libc/bionic/malloc_heapprofd.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.
  */

 #if defined(LIBC_STATIC)
 #error This file should not be compiled for static targets.
 #endif

 #include <dlfcn.h>
 #include <fcntl.h>
 #include <signal.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <unistd.h>

 #include <platform/bionic/malloc.h>
 #include <private/bionic_config.h>
 #include <private/bionic_malloc_dispatch.h>
 #include <sys/system_properties.h>

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

 static constexpr char kHeapprofdSharedLib[] = "heapprofd_client.so";
 static constexpr char kHeapprofdPrefix[] = "heapprofd";
 static constexpr char kHeapprofdPropertyEnable[] = "heapprofd.enable";

 // The logic for triggering heapprofd (at runtime) is as follows:
 // 1. A reserved profiling signal is received by the process, its si_value
 //    discriminating between different handlers. For the case of heapprofd,
 //    HandleHeapprofdSignal is called.
 // 2. If the initialization is not already in flight
 //    (gHeapprofdInitInProgress is false), the malloc hook is set to
 //    point at InitHeapprofdHook, and gHeapprofdInitInProgress is set to
 //    true.
 // 3. The next malloc call enters InitHeapprofdHook, which removes the malloc
 //    hook, and spawns a detached pthread to run the InitHeapprofd task.
 //    (gHeapprofdInitHookInstalled atomic is used to perform this once.)
 // 4. InitHeapprofd, on a dedicated pthread, loads the heapprofd client library,
 //    installs the full set of heapprofd hooks, and invokes the client's
 //    initializer. The dedicated pthread then terminates.
 // 5. gHeapprofdInitInProgress and gHeapprofdInitHookInstalled are
 //    reset to false such that heapprofd can be reinitialized. Reinitialization
 //    means that a new profiling session is started, and any still active is
 //    torn down.
 //
 // The incremental hooking and a dedicated task thread are used since we cannot
 // do heavy work within a signal handler, or when blocking a malloc invocation.

 // The handle returned by dlopen when previously loading the heapprofd
 // hooks. nullptr if shared library has not been already been loaded.
 static _Atomic (void*) gHeapprofdHandle = nullptr;

 static _Atomic bool gHeapprofdInitInProgress = false;
 static _Atomic bool gHeapprofdInitHookInstalled = false;

 // Set to true if the process has enabled malloc_debug or malloc_hooks, which
 // are incompatible (and take precedence over) heapprofd.
 static _Atomic bool gHeapprofdIncompatibleHooks = false;

 extern "C" void* MallocInitHeapprofdHook(size_t);

 static constexpr MallocDispatch __heapprofd_init_dispatch
   __attribute__((unused)) = {
     Malloc(calloc),
     Malloc(free),
     Malloc(mallinfo),
     MallocInitHeapprofdHook, // malloc replacement
     Malloc(malloc_usable_size),
     Malloc(memalign),
     Malloc(posix_memalign),
 #if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
     Malloc(pvalloc),
 #endif
     Malloc(realloc),
 #if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
     Malloc(valloc),
 #endif
     Malloc(malloc_iterate),
     Malloc(malloc_disable),
     Malloc(malloc_enable),
     Malloc(mallopt),
     Malloc(aligned_alloc),
     Malloc(malloc_info),
   };

 constexpr char kHeapprofdProgramPropertyPrefix[] = "heapprofd.enable.";
 constexpr size_t kHeapprofdProgramPropertyPrefixSize = sizeof(kHeapprofdProgramPropertyPrefix) - 1;
 constexpr size_t kMaxCmdlineSize = 512;

 static bool GetHeapprofdProgramProperty(char* data, size_t size) {
   if (size < kHeapprofdProgramPropertyPrefixSize) {
     error_log("%s: Overflow constructing heapprofd property", getprogname());
     return false;
   }
   memcpy(data, kHeapprofdProgramPropertyPrefix, kHeapprofdProgramPropertyPrefixSize);

