/** * @file trigger_structure.h * * @date Dec 22, 2013 * @author Andrey Belomutskiy, (c) 2012-2016 */ #ifndef TRIGGER_STRUCTURE_H_ #define TRIGGER_STRUCTURE_H_ #include "main.h" #include "rusefi_enums.h" #include "EfiWave.h" #include "engine_configuration.h" #define TRIGGER_CHANNEL_COUNT 3 class trigger_shape_helper { public: trigger_shape_helper(); single_wave_s waves[TRIGGER_CHANNEL_COUNT]; private: pin_state_t pinStates[TRIGGER_CHANNEL_COUNT][PWM_PHASE_MAX_COUNT]; }; class Engine; class TriggerState; /** * @brief Trigger shape has all the fields needed to describe and decode trigger signal. */ class TriggerShape { public: TriggerShape(); void initializeTriggerShape(Logging *logger DECLARE_ENGINE_PARAMETER_S); bool isSynchronizationNeeded; bool needSecondTriggerInput; /** * duty cycle for each individual trigger channel */ float dutyCycle[PWM_PHASE_MAX_WAVE_PER_PWM]; /** * These angles are in event coordinates - with synchronization point located at angle zero. * These values are pre-calculated for performance reasons. */ angle_t eventAngles[PWM_PHASE_MAX_COUNT]; /** * this cache allows us to find a close-enough (with one degree precision) trigger wheel index by * given angle with fast constant speed. That's a performance optimization for event scheduling. */ int triggerIndexByAngle[720]; float syncRatioFrom; float syncRatioTo; /** * Usually this is not needed, but some crazy triggers like 36-2-2-2 require two consecutive * gaps ratios to sync */ float secondSyncRatioFrom; float secondSyncRatioTo; float thirdSyncRatioFrom; float thirdSyncRatioTo; /** * Trigger indexes within trigger cycle are counted from synchronization point, and all * engine processes are defined in angles from TDC. * * That's the angle distance from trigger event #0 and actual engine TDC * * see also globalTriggerAngleOffset */ angle_t tdcPosition; /** * In case of a multi-channel trigger, do we want to sync based on primary channel only? * See also gapBothDirections */ bool useOnlyPrimaryForSync; /** * Should we use falls or rises for gap ratio detection? * todo: combine this flag with gapBothDirections? */ bool useRiseEdge; /** * This is about selecting signal edges within partictular trigger channels. * Should we measure gaps with both fall and rise signal edges? * See also useOnlyPrimaryForSync */ bool gapBothDirections; /** * This is used for signal validation */ uint32_t expectedEventCount[PWM_PHASE_MAX_WAVE_PER_PWM]; #if EFI_UNIT_TEST || defined(__DOXYGEN__) /** * These signals are used for trigger export only */ int triggerSignals[PWM_PHASE_MAX_COUNT]; #endif multi_wave_s wave; // todo: add a runtime validation which would verify that this field was set properly // tood: maybe even automate this flag calculation? int initialState[PWM_PHASE_MAX_WAVE_PER_PWM]; int8_t isFrontEvent[PWM_PHASE_MAX_COUNT]; /** * this table translates trigger definition index into 'front-only' index. This translation is not so trivial * in case of a multi-channel signal with overlapping waves, for example Ford Aspire/Mitsubishi */ int frontOnlyIndexes[PWM_PHASE_MAX_COUNT]; /** * This is a pretty questionable option which is considered by 'addEvent' method */ bool invertOnAdd; /** * Total count of shaft events per CAM or CRANK shaft revolution. * TODO this should be migrated to CRANKshaft revolution, this would go together * TODO: rename to triggerDefinitionSize ? */ int size; void addEvent2(angle_t angle, trigger_wheel_e const waveIndex, trigger_value_e const state DECLARE_ENGINE_PARAMETER_S); void addEvent(angle_t angle, trigger_wheel_e const waveIndex, trigger_value_e const state); void addEvent(angle_t angle, trigger_wheel_e const waveIndex, trigger_value_e const stateParam, float filterLeft, float filterRight); operation_mode_e getOperationMode(); void initialize(operation_mode_e operationMode, bool needSecondTriggerInput); void setTriggerSynchronizationGap(float syncRatio); void setTriggerSynchronizationGap2(float syncRatioFrom, float syncRatioTo); void setSecondTriggerSynchronizationGap(float syncRatio); void setSecondTriggerSynchronizationGap2(float syncRatioFrom, float syncRatioTo); void setThirdTriggerSynchronizationGap(float syncRatio); void setThirdTriggerSynchronizationGap2(float syncRatioFrom, float syncRatioTo); /** * this one is per CRANKshaft revolution */ uint32_t getLength() const; int getSize() const; int getTriggerShapeSynchPointIndex(); private: trigger_shape_helper h; /** * index of synchronization event within TriggerShape * See findTriggerZeroEventIndex() */ int triggerShapeSynchPointIndex; /** * Working buffer for 'wave' instance * Values are in the 0..1 range */ float switchTimesBuffer[PWM_PHASE_MAX_COUNT]; /** * These angles are in trigger DESCRIPTION coordinates - i.e. the way you add events while declaring trigger shape */ angle_t getSwitchAngle(int index) const; /** * This variable is used to confirm that events are added in the right order. */ angle_t previousAngle; /** * this is part of performance optimization */ operation_mode_e operationMode; /** * This private method should only be used to prepare the array of pre-calculated values * See eventAngles array */ angle_t getAngle(int phaseIndex) const; angle_t getCycleDuration() const; void calculateTriggerSynchPoint(TriggerState *state DECLARE_ENGINE_PARAMETER_S); }; void setVwConfiguration(TriggerShape *s); void setToothedWheelConfiguration(TriggerShape *s, int total, int skipped, operation_mode_e operationMode); void configureHondaAccordCD(TriggerShape *s, bool withOneEventSignal, bool withFourEventSignal, trigger_wheel_e const oneEventWave, trigger_wheel_e const fourEventWave, float d); #endif /* TRIGGER_STRUCTURE_H_ */