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Last change on this file since 13f2461 was 13f2461, checked in by Jakub Jermar <jakub@…>, 14 years ago
Merge the functionality of assert_abort() and assert_static_abort() into assert_abort(). Print the unexpanded message to klog first. Then try to print the message and the stack trace to standard output using printf. Use the same unabbreviated message wording for both klog and stdout. If a nested or a parallel assert is detected, send the message only to klog and then abort. Re-introduce malloc_assert() to up the malloc_futex. This appears to be inevitable if we want to print to stdout. To prevent undesired macro expansion, call assert_abort() from malloc_assert() directly.
Property mode set to `100644`
File size: 23.7 KB

Rev	Line
[6db6fd1]	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>
[3292623]	45	#include <futex.h>
[d161715]	46	#include <stdlib.h>
[6db6fd1]	47	#include <adt/gcdlcm.h>
[47b7006]	48	#include "private/malloc.h"
[6db6fd1]	49
[0b37882]	50	/** Magic used in heap headers. */
	51	#define HEAP_BLOCK_HEAD_MAGIC UINT32_C(0xBEEF0101)
[6db6fd1]	52
[0b37882]	53	/** Magic used in heap footers. */
	54	#define HEAP_BLOCK_FOOT_MAGIC UINT32_C(0xBEEF0202)
[6db6fd1]	55
[0b37882]	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	*/
[6db6fd1]	65	#define BASE_ALIGN 16
	66
[013a5d7]	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
[0b37882]	77	/** Overhead of each heap block. */
	78	#define STRUCT_OVERHEAD \
	79	(sizeof(heap_block_head_t) + sizeof(heap_block_foot_t))
	80
	81	/** Calculate real size of a heap block.
	82	*
	83	* Add header and footer size.
	84	*
[6db6fd1]	85	*/
[0b37882]	86	#define GROSS_SIZE(size) ((size) + STRUCT_OVERHEAD)
[6db6fd1]	87
[0b37882]	88	/** Calculate net size of a heap block.
	89	*
	90	* Subtract header and footer size.
[6db6fd1]	91	*
	92	*/
[0b37882]	93	#define NET_SIZE(size) ((size) - STRUCT_OVERHEAD)
[6db6fd1]	94
[0b37882]	95	/** Get first block in heap area.
	96	*
[6db6fd1]	97	*/
[013a5d7]	98	#define AREA_FIRST_BLOCK_HEAD(area) \
[0b37882]	99	(ALIGN_UP(((uintptr_t) (area)) + sizeof(heap_area_t), BASE_ALIGN))
[6db6fd1]	100
[013a5d7]	101	/** Get last block in heap area.
	102	*
	103	*/
	104	#define AREA_LAST_BLOCK_FOOT(area) \
	105	(((uintptr_t) (area)->end) - sizeof(heap_block_foot_t))
	106
	107	/** Get header in heap block.
	108	*
	109	*/
	110	#define BLOCK_HEAD(foot) \
	111	((heap_block_head_t *) \
	112	(((uintptr_t) (foot)) + sizeof(heap_block_foot_t) - (foot)->size))
	113
[0b37882]	114	/** Get footer in heap block.
	115	*
[6db6fd1]	116	*/
[0b37882]	117	#define BLOCK_FOOT(head) \
	118	((heap_block_foot_t *) \
[013a5d7]	119	(((uintptr_t) (head)) + (head)->size - sizeof(heap_block_foot_t)))
[0b37882]	120
	121	/** Heap area.
	122	*
	123	* The memory managed by the heap allocator is divided into
	124	* multiple discontinuous heaps. Each heap is represented
	125	* by a separate address space area which has this structure
	126	* at its very beginning.
	127	*
	128	*/
	129	typedef struct heap_area {
	130	/** Start of the heap area (including this structure)
	131	*
	132	* Aligned on page boundary.
