test/pid_fancontroller_unittest.cpp - openbmc/phosphor-pid-control - Gitiles

 #include "pid/ec/pid.hpp"
 #include "pid/fancontroller.hpp"
 #include "test/sensor_mock.hpp"
 #include "test/zone_mock.hpp"

 #include <string>
 #include <vector>

 #include <gmock/gmock.h>
 #include <gtest/gtest.h>

 using ::testing::_;
 using ::testing::DoubleEq;
 using ::testing::Invoke;
 using ::testing::Return;
 using ::testing::StrEq;

 TEST(FanControllerTest, BoringFactoryTest)
 {
     // Verify the factory will properly build the FanPIDController in the
     // boring (uninteresting) case.
     ZoneMock z;

     std::vector<std::string> inputs = {"fan0"};
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p =
         FanController::createFanPid(&z, "fan1", inputs, initial);
     // Success
     EXPECT_FALSE(p == nullptr);
 }

 TEST(FanControllerTest, VerifyFactoryFailsWithZeroInputs)
 {
     // A fan controller needs at least one input.

     ZoneMock z;

     std::vector<std::string> inputs = {};
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p =
         FanController::createFanPid(&z, "fan1", inputs, initial);
     EXPECT_TRUE(p == nullptr);
 }

 TEST(FanControllerTest, InputProc_AllSensorsReturnZero)
 {
     // If all your inputs are 0, return 0.

     ZoneMock z;

     std::vector<std::string> inputs = {"fan0", "fan1"};
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p =
         FanController::createFanPid(&z, "fan1", inputs, initial);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getCachedValue(StrEq("fan0"))).WillOnce(Return(0));
     EXPECT_CALL(z, getCachedValue(StrEq("fan1"))).WillOnce(Return(0));

     EXPECT_EQ(0.0, p->inputProc());
 }

 TEST(FanControllerTest, InputProc_IfSensorNegativeIsIgnored)
 {
     // A sensor value returning sub-zero is ignored as an error.
     ZoneMock z;

     std::vector<std::string> inputs = {"fan0", "fan1"};
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p =
         FanController::createFanPid(&z, "fan1", inputs, initial);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getCachedValue(StrEq("fan0"))).WillOnce(Return(-1));
     EXPECT_CALL(z, getCachedValue(StrEq("fan1"))).WillOnce(Return(-1));

     EXPECT_EQ(0.0, p->inputProc());
 }

 TEST(FanControllerTest, InputProc_ChoosesMinimumValue)
 {
     // Verify it selects the minimum value from its inputs.

     ZoneMock z;

     std::vector<std::string> inputs = {"fan0", "fan1", "fan2"};
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p =
         FanController::createFanPid(&z, "fan1", inputs, initial);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getCachedValue(StrEq("fan0"))).WillOnce(Return(10.0));
     EXPECT_CALL(z, getCachedValue(StrEq("fan1"))).WillOnce(Return(30.0));
     EXPECT_CALL(z, getCachedValue(StrEq("fan2"))).WillOnce(Return(5.0));

     EXPECT_EQ(5.0, p->inputProc());
 }

 // The direction is unused presently, but these tests validate the logic.
 TEST(FanControllerTest, SetPtProc_SpeedChanges_VerifyDirection)
 {
     // The fan direction defaults to neutral, because we have no data.  Verify
     // that after this point it appropriately will indicate speeding up or
     // slowing down based on the RPM values specified.

     ZoneMock z;

     std::vector<std::string> inputs = {"fan0", "fan1"};
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p =
         FanController::createFanPid(&z, "fan1", inputs, initial);
     EXPECT_FALSE(p == nullptr);
     // Grab pointer for mocking.
     FanController* fp = reinterpret_cast<FanController*>(p.get());

     // Fanspeed starts are Neutral.
     EXPECT_EQ(FanSpeedDirection::NEUTRAL, fp->getFanDirection());

     // getMaxSetPointRequest returns a higher value than 0, so the fans should
     // be marked as speeding up.
     EXPECT_CALL(z, getMaxSetPointRequest()).WillOnce(Return(10.0));
     EXPECT_EQ(10.0, p->setptProc());
     EXPECT_EQ(FanSpeedDirection::UP, fp->getFanDirection());

     // getMaxSetPointRequest returns a lower value than 10, so the fans should
     // be marked as slowing down.
     EXPECT_CALL(z, getMaxSetPointRequest()).WillOnce(Return(5.0));
     EXPECT_EQ(5.0, p->setptProc());
     EXPECT_EQ(FanSpeedDirection::DOWN, fp->getFanDirection());

