/* * © 2023, Neil McKechnie. All rights reserved. * * This file is part of DCC++EX API * * This 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. * * It 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 CommandStation. If not, see . */ #include "IO_CMRI.h" #include "defines.h" /************************************************************ * CMRIbus implementation ************************************************************/ // Constructor for CMRIbus CMRIbus::CMRIbus(uint8_t busNo, HardwareSerial &serial, unsigned long baud, uint16_t cycleTimeMS, VPIN transmitEnablePin) { _busNo = busNo; _serial = &serial; _baud = baud; _cycleTime = cycleTimeMS * 1000UL; // convert from milliseconds to microseconds. _transmitEnablePin = transmitEnablePin; if (_transmitEnablePin != VPIN_NONE) { pinMode(_transmitEnablePin, OUTPUT); ArduinoPins::fastWriteDigital(_transmitEnablePin, 0); // transmitter initially off } // Max message length is 256+6=262 bytes. // Each byte is one start bit, 8 data bits and 1 or 2 stop bits, assume 11 bits per byte. // Calculate timeout based on treble this time. _timeoutPeriod = 3 * 11 * 262 * 1000UL / (_baud / 1000UL); #if ARDUINOCMRI_COMPATIBLE // NOTE: The ArduinoCMRI library, unless modified, contains a 'delay(50)' between // receiving the end of the prompt message and starting to send the response. This // is allowed for below. _timeoutPeriod += 50000UL; #endif // Calculate the time in microseconds to transmit one byte (11 bits max). _byteTransmitTime = 1000000UL * 11 / _baud; // Postdelay is only required if we need to allow for data still being sent when // we want to switch off the transmitter. The flush() method of HardwareSerial // ensures that the data has completed being sent over the line. _postDelay = 0; // Add device to HAL device chain IODevice::addDevice(this); // Add bus to CMRIbus chain. _nextBus = _busList; _busList = this; } // Main loop function for CMRIbus. // Work through list of nodes. For each node, in separate loop entries // send initialisation message (once only); then send // output message; then send prompt for input data, and // process any response data received. // When the slot time has finished, move on to the next device. void CMRIbus::_loop(unsigned long currentMicros) { _currentMicros = currentMicros; while (_serial->available()) processIncoming(); // Send any data that needs sending. processOutgoing(); } // Send output data to the bus for nominated CMRInode uint16_t CMRIbus::sendData(CMRInode *node) { uint16_t numDataBytes = (node->getNumOutputs()+7)/8; _serial->write(SYN); _serial->write(SYN); _serial->write(STX); _serial->write(node->getAddress() + 65); _serial->write('T'); // T for Transmit data message uint16_t charsSent = 6; // include header and trailer for (uint8_t index=0; indexgetOutputStates(index); if (value == DLE || value == STX || value == ETX) { _serial->write(DLE); charsSent++; } _serial->write(value); charsSent++; } _serial->write(ETX); return charsSent; // number of characters sent } // Send request for input data to nominated CMRInode. uint16_t CMRIbus::requestData(CMRInode *node) { _serial->write(SYN); _serial->write(SYN); _serial->write(STX); _serial->write(node->getAddress() + 65); _serial->write('P'); // P for Poll message _serial->write(ETX); return 6; // number of characters sent } // Send initialisation message uint16_t CMRIbus::sendInitialisation(CMRInode *node) { _serial->write(SYN); _serial->write(SYN); _serial->write(STX); _serial->write(node->getAddress() + 65); _serial->write('I'); // I for initialise message _serial->write(node->getType()); // NDP _serial->write((uint8_t)0); // dH _serial->write((uint8_t)0); // dL _serial->write((uint8_t)0); // NS _serial->write(ETX); return 10; // number of characters sent } void CMRIbus::processOutgoing() { uint16_t charsSent = 0; if (_currentNode == NULL) { // If we're between read/write cycles then don't do anything else. if (_currentMicros - _cycleStartTime < _cycleTime) return; // ... otherwise start processing the first node in the list _currentNode = _nodeListStart; _transmitState = TD_INIT; _cycleStartTime = _currentMicros; } if (_currentNode == NULL) return; switch (_transmitState) { case TD_IDLE: case TD_INIT: enableTransmitter(); if (!