ESP32-PaxCounter/src/lorawan.cpp

// Basic Config
#include "lorawan.h"

// Local logging Tag
static const char TAG[] = "lora";

#ifdef HAS_LORA

#if CLOCK_ERROR_PROCENTAGE > 7
#warning CLOCK_ERROR_PROCENTAGE value in lmic_config.h is too high; values > 7 will cause side effects
#endif

osjob_t sendjob;
QueueHandle_t LoraSendQueue;

class MyHalConfig_t : public Arduino_LMIC::HalConfiguration_t {

public:
  MyHalConfig_t(){};
  virtual void begin(void) override {
    SPI.begin(LORA_SCK, LORA_MISO, LORA_MOSI, LORA_CS);
  }
};

MyHalConfig_t myHalConfig{};

// LMIC pin mapping

const lmic_pinmap lmic_pins = {
    .nss = LORA_CS,
    .rxtx = LMIC_UNUSED_PIN,
    .rst = LORA_RST == NOT_A_PIN ? LMIC_UNUSED_PIN : LORA_RST,
    .dio = {LORA_IRQ, LORA_IO1,
            LORA_IO2 == NOT_A_PIN ? LMIC_UNUSED_PIN : LORA_IO2},
    // optional: set polarity of rxtx pin.
    .rxtx_rx_active = 0,
    // optional: set RSSI cal for listen-before-talk
    // this value is in dB, and is added to RSSI
    // measured prior to decision.
    // Must include noise guardband! Ignored in US,
    // EU, IN, other markets where LBT is not required.
    .rssi_cal = 0,
    // optional: override LMIC_SPI_FREQ if non-zero
    .spi_freq = 0,
    .pConfig = &myHalConfig};

// DevEUI generator using devices's MAC address
void gen_lora_deveui(uint8_t *pdeveui) {
  uint8_t *p = pdeveui, dmac[6];
  int i = 0;
  esp_efuse_mac_get_default(dmac);
  // deveui is LSB, we reverse it so TTN DEVEUI display
  // will remain the same as MAC address
  // MAC is 6 bytes, devEUI 8, set first 2 ones
  // with an arbitrary value
  *p++ = 0xFF;
  *p++ = 0xFE;
  // Then next 6 bytes are mac address reversed
  for (i = 0; i < 6; i++) {
    *p++ = dmac[5 - i];
  }
}

/* new version, does it with well formed mac according IEEE spec, but is
breaking change
// DevEUI generator using devices's MAC address
void gen_lora_deveui(uint8_t *pdeveui) {
  uint8_t *p = pdeveui, dmac[6];
  ESP_ERROR_CHECK(esp_efuse_mac_get_default(dmac));
  // deveui is LSB, we reverse it so TTN DEVEUI display
  // will remain the same as MAC address
  // MAC is 6 bytes, devEUI 8, set middle 2 ones
  // to an arbitrary value
  *p++ = dmac[5];
  *p++ = dmac[4];
  *p++ = dmac[3];
  *p++ = 0xfe;
  *p++ = 0xff;
  *p++ = dmac[2];
  *p++ = dmac[1];
  *p++ = dmac[0];
}
*/

// Function to do a byte swap in a byte array
void RevBytes(unsigned char *b, size_t c) {
  u1_t i;
  for (i = 0; i < c / 2; i++) {
    unsigned char t = b[i];
    b[i] = b[c - 1 - i];
    b[c - 1 - i] = t;
  }
}

// LMIC callback functions
void os_getDevKey(u1_t *buf) { memcpy(buf, APPKEY, 16); }

void os_getArtEui(u1_t *buf) {
  memcpy(buf, APPEUI, 8);
  RevBytes(buf, 8); // TTN requires it in LSB First order, so we swap bytes
}

void os_getDevEui(u1_t *buf) {
  int i = 0, k = 0;
  memcpy(buf, DEVEUI, 8); // get fixed DEVEUI from loraconf.h
  for (i = 0; i < 8; i++) {
    k += buf[i];
  }
  if (k) {
    RevBytes(buf, 8); // use fixed DEVEUI and swap bytes to LSB format
  } else {
    gen_lora_deveui(buf); // generate DEVEUI from device's MAC
  }

// Get MCP 24AA02E64 hardware DEVEUI (override default settings if found)
#ifdef MCP_24AA02E64_I2C_ADDRESS
  get_hard_deveui(buf);
  RevBytes(buf, 8); // swap bytes to LSB format
#endif
}

void get_hard_deveui(uint8_t *pdeveui) {
  // read DEVEUI from Microchip 24AA02E64 2Kb serial eeprom if present
#ifdef MCP_24AA02E64_I2C_ADDRESS

  uint8_t i2c_ret;