     // getMaxSetPointRequest returns the same value, so the fans should be
     // marked as neutral.
     EXPECT_CALL(z, getMaxSetPointRequest()).WillOnce(Return(5.0));
     EXPECT_EQ(5.0, p->setptProc());
     EXPECT_EQ(FanSpeedDirection::NEUTRAL, fp->getFanDirection());
 }

 TEST(FanControllerTest, OutputProc_VerifiesIfFailsafeEnabledInputIsIgnored)
 {
     // Verify that if failsafe mode is enabled and the input value for the fans
     // is below the failsafe minimum value, the input is not used and the fans
     // are driven at failsafe RPM.

     ZoneMock z;

     std::vector<std::string> inputs = {"fan0", "fan1"};
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p =
         FanController::createFanPid(&z, "fan1", inputs, initial);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getFailSafeMode()).WillOnce(Return(true));
     EXPECT_CALL(z, getFailSafePercent()).Times(2).WillRepeatedly(Return(75.0));

     int64_t timeout = 0;
     std::unique_ptr<Sensor> s1 = std::make_unique<SensorMock>("fan0", timeout);
     std::unique_ptr<Sensor> s2 = std::make_unique<SensorMock>("fan1", timeout);
     // Grab pointers for mocking.
     SensorMock* sm1 = reinterpret_cast<SensorMock*>(s1.get());
     SensorMock* sm2 = reinterpret_cast<SensorMock*>(s2.get());

     EXPECT_CALL(z, getSensor(StrEq("fan0"))).WillOnce(Return(s1.get()));
     EXPECT_CALL(*sm1, write(0.75));
     EXPECT_CALL(z, getSensor(StrEq("fan1"))).WillOnce(Return(s2.get()));
     EXPECT_CALL(*sm2, write(0.75));

     // This is a fan PID, so calling outputProc will try to write this value
     // to the sensors.

     // Setting 50%, will end up being 75% because the sensors are in failsafe
     // mode.
     p->outputProc(50.0);
 }

 TEST(FanControllerTest, OutputProc_BehavesAsExpected)
 {
     // Verifies that when the system is not in failsafe mode, the input value
     // to outputProc is used to drive the sensors (fans).

     ZoneMock z;

     std::vector<std::string> inputs = {"fan0", "fan1"};
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p =
         FanController::createFanPid(&z, "fan1", inputs, initial);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getFailSafeMode()).WillOnce(Return(false));

     int64_t timeout = 0;
     std::unique_ptr<Sensor> s1 = std::make_unique<SensorMock>("fan0", timeout);
     std::unique_ptr<Sensor> s2 = std::make_unique<SensorMock>("fan1", timeout);
     // Grab pointers for mocking.
     SensorMock* sm1 = reinterpret_cast<SensorMock*>(s1.get());
     SensorMock* sm2 = reinterpret_cast<SensorMock*>(s2.get());

     EXPECT_CALL(z, getSensor(StrEq("fan0"))).WillOnce(Return(s1.get()));
     EXPECT_CALL(*sm1, write(0.5));
     EXPECT_CALL(z, getSensor(StrEq("fan1"))).WillOnce(Return(s2.get()));
     EXPECT_CALL(*sm2, write(0.5));

     // This is a fan PID, so calling outputProc will try to write this value
     // to the sensors.
     p->outputProc(50.0);
 }

 TEST(FanControllerTest, OutputProc_VerifyFailSafeIgnoredIfInputHigher)
 {
     // If the requested output is higher than the failsafe value, then use the
     // value provided to outputProc.

     ZoneMock z;

     std::vector<std::string> inputs = {"fan0"};
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p =
         FanController::createFanPid(&z, "fan1", inputs, initial);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getFailSafeMode()).WillOnce(Return(true));
     EXPECT_CALL(z, getFailSafePercent()).WillOnce(Return(75.0));

     int64_t timeout = 0;
     std::unique_ptr<Sensor> s1 = std::make_unique<SensorMock>("fan0", timeout);
     // Grab pointer for mocking.
     SensorMock* sm1 = reinterpret_cast<SensorMock*>(s1.get());

     // Converting from double to double for expectation.
     double percent = 80;
     double value = percent / 100;

     EXPECT_CALL(z, getSensor(StrEq("fan0"))).WillOnce(Return(s1.get()));
     EXPECT_CALL(*sm1, write(value));

