wpilibc/wpilibC++Sim/src/IterativeRobot.cpp

/*----------------------------------------------------------------------------*/
/* Copyright (c) FIRST 2008. 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 $(WIND_BASE)/WPILib.  */
/*----------------------------------------------------------------------------*/

#include "IterativeRobot.h"

#include "DriverStation.h"
#include "SmartDashboard/SmartDashboard.h"
#include "LiveWindow/LiveWindow.h"
#include "networktables/NetworkTable.h"

#include <unistd.h>

constexpr double IterativeRobot::kDefaultPeriod;

/**
 * Constructor for RobotIterativeBase
 * 
 * The constructor initializes the instance variables for the robot to indicate
 * the status of initialization for disabled, autonomous, teleop, and test code.
 */
IterativeRobot::IterativeRobot()
	: m_disabledInitialized (false)
	, m_autonomousInitialized (false)
	, m_teleopInitialized (false)
	, m_testInitialized (false)
	, m_period (kDefaultPeriod)
{
}

/**
 * Free the resources for a RobotIterativeBase class.
 */
IterativeRobot::~IterativeRobot()
{
}

/**
 * Set the period for the periodic functions.
 * 
 * @param period The period of the periodic function calls.  0.0 means sync to driver station control data.
 */
void IterativeRobot::SetPeriod(double period)
{
	if (period > 0.0)
	{
		// Not syncing with the DS, so start the timer for the main loop
		m_mainLoopTimer.Reset();
		m_mainLoopTimer.Start();
	}
	else
	{
		// Syncing with the DS, don't need the timer
		m_mainLoopTimer.Stop();
	}
	m_period = period;
}

/**
 * Get the period for the periodic functions.
 * Returns 0.0 if configured to syncronize with DS control data packets.
 * @return Period of the periodic function calls
 */
double IterativeRobot::GetPeriod()
{
	return m_period;
}

/**
 * Get the number of loops per second for the IterativeRobot
 * @return Frequency of the periodic function calls
 */
double IterativeRobot::GetLoopsPerSec()
{
	// If syncing to the driver station, we don't know the rate,
	//   so guess something close.
	if (m_period <= 0.0)
		return 50.0;
	return 1.0 / m_period;
}

/**
 * Provide an alternate "main loop" via StartCompetition().
 * 
 * This specific StartCompetition() implements "main loop" behavior like that of the FRC
 * control system in 2008 and earlier, with a primary (slow) loop that is
 * called periodically, and a "fast loop" (a.k.a. "spin loop") that is 
 * called as fast as possible with no delay between calls. 
 */
void IterativeRobot::StartCompetition()
{
	LiveWindow *lw = LiveWindow::GetInstance();
	// first and one-time initialization
	SmartDashboard::init();
	NetworkTable::GetTable("LiveWindow")->GetSubTable("~STATUS~")->PutBoolean("LW Enabled", false);
	RobotInit();

