mmap(HUNK_MSTART, HUNK_MSIZE, - PROT_READ | PROT_WRITE, -#ifdef __UCLIBC_HAS_MMU__ - MAP_PRIVATE | MAP_ANONYMOUS -#else - MAP_SHARED | MAP_ANONYMOUS -#endif - , 0, 0)) == (Hunk_t *) MAP_FAILED) - // { - // printf("hunk_alloc failed: %d, %d\n", size, errno); - return NULL; - // } - memset(p, 0, HUNK_MSIZE); - p->id = HUNK_ID; - p->total = __total_h[size]; - /* p->used = 0; */ - p->size = size; - /* p->next = (Hunk_t*)NULL; */ - /* memset(usagemap(p), 0, bound); */ - __free_h[size] = p; - } - - /* Locate free point in usagemap */ - - /* First find a word where not all the bits are set */ - for (cpl = (unsigned long *) usagemap(p); *cpl == 0xFFFFFFFF; cpl++); - - /* Remember the byte position of that word */ - i = ((unsigned char *) cpl) - usagemap(p); - - /* Now find find a free bit in the word using binary search */ - if (*(unsigned short *) cpl != 0xFFFF) { - - if (*(unsigned char *) cpl == 0xFF) { - c = *(((unsigned char *) cpl) + 1); - i++; - } - else - { - c = *(unsigned char *) cpl; - } - } else { - i += 2; - c = *(((unsigned char *) cpl) + 2); - if (c == 0xFF) { - c = *(((unsigned char *) cpl) + 3); - i++; - } - } - - /* - * Multiply i by 8 for the bit position - * Further down, we divide by 8 again to find the byte position - */ - EMUL8(i); - - /* If bottom nibble is set, shift down the top nibble */ - if ((c & 0xF) == 0xF) { - c >>= 4; - i += 4; - } - - /* If bottom 2 bits are set, shift down the top two */ - if ((c & 0x3) == 0x3) { - c >>= 2; - i += 2; - } - - /* Check which one of the two bits is set */ - if (c & 1) - i++; - - usagemap(p)[DIV8(i)] |= (1 << (i & 7)); /* set bit */ - /* Increment counter and update hashes */ - if (++p->used == p->total) { - __free_h[p->size] = p->next; - p->next = NULL; - } - - // fprintf(stderr, "hunk_alloc: i=%d, p->size=%d, p=%p\n", i, p->size, p); - return hunk_ptr(p) + i * p->size; -} -#endif /* L_malloc */ - -extern void __hunk_free(char *ptr); - -#ifdef L__free_support -/* __hunk_free frees blocks allocated by __hunk_alloc */ -void __hunk_free(char *ptr) -{ - unsigned char *up; - int i, v; - Hunk_t *h; - - if (!ptr) - return; - - h = (Hunk_t *) PAGE_DOWNALIGNP(ptr); - - /* Validate `ptr` */ - if (h->id != HUNK_ID) - return; - v = ptr - hunk_ptr(h); - i = v / h->size; - if (v % h->size != 0 || i < 0 || i >= h->total) - return; - - /* Update `usagemap` */ - up = &(usagemap(h)[DIV8(i)]); - i = 1 << (i & 7); - if (!(*up & i)) - return; - *up ^= i; - - /* Update hunk counters */ - if (h->used == h->total) { - if (--h->used) { /* insert into __free_h */ - h->next = __free_h[h->size]; - __free_h[h->size] = h; - } /* else - it will be unmapped */ - } else { - if (!