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ir_Sharp.cpp
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ir_Sharp.cpp
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// Copyright 2009 Ken Shirriff
// Copyright 2017, 2019 David Conran
/// @file
/// @brief Support for Sharp protocols.
/// @see http://www.sbprojects.net/knowledge/ir/sharp.htm
/// @see http://lirc.sourceforge.net/remotes/sharp/GA538WJSA
/// @see http://www.mwftr.com/ucF08/LEC14%20PIC%20IR.pdf
/// @see http://www.hifi-remote.com/johnsfine/DecodeIR.html#Sharp
/// @see GlobalCache's IR Control Tower data.
/// @see https://github.com/crankyoldgit/IRremoteESP8266/issues/638
/// @see https://github.com/ToniA/arduino-heatpumpir/blob/master/SharpHeatpumpIR.cpp
#include "ir_Sharp.h"
#include <algorithm>
#include <cstring>
#ifndef ARDUINO
#include <string>
#endif
#include "IRrecv.h"
#include "IRsend.h"
#include "IRtext.h"
#include "IRutils.h"
// Constants
// period time = 1/38000Hz = 26.316 microseconds.
const uint16_t kSharpTick = 26;
const uint16_t kSharpBitMarkTicks = 10;
const uint16_t kSharpBitMark = kSharpBitMarkTicks * kSharpTick;
const uint16_t kSharpOneSpaceTicks = 70;
const uint16_t kSharpOneSpace = kSharpOneSpaceTicks * kSharpTick;
const uint16_t kSharpZeroSpaceTicks = 30;
const uint16_t kSharpZeroSpace = kSharpZeroSpaceTicks * kSharpTick;
const uint16_t kSharpGapTicks = 1677;
const uint16_t kSharpGap = kSharpGapTicks * kSharpTick;
// Address(5) + Command(8) + Expansion(1) + Check(1)
const uint64_t kSharpToggleMask =
((uint64_t)1 << (kSharpBits - kSharpAddressBits)) - 1;
const uint64_t kSharpAddressMask = ((uint64_t)1 << kSharpAddressBits) - 1;
const uint64_t kSharpCommandMask = ((uint64_t)1 << kSharpCommandBits) - 1;
using irutils::addBoolToString;
using irutils::addFanToString;
using irutils::addIntToString;
using irutils::addLabeledString;
using irutils::addModeToString;
using irutils::addModelToString;
using irutils::addSwingVToString;
using irutils::addTempToString;
using irutils::addToggleToString;
using irutils::minsToString;
// Also used by Denon protocol
#if (SEND_SHARP || SEND_DENON)
/// Send a (raw) Sharp message
/// @note Status: STABLE / Working fine.
/// @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 his procedure handles the inversion of bits required per protocol.
/// The protocol spec says to send the LSB first, but legacy code & usage
/// has us sending the MSB first. Grrrr. Normal invocation of encodeSharp()
/// handles this for you, assuming you are using the correct/standard values.
/// e.g. sendSharpRaw(encodeSharp(address, command));
void IRsend::sendSharpRaw(const uint64_t data, const uint16_t nbits,
const uint16_t repeat) {
uint64_t tempdata = data;
for (uint16_t i = 0; i <= repeat; i++) {
// Protocol demands that the data be sent twice; once normally,
// then with all but the address bits inverted.
// Note: Previously this used to be performed 3 times (normal, inverted,
// normal), however all data points to that being incorrect.
for (uint8_t n = 0; n < 2; n++) {
sendGeneric(0, 0, // No Header
kSharpBitMark, kSharpOneSpace, kSharpBitMark, kSharpZeroSpace,
kSharpBitMark, kSharpGap, tempdata, nbits, 38, true,
0, // Repeats are handled already.
33);
// Invert the data per protocol. This is always called twice, so it's
// returned to original upon exiting the inner loop.
tempdata ^= kSharpToggleMask;
}
}
}
/// Encode a (raw) Sharp message from it's components.
/// Status: STABLE / Works okay.
/// @param[in] address The value of the address to be sent.
/// @param[in] command The value of the address to be sent. (8 bits)
/// @param[in] expansion The value of the expansion bit to use.
/// (0 or 1, typically 1)
/// @param[in] check The value of the check bit to use. (0 or 1, typically 0)
/// @param[in] MSBfirst Flag indicating MSB first or LSB first order.
/// @return A uint32_t containing the raw Sharp message for `sendSharpRaw()`.
/// @note Assumes the standard Sharp bit sizes.