	133	*
	134	*/
	135	void *start;
	136
	137	/** End of the heap area (aligned on page boundary) */
	138	void *end;
	139
[013a5d7]	140	/** Previous heap area */
	141	struct heap_area *prev;
	142
[0b37882]	143	/** Next heap area */
	144	struct heap_area *next;
	145
	146	/** A magic value */
	147	uint32_t magic;
	148	} heap_area_t;
[6db6fd1]	149
	150	/** Header of a heap block
	151	*
	152	*/
	153	typedef struct {
	154	/* Size of the block (including header and footer) */
	155	size_t size;
	156
	157	/* Indication of a free block */
	158	bool free;
	159
[0b37882]	160	/** Heap area this block belongs to */
	161	heap_area_t *area;
	162
[6db6fd1]	163	/* A magic value to detect overwrite of heap header */
	164	uint32_t magic;
	165	} heap_block_head_t;
	166
	167	/** Footer of a heap block
	168	*
	169	*/
	170	typedef struct {
	171	/* Size of the block (including header and footer) */
	172	size_t size;
	173
	174	/* A magic value to detect overwrite of heap footer */
	175	uint32_t magic;
	176	} heap_block_foot_t;
	177
[0b37882]	178	/** First heap area */
	179	static heap_area_t *first_heap_area = NULL;
[6db6fd1]	180
[0b37882]	181	/** Last heap area */
	182	static heap_area_t *last_heap_area = NULL;
[6db6fd1]	183
[0b37882]	184	/** Next heap block to examine (next fit algorithm) */
	185	static heap_block_head_t *next = NULL;
[6db6fd1]	186
[0b37882]	187	/** Futex for thread-safe heap manipulation */
	188	static futex_t malloc_futex = FUTEX_INITIALIZER;
[6db6fd1]	189
[13f2461]	190	#ifndef NDEBUG
	191
	192	#define malloc_assert(expr) \
	193	do { \
	194	if (!(expr)) {\
	195	futex_up(&malloc_futex); \
	196	assert_abort(#expr, __FILE__, STR2(__LINE__)); \
	197	} \
	198	} while (0)
	199
	200	#else /* NDEBUG */
	201
	202	#define malloc_assert(expr)
	203
	204	#endif /* NDEBUG */
	205
[6db6fd1]	206	/** Initialize a heap block
	207	*
[0b37882]	208	* Fill in the structures related to a heap block.
[3292623]	209	* Should be called only inside the critical section.
[6db6fd1]	210	*
	211	* @param addr Address of the block.
	212	* @param size Size of the block including the header and the footer.
	213	* @param free Indication of a free block.
[0b37882]	214	* @param area Heap area the block belongs to.
[6db6fd1]	215	*
	216	*/
[0b37882]	217	static void block_init(void addr, size_t size, bool free, heap_area_t area)
[6db6fd1]	218	{
	219	/* Calculate the position of the header and the footer */
	220	heap_block_head_t head = (heap_block_head_t ) addr;
	221
	222	head->size = size;
	223	head->free = free;
[0b37882]	224	head->area = area;
[6db6fd1]	225	head->magic = HEAP_BLOCK_HEAD_MAGIC;
	226
[0b37882]	227	heap_block_foot_t *foot = BLOCK_FOOT(head);
	228
[6db6fd1]	229	foot->size = size;
	230	foot->magic = HEAP_BLOCK_FOOT_MAGIC;
	231	}
	232
	233	/** Check a heap block
	234	*
	235	* Verifies that the structures related to a heap block still contain
	236	* the magic constants. This helps detect heap corruption early on.
[3292623]	237	* Should be called only inside the critical section.
[6db6fd1]	238	*
	239	* @param addr Address of the block.
	240	*
	241	*/
	242	static void block_check(void *addr)
	243	{
	244	heap_block_head_t head = (heap_block_head_t ) addr;
	245
[13f2461]	246	malloc_assert(head->magic == HEAP_BLOCK_HEAD_MAGIC);
[6db6fd1]	247
[0b37882]	248	heap_block_foot_t *foot = BLOCK_FOOT(head);
[6db6fd1]	249
[13f2461]	250	malloc_assert(foot->magic == HEAP_BLOCK_FOOT_MAGIC);
	251	malloc_assert(head->size == foot->size);
[6db6fd1]	252	}
	253
[0b37882]	254	/** Check a heap area structure
[013a5d7]	255	*
	256	* Should be called only inside the critical section.
[3292623]	257	*
[0b37882]	258	* @param addr Address of the heap area.
