tests/threads_test.cpp - platform/bionic - Git at Google

 /*
  * Copyright (C) 2019 The Android Open Source Project
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  *  * Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  *  * Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in
  *    the documentation and/or other materials provided with the
  *    distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
  * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
  * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
  * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
  * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
  * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
  * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
  * SUCH DAMAGE.
  */

 #include <gtest/gtest.h>

 #if __has_include(<threads.h>)

 #define HAVE_THREADS_H
 #include <threads.h>

 static int g_call_once_call_count;

 static void increment_call_count() {
   ++g_call_once_call_count;
 }

 static int g_dtor_call_count;

 static void tss_dtor(void* ptr) {
   ++g_dtor_call_count;
   free(ptr);
 }

 static int return_arg(void* arg) {
   return static_cast<int>(reinterpret_cast<uintptr_t>(arg));
 }

 static int exit_arg(void* arg) {
   thrd_exit(static_cast<int>(reinterpret_cast<uintptr_t>(arg)));
 }

 #endif

 #include <time.h>

 #include <thread>

 #include "BionicDeathTest.h"
 #include "SignalUtils.h"

 TEST(threads, call_once) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   once_flag flag = ONCE_FLAG_INIT;
   call_once(&flag, increment_call_count);
   call_once(&flag, increment_call_count);
   std::thread([&flag] {
     call_once(&flag, increment_call_count);
   }).join();
   ASSERT_EQ(1, g_call_once_call_count);
 #endif
 }

 TEST(threads, cnd_broadcast__cnd_wait) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));

   cnd_t c;
   ASSERT_EQ(thrd_success, cnd_init(&c));

   std::atomic_int i = 0;

   auto waiter = [&c, &i, &m] {
     ASSERT_EQ(thrd_success, mtx_lock(&m));
     while (i != 1) ASSERT_EQ(thrd_success, cnd_wait(&c, &m));
     ASSERT_EQ(thrd_success, mtx_unlock(&m));
   };
   std::thread t1(waiter);
   std::thread t2(waiter);
   std::thread t3(waiter);

   ASSERT_EQ(thrd_success, mtx_lock(&m));
   i = 1;
   ASSERT_EQ(thrd_success, mtx_unlock(&m));

   ASSERT_EQ(thrd_success, cnd_broadcast(&c));

   t1.join();
   t2.join();
   t3.join();

   mtx_destroy(&m);
   cnd_destroy(&c);
 #endif
 }

 TEST(threads, cnd_init__cnd_destroy) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   cnd_t c;
   ASSERT_EQ(thrd_success, cnd_init(&c));
   cnd_destroy(&c);
 #endif
 }

 TEST(threads, cnd_signal__cnd_wait) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));
   cnd_t c;
   ASSERT_EQ(thrd_success, cnd_init(&c));

   std::atomic_int count = 0;
   auto waiter = [&c, &m, &count] {
     ASSERT_EQ(thrd_success, mtx_lock(&m));
     ASSERT_EQ(thrd_success, cnd_wait(&c, &m));
     ASSERT_EQ(thrd_success, mtx_unlock(&m));
     ++count;
   };
   std::thread t1(waiter);
   std::thread t2(waiter);
   std::thread t3(waiter);

   // This is inherently racy, but attempts to distinguish between cnd_signal and
   // cnd_broadcast.
   usleep(100000);
   ASSERT_EQ(thrd_success, cnd_signal(&c));
   while (count == 0) {
   }
   usleep(100000);
   ASSERT_EQ(1, count);

   ASSERT_EQ(thrd_success, cnd_signal(&c));
   while (count == 1) {
   }
   usleep(100000);
   ASSERT_EQ(2, count);

   ASSERT_EQ(thrd_success, cnd_signal(&c));
   while (count == 2) {
   }
   usleep(100000);
   ASSERT_EQ(3, count);

   t1.join();
   t2.join();
   t3.join();

   mtx_destroy(&m);
   cnd_destroy(&c);
 #endif
 }

 TEST(threads, cnd_timedwait_timedout) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed));
   ASSERT_EQ(thrd_success, mtx_lock(&m));

   cnd_t c;
   ASSERT_EQ(thrd_success, cnd_init(&c));

   timespec ts = {};
   ASSERT_EQ(thrd_timedout, cnd_timedwait(&c, &m, &ts));
 #endif
 }