_currentNode->isInitialised()) { charsSent = sendInitialisation(_currentNode); _currentNode->setInitialised(); _transmitState = TD_TRANSMIT; delayUntil(_currentMicros+_byteTransmitTime*charsSent); break; } /* fallthrough */ case TD_TRANSMIT: charsSent = sendData(_currentNode); _transmitState = TD_PROMPT; // Defer next entry for as long as it takes to transmit the characters, // to allow output queue to empty. Allow 2 bytes extra. delayUntil(_currentMicros+_byteTransmitTime*(charsSent+2)); break; case TD_PROMPT: charsSent = requestData(_currentNode); disableTransmitter(); _transmitState = TD_RECEIVE; _timeoutStart = _currentMicros; // Start timeout on response break; case TD_RECEIVE: // Waiting for response / timeout if (_currentMicros - _timeoutStart > _timeoutPeriod) { // End of time slot allocated for responses. _transmitState = TD_IDLE; // Reset state of receiver _receiveState = RD_SYN1; // Move to next node _currentNode = _currentNode->getNext(); } break; } } // Process any data bytes received from a CMRInode. void CMRIbus::processIncoming() { int data = _serial->read(); if (data < 0) return; // No characters to read if (_transmitState != TD_RECEIVE || !_currentNode) return; // Not waiting for input, so ignore. uint8_t nextState = RD_SYN1; // default to resetting state machine switch(_receiveState) { case RD_SYN1: if (data == SYN) nextState = RD_SYN2; break; case RD_SYN2: if (data == SYN) nextState = RD_STX; else nextState = RD_SYN2; break; case RD_STX: if (data == STX) nextState = RD_ADDR; break; case RD_ADDR: // If address doesn't match, then ignore everything until next SYN-SYN-STX. if (data == _currentNode->getAddress() + 65) nextState = RD_TYPE; break; case RD_TYPE: _receiveDataIndex = 0; // Initialise data pointer if (data == 'R') nextState = RD_DATA; break; case RD_DATA: // data body if (data == DLE) // escape next character nextState = RD_ESCDATA; else if (data == ETX) { // end of data // End of data message. Protocol has all data in one // message, so we don't need to wait any more. Allow // transmitter to proceed with next node in list. _currentNode = _currentNode->getNext(); _transmitState = TD_IDLE; } else { // Not end yet, so save data byte _currentNode->saveIncomingData(_receiveDataIndex++, data); nextState = RD_DATA; // wait for more data } break; case RD_ESCDATA: // escaped data byte _currentNode->saveIncomingData(_receiveDataIndex++, data); nextState = RD_DATA; break; } _receiveState = nextState; } // If configured for half duplex RS485, switch RS485 interface // into transmit mode. void CMRIbus::enableTransmitter() { if (_transmitEnablePin != VPIN_NONE) ArduinoPins::fastWriteDigital(_transmitEnablePin, 1); // If we need a delay before we start the packet header, // we can send a character or two to synchronise the // transmitter and receiver. // SYN characters should be used, but a bug in the // ArduinoCMRI library causes it to ignore the packet if // it's preceded by an odd number of SYN characters. // So send a SYN followed by a NUL in that case. _serial->write(SYN); #if ARDUINOCMRI_COMPATIBLE _serial->write(NUL); // Reset the ArduinoCMRI library's parser #endif } // If configured for half duplex RS485, switch RS485 interface // into receive mode. void CMRIbus::disableTransmitter() { // Wait until all data has been transmitted. On the standard // AVR driver, this waits until the FIFO is empty and all // data has been sent over the link. _serial->flush(); // If we don't trust the 'flush' function and think the // data's still in transit, then wait a bit longer. if (_postDelay > 0) delayMicroseconds(_postDelay); // Hopefully, we can now safely switch off the transmitter. if (_transmitEnablePin != VPIN_NONE) ArduinoPins::fastWriteDigital(_transmitEnablePin, 0); } // Link to chain of CMRI bus instances CMRIbus *CMRIbus::_busList = NULL; /************************************************************ * CMRInode implementation ************************************************************/ // Constructor for CMRInode object CMRInode::CMRInode(VPIN firstVpin, int nPins, uint8_t busNo, uint8_t address, char type, uint16_t inputs, uint16_t outputs) { _firstVpin = firstVpin; _nPins = nPins; _busNo = busNo; _address = address; _type = type; switch (_type) { case 'M': // SMINI, fixed 24 inputs and 48 outputs _numInputs = 24; _numOutputs = 48; break; case 'C': // CPNODE with 16 to 144 inputs/outputs using 8-bit cards _numInputs = inputs; _numOutputs = outputs; break; case 'N': // Classic USIC and SUSIC using 24 bit i/o cards case 'X': // SUSIC using 32 bit i/o cards default: DIAG(F("CMRInode: bus:%d address:%d ERROR unsupported type %c"), _busNo, _address, _type); return; // Don't register device. } if ((unsigned int)_nPins < _numInputs + _numOutputs) DIAG(F("CMRInode: bus:%d address:%d WARNING number of Vpins does not cover all inputs and outputs"), _busNo, _address); // Allocate memory for states _inputStates = (uint8_t *)calloc((_numInputs+7)/8, 1); _outputStates = (uint8_t *)calloc((_numOutputs+7)/8, 1); if (!_inputStates || !_outputStates) { DIAG(F("CMRInode: ERROR insufficient memory")); return; } // Add this device to HAL device list IODevice::addDevice(this); // Add CMRInode to CMRIbus object. CMRIbus *bus = CMRIbus::findBus(_busNo); if (bus != NULL) { bus->addNode(this); return; } }