/* * Copyright (C) 2012 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include "private/ScopeGuard.h" #include "BionicDeathTest.h" #include "ScopedSignalHandler.h" #include "gtest_ex.h" #include #include #include #include #include #include #include #include #include #include TEST(pthread, pthread_key_create) { pthread_key_t key; ASSERT_EQ(0, pthread_key_create(&key, NULL)); ASSERT_EQ(0, pthread_key_delete(key)); // Can't delete a key that's already been deleted. ASSERT_EQ(EINVAL, pthread_key_delete(key)); } TEST(pthread, pthread_keys_max) { // POSIX says PTHREAD_KEYS_MAX should be at least 128. ASSERT_GE(PTHREAD_KEYS_MAX, 128); } TEST(pthread, _SC_THREAD_KEYS_MAX_big_enough_for_POSIX) { // sysconf shouldn't return a smaller value. int sysconf_max = sysconf(_SC_THREAD_KEYS_MAX); ASSERT_GE(sysconf_max, PTHREAD_KEYS_MAX); } TEST(pthread, pthread_key_many_distinct) { // We should be able to allocate at least this many keys. int nkeys = sysconf(_SC_THREAD_KEYS_MAX) / 2; std::vector keys; auto scope_guard = make_scope_guard([&keys]{ for (auto key : keys) { EXPECT_EQ(0, pthread_key_delete(key)); } }); for (int i = 0; i < nkeys; ++i) { pthread_key_t key; // If this fails, it's likely that GLOBAL_INIT_THREAD_LOCAL_BUFFER_COUNT is // wrong. ASSERT_EQ(0, pthread_key_create(&key, NULL)) << i << " of " << nkeys; keys.push_back(key); ASSERT_EQ(0, pthread_setspecific(key, reinterpret_cast(i))); } for (int i = keys.size() - 1; i >= 0; --i) { ASSERT_EQ(reinterpret_cast(i), pthread_getspecific(keys.back())); pthread_key_t key = keys.back(); keys.pop_back(); ASSERT_EQ(0, pthread_key_delete(key)); } } TEST(pthread, pthread_key_EAGAIN) { int sysconf_max = sysconf(_SC_THREAD_KEYS_MAX); std::vector keys; int rv = 0; // Two keys are used by gtest, so sysconf_max should be more than we are // allowed to allocate now. for (int i = 0; i < sysconf_max; i++) { pthread_key_t key; rv = pthread_key_create(&key, NULL); if (rv == EAGAIN) { break; } EXPECT_EQ(0, rv); keys.push_back(key); } // Don't leak keys. for (auto key : keys) { EXPECT_EQ(0, pthread_key_delete(key)); } keys.clear(); // We should have eventually reached the maximum number of keys and received // EAGAIN. ASSERT_EQ(EAGAIN, rv); } TEST(pthread, pthread_key_delete) { void* expected = reinterpret_cast(1234); pthread_key_t key; ASSERT_EQ(0, pthread_key_create(&key, NULL)); ASSERT_EQ(0, pthread_setspecific(key, expected)); ASSERT_EQ(expected, pthread_getspecific(key)); ASSERT_EQ(0, pthread_key_delete(key)); // After deletion, pthread_getspecific returns NULL. ASSERT_EQ(NULL, pthread_getspecific(key)); // And you can't use pthread_setspecific with the deleted key. ASSERT_EQ(EINVAL, pthread_setspecific(key, expected)); } TEST(pthread, pthread_key_fork) { void* expected = reinterpret_cast(1234); pthread_key_t key; ASSERT_EQ(0, pthread_key_create(&key, NULL)); ASSERT_EQ(0, pthread_setspecific(key, expected)); ASSERT_EQ(expected, pthread_getspecific(key)); pid_t pid = fork(); ASSERT_NE(-1, pid) << strerror(errno); if (pid == 0) { // The surviving thread inherits all the forking thread's TLS values... ASSERT_EQ(expected, pthread_getspecific(key)); _exit(99); } int status; ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(99, WEXITSTATUS(status)); ASSERT_EQ(expected, pthread_getspecific(key)); ASSERT_EQ(0, pthread_key_delete(key)); } static void* DirtyKeyFn(void* key) { return pthread_getspecific(*reinterpret_cast(key)); } TEST(pthread, pthread_key_dirty) { pthread_key_t key; ASSERT_EQ(0, pthread_key_create(&key, NULL)); size_t stack_size = 128 * 1024; void* stack = mmap(NULL, stack_size, PROT_READ|PROT_WRITE, MAP_PRIVATE|MAP_ANONYMOUS, -1, 0); ASSERT_NE(MAP_FAILED, stack); memset(stack, 0xff, stack_size); pthread_attr_t attr; ASSERT_EQ(0, pthread_attr_init(&attr)); ASSERT_EQ(0, pthread_attr_setstack(&attr, stack, stack_size)); pthread_t t; ASSERT_EQ(0, pthread_create(&t, &attr, DirtyKeyFn, &key)); void* result; ASSERT_EQ(0, pthread_join(t, &result)); ASSERT_EQ(nullptr, result); // Not ~0! ASSERT_EQ(0, munmap(stack, stack_size)); ASSERT_EQ(0, pthread_key_delete(key)); } static void* IdFn(void* arg) { return arg; } static void* SleepFn(void* arg) { sleep(reinterpret_cast(arg)); return NULL; } static void* SpinFn(void* arg) { volatile bool* b = reinterpret_cast(arg); while (!