// Copyright 2017 Jonny Graham // Copyright 2017-2019 David Conran #include "ir_Fujitsu.h" #include #ifndef ARDUINO #include #endif #include "IRsend.h" #include "IRtext.h" #include "IRutils.h" // Fujitsu A/C support added by Jonny Graham & David Conran // Equipment it seems compatible with: // * Fujitsu ASYG30LFCA with remote AR-RAH2E // * Fujitsu AST9RSGCW with remote AR-DB1 // * Fujitsu ASYG7LMCA with remote AR-REB1E // * Fujitsu AR-RAE1E remote. // * Fujitsu General with remote AR-JW2 // * // Ref: // These values are based on averages of measurements const uint16_t kFujitsuAcHdrMark = 3324; const uint16_t kFujitsuAcHdrSpace = 1574; const uint16_t kFujitsuAcBitMark = 448; const uint16_t kFujitsuAcOneSpace = 1182; const uint16_t kFujitsuAcZeroSpace = 390; const uint16_t kFujitsuAcMinGap = 8100; using irutils::addBoolToString; using irutils::addIntToString; using irutils::addLabeledString; using irutils::addModeToString; using irutils::addModelToString; using irutils::addFanToString; using irutils::addTempToString; using irutils::setBit; using irutils::setBits; #if SEND_FUJITSU_AC // Send a Fujitsu A/C message. // // Args: // data: An array of bytes containing the IR command. // nbytes: Nr. of bytes of data in the array. Typically one of: // kFujitsuAcStateLength // kFujitsuAcStateLength - 1 // kFujitsuAcStateLengthShort // kFujitsuAcStateLengthShort - 1 // repeat: Nr. of times the message is to be repeated. // (Default = kFujitsuAcMinRepeat). // // Status: STABLE / Known Good. // void IRsend::sendFujitsuAC(const unsigned char data[], const uint16_t nbytes, const uint16_t repeat) { sendGeneric(kFujitsuAcHdrMark, kFujitsuAcHdrSpace, kFujitsuAcBitMark, kFujitsuAcOneSpace, kFujitsuAcBitMark, kFujitsuAcZeroSpace, kFujitsuAcBitMark, kFujitsuAcMinGap, data, nbytes, 38, false, repeat, 50); } #endif // SEND_FUJITSU_AC // Code to emulate Fujitsu A/C IR remote control unit. // Initialise the object. IRFujitsuAC::IRFujitsuAC(const uint16_t pin, const fujitsu_ac_remote_model_t model, const bool inverted, const bool use_modulation) : _irsend(pin, inverted, use_modulation) { this->setModel(model); this->stateReset(); } void IRFujitsuAC::setModel(const fujitsu_ac_remote_model_t model) { _model = model; switch (model) { case fujitsu_ac_remote_model_t::ARDB1: case fujitsu_ac_remote_model_t::ARJW2: _state_length = kFujitsuAcStateLength - 1; _state_length_short = kFujitsuAcStateLengthShort - 1; break; case fujitsu_ac_remote_model_t::ARRY4: case fujitsu_ac_remote_model_t::ARRAH2E: case fujitsu_ac_remote_model_t::ARREB1E: default: _state_length = kFujitsuAcStateLength; _state_length_short = kFujitsuAcStateLengthShort; } } fujitsu_ac_remote_model_t IRFujitsuAC::getModel(void) { return _model; } // Reset the state of the remote to a known good state/sequence. void IRFujitsuAC::stateReset(void) { _temp = 24; _fanSpeed = kFujitsuAcFanHigh; _mode = kFujitsuAcModeCool; _swingMode = kFujitsuAcSwingBoth; _cmd = kFujitsuAcCmdTurnOn; _filter = false; _clean = false; this->buildState(); } // Configure the pin for output. void IRFujitsuAC::begin(void) { _irsend.begin(); } #if SEND_FUJITSU_AC // Send the current desired state to the IR LED. void IRFujitsuAC::send(const uint16_t repeat) { this->buildState(); _irsend.sendFujitsuAC(remote_state, getStateLength(), repeat); } #endif // SEND_FUJITSU_AC void IRFujitsuAC::buildState(void) { remote_state[0] = 