[moodlight.git] / ircontrol.c

/* $Id: ircontrol.c,v 1.5 2010/06/30 19:38:28 simimeie Exp $
 * Functions for the infrared receiver
 *
 * The infrared receiver is connected to PB0 / PCINT0.
 */

#include <avr/io.h>
#include <avr/interrupt.h>
#include "ircontrol.h"
#include "timers.h"
#include "console.h"

/* NOTE1: Note that the signal we get from the sensor is inverted. If we
 * read a zero, it means there was infrared on, if we read a one, infrared
 * is off.
 * NOTE2: Only NEC is implemented here right now, because MY remote uses
 * that protocol. However, there may be references to RC5 because I had
 * already thought about that and just left them for possible future use. */

/* For RC5, one bit length is 1778 us, when it toggles we see half
 * of it, i.e. 889 us.
 * that equals around 7100 cpu cycles at 8 MHz. */
#define RC5HALFLENINCYCLES ((CPUFREQ * 889UL) / 1000000UL)

/* For NEC, we start with a 9000 us pulse, then 4500 us silence.
 * Then the bits follow:
 * a 1 is a 560 us pulse followed by 1690 us of silence (=2250 us total).
 * a 0 is a 560 us pulse followed by  560 us of silence (=1120 us total).
 * These values equal the following cpu cycle counts:
 *  9000 us = 72000 cc, 4500 us = 36000 cc, 560 us = 4480, 1690 us = 13520 cc
 * When the key stays pressed, it is not resubmitted, but instead a special
 * "repeat" code is sent. That is: 9000 us pulse, 2250 us silence, 560 us
 * pulse.
 */
#define NECSTARTLEN1 ((CPUFREQ *   9UL) / 1000UL)
#define NECSTARTLEN2 ((CPUFREQ *  45UL) / 10000UL)
#define NECPULSELEN  ((CPUFREQ *  56UL) / 100000UL)
#define NECZEROLEN   ((CPUFREQ * 112UL) / 100000UL)
#define NECONELEN    ((CPUFREQ * 225UL) / 100000UL)
#define NECREPEATLEN ((CPUFREQ * 225UL) / 100000UL)

/* the NEC code contains 4 bytes, sent with LSB first:
 * 0+1 are either the "extended address" or "address and inverted address".
 * 2 is the command code
 * 3 is the inverted command code
 */

static struct timestamp last0irqts;
static struct timestamp last1irqts;
static uint8_t lastpin = 0xff;
static uint8_t codebytes[4];
static uint8_t curcodebit = 0xff;
static uint8_t lastcommand = 0xff;
static uint8_t repeatcommand = 0xff;
static uint16_t repeatticks = 0;
/* Repeat after this many ticks (70 = 0.5s) */
#define REPEATAFTERTICKS 100

/* some example codes
root@moodlight# !NSB! 11111111 00001000 11011111 00100000  (r)
root@moodlight# !NSB! 11111111 00001000 01011111 10100000  (g)
root@moodlight# !NSB! 11111111 00001000 10011111 01100000  (b)
root@moodlight# !NSB! 11111111 00001000 00011111 11100000  (w)
*/

ISR(PCINT0_vect) {
  uint8_t v;
  struct timestamp curirqts;
  uint32_t ts1diff; /* distance from last 1 */
  uint32_t ts0diff; /* distance from last 0 */
  
