mirror of
https://github.com/DCC-EX/CommandStation-EX.git
synced 2024-12-23 12:51:24 +01:00
e78c2f9794
Unused but needed to satisfy other code!
373 lines
13 KiB
C++
373 lines
13 KiB
C++
/*
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* © 2021 Neil McKechnie
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* © 2021 Mike S
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* © 2021 Fred Decker
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* © 2020-2022 Harald Barth
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* © 2020-2021 Chris Harlow
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* All rights reserved.
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*
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* This file is part of CommandStation-EX
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*
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* This 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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* It 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 CommandStation. If not, see <https://www.gnu.org/licenses/>.
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*/
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#ifndef ARDUINO_ARCH_ESP32
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// This code is replaced entirely on an ESP32
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#include <Arduino.h>
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#include "DCCWaveform.h"
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#include "TrackManager.h"
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#include "DCCTimer.h"
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#include "DCCACK.h"
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#include "DIAG.h"
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bool DCCWaveform::cutoutNextTime=false;
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DCCWaveform DCCWaveform::mainTrack(PREAMBLE_BITS_MAIN, true);
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DCCWaveform DCCWaveform::progTrack(PREAMBLE_BITS_PROG, false);
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// This bitmask has 9 entries as each byte is trasmitted as a zero + 8 bits.
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const byte bitMask[] = {0x00, 0x80, 0x40, 0x20, 0x10, 0x08, 0x04, 0x02, 0x01};
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const byte idlePacket[] = {0xFF, 0x00, 0xFF};
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const byte resetPacket[] = {0x00, 0x00, 0x00};
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// For each state of the wave nextState=stateTransform[currentState]
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const WAVE_STATE stateTransform[]={
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/* WAVE_START -> */ WAVE_PENDING,
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/* WAVE_MID_1 -> */ WAVE_START,
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/* WAVE_HIGH_0 -> */ WAVE_MID_0,
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/* WAVE_MID_0 -> */ WAVE_LOW_0,
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/* WAVE_LOW_0 -> */ WAVE_START,
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/* WAVE_PENDING (should not happen) -> */ WAVE_PENDING};
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// For each state of the wave, signal pin is HIGH or LOW
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const bool signalTransform[]={
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/* WAVE_START -> */ HIGH,
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/* WAVE_MID_1 -> */ LOW,
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/* WAVE_HIGH_0 -> */ HIGH,
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/* WAVE_MID_0 -> */ LOW,
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/* WAVE_LOW_0 -> */ LOW,
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/* WAVE_PENDING (should not happen) -> */ LOW};
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void DCCWaveform::begin() {
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DCCTimer::begin(DCCWaveform::interruptHandler);
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}
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void DCCWaveform::loop() {
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// empty placemarker in case ESP32 needs something here
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}
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#pragma GCC push_options
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#pragma GCC optimize ("-O3")
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void DCCWaveform::interruptHandler() {
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// call the timer edge sensitive actions for progtrack and maintrack
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// member functions would be cleaner but have more overhead
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#if defined(HAS_ENOUGH_MEMORY)
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if (cutoutNextTime) {
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cutoutNextTime=false;
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railcomSampleWindow=false; // about to cutout, stop reading railcom data.
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railcomCutoutCounter++;
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DCCTimer::startRailcomTimer(9);
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}
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#endif
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byte sigMain=signalTransform[mainTrack.state];
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byte sigProg=TrackManager::progTrackSyncMain? sigMain : signalTransform[progTrack.state];
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// Set the signal state for both tracks
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TrackManager::setDCCSignal(sigMain);
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TrackManager::setPROGSignal(sigProg);
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// Refresh the values in the ADCee object buffering the values of the ADC HW
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ADCee::scan();
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// Move on in the state engine
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mainTrack.state=stateTransform[mainTrack.state];
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progTrack.state=stateTransform[progTrack.state];
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// WAVE_PENDING means we dont yet know what the next bit is
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if (mainTrack.state==WAVE_PENDING) mainTrack.interrupt2();
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if (progTrack.state==WAVE_PENDING) progTrack.interrupt2();
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else DCCACK::checkAck(progTrack.getResets());
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}
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#pragma GCC pop_options
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// An instance of this class handles the DCC transmissions for one track. (main or prog)
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// Interrupts are marshalled via the statics.
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// A track has a current transmit buffer, and a pending buffer.
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// When the current buffer is exhausted, either the pending buffer (if there is one waiting) or an idle buffer.
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DCCWaveform::DCCWaveform( byte preambleBits, bool isMain) {
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isMainTrack = isMain;
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packetPending = false;
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reminderWindowOpen = false;
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memcpy(transmitPacket, idlePacket, sizeof(idlePacket));
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state = WAVE_START;
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// The +1 below is to allow the preamble generator to create the stop bit
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// for the previous packet.
