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mqtt-ir-remote/IRremoteESP8266/src/ir_Fujitsu.cpp

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// Copyright 2017 Jonny Graham, David Conran
#include "ir_Fujitsu.h"
#include <algorithm>
#ifndef ARDUINO
#include <string>
#endif
#include "IRsend.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
// * <Add models (A/C & remotes) you've gotten it working with here>
// Ref:
// These values are based on averages of measurements
#define FUJITSU_AC_HDR_MARK 3324U
#define FUJITSU_AC_HDR_SPACE 1574U
#define FUJITSU_AC_BIT_MARK 448U
#define FUJITSU_AC_ONE_SPACE 1182U
#define FUJITSU_AC_ZERO_SPACE 390U
#define FUJITSU_AC_MIN_GAP 8100U
#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:
// FUJITSU_AC_STATE_LENGTH
// FUJITSU_AC_STATE_LENGTH - 1
// FUJITSU_AC_STATE_LENGTH_SHORT
// FUJITSU_AC_STATE_LENGTH_SHORT - 1
// repeat: Nr. of times the message is to be repeated.
// (Default = FUJITSU_AC_MIN_REPEAT).
//
// Status: BETA / Appears to be working.
//
void IRsend::sendFujitsuAC(unsigned char data[], uint16_t nbytes,
uint16_t repeat) {
sendGeneric(FUJITSU_AC_HDR_MARK, FUJITSU_AC_HDR_SPACE,
FUJITSU_AC_BIT_MARK, FUJITSU_AC_ONE_SPACE,
FUJITSU_AC_BIT_MARK, FUJITSU_AC_ZERO_SPACE,
FUJITSU_AC_BIT_MARK, FUJITSU_AC_MIN_GAP,
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(uint16_t pin, fujitsu_ac_remote_model_t model)
: _irsend(pin) {
setModel(model);
stateReset();
}
void IRFujitsuAC::setModel(fujitsu_ac_remote_model_t model) {
_model = model;
switch (model) {
case ARDB1:
_state_length = FUJITSU_AC_STATE_LENGTH - 1;
_state_length_short = FUJITSU_AC_STATE_LENGTH_SHORT - 1;
break;
default:
_state_length = FUJITSU_AC_STATE_LENGTH;
_state_length_short = FUJITSU_AC_STATE_LENGTH_SHORT;
}
}
// Reset the state of the remote to a known good state/sequence.
void IRFujitsuAC::stateReset() {
_temp = 24;
_fanSpeed = FUJITSU_AC_FAN_HIGH;
_mode = FUJITSU_AC_MODE_COOL;
_swingMode = FUJITSU_AC_SWING_BOTH;
_cmd = FUJITSU_AC_CMD_TURN_ON;
buildState();
}
// Configure the pin for output.
void IRFujitsuAC::begin() {
_irsend.begin();
}
#if SEND_FUJITSU_AC
// Send the current desired state to the IR LED.
void IRFujitsuAC::send() {
getRaw();
_irsend.sendFujitsuAC(remote_state, getStateLength());
}
#endif // SEND_FUJITSU_AC
void IRFujitsuAC::buildState() {
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 FUJITSU_AC_CMD_TURN_OFF:
remote_state[5] = 0x02;
break;
case FUJITSU_AC_CMD_STEP_HORIZ:
remote_state[5] = 0x79;
break;
case FUJITSU_AC_CMD_STEP_VERT:
remote_state[5] = 0x6C;
break;
default:
switch (_model) {
case ARRAH2E:
remote_state[5] = 0xFE;
break;
case ARDB1:
remote_state[5] = 0xFC;
break;
}
fullCmd = true;
break;
}
if (fullCmd) { // long codes
uint8_t tempByte = _temp - FUJITSU_AC_MIN_TEMP;
// Nr. of bytes in the message after this byte.
