/* * Copyright (C) 2013 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // For the THREAD_SIGNAL definition. #include "BacktraceThread.h" #include #include #include #include #include "thread_utils.h" // Number of microseconds per milliseconds. #define US_PER_MSEC 1000 // Number of nanoseconds in a second. #define NS_PER_SEC 1000000000ULL // Number of simultaneous dumping operations to perform. #define NUM_THREADS 40 // Number of simultaneous threads running in our forked process. #define NUM_PTRACE_THREADS 5 struct thread_t { pid_t tid; int32_t state; pthread_t threadId; }; struct dump_thread_t { thread_t thread; Backtrace* backtrace; int32_t* now; int32_t done; }; extern "C" { // Prototypes for functions in the test library. int test_level_one(int, int, int, int, void (*)(void*), void*); int test_recursive_call(int, void (*)(void*), void*); } uint64_t NanoTime() { struct timespec t = { 0, 0 }; clock_gettime(CLOCK_MONOTONIC, &t); return static_cast(t.tv_sec * NS_PER_SEC + t.tv_nsec); } void DumpFrames(Backtrace* backtrace) { if (backtrace->NumFrames() == 0) { printf(" No frames to dump\n"); return; } for (size_t i = 0; i < backtrace->NumFrames(); i++) { printf(" %s\n", backtrace->FormatFrameData(i).c_str()); } } void WaitForStop(pid_t pid) { uint64_t start = NanoTime(); siginfo_t si; while (ptrace(PTRACE_GETSIGINFO, pid, 0, &si) < 0 && (errno == EINTR || errno == ESRCH)) { if ((NanoTime() - start) > NS_PER_SEC) { printf("The process did not get to a stopping point in 1 second.\n"); break; } usleep(US_PER_MSEC); } } bool ReadyLevelBacktrace(Backtrace* backtrace) { // See if test_level_four is in the backtrace. bool found = false; for (Backtrace::const_iterator it = backtrace->begin(); it != backtrace->end(); ++it) { if (it->func_name == "test_level_four") { found = true; break; } } return found; } void VerifyLevelDump(Backtrace* backtrace) { ASSERT_GT(backtrace->NumFrames(), static_cast(0)); ASSERT_LT(backtrace->NumFrames(), static_cast(MAX_BACKTRACE_FRAMES)); // Look through the frames starting at the highest to find the // frame we want. size_t frame_num = 0; for (size_t i = backtrace->NumFrames()-1; i > 2; i--) { if (backtrace->GetFrame(i)->func_name == "test_level_one") { frame_num = i; break; } } ASSERT_LT(static_cast(0), frame_num); ASSERT_LE(static_cast(3), frame_num); ASSERT_EQ(backtrace->GetFrame(frame_num)->func_name, "test_level_one"); ASSERT_EQ(backtrace->GetFrame(frame_num-1)->func_name, "test_level_two"); ASSERT_EQ(backtrace->GetFrame(frame_num-2)->func_name, "test_level_three"); ASSERT_EQ(backtrace->GetFrame(frame_num-3)->func_name, "test_level_four"); } void VerifyLevelBacktrace(void*) { UniquePtr backtrace( Backtrace::Create(BACKTRACE_CURRENT_PROCESS, BACKTRACE_CURRENT_THREAD)); ASSERT_TRUE(backtrace.get() != NULL); ASSERT_TRUE(backtrace->Unwind(0)); VerifyLevelDump(backtrace.get()); } bool ReadyMaxBacktrace(Backtrace* backtrace) { return (backtrace->NumFrames() == MAX_BACKTRACE_FRAMES); } void VerifyMaxDump(Backtrace* backtrace) { ASSERT_EQ(backtrace->NumFrames(), static_cast(MAX_BACKTRACE_FRAMES)); // Verify that the last frame is our recursive call. ASSERT_EQ(backtrace->GetFrame(MAX_BACKTRACE_FRAMES-1)->func_name, "test_recursive_call"); } void VerifyMaxBacktrace(void*) { UniquePtr