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requiredPreambles = preambleBits+1;
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bytes_sent = 0;
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bits_sent = 0;
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}
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bool DCCWaveform::railcomPossible=false; // High accuracy only
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volatile bool DCCWaveform::railcomActive=false; // switched on by user
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volatile bool DCCWaveform::railcomDebug=false; // switched on by user
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volatile bool DCCWaveform::railcomSampleWindow=false; // true during packet transmit
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volatile byte DCCWaveform::railcomCutoutCounter=0; // cyclic cutout
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volatile byte DCCWaveform::railcomLastAddressHigh=0;
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volatile byte DCCWaveform::railcomLastAddressLow=0;
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bool DCCWaveform::setRailcom(bool on, bool debug) {
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if (on && railcomPossible) {
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railcomActive=true;
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railcomDebug=debug;
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}
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else {
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railcomActive=false;
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railcomDebug=false;
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railcomSampleWindow=false;
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}
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return railcomActive;
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}
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#pragma GCC push_options
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#pragma GCC optimize ("-O3")
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void DCCWaveform::interrupt2() {
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// calculate the next bit to be sent:
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// set state WAVE_MID_1 for a 1=bit
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// or WAVE_HIGH_0 for a 0 bit.
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if (remainingPreambles > 0 ) {
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state=WAVE_MID_1; // switch state to trigger LOW on next interrupt
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remainingPreambles--;
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// As we get to the end of the preambles, open the reminder window.
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// This delays any reminder insertion until the last moment so
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// that the reminder doesn't block a more urgent packet.
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reminderWindowOpen=transmitRepeats==0 && remainingPreambles<10 && remainingPreambles>1;
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if (remainingPreambles==1)
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promotePendingPacket();
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#if defined(HAS_ENOUGH_MEMORY)
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else if (isMainTrack && railcomActive) {
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if (remainingPreambles==(requiredPreambles-1)) {
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// First look if we need to start a railcom cutout on next interrupt
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cutoutNextTime= true;
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} else if (remainingPreambles==(requiredPreambles-12)) {
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// cutout has ended so its now possible to poll the railcom detectors
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// requiredPreambles is one higher that preamble length so
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// if preamble length is 16 then this evaluates to 5
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// Remember address bytes of last sent packet so that Railcom can
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// work out where the channel2 data came from.
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railcomLastAddressHigh=transmitPacket[0];
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railcomLastAddressLow =transmitPacket[1];
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railcomSampleWindow=true;
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} else if (remainingPreambles==(requiredPreambles-3)) {
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// cutout can be ended when read
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// see above for requiredPreambles
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DCCTimer::ackRailcomTimer();
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}
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}
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#endif
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// Update free memory diagnostic as we don't have anything else to do this time.
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// Allow for checkAck and its called functions using 22 bytes more.
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else DCCTimer::updateMinimumFreeMemoryISR(22);
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return;
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}
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// Wave has gone HIGH but what happens next depends on the bit to be transmitted
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// beware OF 9-BIT MASK generating a zero to start each byte
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state=(transmitPacket[bytes_sent] & bitMask[bits_sent])? WAVE_MID_1 : WAVE_HIGH_0;
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bits_sent++;
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// If this is the last bit of a byte, prepare for the next byte
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if (bits_sent == 9) { // zero followed by 8 bits of a byte
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//end of Byte
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bits_sent = 0;
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bytes_sent++;
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// if this is the last byte, prepere for next packet
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if (bytes_sent >= transmitLength) {
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// end of transmission buffer... repeat or switch to next message
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bytes_sent = 0;
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// preamble for next packet will start...
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remainingPreambles = requiredPreambles;
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}
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}
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}
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#pragma GCC pop_options
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// Wait until there is no packet pending, then make this pending
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void DCCWaveform::schedulePacket(const byte buffer[], byte byteCount, byte repeats) {
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if (byteCount > MAX_PACKET_SIZE) return; // allow for chksum
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while (packetPending);
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byte checksum = 0;
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for (byte b = 0; b < byteCount; b++) {
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checksum ^= buffer[b];
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pendingPacket[b] = buffer[b];
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}
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// buffer is MAX_PACKET_SIZE but pendingPacket is one bigger
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pendingPacket[byteCount] = checksum;
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pendingLength = byteCount + 1;
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pendingRepeats = repeats;
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packetPending = true;
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clearResets();
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}
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bool DCCWaveform::isReminderWindowOpen() {
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return reminderWindowOpen && ! packetPending;
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}
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void DCCWaveform::promotePendingPacket() {
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// fill the transmission packet from the pending packet
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// Just keep going if repeating
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if (transmitRepeats > 0) {
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transmitRepeats--;
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return;
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}
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if (packetPending) {
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// Copy pending packet to transmit packet
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// a fixed length memcpy is faster than a variable length loop for these small lengths
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// for (int b = 0; b < pendingLength; b++) transmitPacket[b] = pendingPacket[b];
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memcpy( transmitPacket, pendingPacket, sizeof(pendingPacket));
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transmitLength = pendingLength;
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transmitRepeats = pendingRepeats;
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packetPending = false;
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clearResets();
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return;
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}
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// nothing to do, just send idles or resets
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// Fortunately reset and idle packets are the same length
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// Note: If railcomDebug is on, then we send resets to the main
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// track instead of idles. This means that all data will be zeros
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// and only the presets will be ones, making it much
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// easier to read on a logic analyser.
