#include #include #include #include #include #include #define PAGE_4K_SHIFT 12 #define PAGE_2M_SHIFT 21 #define PAGE_1G_SHIFT 30 #define PAGE_GDT_SHIFT 39 // 不同大小的页的容量 #define PAGE_4K_SIZE (1UL << PAGE_4K_SHIFT) #define PAGE_2M_SIZE (1UL << PAGE_2M_SHIFT) #define PAGE_1G_SIZE (1UL << PAGE_1G_SHIFT) // 屏蔽低于x的数值 #define PAGE_4K_MASK (~(PAGE_4K_SIZE - 1)) #define PAGE_2M_MASK (~(PAGE_2M_SIZE - 1)) // 将addr按照x的上边界对齐 #define PAGE_4K_ALIGN(addr) (((unsigned long)(addr) + PAGE_4K_SIZE - 1) & PAGE_4K_MASK) #define PAGE_2M_ALIGN(addr) (((unsigned long)(addr) + PAGE_2M_SIZE - 1) & PAGE_2M_MASK) /** * @brief 显式链表的结点 * */ typedef struct malloc_mem_chunk_t { uint64_t length; // 整个块所占用的内存区域的大小 struct malloc_mem_chunk_t *prev; // 上一个结点的指针 struct malloc_mem_chunk_t *next; // 下一个结点的指针 } malloc_mem_chunk_t; static uint64_t brk_base_addr = 0; // 堆区域的内存基地址 static uint64_t brk_max_addr = 0; // 堆区域的内存最大地址 static uint64_t brk_managed_addr = 0; // 堆区域已经被管理的地址 // 空闲链表 // 按start_addr升序排序 static malloc_mem_chunk_t *malloc_free_list = NULL; static malloc_mem_chunk_t *malloc_free_list_end = NULL; // 空闲链表的末尾结点 static uint64_t count_last_free_size = 0; // 统计距离上一次回收内存,已经free了多少内存 /** * @brief 将块插入空闲链表 * * @param ck 待插入的块 */ static void malloc_insert_free_list(malloc_mem_chunk_t *ck); /** * @brief 当堆顶空闲空间大于2个页的空间的时候,释放1个页 * */ static void release_brk(); /** * @brief 在链表中检索符合要求的空闲块(best fit) * * @param size 块的大小 * @return malloc_mem_chunk_t* */ static malloc_mem_chunk_t *malloc_query_free_chunk_bf(uint64_t size) { // 在满足best fit的前提下,尽可能的使分配的内存在低地址 // 使得总的堆内存可以更快被释放 if (malloc_free_list == NULL) { return NULL; } malloc_mem_chunk_t *ptr = malloc_free_list; malloc_mem_chunk_t *best = NULL; // printf("query size=%d", size); while (ptr != NULL) { // printf("ptr->length=%#010lx\n", ptr->length); if (ptr->length == size) { best = ptr; break; } if (ptr->length > size) { if (best == NULL) best = ptr; else if (best->length > ptr->length) best = ptr; } ptr = ptr->next; } return best; } /** * @brief 在链表中检索符合要求的空闲块(first fit) * * @param size * @return malloc_mem_chunk_t* */ static malloc_mem_chunk_t *malloc_query_free_chunk_ff(uint64_t size) { if (malloc_free_list == NULL) return NULL; malloc_mem_chunk_t *ptr = malloc_free_list; while (ptr) { if (ptr->length >= size) { return ptr; } ptr = ptr->next; } return NULL; } /** * @brief 扩容malloc管理的内存区域 * * @param size 扩大的内存大小 */ static int malloc_enlarge(int64_t size) { if (brk_base_addr == 0) // 第一次调用,需要初始化 { brk_base_addr = brk(-1); // printf("brk_base_addr=%#018lx\n", brk_base_addr); brk_managed_addr = brk_base_addr; brk_max_addr = brk(-2); } int64_t free_space = brk_max_addr - brk_managed_addr; // printf("size=%ld\tfree_space=%ld\n", size, free_space); if (free_space < size) // 现有堆空间不足 { if (sbrk(size - free_space) != (void *)(-1)) brk_max_addr = brk((-2)); else { put_string("malloc_enlarge(): no_mem\n", COLOR_YELLOW, COLOR_BLACK); return -ENOMEM; } // printf("brk max addr = %#018lx\n", brk_max_addr); } // 扩展管理的堆空间 // 在新分配的内存的底部放置header // printf("managed addr = %#018lx\n", brk_managed_addr); malloc_mem_chunk_t *new_ck = (malloc_mem_chunk_t *)brk_managed_addr; new_ck->length = brk_max_addr - brk_managed_addr; // printf("new_ck->start_addr=%#018lx\tbrk_max_addr=%#018lx\tbrk_managed_addr=%#018lx\n", (uint64_t)new_ck, brk_max_addr, brk_managed_addr); new_ck->prev = NULL; new_ck->next = NULL; brk_managed_addr = brk_max_addr; malloc_insert_free_list(new_ck); return 0; } /** * @brief 合并空闲块 * */ static void malloc_merge_free_chunk() { if (malloc_free_list == NULL) return; malloc_mem_chunk_t *ptr = malloc_free_list->next; while (ptr != NULL) { // 内存块连续 if (((uint64_t)(ptr->prev) + ptr->prev->length == (uint64_t)ptr)) { // printf("merged %#018lx and %#018lx\n", (uint64_t)ptr, (uint64_t)(ptr->prev)); // 将ptr与前面的空闲块合并 ptr->prev->length += ptr->length; ptr->prev->next = ptr->next; if (ptr->next == NULL) malloc_free_list_end = ptr->prev; else ptr->next->prev = ptr->prev; // 由于内存组成结构的原因,不需要free掉header ptr = ptr->prev; } ptr = ptr->next; } } /** * @brief 将块插入空闲链表 * * @param ck 待插入的块 */ static void malloc_insert_free_list(malloc_mem_chunk_t *ck) { if (malloc_free_list == NULL) // 空闲链表为空 { malloc_free_list = ck; malloc_free_list_end = ck; ck->prev = ck->next = NULL; return; } else { malloc_mem_chunk_t *ptr = malloc_free_list; while (ptr != NULL) { if ((uint64_t)ptr < (uint64_t)ck) { if (ptr->next == NULL) // 当前是最后一个项 { ptr->next = ck; ck->next = NULL; ck->prev = ptr; malloc_free_list_end = ck; break; } else if ((uint64_t)(ptr->next) > (uint64_t)ck) { ck->prev = ptr; ck->next = ptr->next; ptr->next = ck; ck->next->prev = ck; break; } } else // 在ptr之前插入 { if (ptr->prev == NULL) // 是第一个项 { malloc_free_list = ck; ck->prev = NULL; ck->next = ptr; ptr->prev = ck; break; } else { ck->prev = ptr->prev; ck->next = ptr; ck->prev->next = ck; ptr->prev = ck; break; } } ptr = ptr->next; } } } /** * @brief 获取一块堆内存 * * @param size 内存大小 * @return void* 内存空间的指针 * * 分配内存的时候,结点的prev next指针所占用的空间被当做空闲空间分配出去 */ void *malloc(ssize_t size) { // printf("malloc\n"); // 计算需要分配的块的大小 if (size + sizeof(uint64_t) <= sizeof(malloc_mem_chunk_t)) size = sizeof(malloc_mem_chunk_t); else size += sizeof(uint64_t); // 采用best fit malloc_mem_chunk_t *ck = malloc_query_free_chunk_bf(size); if (ck == NULL) // 没有空闲块 { // printf("no free blocks\n"); // 尝试合并空闲块 malloc_merge_free_chunk(); ck = malloc_query_free_chunk_bf(size); // 