/** * Copyright © 2020 IBM Corporation * * 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 "action.hpp" #include "chassis.hpp" #include "configuration.hpp" #include "device.hpp" #include "i2c_interface.hpp" #include "id_map.hpp" #include "log_phase_fault_action.hpp" #include "mock_action.hpp" #include "mock_error_logging.hpp" #include "mock_journal.hpp" #include "mock_sensors.hpp" #include "mock_services.hpp" #include "mocked_i2c_interface.hpp" #include "phase_fault.hpp" #include "phase_fault_detection.hpp" #include "presence_detection.hpp" #include "rail.hpp" #include "rule.hpp" #include "sensor_monitoring.hpp" #include "sensors.hpp" #include "services.hpp" #include "system.hpp" #include "test_sdbus_error.hpp" #include "test_utils.hpp" #include #include #include #include #include #include #include using namespace phosphor::power::regulators; using namespace phosphor::power::regulators::test_utils; using ::testing::A; using ::testing::Return; using ::testing::Throw; using ::testing::TypedEq; static const std::string chassisInvPath{ "/xyz/openbmc_project/inventory/system/chassis"}; TEST(SystemTests, Constructor) { // Create Rules std::vector> rules{}; rules.emplace_back(createRule("set_voltage_rule")); // Create Chassis std::vector> chassis{}; std::vector> devices{}; devices.emplace_back(createDevice("reg1", {"rail1"})); chassis.emplace_back( std::make_unique(1, chassisInvPath, std::move(devices))); // Create System System system{std::move(rules), std::move(chassis)}; EXPECT_EQ(system.getChassis().size(), 1); EXPECT_EQ(system.getChassis()[0]->getNumber(), 1); EXPECT_NO_THROW(system.getIDMap().getRule("set_voltage_rule")); EXPECT_NO_THROW(system.getIDMap().getDevice("reg1")); EXPECT_NO_THROW(system.getIDMap().getRail("rail1")); EXPECT_THROW(system.getIDMap().getRail("rail2"), std::invalid_argument); EXPECT_EQ(system.getRules().size(), 1); EXPECT_EQ(system.getRules()[0]->getID(), "set_voltage_rule"); } TEST(SystemTests, ClearCache) { // Create PresenceDetection std::vector> actions{}; auto presenceDetection = std::make_unique(std::move(actions)); PresenceDetection* presenceDetectionPtr = presenceDetection.get(); // Create Device that contains PresenceDetection auto i2cInterface = std::make_unique(); auto device = std::make_unique( "reg1", true, "/xyz/openbmc_project/inventory/system/chassis/motherboard/reg1", std::move(i2cInterface), std::move(presenceDetection)); Device* devicePtr = device.get(); // Create Chassis that contains Device std::vector> devices{}; devices.emplace_back(std::move(device)); auto chassis = std::make_unique(1, chassisInvPath, std::move(devices)); Chassis* chassisPtr = chassis.get(); // Create System that contains Chassis std::vector> rules{}; std::vector> chassisVec{}; chassisVec.emplace_back(std::move(chassis)); System system{std::move(rules), std::move(chassisVec)}; // Cache presence value in PresenceDetection MockServices services{}; presenceDetectionPtr->execute(services, system, *chassisPtr, *devicePtr); EXPECT_TRUE(presenceDetectionPtr->getCachedPresence().has_value()); // Clear cached data in System system.clearCache(); // Verify presence value no longer cached in PresenceDetection EXPECT_FALSE(presenceDetectionPtr->getCachedPresence().has_value()); } TEST(SystemTests, ClearErrorHistory) { // Create SensorMonitoring. Will fail with a DBus exception. auto action = std::make_unique(); EXPECT_CALL(*action, execute) .WillRepeatedly(Throw(TestSDBusError{"Unable to set sensor value"})); std::vector> actions{}; actions.emplace_back(std::move(action)); auto sensorMonitoring = std::make_unique(std::move(actions)); // Create Rail std::unique_ptr configuration{}; auto rail = std::make_unique("vddr1", std::move(configuration), std::move(sensorMonitoring)); // Create Device that contains Rail auto i2cInterface = std::make_unique(); std::unique_ptr presenceDetection{}; std::unique_ptr deviceConfiguration{}; std::unique_ptr