base/simple_thread_unittest.cc - chromium/src - Git at Google

 // Copyright (c) 2010 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "base/atomic_sequence_num.h"
 #include "base/lock.h"
 #include "base/simple_thread.h"
 #include "base/string_number_conversions.h"
 #include "base/waitable_event.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace {

 class SetIntRunner : public base::DelegateSimpleThread::Delegate {
  public:
   SetIntRunner(int* ptr, int val) : ptr_(ptr), val_(val) { }
   ~SetIntRunner() { }

   virtual void Run() {
     *ptr_ = val_;
   }

  private:
   int* ptr_;
   int val_;
 };

 class WaitEventRunner : public base::DelegateSimpleThread::Delegate {
  public:
   explicit WaitEventRunner(base::WaitableEvent* event) : event_(event) { }
   ~WaitEventRunner() { }

   virtual void Run() {
     EXPECT_FALSE(event_->IsSignaled());
     event_->Signal();
     EXPECT_TRUE(event_->IsSignaled());
   }
  private:
   base::WaitableEvent* event_;
 };

 class SeqRunner : public base::DelegateSimpleThread::Delegate {
  public:
   explicit SeqRunner(base::AtomicSequenceNumber* seq) : seq_(seq) { }
   virtual void Run() {
     seq_->GetNext();
   }

  private:
   base::AtomicSequenceNumber* seq_;
 };

 // We count up on a sequence number, firing on the event when we've hit our
 // expected amount, otherwise we wait on the event.  This will ensure that we
 // have all threads outstanding until we hit our expected thread pool size.
 class VerifyPoolRunner : public base::DelegateSimpleThread::Delegate {
  public:
   VerifyPoolRunner(base::AtomicSequenceNumber* seq,
                    int total, base::WaitableEvent* event)
       : seq_(seq), total_(total), event_(event) { }

   virtual void Run() {
     if (seq_->GetNext() == total_) {
       event_->Signal();
     } else {
       event_->Wait();
     }
   }

  private:
   base::AtomicSequenceNumber* seq_;
   int total_;
   base::WaitableEvent* event_;
 };

 }  // namespace

 TEST(SimpleThreadTest, CreateAndJoin) {
   int stack_int = 0;

   SetIntRunner runner(&stack_int, 7);
   EXPECT_EQ(0, stack_int);

   base::DelegateSimpleThread thread(&runner, "int_setter");
   EXPECT_FALSE(thread.HasBeenStarted());
   EXPECT_FALSE(thread.HasBeenJoined());
   EXPECT_EQ(0, stack_int);

   thread.Start();
   EXPECT_TRUE(thread.HasBeenStarted());
   EXPECT_FALSE(thread.HasBeenJoined());

   thread.Join();
   EXPECT_TRUE(thread.HasBeenStarted());
   EXPECT_TRUE(thread.HasBeenJoined());
   EXPECT_EQ(7, stack_int);
 }

 TEST(SimpleThreadTest, WaitForEvent) {
   // Create a thread, and wait for it to signal us.
   base::WaitableEvent event(true, false);

   WaitEventRunner runner(&event);
   base::DelegateSimpleThread thread(&runner, "event_waiter");

   EXPECT_FALSE(event.IsSignaled());
   thread.Start();
   event.Wait();
   EXPECT_TRUE(event.IsSignaled());
   thread.Join();
 }

 TEST(SimpleThreadTest, NamedWithOptions) {
   base::WaitableEvent event(true, false);

   WaitEventRunner runner(&event);
   base::SimpleThread::Options options;
   base::DelegateSimpleThread thread(&runner, "event_waiter", options);
   EXPECT_EQ(thread.name_prefix(), "event_waiter");
   EXPECT_FALSE(event.IsSignaled());

   thread.Start();
   EXPECT_EQ(thread.name_prefix(), "event_waiter");
   EXPECT_EQ(thread.name(),
             std::string("event_waiter/") + base::IntToString(thread.tid()));
   event.Wait();

   EXPECT_TRUE(event.IsSignaled());
   thread.Join();

   // We keep the name and tid, even after the thread is gone.
   EXPECT_EQ(thread.name_prefix(), "event_waiter");
   EXPECT_EQ(thread.name(),
             std::string("event_waiter/") + base::IntToString(thread.tid()));
 }

 TEST(SimpleThreadTest, ThreadPool) {
   base::AtomicSequenceNumber seq;
   SeqRunner runner(&seq);
   base::DelegateSimpleThreadPool pool("seq_runner", 10);

   // Add work before we're running.
   pool.AddWork(&runner, 300);

   EXPECT_EQ(seq.GetNext(), 0);
   pool.Start();

   // Add work while we're running.
   pool.AddWork(&runner, 300);

   pool.JoinAll();

   EXPECT_EQ(seq.GetNext(), 601);

