compiler-rt/lib/sanitizer_common/tests/sanitizer_linux_test.cc - nest-cam/4320010/compiler-rt - Git at Google

 //===-- sanitizer_linux_test.cc -------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // Tests for sanitizer_linux.h
 //
 //===----------------------------------------------------------------------===//

 #include "sanitizer_common/sanitizer_platform.h"
 #if SANITIZER_LINUX

 #include "sanitizer_common/sanitizer_linux.h"

 #include "sanitizer_common/sanitizer_common.h"
 #include "gtest/gtest.h"

 #include <pthread.h>
 #include <sched.h>
 #include <stdlib.h>

 #include <algorithm>
 #include <vector>

 namespace __sanitizer {

 struct TidReporterArgument {
   TidReporterArgument() {
     pthread_mutex_init(&terminate_thread_mutex, NULL);
     pthread_mutex_init(&tid_reported_mutex, NULL);
     pthread_cond_init(&terminate_thread_cond, NULL);
     pthread_cond_init(&tid_reported_cond, NULL);
     terminate_thread = false;
   }

   ~TidReporterArgument() {
     pthread_mutex_destroy(&terminate_thread_mutex);
     pthread_mutex_destroy(&tid_reported_mutex);
     pthread_cond_destroy(&terminate_thread_cond);
     pthread_cond_destroy(&tid_reported_cond);
   }

   pid_t reported_tid;
   // For signaling to spawned threads that they should terminate.
   pthread_cond_t terminate_thread_cond;
   pthread_mutex_t terminate_thread_mutex;
   bool terminate_thread;
   // For signaling to main thread that a child thread has reported its tid.
   pthread_cond_t tid_reported_cond;
   pthread_mutex_t tid_reported_mutex;

  private:
   // Disallow evil constructors
   TidReporterArgument(const TidReporterArgument &);
   void operator=(const TidReporterArgument &);
 };

 class ThreadListerTest : public ::testing::Test {
  protected:
   virtual void SetUp() {
     pthread_t pthread_id;
     pid_t tid;
     for (uptr i = 0; i < kThreadCount; i++) {
       SpawnTidReporter(&pthread_id, &tid);
       pthread_ids_.push_back(pthread_id);
       tids_.push_back(tid);
     }
   }

   virtual void TearDown() {
     pthread_mutex_lock(&thread_arg.terminate_thread_mutex);
     thread_arg.terminate_thread = true;
     pthread_cond_broadcast(&thread_arg.terminate_thread_cond);
     pthread_mutex_unlock(&thread_arg.terminate_thread_mutex);
     for (uptr i = 0; i < pthread_ids_.size(); i++)
       pthread_join(pthread_ids_[i], NULL);
   }

   void SpawnTidReporter(pthread_t *pthread_id, pid_t *tid);

   static const uptr kThreadCount = 20;

   std::vector<pthread_t> pthread_ids_;
   std::vector<pid_t> tids_;

   TidReporterArgument thread_arg;
 };

 // Writes its TID once to reported_tid and waits until signaled to terminate.
 void *TidReporterThread(void *argument) {
   TidReporterArgument *arg = reinterpret_cast<TidReporterArgument *>(argument);
   pthread_mutex_lock(&arg->tid_reported_mutex);
   arg->reported_tid = GetTid();
   pthread_cond_broadcast(&arg->tid_reported_cond);
   pthread_mutex_unlock(&arg->tid_reported_mutex);

   pthread_mutex_lock(&arg->terminate_thread_mutex);
   while (!arg->terminate_thread)
     pthread_cond_wait(&arg->terminate_thread_cond,
                       &arg->terminate_thread_mutex);
   pthread_mutex_unlock(&arg->terminate_thread_mutex);
   return NULL;
 }

 void ThreadListerTest::SpawnTidReporter(pthread_t *pthread_id,
                                         pid_t *tid) {
   pthread_mutex_lock(&thread_arg.tid_reported_mutex);
   thread_arg.reported_tid = -1;
   ASSERT_EQ(0, pthread_create(pthread_id, NULL,
                               TidReporterThread,
                               &thread_arg));
   while (thread_arg.reported_tid == -1)
     pthread_cond_wait(&thread_arg.tid_reported_cond,
                       &thread_arg.tid_reported_mutex);
   pthread_mutex_unlock(&thread_arg.tid_reported_mutex);
   *tid = thread_arg.reported_tid;
 }

