651 lines
36 KiB
C++
651 lines
36 KiB
C++
/*
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Speeduino - Simple engine management for the Arduino Mega 2560 platform
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Copyright (C) Josh Stewart
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A full copy of the license may be found in the projects root directory
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*/
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#include "scheduler.h"
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#include "globals.h"
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void initialiseSchedulers()
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{
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nullSchedule.Status = OFF;
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#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
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// Much help in this from http://arduinomega.blogspot.com.au/2011/05/timer2-and-overflow-interrupt-lets-get.html
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//Fuel Schedules, which uses timer 3
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TCCR3B = 0x00; //Disable Timer3 while we set it up
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TCNT3 = 0; //Reset Timer Count
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TIFR3 = 0x00; //Timer3 INT Flag Reg: Clear Timer Overflow Flag
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TCCR3A = 0x00; //Timer3 Control Reg A: Wave Gen Mode normal
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TCCR3B = (1 << CS12); //Timer3 Control Reg B: Timer Prescaler set to 256. Refer to http://www.instructables.com/files/orig/F3T/TIKL/H3WSA4V7/F3TTIKLH3WSA4V7.jpg
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//TCCR3B = 0x03; //Timer3 Control Reg B: Timer Prescaler set to 64. Refer to http://www.instructables.com/files/orig/F3T/TIKL/H3WSA4V7/F3TTIKLH3WSA4V7.jpg
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//Ignition Schedules, which uses timer 5
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TCCR5B = 0x00; //Disable Timer5 while we set it up
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TCNT5 = 0; //Reset Timer Count
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TIFR5 = 0x00; //Timer5 INT Flag Reg: Clear Timer Overflow Flag
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TCCR5A = 0x00; //Timer5 Control Reg A: Wave Gen Mode normal
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//TCCR5B = (1 << CS12); //Timer5 Control Reg B: Timer Prescaler set to 256. Refer to http://www.instructables.com/files/orig/F3T/TIKL/H3WSA4V7/F3TTIKLH3WSA4V7.jpg
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TCCR5B = 0x03; //aka Divisor = 64 = 490.1Hz
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//The remaining Schedules (Schedules 4 for fuel and ignition) use Timer4
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TCCR4B = 0x00; //Disable Timer4 while we set it up
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TCNT4 = 0; //Reset Timer Count
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TIFR4 = 0x00; //Timer4 INT Flag Reg: Clear Timer Overflow Flag
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TCCR4A = 0x00; //Timer4 Control Reg A: Wave Gen Mode normal
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TCCR4B = (1 << CS12); //Timer4 Control Reg B: aka Divisor = 256 = 122.5HzTimer Prescaler set to 256. Refer to http://www.instructables.com/files/orig/F3T/TIKL/H3WSA4V7/F3TTIKLH3WSA4V7.jpg
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#elif defined (CORE_TEENSY)
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//FlexTimer 0 is used for 4 ignition and 4 injection schedules. There are 8 channels on this module, so no other timers are needed
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FTM0_MODE |= FTM_MODE_WPDIS; // Write Protection Disable
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FTM0_MODE |= FTM_MODE_FTMEN; //Flex Timer module enable
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FTM0_MODE |= FTM_MODE_INIT;
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FTM0_SC = 0x00; // Set this to zero before changing the modulus
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FTM0_CNTIN = 0x0000; //Shouldn't be needed, but just in case
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FTM0_CNT = 0x0000; // Reset the count to zero
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FTM0_MOD = 0xFFFF; // max modulus = 65535
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//FlexTimer 1 is used for schedules on channel 5+. Currently only channel 5 is used, but will likely be expanded later
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FTM1_MODE |= FTM_MODE_WPDIS; // Write Protection Disable
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FTM1_MODE |= FTM_MODE_FTMEN; //Flex Timer module enable
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FTM1_MODE |= FTM_MODE_INIT;
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FTM1_SC = 0x00; // Set this to zero before changing the modulus
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FTM1_CNTIN = 0x0000; //Shouldn't be needed, but just in case
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FTM1_CNT = 0x0000; // Reset the count to zero
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FTM1_MOD = 0xFFFF; // max modulus = 65535
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/*
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* Enable the clock for FTM0/1
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* 00 No clock selected. Disables the FTM counter.
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* 01 System clock
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* 10 Fixed frequency clock
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* 11 External clock
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*/
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FTM0_SC |= FTM_SC_CLKS(0b1);
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FTM1_SC |= FTM_SC_CLKS(0b1);
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/*
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* Set Prescaler
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* This is the slowest that the timer can be clocked (Without used the slow timer, which is too slow). It results in ticks of 2.13333uS on the teensy 3.5:
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* 60000000 Hz = F_BUS
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* 128 * 1000000uS / F_BUS = 2.133uS
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*
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* 000 = Divide by 1
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* 001 Divide by 2
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* 010 Divide by 4
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* 011 Divide by 8
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* 100 Divide by 16
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* 101 Divide by 32
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* 110 Divide by 64
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* 111 Divide by 128
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*/
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FTM0_SC |= FTM_SC_PS(0b111);
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FTM1_SC |= FTM_SC_PS(0b111);
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//Setup the channels (See Pg 1014 of K64 DS).
