hal/lib/athena/HAL.cpp - RealtimeRoboticsGroup/test - Gitiles

 /*----------------------------------------------------------------------------*/
 /* Copyright (c) FIRST 2016-2017. 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 the root directory of */
 /* the project.                                                               */
 /*----------------------------------------------------------------------------*/

 #include "HAL/HAL.h"

 #include <signal.h>  // linux for kill
 #include <sys/prctl.h>
 #include <unistd.h>

 #include <atomic>
 #include <cstdlib>
 #include <fstream>
 #include <iostream>
 #include <mutex>
 #include <thread>

 #include "FRC_NetworkCommunication/CANSessionMux.h"
 #include "FRC_NetworkCommunication/FRCComm.h"
 #include "FRC_NetworkCommunication/LoadOut.h"
 #include "HAL/ChipObject.h"
 #include "HAL/DriverStation.h"
 #include "HAL/Errors.h"
 #include "HAL/Notifier.h"
 #include "HAL/cpp/priority_mutex.h"
 #include "HAL/handles/HandlesInternal.h"
 #include "ctre/ctre.h"
 #include "visa/visa.h"

 using namespace hal;

 static std::unique_ptr<tGlobal> global;
 static std::unique_ptr<tSysWatchdog> watchdog;

 static priority_mutex timeMutex;
 static uint32_t timeEpoch = 0;
 static uint32_t prevFPGATime = 0;
 static HAL_NotifierHandle rolloverNotifier = 0;

 using namespace hal;

 extern "C" {

 HAL_PortHandle HAL_GetPort(int32_t channel) {
   // Dont allow a number that wouldn't fit in a uint8_t
   if (channel < 0 || channel >= 255) return HAL_kInvalidHandle;
   return createPortHandle(channel, 1);
 }

 /**
  * @deprecated Uses module numbers
  */
 HAL_PortHandle HAL_GetPortWithModule(int32_t module, int32_t channel) {
   // Dont allow a number that wouldn't fit in a uint8_t
   if (channel < 0 || channel >= 255) return HAL_kInvalidHandle;
   if (module < 0 || module >= 255) return HAL_kInvalidHandle;
   return createPortHandle(channel, module);
 }

