update_manager/update_manager_unittest.cc - android_system_update_engine - Gitiles

 //
 // Copyright (C) 2014 The Android Open Source Project
 //
 // 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 "update_engine/update_manager/update_manager.h"

 #include <unistd.h>

 #include <algorithm>
 #include <memory>
 #include <string>
 #include <tuple>
 #include <utility>
 #include <vector>

 #include <base/bind.h>
 #include <base/test/simple_test_clock.h>
 #include <base/time/time.h>
 #include <brillo/message_loops/fake_message_loop.h>
 #include <brillo/message_loops/message_loop.h>
 #include <brillo/message_loops/message_loop_utils.h>
 #include <gmock/gmock.h>
 #include <gtest/gtest.h>

 #include "update_engine/common/fake_clock.h"
 #include "update_engine/update_manager/default_policy.h"
 #include "update_engine/update_manager/fake_state.h"
 #include "update_engine/update_manager/mock_policy.h"
 #include "update_engine/update_manager/umtest_utils.h"

 using base::Bind;
 using base::Callback;
 using base::Time;
 using base::TimeDelta;
 using brillo::MessageLoop;
 using brillo::MessageLoopRunMaxIterations;
 using chromeos_update_engine::ErrorCode;
 using chromeos_update_engine::FakeClock;
 using std::pair;
 using std::string;
 using std::tuple;
 using std::unique_ptr;
 using std::vector;

 namespace {

 // Generates a fixed timestamp for use in faking the current time.
 Time FixedTime() {
   Time::Exploded now_exp;
   now_exp.year = 2014;
   now_exp.month = 3;
   now_exp.day_of_week = 2;
   now_exp.day_of_month = 18;
   now_exp.hour = 8;
   now_exp.minute = 5;
   now_exp.second = 33;
   now_exp.millisecond = 675;
   return Time::FromLocalExploded(now_exp);
 }

 }  // namespace

 namespace chromeos_update_manager {

 class UmUpdateManagerTest : public ::testing::Test {
  protected:
   void SetUp() override {
     loop_.SetAsCurrent();
     fake_state_ = new FakeState();
     umut_.reset(new UpdateManager(&fake_clock_, TimeDelta::FromSeconds(5),
                                   TimeDelta::FromSeconds(1), fake_state_));
   }

   void TearDown() override {
     EXPECT_FALSE(loop_.PendingTasks());
   }

   base::SimpleTestClock test_clock_;
   brillo::FakeMessageLoop loop_{&test_clock_};
   FakeState* fake_state_;  // Owned by the umut_.
   FakeClock fake_clock_;
   unique_ptr<UpdateManager> umut_;
 };

 // The FailingPolicy implements a single method and make it always fail. This
 // class extends the DefaultPolicy class to allow extensions of the Policy
 // class without extending nor changing this test.
 class FailingPolicy : public DefaultPolicy {
  public:
   explicit FailingPolicy(int* num_called_p) : num_called_p_(num_called_p) {}
   FailingPolicy() : FailingPolicy(nullptr) {}
   EvalStatus UpdateCheckAllowed(EvaluationContext* ec, State* state,
                                 string* error,
                                 UpdateCheckParams* result) const override {
     if (num_called_p_)
       (*num_called_p_)++;
     *error = "FailingPolicy failed.";
     return EvalStatus::kFailed;
   }

  protected:
   string PolicyName() const override { return "FailingPolicy"; }

  private:
   int* num_called_p_;
 };

 // The LazyPolicy always returns EvalStatus::kAskMeAgainLater.
 class LazyPolicy : public DefaultPolicy {
   EvalStatus UpdateCheckAllowed(EvaluationContext* ec, State* state,
                                 string* error,
                                 UpdateCheckParams* result) const override {
     return EvalStatus::kAskMeAgainLater;
   }

  protected:
   string PolicyName() const override { return "LazyPolicy"; }
 };

 // A policy that sleeps for a predetermined amount of time, then checks for a
 // wallclock-based time threshold (if given) and returns
 // EvalStatus::kAskMeAgainLater if not passed; otherwise, returns
 // EvalStatus::kSucceeded. Increments a counter every time it is being queried,
 // if a pointer to it is provided.
 class DelayPolicy : public DefaultPolicy {
  public:
   DelayPolicy(int sleep_secs, Time time_threshold, int* num_called_p)
       : sleep_secs_(sleep_secs), time_threshold_(time_threshold),
         num_called_p_(num_called_p) {}
   EvalStatus UpdateCheckAllowed(EvaluationContext* ec, State* state,
                                 string* error,
                                 UpdateCheckParams* result) const override {
     if (num_called_p_)
       (*num_called_p_)++;

