wpilibc/simulation/src/DriverStation.cpp - RealtimeRoboticsGroup/test - Gitiles

 /*----------------------------------------------------------------------------*/
 /* 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 "DriverStation.h"
 #include "AnalogInput.h"
 #include "Timer.h"
 #include "NetworkCommunication/FRCComm.h"
 #include "MotorSafetyHelper.h"
 #include "Utility.h"
 #include "WPIErrors.h"
 #include <string.h>
 #include "Log.hpp"

 // set the logging level
 TLogLevel dsLogLevel = logDEBUG;
 const double JOYSTICK_UNPLUGGED_MESSAGE_INTERVAL = 1.0;

 #define DS_LOG(level) \
   if (level > dsLogLevel) ; \
   else Log().Get(level)

 const uint32_t DriverStation::kJoystickPorts;

 /**
  * DriverStation constructor.
  *
  * This is only called once the first time GetInstance() is called
  */
 DriverStation::DriverStation() {
   // All joysticks should default to having zero axes, povs and buttons, so
   // uninitialized memory doesn't get sent to speed controllers.
   for (unsigned int i = 0; i < kJoystickPorts; i++) {
     m_joystickAxes[i].count = 0;
     m_joystickPOVs[i].count = 0;
     m_joystickButtons[i].count = 0;
     m_joystickDescriptor[i].isXbox = 0;
     m_joystickDescriptor[i].type = -1;
     m_joystickDescriptor[i].name[0] = '\0';
   }
   // Register that semaphore with the network communications task.
   // It will signal when new packet data is available.
   HALSetNewDataSem(m_packetDataAvailableCond.native_handle());

   AddToSingletonList();

 }

 void DriverStation::Run() {
   int period = 0;
   while (true) {
     {
       std::unique_lock<priority_mutex> lock(m_packetDataAvailableMutex);
       m_packetDataAvailableCond.wait(lock);
     }
     GetData();
     m_waitForDataCond.notify_all();

     if (++period >= 4) {
       MotorSafetyHelper::CheckMotors();
       period = 0;
     }
     if (m_userInDisabled) HALNetworkCommunicationObserveUserProgramDisabled();
     if (m_userInAutonomous) HALNetworkCommunicationObserveUserProgramAutonomous();
     if (m_userInTeleop) HALNetworkCommunicationObserveUserProgramTeleop();
     if (m_userInTest) HALNetworkCommunicationObserveUserProgramTest();
   }
 }

 /**
  * Return a reference to the singleton DriverStation.
  * @return Pointer to the DS instance
  */
 DriverStation &DriverStation::GetInstance() {
   static DriverStation instance;
   return instance;
 }

 /**
  * Copy data from the DS task for the user.
  * If no new data exists, it will just be returned, otherwise
  * the data will be copied from the DS polling loop.
  */
 void DriverStation::GetData() {
   // Get the status of all of the joysticks
   for (uint8_t stick = 0; stick < kJoystickPorts; stick++) {
     HALGetJoystickAxes(stick, &m_joystickAxes[stick]);
     HALGetJoystickPOVs(stick, &m_joystickPOVs[stick]);
     HALGetJoystickButtons(stick, &m_joystickButtons[stick]);
     HALGetJoystickDescriptor(stick, &m_joystickDescriptor[stick]);
   }
   m_newControlData.give();
 }

 /**
  * Read the battery voltage.
  *
  * @return The battery voltage in Volts.
  */
 float DriverStation::GetBatteryVoltage() const {
   int32_t status = 0;
   float voltage = getVinVoltage(&status);
   wpi_setErrorWithContext(status, "getVinVoltage");

   return voltage;
 }

 /**
  * Reports errors related to unplugged joysticks
  * Throttles the errors so that they don't overwhelm the DS
  */
 void DriverStation::ReportJoystickUnpluggedError(std::string message) {
   double currentTime = Timer::GetFPGATimestamp();
   if (currentTime > m_nextMessageTime) {
     ReportError(message);
     m_nextMessageTime = currentTime + JOYSTICK_UNPLUGGED_MESSAGE_INTERVAL;
   }
 }