 const char* HAL_GetErrorMessage(int32_t code) {
   switch (code) {
     case 0:
       return "";
     case CTR_RxTimeout:
       return CTR_RxTimeout_MESSAGE;
     case CTR_TxTimeout:
       return CTR_TxTimeout_MESSAGE;
     case CTR_InvalidParamValue:
       return CTR_InvalidParamValue_MESSAGE;
     case CTR_UnexpectedArbId:
       return CTR_UnexpectedArbId_MESSAGE;
     case CTR_TxFailed:
       return CTR_TxFailed_MESSAGE;
     case CTR_SigNotUpdated:
       return CTR_SigNotUpdated_MESSAGE;
     case NiFpga_Status_FifoTimeout:
       return NiFpga_Status_FifoTimeout_MESSAGE;
     case NiFpga_Status_TransferAborted:
       return NiFpga_Status_TransferAborted_MESSAGE;
     case NiFpga_Status_MemoryFull:
       return NiFpga_Status_MemoryFull_MESSAGE;
     case NiFpga_Status_SoftwareFault:
       return NiFpga_Status_SoftwareFault_MESSAGE;
     case NiFpga_Status_InvalidParameter:
       return NiFpga_Status_InvalidParameter_MESSAGE;
     case NiFpga_Status_ResourceNotFound:
       return NiFpga_Status_ResourceNotFound_MESSAGE;
     case NiFpga_Status_ResourceNotInitialized:
       return NiFpga_Status_ResourceNotInitialized_MESSAGE;
     case NiFpga_Status_HardwareFault:
       return NiFpga_Status_HardwareFault_MESSAGE;
     case NiFpga_Status_IrqTimeout:
       return NiFpga_Status_IrqTimeout_MESSAGE;
     case SAMPLE_RATE_TOO_HIGH:
       return SAMPLE_RATE_TOO_HIGH_MESSAGE;
     case VOLTAGE_OUT_OF_RANGE:
       return VOLTAGE_OUT_OF_RANGE_MESSAGE;
     case LOOP_TIMING_ERROR:
       return LOOP_TIMING_ERROR_MESSAGE;
     case SPI_WRITE_NO_MOSI:
       return SPI_WRITE_NO_MOSI_MESSAGE;
     case SPI_READ_NO_MISO:
       return SPI_READ_NO_MISO_MESSAGE;
     case SPI_READ_NO_DATA:
       return SPI_READ_NO_DATA_MESSAGE;
     case INCOMPATIBLE_STATE:
       return INCOMPATIBLE_STATE_MESSAGE;
     case NO_AVAILABLE_RESOURCES:
       return NO_AVAILABLE_RESOURCES_MESSAGE;
     case RESOURCE_IS_ALLOCATED:
       return RESOURCE_IS_ALLOCATED_MESSAGE;
     case RESOURCE_OUT_OF_RANGE:
       return RESOURCE_OUT_OF_RANGE_MESSAGE;
     case HAL_INVALID_ACCUMULATOR_CHANNEL:
       return HAL_INVALID_ACCUMULATOR_CHANNEL_MESSAGE;
     case HAL_HANDLE_ERROR:
       return HAL_HANDLE_ERROR_MESSAGE;
     case NULL_PARAMETER:
       return NULL_PARAMETER_MESSAGE;
     case ANALOG_TRIGGER_LIMIT_ORDER_ERROR:
       return ANALOG_TRIGGER_LIMIT_ORDER_ERROR_MESSAGE;
     case ANALOG_TRIGGER_PULSE_OUTPUT_ERROR:
       return ANALOG_TRIGGER_PULSE_OUTPUT_ERROR_MESSAGE;
     case PARAMETER_OUT_OF_RANGE:
       return PARAMETER_OUT_OF_RANGE_MESSAGE;
     case HAL_COUNTER_NOT_SUPPORTED:
       return HAL_COUNTER_NOT_SUPPORTED_MESSAGE;
     case ERR_CANSessionMux_InvalidBuffer:
       return ERR_CANSessionMux_InvalidBuffer_MESSAGE;
     case ERR_CANSessionMux_MessageNotFound:
       return ERR_CANSessionMux_MessageNotFound_MESSAGE;
     case WARN_CANSessionMux_NoToken:
       return WARN_CANSessionMux_NoToken_MESSAGE;
     case ERR_CANSessionMux_NotAllowed:
       return ERR_CANSessionMux_NotAllowed_MESSAGE;
     case ERR_CANSessionMux_NotInitialized:
       return ERR_CANSessionMux_NotInitialized_MESSAGE;
     case VI_ERROR_SYSTEM_ERROR:
       return VI_ERROR_SYSTEM_ERROR_MESSAGE;
     case VI_ERROR_INV_OBJECT:
       return VI_ERROR_INV_OBJECT_MESSAGE;
     case VI_ERROR_RSRC_LOCKED:
       return VI_ERROR_RSRC_LOCKED_MESSAGE;
     case VI_ERROR_RSRC_NFOUND:
       return VI_ERROR_RSRC_NFOUND_MESSAGE;
     case VI_ERROR_INV_RSRC_NAME:
       return VI_ERROR_INV_RSRC_NAME_MESSAGE;
     case VI_ERROR_QUEUE_OVERFLOW:
       return VI_ERROR_QUEUE_OVERFLOW_MESSAGE;
     case VI_ERROR_IO:
       return VI_ERROR_IO_MESSAGE;
     case VI_ERROR_ASRL_PARITY:
       return VI_ERROR_ASRL_PARITY_MESSAGE;
     case VI_ERROR_ASRL_FRAMING:
       return VI_ERROR_ASRL_FRAMING_MESSAGE;
     case VI_ERROR_ASRL_OVERRUN:
       return VI_ERROR_ASRL_OVERRUN_MESSAGE;
     case VI_ERROR_RSRC_BUSY:
       return VI_ERROR_RSRC_BUSY_MESSAGE;
     case VI_ERROR_INV_PARAMETER:
       return VI_ERROR_INV_PARAMETER_MESSAGE;
     case HAL_PWM_SCALE_ERROR:
       return HAL_PWM_SCALE_ERROR_MESSAGE;
     case HAL_SERIAL_PORT_NOT_FOUND:
       return HAL_SERIAL_PORT_NOT_FOUND_MESSAGE;
     case HAL_THREAD_PRIORITY_ERROR:
       return HAL_THREAD_PRIORITY_ERROR_MESSAGE;
     case HAL_THREAD_PRIORITY_RANGE_ERROR:
       return HAL_THREAD_PRIORITY_RANGE_ERROR_MESSAGE;
     case HAL_SERIAL_PORT_OPEN_ERROR:
       return HAL_SERIAL_PORT_OPEN_ERROR_MESSAGE;
     case HAL_SERIAL_PORT_ERROR:
       return HAL_SERIAL_PORT_ERROR_MESSAGE;
     default:
       return "Unknown error status";
   }
 }