找到了合适的块 if (ck) goto found; // printf("before enlarge\n"); // 找不到合适的块,扩容堆区域 if (malloc_enlarge(size) == -ENOMEM) return (void *)-ENOMEM; // 内存不足 malloc_merge_free_chunk(); // 扩容后运行合并,否则会导致碎片 // 扩容后再次尝试获取 ck = malloc_query_free_chunk_bf(size); } found:; // printf("ck = %#018lx\n", (uint64_t)ck); if (ck == NULL) return (void *)-ENOMEM; // printf("ck->prev=%#018lx ck->next=%#018lx\n", ck->prev, ck->next); // 分配空闲块 // 从空闲链表取出 if (ck->prev == NULL) // 当前是链表的第一个块 { malloc_free_list = ck->next; } else ck->prev->next = ck->next; if (ck->next != NULL) // 当前不是最后一个块 ck->next->prev = ck->prev; else malloc_free_list_end = ck->prev; // 当前块剩余的空间还能容纳多一个结点的空间,则分裂当前块 if ((int64_t)(ck->length) - size > sizeof(malloc_mem_chunk_t)) { // printf("seperate\n"); malloc_mem_chunk_t *new_ck = (malloc_mem_chunk_t *)(((uint64_t)ck) + size); new_ck->length = ck->length - size; new_ck->prev = new_ck->next = NULL; // printf("new_ck=%#018lx, new_ck->length=%#010lx\n", (uint64_t)new_ck, new_ck->length); ck->length = size; malloc_insert_free_list(new_ck); } // printf("malloc done: %#018lx, length=%#018lx\n", ((uint64_t)ck + sizeof(uint64_t)), ck->length); // 此时链表结点的指针的空间被分配出去 return (void *)((uint64_t)ck + sizeof(uint64_t)); } /** * @brief 当堆顶空闲空间大于2个页的空间的时候,释放1个页 * */ static void release_brk() { // 先检测最顶上的块 // 由于块按照开始地址排列,因此找最后一个块 if (malloc_free_list_end == NULL) { printf("release(): free list end is null. \n"); return; } if ((uint64_t)malloc_free_list_end + malloc_free_list_end->length == brk_max_addr && (uint64_t)malloc_free_list_end <= brk_max_addr - (PAGE_2M_SIZE << 1)) { int64_t delta = ((brk_max_addr - (uint64_t)malloc_free_list_end) & PAGE_2M_MASK) - PAGE_2M_SIZE; // printf("(brk_max_addr - (uint64_t)malloc_free_list_end) & PAGE_2M_MASK=%#018lx\n ", (brk_max_addr - (uint64_t)malloc_free_list_end) & PAGE_2M_MASK); // printf("PAGE_2M_SIZE=%#018lx\n", PAGE_2M_SIZE); // printf("tdfghgbdfggkmfn=%#018lx\n ", (brk_max_addr - (uint64_t)malloc_free_list_end) & PAGE_2M_MASK - PAGE_2M_SIZE); // printf("delta=%#018lx\n ", delta); if (delta <= 0) // 不用释放内存 return; sbrk(-delta); brk_max_addr = brk(-2); brk_managed_addr = brk_max_addr; malloc_free_list_end->length = brk_max_addr - (uint64_t)malloc_free_list_end; } } /** * @brief 释放一块堆内存 * * @param ptr 堆内存的指针 */ void free(void *ptr) { // 找到结点(此时prev和next都处于未初始化的状态) malloc_mem_chunk_t *ck = (malloc_mem_chunk_t *)((uint64_t)ptr - sizeof(uint64_t)); // printf("free(): addr = %#018lx\t len=%#018lx\n", (uint64_t)ck, ck->length); count_last_free_size += ck->length; malloc_insert_free_list(ck); if (count_last_free_size > PAGE_2M_SIZE) { count_last_free_size = 0; malloc_merge_free_chunk(); release_brk(); } }