*b) { } return NULL; } static void* JoinFn(void* arg) { return reinterpret_cast(pthread_join(reinterpret_cast(arg), NULL)); } static void AssertDetached(pthread_t t, bool is_detached) { pthread_attr_t attr; ASSERT_EQ(0, pthread_getattr_np(t, &attr)); int detach_state; ASSERT_EQ(0, pthread_attr_getdetachstate(&attr, &detach_state)); pthread_attr_destroy(&attr); ASSERT_EQ(is_detached, (detach_state == PTHREAD_CREATE_DETACHED)); } static void MakeDeadThread(pthread_t& t) { ASSERT_EQ(0, pthread_create(&t, NULL, IdFn, NULL)); ASSERT_EQ(0, pthread_join(t, NULL)); } TEST(pthread, pthread_create) { void* expected_result = reinterpret_cast(123); // Can we create a thread? pthread_t t; ASSERT_EQ(0, pthread_create(&t, NULL, IdFn, expected_result)); // If we join, do we get the expected value back? void* result; ASSERT_EQ(0, pthread_join(t, &result)); ASSERT_EQ(expected_result, result); } TEST(pthread, pthread_create_EAGAIN) { pthread_attr_t attributes; ASSERT_EQ(0, pthread_attr_init(&attributes)); ASSERT_EQ(0, pthread_attr_setstacksize(&attributes, static_cast(-1) & ~(getpagesize() - 1))); pthread_t t; ASSERT_EQ(EAGAIN, pthread_create(&t, &attributes, IdFn, NULL)); } TEST(pthread, pthread_no_join_after_detach) { pthread_t t1; ASSERT_EQ(0, pthread_create(&t1, NULL, SleepFn, reinterpret_cast(5))); // After a pthread_detach... ASSERT_EQ(0, pthread_detach(t1)); AssertDetached(t1, true); // ...pthread_join should fail. ASSERT_EQ(EINVAL, pthread_join(t1, NULL)); } TEST(pthread, pthread_no_op_detach_after_join) { bool done = false; pthread_t t1; ASSERT_EQ(0, pthread_create(&t1, NULL, SpinFn, &done)); // If thread 2 is already waiting to join thread 1... pthread_t t2; ASSERT_EQ(0, pthread_create(&t2, NULL, JoinFn, reinterpret_cast(t1))); sleep(1); // (Give t2 a chance to call pthread_join.) // ...a call to pthread_detach on thread 1 will "succeed" (silently fail)... ASSERT_EQ(0, pthread_detach(t1)); AssertDetached(t1, false); done = true; // ...but t2's join on t1 still goes ahead (which we can tell because our join on t2 finishes). void* join_result; ASSERT_EQ(0, pthread_join(t2, &join_result)); ASSERT_EQ(0U, reinterpret_cast(join_result)); } TEST(pthread, pthread_join_self) { ASSERT_EQ(EDEADLK, pthread_join(pthread_self(), NULL)); } struct TestBug37410 { pthread_t main_thread; pthread_mutex_t mutex; static void main() { TestBug37410 data; data.main_thread = pthread_self(); ASSERT_EQ(0, pthread_mutex_init(&data.mutex, NULL)); ASSERT_EQ(0, pthread_mutex_lock(&data.mutex)); pthread_t t; ASSERT_EQ(0, pthread_create(&t, NULL, TestBug37410::thread_fn, reinterpret_cast(&data))); // Wait for the thread to be running... ASSERT_EQ(0, pthread_mutex_lock(&data.mutex)); ASSERT_EQ(0, pthread_mutex_unlock(&data.mutex)); // ...and exit. pthread_exit(NULL); } private: static void* thread_fn(void* arg) { TestBug37410* data = reinterpret_cast(arg); // Let the main thread know we're running. pthread_mutex_unlock(&data->mutex); // And wait for the main thread to exit. pthread_join(data->main_thread, NULL); return NULL; } }; // Even though this isn't really a death test, we have to say "DeathTest" here so gtest knows to // run this test (which exits normally) in its own process. class pthread_DeathTest : public BionicDeathTest {}; TEST_F(pthread_DeathTest, pthread_bug_37410) { // http://code.google.com/p/android/issues/detail?id=37410 ASSERT_EXIT(TestBug37410::main(), ::testing::ExitedWithCode(0), ""); } static void* SignalHandlerFn(void* arg) { sigset_t wait_set; sigfillset(&wait_set); return reinterpret_cast(sigwait(&wait_set, reinterpret_cast(arg))); } TEST(pthread, pthread_sigmask) { // Check that SIGUSR1 isn't blocked. sigset_t original_set; sigemptyset(&original_set); ASSERT_EQ(0, pthread_sigmask(SIG_BLOCK, NULL, &original_set)); ASSERT_FALSE(sigismember(&original_set, SIGUSR1)); // Block SIGUSR1. sigset_t set; sigemptyset(&set); sigaddset(&set, SIGUSR1); ASSERT_EQ(0, pthread_sigmask(SIG_BLOCK, &set, NULL)); // Check that SIGUSR1 is blocked. sigset_t final_set; sigemptyset(&final_set); ASSERT_EQ(0, pthread_sigmask(SIG_BLOCK, NULL, &final_set)); ASSERT_TRUE(sigismember(&final_set, SIGUSR1)); // ...and that sigprocmask agrees with pthread_sigmask. sigemptyset(&final_set); ASSERT_EQ(0, sigprocmask(SIG_BLOCK, NULL, &final_set)); ASSERT_TRUE(sigismember(&final_set, SIGUSR1)); // Spawn a thread that calls sigwait and tells us what it received. pthread_t signal_thread; int received_signal = -1; ASSERT_EQ(0, pthread_create(&signal_thread, NULL, SignalHandlerFn, &received_signal)); // Send that thread SIGUSR1. pthread_kill(signal_thread, SIGUSR1); // See what it got. void* join_result; ASSERT_EQ(0, pthread_join(signal_thread, &join_result)); ASSERT_EQ(SIGUSR1, received_signal); ASSERT_EQ(0U, reinterpret_cast(join_result)); // Restore the original signal mask. ASSERT_EQ(0, pthread_sigmask(SIG_SETMASK, &original_set, NULL)); } TEST(pthread, pthread_setname_np__too_long) { ASSERT_EQ(ERANGE, pthread_setname_np(pthread_self(), "this name is far too long for linux")); } TEST(pthread, pthread_setname_np__self) { ASSERT_EQ(0, pthread_setname_np(pthread_self(), "short 1")); } TEST(pthread, pthread_setname_np__other) { pthread_t t1; ASSERT_EQ(0, pthread_create(&t1, NULL, SleepFn, reinterpret_cast(5))); ASSERT_EQ(0, pthread_setname_np(t1, "short 2")); } TEST(pthread, pthread_setname_np__no_such_thread) { pthread_t dead_thread; MakeDeadThread(dead_thread); // Call pthread_setname_np after thread has already exited. ASSERT_EQ(ENOENT, pthread_setname_np(dead_thread, "short 3")); } TEST(pthread, pthread_kill__0) { // Signal 0 just tests that the thread exists, so it's safe to call on ourselves. ASSERT_EQ(0, pthread_kill(pthread_self(), 0)); } TEST(pthread, pthread_kill__invalid_signal) { ASSERT_EQ(EINVAL, pthread_kill(pthread_self(), -1)); } static void pthread_kill__in_signal_handler_helper(int signal_number) { static int count = 0; ASSERT_EQ(SIGALRM, signal_number); if (++count == 1) { // Can we call pthread_kill from a signal handler? ASSERT_EQ(0, pthread_kill(pthread_self(), SIGALRM)); } } TEST(pthread, pthread_kill__in_signal_handler) { ScopedSignalHandler ssh(SIGALRM, pthread_kill__in_signal_handler_helper); ASSERT_EQ(0, pthread_kill(pthread_self(), SIGALRM)); } TEST(pthread, pthread_detach__no_such_thread) { pthread_t dead_thread; MakeDeadThread(dead_thread); ASSERT_EQ(ESRCH, pthread_detach(dead_thread)); } TEST(pthread, pthread_detach__leak) { size_t initial_bytes = 0; // Run this loop more than once since the first loop causes some memory // to be allocated permenantly. Run an extra loop to help catch any subtle // memory leaks. for (size_t loop = 0; loop < 3; loop++) { // Set the initial bytes on the second loop since the memory in use // should have stabilized. if (loop == 1) { initial_bytes = mallinfo().uordblks; } pthread_attr_t attr; ASSERT_EQ(0, pthread_attr_init(&attr)); ASSERT_EQ(0, pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE)); std::vector threads; for (size_t i = 0; i < 32; ++i) { pthread_t t; ASSERT_EQ(0, pthread_create(&t, &attr, IdFn, NULL)); threads.push_back(t); } sleep(1); for (size_t i = 0; i < 32; ++i) { ASSERT_EQ(0, pthread_detach(threads[i])) << i; } } size_t final_bytes = mallinfo().uordblks; int leaked_bytes = (final_bytes - initial_bytes); // User code (like this test) doesn't know how large pthread_internal_t is. // We can be pretty sure it's more than 128 bytes. ASSERT_LT(leaked_bytes, 32 /*threads*/ * 128 /*bytes*/); } TEST(pthread, pthread_getcpuclockid__clock_gettime) { pthread_t t; ASSERT_EQ(0, pthread_create(&t, NULL, SleepFn, reinterpret_cast(5))); clockid_t c; ASSERT_EQ(0, pthread_getcpuclockid(t, &c)); timespec ts; ASSERT_EQ(0, clock_gettime(c, &ts)); } TEST(pthread, pthread_getcpuclockid__no_such_thread) { pthread_t dead_thread; MakeDeadThread(dead_thread); clockid_t c; ASSERT_EQ(ESRCH, pthread_getcpuclockid(dead_thread, &c)); } TEST(pthread, pthread_getschedparam__no_such_thread) { pthread_t dead_thread; MakeDeadThread(dead_thread); int policy; sched_param param; ASSERT_EQ(ESRCH, pthread_getschedparam(dead_thread, &policy, ¶m)); } TEST(pthread, pthread_setschedparam__no_such_thread) { pthread_t dead_thread; MakeDeadThread(dead_thread); int policy = 0; sched_param param; ASSERT_EQ(ESRCH, pthread_setschedparam(dead_thread, policy, ¶m)); } TEST(pthread, pthread_join__no_such_thread) { pthread_t dead_thread; MakeDeadThread(dead_thread); ASSERT_EQ(ESRCH, pthread_join(dead_thread, NULL)); } TEST(pthread, pthread_kill__no_such_thread) { pthread_t dead_thread; MakeDeadThread(dead_thread); ASSERT_EQ(ESRCH, pthread_kill(dead_thread, 0)); } TEST(pthread, pthread_join__multijoin) { bool done = false; pthread_t t1; ASSERT_EQ(0, pthread_create(&t1, NULL, SpinFn, &done)); pthread_t t2; ASSERT_EQ(0, pthread_create(&t2, NULL, JoinFn, reinterpret_cast(t1))); sleep(1); // (Give t2 a chance to call pthread_join.) // Multiple joins to the same thread should fail. ASSERT_EQ(EINVAL, pthread_join(t1, NULL)); done = true; // ...but t2's join on t1 still goes ahead (which we can tell because our join on t2 finishes). void* join_result; ASSERT_EQ(0, pthread_join(t2, &join_result)); ASSERT_EQ(0U, reinterpret_cast(join_result)); } TEST(pthread, pthread_join__race) { // http://b/11693195 --- pthread_join could return before the thread had actually exited. // If the joiner unmapped the thread's stack, that could lead to SIGSEGV in the thread. for (size_t i = 0; i < 1024; ++i) { size_t stack_size = 64*1024; void* stack = mmap(NULL, stack_size, PROT_READ|PROT_WRITE, MAP_ANON|MAP_PRIVATE, -1, 0); pthread_attr_t a; pthread_attr_init(&a); pthread_attr_setstack(&a, stack, stack_size); pthread_t t; ASSERT_EQ(0, pthread_create(&t, &a, IdFn, NULL)); ASSERT_EQ(0, pthread_join(t, NULL)); ASSERT_EQ(0, munmap(stack, stack_size)); } } static void* GetActualGuardSizeFn(void* arg) { pthread_attr_t attributes; pthread_getattr_np(pthread_self(), &attributes); pthread_attr_getguardsize(&attributes, reinterpret_cast(arg)); return NULL; } static size_t GetActualGuardSize(const pthread_attr_t& attributes) { size_t result; pthread_t t; pthread_create(&t, &attributes, GetActualGuardSizeFn, &result); pthread_join(t, NULL); return result; } static void* GetActualStackSizeFn(void* arg) { pthread_attr_t attributes; pthread_getattr_np(pthread_self(), &attributes); pthread_attr_getstacksize(&attributes, reinterpret_cast(arg)); return NULL; } static size_t GetActualStackSize(const pthread_attr_t& attributes) { size_t result; pthread_t t; pthread_create(&t, &attributes, GetActualStackSizeFn, &result); pthread_join(t, NULL); return result; } TEST(pthread, pthread_attr_setguardsize) { pthread_attr_t attributes; ASSERT_EQ(0, pthread_attr_init(&attributes)); // Get the default guard size. size_t default_guard_size; ASSERT_EQ(0, pthread_attr_getguardsize(&attributes, &default_guard_size)); // No such thing as too small: will