#include #include #include "mem.h" #include "align.h" #define PADD(p, a) (((char*)p) + a) // {{{ mem struct _xc_block_t { #ifdef ALLOC_DEBUG unsigned int magic; #endif xc_memsize_t size; /* reserved even after alloc */ xc_block_t *next; /* not used after alloc */ }; struct _xc_mem_t { xc_memsize_t size; xc_memsize_t avail; /* total free */ xc_block_t headblock[1]; /* just as a pointer to first block*/ }; #ifndef offsetof # define offsetof(type, field) ((int) ((char *) &((type *) 0)->field)) #endif #define SizeOf(type, field) sizeof( ((type *) 0)->field ) #define BLOCK_HEADER_SIZE() (ALIGN( offsetof(xc_block_t, size) + SizeOf(xc_block_t, size) )) #define BLOCK_MAGIC ((unsigned int) 0x87655678) /* }}} */ static inline void xc_block_setup(xc_block_t *b, xc_memsize_t size, xc_block_t *next) /* {{{ */ { #ifdef ALLOC_DEBUG b->magic = BLOCK_MAGIC; #endif b->size = size; b->next = next; } /* }}} */ #ifdef ALLOC_DEBUG static void xc_block_check(xc_block_t *b) /* {{{ */ { if (b->magic != BLOCK_MAGIC) { fprintf(stderr, "0x%X != 0x%X magic wrong \n", b->magic, BLOCK_MAGIC); } } /* }}} */ #else # define xc_block_check(b) do { } while(0) #endif void *xc_mem_malloc(xc_mem_t *mem, xc_memsize_t size) /* {{{ */ { xc_block_t *prev, *cur; xc_block_t *newb, *b; xc_memsize_t realsize; xc_memsize_t minsize; void *p; /* [xc_block_t:size|size] */ realsize = BLOCK_HEADER_SIZE() + size; /* realsize is ALIGNed so next block start at ALIGNed address */ realsize = ALIGN(realsize); do { p = NULL; if (mem->avail < realsize) { break; } b = NULL; minsize = INT_MAX; /* prev|cur */ for (prev = mem->headblock; prev->next; prev = cur) { /* while (prev->next != 0) { */ cur = prev->next; xc_block_check(cur); if (cur->size == realsize) { /* found a perfect fit, stop searching */ b = prev; break; } /* make sure we can split on the block */ else if (cur->size > (sizeof(xc_block_t) + realsize) && cur->size < minsize) { /* cur is acceptable and memller */ b = prev; minsize = cur->size; } prev = cur; } if (b == NULL) { break; } prev = b; cur = prev->next; p = PADD(cur, BLOCK_HEADER_SIZE()); /* update the block header */ mem->avail -= realsize; /*perfect fit, just unlink */ if (cur->size == realsize) { prev->next = cur->next; break; } /* make new free block after alloced space */ /* save, as it might be overwrited by newb (cur->size is ok) */ b = cur->next; /* prev|cur |next=b */ newb = (xc_block_t *)PADD(cur, realsize); xc_block_setup(newb, cur->size - realsize, b); cur->size = realsize; /* prev|cur|newb|next * `--^ */ #ifdef ALLOC_DEBUG fprintf(stderr, "avail: %d (%dKB). size: %d %d (%dKB) new next: %p offset: %d %dKB\n" , mem->avail, mem->avail/1024 , size , realsize, realsize/1024 , newb , ((char*)newb - mem->rw), ((char*)newb - mem->rw) / 1024 ); #endif prev->next = newb; /* prev|cur|newb|next * `-----^ */ } while (0); return p; } /* }}} */ int xc_mem_free(xc_mem_t *mem, const void *p) /* {{{ return block size freed */ { xc_block_t *cur, *b; int size; cur = (xc_block_t *) (((char *) p) - BLOCK_HEADER_SIZE()); xc_block_check(cur); assert((char*)mem < (char*)cur && (char*)cur < (char*)mem + mem->size); /* find free block right before the p */ b = mem->headblock; while (b->next != 0 && b->next < cur) { b = b->next; } /* restore block */ cur->next = b->next; b->next = cur; size = cur->size; mem->avail += size; /* combine prev|cur */ if (PADD(b, b->size) == (char *)cur) { b->size += cur->size; b->next = cur->next; cur = b; } /* combine cur|next */ b = cur->next; if (PADD(cur, cur->size) == (char *)b) { cur->size += b->size; cur->next = b->next; } return size; } /* }}} */ void *xc_mem_calloc(xc_mem_t *mem, xc_memsize_t memb, xc_memsize_t size) /* {{{ */ { xc_memsize_t realsize = memb * size; void *p = xc_mem_malloc(mem, realsize); memset(p, 0, realsize); return p; } /* }}} */ void *xc_mem_realloc(xc_mem_t *mem, const void *p, xc_memsize_t size) /* {{{ */ { void *newp = xc_mem_malloc(mem, size); memcpy(newp, p, size); xc_mem_free(mem, p); return newp; } /* }}} */ char *xc_mem_strndup(xc_mem_t *mem, const char *str, xc_memsize_t len) /* {{{ */ { void *p = xc_mem_malloc(mem, len + 1); memcpy(p, str, len + 1); return p; } /* }}} */ char *xc_mem_strdup(xc_mem_t *mem, const char *str) /* {{{ */ { return xc_mem_strndup(mem, str, strlen(str)); } /* }}} */ xc_memsize_t xc_mem_avail(xc_mem_t *mem) /* {{{ */ { return mem->avail; } /* }}} */ xc_memsize_t xc_mem_size(xc_mem_t *mem) /* {{{ */ { return mem->size; } /* }}} */ const xc_block_t *xc_mem_freeblock_first(xc_mem_t *mem) /* {{{ */ { return mem->headblock->next; } /* }}} */ const xc_block_t *xc_mem_freeblock_next(const xc_block_t *block) /* {{{ */ { return block->next; } /* }}} */ xc_memsize_t xc_mem_block_size(const xc_block_t *block) /* {{{ */ { return block->size; } /* }}} */ xc_memsize_t xc_mem_block_offset(const xc_mem_t *mem, const xc_block_t *block) /* {{{ */ { return ((char *) block) - ((char *) mem); } /* }}} */ xc_mem_t *xc_mem_init(void *ptr, xc_memsize_t size) /* {{{ */ { xc_mem_t *mem = (xc_mem_t *) ptr; xc_block_t *b; mem->size = size; mem->avail = size - ALIGN(sizeof(xc_mem_t)); /* pointer to first block */ b = mem->headblock; xc_block_setup(b, 0, (xc_block_t *)(mem + ALIGN(sizeof(xc_mem_t)))); /* first block*/ b = b->next; xc_block_setup(b, mem->avail, 0); return mem; } /* }}} */ void xc_mem_destroy(xc_mem_t *mem) /* {{{ */ { } /* }}} */