backtrace( Backtrace::Create(BACKTRACE_CURRENT_PROCESS, BACKTRACE_CURRENT_THREAD)); ASSERT_TRUE(backtrace.get() != NULL); ASSERT_TRUE(backtrace->Unwind(0)); VerifyMaxDump(backtrace.get()); } void ThreadSetState(void* data) { thread_t* thread = reinterpret_cast(data); android_atomic_acquire_store(1, &thread->state); volatile int i = 0; while (thread->state) { i++; } } void VerifyThreadTest(pid_t tid, void (*VerifyFunc)(Backtrace*)) { UniquePtr backtrace(Backtrace::Create(getpid(), tid)); ASSERT_TRUE(backtrace.get() != NULL); ASSERT_TRUE(backtrace->Unwind(0)); VerifyFunc(backtrace.get()); } bool WaitForNonZero(int32_t* value, uint64_t seconds) { uint64_t start = NanoTime(); do { if (android_atomic_acquire_load(value)) { return true; } } while ((NanoTime() - start) < seconds * NS_PER_SEC); return false; } TEST(libbacktrace, local_trace) { ASSERT_NE(test_level_one(1, 2, 3, 4, VerifyLevelBacktrace, NULL), 0); } void VerifyIgnoreFrames( Backtrace* bt_all, Backtrace* bt_ign1, Backtrace* bt_ign2, const char* cur_proc) { EXPECT_EQ(bt_all->NumFrames(), bt_ign1->NumFrames() + 1); EXPECT_EQ(bt_all->NumFrames(), bt_ign2->NumFrames() + 2); // Check all of the frames are the same > the current frame. bool check = (cur_proc == NULL); for (size_t i = 0; i < bt_ign2->NumFrames(); i++) { if (check) { EXPECT_EQ(bt_ign2->GetFrame(i)->pc, bt_ign1->GetFrame(i+1)->pc); EXPECT_EQ(bt_ign2->GetFrame(i)->sp, bt_ign1->GetFrame(i+1)->sp); EXPECT_EQ(bt_ign2->GetFrame(i)->stack_size, bt_ign1->GetFrame(i+1)->stack_size); EXPECT_EQ(bt_ign2->GetFrame(i)->pc, bt_all->GetFrame(i+2)->pc); EXPECT_EQ(bt_ign2->GetFrame(i)->sp, bt_all->GetFrame(i+2)->sp); EXPECT_EQ(bt_ign2->GetFrame(i)->stack_size, bt_all->GetFrame(i+2)->stack_size); } if (!check && bt_ign2->GetFrame(i)->func_name == cur_proc) { check = true; } } } void VerifyLevelIgnoreFrames(void*) { UniquePtr all( Backtrace::Create(BACKTRACE_CURRENT_PROCESS, BACKTRACE_CURRENT_THREAD)); ASSERT_TRUE(all.get() != NULL); ASSERT_TRUE(all->Unwind(0)); UniquePtr ign1( Backtrace::Create(BACKTRACE_CURRENT_PROCESS, BACKTRACE_CURRENT_THREAD)); ASSERT_TRUE(ign1.get() != NULL); ASSERT_TRUE(ign1->Unwind(1)); UniquePtr ign2( Backtrace::Create(BACKTRACE_CURRENT_PROCESS, BACKTRACE_CURRENT_THREAD)); ASSERT_TRUE(ign2.get() != NULL); ASSERT_TRUE(ign2->Unwind(2)); VerifyIgnoreFrames(all.get(), ign1.get(), ign2.get(), "VerifyLevelIgnoreFrames"); } TEST(libbacktrace, local_trace_ignore_frames) { ASSERT_NE(test_level_one(1, 2, 3, 4, VerifyLevelIgnoreFrames, NULL), 0); } TEST(libbacktrace, local_max_trace) { ASSERT_NE(test_recursive_call(MAX_BACKTRACE_FRAMES+10, VerifyMaxBacktrace, NULL), 0); } void VerifyProcTest(pid_t pid, pid_t tid, bool share_map, bool (*ReadyFunc)(Backtrace*), void (*VerifyFunc)(Backtrace*)) { pid_t ptrace_tid; if (tid < 0) { ptrace_tid = pid; } else { ptrace_tid = tid; } uint64_t start = NanoTime(); bool verified = false; do { usleep(US_PER_MSEC); if (ptrace(PTRACE_ATTACH, ptrace_tid, 0, 0) == 0) { // Wait for the process to get to a stopping point. WaitForStop(ptrace_tid); UniquePtr map; if (share_map) { map.reset(BacktraceMap::Create(pid)); } UniquePtr backtrace(Backtrace::Create(pid, tid, map.get())); ASSERT_TRUE(backtrace->Unwind(0)); ASSERT_TRUE(backtrace.get() != NULL); if (ReadyFunc(backtrace.get())) { VerifyFunc(backtrace.get()); verified = true; } ASSERT_TRUE(ptrace(PTRACE_DETACH, ptrace_tid, 0, 0) == 0); } // If 5 seconds have passed, then we are done. } while (!verified && (NanoTime() - start) <= 5 * NS_PER_SEC); ASSERT_TRUE(verified); } TEST(libbacktrace, ptrace_trace) { pid_t pid; if ((pid = fork()) == 0) { ASSERT_NE(test_level_one(1, 2, 3, 4, NULL, NULL), 0); _exit(1); } VerifyProcTest(pid, BACKTRACE_CURRENT_THREAD, false, ReadyLevelBacktrace, VerifyLevelDump); kill(pid, SIGKILL); int status; ASSERT_EQ(waitpid(pid, &status, 0), pid); } TEST(libbacktrace, ptrace_trace_shared_map) { pid_t pid; if ((pid = fork()) == 0) { ASSERT_NE(test_level_one(1, 2, 3, 4, NULL, NULL), 0); _exit(1); } VerifyProcTest(pid, BACKTRACE_CURRENT_THREAD, true, ReadyLevelBacktrace, VerifyLevelDump); kill(pid, SIGKILL); int status; ASSERT_EQ(waitpid(pid, &status, 0), pid); } TEST(libbacktrace, ptrace_max_trace) { pid_t pid; if ((pid = fork()) == 0) { ASSERT_NE(test_recursive_call(MAX_BACKTRACE_FRAMES+10, NULL, NULL), 0); _exit(1); } VerifyProcTest(pid, BACKTRACE_CURRENT_THREAD, false, ReadyMaxBacktrace, VerifyMaxDump); kill(pid, SIGKILL); int status; ASSERT_EQ(waitpid(pid, &status, 0), pid); } void VerifyProcessIgnoreFrames(Backtrace* bt_all) { UniquePtr ign1(Backtrace::Create(bt_all->Pid(), BACKTRACE_CURRENT_THREAD)); ASSERT_TRUE(ign1.get() != NULL); ASSERT_TRUE(ign1->Unwind(1)); UniquePtr ign2(Backtrace::Create(bt_all->Pid(), BACKTRACE_CURRENT_THREAD)); ASSERT_TRUE(ign2.get() != NULL); ASSERT_TRUE(ign2->Unwind(2)); VerifyIgnoreFrames(bt_all, ign1.get(), ign2.get(), NULL); } TEST(libbacktrace, ptrace_ignore_frames) { pid_t pid; if ((pid = fork()) == 0) { ASSERT_NE(test_level_one(1, 2, 3, 4, NULL, NULL), 0); _exit(1); } VerifyProcTest(pid, BACKTRACE_CURRENT_THREAD, false, ReadyLevelBacktrace, VerifyProcessIgnoreFrames); kill(pid, SIGKILL); int status; ASSERT_EQ(waitpid(pid, &status, 0), pid); } // Create a process with multiple threads and dump all of the threads. void* PtraceThreadLevelRun(void*) { EXPECT_NE(test_level_one(1, 2, 3, 4, NULL, NULL), 0); return NULL; } void GetThreads(pid_t pid, std::vector* threads) { // Get the list of tasks. char task_path[128]; snprintf(task_path, sizeof(task_path), "/proc/%d/task", pid); DIR* tasks_dir = opendir(task_path); ASSERT_TRUE(tasks_dir != NULL); struct dirent* entry; while ((entry = readdir(tasks_dir)) != NULL) { char* end; pid_t tid = strtoul(entry->d_name, &end, 10); if (*end == '\0') { threads->push_back(tid); } } closedir(tasks_dir); } TEST(libbacktrace, ptrace_threads) { pid_t pid; if ((pid = fork()) == 0) { for (size_t i = 0; i < NUM_PTRACE_THREADS; i++) { pthread_attr_t attr; pthread_attr_init(&attr); pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED); pthread_t thread; ASSERT_TRUE(pthread_create(&thread, &attr, PtraceThreadLevelRun, NULL) == 0); } ASSERT_NE(test_level_one(1, 2, 3, 4, NULL, NULL), 0); _exit(1); } // Check to see that all of the threads are running before unwinding. std::vector threads; uint64_t start = NanoTime(); do { usleep(US_PER_MSEC); threads.clear(); GetThreads(pid, &threads); } while ((threads.size() != NUM_PTRACE_THREADS + 1) && ((NanoTime() - start) <= 5 * NS_PER_SEC)); ASSERT_EQ(threads.size(), static_cast(NUM_PTRACE_THREADS + 1)); ASSERT_TRUE(ptrace(PTRACE_ATTACH, pid, 0, 0) == 