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

 #include "pid/ec/pid.hpp"
 #include "pid/thermalcontroller.hpp"
 #include "test/zone_mock.hpp"

 #include <string>
 #include <vector>

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

 using ::testing::_;
 using ::testing::Return;
 using ::testing::StrEq;

 TEST(ThermalControllerTest, BoringFactoryTest)
 {
     // Verifies building a ThermalPIDController with the factory works as
     // expected in the boring (uninteresting) case.

     ZoneMock z;

     std::vector<std::string> inputs = {"fleeting0"};
     double setpoint = 10.0;
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
         &z, "therm1", inputs, setpoint, initial, ThermalType::margin);
     // Success
     EXPECT_FALSE(p == nullptr);
 }

 TEST(ThermalControllerTest, VerifyFactoryFailsWithZeroInputs)
 {
     // A thermal controller needs at least one input.

     ZoneMock z;

     std::vector<std::string> inputs = {};
     double setpoint = 10.0;
     ec::pidinfo initial;
     std::unique_ptr<PIDController> p;
     EXPECT_THROW(
         {
             p = ThermalController::createThermalPid(
                 &z, "therm1", inputs, setpoint, initial, ThermalType::margin);
         },
         std::exception);
     EXPECT_TRUE(p == nullptr);
 }

 TEST(ThermalControllerTest, InputProc_BehavesAsExpected)
 {
     // This test just verifies inputProc behaves as expected.

     ZoneMock z;

     std::vector<std::string> inputs = {"fleeting0"};
     double setpoint = 10.0;
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
         &z, "therm1", inputs, setpoint, initial, ThermalType::margin);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getCachedValue(StrEq("fleeting0"))).WillOnce(Return(5.0));

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

 TEST(ThermalControllerTest, SetPtProc_BehavesAsExpected)
 {
     // This test just verifies inputProc behaves as expected.

     ZoneMock z;

     std::vector<std::string> inputs = {"fleeting0"};
     double setpoint = 10.0;
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
         &z, "therm1", inputs, setpoint, initial, ThermalType::margin);
     EXPECT_FALSE(p == nullptr);

     EXPECT_EQ(setpoint, p->setptProc());
 }

 TEST(ThermalControllerTest, OutputProc_BehavesAsExpected)
 {
     // This test just verifies outputProc behaves as expected.

     ZoneMock z;

     std::vector<std::string> inputs = {"fleeting0"};
     double setpoint = 10.0;
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
         &z, "therm1", inputs, setpoint, initial, ThermalType::margin);
     EXPECT_FALSE(p == nullptr);

     double value = 90.0;
     EXPECT_CALL(z, addRPMSetPoint(value));

     p->outputProc(value);
 }

 TEST(ThermalControllerTest, InputProc_MultipleInputsAbsolute)
 {
     // This test verifies inputProc behaves as expected with multiple absolute
     // inputs.

     ZoneMock z;

     std::vector<std::string> inputs = {"fleeting0", "fleeting1"};
     double setpoint = 10.0;
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
         &z, "therm1", inputs, setpoint, initial, ThermalType::absolute);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getCachedValue(StrEq("fleeting0"))).WillOnce(Return(5.0));
     EXPECT_CALL(z, getCachedValue(StrEq("fleeting1"))).WillOnce(Return(10.0));

     EXPECT_EQ(10.0, p->inputProc());
 }

 TEST(ThermalControllerTest, InputProc_MultipleInputsMargin)
 {
     // This test verifies inputProc behaves as expected with multiple margin
     // inputs.

