void taskUpdateBaro(void) { if (sensors(SENSOR_BARO)) { uint32_t newDeadline = baroUpdate(); rescheduleTask(TASK_SELF, newDeadline); } }
void taskUpdateBaro(void) { if (sensors(SENSOR_BARO)) { uint32_t newDeadline = baroUpdate(); rescheduleTask(TASK_SELF, newDeadline); } //updatePositionEstimator_BaroTopic(currentTime); }
static void taskUpdateBaro(timeUs_t currentTimeUs) { UNUSED(currentTimeUs); if (sensors(SENSOR_BARO)) { const uint32_t newDeadline = baroUpdate(); if (newDeadline != 0) { rescheduleTask(TASK_SELF, newDeadline); } } }
void taskUpdateBaro(timeUs_t currentTimeUs) { UNUSED(currentTimeUs); if (sensors(SENSOR_BARO)) { const uint32_t newDeadline = baroUpdate(); if (newDeadline != 0) { rescheduleTask(TASK_SELF, newDeadline); } } //updatePositionEstimator_BaroTopic(currentTimeUs); }
bool checkIbusTelemetryState(void) { bool newTelemetryEnabledValue = telemetryDetermineEnabledState(ibusPortSharing); if (newTelemetryEnabledValue == ibusTelemetryEnabled) { return false; } if (newTelemetryEnabledValue) { rescheduleTask(TASK_TELEMETRY, IBUS_TASK_PERIOD_US); configureIbusTelemetryPort(); } else { freeIbusTelemetryPort(); } return true; }
// system void systemInit(void) { int ret; clock_gettime(CLOCK_MONOTONIC, &start_time); printf("[system]Init...\n"); SystemCoreClock = 500 * 1e6; // fake 500MHz FLASH_Unlock(); if (pthread_mutex_init(&updateLock, NULL) != 0) { printf("Create updateLock error!\n"); exit(1); } if (pthread_mutex_init(&mainLoopLock, NULL) != 0) { printf("Create mainLoopLock error!\n"); exit(1); } ret = pthread_create(&tcpWorker, NULL, tcpThread, NULL); if (ret != 0) { printf("Create tcpWorker error!\n"); exit(1); } ret = udpInit(&pwmLink, "127.0.0.1", 9002, false); printf("init PwnOut UDP link...%d\n", ret); ret = udpInit(&stateLink, NULL, 9003, true); printf("start UDP server...%d\n", ret); ret = pthread_create(&udpWorker, NULL, udpThread, NULL); if (ret != 0) { printf("Create udpWorker error!\n"); exit(1); } // serial can't been slow down rescheduleTask(TASK_SERIAL, 1); }
void fcTasksInit(void) { schedulerInit(); #ifdef ASYNC_GYRO_PROCESSING rescheduleTask(TASK_PID, getPidUpdateRate()); setTaskEnabled(TASK_PID, true); if (getAsyncMode() != ASYNC_MODE_NONE) { rescheduleTask(TASK_GYRO, getGyroUpdateRate()); setTaskEnabled(TASK_GYRO, true); } if (getAsyncMode() == ASYNC_MODE_ALL && sensors(SENSOR_ACC)) { rescheduleTask(TASK_ACC, getAccUpdateRate()); setTaskEnabled(TASK_ACC, true); rescheduleTask(TASK_ATTI, getAttitudeUpdateRate()); setTaskEnabled(TASK_ATTI, true); } #else rescheduleTask(TASK_GYROPID, gyro.targetLooptime); setTaskEnabled(TASK_GYROPID, true); #endif setTaskEnabled(TASK_SERIAL, true); #ifdef BEEPER setTaskEnabled(TASK_BEEPER, true); #endif setTaskEnabled(TASK_BATTERY, feature(FEATURE_VBAT) || feature(FEATURE_CURRENT_METER)); setTaskEnabled(TASK_RX, true); #ifdef GPS setTaskEnabled(TASK_GPS, feature(FEATURE_GPS)); #endif #ifdef MAG setTaskEnabled(TASK_COMPASS, sensors(SENSOR_MAG)); #if defined(MPU6500_SPI_INSTANCE) && defined(USE_MAG_AK8963) // fixme temporary solution for AK6983 via slave I2C on MPU9250 rescheduleTask(TASK_COMPASS, TASK_PERIOD_HZ(40)); #endif #endif #ifdef BARO setTaskEnabled(TASK_BARO, sensors(SENSOR_BARO)); #endif #ifdef PITOT setTaskEnabled(TASK_PITOT, sensors(SENSOR_PITOT)); #endif #ifdef SONAR setTaskEnabled(TASK_SONAR, sensors(SENSOR_SONAR)); #endif #ifdef USE_DASHBOARD setTaskEnabled(TASK_DASHBOARD, feature(FEATURE_DASHBOARD)); #endif #ifdef TELEMETRY setTaskEnabled(TASK_TELEMETRY, feature(FEATURE_TELEMETRY)); #endif #ifdef LED_STRIP setTaskEnabled(TASK_LEDSTRIP, feature(FEATURE_LED_STRIP)); #endif #ifdef STACK_CHECK setTaskEnabled(TASK_STACK_CHECK, true); #endif #ifdef USE_PMW_SERVO_DRIVER setTaskEnabled(TASK_PWMDRIVER, feature(FEATURE_PWM_SERVO_DRIVER)); #endif #ifdef OSD setTaskEnabled(TASK_OSD, feature(FEATURE_OSD)); #endif #ifdef CMS #ifdef USE_MSP_DISPLAYPORT setTaskEnabled(TASK_CMS, true); #else setTaskEnabled(TASK_CMS, feature(FEATURE_OSD) || feature(FEATURE_DASHBOARD)); #endif #endif }
void init(void) { printfSupportInit(); initEEPROM(); ensureEEPROMContainsValidData(); readEEPROM(); systemState |= SYSTEM_STATE_CONFIG_LOADED; systemInit(); //i2cSetOverclock(masterConfig.i2c_overclock); // initialize IO (needed for all IO operations) IOInitGlobal(); debugMode = masterConfig.debug_mode; #ifdef USE_HARDWARE_REVISION_DETECTION detectHardwareRevision(); #endif // Latch active features to be used for feature() in the remainder of init(). latchActiveFeatures(); #ifdef ALIENFLIGHTF3 ledInit(hardwareRevision == AFF3_REV_1 ? false : true); #else ledInit(false); #endif LED2_ON; #ifdef USE_EXTI EXTIInit(); #endif #if defined(BUTTONS) gpio_config_t buttonAGpioConfig = { BUTTON_A_PIN, Mode_IPU, Speed_2MHz }; gpioInit(BUTTON_A_PORT, &buttonAGpioConfig); gpio_config_t buttonBGpioConfig = { BUTTON_B_PIN, Mode_IPU, Speed_2MHz }; gpioInit(BUTTON_B_PORT, &buttonBGpioConfig); // Check status of bind plug and exit if not active delayMicroseconds(10); // allow GPIO configuration to settle if (!isMPUSoftReset()) { uint8_t secondsRemaining = 5; bool bothButtonsHeld; do { bothButtonsHeld = !digitalIn(BUTTON_A_PORT, BUTTON_A_PIN) && !digitalIn(BUTTON_B_PORT, BUTTON_B_PIN); if (bothButtonsHeld) { if (--secondsRemaining == 0) { resetEEPROM(); systemReset(); } delay(1000); LED0_TOGGLE; } } while (bothButtonsHeld); } #endif #ifdef SPEKTRUM_BIND if (feature(FEATURE_RX_SERIAL)) { switch (masterConfig.rxConfig.serialrx_provider) { case SERIALRX_SPEKTRUM1024: case SERIALRX_SPEKTRUM2048: // Spektrum satellite binding if enabled on startup. // Must be called before that 100ms sleep so that we don't lose satellite's binding window after startup. // The rest of Spektrum initialization will happen later - via spektrumInit() spektrumBind(&masterConfig.rxConfig); break; } } #endif delay(100); timerInit(); // timer must be initialized before any channel is allocated dmaInit(); #if defined(AVOID_UART1_FOR_PWM_PPM) serialInit(&masterConfig.serialConfig, feature(FEATURE_SOFTSERIAL), feature(FEATURE_RX_PPM) || feature(FEATURE_RX_PARALLEL_PWM) ? SERIAL_PORT_USART1 : SERIAL_PORT_NONE); #elif defined(AVOID_UART2_FOR_PWM_PPM) serialInit(&masterConfig.serialConfig, feature(FEATURE_SOFTSERIAL), feature(FEATURE_RX_PPM) || feature(FEATURE_RX_PARALLEL_PWM) ? SERIAL_PORT_USART2 : SERIAL_PORT_NONE); #elif defined(AVOID_UART3_FOR_PWM_PPM) serialInit(&masterConfig.serialConfig, feature(FEATURE_SOFTSERIAL), feature(FEATURE_RX_PPM) || feature(FEATURE_RX_PARALLEL_PWM) ? SERIAL_PORT_USART3 : SERIAL_PORT_NONE); #else serialInit(&masterConfig.serialConfig, feature(FEATURE_SOFTSERIAL), SERIAL_PORT_NONE); #endif #ifdef USE_SERVOS mixerInit(masterConfig.mixerMode, masterConfig.customMotorMixer, masterConfig.customServoMixer); #else mixerInit(masterConfig.mixerMode, masterConfig.customMotorMixer); #endif drv_pwm_config_t pwm_params; memset(&pwm_params, 0, sizeof(pwm_params)); #ifdef SONAR if (feature(FEATURE_SONAR)) { const sonarHardware_t *sonarHardware = sonarGetHardwareConfiguration(masterConfig.batteryConfig.currentMeterType); if (sonarHardware) { pwm_params.useSonar = true; pwm_params.sonarIOConfig.triggerTag = sonarHardware->triggerTag; pwm_params.sonarIOConfig.echoTag = sonarHardware->echoTag; } } #endif // when using airplane/wing mixer, servo/motor outputs are remapped if (masterConfig.mixerMode == MIXER_AIRPLANE || masterConfig.mixerMode == MIXER_FLYING_WING || masterConfig.mixerMode == MIXER_CUSTOM_AIRPLANE) pwm_params.airplane = true; else pwm_params.airplane = false; #if defined(USE_UART2) && defined(STM32F10X) pwm_params.useUART2 = doesConfigurationUsePort(SERIAL_PORT_USART2); #endif #ifdef STM32F303xC pwm_params.useUART2 = doesConfigurationUsePort(SERIAL_PORT_USART2); pwm_params.useUART3 = doesConfigurationUsePort(SERIAL_PORT_USART3); #endif #if defined(USE_UART2) && defined(STM32F40_41xxx) pwm_params.useUART2 = doesConfigurationUsePort(SERIAL_PORT_USART2); #endif #if defined(USE_UART6) && defined(STM32F40_41xxx) pwm_params.useUART6 = doesConfigurationUsePort(SERIAL_PORT_USART6); #endif pwm_params.useVbat = feature(FEATURE_VBAT); pwm_params.useSoftSerial = feature(FEATURE_SOFTSERIAL); pwm_params.useParallelPWM = feature(FEATURE_RX_PARALLEL_PWM); pwm_params.useRSSIADC = feature(FEATURE_RSSI_ADC); pwm_params.useCurrentMeterADC = feature(FEATURE_CURRENT_METER) && masterConfig.batteryConfig.currentMeterType == CURRENT_SENSOR_ADC; pwm_params.useLEDStrip = feature(FEATURE_LED_STRIP); pwm_params.usePPM = feature(FEATURE_RX_PPM); pwm_params.useSerialRx = feature(FEATURE_RX_SERIAL); #ifdef USE_SERVOS pwm_params.useServos = isMixerUsingServos(); pwm_params.useChannelForwarding = feature(FEATURE_CHANNEL_FORWARDING); pwm_params.servoCenterPulse = masterConfig.escAndServoConfig.servoCenterPulse; pwm_params.servoPwmRate = masterConfig.servo_pwm_rate; #endif bool use_unsyncedPwm = masterConfig.use_unsyncedPwm || masterConfig.motor_pwm_protocol == PWM_TYPE_CONVENTIONAL || masterConfig.motor_pwm_protocol == PWM_TYPE_BRUSHED; // Configurator feature abused for enabling Fast PWM pwm_params.useFastPwm = (masterConfig.motor_pwm_protocol != PWM_TYPE_CONVENTIONAL && masterConfig.motor_pwm_protocol != PWM_TYPE_BRUSHED); pwm_params.pwmProtocolType = masterConfig.motor_pwm_protocol; pwm_params.motorPwmRate = use_unsyncedPwm ? masterConfig.motor_pwm_rate : 0; pwm_params.idlePulse = masterConfig.escAndServoConfig.mincommand; if (feature(FEATURE_3D)) pwm_params.idlePulse = masterConfig.flight3DConfig.neutral3d; if (masterConfig.motor_pwm_protocol == PWM_TYPE_BRUSHED) { featureClear(FEATURE_3D); pwm_params.idlePulse = 0; // brushed motors } #ifdef CC3D pwm_params.useBuzzerP6 = masterConfig.use_buzzer_p6 ? true : false; #endif #ifndef SKIP_RX_PWM_PPM pwmRxInit(masterConfig.inputFilteringMode); #endif // pwmInit() needs to be called as soon as possible for ESC compatibility reasons pwmOutputConfiguration_t *pwmOutputConfiguration = pwmInit(&pwm_params); mixerUsePWMOutputConfiguration(pwmOutputConfiguration, use_unsyncedPwm); systemState |= SYSTEM_STATE_MOTORS_READY; #ifdef BEEPER beeperConfig_t beeperConfig = { .ioTag = IO_TAG(BEEPER), #ifdef BEEPER_INVERTED .isOD = false, .isInverted = true #else .isOD = true, .isInverted = false #endif }; #ifdef NAZE if (hardwareRevision >= NAZE32_REV5) { // naze rev4 and below used opendrain to PNP for buzzer. Rev5 and above use PP to NPN. beeperConfig.isOD = false; beeperConfig.isInverted = true; } #endif /* temp until PGs are implemented. */ #ifdef BLUEJAYF4 if (hardwareRevision <= BJF4_REV2) { beeperConfig.ioTag = IO_TAG(BEEPER_OPT); } #endif #ifdef CC3D if (masterConfig.use_buzzer_p6 == 1) beeperConfig.ioTag = IO_TAG(BEEPER_OPT); #endif beeperInit(&beeperConfig); #endif #ifdef INVERTER initInverter(); #endif #ifdef USE_BST bstInit(BST_DEVICE); #endif #ifdef USE_SPI #ifdef USE_SPI_DEVICE_1 spiInit(SPIDEV_1); #endif #ifdef USE_SPI_DEVICE_2 spiInit(SPIDEV_2); #endif #ifdef USE_SPI_DEVICE_3 #ifdef ALIENFLIGHTF3 if (hardwareRevision == AFF3_REV_2) { spiInit(SPIDEV_3); } #else spiInit(SPIDEV_3); #endif #endif #endif #ifdef VTX vtxInit(); #endif #ifdef USE_HARDWARE_REVISION_DETECTION updateHardwareRevision(); #endif #if defined(NAZE) if (hardwareRevision == NAZE32_SP) { serialRemovePort(SERIAL_PORT_SOFTSERIAL2); } else { serialRemovePort(SERIAL_PORT_USART3); } #endif #if defined(SPRACINGF3) && defined(SONAR) && defined(USE_SOFTSERIAL2) if (feature(FEATURE_SONAR) && feature(FEATURE_SOFTSERIAL)) { serialRemovePort(SERIAL_PORT_SOFTSERIAL2); } #endif #if defined(SPRACINGF3MINI) || defined(OMNIBUS) || defined(X_RACERSPI) #if defined(SONAR) && defined(USE_SOFTSERIAL1) if (feature(FEATURE_SONAR) && feature(FEATURE_SOFTSERIAL)) { serialRemovePort(SERIAL_PORT_SOFTSERIAL1); } #endif #endif #ifdef USE_I2C #if defined(NAZE) if (hardwareRevision != NAZE32_SP) { i2cInit(I2C_DEVICE); } else { if (!doesConfigurationUsePort(SERIAL_PORT_USART3)) { i2cInit(I2C_DEVICE); } } #elif defined(CC3D) if (!doesConfigurationUsePort(SERIAL_PORT_USART3)) { i2cInit(I2C_DEVICE); } #else i2cInit(I2C_DEVICE); #endif #endif #ifdef USE_ADC drv_adc_config_t adc_params; adc_params.enableVBat = feature(FEATURE_VBAT); adc_params.enableRSSI = feature(FEATURE_RSSI_ADC); adc_params.enableCurrentMeter = feature(FEATURE_CURRENT_METER); adc_params.enableExternal1 = false; #ifdef OLIMEXINO adc_params.enableExternal1 = true; #endif #ifdef NAZE // optional ADC5 input on rev.5 hardware adc_params.enableExternal1 = (hardwareRevision >= NAZE32_REV5); #endif adcInit(&adc_params); #endif initBoardAlignment(&masterConfig.boardAlignment); #ifdef DISPLAY if (feature(FEATURE_DISPLAY)) { displayInit(&masterConfig.rxConfig); } #endif #ifdef USE_RTC6705 if (feature(FEATURE_VTX)) { rtc6705_soft_spi_init(); current_vtx_channel = masterConfig.vtx_channel; rtc6705_soft_spi_set_channel(vtx_freq[current_vtx_channel]); rtc6705_soft_spi_set_rf_power(masterConfig.vtx_power); } #endif #ifdef OSD if (feature(FEATURE_OSD)) { osdInit(); } #endif if (!sensorsAutodetect(&masterConfig.sensorAlignmentConfig, masterConfig.acc_hardware, masterConfig.mag_hardware, masterConfig.baro_hardware, masterConfig.mag_declination, masterConfig.gyro_lpf, masterConfig.gyro_sync_denom)) { // if gyro was not detected due to whatever reason, we give up now. failureMode(FAILURE_MISSING_ACC); } systemState |= SYSTEM_STATE_SENSORS_READY; LED1_ON; LED0_OFF; LED2_OFF; for (int i = 0; i < 10; i++) { LED1_TOGGLE; LED0_TOGGLE; delay(25); if (!(getBeeperOffMask() & (1 << (BEEPER_SYSTEM_INIT - 1)))) BEEP_ON; delay(25); BEEP_OFF; } LED0_OFF; LED1_OFF; #ifdef MAG if (sensors(SENSOR_MAG)) compassInit(); #endif imuInit(); mspInit(&masterConfig.serialConfig); #ifdef USE_CLI cliInit(&masterConfig.serialConfig); #endif failsafeInit(&masterConfig.rxConfig, masterConfig.flight3DConfig.deadband3d_throttle); rxInit(&masterConfig.rxConfig, masterConfig.modeActivationConditions); #ifdef GPS if (feature(FEATURE_GPS)) { gpsInit( &masterConfig.serialConfig, &masterConfig.gpsConfig ); navigationInit( &masterConfig.gpsProfile, ¤tProfile->pidProfile ); } #endif #ifdef SONAR if (feature(FEATURE_SONAR)) { sonarInit(); } #endif #ifdef LED_STRIP ledStripInit(masterConfig.ledConfigs, masterConfig.colors, masterConfig.modeColors, &masterConfig.specialColors); if (feature(FEATURE_LED_STRIP)) { ledStripEnable(); } #endif #ifdef TELEMETRY if (feature(FEATURE_TELEMETRY)) { telemetryInit(); } #endif #ifdef USB_CABLE_DETECTION usbCableDetectInit(); #endif #ifdef TRANSPONDER if (feature(FEATURE_TRANSPONDER)) { transponderInit(masterConfig.transponderData); transponderEnable(); transponderStartRepeating(); systemState |= SYSTEM_STATE_TRANSPONDER_ENABLED; } #endif #ifdef USE_FLASHFS #ifdef NAZE if (hardwareRevision == NAZE32_REV5) { m25p16_init(IOTAG_NONE); } #elif defined(USE_FLASH_M25P16) m25p16_init(IOTAG_NONE); #endif flashfsInit(); #endif #ifdef USE_SDCARD bool sdcardUseDMA = false; sdcardInsertionDetectInit(); #ifdef SDCARD_DMA_CHANNEL_TX #if defined(LED_STRIP) && defined(WS2811_DMA_CHANNEL) // Ensure the SPI Tx DMA doesn't overlap with the led strip #ifdef STM32F4 sdcardUseDMA = !feature(FEATURE_LED_STRIP) || SDCARD_DMA_CHANNEL_TX != WS2811_DMA_STREAM; #else sdcardUseDMA = !feature(FEATURE_LED_STRIP) || SDCARD_DMA_CHANNEL_TX != WS2811_DMA_CHANNEL; #endif #else sdcardUseDMA = true; #endif #endif sdcard_init(sdcardUseDMA); afatfs_init(); #endif if (masterConfig.gyro_lpf > 0 && masterConfig.gyro_lpf < 7) { masterConfig.pid_process_denom = 1; // When gyro set to 1khz always set pid speed 1:1 to sampling speed masterConfig.gyro_sync_denom = 1; } setTargetPidLooptime(gyro.targetLooptime * masterConfig.pid_process_denom); // Initialize pid looptime #ifdef BLACKBOX initBlackbox(); #endif if (masterConfig.mixerMode == MIXER_GIMBAL) { accSetCalibrationCycles(CALIBRATING_ACC_CYCLES); } gyroSetCalibrationCycles(); #ifdef BARO baroSetCalibrationCycles(CALIBRATING_BARO_CYCLES); #endif // start all timers // TODO - not implemented yet timerStart(); ENABLE_STATE(SMALL_ANGLE); DISABLE_ARMING_FLAG(PREVENT_ARMING); #ifdef SOFTSERIAL_LOOPBACK // FIXME this is a hack, perhaps add a FUNCTION_LOOPBACK to support it properly loopbackPort = (serialPort_t*)&(softSerialPorts[0]); if (!loopbackPort->vTable) { loopbackPort = openSoftSerial(0, NULL, 19200, SERIAL_NOT_INVERTED); } serialPrint(loopbackPort, "LOOPBACK\r\n"); #endif // Now that everything has powered up the voltage and cell count be determined. if (feature(FEATURE_VBAT | FEATURE_CURRENT_METER)) batteryInit(&masterConfig.batteryConfig); #ifdef DISPLAY if (feature(FEATURE_DISPLAY)) { #ifdef USE_OLED_GPS_DEBUG_PAGE_ONLY