/// Historically sendSharp() sends address & command in
/// MSB first order. This is actually incorrect. It should be sent in LSB
/// order. The behaviour of sendSharp() hasn't been changed to maintain
/// backward compatibility.
uint32_t IRsend::encodeSharp(const uint16_t address, const uint16_t command,
const uint16_t expansion, const uint16_t check,
const bool MSBfirst) {
// Mask any unexpected bits.
uint16_t tempaddress = GETBITS16(address, 0, kSharpAddressBits);
uint16_t tempcommand = GETBITS16(command, 0, kSharpCommandBits);
uint16_t tempexpansion = GETBITS16(expansion, 0, 1);
uint16_t tempcheck = GETBITS16(check, 0, 1);
if (!MSBfirst) { // Correct bit order if needed.
tempaddress = reverseBits(tempaddress, kSharpAddressBits);
tempcommand = reverseBits(tempcommand, kSharpCommandBits);
}
// Concatenate all the bits.
return (tempaddress << (kSharpCommandBits + 2)) | (tempcommand << 2) |
(tempexpansion << 1) | tempcheck;
}
/// Send a Sharp message
/// Status: DEPRECATED / Previously working fine.
/// @deprecated Only use this if you are using legacy from the original
/// Arduino-IRremote library. 99% of the time, you will want to use
/// `sendSharpRaw()` instead
/// @param[in] address Address value to be sent.
/// @param[in] command Command value 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 This procedure has a non-standard invocation style compared to similar
/// sendProtocol() routines. This is due to legacy, compatibility, & historic
/// reasons. Normally the calling syntax version is like sendSharpRaw().
/// This procedure transmits the address & command in MSB first order, which is
/// incorrect. This behaviour is left as-is to maintain backward
/// compatibility with legacy code.
/// In short, you should use sendSharpRaw(), encodeSharp(), and the correct
/// values of address & command instead of using this, & the wrong values.
void IRsend::sendSharp(const uint16_t address, uint16_t const command,
const uint16_t nbits, const uint16_t repeat) {
sendSharpRaw(encodeSharp(address, command, 1, 0, true), nbits, repeat);
}
#endif // (SEND_SHARP || SEND_DENON)
// Used by decodeDenon too.
#if (DECODE_SHARP || DECODE_DENON)
/// Decode the supplied Sharp message.
/// Status: STABLE / Working fine.
/// @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.
/// @param[in] expansion Should we expect the expansion bit to be set.
/// Default is true.
/// @return True if it can decode it, false if it can't.
/// @note This procedure returns a value suitable for use in `sendSharpRaw()`.
/// @todo Need to ensure capture of the inverted message as it can
/// be missed due to the interrupt timeout used to detect an end of message.
/// Several compliance checks are disabled until that is resolved.
bool IRrecv::decodeSharp(decode_results *results, uint16_t offset,
const uint16_t nbits, const bool strict,
const bool expansion) {
if (results->rawlen <= 2 * nbits + kFooter - 1 + offset)
return false; // Not enough entries to be a Sharp message.
// Compliance
if (strict) {
if (nbits != kSharpBits) return false; // Request is out of spec.
// DISABLED - See TODO
#ifdef UNIT_TEST
// An in spec message has the data sent normally, then inverted. So we
// expect twice as many entries than to just get the results.
if (results->rawlen <= (2 * (2 * nbits + kFooter)) - 1 + offset)
return false;
#endif
}
uint64_t data = 0;
// Match Data + Footer
uint16_t used;
used = matchGeneric(results->rawbuf + offset, &data,
results->rawlen - offset, nbits,
0, 0, // No Header
kSharpBitMark, kSharpOneSpace,
kSharpBitMark, kSharpZeroSpace,
kSharpBitMark, kSharpGap, true, 35);
if (!used) return false;
offset += used;
// Compliance
if (strict) {
// Check the state of the expansion bit is what we expect.
if ((data & 0b10) >> 1 != expansion) return false;
// The check bit should be cleared in a normal message.
if (data & 0b1) return false;
// DISABLED - See TODO
#ifdef UNIT_TEST
// Grab the second copy of the data (i.e. inverted)
uint64_t second_data = 0;
// Match Data + Footer
if (!matchGeneric(results->rawbuf + offset, &second_data,
results->rawlen - offset, nbits,
0, 0,
kSharpBitMark, kSharpOneSpace,
kSharpBitMark, kSharpZeroSpace,
kSharpBitMark, kSharpGap, true, 35)) return false;
// Check that second_data has been inverted correctly.
if (data != (second_data ^ kSharpToggleMask)) return false;
#endif // UNIT_TEST
}
// Success
results->decode_type = SHARP;
results->bits = nbits;
results->value = data;
// Address & command are actually transmitted in LSB first order.
results->address = reverseBits(data, nbits) & kSharpAddressMask;
results->command =
reverseBits((data >> 2) & kSharpCommandMask, kSharpCommandBits);
return true;
}
#endif // (DECODE_SHARP || DECODE_DENON)
#if SEND_SHARP_AC
/// Send a Sharp A/C message.
/// Status: Alpha / Untested.
/// @param[in] data The message to be sent.
/// @param[in] nbytes The number of bytes of message to be sent.
/// @param[in] repeat The number of times the command is to be repeated.
