| // -*- Mode: C++; c-basic-offset: 2; indent-tabs-mode: nil -*- |
| // Copyright (c) 2005, Google Inc. |
| // 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. |
| // * Neither the name of Google Inc. nor the names of its |
| // contributors may be used to endorse or promote products derived from |
| // this software without specific prior written permission. |
| // |
| // 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. |
| |
| // --- |
| // All Rights Reserved. |
| // |
| // Author: Maxim Lifantsev |
| // |
| |
| #include "config.h" |
| |
| #include <fcntl.h> // for O_RDONLY (we use syscall to do actual reads) |
| #include <string.h> |
| #include <errno.h> |
| #ifdef HAVE_UNISTD_H |
| #include <unistd.h> |
| #endif |
| #ifdef HAVE_MMAP |
| #include <sys/mman.h> |
| #endif |
| #ifdef HAVE_PTHREAD |
| #include <pthread.h> |
| #endif |
| #include <sys/stat.h> |
| #include <sys/types.h> |
| #include <time.h> |
| #include <assert.h> |
| |
| #if defined(HAVE_LINUX_PTRACE_H) |
| #include <linux/ptrace.h> |
| #endif |
| #ifdef HAVE_SYS_SYSCALL_H |
| #include <sys/syscall.h> |
| #endif |
| #if defined(_WIN32) || defined(__CYGWIN__) || defined(__CYGWIN32__) || defined(__MINGW32__) |
| #include <wtypes.h> |
| #include <winbase.h> |
| #undef ERROR // windows defines these as macros, which can cause trouble |
| #undef max |
| #undef min |
| #endif |
| |
| #include <string> |
| #include <vector> |
| #include <map> |
| #include <set> |
| #include <algorithm> |
| #include <functional> |
| |
| #include <gperftools/heap-checker.h> |
| |
| #include "base/basictypes.h" |
| #include "base/googleinit.h" |
| #include "base/logging.h" |
| #include <gperftools/stacktrace.h> |
| #include "base/commandlineflags.h" |
| #include "base/elfcore.h" // for i386_regs |
| #include "base/thread_lister.h" |
| #include "heap-profile-table.h" |
| #include "base/low_level_alloc.h" |
| #include "malloc_hook-inl.h" |
| #include <gperftools/malloc_hook.h> |
| #include <gperftools/malloc_extension.h> |
| #include "maybe_threads.h" |
| #include "memory_region_map.h" |
| #include "base/spinlock.h" |
| #include "base/sysinfo.h" |
| #include "base/stl_allocator.h" |
| |
| using std::string; |
| using std::basic_string; |
| using std::pair; |
| using std::map; |
| using std::set; |
| using std::vector; |
| using std::swap; |
| using std::make_pair; |
| using std::min; |
| using std::max; |
| using std::less; |
| using std::char_traits; |
| |
| // If current process is being ptrace()d, 'TracerPid' in /proc/self/status |
| // will be non-zero. |
| static bool IsDebuggerAttached(void) { // only works under linux, probably |
| char buf[256]; // TracerPid comes relatively earlier in status output |
| int fd = open("/proc/self/status", O_RDONLY); |
| if (fd == -1) { |
| return false; // Can't tell for sure. |
| } |
| const int len = read(fd, buf, sizeof(buf)); |
| bool rc = false; |
| if (len > 0) { |
| const char *const kTracerPid = "TracerPid:\t"; |
| buf[len - 1] = '\0'; |
| const char *p = strstr(buf, kTracerPid); |
| if (p != NULL) { |
| rc = (strncmp(p + strlen(kTracerPid), "0\n", 2) != 0); |
| } |
| } |
| close(fd); |
| return rc; |
| } |
| |
| // This is the default if you don't link in -lprofiler |
| extern "C" { |
| ATTRIBUTE_WEAK PERFTOOLS_DLL_DECL bool ProfilingIsEnabledForAllThreads(); |
| bool ProfilingIsEnabledForAllThreads() { return false; } |
| } |
| |
| //---------------------------------------------------------------------- |
| // Flags that control heap-checking |
| //---------------------------------------------------------------------- |
| |
| DEFINE_string(heap_check, |
| EnvToString("HEAPCHECK", ""), |
| "The heap leak checking to be done over the whole executable: " |
| "\"minimal\", \"normal\", \"strict\", " |
| "\"draconian\", \"as-is\", and \"local\" " |
| " or the empty string are the supported choices. " |
| "(See HeapLeakChecker_InternalInitStart for details.)"); |
| |
| DEFINE_bool(heap_check_report, true, "Obsolete"); |
| |
| DEFINE_bool(heap_check_before_constructors, |
| true, |
| "deprecated; pretty much always true now"); |
| |
| DEFINE_bool(heap_check_after_destructors, |
| EnvToBool("HEAP_CHECK_AFTER_DESTRUCTORS", false), |
| "If overall heap check is to end after global destructors " |
| "or right after all REGISTER_HEAPCHECK_CLEANUP's"); |
| |
| DEFINE_bool(heap_check_strict_check, true, "Obsolete"); |
| |
| DEFINE_bool(heap_check_ignore_global_live, |
| EnvToBool("HEAP_CHECK_IGNORE_GLOBAL_LIVE", true), |
| "If overall heap check is to ignore heap objects reachable " |
| "from the global data"); |
| |
| DEFINE_bool(heap_check_identify_leaks, |
| EnvToBool("HEAP_CHECK_IDENTIFY_LEAKS", false), |
| "If heap check should generate the addresses of the leaked " |
| "objects in the memory leak profiles. This may be useful " |
| "in tracking down leaks where only a small fraction of " |
| "objects allocated at the same stack trace are leaked."); |
| |
| DEFINE_bool(heap_check_ignore_thread_live, |
| EnvToBool("HEAP_CHECK_IGNORE_THREAD_LIVE", true), |
| "If set to true, objects reachable from thread stacks " |
| "and registers are not reported as leaks"); |
| |
| DEFINE_bool(heap_check_test_pointer_alignment, |
| EnvToBool("HEAP_CHECK_TEST_POINTER_ALIGNMENT", false), |
| "Set to true to check if the found leak can be due to " |
| "use of unaligned pointers"); |
| |
| // Alignment at which all pointers in memory are supposed to be located; |
| // use 1 if any alignment is ok. |
| // heap_check_test_pointer_alignment flag guides if we try the value of 1. |
| // The larger it can be, the lesser is the chance of missing real leaks. |
| static const size_t kPointerSourceAlignment = sizeof(void*); |
| DEFINE_int32(heap_check_pointer_source_alignment, |
| EnvToInt("HEAP_CHECK_POINTER_SOURCE_ALIGNMENT", |
| kPointerSourceAlignment), |
| "Alignment at which all pointers in memory are supposed to be " |
| "located. Use 1 if any alignment is ok."); |
| |
| // A reasonable default to handle pointers inside of typical class objects: |
| // Too low and we won't be able to traverse pointers to normally-used |
| // nested objects and base parts of multiple-inherited objects. |
| // Too high and it will both slow down leak checking (FindInsideAlloc |
| // in HaveOnHeapLocked will get slower when there are large on-heap objects) |
| // and make it probabilistically more likely to miss leaks |
| // of large-sized objects. |
| static const int64 kHeapCheckMaxPointerOffset = 1024; |
| DEFINE_int64(heap_check_max_pointer_offset, |
| EnvToInt("HEAP_CHECK_MAX_POINTER_OFFSET", |
| kHeapCheckMaxPointerOffset), |
| "Largest pointer offset for which we traverse " |
| "pointers going inside of heap allocated objects. " |
| "Set to -1 to use the actual largest heap object size."); |
| |
| DEFINE_bool(heap_check_run_under_gdb, |
| EnvToBool("HEAP_CHECK_RUN_UNDER_GDB", false), |
| "If false, turns off heap-checking library when running under gdb " |
| "(normally, set to 'true' only when debugging the heap-checker)"); |
| |
| DEFINE_int32(heap_check_delay_seconds, 0, |
| "Number of seconds to delay on-exit heap checking." |
| " If you set this flag," |
| " you may also want to set exit_timeout_seconds in order to" |
| " avoid exit timeouts.\n" |
| "NOTE: This flag is to be used only to help diagnose issues" |
| " where it is suspected that the heap checker is reporting" |
| " false leaks that will disappear if the heap checker delays" |
| " its checks. Report any such issues to the heap-checker" |
| " maintainer(s)."); |
| |
| //---------------------------------------------------------------------- |
| |
| DEFINE_string(heap_profile_pprof, |
| EnvToString("PPROF_PATH", "pprof"), |
| "OBSOLETE; not used"); |
| |
| DEFINE_string(heap_check_dump_directory, |
| EnvToString("HEAP_CHECK_DUMP_DIRECTORY", "/tmp"), |
| "Directory to put heap-checker leak dump information"); |
| |
| |
| //---------------------------------------------------------------------- |
| // HeapLeakChecker global data |
| //---------------------------------------------------------------------- |
| |
| // Global lock for all the global data of this module. |
| static SpinLock heap_checker_lock(SpinLock::LINKER_INITIALIZED); |
| |
| //---------------------------------------------------------------------- |
| |
| // Heap profile prefix for leak checking profiles. |
| // Gets assigned once when leak checking is turned on, then never modified. |
| static const string* profile_name_prefix = NULL; |
| |
| // Whole-program heap leak checker. |
| // Gets assigned once when leak checking is turned on, |
| // then main_heap_checker is never deleted. |
| static HeapLeakChecker* main_heap_checker = NULL; |
| |
| // Whether we will use main_heap_checker to do a check at program exit |
| // automatically. In any case user can ask for more checks on main_heap_checker |
| // via GlobalChecker(). |
| static bool do_main_heap_check = false; |
| |
| // The heap profile we use to collect info about the heap. |
| // This is created in HeapLeakChecker::BeforeConstructorsLocked |
| // together with setting heap_checker_on (below) to true |
| // and registering our new/delete malloc hooks; |
| // similarly all are unset in HeapLeakChecker::TurnItselfOffLocked. |
| static HeapProfileTable* heap_profile = NULL; |
| |
| // If we are doing (or going to do) any kind of heap-checking. |
| static bool heap_checker_on = false; |
| |
| // pid of the process that does whole-program heap leak checking |
| static pid_t heap_checker_pid = 0; |
| |
| // If we did heap profiling during global constructors execution |
| static bool constructor_heap_profiling = false; |
| |
| // RAW_VLOG level we dump key INFO messages at. If you want to turn |
| // off these messages, set the environment variable PERFTOOLS_VERBOSE=-1. |
| static const int heap_checker_info_level = 0; |
| |
| //---------------------------------------------------------------------- |
| // HeapLeakChecker's own memory allocator that is |
| // independent of the normal program allocator. |
| //---------------------------------------------------------------------- |
| |
| // Wrapper of LowLevelAlloc for STL_Allocator and direct use. |
| // We always access this class under held heap_checker_lock, |
| // this allows us to in particular protect the period when threads are stopped |
| // at random spots with TCMalloc_ListAllProcessThreads by heap_checker_lock, |
| // w/o worrying about the lock in LowLevelAlloc::Arena. |
| // We rely on the fact that we use an own arena with an own lock here. |
| class HeapLeakChecker::Allocator { |
| public: |
| static void Init() { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| RAW_DCHECK(arena_ == NULL, ""); |
| arena_ = LowLevelAlloc::NewArena(0, LowLevelAlloc::DefaultArena()); |
| } |
| static void Shutdown() { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| if (!LowLevelAlloc::DeleteArena(arena_) || alloc_count_ != 0) { |
| RAW_LOG(FATAL, "Internal heap checker leak of %d objects", alloc_count_); |
| } |
| } |
| static int alloc_count() { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| return alloc_count_; |
| } |
| static void* Allocate(size_t n) { |
| RAW_DCHECK(arena_ && heap_checker_lock.IsHeld(), ""); |
| void* p = LowLevelAlloc::AllocWithArena(n, arena_); |
| if (p) alloc_count_ += 1; |
| return p; |
| } |
| static void Free(void* p) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| if (p) alloc_count_ -= 1; |
| LowLevelAlloc::Free(p); |
| } |
| static void Free(void* p, size_t /* n */) { |
| Free(p); |
| } |
| // destruct, free, and make *p to be NULL |
| template<typename T> static void DeleteAndNull(T** p) { |
| (*p)->~T(); |
| Free(*p); |
| *p = NULL; |
| } |
| template<typename T> static void DeleteAndNullIfNot(T** p) { |
| if (*p != NULL) DeleteAndNull(p); |
| } |
| private: |
| static LowLevelAlloc::Arena* arena_; |
| static int alloc_count_; |
| }; |
| |
| LowLevelAlloc::Arena* HeapLeakChecker::Allocator::arena_ = NULL; |
| int HeapLeakChecker::Allocator::alloc_count_ = 0; |
| |
| //---------------------------------------------------------------------- |