displayShowFixedPage(PAGE_GPS); #else displayResetPageCycling(); displayEnablePageCycling(); #endif } #endif #ifdef CJMCU LED2_ON; #endif // Latch active features AGAIN since some may be modified by init(). latchActiveFeatures(); motorControlEnable = true; systemState |= SYSTEM_STATE_READY; } #ifdef SOFTSERIAL_LOOPBACK void processLoopback(void) { if (loopbackPort) { uint8_t bytesWaiting; while ((bytesWaiting = serialRxBytesWaiting(loopbackPort))) { uint8_t b = serialRead(loopbackPort); serialWrite(loopbackPort, b); }; } } #else #define processLoopback() #endif void main_init(void) { init(); /* Setup scheduler */ schedulerInit(); rescheduleTask(TASK_GYROPID, gyro.targetLooptime); setTaskEnabled(TASK_GYROPID, true); if (sensors(SENSOR_ACC)) { setTaskEnabled(TASK_ACCEL, true); switch (gyro.targetLooptime) { // Switch statement kept in place to change acc rates in the future case 500: case 375: case 250: case 125: accTargetLooptime = 1000; break; default: case 1000: #ifdef STM32F10X accTargetLooptime = 1000; #else accTargetLooptime = 1000; #endif } rescheduleTask(TASK_ACCEL, accTargetLooptime); } setTaskEnabled(TASK_ATTITUDE, sensors(SENSOR_ACC)); setTaskEnabled(TASK_SERIAL, true); #ifdef BEEPER setTaskEnabled(TASK_BEEPER, true); #endif setTaskEnabled(TASK_BATTERY, feature(FEATURE_VBAT) || feature(FEATURE_CURRENT_METER)); setTaskEnabled(TASK_RX, true); #ifdef GPS setTaskEnabled(TASK_GPS, feature(FEATURE_GPS)); #endif #ifdef MAG setTaskEnabled(TASK_COMPASS, sensors(SENSOR_MAG)); #if defined(USE_SPI) && defined(USE_MAG_AK8963) // fixme temporary solution for AK6983 via slave I2C on MPU9250 rescheduleTask(TASK_COMPASS, 1000000 / 40); #endif #endif #ifdef BARO setTaskEnabled(TASK_BARO, sensors(SENSOR_BARO)); #endif #ifdef SONAR setTaskEnabled(TASK_SONAR, sensors(SENSOR_SONAR)); #endif #if defined(BARO) || defined(SONAR) setTaskEnabled(TASK_ALTITUDE, sensors(SENSOR_BARO) || sensors(SENSOR_SONAR)); #endif #ifdef DISPLAY setTaskEnabled(TASK_DISPLAY, feature(FEATURE_DISPLAY)); #endif #ifdef TELEMETRY setTaskEnabled(TASK_TELEMETRY, feature(FEATURE_TELEMETRY)); // Reschedule telemetry to 500hz for Jeti Exbus if (feature(FEATURE_TELEMETRY) || masterConfig.rxConfig.serialrx_provider == SERIALRX_JETIEXBUS) rescheduleTask(TASK_TELEMETRY, 2000); #endif #ifdef LED_STRIP setTaskEnabled(TASK_LEDSTRIP, feature(FEATURE_LED_STRIP)); #endif #ifdef TRANSPONDER setTaskEnabled(TASK_TRANSPONDER, feature(FEATURE_TRANSPONDER)); #endif #ifdef OSD setTaskEnabled(TASK_OSD, feature(FEATURE_OSD)); #endif #ifdef USE_BST setTaskEnabled(TASK_BST_MASTER_PROCESS, true); #endif }
void init(void) { drv_pwm_config_t pwm_params; printfSupportInit(); initEEPROM(); ensureEEPROMContainsValidData(); readEEPROM(); systemState |= SYSTEM_STATE_CONFIG_LOADED; #ifdef STM32F303 // start fpu SCB->CPACR = (0x3 << (10*2)) | (0x3 << (11*2)); #endif #ifdef STM32F303xC SetSysClock(); #endif #ifdef STM32F10X // Configure the System clock frequency, HCLK, PCLK2 and PCLK1 prescalers // Configure the Flash Latency cycles and enable prefetch buffer SetSysClock(systemConfig()->emf_avoidance); #endif i2cSetOverclock(systemConfig()->i2c_highspeed); systemInit(); #ifdef USE_HARDWARE_REVISION_DETECTION detectHardwareRevision(); #endif // Latch active features to be used for feature() in the remainder of init(). latchActiveFeatures(); // initialize IO (needed for all IO operations) IOInitGlobal(); debugMode = debugConfig()->debug_mode; #ifdef USE_EXTI EXTIInit(); #endif #ifdef ALIENFLIGHTF3 if (hardwareRevision == AFF3_REV_1) { ledInit(false); } else { ledInit(true); } #else ledInit(false); #endif #ifdef BEEPER beeperConfig_t beeperConfig = { .gpioPeripheral = BEEP_PERIPHERAL, .gpioPin = BEEP_PIN, .gpioPort = BEEP_GPIO, #ifdef BEEPER_INVERTED .gpioMode = Mode_Out_PP, .isInverted = true #else .gpioMode = Mode_Out_OD, .isInverted = false #endif }; #ifdef NAZE if (hardwareRevision >= NAZE32_REV5) { // naze rev4 and below used opendrain to PNP for buzzer. Rev5 and above use PP to NPN. beeperConfig.gpioMode = Mode_Out_PP; beeperConfig.isInverted = true; } #endif beeperInit(&beeperConfig); #endif #ifdef BUTTONS buttonsInit(); if (!isMPUSoftReset()) { buttonsHandleColdBootButtonPresses(); } #endif #ifdef SPEKTRUM_BIND if (feature(FEATURE_RX_SERIAL)) { switch (rxConfig()->serialrx_provider) { case SERIALRX_SPEKTRUM1024: case SERIALRX_SPEKTRUM2048: // Spektrum satellite binding if enabled on startup. // Must be called before that 100ms sleep so that we don't lose satellite's binding window after startup. // The rest of Spektrum initialization will happen later - via spektrumInit() spektrumBind(rxConfig()); break; } } #endif delay(100); timerInit(); // timer must be initialized before any channel is allocated dmaInit(); serialInit(feature(FEATURE_SOFTSERIAL)); mixerInit(customMotorMixer(0)); #ifdef USE_SERVOS mixerInitServos(customServoMixer(0)); #endif memset(&pwm_params, 0, sizeof(pwm_params)); #ifdef SONAR const sonarHardware_t *sonarHardware = NULL; sonarGPIOConfig_t sonarGPIOConfig; if (feature(FEATURE_SONAR)) { bool usingCurrentMeterIOPins = (feature(FEATURE_AMPERAGE_METER) && batteryConfig()->amperageMeterSource == AMPERAGE_METER_ADC); sonarHardware = sonarGetHardwareConfiguration(usingCurrentMeterIOPins); sonarGPIOConfig.triggerGPIO = sonarHardware->trigger_gpio; sonarGPIOConfig.triggerPin = sonarHardware->trigger_pin; sonarGPIOConfig.echoGPIO = sonarHardware->echo_gpio; sonarGPIOConfig.echoPin = sonarHardware->echo_pin; pwm_params.sonarGPIOConfig = &sonarGPIOConfig; } #endif // when using airplane/wing mixer, servo/motor outputs are remapped if (mixerConfig()->mixerMode == MIXER_AIRPLANE || mixerConfig()->mixerMode == MIXER_FLYING_WING || mixerConfig()->mixerMode == MIXER_CUSTOM_AIRPLANE) pwm_params.airplane = true; else pwm_params.airplane = false; #if defined(USE_UART2) && defined(STM32F10X) pwm_params.useUART2 = doesConfigurationUsePort(SERIAL_PORT_UART2); #endif #if defined(USE_UART3) pwm_params.useUART3 = doesConfigurationUsePort(SERIAL_PORT_UART3); #endif #if defined(USE_UART4) pwm_params.useUART4 = doesConfigurationUsePort(SERIAL_PORT_UART4); #endif #if defined(USE_UART5) pwm_params.useUART5 = doesConfigurationUsePort(SERIAL_PORT_UART5); #endif pwm_params.useVbat = feature(FEATURE_VBAT); pwm_params.useSoftSerial = feature(FEATURE_SOFTSERIAL); pwm_params.useParallelPWM = feature(FEATURE_RX_PARALLEL_PWM); pwm_params.useRSSIADC = feature(FEATURE_RSSI_ADC); pwm_params.useCurrentMeterADC = ( feature(FEATURE_AMPERAGE_METER) && batteryConfig()->amperageMeterSource == AMPERAGE_METER_ADC ); pwm_params.useLEDStrip = feature(FEATURE_LED_STRIP); pwm_params.usePPM = feature(FEATURE_RX_PPM); pwm_params.useSerialRx = feature(FEATURE_RX_SERIAL); #ifdef SONAR pwm_params.useSonar = feature(FEATURE_SONAR); #endif #ifdef USE_SERVOS pwm_params.useServos = isMixerUsingServos(); pwm_params.useChannelForwarding = feature(FEATURE_CHANNEL_FORWARDING); pwm_params.servoCenterPulse = servoConfig()->servoCenterPulse; pwm_params.servoPwmRate = servoConfig()->servo_pwm_rate; #endif pwm_params.useOneshot = feature(FEATURE_ONESHOT125); pwm_params.motorPwmRate = motorConfig()->motor_pwm_rate; pwm_params.idlePulse = calculateMotorOff(); if (pwm_params.motorPwmRate > 500) pwm_params.idlePulse = 0; // brushed motors pwmRxInit(); // pwmInit() needs to be called as soon as possible for ESC compatibility reasons pwmIOConfiguration_t *pwmIOConfiguration = pwmInit(&pwm_params); mixerUsePWMIOConfiguration(pwmIOConfiguration); #ifdef DEBUG_PWM_CONFIGURATION debug[2] = pwmIOConfiguration->pwmInputCount; debug[3] = pwmIOConfiguration->ppmInputCount; #endif if (!feature(FEATURE_ONESHOT125)) motorControlEnable = true; systemState |= SYSTEM_STATE_MOTORS_READY; #ifdef INVERTER initInverter(); #endif #ifdef USE_SPI spiInit(SPI1); spiInit(SPI2); #ifdef STM32F303xC #ifdef ALIENFLIGHTF3 if (hardwareRevision == AFF3_REV_2) { spiInit(SPI3); } #else spiInit(SPI3); #endif #endif #endif #ifdef USE_HARDWARE_REVISION_DETECTION updateHardwareRevision(); #endif #if defined(NAZE) if (hardwareRevision == NAZE32_SP) { serialRemovePort(SERIAL_PORT_SOFTSERIAL2); } else { serialRemovePort(SERIAL_PORT_UART3); } #endif #if defined(SPRACINGF3) && defined(SONAR) && defined(USE_SOFTSERIAL2) if (feature(FEATURE_SONAR) && feature(FEATURE_SOFTSERIAL)) { serialRemovePort(SERIAL_PORT_SOFTSERIAL2); } #endif #if defined(SPRACINGF3MINI) && defined(SONAR) && defined(USE_SOFTSERIAL1) if (feature(FEATURE_SONAR) && feature(FEATURE_SOFTSERIAL)) { serialRemovePort(SERIAL_PORT_SOFTSERIAL1); } #endif #ifdef USE_I2C #if defined(NAZE) if (hardwareRevision != NAZE32_SP) { i2cInit(I2C_DEVICE); } else { if (!doesConfigurationUsePort(SERIAL_PORT_UART3)) { i2cInit(I2C_DEVICE); } } #elif defined(CC3D) if (!doesConfigurationUsePort(SERIAL_PORT_UART3)) { i2cInit(I2C_DEVICE); } #else i2cInit(I2C_DEVICE); #endif #endif #ifdef USE_ADC drv_adc_config_t adc_params; adc_params.channelMask = 0; #ifdef ADC_BATTERY adc_params.channelMask = (feature(FEATURE_VBAT) ? ADC_CHANNEL_MASK(ADC_BATTERY) : 0); #endif #ifdef ADC_RSSI adc_params.channelMask |= (feature(FEATURE_RSSI_ADC) ? ADC_CHANNEL_MASK(ADC_RSSI) : 0); #endif #ifdef ADC_AMPERAGE adc_params.channelMask |= (feature(FEATURE_AMPERAGE_METER) ? ADC_CHANNEL_MASK(ADC_AMPERAGE) : 0); #endif #ifdef ADC_POWER_12V adc_params.channelMask |= ADC_CHANNEL_MASK(ADC_POWER_12V); #endif #ifdef ADC_POWER_5V adc_params.channelMask |= ADC_CHANNEL_MASK(ADC_POWER_5V); #endif #ifdef ADC_POWER_3V adc_params.channelMask |= ADC_CHANNEL_MASK(ADC_POWER_3V); #endif #ifdef NAZE // optional ADC5 input on rev.5 hardware adc_params.channelMask |= (hardwareRevision >= NAZE32_REV5) ? ADC_CHANNEL_MASK(ADC_EXTERNAL) : 0; #endif adcInit(&adc_params); #endif initBoardAlignment(); #ifdef DISPLAY if (feature(FEATURE_DISPLAY)) { displayInit(); } #endif #ifdef NAZE if (hardwareRevision < NAZE32_REV5) { gyroConfig()->gyro_sync = 0; } #endif if (!sensorsAutodetect()) { // if gyro was not detected due to whatever reason, we give up now. failureMode(FAILURE_MISSING_ACC); } systemState |= SYSTEM_STATE_SENSORS_READY; flashLedsAndBeep(); mspInit(); mspSerialInit(); const uint16_t pidPeriodUs = US_FROM_HZ(gyro.sampleFrequencyHz); pidSetTargetLooptime(pidPeriodUs * gyroConfig()->pid_process_denom); pidInitFilters(pidProfile()); #ifdef USE_SERVOS mixerInitialiseServoFiltering(targetPidLooptime); #endif imuInit(); #ifdef USE_CLI cliInit(); #endif failsafeInit(); rxInit(modeActivationProfile()->modeActivationConditions); #ifdef GPS if (feature(FEATURE_GPS)) { gpsInit(); navigationInit(pidProfile()); } #endif #ifdef SONAR if (feature(FEATURE_SONAR)) { sonarInit(sonarHardware); } #endif #ifdef LED_STRIP ledStripInit(); if (feature(FEATURE_LED_STRIP)) { ledStripEnable(); } #endif #ifdef TELEMETRY if (feature(FEATURE_TELEMETRY)) { telemetryInit(); } #endif #ifdef USB_CABLE_DETECTION usbCableDetectInit(); #endif #ifdef TRANSPONDER if (feature(FEATURE_TRANSPONDER)) { transponderInit(transponderConfig()->data); transponderEnable(); transponderStartRepeating(); systemState |= SYSTEM_STATE_TRANSPONDER_ENABLED; } #endif #ifdef USE_FLASHFS #ifdef NAZE if (hardwareRevision == NAZE32_REV5) { m25p16_init(); } #elif defined(USE_FLASH_M25P16) m25p16_init(); #endif flashfsInit(); #endif #ifdef USE_SDCARD bool sdcardUseDMA = false; sdcardInsertionDetectInit(); #ifdef SDCARD_DMA_CHANNEL_TX #if defined(LED_STRIP) && defined(WS2811_DMA_CHANNEL) // Ensure the SPI Tx DMA doesn't overlap with the led strip sdcardUseDMA = !feature(FEATURE_LED_STRIP) || SDCARD_DMA_CHANNEL_TX != WS2811_DMA_CHANNEL; #else sdcardUseDMA = true; #endif #endif sdcard_init(sdcardUseDMA); afatfs_init(); #endif #ifdef BLACKBOX initBlackbox(); #endif if (mixerConfig()->mixerMode == MIXER_GIMBAL) { accSetCalibrationCycles(CALIBRATING_ACC_CYCLES); } gyroSetCalibrationCycles(CALIBRATING_GYRO_CYCLES); #ifdef BARO baroSetCalibrationCycles(CALIBRATING_BARO_CYCLES); #endif // start all timers // TODO - not implemented yet timerStart(); ENABLE_STATE(SMALL_ANGLE); DISABLE_ARMING_FLAG(PREVENT_ARMING); #ifdef SOFTSERIAL_LOOPBACK // FIXME this is a hack, perhaps add a FUNCTION_LOOPBACK to support it properly loopbackPort = (serialPort_t*)&(softSerialPorts[0]); if (!loopbackPort->vTable) { loopbackPort = openSoftSerial(0, NULL, 19200, SERIAL_NOT_INVERTED); } serialPrint(loopbackPort, "LOOPBACK\r\n"); #endif if (feature(FEATURE_VBAT)) { // Now that everything has powered up the voltage and cell count be determined. voltageMeterInit(); batteryInit(); } if (feature(FEATURE_AMPERAGE_METER)) { amperageMeterInit(); } #ifdef DISPLAY if (feature(FEATURE_DISPLAY)) { #ifdef USE_OLED_GPS_DEBUG_PAGE_ONLY displayShowFixedPage(PAGE_GPS); #else displayResetPageCycling(); displayEnablePageCycling(); #endif } #endif #ifdef CJMCU LED2_ON; #endif // Latch active features AGAIN since some may be modified by init(). latchActiveFeatures(); motorControlEnable = true; systemState |= SYSTEM_STATE_READY; } #ifdef SOFTSERIAL_LOOPBACK void processLoopback(void) { if (loopbackPort) { uint8_t bytesWaiting; while ((bytesWaiting = serialRxBytesWaiting(loopbackPort))) { uint8_t b = serialRead(loopbackPort); serialWrite(loopbackPort, b); }; } } #else #define processLoopback() #endif void configureScheduler(void) { schedulerInit(); setTaskEnabled(TASK_SYSTEM, true); uint16_t gyroPeriodUs = US_FROM_HZ(gyro.sampleFrequencyHz); rescheduleTask(TASK_GYRO, gyroPeriodUs); setTaskEnabled(TASK_GYRO, true); rescheduleTask(TASK_PID, gyroPeriodUs); setTaskEnabled(TASK_PID, true); if (sensors(SENSOR_ACC)) { setTaskEnabled(TASK_ACCEL, true); } setTaskEnabled(TASK_ATTITUDE, sensors(SENSOR_ACC)); setTaskEnabled(TASK_SERIAL, true); #ifdef BEEPER setTaskEnabled(TASK_BEEPER, true); #endif setTaskEnabled(TASK_BATTERY, feature(FEATURE_VBAT) || feature(FEATURE_AMPERAGE_METER)); setTaskEnabled(TASK_RX, true); #ifdef GPS setTaskEnabled(TASK_GPS, feature(FEATURE_GPS)); #endif #ifdef MAG setTaskEnabled(TASK_COMPASS, sensors(SENSOR_MAG)); #if defined(MPU6500_SPI_INSTANCE) && defined(USE_MAG_AK8963) // fixme temporary solution for AK6983 via slave I2C on MPU9250 rescheduleTask(TASK_COMPASS, 1000000 / 40); #endif #endif #ifdef BARO setTaskEnabled(TASK_BARO, sensors(SENSOR_BARO)); #endif #ifdef SONAR setTaskEnabled(TASK_SONAR, sensors(SENSOR_SONAR)); #endif #if defined(BARO) || defined(SONAR) setTaskEnabled(TASK_ALTITUDE, sensors(SENSOR_BARO) || sensors(SENSOR_SONAR)); #endif #ifdef DISPLAY setTaskEnabled(TASK_DISPLAY, feature(FEATURE_DISPLAY)); #endif #ifdef TELEMETRY setTaskEnabled(TASK_TELEMETRY, feature(FEATURE_TELEMETRY)); #endif #ifdef LED_STRIP setTaskEnabled(TASK_LEDSTRIP, feature(FEATURE_LED_STRIP)); #endif #ifdef TRANSPONDER setTaskEnabled(TASK_TRANSPONDER, feature(FEATURE_TRANSPONDER)); #endif }
void init(void) { drv_pwm_config_t pwm_params; printfSupportInit(); initEEPROM(); ensureEEPROMContainsValidData(); readEEPROM(); systemState |= SYSTEM_STATE_CONFIG_LOADED; #ifdef STM32F303 // start fpu SCB->CPACR = (0x3 << (10*2)) | (0x3 << (11*2)); #endif #ifdef STM32F303xC SetSysClock(); #endif #ifdef STM32F10X // Configure the System clock frequency, HCLK, PCLK2 and PCLK1 prescalers // Configure the Flash Latency cycles and enable prefetch buffer SetSysClock(masterConfig.emf_avoidance); #endif i2cSetOverclock(masterConfig.i2c_highspeed); #ifdef USE_HARDWARE_REVISION_DETECTION detectHardwareRevision(); #endif systemInit(); // Latch active features to be used for feature() in the remainder of init(). latchActiveFeatures(); ledInit(); #ifdef BEEPER beeperConfig_t beeperConfig = { .gpioPeripheral = BEEP_PERIPHERAL, .gpioPin = BEEP_PIN, .gpioPort = BEEP_GPIO, #ifdef BEEPER_INVERTED .gpioMode = Mode_Out_PP, .isInverted = true #else .gpioMode = Mode_Out_OD, .isInverted = false #endif }; #ifdef NAZE if (hardwareRevision >= NAZE32_REV5) { // naze rev4 and below used opendrain to PNP for buzzer. Rev5 and above use PP to NPN. beeperConfig.gpioMode = Mode_Out_PP; beeperConfig.isInverted = true; } #endif beeperInit(&beeperConfig); #endif #ifdef BUTTONS buttonsInit(); if (!isMPUSoftReset()) { buttonsHandleColdBootButtonPresses(); } #endif #ifdef SPEKTRUM_BIND if (feature(FEATURE_RX_SERIAL)) { switch (masterConfig.rxConfig.serialrx_provider) { case SERIALRX_SPEKTRUM1024: case SERIALRX_SPEKTRUM2048: // Spektrum satellite binding if enabled on startup. // Must be called before that 100ms sleep so that we don't lose satellite's binding window after startup. // The rest of Spektrum initialization will happen later - via spektrumInit() spektrumBind(&masterConfig.rxConfig); break; } } #endif delay(100); timerInit(); // timer must be initialized before any channel