aos/externals/WPILib/WPILib/RobotBase.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 "RobotBase.h"

 #include "DriverStation.h"
 #include "NetworkCommunication/FRCComm.h"
 #include "NetworkCommunication/symModuleLink.h"
 #include "NetworkCommunication/UsageReporting.h"
 #include "Utility.h"
 #include <moduleLib.h>
 #include <taskLib.h>
 #include <unldLib.h>
 #include <cstring>

 RobotBase* RobotBase::m_instance = NULL;

 const char *FILE_NAME = "/c/FRC_Lib_Version.ini";
 const char *VERSION_STRING = "C++ 2014 Update 0";


 void RobotBase::setInstance(RobotBase* robot)
 {
   // No point in synchronization here because it's private and it only gets
   // called from robotTask.
 	wpi_assert(m_instance == NULL);
 	m_instance = robot;
 }

 RobotBase &RobotBase::getInstance()
 {
 	return *m_instance;
 }

 /**
  * Constructor for a generic robot program.
  * User code that should run before the Autonomous or Operator Control period
  * starts should be placed in the subclass constructor.
  * The constructor must finish before Autonomous can be entered.
  *
  * This must be used to ensure that the communications code starts. In the future it would be
  * nice to put this code into it's own task that loads on boot so ensure that it runs.
  */
 RobotBase::RobotBase()
 	: m_task (NULL)
 	, m_ds (NULL)
 {
 	m_ds = DriverStation::GetInstance();
 }

 /**
  * Free the resources for a RobotBase class.
  * This includes deleting all classes that might have been allocated as Singletons so they
  * would never be deleted except here.
  */
 RobotBase::~RobotBase()
 {
 	SensorBase::DeleteSingletons();
 	delete m_task;
 	m_task = NULL;
 	m_instance = NULL;
 }

 /**
  * Check on the overall status of the system.
  *
  * @return Is the system active (i.e. PWM motor outputs, etc. enabled)?
  */
 bool RobotBase::IsSystemActive()
 {
 	return m_watchdog.IsSystemActive();
 }

 /**
  * Return the instance of the Watchdog timer.
  * Get the watchdog timer so the user program can either disable it or feed it when
  * necessary.
  */
 Watchdog &RobotBase::GetWatchdog()
 {
 	return m_watchdog;
 }

 /**
  * Determine if the Robot is currently enabled.
  * @return True if the Robot is currently enabled by the field controls.
  */
 bool RobotBase::IsEnabled()
 {
 	return m_ds->IsEnabled();
 }

 /**
  * Determine if the Robot is currently disabled.
  * @return True if the Robot is currently disabled by the field controls.
  */
 bool RobotBase::IsDisabled()
 {
 	return m_ds->IsDisabled();
 }

 /**
  * Determine if the robot is currently in Autonomous mode.
  * @return True if the robot is currently operating Autonomously as determined by the field controls.
  */
 bool RobotBase::IsAutonomous()
 {
 	return m_ds->IsAutonomous();
 }

 /**
  * Determine if the robot is currently in Operator Control mode.
  * @return True if the robot is currently operating in Tele-Op mode as determined by the field controls.
  */
 bool RobotBase::IsOperatorControl()
 {
 	return m_ds->IsOperatorControl();
 }

 /**
  * Determine if the robot is currently in Test mode.
  * @return True if the robot is currently running tests as determined by the field controls.
  */
 bool RobotBase::IsTest()
 {
     return m_ds->IsTest();
 }

 /**
  * Indicates if new data is available from the driver station.
  * @return Has new data arrived over the network since the last time this function was called?
  */
 bool RobotBase::IsNewDataAvailable()
 {
 	return m_ds->IsNewControlData();
 }

 /**
  * Static interface that will start the competition in the new task.
  */
 void RobotBase::robotTask(FUNCPTR factory, Task *task)
 {
   RobotBase *instance = (RobotBase*)factory();
   instance->m_task = task;
   RobotBase::setInstance(instance);
   instance->StartCompetition();
 }

 void RobotBase::WriteVersionString() {
 	FILE *file = fopen(FILE_NAME, "w");
 	if (file != NULL) {
 		fputs(VERSION_STRING, file);
     fputs(" (customized by Team 971 Spartan Robotics)", file);
 		fclose(file);
 	}
 }