| // HeapLeakChecker live object tracking components |
| //---------------------------------------------------------------------- |
| |
| // Cases of live object placement we distinguish |
| enum ObjectPlacement { |
| MUST_BE_ON_HEAP, // Must point to a live object of the matching size in the |
| // heap_profile map of the heap when we get to it |
| IGNORED_ON_HEAP, // Is a live (ignored) object on heap |
| MAYBE_LIVE, // Is a piece of writable memory from /proc/self/maps |
| IN_GLOBAL_DATA, // Is part of global data region of the executable |
| THREAD_DATA, // Part of a thread stack and a thread descriptor with TLS |
| THREAD_REGISTERS, // Values in registers of some thread |
| }; |
| |
| // Information about an allocated object |
| struct AllocObject { |
| const void* ptr; // the object |
| uintptr_t size; // its size |
| ObjectPlacement place; // where ptr points to |
| |
| AllocObject(const void* p, size_t s, ObjectPlacement l) |
| : ptr(p), size(s), place(l) { } |
| }; |
| |
| // All objects (memory ranges) ignored via HeapLeakChecker::IgnoreObject |
| // Key is the object's address; value is its size. |
| typedef map<uintptr_t, size_t, less<uintptr_t>, |
| STL_Allocator<pair<const uintptr_t, size_t>, |
| HeapLeakChecker::Allocator> |
| > IgnoredObjectsMap; |
| static IgnoredObjectsMap* ignored_objects = NULL; |
| |
| // All objects (memory ranges) that we consider to be the sources of pointers |
| // to live (not leaked) objects. |
| // At different times this holds (what can be reached from) global data regions |
| // and the objects we've been told to ignore. |
| // For any AllocObject::ptr "live_objects" is supposed to contain at most one |
| // record at any time. We maintain this by checking with the heap_profile map |
| // of the heap and removing the live heap objects we've handled from it. |
| // This vector is maintained as a stack and the frontier of reachable |
| // live heap objects in our flood traversal of them. |
| typedef vector<AllocObject, |
| STL_Allocator<AllocObject, HeapLeakChecker::Allocator> |
| > LiveObjectsStack; |
| static LiveObjectsStack* live_objects = NULL; |
| |
| // A special string type that uses my allocator |
| typedef basic_string<char, char_traits<char>, |
| STL_Allocator<char, HeapLeakChecker::Allocator> |
| > HCL_string; |
| |
| // A placeholder to fill-in the starting values for live_objects |
| // for each library so we can keep the library-name association for logging. |
| typedef map<HCL_string, LiveObjectsStack, less<HCL_string>, |
| STL_Allocator<pair<const HCL_string, LiveObjectsStack>, |
| HeapLeakChecker::Allocator> |
| > LibraryLiveObjectsStacks; |
| static LibraryLiveObjectsStacks* library_live_objects = NULL; |
| |
| // Value stored in the map of disabled address ranges; |
| // its key is the end of the address range. |
| // We'll ignore allocations with a return address in a disabled range |
| // if the address occurs at 'max_depth' or less in the stack trace. |
| struct HeapLeakChecker::RangeValue { |
| uintptr_t start_address; // the start of the range |
| int max_depth; // the maximal stack depth to disable at |
| }; |
| typedef map<uintptr_t, HeapLeakChecker::RangeValue, less<uintptr_t>, |
| STL_Allocator<pair<const uintptr_t, HeapLeakChecker::RangeValue>, |
| HeapLeakChecker::Allocator> |
| > DisabledRangeMap; |
| // The disabled program counter address ranges for profile dumping |
| // that are registered with HeapLeakChecker::DisableChecksFromToLocked. |
| static DisabledRangeMap* disabled_ranges = NULL; |
| |
| // Set of stack tops. |
| // These are used to consider live only appropriate chunks of the memory areas |
| // that are used for stacks (and maybe thread-specific data as well) |
| // so that we do not treat pointers from outdated stack frames as live. |
| typedef set<uintptr_t, less<uintptr_t>, |
| STL_Allocator<uintptr_t, HeapLeakChecker::Allocator> |
| > StackTopSet; |
| static StackTopSet* stack_tops = NULL; |
| |
| // A map of ranges of code addresses for the system libraries |
| // that can mmap/mremap/sbrk-allocate memory regions for stacks |
| // and thread-local storage that we want to consider as live global data. |
| // Maps from the end address to the start address. |
| typedef map<uintptr_t, uintptr_t, less<uintptr_t>, |
| STL_Allocator<pair<const uintptr_t, uintptr_t>, |
| HeapLeakChecker::Allocator> |
| > GlobalRegionCallerRangeMap; |
| static GlobalRegionCallerRangeMap* global_region_caller_ranges = NULL; |
| |
| // TODO(maxim): make our big data structs into own modules |
| |
| // Disabler is implemented by keeping track of a per-thread count |
| // of active Disabler objects. Any objects allocated while the |
| // count > 0 are not reported. |
| |
| #ifdef HAVE_TLS |
| |
| static __thread int thread_disable_counter |
| // The "inital exec" model is faster than the default TLS model, at |
| // the cost you can't dlopen this library. But dlopen on heap-checker |
| // doesn't work anyway -- it must run before main -- so this is a good |
| // trade-off. |
| # ifdef HAVE___ATTRIBUTE__ |
| __attribute__ ((tls_model ("initial-exec"))) |
| # endif |
| ; |
| inline int get_thread_disable_counter() { |
| return thread_disable_counter; |
| } |
| inline void set_thread_disable_counter(int value) { |
| thread_disable_counter = value; |
| } |
| |
| #else // #ifdef HAVE_TLS |
| |
| static pthread_key_t thread_disable_counter_key; |
| static int main_thread_counter; // storage for use before main() |
| static bool use_main_thread_counter = true; |
| |
| // TODO(csilvers): this is called from NewHook, in the middle of malloc(). |
| // If perftools_pthread_getspecific calls malloc, that will lead to an |
| // infinite loop. I don't know how to fix that, so I hope it never happens! |
| inline int get_thread_disable_counter() { |
| if (use_main_thread_counter) // means we're running really early |
| return main_thread_counter; |
| void* p = perftools_pthread_getspecific(thread_disable_counter_key); |
| return (intptr_t)p; // kinda evil: store the counter directly in the void* |
| } |
| |
| inline void set_thread_disable_counter(int value) { |
| if (use_main_thread_counter) { // means we're running really early |
| main_thread_counter = value; |
| return; |
| } |
| intptr_t pointer_sized_value = value; |
| // kinda evil: store the counter directly in the void* |
| void* p = (void*)pointer_sized_value; |
| // NOTE: this may call malloc, which will call NewHook which will call |
| // get_thread_disable_counter() which will call pthread_getspecific(). I |
| // don't know if anything bad can happen if we call getspecific() in the |
| // middle of a setspecific() call. It seems to work ok in practice... |
| perftools_pthread_setspecific(thread_disable_counter_key, p); |
| } |
| |
| // The idea here is that this initializer will run pretty late: after |
| // pthreads have been totally set up. At this point we can call |
| // pthreads routines, so we set those up. |
| class InitThreadDisableCounter { |
| public: |
| InitThreadDisableCounter() { |
| perftools_pthread_key_create(&thread_disable_counter_key, NULL); |
| // Set up the main thread's value, which we have a special variable for. |
| void* p = (void*)main_thread_counter; // store the counter directly |
| perftools_pthread_setspecific(thread_disable_counter_key, p); |
| use_main_thread_counter = false; |
| } |
| }; |
| InitThreadDisableCounter init_thread_disable_counter; |
| |
| #endif // #ifdef HAVE_TLS |
| |
| HeapLeakChecker::Disabler::Disabler() { |
| // It is faster to unconditionally increment the thread-local |
| // counter than to check whether or not heap-checking is on |
| // in a thread-safe manner. |
| int counter = get_thread_disable_counter(); |
| set_thread_disable_counter(counter + 1); |
| RAW_VLOG(10, "Increasing thread disable counter to %d", counter + 1); |
| } |
| |
| HeapLeakChecker::Disabler::~Disabler() { |
| int counter = get_thread_disable_counter(); |
| RAW_DCHECK(counter > 0, ""); |
| if (counter > 0) { |
| set_thread_disable_counter(counter - 1); |
| RAW_VLOG(10, "Decreasing thread disable counter to %d", counter); |
| } else { |
| RAW_VLOG(0, "Thread disable counter underflow : %d", counter); |
| } |
| } |
| |
| //---------------------------------------------------------------------- |
| |
| // The size of the largest heap object allocated so far. |
| static size_t max_heap_object_size = 0; |
| // The possible range of addresses that can point |
| // into one of the elements of heap_objects. |
| static uintptr_t min_heap_address = uintptr_t(-1LL); |
| static uintptr_t max_heap_address = 0; |
| |
| //---------------------------------------------------------------------- |
| |
| // Simple casting helpers for uintptr_t and void*: |
| template<typename T> |
| inline static const void* AsPtr(T addr) { |
| return reinterpret_cast<void*>(addr); |
| } |
| inline static uintptr_t AsInt(const void* ptr) { |
| return reinterpret_cast<uintptr_t>(ptr); |
| } |
| |
| //---------------------------------------------------------------------- |
| |
| // We've seen reports that strstr causes heap-checker crashes in some |
| // libc's (?): |
| // http://code.google.com/p/gperftools/issues/detail?id=263 |
| // It's simple enough to use our own. This is not in time-critical code. |
| static const char* hc_strstr(const char* s1, const char* s2) { |
| const size_t len = strlen(s2); |
| RAW_CHECK(len > 0, "Unexpected empty string passed to strstr()"); |
| for (const char* p = strchr(s1, *s2); p != NULL; p = strchr(p+1, *s2)) { |
| if (strncmp(p, s2, len) == 0) { |
| return p; |
| } |
| } |
| return NULL; |
| } |
| |
| //---------------------------------------------------------------------- |
| |
| // Our hooks for MallocHook |
| static void NewHook(const void* ptr, size_t size) { |
| if (ptr != NULL) { |
| const int counter = get_thread_disable_counter(); |
| const bool ignore = (counter > 0); |
| RAW_VLOG(16, "Recording Alloc: %p of %" PRIuS "; %d", ptr, size, |
| int(counter)); |
| |
| // Fetch the caller's stack trace before acquiring heap_checker_lock. |
| void* stack[HeapProfileTable::kMaxStackDepth]; |
| int depth = HeapProfileTable::GetCallerStackTrace(0, stack); |
| |
| { SpinLockHolder l(&heap_checker_lock); |
| if (size > max_heap_object_size) max_heap_object_size = size; |
| uintptr_t addr = AsInt(ptr); |
| if (addr < min_heap_address) min_heap_address = addr; |
| addr += size; |
| if (addr > max_heap_address) max_heap_address = addr; |
| if (heap_checker_on) { |
| heap_profile->RecordAlloc(ptr, size, depth, stack); |
| if (ignore) { |
| heap_profile->MarkAsIgnored(ptr); |
| } |
| } |
| } |
| RAW_VLOG(17, "Alloc Recorded: %p of %" PRIuS "", ptr, size); |
| } |
| } |
| |
| static void DeleteHook(const void* ptr) { |
| if (ptr != NULL) { |
| RAW_VLOG(16, "Recording Free %p", ptr); |
| { SpinLockHolder l(&heap_checker_lock); |
| if (heap_checker_on) heap_profile->RecordFree(ptr); |
| } |
| RAW_VLOG(17, "Free Recorded: %p", ptr); |
| } |
| } |
| |
| //---------------------------------------------------------------------- |
| |
| enum StackDirection { |
| GROWS_TOWARDS_HIGH_ADDRESSES, |
| GROWS_TOWARDS_LOW_ADDRESSES, |
| UNKNOWN_DIRECTION |
| }; |
| |
| // Determine which way the stack grows: |
| |
| static StackDirection ATTRIBUTE_NOINLINE GetStackDirection( |
| const uintptr_t *const ptr) { |
| uintptr_t x; |
| if (&x < ptr) |
| return GROWS_TOWARDS_LOW_ADDRESSES; |
| if (ptr < &x) |
| return GROWS_TOWARDS_HIGH_ADDRESSES; |
| |
| RAW_CHECK(0, ""); // Couldn't determine the stack direction. |
| |
| return UNKNOWN_DIRECTION; |
| } |
| |
| // Direction of stack growth (will initialize via GetStackDirection()) |
| static StackDirection stack_direction = UNKNOWN_DIRECTION; |
| |
| // This routine is called for every thread stack we know about to register it. |
| static void RegisterStackLocked(const void* top_ptr) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| RAW_DCHECK(MemoryRegionMap::LockIsHeld(), ""); |
| RAW_VLOG(10, "Thread stack at %p", top_ptr); |
| uintptr_t top = AsInt(top_ptr); |
| stack_tops->insert(top); // add for later use |
| |
