wpilibcIntegrationTests/src/main/native/cpp/DIOLoopTest.cpp - RealtimeRoboticsGroup/test - Gitiles

 // Copyright (c) FIRST and other WPILib contributors.
 // Open Source Software; you can modify and/or share it under the terms of
 // the WPILib BSD license file in the root directory of this project.

 #include "frc/DigitalInput.h"  // NOLINT(build/include_order)

 #include "frc/DigitalOutput.h"  // NOLINT(build/include_order)

 #include <units/math.h>
 #include <units/time.h>

 #include "TestBench.h"
 #include "frc/AsynchronousInterrupt.h"
 #include "frc/Counter.h"
 #include "frc/SynchronousInterrupt.h"
 #include "frc/Timer.h"
 #include "gtest/gtest.h"

 #define EXPECT_NEAR_UNITS(val1, val2, eps) \
   EXPECT_LE(units::math::abs(val1 - val2), eps)

 static constexpr auto kCounterTime = 1_ms;

 static constexpr auto kDelayTime = 100_ms;

 static constexpr auto kSynchronousInterruptTime = 2_s;
 static constexpr auto kSynchronousInterruptTimeTolerance = 10_ms;

 /**
  * A fixture with a digital input and a digital output physically wired
  * together.
  */
 class DIOLoopTest : public testing::Test {
  protected:
   frc::DigitalInput m_input{TestBench::kLoop1InputChannel};
   frc::DigitalOutput m_output{TestBench::kLoop1OutputChannel};

   void Reset() { m_output.Set(false); }
 };

 /**
  * Test the DigitalInput and DigitalOutput classes by setting the output and
  * reading the input.
  */
 TEST_F(DIOLoopTest, Loop) {
   Reset();

   m_output.Set(false);
   frc::Wait(kDelayTime);
   EXPECT_FALSE(m_input.Get()) << "The digital output was turned off, but "
                               << "the digital input is on.";

   m_output.Set(true);
   frc::Wait(kDelayTime);
   EXPECT_TRUE(m_input.Get()) << "The digital output was turned on, but "
                              << "the digital input is off.";
 }
 /**
  * Tests to see if the DIO PWM functionality works.
  */
 TEST_F(DIOLoopTest, DIOPWM) {
   Reset();

   m_output.Set(false);
   frc::Wait(kDelayTime);
   EXPECT_FALSE(m_input.Get()) << "The digital output was turned off, but "
                               << "the digital input is on.";

   // Set frequency to 2.0 Hz
   m_output.SetPWMRate(2.0);
   // Enable PWM, but leave it off
   m_output.EnablePWM(0.0);
   frc::Wait(0.5_s);
   m_output.UpdateDutyCycle(0.5);
   frc::SynchronousInterrupt interrupt{m_output};
   interrupt.SetInterruptEdges(false, true);
   frc::SynchronousInterrupt::WaitResult result =
       interrupt.WaitForInterrupt(3_s, true);

   frc::Wait(0.5_s);
   bool firstCycle = m_input.Get();
   frc::Wait(0.5_s);
   bool secondCycle = m_input.Get();
   frc::Wait(0.5_s);
   bool thirdCycle = m_input.Get();
   frc::Wait(0.5_s);
   bool forthCycle = m_input.Get();
   frc::Wait(0.5_s);
   bool fifthCycle = m_input.Get();
   frc::Wait(0.5_s);
   bool sixthCycle = m_input.Get();
   frc::Wait(0.5_s);
   bool seventhCycle = m_input.Get();
   m_output.DisablePWM();
   frc::Wait(0.5_s);
   bool firstAfterStop = m_input.Get();
   frc::Wait(0.5_s);
   bool secondAfterStop = m_input.Get();

   EXPECT_EQ(frc::SynchronousInterrupt::WaitResult::kFallingEdge, result)
       << "WaitForInterrupt was not falling.";

   EXPECT_FALSE(firstCycle) << "Input not low after first delay";
   EXPECT_TRUE(secondCycle) << "Input not high after second delay";
   EXPECT_FALSE(thirdCycle) << "Input not low after third delay";
   EXPECT_TRUE(forthCycle) << "Input not high after forth delay";
   EXPECT_FALSE(fifthCycle) << "Input not low after fifth delay";
   EXPECT_TRUE(sixthCycle) << "Input not high after sixth delay";
   EXPECT_FALSE(seventhCycle) << "Input not low after seventh delay";
   EXPECT_FALSE(firstAfterStop) << "Input not low after stopping first read";
   EXPECT_FALSE(secondAfterStop) << "Input not low after stopping second read";
 }

