/** * @file settings.cpp * @brief This file is about configuring engine via the human-readable protocol * * @date Dec 30, 2012 * @author Andrey Belomutskiy, (c) 2012-2020 */ #include "pch.h" #if ! EFI_UNIT_TEST #include "eficonsole.h" #include "trigger_decoder.h" #include "console_io.h" #include "idle_thread.h" #include "alternator_controller.h" #include "trigger_emulator_algo.h" #include "value_lookup.h" #if EFI_RTC #include "rtc_helper.h" #endif // EFI_RTC #if EFI_PROD_CODE #include "can_hw.h" #include "rusefi.h" #include "hardware.h" #endif // EFI_PROD_CODE #if EFI_ELECTRONIC_THROTTLE_BODY #include "electronic_throttle.h" #endif // EFI_ELECTRONIC_THROTTLE_BODY #if (EFI_STORAGE_INT_FLASH == TRUE) || (EFI_STORAGE_MFS == TRUE) #include "flash_main.h" #endif /* (EFI_STORAGE_INT_FLASH == TRUE) || (EFI_STORAGE_MFS == TRUE) */ #if EFI_ENGINE_SNIFFER #include "engine_sniffer.h" extern int waveChartUsedSize; extern WaveChart waveChart; #endif // EFI_ENGINE_SNIFFER void printSpiState() { efiPrintf("spi 1=%s/2=%s/3=%s/4=%s", boolToString(engineConfiguration->is_enabled_spi_1), boolToString(engineConfiguration->is_enabled_spi_2), boolToString(engineConfiguration->is_enabled_spi_3), boolToString(engineConfiguration->is_enabled_spi_4)); } static void printOutputs() { efiPrintf("injectionPins: mode %s", getPin_output_mode_e(engineConfiguration->injectionPinMode)); for (size_t i = 0; i < engineConfiguration->cylindersCount; i++) { brain_pin_e brainPin = engineConfiguration->injectionPins[i]; efiPrintf("injection #%d @ %s", (1 + i), hwPortname(brainPin)); } efiPrintf("ignitionPins: mode %s", getPin_output_mode_e(engineConfiguration->ignitionPinMode)); for (size_t i = 0; i < engineConfiguration->cylindersCount; i++) { brain_pin_e brainPin = engineConfiguration->ignitionPins[i]; efiPrintf("ignition #%d @ %s", (1 + i), hwPortname(brainPin)); } efiPrintf("idlePin: mode %s @ %s freq=%d", getPin_output_mode_e(engineConfiguration->idle.solenoidPinMode), hwPortname(engineConfiguration->idle.solenoidPin), engineConfiguration->idle.solenoidFrequency); efiPrintf("malfunctionIndicator: %s mode=%s", hwPortname(engineConfiguration->malfunctionIndicatorPin), getPin_output_mode_e(engineConfiguration->malfunctionIndicatorPinMode)); efiPrintf("fuelPumpPin: mode %s @ %s", getPin_output_mode_e(engineConfiguration->fuelPumpPinMode), hwPortname(engineConfiguration->fuelPumpPin)); efiPrintf("fanPin: mode %s @ %s", getPin_output_mode_e(engineConfiguration->fanPinMode), hwPortname(engineConfiguration->fanPin)); efiPrintf("mainRelay: mode %s @ %s", getPin_output_mode_e(engineConfiguration->mainRelayPinMode), hwPortname(engineConfiguration->mainRelayPin)); efiPrintf("starterRelay: mode %s @ %s", getPin_output_mode_e(engineConfiguration->starterRelayDisablePinMode), hwPortname(engineConfiguration->starterRelayDisablePin)); efiPrintf("alternator field: mode %s @ %s", getPin_output_mode_e(engineConfiguration->alternatorControlPinMode), hwPortname(engineConfiguration->alternatorControlPin)); } /** * @brief Prints current engine configuration to human-readable console. */ void printConfiguration() { efiPrintf("Template %s/%d trigger %s/%s/%d", getEngine_type_e(engineConfiguration->engineType), engineConfiguration->engineType, getTrigger_type_e(engineConfiguration->trigger.type), getEngine_load_mode_e(engineConfiguration->fuelAlgorithm), engineConfiguration->fuelAlgorithm); efiPrintf("configurationVersion=%d", engine->getGlobalConfigurationVersion()); efiPrintf("rpmHardLimit: %d/operationMode=%d", engineConfiguration->rpmHardLimit, getEngineRotationState()->getOperationMode()); efiPrintf("globalTriggerAngleOffset=%.2f", engineConfiguration->globalTriggerAngleOffset); efiPrintf("=== cranking ==="); efiPrintf("crankingRpm: %d", engineConfiguration->cranking.rpm); efiPrintf("cranking injection %s", getInjection_mode_e(engineConfiguration->crankingInjectionMode)); efiPrintf("cranking timing %.2f", engineConfiguration->crankingTimingAngle); efiPrintf("=== ignition ==="); efiPrintf("ignitionMode: %s/enabled=%s", getIgnition_mode_e(engineConfiguration->ignitionMode), boolToString(engineConfiguration->isIgnitionEnabled)); efiPrintf("timingMode: %s", getTiming_mode_e(engineConfiguration->timingMode)); if (engineConfiguration->timingMode == TM_FIXED) { efiPrintf("fixedModeTiming: %d", (int) engineConfiguration->fixedModeTiming); } efiPrintf("=== injection ==="); efiPrintf("injection %s enabled=%s", getInjection_mode_e(engineConfiguration->injectionMode), boolToString(engineConfiguration->isInjectionEnabled)); printOutputs(); efiPrintf("map_avg=%s/wa=%s", boolToString(engineConfiguration->isMapAveragingEnabled), boolToString(engineConfiguration->isWaveAnalyzerEnabled)); efiPrintf("isManualSpinningMode=%s/isCylinderCleanupEnabled=%s", boolToString(engineConfiguration->isManualSpinningMode), boolToString(engineConfiguration->isCylinderCleanupEnabled)); efiPrintf("clutchUp@%s: %s", hwPortname(engineConfiguration->clutchUpPin), boolToString(engine->engineState.clutchUpState)); efiPrintf("clutchDown@%s: %s", hwPortname(engineConfiguration->clutchDownPin), boolToString(engine->engineState.clutchDownState)); efiPrintf("digitalPotentiometerSpiDevice %d", engineConfiguration->digitalPotentiometerSpiDevice); for (int i = 0; i < DIGIPOT_COUNT; i++) { efiPrintf("digitalPotentiometer CS%d %s", i, hwPortname(engineConfiguration->digitalPotentiometerChipSelect[i])); } #if EFI_PROD_CODE printSpiState(); #endif // EFI_PROD_CODE } #if EFI_ENGINE_CONTROL static void doPrintConfiguration() { printConfiguration(); } static void setFixedModeTiming(int value) { engineConfiguration->fixedModeTiming = value; doPrintConfiguration(); incrementGlobalConfigurationVersion(); } static void setTimingMode(int value) { engineConfiguration->timingMode = (timing_mode_e) value; doPrintConfiguration(); incrementGlobalConfigurationVersion(); } static void setIdleSolenoidFrequency(int value) { engineConfiguration->idle.solenoidFrequency = value; incrementGlobalConfigurationVersion(); } static void setSensorChartMode(int value) { engineConfiguration->sensorChartMode = (sensor_chart_e) value; doPrintConfiguration(); } #endif // EFI_ENGINE_CONTROL static void printTpsSenser(const char *msg, SensorType sensor, int16_t min, int16_t max, adc_channel_e channel) { auto tps = Sensor::get(sensor); auto raw = Sensor::getRaw(sensor); if (!tps.Valid) { efiPrintf("TPS not valid"); } char pinNameBuffer[16]; efiPrintf("tps min (closed) %d/max (full) %d v=%.2f @%s", min, max, raw, getPinNameByAdcChannel(msg, channel, pinNameBuffer)); efiPrintf("current 10bit=%d value=%.2f", convertVoltageTo10bitADC(raw), tps.value_or(0)); } void printTPSInfo(void) { efiPrintf("pedal up %f / down %f", engineConfiguration->throttlePedalUpVoltage, engineConfiguration->throttlePedalWOTVoltage); auto pps = Sensor::get(SensorType::AcceleratorPedal); if (!pps.Valid) { efiPrintf("PPS not valid"); } printTpsSenser("TPS", SensorType::Tps1, engineConfiguration->tpsMin, engineConfiguration->tpsMax, engineConfiguration->tps1_1AdcChannel); printTpsSenser("TPS2", SensorType::Tps2, engineConfiguration->tps2Min, engineConfiguration->tps2Max, engineConfiguration->tps2_1AdcChannel); } #if EFI_ENGINE_CONTROL static void setCrankingRpm(int value) { engineConfiguration->cranking.rpm = value; doPrintConfiguration(); } /** * this method is used in console - it also prints current configuration */ static void setAlgorithmInt(int value) { setAlgorithm((engine_load_mode_e) value); doPrintConfiguration(); } static void setFiringOrder(int value) { engineConfiguration->firingOrder = (firing_order_e) value; doPrintConfiguration(); } static void setRpmHardLimit(int value) { engineConfiguration->rpmHardLimit = value; doPrintConfiguration(); } static void setCrankingIACExtra(float percent) { engineConfiguration->crankingIACposition = percent; efiPrintf("cranking_iac %.2f", percent); } static void setCrankingFuel(float timeMs) { engineConfiguration->cranking.baseFuel = timeMs; efiPrintf("cranking_fuel %.2f", timeMs); } static void