| // make sure stack_direction is initialized |
| if (stack_direction == UNKNOWN_DIRECTION) { |
| stack_direction = GetStackDirection(&top); |
| } |
| |
| // Find memory region with this stack |
| MemoryRegionMap::Region region; |
| if (MemoryRegionMap::FindAndMarkStackRegion(top, ®ion)) { |
| // Make the proper portion of the stack live: |
| if (stack_direction == GROWS_TOWARDS_LOW_ADDRESSES) { |
| RAW_VLOG(11, "Live stack at %p of %" PRIuPTR " bytes", |
| top_ptr, region.end_addr - top); |
| live_objects->push_back(AllocObject(top_ptr, region.end_addr - top, |
| THREAD_DATA)); |
| } else { // GROWS_TOWARDS_HIGH_ADDRESSES |
| RAW_VLOG(11, "Live stack at %p of %" PRIuPTR " bytes", |
| AsPtr(region.start_addr), |
| top - region.start_addr); |
| live_objects->push_back(AllocObject(AsPtr(region.start_addr), |
| top - region.start_addr, |
| THREAD_DATA)); |
| } |
| // not in MemoryRegionMap, look in library_live_objects: |
| } else if (FLAGS_heap_check_ignore_global_live) { |
| for (LibraryLiveObjectsStacks::iterator lib = library_live_objects->begin(); |
| lib != library_live_objects->end(); ++lib) { |
| for (LiveObjectsStack::iterator span = lib->second.begin(); |
| span != lib->second.end(); ++span) { |
| uintptr_t start = AsInt(span->ptr); |
| uintptr_t end = start + span->size; |
| if (start <= top && top < end) { |
| RAW_VLOG(11, "Stack at %p is inside /proc/self/maps chunk %p..%p", |
| top_ptr, AsPtr(start), AsPtr(end)); |
| // Shrink start..end region by chopping away the memory regions in |
| // MemoryRegionMap that land in it to undo merging of regions |
| // in /proc/self/maps, so that we correctly identify what portion |
| // of start..end is actually the stack region. |
| uintptr_t stack_start = start; |
| uintptr_t stack_end = end; |
| // can optimize-away this loop, but it does not run often |
| RAW_DCHECK(MemoryRegionMap::LockIsHeld(), ""); |
| for (MemoryRegionMap::RegionIterator r = |
| MemoryRegionMap::BeginRegionLocked(); |
| r != MemoryRegionMap::EndRegionLocked(); ++r) { |
| if (top < r->start_addr && r->start_addr < stack_end) { |
| stack_end = r->start_addr; |
| } |
| if (stack_start < r->end_addr && r->end_addr <= top) { |
| stack_start = r->end_addr; |
| } |
| } |
| if (stack_start != start || stack_end != end) { |
| RAW_VLOG(11, "Stack at %p is actually inside memory chunk %p..%p", |
| top_ptr, AsPtr(stack_start), AsPtr(stack_end)); |
| } |
| // Make the proper portion of the stack live: |
| if (stack_direction == GROWS_TOWARDS_LOW_ADDRESSES) { |
| RAW_VLOG(11, "Live stack at %p of %" PRIuPTR " bytes", |
| top_ptr, stack_end - top); |
| live_objects->push_back( |
| AllocObject(top_ptr, stack_end - top, THREAD_DATA)); |
| } else { // GROWS_TOWARDS_HIGH_ADDRESSES |
| RAW_VLOG(11, "Live stack at %p of %" PRIuPTR " bytes", |
| AsPtr(stack_start), top - stack_start); |
| live_objects->push_back( |
| AllocObject(AsPtr(stack_start), top - stack_start, THREAD_DATA)); |
| } |
| lib->second.erase(span); // kill the rest of the region |
| // Put the non-stack part(s) of the region back: |
| if (stack_start != start) { |
| lib->second.push_back(AllocObject(AsPtr(start), stack_start - start, |
| MAYBE_LIVE)); |
| } |
| if (stack_end != end) { |
| lib->second.push_back(AllocObject(AsPtr(stack_end), end - stack_end, |
| MAYBE_LIVE)); |
| } |
| return; |
| } |
| } |
| } |
| RAW_LOG(ERROR, "Memory region for stack at %p not found. " |
| "Will likely report false leak positives.", top_ptr); |
| } |
| } |
| |
| // Iterator for heap allocation map data to make ignored objects "live" |
| // (i.e., treated as roots for the mark-and-sweep phase) |
| static void MakeIgnoredObjectsLiveCallbackLocked( |
| const void* ptr, const HeapProfileTable::AllocInfo& info) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| if (info.ignored) { |
| live_objects->push_back(AllocObject(ptr, info.object_size, |
| MUST_BE_ON_HEAP)); |
| } |
| } |
| |
| // Iterator for heap allocation map data to make objects allocated from |
| // disabled regions of code to be live. |
| static void MakeDisabledLiveCallbackLocked( |
| const void* ptr, const HeapProfileTable::AllocInfo& info) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| bool stack_disable = false; |
| bool range_disable = false; |
| for (int depth = 0; depth < info.stack_depth; depth++) { |
| uintptr_t addr = AsInt(info.call_stack[depth]); |
| if (disabled_ranges) { |
| DisabledRangeMap::const_iterator iter |
| = disabled_ranges->upper_bound(addr); |
| if (iter != disabled_ranges->end()) { |
| RAW_DCHECK(iter->first > addr, ""); |
| if (iter->second.start_address < addr && |
| iter->second.max_depth > depth) { |
| range_disable = true; // in range; dropping |
| break; |
| } |
| } |
| } |
| } |
| if (stack_disable || range_disable) { |
| uintptr_t start_address = AsInt(ptr); |
| uintptr_t end_address = start_address + info.object_size; |
| StackTopSet::const_iterator iter |
| = stack_tops->lower_bound(start_address); |
| if (iter != stack_tops->end()) { |
| RAW_DCHECK(*iter >= start_address, ""); |
| if (*iter < end_address) { |
| // We do not disable (treat as live) whole allocated regions |
| // if they are used to hold thread call stacks |
| // (i.e. when we find a stack inside). |
| // The reason is that we'll treat as live the currently used |
| // stack portions anyway (see RegisterStackLocked), |
| // and the rest of the region where the stack lives can well |
| // contain outdated stack variables which are not live anymore, |
| // hence should not be treated as such. |
| RAW_VLOG(11, "Not %s-disabling %" PRIuS " bytes at %p" |
| ": have stack inside: %p", |
| (stack_disable ? "stack" : "range"), |
| info.object_size, ptr, AsPtr(*iter)); |
| return; |
| } |
| } |
| RAW_VLOG(11, "%s-disabling %" PRIuS " bytes at %p", |
| (stack_disable ? "Stack" : "Range"), info.object_size, ptr); |
| live_objects->push_back(AllocObject(ptr, info.object_size, |
| MUST_BE_ON_HEAP)); |
| } |
| } |
| |
| static const char kUnnamedProcSelfMapEntry[] = "UNNAMED"; |
| |
| // This function takes some fields from a /proc/self/maps line: |
| // |
| // start_address start address of a memory region. |
| // end_address end address of a memory region |
| // permissions rwx + private/shared bit |
| // filename filename of the mapped file |
| // |
| // If the region is not writeable, then it cannot have any heap |
| // pointers in it, otherwise we record it as a candidate live region |
| // to get filtered later. |
| static void RecordGlobalDataLocked(uintptr_t start_address, |
| uintptr_t end_address, |
| const char* permissions, |
| const char* filename) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| // Ignore non-writeable regions. |
| if (strchr(permissions, 'w') == NULL) return; |
| if (filename == NULL || *filename == '\0') { |
| filename = kUnnamedProcSelfMapEntry; |
| } |
| RAW_VLOG(11, "Looking into %s: 0x%" PRIxPTR "..0x%" PRIxPTR, |
| filename, start_address, end_address); |
| (*library_live_objects)[filename]. |
| push_back(AllocObject(AsPtr(start_address), |
| end_address - start_address, |
| MAYBE_LIVE)); |
| } |
| |
| // See if 'library' from /proc/self/maps has base name 'library_base' |
| // i.e. contains it and has '.' or '-' after it. |
| static bool IsLibraryNamed(const char* library, const char* library_base) { |
| const char* p = hc_strstr(library, library_base); |
| size_t sz = strlen(library_base); |
| return p != NULL && (p[sz] == '.' || p[sz] == '-'); |
| } |
| |
| // static |
| void HeapLeakChecker::DisableLibraryAllocsLocked(const char* library, |
| uintptr_t start_address, |
| uintptr_t end_address) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| int depth = 0; |
| // TODO(maxim): maybe this should be extended to also use objdump |
| // and pick the text portion of the library more precisely. |
| if (IsLibraryNamed(library, "/libpthread") || |
| // libpthread has a lot of small "system" leaks we don't care about. |
| // In particular it allocates memory to store data supplied via |
| // pthread_setspecific (which can be the only pointer to a heap object). |
| IsLibraryNamed(library, "/libdl") || |
| // library loaders leak some "system" heap that we don't care about |
| IsLibraryNamed(library, "/libcrypto") || |
| // Sometimes libcrypto of OpenSSH is compiled with -fomit-frame-pointer |
| // (any library can be, of course, but this one often is because speed |
| // is so important for making crypto usable). We ignore all its |
| // allocations because we can't see the call stacks. We'd prefer |
| // to ignore allocations done in files/symbols that match |
| // "default_malloc_ex|default_realloc_ex" |
| // but that doesn't work when the end-result binary is stripped. |
| IsLibraryNamed(library, "/libjvm") || |
| // JVM has a lot of leaks we don't care about. |
| IsLibraryNamed(library, "/libzip") |
| // The JVM leaks java.util.zip.Inflater after loading classes. |
| ) { |
| depth = 1; // only disable allocation calls directly from the library code |
| } else if (IsLibraryNamed(library, "/ld") |
| // library loader leaks some "system" heap |
| // (e.g. thread-local storage) that we don't care about |
| ) { |
| depth = 2; // disable allocation calls directly from the library code |
| // and at depth 2 from it. |
| // We need depth 2 here solely because of a libc bug that |
| // forces us to jump through __memalign_hook and MemalignOverride hoops |
| // in tcmalloc.cc. |
| // Those buggy __libc_memalign() calls are in ld-linux.so and happen for |
| // thread-local storage allocations that we want to ignore here. |
| // We go with the depth-2 hack as a workaround for this libc bug: |
| // otherwise we'd need to extend MallocHook interface |
| // so that correct stack depth adjustment can be propagated from |
| // the exceptional case of MemalignOverride. |
| // Using depth 2 here should not mask real leaks because ld-linux.so |
| // does not call user code. |
| } |
| if (depth) { |
| RAW_VLOG(10, "Disabling allocations from %s at depth %d:", library, depth); |
| DisableChecksFromToLocked(AsPtr(start_address), AsPtr(end_address), depth); |
| if (IsLibraryNamed(library, "/libpthread") || |
| IsLibraryNamed(library, "/libdl") || |
| IsLibraryNamed(library, "/ld")) { |
| RAW_VLOG(10, "Global memory regions made by %s will be live data", |
| library); |
| if (global_region_caller_ranges == NULL) { |
| global_region_caller_ranges = |
| new(Allocator::Allocate(sizeof(GlobalRegionCallerRangeMap))) |
| GlobalRegionCallerRangeMap; |
| } |
| global_region_caller_ranges |
| ->insert(make_pair(end_address, start_address)); |
| } |
| } |
| } |
| |
| // static |
| HeapLeakChecker::ProcMapsResult HeapLeakChecker::UseProcMapsLocked( |
| ProcMapsTask proc_maps_task) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| // Need to provide own scratch memory to ProcMapsIterator: |
| ProcMapsIterator::Buffer buffer; |
| ProcMapsIterator it(0, &buffer); |
| if (!it.Valid()) { |
| int errsv = errno; |
| RAW_LOG(ERROR, "Could not open /proc/self/maps: errno=%d. " |
| "Libraries will not be handled correctly.", errsv); |
| return CANT_OPEN_PROC_MAPS; |
| } |
| uint64 start_address, end_address, file_offset; |
| int64 inode; |
| char *permissions, *filename; |
| bool saw_shared_lib = false; |
| bool saw_nonzero_inode = false; |
| bool saw_shared_lib_with_nonzero_inode = false; |
| while (it.Next(&start_address, &end_address, &permissions, |
| &file_offset, &inode, &filename)) { |
| if (start_address >= end_address) { |
| // Warn if a line we can be interested in is ill-formed: |
| if (inode != 0) { |
| RAW_LOG(ERROR, "Errors reading /proc/self/maps. " |
| "Some global memory regions will not " |
| "be handled correctly."); |
| } |
| // Silently skip other ill-formed lines: some are possible |
| // probably due to the interplay of how /proc/self/maps is updated |
| // while we read it in chunks in ProcMapsIterator and |
| // do things in this loop. |
| continue; |
| } |
| // Determine if any shared libraries are present (this is the same |
| // list of extensions as is found in pprof). We want to ignore |
| // 'fake' libraries with inode 0 when determining. However, some |