 TEST(threads, cnd_timedwait) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed));

   cnd_t c;
   ASSERT_EQ(thrd_success, cnd_init(&c));

   std::atomic_bool done = false;
   std::thread t([&c, &m, &done] {
     ASSERT_EQ(thrd_success, mtx_lock(&m));

     // cnd_timewait's time is *absolute*.
     timespec ts;
     ASSERT_EQ(TIME_UTC, timespec_get(&ts, TIME_UTC));
     ts.tv_sec += 666;

     ASSERT_EQ(thrd_success, cnd_timedwait(&c, &m, &ts));
     done = true;
     ASSERT_EQ(thrd_success, mtx_unlock(&m));
   });

   while (!done) ASSERT_EQ(thrd_success, cnd_signal(&c));

   t.join();
 #endif
 }

 TEST(threads, mtx_init) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed));
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain | mtx_recursive));
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed | mtx_recursive));
   ASSERT_EQ(thrd_error, mtx_init(&m, 123));
   ASSERT_EQ(thrd_error, mtx_init(&m, mtx_recursive));
 #endif
 }

 TEST(threads, mtx_destroy) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));
   mtx_destroy(&m);
 #endif
 }

 TEST(threads, mtx_lock_plain) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));

   ASSERT_EQ(thrd_success, mtx_lock(&m));
   ASSERT_EQ(thrd_busy, mtx_trylock(&m));
   ASSERT_EQ(thrd_success, mtx_unlock(&m));

   mtx_destroy(&m);
 #endif
 }

 TEST(threads, mtx_lock_recursive) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain | mtx_recursive));

   ASSERT_EQ(thrd_success, mtx_lock(&m));
   ASSERT_EQ(thrd_success, mtx_trylock(&m));
   ASSERT_EQ(thrd_success, mtx_unlock(&m));
   ASSERT_EQ(thrd_success, mtx_unlock(&m));

   mtx_destroy(&m);
 #endif
 }

 TEST(threads, mtx_timedlock) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed));

   timespec ts = {};
   ASSERT_EQ(thrd_success, mtx_timedlock(&m, &ts));

   std::thread([&m] {
     timespec ts = { .tv_nsec = 500000 };
     ASSERT_EQ(thrd_timedout, mtx_timedlock(&m, &ts));
   }).join();

   ASSERT_EQ(thrd_success, mtx_unlock(&m));
   mtx_destroy(&m);
 #endif
 }


 TEST(threads, mtx_unlock) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   mtx_t m;
   ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));
   ASSERT_EQ(thrd_success, mtx_lock(&m));
   std::thread([&m] {
     ASSERT_EQ(thrd_busy, mtx_trylock(&m));
   }).join();
   ASSERT_EQ(thrd_success, mtx_unlock(&m));
   std::thread([&m] {
     ASSERT_EQ(thrd_success, mtx_trylock(&m));
   }).join();
 #endif
 }

 TEST(threads, thrd_current__thrd_equal) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   thrd_t t1 = thrd_current();
   // (As a side-effect, this demonstrates interoperability with std::thread.)
   std::thread([&t1] {
     thrd_t t2 = thrd_current();
     ASSERT_FALSE(thrd_equal(t1, t2));
     thrd_t t2_2 = thrd_current();
     ASSERT_TRUE(thrd_equal(t2, t2_2));
   }).join();
   thrd_t t1_2 = thrd_current();
   ASSERT_TRUE(thrd_equal(t1, t1_2));
 #endif
 }

 TEST(threads, thrd_create__thrd_detach) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   thrd_t t;
   ASSERT_EQ(thrd_success, thrd_create(&t, exit_arg, reinterpret_cast<void*>(1)));
   ASSERT_EQ(thrd_success, thrd_detach(t));
 #endif
 }

