shaka-packager/packager/media/base/producer_consumer_queue_uni...

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// Copyright 2014 Google Inc. All rights reserved.
//
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file or at
// https://developers.google.com/open-source/licenses/bsd
#include <gtest/gtest.h>
#include "packager/base/bind.h"
#include "packager/base/synchronization/waitable_event.h"
#include "packager/media/base/closure_thread.h"
#include "packager/media/base/producer_consumer_queue.h"
#include "packager/status_test_util.h"
namespace shaka {
namespace {
const size_t kCapacity = 10u;
const int64_t kTimeout = 100; // 0.1s.
} // namespace
namespace media {
TEST(ProducerConsumerQueueTest, CheckEmpty) {
ProducerConsumerQueue<int> queue(kUnlimitedCapacity);
EXPECT_EQ(0u, queue.Size());
EXPECT_TRUE(queue.Empty());
EXPECT_EQ(0u, queue.HeadPos());
}
TEST(ProducerConsumerQueueTest, PushPop) {
ProducerConsumerQueue<size_t> queue(kCapacity);
for (size_t i = 0; i < kCapacity; ++i)
ASSERT_OK(queue.Push(i, kInfiniteTimeout));
EXPECT_EQ(kCapacity, queue.Size());
EXPECT_FALSE(queue.Empty());
EXPECT_EQ(0u, queue.HeadPos());
EXPECT_EQ(kCapacity - 1, queue.TailPos());
for (size_t i = 0; i < kCapacity; ++i) {
size_t val;
ASSERT_OK(queue.Pop(&val, kInfiniteTimeout));
EXPECT_EQ(i, val);
EXPECT_EQ(i + 1, queue.HeadPos());
}
}
TEST(ProducerConsumerQueueTest, Peek) {
ProducerConsumerQueue<size_t> queue(kCapacity);
for (size_t i = 0; i < kCapacity; ++i)
ASSERT_OK(queue.Push(i, kInfiniteTimeout));
for (size_t i = 0; i < kCapacity; ++i) {
size_t val;
ASSERT_OK(queue.Peek(i, &val, kInfiniteTimeout));
EXPECT_EQ(i, val);
// Expect head position to move along with peek position.
EXPECT_EQ(i >= kCapacity / 2 ? i - kCapacity / 2 : 0, queue.HeadPos());
}
EXPECT_EQ(kCapacity - 1, queue.TailPos());
}
TEST(ProducerConsumerQueueTest, PeekOnPoppedElement) {
ProducerConsumerQueue<size_t> queue(kCapacity);
for (size_t i = 0; i < kCapacity; ++i)
ASSERT_OK(queue.Push(i, kInfiniteTimeout));
size_t val;
ASSERT_OK(queue.Pop(&val, kInfiniteTimeout));
ASSERT_OK(queue.Push(kCapacity, kInfiniteTimeout));
ASSERT_OK(queue.Peek(kCapacity, &val, kInfiniteTimeout));
EXPECT_EQ(kCapacity, val);
// Expect head position to move along with peek position.
EXPECT_EQ(kCapacity / 2, queue.HeadPos());
ASSERT_OK(queue.Peek(kCapacity / 2, &val, kInfiniteTimeout));
EXPECT_EQ(kCapacity / 2, val);
ASSERT_EQ(error::INVALID_ARGUMENT,
queue.Peek(kCapacity / 2 - 2, &val, kInfiniteTimeout).error_code());
}
TEST(ProducerConsumerQueueTest, PushWithTimeout) {
std::unique_ptr<base::ElapsedTimer> timer;
ProducerConsumerQueue<size_t> queue(kCapacity);
for (size_t i = 0; i < kCapacity; ++i) {
timer.reset(new base::ElapsedTimer());
ASSERT_OK(queue.Push(i, kTimeout));
// Expect Push to return without waiting for timeout.
EXPECT_LT(timer->Elapsed().InMilliseconds(), kTimeout);
}
timer.reset(new base::ElapsedTimer());
ASSERT_EQ(error::TIME_OUT, queue.Push(0, kTimeout).error_code());
EXPECT_GE(timer->Elapsed().InMilliseconds(), kTimeout);
}
TEST(ProducerConsumerQueueTest, PopWithTimeout) {
std::unique_ptr<base::ElapsedTimer> timer;
ProducerConsumerQueue<size_t> queue(kCapacity);
for (size_t i = 0; i < kCapacity; ++i)
ASSERT_OK(queue.Push(i, kInfiniteTimeout));
size_t val;
for (size_t i = 0; i < kCapacity; ++i) {
timer.reset(new base::ElapsedTimer());
ASSERT_OK(queue.Pop(&val, kTimeout));
// Expect Pop to return without waiting for timeout.
