wpilibcIntegrationTests/src/FakeEncoderTest.cpp - RealtimeRoboticsGroup/test - Gitiles

 /*----------------------------------------------------------------------------*/
 /* Copyright (c) FIRST 2014. All Rights Reserved.                             */
 /* Open Source Software - may be modified and shared by FRC teams. The code
  */
 /* must be accompanied by the FIRST BSD license file in the root directory of */
 /* the project.                                                               */
 /*----------------------------------------------------------------------------*/

 #include <AnalogOutput.h>
 #include <AnalogTrigger.h>
 #include <DigitalOutput.h>
 #include <Encoder.h>
 #include <Timer.h>
 #include "gtest/gtest.h"
 #include "TestBench.h"

 static const double kDelayTime = 0.001;

 class FakeEncoderTest : public testing::Test {
  protected:
   DigitalOutput *m_outputA;
   DigitalOutput *m_outputB;
   AnalogOutput *m_indexOutput;

   Encoder *m_encoder;
   AnalogTrigger *m_indexAnalogTrigger;
   std::shared_ptr<AnalogTriggerOutput> m_indexAnalogTriggerOutput;

   virtual void SetUp() override {
     m_outputA = new DigitalOutput(TestBench::kLoop2OutputChannel);
     m_outputB = new DigitalOutput(TestBench::kLoop1OutputChannel);
     m_indexOutput = new AnalogOutput(TestBench::kAnalogOutputChannel);
     m_outputA->Set(false);
     m_outputB->Set(false);
     m_encoder = new Encoder(TestBench::kLoop1InputChannel,
                             TestBench::kLoop2InputChannel);
     m_indexAnalogTrigger =
         new AnalogTrigger(TestBench::kFakeAnalogOutputChannel);
     m_indexAnalogTrigger->SetLimitsVoltage(2.0, 3.0);
     m_indexAnalogTriggerOutput =
         m_indexAnalogTrigger->CreateOutput(AnalogTriggerType::kState);
   }

   virtual void TearDown() override {
     delete m_outputA;
     delete m_outputB;
     delete m_indexOutput;
     delete m_encoder;
     delete m_indexAnalogTrigger;
   }

   /**
    * Output pulses to the encoder's input channels to simulate a change of 100
    * ticks
    */
   void Simulate100QuadratureTicks() {
     for (int i = 0; i < 100; i++) {
       m_outputA->Set(true);
       Wait(kDelayTime);
       m_outputB->Set(true);
       Wait(kDelayTime);
       m_outputA->Set(false);
       Wait(kDelayTime);
       m_outputB->Set(false);
       Wait(kDelayTime);
     }
   }

   void SetIndexHigh() {
     m_indexOutput->SetVoltage(5.0);
     Wait(kDelayTime);
   }

   void SetIndexLow() {
     m_indexOutput->SetVoltage(0.0);
     Wait(kDelayTime);
   }
 };

 /**
  * Test the encoder by reseting it to 0 and reading the value.
  */
 TEST_F(FakeEncoderTest, TestDefaultState) {
   EXPECT_FLOAT_EQ(0.0f, m_encoder->Get()) << "The encoder did not start at 0.";
 }

 /**
  * Test the encoder by setting the digital outputs and reading the value.
  */
 TEST_F(FakeEncoderTest, TestCountUp) {
   m_encoder->Reset();
   Simulate100QuadratureTicks();

   EXPECT_FLOAT_EQ(100.0f, m_encoder->Get()) << "Encoder did not count to 100.";
 }

 /**
  * Test that the encoder can stay reset while the index source is high
  */
 TEST_F(FakeEncoderTest, TestResetWhileHigh) {
   m_encoder->SetIndexSource(*m_indexAnalogTriggerOutput,
                             Encoder::IndexingType::kResetWhileHigh);

   SetIndexLow();
   Simulate100QuadratureTicks();
   SetIndexHigh();
   EXPECT_EQ(0, m_encoder->Get());

   Simulate100QuadratureTicks();
   EXPECT_EQ(0, m_encoder->Get());
 }

 /**
  * Test that the encoder can reset when the index source goes from low to high
  */
 TEST_F(FakeEncoderTest, TestResetOnRisingEdge) {
   m_encoder->SetIndexSource(*m_indexAnalogTriggerOutput,
                             Encoder::IndexingType::kResetOnRisingEdge);

   SetIndexLow();
   Simulate100QuadratureTicks();
   SetIndexHigh();
   EXPECT_EQ(0, m_encoder->Get());

   Simulate100QuadratureTicks();
   EXPECT_EQ(100, m_encoder->Get());
 }

 /**
  * Test that the encoder can stay reset while the index source is low
  */
 TEST_F(FakeEncoderTest, TestResetWhileLow) {
   m_encoder->SetIndexSource(*m_indexAnalogTriggerOutput,
                             Encoder::IndexingType::kResetWhileLow);

   SetIndexHigh();
   Simulate100QuadratureTicks();
   SetIndexLow();
   EXPECT_EQ(0, m_encoder->Get());

   Simulate100QuadratureTicks();
   EXPECT_EQ(0, m_encoder->Get());
 }

 /**
  * Test that the encoder can reset when the index source goes from high to low
  */
 TEST_F(FakeEncoderTest, TestResetOnFallingEdge) {
   m_encoder->SetIndexSource(*m_indexAnalogTriggerOutput,
                             Encoder::IndexingType::kResetOnFallingEdge);

   SetIndexHigh();
   Simulate100QuadratureTicks();
   SetIndexLow();
   EXPECT_EQ(0, m_encoder->Get());

