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esp32_loraprs
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esp32_loraprs/loraprs_service.cpp

614 wiersze
15 KiB
C++
Czysty Wina Historia

#include "loraprs_service.h"
namespace LoraPrs {
byte Service::rxBuf_[256];
#ifdef USE_RADIOLIB
bool Service::interruptEnabled_ = true;
std::shared_ptr<SX1278> Service::radio_;
#endif
Service::Service()
: Kiss::Processor()
, csmaP_(CfgCsmaPersistence)
, csmaSlotTime_(CfgCsmaSlotTimeMs)
, csmaSlotTimePrev_(0)
, serialBt_()
, serialBLE_()
{
#ifdef USE_RADIOLIB
interruptEnabled_ = true;
#endif
}
void Service::setup(const Config &conf)
{
config_ = conf;
previousBeaconMs_ = 0;
ownCallsign_ = AX25::Callsign(config_.AprsLogin);
if (!ownCallsign_.IsValid()) {
Serial.println("Own callsign is not valid");
}
aprsLoginCommand_ = String("user ") + config_.AprsLogin + String(" pass ") +
config_.AprsPass + String(" vers ") + CfgLoraprsVersion;
if (config_.EnableIsToRf && config_.AprsFilter.length() > 0) {
aprsLoginCommand_ += String(" filter ") + config_.AprsFilter;
}
aprsLoginCommand_ += String("\n");
// peripherals
setupLora(config_.LoraFreq, config_.LoraBw, config_.LoraSf,
config_.LoraCodingRate, config_.LoraPower, config_.LoraSync, config_.LoraEnableCrc);
if (needsWifi()) {
setupWifi(config_.WifiSsid, config_.WifiKey);
}
if (needsBt() || config_.BtName.length() > 0) {
setupBt(config_.BtName);
}
if (needsAprsis() && config_.EnablePersistentAprsConnection) {
reconnectAprsis();
}
if (config_.PttEnable) {
Serial.println("External PTT is enabled");
pinMode(config_.PttPin, OUTPUT);
}
}
void Service::setupWifi(const String &wifiName, const String &wifiKey)
{
Serial.print("WIFI connecting to " + wifiName);
WiFi.setHostname("loraprs");
WiFi.mode(WIFI_STA);
WiFi.begin(wifiName.c_str(), wifiKey.c_str());
int retryCnt = 0;
while (WiFi.status() != WL_CONNECTED) {
delay(CfgConnRetryMs);
Serial.print(".");
if (retryCnt++ >= CfgConnRetryMaxTimes) {
Serial.println("failed");
return;
}
}
Serial.println("ok");
Serial.println(WiFi.localIP());
}
void Service::reconnectWifi() const
{
Serial.print("WIFI re-connecting...");
int retryCnt = 0;
while (WiFi.status() != WL_CONNECTED || WiFi.localIP() == IPAddress(0,0,0,0)) {
WiFi.reconnect();
delay(CfgConnRetryMs);
Serial.print(".");
if (retryCnt++ >= CfgConnRetryMaxTimes) {
Serial.println("failed");
return;
}
}
Serial.println("ok");
}
bool Service::reconnectAprsis()
{
Serial.print("APRSIS connecting...");
if (!aprsisConn_.connect(config_.AprsHost.c_str(), config_.AprsPort)) {
Serial.println("Failed to connect to " + config_.AprsHost + ":" + config_.AprsPort);
return false;
}
Serial.println("ok");
aprsisConn_.print(aprsLoginCommand_);
return true;
}
void Service::setupLora(long loraFreq, long bw, int sf, int cr, int pwr, int sync, bool enableCrc)
{
Serial.print("LoRa init: ");
Serial.print(loraFreq); Serial.print(", ");
Serial.print(bw); Serial.print(", ");
Serial.print(sf); Serial.print(", ");
Serial.print(cr); Serial.print(", ");
Serial.print(pwr); Serial.print(", ");
Serial.print(sync, 16); Serial.print(", ");
Serial.print(enableCrc); Serial.print("...");
isImplicitHeaderMode_ = sf == 6;
#ifdef USE_RADIOLIB
radio_ = std::make_shared<SX1278>(new Module(config_.LoraPinSs, config_.LoraPinDio0, config_.LoraPinRst, RADIOLIB_NC));
int state = radio_->begin((float)loraFreq / 1e6, (float)bw / 1e3, sf, cr, sync, pwr);
if (state != ERR_NONE) {
Serial.print("Radio start error: "); Serial.println(state);