     ZoneMock z;

     std::vector<std::string> inputs = {"fleeting0", "fleeting1"};
     double setpoint = 10.0;
     ec::pidinfo initial;

     std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
         &z, "therm1", inputs, setpoint, initial, ThermalType::margin);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getCachedValue(StrEq("fleeting0"))).WillOnce(Return(5.0));
     EXPECT_CALL(z, getCachedValue(StrEq("fleeting1"))).WillOnce(Return(10.0));

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

 TEST(ThermalControllerTest, NegHysteresis_BehavesAsExpected)
 {

     // This test verifies Negative hysteresis behaves as expected by
     // crossing the setpoint and noticing readings don't change until past the
     // hysteresis value

     ZoneMock z;

     std::vector<std::string> inputs = {"fleeting0"};
     double setpoint = 10.0;
     ec::pidinfo initial;
     initial.negativeHysteresis = 4.0;

     std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
         &z, "therm1", inputs, setpoint, initial, ThermalType::margin);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getCachedValue(StrEq("fleeting0")))
         .Times(3)
         .WillOnce(Return(12.0))
         .WillOnce(Return(9.0))
         .WillOnce(Return(7.0));

     EXPECT_CALL(z, addRPMSetPoint(_)).Times(3);

     std::vector<double> lastReadings = {12.0, 12.0, 7.0};
     for (auto& reading : lastReadings)
     {
         p->process();
         EXPECT_EQ(p->getLastInput(), reading);
     }
 }

 TEST(ThermalControllerTest, PosHysteresis_BehavesAsExpected)
 {
     // This test verifies Positive hysteresis behaves as expected by
     // crossing the setpoint and noticing readings don't change until past the
     // hysteresis value

     ZoneMock z;

     std::vector<std::string> inputs = {"fleeting0"};
     double setpoint = 10.0;
     ec::pidinfo initial;
     initial.positiveHysteresis = 5.0;

     std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
         &z, "therm1", inputs, setpoint, initial, ThermalType::margin);
     EXPECT_FALSE(p == nullptr);

     EXPECT_CALL(z, getCachedValue(StrEq("fleeting0")))
         .Times(3)
         .WillOnce(Return(8.0))
         .WillOnce(Return(13.0))
         .WillOnce(Return(14.0));

     EXPECT_CALL(z, addRPMSetPoint(_)).Times(3);

     std::vector<double> lastReadings = {8.0, 8.0, 14.0};
     for (auto& reading : lastReadings)
     {
         p->process();
         EXPECT_EQ(p->getLastInput(), reading);
     }
 }
	#include "pid/ec/pid.hpp"
	#include "pid/thermalcontroller.hpp"
	#include "test/zone_mock.hpp"

	#include <string>
	#include <vector>

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

	using ::testing::_;
	using ::testing::Return;
	using ::testing::StrEq;

	TEST(ThermalControllerTest, BoringFactoryTest)
	{
	// Verifies building a ThermalPIDController with the factory works as
	// expected in the boring (uninteresting) case.

	ZoneMock z;

	std::vector<std::string> inputs = {"fleeting0"};
	double setpoint = 10.0;
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
	&z, "therm1", inputs, setpoint, initial, ThermalType::margin);
	// Success
	EXPECT_FALSE(p == nullptr);
	}

	TEST(ThermalControllerTest, VerifyFactoryFailsWithZeroInputs)
	{
	// A thermal controller needs at least one input.

	ZoneMock z;

	std::vector<std::string> inputs = {};
	double setpoint = 10.0;
	ec::pidinfo initial;
	std::unique_ptr<PIDController> p;
	EXPECT_THROW(
	{
	p = ThermalController::createThermalPid(
	&z, "therm1", inputs, setpoint, initial, ThermalType::margin);
	},
	std::exception);
	EXPECT_TRUE(p == nullptr);
	}

	TEST(ThermalControllerTest, InputProc_BehavesAsExpected)
	{
	// This test just verifies inputProc behaves as expected.

	ZoneMock z;

	std::vector<std::string> inputs = {"fleeting0"};
	double setpoint = 10.0;
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
	&z, "therm1", inputs, setpoint, initial, ThermalType::margin);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getCachedValue(StrEq("fleeting0"))).WillOnce(Return(5.0));

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

	TEST(ThermalControllerTest, SetPtProc_BehavesAsExpected)
	{
	// This test just verifies inputProc behaves as expected.