 /**
  * Returns the number of axes on a given joystick port
  *
  * @param stick The joystick port number
  * @return The number of axes on the indicated joystick
  */
 int DriverStation::GetStickAxisCount(uint32_t stick) const {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return 0;
   }
   HALJoystickAxes joystickAxes;
   HALGetJoystickAxes(stick, &joystickAxes);
   return joystickAxes.count;
 }

 /**
  * Returns the name of the joystick at the given port
  *
  * @param stick The joystick port number
  * @return The name of the joystick at the given port
  */
 std::string DriverStation::GetJoystickName(uint32_t stick) const {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
   }
   std::string retVal(m_joystickDescriptor[0].name);
   return retVal;
 }

 /**
  * Returns the type of joystick at a given port
  *
  * @param stick The joystick port number
  * @return The HID type of joystick at the given port
  */
 int DriverStation::GetJoystickType(uint32_t stick) const {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return -1;
   }
   return (int)m_joystickDescriptor[stick].type;
 }

 /**
  * Returns a boolean indicating if the controller is an xbox controller.
  *
  * @param stick The joystick port number
  * @return A boolean that is true if the controller is an xbox controller.
  */
 bool DriverStation::GetJoystickIsXbox(uint32_t stick) const {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return false;
   }
   return (bool)m_joystickDescriptor[stick].isXbox;
 }

 /**
  * Returns the types of Axes on a given joystick port
  *
  * @param stick The joystick port number and the target axis
  * @return What type of axis the axis is reporting to be
  */
 int DriverStation::GetJoystickAxisType(uint32_t stick, uint8_t axis) const {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return -1;
   }
   return m_joystickDescriptor[stick].axisTypes[axis];
 }

 /**
  * Returns the number of POVs on a given joystick port
  *
  * @param stick The joystick port number
  * @return The number of POVs on the indicated joystick
  */
 int DriverStation::GetStickPOVCount(uint32_t stick) const {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return 0;
   }
   HALJoystickPOVs joystickPOVs;
   HALGetJoystickPOVs(stick, &joystickPOVs);
   return joystickPOVs.count;
 }

 /**
  * Returns the number of buttons on a given joystick port
  *
  * @param stick The joystick port number
  * @return The number of buttons on the indicated joystick
  */
 int DriverStation::GetStickButtonCount(uint32_t stick) const {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return 0;
   }
   HALJoystickButtons joystickButtons;
   HALGetJoystickButtons(stick, &joystickButtons);
   return joystickButtons.count;
 }

 /**
  * Get the value of the axis on a joystick.
  * This depends on the mapping of the joystick connected to the specified port.
  *
  * @param stick The joystick to read.
  * @param axis The analog axis value to read from the joystick.
  * @return The value of the axis on the joystick.
  */
 float DriverStation::GetStickAxis(uint32_t stick, uint32_t axis) {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return 0;
   }

   if (axis >= m_joystickAxes[stick].count) {
     if (axis >= kMaxJoystickAxes) {
       wpi_setWPIError(BadJoystickAxis);
     }
     else {
       ReportJoystickUnpluggedError(
           "WARNING: Joystick Axis missing, check if all controllers are "
           "plugged in\n");
     }
     return 0.0f;
   }

   int8_t value = m_joystickAxes[stick].axes[axis];

   if (value < 0) {
     return value / 128.0f;
   } else {
     return value / 127.0f;
   }
 }

 /**
  * Get the state of a POV on the joystick.
  *
  * @return the angle of the POV in degrees, or -1 if the POV is not pressed.
  */
 int DriverStation::GetStickPOV(uint32_t stick, uint32_t pov) {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return -1;
   }

   if (pov >= m_joystickPOVs[stick].count) {
     if (pov >= kMaxJoystickPOVs) {
       wpi_setWPIError(BadJoystickAxis);
     }
     else {
       ReportJoystickUnpluggedError(
           "WARNING: Joystick POV missing, check if all controllers are plugged "
           "in\n");
     }
     return -1;
   }

   return m_joystickPOVs[stick].povs[pov];
 }

 /**
  * The state of the buttons on the joystick.
  *
  * @param stick The joystick to read.
  * @return The state of the buttons on the joystick.
  */
 uint32_t DriverStation::GetStickButtons(uint32_t stick) const {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return 0;
   }