     // Sleep for a predetermined amount of time.
     if (sleep_secs_ > 0)
       sleep(sleep_secs_);

     // Check for a time threshold. This can be used to ensure that the policy
     // has some non-constant dependency.
     if (time_threshold_ < Time::Max() &&
         ec->IsWallclockTimeGreaterThan(time_threshold_))
       return EvalStatus::kSucceeded;

     return EvalStatus::kAskMeAgainLater;
   }

  protected:
   string PolicyName() const override { return "DelayPolicy"; }

  private:
   int sleep_secs_;
   Time time_threshold_;
   int* num_called_p_;
 };

 // AccumulateCallsCallback() adds to the passed |acc| accumulator vector pairs
 // of EvalStatus and T instances. This allows to create a callback that keeps
 // track of when it is called and the arguments passed to it, to be used with
 // the UpdateManager::AsyncPolicyRequest().
 template<typename T>
 static void AccumulateCallsCallback(vector<pair<EvalStatus, T>>* acc,
                                     EvalStatus status, const T& result) {
   acc->push_back(std::make_pair(status, result));
 }

 // Tests that policy requests are completed successfully. It is important that
 // this tests cover all policy requests as defined in Policy.
 TEST_F(UmUpdateManagerTest, PolicyRequestCallUpdateCheckAllowed) {
   UpdateCheckParams result;
   EXPECT_EQ(EvalStatus::kSucceeded, umut_->PolicyRequest(
       &Policy::UpdateCheckAllowed, &result));
 }

 TEST_F(UmUpdateManagerTest, PolicyRequestCallUpdateCanStart) {
   UpdateState update_state = UpdateState();
   update_state.is_interactive = true;
   update_state.is_delta_payload = false;
   update_state.first_seen = FixedTime();
   update_state.num_checks = 1;
   update_state.num_failures = 0;
   update_state.failures_last_updated = Time();
   update_state.download_urls = vector<string>{"http://fake/url/"};
   update_state.download_errors_max = 10;
   update_state.p2p_downloading_disabled = false;
   update_state.p2p_sharing_disabled = false;
   update_state.p2p_num_attempts = 0;
   update_state.p2p_first_attempted = Time();
   update_state.last_download_url_idx = -1;
   update_state.last_download_url_num_errors = 0;
   update_state.download_errors = vector<tuple<int, ErrorCode, Time>>();
   update_state.backoff_expiry = Time();
   update_state.is_backoff_disabled = false;
   update_state.scatter_wait_period = TimeDelta::FromSeconds(15);
   update_state.scatter_check_threshold = 4;
   update_state.scatter_wait_period_max = TimeDelta::FromSeconds(60);
   update_state.scatter_check_threshold_min = 2;
   update_state.scatter_check_threshold_max = 8;

   UpdateDownloadParams result;
   EXPECT_EQ(EvalStatus::kSucceeded,
             umut_->PolicyRequest(&Policy::UpdateCanStart, &result,
                                  update_state));
 }

 TEST_F(UmUpdateManagerTest, PolicyRequestCallsDefaultOnError) {
   umut_->set_policy(new FailingPolicy());

   // Tests that the DefaultPolicy instance is called when the method fails,
   // which will set this as true.
   UpdateCheckParams result;
   result.updates_enabled = false;
   EvalStatus status = umut_->PolicyRequest(
       &Policy::UpdateCheckAllowed, &result);
   EXPECT_EQ(EvalStatus::kSucceeded, status);
   EXPECT_TRUE(result.updates_enabled);
 }

 // This test only applies to debug builds where DCHECK is enabled.
 #if DCHECK_IS_ON
 TEST_F(UmUpdateManagerTest, PolicyRequestDoesntBlockDeathTest) {
   // The update manager should die (DCHECK) if a policy called synchronously
   // returns a kAskMeAgainLater value.
   UpdateCheckParams result;
   umut_->set_policy(new LazyPolicy());
   EXPECT_DEATH(umut_->PolicyRequest(&Policy::UpdateCheckAllowed, &result), "");
 }
 #endif  // DCHECK_IS_ON