 static std::vector<pid_t> ReadTidsToVector(ThreadLister *thread_lister) {
   std::vector<pid_t> listed_tids;
   pid_t tid;
   while ((tid = thread_lister->GetNextTID()) >= 0)
     listed_tids.push_back(tid);
   EXPECT_FALSE(thread_lister->error());
   return listed_tids;
 }

 static bool Includes(std::vector<pid_t> first, std::vector<pid_t> second) {
   std::sort(first.begin(), first.end());
   std::sort(second.begin(), second.end());
   return std::includes(first.begin(), first.end(),
                        second.begin(), second.end());
 }

 static bool HasElement(std::vector<pid_t> vector, pid_t element) {
   return std::find(vector.begin(), vector.end(), element) != vector.end();
 }

 // ThreadLister's output should include the current thread's TID and the TID of
 // every thread we spawned.
 TEST_F(ThreadListerTest, ThreadListerSeesAllSpawnedThreads) {
   pid_t self_tid = GetTid();
   ThreadLister thread_lister(getpid());
   std::vector<pid_t> listed_tids = ReadTidsToVector(&thread_lister);
   ASSERT_TRUE(HasElement(listed_tids, self_tid));
   ASSERT_TRUE(Includes(listed_tids, tids_));
 }

 // Calling Reset() should not cause ThreadLister to forget any threads it's
 // supposed to know about.
 TEST_F(ThreadListerTest, ResetDoesNotForgetThreads) {
   ThreadLister thread_lister(getpid());

   // Run the loop body twice, because Reset() might behave differently if called
   // on a freshly created object.
   for (uptr i = 0; i < 2; i++) {
     thread_lister.Reset();
     std::vector<pid_t> listed_tids = ReadTidsToVector(&thread_lister);
     ASSERT_TRUE(Includes(listed_tids, tids_));
   }
 }

 // If new threads have spawned during ThreadLister object's lifetime, calling
 // Reset() should cause ThreadLister to recognize their existence.
 TEST_F(ThreadListerTest, ResetMakesNewThreadsKnown) {
   ThreadLister thread_lister(getpid());
   std::vector<pid_t> threads_before_extra = ReadTidsToVector(&thread_lister);

   pthread_t extra_pthread_id;
   pid_t extra_tid;
   SpawnTidReporter(&extra_pthread_id, &extra_tid);
   // Register the new thread so it gets terminated in TearDown().
   pthread_ids_.push_back(extra_pthread_id);

   // It would be very bizarre if the new TID had been listed before we even
   // spawned that thread, but it would also cause a false success in this test,
   // so better check for that.
   ASSERT_FALSE(HasElement(threads_before_extra, extra_tid));

   thread_lister.Reset();

   std::vector<pid_t> threads_after_extra = ReadTidsToVector(&thread_lister);
   ASSERT_TRUE(HasElement(threads_after_extra, extra_tid));
 }

 TEST(SanitizerCommon, SetEnvTest) {
   const char kEnvName[] = "ENV_FOO";
   SetEnv(kEnvName, "value");
   EXPECT_STREQ("value", getenv(kEnvName));
   unsetenv(kEnvName);
   EXPECT_EQ(0, getenv(kEnvName));
 }

 #if (defined(__x86_64__) || defined(__i386__)) && !SANITIZER_ANDROID
 void *thread_self_offset_test_func(void *arg) {
   bool result =
       *(uptr *)((char *)ThreadSelf() + ThreadSelfOffset()) == ThreadSelf();
   return (void *)result;
 }

 TEST(SanitizerLinux, ThreadSelfOffset) {
   EXPECT_TRUE((bool)thread_self_offset_test_func(0));
   pthread_t tid;
   void *result;
   ASSERT_EQ(0, pthread_create(&tid, 0, thread_self_offset_test_func, 0));
   ASSERT_EQ(0, pthread_join(tid, &result));
   EXPECT_TRUE((bool)result);
 }

 // libpthread puts the thread descriptor at the end of stack space.
 void *thread_descriptor_size_test_func(void *arg) {
   uptr descr_addr = ThreadSelf();
   pthread_attr_t attr;
   pthread_getattr_np(pthread_self(), &attr);
   void *stackaddr;
   size_t stacksize;
   pthread_attr_getstack(&attr, &stackaddr, &stacksize);
   return (void *)((uptr)stackaddr + stacksize - descr_addr);
 }