 /**
  * Returns the runtime type of this HAL
  */
 HAL_RuntimeType HAL_GetRuntimeType() { return HAL_Athena; }

 /**
  * Return the FPGA Version number.
  * For now, expect this to be competition year.
  * @return FPGA Version number.
  */
 int32_t HAL_GetFPGAVersion(int32_t* status) {
   if (!global) {
     *status = NiFpga_Status_ResourceNotInitialized;
     return 0;
   }
   return global->readVersion(status);
 }

 /**
  * Return the FPGA Revision number.
  * The format of the revision is 3 numbers.
  * The 12 most significant bits are the Major Revision.
  * the next 8 bits are the Minor Revision.
  * The 12 least significant bits are the Build Number.
  * @return FPGA Revision number.
  */
 int64_t HAL_GetFPGARevision(int32_t* status) {
   if (!global) {
     *status = NiFpga_Status_ResourceNotInitialized;
     return 0;
   }
   return global->readRevision(status);
 }

 /**
  * Read the microsecond-resolution timer on the FPGA.
  *
  * @return The current time in microseconds according to the FPGA (since FPGA
  * reset).
  */
 uint64_t HAL_GetFPGATime(int32_t* status) {
   if (!global) {
     *status = NiFpga_Status_ResourceNotInitialized;
     return 0;
   }
   std::lock_guard<priority_mutex> lock(timeMutex);
   uint32_t fpgaTime = global->readLocalTime(status);
   if (*status != 0) return 0;
   // check for rollover
   if (fpgaTime < prevFPGATime) ++timeEpoch;
   prevFPGATime = fpgaTime;
   return static_cast<uint64_t>(timeEpoch) << 32 |
          static_cast<uint64_t>(fpgaTime);
 }

 /**
  * Get the state of the "USER" button on the roboRIO
  * @return true if the button is currently pressed down
  */
 HAL_Bool HAL_GetFPGAButton(int32_t* status) {
   if (!global) {
     *status = NiFpga_Status_ResourceNotInitialized;
     return false;
   }
   return global->readUserButton(status);
 }

 HAL_Bool HAL_GetSystemActive(int32_t* status) {
   if (!watchdog) {
     *status = NiFpga_Status_ResourceNotInitialized;
     return false;
   }
   return watchdog->readStatus_SystemActive(status);
 }

