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removed protocol definitions from project

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This commit is contained in:
Rafi Khan
2016-09-24 17:13:09 -06:00
parent 1f6e4d6a2e
commit ad7128544a
17 changed files with 0 additions and 1667 deletions
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105
ir_Aiwa.cpp
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@@ -1,105 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// AAA IIIII W W AAA
// A A I W W A A
// AAAAA I W W W AAAAA
// A A I W W W A A
// A A IIIII WWW A A
//==============================================================================
// Based off the RC-T501 RCU
// Lirc file http://lirc.sourceforge.net/remotes/aiwa/RC-T501
#define AIWA_RC_T501_HZ 38
#define AIWA_RC_T501_BITS 15
#define AIWA_RC_T501_PRE_BITS 26
#define AIWA_RC_T501_POST_BITS 1
#define AIWA_RC_T501_SUM_BITS (AIWA_RC_T501_PRE_BITS + AIWA_RC_T501_BITS + AIWA_RC_T501_POST_BITS)
#define AIWA_RC_T501_HDR_MARK 8800
#define AIWA_RC_T501_HDR_SPACE 4500
#define AIWA_RC_T501_BIT_MARK 500
#define AIWA_RC_T501_ONE_SPACE 600
#define AIWA_RC_T501_ZERO_SPACE 1700
//+=============================================================================
#if SEND_AIWA_RC_T501
void IRsend::sendAiwaRCT501 (int code)
{
unsigned long pre = 0x0227EEC0; // 26-bits
// Set IR carrier frequency
enableIROut(AIWA_RC_T501_HZ);
// Header
mark(AIWA_RC_T501_HDR_MARK);
space(AIWA_RC_T501_HDR_SPACE);
// Send "pre" data
for (unsigned long mask = 1UL << (26 - 1); mask; mask >>= 1) {
mark(AIWA_RC_T501_BIT_MARK);
if (pre & mask) space(AIWA_RC_T501_ONE_SPACE) ;
else space(AIWA_RC_T501_ZERO_SPACE) ;
}
//-v- THIS CODE LOOKS LIKE IT MIGHT BE WRONG - CHECK!
// it only send 15bits and ignores the top bit
// then uses TOPBIT which is 0x80000000 to check the bit code
// I suspect TOPBIT should be changed to 0x00008000
// Skip first code bit
code <<= 1;
// Send code
for (int i = 0; i < 15; i++) {
mark(AIWA_RC_T501_BIT_MARK);
if (code & 0x80000000) space(AIWA_RC_T501_ONE_SPACE) ;
else space(AIWA_RC_T501_ZERO_SPACE) ;
code <<= 1;
}
//-^- THIS CODE LOOKS LIKE IT MIGHT BE WRONG - CHECK!
// POST-DATA, 1 bit, 0x0
mark(AIWA_RC_T501_BIT_MARK);
space(AIWA_RC_T501_ZERO_SPACE);
mark(AIWA_RC_T501_BIT_MARK);
space(0);
}
#endif
//+=============================================================================
#if DECODE_AIWA_RC_T501
bool IRrecv::decodeAiwaRCT501 (decode_results *results)
{
int data = 0;
int offset = 1;
// Check SIZE
if (irparams.rawlen < 2 * (AIWA_RC_T501_SUM_BITS) + 4) return false ;
// Check HDR Mark/Space
if (!MATCH_MARK (results->rawbuf[offset++], AIWA_RC_T501_HDR_MARK )) return false ;
if (!MATCH_SPACE(results->rawbuf[offset++], AIWA_RC_T501_HDR_SPACE)) return false ;
offset += 26; // skip pre-data - optional
while(offset < irparams.rawlen - 4) {
if (MATCH_MARK(results->rawbuf[offset], AIWA_RC_T501_BIT_MARK)) offset++ ;
else return false ;
// ONE & ZERO
if (MATCH_SPACE(results->rawbuf[offset], AIWA_RC_T501_ONE_SPACE)) data = (data << 1) | 1 ;
else if (MATCH_SPACE(results->rawbuf[offset], AIWA_RC_T501_ZERO_SPACE)) data = (data << 1) | 0 ;
else break ; // End of one & zero detected
offset++;
}
results->bits = (offset - 1) / 2;
if (results->bits < 42) return false ;
results->value = data;
results->decode_type = AIWA_RC_T501;
return true;
}
#endif

94
ir_Denon.cpp
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@@ -1,94 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
// Reverse Engineered by looking at RAW dumps generated by IRremote
// I have since discovered that Denon publish all their IR codes:
// https://www.google.co.uk/search?q=DENON+MASTER+IR+Hex+Command+Sheet
// -> http://assets.denon.com/documentmaster/us/denon%20master%20ir%20hex.xls
// Having looked at the official Denon Pronto sheet and reverse engineered
// the timing values from it, it is obvious that Denon have a range of
// different timings and protocols ...the values here work for my AVR-3801 Amp!
//==============================================================================
// DDDD EEEEE N N OOO N N
// D D E NN N O O NN N
// D D EEE N N N O O N N N
// D D E N NN O O N NN
// DDDD EEEEE N N OOO N N
//==============================================================================
#define BITS 14 // The number of bits in the command
#define HDR_MARK 300 // The length of the Header:Mark
#define HDR_SPACE 750 // The lenght of the Header:Space
#define BIT_MARK 300 // The length of a Bit:Mark
#define ONE_SPACE 1800 // The length of a Bit:Space for 1's
#define ZERO_SPACE 750 // The length of a Bit:Space for 0's
//+=============================================================================
//
#if SEND_DENON
void IRsend::sendDenon (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(38);
// Header
mark (HDR_MARK);
space(HDR_SPACE);
// Data
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
mark (BIT_MARK);
space(ONE_SPACE);
} else {
mark (BIT_MARK);
space(ZERO_SPACE);
}
}
// Footer
mark(BIT_MARK);
space(0); // Always end with the LED off
}
#endif
//+=============================================================================
//
#if DECODE_DENON
bool IRrecv::decodeDenon (decode_results *results)
{
unsigned long data = 0; // Somewhere to build our code
int offset = 1; // Skip the Gap reading
// Check we have the right amount of data
if (irparams.rawlen != 1 + 2 + (2 * BITS) + 1) return false ;
// Check initial Mark+Space match
if (!MATCH_MARK (results->rawbuf[offset++], HDR_MARK )) return false ;
if (!MATCH_SPACE(results->rawbuf[offset++], HDR_SPACE)) return false ;
// Read the bits in
for (int i = 0; i < BITS; i++) {
// Each bit looks like: MARK + SPACE_1 -> 1
// or : MARK + SPACE_0 -> 0
if (!MATCH_MARK(results->rawbuf[offset++], BIT_MARK)) return false ;
// IR data is big-endian, so we shuffle it in from the right:
if (MATCH_SPACE(results->rawbuf[offset], ONE_SPACE)) data = (data << 1) | 1 ;
else if (MATCH_SPACE(results->rawbuf[offset], ZERO_SPACE)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
// Success
results->bits = BITS;
results->value = data;
results->decode_type = DENON;
return true;
}
#endif