 TEST_F(UmUpdateManagerTest, AsyncPolicyRequestDelaysEvaluation) {
   // To avoid differences in code execution order between an AsyncPolicyRequest
   // call on a policy that returns AskMeAgainLater the first time and one that
   // succeeds the first time, we ensure that the passed callback is called from
   // the main loop in both cases even when we could evaluate it right now.
   umut_->set_policy(new FailingPolicy());

   vector<pair<EvalStatus, UpdateCheckParams>> calls;
   Callback<void(EvalStatus, const UpdateCheckParams&)> callback = Bind(
       AccumulateCallsCallback<UpdateCheckParams>, &calls);

   umut_->AsyncPolicyRequest(callback, &Policy::UpdateCheckAllowed);
   // The callback should wait until we run the main loop for it to be executed.
   EXPECT_EQ(0U, calls.size());
   MessageLoopRunMaxIterations(MessageLoop::current(), 100);
   EXPECT_EQ(1U, calls.size());
 }

 TEST_F(UmUpdateManagerTest, AsyncPolicyRequestTimeoutDoesNotFire) {
   // Set up an async policy call to return immediately, then wait a little and
   // ensure that the timeout event does not fire.
   int num_called = 0;
   umut_->set_policy(new FailingPolicy(&num_called));

   vector<pair<EvalStatus, UpdateCheckParams>> calls;
   Callback<void(EvalStatus, const UpdateCheckParams&)> callback =
       Bind(AccumulateCallsCallback<UpdateCheckParams>, &calls);

   umut_->AsyncPolicyRequest(callback, &Policy::UpdateCheckAllowed);
   // Run the main loop, ensure that policy was attempted once before deferring
   // to the default.
   MessageLoopRunMaxIterations(MessageLoop::current(), 100);
   EXPECT_EQ(1, num_called);
   ASSERT_EQ(1U, calls.size());
   EXPECT_EQ(EvalStatus::kSucceeded, calls[0].first);
   // Wait for the timeout to expire, run the main loop again, ensure that
   // nothing happened.
   test_clock_.Advance(TimeDelta::FromSeconds(2));
   MessageLoopRunMaxIterations(MessageLoop::current(), 10);
   EXPECT_EQ(1, num_called);
   EXPECT_EQ(1U, calls.size());
 }

 TEST_F(UmUpdateManagerTest, AsyncPolicyRequestTimesOut) {
   // Set up an async policy call to exceed its expiration timeout, make sure
   // that the default policy was not used (no callback) and that evaluation is
   // reattempted.
   int num_called = 0;
   umut_->set_policy(new DelayPolicy(
           0, fake_clock_.GetWallclockTime() + TimeDelta::FromSeconds(3),
           &num_called));

   vector<pair<EvalStatus, UpdateCheckParams>> calls;
   Callback<void(EvalStatus, const UpdateCheckParams&)> callback =
       Bind(AccumulateCallsCallback<UpdateCheckParams>, &calls);

   umut_->AsyncPolicyRequest(callback, &Policy::UpdateCheckAllowed);
   // Run the main loop, ensure that policy was attempted once but the callback
   // was not invoked.
   MessageLoopRunMaxIterations(MessageLoop::current(), 100);
   EXPECT_EQ(1, num_called);
   EXPECT_EQ(0U, calls.size());
   // Wait for the expiration timeout to expire, run the main loop again,
   // ensure that reevaluation occurred but callback was not invoked (i.e.
   // default policy was not consulted).
   test_clock_.Advance(TimeDelta::FromSeconds(2));
   fake_clock_.SetWallclockTime(fake_clock_.GetWallclockTime() +
                                TimeDelta::FromSeconds(2));
   MessageLoopRunMaxIterations(MessageLoop::current(), 10);
   EXPECT_EQ(2, num_called);
   EXPECT_EQ(0U, calls.size());
   // Wait for reevaluation due to delay to happen, ensure that it occurs and
   // that the callback is invoked.
   test_clock_.Advance(TimeDelta::FromSeconds(2));
   fake_clock_.SetWallclockTime(fake_clock_.GetWallclockTime() +
                                TimeDelta::FromSeconds(2));
   MessageLoopRunMaxIterations(MessageLoop::current(), 10);
   EXPECT_EQ(3, num_called);
   ASSERT_EQ(1U, calls.size());
   EXPECT_EQ(EvalStatus::kSucceeded, calls[0].first);
 }