   return m_joystickButtons[stick].buttons;
 }

 /**
  * The state of one joystick button. Button indexes begin at 1.
  *
  * @param stick The joystick to read.
  * @param button The button index, beginning at 1.
  * @return The state of the joystick button.
  */
 bool DriverStation::GetStickButton(uint32_t stick, uint8_t button) {
   if (stick >= kJoystickPorts) {
     wpi_setWPIError(BadJoystickIndex);
     return false;
   }

   if (button > m_joystickButtons[stick].count) {
     ReportJoystickUnpluggedError(
         "WARNING: Joystick Button missing, check if all controllers are "
         "plugged in\n");
     return false;
   }
   if (button == 0) {
     ReportJoystickUnpluggedError(
         "ERROR: Button indexes begin at 1 in WPILib for C++ and Java");
     return false;
   }
   return ((0x1 << (button - 1)) & m_joystickButtons[stick].buttons) != 0;
 }

 /**
  * Check if the DS has enabled the robot
  * @return True if the robot is enabled and the DS is connected
  */
 bool DriverStation::IsEnabled() const {
   HALControlWord controlWord;
   memset(&controlWord, 0, sizeof(controlWord));
   HALGetControlWord(&controlWord);
   return controlWord.enabled && controlWord.dsAttached;
 }

 /**
  * Check if the robot is disabled
  * @return True if the robot is explicitly disabled or the DS is not connected
  */
 bool DriverStation::IsDisabled() const {
   HALControlWord controlWord;
   memset(&controlWord, 0, sizeof(controlWord));
   HALGetControlWord(&controlWord);
   return !(controlWord.enabled && controlWord.dsAttached);
 }

 /**
  * Check if the DS is commanding autonomous mode
  * @return True if the robot is being commanded to be in autonomous mode
  */
 bool DriverStation::IsAutonomous() const {
   HALControlWord controlWord;
   memset(&controlWord, 0, sizeof(controlWord));
   HALGetControlWord(&controlWord);
   return controlWord.autonomous;
 }

 /**
  * Check if the DS is commanding teleop mode
  * @return True if the robot is being commanded to be in teleop mode
  */
 bool DriverStation::IsOperatorControl() const {
   HALControlWord controlWord;
   memset(&controlWord, 0, sizeof(controlWord));
   HALGetControlWord(&controlWord);
   return !(controlWord.autonomous || controlWord.test);
 }

 /**
  * Check if the DS is commanding test mode
  * @return True if the robot is being commanded to be in test mode
  */
 bool DriverStation::IsTest() const {
   HALControlWord controlWord;
   HALGetControlWord(&controlWord);
   return controlWord.test;
 }

 /**
  * Check if the DS is attached
  * @return True if the DS is connected to the robot
  */
 bool DriverStation::IsDSAttached() const {
   HALControlWord controlWord;
   memset(&controlWord, 0, sizeof(controlWord));
   HALGetControlWord(&controlWord);
   return controlWord.dsAttached;
 }

 /**
  * @return always true in simulation
  */
 bool DriverStation::IsSysActive() const {
   return true;
 }

 /**
  * @return always false in simulation
  */
 bool DriverStation::IsSysBrownedOut() const {
   return false;
 }

 /**
  * Has a new control packet from the driver station arrived since the last time
  * this function was called?
  * Warning: If you call this function from more than one place at the same time,
  * you will not get the get the intended behaviour.
  * @return True if the control data has been updated since the last call.
  */
 bool DriverStation::IsNewControlData() const {
   return m_newControlData.tryTake() == false;
 }

 /**
  * Is the driver station attached to a Field Management System?
  * @return True if the robot is competing on a field being controlled by a Field
  * Management System
  */
 bool DriverStation::IsFMSAttached() const {
   HALControlWord controlWord;
   HALGetControlWord(&controlWord);
   return controlWord.fmsAttached;
 }

 /**
  * Return the alliance that the driver station says it is on.
  * This could return kRed or kBlue
  * @return The Alliance enum (kRed, kBlue or kInvalid)
  */
 DriverStation::Alliance DriverStation::GetAlliance() const {
   HALAllianceStationID allianceStationID;
   HALGetAllianceStation(&allianceStationID);
   switch (allianceStationID) {
     case kHALAllianceStationID_red1:
     case kHALAllianceStationID_red2:
     case kHALAllianceStationID_red3:
       return kRed;
     case kHALAllianceStationID_blue1:
     case kHALAllianceStationID_blue2:
     case kHALAllianceStationID_blue3:
       return kBlue;
     default:
       return kInvalid;
   }
 }

