// Copyright 2009 Ken Shirriff // Copyright 2017 David Conran /// @file /// @brief RC-5 & RC-6 support /// RC-5 & RC-6 support added from https://github.com/z3t0/Arduino-IRremote /// RC-5X support added by David Conran /// @see https://en.wikipedia.org/wiki/RC-5 /// @see http://www.sbprojects.net/knowledge/ir/rc5.php /// @see https://en.wikipedia.org/wiki/Manchester_code /// @see https://en.wikipedia.org/wiki/RC-6 /// @see https://www.sbprojects.net/knowledge/ir/rc6.php /// @see http://www.pcbheaven.com/userpages/The_Philips_RC6_Protocol/ /// @see http://www.righto.com/2010/12/64-bit-rc6-codes-arduino-and-xbox.html // Supports: // Brand: Philips, Model: Standard RC-5 (RC5) // Brand: Philips, Model: RC-5X (RC5X) // Brand: Philips, Model: Standard RC-6 (RC6) #include #include "IRrecv.h" #include "IRsend.h" #include "IRtimer.h" #include "IRutils.h" // Constants // RC-5/RC-5X const uint16_t kRc5T1 = 889; const uint32_t kRc5MinCommandLength = 113778; const uint32_t kRc5MinGap = kRc5MinCommandLength - kRC5RawBits * (2 * kRc5T1); const uint16_t kRc5ToggleMask = 0x800; // The 12th bit. const uint16_t kRc5SamplesMin = 11; // RC-6 const uint16_t kRc6Tick = 444; const uint16_t kRc6HdrMarkTicks = 6; const uint16_t kRc6HdrMark = kRc6HdrMarkTicks * kRc6Tick; const uint16_t kRc6HdrSpaceTicks = 2; const uint16_t kRc6HdrSpace = kRc6HdrSpaceTicks * kRc6Tick; const uint16_t kRc6RptLengthTicks = 187; const uint32_t kRc6RptLength = kRc6RptLengthTicks * kRc6Tick; const uint32_t kRc6ToggleMask = 0x10000UL; // The 17th bit. const uint16_t kRc6_36ToggleMask = 0x8000; // The 16th bit. // Common (getRClevel()) const int16_t kMark = 0; const int16_t kSpace = 1; #if SEND_RC5 /// Send a Philips RC-5/RC-5X packet. /// Status: RC-5 (stable), RC-5X (alpha) /// @param[in] data The message to be sent. /// @param[in] nbits The number of bits of message to be sent. /// @param[in] repeat The number of times the command is to be repeated. /// @note Caller needs to take care of flipping the toggle bit. /// That bit differentiates between key press & key release. /// For RC-5 it is the MSB of the data. /// For RC-5X it is the 2nd MSB of the data. /// @todo Testing of the RC-5X components. void IRsend::sendRC5(const uint64_t data, uint16_t nbits, const uint16_t repeat) { if (nbits > sizeof(data) * 8) return; // We can't send something that big. bool skipSpace = true; bool field_bit = true; // Set 36kHz IR carrier frequency & a 1/4 (25%) duty cycle. enableIROut(36, 25); if (nbits >= kRC5XBits) { // Is this a RC-5X message? // field bit is the inverted MSB of RC-5X data. field_bit = ((data >> (nbits - 1)) ^ 1) & 1; nbits--; } IRtimer usecTimer = IRtimer(); for (uint16_t i = 0; i <= repeat; i++) { usecTimer.reset(); // Header // First start bit (0x1). space, then mark. if (skipSpace) skipSpace = false; // First time through, we assume the leading space(). else space(kRc5T1); mark(kRc5T1); // Field/Second start bit. if (field_bit) { // Send a 1. Normal for RC-5. space(kRc5T1); mark(kRc5T1); } else { // Send a 0. Special case for RC-5X. Means 7th command bit is 1. mark(kRc5T1); space(kRc5T1); } // Data for (uint64_t mask = 1ULL << (nbits - 1); mask; mask >>= 1) if (data & mask) { // 1 space(kRc5T1); // 1 is space, then mark. mark(kRc5T1); } else { // 0 mark(kRc5T1); // 0 is mark, then space. space(kRc5T1); } // Footer space(std::max(kRc5MinGap, kRc5MinCommandLength - usecTimer.elapsed())); } } /// Encode a Philips RC-5 data message. /// Status: Beta / Should be working. /// @param[in] address The 5-bit address value for the message. /// @param[in] command The 6-bit command value for the message. /// @param[in] key_released Indicate if the remote key has been released. /// @return A message suitable for use in sendRC5(). uint16_t IRsend::encodeRC5(const uint8_t address, const uint8_t command, const bool key_released) { return (key_released << (kRC5Bits - 1)) | ((address & 0x1f) << 6) | (command & 0x3F); } /// Encode a Philips RC-5X