phaseFaultDetection{}; std::vector> rails{}; rails.emplace_back(std::move(rail)); auto device = std::make_unique( "reg1", true, "/xyz/openbmc_project/inventory/system/chassis/motherboard/reg1", std::move(i2cInterface), std::move(presenceDetection), std::move(deviceConfiguration), std::move(phaseFaultDetection), std::move(rails)); // Create Chassis that contains Device std::vector> devices{}; devices.emplace_back(std::move(device)); auto chassis = std::make_unique(1, chassisInvPath, std::move(devices)); // Create System that contains Chassis std::vector> rules{}; std::vector> chassisVec{}; chassisVec.emplace_back(std::move(chassis)); System system{std::move(rules), std::move(chassisVec)}; // Create lambda that sets MockServices expectations. The lambda allows // us to set expectations multiple times without duplicate code. auto setExpectations = [](MockServices& services) { // Expect Sensors service to be called 10 times MockSensors& sensors = services.getMockSensors(); EXPECT_CALL(sensors, startRail).Times(10); EXPECT_CALL(sensors, setValue).Times(0); EXPECT_CALL(sensors, endRail).Times(10); // Expect Journal service to be called 6 times to log error messages MockJournal& journal = services.getMockJournal(); EXPECT_CALL(journal, logError(A&>())) .Times(6); EXPECT_CALL(journal, logError(A())).Times(6); // Expect ErrorLogging service to be called once to log a DBus error MockErrorLogging& errorLogging = services.getMockErrorLogging(); EXPECT_CALL(errorLogging, logDBusError).Times(1); }; // Monitor sensors 10 times. Verify errors logged. { // Create mock services. Set expectations via lambda. MockServices services{}; setExpectations(services); for (int i = 1; i <= 10; ++i) { system.monitorSensors(services); } } // Clear error history system.clearErrorHistory(); // Monitor sensors 10 more times. Verify errors logged again. { // Create mock services. Set expectations via lambda. MockServices services{}; setExpectations(services); for (int i = 1; i <= 10; ++i) { system.monitorSensors(services); } } } TEST(SystemTests, CloseDevices) { // Specify an empty rules vector std::vector> rules{}; // Create mock services. Expect logDebug() to be called. MockServices services{}; MockJournal& journal = services.getMockJournal(); EXPECT_CALL(journal, logDebug("Closing devices in chassis 1")).Times(1); EXPECT_CALL(journal, logDebug("Closing devices in chassis 3")).Times(1); EXPECT_CALL(journal, logInfo(A())).Times(0); EXPECT_CALL(journal, logError(A())).Times(0); // Create Chassis std::vector> chassis{}; chassis.emplace_back(std::make_unique(1, chassisInvPath + '1')); chassis.emplace_back(std::make_unique(3, chassisInvPath + '3')); // Create System System system{std::move(rules), std::move(chassis)}; // Call closeDevices() system.closeDevices(services); } TEST(SystemTests, Configure) { // Create mock services. Expect logInfo() to be called. MockServices services{}; MockJournal& journal = services.getMockJournal(); EXPECT_CALL(journal, logInfo("Configuring chassis 1")).Times(1); EXPECT_CALL(journal, logInfo("Configuring chassis 3")).Times(1); EXPECT_CALL(journal, logDebug(A())).Times(0); EXPECT_CALL(journal, logError(A())).Times(0); // Specify an empty rules vector std::vector> rules{}; // Create Chassis std::vector> chassis{}; chassis.emplace_back(std::make_unique(1, chassisInvPath + '1')); chassis.emplace_back(std::make_unique(3, chassisInvPath + '3')); // Create System System system{std::move(rules), std::move(chassis)}; // Call configure() system.configure(services); } TEST(SystemTests, DetectPhaseFaults) { // Create mock services with the following expectations: // - 2 error messages in journal for N phase fault detected in reg0 // - 2 error messages in journal for N phase fault detected in reg1 // - 1 N phase fault error logged for reg0 // - 1 N phase fault error logged for reg1 MockServices services{}; MockJournal& journal = services.getMockJournal(); EXPECT_CALL(journal, logError("n phase fault detected in regulator reg0: