/** * slibc — Yet another C library * Copyright © 2015 Mattias Andrée (maandree@member.fsf.org) * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include #include #include #include /* TODO #include */ #include #include /* TODO temporary constants from other headers { */ #define PROT_READ 0 #define PROT_WRITE 0 #define MAP_PRIVATE 0 #define MAP_ANONYMOUS 0 #define _SC_PAGESIZE 0 /* } */ /** * Implementation of `malloc`. */ #define MALLOC(size) memalign(sizeof(max_align_t), size) /** * Create a new memory allocation on the heap. * The allocation will not be initialised. * The returned pointer is unaligned. * * @param size The size of the allocation. * @return Pointer to the beginning of the new allocation. * If `size` is zero, this function will either return * `NULL` (that is what this implement does) or return * a unique pointer that can later be freed with `free`. * `NULL` is returned on error, and `errno` is set to * indicate the error. * * @throws ENOMEM The process cannot allocate more memory. */ static void* unaligned_malloc(size_t size) { char* ptr; size_t full_size; if (size == 0) return NULL; if (__builtin_uaddl_overflow(2 * sizeof(size_t), size, &full_size)) return errno = ENOMEM, NULL; ptr = mmap(NULL, full_size, (PROT_READ | PROT_WRITE), (MAP_PRIVATE | MAP_ANONYMOUS), -1, 0); ((size_t*)ptr)[0] = size; ((size_t*)ptr)[1] = 0; return ptr + 2 * sizeof(size_t); } /** * Create a new memory allocation on the heap. * The allocation will not be initialised. * The returned pointer has an alignment usable * for any compiler-independent intrinsic data type. * * @param size The size of the allocation. * @return Pointer to the beginning of the new allocation. * If `size` is zero, this function will either return * `NULL` (that is what this implement does) or return * a unique pointer that can later be freed with `free`. * `NULL` is returned on error, and `errno` is set to * indicate the error. * * @throws ENOMEM The process cannot allocate more memory. */ void* malloc(size_t size) { return MALLOC(size); } /** * Variant of `malloc` that clears the allocation with zeroes. * * `p = calloc(n, m)` is equivalent to * `(p = malloc(n * m), p ? (explicit_bzero(p, n * m), p) : NULL)` * * @param elem_count The number of elements to allocate. * @param elem_size The size of each element. * @return Pointer to the beginning of the new allocation. * If `elem_count` or `elem_size` is zero, this function * will either return `NULL` (that is what this implement * does) or return a unique pointer that can later be * freed with `free`. `NULL` is returned on error, and * `errno` is set to indicate the error. * * @throws ENOMEM The process cannot allocate more memory. */ void* calloc(size_t elem_count, size_t elem_size) { void* ptr; size_t size; if (__builtin_umull_overflow(elem_count, elem_size, &size)) return errno = ENOMEM, NULL; ptr = MALLOC(size); if (ptr != NULL) explicit_bzero(ptr, size); return ptr; } /** * Variant of `malloc` that conditionally clears the allocation with zeroes. * * This is a Plan 9 from Bell Labs extension. * * @param size The size of the allocation. * @param clear Clear the allocation unless this value is zero. * @return Pointer to the beginning of the new allocation. * If `size` is zero, this function will either return * `NULL` (that is what this implement does) or return * a unique pointer that can later be freed with `free`. * `NULL` is returned on error, and `errno` is set to * indicate the error. * * @throws ENOMEM The process cannot allocate more memory. */ void* mallocz(size_t size, int clear) { void* ptr = MALLOC(size); if ((ptr != NULL) && clear) explicit_bzero(ptr, size); return ptr; } /** * Variant of `malloc` that clears the allocation with zeroes. * * `zalloc(n)` is equivalent to `calloc(1, n)`, or equivalently, * `calloc(n, m)` is equivalent to `zalloc(n * m)` assumming `n * m` * does not overflow (in which case `calloc(n, m)` returns `ENOMEM`.) * * This is a klibc extension. * * @param size The size of the allocation. * @return Pointer to the beginning of the new allocation. * If `size` is zero, this function will either return * `NULL` (that is what this implement does) or return * a unique pointer that can later be freed with `free`. * `NULL` is returned on error, and `errno` is set to * indicate the error. * * @throws ENOMEM The process cannot allocate more memory. */ void* zalloc(size_t size) { void* ptr = MALLOC(size); if (ptr != NULL) explicit_bzero(ptr, size); return ptr; } /** * Variant of `malloc` that extends, or shrinks, an existing allocation, * if beneficial and possible, or creates a new allocation with the new * size, copies the data, and frees the old allocation. The returned * pointer has an alignment usable for any compiler-independent intrinsic * data type, if a new pointer is returned. * * On error, `ptr` is not freed. * * @param ptr Pointer to the beginning of the old memory allocation. * The process may crash if it does not point to the * beginning of a memory allocation on the heap. * However, if it is `NULL`, this function will behave * like `malloc`. * @param size The new allocation size. If zero, this function will * behave like `free`, and will return `NULL`. * @return Pointer to the beginning of the new allocation. * If `size` is zero, `NULL` is returned. On error `NULL` * is returned and `errno` is set to indicate the error. * * @throws ENOMEM The process cannot allocate more memory. */ void* realloc(void* ptr, size_t size) { return fast_realloc(ptr, size); } /** * Free a memory allocation. * * @param ptr Pointer to the beginning of the memory allocation. * The process may crash if it does not point to the * beginning of a memory allocation on the heap. * However, if it is `NULL`, nothing will happen. */ void free(void* ptr) { fast_free(ptr); } /** * This function is identical to `free`. * Any argument beyond the first argument, is ignored. * * This function uses variadic arguments because there * there are multiple conflicting specifications for `cfree`. * * @param ptr Pointer to the beginning of the memory allocation. * The process may crash if it does not point to the * beginning of a memory allocation on the heap. * However, if it is `NULL`, nothing will happen. */ void cfree(void* ptr, ...) { fast_free(ptr); } /** * Variant of `malloc` that returns an address with a * specified alignment. * * It is unspecified how the function works. This implemention * will allocate a bit of extra memory and shift the returned * pointer so that it is aligned. * * As a GNU-compliant slibc extension, memory allocated * with this function can be freed with `free`. * * @param boundary The alignment. * @param size The number of bytes to allocated. * @return Pointer to the beginning of the new allocation. * If `size` is zero, this function will either return * `NULL` (that is what this implement does) or return * a unique pointer that can later be freed with `free`. * `NULL` is returned on error, and `errno` is set to * indicate the error. * * @throws ENOMEM The process cannot allocate more memory. * @throws EINVAL If `boundary` is not a power of two. */ void* memalign(size_t boundary, size_t size) { char* ptr; size_t full_size; size_t address; size_t shift = 0; if (!boundary || (__builtin_ffsl((long int)boundary) != boundary)) /* `size_t` mat not be wider than `long int`. */ return errno = EINVAL, NULL; if (__builtin_uaddl_overflow(boundary - 1, size, &full_size)) return errno = ENOMEM, NULL; ptr = unaligned_malloc(full_size); if (ptr == NULL) return NULL; address = (size_t)ptr; if (address % boundary != 0) { shift = boundary - (address % boundary); ptr += shift; *(size_t*)(ptr - sizeof(size_t)) = shift; } return ptr; } /** * `posix_memalign(p, b, n)` is equivalent to * `(*p = memalign(b, n), *p ? 0 : errno)`, except * `boundary` must also be a multiple of `sizeof(void*)`, * and `errno` is unspecified. * * As a GNU-compliant slibc extension, memory allocated * with this function can be freed with `free`. * * @param ptrptr Output parameter for the allocated memory. * @param boundary The alignment. * @param size The number of bytes to allocated. * @return Zero on success, a value for `errno` on error. * * @throws ENOMEM The process cannot allocate more memory. * @throws EINVAL If `boundary` is not a power-of-two multiple of `sizeof(void*)`. */ int posix_memalign(void** ptrptr, size_t boundary, size_t size) { if (boundary < sizeof(void*)) return EINVAL; *ptrptr = memalign(boundary, size); return *ptrptr ? 0 : errno; } /** * `valloc(n)` is equivalent to `memalign(sysconf(_SC_PAGESIZE), n)`. * * As a GNU-compliant slibc extension, memory allocated * with this function can be freed with `free`. * * @param size The number of bytes to allocated. * @return Pointer to the beginning of the new allocation. * If `size` is zero, this function will either return * `NULL` (that is what this implement does) or return * a unique pointer that can later be freed with `free`. * `NULL` is returned on error, and `errno` is set to * indicate the error. * * @throws ENOMEM The process cannot allocate more memory. */ void* valloc(size_t size) { return memalign((size_t)sysconf(_SC_PAGESIZE), size); } /** * This function works like `valloc`, except the allocation size, * including auxiliary space, is rounded up to the next multiple * of the page size. * * @param size The number of bytes to allocated. * @return Pointer to the beginning of the new allocation. * If `size` is zero, this function will either return * `NULL` (that is what this implement does) or return * a unique pointer that can later be freed with `free`. * `NULL` is returned on error, and `errno` is set to * indicate the error. * * @throws ENOMEM The process cannot allocate more memory. */ void* pvalloc(size_t size) { size_t boundary = (size_t)sysconf(_SC_PAGESIZE); size_t full_size = 2 * sizeof(size_t) + boundary - 1 + size; size_t rounding = 0; if (full_size % boundary != 0) rounding = boundary - (full_size % boundary); if (__builtin_uaddl_overflow(size, rounding, &full_size)) return errno = ENOMEM, NULL; return memalign(boundary, full_size); } /** * This function is identical to `memalign`, * except it can be freed with `free`. * * Variant of `malloc` that returns an address with a * specified alignment. * * It is unspecified how the function works. This implemention * will allocate a bit of extra memory and shift the returned * pointer so that it is aligned. * * @param boundary The alignment. * @param size The number of bytes to allocated. * @return Pointer to the beginning of the new allocation. * If `size` is zero, this function will either return * `NULL` (that is what this implement does) or return * a unique pointer that can later be freed with `free`. * `NULL` is returned on error, and `errno` is set to * indicate the error. * * @throws ENOMEM The process cannot allocate more memory. * @throws EINVAL If `boundary` is not a power of two. */ void* aligned_alloc(size_t boundary, size_t size) { return memalign(boundary, size); } /** * This function returns the allocation size of * a memory segment. * * `p = malloc(n), malloc_usable_size(p)` will return `n`. * * @param segment The memory segment. * @return The size of the memory segment, 0 if `segment` is `NULL`. */ size_t malloc_usable_size(void* segment) { return allocsize(segment); }