   Simulate100QuadratureTicks();
   EXPECT_EQ(100, m_encoder->Get());
 }
	/----------------------------------------------------------------------------/
	/* Copyright (c) FIRST 2014. All Rights Reserved. */
	/* Open Source Software - may be modified and shared by FRC teams. The code
	*/
	/* must be accompanied by the FIRST BSD license file in the root directory of */
	/* the project. */
	/----------------------------------------------------------------------------/

	#include <AnalogOutput.h>
	#include <AnalogTrigger.h>
	#include <DigitalOutput.h>
	#include <Encoder.h>
	#include <Timer.h>
	#include "gtest/gtest.h"
	#include "TestBench.h"

	static const double kDelayTime = 0.001;

	class FakeEncoderTest : public testing::Test {
	protected:
	DigitalOutput *m_outputA;
	DigitalOutput *m_outputB;
	AnalogOutput *m_indexOutput;

	Encoder *m_encoder;
	AnalogTrigger *m_indexAnalogTrigger;
	std::shared_ptr<AnalogTriggerOutput> m_indexAnalogTriggerOutput;

	virtual void SetUp() override {
	m_outputA = new DigitalOutput(TestBench::kLoop2OutputChannel);
	m_outputB = new DigitalOutput(TestBench::kLoop1OutputChannel);
	m_indexOutput = new AnalogOutput(TestBench::kAnalogOutputChannel);
	m_outputA->Set(false);
	m_outputB->Set(false);
	m_encoder = new Encoder(TestBench::kLoop1InputChannel,
	TestBench::kLoop2InputChannel);
	m_indexAnalogTrigger =
	new AnalogTrigger(TestBench::kFakeAnalogOutputChannel);
	m_indexAnalogTrigger->SetLimitsVoltage(2.0, 3.0);
	m_indexAnalogTriggerOutput =
	m_indexAnalogTrigger->CreateOutput(AnalogTriggerType::kState);
	}

	virtual void TearDown() override {
	delete m_outputA;
	delete m_outputB;
	delete m_indexOutput;
	delete m_encoder;
	delete m_indexAnalogTrigger;
	}

	/**
	* Output pulses to the encoder's input channels to simulate a change of 100
	* ticks
	*/
	void Simulate100QuadratureTicks() {
	for (int i = 0; i < 100; i++) {
	m_outputA->Set(true);
	Wait(kDelayTime);
	m_outputB->Set(true);
	Wait(kDelayTime);
	m_outputA->Set(false);
	Wait(kDelayTime);
	m_outputB->Set(false);
	Wait(kDelayTime);
	}
	}

	void SetIndexHigh() {
	m_indexOutput->SetVoltage(5.0);
	Wait(kDelayTime);
	}

	void SetIndexLow() {
	m_indexOutput->SetVoltage(0.0);
	Wait(kDelayTime);
	}
	};

	/**
	* Test the encoder by reseting it to 0 and reading the value.
	*/
	TEST_F(FakeEncoderTest, TestDefaultState) {
	EXPECT_FLOAT_EQ(0.0f, m_encoder->Get()) << "The encoder did not start at 0.";
	}

	/**
	* Test the encoder by setting the digital outputs and reading the value.
	*/
	TEST_F(FakeEncoderTest, TestCountUp) {
	m_encoder->Reset();
	Simulate100QuadratureTicks();

	EXPECT_FLOAT_EQ(100.0f, m_encoder->Get()) << "Encoder did not count to 100.";
	}

	/**
	* Test that the encoder can stay reset while the index source is high
	*/
	TEST_F(FakeEncoderTest, TestResetWhileHigh) {
	m_encoder->SetIndexSource(*m_indexAnalogTriggerOutput,
	Encoder::IndexingType::kResetWhileHigh);

	SetIndexLow();
	Simulate100QuadratureTicks();
	SetIndexHigh();
	EXPECT_EQ(0, m_encoder->Get());

	Simulate100QuadratureTicks();
	EXPECT_EQ(0, m_encoder->Get());
	}

	/**
	* Test that the encoder can reset when the index source goes from low to high
	*/
	TEST_F(FakeEncoderTest, TestResetOnRisingEdge) {
	m_encoder->SetIndexSource(*m_indexAnalogTriggerOutput,
	Encoder::IndexingType::kResetOnRisingEdge);

	SetIndexLow();
	Simulate100QuadratureTicks();
	SetIndexHigh();
	EXPECT_EQ(0, m_encoder->Get());

	Simulate100QuadratureTicks();
	EXPECT_EQ(100, m_encoder->Get());
	}

	/**
	* Test that the encoder can stay reset while the index source is low
	*/
	TEST_F(FakeEncoderTest, TestResetWhileLow) {
	m_encoder->SetIndexSource(*m_indexAnalogTriggerOutput,
	Encoder::IndexingType::kResetWhileLow);

	SetIndexHigh();
	Simulate100QuadratureTicks();
	SetIndexLow();
	EXPECT_EQ(0, m_encoder->Get());

	Simulate100QuadratureTicks();
	EXPECT_EQ(0, m_encoder->Get());
	}

	/**
	* Test that the encoder can reset when the index source goes from high to low
	*/
	TEST_F(FakeEncoderTest, TestResetOnFallingEdge) {
	m_encoder->SetIndexSource(*m_indexAnalogTriggerOutput,
	Encoder::IndexingType::kResetOnFallingEdge);

	SetIndexHigh();
	Simulate100QuadratureTicks();
	SetIndexLow();
	EXPECT_EQ(0, m_encoder->Get());

	Simulate100QuadratureTicks();
	EXPECT_EQ(100, m_encoder->Get());
	}