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Last change on this file since 7aafdb86 was 7aafdb86, checked in by Jakub Jermar <jakub@…>, 13 years ago

When growing heap to satisfy an allocation request of s bytes aligned to
an a-byte boundary, the heap needs to be grown by at least a + s bytes.

When growing heap, try the subsequent allocation on the area which has
been grown to avoid unnecessary search of a suitable area.

(Thanks to Jiri Zarevucky.)

Property mode set to 100644

File size: 24.6 KB

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1	/*
2	* Copyright (c) 2009 Martin Decky
3	* Copyright (c) 2009 Petr Tuma
4	* All rights reserved.
5	*
6	* Redistribution and use in source and binary forms, with or without
7	* modification, are permitted provided that the following conditions
8	* are met:
9	*
10	* - Redistributions of source code must retain the above copyright
11	* notice, this list of conditions and the following disclaimer.
12	* - Redistributions in binary form must reproduce the above copyright
13	* notice, this list of conditions and the following disclaimer in the
14	* documentation and/or other materials provided with the distribution.
15	* - The name of the author may not be used to endorse or promote products
16	* derived from this software without specific prior written permission.
17	*
18	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
19	* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
20	* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
21	* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
22	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
23	* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
24	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
25	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
26	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
27	* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
28	*/
29
30	/** @addtogroup libc
31	* @{
32	*/
33	/** @file
34	*/
35
36	#include <malloc.h>
37	#include <bool.h>
38	#include <as.h>
39	#include <align.h>
40	#include <macros.h>
41	#include <assert.h>
42	#include <errno.h>
43	#include <bitops.h>
44	#include <mem.h>
45	#include <futex.h>
46	#include <stdlib.h>
47	#include <adt/gcdlcm.h>
48	#include "private/malloc.h"
49
50	/** Magic used in heap headers. */
51	#define HEAP_BLOCK_HEAD_MAGIC UINT32_C(0xBEEF0101)
52
53	/** Magic used in heap footers. */
54	#define HEAP_BLOCK_FOOT_MAGIC UINT32_C(0xBEEF0202)
55
56	/** Magic used in heap descriptor. */
57	#define HEAP_AREA_MAGIC UINT32_C(0xBEEFCAFE)
58
59	/** Allocation alignment.
60	*
61	* This also covers the alignment of fields
62	* in the heap header and footer.
63	*
64	*/
65	#define BASE_ALIGN 16
66
67	/** Heap shrink granularity
68	*
69	* Try not to pump and stress the heap to much
70	* by shrinking and enlarging it too often.
71	* A heap area won't shrunk if it the released
72	* free block is smaller than this constant.
73	*
74	*/
75	#define SHRINK_GRANULARITY (64 * PAGE_SIZE)
76
77	/** Overhead of each heap block. */
78	#define STRUCT_OVERHEAD \
79	(sizeof(heap_block_head_t) + sizeof(heap_block_foot_t))
80
81	/** Overhead of each area. */
82	#define AREA_OVERHEAD(size) \
83	(ALIGN_UP(size + sizeof(heap_area_t), BASE_ALIGN))
84
85	/** Calculate real size of a heap block.
86	*
87	* Add header and footer size.
88	*
89	*/
90	#define GROSS_SIZE(size) ((size) + STRUCT_OVERHEAD)
91
92	/** Calculate net size of a heap block.
93	*
94	* Subtract header and footer size.
95	*
96	*/
97	#define NET_SIZE(size) ((size) - STRUCT_OVERHEAD)
98
99	/** Get first block in heap area.
100	*
101	*/
102	#define AREA_FIRST_BLOCK_HEAD(area) \
103	(ALIGN_UP(((uintptr_t) (area)) + sizeof(heap_area_t), BASE_ALIGN))
104
105	/** Get last block in heap area.
106	*
107	*/
108	#define AREA_LAST_BLOCK_FOOT(area) \
109	(((uintptr_t) (area)->end) - sizeof(heap_block_foot_t))
110
111	#define AREA_LAST_BLOCK_HEAD(area) \
112	((uintptr_t) BLOCK_HEAD(((heap_block_foot_t *)AREA_LAST_BLOCK_FOOT(area))))
113
114	/** Get header in heap block.
115	*
116	*/
117	#define BLOCK_HEAD(foot) \
118	((heap_block_head_t *) \
119	(((uintptr_t) (foot)) + sizeof(heap_block_foot_t) - (foot)->size))
120
121	/** Get footer in heap block.