 /**
  * Return the driver station location on the field
  * This could return 1, 2, or 3
  * @return The location of the driver station (1-3, 0 for invalid)
  */
 uint32_t DriverStation::GetLocation() const {
   HALAllianceStationID allianceStationID;
   HALGetAllianceStation(&allianceStationID);
   switch (allianceStationID) {
     case kHALAllianceStationID_red1:
     case kHALAllianceStationID_blue1:
       return 1;
     case kHALAllianceStationID_red2:
     case kHALAllianceStationID_blue2:
       return 2;
     case kHALAllianceStationID_red3:
     case kHALAllianceStationID_blue3:
       return 3;
     default:
       return 0;
   }
 }

 /**
  * Wait until a new packet comes from the driver station
  * This blocks on a semaphore, so the waiting is efficient.
  * This is a good way to delay processing until there is new driver station data
  * to act on
  */
 void DriverStation::WaitForData() {
   std::unique_lock<priority_mutex> lock(m_waitForDataMutex);
   m_waitForDataCond.wait(lock);
 }

 /**
  * Return the approximate match time
  * The FMS does not send an official match time to the robots, but does send an
  * approximate match time.
  * The value will count down the time remaining in the current period (auto or
  * teleop).
  * Warning: This is not an official time (so it cannot be used to dispute ref
  * calls or guarantee that a function
  * will trigger before the match ends)
  * The Practice Match function of the DS approximates the behaviour seen on the
  * field.
  * @return Time remaining in current match period (auto or teleop)
  */
 double DriverStation::GetMatchTime() const {
   float matchTime;
   HALGetMatchTime(&matchTime);
   return (double)matchTime;
 }

 /**
  * Report an error to the DriverStation messages window.
  * The error is also printed to the program console.
  */
 void DriverStation::ReportError(std::string error) {
   std::cout << error << std::endl;

   HALControlWord controlWord;
   HALGetControlWord(&controlWord);
   if (controlWord.dsAttached) {
     HALSetErrorData(error.c_str(), error.size(), 0);
   }
 }
	/----------------------------------------------------------------------------/
	/* 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 "DriverStation.h"
	#include "AnalogInput.h"
	#include "Timer.h"
	#include "NetworkCommunication/FRCComm.h"
	#include "MotorSafetyHelper.h"
	#include "Utility.h"
	#include "WPIErrors.h"
	#include <string.h>
	#include "Log.hpp"

	// set the logging level
	TLogLevel dsLogLevel = logDEBUG;
	const double JOYSTICK_UNPLUGGED_MESSAGE_INTERVAL = 1.0;

	#define DS_LOG(level) \
	if (level > dsLogLevel) ; \
	else Log().Get(level)

	const uint32_t DriverStation::kJoystickPorts;

	/**
	* DriverStation constructor.
	*
	* This is only called once the first time GetInstance() is called
	*/
	DriverStation::DriverStation() {
	// All joysticks should default to having zero axes, povs and buttons, so
	// uninitialized memory doesn't get sent to speed controllers.
	for (unsigned int i = 0; i < kJoystickPorts; i++) {
	m_joystickAxes[i].count = 0;
	m_joystickPOVs[i].count = 0;
	m_joystickButtons[i].count = 0;
	m_joystickDescriptor[i].isXbox = 0;
	m_joystickDescriptor[i].type = -1;
	m_joystickDescriptor[i].name[0] = '\0';
	}
	// Register that semaphore with the network communications task.
	// It will signal when new packet data is available.
	HALSetNewDataSem(m_packetDataAvailableCond.native_handle());

	AddToSingletonList();

	}

	void DriverStation::Run() {
	int period = 0;
	while (true) {
	{
	std::unique_lock<priority_mutex> lock(m_packetDataAvailableMutex);
	m_packetDataAvailableCond.wait(lock);
	}
	GetData();
	m_waitForDataCond.notify_all();

	if (++period >= 4) {
	MotorSafetyHelper::CheckMotors();
	period = 0;
	}
	if (m_userInDisabled) HALNetworkCommunicationObserveUserProgramDisabled();
	if (m_userInAutonomous) HALNetworkCommunicationObserveUserProgramAutonomous();
	if (m_userInTeleop) HALNetworkCommunicationObserveUserProgramTeleop();
	if (m_userInTest) HALNetworkCommunicationObserveUserProgramTest();
	}
	}