  // Init this just in case, no more to 100KHz
  Wire.begin(MY_OLED_SDA, MY_OLED_SCL, 100000);
  Wire.beginTransmission(MCP_24AA02E64_I2C_ADDRESS);
  Wire.write(MCP_24AA02E64_MAC_ADDRESS);
  i2c_ret = Wire.endTransmission();

  // check if device was seen on i2c bus
  if (i2c_ret == 0) {
    char deveui[32] = "";
    uint8_t data;

    Wire.beginTransmission(MCP_24AA02E64_I2C_ADDRESS);
    Wire.write(MCP_24AA02E64_MAC_ADDRESS);
    Wire.endTransmission();

    Wire.requestFrom(MCP_24AA02E64_I2C_ADDRESS, 8);
    while (Wire.available()) {
      data = Wire.read();
      sprintf(deveui + strlen(deveui), "%02X ", data);
      *pdeveui++ = data;
    }
    ESP_LOGI(TAG, "Serial EEPROM found, read DEVEUI %s", deveui);
  } else
    ESP_LOGI(TAG, "Could not read DEVEUI from serial EEPROM");

  // Set back to 400KHz to speed up OLED
  Wire.setClock(400000);
#endif // MCP 24AA02E64
}

#ifdef VERBOSE

// Display OTAA keys
void showLoraKeys(void) {
  // LMIC may not have used callback to fill
  // all EUI buffer so we do it here to a temp
  // buffer to be able to display them
  uint8_t buf[32];
  os_getDevEui((u1_t *)buf);
  printKey("DevEUI", buf, 8, true);
  os_getArtEui((u1_t *)buf);
  printKey("AppEUI", buf, 8, true);
  os_getDevKey((u1_t *)buf);
  printKey("AppKey", buf, 16, false);
}

#endif // VERBOSE

void onEvent(ev_t ev) {
  char buff[24] = "";
  switch (ev) {

  case EV_SCAN_TIMEOUT:
    strcpy_P(buff, PSTR("SCAN_TIMEOUT"));
    break;

  case EV_BEACON_FOUND:
    strcpy_P(buff, PSTR("BEACON_FOUND"));
    break;

  case EV_BEACON_MISSED:
    strcpy_P(buff, PSTR("BEACON_MISSED"));
    break;

  case EV_BEACON_TRACKED:
    strcpy_P(buff, PSTR("BEACON_TRACKED"));
    break;

  case EV_JOINING:
    strcpy_P(buff, PSTR("JOINING"));
    break;

  case EV_JOINED:
    strcpy_P(buff, PSTR("JOINED"));
    sprintf(display_line6, " "); // clear previous lmic status
    // set data rate adaptation according to saved setting
    LMIC_setAdrMode(cfg.adrmode);
    // set cyclic lmic link check to off if no ADR because is not supported by
    // ttn (but enabled by lmic after join)
    LMIC_setLinkCheckMode(cfg.adrmode);
    // Set data rate and transmit power (note: txpower seems to be ignored by
    // the library)
    switch_lora(cfg.lorasf, cfg.txpower);
    // kickoff first send job
    os_setCallback(&sendjob, lora_send);
    // show effective LoRa parameters after join
    ESP_LOGI(TAG, "ADR=%d, SF=%d, TXPOWER=%d", cfg.adrmode, cfg.lorasf,
             cfg.txpower);
    break;

  case EV_JOIN_FAILED:
    strcpy_P(buff, PSTR("JOIN_FAILED"));
    break;

  case EV_REJOIN_FAILED:
    strcpy_P(buff, PSTR("REJOIN_FAILED"));
    break;

  case EV_TXCOMPLETE:
    strcpy_P(buff, (LMIC.txrxFlags & TXRX_ACK) ? PSTR("RECEIVED_ACK")
                                               : PSTR("TX_COMPLETE"));
    sprintf(display_line6, " "); // clear previous lmic status

    if (LMIC.dataLen) {
      ESP_LOGI(TAG, "Received %d bytes of payload, RSSI -%d SNR %d",
               LMIC.dataLen, LMIC.rssi, LMIC.snr / 4);
      sprintf(display_line6, "RSSI -%d SNR %d", LMIC.rssi, LMIC.snr / 4);