 TEST(SanitizerLinux, ThreadDescriptorSize) {
   pthread_t tid;
   void *result;
   ASSERT_EQ(0, pthread_create(&tid, 0, thread_descriptor_size_test_func, 0));
   ASSERT_EQ(0, pthread_join(tid, &result));
   EXPECT_EQ((uptr)result, ThreadDescriptorSize());
 }
 #endif

 TEST(SanitizerCommon, LibraryNameIs) {
   EXPECT_FALSE(LibraryNameIs("", ""));

   char full_name[256];
   const char *paths[] = { "", "/", "/path/to/" };
   const char *suffixes[] = { "", "-linux", ".1.2", "-linux.1.2" };
   const char *base_names[] = { "lib", "lib.0", "lib-i386" };
   const char *wrong_names[] = { "", "lib.9", "lib-x86_64" };
   for (uptr i = 0; i < ARRAY_SIZE(paths); i++)
     for (uptr j = 0; j < ARRAY_SIZE(suffixes); j++) {
       for (uptr k = 0; k < ARRAY_SIZE(base_names); k++) {
         internal_snprintf(full_name, ARRAY_SIZE(full_name), "%s%s%s.so",
                           paths[i], base_names[k], suffixes[j]);
         EXPECT_TRUE(LibraryNameIs(full_name, base_names[k]))
             << "Full name " << full_name
             << " doesn't match base name " << base_names[k];
         for (uptr m = 0; m < ARRAY_SIZE(wrong_names); m++)
           EXPECT_FALSE(LibraryNameIs(full_name, wrong_names[m]))
             << "Full name " << full_name
             << " matches base name " << wrong_names[m];
       }
     }
 }

 #if defined(__mips64)
 // Effectively, this is a test for ThreadDescriptorSize() which is used to
 // compute ThreadSelf().
 TEST(SanitizerLinux, ThreadSelfTest) {
   ASSERT_EQ(pthread_self(), ThreadSelf());
 }
 #endif

 }  // namespace __sanitizer

 #endif  // SANITIZER_LINUX
	//===-- sanitizer_linux_test.cc -------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// Tests for sanitizer_linux.h
	//
	//===----------------------------------------------------------------------===//

	#include "sanitizer_common/sanitizer_platform.h"
	#if SANITIZER_LINUX

	#include "sanitizer_common/sanitizer_linux.h"

	#include "sanitizer_common/sanitizer_common.h"
	#include "gtest/gtest.h"

	#include <pthread.h>
	#include <sched.h>
	#include <stdlib.h>

	#include <algorithm>
	#include <vector>

	namespace __sanitizer {

	struct TidReporterArgument {
	TidReporterArgument() {
	pthread_mutex_init(&terminate_thread_mutex, NULL);
	pthread_mutex_init(&tid_reported_mutex, NULL);
	pthread_cond_init(&terminate_thread_cond, NULL);
	pthread_cond_init(&tid_reported_cond, NULL);
	terminate_thread = false;
	}

	~TidReporterArgument() {
	pthread_mutex_destroy(&terminate_thread_mutex);
	pthread_mutex_destroy(&tid_reported_mutex);
	pthread_cond_destroy(&terminate_thread_cond);
	pthread_cond_destroy(&tid_reported_cond);
	}

	pid_t reported_tid;
	// For signaling to spawned threads that they should terminate.
	pthread_cond_t terminate_thread_cond;
	pthread_mutex_t terminate_thread_mutex;
	bool terminate_thread;
	// For signaling to main thread that a child thread has reported its tid.
	pthread_cond_t tid_reported_cond;
	pthread_mutex_t tid_reported_mutex;

	private:
	// Disallow evil constructors
	TidReporterArgument(const TidReporterArgument &);
	void operator=(const TidReporterArgument &);
	};

	class ThreadListerTest : public ::testing::Test {
	protected:
	virtual void SetUp() {
	pthread_t pthread_id;
	pid_t tid;
	for (uptr i = 0; i < kThreadCount; i++) {
	SpawnTidReporter(&pthread_id, &tid);
	pthread_ids_.push_back(pthread_id);
	tids_.push_back(tid);
	}
	}

