//These functions simply trigger the injector/coil driver off or on. //NOTE: squirt status is changed as per http://www.msextra.com/doc/ms1extra/COM_RS232.htm#Acmd /* #if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) //For the AVR chips, use the faster bit flipping method of switching pins void ignitionSetter(byte *port, bool startCharge) { if( } void openInjector1() { *inj1_pin_port |= (inj1_pin_mask); ; BIT_SET(currentStatus.squirt, BIT_SQUIRT_INJ1); } void closeInjector1() { *inj1_pin_port &= ~(inj1_pin_mask); BIT_CLEAR(currentStatus.squirt, BIT_SQUIRT_INJ1); } void beginCoil1Charge() { *ign1_pin_port |= (ign1_pin_mask); BIT_SET(currentStatus.spark, 0); digitalWrite(pinTachOut, LOW); } void endCoil1Charge() { *ign1_pin_port &= ~(ign1_pin_mask); BIT_CLEAR(currentStatus.spark, 0); } void openInjector2() { *inj2_pin_port |= (inj2_pin_mask); ; BIT_SET(currentStatus.squirt, BIT_SQUIRT_INJ2); } void closeInjector2() { *inj2_pin_port &= ~(inj2_pin_mask); BIT_CLEAR(currentStatus.squirt, BIT_SQUIRT_INJ2); } void beginCoil2Charge() { *ign2_pin_port |= (ign2_pin_mask); BIT_SET(currentStatus.spark, 1); digitalWrite(pinTachOut, LOW); } void endCoil2Charge() { *ign2_pin_port &= ~(ign2_pin_mask); BIT_CLEAR(currentStatus.spark, 1);} void openInjector3() { *inj3_pin_port |= (inj3_pin_mask); ; BIT_SET(currentStatus.squirt, BIT_SQUIRT_INJ3); } void closeInjector3() { *inj3_pin_port &= ~(inj3_pin_mask); BIT_CLEAR(currentStatus.squirt, BIT_SQUIRT_INJ3); } void beginCoil3Charge() { *ign3_pin_port |= (ign3_pin_mask); BIT_SET(currentStatus.spark, 2); digitalWrite(pinTachOut, LOW); } void endCoil3Charge() { *ign3_pin_port &= ~(ign3_pin_mask); BIT_CLEAR(currentStatus.spark, 2);} void openInjector4() { *inj4_pin_port |= (inj4_pin_mask); ; BIT_SET(currentStatus.squirt, BIT_SQUIRT_INJ4); } void closeInjector4() { *inj4_pin_port &= ~(inj4_pin_mask); BIT_CLEAR(currentStatus.squirt, BIT_SQUIRT_INJ4); } void beginCoil4Charge() { *ign4_pin_port |= (ign4_pin_mask); BIT_SET(currentStatus.spark, 3); digitalWrite(pinTachOut, LOW); } void endCoil4Charge() { *ign4_pin_port &= ~(ign4_pin_mask); BIT_CLEAR(currentStatus.spark, 3);} #else */ volatile bool tachoAlt = true; #define TACH_PULSE_HIGH() *tach_pin_port |= (tach_pin_mask) #define TACH_PULSE_LOW() if( (configPage1.tachoDiv == 0) || tachoAlt ) *tach_pin_port &= ~(tach_pin_mask); tachoAlt = !tachoAlt inline void openInjector1() { digitalWrite(pinInjector1, HIGH); BIT_SET(currentStatus.squirt, BIT_SQUIRT_INJ1); } inline void closeInjector1() { digitalWrite(pinInjector1, LOW); BIT_CLEAR(currentStatus.squirt, BIT_SQUIRT_INJ1); } inline void beginCoil1Charge() { digitalWrite(pinCoil1, coilHIGH); TACH_PULSE_LOW(); } inline void endCoil1Charge() { digitalWrite(pinCoil1, coilLOW); TACH_PULSE_HIGH(); } inline void openInjector2() { digitalWrite(pinInjector2, HIGH); BIT_SET(currentStatus.squirt, BIT_SQUIRT_INJ2); } //Sets the relevant pin HIGH and changes the current status bit for injector 2 (2nd bit of currentStatus.squirt) inline void