metrics_utils_unittest.cc - platform/system/update_engine - Gitiles

 //
 // Copyright (C) 2015 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/metrics_utils.h"

 #include <gtest/gtest.h>

 #include "update_engine/common/fake_clock.h"
 #include "update_engine/common/fake_prefs.h"
 #include "update_engine/fake_system_state.h"

 namespace chromeos_update_engine {
 namespace metrics_utils {

 class MetricsUtilsTest : public ::testing::Test {};

 TEST(MetricsUtilsTest, GetConnectionType) {
   // Check that expected combinations map to the right value.
   EXPECT_EQ(metrics::ConnectionType::kUnknown,
             GetConnectionType(ConnectionType::kUnknown,
                               ConnectionTethering::kUnknown));
   EXPECT_EQ(metrics::ConnectionType::kDisconnected,
             GetConnectionType(ConnectionType::kDisconnected,
                               ConnectionTethering::kUnknown));
   EXPECT_EQ(metrics::ConnectionType::kEthernet,
             GetConnectionType(ConnectionType::kEthernet,
                               ConnectionTethering::kUnknown));
   EXPECT_EQ(metrics::ConnectionType::kWifi,
             GetConnectionType(ConnectionType::kWifi,
                               ConnectionTethering::kUnknown));
   EXPECT_EQ(metrics::ConnectionType::kWimax,
             GetConnectionType(ConnectionType::kWimax,
                               ConnectionTethering::kUnknown));
   EXPECT_EQ(metrics::ConnectionType::kBluetooth,
             GetConnectionType(ConnectionType::kBluetooth,
                               ConnectionTethering::kUnknown));
   EXPECT_EQ(metrics::ConnectionType::kCellular,
             GetConnectionType(ConnectionType::kCellular,
                               ConnectionTethering::kUnknown));
   EXPECT_EQ(metrics::ConnectionType::kTetheredEthernet,
             GetConnectionType(ConnectionType::kEthernet,
                               ConnectionTethering::kConfirmed));
   EXPECT_EQ(metrics::ConnectionType::kTetheredWifi,
             GetConnectionType(ConnectionType::kWifi,
                               ConnectionTethering::kConfirmed));

   // Ensure that we don't report tethered ethernet unless it's confirmed.
   EXPECT_EQ(metrics::ConnectionType::kEthernet,
             GetConnectionType(ConnectionType::kEthernet,
                               ConnectionTethering::kNotDetected));
   EXPECT_EQ(metrics::ConnectionType::kEthernet,
             GetConnectionType(ConnectionType::kEthernet,
                               ConnectionTethering::kSuspected));
   EXPECT_EQ(metrics::ConnectionType::kEthernet,
             GetConnectionType(ConnectionType::kEthernet,
                               ConnectionTethering::kUnknown));

   // Ditto for tethered wifi.
   EXPECT_EQ(metrics::ConnectionType::kWifi,
             GetConnectionType(ConnectionType::kWifi,
                               ConnectionTethering::kNotDetected));
   EXPECT_EQ(metrics::ConnectionType::kWifi,
             GetConnectionType(ConnectionType::kWifi,
                               ConnectionTethering::kSuspected));
   EXPECT_EQ(metrics::ConnectionType::kWifi,
             GetConnectionType(ConnectionType::kWifi,
                               ConnectionTethering::kUnknown));
 }

 TEST(MetricsUtilsTest, WallclockDurationHelper) {
   FakeSystemState fake_system_state;
   FakeClock fake_clock;
   base::TimeDelta duration;
   const std::string state_variable_key = "test-prefs";
   FakePrefs fake_prefs;

   fake_system_state.set_clock(&fake_clock);
   fake_system_state.set_prefs(&fake_prefs);

   // Initialize wallclock to 1 sec.
   fake_clock.SetWallclockTime(base::Time::FromInternalValue(1000000));

   // First time called so no previous measurement available.
   EXPECT_FALSE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                       state_variable_key,
                                                       &duration));

   // Next time, we should get zero since the clock didn't advance.
   EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                      state_variable_key,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);

   // We can also call it as many times as we want with it being
   // considered a failure.
   EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                      state_variable_key,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);
   EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                      state_variable_key,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);

