MeshCore/examples/kiss_modem/KissModem.cpp

#include "KissModem.h"
#include <CayenneLPP.h>

KissModem::KissModem(Stream& serial, mesh::LocalIdentity& identity, mesh::RNG& rng,
                     mesh::Radio& radio, mesh::MainBoard& board, SensorManager& sensors)
  : _serial(serial), _identity(identity), _rng(rng), _radio(radio), _board(board), _sensors(sensors) {
  _rx_len = 0;
  _rx_escaped = false;
  _rx_active = false;
  _has_pending_tx = false;
  _pending_tx_len = 0;
  _txdelay = KISS_DEFAULT_TXDELAY;
  _persistence = KISS_DEFAULT_PERSISTENCE;
  _slottime = KISS_DEFAULT_SLOTTIME;
  _txtail = 0;
  _fullduplex = 0;
  _tx_state = TX_IDLE;
  _tx_timer = 0;
  _setRadioCallback = nullptr;
  _setTxPowerCallback = nullptr;
  _getCurrentRssiCallback = nullptr;
  _getStatsCallback = nullptr;
  _sendPacketCallback = nullptr;
  _isSendCompleteCallback = nullptr;
  _onSendFinishedCallback = nullptr;
  _config = {0, 0, 0, 0, 0};
  _signal_report_enabled = true;
}

void KissModem::begin() {
  _rx_len = 0;
  _rx_escaped = false;
  _rx_active = false;
  _has_pending_tx = false;
  _tx_state = TX_IDLE;
}

void KissModem::writeByte(uint8_t b) {
  if (b == KISS_FEND) {
    _serial.write(KISS_FESC);
    _serial.write(KISS_TFEND);
  } else if (b == KISS_FESC) {
    _serial.write(KISS_FESC);
    _serial.write(KISS_TFESC);
  } else {
    _serial.write(b);
  }
}

void KissModem::writeFrame(uint8_t type, const uint8_t* data, uint16_t len) {
  _serial.write(KISS_FEND);
  writeByte(type);
  for (uint16_t i = 0; i < len; i++) {
    writeByte(data[i]);
  }
  _serial.write(KISS_FEND);
}

void KissModem::writeHardwareFrame(uint8_t sub_cmd, const uint8_t* data, uint16_t len) {
  _serial.write(KISS_FEND);
  writeByte(KISS_CMD_SETHARDWARE);
  writeByte(sub_cmd);
  for (uint16_t i = 0; i < len; i++) {
    writeByte(data[i]);
  }
  _serial.write(KISS_FEND);
}

void KissModem::writeHardwareError(uint8_t error_code) {
  writeHardwareFrame(HW_RESP_ERROR, &error_code, 1);
}

void KissModem::loop() {
  while (_serial.available()) {
    uint8_t b = _serial.read();

    if (b == KISS_FEND) {
      if (_rx_active && _rx_len > 0) {
        processFrame();
      }
      _rx_len = 0;
      _rx_escaped = false;
      _rx_active = true;
      continue;
    }

    if (!_rx_active) continue;

    if (b == KISS_FESC) {
      _rx_escaped = true;
      continue;
    }

    if (_rx_escaped) {
      _rx_escaped = false;
      if (b == KISS_TFEND) b = KISS_FEND;
      else if (b == KISS_TFESC) b = KISS_FESC;
      else continue;
    }

    if (_rx_len < KISS_MAX_FRAME_SIZE) {
      _rx_buf[_rx_len++] = b;
    } else {
      /* Buffer full with no FEND; reset so we don't stay stuck ignoring input. */
      _rx_len = 0;
      _rx_escaped = false;
      _rx_active = false;
    }
  }

  processTx();
}

void KissModem::processFrame() {
  if (_rx_len < 1) return;

  uint8_t type_byte = _rx_buf[0];

  if (type_byte == KISS_CMD_RETURN) return;