	ZoneMock z;

	std::vector<std::string> inputs = {"fleeting0"};
	double setpoint = 10.0;
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
	&z, "therm1", inputs, setpoint, initial, ThermalType::margin);
	EXPECT_FALSE(p == nullptr);

	EXPECT_EQ(setpoint, p->setptProc());
	}

	TEST(ThermalControllerTest, OutputProc_BehavesAsExpected)
	{
	// This test just verifies outputProc behaves as expected.

	ZoneMock z;

	std::vector<std::string> inputs = {"fleeting0"};
	double setpoint = 10.0;
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
	&z, "therm1", inputs, setpoint, initial, ThermalType::margin);
	EXPECT_FALSE(p == nullptr);

	double value = 90.0;
	EXPECT_CALL(z, addRPMSetPoint(value));

	p->outputProc(value);
	}

	TEST(ThermalControllerTest, InputProc_MultipleInputsAbsolute)
	{
	// This test verifies inputProc behaves as expected with multiple absolute
	// inputs.

	ZoneMock z;

	std::vector<std::string> inputs = {"fleeting0", "fleeting1"};
	double setpoint = 10.0;
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
	&z, "therm1", inputs, setpoint, initial, ThermalType::absolute);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getCachedValue(StrEq("fleeting0"))).WillOnce(Return(5.0));
	EXPECT_CALL(z, getCachedValue(StrEq("fleeting1"))).WillOnce(Return(10.0));

	EXPECT_EQ(10.0, p->inputProc());
	}

	TEST(ThermalControllerTest, InputProc_MultipleInputsMargin)
	{
	// This test verifies inputProc behaves as expected with multiple margin
	// inputs.

	ZoneMock z;

	std::vector<std::string> inputs = {"fleeting0", "fleeting1"};
	double setpoint = 10.0;
	ec::pidinfo initial;

	std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
	&z, "therm1", inputs, setpoint, initial, ThermalType::margin);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getCachedValue(StrEq("fleeting0"))).WillOnce(Return(5.0));
	EXPECT_CALL(z, getCachedValue(StrEq("fleeting1"))).WillOnce(Return(10.0));

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

	TEST(ThermalControllerTest, NegHysteresis_BehavesAsExpected)
	{

	// This test verifies Negative hysteresis behaves as expected by
	// crossing the setpoint and noticing readings don't change until past the
	// hysteresis value

	ZoneMock z;

	std::vector<std::string> inputs = {"fleeting0"};
	double setpoint = 10.0;
	ec::pidinfo initial;
	initial.negativeHysteresis = 4.0;

	std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
	&z, "therm1", inputs, setpoint, initial, ThermalType::margin);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getCachedValue(StrEq("fleeting0")))
	.Times(3)
	.WillOnce(Return(12.0))
	.WillOnce(Return(9.0))
	.WillOnce(Return(7.0));

	EXPECT_CALL(z, addRPMSetPoint(_)).Times(3);

	std::vector<double> lastReadings = {12.0, 12.0, 7.0};
	for (auto& reading : lastReadings)
	{
	p->process();
	EXPECT_EQ(p->getLastInput(), reading);
	}
	}

	TEST(ThermalControllerTest, PosHysteresis_BehavesAsExpected)
	{
	// This test verifies Positive hysteresis behaves as expected by
	// crossing the setpoint and noticing readings don't change until past the
	// hysteresis value

	ZoneMock z;

	std::vector<std::string> inputs = {"fleeting0"};
	double setpoint = 10.0;
	ec::pidinfo initial;
	initial.positiveHysteresis = 5.0;

	std::unique_ptr<PIDController> p = ThermalController::createThermalPid(
	&z, "therm1", inputs, setpoint, initial, ThermalType::margin);
	EXPECT_FALSE(p == nullptr);

	EXPECT_CALL(z, getCachedValue(StrEq("fleeting0")))
	.Times(3)
	.WillOnce(Return(8.0))
	.WillOnce(Return(13.0))
	.WillOnce(Return(14.0));

	EXPECT_CALL(z, addRPMSetPoint(_)).Times(3);

	std::vector<double> lastReadings = {8.0, 8.0, 14.0};
	for (auto& reading : lastReadings)
	{
	p->process();
	EXPECT_EQ(p->getLastInput(), reading);
	}
	}