   // Advance the clock one second, then we should get 1 sec on the
   // next call and 0 sec on the subsequent call.
   fake_clock.SetWallclockTime(base::Time::FromInternalValue(2000000));
   EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                      state_variable_key,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 1);
   EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                      state_variable_key,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);

   // Advance clock two seconds and we should get 2 sec and then 0 sec.
   fake_clock.SetWallclockTime(base::Time::FromInternalValue(4000000));
   EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                      state_variable_key,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 2);
   EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                      state_variable_key,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);

   // There's a possibility that the wallclock can go backwards (NTP
   // adjustments, for example) so check that we properly handle this
   // case.
   fake_clock.SetWallclockTime(base::Time::FromInternalValue(3000000));
   EXPECT_FALSE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                       state_variable_key,
                                                       &duration));
   fake_clock.SetWallclockTime(base::Time::FromInternalValue(4000000));
   EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
                                                      state_variable_key,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 1);
 }

 TEST(MetricsUtilsTest, MonotonicDurationHelper) {
   int64_t storage = 0;
   FakeSystemState fake_system_state;
   FakeClock fake_clock;
   base::TimeDelta duration;

   fake_system_state.set_clock(&fake_clock);

   // Initialize monotonic clock to 1 sec.
   fake_clock.SetMonotonicTime(base::Time::FromInternalValue(1000000));

   // First time called so no previous measurement available.
   EXPECT_FALSE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
                                                       &storage,
                                                       &duration));

   // Next time, we should get zero since the clock didn't advance.
   EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
                                                      &storage,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);

   // We can also call it as many times as we want with it being
   // considered a failure.
   EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
                                                      &storage,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);
   EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
                                                      &storage,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);

   // Advance the clock one second, then we should get 1 sec on the
   // next call and 0 sec on the subsequent call.
   fake_clock.SetMonotonicTime(base::Time::FromInternalValue(2000000));
   EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
                                                      &storage,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 1);
   EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
                                                      &storage,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);

   // Advance clock two seconds and we should get 2 sec and then 0 sec.
   fake_clock.SetMonotonicTime(base::Time::FromInternalValue(4000000));
   EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
                                                      &storage,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 2);
   EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
                                                      &storage,
                                                      &duration));
   EXPECT_EQ(duration.InSeconds(), 0);
 }

 }  // namespace metrics_utils
 }  // namespace chromeos_update_engine
	//
	// Copyright (C) 2015 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/metrics_utils.h"

	#include <gtest/gtest.h>

	#include "update_engine/common/fake_clock.h"
	#include "update_engine/common/fake_prefs.h"
	#include "update_engine/fake_system_state.h"

	namespace chromeos_update_engine {
	namespace metrics_utils {

	class MetricsUtilsTest : public ::testing::Test {};

	TEST(MetricsUtilsTest, GetConnectionType) {
	// Check that expected combinations map to the right value.
	EXPECT_EQ(metrics::ConnectionType::kUnknown,
	GetConnectionType(ConnectionType::kUnknown,
	ConnectionTethering::kUnknown));
	EXPECT_EQ(metrics::ConnectionType::kDisconnected,
	GetConnectionType(ConnectionType::kDisconnected,
	ConnectionTethering::kUnknown));
	EXPECT_EQ(metrics::ConnectionType::kEthernet,
	GetConnectionType(ConnectionType::kEthernet,
	ConnectionTethering::kUnknown));
	EXPECT_EQ(metrics::ConnectionType::kWifi,
	GetConnectionType(ConnectionType::kWifi,
	ConnectionTethering::kUnknown));
	EXPECT_EQ(metrics::ConnectionType::kWimax,
	GetConnectionType(ConnectionType::kWimax,
	ConnectionTethering::kUnknown));
	EXPECT_EQ(metrics::ConnectionType::kBluetooth,
	GetConnectionType(ConnectionType::kBluetooth,
	ConnectionTethering::kUnknown));
	EXPECT_EQ(metrics::ConnectionType::kCellular,
	GetConnectionType(ConnectionType::kCellular,
	ConnectionTethering::kUnknown));
	EXPECT_EQ(metrics::ConnectionType::kTetheredEthernet,
	GetConnectionType(ConnectionType::kEthernet,
	ConnectionTethering::kConfirmed));
	EXPECT_EQ(metrics::ConnectionType::kTetheredWifi,
	GetConnectionType(ConnectionType::kWifi,
	ConnectionTethering::kConfirmed));