EXPECT_LT(timer->Elapsed().InMilliseconds(), kTimeout);
EXPECT_EQ(i, val);
}
timer.reset(new base::ElapsedTimer());
ASSERT_EQ(error::TIME_OUT, queue.Pop(&val, kTimeout).error_code());
EXPECT_GE(timer->Elapsed().InMilliseconds(), kTimeout);
}
TEST(ProducerConsumerQueueTest, PeekWithTimeout) {
std::unique_ptr<base::ElapsedTimer> timer;
ProducerConsumerQueue<size_t> queue(kCapacity);
for (size_t i = 0; i < kCapacity; ++i)
ASSERT_OK(queue.Push(i, kInfiniteTimeout));
size_t val;
timer.reset(new base::ElapsedTimer());
ASSERT_EQ(error::TIME_OUT,
queue.Peek(kCapacity, &val, kTimeout).error_code());
EXPECT_GE(timer->Elapsed().InMilliseconds(), kTimeout);
for (size_t i = kCapacity / 2; i < kCapacity; ++i) {
timer.reset(new base::ElapsedTimer());
ASSERT_OK(queue.Peek(i, &val, kTimeout));
// Expect Peek to return without waiting for timeout.
EXPECT_LT(timer->Elapsed().InMilliseconds(), kTimeout);
EXPECT_EQ(i, val);
}
}
TEST(ProducerConsumerQueueTest, CheckStop) {
std::unique_ptr<base::ElapsedTimer> timer;
ProducerConsumerQueue<int> queue(kUnlimitedCapacity);
ASSERT_FALSE(queue.Stopped());
queue.Stop();
ASSERT_TRUE(queue.Stopped());
EXPECT_EQ(error::STOPPED, queue.Push(0, kInfiniteTimeout).error_code());
timer.reset(new base::ElapsedTimer());
EXPECT_EQ(error::STOPPED, queue.Push(0, kTimeout).error_code());
// Expect Push to return without waiting for timeout.
EXPECT_LT(timer->Elapsed().InMilliseconds(), kTimeout);
int val;
EXPECT_EQ(error::STOPPED, queue.Pop(&val, kInfiniteTimeout).error_code());
timer.reset(new base::ElapsedTimer());
EXPECT_EQ(error::STOPPED, queue.Pop(&val, kTimeout).error_code());
// Expect Pop to return without waiting for timeout.
EXPECT_LT(timer->Elapsed().InMilliseconds(), kTimeout);
EXPECT_EQ(error::STOPPED, queue.Peek(0, &val, kInfiniteTimeout).error_code());
timer.reset(new base::ElapsedTimer());
EXPECT_EQ(error::STOPPED, queue.Peek(0, &val, kTimeout).error_code());
// Expect Peek to return without waiting for timeout.
EXPECT_LT(timer->Elapsed().InMilliseconds(), kTimeout);
}
class MultiThreadProducerConsumerQueueTest : public ::testing::Test {
public:
MultiThreadProducerConsumerQueueTest()
: thread_("My Push Thread",
base::Bind(&MultiThreadProducerConsumerQueueTest::PushTask,
base::Unretained(this))),
queue_(kCapacity) {}
~MultiThreadProducerConsumerQueueTest() override {}
protected:
void SetUp() override { thread_.Start(); }
void TearDown() override { thread_.Join(); }
void PushTask() {
int val = 0;
// Push elements to the queue until stopped.
while (queue_.Push(val, kInfiniteTimeout).ok())
++val;
}
void SleepUntilQueueIsFull() {
const size_t kMaxNumLoopsWaiting = 1000;
const size_t kSleepDurationInMillisecondsPerLoop = 10;
for (size_t i = 0; i < kMaxNumLoopsWaiting; i++) {
if (queue_.Size() >= kCapacity)
break;
base::PlatformThread::Sleep(base::TimeDelta::FromMilliseconds(
kSleepDurationInMillisecondsPerLoop));
}
}
ClosureThread thread_;
ProducerConsumerQueue<size_t> queue_;
private:
DISALLOW_COPY_AND_ASSIGN(MultiThreadProducerConsumerQueueTest);
};
TEST_F(MultiThreadProducerConsumerQueueTest, Pop) {
// Perform a number of pops.
size_t val;
size_t i = 0;
for (; i < kCapacity * 3; ++i) {
ASSERT_OK(queue_.Pop(&val, kInfiniteTimeout));
EXPECT_EQ(i, val);
}
// Wait until the queue is full. The size of the queue should be kCapacity
// exactly.
