/* * Copyright (C) 2012 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #pragma once /** * @file malloc.h * @brief Heap memory allocation. * * [Debugging Native Memory Use](https://source.android.com/devices/tech/debug/native-memory) * is the canonical source for documentation on Android's heap debugging * features. */ #include #include #include __BEGIN_DECLS #define __BIONIC_ALLOC_SIZE(...) __attribute__((__alloc_size__(__VA_ARGS__))) /** * [malloc(3)](http://man7.org/linux/man-pages/man3/malloc.3.html) allocates * memory on the heap. * * Returns a pointer to the allocated memory on success and returns a null * pointer and sets `errno` on failure. * * Note that Android (like most Unix systems) allows "overcommit". This * allows processes to allocate more memory than the system has, provided * they don't use it all. This works because only "dirty" pages that have * been written to actually require physical memory. In practice, this * means that it's rare to see memory allocation functions return a null * pointer, and that a non-null pointer does not mean that you actually * have all of the memory you asked for. * * Note also that the Linux Out Of Memory (OOM) killer behaves differently * for code run via `adb shell`. The assumption is that if you ran * something via `adb shell` you're a developer who actually wants the * device to do what you're asking it to do _even if_ that means killing * other processes. Obviously this is not the case for apps, which will * be killed in preference to killing other processes. */ void* _Nullable malloc(size_t __byte_count) __mallocfunc __BIONIC_ALLOC_SIZE(1) __wur; /** * [calloc(3)](http://man7.org/linux/man-pages/man3/calloc.3.html) allocates * and clears memory on the heap. * * Returns a pointer to the allocated memory on success and returns a null * pointer and sets `errno` on failure (but see the notes for malloc()). */ void* _Nullable calloc(size_t __item_count, size_t __item_size) __mallocfunc __BIONIC_ALLOC_SIZE(1,2) __wur; /** * [realloc(3)](http://man7.org/linux/man-pages/man3/realloc.3.html) resizes * allocated memory on the heap. * * Returns a pointer (which may be different from `__ptr`) to the resized * memory on success and returns a null pointer and sets `errno` on failure * (but see the notes for malloc()). */ void* _Nullable realloc(void* _Nullable __ptr, size_t __byte_count) __BIONIC_ALLOC_SIZE(2) __wur; /** * [reallocarray(3)](http://man7.org/linux/man-pages/man3/realloc.3.html) resizes * allocated memory on the heap. * * Equivalent to `realloc(__ptr, __item_count * __item_size)` but fails if the * multiplication overflows. * * Returns a pointer (which may be different from `__ptr`) to the resized * memory on success and returns a null pointer and sets `errno` on failure * (but see the notes for malloc()). */ void* _Nullable reallocarray(void* _Nullable __ptr, size_t __item_count, size_t __item_size) __BIONIC_ALLOC_SIZE(2, 3) __wur __INTRODUCED_IN(29); /** * [free(3)](http://man7.org/linux/man-pages/man3/free.3.html) deallocates * memory on the heap. */ void free(void* _Nullable __ptr); /** * [memalign(3)](http://man7.org/linux/man-pages/man3/memalign.3.html) allocates * memory on the heap with the required alignment. * * Returns a pointer to the allocated memory on success and returns a null * pointer and sets `errno` on failure (but see the notes for malloc()). * * See also posix_memalign(). */ void* _Nullable memalign(size_t __alignment, size_t __byte_count) __mallocfunc __BIONIC_ALLOC_SIZE(2) __wur; /** * [malloc_usable_size(3)](http://man7.org/linux/man-pages/man3/malloc_usable_size.3.html) * returns the actual size of the given heap block. */ size_t malloc_usable_size(const void* _Nullable __ptr) __wur; #define __MALLINFO_BODY \ /** Total number of non-mmapped bytes currently allocated from OS. */ \ size_t arena; \ /** Number of free chunks. */ \ size_t ordblks; \ /** (Unused.) */ \ size_t smblks; \ /** (Unused.) */ \ size_t hblks; \ /** Total number of bytes in mmapped regions. */ \ size_t hblkhd; \ /** Maximum total allocated space; greater than total if trimming has occurred. */ \ size_t usmblks; \ /** (Unused.) */ \ size_t fsmblks; \ /** Total allocated space (normal or mmapped.) */ \ size_t uordblks; \ /** Total free space. */ \ size_t fordblks; \ /** Upper bound on number of bytes releasable by a trim operation. */ \ size_t keepcost; #ifndef STRUCT_MALLINFO_DECLARED #define