libc/bionic/malloc_limit.cpp - android_bionic - Gitiles

 /*
  * Copyright (C) 2019 The Android Open Source Project
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  *  * Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  *  * Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in
  *    the documentation and/or other materials provided with the
  *    distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
  * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
  * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
  * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
  * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
  * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
  * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
  * SUCH DAMAGE.
  */

 #include <inttypes.h>
 #include <pthread.h>
 #include <stdatomic.h>
 #include <stdint.h>
 #include <stdio.h>

 #include <private/bionic_malloc_dispatch.h>

 #if __has_feature(hwaddress_sanitizer)
 #include <sanitizer/allocator_interface.h>
 #endif

 #include "malloc_common.h"
 #include "malloc_common_dynamic.h"
 #include "malloc_heapprofd.h"
 #include "malloc_limit.h"

 __BEGIN_DECLS
 static void* LimitCalloc(size_t n_elements, size_t elem_size);
 static void LimitFree(void* mem);
 static void* LimitMalloc(size_t bytes);
 static void* LimitMemalign(size_t alignment, size_t bytes);
 static int LimitPosixMemalign(void** memptr, size_t alignment, size_t size);
 static void* LimitRealloc(void* old_mem, size_t bytes);
 static void* LimitAlignedAlloc(size_t alignment, size_t size);
 #if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
 static void* LimitPvalloc(size_t bytes);
 static void* LimitValloc(size_t bytes);
 #endif

 // Pass through functions.
 static size_t LimitUsableSize(const void* mem);
 static struct mallinfo LimitMallinfo();
 static int LimitIterate(uintptr_t base, size_t size, void (*callback)(uintptr_t, size_t, void*), void* arg);
 static void LimitMallocDisable();
 static void LimitMallocEnable();
 static int LimitMallocInfo(int options, FILE* fp);
 static int LimitMallopt(int param, int value);
 __END_DECLS

 static constexpr MallocDispatch __limit_dispatch
   __attribute__((unused)) = {
     LimitCalloc,
     LimitFree,
     LimitMallinfo,
     LimitMalloc,
     LimitUsableSize,
     LimitMemalign,
     LimitPosixMemalign,
 #if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
     LimitPvalloc,
 #endif
     LimitRealloc,
 #if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
     LimitValloc,
 #endif
     LimitIterate,
     LimitMallocDisable,
     LimitMallocEnable,
     LimitMallopt,
     LimitAlignedAlloc,
     LimitMallocInfo,
   };

 static _Atomic uint64_t gAllocated;
 static uint64_t gAllocLimit;

 static inline bool CheckLimit(size_t bytes) {
   uint64_t total;
   if (__predict_false(__builtin_add_overflow(
                           atomic_load_explicit(&gAllocated, memory_order_relaxed), bytes, &total) ||
                       total > gAllocLimit)) {
     return false;
   }
   return true;
 }

 static inline void* IncrementLimit(void* mem) {
   if (__predict_false(mem == nullptr)) {
     return nullptr;
   }
   atomic_fetch_add(&gAllocated, LimitUsableSize(mem));
   return mem;
 }

 void* LimitCalloc(size_t n_elements, size_t elem_size) {
   size_t total;
   if (__builtin_mul_overflow(n_elements, elem_size, &total) || !CheckLimit(total)) {
     warning_log("malloc_limit: calloc(%zu, %zu) exceeds limit %" PRId64, n_elements, elem_size,
                 gAllocLimit);
     return nullptr;
   }
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return IncrementLimit(dispatch_table->calloc(n_elements, elem_size));
   }
   return IncrementLimit(Malloc(calloc)(n_elements, elem_size));
 }

 void LimitFree(void* mem) {
   atomic_fetch_sub(&gAllocated, LimitUsableSize(mem));
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return dispatch_table->free(mem);
   }
   return Malloc(free)(mem);
 }

