1
0
mirror of git://projects.qi-hardware.com/antorcha.git synced 2024-11-25 20:17:30 +02:00
antorcha/tornado/fw/tornado.c

311 lines
4.6 KiB
C
Raw Permalink Normal View History

#include <stdbool.h>
#include <stdint.h>
#include <avr/interrupt.h>
#include <avr/pgmspace.h>
#define F_CPU 8000000UL
#include <util/delay.h>
#include "io.h"
#include "led.h"
#include "mmc.h"
#include "accel.h"
#define HIGH(port) \
(MASK(port, CARD_nPWR) | \
MASK(port, SW_N) | MASK(port, SW_E) | MASK(port, SW_S) | \
MASK(port, SW_W) | MASK(port, SW_SW))
#define OUTPUTS(port) \
(MASK(port, CARD_nPWR) | MASK(port, CARD_CLK) | \
MASK(port, LED_DS) | MASK(port, LED_LCLK) | MASK(port, LED_SCLK))
#if 0
/*
* @@@ For testing, connect the LED bar via the 8:10 card slot, so that it
* can be disconnected without soldering.
*/
#define SCLK CARD_DAT1
#define LCLK CARD_DAT0
#define DS CARD_CLK
#define VDD CARD_CMD
#else
#define SCLK LED_SCLK
#define LCLK LED_LCLK
#define DS LED_DS
#endif
static void send(uint8_t pattern[N_LEDS/8])
{
uint8_t i, j, mask;
for (i = 0; i != N_LEDS/8; i++) {
mask = 1;
for (j = 0; j != 8; j++) {
if (pattern[i] & mask)
SET(DS);
else
CLR(DS);
SET(SCLK);
CLR(SCLK);
mask <<= 1;
}
}
SET(LCLK);
CLR(LCLK);
}
static inline void admux(bool x)
{
ADMUX =
1 << REFS0 | /* Vref is AVcc */
(x ? ADC_X : ADC_Y);
}
static inline void adcsra(bool start)
{
/*
* The ADC needs to run at clkADC <= 200 kHz for full resolution.
* At clkADC = 125 kHz, a conversion takes about 110 us.
*/
ADCSRA =
1 << ADEN | /* enable ADC */
(start ? 1 << ADSC : 0) |
1 << ADIE | /* enable ADC interrupts */
6; /* clkADC = clk/64 -> 125 kHz */
}
static uint16_t adc(bool x)
{
adcsra(0);
admux(x);
adcsra(1);
while (ADCSRA & (1 << ADSC));
return ADC;
}
#define E_SHIFT 8 /* ~ 0.06 */
#define M_SHIFT 11 /* ~ 2/sample_rate */
#define HYSTERESIS 9 /* 1 g / 3 */
static const uint8_t img[] PROGMEM = {
#include "img.inc"
};
static uint8_t one[LED_BYTES] =
{ 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff };
static volatile uint16_t sample_t = 0, sample_v;
static void zxing(uint16_t x, uint16_t y)
{
static uint32_t e = (uint32_t) 512 << E_SHIFT;
static uint32_t m = (uint32_t) 512 << M_SHIFT;
int16_t d;
static bool up = 0;
static bool on = 0;
static const prog_uint8_t *p;
static uint16_t cols = 0;
sample_t++;
sample_v = x;
e = x+(e-(e >> E_SHIFT));
m = x+(m-(m >> M_SHIFT));
d = (e >> E_SHIFT)-(m >> M_SHIFT);
if (up) {
if (d < -HYSTERESIS)
up = 0;
} else {
if (d > HYSTERESIS) {
up = 1;
p = img;
cols = sizeof(img)/LED_BYTES;
on = 1;
}
}
if (cols) {
led_show_pgm(p);
p += 8;
cols--;
} else {
led_off();
}
}
static void panic(void)
{
cli();
while (1) {
led_show(one);
_delay_ms(100);
led_off();
_delay_ms(100);
}
}
int main(void)
{
PORTB = HIGH(B);
PORTC = HIGH(C);
PORTD = HIGH(D);
DDRB = OUTPUTS(B);
DDRC = OUTPUTS(C);
DDRD = OUTPUTS(D);
CLR(CARD_nPWR);
CLR(SCLK);
CLR(LCLK);
OUT(SCLK);
OUT(LCLK);
OUT(DS);
#ifdef VDD
SET(VDD);
OUT(VDD);
#endif
led_init();
#if 0
led_show(one);
if (!mmc_init())
panic();
if (!mmc_begin_write(0))
panic();
uint16_t n = 0;
for (n = 0; n != 512; n += 2) {
mmc_write(n);
mmc_write(n >> 8);
}
if (!mmc_end_write())
panic();
if (!mmc_begin_write(n))
panic();
for (; n != 1024; n += 2) {
mmc_write(n);
mmc_write(n >> 8);
}
if (!mmc_end_write())
panic();
_delay_ms(1000);
led_off();
while (1);
#endif
#if 1
uint16_t last_t = 0;
uint32_t n = 0;
sample = zxing;
/* MMC doesn't work when running from battery, probably because we
have no regulation. Just disable it for now. */
#if 0
if (!mmc_init())
panic();
#endif
accel_start();
sei();
while (1);
while (1) {
uint16_t t, v;
if (!(n & 511)) {
if (n && !mmc_end_write())
panic();
if (!mmc_begin_write(n))
panic();
}
#if 0
t = n;
v = 0;
#else
do {
cli();
t = sample_t;
v = sample_v;
sei();
}
while (t == last_t);
#endif
last_t = t;
mmc_write(t);
mmc_write(t >> 8);
mmc_write(v);
mmc_write(v >> 8);
n += 4;
}
#endif
#if 0
static uint8_t p[LED_BYTES];
uint8_t mode = 0;
uint16_t n = 0, v;
while (1) {
while (!PIN(SW_SW));
if (!PIN(SW_N))
mode = 0;
if (!PIN(SW_E))
mode = 1;
if (!PIN(SW_S))
mode = 2;
switch (mode) {
case 1:
n = adc(0);
p[0] = n;
p[1] = n >> 8;
p[2] = p[3] = p[4] = p[5] = p[6] = p[7] = 0;
send(p);
break;
case 2:
n = adc(1);
p[0] = n;
p[1] = n >> 8;
p[2] = p[3] = p[4] = p[5] = p[6] = p[7] = 0;
send(p);
break;
default:
v = 63-n;
if (n & 64)
p[(v >> 3) & 7] &= ~(1 << (v & 7));
else
p[(v >> 3) & 7] |= 1 << (v & 7);
led_show(p);
n++;
}
_delay_ms(100);
}
#endif
}