is allocated dmaInit(); serialInit(&masterConfig.serialConfig, feature(FEATURE_SOFTSERIAL)); #ifdef USE_SERVOS mixerInit(masterConfig.mixerMode, masterConfig.customMotorMixer, masterConfig.customServoMixer); #else mixerInit(masterConfig.mixerMode, masterConfig.customMotorMixer); #endif memset(&pwm_params, 0, sizeof(pwm_params)); #ifdef SONAR const sonarHardware_t *sonarHardware = NULL; if (feature(FEATURE_SONAR)) { sonarHardware = sonarGetHardwareConfiguration(&masterConfig.batteryConfig); sonarGPIOConfig_t sonarGPIOConfig = { .gpio = SONAR_GPIO, .triggerPin = sonarHardware->echo_pin, .echoPin = sonarHardware->trigger_pin, }; pwm_params.sonarGPIOConfig = &sonarGPIOConfig; } #endif // when using airplane/wing mixer, servo/motor outputs are remapped if (masterConfig.mixerMode == MIXER_AIRPLANE || masterConfig.mixerMode == MIXER_FLYING_WING || masterConfig.mixerMode == MIXER_CUSTOM_AIRPLANE) pwm_params.airplane = true; else pwm_params.airplane = false; #if defined(USE_UART2) && defined(STM32F10X) pwm_params.useUART2 = doesConfigurationUsePort(SERIAL_PORT_UART2); #endif #if defined(USE_UART3) pwm_params.useUART3 = doesConfigurationUsePort(SERIAL_PORT_UART3); #endif #if defined(USE_UART4) pwm_params.useUART4 = doesConfigurationUsePort(SERIAL_PORT_UART4); #endif #if defined(USE_UART5) pwm_params.useUART5 = doesConfigurationUsePort(SERIAL_PORT_UART5); #endif pwm_params.useVbat = feature(FEATURE_VBAT); pwm_params.useSoftSerial = feature(FEATURE_SOFTSERIAL); pwm_params.useParallelPWM = feature(FEATURE_RX_PARALLEL_PWM); pwm_params.useRSSIADC = feature(FEATURE_RSSI_ADC); pwm_params.useCurrentMeterADC = feature(FEATURE_CURRENT_METER) && masterConfig.batteryConfig.currentMeterType == CURRENT_SENSOR_ADC; pwm_params.useLEDStrip = feature(FEATURE_LED_STRIP); pwm_params.usePPM = feature(FEATURE_RX_PPM); pwm_params.useSerialRx = feature(FEATURE_RX_SERIAL); #ifdef SONAR pwm_params.useSonar = feature(FEATURE_SONAR); #endif #ifdef USE_SERVOS pwm_params.useServos = isMixerUsingServos(); pwm_params.useChannelForwarding = feature(FEATURE_CHANNEL_FORWARDING); pwm_params.servoCenterPulse = masterConfig.escAndServoConfig.servoCenterPulse; pwm_params.servoPwmRate = masterConfig.servo_pwm_rate; #endif pwm_params.useOneshot = feature(FEATURE_ONESHOT125); pwm_params.motorPwmRate = masterConfig.motor_pwm_rate; pwm_params.idlePulse = masterConfig.escAndServoConfig.mincommand; if (feature(FEATURE_3D)) pwm_params.idlePulse = masterConfig.flight3DConfig.neutral3d; if (pwm_params.motorPwmRate > 500) pwm_params.idlePulse = 0; // brushed motors pwmRxInit(masterConfig.inputFilteringMode); // pwmInit() needs to be called as soon as possible for ESC compatibility reasons pwmIOConfiguration_t *pwmIOConfiguration = pwmInit(&pwm_params); mixerUsePWMIOConfiguration(pwmIOConfiguration); debug[2] = pwmIOConfiguration->pwmInputCount; debug[3] = pwmIOConfiguration->ppmInputCount; if (!feature(FEATURE_ONESHOT125)) motorControlEnable = true; systemState |= SYSTEM_STATE_MOTORS_READY; #ifdef INVERTER initInverter(); #endif #ifdef USE_SPI spiInit(SPI1); spiInit(SPI2); #endif #ifdef USE_HARDWARE_REVISION_DETECTION updateHardwareRevision(); #endif #if defined(NAZE) if (hardwareRevision == NAZE32_SP) { serialRemovePort(SERIAL_PORT_SOFTSERIAL2); } else { serialRemovePort(SERIAL_PORT_UART3); } #endif #if defined(SPRACINGF3) && defined(SONAR) && defined(USE_SOFTSERIAL2) if (feature(FEATURE_SONAR) && feature(FEATURE_SOFTSERIAL)) { serialRemovePort(SERIAL_PORT_SOFTSERIAL2); } #endif #if defined(SPRACINGF3MINI) && defined(SONAR) && defined(USE_SOFTSERIAL1) if (feature(FEATURE_SONAR) && feature(FEATURE_SOFTSERIAL)) { serialRemovePort(SERIAL_PORT_SOFTSERIAL1); } #endif #ifdef USE_I2C #if defined(NAZE) if (hardwareRevision != NAZE32_SP) { i2cInit(I2C_DEVICE); } else { if (!doesConfigurationUsePort(SERIAL_PORT_UART3)) { i2cInit(I2C_DEVICE); } } #elif defined(CC3D) if (!doesConfigurationUsePort(SERIAL_PORT_UART3)) { i2cInit(I2C_DEVICE); } #else i2cInit(I2C_DEVICE); #endif #endif #ifdef USE_ADC drv_adc_config_t adc_params; adc_params.enableVBat = feature(FEATURE_VBAT); adc_params.enableRSSI = feature(FEATURE_RSSI_ADC); adc_params.enableCurrentMeter = feature(FEATURE_CURRENT_METER); adc_params.enableExternal1 = false; #ifdef OLIMEXINO adc_params.enableExternal1 = true; #endif #ifdef NAZE // optional ADC5 input on rev.5 hardware adc_params.enableExternal1 = (hardwareRevision >= NAZE32_REV5); #endif adcInit(&adc_params); #endif initBoardAlignment(&masterConfig.boardAlignment); #ifdef DISPLAY if (feature(FEATURE_DISPLAY)) { displayInit(&masterConfig.rxConfig); } #endif if (!sensorsAutodetect(&masterConfig.sensorAlignmentConfig, masterConfig.gyro_lpf, masterConfig.acc_hardware, masterConfig.mag_hardware, masterConfig.baro_hardware, currentProfile->mag_declination, masterConfig.looptime, masterConfig.gyroSync, masterConfig.gyroSyncDenominator)) { // if gyro was not detected due to whatever reason, we give up now. failureMode(FAILURE_MISSING_ACC); } systemState |= SYSTEM_STATE_SENSORS_READY; flashLedsAndBeep(); #ifdef USE_SERVOS mixerInitialiseServoFiltering(targetLooptime); #endif #ifdef MAG if (sensors(SENSOR_MAG)) compassInit(); #endif imuInit(); mspInit(&masterConfig.serialConfig); #ifdef USE_CLI cliInit(&masterConfig.serialConfig); #endif failsafeInit(&masterConfig.rxConfig, masterConfig.flight3DConfig.deadband3d_throttle); rxInit(&masterConfig.rxConfig, currentProfile->modeActivationConditions); #ifdef GPS if (feature(FEATURE_GPS)) { gpsInit( &masterConfig.serialConfig, &masterConfig.gpsConfig ); navigationInit( ¤tProfile->gpsProfile, ¤tProfile->pidProfile ); } #endif #ifdef SONAR if (feature(FEATURE_SONAR)) { sonarInit(sonarHardware); } #endif #ifdef LED_STRIP ledStripInit(masterConfig.ledConfigs, masterConfig.colors); if (feature(FEATURE_LED_STRIP)) { ledStripEnable(); } #endif #ifdef TELEMETRY if (feature(FEATURE_TELEMETRY)) { telemetryInit(); } #endif #ifdef USB_CABLE_DETECTION usbCableDetectInit(); #endif #ifdef TRANSPONDER if (feature(FEATURE_TRANSPONDER)) { transponderInit(masterConfig.transponderData); transponderEnable(); transponderStartRepeating(); systemState |= SYSTEM_STATE_TRANSPONDER_ENABLED; } #endif #ifdef USE_FLASHFS #ifdef NAZE if (hardwareRevision == NAZE32_REV5) { m25p16_init(); } #elif defined(USE_FLASH_M25P16) m25p16_init(); #endif flashfsInit(); #endif #ifdef USE_SDCARD bool sdcardUseDMA = false; sdcardInsertionDetectInit(); #ifdef SDCARD_DMA_CHANNEL_TX #if defined(LED_STRIP) && defined(WS2811_DMA_CHANNEL) // Ensure the SPI Tx DMA doesn't overlap with the led strip sdcardUseDMA = !feature(FEATURE_LED_STRIP) || SDCARD_DMA_CHANNEL_TX != WS2811_DMA_CHANNEL; #else sdcardUseDMA = true; #endif #endif sdcard_init(sdcardUseDMA); afatfs_init(); #endif #ifdef BLACKBOX initBlackbox(); #endif if (masterConfig.mixerMode == MIXER_GIMBAL) { accSetCalibrationCycles(CALIBRATING_ACC_CYCLES); } gyroSetCalibrationCycles(CALIBRATING_GYRO_CYCLES); #ifdef BARO baroSetCalibrationCycles(CALIBRATING_BARO_CYCLES); #endif // start all timers // TODO - not implemented yet timerStart(); ENABLE_STATE(SMALL_ANGLE); DISABLE_ARMING_FLAG(PREVENT_ARMING); #ifdef SOFTSERIAL_LOOPBACK // FIXME this is a hack, perhaps add a FUNCTION_LOOPBACK to support it properly loopbackPort = (serialPort_t*)&(softSerialPorts[0]); if (!loopbackPort->vTable) { loopbackPort = openSoftSerial(0, NULL, 19200, SERIAL_NOT_INVERTED); } serialPrint(loopbackPort, "LOOPBACK\r\n"); #endif // Now that everything has powered up the voltage and cell count be determined. if (feature(FEATURE_VBAT | FEATURE_CURRENT_METER)) batteryInit(&masterConfig.batteryConfig); #ifdef DISPLAY if (feature(FEATURE_DISPLAY)) { #ifdef USE_OLED_GPS_DEBUG_PAGE_ONLY displayShowFixedPage(PAGE_GPS); #else displayResetPageCycling(); displayEnablePageCycling(); #endif } #endif #ifdef CJMCU LED2_ON; #endif // Latch active features AGAIN since some may be modified by init(). latchActiveFeatures(); motorControlEnable = true; systemState |= SYSTEM_STATE_READY; } #ifdef SOFTSERIAL_LOOPBACK void processLoopback(void) { if (loopbackPort) { uint8_t bytesWaiting; while ((bytesWaiting = serialRxBytesWaiting(loopbackPort))) { uint8_t b = serialRead(loopbackPort); serialWrite(loopbackPort, b); }; } } #else #define processLoopback() #endif int main(void) { init(); /* Setup