/*
* EMS-ESP - https://github.com/emsesp/EMS-ESP
* Copyright 2020 Paul Derbyshire
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
#include "thermostat.h"
namespace emsesp {
REGISTER_FACTORY(Thermostat, EMSdevice::DeviceType::THERMOSTAT);
uuid::log::Logger Thermostat::logger_{F_(thermostat), uuid::log::Facility::CONSOLE};
Thermostat::Thermostat(uint8_t device_type, uint8_t device_id, uint8_t product_id, const std::string & version, const std::string & name, uint8_t flags, uint8_t brand)
: EMSdevice(device_type, device_id, product_id, version, name, flags, brand) {
uint8_t actual_master_thermostat = EMSESP::actual_master_thermostat(); // what we're actually using
uint8_t master_thermostat = EMSESP_DEFAULT_MASTER_THERMOSTAT;
EMSESP::webSettingsService.read([&](WebSettings & settings) {
master_thermostat = settings.master_thermostat; // what the user has defined
});
uint8_t model = this->model();
// if we're on auto mode, register this thermostat if it has a device id of 0x10, 0x17 or 0x18
// or if its the master thermostat we defined
// see https://github.com/emsesp/EMS-ESP/issues/362#issuecomment-629628161
if ((master_thermostat == device_id)
|| ((master_thermostat == EMSESP_DEFAULT_MASTER_THERMOSTAT) && (device_id < 0x19) && ((actual_master_thermostat == EMSESP_DEFAULT_MASTER_THERMOSTAT) || (device_id < actual_master_thermostat)))) {
EMSESP::actual_master_thermostat(device_id);
actual_master_thermostat = device_id;
reserve_telgram_functions(25); // reserve some space for the telegram registries, to avoid memory fragmentation
// common telegram handlers
register_telegram_type(EMS_TYPE_RCOutdoorTemp, F("RCOutdoorTemp"), false, MAKE_PF_CB(process_RCOutdoorTemp));
register_telegram_type(EMS_TYPE_RCTime, F("RCTime"), false, MAKE_PF_CB(process_RCTime));
register_telegram_type(0xA2, F("RCError"), false, MAKE_PF_CB(process_RCError));
register_telegram_type(0x12, F("RCErrorMessage"), false, MAKE_PF_CB(process_RCErrorMessage));
}
// RC10
if (model == EMSdevice::EMS_DEVICE_FLAG_RC10) {
monitor_typeids = {0xB1};
set_typeids = {0xB0};
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(monitor_typeids[i], F("RC10Monitor"), false, MAKE_PF_CB(process_RC10Monitor));
register_telegram_type(set_typeids[i], F("RC10Set"), false, MAKE_PF_CB(process_RC10Set));
}
// RC35
} else if ((model == EMSdevice::EMS_DEVICE_FLAG_RC35) || (model == EMSdevice::EMS_DEVICE_FLAG_RC30_N)) {
monitor_typeids = {0x3E, 0x48, 0x52, 0x5C};
set_typeids = {0x3D, 0x47, 0x51, 0x5B};
timer_typeids = {0x3F, 0x49, 0x53, 0x5D};
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(monitor_typeids[i], F("RC35Monitor"), false, MAKE_PF_CB(process_RC35Monitor));
register_telegram_type(set_typeids[i], F("RC35Set"), false, MAKE_PF_CB(process_RC35Set));
register_telegram_type(timer_typeids[i], F("RC35Timer"), false, MAKE_PF_CB(process_RC35Timer));
}
register_telegram_type(EMS_TYPE_IBASettings, F("IBASettings"), true, MAKE_PF_CB(process_IBASettings));
register_telegram_type(EMS_TYPE_wwSettings, F("WWSettings"), true, MAKE_PF_CB(process_RC35wwSettings));
// RC20
} else if (model == EMSdevice::EMS_DEVICE_FLAG_RC20) {
monitor_typeids = {0x91};
set_typeids = {0xA8};
if (actual_master_thermostat == device_id) {
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(monitor_typeids[i], F("RC20Monitor"), false, MAKE_PF_CB(process_RC20Monitor));
register_telegram_type(set_typeids[i], F("RC20Set"), false, MAKE_PF_CB(process_RC20Set));
}
} else {
register_telegram_type(0xAF, F("RC20Remote"), false, MAKE_PF_CB(process_RC20Remote));
}
// RC20 newer
} else if (model == EMSdevice::EMS_DEVICE_FLAG_RC20_N) {
monitor_typeids = {0xAE};
set_typeids = {0xAD};
if (actual_master_thermostat == device_id) {
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(monitor_typeids[i], F("RC20Monitor"), false, MAKE_PF_CB(process_RC20Monitor_2));
register_telegram_type(set_typeids[i], F("RC20Set"), false, MAKE_PF_CB(process_RC20Set_2));
}
} else {
register_telegram_type(0xAF, F("RC20Remote"), false, MAKE_PF_CB(process_RC20Remote));
}
// RC30
} else if (model == EMSdevice::EMS_DEVICE_FLAG_RC30) {
monitor_typeids = {0x41};
set_typeids = {0xA7};
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(monitor_typeids[i], F("RC30Monitor"), false, MAKE_PF_CB(process_RC30Monitor));
register_telegram_type(set_typeids[i], F("RC30Set"), false, MAKE_PF_CB(process_RC30Set));
}
// EASY
} else if (model == EMSdevice::EMS_DEVICE_FLAG_EASY) {
monitor_typeids = {0x0A};
set_typeids = {};
register_telegram_type(monitor_typeids[0], F("EasyMonitor"), true, MAKE_PF_CB(process_EasyMonitor));
} else if (model == EMSdevice::EMS_DEVICE_FLAG_CRF) {
monitor_typeids = {0x02A5, 0x02A6, 0x02A7, 0x02A8};
set_typeids = {};
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(monitor_typeids[i], F("CRFMonitor"), true, MAKE_PF_CB(process_CRFMonitor));
}
// RC300/RC100
} else if ((model == EMSdevice::EMS_DEVICE_FLAG_RC300) || (model == EMSdevice::EMS_DEVICE_FLAG_RC100)) {
monitor_typeids = {0x02A5, 0x02A6, 0x02A7, 0x02A8};
set_typeids = {0x02B9, 0x02BA, 0x02BB, 0x02BC};
summer_typeids = {0x02AF, 0x02B0, 0x02B1, 0x02B2};
curve_typeids = {0x029B, 0x029C, 0x029D, 0x029E};
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(monitor_typeids[i], F("RC300Monitor"), false, MAKE_PF_CB(process_RC300Monitor));
register_telegram_type(set_typeids[i], F("RC300Set"), false, MAKE_PF_CB(process_RC300Set));
register_telegram_type(summer_typeids[i], F("RC300Summer"), false, MAKE_PF_CB(process_RC300Summer));
register_telegram_type(curve_typeids[i], F("RC300Curves"), false, MAKE_PF_CB(process_RC300Curve));
}
register_telegram_type(0x2F5, F("RC300WWmode"), true, MAKE_PF_CB(process_RC300WWmode));
register_telegram_type(0x31B, F("RC300WWtemp"), true, MAKE_PF_CB(process_RC300WWtemp));
register_telegram_type(0x31D, F("RC300WWmode2"), false, MAKE_PF_CB(process_RC300WWmode2));
register_telegram_type(0x31E, F("RC300WWmode2"), false, MAKE_PF_CB(process_RC300WWmode2));
register_telegram_type(0x23A, F("RC300OutdoorTemp"), true, MAKE_PF_CB(process_RC300OutdoorTemp));
register_telegram_type(0x267, F("RC300Floordry"), false, MAKE_PF_CB(process_RC300Floordry));
register_telegram_type(0x240, F("RC300Settings"), true, MAKE_PF_CB(process_RC300Settings));
// JUNKERS/HT3
} else if (model == EMSdevice::EMS_DEVICE_FLAG_JUNKERS) {
monitor_typeids = {0x016F, 0x0170, 0x0171, 0x0172};
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(monitor_typeids[i], F("JunkersMonitor"), false, MAKE_PF_CB(process_JunkersMonitor));
}
if (has_flags(EMS_DEVICE_FLAG_JUNKERS_OLD)) {
// FR120, FR100
set_typeids = {0x0179, 0x017A, 0x017B, 0x017C};
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(set_typeids[i], F("JunkersSet"), false, MAKE_PF_CB(process_JunkersSet2));
}
} else {
set_typeids = {0x0165, 0x0166, 0x0167, 0x0168};
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
register_telegram_type(set_typeids[i], F("JunkersSet"), false, MAKE_PF_CB(process_JunkersSet));
}
}
}
// reserve some memory for the heating circuits (max 4 to start with)
heating_circuits_.reserve(4);
if (actual_master_thermostat != device_id) {
LOG_DEBUG(F("Adding new thermostat with device ID 0x%02X"), device_id);
return; // don't fetch data if more than 1 thermostat
}
//
// this next section is only for the master thermostat....
//
LOG_DEBUG(F("Adding new thermostat with device ID 0x%02X (as master)"), device_id);
// register device values for common values (not heating circuit)
register_device_values();
// only for for the master-thermostat, go a query all the heating circuits. This is only done once.
// The automatic fetch will from now on only update the active heating circuits
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
EMSESP::send_read_request(monitor_typeids[i], device_id);
}
// HA will report an error in the climate component if it doesn't have the setpoint temp, current temperatures and the mode (e.g. auto)
// The mode always comes later (1 minute) so we force a read request to suppress HA errors.