   int fd = open("/proc/self/cmdline", O_RDONLY | O_CLOEXEC);
   if (fd == -1) {
     error_log("%s: Failed to open /proc/self/cmdline", getprogname());
     return false;
   }
   char cmdline[kMaxCmdlineSize];
   ssize_t rd = read(fd, cmdline, sizeof(cmdline) - 1);
   close(fd);
   if (rd == -1) {
     error_log("%s: Failed to read /proc/self/cmdline", getprogname());
     return false;
   }
   cmdline[rd] = '\0';
   char* first_arg = static_cast<char*>(memchr(cmdline, '\0', rd));
   if (first_arg == nullptr) {
     error_log("%s: Overflow reading cmdline", getprogname());
     return false;
   }
   // For consistency with what we do with Java app cmdlines, trim everything
   // after the @ sign of the first arg.
   char* first_at = static_cast<char*>(memchr(cmdline, '@', rd));
   if (first_at != nullptr && first_at < first_arg) {
     *first_at = '\0';
     first_arg = first_at;
   }

   char* start = static_cast<char*>(memrchr(cmdline, '/', first_arg - cmdline));
   if (start == first_arg) {
     // The first argument ended in a slash.
     error_log("%s: cmdline ends in /", getprogname());
     return false;
   } else if (start == nullptr) {
     start = cmdline;
   } else {
     // Skip the /.
     start++;
   }

   size_t name_size = static_cast<size_t>(first_arg - start);
   if (name_size >= size - kHeapprofdProgramPropertyPrefixSize) {
     error_log("%s: overflow constructing heapprofd property.", getprogname());
     return false;
   }
   // + 1 to also copy the trailing null byte.
   memcpy(data + kHeapprofdProgramPropertyPrefixSize, start, name_size + 1);
   return true;
 }

 // Runtime triggering entry-point. Two possible call sites:
 // * when receiving a profiling signal with a si_value indicating heapprofd.
 // * when a Zygote child is marking itself as profileable, and there's a
 //   matching profiling request for this process (in which case heapprofd client
 //   is loaded synchronously).
 // In both cases, the caller is responsible for verifying that the process is
 // considered profileable.
 void HandleHeapprofdSignal() {
   if (atomic_load_explicit(&gHeapprofdIncompatibleHooks, memory_order_acquire)) {
     error_log("%s: not enabling heapprofd, malloc_debug/malloc_hooks are enabled.", getprogname());
     return;
   }

   // Checking this variable is only necessary when this could conflict with
   // the change to enable the allocation limit. All other places will
   // not ever have a conflict modifying the globals.
   if (!atomic_exchange(&gGlobalsMutating, true)) {
     if (!atomic_exchange(&gHeapprofdInitInProgress, true)) {
       __libc_globals.mutate([](libc_globals* globals) {
         atomic_store(&globals->default_dispatch_table, &__heapprofd_init_dispatch);
         auto dispatch_table = GetDispatchTable();
         if (dispatch_table == nullptr || dispatch_table == &globals->malloc_dispatch_table) {
           atomic_store(&globals->current_dispatch_table, &__heapprofd_init_dispatch);
         }
       });
     }
     atomic_store(&gGlobalsMutating, false);
   }
   // Otherwise, we're racing against malloc_limit's enable logic (at most once
   // per process, and a niche feature). This is highly unlikely, so simply give
   // up if it does happen.
 }

 bool HeapprofdShouldLoad() {
   // First check for heapprofd.enable. If it is set to "all", enable
   // heapprofd for all processes. Otherwise, check heapprofd.enable.${prog},
   // if it is set and not 0, enable heap profiling for this process.
   char property_value[PROP_VALUE_MAX];
   if (__system_property_get(kHeapprofdPropertyEnable, property_value) == 0) {
     return false;
   }
   if (strcmp(property_value, "all") == 0) {
     return true;
   }

   char program_property[kHeapprofdProgramPropertyPrefixSize + kMaxCmdlineSize];
   if (!GetHeapprofdProgramProperty(program_property,
                                    sizeof(program_property))) {
     return false;
   }
   if (__system_property_get(program_property, property_value) == 0) {
     return false;
   }
   return property_value[0] != '\0';
 }

 void HeapprofdRememberHookConflict() {
   atomic_store_explicit(&gHeapprofdIncompatibleHooks, true, memory_order_release);
 }