scheduler */ if (masterConfig.gyroSync) { rescheduleTask(TASK_GYROPID, targetLooptime - INTERRUPT_WAIT_TIME); } else { rescheduleTask(TASK_GYROPID, targetLooptime); } setTaskEnabled(TASK_GYROPID, true); setTaskEnabled(TASK_ACCEL, sensors(SENSOR_ACC)); setTaskEnabled(TASK_SERIAL, true); #ifdef BEEPER setTaskEnabled(TASK_BEEPER, true); #endif setTaskEnabled(TASK_BATTERY, feature(FEATURE_VBAT) || feature(FEATURE_CURRENT_METER)); setTaskEnabled(TASK_RX, true); #ifdef GPS setTaskEnabled(TASK_GPS, feature(FEATURE_GPS)); #endif #ifdef MAG setTaskEnabled(TASK_COMPASS, sensors(SENSOR_MAG)); #endif #ifdef BARO setTaskEnabled(TASK_BARO, sensors(SENSOR_BARO)); #endif #ifdef SONAR setTaskEnabled(TASK_SONAR, sensors(SENSOR_SONAR)); #endif #if defined(BARO) || defined(SONAR) setTaskEnabled(TASK_ALTITUDE, sensors(SENSOR_BARO) || sensors(SENSOR_SONAR)); #endif #ifdef DISPLAY setTaskEnabled(TASK_DISPLAY, feature(FEATURE_DISPLAY)); #endif #ifdef TELEMETRY setTaskEnabled(TASK_TELEMETRY, feature(FEATURE_TELEMETRY)); #endif #ifdef LED_STRIP setTaskEnabled(TASK_LEDSTRIP, feature(FEATURE_LED_STRIP)); #endif #ifdef TRANSPONDER setTaskEnabled(TASK_TRANSPONDER, feature(FEATURE_TRANSPONDER)); #endif while (1) { scheduler(); processLoopback(); } } void HardFault_Handler(void) { // fall out of the sky uint8_t requiredStateForMotors = SYSTEM_STATE_CONFIG_LOADED | SYSTEM_STATE_MOTORS_READY; if ((systemState & requiredStateForMotors) == requiredStateForMotors) { stopMotors(); } #ifdef TRANSPONDER // prevent IR LEDs from burning out. uint8_t requiredStateForTransponder = SYSTEM_STATE_CONFIG_LOADED | SYSTEM_STATE_TRANSPONDER_ENABLED; if ((systemState & requiredStateForTransponder) == requiredStateForTransponder) { transponderIrDisable(); } #endif while (1); }
void init(void) { printfSupportInit(); initEEPROM(); ensureEEPROMContainsValidData(); readEEPROM(); systemState |= SYSTEM_STATE_CONFIG_LOADED; // initialize IO (needed for all IO operations) IOInitGlobal(); #ifdef STM32F303 // start fpu SCB->CPACR = (0x3 << (10*2)) | (0x3 << (11*2)); #endif #ifdef STM32F303xC SetSysClock(); #endif #ifdef STM32F10X // Configure the System clock frequency, HCLK, PCLK2 and PCLK1 prescalers // Configure the Flash Latency cycles and enable prefetch buffer SetSysClock(masterConfig.emf_avoidance); #endif i2cSetOverclock(masterConfig.i2c_overclock); #ifdef USE_HARDWARE_REVISION_DETECTION detectHardwareRevision(); #endif systemInit(); // Latch active features to be used for feature() in the remainder of init(). latchActiveFeatures(); #ifdef ALIENFLIGHTF3 ledInit(hardwareRevision == AFF3_REV_1 ? false : true); #else ledInit(false); #endif #ifdef SPEKTRUM_BIND if (feature(FEATURE_RX_SERIAL)) { switch (masterConfig.rxConfig.serialrx_provider) { case SERIALRX_SPEKTRUM1024: case SERIALRX_SPEKTRUM2048: // Spektrum satellite binding if enabled on startup. // Must be called before that 100ms sleep so that we don't lose satellite's binding window after startup. // The rest of Spektrum initialization will happen later - via spektrumInit() spektrumBind(&masterConfig.rxConfig); break; } } #endif delay(500); timerInit(); // timer must be initialized before any channel is allocated serialInit(&masterConfig.serialConfig, feature(FEATURE_SOFTSERIAL)); #ifdef USE_SERVOS mixerInit(masterConfig.mixerMode, masterConfig.customMotorMixer, masterConfig.customServoMixer); #else mixerInit(masterConfig.mixerMode, masterConfig.customMotorMixer); #endif drv_pwm_config_t pwm_params; memset(&pwm_params, 0, sizeof(pwm_params)); #ifdef SONAR if (feature(FEATURE_SONAR)) { const sonarHcsr04Hardware_t *sonarHardware = sonarGetHardwareConfiguration(masterConfig.batteryConfig.currentMeterType); if (sonarHardware) { pwm_params.useSonar = true; pwm_params.sonarIOConfig.triggerTag = sonarHardware->triggerTag; pwm_params.sonarIOConfig.echoTag = sonarHardware->echoTag; } } #endif // when using airplane/wing mixer, servo/motor outputs are remapped if (masterConfig.mixerMode == MIXER_AIRPLANE || masterConfig.mixerMode == MIXER_FLYING_WING || masterConfig.mixerMode == MIXER_CUSTOM_AIRPLANE) pwm_params.airplane = true; else pwm_params.airplane = false; #if defined(USE_USART2) && defined(STM32F10X) pwm_params.useUART2 = doesConfigurationUsePort(SERIAL_PORT_USART2); #endif #ifdef STM32F303xC pwm_params.useUART3 = doesConfigurationUsePort(SERIAL_PORT_USART3); #endif pwm_params.useVbat = feature(FEATURE_VBAT); pwm_params.useSoftSerial = feature(FEATURE_SOFTSERIAL); pwm_params.useParallelPWM = feature(FEATURE_RX_PARALLEL_PWM); pwm_params.useRSSIADC = feature(FEATURE_RSSI_ADC); pwm_params.useCurrentMeterADC = feature(FEATURE_CURRENT_METER) && masterConfig.batteryConfig.currentMeterType == CURRENT_SENSOR_ADC; pwm_params.useLEDStrip = feature(FEATURE_LED_STRIP); pwm_params.usePPM = feature(FEATURE_RX_PPM); pwm_params.useSerialRx = feature(FEATURE_RX_SERIAL); #ifdef USE_SERVOS pwm_params.useServos = isServoOutputEnabled(); pwm_params.useChannelForwarding = feature(FEATURE_CHANNEL_FORWARDING); pwm_params.servoCenterPulse = masterConfig.escAndServoConfig.servoCenterPulse; pwm_params.servoPwmRate = masterConfig.servo_pwm_rate; #endif pwm_params.useOneshot = feature(FEATURE_ONESHOT125); pwm_params.motorPwmRate = masterConfig.motor_pwm_rate; pwm_params.idlePulse = masterConfig.escAndServoConfig.mincommand; if (feature(FEATURE_3D)) pwm_params.idlePulse = masterConfig.flight3DConfig.neutral3d; if (pwm_params.motorPwmRate > 500) pwm_params.idlePulse = 0; // brushed motors #ifndef SKIP_RX_PWM_PPM pwmRxInit(masterConfig.inputFilteringMode); #endif // pwmInit() needs to be called as soon as possible for ESC compatibility reasons pwmInit(&pwm_params); mixerUsePWMIOConfiguration(); if (!feature(FEATURE_ONESHOT125)) motorControlEnable = true; systemState |= SYSTEM_STATE_MOTORS_READY; #ifdef BEEPER beeperConfig_t beeperConfig = { .ioTag = IO_TAG(BEEPER), #ifdef BEEPER_INVERTED .isOD = false, .isInverted = true #else .isOD = true, .isInverted = false #endif }; #ifdef NAZE if (hardwareRevision >= NAZE32_REV5) { // naze rev4 and below used opendrain to PNP for buzzer. Rev5 and above use PP to NPN. beeperConfig.isOD = false; beeperConfig.isInverted = true; } #endif beeperInit(&beeperConfig); #endif #ifdef INVERTER initInverter(); #endif #ifdef USE_SPI spiInit(SPI1); spiInit(SPI2); #endif #ifdef USE_HARDWARE_REVISION_DETECTION updateHardwareRevision(); #endif #if defined(NAZE) if (hardwareRevision == NAZE32_SP) { serialRemovePort(SERIAL_PORT_SOFTSERIAL2); } else { serialRemovePort(SERIAL_PORT_USART3); } #endif #if defined(SPRACINGF3) && defined(SONAR) && defined(USE_SOFTSERIAL2) if (feature(FEATURE_SONAR) && feature(FEATURE_SOFTSERIAL)) { serialRemovePort(SERIAL_PORT_SOFTSERIAL2); } #endif #if defined(FURYF3) && defined(SONAR) && defined(USE_SOFTSERIAL1) if (feature(FEATURE_SONAR) && feature(FEATURE_SOFTSERIAL)) { serialRemovePort(SERIAL_PORT_SOFTSERIAL1); } #endif #ifdef USE_I2C #if defined(NAZE) if (hardwareRevision != NAZE32_SP) { i2cInit(I2C_DEVICE); } else { if (!doesConfigurationUsePort(SERIAL_PORT_USART3)) { i2cInit(I2C_DEVICE); } } #elif defined(CC3D) if (!doesConfigurationUsePort(SERIAL_PORT_USART3)) { i2cInit(I2C_DEVICE); } #else i2cInit(I2C_DEVICE); #endif #endif #ifdef USE_ADC drv_adc_config_t adc_params; adc_params.enableVBat = feature(FEATURE_VBAT); adc_params.enableRSSI = feature(FEATURE_RSSI_ADC); adc_params.enableCurrentMeter = feature(FEATURE_CURRENT_METER); adc_params.enableExternal1 = false; #ifdef OLIMEXINO adc_params.enableExternal1 = true; #endif #ifdef NAZE // optional ADC5 input on rev.5 hardware adc_params.enableExternal1 = (hardwareRevision >= NAZE32_REV5); #endif adcInit(&adc_params); #endif initBoardAlignment(&masterConfig.boardAlignment); #ifdef DISPLAY if (feature(FEATURE_DISPLAY)) { displayInit(&masterConfig.rxConfig); } #endif #ifdef GPS if (feature(FEATURE_GPS)) { gpsPreInit(&masterConfig.gpsConfig); } #endif // Set gyro sampling rate divider before initialization gyroSetSampleRate(masterConfig.looptime, masterConfig.gyro_lpf, masterConfig.gyroSync, masterConfig.gyroSyncDenominator); if (!sensorsAutodetect(&masterConfig.sensorAlignmentConfig, masterConfig.gyro_lpf, masterConfig.acc_hardware, masterConfig.mag_hardware, masterConfig.baro_hardware, currentProfile->mag_declination)) { // if gyro was not detected due to whatever