/// @see https://github.com/crankyoldgit/IRremoteESP8266/issues/638
/// @see https://github.com/ToniA/arduino-heatpumpir/blob/master/SharpHeatpumpIR.cpp
void IRsend::sendSharpAc(const unsigned char data[], const uint16_t nbytes,
const uint16_t repeat) {
if (nbytes < kSharpAcStateLength)
return; // Not enough bytes to send a proper message.
sendGeneric(kSharpAcHdrMark, kSharpAcHdrSpace,
kSharpAcBitMark, kSharpAcOneSpace,
kSharpAcBitMark, kSharpAcZeroSpace,
kSharpAcBitMark, kSharpAcGap,
data, nbytes, 38000, false, repeat, 50);
}
#endif // SEND_SHARP_AC
/// Class constructor
/// @param[in] pin GPIO to be used when sending.
/// @param[in] inverted Is the output signal to be inverted?
/// @param[in] use_modulation Is frequency modulation to be used?
IRSharpAc::IRSharpAc(const uint16_t pin, const bool inverted,
const bool use_modulation)
: _irsend(pin, inverted, use_modulation) { stateReset(); }
/// Set up hardware to be able to send a message.
void IRSharpAc::begin(void) { _irsend.begin(); }
#if SEND_SHARP_AC
/// Send the current internal state as an IR message.
/// @param[in] repeat Nr. of times the message will be repeated.
void IRSharpAc::send(const uint16_t repeat) {
_irsend.sendSharpAc(getRaw(), kSharpAcStateLength, repeat);
}
#endif // SEND_SHARP_AC
/// Calculate the checksum for a given state.
/// @param[in] state The array to calc the checksum of.
/// @param[in] length The length/size of the array.
/// @return The calculated 4-bit checksum value.
uint8_t IRSharpAc::calcChecksum(uint8_t state[], const uint16_t length) {
uint8_t xorsum = xorBytes(state, length - 1);
xorsum ^= GETBITS8(state[length - 1], kLowNibble, kNibbleSize);
xorsum ^= GETBITS8(xorsum, kHighNibble, kNibbleSize);
return GETBITS8(xorsum, kLowNibble, kNibbleSize);
}
/// Verify the checksum is valid for a given state.
/// @param[in] state The array to verify the checksum of.
/// @param[in] length The length/size of the array.
/// @return true, if the state has a valid checksum. Otherwise, false.
bool IRSharpAc::validChecksum(uint8_t state[], const uint16_t length) {
return GETBITS8(state[length - 1], kHighNibble, kNibbleSize) ==
IRSharpAc::calcChecksum(state, length);
}
/// Calculate and set the checksum values for the internal state.
void IRSharpAc::checksum(void) {
_.Sum = calcChecksum(_.raw);
}
/// Reset the state of the remote to a known good state/sequence.
void IRSharpAc::stateReset(void) {
static const uint8_t reset[kSharpAcStateLength] = {
0xAA, 0x5A, 0xCF, 0x10, 0x00, 0x01, 0x00, 0x00, 0x08, 0x80, 0x00, 0xE0,
0x01};
std::memcpy(_.raw, reset, kSharpAcStateLength);
_temp = getTemp();
_mode = _.Mode;
_fan = _.Fan;
_model = getModel(true);
}
/// Get a PTR to the internal state/code for this protocol.
/// @return PTR to a code for this protocol based on the current internal state.
uint8_t *IRSharpAc::getRaw(void) {
checksum(); // Ensure correct settings before sending.
return _.raw;
}
/// Set the internal state from a valid code for this protocol.
/// @param[in] new_code A valid code for this protocol.
/// @param[in] length The length/size of the new_code array.
void IRSharpAc::setRaw(const uint8_t new_code[], const uint16_t length) {
std::memcpy(_.raw, new_code, std::min(length, kSharpAcStateLength));
_model = getModel(true);
}
/// Set the model of the A/C to emulate.
/// @param[in] model The enum of the appropriate model.
void IRSharpAc::setModel(const sharp_ac_remote_model_t model) {
switch (model) {
case sharp_ac_remote_model_t::A705:
case sharp_ac_remote_model_t::A903:
_model = model;
_.Model = true;
break;
default:
_model = sharp_ac_remote_model_t::A907;
_.Model = false;
}
_.Model2 = (_model != sharp_ac_remote_model_t::A907);
// Redo the operating mode as some models don't support all modes.
setMode(_.Mode);
}
/// Get/Detect the model of the A/C.
/// @param[in] raw Try to determine the model from the raw code only.
/// @return The enum of the compatible model.
sharp_ac_remote_model_t IRSharpAc::getModel(const bool raw) const {
if (raw) {
if (_.Model2) {
if (_.Model)
return sharp_ac_remote_model_t::A705;
else
return sharp_ac_remote_model_t::A903;
} else {
return sharp_ac_remote_model_t::A907;
}
}
return _model;
}
/// Set the value of the Power Special setting without any checks.
