#include "rsync.h" #define POOL_DEF_EXTENT (32 * 1024) struct alloc_pool { size_t size; /* extent size */ size_t quantum; /* allocation quantum */ struct pool_extent *live; /* current extent for * allocations */ struct pool_extent *free; /* unfreed extent list */ void (*bomb)(); /* function to call if * malloc fails */ int flags; /* statistical data */ unsigned long e_created; /* extents created */ unsigned long e_freed; /* extents detroyed */ uint64 n_allocated; /* calls to alloc */ uint64 n_freed; /* calls to free */ uint64 b_allocated; /* cum. bytes allocated */ uint64 b_freed; /* cum. bytes freed */ }; struct pool_extent { void *start; /* starting address */ size_t free; /* free bytecount */ size_t bound; /* bytes bound by padding, * overhead and freed */ struct pool_extent *next; }; struct align_test { void *foo; uint64 bar; }; #define MINALIGN offsetof(struct align_test, bar) /* Temporarily cast a void* var into a char* var when adding an offset (to * keep some compilers from complaining about the pointer arithmetic). */ #define PTR_ADD(b,o) ( (void*) ((char*)(b) + (o)) ) alloc_pool_t pool_create(size_t size, size_t quantum, void (*bomb)(char *), int flags) { struct alloc_pool *pool; if (!(pool = (struct alloc_pool*) malloc(sizeof (struct alloc_pool)))) return pool; memset(pool, 0, sizeof (struct alloc_pool)); pool->size = size /* round extent size to min alignment reqs */ ? (size + MINALIGN - 1) & ~(MINALIGN - 1) : POOL_DEF_EXTENT; if (pool->flags & POOL_INTERN) { pool->size -= sizeof (struct pool_extent); flags |= POOL_APPEND; } pool->quantum = quantum ? quantum : MINALIGN; pool->bomb = bomb; pool->flags = flags; return pool; } void pool_destroy(alloc_pool_t p) { struct alloc_pool *pool = (struct alloc_pool *) p; struct pool_extent *cur, *next; if (!pool) return; if (pool->live) { cur = pool->live; free(cur->start); if (!(pool->flags & POOL_APPEND)) free(cur); } for (cur = pool->free; cur; cur = next) { next = cur->next; free(cur->start); if (!(pool->flags & POOL_APPEND)) free(cur); } free(pool); } void * pool_alloc(alloc_pool_t p, size_t len, char *bomb) { struct alloc_pool *pool = (struct alloc_pool *) p; if (!pool) return NULL; if (!len) len = pool->quantum; else if (pool->quantum > 1 && len % pool->quantum) len += pool->quantum - len % pool->quantum; if (len > pool->size) goto bomb; if (!pool->live || len > pool->live->free) { void *start; size_t free; size_t bound; size_t sqew; size_t asize; if (pool->live) { pool->live->next = pool->free; pool->free = pool->live; } free = pool->size; bound = 0; asize = pool->size; if (pool->flags & POOL_APPEND) asize += sizeof (struct pool_extent); if (!(start = (void *) malloc(asize))) goto bomb; if (pool->flags & POOL_CLEAR) memset(start, 0, pool->size); if (pool->flags & POOL_APPEND) { pool->live = PTR_ADD(start, free); } else if (!(pool->live = (struct pool_extent *) malloc(sizeof (struct pool_extent)))) { goto bomb; } if (pool->flags & POOL_QALIGN && pool->quantum > 1 && (sqew = (size_t)PTR_ADD(start, free) % pool->quantum)) { bound += sqew; free -= sqew; } pool->live->start = start; pool->live->free = free; pool->live->bound = bound; pool->live->next = NULL; pool->e_created++; } pool->n_allocated++; pool->b_allocated += len; pool->live->free -= len; return PTR_ADD(pool->live->start, pool->live->free); bomb: if (pool->bomb) (*pool->bomb)(bomb); return NULL; } void pool_free(alloc_pool_t p, size_t len, void *addr) { struct alloc_pool *pool = (struct alloc_pool *) p; struct pool_extent *cur; struct pool_extent *prev; if (!pool) return; if (!len) len = pool->quantum; else if (pool->quantum > 1 && len % pool->quantum) len += pool->quantum - len % pool->quantum; if (!addr && pool->live) { pool->live->next = pool->free; pool->free = pool->live; pool->live = NULL; return; } pool->n_freed++; pool->b_freed += len; cur = pool->live; if (cur && addr >= cur->start && addr < PTR_ADD(cur->start, pool->size)) { if (addr == PTR_ADD(cur->start, cur->free)) { if (pool->flags & POOL_CLEAR) memset(addr, 0, len); pool->b_freed += len; } else { cur->bound += len; } if (cur->free + cur->bound >= pool->size) { size_t sqew; cur->free = pool->size; cur->bound = 0; if (pool->flags & POOL_QALIGN && pool->quantum > 1 && (sqew = (size_t)PTR_ADD(cur->start, cur->free) % pool->quantum)) { cur->bound += sqew; cur->free -= sqew; } } return; } for (prev = NULL, cur = pool->free; cur; prev = cur, cur = cur->next) { if (addr >= cur->start && addr < PTR_ADD(cur->start, pool->size)) break; } if (!cur) return; if (prev) { prev->next = cur->next; cur->next = pool->free; pool->free = cur; } cur->bound += len; if (cur->free + cur->bound >= pool->size) { pool->free = cur->next; free(cur->start); if (!(pool->flags & POOL_APPEND)) free(cur); pool->e_freed++; } return; } #define FDPRINT(label, value) \ snprintf(buf, BUFSIZ, label, value), \ write(fd, buf, strlen(buf)); #define FDEXTSTAT(ext) \ snprintf(buf, BUFSIZ, " %12ld %5ld\n", \ (long) ext->free, \ (long) ext->bound), \ write(fd, buf, strlen(buf)) void pool_stats(alloc_pool_t p, int fd, int summarize) { struct alloc_pool *pool = (struct alloc_pool *) p; struct pool_extent *cur; char buf[BUFSIZ]; if (!pool) return; FDPRINT(" Extent size: %12ld\n", (long) pool->size); FDPRINT(" Alloc quantum: %12ld\n", (long) pool->quantum); FDPRINT(" Extents created: %12ld\n", pool->e_created); FDPRINT(" Extents freed: %12ld\n", pool->e_freed); FDPRINT(" Alloc count: %12.0f\n", (double) pool->n_allocated); FDPRINT(" Free Count: %12.0f\n", (double) pool->n_freed); FDPRINT(" Alloc bytes: %12.0f\n", (double) pool->b_allocated); FDPRINT(" Free bytes: %12.0f\n", (double) pool->b_freed); if (summarize) return; if (!pool->live && !pool->free) return; write(fd, "\n", 1); if (pool->live) { FDEXTSTAT(pool->live); } strcpy(buf, " FREE BOUND\n"); write(fd, buf, strlen(buf)); for (cur = pool->free; cur; cur = cur->next) { FDEXTSTAT(cur); } }