STRUCT_MALLINFO_DECLARED 1 struct mallinfo { __MALLINFO_BODY }; #endif /** * [mallinfo(3)](http://man7.org/linux/man-pages/man3/mallinfo.3.html) returns * information about the current state of the heap. Note that mallinfo() is * inherently unreliable and consider using malloc_info() instead. */ struct mallinfo mallinfo(void); /** * On Android the struct mallinfo and struct mallinfo2 are the same. */ struct mallinfo2 { __MALLINFO_BODY }; /** * [mallinfo2(3)](http://man7.org/linux/man-pages/man3/mallinfo2.3.html) returns * information about the current state of the heap. Note that mallinfo2() is * inherently unreliable and consider using malloc_info() instead. */ struct mallinfo2 mallinfo2(void) __RENAME(mallinfo); /** * [malloc_info(3)](http://man7.org/linux/man-pages/man3/malloc_info.3.html) * writes information about the current state of the heap to the given stream. * * The XML structure for malloc_info() is as follows: * ``` * * * INT * INT * INT * INT * * INT * INT * INT * * * * * * ``` * * Available since API level 23. */ int malloc_info(int __must_be_zero, FILE* _Nonnull __fp) __INTRODUCED_IN(23); /** * mallopt() option to set the decay time. Valid values are -1, 0 and 1. * -1 : Disable the releasing of unused pages. This value is available since * API level 35. * 0 : Release the unused pages immediately. * 1 : Release the unused pages at a device-specific interval. * * Available since API level 27. */ #define M_DECAY_TIME (-100) /** * mallopt() option to immediately purge any memory not in use. This * will release the memory back to the kernel. The value is ignored. * * Available since API level 28. */ #define M_PURGE (-101) /** * mallopt() option to immediately purge all possible memory back to * the kernel. This call can take longer than a normal purge since it * examines everything. In some cases, it can take more than twice the * time of a M_PURGE call. The value is ignored. * * Available since API level 34. */ #define M_PURGE_ALL (-104) /** * mallopt() option to tune the allocator's choice of memory tags to * make it more likely that a certain class of memory errors will be * detected. This is only relevant if MTE is enabled in this process * and ignored otherwise. The value argument should be one of the * M_MEMTAG_TUNING_* flags. * NOTE: This is only available in scudo. * * Available since API level 31. */ #define M_MEMTAG_TUNING (-102) /** * When passed as a value of M_MEMTAG_TUNING mallopt() call, enables * deterministic detection of linear buffer overflow and underflow * bugs by assigning distinct tag values to adjacent allocations. This * mode has a slightly reduced chance to detect use-after-free bugs * because only half of the possible tag values are available for each * memory location. * * Please keep in mind that MTE can not detect overflow within the * same tag granule (16-byte aligned chunk), and can miss small * overflows even in this mode. Such overflow can not be the cause of * a memory corruption, because the memory within one granule is never * used for multiple allocations. */ #define M_MEMTAG_TUNING_BUFFER_OVERFLOW 0 /** * When passed as a value of M_MEMTAG_TUNING mallopt() call, enables * independently randomized tags for uniform ~93% probability of * detecting both spatial (buffer overflow) and temporal (use after * free) bugs. */ #define M_MEMTAG_TUNING_UAF 1 /** * mallopt() option for per-thread memory initialization tuning. * The value argument should be one of: * 1: Disable automatic heap initialization on this thread only. * If memory tagging is enabled, disable as much as possible of the * memory tagging initialization for this thread. * 0: Normal behavior. * * Available since API level 31. */ #define M_THREAD_DISABLE_MEM_INIT (-103) /** * mallopt() option to set the maximum number of items in the secondary * cache of the scudo allocator. * * Available since API level 31. */ #define M_CACHE_COUNT_MAX (-200) /** * mallopt() option to set the maximum size in bytes of a cacheable item in * the secondary cache of the scudo allocator. * * Available since API level 31. */ #define M_CACHE_SIZE_MAX (-201) /** * mallopt() option to increase the maximum number of shared thread-specific * data structures that can be created. This number cannot be decreased, * only increased and only applies to the scudo allocator. * * Available since API level 31. */ #define M_TSDS_COUNT_MAX (-202) /** * mallopt() option to decide whether heap