	/**
	* Return a reference to the singleton DriverStation.
	* @return Pointer to the DS instance
	*/
	DriverStation &DriverStation::GetInstance() {
	static DriverStation instance;
	return instance;
	}

	/**
	* Copy data from the DS task for the user.
	* If no new data exists, it will just be returned, otherwise
	* the data will be copied from the DS polling loop.
	*/
	void DriverStation::GetData() {
	// Get the status of all of the joysticks
	for (uint8_t stick = 0; stick < kJoystickPorts; stick++) {
	HALGetJoystickAxes(stick, &m_joystickAxes[stick]);
	HALGetJoystickPOVs(stick, &m_joystickPOVs[stick]);
	HALGetJoystickButtons(stick, &m_joystickButtons[stick]);
	HALGetJoystickDescriptor(stick, &m_joystickDescriptor[stick]);
	}
	m_newControlData.give();
	}

	/**
	* Read the battery voltage.
	*
	* @return The battery voltage in Volts.
	*/
	float DriverStation::GetBatteryVoltage() const {
	int32_t status = 0;
	float voltage = getVinVoltage(&status);
	wpi_setErrorWithContext(status, "getVinVoltage");

	return voltage;
	}

	/**
	* Reports errors related to unplugged joysticks
	* Throttles the errors so that they don't overwhelm the DS
	*/
	void DriverStation::ReportJoystickUnpluggedError(std::string message) {
	double currentTime = Timer::GetFPGATimestamp();
	if (currentTime > m_nextMessageTime) {
	ReportError(message);
	m_nextMessageTime = currentTime + JOYSTICK_UNPLUGGED_MESSAGE_INTERVAL;
	}
	}

	/**
	* Returns the number of axes on a given joystick port
	*
	* @param stick The joystick port number
	* @return The number of axes on the indicated joystick
	*/
	int DriverStation::GetStickAxisCount(uint32_t stick) const {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return 0;
	}
	HALJoystickAxes joystickAxes;
	HALGetJoystickAxes(stick, &joystickAxes);
	return joystickAxes.count;
	}

	/**
	* Returns the name of the joystick at the given port
	*
	* @param stick The joystick port number
	* @return The name of the joystick at the given port
	*/
	std::string DriverStation::GetJoystickName(uint32_t stick) const {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	}
	std::string retVal(m_joystickDescriptor[0].name);
	return retVal;
	}

	/**
	* Returns the type of joystick at a given port
	*
	* @param stick The joystick port number
	* @return The HID type of joystick at the given port
	*/
	int DriverStation::GetJoystickType(uint32_t stick) const {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return -1;
	}
	return (int)m_joystickDescriptor[stick].type;
	}

	/**
	* Returns a boolean indicating if the controller is an xbox controller.
	*
	* @param stick The joystick port number
	* @return A boolean that is true if the controller is an xbox controller.
	*/
	bool DriverStation::GetJoystickIsXbox(uint32_t stick) const {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return false;
	}
	return (bool)m_joystickDescriptor[stick].isXbox;
	}

	/**
	* Returns the types of Axes on a given joystick port
	*
	* @param stick The joystick port number and the target axis
	* @return What type of axis the axis is reporting to be
	*/
	int DriverStation::GetJoystickAxisType(uint32_t stick, uint8_t axis) const {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return -1;
	}
	return m_joystickDescriptor[stick].axisTypes[axis];
	}

	/**
	* Returns the number of POVs on a given joystick port
	*
	* @param stick The joystick port number
	* @return The number of POVs on the indicated joystick
	*/
	int DriverStation::GetStickPOVCount(uint32_t stick) const {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return 0;
	}
	HALJoystickPOVs joystickPOVs;
	HALGetJoystickPOVs(stick, &joystickPOVs);
	return joystickPOVs.count;
	}

	/**
	* Returns the number of buttons on a given joystick port
	*
	* @param stick The joystick port number
	* @return The number of buttons on the indicated joystick
	*/
	int DriverStation::GetStickButtonCount(uint32_t stick) const {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return 0;
	}
	HALJoystickButtons joystickButtons;
	HALGetJoystickButtons(stick, &joystickButtons);
	return joystickButtons.count;
	}