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//FTM0_C0SC &= ~FTM_CSC_ELSB; //Probably not needed as power on state should be 0
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//FTM0_C0SC &= ~FTM_CSC_ELSA; //Probably not needed as power on state should be 0
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//FTM0_C0SC &= ~FTM_CSC_DMA; //Probably not needed as power on state should be 0
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FTM0_C0SC &= ~FTM_CSC_MSB; //According to Pg 965 of the K64 datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM0_C0SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM0_C0SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM0_C1SC &= ~FTM_CSC_MSB; //According to Pg 965 of the datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM0_C1SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM0_C1SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM0_C2SC &= ~FTM_CSC_MSB; //According to Pg 965 of the datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM0_C2SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM0_C2SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM0_C3SC &= ~FTM_CSC_MSB; //According to Pg 965 of the datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM0_C3SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM0_C3SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM0_C4SC &= ~FTM_CSC_MSB; //According to Pg 965 of the datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM0_C4SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM0_C4SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM0_C5SC &= ~FTM_CSC_MSB; //According to Pg 965 of the datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM0_C5SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM0_C5SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM0_C6SC &= ~FTM_CSC_MSB; //According to Pg 965 of the datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM0_C6SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM0_C6SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM0_C7SC &= ~FTM_CSC_MSB; //According to Pg 965 of the datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM0_C7SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM0_C7SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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//Do the same, but on flex timer 3 (Used for channels 5-8)
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FTM3_C0SC &= ~FTM_CSC_MSB; //According to Pg 965 of the K64 datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM3_C0SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM3_C0SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM3_C1SC &= ~FTM_CSC_MSB; //According to Pg 965 of the K64 datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM3_C1SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM3_C1SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM3_C2SC &= ~FTM_CSC_MSB; //According to Pg 965 of the K64 datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM3_C2SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM3_C2SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM3_C3SC &= ~FTM_CSC_MSB; //According to Pg 965 of the K64 datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM3_C3SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM3_C3SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM3_C4SC &= ~FTM_CSC_MSB; //According to Pg 965 of the K64 datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM3_C4SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM3_C4SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM3_C5SC &= ~FTM_CSC_MSB; //According to Pg 965 of the K64 datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM3_C5SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM3_C5SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM3_C6SC &= ~FTM_CSC_MSB; //According to Pg 965 of the K64 datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM3_C6SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM3_C6SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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FTM3_C7SC &= ~FTM_CSC_MSB; //According to Pg 965 of the K64 datasheet, this should not be needed as MSB is reset to 0 upon reset, but the channel interrupt fails to fire without it
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FTM3_C7SC |= FTM_CSC_MSA; //Enable Compare mode
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FTM3_C7SC |= FTM_CSC_CHIE; //Enable channel compare interrupt
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// enable IRQ Interrupt
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NVIC_ENABLE_IRQ(IRQ_FTM0);
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NVIC_ENABLE_IRQ(IRQ_FTM1);
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#endif
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fuelSchedule1.Status = OFF;
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fuelSchedule2.Status = OFF;
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fuelSchedule3.Status = OFF;
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fuelSchedule4.Status = OFF;
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fuelSchedule5.Status = OFF;
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fuelSchedule1.schedulesSet = 0;
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fuelSchedule2.schedulesSet = 0;
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fuelSchedule3.schedulesSet = 0;
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fuelSchedule4.schedulesSet = 0;
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fuelSchedule5.schedulesSet = 0;
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ignitionSchedule1.Status = OFF;
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ignitionSchedule2.Status = OFF;
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ignitionSchedule3.Status = OFF;
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ignitionSchedule4.Status = OFF;
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ignitionSchedule5.Status = OFF;
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ignitionSchedule1.schedulesSet = 0;
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ignitionSchedule2.schedulesSet = 0;
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ignitionSchedule3.schedulesSet = 0;
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ignitionSchedule4.schedulesSet = 0;
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ignitionSchedule5.schedulesSet = 0;
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}
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/*
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These 8 function turn a schedule on, provides the time to start and the duration and gives it callback functions.
