2 * This module derived from code donated to the FreeBSD Project by
3 * Matthew Dillon <dillon@backplane.com>
5 * Copyright (c) 1998 The FreeBSD Project
8 * Redistribution and use in source and binary forms, with or without
9 * modification, are permitted provided that the following conditions
11 * 1. Redistributions of source code must retain the above copyright
12 * notice, this list of conditions and the following disclaimer.
13 * 2. Redistributions in binary form must reproduce the above copyright
14 * notice, this list of conditions and the following disclaimer in the
15 * documentation and/or other materials provided with the distribution.
17 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
18 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
19 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
20 * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
21 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
22 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
23 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
24 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
25 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
26 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
29 * $FreeBSD: src/lib/libstand/zalloc.c,v 1.5.2.1 2002/12/28 18:04:15 dillon Exp $
30 * $DragonFly: src/lib/libstand/zalloc.c,v 1.2 2003/06/17 04:26:51 dillon Exp $
34 * LIB/MEMORY/ZALLOC.C - self contained low-overhead memory pool/allocation
37 * This subsystem implements memory pools and memory allocation
40 * Pools are managed via a linked list of 'free' areas. Allocating
41 * memory creates holes in the freelist, freeing memory fills them.
42 * Since the freelist consists only of free memory areas, it is possible
43 * to allocate the entire pool without incuring any structural overhead.
45 * The system works best when allocating similarly-sized chunks of
46 * memory. Care must be taken to avoid fragmentation when
47 * allocating/deallocating dissimilar chunks.
49 * When a memory pool is first allocated, the entire pool is marked as
50 * allocated. This is done mainly because we do not want to modify any
51 * portion of a pool's data area until we are given permission. The
52 * caller must explicitly deallocate portions of the pool to make them
55 * z[n]xalloc() works like z[n]alloc() but the allocation is made from
56 * within the specified address range. If the segment could not be
57 * allocated, NULL is returned. WARNING! The address range will be
58 * aligned to an 8 or 16 byte boundry depending on the cpu so if you
59 * give an unaligned address range, unexpected results may occur.
61 * If a standard allocation fails, the reclaim function will be called
62 * to recover some space. This usually causes other portions of the
63 * same pool to be released. Memory allocations at this low level
64 * should not block but you can do that too in your reclaim function
65 * if you want. Reclaim does not function when z[n]xalloc() is used,
66 * only for z[n]alloc().
68 * Allocation and frees of 0 bytes are valid operations.
71 #include "zalloc_defs.h"
74 * znalloc() - allocate memory (without zeroing) from pool. Call reclaim
75 * and retry if appropriate, return NULL if unable to allocate
80 znalloc(MemPool
*mp
, uintptr_t bytes
)
83 * align according to pool object size (can be 0). This is
84 * inclusive of the MEMNODE_SIZE_MASK minimum alignment.
87 bytes
= (bytes
+ MEMNODE_SIZE_MASK
) & ~MEMNODE_SIZE_MASK
;
93 * locate freelist entry big enough to hold the object. If all objects
94 * are the same size, this is a constant-time function.
97 if (bytes
<= mp
->mp_Size
- mp
->mp_Used
) {
101 for (pmn
= &mp
->mp_First
; (mn
=*pmn
) != NULL
; pmn
= &mn
->mr_Next
) {
102 if (bytes
> mn
->mr_Bytes
)
106 * Cut a chunk of memory out of the beginning of this
107 * block and fixup the link appropriately.
111 char *ptr
= (char *)mn
;
113 if (mn
->mr_Bytes
== bytes
) {
116 mn
= (MemNode
*)((char *)mn
+ bytes
);
117 mn
->mr_Next
= ((MemNode
*)ptr
)->mr_Next
;
118 mn
->mr_Bytes
= ((MemNode
*)ptr
)->mr_Bytes
- bytes
;
121 mp
->mp_Used
+= bytes
;
128 * Memory pool is full, return NULL.
135 * zfree() - free previously allocated memory
139 zfree(MemPool
*mp
, void *ptr
, uintptr_t bytes
)
142 * align according to pool object size (can be 0). This is
143 * inclusive of the MEMNODE_SIZE_MASK minimum alignment.