remote_state[6] = _state_length - 7;
remote_state[7] = 0x30;
remote_state[8] = (_cmd == FUJITSU_AC_CMD_TURN_ON) | (tempByte << 4);
remote_state[9] = _mode | 0 << 4; // timer off
remote_state[10] = _fanSpeed | _swingMode << 4;
remote_state[11] = 0; // timerOff values
remote_state[12] = 0; // timerOff/On values
remote_state[13] = 0; // timerOn values
if (_model == ARRAH2E)
remote_state[14] = 0x20;
else
remote_state[14] = 0x00;
uint8_t checksum = 0;
uint8_t checksum_complement = 0;
if (_model == ARRAH2E) {
checksum = sumBytes(remote_state + _state_length_short,
_state_length - _state_length_short - 1);
} else if (_model == ARDB1) {
checksum = sumBytes(remote_state, _state_length - 1);
checksum_complement = 0x9B;
}
// and negate the checksum and store it in the last byte.
remote_state[_state_length - 1] = checksum_complement - checksum;
} else { // short codes
if (_model == ARRAH2E)
// The last byte is the inverse of penultimate byte
remote_state[_state_length_short - 1] = ~remote_state[_state_length_short
- 2];
// Zero the rest of the state.
for (uint8_t i = _state_length_short;
i < FUJITSU_AC_STATE_LENGTH;
i++)
remote_state[i] = 0;
}
}
uint8_t IRFujitsuAC::getStateLength() {
buildState(); // Force an update of the internal state.
if ((_model == ARRAH2E && remote_state[5] != 0xFE) ||
(_model == ARDB1 && 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() {
buildState();
return remote_state;
}
void IRFujitsuAC::buildFromState(const uint16_t length) {
switch (length) {
case FUJITSU_AC_STATE_LENGTH - 1:
case FUJITSU_AC_STATE_LENGTH_SHORT - 1:
setModel(ARDB1);
break;
default:
setModel(ARRAH2E);
}
switch (remote_state[6]) {
case 8:
setModel(ARDB1);
break;
case 9:
setModel(ARRAH2E);
break;
}
setTemp((remote_state[8] >> 4) + FUJITSU_AC_MIN_TEMP);
if (remote_state[8] & 0x1)
setCmd(FUJITSU_AC_CMD_TURN_ON);
else
setCmd(FUJITSU_AC_CMD_STAY_ON);
setMode(remote_state[9] & 0b111);
setFanSpeed(remote_state[10] & 0b111);
setSwing(remote_state[10] >> 4);
switch (remote_state[5]) {
case FUJITSU_AC_CMD_TURN_OFF:
case FUJITSU_AC_CMD_STEP_HORIZ:
case FUJITSU_AC_CMD_STEP_VERT:
setCmd(remote_state[5]);
break;
}
}
bool IRFujitsuAC::setRaw(const uint8_t newState[], const uint16_t length) {
if (length > FUJITSU_AC_STATE_LENGTH) return false;
for (uint16_t i = 0; i < FUJITSU_AC_STATE_LENGTH; i++) {
if (i < length)
remote_state[i] = newState[i];
else
remote_state[i] = 0;
}
buildFromState(length);
return true;
}
// Set the requested power state of the A/C to off.
void IRFujitsuAC::off() {
_cmd = FUJITSU_AC_CMD_TURN_OFF;
}
void IRFujitsuAC::stepHoriz() {
switch (_model) {
case ARDB1: break; // This remote doesn't have a horizontal option.
default:
_cmd = FUJITSU_AC_CMD_STEP_HORIZ;
}
}
void IRFujitsuAC::stepVert() {
_cmd = FUJITSU_AC_CMD_STEP_VERT;
}
// Set the requested command of the A/C.
void IRFujitsuAC::setCmd(uint8_t cmd) {
switch (cmd) {
case FUJITSU_AC_CMD_TURN_OFF:
case FUJITSU_AC_CMD_TURN_ON:
case FUJITSU_AC_CMD_STAY_ON:
case FUJITSU_AC_CMD_STEP_VERT:
_cmd = cmd;
break;
case FUJITSU_AC_CMD_STEP_HORIZ:
if (_model != ARDB1) // AR-DB1 remote doesn't have step horizontal.
