170 lines
5.5 KiB
C++
170 lines
5.5 KiB
C++
/*
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* This file is part of the "bluetoothheater" distribution
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* (https://gitlab.com/mrjones.id.au/bluetoothheater)
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*
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* Copyright (C) 2018 Ray Jones <ray@mrjones.id.au>
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*
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <https://www.gnu.org/licenses/>.
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*
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*/
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#include "TxManage.h"
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#include "NVStorage.h"
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extern void DebugReportFrame(const char* hdr, const CProtocol&, const char* ftr);
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// CTxManage is used to send a data frame to the blue wire
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//
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// As the blue wire is bidirectional, we need to only allow our transmit data
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// to reach the blue wire when we actually want to send data.
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// At all other times we are listening to the blue wire, receiving any async data
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//
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// This requires external circuitry to toggle the Tx/Rx modes.
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// A "Tx Gating" signal is used.
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// when high, transmit data is sent to the blue wire
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// when low, transmit data is blocked (Hi-Z)
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//
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// Ideally the circuit also prevents feeding back our own Tx data into the Rx pin
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// but the main software loop handles this situation by only accepting Rx data when expected.
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//
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// Timing diagram
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// ____________________
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// Tx Gate ____________________| |___________________________
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// _____________________________________________________________________
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// Tx Data |||||||||||||||
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CTxManage::CTxManage(int TxGatePin, HardwareSerial& serial) :
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m_BlueWireSerial(serial),
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m_TxFrame(CProtocol::CtrlMode)
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{
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m_bOnReq = false;
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m_bOffReq = false;
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m_bTxPending = false;
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m_nStartTime = 0;
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m_nTxGatePin = TxGatePin;
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_rawCommand = 0;
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}
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void CTxManage::begin()
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{
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pinMode(m_nTxGatePin, OUTPUT);
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digitalWrite(m_nTxGatePin, LOW); // default to receive mode
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}
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void
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CTxManage::queueOnRequest(bool set)
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{
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m_bOnReq = set; // allow cancellation via heater response frame decode
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m_bOffReq = false;
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}
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void
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CTxManage::queueOffRequest(bool set)
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{
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m_bOffReq = set; // allow cancellation via heater response frame decode
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m_bOnReq = false;
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}
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void
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CTxManage::queueRawCommand(unsigned char val)
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{
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_rawCommand = val;
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}
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void
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CTxManage::PrepareFrame(const CProtocol& basisFrame, bool isBTCmaster)
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{
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// copy supplied frame, typically this will be the values an OEM controller delivered
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// which means we parrot that data by default.
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// When parroting, we must especially avoid ping ponging "set temperature"!
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// Otherwise we are supplied with the default params for standalone mode, which we
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// then instil the NV parameters
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m_TxFrame = basisFrame;
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// ALWAYS install on/off commands if required
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m_TxFrame.resetCommand(); // no command upon blue wire initially, unless a request is pending
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if(_rawCommand) {
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m_TxFrame.setRawCommand(_rawCommand);
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_rawCommand = 0;
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}
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else {
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if(m_bOnReq) {
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// m_bOnReq = false; // requires cancel via queueOnRequest(false)
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m_TxFrame.onCommand();
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}
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if(m_bOffReq) {
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// m_bOffReq = false; // requires cancel via queueOffRequest(false)
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m_TxFrame.offCommand();
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}
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}
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// 0x78 prevents the controller showing bum information when we parrot the OEM controller
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// heater is happy either way, the OEM controller has set the max/min stuff already
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if(isBTCmaster) {
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m_TxFrame.setActiveMode(); // this allows heater to save the tuning params to EEPROM
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m_TxFrame.setFan_Min(pNVStorage->getFmin());
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m_TxFrame.setFan_Max(pNVStorage->getFmax());
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m_TxFrame.setPump_Min(pNVStorage->getPmin());
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m_TxFrame.setPump_Max(pNVStorage->getPmax());
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m_TxFrame.setThermostatMode(pNVStorage->getThermostatMode());
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m_TxFrame.setTemperature_Desired(pNVStorage->getTemperature());
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}
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else {
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m_TxFrame.setPassiveMode(); // this prevents the tuning parameters being saved by heater
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}
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// ensure CRC valid
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m_TxFrame.setCRC();
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}
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void
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CTxManage::Start(unsigned long timenow)
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{
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if(timenow == 0) // avoid a black hole if millis() has wrapped to zero
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timenow++;
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m_nStartTime = timenow;
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m_bTxPending = true;
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}
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// generate a Tx Gate, then send the TxFrame to the Blue wire
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// Note the serial data is ISR driven, we need to hold off
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// for a while to let teh buffewred dat clear before closing the Tx Gate.
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bool
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CTxManage::CheckTx(unsigned long timenow)
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{
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if(m_nStartTime) {
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long diff = timenow - m_nStartTime;
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if(diff > m_nStartDelay) {
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// begin front porch of Tx gating pulse
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digitalWrite(m_nTxGatePin, HIGH);
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}
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if(m_bTxPending && (diff > (m_nStartDelay + m_nFrontPorch))) {
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// front porch expired, perform serial transmission
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// Tx gate remains held high
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m_bTxPending = false;
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m_BlueWireSerial.write(m_TxFrame.Data, 24); // write native binary values
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}
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if(diff > (m_nStartDelay + m_nFrameTime)) {
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// conclude Tx gating after (emperical) delay
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digitalWrite(m_nTxGatePin, LOW);
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m_nStartTime = 0; // cancel, we are DONE
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}
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}
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return m_nStartTime == 0; // returns true when done
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}
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