 TEST(threads, thrd_create__thrd_exit) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   // Similar to the thrd_join test, but with a function that calls thrd_exit
   // instead.
   thrd_t t;
   int result;
   ASSERT_EQ(thrd_success, thrd_create(&t, exit_arg, reinterpret_cast<void*>(1)));
   ASSERT_EQ(thrd_success, thrd_join(t, &result));
   ASSERT_EQ(1, result);

   ASSERT_EQ(thrd_success, thrd_create(&t, exit_arg, reinterpret_cast<void*>(2)));
   ASSERT_EQ(thrd_success, thrd_join(t, &result));
   ASSERT_EQ(2, result);

   // The `result` argument can be null if you don't care...
   ASSERT_EQ(thrd_success, thrd_create(&t, exit_arg, reinterpret_cast<void*>(3)));
   ASSERT_EQ(thrd_success, thrd_join(t, nullptr));
 #endif
 }

 class threads_DeathTest : public BionicDeathTest {};

 TEST(threads_DeathTest, thrd_exit_main_thread) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   // "The program terminates normally after the last thread has been terminated.
   // The behavior is as if the program called the exit function with the status
   // EXIT_SUCCESS at thread termination time." (ISO/IEC 9899:2018)
   ASSERT_EXIT(thrd_exit(12), ::testing::ExitedWithCode(EXIT_SUCCESS), "");
 #endif
 }

 TEST(threads, thrd_create__thrd_join) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   // Similar to the thrd_exit test, but with a function that calls return
   // instead.
   thrd_t t;
   int result;
   ASSERT_EQ(thrd_success, thrd_create(&t, return_arg, reinterpret_cast<void*>(1)));
   ASSERT_EQ(thrd_success, thrd_join(t, &result));
   ASSERT_EQ(1, result);

   ASSERT_EQ(thrd_success, thrd_create(&t, return_arg, reinterpret_cast<void*>(2)));
   ASSERT_EQ(thrd_success, thrd_join(t, &result));
   ASSERT_EQ(2, result);

   // The `result` argument can be null if you don't care...
   ASSERT_EQ(thrd_success, thrd_create(&t, return_arg, reinterpret_cast<void*>(3)));
   ASSERT_EQ(thrd_success, thrd_join(t, nullptr));
 #endif
 }

 TEST(threads, thrd_sleep_signal) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   ScopedSignalHandler ssh{SIGALRM, [](int) {}};
   std::thread t([] {
     timespec long_time = { .tv_sec = 666 };
     timespec remaining = {};
     ASSERT_EQ(-1, thrd_sleep(&long_time, &remaining));
     uint64_t t = remaining.tv_sec * 1000000000 + remaining.tv_nsec;
     ASSERT_LE(t, 666ULL * 1000000000);
   });
   usleep(100000); // 0.1s
   pthread_kill(t.native_handle(), SIGALRM);
   t.join();
 #endif
 }

 TEST(threads, thrd_sleep_signal_nullptr) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   ScopedSignalHandler ssh{SIGALRM, [](int) {}};
   std::thread t([] {
     timespec long_time = { .tv_sec = 666 };
     ASSERT_EQ(-1, thrd_sleep(&long_time, nullptr));
   });
   usleep(100000); // 0.1s
   pthread_kill(t.native_handle(), SIGALRM);
   t.join();
 #endif
 }

 TEST(threads, thrd_sleep_error) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   timespec invalid = { .tv_sec = -1 };
   ASSERT_EQ(-2, thrd_sleep(&invalid, nullptr));
 #endif
 }

 TEST(threads, thrd_yield) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   thrd_yield();
 #endif
 }

 TEST(threads, TSS_DTOR_ITERATIONS_macro) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   ASSERT_EQ(PTHREAD_DESTRUCTOR_ITERATIONS, TSS_DTOR_ITERATIONS);
 #endif
 }

 TEST(threads, tss_create) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   tss_t key;
   ASSERT_EQ(thrd_success, tss_create(&key, nullptr));
   tss_delete(key);
 #endif
 }