 void* LimitMalloc(size_t bytes) {
   if (!CheckLimit(bytes)) {
     warning_log("malloc_limit: malloc(%zu) exceeds limit %" PRId64, bytes, gAllocLimit);
     return nullptr;
   }
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return IncrementLimit(dispatch_table->malloc(bytes));
   }
   return IncrementLimit(Malloc(malloc)(bytes));
 }

 static void* LimitMemalign(size_t alignment, size_t bytes) {
   if (!CheckLimit(bytes)) {
     warning_log("malloc_limit: memalign(%zu, %zu) exceeds limit %" PRId64, alignment, bytes,
                 gAllocLimit);
     return nullptr;
   }
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return IncrementLimit(dispatch_table->memalign(alignment, bytes));
   }
   return IncrementLimit(Malloc(memalign)(alignment, bytes));
 }

 static int LimitPosixMemalign(void** memptr, size_t alignment, size_t size) {
   if (!CheckLimit(size)) {
     warning_log("malloc_limit: posix_memalign(%zu, %zu) exceeds limit %" PRId64, alignment, size,
                 gAllocLimit);
     return ENOMEM;
   }
   int retval;
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     retval = dispatch_table->posix_memalign(memptr, alignment, size);
   } else {
     retval = Malloc(posix_memalign)(memptr, alignment, size);
   }
   if (__predict_false(retval != 0)) {
     return retval;
   }
   IncrementLimit(*memptr);
   return 0;
 }

 static void* LimitAlignedAlloc(size_t alignment, size_t size) {
   if (!CheckLimit(size)) {
     warning_log("malloc_limit: aligned_alloc(%zu, %zu) exceeds limit %" PRId64, alignment, size,
                 gAllocLimit);
     return nullptr;
   }
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return IncrementLimit(dispatch_table->aligned_alloc(alignment, size));
   }
   return IncrementLimit(Malloc(aligned_alloc)(alignment, size));
 }

 static void* LimitRealloc(void* old_mem, size_t bytes) {
   size_t old_usable_size = LimitUsableSize(old_mem);
   void* new_ptr;
   // Need to check the size only if the allocation will increase in size.
   if (bytes > old_usable_size && !CheckLimit(bytes - old_usable_size)) {
     warning_log("malloc_limit: realloc(%p, %zu) exceeds limit %" PRId64, old_mem, bytes,
                 gAllocLimit);
     // Free the old pointer.
     LimitFree(old_mem);
     return nullptr;
   }

   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     new_ptr = dispatch_table->realloc(old_mem, bytes);
   } else {
     new_ptr = Malloc(realloc)(old_mem, bytes);
   }

   if (__predict_false(new_ptr == nullptr)) {
     // This acts as if the pointer was freed.
     atomic_fetch_sub(&gAllocated, old_usable_size);
     return nullptr;
   }

   size_t new_usable_size = LimitUsableSize(new_ptr);
   // Assumes that most allocations increase in size, rather than shrink.
   if (__predict_false(old_usable_size > new_usable_size)) {
     atomic_fetch_sub(&gAllocated, old_usable_size - new_usable_size);
   } else {
     atomic_fetch_add(&gAllocated, new_usable_size - old_usable_size);
   }
   return new_ptr;
 }

 #if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
 static void* LimitPvalloc(size_t bytes) {
   if (!CheckLimit(bytes)) {
     warning_log("malloc_limit: pvalloc(%zu) exceeds limit %" PRId64, bytes, gAllocLimit);
     return nullptr;
   }
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return IncrementLimit(dispatch_table->pvalloc(bytes));
   }
   return IncrementLimit(Malloc(pvalloc)(bytes));
 }

 static void* LimitValloc(size_t bytes) {
   if (!CheckLimit(bytes)) {
     warning_log("malloc_limit: valloc(%zu) exceeds limit %" PRId64, bytes, gAllocLimit);
     return nullptr;
   }
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return IncrementLimit(dispatch_table->valloc(bytes));
   }
   return IncrementLimit(Malloc(valloc)(bytes));
 }
 #endif