	virtual void TearDown() {
	pthread_mutex_lock(&thread_arg.terminate_thread_mutex);
	thread_arg.terminate_thread = true;
	pthread_cond_broadcast(&thread_arg.terminate_thread_cond);
	pthread_mutex_unlock(&thread_arg.terminate_thread_mutex);
	for (uptr i = 0; i < pthread_ids_.size(); i++)
	pthread_join(pthread_ids_[i], NULL);
	}

	void SpawnTidReporter(pthread_t pthread_id, pid_t tid);

	static const uptr kThreadCount = 20;

	std::vector<pthread_t> pthread_ids_;
	std::vector<pid_t> tids_;

	TidReporterArgument thread_arg;
	};

	// Writes its TID once to reported_tid and waits until signaled to terminate.
	void TidReporterThread(void argument) {
	TidReporterArgument arg = reinterpret_cast<TidReporterArgument >(argument);
	pthread_mutex_lock(&arg->tid_reported_mutex);
	arg->reported_tid = GetTid();
	pthread_cond_broadcast(&arg->tid_reported_cond);
	pthread_mutex_unlock(&arg->tid_reported_mutex);

	pthread_mutex_lock(&arg->terminate_thread_mutex);
	while (!arg->terminate_thread)
	pthread_cond_wait(&arg->terminate_thread_cond,
	&arg->terminate_thread_mutex);
	pthread_mutex_unlock(&arg->terminate_thread_mutex);
	return NULL;
	}

	void ThreadListerTest::SpawnTidReporter(pthread_t *pthread_id,
	pid_t *tid) {
	pthread_mutex_lock(&thread_arg.tid_reported_mutex);
	thread_arg.reported_tid = -1;
	ASSERT_EQ(0, pthread_create(pthread_id, NULL,
	TidReporterThread,
	&thread_arg));
	while (thread_arg.reported_tid == -1)
	pthread_cond_wait(&thread_arg.tid_reported_cond,
	&thread_arg.tid_reported_mutex);
	pthread_mutex_unlock(&thread_arg.tid_reported_mutex);
	*tid = thread_arg.reported_tid;
	}

	static std::vector<pid_t> ReadTidsToVector(ThreadLister *thread_lister) {
	std::vector<pid_t> listed_tids;
	pid_t tid;
	while ((tid = thread_lister->GetNextTID()) >= 0)
	listed_tids.push_back(tid);
	EXPECT_FALSE(thread_lister->error());
	return listed_tids;
	}

	static bool Includes(std::vector<pid_t> first, std::vector<pid_t> second) {
	std::sort(first.begin(), first.end());
	std::sort(second.begin(), second.end());
	return std::includes(first.begin(), first.end(),
	second.begin(), second.end());
	}

	static bool HasElement(std::vector<pid_t> vector, pid_t element) {
	return std::find(vector.begin(), vector.end(), element) != vector.end();
	}

	// ThreadLister's output should include the current thread's TID and the TID of
	// every thread we spawned.
	TEST_F(ThreadListerTest, ThreadListerSeesAllSpawnedThreads) {
	pid_t self_tid = GetTid();
	ThreadLister thread_lister(getpid());
	std::vector<pid_t> listed_tids = ReadTidsToVector(&thread_lister);
	ASSERT_TRUE(HasElement(listed_tids, self_tid));
	ASSERT_TRUE(Includes(listed_tids, tids_));
	}

	// Calling Reset() should not cause ThreadLister to forget any threads it's
	// supposed to know about.
	TEST_F(ThreadListerTest, ResetDoesNotForgetThreads) {
	ThreadLister thread_lister(getpid());

	// Run the loop body twice, because Reset() might behave differently if called
	// on a freshly created object.
	for (uptr i = 0; i < 2; i++) {
	thread_lister.Reset();
	std::vector<pid_t> listed_tids = ReadTidsToVector(&thread_lister);
	ASSERT_TRUE(Includes(listed_tids, tids_));
	}
	}