 static void CommonInstallHooks(libc_globals* globals) {
   void* impl_handle = atomic_load(&gHeapprofdHandle);
   bool reusing_handle = impl_handle != nullptr;
   if (!reusing_handle) {
     impl_handle = LoadSharedLibrary(kHeapprofdSharedLib, kHeapprofdPrefix, &globals->malloc_dispatch_table);
     if (impl_handle == nullptr) {
       return;
     }
   } else if (!InitSharedLibrary(impl_handle, kHeapprofdSharedLib, kHeapprofdPrefix, &globals->malloc_dispatch_table)) {
     return;
   }

   if (FinishInstallHooks(globals, nullptr, kHeapprofdPrefix)) {
     atomic_store(&gHeapprofdHandle, impl_handle);
   } else if (!reusing_handle) {
     dlclose(impl_handle);
   }

   atomic_store(&gHeapprofdInitInProgress, false);
 }

 void HeapprofdInstallHooksAtInit(libc_globals* globals) {
   if (atomic_exchange(&gHeapprofdInitInProgress, true)) {
     return;
   }
   CommonInstallHooks(globals);
 }

 static void* InitHeapprofd(void*) {
   pthread_mutex_lock(&gGlobalsMutateLock);
   __libc_globals.mutate([](libc_globals* globals) {
     CommonInstallHooks(globals);
   });
   pthread_mutex_unlock(&gGlobalsMutateLock);

   // Allow to install hook again to re-initialize heap profiling after the
   // current session finished.
   atomic_store(&gHeapprofdInitHookInstalled, false);
   return nullptr;
 }

 extern "C" void* MallocInitHeapprofdHook(size_t bytes) {
   if (!atomic_exchange(&gHeapprofdInitHookInstalled, true)) {
     pthread_mutex_lock(&gGlobalsMutateLock);
     __libc_globals.mutate([](libc_globals* globals) {
       auto old_dispatch = GetDefaultDispatchTable();
       atomic_store(&globals->default_dispatch_table, nullptr);
       if (GetDispatchTable() == old_dispatch) {
         atomic_store(&globals->current_dispatch_table, nullptr);
       }
     });
     pthread_mutex_unlock(&gGlobalsMutateLock);

     pthread_t thread_id;
     if (pthread_create(&thread_id, nullptr, InitHeapprofd, nullptr) != 0) {
       error_log("%s: heapprofd: failed to pthread_create.", getprogname());
     } else if (pthread_detach(thread_id) != 0) {
       error_log("%s: heapprofd: failed to pthread_detach", getprogname());
     }
     if (pthread_setname_np(thread_id, "heapprofdinit") != 0) {
       error_log("%s: heapprod: failed to pthread_setname_np", getprogname());
     }
   }
   return Malloc(malloc)(bytes);
 }

 bool HeapprofdInitZygoteChildProfiling() {
   // Conditionally start "from startup" profiling.
   if (HeapprofdShouldLoad()) {
     // Directly call the signal handler codepath (properly protects against
     // concurrent invocations).
     HandleHeapprofdSignal();
   }
   return true;
 }

 static bool DispatchReset() {
   if (!atomic_exchange(&gHeapprofdInitInProgress, true)) {
     pthread_mutex_lock(&gGlobalsMutateLock);
     __libc_globals.mutate([](libc_globals* globals) {
       auto old_dispatch = GetDefaultDispatchTable();
       atomic_store(&globals->default_dispatch_table, nullptr);
       if (GetDispatchTable() == old_dispatch) {
         atomic_store(&globals->current_dispatch_table, nullptr);
       }
     });
     pthread_mutex_unlock(&gGlobalsMutateLock);
     atomic_store(&gHeapprofdInitInProgress, false);
     return true;
   }
   errno = EAGAIN;
   return false;
 }

 bool HeapprofdMallopt(int opcode, void* arg, size_t arg_size) {
   if (opcode == M_RESET_HOOKS) {
     if (arg != nullptr || arg_size != 0) {
       errno = EINVAL;
       return false;
     }
     return DispatchReset();
   }
   errno = ENOTSUP;
   return false;
 }
	/*
	* 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.
	*/