 }  // namespace chromeos_update_manager
	//
	// Copyright (C) 2014 The Android Open Source Project
	//
	// 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 "update_engine/update_manager/update_manager.h"

	#include <unistd.h>

	#include <algorithm>
	#include <memory>
	#include <string>
	#include <tuple>
	#include <utility>
	#include <vector>

	#include <base/bind.h>
	#include <base/test/simple_test_clock.h>
	#include <base/time/time.h>
	#include <brillo/message_loops/fake_message_loop.h>
	#include <brillo/message_loops/message_loop.h>
	#include <brillo/message_loops/message_loop_utils.h>
	#include <gmock/gmock.h>
	#include <gtest/gtest.h>

	#include "update_engine/common/fake_clock.h"
	#include "update_engine/update_manager/default_policy.h"
	#include "update_engine/update_manager/fake_state.h"
	#include "update_engine/update_manager/mock_policy.h"
	#include "update_engine/update_manager/umtest_utils.h"

	using base::Bind;
	using base::Callback;
	using base::Time;
	using base::TimeDelta;
	using brillo::MessageLoop;
	using brillo::MessageLoopRunMaxIterations;
	using chromeos_update_engine::ErrorCode;
	using chromeos_update_engine::FakeClock;
	using std::pair;
	using std::string;
	using std::tuple;
	using std::unique_ptr;
	using std::vector;

	namespace {

	// Generates a fixed timestamp for use in faking the current time.
	Time FixedTime() {
	Time::Exploded now_exp;
	now_exp.year = 2014;
	now_exp.month = 3;
	now_exp.day_of_week = 2;
	now_exp.day_of_month = 18;
	now_exp.hour = 8;
	now_exp.minute = 5;
	now_exp.second = 33;
	now_exp.millisecond = 675;
	return Time::FromLocalExploded(now_exp);
	}

	} // namespace

	namespace chromeos_update_manager {

	class UmUpdateManagerTest : public ::testing::Test {
	protected:
	void SetUp() override {
	loop_.SetAsCurrent();
	fake_state_ = new FakeState();
	umut_.reset(new UpdateManager(&fake_clock_, TimeDelta::FromSeconds(5),
	TimeDelta::FromSeconds(1), fake_state_));
	}

	void TearDown() override {
	EXPECT_FALSE(loop_.PendingTasks());
	}

	base::SimpleTestClock test_clock_;
	brillo::FakeMessageLoop loop_{&test_clock_};
	FakeState* fake_state_; // Owned by the umut_.
	FakeClock fake_clock_;
	unique_ptr<UpdateManager> umut_;
	};

	// The FailingPolicy implements a single method and make it always fail. This
	// class extends the DefaultPolicy class to allow extensions of the Policy
	// class without extending nor changing this test.
	class FailingPolicy : public DefaultPolicy {
	public:
	explicit FailingPolicy(int* num_called_p) : num_called_p_(num_called_p) {}
	FailingPolicy() : FailingPolicy(nullptr) {}
	EvalStatus UpdateCheckAllowed(EvaluationContext* ec, State* state,
	string* error,
	UpdateCheckParams* result) const override {
	if (num_called_p_)
	(*num_called_p_)++;
	*error = "FailingPolicy failed.";
	return EvalStatus::kFailed;
	}

	protected:
	string PolicyName() const override { return "FailingPolicy"; }

	private:
	int* num_called_p_;
	};

	// The LazyPolicy always returns EvalStatus::kAskMeAgainLater.
	class LazyPolicy : public DefaultPolicy {
	EvalStatus UpdateCheckAllowed(EvaluationContext* ec, State* state,
	string* error,
	UpdateCheckParams* result) const override {
	return EvalStatus::kAskMeAgainLater;
	}

	protected:
	string PolicyName() const override { return "LazyPolicy"; }
	};

	// A policy that sleeps for a predetermined amount of time, then checks for a
	// wallclock-based time threshold (if given) and returns
	// EvalStatus::kAskMeAgainLater if not passed; otherwise, returns
	// EvalStatus::kSucceeded. Increments a counter every time it is being queried,
	// if a pointer to it is provided.
	class DelayPolicy : public DefaultPolicy {
	public:
	DelayPolicy(int sleep_secs, Time time_threshold, int* num_called_p)
	: sleep_secs_(sleep_secs), time_threshold_(time_threshold),
	num_called_p_(num_called_p) {}
	EvalStatus UpdateCheckAllowed(EvaluationContext* ec, State* state,
	string* error,
	UpdateCheckParams* result) const override {
	if (num_called_p_)
	(*num_called_p_)++;