count=1")) .Times(1); EXPECT_CALL(journal, logError("n phase fault detected in regulator reg0: count=2")) .Times(1); EXPECT_CALL(journal, logError("n phase fault detected in regulator reg1: count=1")) .Times(1); EXPECT_CALL(journal, logError("n phase fault detected in regulator reg1: count=2")) .Times(1); MockErrorLogging& errorLogging = services.getMockErrorLogging(); EXPECT_CALL(errorLogging, logPhaseFault).Times(2); std::vector> chassisVec{}; // Create Chassis 1 with regulator reg0 { // Create PhaseFaultDetection auto action = std::make_unique(PhaseFaultType::n); std::vector> actions{}; actions.push_back(std::move(action)); auto phaseFaultDetection = std::make_unique(std::move(actions)); // Create Device auto i2cInterface = std::make_unique(); std::unique_ptr presenceDetection{}; std::unique_ptr configuration{}; auto device = std::make_unique( "reg0", true, "/xyz/openbmc_project/inventory/system/chassis1/motherboard/" "reg0", std::move(i2cInterface), std::move(presenceDetection), std::move(configuration), std::move(phaseFaultDetection)); // Create Chassis std::vector> devices{}; devices.emplace_back(std::move(device)); auto chassis = std::make_unique(1, chassisInvPath + '1', std::move(devices)); chassisVec.emplace_back(std::move(chassis)); } // Create Chassis 2 with regulator reg1 { // Create PhaseFaultDetection auto action = std::make_unique(PhaseFaultType::n); std::vector> actions{}; actions.push_back(std::move(action)); auto phaseFaultDetection = std::make_unique(std::move(actions)); // Create Device auto i2cInterface = std::make_unique(); std::unique_ptr presenceDetection{}; std::unique_ptr configuration{}; auto device = std::make_unique( "reg1", true, "/xyz/openbmc_project/inventory/system/chassis2/motherboard/" "reg1", std::move(i2cInterface), std::move(presenceDetection), std::move(configuration), std::move(phaseFaultDetection)); // Create Chassis std::vector> devices{}; devices.emplace_back(std::move(device)); auto chassis = std::make_unique(2, chassisInvPath + '2', std::move(devices)); chassisVec.emplace_back(std::move(chassis)); } // Create System that contains Chassis std::vector> rules{}; System system{std::move(rules), std::move(chassisVec)}; // Call detectPhaseFaults() 5 times for (int i = 1; i <= 5; ++i) { system.detectPhaseFaults(services); } } TEST(SystemTests, GetChassis) { // Specify an empty rules vector std::vector> rules{}; // Create Chassis std::vector> chassis{}; chassis.emplace_back(std::make_unique(1, chassisInvPath + '1')); chassis.emplace_back(std::make_unique(3, chassisInvPath + '3')); // Create System System system{std::move(rules), std::move(chassis)}; EXPECT_EQ(system.getChassis().size(), 2); EXPECT_EQ(system.getChassis()[0]->getNumber(), 1); EXPECT_EQ(system.getChassis()[1]->getNumber(), 3); } TEST(SystemTests, GetIDMap) { // Create Rules std::vector> rules{}; rules.emplace_back(createRule("set_voltage_rule")); rules.emplace_back(createRule("read_sensors_rule")); // Create Chassis std::vector> chassis{}; { // Chassis 1 std::vector> devices{}; devices.emplace_back(createDevice("reg1", {"rail1"})); devices.emplace_back(createDevice("reg2", {"rail2a", "rail2b"})); chassis.emplace_back(std::make_unique(1, chassisInvPath + '1', std::move(devices))); } { // Chassis 2 std::vector> devices{}; devices.emplace_back(createDevice("reg3", {"rail3a", "rail3b"})); devices.emplace_back(createDevice("reg4")); chassis.emplace_back(std::make_unique(2, chassisInvPath + '2', std::move(devices))); } // Create System System system{std::move(rules), std::move(chassis)}; const IDMap& idMap = system.getIDMap(); // Verify all Rules are in the IDMap EXPECT_NO_THROW(idMap.getRule("set_voltage_rule")); EXPECT_NO_THROW(idMap.getRule("read_sensors_rule")); EXPECT_THROW(idMap.getRule("set_voltage_rule2"), std::invalid_argument); // Verify all Devices are in the IDMap