reason, we give up now. failureMode(FAILURE_MISSING_ACC); } systemState |= SYSTEM_STATE_SENSORS_READY; LED1_ON; LED0_OFF; for (int i = 0; i < 10; i++) { LED1_TOGGLE; LED0_TOGGLE; delay(25); BEEP_ON; delay(25); BEEP_OFF; } LED0_OFF; LED1_OFF; #ifdef MAG if (sensors(SENSOR_MAG)) compassInit(); #endif imuInit(); mspInit(&masterConfig.serialConfig); #ifdef USE_CLI cliInit(&masterConfig.serialConfig); #endif failsafeInit(&masterConfig.rxConfig, masterConfig.flight3DConfig.deadband3d_throttle); rxInit(&masterConfig.rxConfig, currentProfile->modeActivationConditions); #ifdef GPS if (feature(FEATURE_GPS)) { gpsInit( &masterConfig.serialConfig, &masterConfig.gpsConfig ); } #endif #ifdef NAV navigationInit( &masterConfig.navConfig, ¤tProfile->pidProfile, ¤tProfile->rcControlsConfig, &masterConfig.rxConfig, &masterConfig.flight3DConfig, &masterConfig.escAndServoConfig ); #endif #ifdef LED_STRIP ledStripInit(masterConfig.ledConfigs, masterConfig.colors, masterConfig.modeColors, &masterConfig.specialColors); if (feature(FEATURE_LED_STRIP)) { ledStripEnable(); } #endif #ifdef TELEMETRY if (feature(FEATURE_TELEMETRY)) { telemetryInit(); } #endif #ifdef USE_FLASHFS #ifdef NAZE if (hardwareRevision == NAZE32_REV5) { m25p16_init(); } #elif defined(USE_FLASH_M25P16) m25p16_init(); #endif flashfsInit(); #endif #ifdef USE_SDCARD bool sdcardUseDMA = false; sdcardInsertionDetectInit(); #ifdef SDCARD_DMA_CHANNEL_TX #if defined(LED_STRIP) && defined(WS2811_DMA_CHANNEL) // Ensure the SPI Tx DMA doesn't overlap with the led strip sdcardUseDMA = !feature(FEATURE_LED_STRIP) || SDCARD_DMA_CHANNEL_TX != WS2811_DMA_CHANNEL; #else sdcardUseDMA = true; #endif #endif sdcard_init(sdcardUseDMA); afatfs_init(); #endif #ifdef BLACKBOX initBlackbox(); #endif gyroSetCalibrationCycles(CALIBRATING_GYRO_CYCLES); #ifdef BARO baroSetCalibrationCycles(CALIBRATING_BARO_CYCLES); #endif // start all timers // TODO - not implemented yet timerStart(); ENABLE_STATE(SMALL_ANGLE); DISABLE_ARMING_FLAG(PREVENT_ARMING); #ifdef SOFTSERIAL_LOOPBACK // FIXME this is a hack, perhaps add a FUNCTION_LOOPBACK to support it properly loopbackPort = (serialPort_t*)&(softSerialPorts[0]); if (!loopbackPort->vTable) { loopbackPort = openSoftSerial(0, NULL, 19200, SERIAL_NOT_INVERTED); } serialPrint(loopbackPort, "LOOPBACK\r\n"); #endif // Now that everything has powered up the voltage and cell count be determined. if (feature(FEATURE_VBAT | FEATURE_CURRENT_METER)) batteryInit(&masterConfig.batteryConfig); #ifdef CJMCU LED2_ON; #endif // Latch active features AGAIN since some may be modified by init(). latchActiveFeatures(); motorControlEnable = true; systemState |= SYSTEM_STATE_READY; } #ifdef SOFTSERIAL_LOOPBACK void processLoopback(void) { if (loopbackPort) { uint8_t bytesWaiting; while ((bytesWaiting = serialRxBytesWaiting(loopbackPort))) { uint8_t b = serialRead(loopbackPort); serialWrite(loopbackPort, b); }; } } #else #define processLoopback() #endif int main(void) { init(); /* Setup scheduler */ schedulerInit(); rescheduleTask(TASK_GYROPID, targetLooptime); setTaskEnabled(TASK_GYROPID, true); setTaskEnabled(TASK_SERIAL, true); #ifdef BEEPER setTaskEnabled(TASK_BEEPER, true); #endif setTaskEnabled(TASK_BATTERY, feature(FEATURE_VBAT) || feature(FEATURE_CURRENT_METER)); setTaskEnabled(TASK_RX, true); #ifdef GPS setTaskEnabled(TASK_GPS, feature(FEATURE_GPS)); #endif #ifdef MAG setTaskEnabled(TASK_COMPASS, sensors(SENSOR_MAG)); #if defined(MPU6500_SPI_INSTANCE) && defined(USE_MAG_AK8963) // fixme temporary solution for AK6983 via slave I2C on MPU9250 rescheduleTask(TASK_COMPASS, 1000000 / 40); #endif #endif #ifdef BARO setTaskEnabled(TASK_BARO, sensors(SENSOR_BARO)); #endif #ifdef SONAR setTaskEnabled(TASK_SONAR, sensors(SENSOR_SONAR)); #endif #ifdef DISPLAY setTaskEnabled(TASK_DISPLAY, feature(FEATURE_DISPLAY)); #endif #ifdef TELEMETRY setTaskEnabled(TASK_TELEMETRY, feature(FEATURE_TELEMETRY)); #endif #ifdef LED_STRIP setTaskEnabled(TASK_LEDSTRIP, feature(FEATURE_LED_STRIP)); #endif while (true) { scheduler(); processLoopback(); } }
/* * processRx called from taskUpdateRxMain */ bool processRx(timeUs_t currentTimeUs) { static bool armedBeeperOn = false; if (!calculateRxChannelsAndUpdateFailsafe(currentTimeUs)) { return false; } // in 3D mode, we need to be able to disarm by switch at any time if (feature(FEATURE_3D)) { if (!IS_RC_MODE_ACTIVE(BOXARM)) disarm(); } updateRSSI(currentTimeUs); if (currentTimeUs > FAILSAFE_POWER_ON_DELAY_US && !failsafeIsMonitoring()) { failsafeStartMonitoring(); } failsafeUpdateState(); const throttleStatus_e throttleStatus = calculateThrottleStatus(); const uint8_t throttlePercent = calculateThrottlePercent(); if (isAirmodeActive() && ARMING_FLAG(ARMED)) { if (throttlePercent >= rxConfig()->airModeActivateThreshold) { airmodeIsActivated = true; // Prevent Iterm from being reset } } else { airmodeIsActivated = false; } /* In airmode Iterm should be prevented to grow when Low thottle and Roll + Pitch Centered. This is needed to prevent Iterm winding on the ground, but keep full stabilisation on 0 throttle while in air */ if (throttleStatus == THROTTLE_LOW && !airmodeIsActivated) { pidResetITerm(); if (currentPidProfile->pidAtMinThrottle) pidStabilisationState(PID_STABILISATION_ON); else pidStabilisationState(PID_STABILISATION_OFF); } else { pidStabilisationState(PID_STABILISATION_ON); } #ifdef USE_RUNAWAY_TAKEOFF // If runaway_takeoff_prevention is enabled, accumulate the amount of time that throttle // is above runaway_takeoff_deactivate_throttle with the any of the R/P/Y sticks deflected // to at least runaway_takeoff_stick_percent percent while the pidSum on all axis is kept low. // Once the amount of accumulated time exceeds runaway_takeoff_deactivate_delay then disable // prevention for the remainder of the battery. if (ARMING_FLAG(ARMED) && pidConfig()->runaway_takeoff_prevention && !runawayTakeoffCheckDisabled && !flipOverAfterCrashMode && !runawayTakeoffTemporarilyDisabled && !STATE(FIXED_WING)) { // Determine if we're in "flight" // - motors running // - throttle over runaway_takeoff_deactivate_throttle_percent // - sticks are active and have deflection greater than runaway_takeoff_deactivate_stick_percent // - pidSum on all axis is less then runaway_takeoff_deactivate_pidlimit bool inStableFlight = false; if (!feature(FEATURE_MOTOR_STOP) || isAirmodeActive() || (throttleStatus != THROTTLE_LOW)) { // are motors running? const uint8_t lowThrottleLimit = pidConfig()->runaway_takeoff_deactivate_throttle; const uint8_t midThrottleLimit = constrain(lowThrottleLimit * 2, lowThrottleLimit * 2, RUNAWAY_TAKEOFF_HIGH_THROTTLE_PERCENT); if ((((throttlePercent >= lowThrottleLimit) && areSticksActive(RUNAWAY_TAKEOFF_DEACTIVATE_STICK_PERCENT)) || (throttlePercent >= midThrottleLimit)) && (fabsf(pidData[FD_PITCH].Sum) < RUNAWAY_TAKEOFF_DEACTIVATE_PIDSUM_LIMIT) && (fabsf(pidData[FD_ROLL].Sum) < RUNAWAY_TAKEOFF_DEACTIVATE_PIDSUM_LIMIT) && (fabsf(pidData[FD_YAW].Sum) < RUNAWAY_TAKEOFF_DEACTIVATE_PIDSUM_LIMIT)) { inStableFlight = true; if (runawayTakeoffDeactivateUs == 0) { runawayTakeoffDeactivateUs = currentTimeUs; } } } // If we're in flight, then accumulate the time and deactivate once it exceeds runaway_takeoff_deactivate_delay milliseconds if (inStableFlight) { if (runawayTakeoffDeactivateUs == 0) { runawayTakeoffDeactivateUs = currentTimeUs; } uint16_t deactivateDelay = pidConfig()->runaway_takeoff_deactivate_delay; // at high throttle levels reduce deactivation delay by 50% if (throttlePercent >= RUNAWAY_TAKEOFF_HIGH_THROTTLE_PERCENT) { deactivateDelay = deactivateDelay / 2; } if ((cmpTimeUs(currentTimeUs, runawayTakeoffDeactivateUs) + runawayTakeoffAccumulatedUs) > deactivateDelay * 1000) { runawayTakeoffCheckDisabled = true; } } else { if (runawayTakeoffDeactivateUs != 0) { runawayTakeoffAccumulatedUs += cmpTimeUs(currentTimeUs, runawayTakeoffDeactivateUs); } runawayTakeoffDeactivateUs = 0; } if (runawayTakeoffDeactivateUs == 0) { DEBUG_SET(DEBUG_RUNAWAY_TAKEOFF, DEBUG_RUNAWAY_TAKEOFF_DEACTIVATING_DELAY, DEBUG_RUNAWAY_TAKEOFF_FALSE); DEBUG_SET(DEBUG_RUNAWAY_TAKEOFF, DEBUG_RUNAWAY_TAKEOFF_DEACTIVATING_TIME, runawayTakeoffAccumulatedUs / 1000); } else { DEBUG_SET(DEBUG_RUNAWAY_TAKEOFF, DEBUG_RUNAWAY_TAKEOFF_DEACTIVATING_DELAY, DEBUG_RUNAWAY_TAKEOFF_TRUE); DEBUG_SET(DEBUG_RUNAWAY_TAKEOFF, DEBUG_RUNAWAY_TAKEOFF_DEACTIVATING_TIME, (cmpTimeUs(currentTimeUs, runawayTakeoffDeactivateUs) + runawayTakeoffAccumulatedUs) / 1000); } } else { DEBUG_SET(DEBUG_RUNAWAY_TAKEOFF, DEBUG_RUNAWAY_TAKEOFF_DEACTIVATING_DELAY, DEBUG_RUNAWAY_TAKEOFF_FALSE); DEBUG_SET(DEBUG_RUNAWAY_TAKEOFF, DEBUG_RUNAWAY_TAKEOFF_DEACTIVATING_TIME, DEBUG_RUNAWAY_TAKEOFF_FALSE); } #endif // When armed and motors aren't spinning, do beeps and then disarm // board after delay so users without buzzer won't lose fingers. // mixTable constrains motor commands, so checking throttleStatus is enough if (ARMING_FLAG(ARMED) && feature(FEATURE_MOTOR_STOP) && !STATE(FIXED_WING) && !feature(FEATURE_3D) && !isAirmodeActive() ) { if (isUsingSticksForArming()) { if (throttleStatus == THROTTLE_LOW) { if (armingConfig()->auto_disarm_delay != 0 && (int32_t)(disarmAt - millis()) < 0 ) { // auto-disarm configured and delay is over disarm(); armedBeeperOn = false; } else { // still armed; do warning beeps while armed beeper(BEEPER_ARMED); armedBeeperOn = true; } } else { // throttle is not low if (armingConfig()->auto_disarm_delay != 0) { // extend disarm time disarmAt = millis() + armingConfig()->auto_disarm_delay * 1000; } if (armedBeeperOn) { beeperSilence(); armedBeeperOn = false; } } } else { // arming is via AUX switch; beep while throttle low if (throttleStatus == THROTTLE_LOW) { beeper(BEEPER_ARMED); armedBeeperOn = true; } else if (armedBeeperOn) { beeperSilence(); armedBeeperOn = false; } } } processRcStickPositions(); if (feature(FEATURE_INFLIGHT_ACC_CAL)) { updateInflightCalibrationState(); } updateActivatedModes(); #ifdef USE_DSHOT /* Enable beep warning when the crash flip mode is active */ if (isMotorProtocolDshot() && isModeActivationConditionPresent(BOXFLIPOVERAFTERCRASH) && IS_RC_MODE_ACTIVE(BOXFLIPOVERAFTERCRASH)) { beeper(BEEPER_CRASH_FLIP_MODE); } #endif if (!cliMode) { updateAdjustmentStates(); processRcAdjustments(currentControlRateProfile); } bool canUseHorizonMode = true; if ((IS_RC_MODE_ACTIVE(BOXANGLE) || failsafeIsActive()) && (sensors(SENSOR_ACC))) { // bumpless transfer to Level mode canUseHorizonMode = false; if (!FLIGHT_MODE(ANGLE_MODE)) { ENABLE_FLIGHT_MODE(ANGLE_MODE); } } else { DISABLE_FLIGHT_MODE(ANGLE_MODE); // failsafe support } if (IS_RC_MODE_ACTIVE(BOXHORIZON) && canUseHorizonMode) { DISABLE_FLIGHT_MODE(ANGLE_MODE); if (!FLIGHT_MODE(HORIZON_MODE)) { ENABLE_FLIGHT_MODE(HORIZON_MODE); } } else { DISABLE_FLIGHT_MODE(HORIZON_MODE); } #ifdef USE_GPS_RESCUE if (IS_RC_MODE_ACTIVE(BOXGPSRESCUE) || (failsafeIsActive() && failsafeConfig()->failsafe_procedure == FAILSAFE_PROCEDURE_GPS_RESCUE)) { if (!FLIGHT_MODE(GPS_RESCUE_MODE)) { ENABLE_FLIGHT_MODE(GPS_RESCUE_MODE); } } else { DISABLE_FLIGHT_MODE(GPS_RESCUE_MODE); } #endif if (FLIGHT_MODE(ANGLE_MODE) || FLIGHT_MODE(HORIZON_MODE)) { LED1_ON; // increase frequency of attitude task to reduce drift when in angle or horizon mode rescheduleTask(TASK_ATTITUDE, TASK_PERIOD_HZ(500)); } else { LED1_OFF; rescheduleTask(TASK_ATTITUDE, TASK_PERIOD_HZ(100)); } if (!IS_RC_MODE_ACTIVE(BOXPREARM) && ARMING_FLAG(WAS_ARMED_WITH_PREARM)) { DISABLE_ARMING_FLAG(WAS_ARMED_WITH_PREARM); } #if defined(USE_ACC) || defined(USE_MAG) if (sensors(SENSOR_ACC) || sensors(SENSOR_MAG)) { #if defined(USE_GPS) || defined(USE_MAG) if (IS_RC_MODE_ACTIVE(BOXMAG)) { if (!FLIGHT_MODE(MAG_MODE)) { ENABLE_FLIGHT_MODE(MAG_MODE); magHold = DECIDEGREES_TO_DEGREES(attitude.values.yaw); } } else { DISABLE_FLIGHT_MODE(MAG_MODE); } #endif if (IS_RC_MODE_ACTIVE(BOXHEADFREE)) { if (!FLIGHT_MODE(HEADFREE_MODE)) { ENABLE_FLIGHT_MODE(HEADFREE_MODE); } } else { DISABLE_FLIGHT_MODE(HEADFREE_MODE); } if (IS_RC_MODE_ACTIVE(BOXHEADADJ)) { if (imuQuaternionHeadfreeOffsetSet()){ beeper(BEEPER_RX_SET); } } } #endif if (IS_RC_MODE_ACTIVE(BOXPASSTHRU)) { ENABLE_FLIGHT_MODE(PASSTHRU_MODE); } else { DISABLE_FLIGHT_MODE(PASSTHRU_MODE); } if (mixerConfig()->mixerMode == MIXER_FLYING_WING || mixerConfig()->mixerMode == MIXER_AIRPLANE) { DISABLE_FLIGHT_MODE(HEADFREE_MODE); } #ifdef USE_TELEMETRY static bool sharedPortTelemetryEnabled = false; if (feature(FEATURE_TELEMETRY)) { bool enableSharedPortTelemetry = (!isModeActivationConditionPresent(BOXTELEMETRY) && ARMING_FLAG(ARMED)) || (isModeActivationConditionPresent(BOXTELEMETRY) && IS_RC_MODE_ACTIVE(BOXTELEMETRY)); if (enableSharedPortTelemetry && !sharedPortTelemetryEnabled) { mspSerialReleaseSharedTelemetryPorts(); telemetryCheckState(); sharedPortTelemetryEnabled = true; } else if (!enableSharedPortTelemetry && sharedPortTelemetryEnabled) { // the telemetry state must be checked immediately so that shared serial ports are released. telemetryCheckState(); mspSerialAllocatePorts(); sharedPortTelemetryEnabled = false; } } #endif #ifdef USE_VTX_CONTROL vtxUpdateActivatedChannel(); if (canUpdateVTX()) { handleVTXControlButton(); } #endif #ifdef USE_ACRO_TRAINER pidSetAcroTrainerState(IS_RC_MODE_ACTIVE(BOXACROTRAINER) && sensors(SENSOR_ACC)); #endif // USE_ACRO_TRAINER #ifdef USE_RC_SMOOTHING_FILTER if (ARMING_FLAG(ARMED) && !rcSmoothingInitializationComplete()) { beeper(BEEPER_RC_SMOOTHING_INIT_FAIL); } #endif pidSetAntiGravityState(IS_RC_MODE_ACTIVE(BOXANTIGRAVITY) || feature(FEATURE_ANTI_GRAVITY)); return true; }
void fcTasksInit(void) { schedulerInit(); if (sensors(SENSOR_GYRO)) { rescheduleTask(TASK_GYROPID, gyro.targetLooptime); setTaskEnabled(TASK_GYROPID, true); } if (sensors(SENSOR_ACC)) { setTaskEnabled(TASK_ACCEL, true); rescheduleTask(TASK_ACCEL, acc.accSamplingInterval); } setTaskEnabled(TASK_ATTITUDE, sensors(SENSOR_ACC)); setTaskEnabled(TASK_SERIAL, true); rescheduleTask(TASK_SERIAL, TASK_PERIOD_HZ(serialConfig()->serial_update_rate_hz)); bool useBatteryVoltage = batteryConfig()->voltageMeterSource != VOLTAGE_METER_NONE; setTaskEnabled(TASK_BATTERY_VOLTAGE, useBatteryVoltage); bool useBatteryCurrent = batteryConfig()->currentMeterSource != CURRENT_METER_NONE; setTaskEnabled(TASK_BATTERY_CURRENT, useBatteryCurrent); bool useBatteryAlerts = batteryConfig()->useVBatAlerts || batteryConfig()->useConsumptionAlerts || feature(FEATURE_OSD); setTaskEnabled(TASK_BATTERY_ALERTS, (useBatteryVoltage || useBatteryCurrent) && useBatteryAlerts); setTaskEnabled(TASK_RX, true); setTaskEnabled(TASK_DISPATCH, dispatchIsEnabled()); #ifdef BEEPER setTaskEnabled(TASK_BEEPER, true); #endif #ifdef GPS setTaskEnabled(TASK_GPS, feature(FEATURE_GPS)); #endif #ifdef MAG setTaskEnabled(TASK_COMPASS, sensors(SENSOR_MAG)); #if defined(USE_SPI) && defined(USE_MAG_AK8963) // fixme temporary solution for AK6983 via slave I2C on MPU9250 rescheduleTask(TASK_COMPASS, TASK_PERIOD_HZ(40)); #endif #endif #ifdef BARO setTaskEnabled(TASK_BARO, sensors(SENSOR_BARO)); #endif #ifdef SONAR setTaskEnabled(TASK_SONAR, sensors(SENSOR_SONAR)); #endif #if defined(BARO) || defined(SONAR) setTaskEnabled(TASK_ALTITUDE, sensors(SENSOR_BARO) || sensors(SENSOR_SONAR)); #endif #ifdef USE_DASHBOARD setTaskEnabled(TASK_DASHBOARD, feature(FEATURE_DASHBOARD)); #endif #ifdef TELEMETRY setTaskEnabled(TASK_TELEMETRY, feature(FEATURE_TELEMETRY)); if (feature(FEATURE_TELEMETRY)) { if (rxConfig()->serialrx_provider == SERIALRX_JETIEXBUS) { // Reschedule telemetry to 500hz for Jeti Exbus rescheduleTask(TASK_TELEMETRY, TASK_PERIOD_HZ(500)); } else if (rxConfig()->serialrx_provider == SERIALRX_CRSF) { // Reschedule telemetry to 500hz, 2ms for CRSF rescheduleTask(TASK_TELEMETRY, TASK_PERIOD_HZ(500)); } } #endif #ifdef LED_STRIP setTaskEnabled(TASK_LEDSTRIP, feature(FEATURE_LED_STRIP)); #endif #ifdef TRANSPONDER setTaskEnabled(TASK_TRANSPONDER, feature(FEATURE_TRANSPONDER)); #endif #ifdef OSD setTaskEnabled(TASK_OSD, feature(FEATURE_OSD)); #endif #ifdef USE_OSD_SLAVE setTaskEnabled(TASK_OSD_SLAVE, true); #endif #ifdef USE_BST setTaskEnabled(TASK_BST_MASTER_PROCESS, true); #endif #ifdef USE_ESC_SENSOR setTaskEnabled(TASK_ESC_SENSOR, feature(FEATURE_ESC_SENSOR)); #endif #ifdef CMS #ifdef USE_MSP_DISPLAYPORT setTaskEnabled(TASK_CMS, true); #else setTaskEnabled(TASK_CMS, feature(FEATURE_OSD) || feature(FEATURE_DASHBOARD)); #endif #endif #ifdef STACK_CHECK setTaskEnabled(TASK_STACK_CHECK, true); #endif #ifdef VTX_CONTROL #if defined(VTX_RTC6705) || defined(VTX_SMARTAUDIO) || defined(VTX_TRAMP) setTaskEnabled(TASK_VTXCTRL, true); #endif #endif }