/* * Interrupt and PWM utilities for 16 bit Timer1 on ATmega168/328 * Original code by Jesse Tane for http://labs.ideo.com August 2008 * Modified March 2009 by Jérôme Despatis and Jesse Tane for ATmega328 support * Modified June 2009 by Michael Polli and Jesse Tane to fix a bug in setPeriod() which caused the timer to stop * Modified June 2011 by Lex Talionis to add a function to read the timer * Modified Oct 2011 by Andrew Richards to avoid certain problems: * - Add (long) assignments and casts to TimerOne::read() to ensure calculations involving tmp, ICR1 and TCNT1 aren't truncated * - Ensure 16 bit registers accesses are atomic - run with interrupts disabled when accessing * - Remove global enable of interrupts (sei())- could be running within an interrupt routine) * - Disable interrupts whilst TCTN1 == 0. Datasheet vague on this, but experiment shows that overflow interrupt * flag gets set whilst TCNT1 == 0, resulting in a phantom interrupt. Could just set to 1, but gets inaccurate * at very short durations * - startBottom() added to start counter at 0 and handle all interrupt enabling. * - start() amended to enable interrupts * - restart() amended to point at startBottom() * Modiied 7:26 PM Sunday, October 09, 2011 by Lex Talionis * - renamed start() to resume() to reflect it's actual role * - renamed startBottom() to start(). This breaks some old code that expects start to continue counting where it left off * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * * See Google Code project http://code.google.com/p/arduino-timerone/ for latest */ #ifndef TIMERONE_cpp #define TIMERONE_cpp #include "TimerOne.h" TimerOne Timer1; // preinstatiate ISR(TIMER1_OVF_vect) // interrupt service routine that wraps a user defined function supplied by attachInterrupt { Timer1.isrCallback(); } void TimerOne::initialize(long microseconds) { TCCR1A = 0; // clear control register A TCCR1B = _BV(WGM13); // set mode 8: phase and frequency correct pwm, stop the timer setPeriod(microseconds); } void TimerOne::setPeriod(long microseconds) // AR modified for atomic access { long cycles = (F_CPU / 2000000) * microseconds; // the counter runs backwards after TOP, interrupt is at BOTTOM so divide microseconds by 2 if(cycles < RESOLUTION) clockSelectBits = _BV(CS10); // no prescale, full xtal else if((cycles >>= 3) < RESOLUTION) clockSelectBits = _BV(CS11); // prescale by /8 else if((cycles >>= 3) < RESOLUTION) clockSelectBits = _BV(CS11) | _BV(CS10); // prescale by /64 else if((cycles >>= 2) < RESOLUTION) clockSelectBits = _BV(CS12); // prescale by /256 else if((cycles >>= 2) < RESOLUTION) clockSelectBits = _BV(CS12) | _BV(CS10); // prescale by /1024 else cycles = RESOLUTION - 1, clockSelectBits = _BV(CS12) | _BV(CS10); // request was out of bounds, set as maximum oldSREG = SREG; cli(); // Disable interrupts for 16 bit register access ICR1 = pwmPeriod = cycles; // ICR1 is TOP in p & f correct pwm mode SREG = oldSREG; TCCR1B &= ~(_BV(CS10) | _BV(CS11) | _BV(CS12)); TCCR1B |= clockSelectBits; // reset clock select register, and starts the clock } void TimerOne::setPwmDuty(char pin, int duty) { unsigned long dutyCycle = pwmPeriod; dutyCycle *= duty; dutyCycle >>= 10; oldSREG = SREG; cli(); if(pin == 1 || pin == 9) OCR1A = dutyCycle; else if(pin == 2 || pin == 10) OCR1B = dutyCycle; SREG = oldSREG; } void TimerOne::pwm(char pin, int duty, long microseconds) // expects duty cycle to be 10 bit (1024) { if(microseconds > 0) setPeriod(microseconds); if(pin == 1 || pin == 9) { DDRB |= _BV(PORTB1); // sets data direction register for pwm output pin TCCR1A |= _BV(COM1A1); // activates the output pin } else if(pin == 2 || pin == 10) { DDRB |= _BV(PORTB2); TCCR1A |= _BV(COM1B1); } setPwmDuty(pin, duty); resume(); // Lex - make sure the clock is running. We don't want to restart the count, in case we are starting the second WGM // and the first one is in the middle of a cycle } void TimerOne::disablePwm(char pin) { if(pin == 1 || pin == 9) TCCR1A &= ~_BV(COM1A1); // clear the bit that enables pwm on PB1 else if(pin == 2 || pin == 10) TCCR1A &= ~_BV(COM1B1); // clear the bit that enables pwm on PB2 } void TimerOne::attachInterrupt(void (*isr)(), long microseconds) { if(microseconds > 0) setPeriod(microseconds); isrCallback = isr; // register the user's callback with the real ISR TIMSK1 = _BV(TOIE1); // sets the timer overflow interrupt enable bit // might be running with interrupts disabled (eg inside an ISR), so don't touch the global state // sei(); resume(); } void TimerOne::detachInterrupt() { TIMSK1 &= ~_BV(TOIE1); // clears the timer overflow interrupt enable bit // timer continues to count without calling the isr } void TimerOne::resume() // AR suggested { TCCR1B |= clockSelectBits; } void TimerOne::restart() // Depricated - Public interface to start at zero - Lex 10/9/2011 { start(); } void TimerOne::start() // AR addition, renamed by Lex to reflect it's actual role { unsigned int tcnt1; TIMSK1 &= ~_BV(TOIE1); // AR added GTCCR |= _BV(PSRSYNC); // AR added - reset prescaler (NB: shared with all 16 bit timers); oldSREG = SREG; // AR - save status register cli(); // AR - Disable interrupts TCNT1 = 0; SREG = oldSREG; // AR - Restore status register resume(); do { // Nothing -- wait until timer moved on from zero - otherwise get a phantom interrupt oldSREG = SREG; cli(); tcnt1 = TCNT1; SREG = oldSREG; } while (tcnt1==0); // TIFR1 = 0xff; // AR - Clear interrupt flags // TIMSK1 = _BV(TOIE1); // sets the timer overflow interrupt enable bit } void TimerOne::stop() { TCCR1B &= ~(_BV(CS10) | _BV(CS11) | _BV(CS12)); // clears all clock selects bits } unsigned long TimerOne::read() //returns the value of the timer in microseconds { //rember! phase and freq correct mode counts up to then down again unsigned long tmp; // AR amended to hold more than 65536 (could be nearly double this) unsigned int tcnt1; // AR added oldSREG= SREG; cli(); tmp=TCNT1; SREG = oldSREG; char scale=0; switch (clockSelectBits) { case 1:// no prescalse scale=0; break; case 2:// x8 prescale scale=3; break; case 3:// x64 scale=6; break; case 4:// x256 scale=8; break; case 5:// x1024 scale=10; break; } do { // Nothing -- max delay here is ~1023 cycles. AR modified oldSREG = SREG; cli(); tcnt1 = TCNT1; SREG = oldSREG; } while (tcnt1==tmp); //if the timer has not ticked yet //if we are counting down add the top value to how far we have counted down tmp = ( (tcnt1>tmp) ? (tmp) : (long)(ICR1-tcnt1)+(long)ICR1 ); // AR amended to add casts and reuse previous TCNT1 return ((tmp*1000L)/(F_CPU /1000L))<