SleepUntilQueueIsFull();
EXPECT_EQ(kCapacity, queue_.Size());
queue_.Stop();
// Should still have kCapacity elements before STOPPED being returned.
for (size_t j = 0; j < kCapacity; ++j) {
ASSERT_OK(queue_.Pop(&val, kInfiniteTimeout));
EXPECT_EQ(i + j, val);
}
ASSERT_EQ(error::STOPPED, queue_.Pop(&val, kInfiniteTimeout).error_code());
}
TEST_F(MultiThreadProducerConsumerQueueTest, Peek) {
const size_t kPositionOne = 25u;
const size_t kPositionTwo = 88u;
EXPECT_EQ(0u, queue_.HeadPos());
size_t val;
ASSERT_OK(queue_.Peek(kPositionOne, &val, kInfiniteTimeout));
EXPECT_EQ(kPositionOne, val);
EXPECT_EQ(kPositionOne - kCapacity / 2, queue_.HeadPos());
ASSERT_OK(queue_.Peek(kPositionTwo, &val, kInfiniteTimeout));
EXPECT_EQ(kPositionTwo, val);
EXPECT_EQ(kPositionTwo - kCapacity / 2, queue_.HeadPos());
// Wait until the queue is full. The size of the queue should be kCapacity
// exactly.
SleepUntilQueueIsFull();
EXPECT_EQ(kCapacity, queue_.Size());
queue_.Stop();
EXPECT_EQ(kPositionTwo - kCapacity / 2, queue_.HeadPos());
EXPECT_EQ(kPositionTwo + kCapacity / 2 - 1, queue_.TailPos());
ASSERT_EQ(error::STOPPED,
queue_.Peek(kPositionTwo + kCapacity, &val, kInfiniteTimeout)
.error_code());
// Head will be moved pass Tail and the queue is expected to be empty.
EXPECT_EQ(kPositionTwo + kCapacity / 2, queue_.HeadPos());
EXPECT_EQ(kPositionTwo + kCapacity / 2 - 1, queue_.TailPos());
EXPECT_TRUE(queue_.Empty());
}
TEST_F(MultiThreadProducerConsumerQueueTest, PeekOnLargePosition) {
const size_t kVeryLargePosition = 88888888u;
size_t val;
ASSERT_EQ(error::TIME_OUT,
queue_.Peek(kVeryLargePosition, &val, 0).error_code());
base::ElapsedTimer timer;
ASSERT_EQ(error::TIME_OUT,
queue_.Peek(kVeryLargePosition, &val, kTimeout).error_code());
EXPECT_GE(timer.Elapsed().InMilliseconds(), kTimeout);
queue_.Stop();
}
namespace {
enum Operation {
kPush,
kPop,
kPeek,
};
} // namespace
class MultiThreadProducerConsumerQueueStopTest
: public ::testing::TestWithParam<Operation> {
public:
MultiThreadProducerConsumerQueueStopTest()
: queue_(1),
event_(base::WaitableEvent::ResetPolicy::MANUAL,
base::WaitableEvent::InitialState::NOT_SIGNALED) {}
~MultiThreadProducerConsumerQueueStopTest() override {}
public:
void ClosureTask(Operation op) {
int val = 0;
switch (op) {
case kPush:
// The queue was setup with size 1. The first push will return STOPPED
// if Stop() has been called; otherwise it should return OK and the
// second push will block until Stop() being called.
status_ = queue_.Push(0, kInfiniteTimeout);
if (status_.ok())
status_ = queue_.Push(0, kInfiniteTimeout);
break;
case kPop:
status_ = queue_.Pop(&val, kInfiniteTimeout);
break;
case kPeek:
status_ = queue_.Peek(0, &val, kInfiniteTimeout);
break;
default:
NOTREACHED();
}
event_.Signal();
}
protected:
ProducerConsumerQueue<int> queue_;
base::WaitableEvent event_;
private:
Status status_;
DISALLOW_COPY_AND_ASSIGN(MultiThreadProducerConsumerQueueStopTest);
};
// Verify that Stop stops Push/Pop/Peek operations and return immediately.
TEST_P(MultiThreadProducerConsumerQueueStopTest, StopTests) {
Operation op = GetParam();
ClosureThread thread(
"My Thread",
base::Bind(&MultiThreadProducerConsumerQueueStopTest::ClosureTask,
base::Unretained(this),
op));
thread.Start();
ASSERT_TRUE(!event_.IsSignaled());
queue_.Stop();
event_.Wait();
thread.Join();
}
INSTANTIATE_TEST_CASE_P(Operations,
MultiThreadProducerConsumerQueueStopTest,
::testing::Values(kPush, kPop, kPeek));
} // namespace media
} // namespace shaka