122	*
123	*/
124	#define BLOCK_FOOT(head) \
125	((heap_block_foot_t *) \
126	(((uintptr_t) (head)) + (head)->size - sizeof(heap_block_foot_t)))
127
128	/** Heap area.
129	*
130	* The memory managed by the heap allocator is divided into
131	* multiple discontinuous heaps. Each heap is represented
132	* by a separate address space area which has this structure
133	* at its very beginning.
134	*
135	*/
136	typedef struct heap_area {
137	/** Start of the heap area (including this structure)
138	*
139	* Aligned on page boundary.
140	*
141	*/
142	void *start;
143
144	/** End of the heap area (aligned on page boundary) */
145	void *end;
146
147	/** Previous heap area */
148	struct heap_area *prev;
149
150	/** Next heap area */
151	struct heap_area *next;
152
153	/** A magic value */
154	uint32_t magic;
155	} heap_area_t;
156
157	/** Header of a heap block
158	*
159	*/
160	typedef struct {
161	/* Size of the block (including header and footer) */
162	size_t size;
163
164	/* Indication of a free block */
165	bool free;
166
167	/** Heap area this block belongs to */
168	heap_area_t *area;
169
170	/* A magic value to detect overwrite of heap header */
171	uint32_t magic;
172	} heap_block_head_t;
173
174	/** Footer of a heap block
175	*
176	*/
177	typedef struct {
178	/* Size of the block (including header and footer) */
179	size_t size;
180
181	/* A magic value to detect overwrite of heap footer */
182	uint32_t magic;
183	} heap_block_foot_t;
184
185	/** First heap area */
186	static heap_area_t *first_heap_area = NULL;
187
188	/** Last heap area */
189	static heap_area_t *last_heap_area = NULL;
190
191	/** Next heap block to examine (next fit algorithm) */
192	static heap_block_head_t *next_fit = NULL;
193
194	/** Futex for thread-safe heap manipulation */
195	static futex_t malloc_futex = FUTEX_INITIALIZER;
196
197	#ifndef NDEBUG
198
199	#define malloc_assert(expr) \
200	do { \
201	if (!(expr)) {\
202	futex_up(&malloc_futex); \
203	assert_abort(#expr, __FILE__, __LINE__); \
204	} \
205	} while (0)
206
207	#else /* NDEBUG */
208
209	#define malloc_assert(expr)
210
211	#endif /* NDEBUG */
212
213	/** Initialize a heap block
214	*
215	* Fill in the structures related to a heap block.
216	* Should be called only inside the critical section.
217	*
218	* @param addr Address of the block.
219	* @param size Size of the block including the header and the footer.
220	* @param free Indication of a free block.
221	* @param area Heap area the block belongs to.
222	*
223	*/
224	static void block_init(void addr, size_t size, bool free, heap_area_t area)
225	{
226	/* Calculate the position of the header and the footer */
227	heap_block_head_t head = (heap_block_head_t ) addr;
228
229	head->size = size;
230	head->free = free;
231	head->area = area;
232	head->magic = HEAP_BLOCK_HEAD_MAGIC;
233
234	heap_block_foot_t *foot = BLOCK_FOOT(head);
235
236	foot->size = size;
237	foot->magic = HEAP_BLOCK_FOOT_MAGIC;
238	}
239
240	/** Check a heap block
241	*
242	* Verifies that the structures related to a heap block still contain
243	* the magic constants. This helps detect heap corruption early on.
244	* Should be called only inside the critical section.
245	*
246	* @param addr Address of the block.
247	*
248	*/
249	static void block_check(void *addr)
250	{
251	heap_block_head_t head = (heap_block_head_t ) addr;
252
253	malloc_assert(head->magic == HEAP_BLOCK_HEAD_MAGIC);
254
255	heap_block_foot_t *foot = BLOCK_FOOT(head);
256
257	malloc_assert(foot->magic == HEAP_BLOCK_FOOT_MAGIC);
258	malloc_assert(head->size == foot->size);
259	}
260
261	/** Check a heap area structure
262	*
263	* Should be called only inside the critical section.
264	*
265	* @param addr Address of the heap area.