[3292623]	259	*
[0b37882]	260	*/
	261	static void area_check(void *addr)
	262	{
	263	heap_area_t area = (heap_area_t ) addr;
	264
[13f2461]	265	malloc_assert(area->magic == HEAP_AREA_MAGIC);
	266	malloc_assert(addr == area->start);
	267	malloc_assert(area->start < area->end);
	268	malloc_assert(((uintptr_t) area->start % PAGE_SIZE) == 0);
	269	malloc_assert(((uintptr_t) area->end % PAGE_SIZE) == 0);
[0b37882]	270	}
	271
	272	/** Create new heap area
	273	*
[013a5d7]	274	* Should be called only inside the critical section.
	275	*
	276	* @param size Size of the area.
[3292623]	277	*
	278	*/
[0b37882]	279	static bool area_create(size_t size)
[6db6fd1]	280	{
[0b37882]	281	void *start = as_get_mappable_page(size);
	282	if (start == NULL)
[6db6fd1]	283	return false;
[0b37882]	284
	285	/* Align the heap area on page boundary */
	286	void astart = (void ) ALIGN_UP((uintptr_t) start, PAGE_SIZE);
	287	size_t asize = ALIGN_UP(size, PAGE_SIZE);
	288
	289	astart = as_area_create(astart, asize, AS_AREA_WRITE \| AS_AREA_READ);
	290	if (astart == (void *) -1)
[e70edd1]	291	return false;
[6db6fd1]	292
[0b37882]	293	heap_area_t area = (heap_area_t ) astart;
	294
	295	area->start = astart;
[013a5d7]	296	area->end = (void *) ((uintptr_t) astart + asize);
	297	area->prev = NULL;
[0b37882]	298	area->next = NULL;
	299	area->magic = HEAP_AREA_MAGIC;
	300
[013a5d7]	301	void block = (void ) AREA_FIRST_BLOCK_HEAD(area);
[0b37882]	302	size_t bsize = (size_t) (area->end - block);
	303
	304	block_init(block, bsize, true, area);
	305
	306	if (last_heap_area == NULL) {
	307	first_heap_area = area;
	308	last_heap_area = area;
	309	} else {
[013a5d7]	310	area->prev = last_heap_area;
[0b37882]	311	last_heap_area->next = area;
	312	last_heap_area = area;
	313	}
	314
	315	return true;
	316	}
	317
	318	/** Try to enlarge a heap area
[013a5d7]	319	*
	320	* Should be called only inside the critical section.
[0b37882]	321	*
	322	* @param area Heap area to grow.
[013a5d7]	323	* @param size Gross size to grow (bytes).
	324	*
	325	* @return True if successful.
[0b37882]	326	*
	327	*/
	328	static bool area_grow(heap_area_t *area, size_t size)
	329	{
	330	if (size == 0)
	331	return true;
	332
	333	area_check(area);
	334
	335	/* New heap area size */
[013a5d7]	336	size_t gross_size = (size_t) (area->end - area->start) + size;
	337	size_t asize = ALIGN_UP(gross_size, PAGE_SIZE);
	338	void end = (void ) ((uintptr_t) area->start + asize);
[0b37882]	339
	340	/* Check for overflow */
	341	if (end < area->start)
	342	return false;
[6db6fd1]	343
[0b37882]	344	/* Resize the address space area */
	345	int ret = as_area_resize(area->start, asize, 0);
	346	if (ret != EOK)
[6db6fd1]	347	return false;
	348
[0b37882]	349	/* Add new free block */
[013a5d7]	350	size_t net_size = (size_t) (end - area->end);
	351	if (net_size > 0)
	352	block_init(area->end, net_size, true, area);
[6db6fd1]	353
[0b37882]	354	/* Update heap area parameters */
	355	area->end = end;
	356
	357	return true;
	358	}
	359
	360	/** Try to enlarge any of the heap areas
[013a5d7]	361	*
	362	* Should be called only inside the critical section.
[0b37882]	363	*
	364	* @param size Gross size of item to allocate (bytes).
	365	*
	366	*/
	367	static bool heap_grow(size_t size)
	368	{
	369	if (size == 0)
[6db6fd1]	370	return true;
[0b37882]	371
	372	/* First try to enlarge some existing area */
[013a5d7]	373	for (heap_area_t *area = first_heap_area; area != NULL;
	374	area = area->next) {
[0b37882]	375	if (area_grow(area, size))
	376	return true;
[6db6fd1]	377	}
	378
[0b37882]	379	/* Eventually try to create a new area */
[013a5d7]	380	return area_create(AREA_FIRST_BLOCK_HEAD(size));
[6db6fd1]	381	}
	382
[013a5d7]	383	/** Try to shrink heap
[3292623]	384	*
[013a5d7]	385	* Should be called only inside the critical section.