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All 8 functions operate the same, just on different schedules
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Args:
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startCallback: The function to be called once the timeout is reached
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timeout: The number of uS in the future that the startCallback should be triggered
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duration: The number of uS after startCallback is called before endCallback is called
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endCallback: This function is called once the duration time has been reached
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*/
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void setFuelSchedule1(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)())
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{
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if(fuelSchedule1.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
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fuelSchedule1.StartCallback = startCallback; //Name the start callback function
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fuelSchedule1.EndCallback = endCallback; //Name the end callback function
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fuelSchedule1.duration = duration;
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/*
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* The following must be enclosed in the noInterupts block to avoid contention caused if the relevant interrupts fires before the state is fully set
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* We need to calculate the value to reset the timer to (preload) in order to achieve the desired overflow time
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* As the timer is ticking every 16uS (Time per Tick = (Prescale)*(1/Frequency))
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* unsigned int absoluteTimeout = TCNT3 + (timeout / 16); //Each tick occurs every 16uS with the 256 prescaler, so divide the timeout by 16 to get ther required number of ticks. Add this to the current tick count to get the target time. This will automatically overflow as required
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*/
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noInterrupts();
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fuelSchedule1.startCompare = FUEL1_COUNTER + (timeout >> 4); //As above, but with bit shift instead of / 16
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fuelSchedule1.endCompare = fuelSchedule1.startCompare + (duration >> 4);
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fuelSchedule1.Status = PENDING; //Turn this schedule on
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fuelSchedule1.schedulesSet++; //Increment the number of times this schedule has been set
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/*if(channel5InjEnabled) { FUEL1_COMPARE = setQueue(timer3Aqueue, &fuelSchedule1, &fuelSchedule5, FUEL1_COUNTER); } //Schedule 1 shares a timer with schedule 5
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else { timer3Aqueue[0] = &fuelSchedule1; timer3Aqueue[1] = &fuelSchedule1; timer3Aqueue[2] = &fuelSchedule1; timer3Aqueue[3] = &fuelSchedule1; FUEL1_COMPARE = fuelSchedule1.startCompare; }*/
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timer3Aqueue[0] = &fuelSchedule1; timer3Aqueue[1] = &fuelSchedule1; timer3Aqueue[2] = &fuelSchedule1; timer3Aqueue[3] = &fuelSchedule1; FUEL1_COMPARE = fuelSchedule1.startCompare;
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interrupts();
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FUEL1_TIMER_ENABLE();
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}
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void setFuelSchedule2(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)())
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{
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if(fuelSchedule2.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
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fuelSchedule2.StartCallback = startCallback; //Name the start callback function
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fuelSchedule2.EndCallback = endCallback; //Name the end callback function
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fuelSchedule2.duration = duration;
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/*
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* The following must be enclosed in the noIntterupts block to avoid contention caused if the relevant interrupts fires before the state is fully set
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* We need to calculate the value to reset the timer to (preload) in order to achieve the desired overflow time
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* As the timer is ticking every 16uS (Time per Tick = (Prescale)*(1/Frequency))
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* unsigned int absoluteTimeout = TCNT3 + (timeout / 16); //Each tick occurs every 16uS with the 256 prescaler, so divide the timeout by 16 to get ther required number of ticks. Add this to the current tick count to get the target time. This will automatically overflow as required
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*/
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noInterrupts();
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fuelSchedule2.startCompare = FUEL2_COUNTER + (timeout >> 4); //As above, but with bit shift instead of / 16
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fuelSchedule2.endCompare = fuelSchedule2.startCompare + (duration >> 4);
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FUEL2_COMPARE = fuelSchedule2.startCompare; //Use the B copmare unit of timer 3
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fuelSchedule2.Status = PENDING; //Turn this schedule on
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fuelSchedule2.schedulesSet++; //Increment the number of times this schedule has been set
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interrupts();
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FUEL2_TIMER_ENABLE();
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}
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void setFuelSchedule3(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)())
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{
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if(fuelSchedule3.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
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fuelSchedule3.StartCallback = startCallback; //Name the start callback function
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fuelSchedule3.EndCallback = endCallback; //Name the end callback function
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fuelSchedule3.duration = duration;
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/*
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* The following must be enclosed in the noIntterupts block to avoid contention caused if the relevant interrupts fires before the state is fully set
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* We need to calculate the value to reset the timer to (preload) in order to achieve the desired overflow time
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* As the timer is ticking every 16uS (Time per Tick = (Prescale)*(1/Frequency))
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* unsigned int absoluteTimeout = TCNT3 + (timeout / 16); //Each tick occurs every 16uS with the 256 prescaler, so divide the timeout by 16 to get ther required number of ticks. Add this to the current tick count to get the target time. This will automatically overflow as required
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*/
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noInterrupts();
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fuelSchedule3.startCompare = FUEL3_COUNTER + (timeout >> 4); //As above, but with bit shift instead of / 16
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fuelSchedule3.endCompare = fuelSchedule3.startCompare + (duration >> 4);
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FUEL3_COMPARE = fuelSchedule3.startCompare; //Use the C copmare unit of timer 3
