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FRC2016-old/Robot2016/src/Robot.cpp

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#include "WPILib.h"
#include "Shooter.h"
#include <ctime>
#include <iostream>
#include <iomanip>
#include <fstream>
#include <string>
#include <sys/time.h>
#include <vector>
#include <cmath>
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#include <math.h>
#ifndef BUTTON_LAYOUT
#define BUTTON_LAYOUT
#define TRIGGER 1 // Trigger button number
#define THUMB 2 // Thumb button number
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#define RAMP_RAISE 5 // Button 3 for Raising Ramp
#define RAMP_LOWER 3 // Button 4 to lower ramp.
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#define UNJAM 11
#define DEADZONE_RADIUS 0.05 // Deadzone Radius prevents tiny twitches in the joystick's value from
// affecting the robot. Use this for cleaning up drive train and shooter.
// Also used for detecting changes in an axis' value.
#define TURN_FACTOR 1.5 // Left(x,y) = y*(1 + TF*x) : x < 0
// = y : x >= 0
// Right(x,y) = y : x < 0
// = y*(1 - TF*x) : x >= 0
#endif // BUTTON_LAYOUT
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#ifndef LOG
#define LOG(X) logA << X; logB << X; logC << X //for writing data to the csv file
#endif
class Robot: public IterativeRobot
{
TalonSRX left_drive, right_drive;
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CANTalon shooter1, shooter2,
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ramp,
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arms;
RobotDrive drive;
Shooter shooter;
Joystick driver_stick, operator_stick;
//DriverStation DriverStation::GetInstance();
//float power;
public:
Robot():
left_drive(0), // Left DriveTrain Talons plug into PWM channel 1 with a Y-splitter
right_drive(1), // Right DriveTrain Talons plug // left wheel 2
shooter1(11), // shooter drive 1
shooter2(10), // shooter drive 2
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ramp(12),
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arms(13),
drive(&left_drive, &right_drive),
shooter( // initialize Shooter object.
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&shooter1, &shooter2, &ramp),
driver_stick(0), // right stick (operator)
operator_stick(1) // left stick (driver)
{
}
private:
// instance variables
bool pickupRunning; // don't want to spam the Talon with set messages. Toggle the pickup when a button is pressed or released.
bool inverting;
bool ramping;
bool shooting;
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bool unjamming;
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bool arming;
bool arcade;
float shooter_power;
LiveWindow *lw = LiveWindow::GetInstance();
SendableChooser *chooser;
const std::string autoNameDefault = "Default";
const std::string autoNameCustom = "My Auto";
std::string autoSelected;
/*void LogData()
{
static PowerDistributionPanel pdp;
static DriverStation DriverStation::GetInstance() = DriverStation::GetInstance();
static std::vector<CANTalon*> motors;
static std::ofstream logA, logB, logC;
timeval tm;
SmartDashboard::PutBoolean("log A", logA.is_open());
SmartDashboard::PutBoolean("log B", logB.is_open());
SmartDashboard::PutBoolean("log C", logC.is_open());
}*/
void RobotInit()
{
chooser = new SendableChooser();
chooser->AddDefault(autoNameDefault, (void*)&autoNameDefault);
chooser->AddObject(autoNameCustom, (void*)&autoNameCustom);
SmartDashboard::PutData("Auto Modes", chooser);
shooter1.Enable();
shooter2.Enable();
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left_drive.SetInverted(true);
right_drive.SetInverted(true);
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//ramp.SetInverted(true);
inverting = false;
pickupRunning = false;
ramping = false;
shooting = false;
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unjamming = false;
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arming = false;
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shooter_power = 0;
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arcade = false;
}
/**
* This autonomous (along with the chooser code above) shows how to select between different autonomous modes
* using the dashboard. The sendable chooser code works with the Java SmartDashboard. If you prefer the LabVIEW
* Dashboard, remove all of the chooser code and uncomment the GetString line to get the auto name from the text box
* below the Gyro
*
* You can add additional auto modes by adding additional comparisons to the if-else structure below with additional strings.
* If using the SendableChooser make sure to add them to the chooser code above as well.