145 bytes
= (bytes
+ MEMNODE_SIZE_MASK
) & ~MEMNODE_SIZE_MASK
;
151 * panic if illegal pointer
154 if ((char *)ptr
< (char *)mp
->mp_Base
||
155 (char *)ptr
+ bytes
> (char *)mp
->mp_End
||
156 ((uintptr_t)ptr
& MEMNODE_SIZE_MASK
) != 0)
157 panic("zfree(%p,%d): wild pointer", ptr
, bytes
);
167 mp
->mp_Used
-= bytes
;
169 for (pmn
= &mp
->mp_First
; (mn
= *pmn
) != NULL
; pmn
= &mn
->mr_Next
) {
171 * If area between last node and current node
173 * - check merge with next area
174 * - check merge with previous area
176 if ((char *)ptr
<= (char *)mn
) {
180 if ((char *)ptr
+ bytes
> (char *)mn
)
181 panic("zfree(%p,%d): corrupt memlist1",ptr
, bytes
);
184 * merge against next area or create independant area
187 if ((char *)ptr
+ bytes
== (char *)mn
) {
188 ((MemNode
*)ptr
)->mr_Next
= mn
->mr_Next
;
189 ((MemNode
*)ptr
)->mr_Bytes
= bytes
+ mn
->mr_Bytes
;
191 ((MemNode
*)ptr
)->mr_Next
= mn
;
192 ((MemNode
*)ptr
)->mr_Bytes
= bytes
;
194 *pmn
= mn
= (MemNode
*)ptr
;
197 * merge against previous area (if there is a previous
201 if (pmn
!= &mp
->mp_First
) {
202 if ((char*)pmn
+ ((MemNode
*)pmn
)->mr_Bytes
== (char*)ptr
) {
203 ((MemNode
*)pmn
)->mr_Next
= mn
->mr_Next
;
204 ((MemNode
*)pmn
)->mr_Bytes
+= mn
->mr_Bytes
;
211 if ((char *)ptr
< (char *)mn
+ mn
->mr_Bytes
)
212 panic("zfree(%p,%d): corrupt memlist2", ptr
, bytes
);
215 * We are beyond the last MemNode, append new MemNode. Merge against
216 * previous area if possible.
218 if (pmn
== &mp
->mp_First
||
219 (char *)pmn
+ ((MemNode
*)pmn
)->mr_Bytes
!= (char *)ptr
221 ((MemNode
*)ptr
)->mr_Next
= NULL
;
222 ((MemNode
*)ptr
)->mr_Bytes
= bytes
;
223 *pmn
= (MemNode
*)ptr
;
226 ((MemNode
*)pmn
)->mr_Bytes
+= bytes
;
233 * zextendPool() - extend memory pool to cover additional space.
235 * Note: the added memory starts out as allocated, you
236 * must free it to make it available to the memory subsystem.
238 * Note: mp_Size may not reflect (mp_End - mp_Base) range
239 * due to other parts of the system doing their own sbrk()
244 zextendPool(MemPool
*mp
, void *base
, uintptr_t bytes
)
246 if (mp
->mp_Size
== 0) {
249 mp
->mp_End
= (char *)base
+ bytes
;
252 void *pend
= (char *)mp
->mp_Base
+ mp
->mp_Size
;
254 if (base
< mp
->mp_Base
) {
255 mp
->mp_Size
+= (char *)mp
->mp_Base
- (char *)base
;
256 mp
->mp_Used
+= (char *)mp
->mp_Base
- (char *)base
;
259 base
= (char *)base
+ bytes
;
261 mp
->mp_Size
+= (char *)base
- (char *)pend
;
262 mp
->mp_Used
+= (char *)base
- (char *)pend
;
263 mp
->mp_End
= (char *)base
;
271 zallocstats(MemPool
*mp
)
278 printf("%d bytes reserved", (int) mp
->mp_Size
);
282 if ((void *)mn
!= (void *)mp
->mp_Base
) {
283 abytes
+= (char *)mn
- (char *)mp
->mp_Base
;
287 if ((char *)mn
+ mn
->mr_Bytes
!= mp
->mp_End
) {
288 hbytes
+= mn
->mr_Bytes
;
292 abytes
+= (char *)mn
->mr_Next
- ((char *)mn
+ mn
->mr_Bytes
);
295 printf(" %d bytes allocated\n%d fragments (%d bytes fragmented)\n",