memory is zero-initialized on * allocation across the whole process. May be called at any time, including * when multiple threads are running. An argument of zero indicates memory * should not be zero-initialized, any other value indicates to initialize heap * memory to zero. * * Note that this memory mitigation is only implemented in scudo and therefore * this will have no effect when using another allocator (such as jemalloc on * Android Go devices). * * Available since API level 31. */ #define M_BIONIC_ZERO_INIT (-203) /** * mallopt() option to change the heap tagging state. May be called at any * time, including when multiple threads are running. * The value must be one of the M_HEAP_TAGGING_LEVEL_ constants. * NOTE: This is only available in scudo. * * Available since API level 31. */ #define M_BIONIC_SET_HEAP_TAGGING_LEVEL (-204) /** * Constants for use with the M_BIONIC_SET_HEAP_TAGGING_LEVEL mallopt() option. */ enum HeapTaggingLevel { /** * Disable heap tagging and memory tag checks (if supported). * Heap tagging may not be re-enabled after being disabled. */ M_HEAP_TAGGING_LEVEL_NONE = 0, #define M_HEAP_TAGGING_LEVEL_NONE M_HEAP_TAGGING_LEVEL_NONE /** * Address-only tagging. Heap pointers have a non-zero tag in the * most significant ("top") byte which is checked in free(). Memory * accesses ignore the tag using arm64's Top Byte Ignore (TBI) feature. */ M_HEAP_TAGGING_LEVEL_TBI = 1, #define M_HEAP_TAGGING_LEVEL_TBI M_HEAP_TAGGING_LEVEL_TBI /** * Enable heap tagging and asynchronous memory tag checks (if supported). * Disable stack trace collection. */ M_HEAP_TAGGING_LEVEL_ASYNC = 2, #define M_HEAP_TAGGING_LEVEL_ASYNC M_HEAP_TAGGING_LEVEL_ASYNC /** * Enable heap tagging and synchronous memory tag checks (if supported). * Enable stack trace collection. */ M_HEAP_TAGGING_LEVEL_SYNC = 3, #define M_HEAP_TAGGING_LEVEL_SYNC M_HEAP_TAGGING_LEVEL_SYNC }; /** * mallopt() option to print human readable statistics about the memory * allocator to the log. There is no format for this data, each allocator * can use a different format, and the data that is printed can * change at any time. This is expected to be used as a debugging aid. * * Available since API level 35. */ #define M_LOG_STATS (-205) /** * [mallopt(3)](http://man7.org/linux/man-pages/man3/mallopt.3.html) modifies * heap behavior. Values of `__option` are the `M_` constants from this header. * * Returns 1 on success, 0 on error. * * Available since API level 26. */ int mallopt(int __option, int __value) __INTRODUCED_IN(26); /** * [__malloc_hook(3)](http://man7.org/linux/man-pages/man3/__malloc_hook.3.html) * is called to implement malloc(). By default this points to the system's * implementation. * * Available since API level 28. * * See also: [extra documentation](https://android.googlesource.com/platform/bionic/+/main/libc/malloc_hooks/README.md) */ extern void* _Nonnull (*volatile _Nonnull __malloc_hook)(size_t __byte_count, const void* _Nonnull __caller) __INTRODUCED_IN(28); /** * [__realloc_hook(3)](http://man7.org/linux/man-pages/man3/__realloc_hook.3.html) * is called to implement realloc(). By default this points to the system's * implementation. * * Available since API level 28. * * See also: [extra documentation](https://android.googlesource.com/platform/bionic/+/main/libc/malloc_hooks/README.md) */ extern void* _Nonnull (*volatile _Nonnull __realloc_hook)(void* _Nullable __ptr, size_t __byte_count, const void* _Nonnull __caller) __INTRODUCED_IN(28); /** * [__free_hook(3)](http://man7.org/linux/man-pages/man3/__free_hook.3.html) * is called to implement free(). By default this points to the system's * implementation. * * Available since API level 28. * * See also: [extra documentation](https://android.googlesource.com/platform/bionic/+/main/libc/malloc_hooks/README.md) */ extern void (*volatile _Nonnull __free_hook)(void* _Nullable __ptr, const void* _Nonnull __caller) __INTRODUCED_IN(28); /** * [__memalign_hook(3)](http://man7.org/linux/man-pages/man3/__memalign_hook.3.html) * is called to implement memalign(). By default this points to the system's * implementation. * * Available since API level 28. * * See also: [extra documentation](https://android.googlesource.com/platform/bionic/+/main/libc/malloc_hooks/README.md) */ extern void* _Nonnull (*volatile _Nonnull __memalign_hook)(size_t __alignment, size_t __byte_count, const void* _Nonnull __caller) __INTRODUCED_IN(28); __END_DECLS