266	*
267	*/
268	static void area_check(void *addr)
269	{
270	heap_area_t area = (heap_area_t ) addr;
271
272	malloc_assert(area->magic == HEAP_AREA_MAGIC);
273	malloc_assert(addr == area->start);
274	malloc_assert(area->start < area->end);
275	malloc_assert(((uintptr_t) area->start % PAGE_SIZE) == 0);
276	malloc_assert(((uintptr_t) area->end % PAGE_SIZE) == 0);
277	}
278
279	/** Create new heap area
280	*
281	* Should be called only inside the critical section.
282	*
283	* @param size Size of the area.
284	*
285	*/
286	static bool area_create(size_t size)
287	{
288	/* Align the heap area size on page boundary */
289	size_t asize = ALIGN_UP(size, PAGE_SIZE);
290	void *astart = as_area_create(AS_AREA_ANY, asize,
291	AS_AREA_WRITE \| AS_AREA_READ);
292	if (astart == AS_MAP_FAILED)
293	return false;
294
295	heap_area_t area = (heap_area_t ) astart;
296
297	area->start = astart;
298	area->end = (void *) ((uintptr_t) astart + asize);
299	area->prev = NULL;
300	area->next = NULL;
301	area->magic = HEAP_AREA_MAGIC;
302
303	void block = (void ) AREA_FIRST_BLOCK_HEAD(area);
304	size_t bsize = (size_t) (area->end - block);
305
306	block_init(block, bsize, true, area);
307
308	if (last_heap_area == NULL) {
309	first_heap_area = area;
310	last_heap_area = area;
311	} else {
312	area->prev = last_heap_area;
313	last_heap_area->next = area;
314	last_heap_area = area;
315	}
316
317	return true;
318	}
319
320	/** Try to enlarge a heap area
321	*
322	* Should be called only inside the critical section.
323	*
324	* @param area Heap area to grow.
325	* @param size Gross size to grow (bytes).
326	*
327	* @return True if successful.
328	*
329	*/
330	static bool area_grow(heap_area_t *area, size_t size)
331	{
332	if (size == 0)
333	return true;
334
335	area_check(area);
336
337	/* New heap area size */
338	size_t gross_size = (size_t) (area->end - area->start) + size;
339	size_t asize = ALIGN_UP(gross_size, PAGE_SIZE);
340	void end = (void ) ((uintptr_t) area->start + asize);
341
342	/* Check for overflow */
343	if (end < area->start)
344	return false;
345
346	/* Resize the address space area */
347	int ret = as_area_resize(area->start, asize, 0);
348	if (ret != EOK)
349	return false;
350
351	heap_block_head_t last_head = (heap_block_head_t ) AREA_LAST_BLOCK_HEAD(area);
352
353	if (last_head->free) {
354	/* Add the new space to the last block. */
355	size_t net_size = (size_t) (end - area->end) + last_head->size;
356	malloc_assert(net_size > 0);
357	block_init(last_head, net_size, true, area);
358	} else {
359	/* Add new free block */
360	size_t net_size = (size_t) (end - area->end);
361	if (net_size > 0)
362	block_init(area->end, net_size, true, area);
363	}
364
365	/* Update heap area parameters */
366	area->end = end;
367
368	return true;
369	}
370
371	/** Try to shrink heap
372	*
373	* Should be called only inside the critical section.
374	* In all cases the next pointer is reset.
375	*
376	* @param area Last modified heap area.
377	*
378	*/
379	static void heap_shrink(heap_area_t *area)
380	{
381	area_check(area);
382
383	heap_block_foot_t *last_foot =
384	(heap_block_foot_t *) AREA_LAST_BLOCK_FOOT(area);
385	heap_block_head_t *last_head = BLOCK_HEAD(last_foot);
386
387	block_check((void *) last_head);
388	malloc_assert(last_head->area == area);
389
390	if (last_head->free) {
391	/*
392	* The last block of the heap area is
393	* unused. The area might be potentially
394	* shrunk.
395	*/
396
397	heap_block_head_t *first_head =
398	(heap_block_head_t *) AREA_FIRST_BLOCK_HEAD(area);
399
400	block_check((void *) first_head);
401	malloc_assert(first_head->area == area);
402
403	size_t shrink_size = ALIGN_DOWN(last_head->size, PAGE_SIZE);
404
405	if (first_head == last_head) {
406	/*
407	* The entire heap area consists of a single
408	* free heap block. This means we can get rid
409	* of it entirely.
