borgware-2d/borg_hw/borg_hw_gigaborg.c

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#include "../config.h"
#include "../makros.h"
#include <avr/interrupt.h>
#include <avr/io.h>
#include <avr/wdt.h>
#include "borg_hw.h"
/*
// those macros get defined via menuconfig, now
// 16 columns total directly controlled, therefore 2 ports
#define COLPORT1 PORTC
#define COLDDR1 DDRC
#define COLPORT2 PORTA
#define COLDDR2 DDRA
// the other port controls the shift registers
#define ROWPORT PORTD
#define ROWDDR DDRD
// both clock and reset are connected to each shift register
// reset pin is negated
#define PIN_MCLR PD4
#define PIN_CLK PD6
// these are the individual data input pins for the shift registers
#define PIN_DATA PD7
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*/
#define COLDDR1 DDR(COLPORT1)
#define COLDDR2 DDR(COLPORT2)
#define ROWDDR DDR(ROWPORT)
#ifdef __AVR_ATmega644P__
/* more ifdef magic :-( */
#define OCR0 OCR0A
#define SIG_OUTPUT_COMPARE0 SIG_OUTPUT_COMPARE0A
#endif
// buffer which holds the currently shown frame
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unsigned char pixmap[NUMPLANE][NUM_ROWS][LINEBYTES];
// depending on the plane this interrupt gets triggered at 50 kHz, 31.25 kHz or
// 12.5 kHz
SIGNAL( SIG_OUTPUT_COMPARE0) {
// reset watchdog
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wdt_reset();
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COLPORT1 = (pixmap[0][0][0] & 0x0f) | (pixmap[0][1][0] << 4);
COLPORT2 = (pixmap[0][2][0] & 0x0f) | (pixmap[0][3][0] << 4);
}
void timer0_off() {
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cli();
COLPORT1 = 0;
COLPORT2 = 0;
ROWPORT = 0;
#ifdef __AVR_ATmega644P__
TCCR0A = 0x00;
TCCR0B = 0x00;
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#else
TCCR0 = 0x00;
#endif
sei();
}
// initialize timer which triggers the interrupt
void timer0_on() {
/* TCCR0: FOC0 WGM00 COM01 COM00 WGM01 CS02 CS01 CS00
CS02 CS01 CS00
0 0 0 stop
0 0 1 clk
0 1 0 clk/8
0 1 1 clk/64
1 0 0 clk/256
1 0 1 clk/1024
*/
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#ifdef __AVR_ATmega644P__
TCCR0A = 0x02; // CTC Mode
TCCR0B = 0x04; // clk/256
TCNT0 = 0; // reset timer
OCR0 = 20; // compare with this value
TIMSK0 = 0x02; // compare match Interrupt on
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#else
TCCR0 = 0x0C; // CTC Mode, clk/256
TCNT0 = 0; // reset timer
OCR0 = 20; // compare with this value
TIMSK = 0x02; // compare match Interrupt on
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#endif
}
void borg_hw_init() {
// switch column ports to output mode
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COLDDR1 = 0xFF;
COLDDR2 = 0xFF;
// switch pins of the row port to output mode
ROWDDR = (1 << PIN_MCLR) | (1 << PIN_CLK) | (1 << PIN_DATA);
// switch off all columns for now
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COLPORT1 = 0;
COLPORT2 = 0;
// reset shift registers for the rows
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ROWPORT = 0;
// switch on all row output ports of the gigaborg
ROWPORT |= (1 << PIN_DATA) | (1 << PIN_MCLR);
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uint8_t x;
for (x = 0; x < 16; x++) {
ROWPORT |= (1 << PIN_CLK);
ROWPORT &= ~(1 << PIN_CLK);
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}
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timer0_on();
// activate watchdog timer
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wdt_reset();
wdt_enable(0x00); // 17ms watchdog
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}