/// @param[in] value The value to set Power Special to.
inline void IRSharpAc::setPowerSpecial(const uint8_t value) {
_.PowerSpecial = value;
}
/// Get the value of the Power Special setting.
/// @return The setting's value.
uint8_t IRSharpAc::getPowerSpecial(void) const {
return _.PowerSpecial;
}
/// Clear the "special"/non-normal bits in the power section.
/// e.g. for normal/common command modes.
void IRSharpAc::clearPowerSpecial(void) {
setPowerSpecial(_.PowerSpecial & kSharpAcPowerOn);
}
/// Is one of the special power states in use?
/// @return true, it is. false, it isn't.
bool IRSharpAc::isPowerSpecial(void) const {
switch (_.PowerSpecial) {
case kSharpAcPowerSetSpecialOff:
case kSharpAcPowerSetSpecialOn:
case kSharpAcPowerTimerSetting: return true;
default: return false;
}
}
/// Set the requested power state of the A/C to on.
void IRSharpAc::on(void) { setPower(true); }
/// Set the requested power state of the A/C to off.
void IRSharpAc::off(void) { setPower(false); }
/// Change the power setting, including the previous power state.
/// @param[in] on true, the setting is on. false, the setting is off.
/// @param[in] prev_on true, the setting is on. false, the setting is off.
void IRSharpAc::setPower(const bool on, const bool prev_on) {
setPowerSpecial(on ? (prev_on ? kSharpAcPowerOn : kSharpAcPowerOnFromOff)
: kSharpAcPowerOff);
// Power operations are incompatible with clean mode.
if (_.Clean) setClean(false);
_.Special = kSharpAcSpecialPower;
}
/// Get the value of the current power setting.
/// @return true, the setting is on. false, the setting is off.
bool IRSharpAc::getPower(void) const {
switch (_.PowerSpecial) {
case kSharpAcPowerUnknown:
case kSharpAcPowerOff: return false;
default: return true; // Everything else is "probably" on.
}
}
/// Set the value of the Special (button/command?) setting.
/// @param[in] mode The value to set Special to.
void IRSharpAc::setSpecial(const uint8_t mode) {
switch (mode) {
case kSharpAcSpecialPower:
case kSharpAcSpecialTurbo:
case kSharpAcSpecialTempEcono:
case kSharpAcSpecialFan:
case kSharpAcSpecialSwing:
case kSharpAcSpecialTimer:
case kSharpAcSpecialTimerHalfHour:
_.Special = mode;
break;
default:
_.Special = kSharpAcSpecialPower;
}
}
/// Get the value of the Special (button/command?) setting.
/// @return The setting's value.
uint8_t IRSharpAc::getSpecial(void) const { return _.Special; }
/// Set the temperature.
/// @param[in] temp The temperature in degrees celsius.
/// @param[in] save Do we save this setting as a user set one?
void IRSharpAc::setTemp(const uint8_t temp, const bool save) {
switch (_.Mode) {
// Auto & Dry don't allow temp changes and have a special temp.
case kSharpAcAuto:
case kSharpAcDry:
_.raw[kSharpAcByteTemp] = 0;
return;
default:
switch (getModel()) {
case sharp_ac_remote_model_t::A705:
_.raw[kSharpAcByteTemp] = 0xD0;
break;
default:
_.raw[kSharpAcByteTemp] = 0xC0;
}
}
uint8_t degrees = std::max(temp, kSharpAcMinTemp);
degrees = std::min(degrees, kSharpAcMaxTemp);
if (save) _temp = degrees;
_.Temp = degrees - kSharpAcMinTemp;
_.Special = kSharpAcSpecialTempEcono;
clearPowerSpecial();
}
/// Get the current temperature setting.
/// @return The current setting for temp. in degrees celsius.
uint8_t IRSharpAc::getTemp(void) const {
return _.Temp + kSharpAcMinTemp;
}
/// Get the operating mode setting of the A/C.
/// @return The current operating mode setting.
uint8_t IRSharpAc::getMode(void) const {
return _.Mode;
}
/// Set the operating mode of the A/C.
/// @param[in] mode The desired operating mode.
/// @param[in] save Do we save this setting as a user set one?
void IRSharpAc::setMode(const uint8_t mode, const bool save) {
uint8_t realMode = mode;
if (mode == kSharpAcHeat) {
switch (getModel()) {
case sharp_ac_remote_model_t::A705:
case sharp_ac_remote_model_t::A903:
// These models have no heat mode, use Fan mode instead.
realMode = kSharpAcFan;
break;
default:
break;
}
}
switch (realMode) {
case kSharpAcAuto: // Also kSharpAcFan
case kSharpAcDry:
// When Dry or Auto, Fan always 2(Auto)
setFan(kSharpAcFanAuto, false);
// FALLTHRU
case kSharpAcCool:
case kSharpAcHeat:
_.Mode = realMode;
break;
default:
setFan(kSharpAcFanAuto, false);
_.Mode = kSharpAcAuto;
}
// Dry/Auto have no temp setting. This step will enforce it.
setTemp(_temp, false);
// Save the mode in case we need to revert to it. eg. Clean
if (save) _mode = _.Mode;
_.Special = kSharpAcSpecialPower;
clearPowerSpecial();
}
/// Set the speed of the fan.