| // systems don't share inodes via /proc, so we turn off this check |
| // if we don't see any evidence that we're getting inode info. |
| if (inode != 0) { |
| saw_nonzero_inode = true; |
| } |
| if ((hc_strstr(filename, "lib") && hc_strstr(filename, ".so")) || |
| hc_strstr(filename, ".dll") || |
| // not all .dylib filenames start with lib. .dylib is big enough |
| // that we are unlikely to get false matches just checking that. |
| hc_strstr(filename, ".dylib") || hc_strstr(filename, ".bundle")) { |
| saw_shared_lib = true; |
| if (inode != 0) { |
| saw_shared_lib_with_nonzero_inode = true; |
| } |
| } |
| |
| switch (proc_maps_task) { |
| case DISABLE_LIBRARY_ALLOCS: |
| // All lines starting like |
| // "401dc000-4030f000 r??p 00132000 03:01 13991972 lib/bin" |
| // identify a data and code sections of a shared library or our binary |
| if (inode != 0 && strncmp(permissions, "r-xp", 4) == 0) { |
| DisableLibraryAllocsLocked(filename, start_address, end_address); |
| } |
| break; |
| case RECORD_GLOBAL_DATA: |
| RecordGlobalDataLocked(start_address, end_address, |
| permissions, filename); |
| break; |
| default: |
| RAW_CHECK(0, ""); |
| } |
| } |
| // If /proc/self/maps is reporting inodes properly (we saw a |
| // non-zero inode), then we only say we saw a shared lib if we saw a |
| // 'real' one, with a non-zero inode. |
| if (saw_nonzero_inode) { |
| saw_shared_lib = saw_shared_lib_with_nonzero_inode; |
| } |
| if (!saw_shared_lib) { |
| RAW_LOG(ERROR, "No shared libs detected. Will likely report false leak " |
| "positives for statically linked executables."); |
| return NO_SHARED_LIBS_IN_PROC_MAPS; |
| } |
| return PROC_MAPS_USED; |
| } |
| |
| // Total number and size of live objects dropped from the profile; |
| // (re)initialized in IgnoreAllLiveObjectsLocked. |
| static int64 live_objects_total; |
| static int64 live_bytes_total; |
| |
| // pid of the thread that is doing the current leak check |
| // (protected by our lock; IgnoreAllLiveObjectsLocked sets it) |
| static pid_t self_thread_pid = 0; |
| |
| // Status of our thread listing callback execution |
| // (protected by our lock; used from within IgnoreAllLiveObjectsLocked) |
| static enum { |
| CALLBACK_NOT_STARTED, |
| CALLBACK_STARTED, |
| CALLBACK_COMPLETED, |
| } thread_listing_status = CALLBACK_NOT_STARTED; |
| |
| // Ideally to avoid deadlocks this function should not result in any libc |
| // or other function calls that might need to lock a mutex: |
| // It is called when all threads of a process are stopped |
| // at arbitrary points thus potentially holding those locks. |
| // |
| // In practice we are calling some simple i/o and sprintf-type library functions |
| // for logging messages, but use only our own LowLevelAlloc::Arena allocator. |
| // |
| // This is known to be buggy: the library i/o function calls are able to cause |
| // deadlocks when they request a lock that a stopped thread happens to hold. |
| // This issue as far as we know have so far not resulted in any deadlocks |
| // in practice, so for now we are taking our chance that the deadlocks |
| // have insignificant frequency. |
| // |
| // If such deadlocks become a problem we should make the i/o calls |
| // into appropriately direct system calls (or eliminate them), |
| // in particular write() is not safe and vsnprintf() is potentially dangerous |
| // due to reliance on locale functions (these are called through RAW_LOG |
| // and in other ways). |
| // |
| |
| #if defined(HAVE_LINUX_PTRACE_H) && defined(HAVE_SYS_SYSCALL_H) && defined(DUMPER) |
| # if (defined(__i386__) || defined(__x86_64)) |
| # define THREAD_REGS i386_regs |
| # elif defined(__PPC__) |
| # define THREAD_REGS ppc_regs |
| # endif |
| #endif |
| |
| /*static*/ int HeapLeakChecker::IgnoreLiveThreadsLocked(void* parameter, |
| int num_threads, |
| pid_t* thread_pids, |
| va_list /*ap*/) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| thread_listing_status = CALLBACK_STARTED; |
| RAW_VLOG(11, "Found %d threads (from pid %d)", num_threads, getpid()); |
| |
| if (FLAGS_heap_check_ignore_global_live) { |
| UseProcMapsLocked(RECORD_GLOBAL_DATA); |
| } |
| |
| // We put the registers from other threads here |
| // to make pointers stored in them live. |
| vector<void*, STL_Allocator<void*, Allocator> > thread_registers; |
| |
| int failures = 0; |
| for (int i = 0; i < num_threads; ++i) { |
| // the leak checking thread itself is handled |
| // specially via self_thread_stack, not here: |
| if (thread_pids[i] == self_thread_pid) continue; |
| RAW_VLOG(11, "Handling thread with pid %d", thread_pids[i]); |
| #ifdef THREAD_REGS |
| THREAD_REGS thread_regs; |
| #define sys_ptrace(r, p, a, d) syscall(SYS_ptrace, (r), (p), (a), (d)) |
| // We use sys_ptrace to avoid thread locking |
| // because this is called from TCMalloc_ListAllProcessThreads |
| // when all but this thread are suspended. |
| if (sys_ptrace(PTRACE_GETREGS, thread_pids[i], NULL, &thread_regs) == 0) { |
| // Need to use SP to get all the data from the very last stack frame: |
| COMPILE_ASSERT(sizeof(thread_regs.SP) == sizeof(void*), |
| SP_register_does_not_look_like_a_pointer); |
| RegisterStackLocked(reinterpret_cast<void*>(thread_regs.SP)); |
| // Make registers live (just in case PTRACE_ATTACH resulted in some |
| // register pointers still being in the registers and not on the stack): |
| for (void** p = reinterpret_cast<void**>(&thread_regs); |
| p < reinterpret_cast<void**>(&thread_regs + 1); ++p) { |
| RAW_VLOG(12, "Thread register %p", *p); |
| thread_registers.push_back(*p); |
| } |
| } else { |
| failures += 1; |
| } |
| #else |
| failures += 1; |
| #endif |
| } |
| // Use all the collected thread (stack) liveness sources: |
| IgnoreLiveObjectsLocked("threads stack data", ""); |
| if (thread_registers.size()) { |
| // Make thread registers be live heap data sources. |
| // we rely here on the fact that vector is in one memory chunk: |
| RAW_VLOG(11, "Live registers at %p of %" PRIuS " bytes", |
| &thread_registers[0], thread_registers.size() * sizeof(void*)); |
| live_objects->push_back(AllocObject(&thread_registers[0], |
| thread_registers.size() * sizeof(void*), |
| THREAD_REGISTERS)); |
| IgnoreLiveObjectsLocked("threads register data", ""); |
| } |
| // Do all other liveness walking while all threads are stopped: |
| IgnoreNonThreadLiveObjectsLocked(); |
| // Can now resume the threads: |
| TCMalloc_ResumeAllProcessThreads(num_threads, thread_pids); |
| thread_listing_status = CALLBACK_COMPLETED; |
| return failures; |
| } |
| |
| // Stack top of the thread that is doing the current leak check |
| // (protected by our lock; IgnoreAllLiveObjectsLocked sets it) |
| static const void* self_thread_stack_top; |
| |
| // static |
| void HeapLeakChecker::IgnoreNonThreadLiveObjectsLocked() { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| RAW_DCHECK(MemoryRegionMap::LockIsHeld(), ""); |
| RAW_VLOG(11, "Handling self thread with pid %d", self_thread_pid); |
| // Register our own stack: |
| |
| // Important that all stack ranges (including the one here) |
| // are known before we start looking at them |
| // in MakeDisabledLiveCallbackLocked: |
| RegisterStackLocked(self_thread_stack_top); |
| IgnoreLiveObjectsLocked("stack data", ""); |
| |
| // Make objects we were told to ignore live: |
| if (ignored_objects) { |
| for (IgnoredObjectsMap::const_iterator object = ignored_objects->begin(); |
| object != ignored_objects->end(); ++object) { |
| const void* ptr = AsPtr(object->first); |
| RAW_VLOG(11, "Ignored live object at %p of %" PRIuS " bytes", |
| ptr, object->second); |
| live_objects-> |
| push_back(AllocObject(ptr, object->second, MUST_BE_ON_HEAP)); |
| // we do this liveness check for ignored_objects before doing any |
| // live heap walking to make sure it does not fail needlessly: |
| size_t object_size; |
| if (!(heap_profile->FindAlloc(ptr, &object_size) && |
| object->second == object_size)) { |
| RAW_LOG(FATAL, "Object at %p of %" PRIuS " bytes from an" |
| " IgnoreObject() has disappeared", ptr, object->second); |
| } |
| } |
| IgnoreLiveObjectsLocked("ignored objects", ""); |
| } |
| |
| // Treat objects that were allocated when a Disabler was live as |
| // roots. I.e., if X was allocated while a Disabler was active, |
| // and Y is reachable from X, arrange that neither X nor Y are |
| // treated as leaks. |
| heap_profile->IterateAllocs(MakeIgnoredObjectsLiveCallbackLocked); |
| IgnoreLiveObjectsLocked("disabled objects", ""); |
| |
| // Make code-address-disabled objects live and ignored: |
| // This in particular makes all thread-specific data live |
| // because the basic data structure to hold pointers to thread-specific data |
| // is allocated from libpthreads and we have range-disabled that |
| // library code with UseProcMapsLocked(DISABLE_LIBRARY_ALLOCS); |
| // so now we declare all thread-specific data reachable from there as live. |
| heap_profile->IterateAllocs(MakeDisabledLiveCallbackLocked); |
| IgnoreLiveObjectsLocked("disabled code", ""); |
| |
| // Actually make global data live: |
| if (FLAGS_heap_check_ignore_global_live) { |
| bool have_null_region_callers = false; |
| for (LibraryLiveObjectsStacks::iterator l = library_live_objects->begin(); |
| l != library_live_objects->end(); ++l) { |
| RAW_CHECK(live_objects->empty(), ""); |
| // Process library_live_objects in l->second |
| // filtering them by MemoryRegionMap: |
| // It's safe to iterate over MemoryRegionMap |
| // w/o locks here as we are inside MemoryRegionMap::Lock(): |
| RAW_DCHECK(MemoryRegionMap::LockIsHeld(), ""); |
| // The only change to MemoryRegionMap possible in this loop |
| // is region addition as a result of allocating more memory |
| // for live_objects. This won't invalidate the RegionIterator |
| // or the intent of the loop. |
| // --see the comment by MemoryRegionMap::BeginRegionLocked(). |
| for (MemoryRegionMap::RegionIterator region = |
| MemoryRegionMap::BeginRegionLocked(); |
| region != MemoryRegionMap::EndRegionLocked(); ++region) { |
| // "region" from MemoryRegionMap is to be subtracted from |
| // (tentatively live) regions in l->second |
| // if it has a stack inside or it was allocated by |
| // a non-special caller (not one covered by a range |
| // in global_region_caller_ranges). |
| // This will in particular exclude all memory chunks used |
| // by the heap itself as well as what's been allocated with |
| // any allocator on top of mmap. |
| bool subtract = true; |
| if (!region->is_stack && global_region_caller_ranges) { |
| if (region->caller() == static_cast<uintptr_t>(NULL)) { |
| have_null_region_callers = true; |
| } else { |
| GlobalRegionCallerRangeMap::const_iterator iter |
| = global_region_caller_ranges->upper_bound(region->caller()); |
| if (iter != global_region_caller_ranges->end()) { |
| RAW_DCHECK(iter->first > region->caller(), ""); |
| if (iter->second < region->caller()) { // in special region |
| subtract = false; |
| } |
| } |
| } |
| } |
| if (subtract) { |
| // The loop puts the result of filtering l->second into live_objects: |
| for (LiveObjectsStack::const_iterator i = l->second.begin(); |
| i != l->second.end(); ++i) { |
| // subtract *region from *i |
| uintptr_t start = AsInt(i->ptr); |
| uintptr_t end = start + i->size; |
| if (region->start_addr <= start && end <= region->end_addr) { |
| // full deletion due to subsumption |
| } else if (start < region->start_addr && |
| region->end_addr < end) { // cutting-out split |
| live_objects->push_back(AllocObject(i->ptr, |
| region->start_addr - start, |
| IN_GLOBAL_DATA)); |
| live_objects->push_back(AllocObject(AsPtr(region->end_addr), |
| end - region->end_addr, |
| IN_GLOBAL_DATA)); |
| } else if (region->end_addr > start && |
| region->start_addr <= start) { // cut from start |
| live_objects->push_back(AllocObject(AsPtr(region->end_addr), |
| end - region->end_addr, |
| IN_GLOBAL_DATA)); |
| } else if (region->start_addr > start && |
| region->start_addr < end) { // cut from end |
| live_objects->push_back(AllocObject(i->ptr, |
| region->start_addr - start, |
| IN_GLOBAL_DATA)); |