 /**
  * Test a fake "counter" that uses the DIO loop as an input to make sure the
  * Counter class works
  */
 TEST_F(DIOLoopTest, FakeCounter) {
   Reset();

   frc::Counter counter{&m_input};

   EXPECT_EQ(0, counter.Get()) << "Counter did not initialize to 0.";

   /* Count 100 ticks.  The counter value should be 100 after this loop. */
   for (int32_t i = 0; i < 100; ++i) {
     m_output.Set(true);
     frc::Wait(kCounterTime);
     m_output.Set(false);
     frc::Wait(kCounterTime);
   }

   EXPECT_EQ(100, counter.Get()) << "Counter did not count up to 100.";
 }

 TEST_F(DIOLoopTest, AsynchronousInterruptWorks) {
   Reset();

   int32_t param = 0;

   frc::AsynchronousInterrupt interrupt(m_input,
                                        [&](auto a, auto b) { param = 12345; });

   interrupt.Enable();
   // If the voltage rises
   m_output.Set(false);
   m_output.Set(true);

   // Then the int32_t should be 12345
   frc::Wait(kDelayTime);

   interrupt.Disable();

   EXPECT_EQ(12345, param) << "The interrupt did not run.";
 }

 TEST_F(DIOLoopTest, SynchronousInterruptWorks) {
   Reset();

   // Given a synchronous interrupt
   frc::SynchronousInterrupt interrupt(m_input);

   std::thread thr([this]() {
     m_output.Set(false);
     frc::Wait(kSynchronousInterruptTime);
     m_output.Set(true);
   });

   // Then this thread should pause and resume after that number of seconds
   frc::Timer timer;
   timer.Start();
   interrupt.WaitForInterrupt(kSynchronousInterruptTime + 1_s);
   auto time = timer.Get().value();
   if (thr.joinable())
     thr.join();
   EXPECT_NEAR(kSynchronousInterruptTime.value(), time,
               kSynchronousInterruptTimeTolerance.value());
 }
	// Copyright (c) FIRST and other WPILib contributors.
	// Open Source Software; you can modify and/or share it under the terms of
	// the WPILib BSD license file in the root directory of this project.

	#include "frc/DigitalInput.h" // NOLINT(build/include_order)

	#include "frc/DigitalOutput.h" // NOLINT(build/include_order)

	#include <units/math.h>
	#include <units/time.h>

	#include "TestBench.h"
	#include "frc/AsynchronousInterrupt.h"
	#include "frc/Counter.h"
	#include "frc/SynchronousInterrupt.h"
	#include "frc/Timer.h"
	#include "gtest/gtest.h"

	#define EXPECT_NEAR_UNITS(val1, val2, eps) \
	EXPECT_LE(units::math::abs(val1 - val2), eps)

	static constexpr auto kCounterTime = 1_ms;

	static constexpr auto kDelayTime = 100_ms;

	static constexpr auto kSynchronousInterruptTime = 2_s;
	static constexpr auto kSynchronousInterruptTimeTolerance = 10_ms;

	/**
	* A fixture with a digital input and a digital output physically wired
	* together.
	*/
	class DIOLoopTest : public testing::Test {
	protected:
	frc::DigitalInput m_input{TestBench::kLoop1InputChannel};
	frc::DigitalOutput m_output{TestBench::kLoop1OutputChannel};

	void Reset() { m_output.Set(false); }
	};

	/**
	* Test the DigitalInput and DigitalOutput classes by setting the output and
	* reading the input.
	*/
	TEST_F(DIOLoopTest, Loop) {
	Reset();

	m_output.Set(false);
	frc::Wait(kDelayTime);
	EXPECT_FALSE(m_input.Get()) << "The digital output was turned off, but "
	<< "the digital input is on.";

	m_output.Set(true);
	frc::Wait(kDelayTime);
	EXPECT_TRUE(m_input.Get()) << "The digital output was turned on, but "
	<< "the digital input is off.";
	}
	/**
	* Tests to see if the DIO PWM functionality works.
	*/
	TEST_F(DIOLoopTest, DIOPWM) {
	Reset();

	m_output.Set(false);
	frc::Wait(kDelayTime);
	EXPECT_FALSE(m_input.Get()) << "The digital output was turned off, but "
	<< "the digital input is on.";