// https://github.com/emsesp/EMS-ESP/commit/9d5bd11d268a61bbba8dcabacdb96db48b8829ac#commitcomment-48028642
for (uint8_t i = 0; i < set_typeids.size(); i++) {
EMSESP::send_read_request(set_typeids[i], device_id);
}
EMSESP::send_read_request(EMS_TYPE_RCTime, device_id);
EMSESP::send_read_request(0x12, device_id); // read last error (only published on errors)
EMSESP::send_read_request(0xA2, device_id); // read errorCode (only published on errors)
}
// publish HA config
bool Thermostat::publish_ha_config() {
StaticJsonDocument doc;
doc["uniq_id"] = F_(thermostat);
char stat_t[Mqtt::MQTT_TOPIC_MAX_SIZE];
snprintf_P(stat_t, sizeof(stat_t), PSTR("%s/%s"), Mqtt::base().c_str(), Mqtt::tag_to_topic(device_type(), DeviceValueTAG::TAG_NONE).c_str());
doc["stat_t"] = stat_t;
doc["name"] = FJSON("ID");
doc["val_tpl"] = FJSON("{{value_json.id}}");
JsonObject dev = doc.createNestedObject("dev");
dev["name"] = FJSON("EMS-ESP Thermostat");
dev["sw"] = EMSESP_APP_VERSION;
dev["mf"] = brand_to_string();
dev["mdl"] = name();
JsonArray ids = dev.createNestedArray("ids");
ids.add("ems-esp-thermostat");
char topic[Mqtt::MQTT_TOPIC_MAX_SIZE];
snprintf_P(topic, sizeof(topic), PSTR("sensor/%s/thermostat/config"), Mqtt::base().c_str());
Mqtt::publish_ha(topic, doc.as()); // publish the config payload with retain flag
return true;
}
// returns the heating circuit object based on the hc number
// of nullptr if it doesn't exist yet
std::shared_ptr Thermostat::heating_circuit(const uint8_t hc_num) {
// if hc_num is 0 then return the first existing hc in the list
if (hc_num == AUTO_HEATING_CIRCUIT) {
for (const auto & heating_circuit : heating_circuits_) {
if (heating_circuit->is_active()) {
return heating_circuit;
}
}
}
// otherwise find a match
for (const auto & heating_circuit : heating_circuits_) {
if ((heating_circuit->hc_num() == hc_num) && heating_circuit->is_active()) {
return heating_circuit;
}
}
return nullptr; // not found
}
// determine which heating circuit the type ID is referring too
// returns pointer to the HeatingCircuit or nullptr if it can't be found
// if its a new one, the object will be created and also the fetch flags set
std::shared_ptr Thermostat::heating_circuit(std::shared_ptr telegram) {
// look through the Monitor and Set arrays to see if there is a match
uint8_t hc_num = 0;
bool toggle_ = false;
// search monitor message types
for (uint8_t i = 0; i < monitor_typeids.size(); i++) {
if (monitor_typeids[i] == telegram->type_id) {
hc_num = i + 1;
toggle_ = true;
break;
}
}
// not found, search status message/set types
if (hc_num == 0) {
for (uint8_t i = 0; i < set_typeids.size(); i++) {
if (set_typeids[i] == telegram->type_id) {
hc_num = i + 1;
break;
}
}
}
// not found, search summer message types
if (hc_num == 0) {
for (uint8_t i = 0; i < summer_typeids.size(); i++) {
if (summer_typeids[i] == telegram->type_id) {
hc_num = i + 1;
break;
}
}
}
// not found, search heating_curve message types
if (hc_num == 0) {
for (uint8_t i = 0; i < curve_typeids.size(); i++) {
if (curve_typeids[i] == telegram->type_id) {
hc_num = i + 1;
break;
}
}
}
// not found, search timer message types
if (hc_num == 0) {
for (uint8_t i = 0; i < timer_typeids.size(); i++) {
if (timer_typeids[i] == telegram->type_id) {
hc_num = i + 1;
break;
}
}
}
// not found, search device-id types for remote thermostats
if (telegram->src >= 0x18 && telegram->src <= 0x1B) {
hc_num = telegram->src - 0x17;
}
// still didn't recognize it, ignore it
if (hc_num == 0) {
return nullptr;
}
// if we have the heating circuit already present, returns its object
// otherwise create a new object and add it
for (const auto & heating_circuit : heating_circuits_) {
if (heating_circuit->hc_num() == hc_num) {
return heating_circuit;
}
}
// register new heatingcircuits only on active monitor telegrams
if (!toggle_) {
return nullptr;
}
/*
* at this point we have discovered a new heating circuit
*/
// if it's the first set the status flag
if (heating_circuits_.size() == 0) {
strlcpy(status_, "online", sizeof(status_));
id_ = this->product_id();
}
// create a new heating circuit object
auto new_hc = std::make_shared(hc_num, model());
heating_circuits_.push_back(new_hc);
// sort based on hc number so there's a nice order when displaying
std::sort(heating_circuits_.begin(), heating_circuits_.end());
// register the device values
register_device_values_hc(new_hc);
// now create the HA topics to send to MQTT for each sensor
if (Mqtt::ha_enabled()) {
register_mqtt_ha_config_hc(hc_num);
}
// set the flag saying we want its data during the next auto fetch
toggle_fetch(monitor_typeids[hc_num - 1], toggle_);
if (set_typeids.size()) {
toggle_fetch(set_typeids[hc_num - 1], toggle_);
}
if (summer_typeids.size()) {
toggle_fetch(summer_typeids[hc_num - 1], toggle_);
}
if (curve_typeids.size()) {
toggle_fetch(curve_typeids[hc_num - 1], toggle_);
}
if (timer_typeids.size()) {
toggle_fetch(timer_typeids[hc_num - 1], toggle_);
}
return heating_circuits_.back(); // even after sorting, this should still point back to the newly created HC
}
// publish config topic for HA MQTT Discovery for each of the heating circuit
// e.g. homeassistant/climate/ems-esp/thermostat_hc1/config
void Thermostat::register_mqtt_ha_config_hc(uint8_t hc_num) {
StaticJsonDocument doc;
char str1[20];
snprintf_P(str1, sizeof(str1), PSTR("Thermostat hc%d"), hc_num);
char str2[20];
snprintf_P(str2, sizeof(str2), PSTR("thermostat_hc%d"), hc_num);
char str3[25];
snprintf_P(str3, sizeof(str3), PSTR("~/%s"), str2);
doc["mode_cmd_t"] = str3;
doc["temp_cmd_t"] = str3;
doc["name"] = str1;
doc["uniq_id"] = str2;
doc["mode_cmd_t"] = str3;
doc["temp_cmd_t"] = str3;
doc["~"] = Mqtt::base(); // ems-esp
char topic_t[Mqtt::MQTT_TOPIC_MAX_SIZE];
if (Mqtt::nested_format() == 1) {
snprintf_P(topic_t, sizeof(topic_t), PSTR("~/%s"), Mqtt::tag_to_topic(EMSdevice::DeviceType::THERMOSTAT, DeviceValueTAG::TAG_NONE).c_str());
char mode_str_tpl[40];
snprintf_P(mode_str_tpl, sizeof(mode_str_tpl), PSTR("{{value_json.hc%d.hamode}}"), hc_num);
doc["mode_stat_tpl"] = mode_str_tpl;
char seltemp_str[30];
snprintf_P(seltemp_str, sizeof(seltemp_str), PSTR("{{value_json.hc%d.seltemp}}"), hc_num);
doc["temp_stat_tpl"] = seltemp_str;
char currtemp_str[30];
snprintf_P(currtemp_str, sizeof(currtemp_str), PSTR("{{value_json.hc%d.hatemp}}"), hc_num);
doc["curr_temp_tpl"] = currtemp_str;
} else {
snprintf_P(topic_t, sizeof(topic_t), PSTR("~/%s"), Mqtt::tag_to_topic(EMSdevice::DeviceType::THERMOSTAT, DeviceValueTAG::TAG_HC1 + hc_num - 1).c_str());
doc["mode_stat_tpl"] = FJSON("{{value_json.hamode}}");
doc["temp_stat_tpl"] = FJSON("{{value_json.seltemp}}");
doc["curr_temp_tpl"] = FJSON("{{value_json.hatemp}}");
}
doc["mode_stat_t"] = topic_t;
doc["temp_stat_t"] = topic_t;
doc["curr_temp_t"] = topic_t;
doc["min_temp"] = FJSON("5");
doc["max_temp"] = FJSON("30");
doc["temp_step"] = FJSON("0.5");
// the HA climate component only responds to auto, heat and off
JsonArray modes = doc.createNestedArray("modes");
modes.add("auto");
modes.add("heat");
modes.add("off");
JsonObject dev = doc.createNestedObject("dev");
dev["name"] = FJSON("EMS-ESP Thermostat");
dev["sw"] = EMSESP_APP_VERSION;
dev["mf"] = brand_to_string();
dev["mdl"] = name();
JsonArray ids = dev.createNestedArray("ids");
ids.add("ems-esp-thermostat");
char topic[Mqtt::MQTT_TOPIC_MAX_SIZE];
snprintf_P(topic, sizeof(topic), PSTR("climate/%s/thermostat_hc%d/config"), Mqtt::base().c_str(), hc_num);
Mqtt::publish_ha(topic, doc.as()); // publish the config payload with retain flag
// enable the a special "thermostat_hc" topic to take both mode strings and floats for each of the heating circuits
std::string topic2(Mqtt::MQTT_TOPIC_MAX_SIZE, '\0');
snprintf_P(&topic2[0], topic2.capacity() + 1, PSTR("thermostat_hc%d"), hc_num);
register_mqtt_topic(topic2, [=](const char * m) { return thermostat_ha_cmd(m, hc_num); });
}
// for HA specifically when receiving over MQTT in the thermostat topic
// e.g. thermostat_hc1
// it could be either a 'mode' or a float value for a temperature. we try brute force both and see which one works.
// return true if it parses the message correctly
bool Thermostat::thermostat_ha_cmd(const char * message, uint8_t hc_num) {
// check if it's json. We know the message isn't empty
if (message[0] == '{') {
return false;
}
// check for mode first, which is a string
if (!set_mode(message, hc_num)) {
// otherwise handle as a numerical temperature value and set the setpoint temp
float f = strtof((char *)message, 0);
set_temperature(f, HeatingCircuit::Mode::AUTO, hc_num);
}
return true;
}
// decodes the thermostat mode for the heating circuit based on the thermostat type
// modes are off, manual, auto, day, night and holiday
uint8_t Thermostat::HeatingCircuit::get_mode() const {
uint8_t model = get_model();
if (!Helpers::hasValue(mode)) {
return HeatingCircuit::Mode::UNKNOWN;
}
if (model == EMSdevice::EMS_DEVICE_FLAG_RC20) {
if (mode == 0) {
return HeatingCircuit::Mode::OFF;
} else if (mode == 1) {
return HeatingCircuit::Mode::MANUAL;
} else if (mode == 2) {
return HeatingCircuit::Mode::AUTO;
}
} else if (model == EMSdevice::EMS_DEVICE_FLAG_CRF) {
if (mode == 0) {
return HeatingCircuit::Mode::AUTO;
} else if (mode == 1) {
return HeatingCircuit::Mode::OFF;
}
} else if ((model == EMSdevice::EMS_DEVICE_FLAG_RC300) || (model == EMSdevice::EMS_DEVICE_FLAG_RC100)) {
if (mode == 0) {
return HeatingCircuit::Mode::MANUAL;
} else if (mode == 1) {
return HeatingCircuit::Mode::AUTO;
}
} else if (model == EMSdevice::EMS_DEVICE_FLAG_JUNKERS) {
if (mode == 1) {
return HeatingCircuit::Mode::MANUAL;
} else if (mode == 2) {
return HeatingCircuit::Mode::AUTO;
} else if (mode == 3) {
return HeatingCircuit::Mode::HOLIDAY;
}
} else { // default for all other thermostats
if (mode == 0) {
return HeatingCircuit::Mode::NIGHT;
} else if (mode == 1) {
return HeatingCircuit::Mode::DAY;
} else if (mode == 2) {
return HeatingCircuit::Mode::AUTO;
}
}
return HeatingCircuit::Mode::UNKNOWN;
}
// figures out the thermostat day/night mode depending on the thermostat type
// mode types are day, night, eco, comfort
uint8_t Thermostat::HeatingCircuit::get_mode_type() const {
uint8_t model = get_model();
if (model == EMS_DEVICE_FLAG_JUNKERS) {
if (modetype == 3) {
return HeatingCircuit::Mode::HEAT;
} else if (modetype == 2) {
return HeatingCircuit::Mode::ECO;
} else if (modetype == 1) {
return HeatingCircuit::Mode::NOFROST;
}
} else if ((model == EMS_DEVICE_FLAG_RC35) || (model == EMS_DEVICE_FLAG_RC30_N)) {
if (modetype == 0) {
return HeatingCircuit::Mode::NIGHT;
} else if (modetype == 1) {
return HeatingCircuit::Mode::DAY;
}
} else if (model == EMS_DEVICE_FLAG_CRF) {
if (modetype == 0) {
return HeatingCircuit::Mode::OFF;
} else if (modetype == 1) {
return HeatingCircuit::Mode::ON;
}
} else if (model == EMS_DEVICE_FLAG_RC300) {
if (modetype == 0) {
return HeatingCircuit::Mode::ECO;
} else if (modetype == 1) {
return HeatingCircuit::Mode::COMFORT;
}
} else if (model == EMS_DEVICE_FLAG_RC100) {
return HeatingCircuit::Mode::DAY; // no other modes on these devices
}
return HeatingCircuit::Mode::DAY;
}
// decodes the thermostat mode based on the thermostat type
// works with both modes and mode_types
std::string Thermostat::mode_tostring(uint8_t mode) {
switch (mode) {
case HeatingCircuit::Mode::OFF:
return read_flash_string(F_(off));
break;
case HeatingCircuit::Mode::MANUAL:
return read_flash_string(F_(manual));
break;
case HeatingCircuit::Mode::DAY:
return read_flash_string(F_(day));
break;
case HeatingCircuit::Mode::NIGHT:
return read_flash_string(F_(night));
break;
case HeatingCircuit::Mode::ECO:
return read_flash_string(F_(eco));
break;
case HeatingCircuit::Mode::COMFORT:
return read_flash_string(F_(comfort));
break;
case HeatingCircuit::Mode::HEAT:
return read_flash_string(F_(heat));
break;
case HeatingCircuit::Mode::HOLIDAY:
return read_flash_string(F_(holiday));
break;
case HeatingCircuit::Mode::NOFROST:
return read_flash_string(F_(nofrost));
break;
case HeatingCircuit::Mode::AUTO:
return read_flash_string(F_(auto));
break;
case HeatingCircuit::Mode::SUMMER:
return read_flash_string(F_(summer));
break;
case HeatingCircuit::Mode::OFFSET:
return read_flash_string(F_(offset));
break;
case HeatingCircuit::Mode::DESIGN:
return read_flash_string(F_(design));
break;
case HeatingCircuit::Mode::MINFLOW:
return read_flash_string(F_(minflow));
break;
case HeatingCircuit::Mode::MAXFLOW:
return read_flash_string(F_(maxflow));
break;
case HeatingCircuit::Mode::ROOMINFLUENCE:
return read_flash_string(F_(roominfluence[0]));
break;
case HeatingCircuit::Mode::FLOWOFFSET:
return read_flash_string(F_(flowtempoffset[0]));
break;
case HeatingCircuit::Mode::TEMPAUTO:
return read_flash_string(F_(tempauto));
break;
case HeatingCircuit::Mode::NOREDUCE:
return read_flash_string(F_(noreduce));
break;
default:
case HeatingCircuit::Mode::UNKNOWN:
return read_flash_string(F_(unknown));
break;
}
}
// 0xA8 - for reading the mode from the RC20 thermostat (0x17)
void Thermostat::process_RC20Set(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->mode, 23));
}
// type 0xAE - data from the RC20 thermostat (0x17) - not for RC20's
// 17 00 AE 00 80 12 2E 00 D0 00 00 64 (#data=8)
void Thermostat::process_RC20Monitor_2(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_bitvalue(hc->modetype, 0, 7)); // day/night MSB 7th bit is day
has_update(telegram->read_value(hc->setpoint_roomTemp, 2, 1)); // is * 2, force as single byte
has_update(telegram->read_value(hc->curr_roomTemp, 3)); // is * 10
}
// 0xAD - for reading the mode from the RC20/ES72 thermostat (0x17)
// see https://github.com/emsesp/EMS-ESP/issues/334#issuecomment-611698259
// offset: 01-nighttemp, 02-daytemp, 03-mode, 0B-program(1-9), 0D-setpoint_roomtemp(temporary)
void Thermostat::process_RC20Set_2(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->nighttemp, 1)); // is * 2,
has_update(telegram->read_value(hc->daytemp, 2)); // is * 2,
has_update(telegram->read_value(hc->mode, 3));
has_update(telegram->read_value(hc->program, 11)); // 1 .. 9 predefined programs
}
// 0xAF - for reading the roomtemperature from the RC20/ES72 thermostat (0x18, 0x19, ..)