_cmd = cmd;
default:
_cmd = FUJITSU_AC_CMD_STAY_ON;
break;
}
}
uint8_t IRFujitsuAC::getCmd() {
return _cmd;
}
bool IRFujitsuAC::getPower() {
return _cmd != FUJITSU_AC_CMD_TURN_OFF;
}
// Set the temp. in deg C
void IRFujitsuAC::setTemp(uint8_t temp) {
temp = std::max((uint8_t) FUJITSU_AC_MIN_TEMP, temp);
temp = std::min((uint8_t) FUJITSU_AC_MAX_TEMP, temp);
_temp = temp;
}
uint8_t IRFujitsuAC::getTemp() {
return _temp;
}
// Set the speed of the fan
void IRFujitsuAC::setFanSpeed(uint8_t fanSpeed) {
if (fanSpeed > FUJITSU_AC_FAN_QUIET)
fanSpeed = FUJITSU_AC_FAN_HIGH; // Set the fan to maximum if out of range.
_fanSpeed = fanSpeed;
}
uint8_t IRFujitsuAC::getFanSpeed() {
return _fanSpeed;
}
// Set the requested climate operation mode of the a/c unit.
void IRFujitsuAC::setMode(uint8_t mode) {
if (mode > FUJITSU_AC_MODE_HEAT)
mode = FUJITSU_AC_MODE_HEAT; // Set the mode to maximum if out of range.
_mode = mode;
}
uint8_t IRFujitsuAC::getMode() {
return _mode;
}
// Set the requested swing operation mode of the a/c unit.
void IRFujitsuAC::setSwing(uint8_t swingMode) {
switch (_model) {
case ARDB1:
// Set the mode to max if out of range
if (swingMode > FUJITSU_AC_SWING_VERT)
swingMode = FUJITSU_AC_SWING_VERT;
break;
case ARRAH2E:
default:
// Set the mode to max if out of range
if (swingMode > FUJITSU_AC_SWING_BOTH)
swingMode = FUJITSU_AC_SWING_BOTH;
}
_swingMode = swingMode;
}
uint8_t IRFujitsuAC::getSwing() {
return _swingMode;
}
bool IRFujitsuAC::validChecksum(uint8_t state[], uint16_t length) {
uint8_t sum = 0;
uint8_t sum_complement = 0;
uint8_t checksum = 0;
switch (length) {
case FUJITSU_AC_STATE_LENGTH_SHORT: // ARRAH2E
return state[length - 1] == (uint8_t) ~state[length - 2];
case FUJITSU_AC_STATE_LENGTH - 1: // ARDB1
sum = sumBytes(state, length - 1);
sum_complement = 0x9B;
checksum = state[length - 1];
break;
case FUJITSU_AC_STATE_LENGTH: // ARRAH2E
sum = sumBytes(state + FUJITSU_AC_STATE_LENGTH_SHORT,
length - 1 - FUJITSU_AC_STATE_LENGTH_SHORT);
default: // Includes ARDB1 short.
return true; // Assume the checksum is valid for other lengths.
}
return checksum == (uint8_t) (sum_complement - sum); // Does it match?
}
// Convert the internal state into a human readable string.