	// Set frequency to 2.0 Hz
	m_output.SetPWMRate(2.0);
	// Enable PWM, but leave it off
	m_output.EnablePWM(0.0);
	frc::Wait(0.5_s);
	m_output.UpdateDutyCycle(0.5);
	frc::SynchronousInterrupt interrupt{m_output};
	interrupt.SetInterruptEdges(false, true);
	frc::SynchronousInterrupt::WaitResult result =
	interrupt.WaitForInterrupt(3_s, true);

	frc::Wait(0.5_s);
	bool firstCycle = m_input.Get();
	frc::Wait(0.5_s);
	bool secondCycle = m_input.Get();
	frc::Wait(0.5_s);
	bool thirdCycle = m_input.Get();
	frc::Wait(0.5_s);
	bool forthCycle = m_input.Get();
	frc::Wait(0.5_s);
	bool fifthCycle = m_input.Get();
	frc::Wait(0.5_s);
	bool sixthCycle = m_input.Get();
	frc::Wait(0.5_s);
	bool seventhCycle = m_input.Get();
	m_output.DisablePWM();
	frc::Wait(0.5_s);
	bool firstAfterStop = m_input.Get();
	frc::Wait(0.5_s);
	bool secondAfterStop = m_input.Get();

	EXPECT_EQ(frc::SynchronousInterrupt::WaitResult::kFallingEdge, result)
	<< "WaitForInterrupt was not falling.";

	EXPECT_FALSE(firstCycle) << "Input not low after first delay";
	EXPECT_TRUE(secondCycle) << "Input not high after second delay";
	EXPECT_FALSE(thirdCycle) << "Input not low after third delay";
	EXPECT_TRUE(forthCycle) << "Input not high after forth delay";
	EXPECT_FALSE(fifthCycle) << "Input not low after fifth delay";
	EXPECT_TRUE(sixthCycle) << "Input not high after sixth delay";
	EXPECT_FALSE(seventhCycle) << "Input not low after seventh delay";
	EXPECT_FALSE(firstAfterStop) << "Input not low after stopping first read";
	EXPECT_FALSE(secondAfterStop) << "Input not low after stopping second read";
	}

	/**
	* Test a fake "counter" that uses the DIO loop as an input to make sure the
	* Counter class works
	*/
	TEST_F(DIOLoopTest, FakeCounter) {
	Reset();

	frc::Counter counter{&m_input};

	EXPECT_EQ(0, counter.Get()) << "Counter did not initialize to 0.";

	/* Count 100 ticks. The counter value should be 100 after this loop. */
	for (int32_t i = 0; i < 100; ++i) {
	m_output.Set(true);
	frc::Wait(kCounterTime);
	m_output.Set(false);
	frc::Wait(kCounterTime);
	}

	EXPECT_EQ(100, counter.Get()) << "Counter did not count up to 100.";
	}

	TEST_F(DIOLoopTest, AsynchronousInterruptWorks) {
	Reset();

	int32_t param = 0;

	frc::AsynchronousInterrupt interrupt(m_input,
	[&](auto a, auto b) { param = 12345; });

	interrupt.Enable();
	// If the voltage rises
	m_output.Set(false);
	m_output.Set(true);

	// Then the int32_t should be 12345
	frc::Wait(kDelayTime);

	interrupt.Disable();

	EXPECT_EQ(12345, param) << "The interrupt did not run.";
	}

	TEST_F(DIOLoopTest, SynchronousInterruptWorks) {
	Reset();

	// Given a synchronous interrupt
	frc::SynchronousInterrupt interrupt(m_input);

	std::thread thr([this]() {
	m_output.Set(false);
	frc::Wait(kSynchronousInterruptTime);
	m_output.Set(true);
	});

	// Then this thread should pause and resume after that number of seconds
	frc::Timer timer;
	timer.Start();
	interrupt.WaitForInterrupt(kSynchronousInterruptTime + 1_s);
	auto time = timer.Get().value();
	if (thr.joinable())
	thr.join();
	EXPECT_NEAR(kSynchronousInterruptTime.value(), time,
	kSynchronousInterruptTimeTolerance.value());
	}