closeInjector2() { digitalWrite(pinInjector2, LOW); BIT_CLEAR(currentStatus.squirt, BIT_SQUIRT_INJ2); } inline void beginCoil2Charge() { digitalWrite(pinCoil2, coilHIGH); TACH_PULSE_LOW(); } inline void endCoil2Charge() { digitalWrite(pinCoil2, coilLOW); TACH_PULSE_HIGH(); } inline void openInjector3() { digitalWrite(pinInjector3, HIGH); BIT_SET(currentStatus.squirt, BIT_SQUIRT_INJ3); } //Sets the relevant pin HIGH and changes the current status bit for injector 3 (3rd bit of currentStatus.squirt) inline void closeInjector3() { digitalWrite(pinInjector3, LOW); BIT_CLEAR(currentStatus.squirt, BIT_SQUIRT_INJ3); } inline void beginCoil3Charge() { digitalWrite(pinCoil3, coilHIGH); TACH_PULSE_LOW(); } inline void endCoil3Charge() { digitalWrite(pinCoil3, coilLOW); TACH_PULSE_HIGH(); } inline void openInjector4() { digitalWrite(pinInjector4, HIGH); BIT_SET(currentStatus.squirt, BIT_SQUIRT_INJ4); } //Sets the relevant pin HIGH and changes the current status bit for injector 4 (4th bit of currentStatus.squirt) inline void closeInjector4() { digitalWrite(pinInjector4, LOW); BIT_CLEAR(currentStatus.squirt, BIT_SQUIRT_INJ4); } inline void beginCoil4Charge() { digitalWrite(pinCoil4, coilHIGH); TACH_PULSE_LOW(); } inline void endCoil4Charge() { digitalWrite(pinCoil4, coilLOW); TACH_PULSE_HIGH(); } inline void openInjector5() { digitalWrite(pinInjector5, HIGH); } inline void closeInjector5() { digitalWrite(pinInjector5, LOW); } inline void beginCoil5Charge() { digitalWrite(pinCoil5, coilHIGH); TACH_PULSE_LOW(); } inline void endCoil5Charge() { digitalWrite(pinCoil5, coilLOW); TACH_PULSE_HIGH(); } //#endif //Combination functions for semi-sequential injection void openInjector1and4() { digitalWrite(pinInjector1, HIGH); digitalWrite(pinInjector4, HIGH); BIT_SET(currentStatus.squirt, 0); } void closeInjector1and4() { digitalWrite(pinInjector1, LOW); digitalWrite(pinInjector4, LOW);BIT_CLEAR(currentStatus.squirt, 0); } void openInjector2and3() { digitalWrite(pinInjector2, HIGH); digitalWrite(pinInjector3, HIGH); BIT_SET(currentStatus.squirt, 1); } void closeInjector2and3() { digitalWrite(pinInjector2, LOW); digitalWrite(pinInjector3, LOW); BIT_CLEAR(currentStatus.squirt, 1); } //Below functions are used for 5 cylinder support void openInjector3and5() { digitalWrite(pinInjector3, HIGH); digitalWrite(pinInjector5, HIGH); BIT_SET(currentStatus.squirt, 0); } void closeInjector3and5() { digitalWrite(pinInjector3, LOW); digitalWrite(pinInjector5, LOW);BIT_CLEAR(currentStatus.squirt, 0); } //As above but for ignition (Wasted COP mode) void beginCoil1and3Charge() { digitalWrite(pinCoil1, coilHIGH); digitalWrite(pinCoil3, coilHIGH); digitalWrite(pinTachOut, LOW); } void endCoil1and3Charge() { digitalWrite(pinCoil1, coilLOW); digitalWrite(pinCoil3, coilLOW); } void beginCoil2and4Charge() { digitalWrite(pinCoil2, coilHIGH); digitalWrite(pinCoil4, coilHIGH); digitalWrite(pinTachOut, LOW); } void endCoil2and4Charge() { digitalWrite(pinCoil2, coilLOW); digitalWrite(pinCoil4, coilLOW); } void nullCallback() { return; }