   // We can reuse our pool.  Verify that all 10 threads can actually run in
   // parallel, so this test will only pass if there are actually 10 threads.
   base::AtomicSequenceNumber seq2;
   base::WaitableEvent event(true, false);
   // Changing 9 to 10, for example, would cause us JoinAll() to never return.
   VerifyPoolRunner verifier(&seq2, 9, &event);
   pool.Start();

   pool.AddWork(&verifier, 10);

   pool.JoinAll();
   EXPECT_EQ(seq2.GetNext(), 10);
 }
	// Copyright (c) 2010 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "base/atomic_sequence_num.h"
	#include "base/lock.h"
	#include "base/simple_thread.h"
	#include "base/string_number_conversions.h"
	#include "base/waitable_event.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace {

	class SetIntRunner : public base::DelegateSimpleThread::Delegate {
	public:
	SetIntRunner(int* ptr, int val) : ptr_(ptr), val_(val) { }
	~SetIntRunner() { }

	virtual void Run() {
	*ptr_ = val_;
	}

	private:
	int* ptr_;
	int val_;
	};

	class WaitEventRunner : public base::DelegateSimpleThread::Delegate {
	public:
	explicit WaitEventRunner(base::WaitableEvent* event) : event_(event) { }
	~WaitEventRunner() { }

	virtual void Run() {
	EXPECT_FALSE(event_->IsSignaled());
	event_->Signal();
	EXPECT_TRUE(event_->IsSignaled());
	}
	private:
	base::WaitableEvent* event_;
	};

	class SeqRunner : public base::DelegateSimpleThread::Delegate {
	public:
	explicit SeqRunner(base::AtomicSequenceNumber* seq) : seq_(seq) { }
	virtual void Run() {
	seq_->GetNext();
	}

	private:
	base::AtomicSequenceNumber* seq_;
	};

	// We count up on a sequence number, firing on the event when we've hit our
	// expected amount, otherwise we wait on the event. This will ensure that we
	// have all threads outstanding until we hit our expected thread pool size.
	class VerifyPoolRunner : public base::DelegateSimpleThread::Delegate {
	public:
	VerifyPoolRunner(base::AtomicSequenceNumber* seq,
	int total, base::WaitableEvent* event)
	: seq_(seq), total_(total), event_(event) { }

	virtual void Run() {
	if (seq_->GetNext() == total_) {
	event_->Signal();
	} else {
	event_->Wait();
	}
	}

	private:
	base::AtomicSequenceNumber* seq_;
	int total_;
	base::WaitableEvent* event_;
	};

	} // namespace

	TEST(SimpleThreadTest, CreateAndJoin) {
	int stack_int = 0;

	SetIntRunner runner(&stack_int, 7);
	EXPECT_EQ(0, stack_int);

	base::DelegateSimpleThread thread(&runner, "int_setter");
	EXPECT_FALSE(thread.HasBeenStarted());
	EXPECT_FALSE(thread.HasBeenJoined());
	EXPECT_EQ(0, stack_int);

	thread.Start();
	EXPECT_TRUE(thread.HasBeenStarted());
	EXPECT_FALSE(thread.HasBeenJoined());

	thread.Join();
	EXPECT_TRUE(thread.HasBeenStarted());
	EXPECT_TRUE(thread.HasBeenJoined());
	EXPECT_EQ(7, stack_int);
	}

	TEST(SimpleThreadTest, WaitForEvent) {
	// Create a thread, and wait for it to signal us.
	base::WaitableEvent event(true, false);

	WaitEventRunner runner(&event);
	base::DelegateSimpleThread thread(&runner, "event_waiter");

	EXPECT_FALSE(event.IsSignaled());
	thread.Start();
	event.Wait();
	EXPECT_TRUE(event.IsSignaled());
	thread.Join();
	}

	TEST(SimpleThreadTest, NamedWithOptions) {
	base::WaitableEvent event(true, false);

	WaitEventRunner runner(&event);
	base::SimpleThread::Options options;
	base::DelegateSimpleThread thread(&runner, "event_waiter", options);
	EXPECT_EQ(thread.name_prefix(), "event_waiter");
	EXPECT_FALSE(event.IsSignaled());

	thread.Start();
	EXPECT_EQ(thread.name_prefix(), "event_waiter");
	EXPECT_EQ(thread.name(),
	std::string("event_waiter/") + base::IntToString(thread.tid()));
	event.Wait();

	EXPECT_TRUE(event.IsSignaled());
	thread.Join();

	// We keep the name and tid, even after the thread is gone.
	EXPECT_EQ(thread.name_prefix(), "event_waiter");
	EXPECT_EQ(thread.name(),
	std::string("event_waiter/") + base::IntToString(thread.tid()));
	}

	TEST(SimpleThreadTest, ThreadPool) {
	base::AtomicSequenceNumber seq;
	SeqRunner runner(&seq);
	base::DelegateSimpleThreadPool pool("seq_runner", 10);

	// Add work before we're running.
	pool.AddWork(&runner, 300);

	EXPECT_EQ(seq.GetNext(), 0);
	pool.Start();

	// Add work while we're running.
	pool.AddWork(&runner, 300);

	pool.JoinAll();

	EXPECT_EQ(seq.GetNext(), 601);

	// We can reuse our pool. Verify that all 10 threads can actually run in
	// parallel, so this test will only pass if there are actually 10 threads.
	base::AtomicSequenceNumber seq2;
	base::WaitableEvent event(true, false);
	// Changing 9 to 10, for example, would cause us JoinAll() to never return.
	VerifyPoolRunner verifier(&seq2, 9, &event);
	pool.Start();

	pool.AddWork(&verifier, 10);

	pool.JoinAll();
	EXPECT_EQ(seq2.GetNext(), 10);
	}