void Thermostat::process_RC20Remote(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->curr_roomTemp, 0));
}
// type 0xB1 - data from the RC10 thermostat (0x17)
void Thermostat::process_RC10Monitor(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->setpoint_roomTemp, 1, 1)); // is * 2, force as single byte
has_update(telegram->read_value(hc->curr_roomTemp, 2)); // is * 10
}
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-parameter"
// type 0xB0 - for reading the mode from the RC10 thermostat (0x17)
void Thermostat::process_RC10Set(std::shared_ptr telegram) {
// mode not implemented yet
}
#pragma GCC diagnostic pop
// type 0x0165, ff
void Thermostat::process_JunkersSet(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->daytemp, 17)); // is * 2
has_update(telegram->read_value(hc->nighttemp, 16)); // is * 2
has_update(telegram->read_value(hc->nofrosttemp, 15)); // is * 2
}
// type 0x0179, ff
void Thermostat::process_JunkersSet2(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->daytemp, 7)); // is * 2
has_update(telegram->read_value(hc->nighttemp, 6)); // is * 2
has_update(telegram->read_value(hc->nofrosttemp, 5)); // is * 2
}
// type 0xA3 - for external temp settings from the the RC* thermostats (e.g. RC35)
void Thermostat::process_RCOutdoorTemp(std::shared_ptr telegram) {
has_update(telegram->read_value(dampedoutdoortemp_, 0));
has_update(telegram->read_value(tempsensor1_, 3)); // sensor 1 - is * 10
has_update(telegram->read_value(tempsensor2_, 5)); // sensor 2 - is * 10
}
// 0x91 - data from the RC20 thermostat (0x17) - 15 bytes long
void Thermostat::process_RC20Monitor(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->setpoint_roomTemp, 1, 1)); // is * 2, force as single byte
has_update(telegram->read_value(hc->curr_roomTemp, 2)); // is * 10
}
// type 0x0A - data from the Nefit Easy/TC100 thermostat (0x18) - 31 bytes long
void Thermostat::process_EasyMonitor(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->curr_roomTemp, 8)); // is * 100
has_update(telegram->read_value(hc->setpoint_roomTemp, 10)); // is * 100
}
// Settings Parameters - 0xA5 - RC30_1
void Thermostat::process_IBASettings(std::shared_ptr telegram) {
// 22 - display line on RC35
// display on Thermostat: 0 int. temp, 1 int. setpoint, 2 ext. temp., 3 burner temp., 4 ww temp, 5 functioning mode, 6 time, 7 data, 8 smoke temp
has_update(telegram->read_value(ibaMainDisplay_, 0));
has_update(telegram->read_value(ibaLanguage_, 1)); // language on Thermostat: 0 german, 1 dutch, 2 french, 3 italian
has_update(telegram->read_value(ibaCalIntTemperature_, 2)); // offset int. temperature sensor, by * 0.1 Kelvin
has_update(telegram->read_value(ibaBuildingType_, 6)); // building type: 0 = light, 1 = medium, 2 = heavy
has_update(telegram->read_value(ibaMinExtTemperature_, 5)); // min ext temp for heating curve, in deg., 0xF6=-10, 0x0 = 0, 0xFF=-1
has_update(telegram->read_value(ibaClockOffset_, 12)); // offset (in sec) to clock, 0xff = -1 s, 0x02 = 2 s
}
// Settings WW 0x37 - RC35
void Thermostat::process_RC35wwSettings(std::shared_ptr telegram) {
has_update(telegram->read_value(wwMode_, 2)); // 0 off, 1-on, 2-auto
has_update(telegram->read_value(wwCircMode_, 3)); // 0 off, 1-on, 2-auto
}
// type 0x6F - FR10/FR50/FR100/FR110/FR120 Junkers
void Thermostat::process_JunkersMonitor(std::shared_ptr telegram) {
// ignore single byte telegram messages
if (telegram->message_length <= 1) {
return;
}
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->curr_roomTemp, 4)); // value is * 10
has_update(telegram->read_value(hc->setpoint_roomTemp, 2)); // value is * 10
has_update(telegram->read_value(hc->modetype, 0)); // 1 = nofrost, 2 = eco, 3 = heat
has_update(telegram->read_value(hc->mode, 1)); // 1 = manual, 2 = auto
}
// type 0x02A5 - data from Worchester CRF200
void Thermostat::process_CRFMonitor(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->curr_roomTemp, 0)); // is * 10
has_update(telegram->read_bitvalue(hc->modetype, 2, 0));
has_update(telegram->read_bitvalue(hc->mode, 2, 4)); // bit 4, mode (auto=0 or off=1)
has_update(telegram->read_value(hc->setpoint_roomTemp, 6, 1)); // is * 2, force as single byte
has_update(telegram->read_value(hc->targetflowtemp, 4));
}
// type 0x02A5 - data from the Nefit RC1010/3000 thermostat (0x18) and RC300/310s on 0x10
void Thermostat::process_RC300Monitor(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->curr_roomTemp, 0)); // is * 10
has_update(telegram->read_bitvalue(hc->modetype, 10, 1));
has_update(telegram->read_bitvalue(hc->mode, 10, 0)); // bit 1, mode (auto=1 or manual=0)
// if manual, take the current setpoint temp at pos 6
// if auto, take the next setpoint temp at pos 7
// pos 3 is the current target temp and sometimes can be 0
// see https://github.com/emsesp/EMS-ESP/issues/256#issuecomment-585171426
// pos 3 actual setpoint (optimized), i.e. changes with temporary change, summer/holiday-modes
// pos 6 actual setpoint according to programmed changes eco/comfort
// pos 7 next setpoint in the future, time to next setpoint in pos 8/9
has_update(telegram->read_value(hc->setpoint_roomTemp, 3, 1)); // is * 2, force as single byte
has_update(telegram->read_bitvalue(hc->summermode, 2, 4));
has_update(telegram->read_value(hc->targetflowtemp, 4));
}
// type 0x02B9 EMS+ for reading from RC300/RC310 thermostat
void Thermostat::process_RC300Set(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
// NOTE when setting the room temp we pick from two values, hopefully one is correct!
// manual is position 10
// comfort is position 2, there are 3 levels in pos 3, 2, 1
// eco is position 4
// auto is position 8, temporary until next switch
// actual setpoint taken from RC300Monitor (Michael 12.06.2020)
// has_update(telegram->read_value(hc->setpoint_roomTemp, 8, 1); // single byte conversion, value is * 2 - auto?
// has_update(telegram->read_value(hc->setpoint_roomTemp, 10, 1); // single byte conversion, value is * 2 - manual
// check why mode is both in the Monitor and Set for the RC300. It'll be read twice!
// has_update(telegram->read_value(hc->mode, 0); // Auto = xFF, Manual = x00 eg. 10 00 FF 08 01 B9 FF
has_update(telegram->read_value(hc->daytemp, 2)); // is * 2
has_update(telegram->read_value(hc->nighttemp, 4)); // is * 2
has_update(telegram->read_value(hc->tempautotemp, 8));
has_update(telegram->read_value(hc->manualtemp, 10)); // is * 2
has_update(telegram->read_value(hc->program, 11)); // timer program 1 or 2
}
// types 0x2AF ff
void Thermostat::process_RC300Summer(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->roominfluence, 0));
has_update(telegram->read_value(hc->offsettemp, 2));
has_update(telegram->read_value(hc->summertemp, 6));
has_update(telegram->read_value(hc->summer_setmode, 7));
if (hc->heatingtype < 3) {
has_update(telegram->read_value(hc->designtemp, 4));
} else {
has_update(telegram->read_value(hc->designtemp, 5));
}
has_update(telegram->read_value(hc->minflowtemp, 8));
}
// types 0x29B ff
void Thermostat::process_RC300Curve(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->controlmode, 0)); // 1-outdoor, 2-simple, 3-MPC, 4-room, 5-power, 6-const
has_update(telegram->read_value(hc->heatingtype, 1)); // 1=radiator, 2=convector, 3=floor
has_update(telegram->read_value(hc->nofrosttemp, 6));
if (hc->heatingtype < 3) {
has_update(telegram->read_value(hc->maxflowtemp, 8));
} else {
has_update(telegram->read_value(hc->maxflowtemp, 7));
}
}
// types 0x31B (and 0x31C?)
void Thermostat::process_RC300WWtemp(std::shared_ptr telegram) {
has_update(telegram->read_value(wwSetTemp_, 0));
has_update(telegram->read_value(wwSetTempLow_, 1));
}
// type 02F5
// RC300WWmode(0x2F5), data: 01 FF 04 00 00 00 08 05 00 08 04 00 00 00 00 00 00 00 00 00 01
void Thermostat::process_RC300WWmode(std::shared_ptr telegram) {
// circulation pump see: https://github.com/Th3M3/buderus_ems-wiki/blob/master/Einstellungen%20der%20Bedieneinheit%20RC310.md
has_update(telegram->read_value(wwCircPump_, 1)); // FF=off, 0=on ?
has_update(telegram->read_value(wwMode_, 2)); // 0=off, 1=low, 2=high, 3=auto, 4=own prog
has_update(telegram->read_value(wwCircMode_, 3)); // 0=off, 1=on, 2=auto, 4=own?