	// Ensure that we don't report tethered ethernet unless it's confirmed.
	EXPECT_EQ(metrics::ConnectionType::kEthernet,
	GetConnectionType(ConnectionType::kEthernet,
	ConnectionTethering::kNotDetected));
	EXPECT_EQ(metrics::ConnectionType::kEthernet,
	GetConnectionType(ConnectionType::kEthernet,
	ConnectionTethering::kSuspected));
	EXPECT_EQ(metrics::ConnectionType::kEthernet,
	GetConnectionType(ConnectionType::kEthernet,
	ConnectionTethering::kUnknown));

	// Ditto for tethered wifi.
	EXPECT_EQ(metrics::ConnectionType::kWifi,
	GetConnectionType(ConnectionType::kWifi,
	ConnectionTethering::kNotDetected));
	EXPECT_EQ(metrics::ConnectionType::kWifi,
	GetConnectionType(ConnectionType::kWifi,
	ConnectionTethering::kSuspected));
	EXPECT_EQ(metrics::ConnectionType::kWifi,
	GetConnectionType(ConnectionType::kWifi,
	ConnectionTethering::kUnknown));
	}

	TEST(MetricsUtilsTest, WallclockDurationHelper) {
	FakeSystemState fake_system_state;
	FakeClock fake_clock;
	base::TimeDelta duration;
	const std::string state_variable_key = "test-prefs";
	FakePrefs fake_prefs;

	fake_system_state.set_clock(&fake_clock);
	fake_system_state.set_prefs(&fake_prefs);

	// Initialize wallclock to 1 sec.
	fake_clock.SetWallclockTime(base::Time::FromInternalValue(1000000));

	// First time called so no previous measurement available.
	EXPECT_FALSE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));

	// Next time, we should get zero since the clock didn't advance.
	EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);

	// We can also call it as many times as we want with it being
	// considered a failure.
	EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);
	EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);

	// Advance the clock one second, then we should get 1 sec on the
	// next call and 0 sec on the subsequent call.
	fake_clock.SetWallclockTime(base::Time::FromInternalValue(2000000));
	EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 1);
	EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);

	// Advance clock two seconds and we should get 2 sec and then 0 sec.
	fake_clock.SetWallclockTime(base::Time::FromInternalValue(4000000));
	EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 2);
	EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);

	// There's a possibility that the wallclock can go backwards (NTP
	// adjustments, for example) so check that we properly handle this
	// case.
	fake_clock.SetWallclockTime(base::Time::FromInternalValue(3000000));
	EXPECT_FALSE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));
	fake_clock.SetWallclockTime(base::Time::FromInternalValue(4000000));
	EXPECT_TRUE(metrics_utils::WallclockDurationHelper(&fake_system_state,
	state_variable_key,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 1);
	}

	TEST(MetricsUtilsTest, MonotonicDurationHelper) {
	int64_t storage = 0;
	FakeSystemState fake_system_state;
	FakeClock fake_clock;
	base::TimeDelta duration;

	fake_system_state.set_clock(&fake_clock);

	// Initialize monotonic clock to 1 sec.
	fake_clock.SetMonotonicTime(base::Time::FromInternalValue(1000000));

	// First time called so no previous measurement available.
	EXPECT_FALSE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
	&storage,
	&duration));

	// Next time, we should get zero since the clock didn't advance.
	EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
	&storage,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);

	// We can also call it as many times as we want with it being
	// considered a failure.
	EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
	&storage,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);
	EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
	&storage,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);

	// Advance the clock one second, then we should get 1 sec on the
	// next call and 0 sec on the subsequent call.
	fake_clock.SetMonotonicTime(base::Time::FromInternalValue(2000000));
	EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
	&storage,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 1);
	EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
	&storage,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);

	// Advance clock two seconds and we should get 2 sec and then 0 sec.
	fake_clock.SetMonotonicTime(base::Time::FromInternalValue(4000000));
	EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
	&storage,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 2);
	EXPECT_TRUE(metrics_utils::MonotonicDurationHelper(&fake_system_state,
	&storage,
	&duration));
	EXPECT_EQ(duration.InSeconds(), 0);
	}

	} // namespace metrics_utils
	} // namespace chromeos_update_engine