54
ir_Dish.cpp
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@@ -1,54 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// DDDD IIIII SSSS H H
// D D I S H H
// D D I SSS HHHHH
// D D I S H H
// DDDD IIIII SSSS H H
//==============================================================================
// Sharp and DISH support by Todd Treece ( http://unionbridge.org/design/ircommand )
//
// The sned function needs to be repeated 4 times
//
// Only send the last for characters of the hex.
// I.E. Use 0x1C10 instead of 0x0000000000001C10 as listed in the LIRC file.
//
// Here is the LIRC file I found that seems to match the remote codes from the
// oscilloscope:
// DISH NETWORK (echostar 301):
// http://lirc.sourceforge.net/remotes/echostar/301_501_3100_5100_58xx_59xx
#define DISH_BITS 16
#define DISH_HDR_MARK 400
#define DISH_HDR_SPACE 6100
#define DISH_BIT_MARK 400
#define DISH_ONE_SPACE 1700
#define DISH_ZERO_SPACE 2800
#define DISH_RPT_SPACE 6200
//+=============================================================================
#if SEND_DISH
void IRsend::sendDISH (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(56);
mark(DISH_HDR_MARK);
space(DISH_HDR_SPACE);
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
mark(DISH_BIT_MARK);
space(DISH_ONE_SPACE);
} else {
mark(DISH_BIT_MARK);
space(DISH_ZERO_SPACE);
}
}
mark(DISH_HDR_MARK); //added 26th March 2016, by AnalysIR ( https://www.AnalysIR.com )
}
#endif

101
ir_JVC.cpp
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@@ -1,101 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// JJJJJ V V CCCC
// J V V C
// J V V C
// J J V V C
// J V CCCC
//==============================================================================
#define JVC_BITS 16
#define JVC_HDR_MARK 8000
#define JVC_HDR_SPACE 4000
#define JVC_BIT_MARK 600
#define JVC_ONE_SPACE 1600
#define JVC_ZERO_SPACE 550
#define JVC_RPT_LENGTH 60000
//+=============================================================================
// JVC does NOT repeat by sending a separate code (like NEC does).
// The JVC protocol repeats by skipping the header.
// To send a JVC repeat signal, send the original code value
// and set 'repeat' to true
//
#if SEND_JVC
void IRsend::sendJVC (unsigned long data, int nbits, bool repeat)
{
// Set IR carrier frequency
enableIROut(38);
// Only send the Header if this is NOT a repeat command
if (!repeat){
mark(JVC_HDR_MARK);
space(JVC_HDR_SPACE);
}
// Data
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
mark(JVC_BIT_MARK);
space(JVC_ONE_SPACE);
} else {
mark(JVC_BIT_MARK);
space(JVC_ZERO_SPACE);
}
}
// Footer
mark(JVC_BIT_MARK);
space(0); // Always end with the LED off
}
#endif
//+=============================================================================
#if DECODE_JVC
bool IRrecv::decodeJVC (decode_results *results)
{
long data = 0;
int offset = 1; // Skip first space
// Check for repeat
if ( (irparams.rawlen - 1 == 33)
&& MATCH_MARK(results->rawbuf[offset], JVC_BIT_MARK)
&& MATCH_MARK(results->rawbuf[irparams.rawlen-1], JVC_BIT_MARK)
) {
results->bits = 0;
results->value = REPEAT;
results->decode_type = JVC;
return true;
}
// Initial mark
if (!MATCH_MARK(results->rawbuf[offset++], JVC_HDR_MARK)) return false ;
if (irparams.rawlen < (2 * JVC_BITS) + 1 ) return false ;
// Initial space
if (!MATCH_SPACE(results->rawbuf[offset++], JVC_HDR_SPACE)) return false ;
for (int i = 0; i < JVC_BITS; i++) {
if (!MATCH_MARK(results->rawbuf[offset++], JVC_BIT_MARK)) return false ;
if (MATCH_SPACE(results->rawbuf[offset], JVC_ONE_SPACE)) data = (data << 1) | 1 ;
else if (MATCH_SPACE(results->rawbuf[offset], JVC_ZERO_SPACE)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
// Stop bit
if (!MATCH_MARK(results->rawbuf[offset], JVC_BIT_MARK)) return false ;
// Success
results->bits = JVC_BITS;
results->value = data;
results->decode_type = JVC;
return true;
}
#endif

80
ir_LG.cpp
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@@ -1,80 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// L GGGG
// L G
// L G GG
// L G G
// LLLLL GGG
//==============================================================================
#define LG_BITS 28
#define LG_HDR_MARK 8000
#define LG_HDR_SPACE 4000
#define LG_BIT_MARK 600
#define LG_ONE_SPACE 1600
#define LG_ZERO_SPACE 550
#define LG_RPT_LENGTH 60000
//+=============================================================================
#if DECODE_LG
bool IRrecv::decodeLG (decode_results *results)
{
long data = 0;
int offset = 1; // Skip first space
// Check we have the right amount of data
if (irparams.rawlen < (2 * LG_BITS) + 1 ) return false ;
// Initial mark/space
if (!MATCH_MARK(results->rawbuf[offset++], LG_HDR_MARK)) return false ;
if (!MATCH_SPACE(results->rawbuf[offset++], LG_HDR_SPACE)) return false ;
for (int i = 0; i < LG_BITS; i++) {
if (!MATCH_MARK(results->rawbuf[offset++], LG_BIT_MARK)) return false ;
if (MATCH_SPACE(results->rawbuf[offset], LG_ONE_SPACE)) data = (data << 1) | 1 ;
else if (MATCH_SPACE(results->rawbuf[offset], LG_ZERO_SPACE)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
// Stop bit
if (!MATCH_MARK(results->rawbuf[offset], LG_BIT_MARK)) return false ;
// Success
results->bits = LG_BITS;
results->value = data;
results->decode_type = LG;
return true;
}
#endif
//+=============================================================================
#if SEND_LG
void IRsend::sendLG (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(38);
// Header
mark(LG_HDR_MARK);
space(LG_HDR_SPACE);
mark(LG_BIT_MARK);
// Data
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
space(LG_ONE_SPACE);
mark(LG_BIT_MARK);
} else {
space(LG_ZERO_SPACE);
mark(LG_BIT_MARK);
}
}
space(0); // Always end with the LED off
}
#endif