	// loop forever, calling the appropriate mode-dependent function
	lw->SetEnabled(false);
	while (true)
	{
		// Call the appropriate function depending upon the current robot mode
		if (IsDisabled())
		{
			// call DisabledInit() if we are now just entering disabled mode from
			// either a different mode or from power-on
			if(!m_disabledInitialized)
			{
				lw->SetEnabled(false);
				DisabledInit();
				m_disabledInitialized = true;
				// reset the initialization flags for the other modes
				m_autonomousInitialized = false;
                m_teleopInitialized = false;
                m_testInitialized = false;
			}
			if (NextPeriodReady())
			{
                // TODO: HALNetworkCommunicationObserveUserProgramDisabled();
				DisabledPeriodic();
			}
		}
		else if (IsAutonomous())
		{
			// call AutonomousInit() if we are now just entering autonomous mode from
			// either a different mode or from power-on
			if(!m_autonomousInitialized)
			{
				lw->SetEnabled(false);
				AutonomousInit();
				m_autonomousInitialized = true;
				// reset the initialization flags for the other modes
				m_disabledInitialized = false;
                m_teleopInitialized = false;
                m_testInitialized = false;
			}
			if (NextPeriodReady())
			{
				// TODO: HALNetworkCommunicationObserveUserProgramAutonomous();
				AutonomousPeriodic();
			}
		}
        else if (IsTest())
        {
            // call TestInit() if we are now just entering test mode from
            // either a different mode or from power-on
            if(!m_testInitialized)
            {
            	lw->SetEnabled(true);
                TestInit();
                m_testInitialized = true;
                // reset the initialization flags for the other modes
                m_disabledInitialized = false;
                m_autonomousInitialized = false;
                m_teleopInitialized = false;
            }
            if (NextPeriodReady())
            {
                // TODO: HALNetworkCommunicationObserveUserProgramTest();
                TestPeriodic();
            }
        }
		else
		{
			// call TeleopInit() if we are now just entering teleop mode from
			// either a different mode or from power-on
			if(!m_teleopInitialized)
			{
				lw->SetEnabled(false);
				TeleopInit();
				m_teleopInitialized = true;
				// reset the initialization flags for the other modes
				m_disabledInitialized = false;
                m_autonomousInitialized = false;
                m_testInitialized = false;
                Scheduler::GetInstance()->SetEnabled(true);
			}
			if (NextPeriodReady())
			{
				// TODO: HALNetworkCommunicationObserveUserProgramTeleop();
				TeleopPeriodic();
			}
		}
		// wait for driver station data so the loop doesn't hog the CPU
        m_ds->WaitForData();
	}	
}

/**
 * Determine if the periodic functions should be called.
 *
 * If m_period > 0.0, call the periodic function every m_period as compared
 * to Timer.Get().  If m_period == 0.0, call the periodic functions whenever
 * a packet is received from the Driver Station, or about every 20ms.
 *
 * @todo Decide what this should do if it slips more than one cycle.
 */

bool IterativeRobot::NextPeriodReady()
{
	if (m_period > 0.0)
	{
		return m_mainLoopTimer.HasPeriodPassed(m_period);
	}
	else
	{
		// XXX: BROKEN! return m_ds->IsNewControlData();
	}
    return true;
}

/**
 * Robot-wide initialization code should go here.
 * 
 * Users should override this method for default Robot-wide initialization which will
 * be called when the robot is first powered on.  It will be called exactly 1 time.
 */
void IterativeRobot::RobotInit()
{
	printf("Default %s() method... Overload me!\n", __FUNCTION__);
}

/**
 * Initialization code for disabled mode should go here.
 * 
 * Users should override this method for initialization code which will be called each time
 * the robot enters disabled mode.
 */
void IterativeRobot::DisabledInit()
{
	printf("Default %s() method... Overload me!\n", __FUNCTION__);
}

/**
 * Initialization code for autonomous mode should go here.
 * 
 * Users should override this method for initialization code which will be called each time
 * the robot enters autonomous mode.
 */
void IterativeRobot::AutonomousInit()
{
	printf("Default %s() method... Overload me!\n", __FUNCTION__);
}

/**
 * Initialization code for teleop mode should go here.
 * 
 * Users should override this method for initialization code which will be called each time
 * the robot enters teleop mode.
 */
void IterativeRobot::TeleopInit()
{
    printf("Default %s() method... Overload me!\n", __FUNCTION__);
}

/**
 * Initialization code for test mode should go here.
 * 
 * Users should override this method for initialization code which will be called each time
 * the robot enters test mode.
 */
void IterativeRobot::TestInit()
{
    printf("Default %s() method... Overload me!\n", __FUNCTION__);
}