 TEST(threads, tss_create_dtor) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   tss_dtor_t dtor = tss_dtor;
   tss_t key;
   ASSERT_EQ(thrd_success, tss_create(&key, dtor));

   ASSERT_EQ(thrd_success, tss_set(key, strdup("hello")));
   std::thread([&key] {
     ASSERT_EQ(thrd_success, tss_set(key, strdup("world")));
   }).join();
   // Thread exit calls the destructor...
   ASSERT_EQ(1, g_dtor_call_count);

   // "[A call to tss_set] will not invoke the destructor associated with the
   // key on the value being replaced" (ISO/IEC 9899:2018).
   g_dtor_call_count = 0;
   ASSERT_EQ(thrd_success, tss_set(key, strdup("hello")));
   ASSERT_EQ(0, g_dtor_call_count);

   // "Calling tss_delete will not result in the invocation of any
   // destructors" (ISO/IEC 9899:2018).
   // The destructor for "hello" won't be called until *this* thread exits.
   g_dtor_call_count = 0;
   tss_delete(key);
   ASSERT_EQ(0, g_dtor_call_count);
 #endif
 }

 TEST(threads, tss_get__tss_set) {
 #if !defined(HAVE_THREADS_H)
   GTEST_SKIP() << "<threads.h> unavailable";
 #else
   tss_t key;
   ASSERT_EQ(thrd_success, tss_create(&key, nullptr));

   ASSERT_EQ(thrd_success, tss_set(key, const_cast<char*>("hello")));
   ASSERT_STREQ("hello", reinterpret_cast<char*>(tss_get(key)));
   std::thread([&key] {
       ASSERT_EQ(nullptr, tss_get(key));
       ASSERT_EQ(thrd_success, tss_set(key, const_cast<char*>("world")));
       ASSERT_STREQ("world", reinterpret_cast<char*>(tss_get(key)));
   }).join();
   ASSERT_STREQ("hello", reinterpret_cast<char*>(tss_get(key)));

   tss_delete(key);
 #endif
 }
	/*
	* Copyright (C) 2019 The Android Open Source Project
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* * Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in
	* the documentation and/or other materials provided with the
	* distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
	* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
	* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
	* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
	* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
	* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
	* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
	* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
	* SUCH DAMAGE.
	*/

	#include <gtest/gtest.h>

	#if __has_include(<threads.h>)

	#define HAVE_THREADS_H
	#include <threads.h>

	static int g_call_once_call_count;

	static void increment_call_count() {
	++g_call_once_call_count;
	}

	static int g_dtor_call_count;

	static void tss_dtor(void* ptr) {
	++g_dtor_call_count;
	free(ptr);
	}

	static int return_arg(void* arg) {
	return static_cast<int>(reinterpret_cast<uintptr_t>(arg));
	}

	static int exit_arg(void* arg) {
	thrd_exit(static_cast<int>(reinterpret_cast<uintptr_t>(arg)));
	}

	#endif

	#include <time.h>

	#include <thread>

	#include "BionicDeathTest.h"
	#include "SignalUtils.h"

	TEST(threads, call_once) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	once_flag flag = ONCE_FLAG_INIT;
	call_once(&flag, increment_call_count);
	call_once(&flag, increment_call_count);
	std::thread([&flag] {
	call_once(&flag, increment_call_count);
	}).join();
	ASSERT_EQ(1, g_call_once_call_count);
	#endif
	}

	TEST(threads, cnd_broadcast__cnd_wait) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));

	cnd_t c;
	ASSERT_EQ(thrd_success, cnd_init(&c));

	std::atomic_int i = 0;

	auto waiter = [&c, &i, &m] {
	ASSERT_EQ(thrd_success, mtx_lock(&m));
	while (i != 1) ASSERT_EQ(thrd_success, cnd_wait(&c, &m));
	ASSERT_EQ(thrd_success, mtx_unlock(&m));
	};
	std::thread t1(waiter);
	std::thread t2(waiter);
	std::thread t3(waiter);