46
ir_Lego_PF.cpp
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@@ -1,46 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
#include "ir_Lego_PF_BitStreamEncoder.h"
//==============================================================================
// L EEEEEE EEEE OOOO
// L E E O O
// L EEEE E EEE O O
// L E E E O O LEGO Power Functions
// LLLLLL EEEEEE EEEE OOOO Copyright (c) 2016 Philipp Henkel
//==============================================================================
// Supported Devices
// LEGO® Power Functions IR Receiver 8884
//+=============================================================================
//
#if SEND_LEGO_PF
#if DEBUG
namespace {
void logFunctionParameters(uint16_t data, bool repeat) {
DBG_PRINT("sendLegoPowerFunctions(data=");
DBG_PRINT(data);
DBG_PRINT(", repeat=");
DBG_PRINTLN(repeat?"true)" : "false)");
}
} // anonymous namespace
#endif // DEBUG
void IRsend::sendLegoPowerFunctions(uint16_t data, bool repeat)
{
#if DEBUG
::logFunctionParameters(data, repeat);
#endif // DEBUG
enableIROut(38);
static LegoPfBitStreamEncoder bitStreamEncoder;
bitStreamEncoder.reset(data, repeat);
do {
mark(bitStreamEncoder.getMarkDuration());
space(bitStreamEncoder.getPauseDuration());
} while (bitStreamEncoder.next());
}
#endif // SEND_LEGO_PF

115
ir_Lego_PF_BitStreamEncoder.h
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@@ -1,115 +0,0 @@
//==============================================================================
// L EEEEEE EEEE OOOO
// L E E O O
// L EEEE E EEE O O
// L E E E O O LEGO Power Functions
// LLLLLL EEEEEE EEEE OOOO Copyright (c) 2016 Philipp Henkel
//==============================================================================
//+=============================================================================
//
class LegoPfBitStreamEncoder {
private:
uint16_t data;
bool repeatMessage;
int messageBitIdx;
int repeatCount;
int messageLength;
// HIGH data bit = IR mark + high pause
// LOW data bit = IR mark + low pause
static const int LOW_BIT_DURATION = 421;
static const int HIGH_BIT_DURATION = 711;
static const int START_BIT_DURATION = 1184;
static const int STOP_BIT_DURATION = 1184;
static const int IR_MARK_DURATION = 158;
static const int HIGH_PAUSE_DURATION = HIGH_BIT_DURATION - IR_MARK_DURATION;
static const int LOW_PAUSE_DURATION = LOW_BIT_DURATION - IR_MARK_DURATION;
static const int START_PAUSE_DURATION = START_BIT_DURATION - IR_MARK_DURATION;
static const int STOP_PAUSE_DURATION = STOP_BIT_DURATION - IR_MARK_DURATION;
static const int MESSAGE_BITS = 18;
static const int MAX_MESSAGE_LENGTH = 16000;
public:
void reset(uint16_t data, bool repeatMessage) {
this->data = data;
this->repeatMessage = repeatMessage;
messageBitIdx = 0;
repeatCount = 0;
messageLength = getMessageLength();
}
int getChannelId() const { return 1 + ((data >> 12) & 0x3); }
int getMessageLength() const {
// Sum up all marks
int length = MESSAGE_BITS * IR_MARK_DURATION;
// Sum up all pauses
length += START_PAUSE_DURATION;
for (unsigned long mask = 1UL << 15; mask; mask >>= 1) {
if (data & mask) {
length += HIGH_PAUSE_DURATION;
} else {
length += LOW_PAUSE_DURATION;
}
}
length += STOP_PAUSE_DURATION;
return length;
}
boolean next() {
messageBitIdx++;
if (messageBitIdx >= MESSAGE_BITS) {
repeatCount++;
messageBitIdx = 0;
}
if (repeatCount >= 1 && !repeatMessage) {
return false;
} else if (repeatCount >= 5) {
return false;
} else {
return true;
}
}
int getMarkDuration() const { return IR_MARK_DURATION; }
int getPauseDuration() const {
if (messageBitIdx == 0)
return START_PAUSE_DURATION;
else if (messageBitIdx < MESSAGE_BITS - 1) {
return getDataBitPause();
} else {
return getStopPause();
}
}
private:
int getDataBitPause() const {
const int pos = MESSAGE_BITS - 2 - messageBitIdx;
const bool isHigh = data & (1 << pos);
return isHigh ? HIGH_PAUSE_DURATION : LOW_PAUSE_DURATION;
}
int getStopPause() const {
if (repeatMessage) {
return getRepeatStopPause();
} else {
return STOP_PAUSE_DURATION;
}
}
int getRepeatStopPause() const {
if (repeatCount == 0 || repeatCount == 1) {
return STOP_PAUSE_DURATION + 5 * MAX_MESSAGE_LENGTH - messageLength;
} else if (repeatCount == 2 || repeatCount == 3) {
return STOP_PAUSE_DURATION
+ (6 + 2 * getChannelId()) * MAX_MESSAGE_LENGTH - messageLength;
} else {
return STOP_PAUSE_DURATION;
}
}
};