/**
 * Periodic code for disabled mode should go here.
 * 
 * Users should override this method for code which will be called periodically at a regular
 * rate while the robot is in disabled mode.
 */
void IterativeRobot::DisabledPeriodic()
{
	static bool firstRun = true;
	if (firstRun)
	{
		printf("Default %s() method... Overload me!\n", __FUNCTION__);
		firstRun = false;
	}
}

/**
 * Periodic code for autonomous mode should go here.
 *
 * Users should override this method for code which will be called periodically at a regular
 * rate while the robot is in autonomous mode.
 */
void IterativeRobot::AutonomousPeriodic()
{
	static bool firstRun = true;
	if (firstRun)
	{
		printf("Default %s() method... Overload me!\n", __FUNCTION__);
		firstRun = false;
	}
}

/**
 * Periodic code for teleop mode should go here.
 *
 * Users should override this method for code which will be called periodically at a regular
 * rate while the robot is in teleop mode.
 */
void IterativeRobot::TeleopPeriodic()
{
	static bool firstRun = true;
	if (firstRun)
	{
		printf("Default %s() method... Overload me!\n", __FUNCTION__);
		firstRun = false;
	}
}

/**
 * Periodic code for test mode should go here.
 *
 * Users should override this method for code which will be called periodically at a regular
 * rate while the robot is in test mode.
 */
void IterativeRobot::TestPeriodic()
{
    static bool firstRun = true;
    if (firstRun)
    {
        printf("Default %s() method... Overload me!\n", __FUNCTION__);
        firstRun = false;
    }
}
Initial commit of the WPILib simulation support in an alpha quality state. Fixes to deal with the switch to .hpp files in the HAL and other misc problems due to rebasing. Added Omar's changes to the compressor interface Fixes to make C++ plugin compile on linux. Added import of the WPILibSim code from the graduate class. It shows up as wpilibJavaSim to follow the convention set by wpilibJava, wpilibJavaJNI and wpilibJavaFinal. Fixed wpilibJavaSim artifactId to mirror the new convention. Modified the build of the java plugin to pull in the simulation dependencies. Added stacktrace printing. Fixed support for creating projects. Added support for the isReal() and isSimulation() methods along with the AnalogPotentiometer object to support simulating GearsBot. Added support for a "WPILib Simulate" button. Added GearsBot to the built in examples. Added support for specifying the world file during project creation and switched the default from BluntObjectBot to GearsBot. Removed unused import. Added file browser for world files. Added support for debugging in simulation. Change simulate icon to be a Gazebo icon. Switched over to the gazebo messaging system. Updated location of default world file. Reverted cmake change. Fixed bug in WPILibJSim, added better logging and cleaned up code. Made the frc_gazebo_plugin build using raw cmake instead of catkin, breaking the final ROS dependencies. Added installation to frc_gazebo_plugin Makefile. Fixed running of simulation to actually use frcsim. Initial commit of simulation library for C++. Has the minimal subset of features necessary for having a Simple Robot run in teleoperated mode. Added notes for generating protobuf messages. Import of the debuild process into the main repository. Moved frc_gazebo_plugin under simulation and removed the gazebo folder. Updated the gazebo plugin to remove excessive printing and limit motor signal to [-1,1]. Updated WPILibJSim to support latching messages and to sleep for 20ms in iterative robot. Reduced delay between starting frcsim and the users program to 1 second. Updated GearsBot example. Fixed a few minor issues for demoable state. Added simulator support for Victors, Jaguars and Talons. Added NetworkTables, SmartDashboard and LiveWindow to the simulator. Added AnalogPotentiometer for simulation. Added support for simulating encoders. Added simulation support for Gyro. Added IterativeRobot, Fixed Timers, Notifiers, PIDControllers and other minor fixes + cleanup. Added RobotDrive support to simulation. Separated out JavaGazebo so that SimDS will be able to reuse it. Separated out SimDS into its own application.. Fixes so that the SimDS is distributed and runs properly for Java with the eclipse plugins. Added DriverStation support to WPILibCSim Cleanup of DriverStation, WaitUntilCommand and AnalogPotentiometer for WPILibCSim. Cleanup of includes for WPILibCSim Added AnalogPotentiometer to the real WPILibC. Added AnalogPotentiometer to the real WPILibC. Added GearsBot example to C++ eclipse plugin. WPILibCSim fixes to work with launching from the plugin. Package libwpilibsim in a deb file. Added includes to plugin distribution. Added support for external-limit-switches to Gazebo, Java and C++. Added support for Gazebo Rangefinders and Analog channels to read their values in C++ and Java. Added support for internal limit switches. Updated GearsBot programs to use limit switches + range finders. Added disabling of motors when robot is disabled to more closely mimic the real robot. Fixes to deal with the switch to .hpp files in the HAL and other misc problems due to rebasing. Change-Id: I624c5f4d0f28282616a7c92083575bf68adcdce2 2014-06-12 11:02:26 -07:00			`/----------------------------------------------------------------------------/`
			`/* Copyright (c) FIRST 2008. 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 $(WIND_BASE)/WPILib. */`
			`/----------------------------------------------------------------------------/`

