/* * Copyright (c) 2008 Travis Geiselbrecht * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files * (the "Software"), to deal in the Software without restriction, * including without limitation the rights to use, copy, modify, merge, * publish, distribute, sublicense, and/or sell copies of the Software, * and to permit persons to whom the Software is furnished to do so, * subject to the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include #include #include #include #include #include #include #define LOCAL_TRACE 0 #define ROUNDUP(a, b) (((a) + ((b)-1)) & ~((b)-1)) #define HEAP_MAGIC 'HEAP' #if WITH_STATIC_HEAP #if !defined(HEAP_START) || !defined(HEAP_LEN) #error WITH_STATIC_HEAP set but no HEAP_START or HEAP_LEN defined #endif #else // end of the binary extern int _end; // end of memory extern int _end_of_ram; #define HEAP_START ((unsigned long)&_end) #define HEAP_LEN ((size_t)&_end_of_ram - (size_t)&_end) #endif struct free_heap_chunk { struct list_node node; size_t len; }; struct heap { void *base; size_t len; struct list_node free_list; }; // heap static vars static struct heap theheap; // structure placed at the beginning every allocation struct alloc_struct_begin { unsigned int magic; void *ptr; size_t size; }; static void dump_free_chunk(struct free_heap_chunk *chunk) { dprintf(INFO, "\t\tbase %p, end 0x%lx, len 0x%zx\n", chunk, (vaddr_t)chunk + chunk->len, chunk->len); } static void heap_dump(void) { dprintf(INFO, "Heap dump:\n"); dprintf(INFO, "\tbase %p, len 0x%zx\n", theheap.base, theheap.len); dprintf(INFO, "\tfree list:\n"); struct free_heap_chunk *chunk; list_for_every_entry(&theheap.free_list, chunk, struct free_heap_chunk, node) { dump_free_chunk(chunk); } } static void heap_test(void) { void *ptr[16]; ptr[0] = heap_alloc(8, 0); ptr[1] = heap_alloc(32, 0); ptr[2] = heap_alloc(7, 0); ptr[3] = heap_alloc(0, 0); ptr[4] = heap_alloc(98713, 0); ptr[5] = heap_alloc(16, 0); heap_free(ptr[5]); heap_free(ptr[1]); heap_free(ptr[3]); heap_free(ptr[0]); heap_free(ptr[4]); heap_free(ptr[2]); heap_dump(); int i; for (i=0; i < 16; i++) ptr[i] = 0; for (i=0; i < 32768; i++) { unsigned int index = (unsigned int)rand() % 16; if ((i % (16*1024)) == 0) printf("pass %d\n", i); // printf("index 0x%x\n", index); if (ptr[index]) { // printf("freeing ptr[0x%x] = %p\n", index, ptr[index]); heap_free(ptr[index]); ptr[index] = 0; } unsigned int align = 1 << ((unsigned int)rand() % 8); ptr[index] = heap_alloc((unsigned int)rand() % 32768, align); // printf("ptr[0x%x] = %p, align 0x%x\n", index, ptr[index], align); DEBUG_ASSERT(((addr_t)ptr[index] % align) == 0); // heap_dump(); } for (i=0; i < 16; i++) { if (ptr[i]) heap_free(ptr[i]); } heap_dump(); } // try to insert this free chunk into the free list, consuming the chunk by merging it with // nearby ones if possible. Returns base of whatever chunk it became in the list. static struct free_heap_chunk *heap_insert_free_chunk(struct free_heap_chunk *chunk) { #if DEBUGLEVEL > INFO vaddr_t chunk_end = (vaddr_t)chunk + chunk->len; #endif // dprintf("%s: chunk ptr %p, size 0x%lx, chunk_end 0x%x\n", __FUNCTION__, chunk, chunk->len, chunk_end); struct free_heap_chunk *next_chunk; struct free_heap_chunk *last_chunk; // walk through the list, finding the node to insert before list_for_every_entry(&theheap.free_list, next_chunk, struct free_heap_chunk, node) { if (chunk < next_chunk) { DEBUG_ASSERT(chunk_end <= (vaddr_t)next_chunk); list_add_before(&next_chunk->node, &chunk->node); goto try_merge; } } // walked off the end of the list, add it at the tail list_add_tail(&theheap.free_list, &chunk->node); // try to merge with the previous chunk try_merge: last_chunk = list_prev_type(&theheap.free_list, &chunk->node, struct free_heap_chunk, node); if (last_chunk) { if ((vaddr_t)last_chunk + last_chunk->len == (vaddr_t)chunk) { // easy, just extend the previous chunk last_chunk->len += chunk->len; // remove ourself from the list list_delete(&chunk->node); // set the chunk pointer to the newly extended chunk, in case // it needs to merge with the next chunk below chunk = last_chunk; } } // try to merge with the next chunk if (next_chunk) { if ((vaddr_t)chunk + chunk->len == (vaddr_t)next_chunk) { // extend our chunk chunk->len += next_chunk->len; // remove them from the list list_delete(&next_chunk->node); } } return chunk; } struct free_heap_chunk *heap_create_free_chunk(void *ptr, size_t len) { DEBUG_ASSERT((len % sizeof(void *)) == 0); // size must be aligned on pointer boundary struct free_heap_chunk *chunk = (struct free_heap_chunk *)ptr; chunk->len = len; return chunk; } void *heap_alloc(size_t size, unsigned int alignment) { void *ptr; LTRACEF("size %zd, align %d\n", size, alignment); // alignment must be power of 2 if (alignment & (alignment - 1)) return NULL; // we always put a size field + base pointer + magic in front of the allocation size += sizeof(struct alloc_struct_begin); // make sure we allocate at least the size of a struct free_heap_chunk so that // when we free it, we can create a struct free_heap_chunk struct and stick it // in the spot if (size < sizeof(struct free_heap_chunk)) size = sizeof(struct free_heap_chunk); // round up size to a multiple of native pointer size size = ROUNDUP(size, sizeof(void *)); // deal with nonzero alignments if (alignment > 0) { if (alignment < 16) alignment = 16; // add alignment for worst case fit size += alignment; } // critical section enter_critical_section(); // walk through the list ptr = NULL; struct free_heap_chunk *chunk; list_for_every_entry(&theheap.free_list, chunk, struct free_heap_chunk, node) { DEBUG_ASSERT((chunk->len % sizeof(void *)) == 0); // len should always be a multiple of pointer size // is it big enough to service our allocation? if (chunk->len >= size) { ptr = chunk; // remove it from the list struct list_node *next_node = list_next(&theheap.free_list, &chunk->node); list_delete(&chunk->node); if (chunk->len > size + sizeof(struct free_heap_chunk)) { // there's enough space in this chunk to create a new one after the allocation struct free_heap_chunk *newchunk = heap_create_free_chunk((uint8_t *)ptr + size, chunk->len - size); // truncate this chunk chunk->len -= chunk->len - size; // add the new one where chunk used to be if (next_node) list_add_before(next_node, &newchunk->node); else list_add_tail(&theheap.free_list, &newchunk->node); } // the allocated size is actually the length of this chunk, not the size requested DEBUG_ASSERT(chunk->len >= size); size = chunk->len; ptr = (void *)((addr_t)ptr + sizeof(struct alloc_struct_begin)); // align the output if requested if (alignment > 0) { ptr = (void *)ROUNDUP((addr_t)ptr, alignment); } struct alloc_struct_begin *as = (struct alloc_struct_begin *)ptr; as--; as->magic = HEAP_MAGIC; as->ptr = (void *)chunk; as->size = size; break; } } LTRACEF("returning ptr %p\n", ptr); // heap_dump(); exit_critical_section(); return ptr; } void heap_free(void *ptr) { if (ptr == 0) return; LTRACEF("ptr %p\n", ptr); // check for the old allocation structure struct alloc_struct_begin *as = (struct alloc_struct_begin *)ptr; as--; DEBUG_ASSERT(as->magic == HEAP_MAGIC); LTRACEF("allocation was %zd bytes long at ptr %p\n", as->size, as->ptr); // looks good, create a free chunk and add it to the pool enter_critical_section(); heap_insert_free_chunk(heap_create_free_chunk(as->ptr, as->size)); exit_critical_section(); // heap_dump(); } void heap_init(void) { LTRACE_ENTRY; // set the heap range theheap.base = (void *)HEAP_START; theheap.len = HEAP_LEN; LTRACEF("base %p size %zd bytes\n", theheap.base, theheap.len); // initialize the free list list_initialize(&theheap.free_list); // create an initial free chunk heap_insert_free_chunk(heap_create_free_chunk(theheap.base, theheap.len)); // dump heap info // heap_dump(); // dprintf(INFO, "running heap tests\n"); // heap_test(); } #if DEBUGLEVEL > 1 #if WITH_LIB_CONSOLE #include static int cmd_heap(int argc, const cmd_args *argv); STATIC_COMMAND_START { "heap", "heap debug commands", &cmd_heap }, STATIC_COMMAND_END(heap); static int cmd_heap(int argc, const cmd_args *argv) { if (argc < 2) { printf("not enough arguments\n"); return -1; } if (strcmp(argv[1].str, "info") == 0) { heap_dump(); } else { printf("unrecognized command\n"); return -1; } return 0; } #endif #endif