be rounded up to one page by pthread_create. ASSERT_EQ(0, pthread_attr_setguardsize(&attributes, 128)); size_t guard_size; ASSERT_EQ(0, pthread_attr_getguardsize(&attributes, &guard_size)); ASSERT_EQ(128U, guard_size); ASSERT_EQ(4096U, GetActualGuardSize(attributes)); // Large enough and a multiple of the page size. ASSERT_EQ(0, pthread_attr_setguardsize(&attributes, 32*1024)); ASSERT_EQ(0, pthread_attr_getguardsize(&attributes, &guard_size)); ASSERT_EQ(32*1024U, guard_size); // Large enough but not a multiple of the page size; will be rounded up by pthread_create. ASSERT_EQ(0, pthread_attr_setguardsize(&attributes, 32*1024 + 1)); ASSERT_EQ(0, pthread_attr_getguardsize(&attributes, &guard_size)); ASSERT_EQ(32*1024U + 1, guard_size); } TEST(pthread, pthread_attr_setstacksize) { pthread_attr_t attributes; ASSERT_EQ(0, pthread_attr_init(&attributes)); // Get the default stack size. size_t default_stack_size; ASSERT_EQ(0, pthread_attr_getstacksize(&attributes, &default_stack_size)); // Too small. ASSERT_EQ(EINVAL, pthread_attr_setstacksize(&attributes, 128)); size_t stack_size; ASSERT_EQ(0, pthread_attr_getstacksize(&attributes, &stack_size)); ASSERT_EQ(default_stack_size, stack_size); ASSERT_GE(GetActualStackSize(attributes), default_stack_size); // Large enough and a multiple of the page size. ASSERT_EQ(0, pthread_attr_setstacksize(&attributes, 32*1024)); ASSERT_EQ(0, pthread_attr_getstacksize(&attributes, &stack_size)); ASSERT_EQ(32*1024U, stack_size); ASSERT_EQ(GetActualStackSize(attributes), 32*1024U); // Large enough but not a multiple of the page size; will be rounded up by pthread_create. ASSERT_EQ(0, pthread_attr_setstacksize(&attributes, 32*1024 + 1)); ASSERT_EQ(0, pthread_attr_getstacksize(&attributes, &stack_size)); ASSERT_EQ(32*1024U + 1, stack_size); #if defined(__BIONIC__) // Bionic rounds up, which is what POSIX allows. ASSERT_EQ(GetActualStackSize(attributes), (32 + 4)*1024U); #else // __BIONIC__ // glibc rounds down, in violation of POSIX. They document this in their BUGS section. ASSERT_EQ(GetActualStackSize(attributes), 32*1024U); #endif // __BIONIC__ } TEST(pthread, pthread_rwlock_smoke) { pthread_rwlock_t l; ASSERT_EQ(0, pthread_rwlock_init(&l, NULL)); // Single read lock ASSERT_EQ(0, pthread_rwlock_rdlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); // Multiple read lock ASSERT_EQ(0, pthread_rwlock_rdlock(&l)); ASSERT_EQ(0, pthread_rwlock_rdlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); // Write lock ASSERT_EQ(0, pthread_rwlock_wrlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); // Try writer lock ASSERT_EQ(0, pthread_rwlock_trywrlock(&l)); ASSERT_EQ(EBUSY, pthread_rwlock_trywrlock(&l)); ASSERT_EQ(EBUSY, pthread_rwlock_tryrdlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); // Try reader lock ASSERT_EQ(0, pthread_rwlock_tryrdlock(&l)); ASSERT_EQ(0, pthread_rwlock_tryrdlock(&l)); ASSERT_EQ(EBUSY, pthread_rwlock_trywrlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); // Try writer lock after unlock ASSERT_EQ(0, pthread_rwlock_wrlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); #ifdef __BIONIC__ // EDEADLK in "read after write" ASSERT_EQ(0, pthread_rwlock_wrlock(&l)); ASSERT_EQ(EDEADLK, pthread_rwlock_rdlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); // EDEADLK in "write after write" ASSERT_EQ(0, pthread_rwlock_wrlock(&l)); ASSERT_EQ(EDEADLK, pthread_rwlock_wrlock(&l)); ASSERT_EQ(0, pthread_rwlock_unlock(&l)); #endif ASSERT_EQ(0, pthread_rwlock_destroy(&l)); } static int g_once_fn_call_count = 0; static void OnceFn() { ++g_once_fn_call_count; } TEST(pthread, pthread_once_smoke) { pthread_once_t once_control = PTHREAD_ONCE_INIT; ASSERT_EQ(0, pthread_once(&once_control, OnceFn)); ASSERT_EQ(0, pthread_once(&once_control, OnceFn)); ASSERT_EQ(1, g_once_fn_call_count); } static