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fuelSchedule3.Status = PENDING; //Turn this schedule on
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fuelSchedule3.schedulesSet++; //Increment the number of times this schedule has been set
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interrupts();
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FUEL3_TIMER_ENABLE();
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}
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void setFuelSchedule4(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)()) //Uses timer 4 compare B
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{
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if(fuelSchedule4.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
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fuelSchedule4.StartCallback = startCallback; //Name the start callback function
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fuelSchedule4.EndCallback = endCallback; //Name the end callback function
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fuelSchedule4.duration = duration;
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/*
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* The following must be enclosed in the noIntterupts block to avoid contention caused if the relevant interrupts fires before the state is fully set
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* We need to calculate the value to reset the timer to (preload) in order to achieve the desired overflow time
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* As the timer is ticking every 16uS (Time per Tick = (Prescale)*(1/Frequency))
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* unsigned int absoluteTimeout = TCNT3 + (timeout / 16); //Each tick occurs every 16uS with the 256 prescaler, so divide the timeout by 16 to get ther required number of ticks. Add this to the current tick count to get the target time. This will automatically overflow as required
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*/
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noInterrupts();
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fuelSchedule4.startCompare = FUEL4_COUNTER + (timeout >> 4);
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fuelSchedule4.endCompare = fuelSchedule4.startCompare + (duration >> 4);
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FUEL4_COMPARE = fuelSchedule4.startCompare; //Use the C copmare unit of timer 3
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fuelSchedule4.Status = PENDING; //Turn this schedule on
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fuelSchedule4.schedulesSet++; //Increment the number of times this schedule has been set
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interrupts();
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FUEL4_TIMER_ENABLE();
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}
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void setFuelSchedule5(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)())
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{
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if(fuelSchedule5.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
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//We need to calculate the value to reset the timer to (preload) in order to achieve the desired overflow time
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//As the timer is ticking every 16uS (Time per Tick = (Prescale)*(1/Frequency))
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//unsigned int absoluteTimeout = TCNT3 + (timeout / 16); //Each tick occurs every 16uS with the 256 prescaler, so divide the timeout by 16 to get ther required number of ticks. Add this to the current tick count to get the target time. This will automatically overflow as required
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fuelSchedule5.StartCallback = startCallback; //Name the start callback function
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fuelSchedule5.EndCallback = endCallback; //Name the end callback function
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fuelSchedule5.duration = duration;
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/*
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* The following must be enclosed in the noIntterupts block to avoid contention caused if the relevant interrupts fires before the state is fully set
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*/
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#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__)
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noInterrupts();
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fuelSchedule5.startCompare = TCNT3 + (timeout >> 4); //As above, but with bit shift instead of / 16
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fuelSchedule5.endCompare = fuelSchedule5.startCompare + (duration >> 4);
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fuelSchedule5.Status = PENDING; //Turn this schedule on
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fuelSchedule5.schedulesSet++; //Increment the number of times this schedule has been set
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OCR3A = setQueue(timer3Aqueue, &fuelSchedule1, &fuelSchedule5, TCNT3); //Schedule 1 shares a timer with schedule 5
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interrupts();
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TIMSK3 |= (1 << OCIE3A); //Turn on the A compare unit (ie turn on the interrupt)
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#endif
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}
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//Ignition schedulers use Timer 5
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void setIgnitionSchedule1(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)())
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{
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if(ignitionSchedule1.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
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ignitionSchedule1.StartCallback = startCallback; //Name the start callback function
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ignitionSchedule1.EndCallback = endCallback; //Name the start callback function
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ignitionSchedule1.duration = duration;
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//As the timer is ticking every 4uS (Time per Tick = (Prescale)*(1/Frequency))
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if (timeout > MAX_TIMER_PERIOD) { timeout = MAX_TIMER_PERIOD - 1; } // If the timeout is >4x (Each tick represents 4uS) the maximum allowed value of unsigned int (65535), the timer compare value will overflow when appliedcausing erratic behaviour such as erroneous sparking.
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noInterrupts();
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ignitionSchedule1.startCompare = IGN1_COUNTER + uS_TO_TIMER_COMPARE(timeout); //As there is a tick every 4uS, there are timeout/4 ticks until the interrupt should be triggered ( >>2 divides by 4)
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ignitionSchedule1.endCompare = ignitionSchedule1.startCompare + uS_TO_TIMER_COMPARE(duration);
|
|
IGN1_COMPARE = ignitionSchedule1.startCompare;
|
|
ignitionSchedule1.Status = PENDING; //Turn this schedule on
|
|
ignitionSchedule1.schedulesSet++;
|
|
interrupts();
|
|
IGN1_TIMER_ENABLE();
|
|
}
|
|
void setIgnitionSchedule2(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)())
|
|
{
|
|
if(ignitionSchedule2.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
|
|
|
|
ignitionSchedule2.StartCallback = startCallback; //Name the start callback function
|
|
ignitionSchedule2.EndCallback = endCallback; //Name the start callback function
|
|
ignitionSchedule2.duration = duration;
|
|
|
|
//As the timer is ticking every 4uS (Time per Tick = (Prescale)*(1/Frequency))
|
|
if (timeout > MAX_TIMER_PERIOD) { timeout = MAX_TIMER_PERIOD - 1; } // If the timeout is >4x (Each tick represents 4uS) the maximum allowed value of unsigned int (65535), the timer compare value will overflow when appliedcausing erratic behaviour such as erroneous sparking.
