[thirdparty/git.git] / mem-pool.c

/*
 * Memory Pool implementation logic.
 */

#include "cache.h"
#include "mem-pool.h"

#define BLOCK_GROWTH_SIZE (1024 * 1024 - sizeof(struct mp_block))

/*
 * The inner union is an approximation for C11's max_align_t, and the
 * struct + offsetof computes _Alignof. This can all just be replaced
 * with _Alignof(max_align_t) if/when C11 is part of the baseline.
 * Note that _Alignof(X) need not be the same as sizeof(X); it's only
 * required to be a (possibly trivial) factor. They are the same for
 * most architectures, but m68k for example has only 2-byte alignment
 * for its 4-byte and 8-byte types, so using sizeof would waste space.
 *
 * Add more types to the union if the current set is insufficient.
 */
struct git_max_alignment {
	char unalign;
	union {
		uintmax_t max_align_uintmax;
		void *max_align_pointer;
	} aligned;
};
#define GIT_MAX_ALIGNMENT offsetof(struct git_max_alignment, aligned)

/*
 * Allocate a new mp_block and insert it after the block specified in
 * `insert_after`. If `insert_after` is NULL, then insert block at the
 * head of the linked list.
 */
static struct mp_block *mem_pool_alloc_block(struct mem_pool *pool,
					     size_t block_alloc,
					     struct mp_block *insert_after)
{
	struct mp_block *p;

	pool->pool_alloc += sizeof(struct mp_block) + block_alloc;
	p = xmalloc(st_add(sizeof(struct mp_block), block_alloc));

	p->next_free = (char *)p->space;
	p->end = p->next_free + block_alloc;

	if (insert_after) {
		p->next_block = insert_after->next_block;
		insert_after->next_block = p;
	} else {
		p->next_block = pool->mp_block;
		pool->mp_block = p;
	}

	return p;
}

void mem_pool_init(struct mem_pool *pool, size_t initial_size)
{
	memset(pool, 0, sizeof(*pool));
	pool->block_alloc = BLOCK_GROWTH_SIZE;

	if (initial_size > 0)
		mem_pool_alloc_block(pool, initial_size, NULL);
}

void mem_pool_discard(struct mem_pool *pool, int invalidate_memory)
{
	struct mp_block *block, *block_to_free;

	block = pool->mp_block;
	while (block)
	{
		block_to_free = block;
		block = block->next_block;

		if (invalidate_memory)
			memset(block_to_free->space, 0xDD, ((char *)block_to_free->end) - ((char *)block_to_free->space));

		free(block_to_free);
	}

	pool->mp_block = NULL;
	pool->pool_alloc = 0;
}

void *mem_pool_alloc(struct mem_pool *pool, size_t len)
{
	struct mp_block *p = NULL;
	void *r;

	/* round up to a 'GIT_MAX_ALIGNMENT' alignment */
	if (len & (GIT_MAX_ALIGNMENT - 1))
		len += GIT_MAX_ALIGNMENT - (len & (GIT_MAX_ALIGNMENT - 1));

	if (pool->mp_block &&
	    pool->mp_block->end - pool->mp_block->next_free >= len)
		p = pool->mp_block;

	if (!p) {
		if (len >= (pool->block_alloc / 2))
			return mem_pool_alloc_block(pool, len, pool->mp_block);

		p = mem_pool_alloc_block(pool, pool->block_alloc, NULL);
	}

	r = p->next_free;
	p->next_free += len;
	return r;
}

void *mem_pool_calloc(struct mem_pool *pool, size_t count, size_t size)
{
	size_t len = st_mult(count, size);
	void *r = mem_pool_alloc(pool, len);
	memset(r, 0, len);
	return r;
}

char *mem_pool_strdup(struct mem_pool *pool, const char *str)
{
	size_t len = strlen(str) + 1;
	char *ret = mem_pool_alloc(pool, len);

	return memcpy(ret, str, len);
}

char *mem_pool_strndup(struct mem_pool *pool, const char *str, size_t len)
{
	char *p = memchr(str, '\0', len);
	size_t actual_len = (p ? p - str : len);
	char *ret = mem_pool_alloc(pool, actual_len+1);

	ret[actual_len] = '\0';
	return memcpy(ret, str, actual_len);
}

int mem_pool_contains(struct mem_pool *pool, void *mem)
{
	struct mp_block *p;