     // This is a fan PID, so calling outputProc will try to write this value
     // to the sensors.
     p->outputProc(percent);
 }
	#include "pid/ec/pid.hpp"
	#include "pid/fancontroller.hpp"
	#include "test/sensor_mock.hpp"
	#include "test/zone_mock.hpp"

	#include <string>
	#include <vector>

	#include <gmock/gmock.h>
	#include <gtest/gtest.h>

	using ::testing::_;
	using ::testing::DoubleEq;
	using ::testing::Invoke;
	using ::testing::Return;
	using ::testing::StrEq;

	TEST(FanControllerTest, BoringFactoryTest)
	{
	// Verify the factory will properly build the FanPIDController in the
	// boring (uninteresting) case.
	ZoneMock z;

	std::vector<std::string> inputs = {"fan0"};
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p =
	FanController::createFanPid(&z, "fan1", inputs, initial);
	// Success
	EXPECT_FALSE(p == nullptr);
	}

	TEST(FanControllerTest, VerifyFactoryFailsWithZeroInputs)
	{
	// A fan controller needs at least one input.

	ZoneMock z;

	std::vector<std::string> inputs = {};
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p =
	FanController::createFanPid(&z, "fan1", inputs, initial);
	EXPECT_TRUE(p == nullptr);
	}

	TEST(FanControllerTest, InputProc_AllSensorsReturnZero)
	{
	// If all your inputs are 0, return 0.

	ZoneMock z;

	std::vector<std::string> inputs = {"fan0", "fan1"};
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p =
	FanController::createFanPid(&z, "fan1", inputs, initial);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getCachedValue(StrEq("fan0"))).WillOnce(Return(0));
	EXPECT_CALL(z, getCachedValue(StrEq("fan1"))).WillOnce(Return(0));

	EXPECT_EQ(0.0, p->inputProc());
	}

	TEST(FanControllerTest, InputProc_IfSensorNegativeIsIgnored)
	{
	// A sensor value returning sub-zero is ignored as an error.
	ZoneMock z;

	std::vector<std::string> inputs = {"fan0", "fan1"};
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p =
	FanController::createFanPid(&z, "fan1", inputs, initial);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getCachedValue(StrEq("fan0"))).WillOnce(Return(-1));
	EXPECT_CALL(z, getCachedValue(StrEq("fan1"))).WillOnce(Return(-1));

	EXPECT_EQ(0.0, p->inputProc());
	}

	TEST(FanControllerTest, InputProc_ChoosesMinimumValue)
	{
	// Verify it selects the minimum value from its inputs.

	ZoneMock z;

	std::vector<std::string> inputs = {"fan0", "fan1", "fan2"};
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p =
	FanController::createFanPid(&z, "fan1", inputs, initial);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getCachedValue(StrEq("fan0"))).WillOnce(Return(10.0));
	EXPECT_CALL(z, getCachedValue(StrEq("fan1"))).WillOnce(Return(30.0));
	EXPECT_CALL(z, getCachedValue(StrEq("fan2"))).WillOnce(Return(5.0));

	EXPECT_EQ(5.0, p->inputProc());
	}

	// The direction is unused presently, but these tests validate the logic.
	TEST(FanControllerTest, SetPtProc_SpeedChanges_VerifyDirection)
	{
	// The fan direction defaults to neutral, because we have no data. Verify
	// that after this point it appropriately will indicate speeding up or
	// slowing down based on the RPM values specified.

	ZoneMock z;

	std::vector<std::string> inputs = {"fan0", "fan1"};
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p =
	FanController::createFanPid(&z, "fan1", inputs, initial);
	EXPECT_FALSE(p == nullptr);
	// Grab pointer for mocking.
	FanController* fp = reinterpret_cast<FanController*>(p.get());

	// Fanspeed starts are Neutral.
	EXPECT_EQ(FanSpeedDirection::NEUTRAL, fp->getFanDirection());

	// getMaxSetPointRequest returns a higher value than 0, so the fans should
	// be marked as speeding up.
	EXPECT_CALL(z, getMaxSetPointRequest()).WillOnce(Return(10.0));
	EXPECT_EQ(10.0, p->setptProc());
	EXPECT_EQ(FanSpeedDirection::UP, fp->getFanDirection());

	// getMaxSetPointRequest returns a lower value than 10, so the fans should
	// be marked as slowing down.
	EXPECT_CALL(z, getMaxSetPointRequest()).WillOnce(Return(5.0));
	EXPECT_EQ(5.0, p->setptProc());
	EXPECT_EQ(FanSpeedDirection::DOWN, fp->getFanDirection());

	// getMaxSetPointRequest returns the same value, so the fans should be
	// marked as neutral.
	EXPECT_CALL(z, getMaxSetPointRequest()).WillOnce(Return(5.0));
	EXPECT_EQ(5.0, p->setptProc());
	EXPECT_EQ(FanSpeedDirection::NEUTRAL, fp->getFanDirection());
	}

	TEST(FanControllerTest, OutputProc_VerifiesIfFailsafeEnabledInputIsIgnored)
	{
	// Verify that if failsafe mode is enabled and the input value for the fans
	// is below the failsafe minimum value, the input is not used and the fans
	// are driven at failsafe RPM.

