Team2890/allwpilib
4
0
Fork 0
mirror of https://github.com/wpilibsuite/allwpilib synced 2026-06-19 00:41:43 +00:00
Code Issues Packages Projects Releases Wiki Activity
Files
f65e697107ba07bee23dcd50546b40fad95fc404
allwpilib/wpilibc/wpilibC++Sim/src/IterativeRobot.cpp
James Kuszmaul f65e697107 Revert changes preventing old user code from compiling. 
I'm not 100% sure whether we want these, but they are a quick
find and replace to do.

Basically, there are two primary things that we have done
this summer that break existing user code:
-Changing GetInstance() calls to return references instead
 of pointers. This forces users to change from doing something
 like LiveWindow::GetInstance()->AddSensor() to LiveWindow::GetInstance().AddSensor().
-Making PIDGet() and related calls const, forcing users to change
 the function signatures wherever they override them.

The GetInstance() calls don't really matter to me either way,
especially since there are no real ownership issues going on there,
unlike the rest of the smart pointer-related changes.

For the const stuff, it is certainly more correct to mandate that
user PIDGet() functions be const and the such, but at the same time,
I'm not sure that there is any strong need for it, and the errors
generated are not the most helpful. While this wouldn't necessarily
be an issue for more experienced teams or completely new teams (who
don't have any old code to be reusing), it may cause issues for more
average teams who aren't familiar with the intricacies of C++ anything.

Change-Id: I6e7007982069292ea70e6d0fc8ca40203340df1b
2015-09-16 19:10:01 -04:00

313 lines
8.5 KiB
C++
Raw Blame History

/*----------------------------------------------------------------------------*/
/* 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"
//not sure what this is used for yet.
#ifdef _UNIX
#include <unistd.h>
#endif
const double IterativeRobot::kDefaultPeriod = 0;
/**
* 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;
}
}
Reference in New Issue View Git Blame Copy Permalink