}
// types 0x31D and 0x31E
// RC300WWmode2(0x31D), data: 00 00 09 07
void Thermostat::process_RC300WWmode2(std::shared_ptr telegram) {
// 0x31D for WW system 1, 0x31E for WW system 2
// pos 1 = holiday mode
// pos 2 = current status of DHW setpoint
// pos 3 = current status of DHW circulation pump
if (telegram->type_id == 0x031D) {
has_update(telegram->read_value(wwExtra1_, 0)); // 0=no, 1=yes
} else {
has_update(telegram->read_value(wwExtra2_, 0)); // 0=no, 1=yes
}
}
// 0x23A damped outdoor temp
void Thermostat::process_RC300OutdoorTemp(std::shared_ptr telegram) {
has_update(telegram->read_value(dampedoutdoortemp2_, 0)); // is *10
}
// 0x240 RC300 parameter
void Thermostat::process_RC300Settings(std::shared_ptr telegram) {
has_update(telegram->read_value(ibaBuildingType_, 9)); // 1=light, 2=medium, 3=heavy
has_update(telegram->read_value(ibaMinExtTemperature_, 10));
}
// 0x267 RC300 floordrying
void Thermostat::process_RC300Floordry(std::shared_ptr telegram) {
has_update(telegram->read_value(floordrystatus_, 0));
has_update(telegram->read_value(floordrytemp_, 1));
}
// type 0x41 - data from the RC30 thermostat(0x10) - 14 bytes long
void Thermostat::process_RC30Monitor(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->setpoint_roomTemp, 1, 1)); // is * 2, force as single byte
has_update(telegram->read_value(hc->curr_roomTemp, 2));
}
// type 0xA7 - for reading the mode from the RC30 thermostat (0x10)
void Thermostat::process_RC30Set(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->mode, 23));
}
// type 0x3E (HC1), 0x48 (HC2), 0x52 (HC3), 0x5C (HC4) - data from the RC35 thermostat (0x10) - 16 bytes
void Thermostat::process_RC35Monitor(std::shared_ptr telegram) {
// exit if the 15th byte (second from last) is 0x00, which I think is calculated flow setpoint temperature
// with weather controlled RC35s this value is >=5, otherwise can be zero and our setpoint temps will be incorrect
// see https://github.com/emsesp/EMS-ESP/issues/373#issuecomment-627907301
if (telegram->offset > 0 || telegram->message_length < 15) {
return;
}
if (telegram->message_data[14] == 0x00) {
return;
}
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->setpoint_roomTemp, 2, 1)); // is * 2, force to single byte, is 0 in summermode
has_update(telegram->read_value(hc->curr_roomTemp, 3)); // is * 10 - or 0x7D00 if thermostat is mounted on boiler
has_update(telegram->read_bitvalue(hc->modetype, 1, 1));
has_update(telegram->read_bitvalue(hc->summermode, 1, 0));
has_update(telegram->read_bitvalue(hc->holidaymode, 0, 5));
has_update(telegram->read_value(hc->targetflowtemp, 14));
}
// type 0x3D (HC1), 0x47 (HC2), 0x51 (HC3), 0x5B (HC4) - Working Mode Heating - for reading the mode from the RC35 thermostat (0x10)
void Thermostat::process_RC35Set(std::shared_ptr telegram) {
// check to see we have a valid type. heating: 1 radiator, 2 convectors, 3 floors, 4 room supply
if (telegram->offset == 0 && telegram->message_data[0] == 0x00) {
return;
}
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->heatingtype, 0)); // 0- off, 1-radiator, 2-convector, 3-floor
has_update(telegram->read_value(hc->nighttemp, 1)); // is * 2
has_update(telegram->read_value(hc->daytemp, 2)); // is * 2
has_update(telegram->read_value(hc->holidaytemp, 3)); // is * 2
has_update(telegram->read_value(hc->roominfluence, 4)); // is * 1
has_update(telegram->read_value(hc->offsettemp, 6)); // is * 2
has_update(telegram->read_value(hc->mode, 7)); // night, day, auto
has_update(telegram->read_value(hc->summertemp, 22)); // is * 1
has_update(telegram->read_value(hc->nofrosttemp, 23)); // is * 1
has_update(telegram->read_value(hc->flowtempoffset, 24)); // is * 1, only in mixed circuits
has_update(telegram->read_value(hc->reducemode, 25)); // 0-nofrost, 1-reduce, 2-roomhold, 3-outdoorhold
has_update(telegram->read_value(hc->control, 26)); // 0-off, 1-RC20 (remote), 2-RC35
has_update(telegram->read_value(hc->controlmode, 33)); // 0-outdoortemp, 1-roomtemp
has_update(telegram->read_value(hc->tempautotemp, 37));
has_update(telegram->read_value(hc->noreducetemp, 38)); // outdoor temperature for no reduce
has_update(telegram->read_value(hc->minflowtemp, 16));
if (hc->heatingtype == 3) {
has_update(telegram->read_value(hc->designtemp, 36)); // is * 1
has_update(telegram->read_value(hc->maxflowtemp, 35)); // is * 1
} else {
has_update(telegram->read_value(hc->designtemp, 17)); // is * 1
has_update(telegram->read_value(hc->maxflowtemp, 15)); // is * 1
}
}
// type 0x3F (HC1), 0x49 (HC2), 0x53 (HC3), 0x5D (HC4) - timer setting
void Thermostat::process_RC35Timer(std::shared_ptr telegram) {
std::shared_ptr hc = heating_circuit(telegram);
if (hc == nullptr) {
return;
}
has_update(telegram->read_value(hc->program, 84)); // 0 .. 10, 0-userprogram 1, 10-userprogram 2
has_update(telegram->read_value(hc->pause, 85)); // time in hours
has_update(telegram->read_value(hc->party, 86)); // time in hours
}
// process_RCTime - type 0x06 - date and time from a thermostat - 14 bytes long
void Thermostat::process_RCTime(std::shared_ptr telegram) {
if (telegram->offset > 0 || telegram->message_length < 5) {
return;
}
if (flags() == EMS_DEVICE_FLAG_EASY) {
return; // not supported
}
if (telegram->message_length < 7) {
return;
}
if (telegram->message_data[7] & 0x0C) { // date and time not valid
set_datetime("ntp", -1); // set from NTP
return;
}
auto timeold = dateTime_;
// render time to HH:MM:SS DD/MM/YYYY
// had to create separate buffers because of how printf works
char buf1[6];
char buf2[6];
char buf3[6];
char buf4[6];
char buf5[6];
char buf6[6];
snprintf_P(dateTime_,
sizeof(dateTime_),
PSTR("%s:%s:%s %s/%s/%s"),
Helpers::smallitoa(buf1, telegram->message_data[2]), // hour
Helpers::smallitoa(buf2, telegram->message_data[4]), // minute
Helpers::smallitoa(buf3, telegram->message_data[5]), // second
Helpers::smallitoa(buf4, telegram->message_data[3]), // day
Helpers::smallitoa(buf5, telegram->message_data[1]), // month
Helpers::itoa(buf6, telegram->message_data[0] + 2000) // year
);
has_update((strcmp(timeold, dateTime_) != 0));
}
// process_RCError - type 0xA2 - error message - 14 bytes long
// 10 00 A2 00 41 32 32 03 30 00 02 00 00 00 00 00 00 02 CRC
// A 2 2 816
void Thermostat::process_RCError(std::shared_ptr telegram) {
if (telegram->offset > 0 || telegram->message_length < 5) {
return;
}
char buf[4];
buf[0] = telegram->message_data[0];
buf[1] = telegram->message_data[1];
buf[2] = telegram->message_data[2];
buf[3] = 0;
has_update(telegram->read_value(errorNumber_, 3));
snprintf_P(errorCode_, sizeof(errorCode_), PSTR("%s(%d)"), buf, errorNumber_);
}
// 0x12 error log
void Thermostat::process_RCErrorMessage(std::shared_ptr telegram) {
if (telegram->offset > 0 || telegram->message_length < 12) {
return;
}
// data: displaycode(2), errornumber(2), year, month, hour, day, minute, duration(2), src-addr
if (telegram->message_data[4] & 0x80) { // valid date
char code[3];
uint16_t codeNo;
code[0] = telegram->message_data[0];
code[1] = telegram->message_data[1];
code[2] = 0;
telegram->read_value(codeNo, 2);
uint16_t year = (telegram->message_data[4] & 0x7F) + 2000;
uint8_t month = telegram->message_data[5];
uint8_t day = telegram->message_data[7];
uint8_t hour = telegram->message_data[6];
uint8_t min = telegram->message_data[8];
snprintf_P(lastCode_, sizeof(lastCode_), PSTR("%s(%d) %02d.%02d.%d %02d:%02d"), code, codeNo, day, month, year, hour, min);
}
}
// 0xA5 - Set minimum external temperature
bool Thermostat::set_minexttemp(const char * value, const int8_t id) {
int mt = 0;
if (!Helpers::value2number(value, mt)) {
LOG_WARNING(F("Set min external temperature: Invalid value"));
return false;
}
LOG_INFO(F("Setting min external temperature to %d C"), mt);
if ((model() == EMS_DEVICE_FLAG_RC300) || (model() == EMS_DEVICE_FLAG_RC100)) {
write_command(0x240, 10, mt, 0x240);
} else {
write_command(EMS_TYPE_IBASettings, 5, mt, EMS_TYPE_IBASettings);
}
return true;
}
// 0xA5 - Clock offset
bool Thermostat::set_clockoffset(const char * value, const int8_t id) {
int co = 0;
if (!Helpers::value2number(value, co)) {
LOG_WARNING(F("Set clock offset: Invalid value"));
return false;
}
LOG_INFO(F("Setting clock offset to %d"), co);
write_command(EMS_TYPE_IBASettings, 12, co, EMS_TYPE_IBASettings);
return true;
}
// 0xA5 - Calibrate internal temperature
bool Thermostat::set_calinttemp(const char * value, const int8_t id) {
int ct = 0;
if (!Helpers::value2number(value, ct)) {
LOG_WARNING(F("Cal internal temperature: Invalid value"));
return false;
}
LOG_INFO(F("Calibrating internal temperature to %d.%d C"), ct / 10, ct < 0 ? -ct % 10 : ct % 10);
write_command(EMS_TYPE_IBASettings, 2, ct, EMS_TYPE_IBASettings);
return true;
}
// 0xA5 - Set the display settings
bool Thermostat::set_display(const char * value, const int8_t id) {
int ds = 0;
if (!Helpers::value2number(value, ds)) {
LOG_WARNING(F("Set display: Invalid value"));
return false;
}
LOG_INFO(F("Setting display to %d"), ds);
write_command(EMS_TYPE_IBASettings, 0, ds, EMS_TYPE_IBASettings);
return true;
}
bool Thermostat::set_remotetemp(const char * value, const int8_t id) {
float f = 0;
if (!Helpers::value2float(value, f)) {
LOG_WARNING(F("Set remote temperature: Invalid value"));
return false;
}
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
return false;
}
if (f > 100 || f < 0) {
hc->remotetemp = EMS_VALUE_SHORT_NOTSET;
} else {
hc->remotetemp = (int16_t)(f * 10);
}
Roomctrl::set_remotetemp(hc->hc_num() - 1, hc->remotetemp);
return true;
}
// 0xA5 - Set the building settings
bool Thermostat::set_building(const char * value, const int8_t id) {
uint8_t bd = 0;
if ((model() == EMS_DEVICE_FLAG_RC300) || (model() == EMS_DEVICE_FLAG_RC100)) {
if (Helpers::value2enum(value, bd, FL_(enum_ibaBuildingType))) {
LOG_INFO(F("Setting building to %s"), value);
write_command(0x240, 9, bd, 0x240);
return true;
}
} else {
if (Helpers::value2enum(value, bd, FL_(enum_ibaBuildingType2))) {
LOG_INFO(F("Setting building to %s"), value);
write_command(EMS_TYPE_IBASettings, 6, bd, EMS_TYPE_IBASettings);
return true;
}
}
LOG_WARNING(F("Set building: Invalid value"));
return false;
}
// 0xA5 Set the language settings
bool Thermostat::set_language(const char * value, const int8_t id) {
uint8_t lg = 0;
if (!Helpers::value2enum(value, lg, FL_(enum_ibaLanguage))) {
LOG_WARNING(F("Set language: Invalid value"));
return false;
}
LOG_INFO(F("Setting language to %d"), lg);
write_command(EMS_TYPE_IBASettings, 1, lg, EMS_TYPE_IBASettings);
return true;
}
// Set the control-mode for hc 0-off, 1-RC20, 2-RC3x
bool Thermostat::set_control(const char * value, const int8_t id) {
uint8_t ctrl = 0;
if (!Helpers::value2enum(value, ctrl, FL_(enum_control))) {
LOG_WARNING(F("Set control: Invalid value"));
return false;
}
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
return false;
}
LOG_INFO(F("Setting circuit-control for hc%d to %d"), hc_num, ctrl);
write_command(set_typeids[hc->hc_num() - 1], 26, ctrl);
return true;
}
// sets the thermostat ww working mode, where mode is a string, ems and ems+
bool Thermostat::set_wwmode(const char * value, const int8_t id) {
uint8_t set = 0xFF;
if ((model() == EMS_DEVICE_FLAG_RC300) || (model() == EMS_DEVICE_FLAG_RC100)) {
if (!Helpers::value2enum(value, set, FL_(enum_wwMode))) {
LOG_WARNING(F("Set warm water mode: Invalid mode"));
return false;
}
LOG_INFO(F("Setting warm water mode to %s"), value);
write_command(0x02F5, 2, set, 0x02F5);
} else {
if (!Helpers::value2enum(value, set, FL_(enum_wwMode2))) {
LOG_WARNING(F("Set warm water mode: Invalid mode"));
return false;
}
LOG_INFO(F("Setting warm water mode to %s"), value);
write_command(EMS_TYPE_wwSettings, 2, set, EMS_TYPE_wwSettings);
}
return true;
}
// Set ww temperature, ems+
bool Thermostat::set_wwtemp(const char * value, const int8_t id) {
int t = 0;
if (!Helpers::value2number(value, t)) {
LOG_WARNING(F("Set warm water high temperature: Invalid value"));
return false;
}
LOG_INFO(F("Setting warm water high temperature to %d C"), t);
write_command(0x031B, 0, t, 0x031B);
return true;
}
// Set ww low temperature, ems+
bool Thermostat::set_wwtemplow(const char * value, const int8_t id) {
int t = 0;
if (!Helpers::value2number(value, t)) {
LOG_WARNING(F("Set warm water low temperature: Invalid value"));
return false;
}
LOG_INFO(F("Setting warm water low temperature to %d C"), t);
write_command(0x031B, 1, t, 0x031B);
return true;
}
// Set ww onetime RC300, ems+
