/* * This file is part of the "bluetoothheater" distribution * (https://gitlab.com/mrjones.id.au/bluetoothheater) * * Copyright (C) 2020 Ray Jones * * 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 . * */ /////////////////////////////////////////////////////////////////////////// // // CDemandManager // // This provides management of the heater temperature or pump demands // /////////////////////////////////////////////////////////////////////////// #include #include "DemandManager.h" #include "NVStorage.h" #include "helpers.h" #include "../RTC/RTCStore.h" #include "../Protocol/Protocol.h" // Concept of timer operation: // // The volatile variables _setDegC & _setPumpHz are altered when a timer runs. // The timer installs the programmed timer value as the new set point. // But if the timer value is zero, no change takes place. // // _setPumpHz will match _setDegC. // _setPumpHz is converted into Hz based using the interploation that is // performed inside the heater ECU according to Max/min temp & pump settings. // // When the timer interval expires, the volatile values revert back to the stored // RTC memory values. // // Exception. // If a timer is running and the user alters the setting, according to the current // thermostat state _setDegC or _setPumpHz are updated with the new demand and the // associated RTC memory value is also updated accordingly. // When the timer completes, it continues with the same value. // The programmed timer temperature is not altered by the user adjusting the running // setting and the same setpoint will recur in the future when that timer runs again. uint8_t CDemandManager::_setDegC = 22; uint8_t CDemandManager::_setPumpHz = 22; uint8_t CDemandManager::getDegC() { return _setDegC; } uint8_t CDemandManager::getPumpHz() { return _setPumpHz; // value lies in the typical range of 8-35 - interpolated by heater to real Hz } // set a new temperature setpoint, also saving it to non volatile RTC memory (battery backed RAM) void CDemandManager::setDegC(uint8_t newDegC) { BOUNDSLIMIT(newDegC, NVstore.getHeaterTuning().Tmin, NVstore.getHeaterTuning().Tmax); _setDegC = newDegC; RTC_Store.setDesiredTemp(newDegC); } // set a new pump setpoint, also saving it to non volatile RTC memory (battery backed RAM) void CDemandManager::setPumpHz(uint8_t newDemand) { // Pump demands use the same range as temperature demands :-) BOUNDSLIMIT(newDemand, NVstore.getHeaterTuning().Tmin, NVstore.getHeaterTuning().Tmax); _setPumpHz = newDemand; RTC_Store.setDesiredPump(newDemand); } // set a transient setpoint for use by prgrammed timer starts // setpoints only change if timer temperature is actually defined void CDemandManager::setFromTimer(uint8_t timerDemand) { if(timerDemand) { _setPumpHz = timerDemand; _setDegC = timerDemand; } } // revert setpoints to stored RTC memory values void CDemandManager::reload() { _setDegC = RTC_Store.getDesiredTemp(); _setPumpHz = RTC_Store.getDesiredPump(); } // test the ambient temperature and check if it satisfies a start condition when running // in thermostat mode // If running in Fixed Hz, the start is not denied, but cyclic suspend may be engaged CDemandManager::eStartCode CDemandManager::checkStart() { // create a deny start temperature margin int stopDeltaT = 0; // determine temperature error vs desired thermostat value float deltaT = getTemperatureSensor() - getDegC(); int cyclicstop = NVstore.getUserSettings().cyclic.Stop; if(cyclicstop) { // cyclic mode enabled // if cyclic mode, raise the margin by the cyclic stop range stopDeltaT = cyclicstop + 1; // bump up by 1 degree - no point invoking cyclic at 1 deg over! // alows honour cyclic stop threshold - immediate suspend transition if(deltaT > stopDeltaT) { return eStartSuspend; } } if(!isExtThermostatMode()) { if(deltaT > stopDeltaT) { // temperature exceeded the allowed margin // only deny start if actually using inbuilt thermostat mode if(isThermostat()) { return eStartTooWarm; // too warm - deny start } } } return eStartOK; // allow start } // generic method adjust the active heter demand. // thi may be Pump Hz or desired temeperature, dependent upon if thermostat mode is active bool CDemandManager::setDemand(uint8_t newDemand) { if(hasOEMcontroller()) return false; // bounds operate over the same range for either mode BOUNDSLIMIT(newDemand, NVstore.getHeaterTuning().Tmin, NVstore.getHeaterTuning().Tmax); // set and save the demand to NV storage // note that we now maintain fixed Hz and Thermostat set points seperately if(isThermostat()) { setDegC(newDemand); } else { setPumpHz(newDemand); } return true; } bool CDemandManager::deltaDemand(int delta) { if(hasOEMcontroller()) return false; uint8_t newDemand; if(isThermostat()) { newDemand = getDegC() + delta; setDegC(newDemand); } else { newDemand = getPumpHz() + delta; setPumpHz(newDemand); } return true; } bool CDemandManager::toggleThermostat() { return setThermostatMode(isThermostat() ? 0 : 1); } bool CDemandManager::setThermostatMode(uint8_t val, bool save) { if(hasOEMcontroller()) return false; sUserSettings settings = NVstore.getUserSettings(); settings.useThermostat = val ? 0x01 : 0x00; NVstore.setUserSettings(settings); if(save) NVstore.save(); return true; } // set system to show degF or degC void CDemandManager::setDegFMode(bool state) { sUserSettings settings = NVstore.getUserSettings(); settings.degF = state ? 0x01 : 0x00; NVstore.setUserSettings(settings); NVstore.save(); } // return tru is using a thermostat mode bool CDemandManager::isThermostat() { if(hasOEMcontroller()) { return getHeaterInfo().isThermostat(); } else { return NVstore.getUserSettings().useThermostat != 0; } } // generic get demand for Pump Hz or degC, as would be used in the value sent to the heater uint8_t CDemandManager::getDemand() { if(hasOEMcontroller()) { return getHeaterInfo().getHeaterDemand(); } else { if(isThermostat()) { return getDegC(); } else { return getPumpHz(); // timer manager will return pump Hz, as demand value, not real Hz } } } // return true if external thermostat mode is active bool CDemandManager::isExtThermostatMode() { #if USE_JTAG == 0 return GPIOin.usesExternalThermostat() && (NVstore.getUserSettings().ThermostatMethod == 3); #else //CANNOT USE GPIO WITH JTAG DEBUG return false; #endif } // return true if external thermosat is closed bool CDemandManager::isExtThermostatOn() { #if USE_JTAG == 0 return GPIOin.getState(1); #else //CANNOT USE GPIO WITH JTAG DEBUG return false; #endif } const char* CDemandManager::getExtThermostatHoldTime() { #if USE_JTAG == 0 return GPIOin.getExtThermHoldTime(); #else //CANNOT USE GPIO WITH JTAG DEBUG return "00:00"; #endif }