std::string pthread_once_1934122_result = ""; static void Routine2() { pthread_once_1934122_result += "2"; } static void Routine1() { pthread_once_t once_control_2 = PTHREAD_ONCE_INIT; pthread_once_1934122_result += "1"; pthread_once(&once_control_2, &Routine2); } TEST(pthread, pthread_once_1934122) { // Very old versions of Android couldn't call pthread_once from a // pthread_once init routine. http://b/1934122. pthread_once_t once_control_1 = PTHREAD_ONCE_INIT; ASSERT_EQ(0, pthread_once(&once_control_1, &Routine1)); ASSERT_EQ("12", pthread_once_1934122_result); } static int g_atfork_prepare_calls = 0; static void AtForkPrepare1() { g_atfork_prepare_calls = (g_atfork_prepare_calls << 4) | 1; } static void AtForkPrepare2() { g_atfork_prepare_calls = (g_atfork_prepare_calls << 4) | 2; } static int g_atfork_parent_calls = 0; static void AtForkParent1() { g_atfork_parent_calls = (g_atfork_parent_calls << 4) | 1; } static void AtForkParent2() { g_atfork_parent_calls = (g_atfork_parent_calls << 4) | 2; } static int g_atfork_child_calls = 0; static void AtForkChild1() { g_atfork_child_calls = (g_atfork_child_calls << 4) | 1; } static void AtForkChild2() { g_atfork_child_calls = (g_atfork_child_calls << 4) | 2; } TEST(pthread, pthread_atfork_smoke) { test_isolated([] { ASSERT_EQ(0, pthread_atfork(AtForkPrepare1, AtForkParent1, AtForkChild1)); ASSERT_EQ(0, pthread_atfork(AtForkPrepare2, AtForkParent2, AtForkChild2)); int pid = fork(); ASSERT_NE(-1, pid) << strerror(errno); // Child and parent calls are made in the order they were registered. if (pid == 0) { ASSERT_EQ(0x12, g_atfork_child_calls); _exit(0); } ASSERT_EQ(0x12, g_atfork_parent_calls); // Prepare calls are made in the reverse order. ASSERT_EQ(0x21, g_atfork_prepare_calls); }); } TEST(pthread, pthread_attr_getscope) { pthread_attr_t attr; ASSERT_EQ(0, pthread_attr_init(&attr)); int scope; ASSERT_EQ(0, pthread_attr_getscope(&attr, &scope)); ASSERT_EQ(PTHREAD_SCOPE_SYSTEM, scope); } TEST(pthread, pthread_condattr_init) { pthread_condattr_t attr; pthread_condattr_init(&attr); clockid_t clock; ASSERT_EQ(0, pthread_condattr_getclock(&attr, &clock)); ASSERT_EQ(CLOCK_REALTIME, clock); int pshared; ASSERT_EQ(0, pthread_condattr_getpshared(&attr, &pshared)); ASSERT_EQ(PTHREAD_PROCESS_PRIVATE, pshared); } TEST(pthread, pthread_condattr_setclock) { pthread_condattr_t attr; pthread_condattr_init(&attr); ASSERT_EQ(0, pthread_condattr_setclock(&attr, CLOCK_REALTIME)); clockid_t clock; ASSERT_EQ(0, pthread_condattr_getclock(&attr, &clock)); ASSERT_EQ(CLOCK_REALTIME, clock); ASSERT_EQ(0, pthread_condattr_setclock(&attr, CLOCK_MONOTONIC)); ASSERT_EQ(0, pthread_condattr_getclock(&attr, &clock)); ASSERT_EQ(CLOCK_MONOTONIC, clock); ASSERT_EQ(EINVAL, pthread_condattr_setclock(&attr, CLOCK_PROCESS_CPUTIME_ID)); } TEST(pthread, pthread_cond_broadcast__preserves_condattr_flags) { #if defined(__BIONIC__) // This tests a bionic implementation detail. pthread_condattr_t attr; pthread_condattr_init(&attr); ASSERT_EQ(0, pthread_condattr_setclock(&attr, CLOCK_MONOTONIC)); ASSERT_EQ(0, pthread_condattr_setpshared(&attr, PTHREAD_PROCESS_SHARED)); pthread_cond_t cond_var; ASSERT_EQ(0, pthread_cond_init(&cond_var, &attr)); ASSERT_EQ(0, pthread_cond_signal(&cond_var)); ASSERT_EQ(0, pthread_cond_broadcast(&cond_var)); attr = static_cast(cond_var.value); clockid_t clock; ASSERT_EQ(0, pthread_condattr_getclock(&attr, &clock)); ASSERT_EQ(CLOCK_MONOTONIC, clock); int pshared; ASSERT_EQ(0, pthread_condattr_getpshared(&attr, &pshared)); ASSERT_EQ(PTHREAD_PROCESS_SHARED, pshared); #else // __BIONIC__ GTEST_LOG_(INFO) << "This test does nothing.