0); WaitForStop(pid); for (std::vector::const_iterator it = threads.begin(); it != threads.end(); ++it) { // Skip the current forked process, we only care about the threads. if (pid == *it) { continue; } VerifyProcTest(pid, *it, false, ReadyLevelBacktrace, VerifyLevelDump); } ASSERT_TRUE(ptrace(PTRACE_DETACH, pid, 0, 0) == 0); kill(pid, SIGKILL); int status; ASSERT_EQ(waitpid(pid, &status, 0), pid); } void VerifyLevelThread(void*) { UniquePtr backtrace(Backtrace::Create(getpid(), gettid())); ASSERT_TRUE(backtrace.get() != NULL); ASSERT_TRUE(backtrace->Unwind(0)); VerifyLevelDump(backtrace.get()); } TEST(libbacktrace, thread_current_level) { ASSERT_NE(test_level_one(1, 2, 3, 4, VerifyLevelThread, NULL), 0); } void VerifyMaxThread(void*) { UniquePtr backtrace(Backtrace::Create(getpid(), gettid())); ASSERT_TRUE(backtrace.get() != NULL); ASSERT_TRUE(backtrace->Unwind(0)); VerifyMaxDump(backtrace.get()); } TEST(libbacktrace, thread_current_max) { ASSERT_NE(test_recursive_call(MAX_BACKTRACE_FRAMES+10, VerifyMaxThread, NULL), 0); } void* ThreadLevelRun(void* data) { thread_t* thread = reinterpret_cast(data); thread->tid = gettid(); EXPECT_NE(test_level_one(1, 2, 3, 4, ThreadSetState, data), 0); return NULL; } TEST(libbacktrace, thread_level_trace) { pthread_attr_t attr; pthread_attr_init(&attr); pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED); thread_t thread_data = { 0, 0, 0 }; pthread_t thread; ASSERT_TRUE(pthread_create(&thread, &attr, ThreadLevelRun, &thread_data) == 0); // Wait up to 2 seconds for the tid to be set. ASSERT_TRUE(WaitForNonZero(&thread_data.state, 2)); // Make sure that the thread signal used is not visible when compiled for // the target. #if !defined(__GLIBC__) ASSERT_LT(THREAD_SIGNAL, SIGRTMIN); #endif // Save the current signal action and make sure it is restored afterwards. struct sigaction cur_action; ASSERT_TRUE(sigaction(THREAD_SIGNAL, NULL, &cur_action) == 0); UniquePtr backtrace(Backtrace::Create(getpid(), thread_data.tid)); ASSERT_TRUE(backtrace.get() != NULL); ASSERT_TRUE(backtrace->Unwind(0)); VerifyLevelDump(backtrace.get()); // Tell the thread to exit its infinite loop. android_atomic_acquire_store(0, &thread_data.state); // Verify that the old action was restored. struct sigaction new_action; ASSERT_TRUE(sigaction(THREAD_SIGNAL, NULL, &new_action) == 0); EXPECT_EQ(cur_action.sa_sigaction, new_action.sa_sigaction); // The SA_RESTORER flag gets set behind our back, so a direct comparison // doesn't work unless we mask the value off. Mips doesn't have this // flag, so skip this on that platform. #ifdef SA_RESTORER cur_action.sa_flags &= ~SA_RESTORER; new_action.sa_flags &= ~SA_RESTORER; #endif EXPECT_EQ(cur_action.sa_flags, new_action.sa_flags); } TEST(libbacktrace, thread_ignore_frames) { pthread_attr_t attr; pthread_attr_init(&attr); pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED); thread_t thread_data = { 0, 0, 0 }; pthread_t thread; ASSERT_TRUE(pthread_create(&thread, &attr, ThreadLevelRun, &thread_data) == 0); // Wait up to 2 seconds for the tid to be set. ASSERT_TRUE(WaitForNonZero(&thread_data.state, 2)); UniquePtr all(Backtrace::Create(getpid(), thread_data.tid)); ASSERT_TRUE(all.get() != NULL); ASSERT_TRUE(all->Unwind(0)); UniquePtr