*/
void AutonomousInit()
{
autoSelected = *((std::string*)chooser->GetSelected());
//std::string autoSelected = SmartDashboard::GetString("Auto Selector", autoNameDefault);
std::cout << "Auto selected: " << autoSelected << std::endl;
if(autoSelected == autoNameCustom){
//Custom Auto goes here
} else {
//Default Auto goes here
}
}
void AutonomousPeriodic()
{
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LogCSVData();
if(autoSelected == autoNameCustom){
//Custom Auto goes here
} else {
//Default Auto goes here
}
}
void TeleopInit()
{
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}
void TeleopPeriodic()
{
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LogCSVData();
std::cout << "arm encoder position: " << arms.GetEncPosition() << std::endl;
std::cout << "arm encoder velocity: " << arms.GetEncVel() << std::endl;
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drive.ArcadeDrive(-driver_stick.GetY(), -driver_stick.GetX()*0.75);
if(driver_stick.GetRawButton(7))
{
arcade = true;
}
if(driver_stick.GetRawButton(8))
{
arcade = false;
}
if (arcade)
{
drive.ArcadeDrive(driver_stick);
}
else
{
if (driver_stick.GetRawButton(THUMB))
{
float left = driver_stick.GetTwist();
float right = -driver_stick.GetTwist();
drive.TankDrive(left, right);
}
else
{
UpdateDrive();
}
}
//bool rampDoing = false;
// This is shit code for testing. Replace it with real code.
if(!ramping && operator_stick.GetRawButton(RAMP_RAISE))
{
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std::cout << "Raising Ramp.";
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//ramp.Set(1);
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shooter.RaiseRamp();
ramping =true;
}
else if(!ramping && operator_stick.GetRawButton(RAMP_LOWER))
{
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std::cout << "Lowering Ramp.";
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//ramp.Set(-1);
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shooter.LowerRamp();
ramping = true;
}
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/*else if(!ramping && operator_stick.GetRawButton(TRIGGER))
{
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shooter.BoostRamp();
ramping = true;
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}
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else if(ramping && !operator_stick.GetRawButton(RAMP_RAISE)
&& !operator_stick.GetRawButton(RAMP_LOWER))
{
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shooter.StopRamp();
ramping = false;
}
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if(!unjamming && operator_stick.GetRawButton(UNJAM))
{
unjamming = true;
shooter.Unjam();
}
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else if(!unjamming && operator_stick.GetRawButton(TRIGGER))
{
shooter.ShootLow();
unjamming = true;
}
else if(unjamming && !operator_stick.GetRawButton(UNJAM) && !operator_stick.GetRawButton(TRIGGER))
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{
shooter.PickUp(false);
unjamming = false;
}
/*
* Run the Shooter only while the THUMB button is held down on the operator stick.
* the 'pickupRunning' boolean is there to prevent the shooter from calling PickUp
* every iteration of the TeleopPeriodic method (once every 10ms!)
* The pickup is disabled when the thumb button is released, but the code still
* has 'pickupRunning' as true.
*/
if(operator_stick.GetRawButton(THUMB) && !pickupRunning)
{
shooter.PickUp();
pickupRunning = true;
}
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else if(!operator_stick.GetRawButton(THUMB) && pickupRunning)
{
shooter.PickUp(false);
pickupRunning = false;
}
/*
* The 'inverting' variable is used to make sure that the drive train isn't getting
* inverted every iteration of the TeleopPeriodic method while the button is held down.
* This is important because the TeleopPeriodic method executes something like once every 10ms.
* Thus, this if-else if pair make the button a toggle.
*/
if(driver_stick.GetRawButton(TRIGGER) && !inverting)
{
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std::cout << "Inverting Drive Train.";
left_drive.SetInverted(!left_drive.GetInverted());
right_drive.SetInverted(!right_drive.GetInverted());
inverting = true;
}
else if(!driver_stick.GetRawButton(TRIGGER))
{
inverting = false;
}
/*
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* Unlike the previous actions, this method does need to be called every iteration of
* TeleopPeriodic. This is because the logic running this operation needs to be checked
* Every time the method is called. This cannot be a loop in the Shoot method because
* that would lock the robot every time the trigger is hit.
*/
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if(operator_stick.GetRawButton(TRIGGER) || (shooter.GetState() != 0))
{
shooting = true;
shooter.Shoot();
}
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else if(shooting && !operator_stick.GetRawButton(TRIGGER))
{
shooting = false;
shooter.StopShooter();
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}
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if(!arming && driver_stick.GetRawButton(RAMP_RAISE))
{
arming = true;
arms.Set(1);
}
else if(!arming && driver_stick.GetRawButton(RAMP_LOWER))
{
arming = true;
arms.Set(-1);
}
else if(arming && !driver_stick.GetRawButton(RAMP_RAISE) && !driver_stick.GetRawButton(RAMP_LOWER))
{
arming = false;
arms.Set(0);
}
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// This code will become obsolete after the Shooter logic is complete.