/// @param[in] speed The desired setting.
/// @param[in] save Do we save this setting as a user set one?
void IRSharpAc::setFan(const uint8_t speed, const bool save) {
switch (speed) {
case kSharpAcFanAuto:
case kSharpAcFanMin:
case kSharpAcFanMed:
case kSharpAcFanHigh:
case kSharpAcFanMax:
_.Fan = speed;
if (save) _fan = speed;
break;
default:
_.Fan = kSharpAcFanAuto;
_fan = kSharpAcFanAuto;
}
_.Special = kSharpAcSpecialFan;
clearPowerSpecial();
}
/// Get the current fan speed setting.
/// @return The current fan speed/mode.
uint8_t IRSharpAc::getFan(void) const {
return _.Fan;
}
/// Get the Turbo setting of the A/C.
/// @return true, the setting is on. false, the setting is off.
bool IRSharpAc::getTurbo(void) const {
return (_.PowerSpecial == kSharpAcPowerSetSpecialOn) &&
(_.Special == kSharpAcSpecialTurbo);
}
/// Set the Turbo setting of the A/C.
/// @param[in] on true, the setting is on. false, the setting is off.
/// @note If you use this method, you will need to send it before making
/// other changes to the settings, as they may overwrite some of the bits
/// used by this setting.
void IRSharpAc::setTurbo(const bool on) {
if (on) setFan(kSharpAcFanMax);
setPowerSpecial(on ? kSharpAcPowerSetSpecialOn : kSharpAcPowerSetSpecialOff);
_.Special = kSharpAcSpecialTurbo;
}
/// Get the Vertical Swing setting of the A/C.
/// @return The position of the Vertical Swing setting.
uint8_t IRSharpAc::getSwingV(void) const { return _.Swing; }
/// Set the Vertical Swing setting of the A/C.
/// @note Some positions may not work on all models.
/// @param[in] position The desired position/setting.
/// @note `setSwingV(kSharpAcSwingVLowest)` will only allow the Lowest setting
/// in Heat mode, it will default to `kSharpAcSwingVLow` otherwise.
/// If you want to set this value in other modes e.g. Cool, you must
/// use `setSwingV`s optional `force` parameter.
/// @param[in] force Do we override the safety checks and just do it?
void IRSharpAc::setSwingV(const uint8_t position, const bool force) {
switch (position) {
case kSharpAcSwingVCoanda:
// Only allowed in Heat mode.
if (!force && getMode() != kSharpAcHeat) {
setSwingV(kSharpAcSwingVLow); // Use the next lowest setting.
return;
}
// FALLTHRU
case kSharpAcSwingVHigh:
case kSharpAcSwingVMid:
case kSharpAcSwingVLow:
case kSharpAcSwingVToggle:
case kSharpAcSwingVOff:
case kSharpAcSwingVLast: // Technically valid, but we don't use it.
// All expected non-positions set the special bits.
_.Special = kSharpAcSpecialSwing;
// FALLTHRU
case kSharpAcSwingVIgnore:
_.Swing = position;
}
}
/// Convert a standard A/C vertical swing into its native setting.
/// @param[in] position A stdAc::swingv_t position to convert.
/// @return The equivalent native horizontal swing position.
uint8_t IRSharpAc::convertSwingV(const stdAc::swingv_t position) {
switch (position) {
case stdAc::swingv_t::kHighest:
case stdAc::swingv_t::kHigh: return kSharpAcSwingVHigh;
case stdAc::swingv_t::kMiddle: return kSharpAcSwingVMid;
case stdAc::swingv_t::kLow: return kSharpAcSwingVLow;
case stdAc::swingv_t::kLowest: return kSharpAcSwingVCoanda;
case stdAc::swingv_t::kAuto: return kSharpAcSwingVToggle;
case stdAc::swingv_t::kOff: return kSharpAcSwingVOff;
default: return kSharpAcSwingVIgnore;
}
}
/// Get the (vertical) Swing Toggle setting of the A/C.
/// @return true, the setting is on. false, the setting is off.
bool IRSharpAc::getSwingToggle(void) const {
return getSwingV() == kSharpAcSwingVToggle;
}
/// Set the (vertical) Swing Toggle setting of the A/C.
/// @param[in] on true, the setting is on. false, the setting is off.
void IRSharpAc::setSwingToggle(const bool on) {
setSwingV(on ? kSharpAcSwingVToggle : kSharpAcSwingVIgnore);
if (on) _.Special = kSharpAcSpecialSwing;
}
/// Get the Ion (Filter) setting of the A/C.