setGlobalTriggerAngleOffset(float value) { if (cisnan(value)) { warning(ObdCode::CUSTOM_ERR_SGTP_ARGUMENT, "Invalid argument"); return; } engineConfiguration->globalTriggerAngleOffset = value; incrementGlobalConfigurationVersion(); doPrintConfiguration(); } static void setCrankingTimingAngle(float value) { engineConfiguration->crankingTimingAngle = value; incrementGlobalConfigurationVersion(); doPrintConfiguration(); } static void setCrankingInjectionMode(int value) { engineConfiguration->crankingInjectionMode = (injection_mode_e) value; incrementGlobalConfigurationVersion(); doPrintConfiguration(); } static void setInjectionMode(int value) { engineConfiguration->injectionMode = (injection_mode_e) value; incrementGlobalConfigurationVersion(); doPrintConfiguration(); } static void setIgnitionMode(int value) { #if EFI_ENGINE_CONTROL engineConfiguration->ignitionMode = (ignition_mode_e) value; incrementGlobalConfigurationVersion(); prepareOutputSignals(); doPrintConfiguration(); #endif // EFI_ENGINE_CONTROL } static void setIndividualCoilsIgnition() { setIgnitionMode((int)IM_INDIVIDUAL_COILS); } static void setTriggerType(int value) { engineConfiguration->trigger.type = (trigger_type_e) value; incrementGlobalConfigurationVersion(); doPrintConfiguration(); efiPrintf("Do you need to also invoke set operation_mode X?"); engine->resetEngineSnifferIfInTestMode(); } static void setDebugMode(int value) { engineConfiguration->debugMode = (debug_mode_e) value; } static void setWholeTimingMap(float value) { setTable(config->ignitionTable, value); } static void setWholePhaseMapCmd(float value) { efiPrintf("Setting whole injection phase map to %.2f", value); setTable(config->injectionPhase, value); } static void setWholeTimingMapCmd(float value) { efiPrintf("Setting whole timing advance map to %.2f", value); setWholeTimingMap(value); engine->resetEngineSnifferIfInTestMode(); } static void setWholeVeCmd(float value) { efiPrintf("Setting whole VE map to %.2f", value); if (engineConfiguration->fuelAlgorithm != LM_SPEED_DENSITY) { efiPrintf("WARNING: setting VE map not in SD mode is pointless"); } setTable(config->veTable, value); engine->resetEngineSnifferIfInTestMode(); } #endif // EFI_ENGINE_CONTROL #if EFI_PROD_CODE static brain_pin_e parseBrainPinWithErrorMessage(const char *pinName) { brain_pin_e pin = parseBrainPin(pinName); if (pin == Gpio::Invalid) { efiPrintf("invalid pin name [%s]", pinName); } return pin; } /** * For example: * set_ignition_pin 1 PD7 * todo: this method counts index from 1 while at least 'set_trigger_input_pin' counts from 0. * todo: make things consistent */ static void setIgnitionPin(const char *indexStr, const char *pinName) { int index = atoi(indexStr) - 1; // convert from human index into software index if (index < 0 || index >= MAX_CYLINDER_COUNT) return; brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } efiPrintf("setting ignition pin[%d] to %s please save&restart", index, hwPortname(pin)); engineConfiguration->ignitionPins[index] = pin; incrementGlobalConfigurationVersion(); } // this method is useful for desperate time debugging // readpin PA0 void readPin(const char *pinName) { brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } int physicalValue = palReadPad(getHwPort("read", pin), getHwPin("read", pin)); efiPrintf("pin %s value %d", hwPortname(pin), physicalValue); } // this method is useful for desperate time debugging or hardware validation static void benchSetPinValue(const char *pinName, int bit) { brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } palWritePad(getHwPort("write", pin), getHwPin("write", pin), bit); efiPrintf("pin %s set value", hwPortname(pin)); readPin(pinName); } static void benchClearPin(const char *pinName) { benchSetPinValue(pinName, 0); } static void benchSetPin(const char *pinName) { benchSetPinValue(pinName, 1); } static void setIndividualPin(const char *pinName, brain_pin_e *targetPin, const char *name) { brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } efiPrintf("setting %s pin to %s please save&restart", name, hwPortname(pin)); *targetPin = pin; incrementGlobalConfigurationVersion(); } // set vss_pin static void setVssPin(const char *pinName) { setIndividualPin(pinName, &engineConfiguration->vehicleSpeedSensorInputPin, "VSS"); } // set_idle_pin none static void setIdlePin(const char *pinName) { setIndividualPin(pinName, &engineConfiguration->idle.solenoidPin, "idle"); } static void setMainRelayPin(const char *pinName) { setIndividualPin(pinName, &engineConfiguration->mainRelayPin, "main relay"); } static void setTriggerSyncPin(const char *pinName) { setIndividualPin(pinName, &engineConfiguration->debugTriggerSync, "trigger sync"); } static void setStarterRelayPin(const char *pinName) { setIndividualPin(pinName, &engineConfiguration->starterRelayDisablePin, "starter disable relay"); } static void setAlternatorPin(const char *pinName) { setIndividualPin(pinName, &engineConfiguration->alternatorControlPin, "alternator"); } static void setACRelayPin(const char *pinName) { setIndividualPin(pinName, &engineConfiguration->acRelayPin, "A/C"); } static void setFuelPumpPin(const char *pinName) { setIndividualPin(pinName, &engineConfiguration->fuelPumpPin, "fuelPump"); } static void setInjectionPin(const char *indexStr, const char *pinName) { int index = atoi(indexStr) - 1; // convert from human index into software index if (index < 0 || index >= MAX_CYLINDER_COUNT) return; brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } efiPrintf("setting injection pin[%d] to %s please save&restart", index, hwPortname(pin)); engineConfiguration->injectionPins[index] = pin; incrementGlobalConfigurationVersion(); } /** * For example: * set_trigger_input_pin 0 PA5 * todo: this method counts index from 0 while at least 'set_ignition_pin' counts from 1. * todo: make things consistent */ static void setTriggerInputPin(const char *indexStr, const char *pinName) { int index = atoi(indexStr); if (index < 0 || index > 2) return; brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } efiPrintf("setting trigger pin[%d] to %s please save&restart", index, hwPortname(pin)); engineConfiguration->triggerInputPins[index] = pin; incrementGlobalConfigurationVersion(); } static void setTriggerSimulatorPin(const char *indexStr, const char *pinName) { int index = atoi(indexStr); if (index < 0 || index >= TRIGGER_SIMULATOR_PIN_COUNT) return; brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } efiPrintf("setting trigger simulator pin[%d] to %s please save&restart", index, hwPortname(pin)); engineConfiguration->triggerSimulatorPins[index] = pin; incrementGlobalConfigurationVersion(); } #if HAL_USE_ADC // set_analog_input_pin pps pa4 // set_analog_input_pin afr none static void setAnalogInputPin(const char *sensorStr, const char *pinName) { brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } adc_channel_e channel = getAdcChannel(pin); if (channel == EFI_ADC_ERROR) { efiPrintf("Error with [%s]", pinName); return; } if (strEqual("map", sensorStr)) { engineConfiguration->map.sensor.hwChannel = channel; efiPrintf("setting MAP to %s/%d", pinName, channel); } else if (strEqual("pps", sensorStr)) { engineConfiguration->throttlePedalPositionAdcChannel = channel; efiPrintf("setting PPS to %s/%d", pinName, channel); } else if (strEqual("afr", sensorStr)) { engineConfiguration->afr.hwChannel = channel; efiPrintf("setting AFR to %s/%d", pinName, channel); } else if (strEqual("clt", sensorStr)) { engineConfiguration->clt.adcChannel = channel; efiPrintf("setting CLT to %s/%d", pinName, channel); } else if (strEqual("iat", sensorStr)) { engineConfiguration->iat.adcChannel = channel; efiPrintf("setting IAT to %s/%d", pinName, channel); } else if (strEqual("tps", sensorStr)) { engineConfiguration->tps1_1AdcChannel = channel; efiPrintf("setting TPS1 to %s/%d", pinName, channel); } else if (strEqual("tps2", sensorStr)) { engineConfiguration->tps2_1AdcChannel = channel; efiPrintf("setting TPS2 to %s/%d", pinName, channel); } incrementGlobalConfigurationVersion(); } #endif // HAL_USE_ADC static void setLogicInputPin(const char *indexStr, const char *pinName) { int index = atoi(indexStr); if (index < 0 || index > 2) { return; } brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } efiPrintf("setting logic input pin[%d] to %s please save&restart", index, hwPortname(pin)); engineConfiguration->logicAnalyzerPins[index] = pin; incrementGlobalConfigurationVersion(); } static void showPinFunction(const char *pinName) { brain_pin_e pin = parseBrainPinWithErrorMessage(pinName); if (pin == Gpio::Invalid) { return; } efiPrintf("Pin %s: [%s]", pinName, getPinFunction(pin)); } #endif // EFI_PROD_CODE static void setSpiMode(int index, bool mode) { switch (index) { case 1: engineConfiguration->is_enabled_spi_1 = mode; break; case 2: engineConfiguration->is_enabled_spi_2 = mode; break; case 3: engineConfiguration->is_enabled_spi_3 = mode; break; default: efiPrintf("invalid spi index %d", index); return; } printSpiState(); } bool verboseRxCan = false; static void enableOrDisable(const char *param, bool isEnabled) { if (strEqualCaseInsensitive(param, "useTLE8888_cranking_hack")) { engineConfiguration->useTLE8888_cranking_hack = isEnabled; #if EFI_SHAFT_POSITION_INPUT } else if (strEqualCaseInsensitive(param, CMD_TRIGGER_HW_INPUT)) { getTriggerCentral()->hwTriggerInputEnabled = isEnabled; #endif // EFI_SHAFT_POSITION_INPUT } else if (strEqualCaseInsensitive(param, "verboseTLE8888")) { engineConfiguration->verboseTLE8888 = isEnabled; } else if (strEqualCaseInsensitive(param, "verboseRxCan")) { verboseRxCan = isEnabled; } else if (strEqualCaseInsensitive(param, "verboseCan")) { engineConfiguration->verboseCan = isEnabled; } else if (strEqualCaseInsensitive(param, "verboseIsoTp")) { engineConfiguration->verboseIsoTp = isEnabled; } else if (strEqualCaseInsensitive(param, "artificialMisfire")) { engineConfiguration->artificialTestMisfire = isEnabled; } else if (strEqualCaseInsensitive(param, "logic_level_trigger")) { engineConfiguration->displayLogicLevelsInEngineSniffer = isEnabled; } else if (strEqualCaseInsensitive(param, "can_broadcast")) { engineConfiguration->enableVerboseCanTx = isEnabled; } else if (strEqualCaseInsensitive(param, "etb_auto")) { engine->etbAutoTune = isEnabled; } else if (strEqualCaseInsensitive(param, "verboseKLine")) { engineConfiguration->verboseKLine = isEnabled; } else if (strEqualCaseInsensitive(param, "stepperidle")) { engineConfiguration->useStepperIdle = isEnabled; } else if (strEqualCaseInsensitive(param, "boardUseTempPullUp")) { engineConfiguration->boardUseTempPullUp = isEnabled; incrementGlobalConfigurationVersion(); } else if (strEqualCaseInsensitive(param, "boardUseTachPullUp")) { engineConfiguration->boardUseTachPullUp = isEnabled; incrementGlobalConfigurationVersion(); } else if (strEqualCaseInsensitive(param, "two_wire_wasted_spark")) { engineConfiguration->twoWireBatchIgnition = isEnabled; incrementGlobalConfigurationVersion(); } else if (strEqualCaseInsensitive(param, "tpic_advanced_mode")) { engineConfiguration->useTpicAdvancedMode = isEnabled; } else if (strEqualCaseInsensitive(param, "altcontrol")) { engineConfiguration->isAlternatorControlEnabled = isEnabled; } else if (strEqualCaseInsensitive(param, "sd")) { engineConfiguration->isSdCardEnabled = isEnabled; } else if (strEqualCaseInsensitive(param, CMD_FUNCTIONAL_TEST_MODE)) { engine->isFunctionalTestMode = isEnabled; } else if (strEqualCaseInsensitive(param, "can_read")) { engineConfiguration->canReadEnabled = isEnabled; } else if (strEqualCaseInsensitive(param, "can_write")) { engineConfiguration->canWriteEnabled = isEnabled; } else if (strEqualCaseInsensitive(param, CMD_INJECTION)) { engineConfiguration->isInjectionEnabled = isEnabled; } else if (strEqualCaseInsensitive(param, CMD_PWM)) { engine->isPwmEnabled = isEnabled; } else if (strEqualCaseInsensitive(param, "trigger_details")) { engineConfiguration->verboseTriggerSynchDetails = isEnabled; } else if (strEqualCaseInsensitive(param, "vvt_details")) { engineConfiguration->verboseVVTDecoding = isEnabled; } else if (strEqualCaseInsensitive(param, "invertCamVVTSignal")) { engineConfiguration->invertCamVVTSignal = isEnabled; } else if (strEqualCaseInsensitive(param, CMD_IGNITION)) { engineConfiguration->isIgnitionEnabled = isEnabled; #if EFI_EMULATE_POSITION_SENSORS } else if (strEqualCaseInsensitive(param, CMD_SELF_STIMULATION)) { if (isEnabled) { enableTriggerStimulator(); } else { disableTriggerStimulator(); } } else if (strEqualCaseInsensitive(param, CMD_EXTERNAL_STIMULATION)) { if (isEnabled) { enableExternalTriggerStimulator(); } else { disableTriggerStimulator(); } #endif // EFI_EMULATE_POSITION_SENSORS } else { efiPrintf("unexpected [%s]", param); return; // well, MISRA would not like this 'return' here :( } efiPrintf("[%s] %s", param, isEnabled ? "enabled" : "disabled"); } static void enable(const char *param) { enableOrDisable(param, true); } static void disable(const char *param) { enableOrDisable(param, false); } static void enableSpi(int index) { setSpiMode(index, true); } static void disableSpi(int index) { setSpiMode(index, false); } /** * See 'LimpManager::isEngineStop' for code which actually stops engine */ void scheduleStopEngine() { doScheduleStopEngine(); } static void getValue(const char *paramStr) { { float value = getConfigValueByName(paramStr); if (value != EFI_ERROR_CODE) { efiPrintf("%s value: %.2f", paramStr, value); return; } } if (strEqualCaseInsensitive(paramStr, "tps_min")) { efiPrintf("tps_min=%d", engineConfiguration->tpsMin); } else if (strEqualCaseInsensitive(paramStr, "tps_max")) { efiPrintf("tps_max=%d", engineConfiguration->tpsMax); } else if (strEqualCaseInsensitive(paramStr, "global_trigger_offset_angle")) { efiPrintf("global_trigger_offset=%.2f", engineConfiguration->globalTriggerAngleOffset); #if EFI_SHAFT_POSITION_INPUT } else if (strEqualCaseInsensitive(paramStr, "trigger_hw_input")) { efiPrintf("trigger_hw_input=%s", boolToString(getTriggerCentral()->hwTriggerInputEnabled)); #endif // EFI_SHAFT_POSITION_INPUT } else if (strEqualCaseInsensitive(paramStr, "is_enabled_spi_1")) { efiPrintf("is_enabled_spi_1=%s", boolToString(engineConfiguration->is_enabled_spi_1)); } else if (strEqualCaseInsensitive(paramStr, "is_enabled_spi_2")) { efiPrintf("is_enabled_spi_2=%s", boolToString(engineConfiguration->is_enabled_spi_2)); } else if (strEqualCaseInsensitive(paramStr, "is_enabled_spi_3")) { efiPrintf("is_enabled_spi_3=%s", boolToString(engineConfiguration->is_enabled_spi_3)); } else if (strEqualCaseInsensitive(paramStr, "invertCamVVTSignal")) { efiPrintf("invertCamVVTSignal=%s", boolToString(engineConfiguration->invertCamVVTSignal)); } else if (strEqualCaseInsensitive(paramStr, "isHip9011Enabled")) { efiPrintf("isHip9011Enabled=%d", engineConfiguration->isHip9011Enabled); } else if (strEqualCaseInsensitive(paramStr, CMD_DATE)) { printDateTime(); } else { efiPrintf("Invalid Parameter: %s", paramStr); } } static void setScriptCurve1Value(float value) { setLinearCurve(config->scriptCurve1, value, value, 1); } static void setScriptCurve2Value(float value) { setLinearCurve(config->scriptCurve2, value, value, 1); } struct command_i_s { const char *token; VoidInt callback; }; struct command_f_s { const char *token; VoidFloat callback; }; const command_f_s commandsF[] = { #if EFI_ENGINE_CONTROL {"global_trigger_offset_angle", setGlobalTriggerAngleOffset}, {"cranking_fuel", setCrankingFuel}, {"cranking_iac", setCrankingIACExtra}, {"cranking_timing_angle", setCrankingTimingAngle}, {"tps_accel_threshold", setTpsAccelThr}, {"tps_decel_threshold", setTpsDecelThr}, {"tps_decel_multiplier", setTpsDecelMult}, {"flat_injector_lag", setFlatInjectorLag}, #endif // EFI_ENGINE_CONTROL {"script_curve_1_value", setScriptCurve1Value}, {"script_curve_2_value", setScriptCurve2Value}, }; const command_i_s commandsI[] = { #if EFI_ENGINE_CONTROL {"ignition_mode", setIgnitionMode}, {"driveWheelRevPerKm", [](int value) { engineConfiguration->driveWheelRevPerKm = value; }}, {"cranking_rpm", setCrankingRpm}, {"cranking_injection_mode", setCrankingInjectionMode}, {"injection_mode", setInjectionMode}, {"sensor_chart_mode", setSensorChartMode}, {"fixed_mode_timing", setFixedModeTiming}, {"timing_mode", setTimingMode}, {CMD_ENGINE_TYPE, setEngineTypeAndSave}, {"rpm_hard_limit", setRpmHardLimit}, {"firing_order", setFiringOrder}, {"algorithm", setAlgorithmInt}, {"debug_mode", setDebugMode}, {"trigger_type", setTriggerType}, {"idle_solenoid_freq", setIdleSolenoidFrequency}, {"tps_accel_len", setTpsAccelLen}, #endif // EFI_ENGINE_CONTROL #if EFI_PROD_CODE #if EFI_BOR_LEVEL {"bor", setBor}, #endif // EFI_BOR_LEVEL #if EFI_CAN_SUPPORT {"can_mode", setCanType}, {"can_vss", setCanVss}, #endif // EFI_CAN_SUPPORT #if EFI_IDLE_CONTROL {"idle_position", setManualIdleValvePosition}, {"idle_rpm", setTargetIdleRpm}, #endif // EFI_IDLE_CONTROL #endif // EFI_PROD_CODE // {"", }, // {"", }, }; static void setValue(const char *paramStr, const char *valueStr) { float valueF = atoff(valueStr); int valueI = atoi(valueStr); const command_f_s *currentF = &commandsF[0]; while (currentF < commandsF + sizeof(commandsF)/sizeof(commandsF[0])) { if (strEqualCaseInsensitive(paramStr, currentF->token)) { currentF->callback(valueF); return; } currentF++; } const command_i_s *currentI = &commandsI[0]; while (currentI < commandsI + sizeof(commandsI)/sizeof(commandsI[0])) { if (strEqualCaseInsensitive(paramStr, currentI->token)) { currentI->callback(valueI); return; } currentI++; } if (strEqualCaseInsensitive(paramStr, "warning_period")) { engineConfiguration->warningPeriod = valueI; } else if (strEqualCaseInsensitive(paramStr, "dwell")) { setConstantDwell(valueF); } else if (strEqualCaseInsensitive(paramStr, CMD_ENGINESNIFFERRPMTHRESHOLD)) { engineConfiguration->engineSnifferRpmThreshold = valueI; } else if (strEqualCaseInsensitive(paramStr, "tps_max")) { engineConfiguration->tpsMax = valueI; } else if (strEqualCaseInsensitive(paramStr, "tps_min")) { engineConfiguration->tpsMin = valueI; #if EFI_EMULATE_POSITION_SENSORS } else if (strEqualCaseInsensitive(paramStr, CMD_RPM)) { setTriggerEmulatorRPM(valueI); #endif // EFI_EMULATE_POSITION_SENSORS } else if (strEqualCaseInsensitive(paramStr, "mc33_hvolt")) { engineConfiguration->mc33_hvolt = valueI; } else if (strEqualCaseInsensitive(paramStr, "mc33_i_peak")) { engineConfiguration->mc33_i_peak = valueI; } else if (strEqualCaseInsensitive(paramStr, "mc33_i_hold")) { engineConfiguration->mc33_i_hold = valueI; } else if (strEqualCaseInsensitive(paramStr, "mc33_t_max_boost")) { engineConfiguration->mc33_t_max_boost = valueI; } else if (strEqualCaseInsensitive(paramStr, "mc33_t_peak_off")) { engineConfiguration->mc33_t_peak_off = valueI; } else if (strEqualCaseInsensitive(paramStr, "vvt_offset")) { engineConfiguration->vvtOffsets[0] = valueF; } else if (strEqualCaseInsensitive(paramStr, "vvt_mode")) { engineConfiguration->vvtMode[0] = (vvt_mode_e)valueI; } else if (strEqualCaseInsensitive(paramStr, "wwaeTau")) { engineConfiguration->wwaeTau = valueF; } else if (strEqualCaseInsensitive(paramStr, "wwaeBeta")) { engineConfiguration->wwaeBeta = valueF; } else if (strEqualCaseInsensitive(paramStr, "benchTestOffTime")) { engineConfiguration->benchTestOffTime = valueI; } else if (strEqualCaseInsensitive(paramStr, "benchTestCount")) { engineConfiguration->benchTestCount = valueI; } else if (strEqualCaseInsensitive(paramStr, "cranking_dwell")) { engineConfiguration->ignitionDwellForCrankingMs = valueF; #if EFI_PROD_CODE } else if (strEqualCaseInsensitive(paramStr, CMD_VSS_PIN)) { setVssPin(valueStr); #endif // EFI_PROD_CODE } else if (strEqualCaseInsensitive(paramStr, "targetvbatt")) { engineConfiguration->targetVBatt = valueF; } else if (strEqualCaseInsensitive(paramStr, CMD_DATE)) { // rusEfi console invokes this method with timestamp in local timezone setDateTime(valueStr); } bool isGoodName = setConfigValueByName(paramStr, valueF); if (isGoodName) { efiPrintf("Settings: applying [%s][%f]", paramStr, valueF); } engine->resetEngineSnifferIfInTestMode(); } void