	// Sleep for a predetermined amount of time.
	if (sleep_secs_ > 0)
	sleep(sleep_secs_);

	// Check for a time threshold. This can be used to ensure that the policy
	// has some non-constant dependency.
	if (time_threshold_ < Time::Max() &&
	ec->IsWallclockTimeGreaterThan(time_threshold_))
	return EvalStatus::kSucceeded;

	return EvalStatus::kAskMeAgainLater;
	}

	protected:
	string PolicyName() const override { return "DelayPolicy"; }

	private:
	int sleep_secs_;
	Time time_threshold_;
	int* num_called_p_;
	};

	// AccumulateCallsCallback() adds to the passed \|acc\| accumulator vector pairs
	// of EvalStatus and T instances. This allows to create a callback that keeps
	// track of when it is called and the arguments passed to it, to be used with
	// the UpdateManager::AsyncPolicyRequest().
	template<typename T>
	static void AccumulateCallsCallback(vector<pair<EvalStatus, T>>* acc,
	EvalStatus status, const T& result) {
	acc->push_back(std::make_pair(status, result));
	}

	// Tests that policy requests are completed successfully. It is important that
	// this tests cover all policy requests as defined in Policy.
	TEST_F(UmUpdateManagerTest, PolicyRequestCallUpdateCheckAllowed) {
	UpdateCheckParams result;
	EXPECT_EQ(EvalStatus::kSucceeded, umut_->PolicyRequest(
	&Policy::UpdateCheckAllowed, &result));
	}

	TEST_F(UmUpdateManagerTest, PolicyRequestCallUpdateCanStart) {
	UpdateState update_state = UpdateState();
	update_state.is_interactive = true;
	update_state.is_delta_payload = false;
	update_state.first_seen = FixedTime();
	update_state.num_checks = 1;
	update_state.num_failures = 0;
	update_state.failures_last_updated = Time();
	update_state.download_urls = vector<string>{"http://fake/url/"};
	update_state.download_errors_max = 10;
	update_state.p2p_downloading_disabled = false;
	update_state.p2p_sharing_disabled = false;
	update_state.p2p_num_attempts = 0;
	update_state.p2p_first_attempted = Time();
	update_state.last_download_url_idx = -1;
	update_state.last_download_url_num_errors = 0;
	update_state.download_errors = vector<tuple<int, ErrorCode, Time>>();
	update_state.backoff_expiry = Time();
	update_state.is_backoff_disabled = false;
	update_state.scatter_wait_period = TimeDelta::FromSeconds(15);
	update_state.scatter_check_threshold = 4;
	update_state.scatter_wait_period_max = TimeDelta::FromSeconds(60);
	update_state.scatter_check_threshold_min = 2;
	update_state.scatter_check_threshold_max = 8;

	UpdateDownloadParams result;
	EXPECT_EQ(EvalStatus::kSucceeded,
	umut_->PolicyRequest(&Policy::UpdateCanStart, &result,
	update_state));
	}

	TEST_F(UmUpdateManagerTest, PolicyRequestCallsDefaultOnError) {
	umut_->set_policy(new FailingPolicy());

	// Tests that the DefaultPolicy instance is called when the method fails,
	// which will set this as true.
	UpdateCheckParams result;
	result.updates_enabled = false;
	EvalStatus status = umut_->PolicyRequest(
	&Policy::UpdateCheckAllowed, &result);
	EXPECT_EQ(EvalStatus::kSucceeded, status);
	EXPECT_TRUE(result.updates_enabled);
	}

	// This test only applies to debug builds where DCHECK is enabled.
	#if DCHECK_IS_ON
	TEST_F(UmUpdateManagerTest, PolicyRequestDoesntBlockDeathTest) {
	// The update manager should die (DCHECK) if a policy called synchronously
	// returns a kAskMeAgainLater value.
	UpdateCheckParams result;
	umut_->set_policy(new LazyPolicy());
	EXPECT_DEATH(umut_->PolicyRequest(&Policy::UpdateCheckAllowed, &result), "");
	}
	#endif // DCHECK_IS_ON