  uint8_t port = (type_byte >> 4) & 0x0F;
  uint8_t cmd = type_byte & 0x0F;

  if (port != 0) return;

  const uint8_t* data = &_rx_buf[1];
  uint16_t data_len = _rx_len - 1;

  switch (cmd) {
    case KISS_CMD_DATA:
      if (data_len > 0 && data_len <= KISS_MAX_PACKET_SIZE && !_has_pending_tx) {
        memcpy(_pending_tx, data, data_len);
        _pending_tx_len = data_len;
        _has_pending_tx = true;
      }
      break;

    case KISS_CMD_TXDELAY:
      if (data_len >= 1) _txdelay = data[0];
      break;

    case KISS_CMD_PERSISTENCE:
      if (data_len >= 1) _persistence = data[0];
      break;

    case KISS_CMD_SLOTTIME:
      if (data_len >= 1) _slottime = data[0];
      break;

    case KISS_CMD_TXTAIL:
      if (data_len >= 1) _txtail = data[0];
      break;

    case KISS_CMD_FULLDUPLEX:
      if (data_len >= 1) _fullduplex = data[0];
      break;

    case KISS_CMD_SETHARDWARE:
      if (data_len >= 1) {
        handleHardwareCommand(data[0], data + 1, data_len - 1);
      }
      break;

    default:
      break;
  }
}

void KissModem::handleHardwareCommand(uint8_t sub_cmd, const uint8_t* data, uint16_t len) {
  switch (sub_cmd) {
    case HW_CMD_GET_IDENTITY:
      handleGetIdentity();
      break;
    case HW_CMD_GET_RANDOM:
      handleGetRandom(data, len);
      break;
    case HW_CMD_VERIFY_SIGNATURE:
      handleVerifySignature(data, len);
      break;
    case HW_CMD_SIGN_DATA:
      handleSignData(data, len);
      break;
    case HW_CMD_ENCRYPT_DATA:
      handleEncryptData(data, len);
      break;
    case HW_CMD_DECRYPT_DATA:
      handleDecryptData(data, len);
      break;
    case HW_CMD_KEY_EXCHANGE:
      handleKeyExchange(data, len);
      break;
    case HW_CMD_HASH:
      handleHash(data, len);
      break;
    case HW_CMD_SET_RADIO:
      handleSetRadio(data, len);
      break;
    case HW_CMD_SET_TX_POWER:
      handleSetTxPower(data, len);
      break;
    case HW_CMD_GET_RADIO:
      handleGetRadio();
      break;
    case HW_CMD_GET_TX_POWER:
      handleGetTxPower();
      break;
    case HW_CMD_GET_VERSION:
      handleGetVersion();
      break;
    case HW_CMD_GET_CURRENT_RSSI:
      handleGetCurrentRssi();
      break;
    case HW_CMD_IS_CHANNEL_BUSY:
      handleIsChannelBusy();
      break;
    case HW_CMD_GET_AIRTIME:
      handleGetAirtime(data, len);
      break;
    case HW_CMD_GET_NOISE_FLOOR:
      handleGetNoiseFloor();
      break;
    case HW_CMD_GET_STATS:
      handleGetStats();
      break;
    case HW_CMD_GET_BATTERY:
      handleGetBattery();
      break;
    case HW_CMD_PING:
      handlePing();
      break;
    case HW_CMD_GET_SENSORS:
      handleGetSensors(data, len);
      break;
    case HW_CMD_GET_MCU_TEMP:
      handleGetMCUTemp();
      break;
    case HW_CMD_REBOOT:
      handleReboot();
      break;
    case HW_CMD_GET_DEVICE_NAME:
      handleGetDeviceName();
      break;
    case HW_CMD_SET_SIGNAL_REPORT:
      handleSetSignalReport(data, len);
      break;
    case HW_CMD_GET_SIGNAL_REPORT:
      handleGetSignalReport();
      break;
    default:
      writeHardwareError(HW_ERR_UNKNOWN_CMD);
      break;
  }
}