			`#include "IterativeRobot.h"`

			`#include "DriverStation.h"`
			`#include "SmartDashboard/SmartDashboard.h"`
			`#include "LiveWindow/LiveWindow.h"`
			`#include "networktables/NetworkTable.h"`

			`#include <unistd.h>`

			`constexpr double IterativeRobot::kDefaultPeriod;`

			`/**`
			`* Constructor for RobotIterativeBase`
			`*`
			`* The constructor initializes the instance variables for the robot to indicate`
			`* the status of initialization for disabled, autonomous, teleop, and test code.`
			`*/`
			`IterativeRobot::IterativeRobot()`
			`: m_disabledInitialized (false)`
			`, m_autonomousInitialized (false)`
			`, m_teleopInitialized (false)`
			`, m_testInitialized (false)`
			`, m_period (kDefaultPeriod)`
			`{`
			`}`

			`/**`
			`* Free the resources for a RobotIterativeBase class.`
			`*/`
			`IterativeRobot::~IterativeRobot()`
			`{`
			`}`

			`/**`
			`* Set the period for the periodic functions.`
			`*`
			`* @param period The period of the periodic function calls. 0.0 means sync to driver station control data.`
			`*/`
			`void IterativeRobot::SetPeriod(double period)`
			`{`
			`if (period > 0.0)`
			`{`
			`// Not syncing with the DS, so start the timer for the main loop`
			`m_mainLoopTimer.Reset();`
			`m_mainLoopTimer.Start();`
			`}`
			`else`
			`{`
			`// Syncing with the DS, don't need the timer`
			`m_mainLoopTimer.Stop();`
			`}`
			`m_period = period;`
			`}`

			`/**`
			`* Get the period for the periodic functions.`
			`* Returns 0.0 if configured to syncronize with DS control data packets.`
			`* @return Period of the periodic function calls`
			`*/`
			`double IterativeRobot::GetPeriod()`
			`{`
			`return m_period;`
			`}`

			`/**`
			`* Get the number of loops per second for the IterativeRobot`
			`* @return Frequency of the periodic function calls`
			`*/`
			`double IterativeRobot::GetLoopsPerSec()`
			`{`
			`// If syncing to the driver station, we don't know the rate,`
			`// so guess something close.`
			`if (m_period <= 0.0)`
			`return 50.0;`
			`return 1.0 / m_period;`
			`}`

			`/**`
			`* Provide an alternate "main loop" via StartCompetition().`
			`*`
			`* This specific StartCompetition() implements "main loop" behavior like that of the FRC`
			`* control system in 2008 and earlier, with a primary (slow) loop that is`
			`* called periodically, and a "fast loop" (a.k.a. "spin loop") that is`
			`* called as fast as possible with no delay between calls.`
			`*/`
			`void IterativeRobot::StartCompetition()`
			`{`
			`LiveWindow *lw = LiveWindow::GetInstance();`
			`// first and one-time initialization`
			`SmartDashboard::init();`
			`NetworkTable::GetTable("LiveWindow")->GetSubTable("~STATUS~")->PutBoolean("LW Enabled", false);`
			`RobotInit();`