|
|
|
|
noInterrupts();
|
|
ignitionSchedule2.startCompare = IGN2_COUNTER + uS_TO_TIMER_COMPARE(timeout); //As there is a tick every 4uS, there are timeout/4 ticks until the interrupt should be triggered ( >>2 divides by 4)
|
|
ignitionSchedule2.endCompare = ignitionSchedule2.startCompare + uS_TO_TIMER_COMPARE(duration);
|
|
IGN2_COMPARE = ignitionSchedule2.startCompare;
|
|
ignitionSchedule2.Status = PENDING; //Turn this schedule on
|
|
ignitionSchedule2.schedulesSet++;
|
|
interrupts();
|
|
IGN2_TIMER_ENABLE();
|
|
}
|
|
void setIgnitionSchedule3(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)())
|
|
{
|
|
if(ignitionSchedule3.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
|
|
|
|
ignitionSchedule3.StartCallback = startCallback; //Name the start callback function
|
|
ignitionSchedule3.EndCallback = endCallback; //Name the start callback function
|
|
ignitionSchedule3.duration = duration;
|
|
|
|
//The timer is ticking every 4uS (Time per Tick = (Prescale)*(1/Frequency))
|
|
if (timeout > MAX_TIMER_PERIOD) { timeout = MAX_TIMER_PERIOD - 1; } // If the timeout is >4x (Each tick represents 4uS) the maximum allowed value of unsigned int (65535), the timer compare value will overflow when appliedcausing erratic behaviour such as erroneous sparking.
|
|
|
|
noInterrupts();
|
|
ignitionSchedule3.startCompare = IGN3_COUNTER + uS_TO_TIMER_COMPARE(timeout); //As there is a tick every 4uS, there are timeout/4 ticks until the interrupt should be triggered ( >>2 divides by 4)
|
|
ignitionSchedule3.endCompare = ignitionSchedule3.startCompare + uS_TO_TIMER_COMPARE(duration);
|
|
IGN3_COMPARE = ignitionSchedule3.startCompare;
|
|
ignitionSchedule3.Status = PENDING; //Turn this schedule on
|
|
ignitionSchedule3.schedulesSet++;
|
|
interrupts();
|
|
IGN3_TIMER_ENABLE();
|
|
}
|
|
void setIgnitionSchedule4(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)())
|
|
{
|
|
if(ignitionSchedule4.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
|
|
|
|
ignitionSchedule4.StartCallback = startCallback; //Name the start callback function
|
|
ignitionSchedule4.EndCallback = endCallback; //Name the start callback function
|
|
ignitionSchedule4.duration = duration;
|
|
|
|
//We need to calculate the value to reset the timer to (preload) in order to achieve the desired overflow time
|
|
//The timer is ticking every 16uS (Time per Tick = (Prescale)*(1/Frequency))
|
|
//Note this is different to the other ignition timers
|
|
if (timeout > MAX_TIMER_PERIOD) { timeout = MAX_TIMER_PERIOD - 1; } // If the timeout is >4x (Each tick represents 4uS) the maximum allowed value of unsigned int (65535), the timer compare value will overflow when appliedcausing erratic behaviour such as erroneous sparking.
|
|
|
|
noInterrupts();
|
|
ignitionSchedule4.startCompare = IGN4_COUNTER + (timeout >> 4); //As there is a tick every 4uS, there are timeout/4 ticks until the interrupt should be triggered ( >>2 divides by 4)
|
|
ignitionSchedule4.endCompare = ignitionSchedule4.startCompare + (duration >> 4);
|
|
IGN4_COMPARE = ignitionSchedule4.startCompare;
|
|
ignitionSchedule4.Status = PENDING; //Turn this schedule on
|
|
ignitionSchedule4.schedulesSet++;
|
|
interrupts();
|
|
IGN4_TIMER_ENABLE();
|
|
}
|
|
void setIgnitionSchedule5(void (*startCallback)(), unsigned long timeout, unsigned long duration, void(*endCallback)())
|
|
{
|
|
if(ignitionSchedule5.Status == RUNNING) { return; } //Check that we're not already part way through a schedule
|
|
|
|
ignitionSchedule5.StartCallback = startCallback; //Name the start callback function
|
|
ignitionSchedule5.EndCallback = endCallback; //Name the start callback function
|
|
ignitionSchedule5.duration = duration;
|
|
|
|
//We need to calculate the value to reset the timer to (preload) in order to achieve the desired overflow time
|
|
//The timer is ticking every 16uS (Time per Tick = (Prescale)*(1/Frequency))
|
|
//Note this is different to the other ignition timers
|
|
if (timeout > MAX_TIMER_PERIOD) { timeout = MAX_TIMER_PERIOD - 1; } // If the timeout is >4x (Each tick represents 4uS) the maximum allowed value of unsigned int (65535), the timer compare value will overflow when appliedcausing erratic behaviour such as erroneous sparking.
