#include "../power_supply.hpp" #include "../record_manager.hpp" #include "mock.hpp" #include #include #include #include using namespace phosphor::power::psu; using namespace phosphor::pmbus; using ::testing::_; using ::testing::Args; using ::testing::Assign; using ::testing::DoAll; using ::testing::ElementsAre; using ::testing::NotNull; using ::testing::Return; using ::testing::StrEq; static auto PSUInventoryPath = "/xyz/bmc/inv/sys/chassis/board/powersupply0"; static auto PSUGPIOLineName = "presence-ps0"; struct PMBusExpectations { uint16_t statusWordValue{0x0000}; uint8_t statusInputValue{0x00}; uint8_t statusMFRValue{0x00}; uint8_t statusCMLValue{0x00}; uint8_t statusVOUTValue{0x00}; uint8_t statusIOUTValue{0x00}; uint8_t statusFans12Value{0x00}; uint8_t statusTempValue{0x00}; }; // Helper function to setup expectations for various STATUS_* commands void setPMBusExpectations(MockedPMBus& mockPMBus, const PMBusExpectations& expectations) { EXPECT_CALL(mockPMBus, read(STATUS_WORD, _, _)) .Times(1) .WillOnce(Return(expectations.statusWordValue)); if (expectations.statusWordValue != 0) { // If fault bits are on in STATUS_WORD, there will also be a read of // STATUS_INPUT, STATUS_MFR, STATUS_CML, STATUS_VOUT (page 0), and // STATUS_TEMPERATURE. EXPECT_CALL(mockPMBus, read(STATUS_INPUT, _, _)) .Times(1) .WillOnce(Return(expectations.statusInputValue)); EXPECT_CALL(mockPMBus, read(STATUS_MFR, _, _)) .Times(1) .WillOnce(Return(expectations.statusMFRValue)); EXPECT_CALL(mockPMBus, read(STATUS_CML, _, _)) .Times(1) .WillOnce(Return(expectations.statusCMLValue)); // Page will need to be set to 0 to read STATUS_VOUT. EXPECT_CALL(mockPMBus, insertPageNum(STATUS_VOUT, 0)) .Times(1) .WillOnce(Return("status0_vout")); EXPECT_CALL(mockPMBus, read("status0_vout", _, _)) .Times(1) .WillOnce(Return(expectations.statusVOUTValue)); EXPECT_CALL(mockPMBus, read(STATUS_IOUT, _, _)) .Times(1) .WillOnce(Return(expectations.statusIOUTValue)); EXPECT_CALL(mockPMBus, read(STATUS_FANS_1_2, _, _)) .Times(1) .WillOnce(Return(expectations.statusFans12Value)); EXPECT_CALL(mockPMBus, read(STATUS_TEMPERATURE, _, _)) .Times(1) .WillOnce(Return(expectations.statusTempValue)); } } class PowerSupplyTests : public ::testing::Test { public: PowerSupplyTests() : mockedUtil(reinterpret_cast(getUtils())) { ON_CALL(mockedUtil, getPresence(_, _)).WillByDefault(Return(false)); } ~PowerSupplyTests() override { freeUtils(); } const MockedUtil& mockedUtil; }; // Helper function for when a power supply goes from missing to present. void setMissingToPresentExpects(MockedPMBus& pmbus, const MockedUtil& util) { // Call to analyze() will update to present, that will trigger updating // to the correct/latest HWMON directory, in case it changes. EXPECT_CALL(pmbus, findHwmonDir()); // Presence change from missing to present will trigger write to // ON_OFF_CONFIG. EXPECT_CALL(pmbus, writeBinary(ON_OFF_CONFIG, _, _)); // Presence change from missing to present will trigger in1_input read // in an attempt to get CLEAR_FAULTS called. // This READ_VIN for CLEAR_FAULTS does not check the returned value. EXPECT_CALL(pmbus, read(READ_VIN, _, _)).Times(1).WillOnce(Return(1)); // The call for clearing faults includes clearing VIN_UV fault. // The voltage defaults to 0, the first call to analyze should update the // voltage to the current reading, triggering clearing VIN_UV fault(s) // due to below minimum to within range voltage. EXPECT_CALL(pmbus, read("in1_lcrit_alarm", _, _)) .Times(2) .WillRepeatedly(Return(1)); // Missing/present call will update Presence in inventory. EXPECT_CALL(util, setPresence(_, _, true, _)); } TEST_F(PowerSupplyTests, Constructor) { /** * @param[in] invpath - String for inventory path to use * @param[in] i2cbus - The bus number this power supply is on * @param[in] i2caddr - The 16-bit I2C address of the power supply * @param[in] gpioLineName - The string for the gpio-line-name to read for * presence. * @param[in] bindDelay - Time in milliseconds to delay binding the device * driver after seeing the presence line go active. */ auto bus = sdbusplus::bus::new_default(); // Try where inventory path is empty, constructor should fail. try { auto psu = std::make_unique(bus, "", 3, 0x68, "ibm-cffps", PSUGPIOLineName); ADD_FAILURE() << "Should not have reached this line."; } catch (const std::invalid_argument& e) { EXPECT_STREQ(e.what(), "Invalid empty inventoryPath"); } catch (...) { ADD_FAILURE() << "Should not have caught exception."; } // TODO: Try invalid i2c address? // Try where gpioLineName is empty. try { auto psu = std::make_unique(bus, PSUInventoryPath, 3, 0x68, "ibm-cffps", ""); ADD_FAILURE() << "Should not have reached this line. Invalid gpioLineName."; } catch (const std::invalid_argument& e) { EXPECT_STREQ(e.what(), "Invalid empty gpioLineName"); } catch (...) { ADD_FAILURE() << "Should not have caught exception."; } // Test with valid arguments // NOT using D-Bus inventory path for presence. try { auto psu = std::make_unique(bus, PSUInventoryPath, 3, 0x68, "ibm-cffps", PSUGPIOLineName); EXPECT_EQ(psu->isPresent(), false); EXPECT_EQ(psu->isFaulted(), false); EXPECT_EQ(psu->hasCommFault(), false); EXPECT_EQ(psu->hasInputFault(), false); EXPECT_EQ(psu->hasMFRFault(), false); EXPECT_EQ(psu->hasVINUVFault(), false); EXPECT_EQ(psu->hasVoutOVFault(), false); EXPECT_EQ(psu->hasIoutOCFault(), false); EXPECT_EQ(psu->hasVoutUVFault(), false); EXPECT_EQ(psu->hasFanFault(), false); EXPECT_EQ(psu->hasTempFault(), false); EXPECT_EQ(psu->hasPgoodFault(), false); EXPECT_EQ(psu->hasPSKillFault(), false); EXPECT_EQ(psu->hasPS12VcsFault(), false); EXPECT_EQ(psu->hasPSCS12VFault(), false); } catch (...) { ADD_FAILURE() << "Should not have caught exception."; } // Test with valid arguments // TODO: Using D-Bus inventory path for presence. try { // FIXME: How do I get that presenceGPIO.read() in the startup to throw // an exception? // EXPECT_CALL(mockedUtil, getPresence(_, // StrEq(PSUInventoryPath))) // .Times(1); } catch (...) { ADD_FAILURE() << "Should not have caught exception."; } } TEST_F(PowerSupplyTests, Analyze) { auto bus = sdbusplus::bus::new_default(); { // If I default to reading the GPIO, I will NOT expect a call to // getPresence(). PowerSupply psu{bus, PSUInventoryPath, 4, 