 #if defined(LIBC_STATIC)
 static bool EnableLimitDispatchTable() {
   // This is the only valid way to modify the dispatch tables for a
   // static executable so no locks are necessary.
   __libc_globals.mutate([](libc_globals* globals) {
     atomic_store(&globals->current_dispatch_table, &__limit_dispatch);
   });
   return true;
 }
 #else
 static bool EnableLimitDispatchTable() {
   HeapprofdMaskSignal();
   pthread_mutex_lock(&gGlobalsMutateLock);
   // All other code that calls mutate will grab the gGlobalsMutateLock.
   // However, there is one case where the lock cannot be acquired, in the
   // signal handler that enables heapprofd. In order to avoid having two
   // threads calling mutate at the same time, use an atomic variable to
   // verify that only this function or the signal handler are calling mutate.
   // If this function is called at the same time as the signal handler is
   // being called, allow up to five ms for the signal handler to complete
   // before failing.
   bool enabled = false;
   size_t num_tries = 20;
   while (true) {
     if (!atomic_exchange(&gGlobalsMutating, true)) {
       __libc_globals.mutate([](libc_globals* globals) {
         atomic_store(&globals->current_dispatch_table, &__limit_dispatch);
       });
       atomic_store(&gGlobalsMutating, false);
       enabled = true;
       break;
     }
     if (--num_tries == 0) {
       break;
     }
     usleep(1000);
   }
   pthread_mutex_unlock(&gGlobalsMutateLock);
   HeapprofdUnmaskSignal();
   if (enabled) {
     info_log("malloc_limit: Allocation limit enabled, max size %" PRId64 " bytes\n", gAllocLimit);
   } else {
     error_log("malloc_limit: Failed to enable allocation limit.");
   }
   return enabled;
 }
 #endif

 bool LimitEnable(void* arg, size_t arg_size) {
   if (arg == nullptr || arg_size != sizeof(size_t)) {
     errno = EINVAL;
     return false;
   }

   static _Atomic bool limit_enabled;
   if (atomic_exchange(&limit_enabled, true)) {
     // The limit can only be enabled once.
     error_log("malloc_limit: The allocation limit has already been set, it can only be set once.");
     return false;
   }

   gAllocLimit = *reinterpret_cast<size_t*>(arg);
 #if __has_feature(hwaddress_sanitizer)
   size_t current_allocated = __sanitizer_get_current_allocated_bytes();
 #else
   size_t current_allocated;
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     current_allocated = dispatch_table->mallinfo().uordblks;
   } else {
     current_allocated = Malloc(mallinfo)().uordblks;
   }
 #endif
   atomic_store(&gAllocated, current_allocated);

   return EnableLimitDispatchTable();
 }

 static size_t LimitUsableSize(const void* mem) {
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return dispatch_table->malloc_usable_size(mem);
   }
   return Malloc(malloc_usable_size)(mem);
 }

 static struct mallinfo LimitMallinfo() {
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return dispatch_table->mallinfo();
   }
   return Malloc(mallinfo)();
 }

 static int LimitIterate(uintptr_t base, size_t size, void (*callback)(uintptr_t, size_t, void*), void* arg) {
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return dispatch_table->malloc_iterate(base, size, callback, arg);
   }
   return Malloc(malloc_iterate)(base, size, callback, arg);
 }

 static void LimitMallocDisable() {
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     dispatch_table->malloc_disable();
   } else {
     Malloc(malloc_disable)();
   }
 }

 static void LimitMallocEnable() {
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     dispatch_table->malloc_enable();
   } else {
     Malloc(malloc_enable)();
   }
 }

 static int LimitMallocInfo(int options, FILE* fp) {
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return dispatch_table->malloc_info(options, fp);
   }
   return Malloc(malloc_info)(options, fp);
 }

 static int LimitMallopt(int param, int value) {
   auto dispatch_table = GetDefaultDispatchTable();
   if (__predict_false(dispatch_table != nullptr)) {
     return dispatch_table->mallopt(param, value);
   }
   return Malloc(mallopt)(param, value);
 }
	/*
	* Copyright (C) 2019 The Android Open Source Project
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* * Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in
	* the documentation and/or other materials provided with the
	* distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
	* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
	* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
	* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
	* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
	* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
	* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
	* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
	* SUCH DAMAGE.
	*/