	/* Check if memory is allocated in a block */
	for (p = pool->mp_block; p; p = p->next_block)
		if ((mem >= ((void *)p->space)) &&
		    (mem < ((void *)p->end)))
			return 1;

	return 0;
}

void mem_pool_combine(struct mem_pool *dst, struct mem_pool *src)
{
	struct mp_block *p;

	/* Append the blocks from src to dst */
	if (dst->mp_block && src->mp_block) {
		/*
		 * src and dst have blocks, append
		 * blocks from src to dst.
		 */
		p = dst->mp_block;
		while (p->next_block)
			p = p->next_block;

		p->next_block = src->mp_block;
	} else if (src->mp_block) {
		/*
		 * src has blocks, dst is empty.
		 */
		dst->mp_block = src->mp_block;
	} else {
		/* src is empty, nothing to do. */
	}

	dst->pool_alloc += src->pool_alloc;
	src->pool_alloc = 0;
	src->mp_block = NULL;
}
Commit	Line	Data
065feab4 JM	1	/*
	2	* Memory Pool implementation logic.
	3	*/
	4
	5	#include "cache.h"
	6	#include "mem-pool.h"
	7
116affac	8	#define BLOCK_GROWTH_SIZE (1024 * 1024 - sizeof(struct mp_block))
158dfeff	9
e38bcc66 JC	10	/*
	11	* The inner union is an approximation for C11's max_align_t, and the
	12	* struct + offsetof computes _Alignof. This can all just be replaced
	13	* with _Alignof(max_align_t) if/when C11 is part of the baseline.
	14	* Note that _Alignof(X) need not be the same as sizeof(X); it's only
	15	* required to be a (possibly trivial) factor. They are the same for
	16	* most architectures, but m68k for example has only 2-byte alignment
	17	* for its 4-byte and 8-byte types, so using sizeof would waste space.
	18	*
	19	* Add more types to the union if the current set is insufficient.
	20	*/
	21	struct git_max_alignment {
	22	char unalign;
	23	union {
	24	uintmax_t max_align_uintmax;
	25	void *max_align_pointer;
	26	} aligned;
	27	};
	28	#define GIT_MAX_ALIGNMENT offsetof(struct git_max_alignment, aligned)
	29
158dfeff JM	30	/*
	31	* Allocate a new mp_block and insert it after the block specified in
	32	* `insert_after`. If `insert_after` is NULL, then insert block at the
	33	* head of the linked list.
	34	*/
f87bf284 EN	35	static struct mp_block mem_pool_alloc_block(struct mem_pool pool,
	36	size_t block_alloc,
	37	struct mp_block *insert_after)
065feab4 JM	38	{
	39	struct mp_block *p;
	40
f87bf284	41	pool->pool_alloc += sizeof(struct mp_block) + block_alloc;
065feab4	42	p = xmalloc(st_add(sizeof(struct mp_block), block_alloc));
158dfeff	43
065feab4 JM	44	p->next_free = (char *)p->space;
065feab4 JM	45	p->end = p->next_free + block_alloc;
158dfeff JM	46
	47	if (insert_after) {
	48	p->next_block = insert_after->next_block;
	49	insert_after->next_block = p;
	50	} else {
f87bf284 EN	51	p->next_block = pool->mp_block;
f87bf284 EN	52	pool->mp_block = p;
158dfeff	53	}
065feab4 JM	54
	55	return p;
	56	}
	57
44c7e1a7	58	void mem_pool_init(struct mem_pool *pool, size_t initial_size)
158dfeff	59	{
44c7e1a7	60	memset(pool, 0, sizeof(*pool));
158dfeff JM	61	pool->block_alloc = BLOCK_GROWTH_SIZE;
	62
	63	if (initial_size > 0)
	64	mem_pool_alloc_block(pool, initial_size, NULL);
158dfeff JM	65	}
158dfeff JM	66
f87bf284	67	void mem_pool_discard(struct mem_pool *pool, int invalidate_memory)