 HAL_Bool HAL_GetBrownedOut(int32_t* status) {
   if (!watchdog) {
     *status = NiFpga_Status_ResourceNotInitialized;
     return false;
   }
   return !(watchdog->readStatus_PowerAlive(status));
 }

 static void timerRollover(uint64_t currentTime, HAL_NotifierHandle handle) {
   // reschedule timer for next rollover
   int32_t status = 0;
   HAL_UpdateNotifierAlarm(handle, currentTime + 0x80000000ULL, &status);
 }

 void HAL_BaseInitialize(int32_t* status) {
   static std::atomic_bool initialized{false};
   static priority_mutex initializeMutex;
   // Initial check, as if it's true initialization has finished
   if (initialized) return;

   std::lock_guard<priority_mutex> lock(initializeMutex);
   // Second check in case another thread was waiting
   if (initialized) return;
   // image 4; Fixes errors caused by multiple processes. Talk to NI about this
   nFPGA::nRoboRIO_FPGANamespace::g_currentTargetClass =
       nLoadOut::kTargetClass_RoboRIO;

   global.reset(tGlobal::create(status));
   watchdog.reset(tSysWatchdog::create(status));
   initialized = true;
 }

 /**
  * Call this to start up HAL. This is required for robot programs.
  */
 int32_t HAL_Initialize(int32_t mode) {
   setlinebuf(stdin);
   setlinebuf(stdout);

   prctl(PR_SET_PDEATHSIG, SIGTERM);

   FRC_NetworkCommunication_Reserve(nullptr);

   std::atexit([]() {
     // Unregister our new data condition variable.
     setNewDataSem(nullptr);
   });

   int32_t status = 0;
   HAL_BaseInitialize(&status);

   if (!rolloverNotifier)
     rolloverNotifier = HAL_InitializeNotifier(timerRollover, nullptr, &status);
   if (status == 0) {
     uint64_t curTime = HAL_GetFPGATime(&status);
     if (status == 0)
       HAL_UpdateNotifierAlarm(rolloverNotifier, curTime + 0x80000000ULL,
                               &status);
   }

   // Kill any previous robot programs
   std::fstream fs;
   // By making this both in/out, it won't give us an error if it doesnt exist
   fs.open("/var/lock/frc.pid", std::fstream::in | std::fstream::out);
   if (fs.bad()) return 0;

   pid_t pid = 0;
   if (!fs.eof() && !fs.fail()) {
     fs >> pid;
     // see if the pid is around, but we don't want to mess with init id=1, or
     // ourselves
     if (pid >= 2 && kill(pid, 0) == 0 && pid != getpid()) {
       std::cout << "Killing previously running FRC program..." << std::endl;
       kill(pid, SIGTERM);  // try to kill it
       std::this_thread::sleep_for(std::chrono::milliseconds(100));
       if (kill(pid, 0) == 0) {
         // still not successfull
         if (mode == 0) {
           std::cout << "FRC pid " << pid
                     << " did not die within 110ms. Aborting" << std::endl;
           return 0;              // just fail
         } else if (mode == 1) {  // kill -9 it
           kill(pid, SIGKILL);
         } else {
           std::cout << "WARNING: FRC pid " << pid
                     << " did not die within 110ms." << std::endl;
         }
       }
     }
   }
   fs.close();
   // we will re-open it write only to truncate the file
   fs.open("/var/lock/frc.pid", std::fstream::out | std::fstream::trunc);
   fs.seekp(0);
   pid = getpid();
   fs << pid << std::endl;
   fs.close();

   HAL_InitializeDriverStation();

   return 1;
 }

 int64_t HAL_Report(int32_t resource, int32_t instanceNumber, int32_t context,
                    const char* feature) {
   if (feature == nullptr) {
     feature = "";
   }

   return FRC_NetworkCommunication_nUsageReporting_report(
       resource, instanceNumber, context, feature);
 }

 // TODO: HACKS
 // No need for header definitions, as we should not run from user code.
 void NumericArrayResize() {}
 void RTSetCleanupProc() {}
 void EDVR_CreateReference() {}
 void Occur() {}