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memcpy( transmitPacket, (isMainTrack && (!railcomDebug)) ? idlePacket : resetPacket, sizeof(idlePacket));
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transmitLength = sizeof(idlePacket);
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transmitRepeats = 0;
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if (getResets() < 250) sentResetsSincePacket++; // only place to increment (private!)
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}
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#endif //not ARDUINO_ARCH_ESP32
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#ifdef ARDUINO_ARCH_ESP32
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#include "DCCWaveform.h"
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#include "TrackManager.h"
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#include "DCCACK.h"
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#include "Pinpair.h"
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DCCWaveform DCCWaveform::mainTrack(PREAMBLE_BITS_MAIN, true);
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DCCWaveform DCCWaveform::progTrack(PREAMBLE_BITS_PROG, false);
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RMTChannel *DCCWaveform::rmtMainChannel = NULL;
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RMTChannel *DCCWaveform::rmtProgChannel = NULL;
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bool DCCWaveform::railcomPossible=false; // High accuracy only
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volatile bool DCCWaveform::railcomActive=false; // switched on by user
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volatile bool DCCWaveform::railcomDebug=false; // switched on by user
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volatile bool DCCWaveform::railcomSampleWindow=false; // true during packet transmit
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volatile byte DCCWaveform::railcomCutoutCounter=0; // cyclic cutout
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volatile byte DCCWaveform::railcomLastAddressHigh=0;
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volatile byte DCCWaveform::railcomLastAddressLow=0;
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DCCWaveform::DCCWaveform(byte preambleBits, bool isMain) {
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isMainTrack = isMain;
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requiredPreambles = preambleBits;
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}
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void DCCWaveform::begin() {
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for(const auto& md: TrackManager::getMainDrivers()) {
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Pinpair p = md->getSignalPin();
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if(rmtMainChannel) {
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//DIAG(F("added pins %d %d to MAIN channel"), p.pin, p.invpin);
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rmtMainChannel->addPin(p); // add pin to existing main channel
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} else {
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//DIAG(F("new MAIN channel with pins %d %d"), p.pin, p.invpin);
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rmtMainChannel = new RMTChannel(p, true); /* create new main channel */
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}
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}
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MotorDriver *md = TrackManager::getProgDriver();
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if (md) {
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Pinpair p = md->getSignalPin();
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if (rmtProgChannel) {
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//DIAG(F("added pins %d %d to PROG channel"), p.pin, p.invpin);
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rmtProgChannel->addPin(p); // add pin to existing prog channel
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} else {
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//DIAG(F("new PROGchannel with pins %d %d"), p.pin, p.invpin);
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rmtProgChannel = new RMTChannel(p, false);
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}
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}
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}
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void DCCWaveform::schedulePacket(const byte buffer[], byte byteCount, byte repeats) {
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if (byteCount > MAX_PACKET_SIZE) return; // allow for chksum
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byte checksum = 0;
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for (byte b = 0; b < byteCount; b++) {
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checksum ^= buffer[b];
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pendingPacket[b] = buffer[b];
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}
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// buffer is MAX_PACKET_SIZE but pendingPacket is one bigger
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pendingPacket[byteCount] = checksum;
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pendingLength = byteCount + 1;
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pendingRepeats = repeats;
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// DIAG repeated commands (accesories)
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// if (pendingRepeats > 0)
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// DIAG(F("Repeats=%d on %s track"), pendingRepeats, isMainTrack ? "MAIN" : "PROG");
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// The resets will be zero not only now but as well repeats packets into the future
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clearResets(repeats+1);
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{
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int ret = 0;
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do {
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if(isMainTrack) {
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if (rmtMainChannel != NULL)
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ret = rmtMainChannel->RMTfillData(pendingPacket, pendingLength, pendingRepeats);
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} else {
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if (rmtProgChannel != NULL)
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ret = rmtProgChannel->RMTfillData(pendingPacket, pendingLength, pendingRepeats);
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}
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} while(ret > 0);
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}
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}
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bool DCCWaveform::isReminderWindowOpen() {
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if(isMainTrack) {
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if (rmtMainChannel == NULL)
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return false;
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return !rmtMainChannel->busy();
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} else {
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if (rmtProgChannel == NULL)
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return false;
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return !rmtProgChannel->busy();
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}
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}
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void IRAM_ATTR DCCWaveform::loop() {
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DCCACK::checkAck(progTrack.getResets());
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}
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bool DCCWaveform::setRailcom(bool on, bool debug) {
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// todo
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(void)on;
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(void)debug;
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return false;
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}
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#endif
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