bool Thermostat::set_wwonetime(const char * value, const int8_t id) {
bool b = false;
if (!Helpers::value2bool(value, b)) {
LOG_WARNING(F("Set warm water onetime: Invalid value"));
return false;
}
LOG_INFO(F("Setting warm water onetime to %s"), b ? F_(on) : F_(off));
write_command(0x02F5, 11, b ? 0xFF : 0x00, 0x031D);
return true;
}
// sets the thermostat ww circulation working mode, where mode is a string
bool Thermostat::set_wwcircmode(const char * value, const int8_t id) {
uint8_t set = 0xFF;
if ((model() == EMS_DEVICE_FLAG_RC300) || (model() == EMS_DEVICE_FLAG_RC100)) {
if (!Helpers::value2enum(value, set, FL_(enum_wwCircMode))) {
LOG_WARNING(F("Set warm water circulation mode: Invalid mode"));
return false;
}
LOG_INFO(F("Setting warm water circulation mode to %s"), value);
write_command(0x02F5, 3, set, 0x02F5);
return true;
}
if (!Helpers::value2enum(value, set, FL_(enum_wwCircMode2))) {
LOG_WARNING(F("Set warm water circulation mode: Invalid mode"));
return false;
}
LOG_INFO(F("Setting warm water circulation mode to %s"), value);
write_command(EMS_TYPE_wwSettings, 3, set, EMS_TYPE_wwSettings);
return true;
}
// set the holiday as string dd.mm.yyyy-dd.mm.yyyy
bool Thermostat::set_holiday(const char * value, const int8_t id) {
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Set holiday: Heating Circuit %d not found or activated for device ID 0x%02X"), hc_num, device_id());
return false;
}
if (value == nullptr || value[0] == '-') {
read_command(timer_typeids[hc->hc_num() - 1], 87, 6);
return true;
} else if (strlen(value) == 1 && value[0] == '+') {
read_command(timer_typeids[hc->hc_num() - 1], 93, 6);
return true;
} else if (strlen(value) != 21) {
LOG_WARNING(F("Set holiday: Invalid value"));
return false;
}
uint8_t data[6];
data[0] = (value[0] - '0') * 10 + (value[1] - '0');
data[1] = (value[3] - '0') * 10 + (value[4] - '0');
data[2] = (value[7] - '0') * 100 + (value[8] - '0') * 10 + (value[9] - '0');
data[3] = (value[11] - '0') * 10 + (value[12] - '0');
data[4] = (value[14] - '0') * 10 + (value[15] - '0');
data[5] = (value[18] - '0') * 100 + (value[19] - '0') * 10 + (value[20] - '0');
if (value[10] == '-') {
LOG_INFO(F("Setting holiday away from home for hc %d"), hc->hc_num());
write_command(timer_typeids[hc->hc_num() - 1], 87, data, 6, 0);
} else if (value[10] == '+') {
LOG_INFO(F("Setting holiday at home for hc %d"), hc->hc_num());
write_command(timer_typeids[hc->hc_num() - 1], 93, data, 6, 0);
} else {
LOG_WARNING(F("Set holiday: Invalid value"));
return false;
}
return true;
}
// set pause in hours
bool Thermostat::set_pause(const char * value, const int8_t id) {
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Set pause: Heating Circuit %d not found or activated for device ID 0x%02X"), hc_num, device_id());
return false;
}
if (value == nullptr) {
read_command(timer_typeids[hc->hc_num() - 1], 85, 1);
return true;
}
int hrs = 0;
if (!Helpers::value2number(value, hrs)) {
LOG_WARNING(F("Set pause: Invalid value"));
return false;
}
LOG_INFO(F("Setting pause: %d hours, hc: %d"), hrs, hc->hc_num());
write_command(timer_typeids[hc->hc_num() - 1], 85, hrs);
return true;
}
// set partymode in hours
bool Thermostat::set_party(const char * value, const int8_t id) {
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Set party: Heating Circuit %d not found or activated for device ID 0x%02X"), hc_num, device_id());
return false;
}
if (value == nullptr) {
read_command(timer_typeids[hc->hc_num() - 1], 85, 1);
return true;
}
int hrs = 0;
if (!Helpers::value2number(value, hrs)) {
LOG_WARNING(F("Set party: Invalid value"));
return false;
}
LOG_INFO(F("Setting party: %d hours, hc: %d"), hrs, hc->hc_num());
write_command(timer_typeids[hc->hc_num() - 1], 86, hrs);
return true;
}
// set date&time as string hh:mm:ss-dd.mm.yyyy-dw-dst or "NTP" for setting to internet-time
// dw - day of week (0..6), dst- summertime (0/1)
// id is ignored
bool Thermostat::set_datetime(const char * value, const int8_t id) {
std::string dt(30, '\0');
if (!Helpers::value2string(value, dt)) {
LOG_WARNING(F("Set date: Invalid value"));
return false;
}
uint8_t data[9];
if (dt == "ntp") {
time_t now = time(nullptr);
tm * tm_ = localtime(&now);
if (tm_->tm_year < 110) { // no NTP time
LOG_WARNING(F("No NTP time. Cannot set RCtime"));
return false;
}
data[0] = tm_->tm_year - 100; // Bosch counts from 2000
data[1] = tm_->tm_mon + 1;
data[2] = tm_->tm_hour;
data[3] = tm_->tm_mday;
data[4] = tm_->tm_min;
data[5] = tm_->tm_sec;
data[6] = (tm_->tm_wday + 6) % 7; // Bosch counts from Mo, time from Su
data[7] = tm_->tm_isdst + 2; // set DST and flag for ext. clock
char time_string[25];
strftime(time_string, 25, "%FT%T%z", tm_);
LOG_INFO(F("Date and time: %s"), time_string);
} else {
data[0] = (dt[16] - '0') * 100 + (dt[17] - '0') * 10 + (dt[18] - '0'); // year
data[1] = (dt[12] - '0') * 10 + (dt[13] - '0'); // month
data[2] = (dt[0] - '0') * 10 + (dt[1] - '0'); // hour
data[3] = (dt[9] - '0') * 10 + (dt[10] - '0'); // day
data[4] = (dt[3] - '0') * 10 + (dt[4] - '0'); // min
data[5] = (dt[6] - '0') * 10 + (dt[7] - '0'); // sec
data[6] = (dt[20] - '0'); // day of week
data[7] = (dt[22] - '0') + 2; // DST and flag
LOG_INFO(F("Date and time: %02d.%02d.2%03d-%02d:%02d:%02d"), data[3], data[1], data[0], data[2], data[4], data[5]);
}
LOG_INFO(F("Setting date and time"));
write_command(EMS_TYPE_time, 0, data, 8, EMS_TYPE_time);
return true;
}
// sets the thermostat working mode, where mode is a string
// converts string mode to HeatingCircuit::Mode
bool Thermostat::set_mode(const char * value, const int8_t id) {
// quit if its numerical, as it could be mistaken as a temperature value
if (value[0] < 'A') {
return false;
}
std::string mode(10, '\0');
if (!Helpers::value2string(value, mode)) {
LOG_WARNING(F("Set mode: Invalid mode"));
return false;
}
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
if (mode_tostring(HeatingCircuit::Mode::OFF) == mode) {
return set_mode_n(HeatingCircuit::Mode::OFF, hc_num);
}
if (mode_tostring(HeatingCircuit::Mode::MANUAL) == mode) {
return set_mode_n(HeatingCircuit::Mode::MANUAL, hc_num);
}
if (mode_tostring(HeatingCircuit::Mode::AUTO) == mode) {
return set_mode_n(HeatingCircuit::Mode::AUTO, hc_num);
}
if (mode_tostring(HeatingCircuit::Mode::DAY) == mode) {
return set_mode_n(HeatingCircuit::Mode::DAY, hc_num);
}
if (mode_tostring(HeatingCircuit::Mode::NIGHT) == mode) {
return set_mode_n(HeatingCircuit::Mode::NIGHT, hc_num);
}
if (mode_tostring(HeatingCircuit::Mode::HEAT) == mode) {
return set_mode_n(HeatingCircuit::Mode::HEAT, hc_num);
}
if (mode_tostring(HeatingCircuit::Mode::NOFROST) == mode) {
return set_mode_n(HeatingCircuit::Mode::NOFROST, hc_num);
}
if (mode_tostring(HeatingCircuit::Mode::ECO) == mode) {
return set_mode_n(HeatingCircuit::Mode::ECO, hc_num);
}
if (mode_tostring(HeatingCircuit::Mode::HOLIDAY) == mode) {
return set_mode_n(HeatingCircuit::Mode::HOLIDAY, hc_num);
}
if (mode_tostring(HeatingCircuit::Mode::COMFORT) == mode) {
return set_mode_n(HeatingCircuit::Mode::COMFORT, hc_num);
}
LOG_WARNING(F("Set mode: Invalid mode %s"), value);
return false;
}
// Set the thermostat working mode
// mode is HeatingCircuit::Mode
bool Thermostat::set_mode_n(const uint8_t mode, const uint8_t hc_num) {
// get hc based on number
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Set mode: Heating Circuit %d not found or activated"), hc_num);
return false;
}
uint8_t set_mode_value, offset;
uint16_t validate_typeid = 0;
uint8_t hc_p = hc->hc_num() - 1;
// set the value to send via EMS depending on the mode type
switch (mode) {
case HeatingCircuit::Mode::NIGHT:
case HeatingCircuit::Mode::OFF:
set_mode_value = 0;
break;
case HeatingCircuit::Mode::DAY:
case HeatingCircuit::Mode::HEAT:
case HeatingCircuit::Mode::MANUAL:
case HeatingCircuit::Mode::NOFROST:
set_mode_value = 1;
break;
default:
case HeatingCircuit::Mode::AUTO:
case HeatingCircuit::Mode::ECO:
set_mode_value = 2;
break;
}
switch (model()) {
case EMSdevice::EMS_DEVICE_FLAG_RC20:
offset = EMS_OFFSET_RC20Set_mode;
validate_typeid = set_typeids[hc_p];
break;
case EMSdevice::EMS_DEVICE_FLAG_RC20_N: // ES72
offset = EMS_OFFSET_RC20_2_Set_mode;
validate_typeid = set_typeids[hc_p];
break;
case EMSdevice::EMS_DEVICE_FLAG_RC30:
offset = EMS_OFFSET_RC30Set_mode;
validate_typeid = set_typeids[hc_p];
break;
case EMSdevice::EMS_DEVICE_FLAG_RC35:
case EMSdevice::EMS_DEVICE_FLAG_RC30_N:
offset = EMS_OFFSET_RC35Set_mode;
validate_typeid = set_typeids[hc_p];
break;
case EMSdevice::EMS_DEVICE_FLAG_RC300:
case EMSdevice::EMS_DEVICE_FLAG_RC100:
offset = EMS_OFFSET_RCPLUSSet_mode;
validate_typeid = monitor_typeids[hc_p];
if (mode == HeatingCircuit::Mode::AUTO) {
set_mode_value = 0xFF; // special value for auto
} else {
set_mode_value = 0; // everything else, like manual/day etc..
}
break;
case EMSdevice::EMS_DEVICE_FLAG_JUNKERS:
if (has_flags(EMS_DEVICE_FLAG_JUNKERS_OLD)) {
offset = EMS_OFFSET_JunkersSetMessage2_set_mode;
} else {
offset = EMS_OFFSET_JunkersSetMessage_set_mode;
}
validate_typeid = monitor_typeids[hc_p];
if (mode == HeatingCircuit::Mode::NOFROST) {
set_mode_value = 0x01;
} else if (mode == HeatingCircuit::Mode::ECO || (mode == HeatingCircuit::Mode::NIGHT)) {
set_mode_value = 0x02;
} else if ((mode == HeatingCircuit::Mode::DAY) || (mode == HeatingCircuit::Mode::HEAT)) {
set_mode_value = 0x03; // comfort
} else if (mode == HeatingCircuit::Mode::AUTO) {
set_mode_value = 0x04;
}
break;
default:
offset = 0;
break;
}
LOG_INFO(F("Setting thermostat mode to %s for heating circuit %d"), mode_tostring(mode).c_str(), hc->hc_num());
// add the write command to the Tx queue
// post validate is the corresponding monitor or set type IDs as they can differ per model
write_command(set_typeids[hc->hc_num() - 1], offset, set_mode_value, validate_typeid);
return true;
}
// sets the thermostat summermode for RC300
bool Thermostat::set_summermode(const char * value, const int8_t id) {
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Setting summer mode: Heating Circuit %d not found or activated"), hc_num);
return false;
}
uint8_t set = 0xFF;
if (!Helpers::value2enum(value, set, FL_(enum_summermode))) {
LOG_WARNING(F("Setting summer mode: Invalid mode"));
return false;
}
LOG_INFO(F("Setting summer mode to %s for heating circuit %d"), value, hc->hc_num());
write_command(summer_typeids[hc->hc_num() - 1], 7, set, summer_typeids[hc->hc_num() - 1]);
return true;
}
// sets the thermostat reducemode for RC35
bool Thermostat::set_reducemode(const char * value, const int8_t id) {
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Setting reduce mode: Heating Circuit %d not found or activated"), hc_num);
return false;
}
uint8_t set = 0xFF;
if (!Helpers::value2enum(value, set, FL_(enum_reducemode))) {
LOG_WARNING(F("Setting reduce mode: Invalid mode"));
return false;
}
LOG_INFO(F("Setting reduce mode to %s for heating circuit %d"), value, hc->hc_num());
write_command(set_typeids[hc->hc_num() - 1], 25, set, set_typeids[hc->hc_num() - 1]);
return true;
}
// sets the thermostat controlmode for RC35, RC300
bool Thermostat::set_controlmode(const char * value, const int8_t id) {
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Setting control mode: Heating Circuit %d not found or activated"), hc_num);
return false;
}
uint8_t set = 0xFF;
if (model() == EMS_DEVICE_FLAG_RC300 || model() == EMS_DEVICE_FLAG_RC100) {
if (Helpers::value2enum(value, set, FL_(enum_controlmode))) {
LOG_INFO(F("Setting control mode to %d for heating circuit %d"), set, hc->hc_num());
write_command(curve_typeids[hc->hc_num() - 1], 0, set, curve_typeids[hc->hc_num() - 1]);
return true;
}
} else if (model() == EMS_DEVICE_FLAG_RC35 || model() == EMS_DEVICE_FLAG_RC30_N) {
if (Helpers::value2enum(value, set, FL_(enum_controlmode2))) {
LOG_INFO(F("Setting control mode to %d for heating circuit %d"), set, hc->hc_num());
write_command(set_typeids[hc->hc_num() - 1], 33, set, set_typeids[hc->hc_num() - 1]);
return true;
}
}
LOG_WARNING(F("Setting control mode: Invalid mode"));
return false;
}
// sets a single switchtime in the thermostat program for RC35
// format "01:0,1,15:30" Number, day, on, time
bool Thermostat::set_switchtime(const char * value, const int8_t id) {
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Setting switchtime: Heating Circuit %d not found or activated"), hc_num);
return false;
}
if (value == nullptr) {
return false;
} else if (strlen(value) == 2) { // query point 01?