}
radio_->setCRC(enableCrc);
//radio_->forceLDRO(false);
//radio_->setRfSwitchPins(4, 5);
radio_->clearDio0Action();
radio_->setDio0Action(onLoraDataAvailableIsr);
state = radio_->startReceive();
if (state != ERR_NONE) {
Serial.print("Receive start error: "); Serial.println(state);
}
#else // USE_RADIOLIB
LoRa.setPins(config_.LoraPinSs, config_.LoraPinRst, config_.LoraPinDio0);
int retryCnt = 0;
while (!LoRa.begin(loraFreq)) {
Serial.print(".");
delay(CfgConnRetryMs);
if (retryCnt++ >= CfgConnRetryMaxTimes) {
Serial.println("failed");
return;
}
}
LoRa.setSyncWord(sync);
LoRa.setSpreadingFactor(sf);
LoRa.setSignalBandwidth(bw);
LoRa.setCodingRate4(cr);
LoRa.setTxPower(pwr);
if (enableCrc) {
LoRa.enableCrc();
}
if (config_.LoraUseIsr) {
LoRa.onReceive(onLoraDataAvailableIsr);
LoRa.receive();
}
#endif // USE_RADIOLIB
Serial.println("ok");
}
void Service::setupBt(const String &btName)
{
String btType = config_.BtEnableBle ? "BLE" : "BT";
Serial.print(btType + " init " + btName + "...");
bool btOk = config_.BtEnableBle
? serialBLE_.begin(btName.c_str())
: serialBt_.begin(btName);
if (btOk) {
Serial.println("ok");
}
else {
Serial.println("failed");
}
}
void Service::loop()
{
if (needsWifi() && WiFi.status() != WL_CONNECTED) {
reconnectWifi();
}
if (needsAprsis() && !aprsisConn_.connected() && config_.EnablePersistentAprsConnection) {
reconnectAprsis();
}
// RX path, Rig -> Serial
bool isRigToSerialProcessed = false;
#ifdef USE_RADIOLIB
isRigToSerialProcessed = processRigToSerial();
#else
if (config_.LoraUseIsr) {
isRigToSerialProcessed = processRigToSerial();
} else {
if (int packetSize = LoRa.parsePacket()) {
loraReceive(packetSize);
isRigToSerialProcessed = true;
}
}
#endif
// TX path, Serial -> Rig
if (!isRigToSerialProcessed) {
long currentTime = millis();
if (!isLoraRxBusy() && currentTime > csmaSlotTimePrev_ + csmaSlotTime_ && random(0, 255) < csmaP_) {
if (aprsisConn_.available() > 0) {
onAprsisDataAvailable();
}
if (needsBeacon()) {
sendPeriodicBeacon();
}
bool allTxProcessed = processSerialToRig();
if (allTxProcessed) {
#ifdef USE_RADIOLIB
int state = radio_->startReceive();
if (state != ERR_NONE) {
Serial.print("Start receive error: "); Serial.println(state);
}
#else
if (config_.LoraUseIsr) {
LoRa.receive();
}
#endif
}
csmaSlotTimePrev_ = currentTime;
}
}
delay(CfgPollDelayMs);
}
bool Service::isLoraRxBusy() {
#ifdef USE_RADIOLIB
return cfg_.LoraUseCad && (radio_->getModemStatus() & 0x01); // SX1278_STATUS_SIG_DETECT
#else
return false;
#endif
}
#ifdef USE_RADIOLIB
ICACHE_RAM_ATTR void Service::onLoraDataAvailableIsr() {
if (interruptEnabled_) {
int packetSize = radio_->getPacketLength();
if (packetSize > 0) {
int state = radio_->readData(rxBuf_, packetSize);
if (state == ERR_NONE) {
queueRigToSerialIsr(Cmd::Data, rxBuf_, packetSize);
} else {
Serial.print("Read data error: "); Serial.println(state);
}
state = radio_->startReceive();
if (state != ERR_NONE) {
Serial.print("Start receive error: "); Serial.println(state);
}
}
}
}
#else // USE_RADIOLIB
ICACHE_RAM_ATTR void Service::onLoraDataAvailableIsr(int packetSize)
{
int rxBufIndex = 0;
for (int i = 0; i < packetSize; i++) {
rxBuf_[rxBufIndex++] = LoRa.read();
}
queueRigToSerialIsr(Cmd::Data, rxBuf_, rxBufIndex);
}
#endif // USE_RADIOLIB
void Service::sendPeriodicBeacon()
{
long currentMs = millis();
if (previousBeaconMs_ == 0 || currentMs - previousBeaconMs_ >= config_.AprsRawBeaconPeriodMinutes * 60 * 1000) {