	/**
	* Get the value of the axis on a joystick.
	* This depends on the mapping of the joystick connected to the specified port.
	*
	* @param stick The joystick to read.
	* @param axis The analog axis value to read from the joystick.
	* @return The value of the axis on the joystick.
	*/
	float DriverStation::GetStickAxis(uint32_t stick, uint32_t axis) {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return 0;
	}

	if (axis >= m_joystickAxes[stick].count) {
	if (axis >= kMaxJoystickAxes) {
	wpi_setWPIError(BadJoystickAxis);
	}
	else {
	ReportJoystickUnpluggedError(
	"WARNING: Joystick Axis missing, check if all controllers are "
	"plugged in\n");
	}
	return 0.0f;
	}

	int8_t value = m_joystickAxes[stick].axes[axis];

	if (value < 0) {
	return value / 128.0f;
	} else {
	return value / 127.0f;
	}
	}

	/**
	* Get the state of a POV on the joystick.
	*
	* @return the angle of the POV in degrees, or -1 if the POV is not pressed.
	*/
	int DriverStation::GetStickPOV(uint32_t stick, uint32_t pov) {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return -1;
	}

	if (pov >= m_joystickPOVs[stick].count) {
	if (pov >= kMaxJoystickPOVs) {
	wpi_setWPIError(BadJoystickAxis);
	}
	else {
	ReportJoystickUnpluggedError(
	"WARNING: Joystick POV missing, check if all controllers are plugged "
	"in\n");
	}
	return -1;
	}

	return m_joystickPOVs[stick].povs[pov];
	}

	/**
	* The state of the buttons on the joystick.
	*
	* @param stick The joystick to read.
	* @return The state of the buttons on the joystick.
	*/
	uint32_t DriverStation::GetStickButtons(uint32_t stick) const {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return 0;
	}

	return m_joystickButtons[stick].buttons;
	}

	/**
	* The state of one joystick button. Button indexes begin at 1.
	*
	* @param stick The joystick to read.
	* @param button The button index, beginning at 1.
	* @return The state of the joystick button.
	*/
	bool DriverStation::GetStickButton(uint32_t stick, uint8_t button) {
	if (stick >= kJoystickPorts) {
	wpi_setWPIError(BadJoystickIndex);
	return false;
	}

	if (button > m_joystickButtons[stick].count) {
	ReportJoystickUnpluggedError(
	"WARNING: Joystick Button missing, check if all controllers are "
	"plugged in\n");
	return false;
	}
	if (button == 0) {
	ReportJoystickUnpluggedError(
	"ERROR: Button indexes begin at 1 in WPILib for C++ and Java");
	return false;
	}
	return ((0x1 << (button - 1)) & m_joystickButtons[stick].buttons) != 0;
	}

	/**
	* Check if the DS has enabled the robot
	* @return True if the robot is enabled and the DS is connected
	*/
	bool DriverStation::IsEnabled() const {
	HALControlWord controlWord;
	memset(&controlWord, 0, sizeof(controlWord));
	HALGetControlWord(&controlWord);
	return controlWord.enabled && controlWord.dsAttached;
	}

	/**
	* Check if the robot is disabled
	* @return True if the robot is explicitly disabled or the DS is not connected
	*/
	bool DriverStation::IsDisabled() const {
	HALControlWord controlWord;
	memset(&controlWord, 0, sizeof(controlWord));
	HALGetControlWord(&controlWord);
	return !(controlWord.enabled && controlWord.dsAttached);
	}

	/**
	* Check if the DS is commanding autonomous mode
	* @return True if the robot is being commanded to be in autonomous mode
	*/
	bool DriverStation::IsAutonomous() const {
	HALControlWord controlWord;
	memset(&controlWord, 0, sizeof(controlWord));
	HALGetControlWord(&controlWord);
	return controlWord.autonomous;
	}

	/**
	* Check if the DS is commanding teleop mode
	* @return True if the robot is being commanded to be in teleop mode
	*/
	bool DriverStation::IsOperatorControl() const {
	HALControlWord controlWord;
	memset(&controlWord, 0, sizeof(controlWord));
	HALGetControlWord(&controlWord);
	return !(controlWord.autonomous \|\| controlWord.test);
	}