uint8_t no = (value[0] - '0') * 10 + (value[1] - '0');
if (no < 42) {
read_command(timer_typeids[hc->hc_num() - 1], 2 * no, 2);
return true;
}
return false;
} else if (strlen(value) != 12) {
LOG_WARNING(F("Setting switchtime: Invalid data"));
return false;
}
uint8_t no = (value[0] - '0') * 10 + (value[1] - '0');
uint8_t day = value[3] - '0';
uint8_t on = value[5] - '0';
uint8_t time = 6 * ((value[7] - '0') * 10 + (value[8] - '0')) + (value[10] - '0');
uint8_t data[2] = {0xE7, 0x90}; // unset switchtime
if (day != 7 && on != 7) {
data[0] = (day << 5) + on;
data[1] = time;
}
if (no > 41 || day > 7 || (on > 1 && on != 7) || time > 0x90) {
LOG_WARNING(F("Setting switchtime: Invalid data"));
return false;
}
if ((model() == EMS_DEVICE_FLAG_RC35 || model() == EMS_DEVICE_FLAG_RC30_N)) {
write_command(timer_typeids[hc->hc_num() - 1], no * 2, (uint8_t *)&data, 2, timer_typeids[hc->hc_num() - 1]);
} else {
LOG_WARNING(F("Setting switchtime: thermostat not supported"));
return false;
}
if (data[0] == 0xE7) {
LOG_INFO(F("Setting switchtime no %d for heating circuit %d undefined"), no, hc->hc_num());
} else {
LOG_INFO(F("Setting switchtime no %d for heating circuit %d to day %d, %s, %02d:%d0"), no, hc->hc_num(), day, (on == 1) ? "on" : "off", time / 6, time % 6);
}
return true;
}
// sets the thermostat program for RC35 and RC20
bool Thermostat::set_program(const char * value, const int8_t id) {
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Setting program: Heating Circuit %d not found or activated"), hc_num);
return false;
}
int set = 0xFF;
if (!Helpers::value2number(value, set)) {
LOG_WARNING(F("Setting program: Invalid number"));
return false;
}
if (model() == EMS_DEVICE_FLAG_RC20_N && set > 0 && set < 10) {
write_command(set_typeids[hc->hc_num() - 1], 11, set, set_typeids[hc->hc_num() - 1]);
} else if ((model() == EMS_DEVICE_FLAG_RC35 || model() == EMS_DEVICE_FLAG_RC30_N) && set < 11) {
write_command(timer_typeids[hc->hc_num() - 1], 84, set, timer_typeids[hc->hc_num() - 1]);
} else if ((model() == EMS_DEVICE_FLAG_RC300 || model() == EMS_DEVICE_FLAG_RC100) && (set == 1 || set == 2)) {
write_command(set_typeids[hc->hc_num() - 1], 11, set, set_typeids[hc->hc_num() - 1]);
} else {
LOG_WARNING(F("Setting program: Invalid number"));
return false;
}
LOG_INFO(F("Setting program to %d for heating circuit %d"), set, hc->hc_num());
return true;
}
// Set the temperature of the thermostat
// the id passed into this function is the heating circuit number
bool Thermostat::set_temperature(const float temperature, const uint8_t mode, const uint8_t hc_num) {
// get hc based on number
std::shared_ptr hc = heating_circuit(hc_num);
if (hc == nullptr) {
LOG_WARNING(F("Set temperature: Heating Circuit %d not found or activated for device ID 0x%02X"), hc_num, device_id());
return false;
}
uint8_t model = this->model();
int8_t offset = -1; // we use -1 to check if there is a value
uint8_t factor = 2; // some temperatures only use 1
uint16_t validate_typeid = monitor_typeids[hc->hc_num() - 1];
uint16_t set_typeid = set_typeids[hc->hc_num() - 1];
if (model == EMS_DEVICE_FLAG_RC10) {
offset = EMS_OFFSET_RC10Set_temp;
} else if (model == EMS_DEVICE_FLAG_RC20) {
offset = EMS_OFFSET_RC20Set_temp;
} else if (model == EMS_DEVICE_FLAG_RC30) {
offset = EMS_OFFSET_RC30Set_temp;
} else if ((model == EMS_DEVICE_FLAG_RC300) || (model == EMS_DEVICE_FLAG_RC100)) {
validate_typeid = set_typeids[hc->hc_num() - 1];
switch (mode) {
case HeatingCircuit::Mode::SUMMER:
offset = 0x06;
set_typeid = summer_typeids[hc->hc_num() - 1];
validate_typeid = set_typeid;
factor = 1;
break;
case HeatingCircuit::Mode::MANUAL:
offset = 0x0A; // manual offset
break;
case HeatingCircuit::Mode::TEMPAUTO:
offset = 0x08; // manual offset
if (temperature == -1) {
factor = 0xFF; // use factor as value
}
break;
case HeatingCircuit::Mode::COMFORT:
offset = 0x02; // comfort offset level 2
break;
case HeatingCircuit::Mode::ECO:
offset = 0x04; // eco offset
break;
case HeatingCircuit::Mode::OFFSET:
offset = 2;
set_typeid = summer_typeids[hc->hc_num() - 1];
validate_typeid = set_typeid;
factor = 1;
break;
case HeatingCircuit::Mode::DESIGN:
set_typeid = summer_typeids[hc->hc_num() - 1];
validate_typeid = set_typeid;
if (hc->heatingtype == 3) {
offset = 5;
} else {
offset = 4;
}
factor = 1;
break;
case HeatingCircuit::Mode::MINFLOW:
set_typeid = summer_typeids[hc->hc_num() - 1];
validate_typeid = set_typeid;
offset = 8;
factor = 1;
break;
case HeatingCircuit::Mode::MAXFLOW:
set_typeid = curve_typeids[hc->hc_num() - 1];
validate_typeid = set_typeid;
if (hc->heatingtype == 3) {
offset = 7;
} else {
offset = 8;
}
factor = 1;
break;
case HeatingCircuit::Mode::NOFROST:
set_typeid = curve_typeids[hc->hc_num() - 1];
validate_typeid = set_typeid;
offset = 6;
factor = 1;
break;
case HeatingCircuit::Mode::ROOMINFLUENCE:
set_typeid = summer_typeids[hc->hc_num() - 1];
validate_typeid = set_typeid;
offset = 0;
factor = 1;
break;
default:
case HeatingCircuit::Mode::AUTO:
uint8_t mode_ = hc->get_mode();
if (mode_ == HeatingCircuit::Mode::MANUAL) {
offset = 0x0A; // manual offset
} else {
offset = 0x08; // auto offset
// special case to reactivate auto temperature, see #737, #746
if (temperature == -1) {
factor = 0xFF; // use factor as value
}
}
validate_typeid = monitor_typeids[hc->hc_num() - 1]; // get setpoint roomtemp back
break;
}
} else if (model == EMS_DEVICE_FLAG_RC20_N) {
switch (mode) {
case HeatingCircuit::Mode::NIGHT: // change the night temp
offset = EMS_OFFSET_RC20_2_Set_temp_night;
break;
case HeatingCircuit::Mode::DAY: // change the day temp
offset = EMS_OFFSET_RC20_2_Set_temp_day;
break;
default:
case HeatingCircuit::Mode::AUTO: // automatic selection, if no type is defined, we use the standard code
uint8_t modetype = hc->get_mode_type();
offset = (modetype == HeatingCircuit::Mode::NIGHT) ? EMS_OFFSET_RC20_2_Set_temp_night : EMS_OFFSET_RC20_2_Set_temp_day;
break;
}
} else if ((model == EMS_DEVICE_FLAG_RC35) || (model == EMS_DEVICE_FLAG_RC30_N)) {
validate_typeid = set_typeids[hc->hc_num() - 1];
switch (mode) {
case HeatingCircuit::Mode::NIGHT: // change the night temp
offset = EMS_OFFSET_RC35Set_temp_night;
break;
case HeatingCircuit::Mode::DAY: // change the day temp
offset = EMS_OFFSET_RC35Set_temp_day;
break;
case HeatingCircuit::Mode::HOLIDAY: // change the holiday temp
offset = EMS_OFFSET_RC35Set_temp_holiday;
break;
case HeatingCircuit::Mode::OFFSET: // change the offset temp
offset = EMS_OFFSET_RC35Set_temp_offset;
break;
case HeatingCircuit::Mode::FLOWOFFSET: // change the offset of flowtemp
offset = EMS_OFFSET_RC35Set_temp_flowoffset;
factor = 1;
break;
case HeatingCircuit::Mode::DESIGN:
if (hc->heatingtype == 3) {
offset = EMS_OFFSET_RC35Set_temp_design_floor;
} else {
offset = EMS_OFFSET_RC35Set_temp_design;
}
factor = 1;
break;
case HeatingCircuit::Mode::SUMMER:
offset = EMS_OFFSET_RC35Set_temp_summer;
factor = 1;
break;
case HeatingCircuit::Mode::NOFROST:
offset = EMS_OFFSET_RC35Set_temp_nofrost;
factor = 1;
break;
case HeatingCircuit::Mode::ROOMINFLUENCE:
offset = 4;
factor = 1;
break;
case HeatingCircuit::Mode::NOREDUCE:
offset = EMS_OFFSET_RC35Set_noreducetemp;
factor = 1;
break;
case HeatingCircuit::Mode::TEMPAUTO:
offset = EMS_OFFSET_RC35Set_seltemp;
break;
case HeatingCircuit::Mode::MINFLOW:
offset = 16;
factor = 1;
break;
case HeatingCircuit::Mode::MAXFLOW:
if (hc->heatingtype == 3) {
offset = 35;
} else {
offset = 15;
}
factor = 1;
break;
default:
case HeatingCircuit::Mode::AUTO: // automatic selection, if no type is defined, we use the standard code
validate_typeid = monitor_typeids[hc->hc_num() - 1]; //get setpoint roomtemp back
if (model == EMS_DEVICE_FLAG_RC35) {
uint8_t mode_ = hc->get_mode();
if (mode_ == HeatingCircuit::Mode::NIGHT) {
offset = EMS_OFFSET_RC35Set_temp_night;
} else if (mode_ == HeatingCircuit::Mode::DAY) {
offset = EMS_OFFSET_RC35Set_temp_day;
} else {
offset = EMS_OFFSET_RC35Set_seltemp; // https://github.com/emsesp/EMS-ESP/issues/310
}
} else {
uint8_t modetype = hc->get_mode_type();
offset = (modetype == HeatingCircuit::Mode::NIGHT) ? EMS_OFFSET_RC35Set_temp_night : EMS_OFFSET_RC35Set_temp_day;
}
break;
}
} else if (model == EMS_DEVICE_FLAG_JUNKERS) {
// figure out if we have older or new thermostats, Heating Circuits on 0x65 or 0x79
// see https://github.com/emsesp/EMS-ESP/issues/335#issuecomment-593324716)
bool old_junkers = (has_flags(EMS_DEVICE_FLAG_JUNKERS_OLD));
if (!old_junkers) {
switch (mode) {
case HeatingCircuit::Mode::NOFROST:
offset = EMS_OFFSET_JunkersSetMessage_no_frost_temp;
break;
case HeatingCircuit::Mode::NIGHT:
case HeatingCircuit::Mode::ECO:
offset = EMS_OFFSET_JunkersSetMessage_night_temp;
break;
case HeatingCircuit::Mode::HEAT:
case HeatingCircuit::Mode::DAY:
offset = EMS_OFFSET_JunkersSetMessage_day_temp;
break;
default:
case HeatingCircuit::Mode::AUTO: // automatic selection, if no type is defined, we use the standard code
uint8_t modetype = hc->get_mode_type();
if (modetype == HeatingCircuit::Mode::NIGHT || modetype == HeatingCircuit::Mode::ECO) {
offset = EMS_OFFSET_JunkersSetMessage_night_temp;
} else if (modetype == HeatingCircuit::Mode::DAY || modetype == HeatingCircuit::Mode::HEAT) {
offset = EMS_OFFSET_JunkersSetMessage_day_temp;
} else {
offset = EMS_OFFSET_JunkersSetMessage_no_frost_temp;
}
break;
}
} else {
// older, like the FR100
switch (mode) {
case HeatingCircuit::Mode::NOFROST:
offset = EMS_OFFSET_JunkersSetMessage2_no_frost_temp;
break;
case HeatingCircuit::Mode::ECO:
case HeatingCircuit::Mode::NIGHT:
offset = EMS_OFFSET_JunkersSetMessage2_eco_temp;
break;
case HeatingCircuit::Mode::HEAT:
case HeatingCircuit::Mode::DAY:
offset = EMS_OFFSET_JunkersSetMessage2_heat_temp;
break;
default:
case HeatingCircuit::Mode::AUTO: // automatic selection, if no type is defined, we use the standard code
uint8_t modetype = hc->get_mode_type();
if (modetype == HeatingCircuit::Mode::NIGHT || modetype == HeatingCircuit::Mode::ECO) {
offset = EMS_OFFSET_JunkersSetMessage2_eco_temp;
} else if (modetype == HeatingCircuit::Mode::DAY || modetype == HeatingCircuit::Mode::HEAT) {
offset = EMS_OFFSET_JunkersSetMessage2_heat_temp;
} else {
offset = EMS_OFFSET_JunkersSetMessage2_no_frost_temp;
}
break;
}
}
}