[0b37882]	386	* In all cases the next pointer is reset.
[3292623]	387	*
[013a5d7]	388	* @param area Last modified heap area.
	389	*
[3292623]	390	*/
[013a5d7]	391	static void heap_shrink(heap_area_t *area)
[6db6fd1]	392	{
[013a5d7]	393	area_check(area);
	394
	395	heap_block_foot_t *last_foot =
	396	(heap_block_foot_t *) AREA_LAST_BLOCK_FOOT(area);
	397	heap_block_head_t *last_head = BLOCK_HEAD(last_foot);
	398
	399	block_check((void *) last_head);
[13f2461]	400	malloc_assert(last_head->area == area);
[013a5d7]	401
	402	if (last_head->free) {
	403	/*
	404	* The last block of the heap area is
	405	* unused. The area might be potentially
	406	* shrunk.
	407	*/
	408
	409	heap_block_head_t *first_head =
	410	(heap_block_head_t *) AREA_FIRST_BLOCK_HEAD(area);
	411
	412	block_check((void *) first_head);
[13f2461]	413	malloc_assert(first_head->area == area);
[013a5d7]	414
[e6eee2b]	415	size_t shrink_size = ALIGN_DOWN(last_head->size, PAGE_SIZE);
	416
[013a5d7]	417	if (first_head == last_head) {
	418	/*
	419	* The entire heap area consists of a single
	420	* free heap block. This means we can get rid
	421	* of it entirely.
	422	*/
	423
	424	heap_area_t *prev = area->prev;
	425	heap_area_t *next = area->next;
	426
	427	if (prev != NULL) {
	428	area_check(prev);
	429	prev->next = next;
	430	} else
	431	first_heap_area = next;
	432
	433	if (next != NULL) {
	434	area_check(next);
	435	next->prev = prev;
	436	} else
	437	last_heap_area = prev;
	438
	439	as_area_destroy(area->start);
[e6eee2b]	440	} else if (shrink_size >= SHRINK_GRANULARITY) {
[013a5d7]	441	/*
	442	* Make sure that we always shrink the area
	443	* by a multiple of page size and update
	444	* the block layout accordingly.
	445	*/
	446
	447	size_t asize = (size_t) (area->end - area->start) - shrink_size;
	448	void end = (void ) ((uintptr_t) area->start + asize);
	449
	450	/* Resize the address space area */
	451	int ret = as_area_resize(area->start, asize, 0);
	452	if (ret != EOK)
	453	abort();
	454
	455	/* Update heap area parameters */
	456	area->end = end;
	457
	458	/* Update block layout */
	459	void last = (void ) last_head;
	460	size_t excess = (size_t) (area->end - last);
	461
	462	if (excess > 0) {
	463	if (excess >= STRUCT_OVERHEAD) {
	464	/*
	465	* The previous block cannot be free and there
	466	* is enough free space left in the area to
	467	* create a new free block.
	468	*/
	469	block_init(last, excess, true, area);
	470	} else {
	471	/*
	472	* The excess is small. Therefore just enlarge
	473	* the previous block.
	474	*/
	475	heap_block_foot_t prev_foot = (heap_block_foot_t )
	476	(((uintptr_t) last_head) - sizeof(heap_block_foot_t));
	477	heap_block_head_t *prev_head = BLOCK_HEAD(prev_foot);
	478
	479	block_check((void *) prev_head);
	480
	481	block_init(prev_head, prev_head->size + excess,
	482	prev_head->free, area);
	483	}
	484	}
	485	}
	486	}
	487
[0b37882]	488	next = NULL;
[6db6fd1]	489	}
	490
	491	/** Initialize the heap allocator
	492	*
[47b7006]	493	* Create initial heap memory area. This routine is
	494	* only called from libc initialization, thus we do not
	495	* take any locks.
[6db6fd1]	496	*
	497	*/
[47b7006]	498	void __malloc_init(void)
[6db6fd1]	499	{
[0b37882]	500	if (!area_create(PAGE_SIZE))
[47b7006]	501	abort();
[6db6fd1]	502	}
	503
[3292623]	504	/** Split heap block and mark it as used.
	505	*
	506	* Should be called only inside the critical section.
	507	*
	508	* @param cur Heap block to split.