0x69, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); EXPECT_CALL(*mockPresenceGPIO, read()).Times(1).WillOnce(Return(0)); psu.analyze(); // By default, nothing should change. EXPECT_EQ(psu.isPresent(), false); EXPECT_EQ(psu.isFaulted(), false); EXPECT_EQ(psu.hasInputFault(), false); EXPECT_EQ(psu.hasMFRFault(), false); EXPECT_EQ(psu.hasVINUVFault(), false); EXPECT_EQ(psu.hasCommFault(), false); EXPECT_EQ(psu.hasVoutOVFault(), false); EXPECT_EQ(psu.hasIoutOCFault(), false); EXPECT_EQ(psu.hasVoutUVFault(), false); EXPECT_EQ(psu.hasFanFault(), false); EXPECT_EQ(psu.hasTempFault(), false); EXPECT_EQ(psu.hasPgoodFault(), false); EXPECT_EQ(psu.hasPSKillFault(), false); EXPECT_EQ(psu.hasPS12VcsFault(), false); EXPECT_EQ(psu.hasPSCS12VFault(), false); } PowerSupply psu2{bus, PSUInventoryPath, 5, 0x6a, "ibm-cffps", PSUGPIOLineName}; // In order to get the various faults tested, the power supply needs to // be present in order to read from the PMBus device(s). MockedGPIOInterface* mockPresenceGPIO2 = static_cast(psu2.getPresenceGPIO()); // Always return 1 to indicate present. // Each analyze() call will trigger a read of the presence GPIO. EXPECT_CALL(*mockPresenceGPIO2, read()).WillRepeatedly(Return(1)); EXPECT_EQ(psu2.isPresent(), false); MockedPMBus& mockPMBus = static_cast(psu2.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD INPUT fault. { // Start with STATUS_WORD 0x0000. Powered on, no faults. // Set expectations for a no fault PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // After reading STATUS_WORD, etc., there will be a READ_VIN check. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("206000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), false); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), false); EXPECT_EQ(psu2.hasPSKillFault(), false); EXPECT_EQ(psu2.hasPS12VcsFault(), false); EXPECT_EQ(psu2.hasPSCS12VFault(), false); // Update expectations for STATUS_WORD input fault/warn // STATUS_INPUT fault bits ... on. expectations.statusWordValue = (status_word::INPUT_FAULT_WARN); // IIN_OC fault. expectations.statusInputValue = 0x04; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("207000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); // Should not be faulted until it reaches the deglitch limit. EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), false); EXPECT_EQ(psu2.hasPSKillFault(), false); EXPECT_EQ(psu2.hasPS12VcsFault(), false); EXPECT_EQ(psu2.hasPSCS12VFault(), false); } } EXPECT_CALL(mockPMBus, read(READ_VIN, _, _)).Times(1).WillOnce(Return(1)); EXPECT_CALL(mockPMBus, read("in1_lcrit_alarm", _, _)) .Times(1) .WillOnce(Return(1)); psu2.clearFaults(); // STATUS_WORD INPUT/UV fault. { // First need it to return good status, then the fault PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208000")); psu2.analyze(); EXPECT_EQ(psu2.isFaulted(), false); EXPECT_EQ(psu2.hasInputFault(), false); // Now set fault bits in STATUS_WORD expectations.statusWordValue = (status_word::INPUT_FAULT_WARN | status_word::VIN_UV_FAULT); // STATUS_INPUT fault bits ... on. expectations.statusInputValue = 0x18; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); // Input/UV fault, so voltage should read back low. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("19123")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); // Only faulted if hit deglitch limit EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasVINUVFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), false); EXPECT_EQ(psu2.hasPSKillFault(), false); EXPECT_EQ(psu2.hasPS12VcsFault(), false); EXPECT_EQ(psu2.hasPSCS12VFault(), false); } // Turning VIN_UV fault off causes clearing of faults, causing read of // in1_input as an attempt to get CLEAR_FAULTS called. expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); // The call to read the voltage EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209000")); // The call to clear VIN_UV/Off fault(s) EXPECT_CALL(mockPMBus, read("in1_lcrit_alarm", _, _)) .Times(1) .WillOnce(Return(1)); psu2.analyze(); // Should remain present, no longer be faulted, no input fault, no // VIN_UV fault. Nothing else should change. EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), false); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); } EXPECT_CALL(mockPMBus, read(READ_VIN, _, _)).Times(1).WillOnce(Return(1)); EXPECT_CALL(mockPMBus, read("in1_lcrit_alarm", _, _)) .Times(1) .WillOnce(Return(1)); psu2.clearFaults(); // STATUS_WORD MFR fault. { // First need it to return good status, then the fault PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("210000")); psu2.analyze(); // Now STATUS_WORD with MFR fault bit on. expectations.statusWordValue = (status_word::MFR_SPECIFIC_FAULT); // STATUS_MFR bits on. expectations.statusMFRValue = 0xFF; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("211000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasMFRFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasPSKillFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasPS12VcsFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasPSCS12VFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), false); } } EXPECT_CALL(mockPMBus, read(READ_VIN, _, _)).Times(1).WillOnce(Return(1)); EXPECT_CALL(mockPMBus, read("in1_lcrit_alarm", _, _)) .Times(1) .WillOnce(Return(1)); psu2.clearFaults(); // Temperature fault. { // First STATUS_WORD with no bits set, then with temperature fault. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("212000")); psu2.analyze(); // STATUS_WORD with temperature fault bit on. expectations.statusWordValue = (status_word::TEMPERATURE_FAULT_WARN); // STATUS_TEMPERATURE with fault bit(s) on. expectations.statusTempValue = 0x10; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("213000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasPgoodFault(), false); EXPECT_EQ(psu2.hasPSKillFault(), false); EXPECT_EQ(psu2.hasPS12VcsFault(), false); EXPECT_EQ(psu2.hasPSCS12VFault(), false); } } EXPECT_CALL(mockPMBus, read(READ_VIN, _, _)).Times(1).WillOnce(Return(1)); EXPECT_CALL(mockPMBus, read("in1_lcrit_alarm", _, _)) .Times(1) .WillOnce(Return(1)); psu2.clearFaults(); // CML fault { // First STATUS_WORD wit no bits set, then with CML fault. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("214000")); psu2.analyze(); // STATUS_WORD with CML fault bit on. expectations.statusWordValue = (status_word::CML_FAULT); // Turn on STATUS_CML fault bit(s) expectations.statusCMLValue = 0xFF; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("215000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasCommFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), false); EXPECT_EQ(psu2.hasPSKillFault(), false); EXPECT_EQ(psu2.hasPS12VcsFault(), false); EXPECT_EQ(psu2.hasPSCS12VFault(), false); } } EXPECT_CALL(mockPMBus, read(READ_VIN, _, _)).Times(1).WillOnce(Return(1)); EXPECT_CALL(mockPMBus, read("in1_lcrit_alarm", _, _)) .Times(1) .WillOnce(Return(1)); psu2.clearFaults(); // VOUT_OV_FAULT fault { // First STATUS_WORD with no bits set, then with VOUT/VOUT_OV fault. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("216000")); psu2.analyze(); // STATUS_WORD with VOUT/VOUT_OV fault. expectations.statusWordValue = ((status_word::VOUT_FAULT) | (status_word::VOUT_OV_FAULT)); // Turn on STATUS_VOUT fault bit(s) expectations.statusVOUTValue = 0xA0; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { // STATUS_TEMPERATURE don't care (default) setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("217000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), false); EXPECT_EQ(psu2.hasPSKillFault(), false); EXPECT_EQ(psu2.hasPS12VcsFault(), false); EXPECT_EQ(psu2.hasPSCS12VFault(), false); } } // IOUT_OC_FAULT fault { // First STATUS_WORD with no bits set, then with IOUT_OC fault. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("218000")); psu2.analyze(); // STATUS_WORD with IOUT_OC fault. expectations.statusWordValue = status_word::IOUT_OC_FAULT; // Turn on STATUS_IOUT fault bit(s) expectations.statusIOUTValue = 0x88; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("219000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), false); EXPECT_EQ(psu2.hasPSKillFault(), false); EXPECT_EQ(psu2.hasPS12VcsFault(), false); EXPECT_EQ(psu2.hasPSCS12VFault(), false); } } // VOUT_UV_FAULT { // First STATUS_WORD with no bits set, then with VOUT fault. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("220000")); psu2.analyze(); // Change STATUS_WORD to indicate VOUT fault. expectations.statusWordValue = (status_word::VOUT_FAULT); // Turn on STATUS_VOUT fault bit(s) expectations.statusVOUTValue = 0x30; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("221000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasVoutUVFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), false); EXPECT_EQ(psu2.hasPSKillFault(), false); EXPECT_EQ(psu2.hasPS12VcsFault(), false); EXPECT_EQ(psu2.hasPSCS12VFault(), false); } } // Fan fault { // First STATUS_WORD with no bits set, then with fan fault. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("222000")); psu2.analyze(); expectations.statusWordValue = (status_word::FAN_FAULT); // STATUS_FANS_1_2 with fan 1 warning & fault bits on. expectations.statusFans12Value = 0xA0; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("223000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasFanFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), false); EXPECT_EQ(psu2.hasPSKillFault(), false); EXPECT_EQ(psu2.hasPS12VcsFault(), false); EXPECT_EQ(psu2.hasPSCS12VFault(), false); } } // PGOOD/OFF fault. Deglitched, needs to reach DEGLITCH_LIMIT. { // First STATUS_WORD with no bits set. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("123000")); psu2.analyze(); EXPECT_EQ(psu2.isFaulted(), false); // POWER_GOOD# inactive, and OFF bit on. expectations.statusWordValue = ((status_word::POWER_GOOD_NEGATED) | (status_word::UNIT_IS_OFF)); for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { // STATUS_INPUT, STATUS_MFR, STATUS_CML, STATUS_VOUT, and // STATUS_TEMPERATURE: Don't care if bits set or not (defaults). setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("124000")); psu2.analyze(); EXPECT_EQ(psu2.isPresent(), true); EXPECT_EQ(psu2.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu2.hasInputFault(), false); EXPECT_EQ(psu2.hasMFRFault(), false); EXPECT_EQ(psu2.hasVINUVFault(), false); EXPECT_EQ(psu2.hasCommFault(), false); EXPECT_EQ(psu2.hasVoutOVFault(), false); EXPECT_EQ(psu2.hasVoutUVFault(), false); EXPECT_EQ(psu2.hasIoutOCFault(), false); EXPECT_EQ(psu2.hasFanFault(), false); EXPECT_EQ(psu2.hasTempFault(), false); EXPECT_EQ(psu2.hasPgoodFault(), x >= DEGLITCH_LIMIT); } } // TODO: ReadFailure } TEST_F(PowerSupplyTests, OnOffConfig) { auto bus = sdbusplus::bus::new_default(); uint8_t data = 0x15; // Test where PSU is NOT present try { // Assume GPIO presence, not inventory presence? EXPECT_CALL(mockedUtil, setAvailable(_, _, _)).Times(0); PowerSupply psu{bus, PSUInventoryPath, 4, 0x69, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); ON_CALL(*mockPresenceGPIO, read()).WillByDefault(Return(0)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); // Constructor should set initial presence, default read returns 0. // If it is not present, I should not be trying to write to it. EXPECT_CALL(mockPMBus, writeBinary(_, _, _)).Times(0); psu.onOffConfig(data); } catch (...) {} // Test where PSU is present try { // Assume GPIO presence, not inventory presence? EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); PowerSupply psu{bus, PSUInventoryPath, 5, 0x6a, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // There will potentially be multiple calls, we want it to continue // returning 1 for the GPIO read to keep the power supply present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // If I am calling analyze(), I should probably give it good data. // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("205000")); psu.analyze(); // I definitely should be writting ON_OFF_CONFIG if I call the function EXPECT_CALL(mockPMBus, writeBinary(ON_OFF_CONFIG, ElementsAre(0x15), Type::HwmonDeviceDebug)) .Times(1); psu.onOffConfig(data); } catch (...) {} } TEST_F(PowerSupplyTests, ClearFaults) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 13, 0x68, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. // Each analyze() call will trigger a read of the presence GPIO. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("207000")); psu.analyze(); EXPECT_EQ(psu.isPresent(), true); EXPECT_EQ(psu.isFaulted(), false); EXPECT_EQ(psu.hasInputFault(), false); EXPECT_EQ(psu.hasMFRFault(), false); EXPECT_EQ(psu.hasVINUVFault(), false); EXPECT_EQ(psu.hasCommFault(), false); EXPECT_EQ(psu.hasVoutOVFault(), false); EXPECT_EQ(psu.hasIoutOCFault(), false); EXPECT_EQ(psu.hasVoutUVFault(), false); EXPECT_EQ(psu.hasFanFault(), false); EXPECT_EQ(psu.hasTempFault(), false); EXPECT_EQ(psu.hasPgoodFault(), false); EXPECT_EQ(psu.hasPSKillFault(), false); EXPECT_EQ(psu.hasPS12VcsFault(), false); EXPECT_EQ(psu.hasPSCS12VFault(), false); // STATUS_WORD with fault bits galore! expectations.statusWordValue = 0xFFFF; // STATUS_INPUT with fault bits on. expectations.statusInputValue = 0xFF; // STATUS_MFR_SPEFIC with bits on. expectations.statusMFRValue = 0xFF; // STATUS_CML with bits on. expectations.statusCMLValue = 0xFF; // STATUS_VOUT with bits on. expectations.statusVOUTValue = 0xFF; // STATUS_IOUT with bits on. expectations.statusIOUTValue = 0xFF; // STATUS_FANS_1_2 with bits on. expectations.statusFans12Value = 0xFF; // STATUS_TEMPERATURE with bits on. expectations.statusTempValue = 0xFF; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("0")); if (x == DEGLITCH_LIMIT) { EXPECT_CALL(mockedUtil, setAvailable(_, _, false)); } psu.analyze(); EXPECT_EQ(psu.isPresent(), true); // Cannot have VOUT_OV_FAULT and VOUT_UV_FAULT. // Rely on HasVoutUVFault() to verify this sets and clears. EXPECT_EQ(psu.hasVoutUVFault(), false); // All faults are deglitched up to DEGLITCH_LIMIT EXPECT_EQ(psu.isFaulted(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasInputFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasMFRFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasVINUVFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasCommFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasVoutOVFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasIoutOCFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasFanFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasTempFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasPgoodFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasPSKillFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasPS12VcsFault(), x >= DEGLITCH_LIMIT); EXPECT_EQ(psu.hasPSCS12VFault(), x >= DEGLITCH_LIMIT); } EXPECT_CALL(mockPMBus, read(READ_VIN, _, _)) .Times(1) .WillOnce(Return(207000)); // Clearing VIN_UV fault via in1_lcrit_alarm EXPECT_CALL(mockPMBus, read("in1_lcrit_alarm", _, _)) .Times(1) .WillOnce(Return(1)); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); psu.clearFaults(); EXPECT_EQ(psu.isPresent(), true); EXPECT_EQ(psu.isFaulted(), false); EXPECT_EQ(psu.hasInputFault(), false); EXPECT_EQ(psu.hasMFRFault(), false); EXPECT_EQ(psu.hasVINUVFault(), false); EXPECT_EQ(psu.hasCommFault(), false); EXPECT_EQ(psu.hasVoutOVFault(), false); EXPECT_EQ(psu.hasIoutOCFault(), false); EXPECT_EQ(psu.hasVoutUVFault(), false); EXPECT_EQ(psu.hasFanFault(), false); EXPECT_EQ(psu.hasTempFault(), false); EXPECT_EQ(psu.hasPgoodFault(), false); EXPECT_EQ(psu.hasPSKillFault(), false); EXPECT_EQ(psu.hasPS12VcsFault(), false); EXPECT_EQ(psu.hasPSCS12VFault(), false); // Faults clear on READ_VIN 0 -> !0 // STATUS_WORD with fault bits galore! expectations.statusWordValue = 0xFFFF; // STATUS_INPUT with fault bits on. expectations.statusInputValue = 0xFF; // STATUS_MFR_SPEFIC with bits on. expectations.statusMFRValue = 0xFF; // STATUS_CML with bits on. expectations.statusCMLValue = 0xFF; // STATUS_VOUT with bits on. expectations.statusVOUTValue = 0xFF; // STATUS_IOUT with bits on. expectations.statusIOUTValue = 0xFF; // STATUS_FANS_1_2 with bits on. expectations.statusFans12Value = 0xFF; // STATUS_TEMPERATURE with bits on. expectations.statusTempValue = 0xFF; // All faults degltiched now. Check for false before limit above. for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("0")); if (x == DEGLITCH_LIMIT) { EXPECT_CALL(mockedUtil, setAvailable(_, _, false)); } psu.analyze(); } EXPECT_EQ(psu.isPresent(), true); EXPECT_EQ(psu.isFaulted(), true); EXPECT_EQ(psu.hasInputFault(), true); EXPECT_EQ(psu.hasMFRFault(), true); EXPECT_EQ(psu.hasVINUVFault(), true); // True due to CML fault bits on EXPECT_EQ(psu.hasCommFault(), true); EXPECT_EQ(psu.hasVoutOVFault(), true); EXPECT_EQ(psu.hasIoutOCFault(), true); // Cannot have VOUT_OV_FAULT and VOUT_UV_FAULT. // Rely on HasVoutUVFault() to verify this sets and clears. EXPECT_EQ(psu.hasVoutUVFault(), false); EXPECT_EQ(psu.hasFanFault(), true); EXPECT_EQ(psu.hasTempFault(), true); EXPECT_EQ(psu.hasPgoodFault(), true); EXPECT_EQ(psu.hasPSKillFault(), true); EXPECT_EQ(psu.hasPS12VcsFault(), true); EXPECT_EQ(psu.hasPSCS12VFault(), true); // STATUS_WORD with INPUT/VIN_UV fault bits off. expectations.statusWordValue = 0xDFF7; // STATUS_INPUT with VIN_UV_WARNING, VIN_UV_FAULT, and Unit Off For // Insufficient Input Voltage bits off. expectations.statusInputValue = 0xC7; setPMBusExpectations(mockPMBus, expectations); // READ_VIN back in range. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("206000")); // VIN_UV cleared via in1_lcrit_alarm when voltage back in range. EXPECT_CALL(mockPMBus, read("in1_lcrit_alarm", _, _)) .Times(1) .WillOnce(Return(1)); psu.analyze(); // We only cleared the VIN_UV and OFF faults. EXPECT_EQ(psu.isPresent(), true); EXPECT_EQ(psu.isFaulted(), true); EXPECT_EQ(psu.hasInputFault(), false); EXPECT_EQ(psu.hasMFRFault(), true); EXPECT_EQ(psu.hasVINUVFault(), false); EXPECT_EQ(psu.hasCommFault(), true); EXPECT_EQ(psu.hasVoutOVFault(), true); EXPECT_EQ(psu.hasIoutOCFault(), true); EXPECT_EQ(psu.hasVoutUVFault(), false); EXPECT_EQ(psu.hasFanFault(), true); EXPECT_EQ(psu.hasTempFault(), true); EXPECT_EQ(psu.hasPgoodFault(), true); EXPECT_EQ(psu.hasPSKillFault(), true); EXPECT_EQ(psu.hasPS12VcsFault(), true); EXPECT_EQ(psu.hasPSCS12VFault(), true); // All faults cleared expectations = {0}; setPMBusExpectations(mockPMBus, expectations); // READ_VIN back in range. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("206000")); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); psu.analyze(); EXPECT_EQ(psu.isPresent(), true); EXPECT_EQ(psu.isFaulted(), false); EXPECT_EQ(psu.hasInputFault(), false); EXPECT_EQ(psu.hasMFRFault(), false); EXPECT_EQ(psu.hasVINUVFault(), false); EXPECT_EQ(psu.hasCommFault(), false); EXPECT_EQ(psu.hasVoutOVFault(), false); EXPECT_EQ(psu.hasIoutOCFault(), false); EXPECT_EQ(psu.hasVoutUVFault(), false); EXPECT_EQ(psu.hasFanFault(), false); EXPECT_EQ(psu.hasTempFault(), false); EXPECT_EQ(psu.hasPgoodFault(), false); EXPECT_EQ(psu.hasPSKillFault(), false); EXPECT_EQ(psu.hasPS12VcsFault(), false); EXPECT_EQ(psu.hasPSCS12VFault(), false); // TODO: Faults clear on missing/present? } TEST_F(PowerSupplyTests, UpdateInventory) { auto bus = sdbusplus::bus::new_default(); try { PowerSupply psu{bus, PSUInventoryPath, 3, 0x68, "ibm-cffps", PSUGPIOLineName}; MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); // If it is not present, I should not be trying to read a string EXPECT_CALL(mockPMBus, readString(_, _)).Times(0); psu.updateInventory(); } catch (...) { ADD_FAILURE() << "Should not have caught exception."; } try { PowerSupply psu{bus, PSUInventoryPath, 13, 0x69, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // GPIO read return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).Times(1).WillOnce(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will read voltage, trigger clear faults for 0 to // within range. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("123456")); psu.analyze(); EXPECT_CALL(mockPMBus, readString(_, _)).WillRepeatedly(Return("")); psu.updateInventory(); #if IBM_VPD EXPECT_CALL(mockPMBus, readString(_, _)) .WillOnce(Return("CCIN")) .WillOnce(Return("PN3456")) .WillOnce(Return("FN3456")) .WillOnce(Return("HEADER")) .WillOnce(Return("SN3456")) .WillOnce(Return("FW3456")); #endif psu.updateInventory(); // TODO: D-Bus mocking to verify values stored on D-Bus (???) } catch (...) { ADD_FAILURE() << "Should not have caught exception."; } } TEST_F(PowerSupplyTests, IsPresent) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 3, 0x68, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); EXPECT_EQ(psu.isPresent(), false); // Change GPIO read to return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).Times(1).WillOnce(Return(1)); // Call to analyze() will update to present, that will trigger updating // to the correct/latest HWMON directory, in case it changes. MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // Call to analyze things will trigger read of STATUS_WORD and READ_VIN. // Default expectations will be on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Give it an input voltage in the 100-volt range. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("123456")); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); psu.analyze(); EXPECT_EQ(psu.isPresent(), true); } TEST_F(PowerSupplyTests, IsFaulted) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 11, 0x6f, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // Call to analyze things will trigger read of STATUS_WORD and READ_VIN. // Default expectations will be on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Give it an input voltage in the 100-volt range. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("124680")); psu.analyze(); EXPECT_EQ(psu.isFaulted(), false); // STATUS_WORD with fault bits on. expectations.statusWordValue = 0xFFFF; // STATUS_INPUT with fault bits on. expectations.statusInputValue = 0xFF; // STATUS_MFR_SPECIFIC with faults bits on. expectations.statusMFRValue = 0xFF; // STATUS_CML with faults bits on. expectations.statusCMLValue = 0xFF; // STATUS_VOUT with fault bits on. expectations.statusVOUTValue = 0xFF; // STATUS_IOUT with fault bits on. expectations.statusIOUTValue = 0xFF; // STATUS_FANS_1_2 with bits on. expectations.statusFans12Value = 0xFF; // STATUS_TEMPERATURE with fault bits on. expectations.statusTempValue = 0xFF; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); // Also get another read of READ_VIN, faulted, so not in 100-volt range EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("19000")); if (x == DEGLITCH_LIMIT) { EXPECT_CALL(mockedUtil, setAvailable(_, _, false)); } psu.analyze(); EXPECT_EQ(psu.isFaulted(), x >= DEGLITCH_LIMIT); } } TEST_F(PowerSupplyTests, HasInputFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 3, 0x68, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Analyze call will also need good READ_VIN value to check. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("201100")); psu.analyze(); EXPECT_EQ(psu.hasInputFault(), false); // STATUS_WORD with input fault/warn on. expectations.statusWordValue = (status_word::INPUT_FAULT_WARN); // STATUS_INPUT with an input fault bit on. expectations.statusInputValue = 0x80; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); // Analyze call will also need good READ_VIN value to check. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("201200")); if (x == DEGLITCH_LIMIT) { EXPECT_CALL(mockedUtil, setAvailable(_, _, false)); } psu.analyze(); EXPECT_EQ(psu.hasInputFault(), x >= DEGLITCH_LIMIT); } // STATUS_WORD with no bits on. expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); // Analyze call will also need good READ_VIN value to check. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("201300")); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); psu.analyze(); EXPECT_EQ(psu.hasInputFault(), false); } TEST_F(PowerSupplyTests, HasMFRFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 3, 0x68, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // First return STATUS_WORD with no bits on. // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Analyze call will also need good READ_VIN value to check. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("202100")); psu.analyze(); EXPECT_EQ(psu.hasMFRFault(), false); // Next return STATUS_WORD with MFR fault bit on. expectations.statusWordValue = (status_word::MFR_SPECIFIC_FAULT); // STATUS_MFR_SPEFIC with bit(s) on. expectations.statusMFRValue = 0xFF; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("202200")); psu.analyze(); EXPECT_EQ(psu.hasMFRFault(), x >= DEGLITCH_LIMIT); } // Back to no bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("202300")); psu.analyze(); EXPECT_EQ(psu.hasMFRFault(), false); } TEST_F(PowerSupplyTests, HasVINUVFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 3, 0x68, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // Presence change from missing to present will trigger in1_input read in // an attempt to get CLEAR_FAULTS called. Return value ignored. // Zero to non-zero voltage, for missing/present change, triggers clear // faults call again. Return value ignored. // Fault (low voltage) to not faulted (voltage in range) triggers clear // faults call a third time. // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Analyze call will also need good READ_VIN value to check. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("201100")); psu.analyze(); EXPECT_EQ(psu.hasVINUVFault(), false); // Turn fault on. expectations.statusWordValue = (status_word::VIN_UV_FAULT); // Curious disagreement between PMBus Spec. Part II Figure 16 and 33. Go by // Figure 16, and assume bits on in STATUS_INPUT. expectations.statusInputValue = 0x18; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); // If there is a VIN_UV fault, fake reading voltage of less than 20V EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("19876")); if (x == DEGLITCH_LIMIT) { EXPECT_CALL(mockedUtil, setAvailable(_, _, false)); } psu.analyze(); EXPECT_EQ(psu.hasVINUVFault(), x >= DEGLITCH_LIMIT); } // Back to no fault bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); // Updates now result in clearing faults if read voltage goes from below the // minimum, to within a valid range. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("201300")); // Went from below minimum to within range, expect clearVinUVFault(). EXPECT_CALL(mockPMBus, read("in1_lcrit_alarm", _, _)) .Times(1) .WillOnce(Return(1)); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); psu.analyze(); EXPECT_EQ(psu.hasVINUVFault(), false); } TEST_F(PowerSupplyTests, HasVoutOVFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 3, 0x69, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. // Initial value would be 0, so this read updates it to non-zero. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("202100")); psu.analyze(); EXPECT_EQ(psu.hasVoutOVFault(), false); // Turn fault on. expectations.statusWordValue = (status_word::VOUT_OV_FAULT); // STATUS_VOUT fault bit(s) expectations.statusVOUTValue = 0x80; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("202200")); psu.analyze(); EXPECT_EQ(psu.hasVoutOVFault(), x >= DEGLITCH_LIMIT); } // Back to no fault bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("202300")); psu.analyze(); EXPECT_EQ(psu.hasVoutOVFault(), false); } TEST_F(PowerSupplyTests, HasIoutOCFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 3, 0x6d, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. // Initial value would be 0, so this read updates it to non-zero. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("203100")); psu.analyze(); EXPECT_EQ(psu.hasIoutOCFault(), false); // Turn fault on. expectations.statusWordValue = status_word::IOUT_OC_FAULT; // STATUS_IOUT fault bit(s) expectations.statusIOUTValue = 0x88; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("203200")); if (x == DEGLITCH_LIMIT) { EXPECT_CALL(mockedUtil, setAvailable(_, _, false)); } psu.analyze(); EXPECT_EQ(psu.hasIoutOCFault(), x >= DEGLITCH_LIMIT); } // Back to no fault bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("203300")); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); psu.analyze(); EXPECT_EQ(psu.hasIoutOCFault(), false); } TEST_F(PowerSupplyTests, HasVoutUVFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 3, 0x6a, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. // Initial value would be 0, so this read updates it to non-zero. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("204100")); psu.analyze(); EXPECT_EQ(psu.hasVoutUVFault(), false); // Turn fault on. expectations.statusWordValue = (status_word::VOUT_FAULT); // STATUS_VOUT fault bit(s) expectations.statusVOUTValue = 0x30; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("204200")); psu.analyze(); EXPECT_EQ(psu.hasVoutUVFault(), x >= DEGLITCH_LIMIT); } // Back to no fault bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("204300")); psu.analyze(); EXPECT_EQ(psu.hasVoutUVFault(), false); } TEST_F(PowerSupplyTests, HasFanFault) { auto bus = sdbusplus::bus::new_default(); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)).Times(1); EXPECT_CALL(mockedUtil, setAvailable(_, _, false)).Times(0); PowerSupply psu{bus, PSUInventoryPath, 3, 0x6d, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. // Initial value would be 0, so this read updates it to non-zero. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("205100")); psu.analyze(); EXPECT_EQ(psu.hasFanFault(), false); // Turn fault on. expectations.statusWordValue = (status_word::FAN_FAULT); // STATUS_FANS_1_2 fault bit on (Fan 1 Fault) expectations.statusFans12Value = 0x80; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("205200")); psu.analyze(); EXPECT_EQ(psu.hasFanFault(), x >= DEGLITCH_LIMIT); } // Back to no fault bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("205300")); psu.analyze(); EXPECT_EQ(psu.hasFanFault(), false); } TEST_F(PowerSupplyTests, HasTempFault) { auto bus = sdbusplus::bus::new_default(); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)).Times(1); EXPECT_CALL(mockedUtil, setAvailable(_, _, false)).Times(0); PowerSupply psu{bus, PSUInventoryPath, 3, 0x6a, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. // Initial value would be 0, so this read updates it to non-zero. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("206100")); psu.analyze(); EXPECT_EQ(psu.hasTempFault(), false); // Turn fault on. expectations.statusWordValue = (status_word::TEMPERATURE_FAULT_WARN); // STATUS_TEMPERATURE fault bit on (OT Fault) expectations.statusTempValue = 0x80; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("206200")); psu.analyze(); EXPECT_EQ(psu.hasTempFault(), x >= DEGLITCH_LIMIT); } // Back to no fault bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("206300")); psu.analyze(); EXPECT_EQ(psu.hasTempFault(), false); } TEST_F(PowerSupplyTests, HasPgoodFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 3, 0x6b, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. // Initial value would be 0, so this read updates it to non-zero. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("207100")); psu.analyze(); EXPECT_EQ(psu.hasPgoodFault(), false); // Setup another expectation of no faults. setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("207200")); psu.analyze(); EXPECT_EQ(psu.hasPgoodFault(), false); // Setup another expectation of no faults. setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("207300")); psu.analyze(); EXPECT_EQ(psu.hasPgoodFault(), false); // Turn PGOOD# off (fault on). expectations.statusWordValue = (status_word::POWER_GOOD_NEGATED); setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("207400")); psu.analyze(); // Expect false until reaches DEGLITCH_LIMIT EXPECT_EQ(psu.hasPgoodFault(), false); setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("207500")); psu.analyze(); // Expect false until reaches DEGLITCH_LIMIT EXPECT_EQ(psu.hasPgoodFault(), false); setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("207600")); psu.analyze(); // DEGLITCH_LIMIT reached, expect true. EXPECT_EQ(psu.hasPgoodFault(), true); // Back to no fault bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("207700")); psu.analyze(); EXPECT_EQ(psu.hasPgoodFault(), false); // Turn OFF bit on expectations.statusWordValue = (status_word::UNIT_IS_OFF); setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208100")); psu.analyze(); EXPECT_EQ(psu.hasPgoodFault(), false); setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208200")); psu.analyze(); EXPECT_EQ(psu.hasPgoodFault(), false); setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208300")); psu.analyze(); EXPECT_EQ(psu.hasPgoodFault(), true); // Back to no fault bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208400")); psu.analyze(); EXPECT_EQ(psu.hasPgoodFault(), false); } TEST_F(PowerSupplyTests, HasPSKillFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 4, 0x6d, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. // Initial value would be 0, so this read updates it to non-zero. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208100")); psu.analyze(); EXPECT_EQ(psu.hasPSKillFault(), false); // Next return STATUS_WORD with MFR fault bit on. expectations.statusWordValue = (status_word::MFR_SPECIFIC_FAULT); // STATUS_MFR_SPEFIC with bit(s) on. expectations.statusMFRValue = 0xFF; // Deglitching faults, false until read the fault bits on up to the limit. for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208200")); if (x == DEGLITCH_LIMIT) { EXPECT_CALL(mockedUtil, setAvailable(_, _, false)); } psu.analyze(); EXPECT_EQ(psu.hasPSKillFault(), x >= DEGLITCH_LIMIT); } // Back to no bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208300")); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); psu.analyze(); EXPECT_EQ(psu.hasPSKillFault(), false); // Next return STATUS_WORD with MFR fault bit on. expectations.statusWordValue = (status_word::MFR_SPECIFIC_FAULT); // STATUS_MFR_SPEFIC with bit 4 on. expectations.statusMFRValue = 0x10; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208400")); if (x == DEGLITCH_LIMIT) { EXPECT_CALL(mockedUtil, setAvailable(_, _, false)); } psu.analyze(); EXPECT_EQ(psu.hasPSKillFault(), x >= DEGLITCH_LIMIT); } // Back to no bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("208500")); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); psu.analyze(); EXPECT_EQ(psu.hasPSKillFault(), false); } TEST_F(PowerSupplyTests, HasPS12VcsFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 5, 0x6e, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // Call to analyze will trigger read of "in1_input" to check voltage. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209100")); psu.analyze(); EXPECT_EQ(psu.hasPS12VcsFault(), false); // Next return STATUS_WORD with MFR fault bit on. expectations.statusWordValue = (status_word::MFR_SPECIFIC_FAULT); // STATUS_MFR_SPEFIC with bit(s) on. expectations.statusMFRValue = 0xFF; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209200")); psu.analyze(); EXPECT_EQ(psu.hasPS12VcsFault(), x >= DEGLITCH_LIMIT); } // Back to no bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209300")); psu.analyze(); EXPECT_EQ(psu.hasPS12VcsFault(), false); // Next return STATUS_WORD with MFR fault bit on. expectations.statusWordValue = (status_word::MFR_SPECIFIC_FAULT); // STATUS_MFR_SPEFIC with bit 6 on. expectations.statusMFRValue = 0x40; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209400")); psu.analyze(); EXPECT_EQ(psu.hasPS12VcsFault(), x >= DEGLITCH_LIMIT); } // Back to no bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209500")); psu.analyze(); EXPECT_EQ(psu.hasPS12VcsFault(), false); } TEST_F(PowerSupplyTests, HasPSCS12VFault) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 6, 0x6f, "ibm-cffps", PSUGPIOLineName}; MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); // STATUS_WORD 0x0000 is powered on, no faults. PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209100")); psu.analyze(); EXPECT_EQ(psu.hasPSCS12VFault(), false); // Next return STATUS_WORD with MFR fault bit on. expectations.statusWordValue = (status_word::MFR_SPECIFIC_FAULT); // STATUS_MFR_SPEFIC with bit(s) on. expectations.statusMFRValue = 0xFF; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209200")); psu.analyze(); EXPECT_EQ(psu.hasPSCS12VFault(), x >= DEGLITCH_LIMIT); } // Back to no bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209300")); psu.analyze(); EXPECT_EQ(psu.hasPSCS12VFault(), false); // Next return STATUS_WORD with MFR fault bit on. expectations.statusWordValue = (status_word::MFR_SPECIFIC_FAULT); // STATUS_MFR_SPEFIC with bit 7 on. expectations.statusMFRValue = 0x80; for (auto x = 1; x <= DEGLITCH_LIMIT; x++) { setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209400")); psu.analyze(); EXPECT_EQ(psu.hasPSCS12VFault(), x >= DEGLITCH_LIMIT); } // Back to no bits on in STATUS_WORD expectations.statusWordValue = 0; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("209500")); psu.analyze(); EXPECT_EQ(psu.hasPSCS12VFault(), false); } TEST_F(PowerSupplyTests, SetupInputHistory) { auto bus = sdbusplus::bus::new_default(); { PowerSupply psu{bus, PSUInventoryPath, 6, 0x6f, "ibm-cffps", PSUGPIOLineName}; // Defaults to not present due to constructor and mock ordering. psu.setupInputHistory(); EXPECT_EQ(psu.hasInputHistory(), false); MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); setMissingToPresentExpects(mockPMBus, mockedUtil); PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // After reading STATUS_WORD, etc., there will be a READ_VIN check. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("206000")); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. /// Also called when I redo setupInputHistory(). EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(2) .WillRepeatedly(Return("2000")); // Call to analyze() and above expectations to get missing/present and // good status. psu.analyze(); psu.setupInputHistory(); EXPECT_EQ(psu.hasInputHistory(), true); } { // Workaround - Disable INPUT_HISTORY collection if 1400W PowerSupply psu{bus, PSUInventoryPath, 3, 0x68, "ibm-cffps", PSUGPIOLineName}; // Defaults to not present due to constructor and mock ordering. psu.setupInputHistory(); EXPECT_EQ(psu.hasInputHistory(), false); MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate 1400W IBM value, unsupported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(2) .WillRepeatedly(Return("30725")); PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // After reading STATUS_WORD, etc., there will be a READ_VIN check. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("206000")); // Call to analyze() and above expectations to get missing/present and // good status. psu.analyze(); psu.setupInputHistory(); // After updating to present, and retrying setup, expect ibm-cffps with // 1400W to still not support INPUT_HISTORY. EXPECT_EQ(psu.hasInputHistory(), false); } { PowerSupply psu{bus, PSUInventoryPath, 11, 0x58, "inspur-ipsps", PSUGPIOLineName}; // Defaults to not present due to constructor and mock ordering. psu.setupInputHistory(); EXPECT_EQ(psu.hasInputHistory(), false); MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); setMissingToPresentExpects(mockPMBus, mockedUtil); PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); // After reading STATUS_WORD, etc., there will be a READ_VIN check. EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillOnce(Return("206000")); // Call to analyze() and above expectations to get missing/present and // good status. psu.analyze(); psu.setupInputHistory(); // After updating to present, and retrying setup, expect inspur-ipsps to // still not support INPUT_HISTORY. EXPECT_EQ(psu.hasInputHistory(), false); } } TEST_F(PowerSupplyTests, UpdateHistory) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 7, 0x6e, "ibm-cffps", PSUGPIOLineName}; EXPECT_EQ(psu.hasInputHistory(), false); EXPECT_EQ(psu.getNumInputHistoryRecords(), 0); MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(6) .WillRepeatedly(Return("205000")); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); // First read after missing/present will have no data. std::vector emptyHistory{}; // Second read, after about 30 seconds, should have a record. 5-bytes. // Sequence Number: 0x00, Average: 0x50 0xf3 (212), Maximum: 0x54 0xf3 (213) std::vector firstHistory{0x00, 0x50, 0xf3, 0x54, 0xf3}; // Third read, after about 60 seconds, should have two records, 10-bytes, // but only reading 5 bytes, so make sure new/next sequence number std::vector secondHistory{0x01, 0x54, 0xf3, 0x58, 0xf3}; // Fourth read, 3rd sequence number (0x02). std::vector thirdHistory{0x02, 0x54, 0xf3, 0x58, 0xf3}; // Fifth read, out of sequence, clear and insert this one? std::vector outseqHistory{0xff, 0x5c, 0xf3, 0x60, 0xf3}; EXPECT_CALL( mockPMBus, readBinary(INPUT_HISTORY, Type::HwmonDeviceDebug, phosphor::power::history::RecordManager::RAW_RECORD_SIZE)) .Times(6) .WillOnce(Return(emptyHistory)) .WillOnce(Return(firstHistory)) .WillOnce(Return(secondHistory)) .WillOnce(Return(thirdHistory)) .WillOnce(Return(outseqHistory)) .WillOnce(Return(emptyHistory)); // Calling analyze will update the presence, which will setup the input // history if the power supply went from missing to present. psu.analyze(); // The ibm-cffps power supply should support input history EXPECT_EQ(psu.hasInputHistory(), true); // Usually should have empty buffer right after missing to present. // Faked that out above with mocked readBinary with emptyHistory data. EXPECT_EQ(psu.getNumInputHistoryRecords(), 0); // Second run through... setPMBusExpectations(mockPMBus, expectations); psu.analyze(); EXPECT_EQ(psu.hasInputHistory(), true); EXPECT_EQ(psu.getNumInputHistoryRecords(), 1); // Third run through setPMBusExpectations(mockPMBus, expectations); psu.analyze(); EXPECT_EQ(psu.hasInputHistory(), true); EXPECT_EQ(psu.getNumInputHistoryRecords(), 2); // Fourth run through. Up to 3 records now? setPMBusExpectations(mockPMBus, expectations); psu.analyze(); EXPECT_EQ(psu.hasInputHistory(), true); EXPECT_EQ(psu.getNumInputHistoryRecords(), 3); // Out of sequencer, reset, insert new one. setPMBusExpectations(mockPMBus, expectations); psu.analyze(); EXPECT_EQ(psu.hasInputHistory(), true); EXPECT_EQ(psu.getNumInputHistoryRecords(), 1); // Empty one after last one good. Reset/clear. setPMBusExpectations(mockPMBus, expectations); psu.analyze(); EXPECT_EQ(psu.hasInputHistory(), true); EXPECT_EQ(psu.getNumInputHistoryRecords(), 0); } TEST_F(PowerSupplyTests, IsSyncHistoryRequired) { auto bus = sdbusplus::bus::new_default(); PowerSupply psu{bus, PSUInventoryPath, 8, 0x6f, "ibm-cffps", PSUGPIOLineName}; EXPECT_EQ(psu.hasInputHistory(), false); EXPECT_EQ(psu.isSyncHistoryRequired(), false); MockedGPIOInterface* mockPresenceGPIO = static_cast(psu.getPresenceGPIO()); // Always return 1 to indicate present. EXPECT_CALL(*mockPresenceGPIO, read()).WillRepeatedly(Return(1)); MockedPMBus& mockPMBus = static_cast(psu.getPMBus()); setMissingToPresentExpects(mockPMBus, mockedUtil); // Missing/present will trigger attempt to setup INPUT_HISTORY. Setup // for INPUT_HISTORY will check max_power_out to see if it is // old/unsupported power supply. Indicate good value, supported. EXPECT_CALL(mockPMBus, readString(MFR_POUT_MAX, _)) .Times(1) .WillOnce(Return("2000")); PMBusExpectations expectations; setPMBusExpectations(mockPMBus, expectations); EXPECT_CALL(mockPMBus, readString(READ_VIN, _)) .Times(1) .WillRepeatedly(Return("205000")); EXPECT_CALL(mockedUtil, setAvailable(_, _, true)); psu.analyze(); // The ibm-cffps power supply should support input history EXPECT_EQ(psu.hasInputHistory(), true); // Missing -> Present requires history sync EXPECT_EQ(psu.isSyncHistoryRequired(), true); psu.clearSyncHistoryRequired(); EXPECT_EQ(psu.isSyncHistoryRequired(), false); }