	ZoneMock z;

	std::vector<std::string> inputs = {"fan0", "fan1"};
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p =
	FanController::createFanPid(&z, "fan1", inputs, initial);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getFailSafeMode()).WillOnce(Return(true));
	EXPECT_CALL(z, getFailSafePercent()).Times(2).WillRepeatedly(Return(75.0));

	int64_t timeout = 0;
	std::unique_ptr<Sensor> s1 = std::make_unique<SensorMock>("fan0", timeout);
	std::unique_ptr<Sensor> s2 = std::make_unique<SensorMock>("fan1", timeout);
	// Grab pointers for mocking.
	SensorMock* sm1 = reinterpret_cast<SensorMock*>(s1.get());
	SensorMock* sm2 = reinterpret_cast<SensorMock*>(s2.get());

	EXPECT_CALL(z, getSensor(StrEq("fan0"))).WillOnce(Return(s1.get()));
	EXPECT_CALL(*sm1, write(0.75));
	EXPECT_CALL(z, getSensor(StrEq("fan1"))).WillOnce(Return(s2.get()));
	EXPECT_CALL(*sm2, write(0.75));

	// This is a fan PID, so calling outputProc will try to write this value
	// to the sensors.

	// Setting 50%, will end up being 75% because the sensors are in failsafe
	// mode.
	p->outputProc(50.0);
	}

	TEST(FanControllerTest, OutputProc_BehavesAsExpected)
	{
	// Verifies that when the system is not in failsafe mode, the input value
	// to outputProc is used to drive the sensors (fans).

	ZoneMock z;

	std::vector<std::string> inputs = {"fan0", "fan1"};
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p =
	FanController::createFanPid(&z, "fan1", inputs, initial);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getFailSafeMode()).WillOnce(Return(false));

	int64_t timeout = 0;
	std::unique_ptr<Sensor> s1 = std::make_unique<SensorMock>("fan0", timeout);
	std::unique_ptr<Sensor> s2 = std::make_unique<SensorMock>("fan1", timeout);
	// Grab pointers for mocking.
	SensorMock* sm1 = reinterpret_cast<SensorMock*>(s1.get());
	SensorMock* sm2 = reinterpret_cast<SensorMock*>(s2.get());

	EXPECT_CALL(z, getSensor(StrEq("fan0"))).WillOnce(Return(s1.get()));
	EXPECT_CALL(*sm1, write(0.5));
	EXPECT_CALL(z, getSensor(StrEq("fan1"))).WillOnce(Return(s2.get()));
	EXPECT_CALL(*sm2, write(0.5));

	// This is a fan PID, so calling outputProc will try to write this value
	// to the sensors.
	p->outputProc(50.0);
	}

	TEST(FanControllerTest, OutputProc_VerifyFailSafeIgnoredIfInputHigher)
	{
	// If the requested output is higher than the failsafe value, then use the
	// value provided to outputProc.

	ZoneMock z;

	std::vector<std::string> inputs = {"fan0"};
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p =
	FanController::createFanPid(&z, "fan1", inputs, initial);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getFailSafeMode()).WillOnce(Return(true));
	EXPECT_CALL(z, getFailSafePercent()).WillOnce(Return(75.0));

	int64_t timeout = 0;
	std::unique_ptr<Sensor> s1 = std::make_unique<SensorMock>("fan0", timeout);
	// Grab pointer for mocking.
	SensorMock* sm1 = reinterpret_cast<SensorMock*>(s1.get());

	// Converting from double to double for expectation.
	double percent = 80;
	double value = percent / 100;

	EXPECT_CALL(z, getSensor(StrEq("fan0"))).WillOnce(Return(s1.get()));
	EXPECT_CALL(*sm1, write(value));

	// This is a fan PID, so calling outputProc will try to write this value
	// to the sensors.
	p->outputProc(percent);
	}