 }  // extern "C"
	/----------------------------------------------------------------------------/
	/* Copyright (c) FIRST 2016-2017. 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 the root directory of */
	/* the project. */
	/----------------------------------------------------------------------------/

	#include "HAL/HAL.h"

	#include <signal.h> // linux for kill
	#include <sys/prctl.h>
	#include <unistd.h>

	#include <atomic>
	#include <cstdlib>
	#include <fstream>
	#include <iostream>
	#include <mutex>
	#include <thread>

	#include "FRC_NetworkCommunication/CANSessionMux.h"
	#include "FRC_NetworkCommunication/FRCComm.h"
	#include "FRC_NetworkCommunication/LoadOut.h"
	#include "HAL/ChipObject.h"
	#include "HAL/DriverStation.h"
	#include "HAL/Errors.h"
	#include "HAL/Notifier.h"
	#include "HAL/cpp/priority_mutex.h"
	#include "HAL/handles/HandlesInternal.h"
	#include "ctre/ctre.h"
	#include "visa/visa.h"

	using namespace hal;

	static std::unique_ptr<tGlobal> global;
	static std::unique_ptr<tSysWatchdog> watchdog;

	static priority_mutex timeMutex;
	static uint32_t timeEpoch = 0;
	static uint32_t prevFPGATime = 0;
	static HAL_NotifierHandle rolloverNotifier = 0;

	using namespace hal;

	extern "C" {

	HAL_PortHandle HAL_GetPort(int32_t channel) {
	// Dont allow a number that wouldn't fit in a uint8_t
	if (channel < 0 \|\| channel >= 255) return HAL_kInvalidHandle;
	return createPortHandle(channel, 1);
	}

	/**
	* @deprecated Uses module numbers
	*/
	HAL_PortHandle HAL_GetPortWithModule(int32_t module, int32_t channel) {
	// Dont allow a number that wouldn't fit in a uint8_t
	if (channel < 0 \|\| channel >= 255) return HAL_kInvalidHandle;
	if (module < 0 \|\| module >= 255) return HAL_kInvalidHandle;
	return createPortHandle(channel, module);
	}