  v = PINB & _BV(PB0);
  if (v == lastpin) {  /* No change visible - spurious interrupt */
    return;
  }
  curirqts = gettimestamp_noirq();
  ts1diff = ((uint32_t)curirqts.ticks << 16) + curirqts.partticks;
  ts0diff = ts1diff;
  ts1diff -= ((uint32_t)last1irqts.ticks << 16) + last1irqts.partticks;
  ts0diff -= ((uint32_t)last0irqts.ticks << 16) + last0irqts.partticks;
  if (v) { /* Infrared just went away! */
    if ((ts1diff >= (( 8 * NECSTARTLEN1) / 10))
     && (ts1diff <= ((12 * NECSTARTLEN1) / 10))) {
        /* NEC start bit */
        /* console_printpgm_P(PSTR("!NSB!")); */
        curcodebit = 0xfe; /* Wait for second part of start sequence */
    } else {
      if (curcodebit <= 32) { /* We're in a decoding attempt, so */
                              /* Check pulse length */
        if ((ts1diff < (( 8 * NECPULSELEN) / 10))
         || (ts1diff > ((12 * NECPULSELEN) / 10))) {
            /* WRONG */
            curcodebit = 0xff;
        }
      }
      if (curcodebit == 32) {
        if (codebytes[2] != (codebytes[3] ^ 0xff)) {
          console_printpgm_P(PSTR("!CRC!"));
        } else {
          /* Successful decode! */
          lastcommand = codebytes[2];
          repeatcommand = codebytes[2];
          repeatticks = curirqts.ticks;
          console_printpgm_P(PSTR(" DEC>"));
          console_printhex8(codebytes[0]);
          console_printhex8(codebytes[1]);
          console_printhex8(codebytes[2]);
          console_printhex8(codebytes[3]);
        }
      }
    }
    last0irqts = curirqts;
  } else { /* Infrared went on */
    if ((ts1diff >= (( 8 * NECZEROLEN) / 10))
     && (ts1diff <= ((12 * NECZEROLEN) / 10))) {
        /* console_printpgm_P(PSTR("0")); */
        if (curcodebit < 32) {
          curcodebit++;
        }
    } else if ((ts1diff >= (( 8 * NECONELEN) / 10))
            && (ts1diff <= ((12 * NECONELEN) / 10))) {
        /* console_printpgm_P(PSTR("1")); */
        if (curcodebit < 32) {
          codebytes[curcodebit >> 3] |= (1 << (curcodebit & 0x07));
          curcodebit++;
        } else {
          curcodebit = 0xff;
        }
    } else if ((ts0diff >= (( 8 * NECSTARTLEN2) / 10))
            && (ts0diff <= ((12 * NECSTARTLEN2) / 10))) {
        if (curcodebit == 0xfe) { /* voila, correct start sequence */
          curcodebit = 0;
          codebytes[0] = codebytes[1] = codebytes[2] = codebytes[3] = 0;
        }
    } else if ((ts0diff >= (( 8 * NECREPEATLEN) / 10))
            && (ts0diff <= ((12 * NECREPEATLEN) / 10))) {
        if (curcodebit == 0xfe) {
          console_printpgm_P(PSTR(".REP."));
          if ((curirqts.ticks - repeatticks) > REPEATAFTERTICKS) {
            if ((repeatcommand == 0x00) || (repeatcommand == 0x01)) {
              /* Only the up/down arrows are allowed to be repeated */
              lastcommand = repeatcommand;
            }
          }
        }
    }
    last1irqts = curirqts;
  }
#if 0
  console_printpgm_P(PSTR("!"));
  console_printhex8(tsdiff >> 24);
  console_printhex8(tsdiff >> 16);
  console_printhex8(tsdiff >>  8);
  console_printhex8(tsdiff >>  0);
  console_printpgm_P(PSTR("!"));
#endif
#if 0
  if (tsdiff > ((24 * HALFRC5LENINCYCLES) / 10)) {
    /* Start of new transmission */
    console_printpgm_P(PSTR("!1["));
    console_printhex8(v);
    lastbit = 1;
  } else if (tsdiff > ((15 * HALFRC5LENINCYCLES) / 10)) {
    /* Different bit than last time */
    lastbit = !lastbit;
    if (lastbit) {
      console_printpgm_P(PSTR("1"));
    } else {
      console_printpgm_P(PSTR("0"));
    }
  } else if ((tsdiff < ((15 * HALFRC5LENINCYCLES) / 10))
          && (tsdiff > (( 5 * HALFRC5LENINCYCLES) / 10))) {
    /* Same bit as last time */
    if (lastbit) {
      console_printpgm_P(PSTR("1"));
    } else {
      console_printpgm_P(PSTR("0"));
    }
  }
#endif
  lastpin = v;
}

void ircontrol_init(void)
{
  /* Activate pullup */
  PORTB |= _BV(PB0);
  /* enable PCINT0 */
  PCICR |= _BV(PCIE0);
  /* Enable pin change interrupt 0 (=PB0) in pcint0 */
  PCMSK0 |= _BV(PCINT0);
}

