grbl-LPC-CoreXY/sim/avr/interrupt.c

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/*
interrupt.c - replacement for the avr library of the same name to provide
dummy register variables
Part of Grbl Simulator
Copyright (c) 2012 Jens Geisler
Grbl 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.
Grbl 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 Grbl. If not, see <http://www.gnu.org/licenses/>.
*/
#include "interrupt.h"
#include "io.h"
#include "wdt.h"
//pseudo-Interrupt vector table
isr_fp compa_vect[6]={0};
isr_fp compb_vect[6]={0};
isr_fp ovf_vect[6]={0};
isr_fp wdt_vect = 0;
isr_fp pc_vect = 0;
void sei() {io.sreg|=SEI;}
void cli() {io.sreg&=~SEI;}
int16_t sim_scaling[8]={0,1,8,64,256,1024,1,1}; //clock scalars
//Timer/Counter modes: these are incomplete, but enough for this application
enum sim_wgm_mode {
wgm_NORMAL,
wgm_CTC,
wgm_FAST_PWM,
wgm_PHASE_PWM,
wgm_PH_F_PWM,
wgm_RESERVED
};
//3-bit wgm table for 8-bit timers
enum sim_wgm_mode sim_wgm_3[] = {wgm_NORMAL,wgm_PHASE_PWM,wgm_CTC,wgm_FAST_PWM,
wgm_RESERVED,wgm_PHASE_PWM, wgm_RESERVED, wgm_FAST_PWM};
//4-bit wgm modes for 16-bit timers
enum sim_wgm_mode sim_wgm_4[16] = {wgm_NORMAL,wgm_PHASE_PWM,wgm_PHASE_PWM,wgm_PHASE_PWM,
wgm_CTC, wgm_FAST_PWM, wgm_FAST_PWM, wgm_FAST_PWM,
wgm_PH_F_PWM, wgm_PH_F_PWM, wgm_PHASE_PWM, wgm_PHASE_PWM,
wgm_CTC, wgm_RESERVED, wgm_FAST_PWM, wgm_FAST_PWM};
static const uint16_t timer_bitdepth[SIM_N_TIMERS] = {
0xFF,0xFFFF,0xFF,
//0xFFFF,0xFFFF,0xFFFF 3 more for mega
};
void timer_interrupts() {
int i;
uint8_t ien = io.sreg&SEI; //interrupts enabled?
io.prescaler++;
//all clocks
for (i=0;i<SIM_N_TIMERS;i++){
uint8_t cs = io.tccrb[i]&7; //clock select bits
int16_t increment = sim_scaling[cs];
uint16_t bitmask = timer_bitdepth[i];
//check scaling to see if timer fires
if (increment && (io.prescaler&(increment-1))==0) {
//select waveform generation mode
enum sim_wgm_mode mode;
if (i==0 || i==2) { //(T0 and T2 use only 3 wgm bits)
uint8_t wgm = ((io.tccrb[i]&0x08)>>1) | (io.tccra[i]&3);
mode = sim_wgm_3[wgm];
}
else {
uint8_t wgm = ((io.tccrb[i]&0x18)>>1) | (io.tccra[i]&3); //4 wgm bits
mode = sim_wgm_4[wgm];
}
//tick
if (io.tifr[i]&(1<<SIM_ROLL)) { //handle CTC mode rollover
io.tcnt[i]=0;
io.tifr[i]&=~(1<<SIM_ROLL);
}
else {
io.tcnt[i]++;
}
io.tcnt[i]&=bitmask; //limit the 8 bit timers
switch (mode) {
case wgm_NORMAL: //Normal mode, ovf on rollover
if (io.tcnt[i]==0) io.tifr[i]|=(1<<SIM_TOV); //overflow
break;
case wgm_CTC: //CTC mode, ovf at TOP, 0 next tick
if (io.tcnt[i]==(io.ocra[i]&bitmask)) {
io.tifr[i]|=(1<<SIM_TOV)|(1<<SIM_ROLL); //overflow
}
break;
default: //unsupported
break;
}
//comparators
if ((io.timsk[i]&(1<<SIM_OCA)) && io.tcnt[i]==(io.ocra[i]&bitmask)) io.tifr[i]|=(1<<SIM_OCA);
if ((io.timsk[i]&(1<<SIM_OCB)) && io.tcnt[i]==(io.ocrb[i]&bitmask)) io.tifr[i]|=(1<<SIM_OCB);
if ((io.timsk[i]&(1<<SIM_OCC)) && io.tcnt[i]==(io.ocrc[i]&bitmask)) io.tifr[i]|=(1<<SIM_OCC);
//call any triggered interupts
if (ien && io.tifr[i]) {
if (compa_vect[i] && (io.tifr[i]&(1<<SIM_OCA))) {
compa_vect[i]();
io.tifr[i]&=~(1<<SIM_OCA);
//TODO: insert port_monitor call here
}
if (compb_vect[i] && (io.tifr[i]&(1<<SIM_OCB))) {
compb_vect[i]();
io.tifr[i]&=~(1<<SIM_OCB);
}
if (ovf_vect[i] && (io.tifr[i]&(1<<SIM_TOV))) {
ovf_vect[i]();
io.tifr[i]&=~(1<<SIM_TOV);
}
}
}
}
//// TODO for more complete timer sim.
// pwm modes. (only used for variable spindle, I think).
// -- would require fixing wgm mode for Timers1..5
// -- phase correct modes need updown counter.
// output pins (also only for variable spindle, I think).
//// Other chip features not needed yet for grbl:
// writes to TCNT0 prevent compare match (need write detector.)
// force output compare (unused)
// input capture (unused and how would we signal it?)
// define the other output compare registers.
// usercode can clear unhandled interrupt flags by writing 1.
// --(this may be impossible, since bit was 1 before the write.)
// prescaler reset.
// maybe need to cli on interrupt entry
}