	TEST_F(UmUpdateManagerTest, AsyncPolicyRequestDelaysEvaluation) {
	// To avoid differences in code execution order between an AsyncPolicyRequest
	// call on a policy that returns AskMeAgainLater the first time and one that
	// succeeds the first time, we ensure that the passed callback is called from
	// the main loop in both cases even when we could evaluate it right now.
	umut_->set_policy(new FailingPolicy());

	vector<pair<EvalStatus, UpdateCheckParams>> calls;
	Callback<void(EvalStatus, const UpdateCheckParams&)> callback = Bind(
	AccumulateCallsCallback<UpdateCheckParams>, &calls);

	umut_->AsyncPolicyRequest(callback, &Policy::UpdateCheckAllowed);
	// The callback should wait until we run the main loop for it to be executed.
	EXPECT_EQ(0U, calls.size());
	MessageLoopRunMaxIterations(MessageLoop::current(), 100);
	EXPECT_EQ(1U, calls.size());
	}

	TEST_F(UmUpdateManagerTest, AsyncPolicyRequestTimeoutDoesNotFire) {
	// Set up an async policy call to return immediately, then wait a little and
	// ensure that the timeout event does not fire.
	int num_called = 0;
	umut_->set_policy(new FailingPolicy(&num_called));

	vector<pair<EvalStatus, UpdateCheckParams>> calls;
	Callback<void(EvalStatus, const UpdateCheckParams&)> callback =
	Bind(AccumulateCallsCallback<UpdateCheckParams>, &calls);

	umut_->AsyncPolicyRequest(callback, &Policy::UpdateCheckAllowed);
	// Run the main loop, ensure that policy was attempted once before deferring
	// to the default.
	MessageLoopRunMaxIterations(MessageLoop::current(), 100);
	EXPECT_EQ(1, num_called);
	ASSERT_EQ(1U, calls.size());
	EXPECT_EQ(EvalStatus::kSucceeded, calls[0].first);
	// Wait for the timeout to expire, run the main loop again, ensure that
	// nothing happened.
	test_clock_.Advance(TimeDelta::FromSeconds(2));
	MessageLoopRunMaxIterations(MessageLoop::current(), 10);
	EXPECT_EQ(1, num_called);
	EXPECT_EQ(1U, calls.size());
	}

	TEST_F(UmUpdateManagerTest, AsyncPolicyRequestTimesOut) {
	// Set up an async policy call to exceed its expiration timeout, make sure
	// that the default policy was not used (no callback) and that evaluation is
	// reattempted.
	int num_called = 0;
	umut_->set_policy(new DelayPolicy(
	0, fake_clock_.GetWallclockTime() + TimeDelta::FromSeconds(3),
	&num_called));

	vector<pair<EvalStatus, UpdateCheckParams>> calls;
	Callback<void(EvalStatus, const UpdateCheckParams&)> callback =
	Bind(AccumulateCallsCallback<UpdateCheckParams>, &calls);

	umut_->AsyncPolicyRequest(callback, &Policy::UpdateCheckAllowed);
	// Run the main loop, ensure that policy was attempted once but the callback
	// was not invoked.
	MessageLoopRunMaxIterations(MessageLoop::current(), 100);
	EXPECT_EQ(1, num_called);
	EXPECT_EQ(0U, calls.size());
	// Wait for the expiration timeout to expire, run the main loop again,
	// ensure that reevaluation occurred but callback was not invoked (i.e.
	// default policy was not consulted).
	test_clock_.Advance(TimeDelta::FromSeconds(2));
	fake_clock_.SetWallclockTime(fake_clock_.GetWallclockTime() +
	TimeDelta::FromSeconds(2));
	MessageLoopRunMaxIterations(MessageLoop::current(), 10);
	EXPECT_EQ(2, num_called);
	EXPECT_EQ(0U, calls.size());
	// Wait for reevaluation due to delay to happen, ensure that it occurs and
	// that the callback is invoked.
	test_clock_.Advance(TimeDelta::FromSeconds(2));
	fake_clock_.SetWallclockTime(fake_clock_.GetWallclockTime() +
	TimeDelta::FromSeconds(2));
	MessageLoopRunMaxIterations(MessageLoop::current(), 10);
	EXPECT_EQ(3, num_called);
	ASSERT_EQ(1U, calls.size());
	EXPECT_EQ(EvalStatus::kSucceeded, calls[0].first);
	}

	} // namespace chromeos_update_manager