 /**
  *
  * Start the robot code.
  * This function starts the robot code running by spawning a task. Currently
  * tasks seem to be started by LVRT without setting the VX_FP_TASK flag which
  * means that the floating point registers are not saved on interrupts and task
  * switches. That causes the program to experience hard to debug and
  * unpredictable results, so the LVRT code starts this function, so that it, in
  * turn, can start the actual user program.
  */
 void RobotBase::startRobotTask(FUNCPTR factory)
 {
 #ifdef SVN_REV
 	if (strlen(SVN_REV))
 	{
 		printf("WPILib was compiled from SVN revision %s\n", SVN_REV);
 	}
 	else
 	{
 		printf("WPILib was compiled from a location that is not source controlled.\n");
 	}
 #else
 	printf("WPILib was compiled without -D'SVN_REV=nnnn'\n");
 #endif
   printf("This WPILib has been fixed by Team 971 Spartan Robotics.\n");

 	// Check for startup code already running
 	int32_t oldId = taskNameToId(const_cast<char*>("FRC_RobotTask"));
 	if (oldId != ERROR)
 	{
 		// Find the startup code module.
 		char moduleName[256];
 		moduleNameFindBySymbolName("FRC_UserProgram_StartupLibraryInit", moduleName);
 		MODULE_ID startupModId = moduleFindByName(moduleName);
 		if (startupModId != NULL)
 		{
 			// Remove the startup code.
 			unldByModuleId(startupModId, 0);
 			printf("!!!   Error: Default code was still running... It was unloaded for you... Please try again.\n");
 			return;
 		}
 		// This case should no longer get hit.
 		printf("!!!   Error: Other robot code is still running... Unload it and then try again.\n");
 		return;
 	}

 	// Let the framework know that we are starting a new user program so the Driver Station can disable.
 	FRC_NetworkCommunication_observeUserProgramStarting();

 	// Let the Usage Reporting framework know that there is a C++ program running
 	nUsageReporting::report(nUsageReporting::kResourceType_Language, nUsageReporting::kLanguage_CPlusPlus);

 	RobotBase::WriteVersionString();

 	// Start robot task
 	// This is done to ensure that the C++ robot task is spawned with the floating point
 	// context save parameter.
 	Task *task = new Task("RobotTask", (FUNCPTR)RobotBase::robotTask, Task::kDefaultPriority, 64000);
 	task->Start((int32_t)factory, (int32_t)task);
 }

 /**
  * This class exists for the sole purpose of getting its destructor called when the module unloads.
  * Before the module is done unloading, we need to delete the RobotBase derived singleton.  This should delete
  * the other remaining singletons that were registered.
  */
 class RobotDeleter
 {
 public:
 	RobotDeleter() {}
 	~RobotDeleter()
 	{
 		delete &RobotBase::getInstance();
 	}
 };
 static RobotDeleter g_robotDeleter;
	/----------------------------------------------------------------------------/
	/* 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 "RobotBase.h"

	#include "DriverStation.h"
	#include "NetworkCommunication/FRCComm.h"
	#include "NetworkCommunication/symModuleLink.h"
	#include "NetworkCommunication/UsageReporting.h"
	#include "Utility.h"
	#include <moduleLib.h>
	#include <taskLib.h>
	#include <unldLib.h>
	#include <cstring>

	RobotBase* RobotBase::m_instance = NULL;

	const char *FILE_NAME = "/c/FRC_Lib_Version.ini";
	const char *VERSION_STRING = "C++ 2014 Update 0";


	void RobotBase::setInstance(RobotBase* robot)
	{
	// No point in synchronization here because it's private and it only gets
	// called from robotTask.
	wpi_assert(m_instance == NULL);
	m_instance = robot;
	}

	RobotBase &RobotBase::getInstance()
	{
	return *m_instance;
	}

	/**
	* Constructor for a generic robot program.
	* User code that should run before the Autonomous or Operator Control period
	* starts should be placed in the subclass constructor.
	* The constructor must finish before Autonomous can be entered.
	*
	* This must be used to ensure that the communications code starts. In the future it would be
	* nice to put this code into it's own task that loads on boot so ensure that it runs.
	*/
	RobotBase::RobotBase()
	: m_task (NULL)
	, m_ds (NULL)
	{
	m_ds = DriverStation::GetInstance();
	}

	/**
	* Free the resources for a RobotBase class.
	* This includes deleting all classes that might have been allocated as Singletons so they
	* would never be deleted except here.
	*/
	RobotBase::~RobotBase()
	{
	SensorBase::DeleteSingletons();
	delete m_task;
	m_task = NULL;
	m_instance = NULL;
	}

	/**
	* Check on the overall status of the system.
	*
	* @return Is the system active (i.e. PWM motor outputs, etc. enabled)?
	*/
	bool RobotBase::IsSystemActive()
	{
	return m_watchdog.IsSystemActive();
	}

	/**
	* Return the instance of the Watchdog timer.
	* Get the watchdog timer so the user program can either disable it or feed it when
	* necessary.
	*/
	Watchdog &RobotBase::GetWatchdog()
	{
	return m_watchdog;
	}