85
ir_Mitsubishi.cpp
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@@ -1,85 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// MMMMM IIIII TTTTT SSSS U U BBBB IIIII SSSS H H IIIII
// M M M I T S U U B B I S H H I
// M M M I T SSS U U BBBB I SSS HHHHH I
// M M I T S U U B B I S H H I
// M M IIIII T SSSS UUU BBBBB IIIII SSSS H H IIIII
//==============================================================================
// Looks like Sony except for timings, 48 chars of data and time/space different
#define MITSUBISHI_BITS 16
// Mitsubishi RM 75501
// 14200 7 41 7 42 7 42 7 17 7 17 7 18 7 41 7 18 7 17 7 17 7 18 7 41 8 17 7 17 7 18 7 17 7
// #define MITSUBISHI_HDR_MARK 250 // seen range 3500
#define MITSUBISHI_HDR_SPACE 350 // 7*50+100
#define MITSUBISHI_ONE_MARK 1950 // 41*50-100
#define MITSUBISHI_ZERO_MARK 750 // 17*50-100
// #define MITSUBISHI_DOUBLE_SPACE_USECS 800 // usually ssee 713 - not using ticks as get number wrapround
// #define MITSUBISHI_RPT_LENGTH 45000
//+=============================================================================
#if DECODE_MITSUBISHI
bool IRrecv::decodeMitsubishi (decode_results *results)
{
// Serial.print("?!? decoding Mitsubishi:");Serial.print(irparams.rawlen); Serial.print(" want "); Serial.println( 2 * MITSUBISHI_BITS + 2);
long data = 0;
if (irparams.rawlen < 2 * MITSUBISHI_BITS + 2) return false ;
int offset = 0; // Skip first space
// Initial space
#if 0
// Put this back in for debugging - note can't use #DEBUG as if Debug on we don't see the repeat cos of the delay
Serial.print("IR Gap: ");
Serial.println( results->rawbuf[offset]);
Serial.println( "test against:");
Serial.println(results->rawbuf[offset]);
#endif
#if 0
// Not seeing double keys from Mitsubishi
if (results->rawbuf[offset] < MITSUBISHI_DOUBLE_SPACE_USECS) {
// Serial.print("IR Gap found: ");
results->bits = 0;
results->value = REPEAT;
results->decode_type = MITSUBISHI;
return true;
}
#endif
offset++;
// Typical
// 14200 7 41 7 42 7 42 7 17 7 17 7 18 7 41 7 18 7 17 7 17 7 18 7 41 8 17 7 17 7 18 7 17 7
// Initial Space
if (!MATCH_MARK(results->rawbuf[offset], MITSUBISHI_HDR_SPACE)) return false ;
offset++;
while (offset + 1 < irparams.rawlen) {
if (MATCH_MARK(results->rawbuf[offset], MITSUBISHI_ONE_MARK)) data = (data << 1) | 1 ;
else if (MATCH_MARK(results->rawbuf[offset], MITSUBISHI_ZERO_MARK)) data <<= 1 ;
else return false ;
offset++;
if (!MATCH_SPACE(results->rawbuf[offset], MITSUBISHI_HDR_SPACE)) break ;
offset++;
}
// Success
results->bits = (offset - 1) / 2;
if (results->bits < MITSUBISHI_BITS) {
results->bits = 0;
return false;
}
results->value = data;
results->decode_type = MITSUBISHI;
return true;
}
#endif

98
ir_NEC.cpp
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@@ -1,98 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// N N EEEEE CCCC
// NN N E C
// N N N EEE C
// N NN E C
// N N EEEEE CCCC
//==============================================================================
#define NEC_BITS 32
#define NEC_HDR_MARK 9000
#define NEC_HDR_SPACE 4500
#define NEC_BIT_MARK 560
#define NEC_ONE_SPACE 1690
#define NEC_ZERO_SPACE 560
#define NEC_RPT_SPACE 2250
//+=============================================================================
#if SEND_NEC
void IRsend::sendNEC (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(38);
// Header
mark(NEC_HDR_MARK);
space(NEC_HDR_SPACE);
// Data
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
mark(NEC_BIT_MARK);
space(NEC_ONE_SPACE);
} else {
mark(NEC_BIT_MARK);
space(NEC_ZERO_SPACE);
}
}
// Footer
mark(NEC_BIT_MARK);
space(0); // Always end with the LED off
}
#endif
//+=============================================================================
// NECs have a repeat only 4 items long
//
#if DECODE_NEC
bool IRrecv::decodeNEC (decode_results *results)
{
long data = 0; // We decode in to here; Start with nothing
int offset = 1; // Index in to results; Skip first entry!?
// Check header "mark"
if (!MATCH_MARK(results->rawbuf[offset], NEC_HDR_MARK)) return false ;
offset++;
// Check for repeat
if ( (irparams.rawlen == 4)
&& MATCH_SPACE(results->rawbuf[offset ], NEC_RPT_SPACE)
&& MATCH_MARK (results->rawbuf[offset+1], NEC_BIT_MARK )
) {
results->bits = 0;
results->value = REPEAT;
results->decode_type = NEC;
return true;
}
// Check we have enough data
if (irparams.rawlen < (2 * NEC_BITS) + 4) return false ;
// Check header "space"
if (!MATCH_SPACE(results->rawbuf[offset], NEC_HDR_SPACE)) return false ;
offset++;
// Build the data
for (int i = 0; i < NEC_BITS; i++) {
// Check data "mark"
if (!MATCH_MARK(results->rawbuf[offset], NEC_BIT_MARK)) return false ;
offset++;
// Suppend this bit
if (MATCH_SPACE(results->rawbuf[offset], NEC_ONE_SPACE )) data = (data << 1) | 1 ;
else if (MATCH_SPACE(results->rawbuf[offset], NEC_ZERO_SPACE)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
// Success
results->bits = NEC_BITS;
results->value = data;
results->decode_type = NEC;
return true;
}
#endif