| } else { // pass: no intersection |
| live_objects->push_back(AllocObject(i->ptr, i->size, |
| IN_GLOBAL_DATA)); |
| } |
| } |
| // Move live_objects back into l->second |
| // for filtering by the next region. |
| live_objects->swap(l->second); |
| live_objects->clear(); |
| } |
| } |
| // Now get and use live_objects from the final version of l->second: |
| if (VLOG_IS_ON(11)) { |
| for (LiveObjectsStack::const_iterator i = l->second.begin(); |
| i != l->second.end(); ++i) { |
| RAW_VLOG(11, "Library live region at %p of %" PRIuPTR " bytes", |
| i->ptr, i->size); |
| } |
| } |
| live_objects->swap(l->second); |
| IgnoreLiveObjectsLocked("in globals of\n ", l->first.c_str()); |
| } |
| if (have_null_region_callers) { |
| RAW_LOG(ERROR, "Have memory regions w/o callers: " |
| "might report false leaks"); |
| } |
| Allocator::DeleteAndNull(&library_live_objects); |
| } |
| } |
| |
| // Callback for TCMalloc_ListAllProcessThreads in IgnoreAllLiveObjectsLocked below |
| // to test/verify that we have just the one main thread, in which case |
| // we can do everything in that main thread, |
| // so that CPU profiler can collect all its samples. |
| // Returns the number of threads in the process. |
| static int IsOneThread(void* parameter, int num_threads, |
| pid_t* thread_pids, va_list ap) { |
| if (num_threads != 1) { |
| RAW_LOG(WARNING, "Have threads: Won't CPU-profile the bulk of leak " |
| "checking work happening in IgnoreLiveThreadsLocked!"); |
| } |
| TCMalloc_ResumeAllProcessThreads(num_threads, thread_pids); |
| return num_threads; |
| } |
| |
| // Dummy for IgnoreAllLiveObjectsLocked below. |
| // Making it global helps with compiler warnings. |
| static va_list dummy_ap; |
| |
| // static |
| void HeapLeakChecker::IgnoreAllLiveObjectsLocked(const void* self_stack_top) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| RAW_CHECK(live_objects == NULL, ""); |
| live_objects = new(Allocator::Allocate(sizeof(LiveObjectsStack))) |
| LiveObjectsStack; |
| stack_tops = new(Allocator::Allocate(sizeof(StackTopSet))) StackTopSet; |
| // reset the counts |
| live_objects_total = 0; |
| live_bytes_total = 0; |
| // Reduce max_heap_object_size to FLAGS_heap_check_max_pointer_offset |
| // for the time of leak check. |
| // FLAGS_heap_check_max_pointer_offset caps max_heap_object_size |
| // to manage reasonably low chances of random bytes |
| // appearing to be pointing into large actually leaked heap objects. |
| const size_t old_max_heap_object_size = max_heap_object_size; |
| max_heap_object_size = ( |
| FLAGS_heap_check_max_pointer_offset != -1 |
| ? min(size_t(FLAGS_heap_check_max_pointer_offset), max_heap_object_size) |
| : max_heap_object_size); |
| // Record global data as live: |
| if (FLAGS_heap_check_ignore_global_live) { |
| library_live_objects = |
| new(Allocator::Allocate(sizeof(LibraryLiveObjectsStacks))) |
| LibraryLiveObjectsStacks; |
| } |
| // Ignore all thread stacks: |
| thread_listing_status = CALLBACK_NOT_STARTED; |
| bool need_to_ignore_non_thread_objects = true; |
| self_thread_pid = getpid(); |
| self_thread_stack_top = self_stack_top; |
| if (FLAGS_heap_check_ignore_thread_live) { |
| // In case we are doing CPU profiling we'd like to do all the work |
| // in the main thread, not in the special thread created by |
| // TCMalloc_ListAllProcessThreads, so that CPU profiler can |
| // collect all its samples. The machinery of |
| // TCMalloc_ListAllProcessThreads conflicts with the CPU profiler |
| // by also relying on signals and ::sigaction. We can do this |
| // (run everything in the main thread) safely only if there's just |
| // the main thread itself in our process. This variable reflects |
| // these two conditions: |
| bool want_and_can_run_in_main_thread = |
| ProfilingIsEnabledForAllThreads() && |
| TCMalloc_ListAllProcessThreads(NULL, IsOneThread) == 1; |
| // When the normal path of TCMalloc_ListAllProcessThreads below is taken, |
| // we fully suspend the threads right here before any liveness checking |
| // and keep them suspended for the whole time of liveness checking |
| // inside of the IgnoreLiveThreadsLocked callback. |
| // (The threads can't (de)allocate due to lock on the delete hook but |
| // if not suspended they could still mess with the pointer |
| // graph while we walk it). |
| int r = want_and_can_run_in_main_thread |
| ? IgnoreLiveThreadsLocked(NULL, 1, &self_thread_pid, dummy_ap) |
| : TCMalloc_ListAllProcessThreads(NULL, IgnoreLiveThreadsLocked); |
| need_to_ignore_non_thread_objects = r < 0; |
| if (r < 0) { |
| RAW_LOG(WARNING, "Thread finding failed with %d errno=%d", r, errno); |
| if (thread_listing_status == CALLBACK_COMPLETED) { |
| RAW_LOG(INFO, "Thread finding callback " |
| "finished ok; hopefully everything is fine"); |
| need_to_ignore_non_thread_objects = false; |
| } else if (thread_listing_status == CALLBACK_STARTED) { |
| RAW_LOG(FATAL, "Thread finding callback was " |
| "interrupted or crashed; can't fix this"); |
| } else { // CALLBACK_NOT_STARTED |
| RAW_LOG(ERROR, "Could not find thread stacks. " |
| "Will likely report false leak positives."); |
| } |
| } else if (r != 0) { |
| RAW_LOG(ERROR, "Thread stacks not found for %d threads. " |
| "Will likely report false leak positives.", r); |
| } else { |
| RAW_VLOG(11, "Thread stacks appear to be found for all threads"); |
| } |
| } else { |
| RAW_LOG(WARNING, "Not looking for thread stacks; " |
| "objects reachable only from there " |
| "will be reported as leaks"); |
| } |
| // Do all other live data ignoring here if we did not do it |
| // within thread listing callback with all threads stopped. |
| if (need_to_ignore_non_thread_objects) { |
| if (FLAGS_heap_check_ignore_global_live) { |
| UseProcMapsLocked(RECORD_GLOBAL_DATA); |
| } |
| IgnoreNonThreadLiveObjectsLocked(); |
| } |
| if (live_objects_total) { |
| RAW_VLOG(10, "Ignoring %" PRId64 " reachable objects of %" PRId64 " bytes", |
| live_objects_total, live_bytes_total); |
| } |
| // Free these: we made them here and heap_profile never saw them |
| Allocator::DeleteAndNull(&live_objects); |
| Allocator::DeleteAndNull(&stack_tops); |
| max_heap_object_size = old_max_heap_object_size; // reset this var |
| } |
| |
| // Alignment at which we should consider pointer positions |
| // in IgnoreLiveObjectsLocked. Will normally use the value of |
| // FLAGS_heap_check_pointer_source_alignment. |
| static size_t pointer_source_alignment = kPointerSourceAlignment; |
| // Global lock for HeapLeakChecker::DoNoLeaks |
| // to protect pointer_source_alignment. |
| static SpinLock alignment_checker_lock(SpinLock::LINKER_INITIALIZED); |
| |
| // This function changes the live bits in the heap_profile-table's state: |
| // we only record the live objects to be skipped. |
| // |
| // When checking if a byte sequence points to a heap object we use |
| // HeapProfileTable::FindInsideAlloc to handle both pointers to |
| // the start and inside of heap-allocated objects. |
| // The "inside" case needs to be checked to support |
| // at least the following relatively common cases: |
| // - C++ arrays allocated with new FooClass[size] for classes |
| // with destructors have their size recorded in a sizeof(int) field |
| // before the place normal pointers point to. |
| // - basic_string<>-s for e.g. the C++ library of gcc 3.4 |
| // have the meta-info in basic_string<...>::_Rep recorded |
| // before the place normal pointers point to. |
| // - Multiple-inherited objects have their pointers when cast to |
| // different base classes pointing inside of the actually |
| // allocated object. |
| // - Sometimes reachability pointers point to member objects of heap objects, |
| // and then those member objects point to the full heap object. |
| // - Third party UnicodeString: it stores a 32-bit refcount |
| // (in both 32-bit and 64-bit binaries) as the first uint32 |
| // in the allocated memory and a normal pointer points at |
| // the second uint32 behind the refcount. |
| // By finding these additional objects here |
| // we slightly increase the chance to mistake random memory bytes |
| // for a pointer and miss a leak in a particular run of a binary. |
| // |
| /*static*/ void HeapLeakChecker::IgnoreLiveObjectsLocked(const char* name, |
| const char* name2) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| int64 live_object_count = 0; |
| int64 live_byte_count = 0; |
| while (!live_objects->empty()) { |
| const char* object = |
| reinterpret_cast<const char*>(live_objects->back().ptr); |
| size_t size = live_objects->back().size; |
| const ObjectPlacement place = live_objects->back().place; |
| live_objects->pop_back(); |
| if (place == MUST_BE_ON_HEAP && heap_profile->MarkAsLive(object)) { |
| live_object_count += 1; |
| live_byte_count += size; |
| } |
| RAW_VLOG(13, "Looking for heap pointers in %p of %" PRIuS " bytes", |
| object, size); |
| const char* const whole_object = object; |
| size_t const whole_size = size; |
| // Try interpretting any byte sequence in object,size as a heap pointer: |
| const size_t remainder = AsInt(object) % pointer_source_alignment; |
| if (remainder) { |
| object += pointer_source_alignment - remainder; |
| if (size >= pointer_source_alignment - remainder) { |
| size -= pointer_source_alignment - remainder; |
| } else { |
| size = 0; |
| } |
| } |
| if (size < sizeof(void*)) continue; |
| |
| #ifdef NO_FRAME_POINTER |
| // Frame pointer omission requires us to use libunwind, which uses direct |
| // mmap and munmap system calls, and that needs special handling. |
| if (name2 == kUnnamedProcSelfMapEntry) { |
| static const uintptr_t page_mask = ~(getpagesize() - 1); |
| const uintptr_t addr = reinterpret_cast<uintptr_t>(object); |
| if ((addr & page_mask) == 0 && (size & page_mask) == 0) { |
| // This is an object we slurped from /proc/self/maps. |
| // It may or may not be readable at this point. |
| // |
| // In case all the above conditions made a mistake, and the object is |
| // not related to libunwind, we also verify that it's not readable |
| // before ignoring it. |
| if (msync(const_cast<char*>(object), size, MS_ASYNC) != 0) { |
| // Skip unreadable object, so we don't crash trying to sweep it. |
| RAW_VLOG(0, "Ignoring inaccessible object [%p, %p) " |
| "(msync error %d (%s))", |
| object, object + size, errno, strerror(errno)); |
| continue; |
| } |
| } |
| } |
| #endif |
| |
| const char* const max_object = object + size - sizeof(void*); |
| while (object <= max_object) { |
| // potentially unaligned load: |
| const uintptr_t addr = *reinterpret_cast<const uintptr_t*>(object); |
| // Do fast check before the more expensive HaveOnHeapLocked lookup: |
| // this code runs for all memory words that are potentially pointers: |
| const bool can_be_on_heap = |
| // Order tests by the likelyhood of the test failing in 64/32 bit modes. |
| // Yes, this matters: we either lose 5..6% speed in 32 bit mode |
| // (which is already slower) or by a factor of 1.5..1.91 in 64 bit mode. |
| // After the alignment test got dropped the above performance figures |
| // must have changed; might need to revisit this. |
| #if defined(__x86_64__) |
| addr <= max_heap_address && // <= is for 0-sized object with max addr |
| min_heap_address <= addr; |
| #else |
| min_heap_address <= addr && |
| addr <= max_heap_address; // <= is for 0-sized object with max addr |
| #endif |
| if (can_be_on_heap) { |
| const void* ptr = reinterpret_cast<const void*>(addr); |
| // Too expensive (inner loop): manually uncomment when debugging: |
| // RAW_VLOG(17, "Trying pointer to %p at %p", ptr, object); |
| size_t object_size; |
| if (HaveOnHeapLocked(&ptr, &object_size) && |
| heap_profile->MarkAsLive(ptr)) { |
| // We take the (hopefully low) risk here of encountering by accident |
| // a byte sequence in memory that matches an address of |
| // a heap object which is in fact leaked. |
| // I.e. in very rare and probably not repeatable/lasting cases |
| // we might miss some real heap memory leaks. |
| RAW_VLOG(14, "Found pointer to %p of %" PRIuS " bytes at %p " |
| "inside %p of size %" PRIuS "", |