/// @return true, the setting is on. false, the setting is off.
bool IRSharpAc::getIon(void) const { return _.Ion; }
/// Set the Ion (Filter) setting of the A/C.
/// @param[in] on true, the setting is on. false, the setting is off.
void IRSharpAc::setIon(const bool on) {
_.Ion = on;
clearPowerSpecial();
if (on) _.Special = kSharpAcSpecialSwing;
}
/// Get the Economical mode toggle setting of the A/C.
/// @return true, the setting is on. false, the setting is off.
/// @note Shares the same location as the Light setting on A705.
bool IRSharpAc::_getEconoToggle(void) const {
return (_.PowerSpecial == kSharpAcPowerSetSpecialOn) &&
(_.Special == kSharpAcSpecialTempEcono);
}
/// Set the Economical mode toggle setting of the A/C.
/// @param[in] on true, the setting is on. false, the setting is off.
/// @warning Probably incompatible with `setTurbo()`
/// @note Shares the same location as the Light setting on A705.
void IRSharpAc::_setEconoToggle(const bool on) {
if (on) _.Special = kSharpAcSpecialTempEcono;
setPowerSpecial(on ? kSharpAcPowerSetSpecialOn : kSharpAcPowerSetSpecialOff);
}
/// Set the Economical mode toggle setting of the A/C.
/// @param[in] on true, the setting is on. false, the setting is off.
/// @warning Probably incompatible with `setTurbo()`
/// @note Available on the A907 models.
void IRSharpAc::setEconoToggle(const bool on) {
if (_model == sharp_ac_remote_model_t::A907) _setEconoToggle(on);
}
/// Get the Economical mode toggle setting of the A/C.
/// @return true, the setting is on. false, the setting is off.
/// @note Available on the A907 models.
bool IRSharpAc::getEconoToggle(void) const {
return _model == sharp_ac_remote_model_t::A907 && _getEconoToggle();
}
/// Set the Light mode toggle setting of the A/C.
/// @param[in] on true, the setting is on. false, the setting is off.
/// @warning Probably incompatible with `setTurbo()`
/// @note Not available on the A907 model.
void IRSharpAc::setLightToggle(const bool on) {
if (_model != sharp_ac_remote_model_t::A907) _setEconoToggle(on);
}
/// Get the Light toggle setting of the A/C.
/// @return true, the setting is on. false, the setting is off.
/// @note Not available on the A907 model.
bool IRSharpAc::getLightToggle(void) const {
return _model != sharp_ac_remote_model_t::A907 && _getEconoToggle();
}
/// Get how long the timer is set for, in minutes.
/// @return The time in nr of minutes.
uint16_t IRSharpAc::getTimerTime(void) const {
return _.TimerHours * kSharpAcTimerIncrement * 2 +
((_.Special == kSharpAcSpecialTimerHalfHour) ? kSharpAcTimerIncrement
: 0);
}
/// Is the Timer enabled?
/// @return true, the setting is on. false, the setting is off.
bool IRSharpAc::getTimerEnabled(void) const { return _.TimerEnabled; }
/// Get the current timer type.
/// @return true, It's an "On" timer. false, It's an "Off" timer.
bool IRSharpAc::getTimerType(void) const { return _.TimerType; }
/// Set or cancel the timer function.
/// @param[in] enable Is the timer to be enabled (true) or canceled(false)?
/// @param[in] timer_type An On (true) or an Off (false). Ignored if canceled.
/// @param[in] mins Nr. of minutes the timer is to be set to.
/// @note Rounds down to 30 min increments. (max: 720 mins (12h), 0 is Off)
void IRSharpAc::setTimer(bool enable, bool timer_type, uint16_t mins) {
uint8_t half_hours = std::min(mins / kSharpAcTimerIncrement,
kSharpAcTimerHoursMax * 2);
if (half_hours == 0) enable = false;
if (!enable) {
half_hours = 0;
timer_type = kSharpAcOffTimerType;
}
_.TimerEnabled = enable;
_.TimerType = timer_type;
_.TimerHours = half_hours / 2;
// Handle non-round hours.
_.Special = (half_hours % 2) ? kSharpAcSpecialTimerHalfHour
: kSharpAcSpecialTimer;
setPowerSpecial(kSharpAcPowerTimerSetting);
}
/// Get the Clean setting of the A/C.
/// @return true, the setting is on. false, the setting is off.
bool IRSharpAc::getClean(void) const {
return _.Clean;
}
/// Set the Economical mode toggle setting of the A/C.
/// @param[in] on true, the setting is on. false, the setting is off.
/// @note Officially A/C unit needs to be "Off" before clean mode can be entered
void IRSharpAc::setClean(const bool on) {
// Clean mode appears to be just default dry mode, with an extra bit set.
if (on) {
setMode(kSharpAcDry, false);
setPower(true, false);
} else {
// Restore the previous operation mode & fan speed.
setMode(_mode, false);
setFan(_fan, false);
}
_.Clean = on;
clearPowerSpecial();
}
/// Convert a stdAc::opmode_t enum into its native mode.
