src/starboard/nplb/condition_variable_wait_timed_test.cc - cobalt - Git at Google

 // Copyright 2015 The Cobalt Authors. All Rights Reserved.
 //
 // 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 "starboard/common/condition_variable.h"
 #include "starboard/common/mutex.h"
 #include "starboard/nplb/thread_helpers.h"
 #include "starboard/thread.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace starboard {
 namespace nplb {
 namespace {

 // The SunnyDay, SunnyDayAutoInit, and SunnyDayNearMaxTime test cases directly
 // (performs checks in the test case) or indirectly (invokes DoSunnyDay() which
 // performs the checks) rely on timing constraints that are prone to failure,
 // such as ensuring an action happens within 10 milliseconds. This requirement
 // makes the tests flaky since none of these actions can be guaranteed to always
 // run within the specified time.

 void DoSunnyDay(TakeThenSignalContext* context, bool check_timeout) {
   SbThread thread =
       SbThreadCreate(0, kSbThreadNoPriority, kSbThreadNoAffinity, true, NULL,
                      TakeThenSignalEntryPoint, context);

   const SbTime kDelay = kSbTimeMillisecond * 10;
   // Allow two-millisecond-level precision.
   const SbTime kPrecision = kSbTimeMillisecond*2;

   // We know the thread hasn't signaled the condition variable yet, and won't
   // unless we tell it, so it should wait at least the whole delay time.
   if (check_timeout) {
     EXPECT_TRUE(SbMutexIsSuccess(SbMutexAcquire(&context->mutex)));
     SbTimeMonotonic start = SbTimeGetMonotonicNow();
     SbConditionVariableResult result = SbConditionVariableWaitTimed(
         &context->condition, &context->mutex, kDelay);
     EXPECT_EQ(kSbConditionVariableTimedOut, result);
     SbTimeMonotonic elapsed = SbTimeGetMonotonicNow() - start;
     EXPECT_LE(kDelay, elapsed + kPrecision);
     EXPECT_GT(kDelay * 2, elapsed - kPrecision);
     EXPECT_TRUE(SbMutexRelease(&context->mutex));
   }

   {
     EXPECT_TRUE(SbMutexIsSuccess(SbMutexAcquire(&context->mutex)));

     // Tell the thread to signal the condvar, which will cause it to attempt to
     // acquire the mutex we are holding.
     context->do_signal.Put();

     SbTimeMonotonic start = SbTimeGetMonotonicNow();

     // We release the mutex when we wait, allowing the thread to actually do the
     // signaling, and ensuring we are waiting before it signals.
     SbConditionVariableResult result = SbConditionVariableWaitTimed(
         &context->condition, &context->mutex, kDelay);
     EXPECT_EQ(kSbConditionVariableSignaled, result);

     // We should have waited only a very small amount of time.
     EXPECT_GT(kDelay, SbTimeGetMonotonicNow() - start);

     EXPECT_TRUE(SbMutexRelease(&context->mutex));
   }

   // Now we wait for the thread to exit.
   EXPECT_TRUE(SbThreadJoin(thread, NULL));
   EXPECT_TRUE(SbConditionVariableDestroy(&context->condition));
   EXPECT_TRUE(SbMutexDestroy(&context->mutex));
 }

 // Test marked as flaky because it calls DoSunnyDay().
 TEST(SbConditionVariableWaitTimedTest, FLAKY_SunnyDay) {
   TakeThenSignalContext context;
   context.delay_after_signal = 0;
   EXPECT_TRUE(SbMutexCreate(&context.mutex));
   EXPECT_TRUE(SbConditionVariableCreate(&context.condition, &context.mutex));
   DoSunnyDay(&context, true);
 }

 // Test marked as flaky because it calls DoSunnyDay().
 TEST(SbConditionVariableWaitTimedTest, FLAKY_SunnyDayAutoInit) {
   {
     TakeThenSignalContext context = {TestSemaphore(0), SB_MUTEX_INITIALIZER,
                                      SB_CONDITION_VARIABLE_INITIALIZER, 0};
     DoSunnyDay(&context, true);
   }

   // Without the initial timeout test, the two threads will be racing to
   // auto-init the mutex and condition variable. So we run several trials in
   // this mode, hoping to have the auto-initting contend in various ways.
   const int kTrials = 64;
   for (int i = 0; i < kTrials; ++i) {
     TakeThenSignalContext context = {TestSemaphore(0), SB_MUTEX_INITIALIZER,
                                      SB_CONDITION_VARIABLE_INITIALIZER, 0};
     DoSunnyDay(&context, false);
   }
 }

 // Test marked as flaky because it relies on timing sensitive execution similar
 // to DoSunnyDay().
 TEST(SbConditionVariableWaitTimedTest, FLAKY_SunnyDayNearMaxTime) {
   const SbTime kOtherDelay = kSbTimeMillisecond * 10;
   TakeThenSignalContext context = {TestSemaphore(0), SB_MUTEX_INITIALIZER,
                                    SB_CONDITION_VARIABLE_INITIALIZER,
                                    kOtherDelay};
   EXPECT_TRUE(SbMutexCreate(&context.mutex));
   EXPECT_TRUE(SbConditionVariableCreate(&context.condition, &context.mutex));
   SbThread thread =
       SbThreadCreate(0, kSbThreadNoPriority, kSbThreadNoAffinity, true, NULL,
                      TakeThenSignalEntryPoint, &context);