410	*/
411
412	heap_area_t *prev = area->prev;
413	heap_area_t *next = area->next;
414
415	if (prev != NULL) {
416	area_check(prev);
417	prev->next = next;
418	} else
419	first_heap_area = next;
420
421	if (next != NULL) {
422	area_check(next);
423	next->prev = prev;
424	} else
425	last_heap_area = prev;
426
427	as_area_destroy(area->start);
428	} else if (shrink_size >= SHRINK_GRANULARITY) {
429	/*
430	* Make sure that we always shrink the area
431	* by a multiple of page size and update
432	* the block layout accordingly.
433	*/
434
435	size_t asize = (size_t) (area->end - area->start) - shrink_size;
436	void end = (void ) ((uintptr_t) area->start + asize);
437
438	/* Resize the address space area */
439	int ret = as_area_resize(area->start, asize, 0);
440	if (ret != EOK)
441	abort();
442
443	/* Update heap area parameters */
444	area->end = end;
445	size_t excess = ((size_t) area->end) - ((size_t) last_head);
446
447	if (excess > 0) {
448	if (excess >= STRUCT_OVERHEAD) {
449	/*
450	* The previous block cannot be free and there
451	* is enough free space left in the area to
452	* create a new free block.
453	*/
454	block_init((void *) last_head, excess, true, area);
455	} else {
456	/*
457	* The excess is small. Therefore just enlarge
458	* the previous block.
459	*/
460	heap_block_foot_t prev_foot = (heap_block_foot_t )
461	(((uintptr_t) last_head) - sizeof(heap_block_foot_t));
462	heap_block_head_t *prev_head = BLOCK_HEAD(prev_foot);
463
464	block_check((void *) prev_head);
465
466	block_init(prev_head, prev_head->size + excess,
467	prev_head->free, area);
468	}
469	}
470	}
471	}
472
473	next_fit = NULL;
474	}
475
476	/** Initialize the heap allocator
477	*
478	* Create initial heap memory area. This routine is
479	* only called from libc initialization, thus we do not
480	* take any locks.
481	*
482	*/
483	void __malloc_init(void)
484	{
485	if (!area_create(PAGE_SIZE))
486	abort();
487	}
488
489	/** Split heap block and mark it as used.
490	*
491	* Should be called only inside the critical section.
492	*
493	* @param cur Heap block to split.
494	* @param size Number of bytes to split and mark from the beginning
495	* of the block.
496	*
497	*/
498	static void split_mark(heap_block_head_t *cur, const size_t size)
499	{
500	malloc_assert(cur->size >= size);
501
502	/* See if we should split the block. */
503	size_t split_limit = GROSS_SIZE(size);
504
505	if (cur->size > split_limit) {
506	/* Block big enough -> split. */
507	void next = ((void ) cur) + size;
508	block_init(next, cur->size - size, true, cur->area);
509	block_init(cur, size, false, cur->area);
510	} else {
511	/* Block too small -> use as is. */
512	cur->free = false;
513	}
514	}
515
516	/** Allocate memory from heap area starting from given block
517	*
518	* Should be called only inside the critical section.
519	* As a side effect this function also sets the current
520	* pointer on successful allocation.
521	*
522	* @param area Heap area where to allocate from.
523	* @param first_block Starting heap block.
524	* @param final_block Heap block where to finish the search
525	* (may be NULL).
526	* @param real_size Gross number of bytes to allocate.
527	* @param falign Physical alignment of the block.
528	*
529	* @return Address of the allocated block or NULL on not enough memory.
530	*
531	*/
532	static void malloc_area(heap_area_t area, heap_block_head_t *first_block,
533	heap_block_head_t *final_block, size_t real_size, size_t falign)
534	{
535	area_check((void *) area);
536	malloc_assert((void ) first_block >= (void ) AREA_FIRST_BLOCK_HEAD(area));
537	malloc_assert((void *) first_block < area->end);
538
539	for (heap_block_head_t cur = first_block; (void ) cur < area->end;
540	cur = (heap_block_head_t ) (((void ) cur) + cur->size)) {
541	block_check(cur);
542
543	/* Finish searching on the final block */
544	if ((final_block != NULL) && (cur == final_block))
545	break;
546
547	/* Try to find a block that is free and large enough. */
548	if ((cur->free) && (cur->size >= real_size)) {
549	/*
550	* We have found a suitable block.
551	* Check for alignment properties.