AX25::Payload payload(config_.AprsRawBeacon);
if (payload.IsValid()) {
sendAX25ToLora(payload);
if (config_.EnableRfToIs) {
sendToAprsis(payload.ToString());
}
Serial.println("Periodic beacon is sent");
}
else {
Serial.println("Beacon payload is invalid");
}
previousBeaconMs_ = currentMs;
}
}
void Service::sendToAprsis(const String &aprsMessage)
{
if (needsWifi() && WiFi.status() != WL_CONNECTED) {
reconnectWifi();
}
if (needsAprsis() && !aprsisConn_.connected()) {
reconnectAprsis();
}
aprsisConn_.println(aprsMessage);
if (!config_.EnablePersistentAprsConnection) {
aprsisConn_.stop();
}
}
void Service::onAprsisDataAvailable()
{
String aprsisData;
while (aprsisConn_.available() > 0) {
char c = aprsisConn_.read();
if (c == '\r') continue;
Serial.print(c);
if (c == '\n') break;
aprsisData += c;
if (aprsisData.length() >= CfgMaxAprsInMessageSize) {
Serial.println("APRS-IS incoming message is too long, skipping tail");
break;
}
}
if (config_.EnableIsToRf && aprsisData.length() > 0) {
AX25::Payload payload(aprsisData);
if (payload.IsValid()) {
sendAX25ToLora(payload);
}
else {
Serial.println("Unknown payload from APRSIS, ignoring");
}
}
}
void Service::sendSignalReportEvent(int rssi, float snr)
{
struct SignalReport signalReport;
signalReport.rssi = htobe16(rssi);
signalReport.snr = htobe16(snr * 100);
sendRigToSerial(Cmd::SignalReport, (const byte *)&signalReport, sizeof(SignalReport));
}
bool Service::sendAX25ToLora(const AX25::Payload &payload)
{
byte buf[CfgMaxAX25PayloadSize];
int bytesWritten = payload.ToBinary(buf, sizeof(buf));
if (bytesWritten <= 0) {
Serial.println("Failed to serialize payload");
return false;
}
queueSerialToRig(Cmd::Data, buf, bytesWritten);
return true;
}
void Service::onRigPacket(void *packet, int packetLength)
{
#ifdef USE_RADIOLIB
long frequencyErrorHz = radio_->getFrequencyError();
#else
long frequencyErrorHz = LoRa.packetFrequencyError();
#endif
if (config_.EnableAutoFreqCorrection && abs(frequencyErrorHz) > config_.AutoFreqCorrectionDeltaHz) {
config_.LoraFreq -= frequencyErrorHz;
Serial.print("Correcting frequency: "); Serial.println(frequencyErrorHz);
#ifdef USE_RADIOLIB
radio_->setFrequency((float)config_.LoraFreq / 1e6);
int state = radio_->startReceive();
if (state != ERR_NONE) {
Serial.print("Start receive error: "); Serial.println(state);
}
#else
LoRa.setFrequency(config_.LoraFreq);
if (config_.LoraUseIsr) {
LoRa.idle();
LoRa.receive();
}
#endif
}
if (config_.KissEnableExtensions) {
#ifdef USE_RADIOLIB
sendSignalReportEvent(radio_->getRSSI(), radio_->getSNR());
#else
sendSignalReportEvent(LoRa.packetRssi(), LoRa.packetSnr());
#endif
}
if (!config_.IsClientMode) {
processIncomingRawPacketAsServer((const byte*)packet, packetLength);
}
}
#ifndef USE_RADIOLIB
void Service::loraReceive(int packetSize)
{
int rxBufIndex = 0;
byte rxBuf[packetSize];
while (LoRa.available()) {
rxBuf[rxBufIndex++] = LoRa.read();
}
sendRigToSerial(Cmd::Data, rxBuf, rxBufIndex);
onRigPacket(rxBuf, rxBufIndex);
}
#endif
void Service::processIncomingRawPacketAsServer(const byte *packet, int packetLength) {
AX25::Payload payload(packet, packetLength);
if (payload.IsValid()) {
#ifdef USE_RADIOLIB
float snr = radio_->getSNR();
int rssi = radio_->getRSSI();
long frequencyError = radio_->getFrequencyError();
#else
float snr = LoRa.packetSnr();
int rssi = LoRa.packetRssi();
long frequencyError = LoRa.packetFrequencyError();
#endif
String signalReport = String(" ") +
