/* * Copyright © 2010 Intel Corporation * * 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 (including the next * paragraph) 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 /* Some versions of MinGW are missing _vscprintf's declaration, although they * still provide the symbol in the import library. */ #ifdef __MINGW32__ _CRTIMP int _vscprintf(const char *format, va_list argptr); #endif #include "ralloc.h" #ifndef va_copy #ifdef __va_copy #define va_copy(dest, src) __va_copy((dest), (src)) #else #define va_copy(dest, src) (dest) = (src) #endif #endif #define CANARY 0x5A1106 /* Align the header's size so that ralloc() allocations will return with the * same alignment as a libc malloc would have (8 on 32-bit GLIBC, 16 on * 64-bit), avoiding performance penalities on x86 and alignment faults on * ARM. */ struct #ifdef _MSC_VER __declspec(align(8)) #elif defined(__LP64__) __attribute__((aligned(16))) #else __attribute__((aligned(8))) #endif ralloc_header { #ifdef DEBUG /* A canary value used to determine whether a pointer is ralloc'd. */ unsigned canary; #endif struct ralloc_header *parent; /* The first child (head of a linked list) */ struct ralloc_header *child; /* Linked list of siblings */ struct ralloc_header *prev; struct ralloc_header *next; void (*destructor)(void *); }; typedef struct ralloc_header ralloc_header; static void unlink_block(ralloc_header *info); static void unsafe_free(ralloc_header *info); static ralloc_header * get_header(const void *ptr) { ralloc_header *info = (ralloc_header *) (((char *) ptr) - sizeof(ralloc_header)); #ifdef DEBUG assert(info->canary == CANARY); #endif return info; } #define PTR_FROM_HEADER(info) (((char *) info) + sizeof(ralloc_header)) static void add_child(ralloc_header *parent, ralloc_header *info) { if (parent != NULL) { info->parent = parent; info->next = parent->child; parent->child = info; if (info->next != NULL) info->next->prev = info; } } void * ralloc_context(const void *ctx) { return ralloc_size(ctx, 0); } void * ralloc_size(const void *ctx, size_t size) { void *block = malloc(size + sizeof(ralloc_header)); ralloc_header *info; ralloc_header *parent; if (unlikely(block == NULL)) return NULL; info = (ralloc_header *) block; /* measurements have shown that calloc is slower (because of * the multiplication overflow checking?), so clear things * manually */ info->parent = NULL; info->child = NULL; info->prev = NULL; info->next = NULL; info->destructor = NULL; parent = ctx != NULL ? get_header(ctx) : NULL; add_child(parent, info); #ifdef DEBUG info->canary = CANARY; #endif return PTR_FROM_HEADER(info); } void * rzalloc_size(const void *ctx, size_t size) { void *ptr = ralloc_size(ctx, size); if (likely(ptr)) memset(ptr, 0, size); return ptr; } /* helper function - assumes ptr != NULL */ static void * resize(void *ptr, size_t size) { ralloc_header *child, *old, *info; old = get_header(ptr); info = realloc(old, size + sizeof(ralloc_header)); if (info == NULL) return NULL; /* Update parent and sibling's links to the reallocated node. */ if (info != old && info->parent != NULL) { if (info->parent->child == old) info->parent->child = info; if (info->prev != NULL) info->prev->next = info; if (info->next != NULL) info->next->prev = info; } /* Update child->parent links for all children */ for (child = info->child; child != NULL; child = child->next) child->parent = info; return PTR_FROM_HEADER(info); } void * reralloc_size(const void *ctx, void *ptr, size_t size) { if (unlikely(ptr == NULL)) return ralloc_size(ctx, size); assert(ralloc_parent(ptr) == ctx); return resize(ptr, size); } void * ralloc_array_size(const void *ctx, size_t size, unsigned count) { if (count > SIZE_MAX/size) return NULL; return ralloc_size(ctx, size * count); } void * rzalloc_array_size(const void *ctx, size_t size, unsigned count) { if (count > SIZE_MAX/size) return NULL; return rzalloc_size(ctx, size * count); } void * reralloc_array_size(const void *ctx, void *ptr, size_t size, unsigned count) { if (count > SIZE_MAX/size) return NULL; return reralloc_size(ctx, ptr, size * count); } void ralloc_free(void *ptr) { ralloc_header *info; if (ptr == NULL) return; info = get_header(ptr); unlink_block(info); unsafe_free(info); } static void unlink_block(ralloc_header *info) { /* Unlink from parent & siblings */ if (info->parent != NULL) { if (info->parent->child == info) info->parent->child = info->next; if (info->prev != NULL) info->prev->next = info->next; if (info->next != NULL) info->next->prev = info->prev; } info->parent = NULL; info->prev = NULL; info->next = NULL; } static void unsafe_free(ralloc_header *info) { /* Recursively free any children...don't waste time unlinking them. */ ralloc_header *temp; while (info->child != NULL) { temp = info->child; info->child = temp->next; unsafe_free(temp); } /* Free the block itself. Call the destructor first, if any. */ if (info->destructor != NULL) info->destructor(PTR_FROM_HEADER(info)); free(info); } void ralloc_steal(const void *new_ctx, void *ptr) { ralloc_header *info, *parent; if (unlikely(ptr == NULL)) return; info = get_header(ptr); parent = get_header(new_ctx); unlink_block(info); add_child(parent, info); } void ralloc_adopt(const void *new_ctx, void *old_ctx) { ralloc_header *new_info, *old_info, *child; if (unlikely(old_ctx == NULL)) return; old_info = get_header(old_ctx); new_info = get_header(new_ctx); /* If there are no children, bail. */ if (unlikely(old_info->child == NULL)) return; /* Set all the children's parent to new_ctx; get a pointer to the last child. */ for (child = old_info->child; child->next != NULL; child = child->next) { child->parent = new_info; } child->parent = new_info; /* Connect the two lists together; parent them to new_ctx; make old_ctx empty. */ child->next = new_info->child; if (child->next) child->next->prev = child; new_info->child = old_info->child; old_info->child = NULL; } void * ralloc_parent(const void *ptr) { ralloc_header *info; if (unlikely(ptr == NULL)) return NULL; info = get_header(ptr); return info->parent ? PTR_FROM_HEADER(info->parent) : NULL; } void ralloc_set_destructor(const void *ptr, void(*destructor)(void *)) { ralloc_header *info = get_header(ptr); info->destructor = destructor; } char * ralloc_strdup(const void *ctx, const char *str) { size_t n; char *ptr; if (unlikely(str == NULL)) return NULL; n = strlen(str); ptr = ralloc_array(ctx, char, n + 1); memcpy(ptr, str, n); ptr[n] = '\0'; return ptr; } char * ralloc_strndup(const void *ctx, const char *str, size_t max) { size_t n; char *ptr; if (unlikely(str == NULL)) return NULL; n = strnlen(str, max); ptr = ralloc_array(ctx, char, n + 1); memcpy(ptr, str, n); ptr[n] = '\0'; return ptr; } /* helper routine for strcat/strncat - n is the exact amount to copy */ static bool cat(char **dest, const char *str, size_t n) { char *both; size_t existing_length; assert(dest != NULL && *dest != NULL); existing_length = strlen(*dest); both = resize(*dest, existing_length + n + 1); if (unlikely(both == NULL)) return false; memcpy(both + existing_length, str, n); both[existing_length + n] = '\0'; *dest = both; return true; } bool ralloc_strcat(char **dest, const char *str) { return cat(dest, str, strlen(str)); } bool ralloc_strncat(char **dest, const char *str, size_t n) { return cat(dest, str, strnlen(str, n)); } bool ralloc_str_append(char **dest, const char *str, size_t existing_length, size_t str_size) { char *both; assert(dest != NULL && *dest != NULL); both = resize(*dest, existing_length + str_size + 1); if (unlikely(both == NULL)) return false; memcpy(both + existing_length, str, str_size); both[existing_length + str_size] = '\0'; *dest = both; return true; } char * ralloc_asprintf(const void *ctx, const char *fmt, ...) { char *ptr; va_list args; va_start(args, fmt); ptr = ralloc_vasprintf(ctx, fmt, args); va_end(args); return ptr; } /* Return the length of the string that would be generated by a printf-style * format and argument list, not including the \0 byte. */ static size_t printf_length(const char *fmt, va_list untouched_args) { int size; char junk; /* Make a copy of the va_list so the original caller can still use it */ va_list args; va_copy(args, untouched_args); #ifdef _WIN32 /* We need to use _vcsprintf to calculate the size as vsnprintf returns -1 * if the number of characters to write is greater than count. */ size = _vscprintf(fmt, args); (void)junk; #else size = vsnprintf(&junk, 1, fmt, args); #endif assert(size >= 0); va_end(args); return size; } char * ralloc_vasprintf(const void *ctx, const char *fmt, va_list args) { size_t size = printf_length(fmt, args) + 1; char *ptr = ralloc_size(ctx, size); if (ptr != NULL) vsnprintf(ptr, size, fmt, args); return ptr; } bool ralloc_asprintf_append(char **str, const