	const char* HAL_GetErrorMessage(int32_t code) {
	switch (code) {
	case 0:
	return "";
	case CTR_RxTimeout:
	return CTR_RxTimeout_MESSAGE;
	case CTR_TxTimeout:
	return CTR_TxTimeout_MESSAGE;
	case CTR_InvalidParamValue:
	return CTR_InvalidParamValue_MESSAGE;
	case CTR_UnexpectedArbId:
	return CTR_UnexpectedArbId_MESSAGE;
	case CTR_TxFailed:
	return CTR_TxFailed_MESSAGE;
	case CTR_SigNotUpdated:
	return CTR_SigNotUpdated_MESSAGE;
	case NiFpga_Status_FifoTimeout:
	return NiFpga_Status_FifoTimeout_MESSAGE;
	case NiFpga_Status_TransferAborted:
	return NiFpga_Status_TransferAborted_MESSAGE;
	case NiFpga_Status_MemoryFull:
	return NiFpga_Status_MemoryFull_MESSAGE;
	case NiFpga_Status_SoftwareFault:
	return NiFpga_Status_SoftwareFault_MESSAGE;
	case NiFpga_Status_InvalidParameter:
	return NiFpga_Status_InvalidParameter_MESSAGE;
	case NiFpga_Status_ResourceNotFound:
	return NiFpga_Status_ResourceNotFound_MESSAGE;
	case NiFpga_Status_ResourceNotInitialized:
	return NiFpga_Status_ResourceNotInitialized_MESSAGE;
	case NiFpga_Status_HardwareFault:
	return NiFpga_Status_HardwareFault_MESSAGE;
	case NiFpga_Status_IrqTimeout:
	return NiFpga_Status_IrqTimeout_MESSAGE;
	case SAMPLE_RATE_TOO_HIGH:
	return SAMPLE_RATE_TOO_HIGH_MESSAGE;
	case VOLTAGE_OUT_OF_RANGE:
	return VOLTAGE_OUT_OF_RANGE_MESSAGE;
	case LOOP_TIMING_ERROR:
	return LOOP_TIMING_ERROR_MESSAGE;
	case SPI_WRITE_NO_MOSI:
	return SPI_WRITE_NO_MOSI_MESSAGE;
	case SPI_READ_NO_MISO:
	return SPI_READ_NO_MISO_MESSAGE;
	case SPI_READ_NO_DATA:
	return SPI_READ_NO_DATA_MESSAGE;
	case INCOMPATIBLE_STATE:
	return INCOMPATIBLE_STATE_MESSAGE;
	case NO_AVAILABLE_RESOURCES:
	return NO_AVAILABLE_RESOURCES_MESSAGE;
	case RESOURCE_IS_ALLOCATED:
	return RESOURCE_IS_ALLOCATED_MESSAGE;
	case RESOURCE_OUT_OF_RANGE:
	return RESOURCE_OUT_OF_RANGE_MESSAGE;
	case HAL_INVALID_ACCUMULATOR_CHANNEL:
	return HAL_INVALID_ACCUMULATOR_CHANNEL_MESSAGE;
	case HAL_HANDLE_ERROR:
	return HAL_HANDLE_ERROR_MESSAGE;
	case NULL_PARAMETER:
	return NULL_PARAMETER_MESSAGE;
	case ANALOG_TRIGGER_LIMIT_ORDER_ERROR:
	return ANALOG_TRIGGER_LIMIT_ORDER_ERROR_MESSAGE;
	case ANALOG_TRIGGER_PULSE_OUTPUT_ERROR:
	return ANALOG_TRIGGER_PULSE_OUTPUT_ERROR_MESSAGE;
	case PARAMETER_OUT_OF_RANGE:
	return PARAMETER_OUT_OF_RANGE_MESSAGE;
	case HAL_COUNTER_NOT_SUPPORTED:
	return HAL_COUNTER_NOT_SUPPORTED_MESSAGE;
	case ERR_CANSessionMux_InvalidBuffer:
	return ERR_CANSessionMux_InvalidBuffer_MESSAGE;
	case ERR_CANSessionMux_MessageNotFound:
	return ERR_CANSessionMux_MessageNotFound_MESSAGE;
	case WARN_CANSessionMux_NoToken:
	return WARN_CANSessionMux_NoToken_MESSAGE;
	case ERR_CANSessionMux_NotAllowed:
	return ERR_CANSessionMux_NotAllowed_MESSAGE;
	case ERR_CANSessionMux_NotInitialized:
	return ERR_CANSessionMux_NotInitialized_MESSAGE;
	case VI_ERROR_SYSTEM_ERROR:
	return VI_ERROR_SYSTEM_ERROR_MESSAGE;
	case VI_ERROR_INV_OBJECT:
	return VI_ERROR_INV_OBJECT_MESSAGE;
	case VI_ERROR_RSRC_LOCKED:
	return VI_ERROR_RSRC_LOCKED_MESSAGE;
	case VI_ERROR_RSRC_NFOUND:
	return VI_ERROR_RSRC_NFOUND_MESSAGE;
	case VI_ERROR_INV_RSRC_NAME:
	return VI_ERROR_INV_RSRC_NAME_MESSAGE;
	case VI_ERROR_QUEUE_OVERFLOW:
	return VI_ERROR_QUEUE_OVERFLOW_MESSAGE;
	case VI_ERROR_IO:
	return VI_ERROR_IO_MESSAGE;
	case VI_ERROR_ASRL_PARITY:
	return VI_ERROR_ASRL_PARITY_MESSAGE;
	case VI_ERROR_ASRL_FRAMING:
	return VI_ERROR_ASRL_FRAMING_MESSAGE;
	case VI_ERROR_ASRL_OVERRUN:
	return VI_ERROR_ASRL_OVERRUN_MESSAGE;
	case VI_ERROR_RSRC_BUSY:
	return VI_ERROR_RSRC_BUSY_MESSAGE;
	case VI_ERROR_INV_PARAMETER:
	return VI_ERROR_INV_PARAMETER_MESSAGE;
	case HAL_PWM_SCALE_ERROR:
	return HAL_PWM_SCALE_ERROR_MESSAGE;
	case HAL_SERIAL_PORT_NOT_FOUND:
	return HAL_SERIAL_PORT_NOT_FOUND_MESSAGE;
	case HAL_THREAD_PRIORITY_ERROR:
	return HAL_THREAD_PRIORITY_ERROR_MESSAGE;
	case HAL_THREAD_PRIORITY_RANGE_ERROR:
	return HAL_THREAD_PRIORITY_RANGE_ERROR_MESSAGE;
	case HAL_SERIAL_PORT_OPEN_ERROR:
	return HAL_SERIAL_PORT_OPEN_ERROR_MESSAGE;
	case HAL_SERIAL_PORT_ERROR:
	return HAL_SERIAL_PORT_ERROR_MESSAGE;
	default:
	return "Unknown error status";
	}
	}