	/**
	* Check if the DS is commanding test mode
	* @return True if the robot is being commanded to be in test mode
	*/
	bool DriverStation::IsTest() const {
	HALControlWord controlWord;
	HALGetControlWord(&controlWord);
	return controlWord.test;
	}

	/**
	* Check if the DS is attached
	* @return True if the DS is connected to the robot
	*/
	bool DriverStation::IsDSAttached() const {
	HALControlWord controlWord;
	memset(&controlWord, 0, sizeof(controlWord));
	HALGetControlWord(&controlWord);
	return controlWord.dsAttached;
	}

	/**
	* @return always true in simulation
	*/
	bool DriverStation::IsSysActive() const {
	return true;
	}

	/**
	* @return always false in simulation
	*/
	bool DriverStation::IsSysBrownedOut() const {
	return false;
	}

	/**
	* Has a new control packet from the driver station arrived since the last time
	* this function was called?
	* Warning: If you call this function from more than one place at the same time,
	* you will not get the get the intended behaviour.
	* @return True if the control data has been updated since the last call.
	*/
	bool DriverStation::IsNewControlData() const {
	return m_newControlData.tryTake() == false;
	}

	/**
	* Is the driver station attached to a Field Management System?
	* @return True if the robot is competing on a field being controlled by a Field
	* Management System
	*/
	bool DriverStation::IsFMSAttached() const {
	HALControlWord controlWord;
	HALGetControlWord(&controlWord);
	return controlWord.fmsAttached;
	}

	/**
	* Return the alliance that the driver station says it is on.
	* This could return kRed or kBlue
	* @return The Alliance enum (kRed, kBlue or kInvalid)
	*/
	DriverStation::Alliance DriverStation::GetAlliance() const {
	HALAllianceStationID allianceStationID;
	HALGetAllianceStation(&allianceStationID);
	switch (allianceStationID) {
	case kHALAllianceStationID_red1:
	case kHALAllianceStationID_red2:
	case kHALAllianceStationID_red3:
	return kRed;
	case kHALAllianceStationID_blue1:
	case kHALAllianceStationID_blue2:
	case kHALAllianceStationID_blue3:
	return kBlue;
	default:
	return kInvalid;
	}
	}

	/**
	* Return the driver station location on the field
	* This could return 1, 2, or 3
	* @return The location of the driver station (1-3, 0 for invalid)
	*/
	uint32_t DriverStation::GetLocation() const {
	HALAllianceStationID allianceStationID;
	HALGetAllianceStation(&allianceStationID);
	switch (allianceStationID) {
	case kHALAllianceStationID_red1:
	case kHALAllianceStationID_blue1:
	return 1;
	case kHALAllianceStationID_red2:
	case kHALAllianceStationID_blue2:
	return 2;
	case kHALAllianceStationID_red3:
	case kHALAllianceStationID_blue3:
	return 3;
	default:
	return 0;
	}
	}

	/**
	* Wait until a new packet comes from the driver station
	* This blocks on a semaphore, so the waiting is efficient.
	* This is a good way to delay processing until there is new driver station data
	* to act on
	*/
	void DriverStation::WaitForData() {
	std::unique_lock<priority_mutex> lock(m_waitForDataMutex);
	m_waitForDataCond.wait(lock);
	}

	/**
	* Return the approximate match time
	* The FMS does not send an official match time to the robots, but does send an
	* approximate match time.
	* The value will count down the time remaining in the current period (auto or
	* teleop).
	* Warning: This is not an official time (so it cannot be used to dispute ref
	* calls or guarantee that a function
	* will trigger before the match ends)
	* The Practice Match function of the DS approximates the behaviour seen on the
	* field.
	* @return Time remaining in current match period (auto or teleop)
	*/
	double DriverStation::GetMatchTime() const {
	float matchTime;
	HALGetMatchTime(&matchTime);
	return (double)matchTime;
	}

	/**
	* Report an error to the DriverStation messages window.
	* The error is also printed to the program console.
	*/
	void DriverStation::ReportError(std::string error) {
	std::cout << error << std::endl;

	HALControlWord controlWord;
	HALGetControlWord(&controlWord);
	if (controlWord.dsAttached) {
	HALSetErrorData(error.c_str(), error.size(), 0);
	}
	}