/// @param[in] mode The enum to be converted.
/// @return The native equivalent of the enum.
uint8_t IRSharpAc::convertMode(const stdAc::opmode_t mode) {
switch (mode) {
case stdAc::opmode_t::kCool: return kSharpAcCool;
case stdAc::opmode_t::kHeat: return kSharpAcHeat;
case stdAc::opmode_t::kDry: return kSharpAcDry;
// No Fan mode.
default: return kSharpAcAuto;
}
}
/// Convert a stdAc::fanspeed_t enum into it's native speed.
/// @param[in] speed The enum to be converted.
/// @param[in] model The enum of the appropriate model.
/// @return The native equivalent of the enum.
uint8_t IRSharpAc::convertFan(const stdAc::fanspeed_t speed,
const sharp_ac_remote_model_t model) {
switch (model) {
case sharp_ac_remote_model_t::A705:
case sharp_ac_remote_model_t::A903:
switch (speed) {
case stdAc::fanspeed_t::kLow: return kSharpAcFanA705Low;
case stdAc::fanspeed_t::kMedium: return kSharpAcFanA705Med;
default: {}; // Fall thru to the next/default clause if not the above
// special cases.
}
// FALL THRU
default:
switch (speed) {
case stdAc::fanspeed_t::kMin:
case stdAc::fanspeed_t::kLow: return kSharpAcFanMin;
case stdAc::fanspeed_t::kMedium: return kSharpAcFanMed;
case stdAc::fanspeed_t::kHigh: return kSharpAcFanHigh;
case stdAc::fanspeed_t::kMax: return kSharpAcFanMax;
default: return kSharpAcFanAuto;
}
}
}
/// Convert a native mode into its stdAc equivalent.
/// @param[in] mode The native setting to be converted.
/// @return The stdAc equivalent of the native setting.
stdAc::opmode_t IRSharpAc::toCommonMode(const uint8_t mode) const {
switch (mode) {
case kSharpAcCool: return stdAc::opmode_t::kCool;
case kSharpAcHeat: return stdAc::opmode_t::kHeat;
case kSharpAcDry: return stdAc::opmode_t::kDry;
case kSharpAcAuto: // Also kSharpAcFan
switch (getModel()) {
case sharp_ac_remote_model_t::A705: return stdAc::opmode_t::kFan;
default: return stdAc::opmode_t::kAuto;
}
break;
default: return stdAc::opmode_t::kAuto;
}
}
/// Convert a native fan speed into its stdAc equivalent.
/// @param[in] speed The native setting to be converted.
/// @return The stdAc equivalent of the native setting.
stdAc::fanspeed_t IRSharpAc::toCommonFanSpeed(const uint8_t speed) const {
switch (getModel()) {
case sharp_ac_remote_model_t::A705:
case sharp_ac_remote_model_t::A903:
switch (speed) {
case kSharpAcFanA705Low: return stdAc::fanspeed_t::kLow;
case kSharpAcFanA705Med: return stdAc::fanspeed_t::kMedium;
}
// FALL-THRU
default:
switch (speed) {
case kSharpAcFanMax: return stdAc::fanspeed_t::kMax;
case kSharpAcFanHigh: return stdAc::fanspeed_t::kHigh;
case kSharpAcFanMed: return stdAc::fanspeed_t::kMedium;
case kSharpAcFanMin: return stdAc::fanspeed_t::kMin;
default: return stdAc::fanspeed_t::kAuto;
}
}
}
/// Convert a native vertical swing postion to it's common equivalent.
/// @param[in] pos A native position to convert.
/// @param[in] mode What operating mode are we in?
/// @return The common vertical swing position.
stdAc::swingv_t IRSharpAc::toCommonSwingV(const uint8_t pos,
const stdAc::opmode_t mode) const {
switch (pos) {
case kSharpAcSwingVHigh: return stdAc::swingv_t::kHighest;
case kSharpAcSwingVMid: return stdAc::swingv_t::kMiddle;
case kSharpAcSwingVLow: return stdAc::swingv_t::kLow;
case kSharpAcSwingVCoanda: // Coanda has mode dependent positionss
switch (mode) {
case stdAc::opmode_t::kCool: return stdAc::swingv_t::kHighest;
case stdAc::opmode_t::kHeat: return stdAc::swingv_t::kLowest;
default: return stdAc::swingv_t::kOff;
}
case kSharpAcSwingVToggle: return stdAc::swingv_t::kAuto;
default: return stdAc::swingv_t::kOff;
}
}
/// Convert the current internal state into its stdAc::state_t equivalent.
/// @param[in] prev Ptr to the previous state if required.