	/**
	* Returns the runtime type of this HAL
	*/
	HAL_RuntimeType HAL_GetRuntimeType() { return HAL_Athena; }

	/**
	* Return the FPGA Version number.
	* For now, expect this to be competition year.
	* @return FPGA Version number.
	*/
	int32_t HAL_GetFPGAVersion(int32_t* status) {
	if (!global) {
	*status = NiFpga_Status_ResourceNotInitialized;
	return 0;
	}
	return global->readVersion(status);
	}

	/**
	* Return the FPGA Revision number.
	* The format of the revision is 3 numbers.
	* The 12 most significant bits are the Major Revision.
	* the next 8 bits are the Minor Revision.
	* The 12 least significant bits are the Build Number.
	* @return FPGA Revision number.
	*/
	int64_t HAL_GetFPGARevision(int32_t* status) {
	if (!global) {
	*status = NiFpga_Status_ResourceNotInitialized;
	return 0;
	}
	return global->readRevision(status);
	}

	/**
	* Read the microsecond-resolution timer on the FPGA.
	*
	* @return The current time in microseconds according to the FPGA (since FPGA
	* reset).
	*/
	uint64_t HAL_GetFPGATime(int32_t* status) {
	if (!global) {
	*status = NiFpga_Status_ResourceNotInitialized;
	return 0;
	}
	std::lock_guard<priority_mutex> lock(timeMutex);
	uint32_t fpgaTime = global->readLocalTime(status);
	if (*status != 0) return 0;
	// check for rollover
	if (fpgaTime < prevFPGATime) ++timeEpoch;
	prevFPGATime = fpgaTime;
	return static_cast<uint64_t>(timeEpoch) << 32 \|
	static_cast<uint64_t>(fpgaTime);
	}

	/**
	* Get the state of the "USER" button on the roboRIO
	* @return true if the button is currently pressed down
	*/
	HAL_Bool HAL_GetFPGAButton(int32_t* status) {
	if (!global) {
	*status = NiFpga_Status_ResourceNotInitialized;
	return false;
	}
	return global->readUserButton(status);
	}

	HAL_Bool HAL_GetSystemActive(int32_t* status) {
	if (!watchdog) {
	*status = NiFpga_Status_ResourceNotInitialized;
	return false;
	}
	return watchdog->readStatus_SystemActive(status);
	}

