Mercurial > MadButterfly
view src/tools.c @ 930:30cd14b11bc7
USe the graphics from the Max.
author | wycc |
---|---|
date | Sat, 06 Nov 2010 00:53:59 +0800 |
parents | 586e50f82c1f |
children |
line wrap: on
line source
// -*- indent-tabs-mode: t; tab-width: 8; c-basic-offset: 4; -*- // vim: sw=4:ts=8:sts=4 #include <stdlib.h> #include "mb_tools.h" /*! \brief Small fixed size data elements management. * * It is used to management a large number of data elements * they with the same memory size, a fixed size. It allocate * a large block for a lot of elements a time for more efficiency * utilization of memory. * * Elements with the size and in a large number usually be accessed * very close in time. Allocate a large block for elements also * increase cache hit rate. * * Blocks are keep track as a linking list. They are freed when * the elmpool_t is freed. It costs overhead of size of a element * for each block. We use memory of first element of blocks to * be next pointer of linking list. So, it can not be used by user * code. */ struct _elmpool { int elm_sz; int inc_num; void *frees; void *blks; /* list of allocated blocks. */ }; /*! \brief Create a new data elements pool. * * elmpool_t provide a pool of fixed size elements to gain better * utilization of memory. It try to allocate bigger memory blocks * for multiple elements. * * \param elm_sz size of elements. * \param inc_num is number of elments to allocate every time. (>= 16) * \return A elmpool or NULL for error. */ elmpool_t *elmpool_new(int elm_sz, int inc_num) { int _elm_sz; elmpool_t *pool; if(inc_num < 16) return NULL; if(elm_sz >= sizeof(void *)) _elm_sz = elm_sz; else _elm_sz = sizeof(void *); pool = (elmpool_t *)malloc(sizeof(elmpool_t)); if(pool == NULL) return NULL; pool->elm_sz = _elm_sz; if(inc_num == 0) inc_num = 256; pool->inc_num = inc_num; pool->frees = NULL; pool->blks = NULL; return pool; } void *elmpool_elm_alloc(elmpool_t *pool) { void *blk, *elm; int elm_sz, inc_num; int i; if(pool->frees == NULL) { inc_num = pool->inc_num; elm_sz = pool->elm_sz; blk = malloc(elm_sz * inc_num); if(blk == NULL) return NULL; *(void **)blk = pool->blks; pool->blks = blk; blk = blk + elm_sz; pool->frees = blk; for(i = 2; i < inc_num; i++) { *(void **)blk = blk + elm_sz; blk = *(void **)blk; } *(void **)blk = NULL; } elm = pool->frees; pool->frees = *(void **)elm; return elm; } void elmpool_elm_free(elmpool_t *pool, void *elm) { *(void **)elm = pool->frees; pool->frees = elm; } void elmpool_free(elmpool_t *pool) { void *blk, *next_blk; blk = pool->blks; while(blk) { next_blk = *(void **)blk; free(blk); blk = next_blk; } } #ifdef UNITTEST #include <CUnit/Basic.h> void test_elmpool(void) { elmpool_t *pool; void *elm; int i; pool = elmpool_new(64, 16); for(i = 0; i < 15; i++) { elm = elmpool_elm_alloc(pool); CU_ASSERT(elm != NULL); } CU_ASSERT(pool->frees == NULL); for(i = 0; i < 15; i++) { elm = elmpool_elm_alloc(pool); CU_ASSERT(elm != NULL); } CU_ASSERT(pool->frees == NULL); elmpool_elm_free(pool, elm); CU_ASSERT(pool->frees == elm); elm = elmpool_elm_alloc(pool); CU_ASSERT(elm != NULL); CU_ASSERT(pool->frees == NULL); elmpool_free(pool); } CU_pSuite get_tools_suite(void) { CU_pSuite suite; suite = CU_add_suite("Suite_tools", NULL, NULL); CU_ADD_TEST(suite, test_elmpool); return suite; } #endif /* UNITTEST */