	509	* @param size Number of bytes to split and mark from the beginning
	510	* of the block.
	511	*
	512	*/
[6db6fd1]	513	static void split_mark(heap_block_head_t *cur, const size_t size)
	514	{
[13f2461]	515	malloc_assert(cur->size >= size);
[6db6fd1]	516
	517	/* See if we should split the block. */
	518	size_t split_limit = GROSS_SIZE(size);
	519
	520	if (cur->size > split_limit) {
	521	/* Block big enough -> split. */
	522	void next = ((void ) cur) + size;
[0b37882]	523	block_init(next, cur->size - size, true, cur->area);
	524	block_init(cur, size, false, cur->area);
[6db6fd1]	525	} else {
	526	/* Block too small -> use as is. */
	527	cur->free = false;
	528	}
	529	}
	530
[0b37882]	531	/** Allocate memory from heap area starting from given block
[3292623]	532	*
	533	* Should be called only inside the critical section.
[0b37882]	534	* As a side effect this function also sets the current
	535	* pointer on successful allocation.
[6db6fd1]	536	*
[0b37882]	537	* @param area Heap area where to allocate from.
	538	* @param first_block Starting heap block.
	539	* @param final_block Heap block where to finish the search
	540	* (may be NULL).
	541	* @param real_size Gross number of bytes to allocate.
	542	* @param falign Physical alignment of the block.
[6db6fd1]	543	*
[0b37882]	544	* @return Address of the allocated block or NULL on not enough memory.
[6db6fd1]	545	*
	546	*/
[0b37882]	547	static void malloc_area(heap_area_t area, heap_block_head_t *first_block,
	548	heap_block_head_t *final_block, size_t real_size, size_t falign)
[6db6fd1]	549	{
[0b37882]	550	area_check((void *) area);
[13f2461]	551	malloc_assert((void ) first_block >= (void ) AREA_FIRST_BLOCK_HEAD(area));
	552	malloc_assert((void *) first_block < area->end);
[6db6fd1]	553
[013a5d7]	554	for (heap_block_head_t cur = first_block; (void ) cur < area->end;
[0b37882]	555	cur = (heap_block_head_t ) (((void ) cur) + cur->size)) {
[6db6fd1]	556	block_check(cur);
	557
[0b37882]	558	/* Finish searching on the final block */
	559	if ((final_block != NULL) && (cur == final_block))
	560	break;
	561
[6db6fd1]	562	/* Try to find a block that is free and large enough. */
	563	if ((cur->free) && (cur->size >= real_size)) {
[0b37882]	564	/*
	565	* We have found a suitable block.
	566	* Check for alignment properties.
	567	*/
	568	void addr = (void )
	569	((uintptr_t) cur + sizeof(heap_block_head_t));
	570	void aligned = (void )
	571	ALIGN_UP((uintptr_t) addr, falign);
[6db6fd1]	572
	573	if (addr == aligned) {
	574	/* Exact block start including alignment. */
	575	split_mark(cur, real_size);
[0b37882]	576
	577	next = cur;
	578	return addr;
[6db6fd1]	579	} else {
[d851f597]	580	/* Block start has to be aligned */
[6db6fd1]	581	size_t excess = (size_t) (aligned - addr);
	582
	583	if (cur->size >= real_size + excess) {
[0b37882]	584	/*
	585	* The current block is large enough to fit
	586	* data in (including alignment).
	587	*/
[013a5d7]	588	if ((void ) cur > (void ) AREA_FIRST_BLOCK_HEAD(area)) {
[0b37882]	589	/*
	590	* There is a block before the current block.
	591	* This previous block can be enlarged to
	592	* compensate for the alignment excess.
	593	*/
	594	heap_block_foot_t prev_foot = (heap_block_foot_t )
	595	((void *) cur - sizeof(heap_block_foot_t));
[6db6fd1]	596
[0b37882]	597	heap_block_head_t prev_head = (heap_block_head_t )
	598	((void *) cur - prev_foot->size);
[6db6fd1]	599
	600	block_check(prev_head);
	601
	602	size_t reduced_size = cur->size - excess;
[d851f597]	603	heap_block_head_t next_head = ((void ) cur) + excess;
[6db6fd1]	604
[0b37882]	605	if ((!prev_head->free) &&
	606	(excess >= STRUCT_OVERHEAD)) {
	607	/*
	608	* The previous block is not free and there
	609	* is enough free space left to fill in
	610	* a new free block between the previous
	611	* and current block.