	#include <inttypes.h>
	#include <pthread.h>
	#include <stdatomic.h>
	#include <stdint.h>
	#include <stdio.h>

	#include <private/bionic_malloc_dispatch.h>

	#if __has_feature(hwaddress_sanitizer)
	#include <sanitizer/allocator_interface.h>
	#endif

	#include "malloc_common.h"
	#include "malloc_common_dynamic.h"
	#include "malloc_heapprofd.h"
	#include "malloc_limit.h"

	__BEGIN_DECLS
	static void* LimitCalloc(size_t n_elements, size_t elem_size);
	static void LimitFree(void* mem);
	static void* LimitMalloc(size_t bytes);
	static void* LimitMemalign(size_t alignment, size_t bytes);
	static int LimitPosixMemalign(void** memptr, size_t alignment, size_t size);
	static void* LimitRealloc(void* old_mem, size_t bytes);
	static void* LimitAlignedAlloc(size_t alignment, size_t size);
	#if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
	static void* LimitPvalloc(size_t bytes);
	static void* LimitValloc(size_t bytes);
	#endif

	// Pass through functions.
	static size_t LimitUsableSize(const void* mem);
	static struct mallinfo LimitMallinfo();
	static int LimitIterate(uintptr_t base, size_t size, void (callback)(uintptr_t, size_t, void), void* arg);
	static void LimitMallocDisable();
	static void LimitMallocEnable();
	static int LimitMallocInfo(int options, FILE* fp);
	static int LimitMallopt(int param, int value);
	__END_DECLS

	static constexpr MallocDispatch __limit_dispatch
	__attribute__((unused)) = {
	LimitCalloc,
	LimitFree,
	LimitMallinfo,
	LimitMalloc,
	LimitUsableSize,
	LimitMemalign,
	LimitPosixMemalign,
	#if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
	LimitPvalloc,
	#endif
	LimitRealloc,
	#if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
	LimitValloc,
	#endif
	LimitIterate,
	LimitMallocDisable,
	LimitMallocEnable,
	LimitMallopt,
	LimitAlignedAlloc,
	LimitMallocInfo,
	};

	static _Atomic uint64_t gAllocated;
	static uint64_t gAllocLimit;

	static inline bool CheckLimit(size_t bytes) {
	uint64_t total;
	if (__predict_false(__builtin_add_overflow(
	atomic_load_explicit(&gAllocated, memory_order_relaxed), bytes, &total) \|\|
	total > gAllocLimit)) {
	return false;
	}
	return true;
	}

	static inline void* IncrementLimit(void* mem) {
	if (__predict_false(mem == nullptr)) {
	return nullptr;
	}
	atomic_fetch_add(&gAllocated, LimitUsableSize(mem));
	return mem;
	}

	void* LimitCalloc(size_t n_elements, size_t elem_size) {
	size_t total;
	if (__builtin_mul_overflow(n_elements, elem_size, &total) \|\| !CheckLimit(total)) {
	warning_log("malloc_limit: calloc(%zu, %zu) exceeds limit %" PRId64, n_elements, elem_size,
	gAllocLimit);
	return nullptr;
	}
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return IncrementLimit(dispatch_table->calloc(n_elements, elem_size));
	}
	return IncrementLimit(Malloc(calloc)(n_elements, elem_size));
	}

	void LimitFree(void* mem) {
	atomic_fetch_sub(&gAllocated, LimitUsableSize(mem));
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return dispatch_table->free(mem);
	}
	return Malloc(free)(mem);
	}