78
ir_Panasonic.cpp
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@@ -1,78 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// PPPP AAA N N AAA SSSS OOO N N IIIII CCCC
// P P A A NN N A A S O O NN N I C
// PPPP AAAAA N N N AAAAA SSS O O N N N I C
// P A A N NN A A S O O N NN I C
// P A A N N A A SSSS OOO N N IIIII CCCC
//==============================================================================
#define PANASONIC_BITS 48
#define PANASONIC_HDR_MARK 3502
#define PANASONIC_HDR_SPACE 1750
#define PANASONIC_BIT_MARK 502
#define PANASONIC_ONE_SPACE 1244
#define PANASONIC_ZERO_SPACE 400
//+=============================================================================
#if SEND_PANASONIC
void IRsend::sendPanasonic (unsigned int address, unsigned long data)
{
// Set IR carrier frequency
enableIROut(35);
// Header
mark(PANASONIC_HDR_MARK);
space(PANASONIC_HDR_SPACE);
// Address
for (unsigned long mask = 1UL << (16 - 1); mask; mask >>= 1) {
mark(PANASONIC_BIT_MARK);
if (address & mask) space(PANASONIC_ONE_SPACE) ;
else space(PANASONIC_ZERO_SPACE) ;
}
// Data
for (unsigned long mask = 1UL << (32 - 1); mask; mask >>= 1) {
mark(PANASONIC_BIT_MARK);
if (data & mask) space(PANASONIC_ONE_SPACE) ;
else space(PANASONIC_ZERO_SPACE) ;
}
// Footer
mark(PANASONIC_BIT_MARK);
space(0); // Always end with the LED off
}
#endif
//+=============================================================================
#if DECODE_PANASONIC
bool IRrecv::decodePanasonic (decode_results *results)
{
unsigned long long data = 0;
int offset = 1;
if (!MATCH_MARK(results->rawbuf[offset++], PANASONIC_HDR_MARK )) return false ;
if (!MATCH_MARK(results->rawbuf[offset++], PANASONIC_HDR_SPACE)) return false ;
// decode address
for (int i = 0; i < PANASONIC_BITS; i++) {
if (!MATCH_MARK(results->rawbuf[offset++], PANASONIC_BIT_MARK)) return false ;
if (MATCH_SPACE(results->rawbuf[offset],PANASONIC_ONE_SPACE )) data = (data << 1) | 1 ;
else if (MATCH_SPACE(results->rawbuf[offset],PANASONIC_ZERO_SPACE)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
results->value = (unsigned long)data;
results->address = (unsigned int)(data >> 32);
results->decode_type = PANASONIC;
results->bits = PANASONIC_BITS;
return true;
}
#endif

207
ir_RC5_RC6.cpp
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@@ -1,207 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//+=============================================================================
// Gets one undecoded level at a time from the raw buffer.
// The RC5/6 decoding is easier if the data is broken into time intervals.
// E.g. if the buffer has MARK for 2 time intervals and SPACE for 1,
// successive calls to getRClevel will return MARK, MARK, SPACE.
// offset and used are updated to keep track of the current position.
// t1 is the time interval for a single bit in microseconds.
// Returns -1 for error (measured time interval is not a multiple of t1).
//
#if (DECODE_RC5 || DECODE_RC6)
int IRrecv::getRClevel (decode_results *results, int *offset, int *used, int t1)
{
int width;
int val;
int correction;
int avail;
if (*offset >= results->rawlen) return SPACE ; // After end of recorded buffer, assume SPACE.
width = results->rawbuf[*offset];
val = ((*offset) % 2) ? MARK : SPACE;
correction = (val == MARK) ? MARK_EXCESS : - MARK_EXCESS;
if (MATCH(width, ( t1) + correction)) avail = 1 ;
else if (MATCH(width, (2*t1) + correction)) avail = 2 ;
else if (MATCH(width, (3*t1) + correction)) avail = 3 ;
else return -1 ;
(*used)++;
if (*used >= avail) {
*used = 0;
(*offset)++;
}
DBG_PRINTLN( (val == MARK) ? "MARK" : "SPACE" );
return val;
}
#endif
//==============================================================================
// RRRR CCCC 55555
// R R C 5
// RRRR C 5555
// R R C 5
// R R CCCC 5555
//
// NB: First bit must be a one (start bit)
//
#define MIN_RC5_SAMPLES 11
#define RC5_T1 889
#define RC5_RPT_LENGTH 46000
//+=============================================================================
#if SEND_RC5
void IRsend::sendRC5 (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(36);
// Start
mark(RC5_T1);
space(RC5_T1);
mark(RC5_T1);
// Data
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
space(RC5_T1); // 1 is space, then mark
mark(RC5_T1);
} else {
mark(RC5_T1);
space(RC5_T1);
}
}
space(0); // Always end with the LED off
}
#endif
//+=============================================================================
#if DECODE_RC5
bool IRrecv::decodeRC5 (decode_results *results)
{
int nbits;
long data = 0;
int used = 0;
int offset = 1; // Skip gap space
if (irparams.rawlen < MIN_RC5_SAMPLES + 2) return false ;
// Get start bits
if (getRClevel(results, &offset, &used, RC5_T1) != MARK) return false ;
if (getRClevel(results, &offset, &used, RC5_T1) != SPACE) return false ;
if (getRClevel(results, &offset, &used, RC5_T1) != MARK) return false ;
for (nbits = 0; offset < irparams.rawlen; nbits++) {
int levelA = getRClevel(results, &offset, &used, RC5_T1);
int levelB = getRClevel(results, &offset, &used, RC5_T1);
if ((levelA == SPACE) && (levelB == MARK )) data = (data << 1) | 1 ;
else if ((levelA == MARK ) && (levelB == SPACE)) data = (data << 1) | 0 ;
else return false ;
}
// Success
results->bits = nbits;
results->value = data;
results->decode_type = RC5;
return true;
}
#endif
//+=============================================================================
// RRRR CCCC 6666
// R R C 6
// RRRR C 6666
// R R C 6 6
// R R CCCC 666
//
// NB : Caller needs to take care of flipping the toggle bit
//
#define MIN_RC6_SAMPLES 1
#define RC6_HDR_MARK 2666
#define RC6_HDR_SPACE 889
#define RC6_T1 444
#define RC6_RPT_LENGTH 46000
#if SEND_RC6
void IRsend::sendRC6 (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(36);
// Header
mark(RC6_HDR_MARK);
space(RC6_HDR_SPACE);
// Start bit
mark(RC6_T1);
space(RC6_T1);
// Data
for (unsigned long i = 1, mask = 1UL << (nbits - 1); mask; i++, mask >>= 1) {
// The fourth bit we send is a "double width trailer bit"
int t = (i == 4) ? (RC6_T1 * 2) : (RC6_T1) ;
if (data & mask) {
mark(t);
space(t);
} else {
space(t);
mark(t);
}
}
space(0); // Always end with the LED off
}
#endif
//+=============================================================================
#if DECODE_RC6
bool IRrecv::decodeRC6 (decode_results *results)
{
int nbits;
long data = 0;
int used = 0;
int offset = 1; // Skip first space
if (results->rawlen < MIN_RC6_SAMPLES) return false ;
// Initial mark
if (!MATCH_MARK(results->rawbuf[offset++], RC6_HDR_MARK)) return false ;
if (!MATCH_SPACE(results->rawbuf[offset++], RC6_HDR_SPACE)) return false ;
// Get start bit (1)
if (getRClevel(results, &offset, &used, RC6_T1) != MARK) return false ;
if (getRClevel(results, &offset, &used, RC6_T1) != SPACE) return false ;
for (nbits = 0; offset < results->rawlen; nbits++) {
int levelA, levelB; // Next two levels
levelA = getRClevel(results, &offset, &used, RC6_T1);
if (nbits == 3) {
// T bit is double wide; make sure second half matches
if (levelA != getRClevel(results, &offset, &used, RC6_T1)) return false;
}
levelB = getRClevel(results, &offset, &used, RC6_T1);
if (nbits == 3) {
// T bit is double wide; make sure second half matches
if (levelB != getRClevel(results, &offset, &used, RC6_T1)) return false;
}
if ((levelA == MARK ) && (levelB == SPACE)) data = (data << 1) | 1 ; // inverted compared to RC5
else if ((levelA == SPACE) && (levelB == MARK )) data = (data << 1) | 0 ; // ...
else return false ; // Error
}
// Success
results->bits = nbits;
results->value = data;
results->decode_type = RC6;
return true;
}
#endif