void KissModem::processTx() {
  switch (_tx_state) {
    case TX_IDLE:
      if (_has_pending_tx) {
        if (_fullduplex) {
          _tx_timer = millis();
          _tx_state = TX_DELAY;
        } else {
          _tx_state = TX_WAIT_CLEAR;
        }
      }
      break;

    case TX_WAIT_CLEAR:
      if (!_radio.isReceiving()) {
        uint8_t rand_val;
        _rng.random(&rand_val, 1);
        if (rand_val <= _persistence) {
          _tx_timer = millis();
          _tx_state = TX_DELAY;
        } else {
          _tx_timer = millis();
          _tx_state = TX_SLOT_WAIT;
        }
      }
      break;

    case TX_SLOT_WAIT:
      if (millis() - _tx_timer >= (uint32_t)_slottime * 10) {
        _tx_state = TX_WAIT_CLEAR;
      }
      break;

    case TX_DELAY:
      if (millis() - _tx_timer >= (uint32_t)_txdelay * 10) {
        if (_sendPacketCallback) {
          _sendPacketCallback(_pending_tx, _pending_tx_len);
          _tx_state = TX_SENDING;
        } else {
          _has_pending_tx = false;
          _tx_state = TX_IDLE;
        }
      }
      break;

    case TX_SENDING:
      if (_isSendCompleteCallback && _isSendCompleteCallback()) {
        if (_onSendFinishedCallback) _onSendFinishedCallback();
        uint8_t result = 0x01;
        writeHardwareFrame(HW_RESP_TX_DONE, &result, 1);
        _has_pending_tx = false;
        _tx_state = TX_IDLE;
      }
      break;
  }
}

void KissModem::onPacketReceived(int8_t snr, int8_t rssi, const uint8_t* packet, uint16_t len) {
  writeFrame(KISS_CMD_DATA, packet, len);
  if (_signal_report_enabled) {
    uint8_t meta[2] = { (uint8_t)snr, (uint8_t)rssi };
    writeHardwareFrame(HW_RESP_RX_META, meta, 2);
  }
}

void KissModem::handleGetIdentity() {
  writeHardwareFrame(HW_RESP_IDENTITY, _identity.pub_key, PUB_KEY_SIZE);
}

void KissModem::handleGetRandom(const uint8_t* data, uint16_t len) {
  if (len < 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }

  uint8_t requested = data[0];
  if (requested < 1 || requested > 64) {
    writeHardwareError(HW_ERR_INVALID_PARAM);
    return;
  }

  uint8_t buf[64];
  _rng.random(buf, requested);
  writeHardwareFrame(HW_RESP_RANDOM, buf, requested);
}

void KissModem::handleVerifySignature(const uint8_t* data, uint16_t len) {
  if (len < PUB_KEY_SIZE + SIGNATURE_SIZE + 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }

  mesh::Identity signer(data);
  const uint8_t* signature = data + PUB_KEY_SIZE;
  const uint8_t* msg = data + PUB_KEY_SIZE + SIGNATURE_SIZE;
  uint16_t msg_len = len - PUB_KEY_SIZE - SIGNATURE_SIZE;

  uint8_t result = signer.verify(signature, msg, msg_len) ? 0x01 : 0x00;
  writeHardwareFrame(HW_RESP_VERIFY, &result, 1);
}

void KissModem::handleSignData(const uint8_t* data, uint16_t len) {
  if (len < 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }

  uint8_t signature[SIGNATURE_SIZE];
  _identity.sign(signature, data, len);
  writeHardwareFrame(HW_RESP_SIGNATURE, signature, SIGNATURE_SIZE);
}

void KissModem::handleEncryptData(const uint8_t* data, uint16_t len) {
  if (len < PUB_KEY_SIZE + 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }

  const uint8_t* key = data;
  const uint8_t* plaintext = data + PUB_KEY_SIZE;
  uint16_t plaintext_len = len - PUB_KEY_SIZE;