	612	*/
	613	block_init(cur, excess, true, area);
[d851f597]	614	} else {
[0b37882]	615	/*
	616	* The previous block is free (thus there
	617	* is no need to induce additional
	618	* fragmentation to the heap) or the
	619	* excess is small. Therefore just enlarge
	620	* the previous block.
	621	*/
	622	block_init(prev_head, prev_head->size + excess,
	623	prev_head->free, area);
[d851f597]	624	}
	625
[0b37882]	626	block_init(next_head, reduced_size, true, area);
[d851f597]	627	split_mark(next_head, real_size);
[0b37882]	628
	629	next = next_head;
	630	return aligned;
[6db6fd1]	631	} else {
[0b37882]	632	/*
	633	* The current block is the first block
	634	* in the heap area. We have to make sure
	635	* that the alignment excess is large enough
	636	* to fit a new free block just before the
	637	* current block.
	638	*/
[6db6fd1]	639	while (excess < STRUCT_OVERHEAD) {
	640	aligned += falign;
	641	excess += falign;
	642	}
	643
[d851f597]	644	/* Check for current block size again */
[6db6fd1]	645	if (cur->size >= real_size + excess) {
	646	size_t reduced_size = cur->size - excess;
[0b37882]	647	cur = (heap_block_head_t *)
[013a5d7]	648	(AREA_FIRST_BLOCK_HEAD(area) + excess);
[6db6fd1]	649
[013a5d7]	650	block_init((void *) AREA_FIRST_BLOCK_HEAD(area),
	651	excess, true, area);
[0b37882]	652	block_init(cur, reduced_size, true, area);
[6db6fd1]	653	split_mark(cur, real_size);
[0b37882]	654
	655	next = cur;
	656	return aligned;
[6db6fd1]	657	}
	658	}
	659	}
	660	}
	661	}
[0b37882]	662	}
	663
	664	return NULL;
	665	}
	666
	667	/** Allocate a memory block
	668	*
	669	* Should be called only inside the critical section.
	670	*
	671	* @param size The size of the block to allocate.
	672	* @param align Memory address alignment.
	673	*
	674	* @return Address of the allocated block or NULL on not enough memory.
	675	*
	676	*/
	677	static void *malloc_internal(const size_t size, const size_t align)
	678	{
[13f2461]	679	malloc_assert(first_heap_area != NULL);
[0b37882]	680
	681	if (align == 0)
	682	return NULL;
	683
	684	size_t falign = lcm(align, BASE_ALIGN);
	685	size_t real_size = GROSS_SIZE(ALIGN_UP(size, falign));
	686
	687	bool retry = false;
	688	heap_block_head_t *split;
	689
	690	loop:
	691
	692	/* Try the next fit approach */
	693	split = next;
	694
	695	if (split != NULL) {
	696	void *addr = malloc_area(split->area, split, NULL, real_size,
	697	falign);
[6db6fd1]	698
[0b37882]	699	if (addr != NULL)
	700	return addr;
[6db6fd1]	701	}
	702
[0b37882]	703	/* Search the entire heap */
[013a5d7]	704	for (heap_area_t *area = first_heap_area; area != NULL;
	705	area = area->next) {
[0b37882]	706	heap_block_head_t first = (heap_block_head_t )
[013a5d7]	707	AREA_FIRST_BLOCK_HEAD(area);
[0b37882]	708
	709	void *addr = malloc_area(area, first, split, real_size,
	710	falign);
	711
	712	if (addr != NULL)
	713	return addr;
	714	}
	715
	716	if (!retry) {
	717	/* Try to grow the heap space */
	718	if (heap_grow(real_size)) {
	719	retry = true;
[6db6fd1]	720	goto loop;
	721	}
	722	}
	723
[0b37882]	724	return NULL;
[6db6fd1]	725	}
	726
[3292623]	727	/** Allocate memory by number of elements
	728	*
	729	* @param nmemb Number of members to allocate.
	730	* @param size Size of one member in bytes.
	731	*
	732	* @return Allocated memory or NULL.