			`// loop forever, calling the appropriate mode-dependent function`
			`lw->SetEnabled(false);`
			`while (true)`
			`{`
			`// Call the appropriate function depending upon the current robot mode`
			`if (IsDisabled())`
			`{`
			`// call DisabledInit() if we are now just entering disabled mode from`
			`// either a different mode or from power-on`
			`if(!m_disabledInitialized)`
			`{`
			`lw->SetEnabled(false);`
			`DisabledInit();`
			`m_disabledInitialized = true;`
			`// reset the initialization flags for the other modes`
			`m_autonomousInitialized = false;`
			`m_teleopInitialized = false;`
			`m_testInitialized = false;`
			`}`
			`if (NextPeriodReady())`
			`{`
			`// TODO: HALNetworkCommunicationObserveUserProgramDisabled();`
			`DisabledPeriodic();`
			`}`
			`}`
			`else if (IsAutonomous())`
			`{`
			`// call AutonomousInit() if we are now just entering autonomous mode from`
			`// either a different mode or from power-on`
			`if(!m_autonomousInitialized)`
			`{`
			`lw->SetEnabled(false);`
			`AutonomousInit();`
			`m_autonomousInitialized = true;`
			`// reset the initialization flags for the other modes`
			`m_disabledInitialized = false;`
			`m_teleopInitialized = false;`
			`m_testInitialized = false;`
			`}`
			`if (NextPeriodReady())`
			`{`
			`// TODO: HALNetworkCommunicationObserveUserProgramAutonomous();`
			`AutonomousPeriodic();`
			`}`
			`}`
			`else if (IsTest())`
			`{`
			`// call TestInit() if we are now just entering test mode from`
			`// either a different mode or from power-on`
			`if(!m_testInitialized)`
			`{`
			`lw->SetEnabled(true);`
			`TestInit();`
			`m_testInitialized = true;`
			`// reset the initialization flags for the other modes`
			`m_disabledInitialized = false;`
			`m_autonomousInitialized = false;`
			`m_teleopInitialized = false;`
			`}`
			`if (NextPeriodReady())`
			`{`
			`// TODO: HALNetworkCommunicationObserveUserProgramTest();`
			`TestPeriodic();`
			`}`
			`}`
			`else`
			`{`
			`// call TeleopInit() if we are now just entering teleop mode from`
			`// either a different mode or from power-on`
			`if(!m_teleopInitialized)`
			`{`
			`lw->SetEnabled(false);`
			`TeleopInit();`
			`m_teleopInitialized = true;`
			`// reset the initialization flags for the other modes`
			`m_disabledInitialized = false;`
			`m_autonomousInitialized = false;`
			`m_testInitialized = false;`
			`Scheduler::GetInstance()->SetEnabled(true);`
			`}`
			`if (NextPeriodReady())`
			`{`
			`// TODO: HALNetworkCommunicationObserveUserProgramTeleop();`
			`TeleopPeriodic();`
			`}`
			`}`
			`// wait for driver station data so the loop doesn't hog the CPU`
			`m_ds->WaitForData();`
			`}`
			`}`

			`/**`
			`* Determine if the periodic functions should be called.`
			`*`
			`* If m_period > 0.0, call the periodic function every m_period as compared`
			`* to Timer.Get(). If m_period == 0.0, call the periodic functions whenever`
			`* a packet is received from the Driver Station, or about every 20ms.`
			`*`
			`* @todo Decide what this should do if it slips more than one cycle.`
			`*/`