| ptr, object_size, object, whole_object, whole_size); |
| if (VLOG_IS_ON(15)) { |
| // log call stacks to help debug how come something is not a leak |
| HeapProfileTable::AllocInfo alloc; |
| if (!heap_profile->FindAllocDetails(ptr, &alloc)) { |
| RAW_LOG(FATAL, "FindAllocDetails failed on ptr %p", ptr); |
| } |
| RAW_LOG(INFO, "New live %p object's alloc stack:", ptr); |
| for (int i = 0; i < alloc.stack_depth; ++i) { |
| RAW_LOG(INFO, " @ %p", alloc.call_stack[i]); |
| } |
| } |
| live_object_count += 1; |
| live_byte_count += object_size; |
| live_objects->push_back(AllocObject(ptr, object_size, |
| IGNORED_ON_HEAP)); |
| } |
| } |
| object += pointer_source_alignment; |
| } |
| } |
| live_objects_total += live_object_count; |
| live_bytes_total += live_byte_count; |
| if (live_object_count) { |
| RAW_VLOG(10, "Removed %" PRId64 " live heap objects of %" PRId64 " bytes: %s%s", |
| live_object_count, live_byte_count, name, name2); |
| } |
| } |
| |
| //---------------------------------------------------------------------- |
| // HeapLeakChecker leak check disabling components |
| //---------------------------------------------------------------------- |
| |
| // static |
| void HeapLeakChecker::DisableChecksIn(const char* pattern) { |
| RAW_LOG(WARNING, "DisableChecksIn(%s) is ignored", pattern); |
| } |
| |
| // static |
| void HeapLeakChecker::DoIgnoreObject(const void* ptr) { |
| SpinLockHolder l(&heap_checker_lock); |
| if (!heap_checker_on) return; |
| size_t object_size; |
| if (!HaveOnHeapLocked(&ptr, &object_size)) { |
| RAW_LOG(ERROR, "No live heap object at %p to ignore", ptr); |
| } else { |
| RAW_VLOG(10, "Going to ignore live object at %p of %" PRIuS " bytes", |
| ptr, object_size); |
| if (ignored_objects == NULL) { |
| ignored_objects = new(Allocator::Allocate(sizeof(IgnoredObjectsMap))) |
| IgnoredObjectsMap; |
| } |
| if (!ignored_objects->insert(make_pair(AsInt(ptr), object_size)).second) { |
| RAW_LOG(WARNING, "Object at %p is already being ignored", ptr); |
| } |
| } |
| } |
| |
| // static |
| void HeapLeakChecker::UnIgnoreObject(const void* ptr) { |
| SpinLockHolder l(&heap_checker_lock); |
| if (!heap_checker_on) return; |
| size_t object_size; |
| if (!HaveOnHeapLocked(&ptr, &object_size)) { |
| RAW_LOG(FATAL, "No live heap object at %p to un-ignore", ptr); |
| } else { |
| bool found = false; |
| if (ignored_objects) { |
| IgnoredObjectsMap::iterator object = ignored_objects->find(AsInt(ptr)); |
| if (object != ignored_objects->end() && object_size == object->second) { |
| ignored_objects->erase(object); |
| found = true; |
| RAW_VLOG(10, "Now not going to ignore live object " |
| "at %p of %" PRIuS " bytes", ptr, object_size); |
| } |
| } |
| if (!found) RAW_LOG(FATAL, "Object at %p has not been ignored", ptr); |
| } |
| } |
| |
| //---------------------------------------------------------------------- |
| // HeapLeakChecker non-static functions |
| //---------------------------------------------------------------------- |
| |
| char* HeapLeakChecker::MakeProfileNameLocked() { |
| RAW_DCHECK(lock_->IsHeld(), ""); |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| const int len = profile_name_prefix->size() + strlen(name_) + 5 + |
| strlen(HeapProfileTable::kFileExt) + 1; |
| char* file_name = reinterpret_cast<char*>(Allocator::Allocate(len)); |
| snprintf(file_name, len, "%s.%s-end%s", |
| profile_name_prefix->c_str(), name_, |
| HeapProfileTable::kFileExt); |
| return file_name; |
| } |
| |
| void HeapLeakChecker::Create(const char *name, bool make_start_snapshot) { |
| SpinLockHolder l(lock_); |
| name_ = NULL; // checker is inactive |
| start_snapshot_ = NULL; |
| has_checked_ = false; |
| inuse_bytes_increase_ = 0; |
| inuse_allocs_increase_ = 0; |
| keep_profiles_ = false; |
| char* n = new char[strlen(name) + 1]; // do this before we lock |
| IgnoreObject(n); // otherwise it might be treated as live due to our stack |
| { // Heap activity in other threads is paused for this whole scope. |
| SpinLockHolder al(&alignment_checker_lock); |
| SpinLockHolder hl(&heap_checker_lock); |
| MemoryRegionMap::LockHolder ml; |
| if (heap_checker_on && profile_name_prefix != NULL) { |
| RAW_DCHECK(strchr(name, '/') == NULL, "must be a simple name"); |
| memcpy(n, name, strlen(name) + 1); |
| name_ = n; // checker is active |
| if (make_start_snapshot) { |
| start_snapshot_ = heap_profile->TakeSnapshot(); |
| } |
| |
| const HeapProfileTable::Stats& t = heap_profile->total(); |
| const size_t start_inuse_bytes = t.alloc_size - t.free_size; |
| const size_t start_inuse_allocs = t.allocs - t.frees; |
| RAW_VLOG(10, "Start check \"%s\" profile: %" PRIuS " bytes " |
| "in %" PRIuS " objects", |
| name_, start_inuse_bytes, start_inuse_allocs); |
| } else { |
| RAW_LOG(WARNING, "Heap checker is not active, " |
| "hence checker \"%s\" will do nothing!", name); |
| RAW_LOG(WARNING, "To activate set the HEAPCHECK environment variable.\n"); |
| } |
| } |
| if (name_ == NULL) { |
| UnIgnoreObject(n); |
| delete[] n; // must be done after we unlock |
| } |
| } |
| |
| HeapLeakChecker::HeapLeakChecker(const char *name) : lock_(new SpinLock) { |
| RAW_DCHECK(strcmp(name, "_main_") != 0, "_main_ is reserved"); |
| Create(name, true/*create start_snapshot_*/); |
| } |
| |
| HeapLeakChecker::HeapLeakChecker() : lock_(new SpinLock) { |
| if (FLAGS_heap_check_before_constructors) { |
| // We want to check for leaks of objects allocated during global |
| // constructors (i.e., objects allocated already). So we do not |
| // create a baseline snapshot and hence check for leaks of objects |
| // that may have already been created. |
| Create("_main_", false); |
| } else { |
| // We want to ignore leaks of objects allocated during global |
| // constructors (i.e., objects allocated already). So we snapshot |
| // the current heap contents and use them as a baseline that is |
| // not reported by the leak checker. |
| Create("_main_", true); |
| } |
| } |
| |
| ssize_t HeapLeakChecker::BytesLeaked() const { |
| SpinLockHolder l(lock_); |
| if (!has_checked_) { |
| RAW_LOG(FATAL, "*NoLeaks|SameHeap must execute before this call"); |
| } |
| return inuse_bytes_increase_; |
| } |
| |
| ssize_t HeapLeakChecker::ObjectsLeaked() const { |
| SpinLockHolder l(lock_); |
| if (!has_checked_) { |
| RAW_LOG(FATAL, "*NoLeaks|SameHeap must execute before this call"); |
| } |
| return inuse_allocs_increase_; |
| } |
| |
| // Save pid of main thread for using in naming dump files |
| static int32 main_thread_pid = getpid(); |
| #ifdef HAVE_PROGRAM_INVOCATION_NAME |
| #ifdef __UCLIBC__ |
| extern const char* program_invocation_name; |
| extern const char* program_invocation_short_name; |
| #else |
| extern char* program_invocation_name; |
| extern char* program_invocation_short_name; |
| #endif |
| static const char* invocation_name() { return program_invocation_short_name; } |
| static string invocation_path() { return program_invocation_name; } |
| #else |
| static const char* invocation_name() { return "<your binary>"; } |
| static string invocation_path() { return "<your binary>"; } |
| #endif |
| |
| // Prints commands that users can run to get more information |
| // about the reported leaks. |
| static void SuggestPprofCommand(const char* pprof_file_arg) { |
| // Extra help information to print for the user when the test is |
| // being run in a way where the straightforward pprof command will |
| // not suffice. |
| string extra_help; |
| |
| // Common header info to print for remote runs |
| const string remote_header = |
| "This program is being executed remotely and therefore the pprof\n" |
| "command printed above will not work. Either run this program\n" |
| "locally, or adjust the pprof command as follows to allow it to\n" |
| "work on your local machine:\n"; |
| |
| // Extra command for fetching remote data |
| string fetch_cmd; |
| |
| RAW_LOG(WARNING, |
| "\n\n" |
| "If the preceding stack traces are not enough to find " |
| "the leaks, try running THIS shell command:\n\n" |
| "%s%s %s \"%s\" --inuse_objects --lines --heapcheck " |
| " --edgefraction=1e-10 --nodefraction=1e-10 --gv\n" |
| "\n" |
| "%s" |
| "If you are still puzzled about why the leaks are " |
| "there, try rerunning this program with " |
| "HEAP_CHECK_TEST_POINTER_ALIGNMENT=1 and/or with " |
| "HEAP_CHECK_MAX_POINTER_OFFSET=-1\n" |
| "If the leak report occurs in a small fraction of runs, " |
| "try running with TCMALLOC_MAX_FREE_QUEUE_SIZE of few hundred MB " |
| "or with TCMALLOC_RECLAIM_MEMORY=false, " // only works for debugalloc |
| "it might help find leaks more repeatably\n", |
| fetch_cmd.c_str(), |
| "pprof", // works as long as pprof is on your path |
| invocation_path().c_str(), |
| pprof_file_arg, |
| extra_help.c_str() |
| ); |
| } |
| |
| bool HeapLeakChecker::DoNoLeaks(ShouldSymbolize should_symbolize) { |
| SpinLockHolder l(lock_); |
| // The locking also helps us keep the messages |
| // for the two checks close together. |
| SpinLockHolder al(&alignment_checker_lock); |
| |
| // thread-safe: protected by alignment_checker_lock |
| static bool have_disabled_hooks_for_symbolize = false; |
| // Once we've checked for leaks and symbolized the results once, it's |
| // not safe to do it again. This is because in order to symbolize |
| // safely, we had to disable all the malloc hooks here, so we no |
| // longer can be confident we've collected all the data we need. |
| if (have_disabled_hooks_for_symbolize) { |
| RAW_LOG(FATAL, "Must not call heap leak checker manually after " |
| " program-exit's automatic check."); |
| } |
| |
| HeapProfileTable::Snapshot* leaks = NULL; |
| char* pprof_file = NULL; |
| |
| { |
| // Heap activity in other threads is paused during this function |
| // (i.e. until we got all profile difference info). |
| SpinLockHolder hl(&heap_checker_lock); |
| if (heap_checker_on == false) { |
| if (name_ != NULL) { // leak checking enabled when created the checker |
| RAW_LOG(WARNING, "Heap leak checker got turned off after checker " |
| "\"%s\" has been created, no leak check is being done for it!", |
| name_); |
| } |
| return true; |
| } |
| |
| // Update global_region_caller_ranges. They may need to change since |
| // e.g. initialization because shared libraries might have been loaded or |
| // unloaded. |
| Allocator::DeleteAndNullIfNot(&global_region_caller_ranges); |
| ProcMapsResult pm_result = UseProcMapsLocked(DISABLE_LIBRARY_ALLOCS); |
| RAW_CHECK(pm_result == PROC_MAPS_USED, ""); |
| |
| // Keep track of number of internally allocated objects so we |
| // can detect leaks in the heap-leak-checket itself |
| const int initial_allocs = Allocator::alloc_count(); |
| |
| if (name_ == NULL) { |
| RAW_LOG(FATAL, "Heap leak checker must not be turned on " |
| "after construction of a HeapLeakChecker"); |
| } |
| |
| MemoryRegionMap::LockHolder ml; |
| int a_local_var; // Use our stack ptr to make stack data live: |
| |
| // Make the heap profile, other threads are locked out. |
| HeapProfileTable::Snapshot* base = |
| reinterpret_cast<HeapProfileTable::Snapshot*>(start_snapshot_); |
| RAW_DCHECK(FLAGS_heap_check_pointer_source_alignment > 0, ""); |
| pointer_source_alignment = FLAGS_heap_check_pointer_source_alignment; |
| IgnoreAllLiveObjectsLocked(&a_local_var); |
| leaks = heap_profile->NonLiveSnapshot(base); |
| |
| inuse_bytes_increase_ = static_cast<ssize_t>(leaks->total().alloc_size); |
| inuse_allocs_increase_ = static_cast<ssize_t>(leaks->total().allocs); |
| if (leaks->Empty()) { |
| heap_profile->ReleaseSnapshot(leaks); |
| leaks = NULL; |
| |
| // We can only check for internal leaks along the no-user-leak |
| // path since in the leak path we temporarily release |
| // heap_checker_lock and another thread can come in and disturb |
| // allocation counts. |
| if (Allocator::alloc_count() != initial_allocs) { |
| RAW_LOG(FATAL, "Internal HeapChecker leak of %d objects ; %d -> %d", |
| Allocator::alloc_count() - initial_allocs, |
| initial_allocs, Allocator::alloc_count()); |
| } |
| } else if (FLAGS_heap_check_test_pointer_alignment) { |
| if (pointer_source_alignment == 1) { |