|
|
|
|
noInterrupts();
|
|
ignitionSchedule5.startCompare = IGN5_COUNTER + (timeout >> 4); //As there is a tick every 4uS, there are timeout/4 ticks until the interrupt should be triggered ( >>2 divides by 4)
|
|
ignitionSchedule5.endCompare = ignitionSchedule5.startCompare + (duration >> 4);
|
|
IGN5_COMPARE = ignitionSchedule5.startCompare;
|
|
ignitionSchedule5.Status = PENDING; //Turn this schedule on
|
|
ignitionSchedule5.schedulesSet++;
|
|
interrupts();
|
|
IGN5_TIMER_ENABLE();
|
|
}
|
|
|
|
/*******************************************************************************************************************************************************************************************************/
|
|
//This function (All 8 ISR functions that are below) gets called when either the start time or the duration time are reached
|
|
//This calls the relevant callback function (startCallback or endCallback) depending on the status of the schedule.
|
|
//If the startCallback function is called, we put the scheduler into RUNNING state
|
|
//Timer3A (fuel schedule 1) Compare Vector
|
|
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
|
|
ISR(TIMER3_COMPA_vect, ISR_NOBLOCK) //fuelSchedules 1 and 5
|
|
#elif defined (CORE_TEENSY)
|
|
static inline void fuelSchedule1Interrupt() //Most ARM chips can simply call a function
|
|
#endif
|
|
{
|
|
if (timer3Aqueue[0]->Status == OFF) { FUEL1_TIMER_DISABLE(); return; } //Safety check. Turn off this output compare unit and return without performing any action
|
|
if (timer3Aqueue[0]->Status == PENDING) //Check to see if this schedule is turn on
|
|
{
|
|
timer3Aqueue[0]->StartCallback();
|
|
timer3Aqueue[0]->Status = RUNNING; //Set the status to be in progress (ie The start callback has been called, but not the end callback)
|
|
FUEL1_COMPARE = popQueue(timer3Aqueue);
|
|
}
|
|
else if (timer3Aqueue[0]->Status == RUNNING)
|
|
{
|
|
timer3Aqueue[0]->EndCallback();
|
|
timer3Aqueue[0]->Status = OFF; //Turn off the schedule
|
|
timer3Aqueue[0]->schedulesSet = 0;
|
|
FUEL1_COMPARE = popQueue(timer3Aqueue);
|
|
}
|
|
}
|
|
|
|
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
|
|
ISR(TIMER3_COMPB_vect, ISR_NOBLOCK) //fuelSchedule2
|
|
#elif defined (CORE_TEENSY)
|
|
static inline void fuelSchedule2Interrupt() //Most ARM chips can simply call a function
|
|
#endif
|
|
{
|
|
if (fuelSchedule2.Status == PENDING) //Check to see if this schedule is turn on
|
|
{
|
|
fuelSchedule2.StartCallback();
|
|
fuelSchedule2.Status = RUNNING; //Set the status to be in progress (ie The start callback has been called, but not the end callback)
|
|
FUEL2_COMPARE = fuelSchedule2.endCompare;
|
|
}
|
|
else if (fuelSchedule2.Status == RUNNING)
|
|
{
|
|
fuelSchedule2.EndCallback();
|
|
fuelSchedule2.Status = OFF; //Turn off the schedule
|
|
fuelSchedule2.schedulesSet = 0;
|
|
FUEL2_TIMER_DISABLE();
|
|
}
|
|
}
|
|
|
|
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
|
|
ISR(TIMER3_COMPC_vect, ISR_NOBLOCK) //fuelSchedule3
|
|
#elif defined (CORE_TEENSY)
|
|
static inline void fuelSchedule3Interrupt() //Most ARM chips can simply call a function
|
|
#endif
|
|
{
|
|
if (fuelSchedule3.Status == PENDING) //Check to see if this schedule is turn on
|
|
{
|
|
fuelSchedule3.StartCallback();
|
|
fuelSchedule3.Status = RUNNING; //Set the status to be in progress (ie The start callback has been called, but not the end callback)
|
|
FUEL3_COMPARE = fuelSchedule3.endCompare;
|
|
}
|
|
else if (fuelSchedule3.Status == RUNNING)