uint8_t ircontrol_getlastcommand(void)
{
  uint8_t res;
  res = lastcommand;
  lastcommand = 0xff;
  return res;
}
Commit	Line	Data
32eb657a	1	/* $Id: ircontrol.c,v 1.5 2010/06/30 19:38:28 simimeie Exp $
17aea8ef	2	* Functions for the infrared receiver
	3	*
	4	* The infrared receiver is connected to PB0 / PCINT0.
	5	*/
	6
	7	#include <avr/io.h>
	8	#include <avr/interrupt.h>
	9	#include "ircontrol.h"
8a1c848b	10	#include "timers.h"
17aea8ef	11	#include "console.h"
17aea8ef	12
8a1c848b	13	/* NOTE1: Note that the signal we get from the sensor is inverted. If we
	14	* read a zero, it means there was infrared on, if we read a one, infrared
	15	* is off.
	16	* NOTE2: Only NEC is implemented here right now, because MY remote uses
	17	* that protocol. However, there may be references to RC5 because I had
	18	* already thought about that and just left them for possible future use. */
	19
	20	/* For RC5, one bit length is 1778 us, when it toggles we see half
	21	* of it, i.e. 889 us.
	22	* that equals around 7100 cpu cycles at 8 MHz. */
	23	#define RC5HALFLENINCYCLES ((CPUFREQ * 889UL) / 1000000UL)
	24
	25	/* For NEC, we start with a 9000 us pulse, then 4500 us silence.
	26	* Then the bits follow:
32eb657a	27	* a 1 is a 560 us pulse followed by 1690 us of silence (=2250 us total).
32eb657a	28	* a 0 is a 560 us pulse followed by 560 us of silence (=1120 us total).
8a1c848b	29	* These values equal the following cpu cycle counts:
8a1c848b	30	* 9000 us = 72000 cc, 4500 us = 36000 cc, 560 us = 4480, 1690 us = 13520 cc
32eb657a	31	* When the key stays pressed, it is not resubmitted, but instead a special
	32	* "repeat" code is sent. That is: 9000 us pulse, 2250 us silence, 560 us
	33	* pulse.
8a1c848b	34	*/
	35	#define NECSTARTLEN1 ((CPUFREQ * 9UL) / 1000UL)
	36	#define NECSTARTLEN2 ((CPUFREQ * 45UL) / 10000UL)
	37	#define NECPULSELEN ((CPUFREQ * 56UL) / 100000UL)
2e7f4185	38	#define NECZEROLEN ((CPUFREQ * 112UL) / 100000UL)
2e7f4185	39	#define NECONELEN ((CPUFREQ * 225UL) / 100000UL)
6dc7afb2	40	#define NECREPEATLEN ((CPUFREQ * 225UL) / 100000UL)
8a1c848b	41
	42	/* the NEC code contains 4 bytes, sent with LSB first:
	43	* 0+1 are either the "extended address" or "address and inverted address".
	44	* 2 is the command code
	45	* 3 is the inverted command code
	46	*/
	47
	48	static struct timestamp last0irqts;
	49	static struct timestamp last1irqts;
32eb657a	50	static uint8_t lastpin = 0xff;
8a1c848b	51	static uint8_t codebytes[4];
8a1c848b	52	static uint8_t curcodebit = 0xff;
32eb657a	53	static uint8_t lastcommand = 0xff;
	54	static uint8_t repeatcommand = 0xff;
	55	static uint16_t repeatticks = 0;
	56	/* Repeat after this many ticks (70 = 0.5s) */
	57	#define REPEATAFTERTICKS 100
8a1c848b	58
	59	/* some example codes
	60	root@moodlight# !NSB! 11111111 00001000 11011111 00100000 (r)
	61	root@moodlight# !NSB! 11111111 00001000 01011111 10100000 (g)
	62	root@moodlight# !NSB! 11111111 00001000 10011111 01100000 (b)
	63	root@moodlight# !NSB! 11111111 00001000 00011111 11100000 (w)
	64	*/
	65
17aea8ef	66	ISR(PCINT0_vect) {
8a1c848b	67	uint8_t v;
	68	struct timestamp curirqts;
	69	uint32_t ts1diff; /* distance from last 1 */
	70	uint32_t ts0diff; /* distance from last 0 */
	71
	72	v = PINB & _BV(PB0);
	73	if (v == lastpin) { /* No change visible - spurious interrupt */
	74	return;
	75	}
	76	curirqts = gettimestamp_noirq();
	77	ts1diff = ((uint32_t)curirqts.ticks << 16) + curirqts.partticks;
	78	ts0diff = ts1diff;
	79	ts1diff -= ((uint32_t)last1irqts.ticks << 16) + last1irqts.partticks;
	80	ts0diff -= ((uint32_t)last0irqts.ticks << 16) + last0irqts.partticks;
	81	if (v) { /* Infrared just went away! */
	82	if ((ts1diff >= (( 8 * NECSTARTLEN1) / 10))