92
ir_Samsung.cpp
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@@ -1,92 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// SSSS AAA MMM SSSS U U N N GGGG
// S A A M M M S U U NN N G
// SSS AAAAA M M M SSS U U N N N G GG
// S A A M M S U U N NN G G
// SSSS A A M M SSSS UUU N N GGG
//==============================================================================
#define SAMSUNG_BITS 32
#define SAMSUNG_HDR_MARK 5000
#define SAMSUNG_HDR_SPACE 5000
#define SAMSUNG_BIT_MARK 560
#define SAMSUNG_ONE_SPACE 1600
#define SAMSUNG_ZERO_SPACE 560
#define SAMSUNG_RPT_SPACE 2250
//+=============================================================================
#if SEND_SAMSUNG
void IRsend::sendSAMSUNG (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(38);
// Header
mark(SAMSUNG_HDR_MARK);
space(SAMSUNG_HDR_SPACE);
// Data
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
mark(SAMSUNG_BIT_MARK);
space(SAMSUNG_ONE_SPACE);
} else {
mark(SAMSUNG_BIT_MARK);
space(SAMSUNG_ZERO_SPACE);
}
}
// Footer
mark(SAMSUNG_BIT_MARK);
space(0); // Always end with the LED off
}
#endif
//+=============================================================================
// SAMSUNGs have a repeat only 4 items long
//
#if DECODE_SAMSUNG
bool IRrecv::decodeSAMSUNG (decode_results *results)
{
long data = 0;
int offset = 1; // Skip first space
// Initial mark
if (!MATCH_MARK(results->rawbuf[offset], SAMSUNG_HDR_MARK)) return false ;
offset++;
// Check for repeat
if ( (irparams.rawlen == 4)
&& MATCH_SPACE(results->rawbuf[offset], SAMSUNG_RPT_SPACE)
&& MATCH_MARK(results->rawbuf[offset+1], SAMSUNG_BIT_MARK)
) {
results->bits = 0;
results->value = REPEAT;
results->decode_type = SAMSUNG;
return true;
}
if (irparams.rawlen < (2 * SAMSUNG_BITS) + 4) return false ;
// Initial space
if (!MATCH_SPACE(results->rawbuf[offset++], SAMSUNG_HDR_SPACE)) return false ;
for (int i = 0; i < SAMSUNG_BITS; i++) {
if (!MATCH_MARK(results->rawbuf[offset++], SAMSUNG_BIT_MARK)) return false ;
if (MATCH_SPACE(results->rawbuf[offset], SAMSUNG_ONE_SPACE)) data = (data << 1) | 1 ;
else if (MATCH_SPACE(results->rawbuf[offset], SAMSUNG_ZERO_SPACE)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
// Success
results->bits = SAMSUNG_BITS;
results->value = data;
results->decode_type = SAMSUNG;
return true;
}
#endif

76
ir_Sanyo.cpp
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@@ -1,76 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// SSSS AAA N N Y Y OOO
// S A A NN N Y Y O O
// SSS AAAAA N N N Y O O
// S A A N NN Y O O
// SSSS A A N N Y OOO
//==============================================================================
// I think this is a Sanyo decoder: Serial = SA 8650B
// Looks like Sony except for timings, 48 chars of data and time/space different
#define SANYO_BITS 12
#define SANYO_HDR_MARK 3500 // seen range 3500
#define SANYO_HDR_SPACE 950 // seen 950
#define SANYO_ONE_MARK 2400 // seen 2400
#define SANYO_ZERO_MARK 700 // seen 700
#define SANYO_DOUBLE_SPACE_USECS 800 // usually ssee 713 - not using ticks as get number wrapround
#define SANYO_RPT_LENGTH 45000
//+=============================================================================
#if DECODE_SANYO
bool IRrecv::decodeSanyo (decode_results *results)
{
long data = 0;
int offset = 0; // Skip first space <-- CHECK THIS!
if (irparams.rawlen < (2 * SANYO_BITS) + 2) return false ;
#if 0
// Put this back in for debugging - note can't use #DEBUG as if Debug on we don't see the repeat cos of the delay
Serial.print("IR Gap: ");
Serial.println( results->rawbuf[offset]);
Serial.println( "test against:");
Serial.println(results->rawbuf[offset]);
#endif
// Initial space
if (results->rawbuf[offset] < SANYO_DOUBLE_SPACE_USECS) {
//Serial.print("IR Gap found: ");
results->bits = 0;
results->value = REPEAT;
results->decode_type = SANYO;
return true;
}
offset++;
// Initial mark
if (!MATCH_MARK(results->rawbuf[offset++], SANYO_HDR_MARK)) return false ;
// Skip Second Mark
if (!MATCH_MARK(results->rawbuf[offset++], SANYO_HDR_MARK)) return false ;
while (offset + 1 < irparams.rawlen) {
if (!MATCH_SPACE(results->rawbuf[offset++], SANYO_HDR_SPACE)) break ;
if (MATCH_MARK(results->rawbuf[offset], SANYO_ONE_MARK)) data = (data << 1) | 1 ;
else if (MATCH_MARK(results->rawbuf[offset], SANYO_ZERO_MARK)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
// Success
results->bits = (offset - 1) / 2;
if (results->bits < 12) {
results->bits = 0;
return false;
}
results->value = data;
results->decode_type = SANYO;
return true;
}
#endif