--h->used) { /* delete from __free_h - will be __bl_freed */ - Hunk_t *p, *pp; - - for (p = __free_h[h->size], pp = NULL; p != h; - pp = p, p = p->next); - if (!pp) - __free_h[h->size] = p->next; - else - pp->next = p->next; - } - } - - /* Unmap empty Hunk_t */ - if (!h->used) - munmap((void *) h, HUNK_MSIZE); -} -#endif /* L__free_support */ - -/* BLOCK MANAGER */ - -typedef struct Block_s Block_t; - -struct Block_s { /* 32-bytes long control structure (if 4-byte aligned) */ - char *ptr; /* pointer to related data */ - Block_t *next; /* next in free_mem list */ - Block_t *l_free_mem, *r_free_mem; /* left & right subtrees of */ - Block_t *l_ptrs, *r_ptrs; /* left & right subtrees of */ - size_t size; /* size - divided by align */ - - /* packed 4-byte attributes */ -/* { */ - signed char bal_free_mem:8; /* balance of subtree */ - signed char bal_ptrs:8; /* balance of subtree */ - unsigned int used:1; /* used/free state of the block */ - unsigned int broken:1; /* 1 if previous block can't be merged with it */ -/* } */ -}; - -extern Block_t *__bl_last; /* last mmapped block */ - -#ifdef L__malloc_init -Block_t *__bl_last; /* last mmapped block */ -#endif - -#define bl_get() __hunk_alloc(sizeof(Block_t)) -#define bl_rel(p) __hunk_free((char*)p) - -extern Block_t *__Avl_Block_tfree_mem_tree; -extern Block_t *__free_mem_ins(Block_t * data); -extern void __free_mem_del(Block_t * data); -extern void __free_mem_replace(Block_t * data); -extern Block_t *__Avl_Block_tptrs_tree; -extern Block_t *__ptrs_ins(Block_t * data); -extern void __ptrs_del(Block_t * data); - -extern void __bl_uncommit(Block_t * b); -extern void __bl_free(Block_t * b); - -/* like C++ templates ;-) */ -#include "avlmacro.h" - -#define FREE_MEM_COMPARE(i,a,b) \ -{ \ - if ( (a)->size < (b)->size ) { \ - i = -1; \ - } else if ( (a)->size > (b)->size ) { \ - i = 1; \ - } else { \ - i = 0; \ - } \ -} - -#define PTRS_COMPARE(i,a,b) \ -{ \ - if ( (a)->ptr < (b)->ptr ) { \ - i = -1; \ - } else if ( (a)->ptr > (b)->ptr ) { \ - i = 1; \ - } else { \ - i = 0; \ - } \ -} - -#ifdef L__avl_support -Avl_Tree(free_mem, Block_t, free_mem, FREE_MEM_COMPARE) - Avl_Tree_no_replace(ptrs, Block_t, ptrs, PTRS_COMPARE) -#endif -#define free_mem_root Avl_Root(Block_t, free_mem) -#define ptrs_root Avl_Root(Block_t, ptrs) -/* pp is freed block */ -#define FREE_MEM_DEL_BLOCK(pp,p) {p = __free_mem_del_block(pp,p);} -extern Block_t *__free_mem_del_block(Block_t * pp, Block_t * p); - -#ifdef L_malloc -Block_t *__free_mem_del_block(Block_t * pp, Block_t * p) -{ - for (p = free_mem_root;;) - if (p->size > pp->size) - p = p->l_free_mem; - else if (p->size < pp->size) - p = p->r_free_mem; - else - break; - if (p == pp) { - if (pp->next) - __free_mem_replace(pp->next); - else - __free_mem_del(pp); - } else { - for (; p->next != pp; p = p->next); - p->next = pp->next; - } - return p; -} -#endif /* L_malloc */ - -#define FREE_MEM_INS_BLOCK(pp) \ -{ \ - if ((p = __free_mem_ins(pp)) != NULL)\ - {\ - pp->next = p->next;\ - p->next = pp;\ - }\ - else pp->next = NULL; \ -} - -/* `b` is current block, `pp` is next block */ -#define COMBINE_BLOCKS(b,pp) \ -{\ - __ptrs_del(pp); \ - b->size += pp->size; \ - if (pp == __bl_last) __bl_last = b; \ - bl_rel(pp); \ -} - -/* initializes new block b */ -#define INIT_BLOCK(b, pppp, sz) { p = __init_block(b, pppp, sz); } - -extern Block_t *__init_block(Block_t * b, char *pppp, size_t sz); - -#ifdef L_malloc -Block_t *__init_block(Block_t * b, char *pppp, size_t sz) -{ - Block_t *p; - - memset(b, 