// if we know what to send and to where, go and do it
if (offset != -1) {
char s[10];
LOG_INFO(F("Setting thermostat temperature to %s for heating circuit %d, mode %s"), Helpers::render_value(s, temperature, 2), hc->hc_num(), mode_tostring(mode).c_str());
// add the write command to the Tx queue. value is *2
// post validate is the corresponding monitor or set type IDs as they can differ per model
if (factor == 0xFF) {
write_command(set_typeid, offset, factor, validate_typeid);
} else {
write_command(set_typeid, offset, (uint8_t)((float)temperature * (float)factor), validate_typeid);
}
return true;
}
LOG_WARNING(F("Set temperature: Invalid value"));
return false;
}
bool Thermostat::set_temperature_value(const char * value, const int8_t id, const uint8_t mode) {
float f = 0;
uint8_t hc_num = (id == -1) ? AUTO_HEATING_CIRCUIT : id;
if (Helpers::value2float(value, f)) {
return set_temperature(f, mode, hc_num);
} else {
LOG_WARNING(F("Set temperature: Invalid value"));
return false;
}
}
bool Thermostat::set_temp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::AUTO);
}
bool Thermostat::set_nighttemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::NIGHT);
}
bool Thermostat::set_daytemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::DAY);
}
bool Thermostat::set_comforttemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::COMFORT);
}
bool Thermostat::set_nofrosttemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::NOFROST);
}
bool Thermostat::set_ecotemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::ECO);
}
bool Thermostat::set_heattemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::HEAT);
}
bool Thermostat::set_summertemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::SUMMER);
}
bool Thermostat::set_designtemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::DESIGN);
}
bool Thermostat::set_offsettemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::OFFSET);
}
bool Thermostat::set_holidaytemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::HOLIDAY);
}
bool Thermostat::set_manualtemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::MANUAL);
}
bool Thermostat::set_tempautotemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::TEMPAUTO);
}
bool Thermostat::set_noreducetemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::NOREDUCE);
}
bool Thermostat::set_flowtempoffset(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::FLOWOFFSET);
}
bool Thermostat::set_maxflowtemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::MAXFLOW);
}
bool Thermostat::set_minflowtemp(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::MINFLOW);
}
bool Thermostat::set_roominfluence(const char * value, const int8_t id) {
return set_temperature_value(value, id, HeatingCircuit::Mode::ROOMINFLUENCE);
}
// register main device values, top level for all thermostats (excluding heating circuits)
// as these are done in void Thermostat::register_device_values_hc()
void Thermostat::register_device_values() {
// Common for all thermostats
register_device_value(TAG_THERMOSTAT_DATA, &id_, DeviceValueType::UINT, nullptr, FL_(ID), DeviceValueUOM::NONE);
register_device_value(TAG_THERMOSTAT_DATA, &errorCode_, DeviceValueType::TEXT, nullptr, FL_(errorCode), DeviceValueUOM::NONE);
register_device_value(TAG_THERMOSTAT_DATA, &lastCode_, DeviceValueType::TEXT, nullptr, FL_(lastCode), DeviceValueUOM::NONE);
switch (this->model()) {
case EMS_DEVICE_FLAG_RC100:
case EMS_DEVICE_FLAG_RC300:
register_device_value(TAG_THERMOSTAT_DATA, &dateTime_, DeviceValueType::TEXT, nullptr, FL_(dateTime), DeviceValueUOM::NONE, MAKE_CF_CB(set_datetime));
register_device_value(TAG_THERMOSTAT_DATA, &floordrystatus_, DeviceValueType::ENUM, FL_(enum_floordrystatus), FL_(floordrystatus), DeviceValueUOM::NONE);
register_device_value(TAG_THERMOSTAT_DATA, &dampedoutdoortemp2_, DeviceValueType::SHORT, FL_(div10), FL_(dampedoutdoortemp), DeviceValueUOM::DEGREES);
register_device_value(TAG_THERMOSTAT_DATA, &floordrytemp_, DeviceValueType::UINT, nullptr, FL_(floordrytemp), DeviceValueUOM::DEGREES);
register_device_value(TAG_THERMOSTAT_DATA, &ibaBuildingType_, DeviceValueType::ENUM, FL_(enum_ibaBuildingType), FL_(ibaBuildingType), DeviceValueUOM::NONE, MAKE_CF_CB(set_building));
register_device_value(TAG_DEVICE_DATA_WW, &wwSetTemp_, DeviceValueType::UINT, nullptr, FL_(wwSetTemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_wwtemp));
register_device_value(TAG_DEVICE_DATA_WW, &wwMode_, DeviceValueType::ENUM, FL_(enum_wwMode), FL_(wwMode), DeviceValueUOM::NONE, MAKE_CF_CB(set_wwmode));
register_device_value(TAG_DEVICE_DATA_WW, &wwSetTempLow_, DeviceValueType::UINT, nullptr, FL_(wwSetTempLow), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_wwtemplow));
register_device_value(TAG_DEVICE_DATA_WW, &wwCircMode_, DeviceValueType::ENUM, FL_(enum_wwCircMode), FL_(wWCircMode), DeviceValueUOM::NONE, MAKE_CF_CB(set_wwcircmode));
register_device_value(TAG_DEVICE_DATA_WW, &wwExtra1_, DeviceValueType::UINT, nullptr, FL_(wwExtra1), DeviceValueUOM::DEGREES);
register_device_value(TAG_DEVICE_DATA_WW, &wwExtra2_, DeviceValueType::UINT, nullptr, FL_(wwExtra2), DeviceValueUOM::DEGREES);
break;
case EMS_DEVICE_FLAG_RC20_N:
case EMS_DEVICE_FLAG_RC20:
register_device_value(TAG_THERMOSTAT_DATA, &dateTime_, DeviceValueType::TEXT, nullptr, FL_(dateTime), DeviceValueUOM::NONE); // can't set datetime
break;
case EMS_DEVICE_FLAG_RC30_N:
register_device_value(TAG_THERMOSTAT_DATA, &dateTime_, DeviceValueType::TEXT, nullptr, FL_(dateTime), DeviceValueUOM::NONE); // can't set datetime
register_device_value(TAG_THERMOSTAT_DATA, &ibaMainDisplay_, DeviceValueType::ENUM, FL_(enum_ibaMainDisplay), FL_(ibaMainDisplay), DeviceValueUOM::NONE);
register_device_value(TAG_THERMOSTAT_DATA, &ibaLanguage_, DeviceValueType::ENUM, FL_(enum_ibaLanguage), FL_(ibaLanguage), DeviceValueUOM::NONE);
register_device_value(TAG_THERMOSTAT_DATA, &ibaClockOffset_, DeviceValueType::UINT, nullptr, FL_(ibaClockOffset), DeviceValueUOM::NONE); // offset (in sec) to clock, 0xff=-1s, 0x02=2s
register_device_value(TAG_THERMOSTAT_DATA, &ibaCalIntTemperature_, DeviceValueType::INT, FL_(div2), FL_(ibaCalIntTemperature), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_calinttemp));
register_device_value(TAG_THERMOSTAT_DATA, &ibaMinExtTemperature_, DeviceValueType::INT, nullptr, FL_(ibaMinExtTemperature), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_minexttemp));
register_device_value(TAG_THERMOSTAT_DATA, &dampedoutdoortemp_, DeviceValueType::INT, nullptr, FL_(dampedoutdoortemp), DeviceValueUOM::DEGREES);
register_device_value(TAG_THERMOSTAT_DATA, &ibaBuildingType_, DeviceValueType::ENUM, FL_(enum_ibaBuildingType2), FL_(ibaBuildingType), DeviceValueUOM::NONE, MAKE_CF_CB(set_building));
register_device_value(TAG_DEVICE_DATA_WW, &wwMode_, DeviceValueType::ENUM, FL_(enum_wwMode2), FL_(wwMode), DeviceValueUOM::NONE, MAKE_CF_CB(set_wwmode));
register_device_value(TAG_DEVICE_DATA_WW, &wwCircMode_, DeviceValueType::ENUM, FL_(enum_wwCircMode2), FL_(wWCircMode), DeviceValueUOM::NONE, MAKE_CF_CB(set_wwcircmode));
break;
case EMS_DEVICE_FLAG_RC35:
register_device_value(TAG_THERMOSTAT_DATA, &dateTime_, DeviceValueType::TEXT, nullptr, FL_(dateTime), DeviceValueUOM::NONE, MAKE_CF_CB(set_datetime));
register_device_value(TAG_THERMOSTAT_DATA, &ibaCalIntTemperature_, DeviceValueType::INT, FL_(div2), FL_(ibaCalIntTemperature), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_calinttemp));
register_device_value(TAG_THERMOSTAT_DATA, &ibaMinExtTemperature_, DeviceValueType::INT, nullptr, FL_(ibaMinExtTemperature), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_minexttemp));
register_device_value(TAG_THERMOSTAT_DATA, &tempsensor1_, DeviceValueType::USHORT, FL_(div10), FL_(tempsensor1), DeviceValueUOM::DEGREES);
register_device_value(TAG_THERMOSTAT_DATA, &tempsensor2_, DeviceValueType::USHORT, FL_(div10), FL_(tempsensor2), DeviceValueUOM::DEGREES);
register_device_value(TAG_THERMOSTAT_DATA, &dampedoutdoortemp_, DeviceValueType::INT, nullptr, FL_(dampedoutdoortemp), DeviceValueUOM::DEGREES);
register_device_value(TAG_THERMOSTAT_DATA, &ibaBuildingType_, DeviceValueType::ENUM, FL_(enum_ibaBuildingType2), FL_(ibaBuildingType), DeviceValueUOM::NONE, MAKE_CF_CB(set_building));
register_device_value(TAG_DEVICE_DATA_WW, &wwMode_, DeviceValueType::ENUM, FL_(enum_wwMode2), FL_(wwMode), DeviceValueUOM::NONE, MAKE_CF_CB(set_wwmode));
register_device_value(TAG_DEVICE_DATA_WW, &wwCircMode_, DeviceValueType::ENUM, FL_(enum_wwCircMode2), FL_(wWCircMode), DeviceValueUOM::NONE, MAKE_CF_CB(set_wwcircmode));
break;
case EMS_DEVICE_FLAG_JUNKERS:
register_device_value(TAG_THERMOSTAT_DATA, &dateTime_, DeviceValueType::TEXT, nullptr, FL_(dateTime), DeviceValueUOM::NONE, MAKE_CF_CB(set_datetime));
break;
default:
break;
}
}
// registers the values for a heating circuit
void Thermostat::register_device_values_hc(std::shared_ptr hc) {
uint8_t model = hc->get_model();
// heating circuit
uint8_t tag = TAG_HC1 + hc->hc_num() - 1;
// different logic on how temperature values are stored, depending on model
const __FlashStringHelper * const * setpoint_temp_divider;
const __FlashStringHelper * const * curr_temp_divider;
if (model == EMS_DEVICE_FLAG_EASY) {
setpoint_temp_divider = FL_(div100);
curr_temp_divider = FL_(div100);
} else if (model == EMS_DEVICE_FLAG_JUNKERS) {
setpoint_temp_divider = FL_(div10);
curr_temp_divider = FL_(div10);
} else {
setpoint_temp_divider = FL_(div2);
curr_temp_divider = FL_(div10);
}
if (has_flags(EMS_DEVICE_FLAG_NO_WRITE) || device_id() != EMSESP::actual_master_thermostat()) {
register_device_value(tag, &hc->setpoint_roomTemp, DeviceValueType::SHORT, setpoint_temp_divider, FL_(setpoint_roomTemp), DeviceValueUOM::DEGREES);
} else {
register_device_value(tag, &hc->setpoint_roomTemp, DeviceValueType::SHORT, setpoint_temp_divider, FL_(setpoint_roomTemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_temp), 5, 29);
register_device_value(tag, &hc->setpoint_roomTemp, DeviceValueType::SHORT, setpoint_temp_divider, FL_(temp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_temp), 5, 29);
}
register_device_value(tag, &hc->curr_roomTemp, DeviceValueType::SHORT, curr_temp_divider, FL_(curr_roomTemp), DeviceValueUOM::DEGREES);