	ASSERT_EQ(thrd_success, mtx_lock(&m));
	i = 1;
	ASSERT_EQ(thrd_success, mtx_unlock(&m));

	ASSERT_EQ(thrd_success, cnd_broadcast(&c));

	t1.join();
	t2.join();
	t3.join();

	mtx_destroy(&m);
	cnd_destroy(&c);
	#endif
	}

	TEST(threads, cnd_init__cnd_destroy) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	cnd_t c;
	ASSERT_EQ(thrd_success, cnd_init(&c));
	cnd_destroy(&c);
	#endif
	}

	TEST(threads, cnd_signal__cnd_wait) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));
	cnd_t c;
	ASSERT_EQ(thrd_success, cnd_init(&c));

	std::atomic_int count = 0;
	auto waiter = [&c, &m, &count] {
	ASSERT_EQ(thrd_success, mtx_lock(&m));
	ASSERT_EQ(thrd_success, cnd_wait(&c, &m));
	ASSERT_EQ(thrd_success, mtx_unlock(&m));
	++count;
	};
	std::thread t1(waiter);
	std::thread t2(waiter);
	std::thread t3(waiter);

	// This is inherently racy, but attempts to distinguish between cnd_signal and
	// cnd_broadcast.
	usleep(100000);
	ASSERT_EQ(thrd_success, cnd_signal(&c));
	while (count == 0) {
	}
	usleep(100000);
	ASSERT_EQ(1, count);

	ASSERT_EQ(thrd_success, cnd_signal(&c));
	while (count == 1) {
	}
	usleep(100000);
	ASSERT_EQ(2, count);

	ASSERT_EQ(thrd_success, cnd_signal(&c));
	while (count == 2) {
	}
	usleep(100000);
	ASSERT_EQ(3, count);

	t1.join();
	t2.join();
	t3.join();

	mtx_destroy(&m);
	cnd_destroy(&c);
	#endif
	}

	TEST(threads, cnd_timedwait_timedout) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed));
	ASSERT_EQ(thrd_success, mtx_lock(&m));

	cnd_t c;
	ASSERT_EQ(thrd_success, cnd_init(&c));

	timespec ts = {};
	ASSERT_EQ(thrd_timedout, cnd_timedwait(&c, &m, &ts));
	#endif
	}

	TEST(threads, cnd_timedwait) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed));

	cnd_t c;
	ASSERT_EQ(thrd_success, cnd_init(&c));

	std::atomic_bool done = false;
	std::thread t([&c, &m, &done] {
	ASSERT_EQ(thrd_success, mtx_lock(&m));

	// cnd_timewait's time is absolute.
	timespec ts;
	ASSERT_EQ(TIME_UTC, timespec_get(&ts, TIME_UTC));
	ts.tv_sec += 666;

	ASSERT_EQ(thrd_success, cnd_timedwait(&c, &m, &ts));
	done = true;
	ASSERT_EQ(thrd_success, mtx_unlock(&m));
	});

	while (!done) ASSERT_EQ(thrd_success, cnd_signal(&c));

	t.join();
	#endif
	}

	TEST(threads, mtx_init) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed));
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain \| mtx_recursive));
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed \| mtx_recursive));
	ASSERT_EQ(thrd_error, mtx_init(&m, 123));
	ASSERT_EQ(thrd_error, mtx_init(&m, mtx_recursive));
	#endif
	}

	TEST(threads, mtx_destroy) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));
	mtx_destroy(&m);
	#endif
	}

	TEST(threads, mtx_lock_plain) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));

	ASSERT_EQ(thrd_success, mtx_lock(&m));
	ASSERT_EQ(thrd_busy, mtx_trylock(&m));
	ASSERT_EQ(thrd_success, mtx_unlock(&m));

	mtx_destroy(&m);
	#endif
	}

	TEST(threads, mtx_lock_recursive) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain \| mtx_recursive));