/// @return The stdAc equivalent of the native settings.
stdAc::state_t IRSharpAc::toCommon(const stdAc::state_t *prev) const {
stdAc::state_t result{};
// Start with the previous state if given it.
if (prev != NULL) result = *prev;
result.protocol = decode_type_t::SHARP_AC;
result.model = getModel();
result.power = getPower();
result.mode = toCommonMode(_.Mode);
result.celsius = true;
result.degrees = getTemp();
result.fanspeed = toCommonFanSpeed(_.Fan);
result.turbo = getTurbo();
if (getSwingV() != kSharpAcSwingVIgnore)
result.swingv = toCommonSwingV(getSwingV(), result.mode);
result.filter = _.Ion;
result.econo = getEconoToggle();
result.light = getLightToggle();
result.clean = _.Clean;
// Not supported.
result.swingh = stdAc::swingh_t::kOff;
result.quiet = false;
result.beep = false;
result.sleep = -1;
result.clock = -1;
return result;
}
/// Convert the current internal state into a human readable string.
/// @return A human readable string.
String IRSharpAc::toString(void) const {
String result = "";
const sharp_ac_remote_model_t model = getModel();
result.reserve(170); // Reserve some heap for the string to reduce fragging.
result += addModelToString(decode_type_t::SHARP_AC, getModel(), false);
result += addLabeledString(isPowerSpecial() ? String("-")
: String(getPower() ? kOnStr
: kOffStr),
kPowerStr);
const uint8_t mode = _.Mode;
result += addModeToString(
mode,
// Make the value invalid if the model doesn't support an Auto mode.
(model == sharp_ac_remote_model_t::A907) ? kSharpAcAuto : 255,
kSharpAcCool, kSharpAcHeat, kSharpAcDry, kSharpAcFan);
result += addTempToString(getTemp());
switch (model) {
case sharp_ac_remote_model_t::A705:
case sharp_ac_remote_model_t::A903:
result += addFanToString(_.Fan, kSharpAcFanMax, kSharpAcFanA705Low,
kSharpAcFanAuto, kSharpAcFanAuto,
kSharpAcFanA705Med);
break;
default:
result += addFanToString(_.Fan, kSharpAcFanMax, kSharpAcFanMin,
kSharpAcFanAuto, kSharpAcFanAuto,
kSharpAcFanMed);
}
if (getSwingV() == kSharpAcSwingVIgnore) {
result += addIntToString(kSharpAcSwingVIgnore, kSwingVStr);
result += kSpaceLBraceStr;
result += kNAStr;
result += ')';
} else {
result += addSwingVToString(
getSwingV(), 0xFF,
// Coanda means Highest when in Cool mode.
(mode == kSharpAcCool) ? kSharpAcSwingVCoanda : kSharpAcSwingVToggle,
kSharpAcSwingVHigh,
0xFF, // Upper Middle is unused
kSharpAcSwingVMid,
0xFF, // Lower Middle is unused
kSharpAcSwingVLow,
kSharpAcSwingVCoanda,
kSharpAcSwingVOff,
// Below are unused.
kSharpAcSwingVToggle,
0xFF,
0xFF);
}
result += addBoolToString(getTurbo(), kTurboStr);
result += addBoolToString(_.Ion, kIonStr);
switch (model) {
case sharp_ac_remote_model_t::A705:
case sharp_ac_remote_model_t::A903:
result += addToggleToString(getLightToggle(), kLightStr);
break;
default:
result += addToggleToString(getEconoToggle(), kEconoStr);
}
result += addBoolToString(_.Clean, kCleanStr);
if (_.TimerEnabled)
result += addLabeledString(minsToString(getTimerTime()),
_.TimerType ? kOnTimerStr : kOffTimerStr);
return result;
}
#if DECODE_SHARP_AC
/// Decode the supplied Sharp A/C message.
/// Status: STABLE / Known working.
/// @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.
/// @see https://github.com/crankyoldgit/IRremoteESP8266/issues/638
/// @see https://github.com/ToniA/arduino-heatpumpir/blob/master/SharpHeatpumpIR.cpp
bool IRrecv::decodeSharpAc(decode_results *results, uint16_t offset,
const uint16_t nbits, const bool strict) {
// Compliance
if (strict && nbits != kSharpAcBits) return false;
// Match Header + Data + Footer
uint16_t used;
used = matchGeneric(results->rawbuf + offset, results->state,
results->rawlen - offset, nbits,
kSharpAcHdrMark, kSharpAcHdrSpace,
kSharpAcBitMark, kSharpAcOneSpace,
kSharpAcBitMark, kSharpAcZeroSpace,
kSharpAcBitMark, kSharpAcGap, true,
_tolerance, kMarkExcess, false);
if (used == 0) return false;
offset += used;
// Compliance
if (strict) {
if (!IRSharpAc::validChecksum(results->state)) return false;
}
// Success
results->decode_type = SHARP_AC;
results->bits = nbits;
// No need to record the state as we stored it as we decoded it.
// As we use result->state, we don't record value, address, or command as it
// is a union data type.
return true;
}
#endif // DECODE_SHARP_AC