if (device_id() != EMSESP::actual_master_thermostat()) {
return;
}
// special handling for Home Assistant
// we create special values called hatemp and hamode, which have empty fullnames so not shown in the web or console
if (Mqtt::ha_enabled()) {
uint8_t option = Mqtt::ha_climate_format();
if (option == Mqtt::HA_Climate_Format::CURRENT) {
register_device_value(tag, &hc->curr_roomTemp, DeviceValueType::SHORT, curr_temp_divider, FL_(hatemp), DeviceValueUOM::NONE);
} else if (option == Mqtt::HA_Climate_Format::SETPOINT) {
register_device_value(tag, &hc->setpoint_roomTemp, DeviceValueType::SHORT, setpoint_temp_divider, FL_(hatemp), DeviceValueUOM::NONE);
} else if (option == Mqtt::HA_Climate_Format::ZERO) {
register_device_value(tag, &zero_value_, DeviceValueType::UINT, nullptr, FL_(hatemp), DeviceValueUOM::NONE);
}
// if we're sending to HA the only valid mode types are heat, auto and off
// manual & day = heat
// night & off = off
// everything else auto
register_device_value(tag, &hc->mode, DeviceValueType::ENUM, FL_(enum_hamode), FL_(hamode), DeviceValueUOM::NONE);
}
switch (model) {
case EMS_DEVICE_FLAG_RC100:
case EMS_DEVICE_FLAG_RC300:
register_device_value(tag, &hc->mode, DeviceValueType::ENUM, FL_(enum_mode), FL_(mode), DeviceValueUOM::NONE, MAKE_CF_CB(set_mode));
register_device_value(tag, &hc->modetype, DeviceValueType::ENUM, FL_(enum_modetype), FL_(modetype), DeviceValueUOM::NONE);
register_device_value(tag, &hc->nighttemp, DeviceValueType::UINT, FL_(div2), FL_(ecotemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_ecotemp));
register_device_value(tag, &hc->manualtemp, DeviceValueType::UINT, FL_(div2), FL_(manualtemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_manualtemp));
register_device_value(tag, &hc->daytemp, DeviceValueType::UINT, FL_(div2), FL_(comforttemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_comforttemp));
register_device_value(tag, &hc->summertemp, DeviceValueType::UINT, nullptr, FL_(summertemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_summertemp));
register_device_value(tag, &hc->designtemp, DeviceValueType::UINT, nullptr, FL_(designtemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_designtemp));
register_device_value(tag, &hc->offsettemp, DeviceValueType::INT, nullptr, FL_(offsettemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_offsettemp));
register_device_value(tag, &hc->minflowtemp, DeviceValueType::UINT, nullptr, FL_(minflowtemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_minflowtemp));
register_device_value(tag, &hc->maxflowtemp, DeviceValueType::UINT, nullptr, FL_(maxflowtemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_maxflowtemp));
register_device_value(tag, &hc->roominfluence, DeviceValueType::UINT, nullptr, FL_(roominfluence), DeviceValueUOM::NONE, MAKE_CF_CB(set_roominfluence));
register_device_value(tag, &hc->nofrosttemp, DeviceValueType::INT, nullptr, FL_(nofrosttemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_nofrosttemp));
register_device_value(tag, &hc->targetflowtemp, DeviceValueType::UINT, nullptr, FL_(targetflowtemp), DeviceValueUOM::DEGREES);
register_device_value(tag, &hc->heatingtype, DeviceValueType::ENUM, FL_(enum_heatingtype), FL_(heatingtype), DeviceValueUOM::NONE);
register_device_value(tag, &hc->summer_setmode, DeviceValueType::ENUM, FL_(enum_summermode), FL_(summermode), DeviceValueUOM::NONE, MAKE_CF_CB(set_summermode));
register_device_value(tag, &hc->summermode, DeviceValueType::BOOL, nullptr, FL_(summermode), DeviceValueUOM::NONE);
register_device_value(tag, &hc->controlmode, DeviceValueType::ENUM, FL_(enum_controlmode), FL_(controlmode), DeviceValueUOM::NONE, MAKE_CF_CB(set_controlmode));
register_device_value(tag, &hc->program, DeviceValueType::UINT, nullptr, FL_(program), DeviceValueUOM::NONE, MAKE_CF_CB(set_program));
register_device_value(tag, &hc->tempautotemp, DeviceValueType::UINT, FL_(div2), FL_(tempautotemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_tempautotemp));
break;
case EMS_DEVICE_FLAG_CRF:
register_device_value(tag, &hc->mode, DeviceValueType::ENUM, FL_(enum_mode5), FL_(mode), DeviceValueUOM::NONE);
register_device_value(tag, &hc->modetype, DeviceValueType::ENUM, FL_(enum_modetype5), FL_(modetype), DeviceValueUOM::NONE);
register_device_value(tag, &hc->targetflowtemp, DeviceValueType::UINT, nullptr, FL_(targetflowtemp), DeviceValueUOM::DEGREES);
break;
case EMS_DEVICE_FLAG_RC20:
register_device_value(tag, &hc->mode, DeviceValueType::ENUM, FL_(enum_mode2), FL_(mode), DeviceValueUOM::NONE, MAKE_CF_CB(set_mode));
break;
case EMS_DEVICE_FLAG_RC20_N:
register_device_value(tag, &hc->mode, DeviceValueType::ENUM, FL_(enum_mode2), FL_(mode), DeviceValueUOM::NONE, MAKE_CF_CB(set_mode));
register_device_value(tag, &hc->modetype, DeviceValueType::ENUM, FL_(enum_modetype2), FL_(modetype), DeviceValueUOM::NONE);
register_device_value(tag, &hc->daytemp, DeviceValueType::UINT, FL_(div2), FL_(daytemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_daytemp));
register_device_value(tag, &hc->nighttemp, DeviceValueType::UINT, FL_(div2), FL_(nighttemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_nighttemp));
register_device_value(tag, &hc->program, DeviceValueType::UINT, nullptr, FL_(program), DeviceValueUOM::NONE, MAKE_CF_CB(set_program));
break;
case EMS_DEVICE_FLAG_RC30_N:
case EMS_DEVICE_FLAG_RC35:
register_device_value(tag, &hc->mode, DeviceValueType::ENUM, FL_(enum_mode3), FL_(mode), DeviceValueUOM::NONE, MAKE_CF_CB(set_mode));
register_device_value(tag, &hc->modetype, DeviceValueType::ENUM, FL_(enum_modetype3), FL_(modetype), DeviceValueUOM::NONE);
register_device_value(tag, &hc->daytemp, DeviceValueType::UINT, FL_(div2), FL_(daytemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_daytemp));
register_device_value(tag, &hc->nighttemp, DeviceValueType::UINT, FL_(div2), FL_(nighttemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_nighttemp));
register_device_value(tag, &hc->designtemp, DeviceValueType::UINT, nullptr, FL_(designtemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_designtemp));
register_device_value(tag, &hc->offsettemp, DeviceValueType::INT, FL_(div2), FL_(offsettemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_offsettemp));
register_device_value(tag, &hc->holidaytemp, DeviceValueType::UINT, FL_(div2), FL_(holidaytemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_holidaytemp));
register_device_value(tag, &hc->targetflowtemp, DeviceValueType::UINT, nullptr, FL_(targetflowtemp), DeviceValueUOM::DEGREES);
register_device_value(tag, &hc->summertemp, DeviceValueType::UINT, nullptr, FL_(summertemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_summertemp));
register_device_value(tag, &hc->summermode, DeviceValueType::BOOL, nullptr, FL_(summermode), DeviceValueUOM::NONE);
register_device_value(tag, &hc->holidaymode, DeviceValueType::BOOL, nullptr, FL_(holidaymode), DeviceValueUOM::NONE, MAKE_CF_CB(set_holiday));
register_device_value(tag, &hc->nofrosttemp, DeviceValueType::INT, nullptr, FL_(nofrosttemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_nofrosttemp));
register_device_value(tag, &hc->roominfluence, DeviceValueType::UINT, nullptr, FL_(roominfluence), DeviceValueUOM::NONE, MAKE_CF_CB(set_roominfluence));
register_device_value(tag, &hc->minflowtemp, DeviceValueType::UINT, nullptr, FL_(minflowtemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_minflowtemp));
register_device_value(tag, &hc->maxflowtemp, DeviceValueType::UINT, nullptr, FL_(maxflowtemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_maxflowtemp));
register_device_value(tag, &hc->flowtempoffset, DeviceValueType::UINT, nullptr, FL_(flowtempoffset), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_flowtempoffset));
register_device_value(tag, &hc->heatingtype, DeviceValueType::ENUM, FL_(enum_heatingtype), FL_(heatingtype), DeviceValueUOM::NONE);
register_device_value(tag, &hc->reducemode, DeviceValueType::ENUM, FL_(enum_reducemode), FL_(reducemode), DeviceValueUOM::NONE, MAKE_CF_CB(set_reducemode));
register_device_value(tag, &hc->controlmode, DeviceValueType::ENUM, FL_(enum_controlmode2), FL_(controlmode), DeviceValueUOM::NONE, MAKE_CF_CB(set_controlmode));
register_device_value(tag, &hc->control, DeviceValueType::ENUM, FL_(enum_control), FL_(control), DeviceValueUOM::NONE, MAKE_CF_CB(set_control));
register_device_value(tag, &hc->program, DeviceValueType::UINT, nullptr, FL_(program), DeviceValueUOM::NONE, MAKE_CF_CB(set_program));
register_device_value(tag, &hc->pause, DeviceValueType::UINT, nullptr, FL_(pause), DeviceValueUOM::HOURS, MAKE_CF_CB(set_pause));
register_device_value(tag, &hc->party, DeviceValueType::UINT, nullptr, FL_(party), DeviceValueUOM::HOURS, MAKE_CF_CB(set_party));
register_device_value(tag, &hc->tempautotemp, DeviceValueType::UINT, FL_(div2), FL_(tempautotemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_tempautotemp));
register_device_value(tag, &hc->noreducetemp, DeviceValueType::INT, nullptr, FL_(noreducetemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_noreducetemp));
register_device_value(tag, &hc->remotetemp, DeviceValueType::SHORT, FL_(div10), FL_(remotetemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_remotetemp));
register_device_value(tag, &dummychar_, DeviceValueType::TEXT, nullptr, FL_(switchtime), DeviceValueUOM::NONE, MAKE_CF_CB(set_switchtime));
break;
case EMS_DEVICE_FLAG_JUNKERS:
register_device_value(tag, &hc->mode, DeviceValueType::ENUM, FL_(enum_mode4), FL_(mode), DeviceValueUOM::NONE, MAKE_CF_CB(set_mode));
register_device_value(tag, &hc->modetype, DeviceValueType::ENUM, FL_(enum_modetype4), FL_(modetype), DeviceValueUOM::NONE);
register_device_value(tag, &hc->daytemp, DeviceValueType::UINT, FL_(div2), FL_(heattemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_heattemp));
register_device_value(tag, &hc->nighttemp, DeviceValueType::UINT, FL_(div2), FL_(ecotemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_ecotemp));
register_device_value(tag, &hc->nofrosttemp, DeviceValueType::INT, FL_(div2), FL_(nofrosttemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_nofrosttemp));
break;
}
}
} // namespace emsesp