ign1(Backtrace::Create(getpid(), thread_data.tid)); ASSERT_TRUE(ign1.get() != NULL); ASSERT_TRUE(ign1->Unwind(1)); UniquePtr ign2(Backtrace::Create(getpid(), thread_data.tid)); ASSERT_TRUE(ign2.get() != NULL); ASSERT_TRUE(ign2->Unwind(2)); VerifyIgnoreFrames(all.get(), ign1.get(), ign2.get(), NULL); // Tell the thread to exit its infinite loop. android_atomic_acquire_store(0, &thread_data.state); } void* ThreadMaxRun(void* data) { thread_t* thread = reinterpret_cast(data); thread->tid = gettid(); EXPECT_NE(test_recursive_call(MAX_BACKTRACE_FRAMES+10, ThreadSetState, data), 0); return NULL; } TEST(libbacktrace, thread_max_trace) { pthread_attr_t attr; pthread_attr_init(&attr); pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED); thread_t thread_data = { 0, 0, 0 }; pthread_t thread; ASSERT_TRUE(pthread_create(&thread, &attr, ThreadMaxRun, &thread_data) == 0); // Wait for the tid to be set. ASSERT_TRUE(WaitForNonZero(&thread_data.state, 2)); UniquePtr backtrace(Backtrace::Create(getpid(), thread_data.tid)); ASSERT_TRUE(backtrace.get() != NULL); ASSERT_TRUE(backtrace->Unwind(0)); VerifyMaxDump(backtrace.get()); // Tell the thread to exit its infinite loop. android_atomic_acquire_store(0, &thread_data.state); } void* ThreadDump(void* data) { dump_thread_t* dump = reinterpret_cast(data); while (true) { if (android_atomic_acquire_load(dump->now)) { break; } } // The status of the actual unwind will be checked elsewhere. dump->backtrace = Backtrace::Create(getpid(), dump->thread.tid); dump->backtrace->Unwind(0); android_atomic_acquire_store(1, &dump->done); return NULL; } TEST(libbacktrace, thread_multiple_dump) { // Dump NUM_THREADS simultaneously. std::vector runners(NUM_THREADS); std::vector dumpers(NUM_THREADS); pthread_attr_t attr; pthread_attr_init(&attr); pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED); for (size_t i = 0; i < NUM_THREADS; i++) { // Launch the runners, they will spin in hard loops doing nothing. runners[i].tid = 0; runners[i].state = 0; ASSERT_TRUE(pthread_create(&runners[i].threadId, &attr, ThreadMaxRun, &runners[i]) == 0); } // Wait for tids to be set. for (std::vector::iterator it = runners.begin(); it != runners.end(); ++it) { ASSERT_TRUE(WaitForNonZero(&it->state, 30)); } // Start all of the dumpers at once, they will spin until they are signalled // to begin their dump run. int32_t dump_now = 0; for (size_t i = 0; i < NUM_THREADS; i++) { dumpers[i].thread.tid = runners[i].tid; dumpers[i].thread.state = 0; dumpers[i].done = 0; dumpers[i].now = &dump_now; ASSERT_TRUE(pthread_create(&dumpers[i].thread.threadId, &attr, ThreadDump, &dumpers[i]) == 0); } // Start all of the dumpers going at once. android_atomic_acquire_store(1, &dump_now); for (size_t i = 0; i < NUM_THREADS; i++) { ASSERT_TRUE(WaitForNonZero(&dumpers[i].done, 30)); // Tell the runner thread to exit its infinite loop. android_atomic_acquire_store(0, &runners[i].state); ASSERT_TRUE(dumpers[i].backtrace != NULL); VerifyMaxDump(dumpers[i].backtrace); delete dumpers[i].backtrace; dumpers[i].backtrace = NULL; } } TEST(libbacktrace, thread_multiple_dump_same_thread) { pthread_attr_t attr; pthread_attr_init(&attr); pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED); thread_t runner; runner.tid = 0; runner.state = 0; ASSERT_TRUE(pthread_create(&runner.threadId, &attr, ThreadMaxRun, &runner) == 