|
|
{
|
|
fuelSchedule3.EndCallback();
|
|
fuelSchedule3.Status = OFF; //Turn off the schedule
|
|
fuelSchedule3.schedulesSet = 0;
|
|
FUEL3_TIMER_DISABLE();
|
|
}
|
|
}
|
|
|
|
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
|
|
ISR(TIMER4_COMPB_vect, ISR_NOBLOCK) //fuelSchedule4
|
|
#elif defined (CORE_TEENSY)
|
|
static inline void fuelSchedule4Interrupt() //Most ARM chips can simply call a function
|
|
#endif
|
|
{
|
|
if (fuelSchedule4.Status == PENDING) //Check to see if this schedule is turn on
|
|
{
|
|
fuelSchedule4.StartCallback();
|
|
fuelSchedule4.Status = RUNNING; //Set the status to be in progress (ie The start callback has been called, but not the end callback)
|
|
FUEL4_COMPARE = fuelSchedule4.endCompare;
|
|
}
|
|
else if (fuelSchedule4.Status == RUNNING)
|
|
{
|
|
fuelSchedule4.EndCallback();
|
|
fuelSchedule4.Status = OFF; //Turn off the schedule
|
|
fuelSchedule4.schedulesSet = 0;
|
|
FUEL4_TIMER_DISABLE();
|
|
}
|
|
}
|
|
|
|
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
|
|
ISR(TIMER5_COMPA_vect) //ignitionSchedule1
|
|
#elif defined (CORE_TEENSY)
|
|
static inline void ignitionSchedule1Interrupt() //Most ARM chips can simply call a function
|
|
#endif
|
|
{
|
|
if (ignitionSchedule1.Status == PENDING) //Check to see if this schedule is turn on
|
|
{
|
|
ignitionSchedule1.StartCallback();
|
|
ignitionSchedule1.Status = RUNNING; //Set the status to be in progress (ie The start callback has been called, but not the end callback)
|
|
ignitionSchedule1.startTime = micros();
|
|
ign1LastRev = currentStatus.startRevolutions;
|
|
IGN1_COMPARE = ignitionSchedule1.endCompare; //OCR5A = TCNT5 + (ignitionSchedule1.duration >> 2); //Divide by 4
|
|
}
|
|
else if (ignitionSchedule1.Status == RUNNING)
|
|
{
|
|
ignitionSchedule1.EndCallback();
|
|
ignitionSchedule1.Status = OFF; //Turn off the schedule
|
|
ignitionSchedule1.schedulesSet = 0;
|
|
ignitionCount += 1; //Increment the igintion counter
|
|
IGN1_TIMER_DISABLE();
|
|
}
|
|
}
|
|
|
|
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
|
|
ISR(TIMER5_COMPB_vect) //ignitionSchedule2
|
|
#elif defined (CORE_TEENSY)
|
|
static inline void ignitionSchedule2Interrupt() //Most ARM chips can simply call a function
|
|
#endif
|
|
{
|
|
if (ignitionSchedule2.Status == PENDING) //Check to see if this schedule is turn on
|
|
{
|
|
ignitionSchedule2.StartCallback();
|
|
ignitionSchedule2.Status = RUNNING; //Set the status to be in progress (ie The start callback has been called, but not the end callback)
|
|
ignitionSchedule2.startTime = micros();
|
|
ign2LastRev = currentStatus.startRevolutions;
|
|
IGN2_COMPARE = ignitionSchedule2.endCompare; //OCR5B = TCNT5 + (ignitionSchedule2.duration >> 2);
|
|
}
|
|
else if (ignitionSchedule2.Status == RUNNING)
|
|
{
|
|
ignitionSchedule2.Status = OFF; //Turn off the schedule
|
|
ignitionSchedule2.EndCallback();
|
|
ignitionSchedule2.schedulesSet = 0;
|
|
ignitionCount += 1; //Increment the igintion counter
|
|
IGN2_TIMER_DISABLE();
|
|
}
|
|
}
|
|
|
|
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
|
|
ISR(TIMER5_COMPC_vect) //ignitionSchedule3
|
|
#elif defined (CORE_TEENSY)
|
|
static inline void ignitionSchedule3Interrupt() //Most ARM chips can simply call a function
|
|
#endif
|
|
{
|
|
if (ignitionSchedule3.Status == PENDING) //Check to see if this schedule is turn on
|
|
{
|
|
ignitionSchedule3.StartCallback();
|
|
ignitionSchedule3.Status = RUNNING; //Set the status to be in progress (ie The start callback has been called, but not the end callback)