	void* LimitMalloc(size_t bytes) {
	if (!CheckLimit(bytes)) {
	warning_log("malloc_limit: malloc(%zu) exceeds limit %" PRId64, bytes, gAllocLimit);
	return nullptr;
	}
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return IncrementLimit(dispatch_table->malloc(bytes));
	}
	return IncrementLimit(Malloc(malloc)(bytes));
	}

	static void* LimitMemalign(size_t alignment, size_t bytes) {
	if (!CheckLimit(bytes)) {
	warning_log("malloc_limit: memalign(%zu, %zu) exceeds limit %" PRId64, alignment, bytes,
	gAllocLimit);
	return nullptr;
	}
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return IncrementLimit(dispatch_table->memalign(alignment, bytes));
	}
	return IncrementLimit(Malloc(memalign)(alignment, bytes));
	}

	static int LimitPosixMemalign(void** memptr, size_t alignment, size_t size) {
	if (!CheckLimit(size)) {
	warning_log("malloc_limit: posix_memalign(%zu, %zu) exceeds limit %" PRId64, alignment, size,
	gAllocLimit);
	return ENOMEM;
	}
	int retval;
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	retval = dispatch_table->posix_memalign(memptr, alignment, size);
	} else {
	retval = Malloc(posix_memalign)(memptr, alignment, size);
	}
	if (__predict_false(retval != 0)) {
	return retval;
	}
	IncrementLimit(*memptr);
	return 0;
	}

	static void* LimitAlignedAlloc(size_t alignment, size_t size) {
	if (!CheckLimit(size)) {
	warning_log("malloc_limit: aligned_alloc(%zu, %zu) exceeds limit %" PRId64, alignment, size,
	gAllocLimit);
	return nullptr;
	}
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return IncrementLimit(dispatch_table->aligned_alloc(alignment, size));
	}
	return IncrementLimit(Malloc(aligned_alloc)(alignment, size));
	}

	static void* LimitRealloc(void* old_mem, size_t bytes) {
	size_t old_usable_size = LimitUsableSize(old_mem);
	void* new_ptr;
	// Need to check the size only if the allocation will increase in size.
	if (bytes > old_usable_size && !CheckLimit(bytes - old_usable_size)) {
	warning_log("malloc_limit: realloc(%p, %zu) exceeds limit %" PRId64, old_mem, bytes,
	gAllocLimit);
	// Free the old pointer.
	LimitFree(old_mem);
	return nullptr;
	}

	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	new_ptr = dispatch_table->realloc(old_mem, bytes);
	} else {
	new_ptr = Malloc(realloc)(old_mem, bytes);
	}

	if (__predict_false(new_ptr == nullptr)) {
	// This acts as if the pointer was freed.
	atomic_fetch_sub(&gAllocated, old_usable_size);
	return nullptr;
	}

	size_t new_usable_size = LimitUsableSize(new_ptr);
	// Assumes that most allocations increase in size, rather than shrink.
	if (__predict_false(old_usable_size > new_usable_size)) {
	atomic_fetch_sub(&gAllocated, old_usable_size - new_usable_size);
	} else {
	atomic_fetch_add(&gAllocated, new_usable_size - old_usable_size);
	}
	return new_ptr;
	}

	#if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
	static void* LimitPvalloc(size_t bytes) {
	if (!CheckLimit(bytes)) {
	warning_log("malloc_limit: pvalloc(%zu) exceeds limit %" PRId64, bytes, gAllocLimit);
	return nullptr;
	}
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return IncrementLimit(dispatch_table->pvalloc(bytes));
	}
	return IncrementLimit(Malloc(pvalloc)(bytes));
	}

	static void* LimitValloc(size_t bytes) {
	if (!CheckLimit(bytes)) {
	warning_log("malloc_limit: valloc(%zu) exceeds limit %" PRId64, bytes, gAllocLimit);
	return nullptr;
	}
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return IncrementLimit(dispatch_table->valloc(bytes));
	}
	return IncrementLimit(Malloc(valloc)(bytes));
	}
	#endif