	#if defined(LIBC_STATIC)
	#error This file should not be compiled for static targets.
	#endif

	#include <dlfcn.h>
	#include <fcntl.h>
	#include <signal.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <unistd.h>

	#include <platform/bionic/malloc.h>
	#include <private/bionic_config.h>
	#include <private/bionic_malloc_dispatch.h>
	#include <sys/system_properties.h>

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

	static constexpr char kHeapprofdSharedLib[] = "heapprofd_client.so";
	static constexpr char kHeapprofdPrefix[] = "heapprofd";
	static constexpr char kHeapprofdPropertyEnable[] = "heapprofd.enable";

	// The logic for triggering heapprofd (at runtime) is as follows:
	// 1. A reserved profiling signal is received by the process, its si_value
	// discriminating between different handlers. For the case of heapprofd,
	// HandleHeapprofdSignal is called.
	// 2. If the initialization is not already in flight
	// (gHeapprofdInitInProgress is false), the malloc hook is set to
	// point at InitHeapprofdHook, and gHeapprofdInitInProgress is set to
	// true.
	// 3. The next malloc call enters InitHeapprofdHook, which removes the malloc
	// hook, and spawns a detached pthread to run the InitHeapprofd task.
	// (gHeapprofdInitHookInstalled atomic is used to perform this once.)
	// 4. InitHeapprofd, on a dedicated pthread, loads the heapprofd client library,
	// installs the full set of heapprofd hooks, and invokes the client's
	// initializer. The dedicated pthread then terminates.
	// 5. gHeapprofdInitInProgress and gHeapprofdInitHookInstalled are
	// reset to false such that heapprofd can be reinitialized. Reinitialization
	// means that a new profiling session is started, and any still active is
	// torn down.
	//
	// The incremental hooking and a dedicated task thread are used since we cannot
	// do heavy work within a signal handler, or when blocking a malloc invocation.

	// The handle returned by dlopen when previously loading the heapprofd
	// hooks. nullptr if shared library has not been already been loaded.
	static _Atomic (void*) gHeapprofdHandle = nullptr;

	static _Atomic bool gHeapprofdInitInProgress = false;
	static _Atomic bool gHeapprofdInitHookInstalled = false;

	// Set to true if the process has enabled malloc_debug or malloc_hooks, which
	// are incompatible (and take precedence over) heapprofd.
	static _Atomic bool gHeapprofdIncompatibleHooks = false;

	extern "C" void* MallocInitHeapprofdHook(size_t);

	static constexpr MallocDispatch __heapprofd_init_dispatch
	__attribute__((unused)) = {
	Malloc(calloc),
	Malloc(free),
	Malloc(mallinfo),
	MallocInitHeapprofdHook, // malloc replacement
	Malloc(malloc_usable_size),
	Malloc(memalign),
	Malloc(posix_memalign),
	#if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
	Malloc(pvalloc),
	#endif
	Malloc(realloc),
	#if defined(HAVE_DEPRECATED_MALLOC_FUNCS)
	Malloc(valloc),
	#endif
	Malloc(malloc_iterate),
	Malloc(malloc_disable),
	Malloc(malloc_enable),
	Malloc(mallopt),
	Malloc(aligned_alloc),
	Malloc(malloc_info),
	};

	constexpr char kHeapprofdProgramPropertyPrefix[] = "heapprofd.enable.";
	constexpr size_t kHeapprofdProgramPropertyPrefixSize = sizeof(kHeapprofdProgramPropertyPrefix) - 1;
	constexpr size_t kMaxCmdlineSize = 512;

	static bool GetHeapprofdProgramProperty(char* data, size_t size) {
	if (size < kHeapprofdProgramPropertyPrefixSize) {
	error_log("%s: Overflow constructing heapprofd property", getprogname());
	return false;
	}
	memcpy(data, kHeapprofdProgramPropertyPrefix, kHeapprofdProgramPropertyPrefixSize);