|
|
ignitionSchedule3.startTime = micros();
|
|
ign3LastRev = currentStatus.startRevolutions;
|
|
IGN3_COMPARE = ignitionSchedule3.endCompare; //OCR5C = TCNT5 + (ignitionSchedule3.duration >> 2);
|
|
}
|
|
else if (ignitionSchedule3.Status == RUNNING)
|
|
{
|
|
ignitionSchedule3.Status = OFF; //Turn off the schedule
|
|
ignitionSchedule3.EndCallback();
|
|
ignitionSchedule3.schedulesSet = 0;
|
|
ignitionCount += 1; //Increment the igintion counter
|
|
IGN3_TIMER_DISABLE();
|
|
}
|
|
}
|
|
|
|
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
|
|
ISR(TIMER4_COMPA_vect) //ignitionSchedule4
|
|
#elif defined (CORE_TEENSY)
|
|
static inline void ignitionSchedule4Interrupt() //Most ARM chips can simply call a function
|
|
#endif
|
|
{
|
|
if (ignitionSchedule4.Status == PENDING) //Check to see if this schedule is turn on
|
|
{
|
|
ignitionSchedule4.StartCallback();
|
|
ignitionSchedule4.Status = RUNNING; //Set the status to be in progress (ie The start callback has been called, but not the end callback)
|
|
ignitionSchedule4.startTime = micros();
|
|
ign4LastRev = currentStatus.startRevolutions;
|
|
IGN4_COMPARE = ignitionSchedule4.endCompare; //OCR4A = TCNT4 + (ignitionSchedule4.duration >> 4); //Divide by 16
|
|
}
|
|
else if (ignitionSchedule4.Status == RUNNING)
|
|
{
|
|
ignitionSchedule4.Status = OFF; //Turn off the schedule
|
|
ignitionSchedule4.EndCallback();
|
|
ignitionSchedule4.schedulesSet = 0;
|
|
ignitionCount += 1; //Increment the igintion counter
|
|
IGN4_TIMER_DISABLE();
|
|
}
|
|
}
|
|
|
|
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) || defined(__AVR_ATmega2561__) //AVR chips use the ISR for this
|
|
ISR(TIMER1_COMPC_vect) //ignitionSchedule5
|
|
#elif defined (CORE_TEENSY)
|
|
static inline void ignitionSchedule5Interrupt() //Most ARM chips can simply call a function
|
|
#endif
|
|
{
|
|
if (ignitionSchedule5.Status == PENDING) //Check to see if this schedule is turn on
|
|
{
|
|
ignitionSchedule5.StartCallback();
|
|
ignitionSchedule5.Status = RUNNING; //Set the status to be in progress (ie The start callback has been called, but not the end callback)
|
|
ignitionSchedule5.startTime = micros();
|
|
ign5LastRev = currentStatus.startRevolutions;
|
|
IGN5_COMPARE = ignitionSchedule5.endCompare;
|
|
}
|
|
else if (ignitionSchedule5.Status == RUNNING)
|
|
{
|
|
ignitionSchedule5.Status = OFF; //Turn off the schedule
|
|
ignitionSchedule5.EndCallback();
|
|
ignitionSchedule5.schedulesSet = 0;
|
|
ignitionCount += 1; //Increment the igintion counter
|
|
IGN5_TIMER_DISABLE();
|
|
}
|
|
}
|
|
|
|
|
|
|
|
#if defined(CORE_TEENSY)
|
|
void ftm0_isr(void)
|
|
{
|
|
|
|
if(FTM0_C0SC & FTM_CSC_CHF) { FTM0_C0SC &= ~FTM_CSC_CHF; fuelSchedule1Interrupt(); }
|
|
else if(FTM0_C1SC & FTM_CSC_CHF) { FTM0_C1SC &= ~FTM_CSC_CHF; fuelSchedule2Interrupt(); }
|
|
else if(FTM0_C2SC & FTM_CSC_CHF) { FTM0_C2SC &= ~FTM_CSC_CHF; fuelSchedule3Interrupt(); }
|
|
else if(FTM0_C3SC & FTM_CSC_CHF) { FTM0_C3SC &= ~FTM_CSC_CHF; fuelSchedule4Interrupt(); }
|
|
else if(FTM0_C4SC & FTM_CSC_CHF) { FTM0_C4SC &= ~FTM_CSC_CHF; ignitionSchedule1Interrupt(); }
|
|
else if(FTM0_C5SC & FTM_CSC_CHF) { FTM0_C5SC &= ~FTM_CSC_CHF; ignitionSchedule2Interrupt(); }
|
|
else if(FTM0_C6SC & FTM_CSC_CHF) { FTM0_C6SC &= ~FTM_CSC_CHF; ignitionSchedule3Interrupt(); }
|
|
else if(FTM0_C7SC & FTM_CSC_CHF) { FTM0_C7SC &= ~FTM_CSC_CHF; ignitionSchedule4Interrupt(); }
|
|
|
|
}
|
|
#endif
|