\n"; #endif // __BIONIC__ } TEST(pthread, pthread_mutex_timedlock) { pthread_mutex_t m; ASSERT_EQ(0, pthread_mutex_init(&m, NULL)); // If the mutex is already locked, pthread_mutex_timedlock should time out. ASSERT_EQ(0, pthread_mutex_lock(&m)); timespec ts; ASSERT_EQ(0, clock_gettime(CLOCK_REALTIME, &ts)); ts.tv_nsec += 1; ASSERT_EQ(ETIMEDOUT, pthread_mutex_timedlock(&m, &ts)); // If the mutex is unlocked, pthread_mutex_timedlock should succeed. ASSERT_EQ(0, pthread_mutex_unlock(&m)); ASSERT_EQ(0, clock_gettime(CLOCK_REALTIME, &ts)); ts.tv_nsec += 1; ASSERT_EQ(0, pthread_mutex_timedlock(&m, &ts)); ASSERT_EQ(0, pthread_mutex_unlock(&m)); ASSERT_EQ(0, pthread_mutex_destroy(&m)); } TEST(pthread, pthread_attr_getstack__main_thread) { // This test is only meaningful for the main thread, so make sure we're running on it! ASSERT_EQ(getpid(), syscall(__NR_gettid)); // Get the main thread's attributes. pthread_attr_t attributes; ASSERT_EQ(0, pthread_getattr_np(pthread_self(), &attributes)); // Check that we correctly report that the main thread has no guard page. size_t guard_size; ASSERT_EQ(0, pthread_attr_getguardsize(&attributes, &guard_size)); ASSERT_EQ(0U, guard_size); // The main thread has no guard page. // Get the stack base and the stack size (both ways). void* stack_base; size_t stack_size; ASSERT_EQ(0, pthread_attr_getstack(&attributes, &stack_base, &stack_size)); size_t stack_size2; ASSERT_EQ(0, pthread_attr_getstacksize(&attributes, &stack_size2)); // The two methods of asking for the stack size should agree. EXPECT_EQ(stack_size, stack_size2); // What does /proc/self/maps' [stack] line say? void* maps_stack_hi = NULL; FILE* fp = fopen("/proc/self/maps", "r"); ASSERT_TRUE(fp != NULL); char line[BUFSIZ]; while (fgets(line, sizeof(line), fp) != NULL) { uintptr_t lo, hi; char name[10]; sscanf(line, "%" PRIxPTR "-%" PRIxPTR " %*4s %*x %*x:%*x %*d %10s", &lo, &hi, name); if (strcmp(name, "[stack]") == 0) { maps_stack_hi = reinterpret_cast(hi); break; } } fclose(fp); // The stack size should correspond to RLIMIT_STACK. rlimit rl; ASSERT_EQ(0, getrlimit(RLIMIT_STACK, &rl)); uint64_t original_rlim_cur = rl.rlim_cur; #if defined(__BIONIC__) if (rl.rlim_cur == RLIM_INFINITY) { rl.rlim_cur = 8 * 1024 * 1024; // Bionic reports unlimited stacks as 8MiB. } #endif EXPECT_EQ(rl.rlim_cur, stack_size); auto guard = make_scope_guard([&rl, original_rlim_cur]() { rl.rlim_cur = original_rlim_cur; ASSERT_EQ(0, setrlimit(RLIMIT_STACK, &rl)); }); // The high address of the /proc/self/maps [stack] region should equal stack_base + stack_size. // Remember that the stack grows down (and is mapped in on demand), so the low address of the // region isn't very interesting. EXPECT_EQ(maps_stack_hi, reinterpret_cast(stack_base) + stack_size); // // What if RLIMIT_STACK is smaller than the stack's current extent? // rl.rlim_cur = rl.rlim_max = 1024; // 1KiB. We know the stack must be at least a page already. rl.rlim_max = RLIM_INFINITY; ASSERT_EQ(0, setrlimit(RLIMIT_STACK, &rl)); ASSERT_EQ(0, pthread_getattr_np(pthread_self(), &attributes)); ASSERT_EQ(0, pthread_attr_getstack(&attributes, &stack_base, &stack_size)); ASSERT_EQ(0, pthread_attr_getstacksize(&attributes, &stack_size2)); EXPECT_EQ(stack_size, stack_size2); ASSERT_EQ(1024U, stack_size); // // What if RLIMIT_STACK isn't a whole number of pages? // rl.rlim_cur = rl.rlim_max = 6666; // Not a whole number of pages. rl.rlim_max = RLIM_INFINITY; ASSERT_EQ(0, setrlimit(RLIMIT_STACK, &rl)); ASSERT_EQ(0, pthread_getattr_np(pthread_self(), &attributes)); ASSERT_EQ(0, pthread_attr_getstack(&attributes, &stack_base, &stack_size)); ASSERT_EQ(0, pthread_attr_getstacksize(&attributes, &stack_size2)); EXPECT_EQ(stack_size, stack_size2); ASSERT_EQ(6666U, stack_size); } #if defined(__BIONIC__) static void* pthread_gettid_np_helper(void* arg) { *reinterpret_cast(arg) = gettid(); return NULL; } #endif TEST(pthread, pthread_gettid_np) { #if defined(__BIONIC__) ASSERT_EQ(gettid(), pthread_gettid_np(pthread_self())); pid_t t_gettid_result; pthread_t t; pthread_create(&t, NULL, pthread_gettid_np_helper, &t_gettid_result); pid_t t_pthread_gettid_np_result = pthread_gettid_np(t); pthread_join(t, NULL); ASSERT_EQ(t_gettid_result, t_pthread_gettid_np_result); #else GTEST_LOG_(INFO) << "This test does nothing.