	#if defined(LIBC_STATIC)
	static bool EnableLimitDispatchTable() {
	// This is the only valid way to modify the dispatch tables for a
	// static executable so no locks are necessary.
	__libc_globals.mutate([](libc_globals* globals) {
	atomic_store(&globals->current_dispatch_table, &__limit_dispatch);
	});
	return true;
	}
	#else
	static bool EnableLimitDispatchTable() {
	HeapprofdMaskSignal();
	pthread_mutex_lock(&gGlobalsMutateLock);
	// All other code that calls mutate will grab the gGlobalsMutateLock.
	// However, there is one case where the lock cannot be acquired, in the
	// signal handler that enables heapprofd. In order to avoid having two
	// threads calling mutate at the same time, use an atomic variable to
	// verify that only this function or the signal handler are calling mutate.
	// If this function is called at the same time as the signal handler is
	// being called, allow up to five ms for the signal handler to complete
	// before failing.
	bool enabled = false;
	size_t num_tries = 20;
	while (true) {
	if (!atomic_exchange(&gGlobalsMutating, true)) {
	__libc_globals.mutate([](libc_globals* globals) {
	atomic_store(&globals->current_dispatch_table, &__limit_dispatch);
	});
	atomic_store(&gGlobalsMutating, false);
	enabled = true;
	break;
	}
	if (--num_tries == 0) {
	break;
	}
	usleep(1000);
	}
	pthread_mutex_unlock(&gGlobalsMutateLock);
	HeapprofdUnmaskSignal();
	if (enabled) {
	info_log("malloc_limit: Allocation limit enabled, max size %" PRId64 " bytes\n", gAllocLimit);
	} else {
	error_log("malloc_limit: Failed to enable allocation limit.");
	}
	return enabled;
	}
	#endif

	bool LimitEnable(void* arg, size_t arg_size) {
	if (arg == nullptr \|\| arg_size != sizeof(size_t)) {
	errno = EINVAL;
	return false;
	}

	static _Atomic bool limit_enabled;
	if (atomic_exchange(&limit_enabled, true)) {
	// The limit can only be enabled once.
	error_log("malloc_limit: The allocation limit has already been set, it can only be set once.");
	return false;
	}

	gAllocLimit = reinterpret_cast<size_t>(arg);
	#if __has_feature(hwaddress_sanitizer)
	size_t current_allocated = __sanitizer_get_current_allocated_bytes();
	#else
	size_t current_allocated;
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	current_allocated = dispatch_table->mallinfo().uordblks;
	} else {
	current_allocated = Malloc(mallinfo)().uordblks;
	}
	#endif
	atomic_store(&gAllocated, current_allocated);

	return EnableLimitDispatchTable();
	}

	static size_t LimitUsableSize(const void* mem) {
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return dispatch_table->malloc_usable_size(mem);
	}
	return Malloc(malloc_usable_size)(mem);
	}

	static struct mallinfo LimitMallinfo() {
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return dispatch_table->mallinfo();
	}
	return Malloc(mallinfo)();
	}

	static int LimitIterate(uintptr_t base, size_t size, void (callback)(uintptr_t, size_t, void), void* arg) {
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return dispatch_table->malloc_iterate(base, size, callback, arg);
	}
	return Malloc(malloc_iterate)(base, size, callback, arg);
	}

	static void LimitMallocDisable() {
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	dispatch_table->malloc_disable();
	} else {
	Malloc(malloc_disable)();
	}
	}

	static void LimitMallocEnable() {
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	dispatch_table->malloc_enable();
	} else {
	Malloc(malloc_enable)();
	}
	}

	static int LimitMallocInfo(int options, FILE* fp) {
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return dispatch_table->malloc_info(options, fp);
	}
	return Malloc(malloc_info)(options, fp);
	}

	static int LimitMallopt(int param, int value) {
	auto dispatch_table = GetDefaultDispatchTable();
	if (__predict_false(dispatch_table != nullptr)) {
	return dispatch_table->mallopt(param, value);
	}
	return Malloc(mallopt)(param, value);
	}