initSettings() { #if EFI_SIMULATOR printf("initSettings\n"); #endif // EFI_SIMULATOR // todo: start saving values into flash right away? addConsoleAction("tpsinfo", printTPSInfo); addConsoleAction("calibrate_tps_1_closed", grabTPSIsClosed); addConsoleAction("calibrate_tps_1_wot", grabTPSIsWideOpen); #if EFI_ENGINE_CONTROL // used by HW CI addConsoleAction(CMD_INDIVIDUAL_INJECTION, setIndividualCoilsIgnition); addConsoleAction("showconfig", doPrintConfiguration); addConsoleActionF("set_whole_phase_map", setWholePhaseMapCmd); addConsoleActionF("set_whole_timing_map", setWholeTimingMapCmd); addConsoleActionF("set_whole_ve_map", setWholeVeCmd); addConsoleActionF("set_whole_ign_corr_map", setWholeIgnitionIatCorr); #endif // EFI_ENGINE_CONTROL addConsoleAction("stopengine", (Void) scheduleStopEngine); // todo: refactor this - looks like all boolean flags should be controlled with less code duplication addConsoleActionI("enable_spi", enableSpi); addConsoleActionI("disable_spi", disableSpi); addConsoleActionS(CMD_ENABLE, enable); addConsoleActionS(CMD_DISABLE, disable); addConsoleActionSS(CMD_SET, setValue); addConsoleActionS(CMD_GET, getValue); #if EFI_PROD_CODE addConsoleActionS("showpin", showPinFunction); addConsoleActionSS(CMD_INJECTION_PIN, setInjectionPin); addConsoleActionSS(CMD_IGNITION_PIN, setIgnitionPin); addConsoleActionSS(CMD_TRIGGER_PIN, setTriggerInputPin); addConsoleActionSS(CMD_TRIGGER_SIMULATOR_PIN, setTriggerSimulatorPin); addConsoleActionI(CMD_ECU_UNLOCK, unlockEcu); addConsoleActionS("set_fuel_pump_pin", setFuelPumpPin); addConsoleActionS("set_acrelay_pin", setACRelayPin); addConsoleActionS(CMD_ALTERNATOR_PIN, setAlternatorPin); addConsoleActionS(CMD_IDLE_PIN, setIdlePin); addConsoleActionS("set_main_relay_pin", setMainRelayPin); addConsoleActionS("set_starter_relay_pin", setStarterRelayPin); addConsoleActionS("set_trigger_sync_pin", setTriggerSyncPin); addConsoleActionS("bench_clearpin", benchClearPin); addConsoleActionS("bench_setpin", benchSetPin); addConsoleActionS("readpin", readPin); #if HAL_USE_ADC addConsoleAction("adc_report", printFullAdcReport); addConsoleActionSS("set_analog_input_pin", setAnalogInputPin); #endif // HAL_USE_ADC addConsoleActionSS(CMD_LOGIC_PIN, setLogicInputPin); #endif // EFI_PROD_CODE } void printDateTime() { #if EFI_RTC printRtcDateTime(); #else // EFI_RTC efiPrintf("Cannot print time: RTC not supported"); #endif // EFI_RTC } void setDateTime(const char * const isoDateTime) { #if EFI_RTC if (strlen(isoDateTime) >= 19 && isoDateTime[10] == 'T') { efidatetime_t dateTime; dateTime.year = atoi(isoDateTime); dateTime.month = atoi(isoDateTime + 5); dateTime.day = atoi(isoDateTime + 8); dateTime.hour = atoi(isoDateTime + 11); dateTime.minute = atoi(isoDateTime + 14); dateTime.second = atoi(isoDateTime + 17); if (dateTime.year != ATOI_ERROR_CODE && dateTime.month >= 1 && dateTime.month <= 12 && dateTime.day >= 1 && dateTime.day <= 31 && dateTime.hour <= 23 && dateTime.minute <= 59 && dateTime.second <= 59) { // doesn't concern about leap years or seconds; ChibiOS doesn't support (added) leap seconds anyway setRtcDateTime(&dateTime); return; } } efiPrintf("date_set Date parameter %s is wrong", isoDateTime); #else // EFI_RTC efiPrintf("Cannot set time: RTC not supported"); #endif // EFI_RTC } #endif // ! EFI_UNIT_TEST void setEngineTypeAndSave(int value) { setEngineType(value, true); } void setEngineType(int value, bool isWriteToFlash) { { #if EFI_PROD_CODE chibios_rt::CriticalSectionLocker csl; #endif // EFI_PROD_CODE engineConfiguration->engineType = (engine_type_e)value; resetConfigurationExt((engine_type_e)value); engine->resetEngineSnifferIfInTestMode(); #if (EFI_STORAGE_INT_FLASH == TRUE) || (EFI_STORAGE_MFS == TRUE) if (isWriteToFlash) { writeToFlashNow(); } #endif /* (EFI_STORAGE_INT_FLASH == TRUE) || (EFI_STORAGE_MFS == TRUE) */ } incrementGlobalConfigurationVersion("engineType"); #if EFI_ENGINE_CONTROL && ! EFI_UNIT_TEST doPrintConfiguration(); #endif // ! EFI_UNIT_TEST }