  uint8_t buf[KISS_MAX_FRAME_SIZE];
  int encrypted_len = mesh::Utils::encryptThenMAC(key, buf, plaintext, plaintext_len);

  if (encrypted_len > 0) {
    writeHardwareFrame(HW_RESP_ENCRYPTED, buf, encrypted_len);
  } else {
    writeHardwareError(HW_ERR_ENCRYPT_FAILED);
  }
}

void KissModem::handleDecryptData(const uint8_t* data, uint16_t len) {
  if (len < PUB_KEY_SIZE + CIPHER_MAC_SIZE + 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }

  const uint8_t* key = data;
  const uint8_t* ciphertext = data + PUB_KEY_SIZE;
  uint16_t ciphertext_len = len - PUB_KEY_SIZE;

  uint8_t buf[KISS_MAX_FRAME_SIZE];
  int decrypted_len = mesh::Utils::MACThenDecrypt(key, buf, ciphertext, ciphertext_len);

  if (decrypted_len > 0) {
    writeHardwareFrame(HW_RESP_DECRYPTED, buf, decrypted_len);
  } else {
    writeHardwareError(HW_ERR_MAC_FAILED);
  }
}

void KissModem::handleKeyExchange(const uint8_t* data, uint16_t len) {
  if (len < PUB_KEY_SIZE) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }

  uint8_t shared_secret[PUB_KEY_SIZE];
  _identity.calcSharedSecret(shared_secret, data);
  writeHardwareFrame(HW_RESP_SHARED_SECRET, shared_secret, PUB_KEY_SIZE);
}

void KissModem::handleHash(const uint8_t* data, uint16_t len) {
  if (len < 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }

  uint8_t hash[32];
  mesh::Utils::sha256(hash, 32, data, len);
  writeHardwareFrame(HW_RESP_HASH, hash, 32);
}

void KissModem::handleSetRadio(const uint8_t* data, uint16_t len) {
  if (len < 10) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }
  if (!_setRadioCallback) {
    writeHardwareError(HW_ERR_NO_CALLBACK);
    return;
  }

  uint32_t freq_hz, bw_hz;
  memcpy(&freq_hz, data, 4);
  memcpy(&bw_hz, data + 4, 4);
  uint8_t sf = data[8];
  uint8_t cr = data[9];

  _config.freq_hz = freq_hz;
  _config.bw_hz = bw_hz;
  _config.sf = sf;
  _config.cr = cr;

  float freq = freq_hz / 1000000.0f;
  float bw = bw_hz / 1000.0f;

  _setRadioCallback(freq, bw, sf, cr);
  writeHardwareFrame(HW_RESP_OK, nullptr, 0);
}

void KissModem::handleSetTxPower(const uint8_t* data, uint16_t len) {
  if (len < 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }
  if (!_setTxPowerCallback) {
    writeHardwareError(HW_ERR_NO_CALLBACK);
    return;
  }

  _config.tx_power = data[0];
  _setTxPowerCallback(data[0]);
  writeHardwareFrame(HW_RESP_OK, nullptr, 0);
}

void KissModem::handleGetRadio() {
  uint8_t buf[10];
  memcpy(buf, &_config.freq_hz, 4);
  memcpy(buf + 4, &_config.bw_hz, 4);
  buf[8] = _config.sf;
  buf[9] = _config.cr;
  writeHardwareFrame(HW_RESP_RADIO, buf, 10);
}

void KissModem::handleGetTxPower() {
  writeHardwareFrame(HW_RESP_TX_POWER, &_config.tx_power, 1);
}

void KissModem::handleGetVersion() {
  uint8_t buf[2];
  buf[0] = KISS_FIRMWARE_VERSION;
  buf[1] = 0;
  writeHardwareFrame(HW_RESP_VERSION, buf, 2);
}