158dfeff JM	68	{
	69	struct mp_block block, block_to_free;
	70
f87bf284	71	block = pool->mp_block;
8e72d675	72	while (block)
158dfeff JM	73	{
	74	block_to_free = block;
	75	block = block->next_block;
8616a2d0 JM	76
	77	if (invalidate_memory)
	78	memset(block_to_free->space, 0xDD, ((char )block_to_free->end) - ((char )block_to_free->space));
	79
158dfeff JM	80	free(block_to_free);
	81	}
	82
f87bf284 EN	83	pool->mp_block = NULL;
f87bf284 EN	84	pool->pool_alloc = 0;
158dfeff JM	85	}
158dfeff JM	86
f87bf284	87	void mem_pool_alloc(struct mem_pool pool, size_t len)
065feab4	88	{
8fb8e3f6	89	struct mp_block *p = NULL;
065feab4 JM	90	void *r;
065feab4 JM	91
e38bcc66 JC	92	/* round up to a 'GIT_MAX_ALIGNMENT' alignment */
	93	if (len & (GIT_MAX_ALIGNMENT - 1))
	94	len += GIT_MAX_ALIGNMENT - (len & (GIT_MAX_ALIGNMENT - 1));
065feab4	95
f87bf284 EN	96	if (pool->mp_block &&
	97	pool->mp_block->end - pool->mp_block->next_free >= len)
	98	p = pool->mp_block;
065feab4 JM	99
065feab4 JM	100	if (!p) {
f87bf284 EN	101	if (len >= (pool->block_alloc / 2))
f87bf284 EN	102	return mem_pool_alloc_block(pool, len, pool->mp_block);
065feab4	103
f87bf284	104	p = mem_pool_alloc_block(pool, pool->block_alloc, NULL);
065feab4 JM	105	}
	106
	107	r = p->next_free;
	108	p->next_free += len;
	109	return r;
	110	}
	111
f87bf284	112	void mem_pool_calloc(struct mem_pool pool, size_t count, size_t size)
065feab4 JM	113	{
065feab4 JM	114	size_t len = st_mult(count, size);
f87bf284	115	void *r = mem_pool_alloc(pool, len);
065feab4 JM	116	memset(r, 0, len);
	117	return r;
	118	}
0e58301d	119
a762c8c1 EN	120	char mem_pool_strdup(struct mem_pool pool, const char *str)
	121	{
	122	size_t len = strlen(str) + 1;
	123	char *ret = mem_pool_alloc(pool, len);
	124
	125	return memcpy(ret, str, len);
	126	}
	127
	128	char mem_pool_strndup(struct mem_pool pool, const char *str, size_t len)
	129	{
	130	char *p = memchr(str, '\0', len);
	131	size_t actual_len = (p ? p - str : len);
	132	char *ret = mem_pool_alloc(pool, actual_len+1);
	133
	134	ret[actual_len] = '\0';
	135	return memcpy(ret, str, actual_len);
	136	}
	137
f87bf284	138	int mem_pool_contains(struct mem_pool pool, void mem)
0e58301d JM	139	{
	140	struct mp_block *p;
	141
	142	/* Check if memory is allocated in a block */
f87bf284	143	for (p = pool->mp_block; p; p = p->next_block)
0e58301d JM	144	if ((mem >= ((void *)p->space)) &&
	145	(mem < ((void *)p->end)))
	146	return 1;
	147
	148	return 0;
	149	}
	150
	151	void mem_pool_combine(struct mem_pool dst, struct mem_pool src)
	152	{
	153	struct mp_block *p;
	154
	155	/* Append the blocks from src to dst */
	156	if (dst->mp_block && src->mp_block) {
	157	/*
	158	* src and dst have blocks, append
	159	* blocks from src to dst.
	160	*/
	161	p = dst->mp_block;
	162	while (p->next_block)
	163	p = p->next_block;
	164
	165	p->next_block = src->mp_block;
	166	} else if (src->mp_block) {
	167	/*
	168	* src has blocks, dst is empty.
	169	*/
	170	dst->mp_block = src->mp_block;
	171	} else {
	172	/* src is empty, nothing to do. */
	173	}
	174
	175	dst->pool_alloc += src->pool_alloc;
	176	src->pool_alloc = 0;
	177	src->mp_block = NULL;
	178	}