   // Try to wait until the end of time.
   const SbTime kDelay = kSbTimeMax;

   EXPECT_TRUE(SbMutexIsSuccess(SbMutexAcquire(&context.mutex)));

   // Tell the thread to signal the condvar, which will cause it to attempt to
   // acquire the mutex we are holding, after it waits for delay_after_signal.
   context.do_signal.Put();

   SbTimeMonotonic start = SbTimeGetMonotonicNow();

   // We release the mutex when we wait, allowing the thread to actually do the
   // signaling, and ensuring we are waiting before it signals.
   SbConditionVariableResult result =
       SbConditionVariableWaitTimed(&context.condition, &context.mutex, kDelay);
   EXPECT_EQ(kSbConditionVariableSignaled, result);

   // We should have waited at least the delay_after_signal amount, but not the
   // full delay.
   // Add some padding to tolerate slightly imprecise sleeps.
   EXPECT_LT(context.delay_after_signal, SbTimeGetMonotonicNow() - start +
                                             (context.delay_after_signal / 10));
   EXPECT_GT(kDelay, SbTimeGetMonotonicNow() - start);

   EXPECT_TRUE(SbMutexRelease(&context.mutex));

   // Now we wait for the thread to exit.
   EXPECT_TRUE(SbThreadJoin(thread, NULL));
   EXPECT_TRUE(SbConditionVariableDestroy(&context.condition));
   EXPECT_TRUE(SbMutexDestroy(&context.mutex));
 }

 TEST(SbConditionVariableWaitTimedTest, RainyDayNull) {
   SbConditionVariableResult result =
       SbConditionVariableWaitTimed(NULL, NULL, 0);
   EXPECT_EQ(kSbConditionVariableFailed, result);

   SbMutex mutex = SB_MUTEX_INITIALIZER;
   result = SbConditionVariableWaitTimed(NULL, &mutex, 0);
   EXPECT_EQ(kSbConditionVariableFailed, result);

   SbConditionVariable condition = SB_CONDITION_VARIABLE_INITIALIZER;
   result = SbConditionVariableWaitTimed(&condition, NULL, 0);
   EXPECT_EQ(kSbConditionVariableFailed, result);
 }

 }  // namespace
 }  // namespace nplb
 }  // namespace starboard
	// Copyright 2015 The Cobalt Authors. All Rights Reserved.
	//
	// 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 "starboard/common/condition_variable.h"
	#include "starboard/common/mutex.h"
	#include "starboard/nplb/thread_helpers.h"
	#include "starboard/thread.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace starboard {
	namespace nplb {
	namespace {

	// The SunnyDay, SunnyDayAutoInit, and SunnyDayNearMaxTime test cases directly
	// (performs checks in the test case) or indirectly (invokes DoSunnyDay() which
	// performs the checks) rely on timing constraints that are prone to failure,
	// such as ensuring an action happens within 10 milliseconds. This requirement
	// makes the tests flaky since none of these actions can be guaranteed to always
	// run within the specified time.

	void DoSunnyDay(TakeThenSignalContext* context, bool check_timeout) {
	SbThread thread =
	SbThreadCreate(0, kSbThreadNoPriority, kSbThreadNoAffinity, true, NULL,
	TakeThenSignalEntryPoint, context);

	const SbTime kDelay = kSbTimeMillisecond * 10;
	// Allow two-millisecond-level precision.
	const SbTime kPrecision = kSbTimeMillisecond*2;

	// We know the thread hasn't signaled the condition variable yet, and won't
	// unless we tell it, so it should wait at least the whole delay time.
	if (check_timeout) {
	EXPECT_TRUE(SbMutexIsSuccess(SbMutexAcquire(&context->mutex)));
	SbTimeMonotonic start = SbTimeGetMonotonicNow();
	SbConditionVariableResult result = SbConditionVariableWaitTimed(
	&context->condition, &context->mutex, kDelay);
	EXPECT_EQ(kSbConditionVariableTimedOut, result);
	SbTimeMonotonic elapsed = SbTimeGetMonotonicNow() - start;
	EXPECT_LE(kDelay, elapsed + kPrecision);
	EXPECT_GT(kDelay * 2, elapsed - kPrecision);
	EXPECT_TRUE(SbMutexRelease(&context->mutex));
	}

	{
	EXPECT_TRUE(SbMutexIsSuccess(SbMutexAcquire(&context->mutex)));

	// Tell the thread to signal the condvar, which will cause it to attempt to
	// acquire the mutex we are holding.
	context->do_signal.Put();

	SbTimeMonotonic start = SbTimeGetMonotonicNow();