0x14; remote_state[1] = 0x63; remote_state[2] = 0x00; remote_state[3] = 0x10; remote_state[4] = 0x10; bool fullCmd = false; switch (_cmd) { case kFujitsuAcCmdTurnOff: // 0x02 case kFujitsuAcCmdEcono: // 0x09 case kFujitsuAcCmdPowerful: // 0x39 case kFujitsuAcCmdStepVert: // 0x6C case kFujitsuAcCmdToggleSwingVert: // 0x6D case kFujitsuAcCmdStepHoriz: // 0x79 case kFujitsuAcCmdToggleSwingHoriz: // 0x7A remote_state[5] = _cmd; break; default: switch (_model) { case fujitsu_ac_remote_model_t::ARRY4: case fujitsu_ac_remote_model_t::ARRAH2E: case fujitsu_ac_remote_model_t::ARREB1E: remote_state[5] = 0xFE; break; case fujitsu_ac_remote_model_t::ARDB1: case fujitsu_ac_remote_model_t::ARJW2: remote_state[5] = 0xFC; break; } fullCmd = true; break; } if (fullCmd) { // long codes uint8_t tempByte = _temp - kFujitsuAcMinTemp; // Nr. of bytes in the message after this byte. remote_state[6] = _state_length - 7; remote_state[7] = 0x30; remote_state[8] = (_cmd == kFujitsuAcCmdTurnOn) | (tempByte << 4); remote_state[9] = _mode | 0 << 4; // timer off remote_state[10] = _fanSpeed; remote_state[11] = 0; // timerOff values remote_state[12] = 0; // timerOff/On values remote_state[13] = 0; // timerOn values switch (_model) { case fujitsu_ac_remote_model_t::ARRY4: remote_state[14] = _filter << 3; remote_state[9] |= (_clean << 3); break; default: remote_state[14] = 0; } uint8_t checksum = 0; uint8_t checksum_complement = 0; switch (_model) { case fujitsu_ac_remote_model_t::ARDB1: case fujitsu_ac_remote_model_t::ARJW2: checksum = sumBytes(remote_state, _state_length - 1); checksum_complement = 0x9B; break; case fujitsu_ac_remote_model_t::ARREB1E: setBit(&remote_state[14], kFujitsuAcOutsideQuietOffset, _outsideQuiet); // FALL THRU case fujitsu_ac_remote_model_t::ARRAH2E: case fujitsu_ac_remote_model_t::ARRY4: setBit(&remote_state[14], 5); // |= 0b00100000 setBits(&remote_state[10], kHighNibble, kFujitsuAcSwingSize, _swingMode); // FALL THRU default: checksum = sumBytes(remote_state + _state_length_short, _state_length - _state_length_short - 1); } // and negate the checksum and store it in the last byte. remote_state[_state_length - 1] = checksum_complement - checksum; } else { // short codes switch (_model) { case fujitsu_ac_remote_model_t::ARRY4: case fujitsu_ac_remote_model_t::ARRAH2E: case fujitsu_ac_remote_model_t::ARREB1E: // The last byte is the inverse of penultimate byte remote_state[_state_length_short - 1] = ~remote_state[_state_length_short - 2]; break; default: {}; // We don't need to do anything for the others. } // Zero the rest of the state. for (uint8_t i = _state_length_short; i < kFujitsuAcStateLength; i++) remote_state[i] = 0; } } uint8_t IRFujitsuAC::getStateLength(void) { this->buildState(); // Force an update of the internal state. if (((_model == fujitsu_ac_remote_model_t::ARRAH2E || _model == fujitsu_ac_remote_model_t::ARREB1E || _model == fujitsu_ac_remote_model_t::ARRY4) && remote_state[5] != 0xFE) || ((_model == fujitsu_ac_remote_model_t::ARDB1 || _model == fujitsu_ac_remote_model_t::ARJW2) && remote_state[5] != 0xFC)) return _state_length_short; else return _state_length; } // Return a pointer to the internal state date of the remote. uint8_t* IRFujitsuAC::getRaw(void) { this->buildState(); return remote_state; } void IRFujitsuAC::buildFromState(const uint16_t length) { switch (length) { case kFujitsuAcStateLength - 1: case