			`bool IterativeRobot::NextPeriodReady()`
			`{`
			`if (m_period > 0.0)`
			`{`
			`return m_mainLoopTimer.HasPeriodPassed(m_period);`
			`}`
			`else`
			`{`
			`// XXX: BROKEN! return m_ds->IsNewControlData();`
			`}`
			`return true;`
			`}`

			`/**`
			`* Robot-wide initialization code should go here.`
			`*`
			`* Users should override this method for default Robot-wide initialization which will`
			`* be called when the robot is first powered on. It will be called exactly 1 time.`
			`*/`
			`void IterativeRobot::RobotInit()`
			`{`
			`printf("Default %s() method... Overload me!\n", __FUNCTION__);`
			`}`

			`/**`
			`* Initialization code for disabled mode should go here.`
			`*`
			`* Users should override this method for initialization code which will be called each time`
			`* the robot enters disabled mode.`
			`*/`
			`void IterativeRobot::DisabledInit()`
			`{`
			`printf("Default %s() method... Overload me!\n", __FUNCTION__);`
			`}`

			`/**`
			`* Initialization code for autonomous mode should go here.`
			`*`
			`* Users should override this method for initialization code which will be called each time`
			`* the robot enters autonomous mode.`
			`*/`
			`void IterativeRobot::AutonomousInit()`
			`{`
			`printf("Default %s() method... Overload me!\n", __FUNCTION__);`
			`}`

			`/**`
			`* Initialization code for teleop mode should go here.`
			`*`
			`* Users should override this method for initialization code which will be called each time`
			`* the robot enters teleop mode.`
			`*/`
			`void IterativeRobot::TeleopInit()`
			`{`
			`printf("Default %s() method... Overload me!\n", __FUNCTION__);`
			`}`

			`/**`
			`* Initialization code for test mode should go here.`
			`*`
			`* Users should override this method for initialization code which will be called each time`
			`* the robot enters test mode.`
			`*/`
			`void IterativeRobot::TestInit()`
			`{`
			`printf("Default %s() method... Overload me!\n", __FUNCTION__);`
			`}`

			`/**`
			`* Periodic code for disabled mode should go here.`
			`*`
			`* Users should override this method for code which will be called periodically at a regular`
			`* rate while the robot is in disabled mode.`
			`*/`
			`void IterativeRobot::DisabledPeriodic()`
			`{`
			`static bool firstRun = true;`
			`if (firstRun)`
			`{`
			`printf("Default %s() method... Overload me!\n", __FUNCTION__);`
			`firstRun = false;`
			`}`
			`}`

			`/**`
			`* Periodic code for autonomous mode should go here.`
			`*`
			`* Users should override this method for code which will be called periodically at a regular`
			`* rate while the robot is in autonomous mode.`
			`*/`
			`void IterativeRobot::AutonomousPeriodic()`
			`{`
			`static bool firstRun = true;`
			`if (firstRun)`
			`{`
			`printf("Default %s() method... Overload me!\n", __FUNCTION__);`
			`firstRun = false;`
			`}`
			`}`

			`/**`
			`* Periodic code for teleop mode should go here.`
			`*`
			`* Users should override this method for code which will be called periodically at a regular`
			`* rate while the robot is in teleop mode.`
			`*/`
			`void IterativeRobot::TeleopPeriodic()`
			`{`
			`static bool firstRun = true;`
			`if (firstRun)`
			`{`
			`printf("Default %s() method... Overload me!\n", __FUNCTION__);`
			`firstRun = false;`
			`}`
			`}`

			`/**`
			`* Periodic code for test mode should go here.`
			`*`
			`* Users should override this method for code which will be called periodically at a regular`
			`* rate while the robot is in test mode.`
			`*/`
			`void IterativeRobot::TestPeriodic()`
			`{`
			`static bool firstRun = true;`
			`if (firstRun)`
			`{`
			`printf("Default %s() method... Overload me!\n", __FUNCTION__);`
			`firstRun = false;`
			`}`
			`}`