String("rssi: ") +
String(snr < 0 ? rssi + snr : rssi) +
String("dBm, ") +
String("snr: ") +
String(snr) +
String("dB, ") +
String("err: ") +
String(frequencyError) +
String("Hz");
String textPayload = payload.ToString(config_.EnableSignalReport ? signalReport : String());
Serial.println(textPayload);
if (config_.EnableRfToIs) {
sendToAprsis(textPayload);
Serial.println("Packet sent to APRS-IS");
}
if (config_.EnableRepeater && payload.Digirepeat(ownCallsign_)) {
sendAX25ToLora(payload);
Serial.println("Packet digirepeated");
}
} else {
Serial.println("Skipping non-AX25 payload");
}
}
bool Service::onRigTxBegin()
{
if (config_.PttEnable) {
digitalWrite(config_.PttPin, HIGH);
delay(config_.PttTxDelayMs);
} else {
delay(CfgPollDelayMs);
}
#ifdef USE_RADIOLIB
return true;
#else
return (LoRa.beginPacket(isImplicitHeaderMode_) == 1);
#endif
}
void Service::onRigTx(byte b)
{
#ifdef USE_RADIOLIB
txQueue_.push(b);
#else
LoRa.write(b);
#endif
}
void Service::onRigTxEnd()
{
#ifdef USE_RADIOLIB
int txPacketSize = txQueue_.size();
byte txBuf[txPacketSize];
for (int i = 0; i < txPacketSize; i++) {
txBuf[i] = txQueue_.shift();
}
interruptEnabled_ = false;
int state = radio_->transmit(txBuf, txPacketSize);
if (state != ERR_NONE) {
Serial.print("TX error: "); Serial.println(state);
}
interruptEnabled_ = true;
#endif
if (config_.PttEnable) {
#ifndef USE_RADIOLIB
LoRa.endPacket(false);
#endif
delay(config_.PttTxTailMs);
digitalWrite(config_.PttPin, LOW);
} else {
#ifndef USE_RADIOLIB
LoRa.endPacket(true);
#endif
}
}
void Service::onSerialTx(byte b)
{
if (config_.BtEnableBle) {
serialBLE_.write(b);
}
else {
serialBt_.write(b);
}
}
bool Service::onSerialRxHasData()
{
if (config_.BtEnableBle) {
return serialBLE_.available();
}
else {
return serialBt_.available();
}
}
bool Service::onSerialRx(byte *b)
{
int rxResult = config_.BtEnableBle
? serialBLE_.read()
: serialBt_.read();
if (rxResult == -1) {
return false;
}
*b = (byte)rxResult;
return true;
}
void Service::onControlCommand(Cmd cmd, byte value)
{
switch (cmd) {
case Cmd::P:
Serial.print("CSMA P: "); Serial.println(value);
csmaP_ = value;
break;
case Cmd::SlotTime:
Serial.print("CSMA SlotTime: "); Serial.println(value);
csmaSlotTime_ = (long)value * 10;
break;
case Cmd::TxDelay:
Serial.print("TX delay: "); Serial.println(value);
config_.PttTxDelayMs = (long)value * 10;
break;
case Cmd::TxTail:
Serial.print("TX tail: "); Serial.println(value);
config_.PttTxTailMs = (long)value * 10;
break;
default:
break;
}
}
void Service::onRadioControlCommand(const std::vector<byte> &rawCommand) {
if (config_.KissEnableExtensions && rawCommand.size() == sizeof(SetHardware)) {
const struct SetHardware * setHardware = reinterpret_cast<const struct SetHardware*>(rawCommand.data());
config_.LoraFreq = be32toh(setHardware->freq);
config_.LoraBw = be32toh(setHardware->bw);
config_.LoraSf = be16toh(setHardware->sf);
config_.LoraCodingRate = be16toh(setHardware->cr);
config_.LoraPower = be16toh(setHardware->pwr);
config_.LoraSync = be16toh(setHardware->sync);
config_.LoraEnableCrc = setHardware->crc;
setupLora(config_.LoraFreq, config_.LoraBw, config_.LoraSf,
config_.LoraCodingRate, config_.LoraPower, config_.LoraSync, config_.LoraEnableCrc);
} else {
Serial.println("Radio control command of wrong size");
}
}
void Service::onRebootCommand()
{
Serial.println("Reboot requested");
ESP.restart();
}
} // LoraPrs
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