\n"; #endif } static size_t cleanup_counter = 0; static void AbortCleanupRoutine(void*) { abort(); } static void CountCleanupRoutine(void*) { ++cleanup_counter; } static void PthreadCleanupTester() { pthread_cleanup_push(CountCleanupRoutine, NULL); pthread_cleanup_push(CountCleanupRoutine, NULL); pthread_cleanup_push(AbortCleanupRoutine, NULL); pthread_cleanup_pop(0); // Pop the abort without executing it. pthread_cleanup_pop(1); // Pop one count while executing it. ASSERT_EQ(1U, cleanup_counter); // Exit while the other count is still on the cleanup stack. pthread_exit(NULL); // Calls to pthread_cleanup_pop/pthread_cleanup_push must always be balanced. pthread_cleanup_pop(0); } static void* PthreadCleanupStartRoutine(void*) { PthreadCleanupTester(); return NULL; } TEST(pthread, pthread_cleanup_push__pthread_cleanup_pop) { pthread_t t; ASSERT_EQ(0, pthread_create(&t, NULL, PthreadCleanupStartRoutine, NULL)); pthread_join(t, NULL); ASSERT_EQ(2U, cleanup_counter); } TEST(pthread, PTHREAD_MUTEX_DEFAULT_is_PTHREAD_MUTEX_NORMAL) { ASSERT_EQ(PTHREAD_MUTEX_NORMAL, PTHREAD_MUTEX_DEFAULT); } TEST(pthread, pthread_mutexattr_gettype) { pthread_mutexattr_t attr; ASSERT_EQ(0, pthread_mutexattr_init(&attr)); int attr_type; ASSERT_EQ(0, pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_NORMAL)); ASSERT_EQ(0, pthread_mutexattr_gettype(&attr, &attr_type)); ASSERT_EQ(PTHREAD_MUTEX_NORMAL, attr_type); ASSERT_EQ(0, pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_ERRORCHECK)); ASSERT_EQ(0, pthread_mutexattr_gettype(&attr, &attr_type)); ASSERT_EQ(PTHREAD_MUTEX_ERRORCHECK, attr_type); ASSERT_EQ(0, pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_RECURSIVE)); ASSERT_EQ(0, pthread_mutexattr_gettype(&attr, &attr_type)); ASSERT_EQ(PTHREAD_MUTEX_RECURSIVE, attr_type); } TEST(pthread, pthread_mutex_lock_NORMAL) { pthread_mutexattr_t attr; ASSERT_EQ(0, pthread_mutexattr_init(&attr)); ASSERT_EQ(0, pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_NORMAL)); pthread_mutex_t lock; ASSERT_EQ(0, pthread_mutex_init(&lock, &attr)); ASSERT_EQ(0, pthread_mutex_lock(&lock)); ASSERT_EQ(0, pthread_mutex_unlock(&lock)); ASSERT_EQ(0, pthread_mutex_destroy(&lock)); } TEST(pthread, pthread_mutex_lock_ERRORCHECK) { pthread_mutexattr_t attr; ASSERT_EQ(0, pthread_mutexattr_init(&attr)); ASSERT_EQ(0, pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_ERRORCHECK)); pthread_mutex_t lock; ASSERT_EQ(0, pthread_mutex_init(&lock, &attr)); ASSERT_EQ(0, pthread_mutex_lock(&lock)); ASSERT_EQ(EDEADLK, pthread_mutex_lock(&lock)); ASSERT_EQ(0, pthread_mutex_unlock(&lock)); ASSERT_EQ(0, pthread_mutex_trylock(&lock)); ASSERT_EQ(EBUSY, pthread_mutex_trylock(&lock)); ASSERT_EQ(0, pthread_mutex_unlock(&lock)); ASSERT_EQ(EPERM, pthread_mutex_unlock(&lock)); ASSERT_EQ(0, pthread_mutex_destroy(&lock)); } TEST(pthread, pthread_mutex_lock_RECURSIVE) { pthread_mutexattr_t attr; ASSERT_EQ(0, pthread_mutexattr_init(&attr)); ASSERT_EQ(0, pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_RECURSIVE)); pthread_mutex_t lock; ASSERT_EQ(0, pthread_mutex_init(&lock, &attr)); ASSERT_EQ(0, pthread_mutex_lock(&lock)); ASSERT_EQ(0, pthread_mutex_lock(&lock)); ASSERT_EQ(0, pthread_mutex_unlock(&lock)); ASSERT_EQ(0, pthread_mutex_unlock(&lock)); ASSERT_EQ(0, pthread_mutex_trylock(&lock)); ASSERT_EQ(0, pthread_mutex_unlock(&lock)); ASSERT_EQ(EPERM, pthread_mutex_unlock(&lock)); ASSERT_EQ(0, pthread_mutex_destroy(&lock)); }