	// We release the mutex when we wait, allowing the thread to actually do the
	// signaling, and ensuring we are waiting before it signals.
	SbConditionVariableResult result = SbConditionVariableWaitTimed(
	&context->condition, &context->mutex, kDelay);
	EXPECT_EQ(kSbConditionVariableSignaled, result);

	// We should have waited only a very small amount of time.
	EXPECT_GT(kDelay, SbTimeGetMonotonicNow() - start);

	EXPECT_TRUE(SbMutexRelease(&context->mutex));
	}

	// Now we wait for the thread to exit.
	EXPECT_TRUE(SbThreadJoin(thread, NULL));
	EXPECT_TRUE(SbConditionVariableDestroy(&context->condition));
	EXPECT_TRUE(SbMutexDestroy(&context->mutex));
	}

	// Test marked as flaky because it calls DoSunnyDay().
	TEST(SbConditionVariableWaitTimedTest, FLAKY_SunnyDay) {
	TakeThenSignalContext context;
	context.delay_after_signal = 0;
	EXPECT_TRUE(SbMutexCreate(&context.mutex));
	EXPECT_TRUE(SbConditionVariableCreate(&context.condition, &context.mutex));
	DoSunnyDay(&context, true);
	}

	// Test marked as flaky because it calls DoSunnyDay().
	TEST(SbConditionVariableWaitTimedTest, FLAKY_SunnyDayAutoInit) {
	{
	TakeThenSignalContext context = {TestSemaphore(0), SB_MUTEX_INITIALIZER,
	SB_CONDITION_VARIABLE_INITIALIZER, 0};
	DoSunnyDay(&context, true);
	}

	// Without the initial timeout test, the two threads will be racing to
	// auto-init the mutex and condition variable. So we run several trials in
	// this mode, hoping to have the auto-initting contend in various ways.
	const int kTrials = 64;
	for (int i = 0; i < kTrials; ++i) {
	TakeThenSignalContext context = {TestSemaphore(0), SB_MUTEX_INITIALIZER,
	SB_CONDITION_VARIABLE_INITIALIZER, 0};
	DoSunnyDay(&context, false);
	}
	}

	// Test marked as flaky because it relies on timing sensitive execution similar
	// to DoSunnyDay().
	TEST(SbConditionVariableWaitTimedTest, FLAKY_SunnyDayNearMaxTime) {
	const SbTime kOtherDelay = kSbTimeMillisecond * 10;
	TakeThenSignalContext context = {TestSemaphore(0), SB_MUTEX_INITIALIZER,
	SB_CONDITION_VARIABLE_INITIALIZER,
	kOtherDelay};
	EXPECT_TRUE(SbMutexCreate(&context.mutex));
	EXPECT_TRUE(SbConditionVariableCreate(&context.condition, &context.mutex));
	SbThread thread =
	SbThreadCreate(0, kSbThreadNoPriority, kSbThreadNoAffinity, true, NULL,
	TakeThenSignalEntryPoint, &context);

	// Try to wait until the end of time.
	const SbTime kDelay = kSbTimeMax;

	EXPECT_TRUE(SbMutexIsSuccess(SbMutexAcquire(&context.mutex)));

	// Tell the thread to signal the condvar, which will cause it to attempt to
	// acquire the mutex we are holding, after it waits for delay_after_signal.
	context.do_signal.Put();

	SbTimeMonotonic start = SbTimeGetMonotonicNow();

	// We release the mutex when we wait, allowing the thread to actually do the
	// signaling, and ensuring we are waiting before it signals.
	SbConditionVariableResult result =
	SbConditionVariableWaitTimed(&context.condition, &context.mutex, kDelay);
	EXPECT_EQ(kSbConditionVariableSignaled, result);

	// We should have waited at least the delay_after_signal amount, but not the
	// full delay.
	// Add some padding to tolerate slightly imprecise sleeps.
	EXPECT_LT(context.delay_after_signal, SbTimeGetMonotonicNow() - start +
	(context.delay_after_signal / 10));
	EXPECT_GT(kDelay, SbTimeGetMonotonicNow() - start);

	EXPECT_TRUE(SbMutexRelease(&context.mutex));

	// Now we wait for the thread to exit.
	EXPECT_TRUE(SbThreadJoin(thread, NULL));
	EXPECT_TRUE(SbConditionVariableDestroy(&context.condition));
	EXPECT_TRUE(SbMutexDestroy(&context.mutex));
	}

	TEST(SbConditionVariableWaitTimedTest, RainyDayNull) {
	SbConditionVariableResult result =
	SbConditionVariableWaitTimed(NULL, NULL, 0);
	EXPECT_EQ(kSbConditionVariableFailed, result);

	SbMutex mutex = SB_MUTEX_INITIALIZER;
	result = SbConditionVariableWaitTimed(NULL, &mutex, 0);
	EXPECT_EQ(kSbConditionVariableFailed, result);

	SbConditionVariable condition = SB_CONDITION_VARIABLE_INITIALIZER;
	result = SbConditionVariableWaitTimed(&condition, NULL, 0);
	EXPECT_EQ(kSbConditionVariableFailed, result);
	}

	} // namespace
	} // namespace nplb
	} // namespace starboard