	/**
	* Determine if the Robot is currently enabled.
	* @return True if the Robot is currently enabled by the field controls.
	*/
	bool RobotBase::IsEnabled()
	{
	return m_ds->IsEnabled();
	}

	/**
	* Determine if the Robot is currently disabled.
	* @return True if the Robot is currently disabled by the field controls.
	*/
	bool RobotBase::IsDisabled()
	{
	return m_ds->IsDisabled();
	}

	/**
	* Determine if the robot is currently in Autonomous mode.
	* @return True if the robot is currently operating Autonomously as determined by the field controls.
	*/
	bool RobotBase::IsAutonomous()
	{
	return m_ds->IsAutonomous();
	}

	/**
	* Determine if the robot is currently in Operator Control mode.
	* @return True if the robot is currently operating in Tele-Op mode as determined by the field controls.
	*/
	bool RobotBase::IsOperatorControl()
	{
	return m_ds->IsOperatorControl();
	}

	/**
	* Determine if the robot is currently in Test mode.
	* @return True if the robot is currently running tests as determined by the field controls.
	*/
	bool RobotBase::IsTest()
	{
	return m_ds->IsTest();
	}

	/**
	* Indicates if new data is available from the driver station.
	* @return Has new data arrived over the network since the last time this function was called?
	*/
	bool RobotBase::IsNewDataAvailable()
	{
	return m_ds->IsNewControlData();
	}

	/**
	* Static interface that will start the competition in the new task.
	*/
	void RobotBase::robotTask(FUNCPTR factory, Task *task)
	{
	RobotBase instance = (RobotBase)factory();
	instance->m_task = task;
	RobotBase::setInstance(instance);
	instance->StartCompetition();
	}

	void RobotBase::WriteVersionString() {
	FILE *file = fopen(FILE_NAME, "w");
	if (file != NULL) {
	fputs(VERSION_STRING, file);
	fputs(" (customized by Team 971 Spartan Robotics)", file);
	fclose(file);
	}
	}

	/**
	*
	* Start the robot code.
	* This function starts the robot code running by spawning a task. Currently
	* tasks seem to be started by LVRT without setting the VX_FP_TASK flag which
	* means that the floating point registers are not saved on interrupts and task
	* switches. That causes the program to experience hard to debug and
	* unpredictable results, so the LVRT code starts this function, so that it, in
	* turn, can start the actual user program.
	*/
	void RobotBase::startRobotTask(FUNCPTR factory)
	{
	#ifdef SVN_REV
	if (strlen(SVN_REV))
	{
	printf("WPILib was compiled from SVN revision %s\n", SVN_REV);
	}
	else
	{
	printf("WPILib was compiled from a location that is not source controlled.\n");
	}
	#else
	printf("WPILib was compiled without -D'SVN_REV=nnnn'\n");
	#endif
	printf("This WPILib has been fixed by Team 971 Spartan Robotics.\n");

	// Check for startup code already running
	int32_t oldId = taskNameToId(const_cast<char*>("FRC_RobotTask"));
	if (oldId != ERROR)
	{
	// Find the startup code module.
	char moduleName[256];
	moduleNameFindBySymbolName("FRC_UserProgram_StartupLibraryInit", moduleName);
	MODULE_ID startupModId = moduleFindByName(moduleName);
	if (startupModId != NULL)
	{
	// Remove the startup code.
	unldByModuleId(startupModId, 0);
	printf("!!! Error: Default code was still running... It was unloaded for you... Please try again.\n");
	return;
	}
	// This case should no longer get hit.
	printf("!!! Error: Other robot code is still running... Unload it and then try again.\n");
	return;
	}

	// Let the framework know that we are starting a new user program so the Driver Station can disable.
	FRC_NetworkCommunication_observeUserProgramStarting();

	// Let the Usage Reporting framework know that there is a C++ program running
	nUsageReporting::report(nUsageReporting::kResourceType_Language, nUsageReporting::kLanguage_CPlusPlus);

	RobotBase::WriteVersionString();

	// Start robot task
	// This is done to ensure that the C++ robot task is spawned with the floating point
	// context save parameter.
	Task *task = new Task("RobotTask", (FUNCPTR)RobotBase::robotTask, Task::kDefaultPriority, 64000);
	task->Start((int32_t)factory, (int32_t)task);
	}

	/**
	* This class exists for the sole purpose of getting its destructor called when the module unloads.
	* Before the module is done unloading, we need to delete the RobotBase derived singleton. This should delete
	* the other remaining singletons that were registered.
	*/
	class RobotDeleter
	{
	public:
	RobotDeleter() {}
	~RobotDeleter()
	{
	delete &RobotBase::getInstance();
	}
	};
	static RobotDeleter g_robotDeleter;