      // check if command is received on command port, then call interpreter
      if ((LMIC.txrxFlags & TXRX_PORT) &&
          (LMIC.frame[LMIC.dataBeg - 1] == RCMDPORT))
        rcommand(LMIC.frame + LMIC.dataBeg, LMIC.dataLen);
    }
    break;

  case EV_LOST_TSYNC:
    strcpy_P(buff, PSTR("LOST_TSYNC"));
    break;

  case EV_RESET:
    strcpy_P(buff, PSTR("RESET"));
    break;

  case EV_RXCOMPLETE:
    // data received in ping slot
    strcpy_P(buff, PSTR("RX_COMPLETE"));
    break;

  case EV_LINK_DEAD:
    strcpy_P(buff, PSTR("LINK_DEAD"));
    break;

  case EV_LINK_ALIVE:
    strcpy_P(buff, PSTR("LINK_ALIVE"));
    break;

  case EV_TXSTART:
    if (!(LMIC.opmode & OP_JOINING))
      strcpy_P(buff, PSTR("TX_START"));
    break;

  case EV_SCAN_FOUND:
    strcpy_P(buff, PSTR("SCAN_FOUND"));
    break;

  case EV_RFU1:
    strcpy_P(buff, PSTR("RFU1"));
    break;

  default:
    sprintf_P(buff, PSTR("UNKNOWN_EVENT_%d"), ev);
    break;
  }

  // Log & Display if asked
  if (*buff) {
    ESP_LOGI(TAG, "EV_%s", buff);
    sprintf(display_line7, buff);
  }
}

// helper function to assign LoRa datarates to numeric spreadfactor values
void switch_lora(uint8_t sf, uint8_t tx) {
  if (tx > 20)
    return;
  cfg.txpower = tx;
  switch (sf) {
  case 7:
    LMIC_setDrTxpow(DR_SF7, tx);
    cfg.lorasf = sf;
    break;
  case 8:
    LMIC_setDrTxpow(DR_SF8, tx);
    cfg.lorasf = sf;
    break;
  case 9:
    LMIC_setDrTxpow(DR_SF9, tx);
    cfg.lorasf = sf;
    break;
  case 10:
    LMIC_setDrTxpow(DR_SF10, tx);
    cfg.lorasf = sf;
    break;
  case 11:
#if defined(CFG_us915)
    LMIC_setDrTxpow(DR_SF11CR, tx);
    cfg.lorasf = sf;
    break;
#else
    LMIC_setDrTxpow(DR_SF11, tx);
    cfg.lorasf = sf;
    break;
#endif
  case 12:
#if defined(CFG_us915)
    LMIC_setDrTxpow(DR_SF12CR, tx);
    cfg.lorasf = sf;
    break;
#else
    LMIC_setDrTxpow(DR_SF12, tx);
    cfg.lorasf = sf;
    break;
#endif
  default:
    break;
  }
}

void lora_send(osjob_t *job) {
  MessageBuffer_t SendBuffer;
  // Check if there is a pending TX/RX job running, if yes don't eat data
  // since it cannot be sent right now
  if ((LMIC.opmode & (OP_JOINING | OP_REJOIN | OP_TXDATA | OP_POLL)) != 0) {
    // waiting for LoRa getting ready
  } else {
    if (xQueueReceive(LoraSendQueue, &SendBuffer, (TickType_t)0) == pdTRUE) {
      // SendBuffer now filled with next payload from queue
      if (!LMIC_setTxData2(SendBuffer.MessagePort, SendBuffer.Message,
                           SendBuffer.MessageSize, (cfg.countermode & 0x02))) {
        ESP_LOGI(TAG, "%d byte(s) sent to LoRa", SendBuffer.MessageSize);
      } else {
        ESP_LOGE(TAG, "could not send %d byte(s) to LoRa",
                 SendBuffer.MessageSize);
      }
      // sprintf(display_line7, "PACKET QUEUED");
    }
  }
  // reschedule job every 0,5 - 1 sec. including a bit of random to prevent
  // systematic collisions
  os_setTimedCallback(job, os_getTime() + 500 + ms2osticks(random(500)),
                      lora_send);
}

#endif // HAS_LORA

esp_err_t lora_stack_init() {
#ifndef HAS_LORA
  return ESP_OK; // continue main program
#else
  assert(SEND_QUEUE_SIZE);
  LoraSendQueue = xQueueCreate(SEND_QUEUE_SIZE, sizeof(MessageBuffer_t));
  if (LoraSendQueue == 0) {
    ESP_LOGE(TAG, "Could not create LORA send queue. Aborting.");
    return ESP_FAIL;
  }
  ESP_LOGI(TAG, "LORA send queue created, size %d Bytes",
           SEND_QUEUE_SIZE * PAYLOAD_BUFFER_SIZE);