float opThrottle = SaneThrottle(operator_stick.GetThrottle());
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if(!pickupRunning && ( opThrottle > shooter_power + DEADZONE_RADIUS
|| opThrottle < shooter_power - DEADZONE_RADIUS))
{
shooter.SetPower(opThrottle);
}
}
/**
* Takes the gross raw throttle input from joystick and returns a
* value between 0.0-1.0 (no negative values)
*/
float SaneThrottle(float rawThrottle)
{
return ((1.0 - rawThrottle) / 2.0);
}
void TestPeriodic()
{
lw->Run();
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LogCSVData();
}
void LogCSVData()
{
static PowerDistributionPanel pdp; // preparing to read from the pdp
static std::vector<CANTalon*> motors;
static std::ofstream logA, logB, logC;
timeval tm;
SmartDashboard::PutBoolean("log A", logA.is_open());
SmartDashboard::PutBoolean("log B", logB.is_open());
SmartDashboard::PutBoolean("log C", logC.is_open());
if (!logA.is_open() && !logB.is_open() && !logC.is_open())
{
std::fstream logNumFile;
int logNum;
logNumFile.open("/home/lvuser/logNum");
logNumFile >> logNum;
logNum++;
logNumFile.seekp(0);
logNumFile << logNum;
// writing to /home/lvuser/logs/[unixtime].log
logA.open("/media/sda1/logs/log" + std::to_string(logNum) + ".csv");
std::cerr << (logA.is_open() ? "Opened" : "Failed to open") << "log A." << std::endl;
logB.open("/media/sdb1/logs/log" + std::to_string(logNum) + ".csv");
std::cerr << (logB.is_open() ? "Opened" : "Failed to open") << "log B." << std::endl;
logC.open("/home/lvuser/logs/log" + std::to_string(logNum) + ".csv");
std::cerr << (logC.is_open() ? "Opened" : "Failed to open") << "log C." << std::endl;
LOG("Time\tpdpInput voltage\tpdpTemperature\tpdpTotal Current\t");
for (int ii = 0; ii < 16; ii++)
{
LOG("pdpChannel " << ii << " current\t");
}
LOG("tlaunch_spinny Bus Voltage\ttlaunch_spinny Output Current\ttlaunch_spinny Output Voltage\ttlaunch_spinny Temperature");
motors.push_back(&ramp);
LOG("\tShooter1 Bus Voltage\tShooter1 Output Current\tShooter1 Output Voltage\tShooter1 Temperature");
motors.push_back(&shooter1);
LOG("\tShooter2 Bus Voltage\tShooter2 Output Current\tShooter2 Output Voltage\tShooter2 Temperature");
motors.push_back(&shooter2);
LOG("\tJoystick X\tJoystick Y\tJoystick Twist");
LOG("\tAlliance\tLocation\tMatch Time\tFMS Attached\tBrowned Out");
LOG("\tTestStage");
LOG(std::endl);
}
gettimeofday(&tm, NULL);
LOG(time(0) << '.' << std::setfill('0') << std::setw(3) << tm.tv_usec/1000);
// Some general information
LOG("\t" << pdp.GetVoltage());
LOG("\t" << pdp.GetTemperature());
LOG("\t" << pdp.GetTotalCurrent());
// current on each channel
for (int ii = 0; ii < 16; ii++)
{
LOG("\t" << pdp.GetCurrent(ii));
}
//Talon Data
for(int ii = 0; ii < motors.size(); ii++)
{
LOG("\t" << motors[ii]->GetBusVoltage());
LOG("\t" << motors[ii]->GetOutputVoltage());
LOG("\t" << motors[ii]->GetOutputCurrent());
LOG("\t" << motors[ii]->GetTemperature());
}
//control data
LOG("\t" << driver_stick.GetX());
LOG("\t" << driver_stick.GetY());
LOG("\t" << driver_stick.GetTwist());
//DriverStation Data
LOG("\t" << DriverStation::GetInstance().GetAlliance());
LOG("\t" << DriverStation::GetInstance().GetLocation());
LOG("\t" << DriverStation::GetInstance().GetMatchTime());
LOG("\t" << DriverStation::GetInstance().IsFMSAttached());
LOG("\t" << DriverStation::GetInstance().IsSysBrownedOut());
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LOG(std::endl);
}
void SimpleDrive()
{
float x = -driver_stick.GetX();
float y = -driver_stick.GetY();
float left = 0;
float right = 0;
if (x > 0)
{
right = y;
left = (1- x*TURN_FACTOR)*y ;
}
else
{
left = y;
right = (1+x*TURN_FACTOR)*y;
}
drive.TankDrive(left, right);
}
void UpdateDrive()
{
float x = -driver_stick.GetX();
float y = -driver_stick.GetY();
if (x > 0)
{
float right = y * SaneThrottle(driver_stick.GetThrottle());
float left = (1-x)*y * SaneThrottle(driver_stick.GetThrottle());
drive.TankDrive(left, right);
}
else
{
float left = y * SaneThrottle(driver_stick.GetThrottle());
float right = (1+x)*y * SaneThrottle(driver_stick.GetThrottle());
drive.TankDrive(left, right);
}
}
};
START_ROBOT_CLASS(Robot)