/*----------------------------------------------------------------------------*/ /* Copyright (c) FIRST 2016. 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 // linux for kill #include #include #include #include #include #include #include #include "ChipObject.h" #include "FRC_NetworkCommunication/CANSessionMux.h" #include "FRC_NetworkCommunication/FRCComm.h" #include "FRC_NetworkCommunication/LoadOut.h" #include "HAL/Errors.h" #include "HAL/cpp/priority_mutex.h" #include "HAL/handles/HandlesInternal.h" #include "ctre/ctre.h" #include "visa/visa.h" static std::unique_ptr global; static std::unique_ptr 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; default: return "Unknown error status"; } } /** * 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 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(timeEpoch) << 32 | static_cast(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 HALCleanupAtExit() { global = nullptr; watchdog = nullptr; // Unregister our new data condition variable. setNewDataSem(nullptr); } static void timerRollover(uint64_t currentTime, HAL_NotifierHandle handle) { // reschedule timer for next rollover int32_t status = 0; HAL_UpdateNotifierAlarm(handle, currentTime + 0x80000000ULL, &status); } /** * 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); // image 4; Fixes errors caused by multiple processes. Talk to NI about this nFPGA::nRoboRIO_FPGANamespace::g_currentTargetClass = nLoadOut::kTargetClass_RoboRIO; int32_t status = 0; global.reset(tGlobal::create(&status)); watchdog.reset(tSysWatchdog::create(&status)); std::atexit(HALCleanupAtExit); 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"