552	*/
553	void addr = (void )
554	((uintptr_t) cur + sizeof(heap_block_head_t));
555	void aligned = (void )
556	ALIGN_UP((uintptr_t) addr, falign);
557
558	if (addr == aligned) {
559	/* Exact block start including alignment. */
560	split_mark(cur, real_size);
561
562	next_fit = cur;
563	return addr;
564	} else {
565	/* Block start has to be aligned */
566	size_t excess = (size_t) (aligned - addr);
567
568	if (cur->size >= real_size + excess) {
569	/*
570	* The current block is large enough to fit
571	* data in (including alignment).
572	*/
573	if ((void ) cur > (void ) AREA_FIRST_BLOCK_HEAD(area)) {
574	/*
575	* There is a block before the current block.
576	* This previous block can be enlarged to
577	* compensate for the alignment excess.
578	*/
579	heap_block_foot_t prev_foot = (heap_block_foot_t )
580	((void *) cur - sizeof(heap_block_foot_t));
581
582	heap_block_head_t prev_head = (heap_block_head_t )
583	((void *) cur - prev_foot->size);
584
585	block_check(prev_head);
586
587	size_t reduced_size = cur->size - excess;
588	heap_block_head_t next_head = ((void ) cur) + excess;
589
590	if ((!prev_head->free) &&
591	(excess >= STRUCT_OVERHEAD)) {
592	/*
593	* The previous block is not free and there
594	* is enough free space left to fill in
595	* a new free block between the previous
596	* and current block.
597	*/
598	block_init(cur, excess, true, area);
599	} else {
600	/*
601	* The previous block is free (thus there
602	* is no need to induce additional
603	* fragmentation to the heap) or the
604	* excess is small. Therefore just enlarge
605	* the previous block.
606	*/
607	block_init(prev_head, prev_head->size + excess,
608	prev_head->free, area);
609	}
610
611	block_init(next_head, reduced_size, true, area);
612	split_mark(next_head, real_size);
613
614	next_fit = next_head;
615	return aligned;
616	} else {
617	/*
618	* The current block is the first block
619	* in the heap area. We have to make sure
620	* that the alignment excess is large enough
621	* to fit a new free block just before the
622	* current block.
623	*/
624	while (excess < STRUCT_OVERHEAD) {
625	aligned += falign;
626	excess += falign;
627	}
628
629	/* Check for current block size again */
630	if (cur->size >= real_size + excess) {
631	size_t reduced_size = cur->size - excess;
632	cur = (heap_block_head_t *)
633	(AREA_FIRST_BLOCK_HEAD(area) + excess);
634
635	block_init((void *) AREA_FIRST_BLOCK_HEAD(area),
636	excess, true, area);
637	block_init(cur, reduced_size, true, area);
638	split_mark(cur, real_size);
639
640	next_fit = cur;
641	return aligned;
642	}
643	}
644	}
645	}
646	}
647	}
648
649	return NULL;
650	}
651
652	/** Try to enlarge any of the heap areas.
653	* If successful, allocate block of the given size in the area.
654	*
655	* Should be called only inside the critical section.
656	*
657	* @param size Gross size of item to allocate (bytes).
658	* @param align Memory address alignment.
659	*
660	*/
661	static void *heap_grow_and_alloc(size_t size, size_t align)
662	{
663	if (size == 0)
664	return NULL;
665
666	/* First try to enlarge some existing area */
667	for (heap_area_t *area = first_heap_area; area != NULL;
668	area = area->next) {
669
670	if (area_grow(area, size + align)) {
671	heap_block_head_t first = (heap_block_head_t ) AREA_LAST_BLOCK_HEAD(area);
672
673	void *addr = malloc_area(area, first, NULL, size, align);
674	malloc_assert(addr != NULL);
675	return addr;
676	}
677	}
678
679	/* Eventually try to create a new area */
680	if (area_create(AREA_OVERHEAD(size + align))) {
681	heap_block_head_t first = (heap_block_head_t ) AREA_FIRST_BLOCK_HEAD(last_heap_area);
682
683	void *addr = malloc_area(last_heap_area, first, NULL, size, align);
684	malloc_assert(addr != NULL);
685	return addr;
686	}
687
688	return NULL;
689	}
690
691	/** Allocate a memory block
692	*
693	* Should be called only inside the critical section.
694	*
695	* @param size The size of the block to allocate.
696	* @param align Memory address alignment.