  ESP_LOGI(TAG, "Starting LMIC...");

  os_init();    // initialize lmic run-time environment on core 1
  LMIC_reset(); // initialize lmic MAC
  LMIC_setLinkCheckMode(0);
  // This tells LMIC to make the receive windows bigger, in case your clock is
  // faster or slower. This causes the transceiver to be earlier switched on,
  // so consuming more power. You may sharpen (reduce) CLOCK_ERROR_PERCENTAGE
  // in src/lmic_config.h if you are limited on battery.
  LMIC_setClockError(MAX_CLOCK_ERROR * CLOCK_ERROR_PROCENTAGE / 100);
  // Set the data rate to Spreading Factor 7.  This is the fastest supported
  // rate for 125 kHz channels, and it minimizes air time and battery power. Set
  // the transmission power to 14 dBi (25 mW).
  LMIC_setDrTxpow(DR_SF7, 14);

#if defined(CFG_US915) || defined(CFG_au921)
  // in the US, with TTN, it saves join time if we start on subband 1 (channels
  // 8-15). This will get overridden after the join by parameters from the
  // network. If working with other networks or in other regions, this will need
  // to be changed.
  LMIC_selectSubBand(1);
#endif

  if (!LMIC_startJoining()) { // start joining
    ESP_LOGI(TAG, "Already joined");
  }

  return ESP_OK; // continue main program
#endif // HAS_LORA
}

void lora_enqueuedata(MessageBuffer_t *message, sendprio_t prio) {
  // enqueue message in LORA send queue
#ifdef HAS_LORA
  BaseType_t ret;
  switch (prio) {
  case prio_high:
    ret = xQueueSendToFront(LoraSendQueue, (void *)message, (TickType_t)0);
    break;
  case prio_low:
  case prio_normal:
  default:
    ret = xQueueSendToBack(LoraSendQueue, (void *)message, (TickType_t)0);
    break;
  }
  if (ret == pdTRUE) {
    ESP_LOGI(TAG, "%d bytes enqueued for LORA interface", message->MessageSize);
  } else {
    ESP_LOGW(TAG, "LORA sendqueue is full");
  }
#endif
}

void lora_queuereset(void) {
#ifdef HAS_LORA
  xQueueReset(LoraSendQueue);
#endif
}

void lora_housekeeping(void) {
#ifdef HAS_LORA
// ESP_LOGD(TAG, "loraloop %d bytes left",
// uxTaskGetStackHighWaterMark(LoraTask));
#endif
}

void user_request_network_time_callback(void *pVoidUserUTCTime,
                                        int flagSuccess) {
#ifdef HAS_LORA
  // Explicit conversion from void* to uint32_t* to avoid compiler errors
  uint32_t *pUserUTCTime = (uint32_t *)pVoidUserUTCTime;
  lmic_time_reference_t lmicTimeReference;

  if (flagSuccess != 1) {
    ESP_LOGW(TAG, "LoRaWAN network did not answer time request");
    return;
  }

  // Populate lmic_time_reference
  flagSuccess = LMIC_getNetworkTimeReference(&lmicTimeReference);
  if (flagSuccess != 1) {
    ESP_LOGW(TAG, "LoRaWAN time request failed");
    return;
  }

  // Update userUTCTime, considering the difference between the GPS and UTC
  // time, and the leap seconds
  // !!! DANGER !!! This code will expire in next year with leap second
  *pUserUTCTime = lmicTimeReference.tNetwork + 315964800;
  // Current time, in ticks
  ostime_t ticksNow = os_getTime();
  // Time when the request was sent, in ticks
  ostime_t ticksRequestSent = lmicTimeReference.tLocal;
  // Add the delay between the instant the time was transmitted and
  // the current time
  uint32_t requestDelaySec = osticks2ms(ticksNow - ticksRequestSent) / 1000;
  *pUserUTCTime += requestDelaySec;

  // Update system time with time read from the network
  if (syncTime(*pUserUTCTime, lora)) { // do we have a valid time?
#ifdef HAS_RTC
    if (TimeIsSynced)
      set_rtctime(now()); // UTC time
#endif
    ESP_LOGI(TAG, "LORA has set the system time");
  } else
    ESP_LOGI(TAG, "Unable to sync system time with LORA");
#endif // HAS_LORA
} // user_request_network_time_callback