	int fd = open("/proc/self/cmdline", O_RDONLY \| O_CLOEXEC);
	if (fd == -1) {
	error_log("%s: Failed to open /proc/self/cmdline", getprogname());
	return false;
	}
	char cmdline[kMaxCmdlineSize];
	ssize_t rd = read(fd, cmdline, sizeof(cmdline) - 1);
	close(fd);
	if (rd == -1) {
	error_log("%s: Failed to read /proc/self/cmdline", getprogname());
	return false;
	}
	cmdline[rd] = '\0';
	char* first_arg = static_cast<char*>(memchr(cmdline, '\0', rd));
	if (first_arg == nullptr) {
	error_log("%s: Overflow reading cmdline", getprogname());
	return false;
	}
	// For consistency with what we do with Java app cmdlines, trim everything
	// after the @ sign of the first arg.
	char* first_at = static_cast<char*>(memchr(cmdline, '@', rd));
	if (first_at != nullptr && first_at < first_arg) {
	*first_at = '\0';
	first_arg = first_at;
	}

	char* start = static_cast<char*>(memrchr(cmdline, '/', first_arg - cmdline));
	if (start == first_arg) {
	// The first argument ended in a slash.
	error_log("%s: cmdline ends in /", getprogname());
	return false;
	} else if (start == nullptr) {
	start = cmdline;
	} else {
	// Skip the /.
	start++;
	}

	size_t name_size = static_cast<size_t>(first_arg - start);
	if (name_size >= size - kHeapprofdProgramPropertyPrefixSize) {
	error_log("%s: overflow constructing heapprofd property.", getprogname());
	return false;
	}
	// + 1 to also copy the trailing null byte.
	memcpy(data + kHeapprofdProgramPropertyPrefixSize, start, name_size + 1);
	return true;
	}

	// Runtime triggering entry-point. Two possible call sites:
	// * when receiving a profiling signal with a si_value indicating heapprofd.
	// * when a Zygote child is marking itself as profileable, and there's a
	// matching profiling request for this process (in which case heapprofd client
	// is loaded synchronously).
	// In both cases, the caller is responsible for verifying that the process is
	// considered profileable.
	void HandleHeapprofdSignal() {
	if (atomic_load_explicit(&gHeapprofdIncompatibleHooks, memory_order_acquire)) {
	error_log("%s: not enabling heapprofd, malloc_debug/malloc_hooks are enabled.", getprogname());
	return;
	}

	// Checking this variable is only necessary when this could conflict with
	// the change to enable the allocation limit. All other places will
	// not ever have a conflict modifying the globals.
	if (!atomic_exchange(&gGlobalsMutating, true)) {
	if (!atomic_exchange(&gHeapprofdInitInProgress, true)) {
	__libc_globals.mutate([](libc_globals* globals) {
	atomic_store(&globals->default_dispatch_table, &__heapprofd_init_dispatch);
	auto dispatch_table = GetDispatchTable();
	if (dispatch_table == nullptr \|\| dispatch_table == &globals->malloc_dispatch_table) {
	atomic_store(&globals->current_dispatch_table, &__heapprofd_init_dispatch);
	}
	});
	}
	atomic_store(&gGlobalsMutating, false);
	}
	// Otherwise, we're racing against malloc_limit's enable logic (at most once
	// per process, and a niche feature). This is highly unlikely, so simply give
	// up if it does happen.
	}

	bool HeapprofdShouldLoad() {
	// First check for heapprofd.enable. If it is set to "all", enable
	// heapprofd for all processes. Otherwise, check heapprofd.enable.${prog},
	// if it is set and not 0, enable heap profiling for this process.
	char property_value[PROP_VALUE_MAX];
	if (__system_property_get(kHeapprofdPropertyEnable, property_value) == 0) {
	return false;
	}
	if (strcmp(property_value, "all") == 0) {
	return true;
	}

	char program_property[kHeapprofdProgramPropertyPrefixSize + kMaxCmdlineSize];
	if (!GetHeapprofdProgramProperty(program_property,
	sizeof(program_property))) {
	return false;
	}
	if (__system_property_get(program_property, property_value) == 0) {
	return false;
	}
	return property_value[0] != '\0';
	}

	void HeapprofdRememberHookConflict() {
	atomic_store_explicit(&gHeapprofdIncompatibleHooks, true, memory_order_release);
	}