0, sizeof(Block_t)); - b->ptr = pppp; - b->size = sz; - __ptrs_ins(b); - FREE_MEM_INS_BLOCK(b); - return p; -} -#endif /* L_malloc */ - -/* `b` is current block, `sz` its new size */ -/* block `b` will be splitted to one busy & one free block */ -#define SPLIT_BLOCK(b,sz) \ -{\ - Block_t *bt; \ - bt = bl_get(); \ - INIT_BLOCK(bt, b->ptr + sz, b->size - sz); \ - b->size = sz; \ - if (__bl_last == b) __bl_last = bt; \ - __bl_uncommit(bt);\ -} - -/* `b` is current block, `pp` is next free block, `sz` is needed size */ -#define SHRINK_BLOCK(b,pp,sz) \ -{\ - FREE_MEM_DEL_BLOCK(pp,p); \ - pp->ptr = b->ptr + sz; \ - pp->size += b->size - sz; \ - b->size = sz; \ - FREE_MEM_INS_BLOCK(pp); \ - __bl_uncommit(pp); \ -} - -#ifdef L_malloc -static Block_t *bl_mapnew(size_t size) -{ - size_t map_size; - Block_t *pp, *p; - void *pt; - - map_size = PAGE_ALIGN(size); - pt = mmap(LARGE_MSTART, map_size, PROT_READ | PROT_WRITE | PROT_EXEC, -#ifdef __UCLIBC_HAS_MMU__ - MAP_PRIVATE | MAP_ANONYMOUS -#else - MAP_SHARED | MAP_ANONYMOUS -#endif - , 0, 0); - - if (pt == MAP_FAILED) - return (Block_t *) NULL; - - __bl_last = pp = bl_get(); - INIT_BLOCK(pp, (char *) pt, map_size); - pp->broken = 1; - - return pp; -} - -void __bl_uncommit(Block_t * b) -{ - char *u_start, *u_end; - - u_start = PAGE_ALIGNP(b->ptr); - u_end = PAGE_DOWNALIGNP(b->ptr + b->size); - if (u_end <= u_start) - return; - -#if M_DOTRIMMING - mmap(u_start, u_end - u_start, PROT_READ | PROT_WRITE | PROT_EXEC, -#ifdef __UCLIBC_HAS_MMU__ - MAP_PRIVATE | MAP_ANONYMOUS |MAP_FIXED -#else - MAP_SHARED | MAP_ANONYMOUS |MAP_FIXED -#endif - , 0, 0); -#endif -} - -/* requested size must be aligned to ALIGNMENT */ -static Block_t *bl_alloc(size_t size) -{ - Block_t *p, *pp; - - /* try to find needed space in existing memory */ - for (p = free_mem_root, pp = NULL; p;) { - if (p->size > size) { - pp = p; - p = p->l_free_mem; - } else if (p->size < size) - p = p->r_free_mem; - else { - pp = p; - break; - } - } - - if (!pp) { /* map some memory */ - if (!__bl_last) { /* just do initial mmap */ - pp = bl_mapnew(size); - if (!pp) - return NULL; - } else if (!__bl_last->used) { /* try growing last unused */ - if (mremap(PAGE_DOWNALIGNP(__bl_last->ptr), - PAGE_ALIGNP(__bl_last->ptr + __bl_last->size) - - PAGE_DOWNALIGNP(__bl_last->ptr), - PAGE_ALIGNP(__bl_last->ptr + size) - - PAGE_DOWNALIGNP(__bl_last->ptr), 0) == MAP_FAILED) { /* unable to grow -- initiate new block */ - pp = bl_mapnew(size); - if (!pp) - return NULL; - } else { - pp = __bl_last; - FREE_MEM_DEL_BLOCK(pp, p); - pp->size = PAGE_ALIGNP(pp->ptr + size) - pp->ptr; - FREE_MEM_INS_BLOCK(pp); - } - } else { /* __bl_last is used block */ - if (mremap(PAGE_DOWNALIGNP(__bl_last->ptr), - PAGE_ALIGNP(__bl_last->ptr + __bl_last->size) - - PAGE_DOWNALIGNP(__bl_last->ptr), - PAGE_ALIGNP(__bl_last->ptr + __bl_last->size + - size) - PAGE_DOWNALIGNP(__bl_last->ptr), - 0) == MAP_FAILED) { - pp = bl_mapnew(size); - if (!pp) - return NULL; - } else { - pp = bl_get(); - INIT_BLOCK(pp, __bl_last->ptr + __bl_last->size, - PAGE_ALIGNP(__bl_last->ptr + __bl_last->size + - size) - __bl_last->ptr - - __bl_last->size); - __bl_last = pp; - } - } - } - - /* just delete this node from free_mem tree */ - if (pp->next) - __free_mem_replace(pp->next); - else - __free_mem_del(pp); - pp->used = 1; - - if (pp->size - size > MALLOC_ALIGN) { /* this block can be splitted (it is unused,not_broken) */ - SPLIT_BLOCK(pp, size); - } - - return pp; -} -#endif /* L_malloc */ - -#ifdef L__free_support -void __bl_free(Block_t * b) -{ - Block_t *p, *bl_next, *bl_prev; - - /* Look for blocks before & after `b` */ - for (p = ptrs_root, bl_next = NULL, bl_prev = NULL; p;) { - if (p->ptr > b->ptr) { - bl_next = p; - p = p->l_ptrs; - } else if (p->ptr < b->ptr) { - bl_prev = p; - p = p->r_ptrs; - } else - break; - } - if (b->l_ptrs) - for (bl_prev = b->l_ptrs; bl_prev->r_ptrs; - bl_prev = bl_prev->r_ptrs); - if (b->r_ptrs) - for (bl_next = b->r_ptrs; bl_next->l_ptrs; - bl_next = bl_next->l_ptrs); - - if (bl_next && !bl_next->broken && !bl_next->used) { - FREE_MEM_DEL_BLOCK(bl_next, p) - COMBINE_BLOCKS(b, bl_next) - } - - if (bl_prev && !b->broken && !bl_prev->used) { - FREE_MEM_DEL_BLOCK(bl_prev, p) - COMBINE_BLOCKS(bl_prev, b) - b = bl_prev; - } - - b->used = 0; - FREE_MEM_INS_BLOCK(b) - __bl_uncommit(b); -} -#endif /* L__free_support */ - -extern void __malloc_init(void); - -#ifdef L__malloc_init -void __malloc_init(void) -{ - int i, mapsize, x, old_x, gcount; - - mapsize = M_PAGESIZE; - - __malloc_initialized = 0; - __bl_last = NULL; - free_mem_root = NULL; - ptrs_root = NULL; - mapsize -= sizeof(Hunk_t); - for (i = 1; i <= HUNK_MAXSIZE; i++) { - __free_h[i] = (Hunk_t *) NULL; - for (x = mapsize / i, gcount = 0, old_x = 0; old_x != x;) { - old_x = x; - x = (mapsize - ALIGN(DIV8(old_x + 7))) / i; - if (gcount > 1 && x * i + ALIGN(DIV8(x + 7)) <= mapsize) - break; - if (x * i + ALIGN(DIV8(x + 7)) > mapsize) - gcount++; - } - __total_h[i] = x; - } - mutex_init(&malloc_lock); - __malloc_initialized = 1; - // fprintf(stderr, "malloc_init: hunk_t=%d\n", sizeof(Hunk_t)); -} -#endif /* L__malloc_init */ - -#ifdef L_malloc -void *malloc(size_t size) -{ - void *p; - - if (size == 0) - return NULL; - - if (__malloc_initialized < 0) - __malloc_init(); - if (__malloc_initialized) - mutex_lock(&malloc_lock); - - if (size <= HUNK_MAXSIZE) - p = __hunk_alloc(size); - else { - if ((p = bl_alloc(ALIGN(size))) != NULL) - p = ((Block_t *) p)->ptr; - } - - if (__malloc_initialized) - mutex_unlock(&malloc_lock); - - // fprintf(stderr, "malloc returning: s=%d, p=%p\n", size, p); - return p; -} -#endif /* L_malloc */ - -#ifdef L_free -void free(void *ptr) -{ - Block_t *p, *best; - - if (__malloc_initialized < 0) - return; - if (__malloc_initialized) - mutex_lock(&malloc_lock); - - for (p = ptrs_root, best = NULL; p;) { - if (p->ptr > (char *) ptr) - p = p->l_ptrs; - else { - best = p; - p = p->r_ptrs; - } - } - - if (!best || !best->used || best->ptr != (char *) ptr) { - __hunk_free(ptr); - if (__malloc_initialized) - mutex_unlock(&malloc_lock); - return; - } - - __bl_free(best); - - if (__malloc_initialized) - mutex_unlock(&malloc_lock); -} -#endif /* L_free */ - -extern void *_realloc_no_move(void *ptr, size_t size); - -#ifdef L__realloc_no_move -void *_realloc_no_move(void *ptr, size_t size) -{ - Block_t *p, *best, *next; - - if (size <= HUNK_MAXSIZE) - return NULL; - - if (__malloc_initialized <= 0) - return malloc(size); - - mutex_lock(&malloc_lock); - - /* Locate block */ - for (p = ptrs_root, best = NULL; p;) { - if (p->ptr > (char *) ptr) - p = p->l_ptrs; - else { - best = p; - p = p->r_ptrs; - } - } - - if (!best || !best->used || best->ptr != (char *) ptr) { - mutex_unlock(&malloc_lock); - return NULL; - } - - size = ALIGN(size); - - if (size == best->size) { - mutex_unlock(&malloc_lock); - return ptr; - } - - if (best->r_ptrs) /* get block just after */ - for (next = best->r_ptrs; next->l_ptrs; next = next->l_ptrs); - else - for (p = ptrs_root, next = NULL; p;) { - if (p->ptr > best->ptr) { - next = p; - p = p->l_ptrs; - } else if (p->ptr < best->ptr) - p = p->r_ptrs; - else - break; - } - - if (size < best->size) { /* shrink block */ - if (!next || next->used || next->broken) { - if (best->size - size > MALLOC_ALIGN) { /* do split */ - SPLIT_BLOCK(best, size); - } - } else { /* just move border of next block */ - SHRINK_BLOCK(best, next, size); - } - } else if (next && !next->broken && !next->used) { /* can expand */ - if (best->size + next->size > size + HUNK_MAXSIZE) { /* shrink next free block */ - SHRINK_BLOCK(best, next, size); - } else if (best->size + next->size >= size) { /* combine blocks (eat next one) */ - FREE_MEM_DEL_BLOCK(next, p); - COMBINE_BLOCKS(best, next); - } else { /* not enough memory in next block */ - mutex_unlock(&malloc_lock); - return NULL; - } - } else { /* no next block */ - mutex_unlock(&malloc_lock); - return NULL; - } - mutex_unlock(&malloc_lock); - return best->ptr; -} -#endif /* L__realloc_no_move */ - -#ifdef L_realloc -void *realloc(void *ptr, size_t size) -{ - void *tmp; - - tmp = _realloc_no_move(ptr, size); - - if (!tmp) { - Block_t *p, *best; - - mutex_lock(&malloc_lock); - - for (p = ptrs_root, best = NULL; p;) { - if (p->ptr > (char *) ptr) - p = p->l_ptrs; - else { - best = p; - p = p->r_ptrs; - } - } - - if (!best || !best->used || best->ptr != (char *) ptr) { - if (ptr) { - Hunk_t *h; +#include "malloc.h" +#include "heap.h" - h = (Hunk_t *) PAGE_DOWNALIGNP(ptr); - if (h->id == HUNK_ID) { - mutex_unlock(&malloc_lock); - if ((size >= HUNK_THRESHOLD && ALIGN(size) == h->size) - || size == h->size) - return ptr; - if ((tmp = malloc(size)) == NULL) - return NULL; - mutex_lock(&malloc_lock); - memcpy(tmp, ptr, ((size < h->size) ? size : h->size)); - __hunk_free(ptr); - mutex_unlock(&malloc_lock); - return tmp; - } - } - mutex_unlock(&malloc_lock); - return malloc(size); - } - mutex_unlock(&malloc_lock); +/* When we give memory to the heap, start this many bytes after the + beginning of the mmaped block. This is because we must ensure that + malloc return values are aligned to MALLOC_ALIGNMENT, but since we need + to use one word _before_ the beginning of that, we actually want the heap + to return values that are MALLOC_ALIGNMENT aligned - sizeof (size_t). + Since the heap always allocates in multiples of HEAP_GRANULARITY, we can + do this by (1) ensuring that HEAP_GRANULARITY is a multiple of + MALLOC_ALIGNMENT, and (2) making sure that the heap's free areas start + sizeof(size_t) bytes before our required alignment. */ +#define MALLOC_HEAP_BLOCK_SHIM (MALLOC_ALIGNMENT - sizeof (size_t)) - /* copy whole block */ - if ((tmp = malloc(size)) == NULL) - return NULL; - memcpy(tmp, ptr, ((size < best->size) ? size : best->size)); - mutex_lock(&malloc_lock); - __bl_free(best); - mutex_unlock(&malloc_lock); - } - return tmp; -} -#endif /* L_realloc */ +/* The heap used for small allocations. */ +struct heap __malloc_heap = HEAP_INIT; -#ifdef L_calloc -void *calloc(size_t unit, size_t quantity) + +void *malloc (size_t size) { - void *p; - - unit *= quantity; - - if ((p = malloc(unit)) == NULL) - return NULL; - memset(p, 0, unit); - return p; + void *mem; + + MALLOC_DEBUG ("malloc: %d bytes\n", size); + + /* Include an extra word to record the size of the allocated block. */ + size += sizeof (size_t); + + if (size >= MALLOC_MMAP_THRESHOLD) + /* Use mmap for large allocations. */ + { + /* Make sure we request enough memory to align the result correctly, + and that SIZE reflects that mmap hands back whole pages. */ + size += MALLOC_ROUND_UP_TO_PAGE_SIZE (MALLOC_ALIGNMENT - sizeof(size_t)); + + mem = mmap (0, size, PROT_READ | PROT_WRITE, + MAP_SHARED | MAP_ANONYMOUS, 0, 0); + if (mem == MAP_FAILED) + return 0; + } + else + /* Use the heap for small allocations. */ + { + mem = __heap_alloc (&__malloc_heap, &size); + + if (! mem) + /* We couldn't allocate from the heap, so get some more memory + from the system, add it to the heap, and try again. */ + { + /* If we're trying to allocate a block bigger than the default + MALLOC_HEAP_EXTEND_SIZE, make sure we get enough to hold it. */ + size_t block_size = (size < MALLOC_HEAP_EXTEND_SIZE + ? MALLOC_HEAP_EXTEND_SIZE + : MALLOC_ROUND_UP_TO_PAGE_SIZE (size)); + /* Allocate the new heap block. */ + void *block = mmap (0, block_size, + PROT_READ | PROT_WRITE, + MAP_SHARED | MAP_ANONYMOUS, 0, 0); + + if (block != MAP_FAILED) + { + /* Put BLOCK into the heap. We first try to append BLOCK to + an existing free area, which is more efficient because it + doesn't require using a `shim' at the beginning (which + would prevent merging free-areas); since mmap often returns + contiguous areas, this is worth it. */ + if (! __heap_append_free (&__malloc_heap, block, block_size)) + /* Couldn't append, just add BLOCK as a new free-area. */ + __heap_free (&__malloc_heap, + block + MALLOC_HEAP_BLOCK_SHIM, + block_size - MALLOC_HEAP_BLOCK_SHIM); + + /* Try again to allocate. */ + mem = __heap_alloc (&__malloc_heap, &size); + } + } + } + + if (mem) + /* Record the size of this block just before the returned address. */ + { + *(size_t *)mem = size; + mem = (size_t *)mem + 1; + + MALLOC_DEBUG (" malloc: returning 0x%lx (base:0x%lx, total_size:%d)\n", + (long)mem, (long)mem - sizeof (size_t), size); + } + + return mem; } -#endif /* L_calloc */ -- cgit v1.2.3