	ASSERT_EQ(thrd_success, mtx_lock(&m));
	ASSERT_EQ(thrd_success, mtx_trylock(&m));
	ASSERT_EQ(thrd_success, mtx_unlock(&m));
	ASSERT_EQ(thrd_success, mtx_unlock(&m));

	mtx_destroy(&m);
	#endif
	}

	TEST(threads, mtx_timedlock) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_timed));

	timespec ts = {};
	ASSERT_EQ(thrd_success, mtx_timedlock(&m, &ts));

	std::thread([&m] {
	timespec ts = { .tv_nsec = 500000 };
	ASSERT_EQ(thrd_timedout, mtx_timedlock(&m, &ts));
	}).join();

	ASSERT_EQ(thrd_success, mtx_unlock(&m));
	mtx_destroy(&m);
	#endif
	}


	TEST(threads, mtx_unlock) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	mtx_t m;
	ASSERT_EQ(thrd_success, mtx_init(&m, mtx_plain));
	ASSERT_EQ(thrd_success, mtx_lock(&m));
	std::thread([&m] {
	ASSERT_EQ(thrd_busy, mtx_trylock(&m));
	}).join();
	ASSERT_EQ(thrd_success, mtx_unlock(&m));
	std::thread([&m] {
	ASSERT_EQ(thrd_success, mtx_trylock(&m));
	}).join();
	#endif
	}

	TEST(threads, thrd_current__thrd_equal) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	thrd_t t1 = thrd_current();
	// (As a side-effect, this demonstrates interoperability with std::thread.)
	std::thread([&t1] {
	thrd_t t2 = thrd_current();
	ASSERT_FALSE(thrd_equal(t1, t2));
	thrd_t t2_2 = thrd_current();
	ASSERT_TRUE(thrd_equal(t2, t2_2));
	}).join();
	thrd_t t1_2 = thrd_current();
	ASSERT_TRUE(thrd_equal(t1, t1_2));
	#endif
	}

	TEST(threads, thrd_create__thrd_detach) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	thrd_t t;
	ASSERT_EQ(thrd_success, thrd_create(&t, exit_arg, reinterpret_cast<void*>(1)));
	ASSERT_EQ(thrd_success, thrd_detach(t));
	#endif
	}

	TEST(threads, thrd_create__thrd_exit) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	// Similar to the thrd_join test, but with a function that calls thrd_exit
	// instead.
	thrd_t t;
	int result;
	ASSERT_EQ(thrd_success, thrd_create(&t, exit_arg, reinterpret_cast<void*>(1)));
	ASSERT_EQ(thrd_success, thrd_join(t, &result));
	ASSERT_EQ(1, result);

	ASSERT_EQ(thrd_success, thrd_create(&t, exit_arg, reinterpret_cast<void*>(2)));
	ASSERT_EQ(thrd_success, thrd_join(t, &result));
	ASSERT_EQ(2, result);

	// The `result` argument can be null if you don't care...
	ASSERT_EQ(thrd_success, thrd_create(&t, exit_arg, reinterpret_cast<void*>(3)));
	ASSERT_EQ(thrd_success, thrd_join(t, nullptr));
	#endif
	}

	class threads_DeathTest : public BionicDeathTest {};

	TEST(threads_DeathTest, thrd_exit_main_thread) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	// "The program terminates normally after the last thread has been terminated.
	// The behavior is as if the program called the exit function with the status
	// EXIT_SUCCESS at thread termination time." (ISO/IEC 9899:2018)
	ASSERT_EXIT(thrd_exit(12), ::testing::ExitedWithCode(EXIT_SUCCESS), "");
	#endif
	}

	TEST(threads, thrd_create__thrd_join) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	// Similar to the thrd_exit test, but with a function that calls return
	// instead.
	thrd_t t;
	int result;
	ASSERT_EQ(thrd_success, thrd_create(&t, return_arg, reinterpret_cast<void*>(1)));
	ASSERT_EQ(thrd_success, thrd_join(t, &result));
	ASSERT_EQ(1, result);

	ASSERT_EQ(thrd_success, thrd_create(&t, return_arg, reinterpret_cast<void*>(2)));
	ASSERT_EQ(thrd_success, thrd_join(t, &result));
	ASSERT_EQ(2, result);