697	*
698	* @return Address of the allocated block or NULL on not enough memory.
699	*
700	*/
701	static void *malloc_internal(const size_t size, const size_t align)
702	{
703	malloc_assert(first_heap_area != NULL);
704
705	if (align == 0)
706	return NULL;
707
708	size_t falign = lcm(align, BASE_ALIGN);
709	size_t gross_size = GROSS_SIZE(size);
710
711	heap_block_head_t *split;
712
713	/* Try the next fit approach */
714	split = next_fit;
715
716	if (split != NULL) {
717	void *addr = malloc_area(split->area, split, NULL, gross_size,
718	falign);
719
720	if (addr != NULL)
721	return addr;
722	}
723
724	/* Search the entire heap */
725	for (heap_area_t *area = first_heap_area; area != NULL;
726	area = area->next) {
727	heap_block_head_t first = (heap_block_head_t )
728	AREA_FIRST_BLOCK_HEAD(area);
729
730	void *addr = malloc_area(area, first, split, gross_size,
731	falign);
732
733	if (addr != NULL)
734	return addr;
735	}
736
737	/* Finally, try to grow heap space and allocate in the new area. */
738	return heap_grow_and_alloc(gross_size, falign);
739	}
740
741	/** Allocate memory by number of elements
742	*
743	* @param nmemb Number of members to allocate.
744	* @param size Size of one member in bytes.
745	*
746	* @return Allocated memory or NULL.
747	*
748	*/
749	void *calloc(const size_t nmemb, const size_t size)
750	{
751	void block = malloc(nmemb size);
752	if (block == NULL)
753	return NULL;
754
755	memset(block, 0, nmemb * size);
756	return block;
757	}
758
759	/** Allocate memory
760	*
761	* @param size Number of bytes to allocate.
762	*
763	* @return Allocated memory or NULL.
764	*
765	*/
766	void *malloc(const size_t size)
767	{
768	futex_down(&malloc_futex);
769	void *block = malloc_internal(size, BASE_ALIGN);
770	futex_up(&malloc_futex);
771
772	return block;
773	}
774
775	/** Allocate memory with specified alignment
776	*
777	* @param align Alignment in byes.
778	* @param size Number of bytes to allocate.
779	*
780	* @return Allocated memory or NULL.
781	*
782	*/
783	void *memalign(const size_t align, const size_t size)
784	{
785	if (align == 0)
786	return NULL;
787
788	size_t palign =
789	1 << (fnzb(max(sizeof(void *), align) - 1) + 1);
790
791	futex_down(&malloc_futex);
792	void *block = malloc_internal(size, palign);
793	futex_up(&malloc_futex);
794
795	return block;
796	}
797
798	/** Reallocate memory block
799	*
800	* @param addr Already allocated memory or NULL.
801	* @param size New size of the memory block.
802	*
803	* @return Reallocated memory or NULL.
804	*
805	*/
806	void realloc(const void addr, const size_t size)
807	{
808	if (addr == NULL)
809	return malloc(size);
810
811	futex_down(&malloc_futex);
812
813	/* Calculate the position of the header. */
814	heap_block_head_t *head =
815	(heap_block_head_t *) (addr - sizeof(heap_block_head_t));
816
817	block_check(head);
818	malloc_assert(!head->free);
819
820	heap_area_t *area = head->area;
821
822	area_check(area);
823	malloc_assert((void ) head >= (void ) AREA_FIRST_BLOCK_HEAD(area));
824	malloc_assert((void *) head < area->end);
825
826	void *ptr = NULL;
827	bool reloc = false;
828	size_t real_size = GROSS_SIZE(ALIGN_UP(size, BASE_ALIGN));
829	size_t orig_size = head->size;
830
831	if (orig_size > real_size) {
832	/* Shrink */
833	if (orig_size - real_size >= STRUCT_OVERHEAD) {
834	/*
835	* Split the original block to a full block
836	* and a trailing free block.
837	*/
838	block_init((void *) head, real_size, false, area);
839	block_init((void *) head + real_size,
840	orig_size - real_size, true, area);
841	heap_shrink(area);
842	}
843
844	ptr = ((void *) head) + sizeof(heap_block_head_t);
845	} else {
846	/*
847	* Look at the next block. If it is free and the size is
848	* sufficient then merge the two. Otherwise just allocate
849	* a new block, copy the original data into it and
850	* free the original block.