void KissModem::handleGetCurrentRssi() {
  if (!_getCurrentRssiCallback) {
    writeHardwareError(HW_ERR_NO_CALLBACK);
    return;
  }

  float rssi = _getCurrentRssiCallback();
  int8_t rssi_byte = (int8_t)rssi;
  writeHardwareFrame(HW_RESP_CURRENT_RSSI, (uint8_t*)&rssi_byte, 1);
}

void KissModem::handleIsChannelBusy() {
  uint8_t busy = _radio.isReceiving() ? 0x01 : 0x00;
  writeHardwareFrame(HW_RESP_CHANNEL_BUSY, &busy, 1);
}

void KissModem::handleGetAirtime(const uint8_t* data, uint16_t len) {
  if (len < 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }

  uint8_t packet_len = data[0];
  uint32_t airtime = _radio.getEstAirtimeFor(packet_len);
  writeHardwareFrame(HW_RESP_AIRTIME, (uint8_t*)&airtime, 4);
}

void KissModem::handleGetNoiseFloor() {
  int16_t noise_floor = _radio.getNoiseFloor();
  writeHardwareFrame(HW_RESP_NOISE_FLOOR, (uint8_t*)&noise_floor, 2);
}

void KissModem::handleGetStats() {
  if (!_getStatsCallback) {
    writeHardwareError(HW_ERR_NO_CALLBACK);
    return;
  }

  uint32_t rx, tx, errors;
  _getStatsCallback(&rx, &tx, &errors);
  uint8_t buf[12];
  memcpy(buf, &rx, 4);
  memcpy(buf + 4, &tx, 4);
  memcpy(buf + 8, &errors, 4);
  writeHardwareFrame(HW_RESP_STATS, buf, 12);
}

void KissModem::handleGetBattery() {
  uint16_t mv = _board.getBattMilliVolts();
  writeHardwareFrame(HW_RESP_BATTERY, (uint8_t*)&mv, 2);
}

void KissModem::handlePing() {
  writeHardwareFrame(HW_RESP_PONG, nullptr, 0);
}

void KissModem::handleGetSensors(const uint8_t* data, uint16_t len) {
  if (len < 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }

  uint8_t permissions = data[0];
  CayenneLPP telemetry(255);
  if (_sensors.querySensors(permissions, telemetry)) {
    writeHardwareFrame(HW_RESP_SENSORS, telemetry.getBuffer(), telemetry.getSize());
  } else {
    writeHardwareFrame(HW_RESP_SENSORS, nullptr, 0);
  }
}

void KissModem::handleGetMCUTemp() {
  float temp = _board.getMCUTemperature();
  if (isnan(temp)) {
    writeHardwareError(HW_ERR_NO_CALLBACK);
    return;
  }
  int16_t temp_tenths = (int16_t)(temp * 10.0f);
  writeHardwareFrame(HW_RESP_MCU_TEMP, (uint8_t*)&temp_tenths, 2);
}

void KissModem::handleReboot() {
  writeHardwareFrame(HW_RESP_OK, nullptr, 0);
  _serial.flush();
  delay(50);
  _board.reboot();
}

void KissModem::handleGetDeviceName() {
  const char* name = _board.getManufacturerName();
  writeHardwareFrame(HW_RESP_DEVICE_NAME, (const uint8_t*)name, strlen(name));
}

void KissModem::handleSetSignalReport(const uint8_t* data, uint16_t len) {
  if (len < 1) {
    writeHardwareError(HW_ERR_INVALID_LENGTH);
    return;
  }
  _signal_report_enabled = (data[0] != 0x00);
  uint8_t val = _signal_report_enabled ? 0x01 : 0x00;
  writeHardwareFrame(HW_RESP_SIGNAL_REPORT, &val, 1);
}

void KissModem::handleGetSignalReport() {
  uint8_t val = _signal_report_enabled ? 0x01 : 0x00;
  writeHardwareFrame(HW_RESP_SIGNAL_REPORT, &val, 1);
}