	733	*
	734	*/
[15b8e495]	735	void *calloc(const size_t nmemb, const size_t size)
	736	{
[e6b73ad0]	737	void block = malloc(nmemb size);
	738	if (block == NULL)
	739	return NULL;
[3292623]	740
[e6b73ad0]	741	memset(block, 0, nmemb * size);
	742	return block;
[15b8e495]	743	}
	744
[3292623]	745	/** Allocate memory
	746	*
	747	* @param size Number of bytes to allocate.
	748	*
	749	* @return Allocated memory or NULL.
	750	*
	751	*/
[6db6fd1]	752	void *malloc(const size_t size)
	753	{
[3292623]	754	futex_down(&malloc_futex);
	755	void *block = malloc_internal(size, BASE_ALIGN);
	756	futex_up(&malloc_futex);
	757
	758	return block;
[6db6fd1]	759	}
	760
[3292623]	761	/** Allocate memory with specified alignment
	762	*
	763	* @param align Alignment in byes.
	764	* @param size Number of bytes to allocate.
	765	*
	766	* @return Allocated memory or NULL.
	767	*
	768	*/
[6db6fd1]	769	void *memalign(const size_t align, const size_t size)
	770	{
	771	if (align == 0)
	772	return NULL;
	773
	774	size_t palign =
	775	1 << (fnzb(max(sizeof(void *), align) - 1) + 1);
	776
[3292623]	777	futex_down(&malloc_futex);
	778	void *block = malloc_internal(size, palign);
	779	futex_up(&malloc_futex);
	780
	781	return block;
[6db6fd1]	782	}
	783
[3292623]	784	/** Reallocate memory block
	785	*
	786	* @param addr Already allocated memory or NULL.
	787	* @param size New size of the memory block.
	788	*
	789	* @return Reallocated memory or NULL.
	790	*
	791	*/
[6db6fd1]	792	void realloc(const void addr, const size_t size)
	793	{
	794	if (addr == NULL)
	795	return malloc(size);
	796
[3292623]	797	futex_down(&malloc_futex);
	798
[6db6fd1]	799	/* Calculate the position of the header. */
	800	heap_block_head_t *head =
	801	(heap_block_head_t *) (addr - sizeof(heap_block_head_t));
	802
	803	block_check(head);
[13f2461]	804	malloc_assert(!head->free);
[6db6fd1]	805
[0b37882]	806	heap_area_t *area = head->area;
	807
	808	area_check(area);
[13f2461]	809	malloc_assert((void ) head >= (void ) AREA_FIRST_BLOCK_HEAD(area));
	810	malloc_assert((void *) head < area->end);
[0b37882]	811
[6db6fd1]	812	void *ptr = NULL;
[3292623]	813	bool reloc = false;
[f450280]	814	size_t real_size = GROSS_SIZE(ALIGN_UP(size, BASE_ALIGN));
[6db6fd1]	815	size_t orig_size = head->size;
	816
	817	if (orig_size > real_size) {
	818	/* Shrink */
	819	if (orig_size - real_size >= STRUCT_OVERHEAD) {
[0b37882]	820	/*
	821	* Split the original block to a full block
	822	* and a trailing free block.
	823	*/
	824	block_init((void *) head, real_size, false, area);
[6db6fd1]	825	block_init((void *) head + real_size,
[0b37882]	826	orig_size - real_size, true, area);
[013a5d7]	827	heap_shrink(area);
[6db6fd1]	828	}
	829
	830	ptr = ((void *) head) + sizeof(heap_block_head_t);
	831	} else {
[0b37882]	832	/*
	833	* Look at the next block. If it is free and the size is
	834	* sufficient then merge the two. Otherwise just allocate
	835	* a new block, copy the original data into it and
	836	* free the original block.
	837	*/
[6db6fd1]	838	heap_block_head_t *next_head =
	839	(heap_block_head_t ) (((void ) head) + head->size);
	840
[0b37882]	841	if (((void *) next_head < area->end) &&
[7d88587]	842	(head->size + next_head->size >= real_size) &&
	843	(next_head->free)) {
[6db6fd1]	844	block_check(next_head);
[0b37882]	845	block_init(head, head->size + next_head->size, false, area);
[ba0aa6f]	846	split_mark(head, real_size);
[6db6fd1]	847
	848	ptr = ((void *) head) + sizeof(heap_block_head_t);
[0b37882]	849	next = NULL;
[3292623]	850	} else
	851	reloc = true;
	852	}
	853
	854	futex_up(&malloc_futex);
	855
	856	if (reloc) {
	857	ptr = malloc(size);
	858	if (ptr != NULL) {
	859	memcpy(ptr, addr, NET_SIZE(orig_size));
	860	free(addr);
[6db6fd1]	861	}
	862	}
	863
	864	return ptr;
	865	}
	866
	867	/** Free a memory block
	868	*
	869	* @param addr The address of the block.