	83	&& (ts1diff <= ((12 * NECSTARTLEN1) / 10))) {
	84	/* NEC start bit */
	85	/* console_printpgm_P(PSTR("!NSB!")); */
	86	curcodebit = 0xfe; /* Wait for second part of start sequence */
	87	} else {
	88	if (curcodebit <= 32) { /* We're in a decoding attempt, so */
	89	/* Check pulse length */
	90	if ((ts1diff < (( 8 * NECPULSELEN) / 10))
	91	\|\| (ts1diff > ((12 * NECPULSELEN) / 10))) {
	92	/* WRONG */
	93	curcodebit = 0xff;
	94	}
	95	}
	96	if (curcodebit == 32) {
	97	if (codebytes[2] != (codebytes[3] ^ 0xff)) {
	98	console_printpgm_P(PSTR("!CRC!"));
	99	} else {
	100	/* Successful decode! */
32eb657a	101	lastcommand = codebytes[2];
	102	repeatcommand = codebytes[2];
	103	repeatticks = curirqts.ticks;
8a1c848b	104	console_printpgm_P(PSTR(" DEC>"));
	105	console_printhex8(codebytes[0]);
	106	console_printhex8(codebytes[1]);
	107	console_printhex8(codebytes[2]);
	108	console_printhex8(codebytes[3]);
	109	}
	110	}
	111	}
	112	last0irqts = curirqts;
	113	} else { /* Infrared went on */
	114	if ((ts1diff >= (( 8 * NECZEROLEN) / 10))
	115	&& (ts1diff <= ((12 * NECZEROLEN) / 10))) {
	116	/* console_printpgm_P(PSTR("0")); */
	117	if (curcodebit < 32) {
	118	curcodebit++;
	119	}
	120	} else if ((ts1diff >= (( 8 * NECONELEN) / 10))
	121	&& (ts1diff <= ((12 * NECONELEN) / 10))) {
	122	/* console_printpgm_P(PSTR("1")); */
	123	if (curcodebit < 32) {
	124	codebytes[curcodebit >> 3] \|= (1 << (curcodebit & 0x07));
	125	curcodebit++;
	126	} else {
	127	curcodebit = 0xff;
	128	}
	129	} else if ((ts0diff >= (( 8 * NECSTARTLEN2) / 10))
	130	&& (ts0diff <= ((12 * NECSTARTLEN2) / 10))) {
	131	if (curcodebit == 0xfe) { /* voila, correct start sequence */
	132	curcodebit = 0;
	133	codebytes[0] = codebytes[1] = codebytes[2] = codebytes[3] = 0;
	134	}
6dc7afb2	135	} else if ((ts0diff >= (( 8 * NECREPEATLEN) / 10))
	136	&& (ts0diff <= ((12 * NECREPEATLEN) / 10))) {
	137	if (curcodebit == 0xfe) {
	138	console_printpgm_P(PSTR(".REP."));
32eb657a	139	if ((curirqts.ticks - repeatticks) > REPEATAFTERTICKS) {
	140	if ((repeatcommand == 0x00) \|\| (repeatcommand == 0x01)) {
	141	/* Only the up/down arrows are allowed to be repeated */
	142	lastcommand = repeatcommand;
	143	}
	144	}
6dc7afb2	145	}
8a1c848b	146	}
	147	last1irqts = curirqts;
	148	}
	149	#if 0
	150	console_printpgm_P(PSTR("!"));
	151	console_printhex8(tsdiff >> 24);
	152	console_printhex8(tsdiff >> 16);
	153	console_printhex8(tsdiff >> 8);
	154	console_printhex8(tsdiff >> 0);
	155	console_printpgm_P(PSTR("!"));
	156	#endif
	157	#if 0
	158	if (tsdiff > ((24 * HALFRC5LENINCYCLES) / 10)) {
	159	/* Start of new transmission */
	160	console_printpgm_P(PSTR("!1["));
	161	console_printhex8(v);
	162	lastbit = 1;
	163	} else if (tsdiff > ((15 * HALFRC5LENINCYCLES) / 10)) {
	164	/* Different bit than last time */
	165	lastbit = !lastbit;
	166	if (lastbit) {
	167	console_printpgm_P(PSTR("1"));
	168	} else {
	169	console_printpgm_P(PSTR("0"));
	170	}
	171	} else if ((tsdiff < ((15 * HALFRC5LENINCYCLES) / 10))
	172	&& (tsdiff > (( 5 * HALFRC5LENINCYCLES) / 10))) {
	173	/* Same bit as last time */
	174	if (lastbit) {
	175	console_printpgm_P(PSTR("1"));
	176	} else {
	177	console_printpgm_P(PSTR("0"));
	178	}
17aea8ef	179	}
8a1c848b	180	#endif
8a1c848b	181	lastpin = v;
17aea8ef	182	}
	183
	184	void ircontrol_init(void)
	185	{
	186	/* Activate pullup */
	187	PORTB \|= _BV(PB0);
	188	/* enable PCINT0 */
	189	PCICR \|= _BV(PCIE0);
	190	/* Enable pin change interrupt 0 (=PB0) in pcint0 */
	191	PCMSK0 \|= _BV(PCINT0);
	192	}
32eb657a	193
	194	uint8_t ircontrol_getlastcommand(void)
	195	{
	196	uint8_t res;
	197	res = lastcommand;
	198	lastcommand = 0xff;
	199	return res;
	200	}