char *fmt, ...) { bool success; va_list args; va_start(args, fmt); success = ralloc_vasprintf_append(str, fmt, args); va_end(args); return success; } bool ralloc_vasprintf_append(char **str, const char *fmt, va_list args) { size_t existing_length; assert(str != NULL); existing_length = *str ? strlen(*str) : 0; return ralloc_vasprintf_rewrite_tail(str, &existing_length, fmt, args); } bool ralloc_asprintf_rewrite_tail(char **str, size_t *start, const char *fmt, ...) { bool success; va_list args; va_start(args, fmt); success = ralloc_vasprintf_rewrite_tail(str, start, fmt, args); va_end(args); return success; } bool ralloc_vasprintf_rewrite_tail(char **str, size_t *start, const char *fmt, va_list args) { size_t new_length; char *ptr; assert(str != NULL); if (unlikely(*str == NULL)) { // Assuming a NULL context is probably bad, but it's expected behavior. *str = ralloc_vasprintf(NULL, fmt, args); *start = strlen(*str); return true; } new_length = printf_length(fmt, args); ptr = resize(*str, *start + new_length + 1); if (unlikely(ptr == NULL)) return false; vsnprintf(ptr + *start, new_length + 1, fmt, args); *str = ptr; *start += new_length; return true; } /*************************************************************************** * Linear allocator for short-lived allocations. *************************************************************************** * * The allocator consists of a parent node (2K buffer), which requires * a ralloc parent, and child nodes (allocations). Child nodes can't be freed * directly, because the parent doesn't track them. You have to release * the parent node in order to release all its children. * * The allocator uses a fixed-sized buffer with a monotonically increasing * offset after each allocation. If the buffer is all used, another buffer * is allocated, sharing the same ralloc parent, so all buffers are at * the same level in the ralloc hierarchy. * * The linear parent node is always the first buffer and keeps track of all * other buffers. */ #define ALIGN_POT(x, y) (((x) + (y) - 1) & ~((y) - 1)) #define MIN_LINEAR_BUFSIZE 2048 #define SUBALLOC_ALIGNMENT sizeof(uintptr_t) #define LMAGIC 0x87b9c7d3 struct linear_header { #ifdef DEBUG unsigned magic; /* for debugging */ #endif unsigned offset; /* points to the first unused byte in the buffer */ unsigned size; /* size of the buffer */ void *ralloc_parent; /* new buffers will use this */ struct linear_header *next; /* next buffer if we have more */ struct linear_header *latest; /* the only buffer that has free space */ /* After this structure, the buffer begins. * Each suballocation consists of linear_size_chunk as its header followed * by the suballocation, so it goes: * * - linear_size_chunk * - allocated space * - linear_size_chunk * - allocated space * etc. * * linear_size_chunk is only needed by linear_realloc. */ }; struct linear_size_chunk { unsigned size; /* for realloc */ unsigned _padding; }; typedef struct linear_header linear_header; typedef struct linear_size_chunk linear_size_chunk; #define LINEAR_PARENT_TO_HEADER(parent) \ (linear_header*) \ ((char*)(parent) - sizeof(linear_size_chunk) - sizeof(linear_header)) /* Allocate the linear buffer with its header. */ static linear_header * create_linear_node(void *ralloc_ctx, unsigned min_size) { linear_header *node; min_size += sizeof(linear_size_chunk); if (likely(min_size < MIN_LINEAR_BUFSIZE)) min_size = MIN_LINEAR_BUFSIZE; node = ralloc_size(ralloc_ctx, sizeof(linear_header) + min_size); if (unlikely(!node)) return NULL; #ifdef DEBUG node->magic = LMAGIC; #endif node->offset = 0; node->size = min_size; node->ralloc_parent = ralloc_ctx; node->next = NULL; node->latest = node; return node; } void * linear_alloc_child(void *parent, unsigned size) { linear_header *first = LINEAR_PARENT_TO_HEADER(parent); linear_header *latest = first->latest; linear_header *new_node; linear_size_chunk *ptr; unsigned full_size; assert(first->magic == LMAGIC); assert(!latest->next); size = ALIGN_POT(size, SUBALLOC_ALIGNMENT); full_size = sizeof(linear_size_chunk) + size; if (unlikely(latest->offset + full_size > latest->size)) { /* allocate a new node */ new_node = create_linear_node(latest->ralloc_parent, size); if (unlikely(!new_node)) return NULL; first->latest = new_node; latest->latest = new_node; latest->next = new_node; latest = new_node; } ptr = (linear_size_chunk *)((char*)&latest[1] + latest->offset); ptr->size = size; latest->offset += full_size; return &ptr[1]; } void * linear_alloc_parent(void *ralloc_ctx, unsigned size) { linear_header *node; if (unlikely(!ralloc_ctx)) return NULL; size = ALIGN_POT(size, SUBALLOC_ALIGNMENT); node = create_linear_node(ralloc_ctx, size); if (unlikely(!node)) return NULL; return linear_alloc_child((char*)node + sizeof(linear_header) + sizeof(linear_size_chunk), size); } void * linear_zalloc_child(void *parent, unsigned size) { void *ptr = linear_alloc_child(parent, size); if (likely(ptr)) memset(ptr, 0, size); return ptr; } void * linear_zalloc_parent(void *parent, unsigned size) { void *ptr = linear_alloc_parent(parent, size); if (likely(ptr)) memset(ptr, 0, size); return ptr; } void linear_free_parent(void *ptr) { linear_header *node; if (unlikely(!ptr)) return; node = LINEAR_PARENT_TO_HEADER(ptr); assert(node->magic == LMAGIC); while (node) { void *ptr = node; node = node->next; ralloc_free(ptr); } } void ralloc_steal_linear_parent(void *new_ralloc_ctx, void *ptr) { linear_header *node; if (unlikely(!ptr)) return; node = LINEAR_PARENT_TO_HEADER(ptr); assert(node->magic == LMAGIC); while (node) { ralloc_steal(new_ralloc_ctx, node); node->ralloc_parent = new_ralloc_ctx; node = node->next; } } void * ralloc_parent_of_linear_parent(void *ptr) { linear_header *node = LINEAR_PARENT_TO_HEADER(ptr); assert(node->magic == LMAGIC); return node->ralloc_parent; } void * linear_realloc(void *parent, void *old, unsigned new_size) { unsigned old_size = 0; ralloc_header *new_ptr; new_ptr = linear_alloc_child(parent, new_size); if (unlikely(!old)) return new_ptr; old_size = ((linear_size_chunk*)old)[-1].size; if (likely(new_ptr && old_size)) memcpy(new_ptr, old, MIN2(old_size, new_size)); return new_ptr; } /* All code below is pretty much copied from ralloc and only the alloc * calls are different. */ char * linear_strdup(void *parent, const char *str) { unsigned n; char *ptr; if (unlikely(!str)) return NULL; n = strlen(str); ptr = linear_alloc_child(parent, n + 1); if (unlikely(!ptr)) return NULL; memcpy(ptr, str, n); ptr[n] = '\0'; return ptr; } char * linear_asprintf(void *parent, const char *fmt, ...) { char *ptr; va_list args; va_start(args, fmt); ptr = linear_vasprintf(parent, fmt, args); va_end(args); return ptr; } char * linear_vasprintf(void *parent, const char *fmt, va_list args) { unsigned size = printf_length(fmt, args) + 1; char *ptr = linear_alloc_child(parent, size); if (ptr != NULL) vsnprintf(ptr, size, fmt, args); return ptr; } bool linear_asprintf_append(void *parent, char **str, const char *fmt, ...) { bool success; va_list args; va_start(args, fmt); success = linear_vasprintf_append(parent, str, fmt, args); va_end(args); return success; } bool linear_vasprintf_append(void *parent, char **str, const char *fmt, va_list args) { size_t existing_length; assert(str != NULL); existing_length = *str ? strlen(*str) : 0; return linear_vasprintf_rewrite_tail(parent, str, &existing_length, fmt, args); } bool linear_asprintf_rewrite_tail(void *parent, char **str, size_t *start, const char *fmt, ...) { bool success; va_list args; va_start(args, fmt); success = linear_vasprintf_rewrite_tail(parent, str, start, fmt, args); va_end(args); return success; } bool linear_vasprintf_rewrite_tail(void *parent, char **str, size_t *start, const char *fmt, va_list args) { size_t new_length; char *ptr; assert(str != NULL); if (unlikely(*str == NULL)) { *str = linear_vasprintf(parent, fmt, args); *start = strlen(*str); return true; } new_length = printf_length(fmt, args); ptr = linear_realloc(parent, *str, *start + new_length + 1); if (unlikely(ptr == NULL)) return false; vsnprintf(ptr + *start, new_length + 1, fmt, args); *str = ptr; *start += new_length; return true; } /* helper routine for strcat/strncat - n is the exact amount to copy */ static bool linear_cat(void *parent, char **dest, const char *str, unsigned n) { char *both; unsigned existing_length; assert(dest != NULL && *dest != NULL); existing_length = strlen(*dest); both = linear_realloc(parent, *dest, existing_length + n + 1); if (unlikely(both == NULL)) return false; memcpy(both + existing_length, str, n); both[existing_length + n] = '\0'; *dest = both; return true; } bool linear_strcat(void *parent, char **dest, const char *str) { return linear_cat(parent, dest, str, strlen(str)); }