#ifdef ARDUINO
String IRFujitsuAC::toString() {
String result = "";
#else
std::string IRFujitsuAC::toString() {
std::string result = "";
#endif // ARDUINO
result += "Power: ";
if (getPower())
result += "On";
else
result += "Off";
result += ", Mode: " + uint64ToString(getMode());
switch (getMode()) {
case FUJITSU_AC_MODE_AUTO:
result += " (AUTO)";
break;
case FUJITSU_AC_MODE_COOL:
result += " (COOL)";
break;
case FUJITSU_AC_MODE_HEAT:
result += " (HEAT)";
break;
case FUJITSU_AC_MODE_DRY:
result += " (DRY)";
break;
case FUJITSU_AC_MODE_FAN:
result += " (FAN)";
break;
default:
result += " (UNKNOWN)";
}
result += ", Temp: " + uint64ToString(getTemp()) + "C";
result += ", Fan: " + uint64ToString(getFanSpeed());
switch (getFanSpeed()) {
case FUJITSU_AC_FAN_AUTO:
result += " (AUTO)";
break;
case FUJITSU_AC_FAN_HIGH:
result += " (HIGH)";
break;
case FUJITSU_AC_FAN_MED:
result += " (MED)";
break;
case FUJITSU_AC_FAN_LOW:
result += " (LOW)";
break;
case FUJITSU_AC_FAN_QUIET:
result += " (QUIET)";
break;
}
result += ", Swing: ";
switch (getSwing()) {
case FUJITSU_AC_SWING_OFF:
result += "Off";
break;
case FUJITSU_AC_SWING_VERT:
result += "Vert";
break;
case FUJITSU_AC_SWING_HORIZ:
result += "Horiz";
break;
case FUJITSU_AC_SWING_BOTH:
result += "Vert + Horiz";
break;
default:
result += "UNKNOWN";
}
result += ", Command: ";
switch (getCmd()) {
case FUJITSU_AC_CMD_STEP_HORIZ:
result += "Step vane horizontally";
break;
case FUJITSU_AC_CMD_STEP_VERT:
result += "Step vane vertically";
break;
default:
result += "N/A";
}
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 FUJITSU_AC_BITS.
// 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 = OFFSET_START;
uint16_t dataBitsSoFar = 0;
// Have we got enough data to successfully decode?
if (results->rawlen < (2 * FUJITSU_AC_MIN_BITS) + HEADER + FOOTER - 1)
return false; // Can't possibly be a valid message.
// Compliance
if (strict) {
switch (nbits) {
case FUJITSU_AC_BITS:
case FUJITSU_AC_BITS - 8:
case FUJITSU_AC_MIN_BITS:
case FUJITSU_AC_MIN_BITS + 8:
break;
default:
return false; // Must be called with the correct nr. of bits.
}
}
// Header
if (!matchMark(results->rawbuf[offset++], FUJITSU_AC_HDR_MARK))
return false;
if (!matchSpace(results->rawbuf[offset++], FUJITSU_AC_HDR_SPACE))
return false;
// Data (Fixed signature)
match_result_t data_result = matchData(&(results->rawbuf[offset]),
FUJITSU_AC_MIN_BITS - 8,
FUJITSU_AC_BIT_MARK,
FUJITSU_AC_ONE_SPACE,
FUJITSU_AC_BIT_MARK,
FUJITSU_AC_ZERO_SPACE);
if (data_result.success == false) return false; // Fail
if (reverseBits(data_result.data, FUJITSU_AC_MIN_BITS - 8) != 0x1010006314)
return false; // Signature failed.
dataBitsSoFar += FUJITSU_AC_MIN_BITS - 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 < FUJITSU_AC_STATE_LENGTH;
i++, dataBitsSoFar += 8, offset += data_result.used) {
data_result = matchData(&(results->rawbuf[offset]), 8,
FUJITSU_AC_BIT_MARK,
FUJITSU_AC_ONE_SPACE,
FUJITSU_AC_BIT_MARK,
FUJITSU_AC_ZERO_SPACE);
if (data_result.success == false) break; // Fail
results->state[i] = (uint8_t) reverseBits(data_result.data, 8);
}
// Footer
if (offset > results->rawlen ||
!matchMark(results->rawbuf[offset++], FUJITSU_AC_BIT_MARK)) return false;
// The space is optional if we are out of capture.
if (offset < results->rawlen &&
!matchAtLeast(results->rawbuf[offset], FUJITSU_AC_MIN_GAP)) return false;
// Compliance
if (strict) {
if (dataBitsSoFar != nbits) return false;
}
results->decode_type = FUJITSU_AC;
results->bits = dataBitsSoFar;
// Compliance
switch (dataBitsSoFar) {
case FUJITSU_AC_MIN_BITS:
// 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 FUJITSU_AC_MIN_BITS + 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 FUJITSU_AC_BITS - 8:
// Long messages of this size require this byte be correct.
if (results->state[5] != 0xFC) return false;
break;
case FUJITSU_AC_BITS:
// 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
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