0); // Wait for tids to be set. ASSERT_TRUE(WaitForNonZero(&runner.state, 30)); // Start all of the dumpers at once, they will spin until they are signalled // to begin their dump run. int32_t dump_now = 0; // Dump the same thread NUM_THREADS simultaneously. std::vector dumpers(NUM_THREADS); for (size_t i = 0; i < NUM_THREADS; i++) { dumpers[i].thread.tid = runner.tid; dumpers[i].thread.state = 0; dumpers[i].done = 0; dumpers[i].now = &dump_now; ASSERT_TRUE(pthread_create(&dumpers[i].thread.threadId, &attr, ThreadDump, &dumpers[i]) == 0); } // Start all of the dumpers going at once. android_atomic_acquire_store(1, &dump_now); for (size_t i = 0; i < NUM_THREADS; i++) { ASSERT_TRUE(WaitForNonZero(&dumpers[i].done, 30)); ASSERT_TRUE(dumpers[i].backtrace != NULL); VerifyMaxDump(dumpers[i].backtrace); delete dumpers[i].backtrace; dumpers[i].backtrace = NULL; } // Tell the runner thread to exit its infinite loop. android_atomic_acquire_store(0, &runner.state); } // This test is for UnwindMaps that should share the same map cursor when // multiple maps are created for the current process at the same time. TEST(libbacktrace, simultaneous_maps) { BacktraceMap* map1 = BacktraceMap::Create(getpid()); BacktraceMap* map2 = BacktraceMap::Create(getpid()); BacktraceMap* map3 = BacktraceMap::Create(getpid()); Backtrace* back1 = Backtrace::Create(getpid(), BACKTRACE_CURRENT_THREAD, map1); EXPECT_TRUE(back1->Unwind(0)); delete back1; delete map1; Backtrace* back2 = Backtrace::Create(getpid(), BACKTRACE_CURRENT_THREAD, map2); EXPECT_TRUE(back2->Unwind(0)); delete back2; delete map2; Backtrace* back3 = Backtrace::Create(getpid(), BACKTRACE_CURRENT_THREAD, map3); EXPECT_TRUE(back3->Unwind(0)); delete back3; delete map3; } TEST(libbacktrace, format_test) { UniquePtr backtrace(Backtrace::Create(getpid(), BACKTRACE_CURRENT_THREAD)); ASSERT_TRUE(backtrace.get() != NULL); backtrace_frame_data_t frame; frame.num = 1; frame.pc = 2; frame.sp = 0; frame.stack_size = 0; frame.map = NULL; frame.func_offset = 0; backtrace_map_t map; map.start = 0; map.end = 0; // Check no map set. frame.num = 1; #if defined(__LP64__) EXPECT_EQ("#01 pc 0000000000000002 ", #else EXPECT_EQ("#01 pc 00000002 ", #endif backtrace->FormatFrameData(&frame)); // Check map name empty, but exists. frame.map = ↦ map.start = 1; #if defined(__LP64__) EXPECT_EQ("#01 pc 0000000000000001 ", #else EXPECT_EQ("#01 pc 00000001 ", #endif backtrace->FormatFrameData(&frame)); // Check relative pc is set and map name is set. frame.pc = 0x12345679; frame.map = ↦ map.name = "MapFake"; map.start = 1; #if defined(__LP64__) EXPECT_EQ("#01 pc 0000000012345678 MapFake", #else EXPECT_EQ("#01 pc 12345678 MapFake", #endif backtrace->FormatFrameData(&frame)); // Check func_name is set, but no func offset. frame.func_name = "ProcFake"; #if defined(__LP64__) EXPECT_EQ("#01 pc 0000000012345678 MapFake (ProcFake)", #else EXPECT_EQ("#01 pc 12345678 MapFake (ProcFake)", #endif backtrace->FormatFrameData(&frame)); // Check func_name is set, and func offset is non-zero. frame.func_offset = 645; #if defined(__LP64__) EXPECT_EQ("#01 pc 0000000012345678 MapFake (ProcFake+645)", #else EXPECT_EQ("#01 pc 12345678 MapFake (ProcFake+645)", #endif backtrace->FormatFrameData(&frame)); } struct map_test_t { uintptr_t