| RAW_LOG(WARNING, "--heap_check_test_pointer_alignment has no effect: " |
| "--heap_check_pointer_source_alignment was already set to 1"); |
| } else { |
| // Try with reduced pointer aligment |
| pointer_source_alignment = 1; |
| IgnoreAllLiveObjectsLocked(&a_local_var); |
| HeapProfileTable::Snapshot* leaks_wo_align = |
| heap_profile->NonLiveSnapshot(base); |
| pointer_source_alignment = FLAGS_heap_check_pointer_source_alignment; |
| if (leaks_wo_align->Empty()) { |
| RAW_LOG(WARNING, "Found no leaks without pointer alignment: " |
| "something might be placing pointers at " |
| "unaligned addresses! This needs to be fixed."); |
| } else { |
| RAW_LOG(INFO, "Found leaks without pointer alignment as well: " |
| "unaligned pointers must not be the cause of leaks."); |
| RAW_LOG(INFO, "--heap_check_test_pointer_alignment did not help " |
| "to diagnose the leaks."); |
| } |
| heap_profile->ReleaseSnapshot(leaks_wo_align); |
| } |
| } |
| |
| if (leaks != NULL) { |
| pprof_file = MakeProfileNameLocked(); |
| } |
| } |
| |
| has_checked_ = true; |
| if (leaks == NULL) { |
| if (FLAGS_heap_check_max_pointer_offset == -1) { |
| RAW_LOG(WARNING, |
| "Found no leaks without max_pointer_offset restriction: " |
| "it's possible that the default value of " |
| "heap_check_max_pointer_offset flag is too low. " |
| "Do you use pointers with larger than that offsets " |
| "pointing in the middle of heap-allocated objects?"); |
| } |
| const HeapProfileTable::Stats& stats = heap_profile->total(); |
| RAW_VLOG(heap_checker_info_level, |
| "No leaks found for check \"%s\" " |
| "(but no 100%% guarantee that there aren't any): " |
| "found %" PRId64 " reachable heap objects of %" PRId64 " bytes", |
| name_, |
| int64(stats.allocs - stats.frees), |
| int64(stats.alloc_size - stats.free_size)); |
| } else { |
| if (should_symbolize == SYMBOLIZE) { |
| // To turn addresses into symbols, we need to fork, which is a |
| // problem if both parent and child end up trying to call the |
| // same malloc-hooks we've set up, at the same time. To avoid |
| // trouble, we turn off the hooks before symbolizing. Note that |
| // this makes it unsafe to ever leak-report again! Luckily, we |
| // typically only want to report once in a program's run, at the |
| // very end. |
| if (MallocHook::GetNewHook() == NewHook) |
| MallocHook::SetNewHook(NULL); |
| if (MallocHook::GetDeleteHook() == DeleteHook) |
| MallocHook::SetDeleteHook(NULL); |
| MemoryRegionMap::Shutdown(); |
| // Make sure all the hooks really got unset: |
| RAW_CHECK(MallocHook::GetNewHook() == NULL, ""); |
| RAW_CHECK(MallocHook::GetDeleteHook() == NULL, ""); |
| RAW_CHECK(MallocHook::GetMmapHook() == NULL, ""); |
| RAW_CHECK(MallocHook::GetSbrkHook() == NULL, ""); |
| have_disabled_hooks_for_symbolize = true; |
| leaks->ReportLeaks(name_, pprof_file, true); // true = should_symbolize |
| } else { |
| leaks->ReportLeaks(name_, pprof_file, false); |
| } |
| if (FLAGS_heap_check_identify_leaks) { |
| leaks->ReportIndividualObjects(); |
| } |
| |
| SuggestPprofCommand(pprof_file); |
| |
| { |
| SpinLockHolder hl(&heap_checker_lock); |
| heap_profile->ReleaseSnapshot(leaks); |
| Allocator::Free(pprof_file); |
| } |
| } |
| |
| return (leaks == NULL); |
| } |
| |
| HeapLeakChecker::~HeapLeakChecker() { |
| if (name_ != NULL) { // had leak checking enabled when created the checker |
| if (!has_checked_) { |
| RAW_LOG(FATAL, "Some *NoLeaks|SameHeap method" |
| " must be called on any created HeapLeakChecker"); |
| } |
| |
| // Deallocate any snapshot taken at start |
| if (start_snapshot_ != NULL) { |
| SpinLockHolder l(&heap_checker_lock); |
| heap_profile->ReleaseSnapshot( |
| reinterpret_cast<HeapProfileTable::Snapshot*>(start_snapshot_)); |
| } |
| |
| UnIgnoreObject(name_); |
| delete[] name_; |
| name_ = NULL; |
| } |
| delete lock_; |
| } |
| |
| //---------------------------------------------------------------------- |
| // HeapLeakChecker overall heap check components |
| //---------------------------------------------------------------------- |
| |
| // static |
| bool HeapLeakChecker::IsActive() { |
| SpinLockHolder l(&heap_checker_lock); |
| return heap_checker_on; |
| } |
| |
| vector<HeapCleaner::void_function>* HeapCleaner::heap_cleanups_ = NULL; |
| |
| // When a HeapCleaner object is intialized, add its function to the static list |
| // of cleaners to be run before leaks checking. |
| HeapCleaner::HeapCleaner(void_function f) { |
| if (heap_cleanups_ == NULL) |
| heap_cleanups_ = new vector<HeapCleaner::void_function>; |
| heap_cleanups_->push_back(f); |
| } |
| |
| // Run all of the cleanup functions and delete the vector. |
| void HeapCleaner::RunHeapCleanups() { |
| if (!heap_cleanups_) |
| return; |
| for (int i = 0; i < heap_cleanups_->size(); i++) { |
| void (*f)(void) = (*heap_cleanups_)[i]; |
| f(); |
| } |
| delete heap_cleanups_; |
| heap_cleanups_ = NULL; |
| } |
| |
| // Program exit heap cleanup registered as a module object destructor. |
| // Will not get executed when we crash on a signal. |
| // |
| void HeapLeakChecker_RunHeapCleanups() { |
| if (FLAGS_heap_check == "local") // don't check heap in this mode |
| return; |
| { SpinLockHolder l(&heap_checker_lock); |
| // can get here (via forks?) with other pids |
| if (heap_checker_pid != getpid()) return; |
| } |
| HeapCleaner::RunHeapCleanups(); |
| if (!FLAGS_heap_check_after_destructors) HeapLeakChecker::DoMainHeapCheck(); |
| } |
| |
| static bool internal_init_start_has_run = false; |
| |
| // Called exactly once, before main() (but hopefully just before). |
| // This picks a good unique name for the dumped leak checking heap profiles. |
| // |
| // Because we crash when InternalInitStart is called more than once, |
| // it's fine that we hold heap_checker_lock only around pieces of |
| // this function: this is still enough for thread-safety w.r.t. other functions |
| // of this module. |
| // We can't hold heap_checker_lock throughout because it would deadlock |
| // on a memory allocation since our new/delete hooks can be on. |
| // |
| void HeapLeakChecker_InternalInitStart() { |
| { SpinLockHolder l(&heap_checker_lock); |
| RAW_CHECK(!internal_init_start_has_run, |
| "Heap-check constructor called twice. Perhaps you both linked" |
| " in the heap checker, and also used LD_PRELOAD to load it?"); |
| internal_init_start_has_run = true; |
| |
| #ifdef ADDRESS_SANITIZER |
| // AddressSanitizer's custom malloc conflicts with HeapChecker. |
| FLAGS_heap_check = ""; |
| #endif |
| |
| if (FLAGS_heap_check.empty()) { |
| // turns out we do not need checking in the end; can stop profiling |
| HeapLeakChecker::TurnItselfOffLocked(); |
| return; |
| } else if (RunningOnValgrind()) { |
| // There is no point in trying -- we'll just fail. |
| RAW_LOG(WARNING, "Can't run under Valgrind; will turn itself off"); |
| HeapLeakChecker::TurnItselfOffLocked(); |
| return; |
| } |
| } |
| |
| // Changing this to false can be useful when debugging heap-checker itself: |
| if (!FLAGS_heap_check_run_under_gdb && IsDebuggerAttached()) { |
| RAW_LOG(WARNING, "Someone is ptrace()ing us; will turn itself off"); |
| SpinLockHolder l(&heap_checker_lock); |
| HeapLeakChecker::TurnItselfOffLocked(); |
| return; |
| } |
| |
| { SpinLockHolder l(&heap_checker_lock); |
| if (!constructor_heap_profiling) { |
| RAW_LOG(FATAL, "Can not start so late. You have to enable heap checking " |
| "with HEAPCHECK=<mode>."); |
| } |
| } |
| |
| // Set all flags |
| RAW_DCHECK(FLAGS_heap_check_pointer_source_alignment > 0, ""); |
| if (FLAGS_heap_check == "minimal") { |
| // The least we can check. |
| FLAGS_heap_check_before_constructors = false; // from after main |
| // (ignore more) |
| FLAGS_heap_check_after_destructors = false; // to after cleanup |
| // (most data is live) |
| FLAGS_heap_check_ignore_thread_live = true; // ignore all live |
| FLAGS_heap_check_ignore_global_live = true; // ignore all live |
| } else if (FLAGS_heap_check == "normal") { |
| // Faster than 'minimal' and not much stricter. |
| FLAGS_heap_check_before_constructors = true; // from no profile (fast) |
| FLAGS_heap_check_after_destructors = false; // to after cleanup |
| // (most data is live) |
| FLAGS_heap_check_ignore_thread_live = true; // ignore all live |
| FLAGS_heap_check_ignore_global_live = true; // ignore all live |
| } else if (FLAGS_heap_check == "strict") { |
| // A bit stricter than 'normal': global destructors must fully clean up |
| // after themselves if they are present. |
| FLAGS_heap_check_before_constructors = true; // from no profile (fast) |
| FLAGS_heap_check_after_destructors = true; // to after destructors |
| // (less data live) |
| FLAGS_heap_check_ignore_thread_live = true; // ignore all live |
| FLAGS_heap_check_ignore_global_live = true; // ignore all live |
| } else if (FLAGS_heap_check == "draconian") { |
| // Drop not very portable and not very exact live heap flooding. |
| FLAGS_heap_check_before_constructors = true; // from no profile (fast) |
| FLAGS_heap_check_after_destructors = true; // to after destructors |
| // (need them) |
| FLAGS_heap_check_ignore_thread_live = false; // no live flood (stricter) |
| FLAGS_heap_check_ignore_global_live = false; // no live flood (stricter) |
| } else if (FLAGS_heap_check == "as-is") { |
| // do nothing: use other flags as is |
| } else if (FLAGS_heap_check == "local") { |
| // do nothing |
| } else { |
| RAW_LOG(FATAL, "Unsupported heap_check flag: %s", |
| FLAGS_heap_check.c_str()); |
| } |
| // FreeBSD doesn't seem to honor atexit execution order: |
| // http://code.google.com/p/gperftools/issues/detail?id=375 |
| // Since heap-checking before destructors depends on atexit running |
| // at the right time, on FreeBSD we always check after, even in the |
| // less strict modes. This just means FreeBSD is always a bit |
| // stricter in its checking than other OSes. |
| // This now appears to be the case in other OSes as well; |
| // so always check afterwards. |
| FLAGS_heap_check_after_destructors = true; |
| |
| { SpinLockHolder l(&heap_checker_lock); |
| RAW_DCHECK(heap_checker_pid == getpid(), ""); |
| heap_checker_on = true; |
| RAW_DCHECK(heap_profile, ""); |
| HeapLeakChecker::ProcMapsResult pm_result = HeapLeakChecker::UseProcMapsLocked(HeapLeakChecker::DISABLE_LIBRARY_ALLOCS); |
| // might neeed to do this more than once |
| // if one later dynamically loads libraries that we want disabled |
| if (pm_result != HeapLeakChecker::PROC_MAPS_USED) { // can't function |
| HeapLeakChecker::TurnItselfOffLocked(); |
| return; |
| } |
| } |
| |
| // make a good place and name for heap profile leak dumps |
| string* profile_prefix = |
| new string(FLAGS_heap_check_dump_directory + "/" + invocation_name()); |
| |
| // Finalize prefix for dumping leak checking profiles. |
| const int32 our_pid = getpid(); // safest to call getpid() outside lock |
| { SpinLockHolder l(&heap_checker_lock); |
| // main_thread_pid might still be 0 if this function is being called before |
| // global constructors. In that case, our pid *is* the main pid. |
| if (main_thread_pid == 0) |
| main_thread_pid = our_pid; |
| } |
| char pid_buf[15]; |
| snprintf(pid_buf, sizeof(pid_buf), ".%d", main_thread_pid); |
| *profile_prefix += pid_buf; |
| { SpinLockHolder l(&heap_checker_lock); |
| RAW_DCHECK(profile_name_prefix == NULL, ""); |
| profile_name_prefix = profile_prefix; |
| } |
| |
| // Make sure new/delete hooks are installed properly |
| // and heap profiler is indeed able to keep track |
| // of the objects being allocated. |
| // We test this to make sure we are indeed checking for leaks. |
| char* test_str = new char[5]; |
| size_t size; |
| { SpinLockHolder l(&heap_checker_lock); |
| RAW_CHECK(heap_profile->FindAlloc(test_str, &size), |
| "our own new/delete not linked?"); |
| } |
| delete[] test_str; |
| { SpinLockHolder l(&heap_checker_lock); |
| // This check can fail when it should not if another thread allocates |
| // into this same spot right this moment, |
| // which is unlikely since this code runs in InitGoogle. |
| RAW_CHECK(!heap_profile->FindAlloc(test_str, &size), |