71
ir_Sharp.cpp
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@@ -1,71 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// SSSS H H AAA RRRR PPPP
// S H H A A R R P P
// SSS HHHHH AAAAA RRRR PPPP
// S H H A A R R P
// SSSS H H A A R R P
//==============================================================================
// Sharp and DISH support by Todd Treece: http://unionbridge.org/design/ircommand
//
// The send function has the necessary repeat built in because of the need to
// invert the signal.
//
// Sharp protocol documentation:
// http://www.sbprojects.com/knowledge/ir/sharp.htm
//
// Here is the LIRC file I found that seems to match the remote codes from the
// oscilloscope:
// Sharp LCD TV:
// http://lirc.sourceforge.net/remotes/sharp/GA538WJSA
#define SHARP_BITS 15
#define SHARP_BIT_MARK 245
#define SHARP_ONE_SPACE 1805
#define SHARP_ZERO_SPACE 795
#define SHARP_GAP 600000
#define SHARP_RPT_SPACE 3000
#define SHARP_TOGGLE_MASK 0x3FF
//+=============================================================================
#if SEND_SHARP
void IRsend::sendSharpRaw (unsigned long data, int nbits)
{
enableIROut(38);
// Sending codes in bursts of 3 (normal, inverted, normal) makes transmission
// much more reliable. That's the exact behaviour of CD-S6470 remote control.
for (int n = 0; n < 3; n++) {
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
mark(SHARP_BIT_MARK);
space(SHARP_ONE_SPACE);
} else {
mark(SHARP_BIT_MARK);
space(SHARP_ZERO_SPACE);
}
}
mark(SHARP_BIT_MARK);
space(SHARP_ZERO_SPACE);
delay(40);
data = data ^ SHARP_TOGGLE_MASK;
}
}
#endif
//+=============================================================================
// Sharp send compatible with data obtained through decodeSharp()
// ^^^^^^^^^^^^^ FUNCTION MISSING!
//
#if SEND_SHARP
void IRsend::sendSharp (unsigned int address, unsigned int command)
{
sendSharpRaw((address << 10) | (command << 2) | 2, SHARP_BITS);
}
#endif

95
ir_Sony.cpp
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@@ -1,95 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// SSSS OOO N N Y Y
// S O O NN N Y Y
// SSS O O N N N Y
// S O O N NN Y
// SSSS OOO N N Y
//==============================================================================
#define SONY_BITS 12
#define SONY_HDR_MARK 2400
#define SONY_HDR_SPACE 600
#define SONY_ONE_MARK 1200
#define SONY_ZERO_MARK 600
#define SONY_RPT_LENGTH 45000
#define SONY_DOUBLE_SPACE_USECS 500 // usually ssee 713 - not using ticks as get number wrapround
//+=============================================================================
#if SEND_SONY
void IRsend::sendSony (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(40);
// Header
mark(SONY_HDR_MARK);
space(SONY_HDR_SPACE);
// Data
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
mark(SONY_ONE_MARK);
space(SONY_HDR_SPACE);
} else {
mark(SONY_ZERO_MARK);
space(SONY_HDR_SPACE);
}
}
// We will have ended with LED off
}
#endif
//+=============================================================================
#if DECODE_SONY
bool IRrecv::decodeSony (decode_results *results)
{
long data = 0;
int offset = 0; // Dont skip first space, check its size
if (irparams.rawlen < (2 * SONY_BITS) + 2) return false ;
// Some Sony's deliver repeats fast after first
// unfortunately can't spot difference from of repeat from two fast clicks
if (results->rawbuf[offset] < SONY_DOUBLE_SPACE_USECS) {
// Serial.print("IR Gap found: ");
results->bits = 0;
results->value = REPEAT;
# ifdef DECODE_SANYO
results->decode_type = SANYO;
# else
results->decode_type = UNKNOWN;
# endif
return true;
}
offset++;
// Initial mark
if (!MATCH_MARK(results->rawbuf[offset++], SONY_HDR_MARK)) return false ;
while (offset + 1 < irparams.rawlen) {
if (!MATCH_SPACE(results->rawbuf[offset++], SONY_HDR_SPACE)) break ;
if (MATCH_MARK(results->rawbuf[offset], SONY_ONE_MARK)) data = (data << 1) | 1 ;
else if (MATCH_MARK(results->rawbuf[offset], SONY_ZERO_MARK)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
// Success
results->bits = (offset - 1) / 2;
if (results->bits < 12) {
results->bits = 0;
return false;
}
results->value = data;
results->decode_type = SONY;
return true;
}
#endif