start; uintptr_t end; }; bool map_sort(map_test_t i, map_test_t j) { return i.start < j.start; } static void VerifyMap(pid_t pid) { char buffer[4096]; snprintf(buffer, sizeof(buffer), "/proc/%d/maps", pid); FILE* map_file = fopen(buffer, "r"); ASSERT_TRUE(map_file != NULL); std::vector test_maps; while (fgets(buffer, sizeof(buffer), map_file)) { map_test_t map; ASSERT_EQ(2, sscanf(buffer, "%" SCNxPTR "-%" SCNxPTR " ", &map.start, &map.end)); test_maps.push_back(map); } fclose(map_file); std::sort(test_maps.begin(), test_maps.end(), map_sort); UniquePtr map(BacktraceMap::Create(pid)); // Basic test that verifies that the map is in the expected order. std::vector::const_iterator test_it = test_maps.begin(); for (BacktraceMap::const_iterator it = map->begin(); it != map->end(); ++it) { ASSERT_TRUE(test_it != test_maps.end()); ASSERT_EQ(test_it->start, it->start); ASSERT_EQ(test_it->end, it->end); ++test_it; } ASSERT_TRUE(test_it == test_maps.end()); } TEST(libbacktrace, verify_map_remote) { pid_t pid; if ((pid = fork()) == 0) { while (true) { } _exit(0); } ASSERT_LT(0, pid); ASSERT_TRUE(ptrace(PTRACE_ATTACH, pid, 0, 0) == 0); // Wait for the process to get to a stopping point. WaitForStop(pid); // The maps should match exactly since the forked process has been paused. VerifyMap(pid); ASSERT_TRUE(ptrace(PTRACE_DETACH, pid, 0, 0) == 0); kill(pid, SIGKILL); ASSERT_EQ(waitpid(pid, NULL, 0), pid); } #if defined(ENABLE_PSS_TESTS) #include "GetPss.h" #define MAX_LEAK_BYTES 32*1024UL static void CheckForLeak(pid_t pid, pid_t tid) { // Do a few runs to get the PSS stable. for (size_t i = 0; i < 100; i++) { Backtrace* backtrace = Backtrace::Create(pid, tid); ASSERT_TRUE(backtrace != NULL); ASSERT_TRUE(backtrace->Unwind(0)); delete backtrace; } size_t stable_pss = GetPssBytes(); // Loop enough that even a small leak should be detectable. for (size_t i = 0; i < 4096; i++) { Backtrace* backtrace = Backtrace::Create(pid, tid); ASSERT_TRUE(backtrace != NULL); ASSERT_TRUE(backtrace->Unwind(0)); delete backtrace; } size_t new_pss = GetPssBytes(); size_t abs_diff = (new_pss > stable_pss) ? new_pss - stable_pss : stable_pss - new_pss; // As long as the new pss is within a certain amount, consider everything okay. ASSERT_LE(abs_diff, MAX_LEAK_BYTES); } TEST(libbacktrace, check_for_leak_local) { CheckForLeak(BACKTRACE_CURRENT_PROCESS, BACKTRACE_CURRENT_THREAD); } TEST(libbacktrace, check_for_leak_local_thread) { thread_t thread_data = { 0, 0, 0 }; pthread_t thread; ASSERT_TRUE(pthread_create(&thread, NULL, ThreadLevelRun, &thread_data) == 0); // Wait up to 2 seconds for the tid to be set. ASSERT_TRUE(WaitForNonZero(&thread_data.state, 2)); CheckForLeak(BACKTRACE_CURRENT_PROCESS, thread_data.tid); // Tell the thread to exit its infinite loop. android_atomic_acquire_store(0, &thread_data.state); ASSERT_TRUE(pthread_join(thread, NULL) == 0); } TEST(libbacktrace, check_for_leak_remote) { pid_t pid; if ((pid = fork()) == 0) { while (true) { } _exit(0); } ASSERT_LT(0, pid); ASSERT_TRUE(ptrace(PTRACE_ATTACH, pid, 0, 0) == 0); // Wait for the process to get to a stopping point. WaitForStop(pid); CheckForLeak(pid, BACKTRACE_CURRENT_THREAD); ASSERT_TRUE(ptrace(PTRACE_DETACH, pid, 0, 0) == 0); kill(pid, SIGKILL); ASSERT_EQ(waitpid(pid, NULL, 0), pid); } #endif