	static void CommonInstallHooks(libc_globals* globals) {
	void* impl_handle = atomic_load(&gHeapprofdHandle);
	bool reusing_handle = impl_handle != nullptr;
	if (!reusing_handle) {
	impl_handle = LoadSharedLibrary(kHeapprofdSharedLib, kHeapprofdPrefix, &globals->malloc_dispatch_table);
	if (impl_handle == nullptr) {
	return;
	}
	} else if (!InitSharedLibrary(impl_handle, kHeapprofdSharedLib, kHeapprofdPrefix, &globals->malloc_dispatch_table)) {
	return;
	}

	if (FinishInstallHooks(globals, nullptr, kHeapprofdPrefix)) {
	atomic_store(&gHeapprofdHandle, impl_handle);
	} else if (!reusing_handle) {
	dlclose(impl_handle);
	}

	atomic_store(&gHeapprofdInitInProgress, false);
	}

	void HeapprofdInstallHooksAtInit(libc_globals* globals) {
	if (atomic_exchange(&gHeapprofdInitInProgress, true)) {
	return;
	}
	CommonInstallHooks(globals);
	}

	static void* InitHeapprofd(void*) {
	pthread_mutex_lock(&gGlobalsMutateLock);
	__libc_globals.mutate([](libc_globals* globals) {
	CommonInstallHooks(globals);
	});
	pthread_mutex_unlock(&gGlobalsMutateLock);

	// Allow to install hook again to re-initialize heap profiling after the
	// current session finished.
	atomic_store(&gHeapprofdInitHookInstalled, false);
	return nullptr;
	}

	extern "C" void* MallocInitHeapprofdHook(size_t bytes) {
	if (!atomic_exchange(&gHeapprofdInitHookInstalled, true)) {
	pthread_mutex_lock(&gGlobalsMutateLock);
	__libc_globals.mutate([](libc_globals* globals) {
	auto old_dispatch = GetDefaultDispatchTable();
	atomic_store(&globals->default_dispatch_table, nullptr);
	if (GetDispatchTable() == old_dispatch) {
	atomic_store(&globals->current_dispatch_table, nullptr);
	}
	});
	pthread_mutex_unlock(&gGlobalsMutateLock);

	pthread_t thread_id;
	if (pthread_create(&thread_id, nullptr, InitHeapprofd, nullptr) != 0) {
	error_log("%s: heapprofd: failed to pthread_create.", getprogname());
	} else if (pthread_detach(thread_id) != 0) {
	error_log("%s: heapprofd: failed to pthread_detach", getprogname());
	}
	if (pthread_setname_np(thread_id, "heapprofdinit") != 0) {
	error_log("%s: heapprod: failed to pthread_setname_np", getprogname());
	}
	}
	return Malloc(malloc)(bytes);
	}

	bool HeapprofdInitZygoteChildProfiling() {
	// Conditionally start "from startup" profiling.
	if (HeapprofdShouldLoad()) {
	// Directly call the signal handler codepath (properly protects against
	// concurrent invocations).
	HandleHeapprofdSignal();
	}
	return true;
	}

	static bool DispatchReset() {
	if (!atomic_exchange(&gHeapprofdInitInProgress, true)) {
	pthread_mutex_lock(&gGlobalsMutateLock);
	__libc_globals.mutate([](libc_globals* globals) {
	auto old_dispatch = GetDefaultDispatchTable();
	atomic_store(&globals->default_dispatch_table, nullptr);
	if (GetDispatchTable() == old_dispatch) {
	atomic_store(&globals->current_dispatch_table, nullptr);
	}
	});
	pthread_mutex_unlock(&gGlobalsMutateLock);
	atomic_store(&gHeapprofdInitInProgress, false);
	return true;
	}
	errno = EAGAIN;
	return false;
	}

	bool HeapprofdMallopt(int opcode, void* arg, size_t arg_size) {
	if (opcode == M_RESET_HOOKS) {
	if (arg != nullptr \|\| arg_size != 0) {
	errno = EINVAL;
	return false;
	}
	return DispatchReset();
	}
	errno = ENOTSUP;
	return false;
	}