EXPECT_NO_THROW(idMap.getDevice("reg1")); EXPECT_NO_THROW(idMap.getDevice("reg2")); EXPECT_NO_THROW(idMap.getDevice("reg3")); EXPECT_NO_THROW(idMap.getDevice("reg4")); EXPECT_THROW(idMap.getDevice("reg5"), std::invalid_argument); // Verify all Rails are in the IDMap EXPECT_NO_THROW(idMap.getRail("rail1")); EXPECT_NO_THROW(idMap.getRail("rail2a")); EXPECT_NO_THROW(idMap.getRail("rail2b")); EXPECT_NO_THROW(idMap.getRail("rail3a")); EXPECT_NO_THROW(idMap.getRail("rail3b")); EXPECT_THROW(idMap.getRail("rail4"), std::invalid_argument); } TEST(SystemTests, GetRules) { // Create Rules std::vector> rules{}; rules.emplace_back(createRule("set_voltage_rule")); rules.emplace_back(createRule("read_sensors_rule")); // Create Chassis std::vector> chassis{}; chassis.emplace_back(std::make_unique(1, chassisInvPath)); // Create System System system{std::move(rules), std::move(chassis)}; EXPECT_EQ(system.getRules().size(), 2); EXPECT_EQ(system.getRules()[0]->getID(), "set_voltage_rule"); EXPECT_EQ(system.getRules()[1]->getID(), "read_sensors_rule"); } TEST(SystemTests, MonitorSensors) { // Create mock services. Set Sensors service expectations. MockServices services{}; MockSensors& sensors = services.getMockSensors(); EXPECT_CALL(sensors, startRail("c1_vdd0", "/xyz/openbmc_project/inventory/system/" "chassis1/motherboard/vdd0_reg", chassisInvPath + '1')) .Times(1); EXPECT_CALL(sensors, startRail("c2_vdd0", "/xyz/openbmc_project/inventory/system/" "chassis2/motherboard/vdd0_reg", chassisInvPath + '2')) .Times(1); EXPECT_CALL(sensors, setValue).Times(0); EXPECT_CALL(sensors, endRail(false)).Times(2); std::vector> chassisVec{}; // Create Chassis 1 { // Create SensorMonitoring for Rail auto action = std::make_unique(); EXPECT_CALL(*action, execute).Times(1).WillOnce(Return(true)); std::vector> actions{}; actions.emplace_back(std::move(action)); auto sensorMonitoring = std::make_unique(std::move(actions)); // Create Rail std::unique_ptr configuration{}; auto rail = std::make_unique("c1_vdd0", std::move(configuration), std::move(sensorMonitoring)); // Create Device auto i2cInterface = std::make_unique(); std::unique_ptr presenceDetection{}; std::unique_ptr deviceConfiguration{}; std::unique_ptr phaseFaultDetection{}; std::vector> rails{}; rails.emplace_back(std::move(rail)); auto device = std::make_unique( "c1_vdd0_reg", true, "/xyz/openbmc_project/inventory/system/chassis1/motherboard/" "vdd0_reg", std::move(i2cInterface), std::move(presenceDetection), std::move(deviceConfiguration), std::move(phaseFaultDetection), std::move(rails)); // Create Chassis std::vector> devices{}; devices.emplace_back(std::move(device)); auto chassis = std::make_unique(1, chassisInvPath + '1', std::move(devices)); chassisVec.emplace_back(std::move(chassis)); } // Create Chassis 2 { // Create SensorMonitoring for Rail auto action = std::make_unique(); EXPECT_CALL(*action, execute).Times(1).WillOnce(Return(true)); std::vector> actions{}; actions.emplace_back(std::move(action)); auto sensorMonitoring = std::make_unique(std::move(actions)); // Create Rail std::unique_ptr configuration{}; auto rail = std::make_unique("c2_vdd0", std::move(configuration), std::move(sensorMonitoring)); // Create Device auto i2cInterface = std::make_unique(); std::unique_ptr presenceDetection{}; std::unique_ptr deviceConfiguration{}; std::unique_ptr phaseFaultDetection{}; std::vector> rails{}; rails.emplace_back(std::move(rail)); auto device = std::make_unique( "c2_vdd0_reg", true, "/xyz/openbmc_project/inventory/system/chassis2/motherboard/" "vdd0_reg", std::move(i2cInterface), std::move(presenceDetection), std::move(deviceConfiguration), std::move(phaseFaultDetection), std::move(rails)); // Create Chassis std::vector> devices{}; devices.emplace_back(std::move(device)); auto chassis = std::make_unique(2, chassisInvPath + '2', std::move(devices)); chassisVec.emplace_back(std::move(chassis)); } // Create System that contains Chassis std::vector> rules{}; System system{std::move(rules), std::move(chassisVec)}; // Call monitorSensors() system.monitorSensors(services); }