[3292623]	870	*
[6db6fd1]	871	*/
	872	void free(const void *addr)
	873	{
[3292623]	874	futex_down(&malloc_futex);
	875
[6db6fd1]	876	/* Calculate the position of the header. */
	877	heap_block_head_t *head
	878	= (heap_block_head_t *) (addr - sizeof(heap_block_head_t));
	879
	880	block_check(head);
[13f2461]	881	malloc_assert(!head->free);
[6db6fd1]	882
[0b37882]	883	heap_area_t *area = head->area;
	884
	885	area_check(area);
[13f2461]	886	malloc_assert((void ) head >= (void ) AREA_FIRST_BLOCK_HEAD(area));
	887	malloc_assert((void *) head < area->end);
[0b37882]	888
[6db6fd1]	889	/* Mark the block itself as free. */
	890	head->free = true;
	891
	892	/* Look at the next block. If it is free, merge the two. */
	893	heap_block_head_t *next_head
	894	= (heap_block_head_t ) (((void ) head) + head->size);
	895
[0b37882]	896	if ((void *) next_head < area->end) {
[6db6fd1]	897	block_check(next_head);
	898	if (next_head->free)
[0b37882]	899	block_init(head, head->size + next_head->size, true, area);
[6db6fd1]	900	}
	901
	902	/* Look at the previous block. If it is free, merge the two. */
[013a5d7]	903	if ((void ) head > (void ) AREA_FIRST_BLOCK_HEAD(area)) {
[6db6fd1]	904	heap_block_foot_t *prev_foot =
	905	(heap_block_foot_t ) (((void ) head) - sizeof(heap_block_foot_t));
	906
	907	heap_block_head_t *prev_head =
	908	(heap_block_head_t ) (((void ) head) - prev_foot->size);
	909
	910	block_check(prev_head);
	911
	912	if (prev_head->free)
[0b37882]	913	block_init(prev_head, prev_head->size + head->size, true,
	914	area);
[6db6fd1]	915	}
	916
[013a5d7]	917	heap_shrink(area);
[3292623]	918
	919	futex_up(&malloc_futex);
[6db6fd1]	920	}
	921
[1b3e854]	922	void *heap_check(void)
	923	{
	924	futex_down(&malloc_futex);
	925
	926	if (first_heap_area == NULL) {
	927	futex_up(&malloc_futex);
	928	return (void *) -1;
	929	}
	930
	931	/* Walk all heap areas */
	932	for (heap_area_t *area = first_heap_area; area != NULL;
	933	area = area->next) {
	934
	935	/* Check heap area consistency */
	936	if ((area->magic != HEAP_AREA_MAGIC) \|\|
	937	((void *) area != area->start) \|\|
	938	(area->start >= area->end) \|\|
	939	(((uintptr_t) area->start % PAGE_SIZE) != 0) \|\|
	940	(((uintptr_t) area->end % PAGE_SIZE) != 0)) {
	941	futex_up(&malloc_futex);
	942	return (void *) area;
	943	}
	944
	945	/* Walk all heap blocks */
	946	for (heap_block_head_t head = (heap_block_head_t )
	947	AREA_FIRST_BLOCK_HEAD(area); (void *) head < area->end;
	948	head = (heap_block_head_t ) (((void ) head) + head->size)) {
	949
	950	/* Check heap block consistency */
	951	if (head->magic != HEAP_BLOCK_HEAD_MAGIC) {
	952	futex_up(&malloc_futex);
	953	return (void *) head;
	954	}
	955
	956	heap_block_foot_t *foot = BLOCK_FOOT(head);
	957
	958	if ((foot->magic != HEAP_BLOCK_FOOT_MAGIC) \|\|
	959	(head->size != foot->size)) {
	960	futex_up(&malloc_futex);
	961	return (void *) foot;
	962	}
	963	}
	964	}
	965
	966	futex_up(&malloc_futex);
	967
	968	return NULL;
	969	}
	970
[6db6fd1]	971	/** @}
	972	*/

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