	// The `result` argument can be null if you don't care...
	ASSERT_EQ(thrd_success, thrd_create(&t, return_arg, reinterpret_cast<void*>(3)));
	ASSERT_EQ(thrd_success, thrd_join(t, nullptr));
	#endif
	}

	TEST(threads, thrd_sleep_signal) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	ScopedSignalHandler ssh{SIGALRM, [](int) {}};
	std::thread t([] {
	timespec long_time = { .tv_sec = 666 };
	timespec remaining = {};
	ASSERT_EQ(-1, thrd_sleep(&long_time, &remaining));
	uint64_t t = remaining.tv_sec * 1000000000 + remaining.tv_nsec;
	ASSERT_LE(t, 666ULL * 1000000000);
	});
	usleep(100000); // 0.1s
	pthread_kill(t.native_handle(), SIGALRM);
	t.join();
	#endif
	}

	TEST(threads, thrd_sleep_signal_nullptr) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	ScopedSignalHandler ssh{SIGALRM, [](int) {}};
	std::thread t([] {
	timespec long_time = { .tv_sec = 666 };
	ASSERT_EQ(-1, thrd_sleep(&long_time, nullptr));
	});
	usleep(100000); // 0.1s
	pthread_kill(t.native_handle(), SIGALRM);
	t.join();
	#endif
	}

	TEST(threads, thrd_sleep_error) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	timespec invalid = { .tv_sec = -1 };
	ASSERT_EQ(-2, thrd_sleep(&invalid, nullptr));
	#endif
	}

	TEST(threads, thrd_yield) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	thrd_yield();
	#endif
	}

	TEST(threads, TSS_DTOR_ITERATIONS_macro) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	ASSERT_EQ(PTHREAD_DESTRUCTOR_ITERATIONS, TSS_DTOR_ITERATIONS);
	#endif
	}

	TEST(threads, tss_create) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	tss_t key;
	ASSERT_EQ(thrd_success, tss_create(&key, nullptr));
	tss_delete(key);
	#endif
	}

	TEST(threads, tss_create_dtor) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	tss_dtor_t dtor = tss_dtor;
	tss_t key;
	ASSERT_EQ(thrd_success, tss_create(&key, dtor));

	ASSERT_EQ(thrd_success, tss_set(key, strdup("hello")));
	std::thread([&key] {
	ASSERT_EQ(thrd_success, tss_set(key, strdup("world")));
	}).join();
	// Thread exit calls the destructor...
	ASSERT_EQ(1, g_dtor_call_count);

	// "[A call to tss_set] will not invoke the destructor associated with the
	// key on the value being replaced" (ISO/IEC 9899:2018).
	g_dtor_call_count = 0;
	ASSERT_EQ(thrd_success, tss_set(key, strdup("hello")));
	ASSERT_EQ(0, g_dtor_call_count);

	// "Calling tss_delete will not result in the invocation of any
	// destructors" (ISO/IEC 9899:2018).
	// The destructor for "hello" won't be called until this thread exits.
	g_dtor_call_count = 0;
	tss_delete(key);
	ASSERT_EQ(0, g_dtor_call_count);
	#endif
	}

	TEST(threads, tss_get__tss_set) {
	#if !defined(HAVE_THREADS_H)
	GTEST_SKIP() << "<threads.h> unavailable";
	#else
	tss_t key;
	ASSERT_EQ(thrd_success, tss_create(&key, nullptr));

	ASSERT_EQ(thrd_success, tss_set(key, const_cast<char*>("hello")));
	ASSERT_STREQ("hello", reinterpret_cast<char*>(tss_get(key)));
	std::thread([&key] {
	ASSERT_EQ(nullptr, tss_get(key));
	ASSERT_EQ(thrd_success, tss_set(key, const_cast<char*>("world")));
	ASSERT_STREQ("world", reinterpret_cast<char*>(tss_get(key)));
	}).join();
	ASSERT_STREQ("hello", reinterpret_cast<char*>(tss_get(key)));

	tss_delete(key);
	#endif
	}