| "our own new/delete not linked?"); |
| } |
| // If we crash in the above code, it probably means that |
| // "nm <this_binary> | grep new" will show that tcmalloc's new/delete |
| // implementation did not get linked-in into this binary |
| // (i.e. nm will list __builtin_new and __builtin_vec_new as undefined). |
| // If this happens, it is a BUILD bug to be fixed. |
| |
| RAW_VLOG(heap_checker_info_level, |
| "WARNING: Perftools heap leak checker is active " |
| "-- Performance may suffer"); |
| |
| if (FLAGS_heap_check != "local") { |
| HeapLeakChecker* main_hc = new HeapLeakChecker(); |
| SpinLockHolder l(&heap_checker_lock); |
| RAW_DCHECK(main_heap_checker == NULL, |
| "Repeated creation of main_heap_checker"); |
| main_heap_checker = main_hc; |
| do_main_heap_check = true; |
| } |
| |
| { SpinLockHolder l(&heap_checker_lock); |
| RAW_CHECK(heap_checker_on && constructor_heap_profiling, |
| "Leak checking is expected to be fully turned on now"); |
| } |
| |
| // For binaries built in debug mode, this will set release queue of |
| // debugallocation.cc to 100M to make it less likely for real leaks to |
| // be hidden due to reuse of heap memory object addresses. |
| // Running a test with --malloc_reclaim_memory=0 would help find leaks even |
| // better, but the test might run out of memory as a result. |
| // The scenario is that a heap object at address X is allocated and freed, |
| // but some other data-structure still retains a pointer to X. |
| // Then the same heap memory is used for another object, which is leaked, |
| // but the leak is not noticed due to the pointer to the original object at X. |
| // TODO(csilvers): support this in some manner. |
| #if 0 |
| SetCommandLineOptionWithMode("max_free_queue_size", "104857600", // 100M |
| SET_FLAG_IF_DEFAULT); |
| #endif |
| } |
| |
| // We want this to run early as well, but not so early as |
| // ::BeforeConstructors (we want flag assignments to have already |
| // happened, for instance). Initializer-registration does the trick. |
| REGISTER_MODULE_INITIALIZER(init_start, HeapLeakChecker_InternalInitStart()); |
| REGISTER_MODULE_DESTRUCTOR(init_start, HeapLeakChecker_RunHeapCleanups()); |
| |
| // static |
| bool HeapLeakChecker::NoGlobalLeaksMaybeSymbolize( |
| ShouldSymbolize should_symbolize) { |
| // we never delete or change main_heap_checker once it's set: |
| HeapLeakChecker* main_hc = GlobalChecker(); |
| if (main_hc) { |
| RAW_VLOG(10, "Checking for whole-program memory leaks"); |
| return main_hc->DoNoLeaks(should_symbolize); |
| } |
| return true; |
| } |
| |
| // static |
| bool HeapLeakChecker::DoMainHeapCheck() { |
| if (FLAGS_heap_check_delay_seconds > 0) { |
| sleep(FLAGS_heap_check_delay_seconds); |
| } |
| { SpinLockHolder l(&heap_checker_lock); |
| if (!do_main_heap_check) return false; |
| RAW_DCHECK(heap_checker_pid == getpid(), ""); |
| do_main_heap_check = false; // will do it now; no need to do it more |
| } |
| |
| // The program is over, so it's safe to symbolize addresses (which |
| // requires a fork) because no serious work is expected to be done |
| // after this. Symbolizing is really useful -- knowing what |
| // function has a leak is better than knowing just an address -- |
| // and while we can only safely symbolize once in a program run, |
| // now is the time (after all, there's no "later" that would be better). |
| if (!NoGlobalLeaksMaybeSymbolize(SYMBOLIZE)) { |
| if (FLAGS_heap_check_identify_leaks) { |
| RAW_LOG(FATAL, "Whole-program memory leaks found."); |
| } |
| RAW_LOG(ERROR, "Exiting with error code (instead of crashing) " |
| "because of whole-program memory leaks"); |
| _exit(1); // we don't want to call atexit() routines! |
| } |
| return true; |
| } |
| |
| // static |
| HeapLeakChecker* HeapLeakChecker::GlobalChecker() { |
| SpinLockHolder l(&heap_checker_lock); |
| return main_heap_checker; |
| } |
| |
| // static |
| bool HeapLeakChecker::NoGlobalLeaks() { |
| // symbolizing requires a fork, which isn't safe to do in general. |
| return NoGlobalLeaksMaybeSymbolize(DO_NOT_SYMBOLIZE); |
| } |
| |
| // static |
| void HeapLeakChecker::CancelGlobalCheck() { |
| SpinLockHolder l(&heap_checker_lock); |
| if (do_main_heap_check) { |
| RAW_VLOG(heap_checker_info_level, |
| "Canceling the automatic at-exit whole-program memory leak check"); |
| do_main_heap_check = false; |
| } |
| } |
| |
| // static |
| void HeapLeakChecker::BeforeConstructorsLocked() { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| RAW_CHECK(!constructor_heap_profiling, |
| "BeforeConstructorsLocked called multiple times"); |
| #ifdef ADDRESS_SANITIZER |
| // AddressSanitizer's custom malloc conflicts with HeapChecker. |
| return; |
| #endif |
| // Set hooks early to crash if 'new' gets called before we make heap_profile, |
| // and make sure no other hooks existed: |
| RAW_CHECK(MallocHook::AddNewHook(&NewHook), ""); |
| RAW_CHECK(MallocHook::AddDeleteHook(&DeleteHook), ""); |
| constructor_heap_profiling = true; |
| MemoryRegionMap::Init(1, /* use_buckets */ false); |
| // Set up MemoryRegionMap with (at least) one caller stack frame to record |
| // (important that it's done before HeapProfileTable creation below). |
| Allocator::Init(); |
| RAW_CHECK(heap_profile == NULL, ""); |
| heap_profile = new(Allocator::Allocate(sizeof(HeapProfileTable))) |
| HeapProfileTable(&Allocator::Allocate, &Allocator::Free, |
| /* profile_mmap */ false); |
| RAW_VLOG(10, "Starting tracking the heap"); |
| heap_checker_on = true; |
| } |
| |
| // static |
| void HeapLeakChecker::TurnItselfOffLocked() { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| // Set FLAGS_heap_check to "", for users who test for it |
| if (!FLAGS_heap_check.empty()) // be a noop in the common case |
| FLAGS_heap_check.clear(); // because clear() could allocate memory |
| if (constructor_heap_profiling) { |
| RAW_CHECK(heap_checker_on, ""); |
| RAW_VLOG(heap_checker_info_level, "Turning perftools heap leak checking off"); |
| heap_checker_on = false; |
| // Unset our hooks checking they were set: |
| RAW_CHECK(MallocHook::RemoveNewHook(&NewHook), ""); |
| RAW_CHECK(MallocHook::RemoveDeleteHook(&DeleteHook), ""); |
| Allocator::DeleteAndNull(&heap_profile); |
| // free our optional global data: |
| Allocator::DeleteAndNullIfNot(&ignored_objects); |
| Allocator::DeleteAndNullIfNot(&disabled_ranges); |
| Allocator::DeleteAndNullIfNot(&global_region_caller_ranges); |
| Allocator::Shutdown(); |
| MemoryRegionMap::Shutdown(); |
| } |
| RAW_CHECK(!heap_checker_on, ""); |
| } |
| |
| extern bool heap_leak_checker_bcad_variable; // in heap-checker-bcad.cc |
| |
| static bool has_called_before_constructors = false; |
| |
| // TODO(maxim): inline this function with |
| // MallocHook_InitAtFirstAllocation_HeapLeakChecker, and also rename |
| // HeapLeakChecker::BeforeConstructorsLocked. |
| void HeapLeakChecker_BeforeConstructors() { |
| SpinLockHolder l(&heap_checker_lock); |
| // We can be called from several places: the first mmap/sbrk/alloc call |
| // or the first global c-tor from heap-checker-bcad.cc: |
| // Do not re-execute initialization: |
| if (has_called_before_constructors) return; |
| has_called_before_constructors = true; |
| |
| heap_checker_pid = getpid(); // set it always |
| heap_leak_checker_bcad_variable = true; |
| // just to reference it, so that heap-checker-bcad.o is linked in |
| |
| // This function can be called *very* early, before the normal |
| // global-constructor that sets FLAGS_verbose. Set it manually now, |
| // so the RAW_LOG messages here are controllable. |
| const char* verbose_str = GetenvBeforeMain("PERFTOOLS_VERBOSE"); |
| if (verbose_str && atoi(verbose_str)) { // different than the default of 0? |
| FLAGS_verbose = atoi(verbose_str); |
| } |
| |
| bool need_heap_check = true; |
| // The user indicates a desire for heap-checking via the HEAPCHECK |
| // environment variable. If it's not set, there's no way to do |
| // heap-checking. |
| if (!GetenvBeforeMain("HEAPCHECK")) { |
| need_heap_check = false; |
| } |
| #ifdef HAVE_GETEUID |
| if (need_heap_check && getuid() != geteuid()) { |
| // heap-checker writes out files. Thus, for security reasons, we don't |
| // recognize the env. var. to turn on heap-checking if we're setuid. |
| RAW_LOG(WARNING, ("HeapChecker: ignoring HEAPCHECK because " |
| "program seems to be setuid\n")); |
| need_heap_check = false; |
| } |
| #endif |
| if (need_heap_check) { |
| HeapLeakChecker::BeforeConstructorsLocked(); |
| } |
| } |
| |
| // This function overrides the weak function defined in malloc_hook.cc and |
| // called by one of the initial malloc hooks (malloc_hook.cc) when the very |
| // first memory allocation or an mmap/sbrk happens. This ensures that |
| // HeapLeakChecker is initialized and installs all its hooks early enough to |
| // track absolutely all memory allocations and all memory region acquisitions |
| // via mmap and sbrk. |
| extern "C" void MallocHook_InitAtFirstAllocation_HeapLeakChecker() { |
| HeapLeakChecker_BeforeConstructors(); |
| } |
| |
| // This function is executed after all global object destructors run. |
| void HeapLeakChecker_AfterDestructors() { |
| { SpinLockHolder l(&heap_checker_lock); |
| // can get here (via forks?) with other pids |
| if (heap_checker_pid != getpid()) return; |
| } |
| if (FLAGS_heap_check_after_destructors) { |
| if (HeapLeakChecker::DoMainHeapCheck()) { |
| const struct timespec sleep_time = { 0, 500000000 }; // 500 ms |
| nanosleep(&sleep_time, NULL); |
| // Need this hack to wait for other pthreads to exit. |
| // Otherwise tcmalloc find errors |
| // on a free() call from pthreads. |
| } |
| } |
| SpinLockHolder l(&heap_checker_lock); |
| RAW_CHECK(!do_main_heap_check, "should have done it"); |
| } |
| |
| //---------------------------------------------------------------------- |
| // HeapLeakChecker disabling helpers |
| //---------------------------------------------------------------------- |
| |
| // These functions are at the end of the file to prevent their inlining: |
| |
| // static |
| void HeapLeakChecker::DisableChecksFromToLocked(const void* start_address, |
| const void* end_address, |
| int max_depth) { |
| RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| RAW_DCHECK(start_address < end_address, ""); |
| if (disabled_ranges == NULL) { |
| disabled_ranges = new(Allocator::Allocate(sizeof(DisabledRangeMap))) |
| DisabledRangeMap; |
| } |
| RangeValue value; |
| value.start_address = AsInt(start_address); |
| value.max_depth = max_depth; |
| if (disabled_ranges->insert(make_pair(AsInt(end_address), value)).second) { |
| RAW_VLOG(10, "Disabling leak checking in stack traces " |
| "under frame addresses between %p..%p", |
| start_address, end_address); |
| } else { // check that this is just a verbatim repetition |
| RangeValue const& val = disabled_ranges->find(AsInt(end_address))->second; |
| if (val.max_depth != value.max_depth || |
| val.start_address != value.start_address) { |
| RAW_LOG(FATAL, "Two DisableChecksToHereFrom calls conflict: " |
| "(%p, %p, %d) vs. (%p, %p, %d)", |
| AsPtr(val.start_address), end_address, val.max_depth, |
| start_address, end_address, max_depth); |
| } |
| } |
| } |
| |
| // static |
| inline bool HeapLeakChecker::HaveOnHeapLocked(const void** ptr, |
| size_t* object_size) { |
| // Commented-out because HaveOnHeapLocked is very performance-critical: |
| // RAW_DCHECK(heap_checker_lock.IsHeld(), ""); |
| const uintptr_t addr = AsInt(*ptr); |
| if (heap_profile->FindInsideAlloc( |
| *ptr, max_heap_object_size, ptr, object_size)) { |
| RAW_VLOG(16, "Got pointer into %p at +%" PRIuPTR " offset", |
| *ptr, addr - AsInt(*ptr)); |
| return true; |
| } |
| return false; |
| } |
| |
| // static |
| const void* HeapLeakChecker::GetAllocCaller(void* ptr) { |
| // this is used only in the unittest, so the heavy checks are fine |
| HeapProfileTable::AllocInfo info; |
| { SpinLockHolder l(&heap_checker_lock); |
| RAW_CHECK(heap_profile->FindAllocDetails(ptr, &info), ""); |
| } |
| RAW_CHECK(info.stack_depth >= 1, ""); |
| return info.call_stack[0]; |
| } |