kFujitsuAcStateLengthShort - 1: this->setModel(fujitsu_ac_remote_model_t::ARDB1); // ARJW2 has horizontal swing. if (this->getSwing(true) > kFujitsuAcSwingVert) this->setModel(fujitsu_ac_remote_model_t::ARJW2); break; default: switch (this->getCmd(true)) { case kFujitsuAcCmdEcono: case kFujitsuAcCmdPowerful: this->setModel(fujitsu_ac_remote_model_t::ARREB1E); break; default: this->setModel(fujitsu_ac_remote_model_t::ARRAH2E); } } switch (remote_state[6]) { case 8: if (this->getModel() != fujitsu_ac_remote_model_t::ARJW2) this->setModel(fujitsu_ac_remote_model_t::ARDB1); break; case 9: if (this->getModel() != fujitsu_ac_remote_model_t::ARREB1E) this->setModel(fujitsu_ac_remote_model_t::ARRAH2E); break; } setTemp((remote_state[8] >> 4) + kFujitsuAcMinTemp); if (GETBIT8(remote_state[8], 0)) setCmd(kFujitsuAcCmdTurnOn); else setCmd(kFujitsuAcCmdStayOn); setMode(GETBITS8(remote_state[9], kLowNibble, kModeBitsSize)); setFanSpeed(GETBITS8(remote_state[10], kLowNibble, kFujitsuAcFanSize)); setSwing(GETBITS8(remote_state[10], kHighNibble, kFujitsuAcSwingSize)); setClean(getClean(true)); setFilter(getFilter(true)); // Currently the only way we know how to tell ARRAH2E & ARRY4 apart is if // either the raw Filter or Clean setting is on. if (getModel() == fujitsu_ac_remote_model_t::ARRAH2E && (getFilter(true) || getClean(true))) setModel(fujitsu_ac_remote_model_t::ARRY4); switch (remote_state[5]) { case kFujitsuAcCmdTurnOff: case kFujitsuAcCmdStepHoriz: case kFujitsuAcCmdToggleSwingHoriz: case kFujitsuAcCmdStepVert: case kFujitsuAcCmdToggleSwingVert: case kFujitsuAcCmdEcono: case kFujitsuAcCmdPowerful: setCmd(remote_state[5]); break; } _outsideQuiet = this->getOutsideQuiet(true); } bool IRFujitsuAC::setRaw(const uint8_t newState[], const uint16_t length) { if (length > kFujitsuAcStateLength) return false; for (uint16_t i = 0; i < kFujitsuAcStateLength; i++) { if (i < length) remote_state[i] = newState[i]; else remote_state[i] = 0; } buildFromState(length); return true; } void IRFujitsuAC::stepHoriz(void) { this->setCmd(kFujitsuAcCmdStepHoriz); } void IRFujitsuAC::toggleSwingHoriz(const bool update) { // Toggle the current setting. if (update) this->setSwing(this->getSwing() ^ kFujitsuAcSwingHoriz); // and set the appropriate special command. this->setCmd(kFujitsuAcCmdToggleSwingHoriz); } void IRFujitsuAC::stepVert(void) { this->setCmd(kFujitsuAcCmdStepVert); } void IRFujitsuAC::toggleSwingVert(const bool update) { // Toggle the current setting. if (update) this->setSwing(this->getSwing() ^ kFujitsuAcSwingVert); // and set the appropriate special command. this->setCmd(kFujitsuAcCmdToggleSwingVert); } // Set the requested command of the A/C. void IRFujitsuAC::setCmd(const uint8_t cmd) { switch (cmd) { case kFujitsuAcCmdTurnOff: case kFujitsuAcCmdTurnOn: case kFujitsuAcCmdStayOn: case kFujitsuAcCmdStepVert: case kFujitsuAcCmdToggleSwingVert: _cmd = cmd; break; case kFujitsuAcCmdStepHoriz: case kFujitsuAcCmdToggleSwingHoriz: switch (_model) { // Only these remotes have horizontal. case fujitsu_ac_remote_model_t::ARRAH2E: case fujitsu_ac_remote_model_t::ARJW2: _cmd = cmd; break; default: _cmd = kFujitsuAcCmdStayOn; } break; case kFujitsuAcCmdEcono: case kFujitsuAcCmdPowerful: switch (_model) { // Only these remotes have these commands. case ARREB1E: _cmd = cmd; break; default: _cmd = kFujitsuAcCmdStayOn; } break; default: _cmd = kFujitsuAcCmdStayOn; } } // Get the special command part of the message. // Args: // raw: Do we need to get it from first principles from the raw data? // Returns: // A uint8_t containing the contents of the special command byte. uint8_t IRFujitsuAC::getCmd(const bool raw) { if (raw) return remote_state[5]; return _cmd; } // Set the requested power state of the A/C. void IRFujitsuAC::setPower(const bool on) { this->setCmd(on ? kFujitsuAcCmdTurnOn : kFujitsuAcCmdTurnOff); } // Set the requested power state of the A/C to off. void IRFujitsuAC::off(void) { this->setPower(false); } // Set the requested power state of the A/C to on. void IRFujitsuAC::on(void) { this->setPower(true); } bool IRFujitsuAC::getPower(void) { return _cmd != kFujitsuAcCmdTurnOff; } void IRFujitsuAC::setOutsideQuiet(const bool on) { _outsideQuiet = on; this->setCmd(kFujitsuAcCmdStayOn); // No special command involved. } // Get the status of the Outside Quiet setting. // Args: // raw: Do we get the result from base data? // Returns: // A boolean for if it is set or not. bool IRFujitsuAC::getOutsideQuiet(const bool raw) { if (_state_length == kFujitsuAcStateLength && raw) { _outsideQuiet = GETBIT8(remote_state[14], kFujitsuAcOutsideQuietOffset); // Only ARREB1E seems to have this mode. if (_outsideQuiet) this->setModel(fujitsu_ac_remote_model_t::ARREB1E); } return _outsideQuiet; } // Set the temp. in deg C void IRFujitsuAC::setTemp(const uint8_t temp) { _temp = std::max((uint8_t)kFujitsuAcMinTemp, temp); _temp = std::min((uint8_t)kFujitsuAcMaxTemp, _temp); this->setCmd(kFujitsuAcCmdStayOn); // No special command involved. } uint8_t IRFujitsuAC::getTemp(void) { return _temp; } // Set the speed of the fan void IRFujitsuAC::setFanSpeed(const uint8_t fanSpeed) { if (fanSpeed > kFujitsuAcFanQuiet) _fanSpeed = kFujitsuAcFanHigh; // Set the fan to maximum if out of range. else _fanSpeed = fanSpeed; this->setCmd(kFujitsuAcCmdStayOn); // No special command involved. } uint8_t IRFujitsuAC::getFanSpeed(void) { return _fanSpeed; } // Set the requested climate operation mode of the a/c unit. void IRFujitsuAC::setMode(const uint8_t mode) { if (mode > kFujitsuAcModeHeat) _mode = kFujitsuAcModeHeat; // Set the mode to maximum if out of range. else _mode = mode; this->setCmd(kFujitsuAcCmdStayOn); // No special command involved. } uint8_t IRFujitsuAC::getMode(void) { return _mode; } // Set the requested swing operation mode of the a/c unit. void IRFujitsuAC::setSwing(const uint8_t swingMode) { _swingMode = swingMode; switch (_model) { // No Horizontal support. case fujitsu_ac_remote_model_t::ARDB1: case fujitsu_ac_remote_model_t::ARREB1E: case fujitsu_ac_remote_model_t::ARRY4: // Set the mode to max if out of range if (swingMode > kFujitsuAcSwingVert) _swingMode = kFujitsuAcSwingVert; break; // Has Horizontal support. case fujitsu_ac_remote_model_t::ARRAH2E: case fujitsu_ac_remote_model_t::ARJW2: default: // Set the mode to max if out of range if (swingMode > kFujitsuAcSwingBoth) _swingMode = kFujitsuAcSwingBoth; } this->setCmd(kFujitsuAcCmdStayOn); // No special command involved. } // Get what the swing part of the message should be. // Args: // raw: Do we need to get it from first principles from the raw data? // Returns: // A uint8_t containing the contents of the swing state. uint8_t IRFujitsuAC::getSwing(const bool raw) { if (raw) _swingMode = GETBITS8(remote_state[10], kHighNibble, kFujitsuAcSwingSize); return _swingMode; } void IRFujitsuAC::setClean(const bool on) { _clean = on; this->setCmd(kFujitsuAcCmdStayOn); // No special command involved. } bool IRFujitsuAC::getClean(const bool raw) { if (raw) { return GETBIT8(remote_state[9], kFujitsuAcCleanOffset); } else { switch (getModel()) { case fujitsu_ac_remote_model_t::ARRY4: return _clean; default: return false; } } } void IRFujitsuAC::setFilter(const bool on) { _filter = on; this->setCmd(kFujitsuAcCmdStayOn); // No special command involved. } bool IRFujitsuAC::getFilter(const bool raw) { if (raw) { return GETBIT8(remote_state[14], kFujitsuAcFilterOffset); } else { switch (getModel()) { case fujitsu_ac_remote_model_t::ARRY4: return _filter; default: return false; } } } bool IRFujitsuAC::validChecksum(uint8_t state[], const uint16_t length) { uint8_t sum = 0; uint8_t sum_complement = 0; uint8_t checksum = state[length - 1]; switch (length) { case kFujitsuAcStateLengthShort: // ARRAH2E, ARREB1E, & ARRY4 return state[length - 1] == (uint8_t)~state[length - 2]; case kFujitsuAcStateLength - 1: // ARDB1 & ARJW2 sum = sumBytes(state, length - 1); sum_complement = 0x9B; break; case kFujitsuAcStateLength: // ARRAH2E, ARRY4, & ARREB1E sum = sumBytes(state + kFujitsuAcStateLengthShort, length - 1 - kFujitsuAcStateLengthShort); break; default: // Includes ARDB1 & ARJW2 short. return true; // Assume the checksum is valid for other lengths. } return checksum == (uint8_t)(sum_complement - sum); // Does it match? } // Convert a standard A/C mode into its native mode. uint8_t IRFujitsuAC::convertMode(const stdAc::opmode_t mode) { switch (mode) { case stdAc::opmode_t::kCool: return kFujitsuAcModeCool; case stdAc::opmode_t::kHeat: return kFujitsuAcModeHeat; case stdAc::opmode_t::kDry: return kFujitsuAcModeDry; case stdAc::opmode_t::kFan: return kFujitsuAcModeFan; default: return kFujitsuAcModeAuto; } } // Convert a standard A/C Fan speed into its native fan speed. uint8_t IRFujitsuAC::convertFan(stdAc::fanspeed_t speed) { switch (speed) { case stdAc::fanspeed_t::kMin: return kFujitsuAcFanQuiet; case stdAc::fanspeed_t::kLow: return kFujitsuAcFanLow; case stdAc::fanspeed_t::kMedium: return kFujitsuAcFanMed; case stdAc::fanspeed_t::kHigh: case stdAc::fanspeed_t::kMax: return kFujitsuAcFanHigh; default: return kFujitsuAcFanAuto; } } // Convert a native mode to it's common equivalent. stdAc::opmode_t IRFujitsuAC::toCommonMode(const uint8_t mode) { switch (mode) { case kFujitsuAcModeCool: return stdAc::opmode_t::kCool; case kFujitsuAcModeHeat: return stdAc::opmode_t::kHeat; case kFujitsuAcModeDry: return stdAc::opmode_t::kDry; case kFujitsuAcModeFan: return stdAc::opmode_t::kFan; default: return stdAc::opmode_t::kAuto; } } // Convert a native fan speed to it's common equivalent. stdAc::fanspeed_t IRFujitsuAC::toCommonFanSpeed(const uint8_t speed) { switch (speed) { case kFujitsuAcFanHigh: return stdAc::fanspeed_t::kMax; case kFujitsuAcFanMed: return stdAc::fanspeed_t::kMedium; case kFujitsuAcFanLow: return stdAc::fanspeed_t::kLow; case kFujitsuAcFanQuiet: return stdAc::fanspeed_t::kMin; default: return stdAc::fanspeed_t::kAuto; } } // Convert the A/C state to it's common equivalent. stdAc::state_t IRFujitsuAC::toCommon(void) { stdAc::state_t result; result.protocol = decode_type_t::FUJITSU_AC; result.model = this->getModel(); result.power = this->getPower(); result.mode = this->toCommonMode(this->getMode()); result.celsius = true; result.degrees = this->getTemp(); result.fanspeed = this->toCommonFanSpeed(this->getFanSpeed()); uint8_t swing = this->getSwing(); switch (result.model) { case fujitsu_ac_remote_model_t::ARREB1E: case fujitsu_ac_remote_model_t::ARRAH2E: case fujitsu_ac_remote_model_t::ARRY4: result.clean = _clean; result.filter = _filter; result.swingv = (swing & kFujitsuAcSwingVert) ? stdAc::swingv_t::kAuto : stdAc::swingv_t::kOff; result.swingh = (swing & kFujitsuAcSwingHoriz) ? stdAc::swingh_t::kAuto : stdAc::swingh_t::kOff; break; case fujitsu_ac_remote_model_t::ARDB1: case fujitsu_ac_remote_model_t::ARJW2: default: result.swingv = stdAc::swingv_t::kOff; result.swingh = stdAc::swingh_t::kOff; } result.quiet = (this->getFanSpeed() == kFujitsuAcFanQuiet); result.turbo = this->getCmd() == kFujitsuAcCmdPowerful; result.econo = this->getCmd() == kFujitsuAcCmdEcono; // Not supported. result.light = false; result.filter = false; result.clean = false; result.beep = false; result.sleep = -1; result.clock = -1; return result; } // Convert the internal state into a human readable string. String IRFujitsuAC::toString(void) { String result = ""; result.reserve(100); // Reserve some heap for the string to reduce fragging. fujitsu_ac_remote_model_t model = this->getModel(); result += addModelToString(decode_type_t::FUJITSU_AC, model, false); result += addBoolToString(getPower(), kPowerStr); result += addModeToString(getMode(), kFujitsuAcModeAuto, kFujitsuAcModeCool, kFujitsuAcModeHeat, kFujitsuAcModeDry, kFujitsuAcModeFan); result += addTempToString(getTemp()); result += addFanToString(getFanSpeed(), kFujitsuAcFanHigh, kFujitsuAcFanLow, kFujitsuAcFanAuto, kFujitsuAcFanQuiet, kFujitsuAcFanMed); switch (model) { // These models have no internal swing, clean. or filter state. case fujitsu_ac_remote_model_t::ARDB1: case fujitsu_ac_remote_model_t::ARJW2: break; default: // Assume everything else does. result += addBoolToString(getClean(), kCleanStr); result += addBoolToString(getFilter(), kFilterStr); result += addIntToString(this->getSwing(), kSwingStr); result += kSpaceLBraceStr; switch (this->getSwing()) { case kFujitsuAcSwingOff: result += kOffStr; break; case kFujitsuAcSwingVert: result += kSwingVStr; break; case kFujitsuAcSwingHoriz: result += kSwingHStr; break; case kFujitsuAcSwingBoth: result += kSwingVStr + '+' + kSwingHStr; break; default: result += kUnknownStr; } result += ')'; } result += kCommaSpaceStr + kCommandStr + kColonSpaceStr; switch (this->getCmd()) { case kFujitsuAcCmdStepHoriz: result += kStepStr + ' ' + kSwingHStr; break; case kFujitsuAcCmdStepVert: result += kStepStr + ' ' + kSwingVStr; break; case kFujitsuAcCmdToggleSwingHoriz: result += kToggleStr + ' ' + kSwingHStr; break; case kFujitsuAcCmdToggleSwingVert: result += kToggleStr + ' ' + kSwingVStr; break; case kFujitsuAcCmdEcono: result += kEconoStr; break; case kFujitsuAcCmdPowerful: result += kPowerfulStr; break; default: result += kNAStr; } if (this->getModel() == fujitsu_ac_remote_model_t::ARREB1E) result += addBoolToString(getOutsideQuiet(), kOutsideStr + ' ' + kQuietStr); return result; } #if DECODE_FUJITSU_AC // Decode a Fujitsu AC IR message if possible. // Places successful decode information in the results pointer. // Args: // results: Ptr to the data to decode and where to store the decode result. // nbits: The number of data bits to expect. Typically kFujitsuAcBits. // strict: Flag to indicate if we strictly adhere to the specification. // Returns: // boolean: True if it can decode it, false if it can't. // // Status: ALPHA / Untested. // // Ref: // bool IRrecv::decodeFujitsuAC(decode_results* results, uint16_t nbits, bool strict) { uint16_t offset = kStartOffset; uint16_t dataBitsSoFar = 0; // Have we got enough data to successfully decode? if (results->rawlen < (2 * kFujitsuAcMinBits) + kHeader + kFooter - 1) return false; // Can't possibly be a valid message. // Compliance if (strict) { switch (nbits) { case kFujitsuAcBits: case kFujitsuAcBits - 8: case kFujitsuAcMinBits: case kFujitsuAcMinBits + 8: break; default: return false; // Must be called with the correct nr. of bits. } } // Header if (!matchMark(results->rawbuf[offset++], kFujitsuAcHdrMark)) return false; if (!matchSpace(results->rawbuf[offset++], kFujitsuAcHdrSpace)) return false; // Data (Fixed signature) match_result_t data_result = matchData(&(results->rawbuf[offset]), kFujitsuAcMinBits - 8, kFujitsuAcBitMark, kFujitsuAcOneSpace, kFujitsuAcBitMark, kFujitsuAcZeroSpace, _tolerance, kMarkExcess, false); if (data_result.success == false) return false; // Fail if (data_result.data != 0x1010006314) return false; // Signature failed. dataBitsSoFar += kFujitsuAcMinBits - 8; offset += data_result.used; results->state[0] = 0x14; results->state[1] = 0x63; results->state[2] = 0x00; results->state[3] = 0x10; results->state[4] = 0x10; // Keep reading bytes until we either run out of message or state to fill. for (uint16_t i = 5; offset <= results->rawlen - 16 && i < kFujitsuAcStateLength; i++, dataBitsSoFar += 8, offset += data_result.used) { data_result = matchData( &(results->rawbuf[offset]), 8, kFujitsuAcBitMark, kFujitsuAcOneSpace, kFujitsuAcBitMark, kFujitsuAcZeroSpace, _tolerance, kMarkExcess, false); if (data_result.success == false) break; // Fail results->state[i] = data_result.data; } // Footer if (offset > results->rawlen || !matchMark(results->rawbuf[offset++], kFujitsuAcBitMark)) return false; // The space is optional if we are out of capture. if (offset < results->rawlen && !matchAtLeast(results->rawbuf[offset], kFujitsuAcMinGap)) return false; // Compliance if (strict) { if (dataBitsSoFar != nbits) return false; } results->decode_type = FUJITSU_AC; results->bits = dataBitsSoFar; // Compliance switch (dataBitsSoFar) { case kFujitsuAcMinBits: // Check if this values indicate that this should have been a long state // message. if (results->state[5] == 0xFC) return false; return true; // Success case kFujitsuAcMinBits + 8: // Check if this values indicate that this should have been a long state // message. if (results->state[5] == 0xFE) return false; // The last byte needs to be the inverse of the penultimate byte. if (results->state[5] != (uint8_t)~results->state[6]) return false; return true; // Success case kFujitsuAcBits - 8: // Long messages of this size require this byte be correct. if (results->state[5] != 0xFC) return false; break; case kFujitsuAcBits: // Long messages of this size require this byte be correct. if (results->state[5] != 0xFE) return false; break; default: return false; // Unexpected size. } if (!IRFujitsuAC::validChecksum(results->state, dataBitsSoFar / 8)) return false; // Success return true; // All good. } #endif // DECODE_FUJITSU_AC