	HAL_Bool HAL_GetBrownedOut(int32_t* status) {
	if (!watchdog) {
	*status = NiFpga_Status_ResourceNotInitialized;
	return false;
	}
	return !(watchdog->readStatus_PowerAlive(status));
	}

	static void timerRollover(uint64_t currentTime, HAL_NotifierHandle handle) {
	// reschedule timer for next rollover
	int32_t status = 0;
	HAL_UpdateNotifierAlarm(handle, currentTime + 0x80000000ULL, &status);
	}

	void HAL_BaseInitialize(int32_t* status) {
	static std::atomic_bool initialized{false};
	static priority_mutex initializeMutex;
	// Initial check, as if it's true initialization has finished
	if (initialized) return;

	std::lock_guard<priority_mutex> lock(initializeMutex);
	// Second check in case another thread was waiting
	if (initialized) return;
	// image 4; Fixes errors caused by multiple processes. Talk to NI about this
	nFPGA::nRoboRIO_FPGANamespace::g_currentTargetClass =
	nLoadOut::kTargetClass_RoboRIO;

	global.reset(tGlobal::create(status));
	watchdog.reset(tSysWatchdog::create(status));
	initialized = true;
	}

	/**
	* Call this to start up HAL. This is required for robot programs.
	*/
	int32_t HAL_Initialize(int32_t mode) {
	setlinebuf(stdin);
	setlinebuf(stdout);

	prctl(PR_SET_PDEATHSIG, SIGTERM);

	FRC_NetworkCommunication_Reserve(nullptr);

	std::atexit([]() {
	// Unregister our new data condition variable.
	setNewDataSem(nullptr);
	});

	int32_t status = 0;
	HAL_BaseInitialize(&status);

	if (!rolloverNotifier)
	rolloverNotifier = HAL_InitializeNotifier(timerRollover, nullptr, &status);
	if (status == 0) {
	uint64_t curTime = HAL_GetFPGATime(&status);
	if (status == 0)
	HAL_UpdateNotifierAlarm(rolloverNotifier, curTime + 0x80000000ULL,
	&status);
	}

	// Kill any previous robot programs
	std::fstream fs;
	// By making this both in/out, it won't give us an error if it doesnt exist
	fs.open("/var/lock/frc.pid", std::fstream::in \| std::fstream::out);
	if (fs.bad()) return 0;

	pid_t pid = 0;
	if (!fs.eof() && !fs.fail()) {
	fs >> pid;
	// see if the pid is around, but we don't want to mess with init id=1, or
	// ourselves
	if (pid >= 2 && kill(pid, 0) == 0 && pid != getpid()) {
	std::cout << "Killing previously running FRC program..." << std::endl;
	kill(pid, SIGTERM); // try to kill it
	std::this_thread::sleep_for(std::chrono::milliseconds(100));
	if (kill(pid, 0) == 0) {
	// still not successfull
	if (mode == 0) {
	std::cout << "FRC pid " << pid
	<< " did not die within 110ms. Aborting" << std::endl;
	return 0; // just fail
	} else if (mode == 1) { // kill -9 it
	kill(pid, SIGKILL);
	} else {
	std::cout << "WARNING: FRC pid " << pid
	<< " did not die within 110ms." << std::endl;
	}
	}
	}
	}
	fs.close();
	// we will re-open it write only to truncate the file
	fs.open("/var/lock/frc.pid", std::fstream::out \| std::fstream::trunc);
	fs.seekp(0);
	pid = getpid();
	fs << pid << std::endl;
	fs.close();

	HAL_InitializeDriverStation();

	return 1;
	}

	int64_t HAL_Report(int32_t resource, int32_t instanceNumber, int32_t context,
	const char* feature) {
	if (feature == nullptr) {
	feature = "";
	}

	return FRC_NetworkCommunication_nUsageReporting_report(
	resource, instanceNumber, context, feature);
	}

	// TODO: HACKS
	// No need for header definitions, as we should not run from user code.
	void NumericArrayResize() {}
	void RTSetCleanupProc() {}
	void EDVR_CreateReference() {}
	void Occur() {}

	} // extern "C"