data message. /// Status: Beta / Should be working. /// @param[in] address The 5-bit address value for the message. /// @param[in] command The 7-bit command value for the message. /// @param[in] key_released Indicate if the remote key has been released. /// @return A message suitable for use in sendRC5(). uint16_t IRsend::encodeRC5X(const uint8_t address, const uint8_t command, const bool key_released) { // The 2nd start/field bit (MSB of the return value) is the value of the 7th // command bit. bool s2 = (command >> 6) & 1; return ((uint16_t)s2 << (kRC5XBits - 1)) | encodeRC5(address, command, key_released); } /// Flip the toggle bit of a Philips RC-5/RC-5X data message. /// Used to indicate a change of remote button's state. /// Status: STABLE. /// @param[in] data The existing RC-5/RC-5X message. /// @return A data message suitable for use in sendRC5() with the toggle bit /// flipped. uint64_t IRsend::toggleRC5(const uint64_t data) { return data ^ kRc5ToggleMask; } #endif // SEND_RC5 #if SEND_RC6 /// Flip the toggle bit of a Philips RC-6 data message. /// Used to indicate a change of remote button's state. /// Status: STABLE / Should work fine. /// @param[in] data The existing RC-6 message. /// @param [in] nbits Nr. of bits in the RC-6 protocol. /// @return A data message suitable for use in sendRC6() with the toggle bit /// flipped. /// @note For RC-6 (20-bits), it is the 17th least significant bit. /// @note For RC-6 (36-bits/Xbox-360), it is the 16th least significant bit. uint64_t IRsend::toggleRC6(const uint64_t data, const uint16_t nbits) { if (nbits == kRC6_36Bits) return data ^ kRc6_36ToggleMask; return data ^ kRc6ToggleMask; } /// Encode a Philips RC-6 data message. /// Status: Beta / Should be working. /// @param[in] address The address (aka. control) value for the message. /// Includes the field/mode/toggle bits. /// @param[in] command The 8-bit command value for the message. /// (aka. information) /// @param[in] mode Which protocol to use. /// Defined by nr. of bits in the protocol. /// @return A data message suitable for use in `sendRC6()`. uint64_t IRsend::encodeRC6(const uint32_t address, const uint8_t command, const uint16_t mode) { switch (mode) { case kRC6Mode0Bits: return ((address & 0xFFF) << 8) | (command & 0xFF); case kRC6_36Bits: return ((uint64_t)(address & 0xFFFFFFF) << 8) | (command & 0xFF); default: return 0; } } /// Send a Philips RC-6 packet. /// Status: Stable. /// @note Caller needs to take care of flipping the toggle bit (The 4th Most /// Significant Bit). That bit differentiates between key press & key release. /// @param[in] data The message to be sent. /// @param[in] nbits The number of bits of message to be sent. /// @param[in] repeat The number of times the command is to be repeated. void IRsend::sendRC6(const uint64_t data, const uint16_t nbits, const uint16_t repeat) { // Check we can send the number of bits requested. if (nbits > sizeof(data) * 8) return; // Set 36kHz IR carrier frequency & a 1/3 (33%) duty cycle. enableIROut(36, 33); for (uint16_t r = 0; r <= repeat; r++) { // Header mark(kRc6HdrMark); space(kRc6HdrSpace); // Start bit. mark(kRc6Tick); // mark, then space == 0x1. space(kRc6Tick); // Data uint16_t bitTime; for (uint64_t i = 1, mask = 1ULL << (nbits - 1); mask; i++, mask >>= 1) { if (i == 4) // The fourth bit we send is a "double width trailer bit". bitTime = 2 * kRc6Tick; // double-wide trailer bit else bitTime = kRc6Tick; // Normal bit if (data & mask) { // 1 mark(bitTime); space(bitTime); } else { // 0 space(bitTime); mark(bitTime); } } // Footer space(kRc6RptLength); } } #endif // SEND_RC6 #if (DECODE_RC5 || DECODE_RC6 || DECODE_LASERTAG) /// 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. /// @param[in,out] results Ptr to the data to decode and where to store the /// decode result. /// @param[in,out] offset Ptr to the currect offset to the rawbuf. /// @param[in,out] used Ptr to the current used counter. /// @param[in] bitTime