179
ir_Template.cpp
View File

@@ -1,179 +0,0 @@
/*
Assuming the protocol we are adding is for the (imaginary) manufacturer: Shuzu
Our fantasy protocol is a standard protocol, so we can use this standard
template without too much work. Some protocols are quite unique and will require
considerably more work in this file! It is way beyond the scope of this text to
explain how to reverse engineer "unusual" IR protocols. But, unless you own an
oscilloscope, the starting point is probably to use the rawDump.ino sketch and
try to spot the pattern!
Before you start, make sure the IR library is working OK:
# Open up the Arduino IDE
# Load up the rawDump.ino example sketch
# Run it
Now we can start to add our new protocol...
1. Copy this file to : ir_Shuzu.cpp
2. Replace all occurrences of "Shuzu" with the name of your protocol.
3. Tweak the #defines to suit your protocol.
4. If you're lucky, tweaking the #defines will make the default send() function
work.
5. Again, if you're lucky, tweaking the #defines will have made the default
decode() function work.
You have written the code to support your new protocol!
Now you must do a few things to add it to the IRremote system:
1. Open IRremote.h and make the following changes:
REMEMEBER to change occurences of "SHUZU" with the name of your protocol
A. At the top, in the section "Supported Protocols", add:
#define DECODE_SHUZU 1
#define SEND_SHUZU 1
B. In the section "enumerated list of all supported formats", add:
SHUZU,
to the end of the list (notice there is a comma after the protocol name)
C. Further down in "Main class for receiving IR", add:
//......................................................................
#if DECODE_SHUZU
bool decodeShuzu (decode_results *results) ;
#endif
D. Further down in "Main class for sending IR", add:
//......................................................................
#if SEND_SHUZU
void sendShuzu (unsigned long data, int nbits) ;
#endif
E. Save your changes and close the file
2. Now open irRecv.cpp and make the following change:
A. In the function IRrecv::decode(), add:
#ifdef DECODE_NEC
DBG_PRINTLN("Attempting Shuzu decode");
if (decodeShuzu(results)) return true ;
#endif
B. Save your changes and close the file
You will probably want to add your new protocol to the example sketch
3. Open MyDocuments\Arduino\libraries\IRremote\examples\IRrecvDumpV2.ino
A. In the encoding() function, add:
case SHUZU: Serial.print("SHUZU"); break ;
Now open the Arduino IDE, load up the rawDump.ino sketch, and run it.
Hopefully it will compile and upload.
If it doesn't, you've done something wrong. Check your work.
If you can't get it to work - seek help from somewhere.
If you get this far, I will assume you have successfully added your new protocol
There is one last thing to do.
1. Delete this giant instructional comment.
2. Send a copy of your work to us so we can include it in the library and
others may benefit from your hard work and maybe even write a song about how
great you are for helping them! :)
Regards,
BlueChip
*/
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
//
//
// S H U Z U
//
//
//==============================================================================
#define BITS 32 // The number of bits in the command
#define HDR_MARK 1000 // The length of the Header:Mark
#define HDR_SPACE 2000 // The lenght of the Header:Space
#define BIT_MARK 3000 // The length of a Bit:Mark
#define ONE_SPACE 4000 // The length of a Bit:Space for 1's
#define ZERO_SPACE 5000 // The length of a Bit:Space for 0's
#define OTHER 1234 // Other things you may need to define
//+=============================================================================
//
#if SEND_SHUZU
void IRsend::sendShuzu (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(38);
// Header
mark (HDR_MARK);
space(HDR_SPACE);
// Data
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
mark (BIT_MARK);
space(ONE_SPACE);
} else {
mark (BIT_MARK);
space(ZERO_SPACE);
}
}
// Footer
mark(BIT_MARK);
space(0); // Always end with the LED off
}
#endif
//+=============================================================================
//
#if DECODE_SHUZU
bool IRrecv::decodeShuzu (decode_results *results)
{
unsigned long data = 0; // Somewhere to build our code
int offset = 1; // Skip the Gap reading
// Check we have the right amount of data
if (irparams.rawlen != 1 + 2 + (2 * BITS) + 1) return false ;
// Check initial Mark+Space match
if (!MATCH_MARK (results->rawbuf[offset++], HDR_MARK )) return false ;
if (!MATCH_SPACE(results->rawbuf[offset++], HDR_SPACE)) return false ;
// Read the bits in
for (int i = 0; i < SHUZU_BITS; i++) {
// Each bit looks like: MARK + SPACE_1 -> 1
// or : MARK + SPACE_0 -> 0
if (!MATCH_MARK(results->rawbuf[offset++], BIT_MARK)) return false ;
// IR data is big-endian, so we shuffle it in from the right:
if (MATCH_SPACE(results->rawbuf[offset], ONE_SPACE)) data = (data << 1) | 1 ;
else if (MATCH_SPACE(results->rawbuf[offset], ZERO_SPACE)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
// Success
results->bits = BITS;
results->value = data;
results->decode_type = SHUZU;
return true;
}
#endif

91
ir_Whynter.cpp
View File

@@ -1,91 +0,0 @@
#include "IRremote.h"
#include "IRremoteInt.h"
//==============================================================================
// W W H H Y Y N N TTTTT EEEEE RRRRR
// W W H H Y Y NN N T E R R
// W W W HHHHH Y N N N T EEE RRRR
// W W W H H Y N NN T E R R
// WWW H H Y N N T EEEEE R R
//==============================================================================
#define WHYNTER_BITS 32
#define WHYNTER_HDR_MARK 2850
#define WHYNTER_HDR_SPACE 2850
#define WHYNTER_BIT_MARK 750
#define WHYNTER_ONE_MARK 750
#define WHYNTER_ONE_SPACE 2150
#define WHYNTER_ZERO_MARK 750
#define WHYNTER_ZERO_SPACE 750
//+=============================================================================
#if SEND_WHYNTER
void IRsend::sendWhynter (unsigned long data, int nbits)
{
// Set IR carrier frequency
enableIROut(38);
// Start
mark(WHYNTER_ZERO_MARK);
space(WHYNTER_ZERO_SPACE);
// Header
mark(WHYNTER_HDR_MARK);
space(WHYNTER_HDR_SPACE);
// Data
for (unsigned long mask = 1UL << (nbits - 1); mask; mask >>= 1) {
if (data & mask) {
mark(WHYNTER_ONE_MARK);
space(WHYNTER_ONE_SPACE);
} else {
mark(WHYNTER_ZERO_MARK);
space(WHYNTER_ZERO_SPACE);
}
}
// Footer
mark(WHYNTER_ZERO_MARK);
space(WHYNTER_ZERO_SPACE); // Always end with the LED off
}
#endif
//+=============================================================================
#if DECODE_WHYNTER
bool IRrecv::decodeWhynter (decode_results *results)
{
long data = 0;
int offset = 1; // skip initial space
// Check we have the right amount of data
if (irparams.rawlen < (2 * WHYNTER_BITS) + 6) return false ;
// Sequence begins with a bit mark and a zero space
if (!MATCH_MARK (results->rawbuf[offset++], WHYNTER_BIT_MARK )) return false ;
if (!MATCH_SPACE(results->rawbuf[offset++], WHYNTER_ZERO_SPACE)) return false ;
// header mark and space
if (!MATCH_MARK (results->rawbuf[offset++], WHYNTER_HDR_MARK )) return false ;
if (!MATCH_SPACE(results->rawbuf[offset++], WHYNTER_HDR_SPACE)) return false ;
// data bits
for (int i = 0; i < WHYNTER_BITS; i++) {
if (!MATCH_MARK(results->rawbuf[offset++], WHYNTER_BIT_MARK)) return false ;
if (MATCH_SPACE(results->rawbuf[offset], WHYNTER_ONE_SPACE )) data = (data << 1) | 1 ;
else if (MATCH_SPACE(results->rawbuf[offset], WHYNTER_ZERO_SPACE)) data = (data << 1) | 0 ;
else return false ;
offset++;
}
// trailing mark
if (!MATCH_MARK(results->rawbuf[offset], WHYNTER_BIT_MARK)) return false ;
// Success
results->bits = WHYNTER_BITS;
results->value = data;
results->decode_type = WHYNTER;
return true;
}
#endif