	// If new threads have spawned during ThreadLister object's lifetime, calling
	// Reset() should cause ThreadLister to recognize their existence.
	TEST_F(ThreadListerTest, ResetMakesNewThreadsKnown) {
	ThreadLister thread_lister(getpid());
	std::vector<pid_t> threads_before_extra = ReadTidsToVector(&thread_lister);

	pthread_t extra_pthread_id;
	pid_t extra_tid;
	SpawnTidReporter(&extra_pthread_id, &extra_tid);
	// Register the new thread so it gets terminated in TearDown().
	pthread_ids_.push_back(extra_pthread_id);

	// It would be very bizarre if the new TID had been listed before we even
	// spawned that thread, but it would also cause a false success in this test,
	// so better check for that.
	ASSERT_FALSE(HasElement(threads_before_extra, extra_tid));

	thread_lister.Reset();

	std::vector<pid_t> threads_after_extra = ReadTidsToVector(&thread_lister);
	ASSERT_TRUE(HasElement(threads_after_extra, extra_tid));
	}

	TEST(SanitizerCommon, SetEnvTest) {
	const char kEnvName[] = "ENV_FOO";
	SetEnv(kEnvName, "value");
	EXPECT_STREQ("value", getenv(kEnvName));
	unsetenv(kEnvName);
	EXPECT_EQ(0, getenv(kEnvName));
	}

	#if (defined(__x86_64__) \|\| defined(__i386__)) && !SANITIZER_ANDROID
	void thread_self_offset_test_func(void arg) {
	bool result =
	(uptr )((char *)ThreadSelf() + ThreadSelfOffset()) == ThreadSelf();
	return (void *)result;
	}

	TEST(SanitizerLinux, ThreadSelfOffset) {
	EXPECT_TRUE((bool)thread_self_offset_test_func(0));
	pthread_t tid;
	void *result;
	ASSERT_EQ(0, pthread_create(&tid, 0, thread_self_offset_test_func, 0));
	ASSERT_EQ(0, pthread_join(tid, &result));
	EXPECT_TRUE((bool)result);
	}

	// libpthread puts the thread descriptor at the end of stack space.
	void thread_descriptor_size_test_func(void arg) {
	uptr descr_addr = ThreadSelf();
	pthread_attr_t attr;
	pthread_getattr_np(pthread_self(), &attr);
	void *stackaddr;
	size_t stacksize;
	pthread_attr_getstack(&attr, &stackaddr, &stacksize);
	return (void *)((uptr)stackaddr + stacksize - descr_addr);
	}

	TEST(SanitizerLinux, ThreadDescriptorSize) {
	pthread_t tid;
	void *result;
	ASSERT_EQ(0, pthread_create(&tid, 0, thread_descriptor_size_test_func, 0));
	ASSERT_EQ(0, pthread_join(tid, &result));
	EXPECT_EQ((uptr)result, ThreadDescriptorSize());
	}
	#endif

	TEST(SanitizerCommon, LibraryNameIs) {
	EXPECT_FALSE(LibraryNameIs("", ""));

	char full_name[256];
	const char *paths[] = { "", "/", "/path/to/" };
	const char *suffixes[] = { "", "-linux", ".1.2", "-linux.1.2" };
	const char *base_names[] = { "lib", "lib.0", "lib-i386" };
	const char *wrong_names[] = { "", "lib.9", "lib-x86_64" };
	for (uptr i = 0; i < ARRAY_SIZE(paths); i++)
	for (uptr j = 0; j < ARRAY_SIZE(suffixes); j++) {
	for (uptr k = 0; k < ARRAY_SIZE(base_names); k++) {
	internal_snprintf(full_name, ARRAY_SIZE(full_name), "%s%s%s.so",
	paths[i], base_names[k], suffixes[j]);
	EXPECT_TRUE(LibraryNameIs(full_name, base_names[k]))
	<< "Full name " << full_name
	<< " doesn't match base name " << base_names[k];
	for (uptr m = 0; m < ARRAY_SIZE(wrong_names); m++)
	EXPECT_FALSE(LibraryNameIs(full_name, wrong_names[m]))
	<< "Full name " << full_name
	<< " matches base name " << wrong_names[m];
	}
	}
	}

	#if defined(__mips64)
	// Effectively, this is a test for ThreadDescriptorSize() which is used to
	// compute ThreadSelf().
	TEST(SanitizerLinux, ThreadSelfTest) {
	ASSERT_EQ(pthread_self(), ThreadSelf());
	}
	#endif

	} // namespace __sanitizer

	#endif // SANITIZER_LINUX