Time interval of single bit in microseconds. /// @param[in] tolerance Percent tolerance to be used in matching. /// @param[in] excess Extra useconds to add to Marks & removed from Spaces. /// @param[in] delta A non-scaling (+/-) error margin (in useconds). /// @param[in] maxwidth Maximum number of successive levels to find in a single /// level (default is 3) /// @return MARK, SPACE, or -1 for error. /// (The measured time interval is not a multiple of t1.) /// @see https://en.wikipedia.org/wiki/Manchester_code int16_t IRrecv::getRClevel(decode_results *results, uint16_t *offset, uint16_t *used, const uint16_t bitTime, const uint8_t tolerance, const int16_t excess, const uint16_t delta, const uint8_t maxwidth) { DPRINT("DEBUG: getRClevel: offset = "); DPRINTLN(uint64ToString(*offset)); DPRINT("DEBUG: getRClevel: rawlen = "); DPRINTLN(uint64ToString(results->rawlen)); if (*offset >= results->rawlen) { DPRINTLN("DEBUG: getRClevel: SPACE, past end of rawbuf"); return kSpace; // After end of recorded buffer, assume SPACE. } uint16_t width = results->rawbuf[*offset]; // If the value of offset is odd, it's a MARK. Even, it's a SPACE. uint16_t val = ((*offset) % 2) ? kMark : kSpace; // Check to see if we have hit an inter-message gap (> 20ms). if (val == kSpace && (width > 20000 - delta || width > maxwidth * bitTime + delta)) { DPRINTLN("DEBUG: getRClevel: SPACE, hit end of mesg gap."); return kSpace; } int16_t correction = (val == kMark) ? excess : -excess; // Calculate the look-ahead for our current position in the buffer. uint16_t avail; // Note: We want to match in greedy order as the other way leads to // mismatches due to overlaps induced by the correction and tolerance // values. for (avail = maxwidth; avail > 0; avail--) { if (match(width, avail * bitTime + correction, tolerance, delta)) { break; } } if (!avail) { DPRINTLN("DEBUG: getRClevel: Unexpected width. Exiting."); return -1; // The width is not what we expected. } (*used)++; // Count another one of the avail slots as used. if (*used >= avail) { // Are we out of look-ahead/avail slots? // Yes, so reset the used counter, and move the offset ahead. *used = 0; (*offset)++; } if (val == kMark) { DPRINTLN("DEBUG: getRClevel: MARK"); } else { DPRINTLN("DEBUG: getRClevel: SPACE"); } return val; } #endif // (DECODE_RC5 || DECODE_RC6 || DECODE_LASERTAG) #if DECODE_RC5 /// Decode the supplied RC-5/RC5X message. /// Status: RC-5 (stable), RC-5X (alpha) /// @param[in,out] results Ptr to the data to decode & where to store the result /// @param[in] offset The starting index to use when attempting to decode the /// raw data. Typically/Defaults to kStartOffset. /// @param[in] nbits The number of data bits to expect. /// @param[in] strict Flag indicating if we should perform strict matching. /// @return True if it can decode it, false if it can't. /// @note The 'toggle' bit is included as the 6th (MSB) address bit, the MSB of /// data, & in the count of bits decoded. /// @todo Serious testing of the RC-5X and strict aspects needs to be done. bool IRrecv::decodeRC5(decode_results *results, uint16_t offset, const uint16_t nbits, const bool strict) { if (results->rawlen <= kRc5SamplesMin + kHeader - 1 + offset) return false; // Compliance if (strict && nbits != kRC5Bits && nbits != kRC5XBits) return false; // It's neither RC-5 or RC-5X. uint16_t used = 0; bool is_rc5x = false; uint64_t data = 0; // Header // Get start bit #1. if (getRClevel(results, &offset, &used, kRc5T1) != kMark) return false; // Get field/start bit #2 (inverted bit-7 of the command if RC-5X protocol) uint16_t actual_bits = 1; int16_t levelA = getRClevel(results, &offset, &used, kRc5T1); int16_t levelB = getRClevel(results, &offset, &used, kRc5T1); if (levelA == kSpace && levelB == kMark) { // Matched a 1. is_rc5x = false; } else if (levelA == kMark && levelB == kSpace) { // Matched a 0. if (nbits <= kRC5Bits) return false; // Field bit must be '1' for RC5. is_rc5x = true; data = 1; } else { return false; // Not what we expected. } // Data for (; offset < results->rawlen; actual_bits++) { int16_t levelA = getRClevel(results, &offset, &used, kRc5T1); int16_t levelB = getRClevel(results, &offset, &used, kRc5T1); if (levelA == kSpace && levelB == kMark) data = (data << 1) | 1; // 1 else if (levelA == kMark && levelB == kSpace) data <<= 1; // 0 else break; } // Footer (None) // Compliance if (actual_bits < nbits) return false; // Less data than we expected. if (strict && actual_bits != kRC5Bits && actual_bits != kRC5XBits) return false; // Success results->value = data; results->address = (data >> 6) & 0x1F; results->command = data & 0x3F; results->repeat = false; if (is_rc5x) { results->decode_type = RC5X; results->command |= ((uint32_t)is_rc5x) << 6; } else { results->decode_type = RC5; actual_bits--; // RC5 doesn't count the field bit as data. } results->bits = actual_bits; return true; } #endif // DECODE_RC5 #if DECODE_RC6 /// Decode the supplied RC6 message. /// Status: Stable. /// @param[in,out] results Ptr to the data to decode & where to store the result /// @param[in] offset The starting index to use when attempting to decode the /// raw data. Typically/Defaults to kStartOffset. /// @param[in] nbits The number of data bits to expect. /// @param[in] strict Flag indicating if we should perform strict matching. /// @return True if it can decode it, false if it can't. /// @todo Testing of the strict compliance aspects. bool IRrecv::decodeRC6(decode_results *results, uint16_t offset, const uint16_t nbits, const bool strict) { if (results->rawlen <= kHeader + 2 + 4 + offset) // Up to the double-wide T bit. return false; // Smaller than absolute smallest possible RC6 message. if (strict) { // Compliance // Unlike typical protocols, the ability to have mark+space, and space+mark // as data bits means it is possible to only have nbits of entries for the // data portion, rather than the typically required 2 * nbits. // Also due to potential melding with the start bit, we can only count // the start bit as 1, instead of a more typical 2 value. The header still // remains as normal. if (results->rawlen <= nbits + kHeader + 1 + offset) return false; // Don't have enough entries/samples to be valid. switch (nbits) { case kRC6Mode0Bits: case kRC6_36Bits: break; default: return false; // Asking for the wrong number of bits. } } // Header if (!matchMark(results->rawbuf[offset], kRc6HdrMark)) return false; // Calculate how long the common tick time is based on the header mark. uint32_t tick = results->rawbuf[offset++] * kRawTick / kRc6HdrMarkTicks; if (!matchSpace(results->rawbuf[offset++], kRc6HdrSpaceTicks * tick)) return false; uint16_t used = 0; // Get the start bit. e.g. 1. if (getRClevel(results, &offset, &used, tick) != kMark) return false; if (getRClevel(results, &offset, &used, tick) != kSpace) return false; uint16_t actual_bits; uint64_t data = 0; // Data (Warning: Here be dragons^Wpointers!!) for (actual_bits = 0; offset < results->rawlen; actual_bits++) { int16_t levelA, levelB; // Next two levels levelA = getRClevel(results, &offset, &used, tick); // T bit is double wide; make sure second half matches if (actual_bits == 3 && levelA != getRClevel(results, &offset, &used, tick)) return false; levelB = getRClevel(results, &offset, &used, tick); // T bit is double wide; make sure second half matches if (actual_bits == 3 && levelB != getRClevel(results, &offset, &used, tick)) return false; if (levelA == kMark && levelB == kSpace) // reversed compared to RC5 data = (data << 1) | 1; // 1 else if (levelA == kSpace && levelB == kMark) data <<= 1; // 0 else break; } // More compliance if (strict && actual_bits != nbits) return false; // Actual nr. of bits didn't match expected. // Success results->decode_type = RC6; results->bits = actual_bits; results->value = data; results->address = data >> 8; results->command = data & 0xFF; return true; } #endif // DECODE_RC6