851	*/
852	heap_block_head_t *next_head =
853	(heap_block_head_t ) (((void ) head) + head->size);
854
855	if (((void *) next_head < area->end) &&
856	(head->size + next_head->size >= real_size) &&
857	(next_head->free)) {
858	block_check(next_head);
859	block_init(head, head->size + next_head->size, false, area);
860	split_mark(head, real_size);
861
862	ptr = ((void *) head) + sizeof(heap_block_head_t);
863	next_fit = NULL;
864	} else
865	reloc = true;
866	}
867
868	futex_up(&malloc_futex);
869
870	if (reloc) {
871	ptr = malloc(size);
872	if (ptr != NULL) {
873	memcpy(ptr, addr, NET_SIZE(orig_size));
874	free(addr);
875	}
876	}
877
878	return ptr;
879	}
880
881	/** Free a memory block
882	*
883	* @param addr The address of the block.
884	*
885	*/
886	void free(const void *addr)
887	{
888	if (addr == NULL)
889	return;
890
891	futex_down(&malloc_futex);
892
893	/* Calculate the position of the header. */
894	heap_block_head_t *head
895	= (heap_block_head_t *) (addr - sizeof(heap_block_head_t));
896
897	block_check(head);
898	malloc_assert(!head->free);
899
900	heap_area_t *area = head->area;
901
902	area_check(area);
903	malloc_assert((void ) head >= (void ) AREA_FIRST_BLOCK_HEAD(area));
904	malloc_assert((void *) head < area->end);
905
906	/* Mark the block itself as free. */
907	head->free = true;
908
909	/* Look at the next block. If it is free, merge the two. */
910	heap_block_head_t *next_head
911	= (heap_block_head_t ) (((void ) head) + head->size);
912
913	if ((void *) next_head < area->end) {
914	block_check(next_head);
915	if (next_head->free)
916	block_init(head, head->size + next_head->size, true, area);
917	}
918
919	/* Look at the previous block. If it is free, merge the two. */
920	if ((void ) head > (void ) AREA_FIRST_BLOCK_HEAD(area)) {
921	heap_block_foot_t *prev_foot =
922	(heap_block_foot_t ) (((void ) head) - sizeof(heap_block_foot_t));
923
924	heap_block_head_t *prev_head =
925	(heap_block_head_t ) (((void ) head) - prev_foot->size);
926
927	block_check(prev_head);
928
929	if (prev_head->free)
930	block_init(prev_head, prev_head->size + head->size, true,
931	area);
932	}
933
934	heap_shrink(area);
935
936	futex_up(&malloc_futex);
937	}
938
939	void *heap_check(void)
940	{
941	futex_down(&malloc_futex);
942
943	if (first_heap_area == NULL) {
944	futex_up(&malloc_futex);
945	return (void *) -1;
946	}
947
948	/* Walk all heap areas */
949	for (heap_area_t *area = first_heap_area; area != NULL;
950	area = area->next) {
951
952	/* Check heap area consistency */
953	if ((area->magic != HEAP_AREA_MAGIC) \|\|
954	((void *) area != area->start) \|\|
955	(area->start >= area->end) \|\|
956	(((uintptr_t) area->start % PAGE_SIZE) != 0) \|\|
957	(((uintptr_t) area->end % PAGE_SIZE) != 0)) {
958	futex_up(&malloc_futex);
959	return (void *) area;
960	}
961
962	/* Walk all heap blocks */
963	for (heap_block_head_t head = (heap_block_head_t )
964	AREA_FIRST_BLOCK_HEAD(area); (void *) head < area->end;
965	head = (heap_block_head_t ) (((void ) head) + head->size)) {
966
967	/* Check heap block consistency */
968	if (head->magic != HEAP_BLOCK_HEAD_MAGIC) {
969	futex_up(&malloc_futex);
970	return (void *) head;
971	}
972
973	heap_block_foot_t *foot = BLOCK_FOOT(head);
974
975	if ((foot->magic != HEAP_BLOCK_FOOT_MAGIC) \|\|
976	(head->size != foot->size)) {
977	futex_up(&malloc_futex);
978	return (void *) foot;
979	}
980	}
981	}
982
983	futex_up(&malloc_futex);
984
985	return NULL;
986	}
987
988	/** @}
989	*/

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source: mainline/uspace/lib/c/generic/malloc.c@ 7aafdb86

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