/* Copyright 2018 Oliver Brandmueller Copyright 2018 Klaus Wilting Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. NOTICE: Parts of the source files in this repository are made available under different licenses. Refer to LICENSE.txt file in repository for more details. */ // Basic Config #include "globals.h" // std::set for unified array functions #include // Does nothing and avoid any compilation error with I2C #include // LMIC-Arduino LoRaWAN Stack #include "loraconf.h" #include #include // ESP32 Functions #include // needed for Wifi event handler #include // needed for reading ESP32 chip attributes #include // needed for ESP_LOGx on arduino framework configData_t cfg; // struct holds current device configuration osjob_t sendjob, initjob; // LMIC // Initialize global variables char display_lora[16], display_lmic[16]; uint8_t channel = 0; int macnum = 0; uint64_t currentMillis = 0, previousLEDmillis = 0, previousDisplaymillis = 0; bool joinstate = false; uint8_t DisplayState, LEDState; uint16_t LEDBlinkduration = 500, LEDInterval = 1000, color = COLOR_NONE; std::set macs; // associative container holds total of unique MAC adress hashes (Wifi + BLE) std::set wifis; // associative container holds unique Wifi MAC adress hashes #ifdef BLECOUNTER std::set bles; // associative container holds unique BLE MAC adresses hashes int scanTime; #endif // this variable will be changed in the ISR, and read in main loop static volatile bool ButtonTriggered = false; // local Tag for logging static const char *TAG = "paxcnt"; // Note: Log level control seems not working during runtime, // so we need to switch loglevel by compiler build option in platformio.ini #ifndef VERBOSE int redirect_log(const char * fmt, va_list args) { //do nothing return 0; } #endif // defined in configmanager.cpp void eraseConfig(void); void saveConfig(void); void loadConfig(void); /* begin LMIC specific parts ------------------------------------------------------------ */ // defined in lorawan.cpp void gen_lora_deveui(uint8_t * pdeveui); void RevBytes(unsigned char* b, size_t c); void get_hard_deveui(uint8_t *pdeveui); #ifdef VERBOSE void printKeys(void); #endif // VERBOSE // 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 } // LMIC enhanced Pin mapping const lmic_pinmap lmic_pins = { .mosi = PIN_SPI_MOSI, .miso = PIN_SPI_MISO, .sck = PIN_SPI_SCK, .nss = PIN_SPI_SS, .rxtx = LMIC_UNUSED_PIN, .rst = RST, .dio = {DIO0, DIO1, DIO2} }; // LMIC functions void onEvent(ev_t ev); void do_send(osjob_t* j); // LoRaWAN Initjob static void lora_init (osjob_t* j) { // reset MAC state LMIC_reset(); // This tells LMIC to make the receive windows bigger, in case your clock is 1% faster or slower. LMIC_setClockError(MAX_CLOCK_ERROR * 1 / 100); // start joining LMIC_startJoining(); } // LMIC FreeRTos Task void lorawan_loop(void * pvParameters) { configASSERT( ( ( uint32_t ) pvParameters ) == 1 ); // FreeRTOS check while(1) { os_runloop_once(); // LED management for viusalizing LoRaWAN state if ( LMIC.opmode & (OP_JOINING | OP_REJOIN) ) { // quick blink 20ms on each 1/5 second color = COLOR_YELLOW; LEDBlinkduration = 20; LEDInterval = 200; LEDState = 1; // TX data pending } else if (LMIC.opmode & (OP_TXDATA | OP_TXRXPEND)) { // small blink 10ms on each 1/2sec (not when joining) color = COLOR_BLUE; LEDBlinkduration = 10; LEDInterval = 500; LEDState =1; // This should not happen so indicate a problem } else if ( LMIC.opmode & (OP_TXDATA | OP_TXRXPEND | OP_JOINING | OP_REJOIN) == 0 ) { // heartbeat long blink 200ms on each 2 seconds color = COLOR_RED; LEDBlinkduration = 200; LEDInterval = 2000; LEDState = 1; } else { // led off color = COLOR_NONE; LEDState = 0; } vTaskDelay(10/portTICK_PERIOD_MS); yield(); } } /* end LMIC specific parts --------------------------------------------------------------- */ /* beginn hardware specific parts -------------------------------------------------------- */ #ifdef HAS_DISPLAY HAS_DISPLAY u8x8(OLED_RST, OLED_SCL, OLED_SDA); #endif #ifdef HAS_ANTENNA_SWITCH // defined in antenna.cpp void antenna_init(); void antenna_select(const int8_t _ant); #endif #ifndef BLECOUNTER bool btstop = btStop(); #endif #ifdef HAS_BUTTON // Button Handling, board dependent -> perhaps to be moved to hal/<$board.h> // IRAM_ATTR necessary here, see https://github.com/espressif/arduino-esp32/issues/855 void IRAM_ATTR isr_button_pressed(void) { ButtonTriggered = true; } #endif /* end hardware specific parts -------------------------------------------------------- */ /* begin wifi specific parts ---------------------------------------------------------- */ // defined in wifisniffer.cpp void wifi_sniffer_init(void); void wifi_sniffer_set_channel(uint8_t channel); void wifi_sniffer_packet_handler(void *buff, wifi_promiscuous_pkt_type_t type); // defined in blescan.cpp void bt_loop(void *ignore); // Sniffer Task void sniffer_loop(void * pvParameters) { configASSERT( ( ( uint32_t ) pvParameters ) == 1 ); // FreeRTOS check channel=0; char buff[16]; int nloop=0, lorawait=0; while (true) { nloop++; // actual number of wifi loops, controls cycle when data is sent vTaskDelay(cfg.wifichancycle*10 / portTICK_PERIOD_MS); yield(); channel = (channel % WIFI_CHANNEL_MAX) + 1; // rotates variable channel 1..WIFI_CHANNEL_MAX wifi_sniffer_set_channel(channel); ESP_LOGD(TAG, "Wifi set channel %d", channel); // duration of one wifi scan loop reached? then send data and begin new scan cycle if ( nloop >= ( (100 / cfg.wifichancycle) * (cfg.wifiscancycle * 2)) +1 ) { nloop=0; channel=0; // reset wifi scan + channel loop counter do_send(&sendjob); // Prepare and execute LoRaWAN data upload vTaskDelay(500/portTICK_PERIOD_MS); yield(); // clear counter if not in cumulative counter mode if (cfg.countermode != 1) { macs.clear(); // clear all macs container wifis.clear(); // clear Wifi macs couner #ifdef BLECOUNTER bles.clear(); // clear BLE macs counter #endif salt_reset(); // get new salt for salting hashes } // check if payload is sent lorawait = 0; while(LMIC.opmode & OP_TXRXPEND) { if(!lorawait) sprintf(display_lora, "LoRa wait"); lorawait++; // in case sending really fails: reset and rejoin network if( (lorawait % MAXLORARETRY ) == 0) { ESP_LOGI(TAG, "Payload not sent, trying reset and rejoin"); esp_restart(); }; vTaskDelay(1000/portTICK_PERIOD_MS); yield(); } sprintf(display_lora, " "); // clear LoRa wait message fromd display } // end of send data cycle } // end of infinite wifi channel rotation loop } /* end wifi specific parts ------------------------------------------------------------ */ // uptime counter 64bit to prevent millis() rollover after 49 days uint64_t uptime() { static uint32_t low32, high32; uint32_t new_low32 = millis(); if (new_low32 < low32) high32++; low32 = new_low32; return (uint64_t) high32 << 32 | low32; } #ifdef HAS_DISPLAY // Print a key on display void DisplayKey(const uint8_t * key, uint8_t len, bool lsb) { uint8_t start=lsb?len:0; uint8_t end = lsb?0:len; const uint8_t * p ; for (uint8_t i=0; i= ( 1 / DISPLAYFPS * (1000/portTICK_PERIOD_MS))) { refreshDisplay(); previousDisplaymillis += ( 1 / DISPLAYFPS * (1000/portTICK_PERIOD_MS)); } // set display on/off according to current device configuration if (DisplayState != cfg.screenon) { DisplayState = cfg.screenon; u8x8.setPowerSave(!cfg.screenon); } } // updateDisplay() #endif // HAS_DISPLAY #ifdef HAS_BUTTON void readButton() { if (ButtonTriggered) { ButtonTriggered = false; ESP_LOGI(TAG, "Button pressed, resetting device to factory defaults"); eraseConfig(); esp_restart(); } } #endif #ifdef HAS_LED void updateLEDstatus() { if (LEDState == LOW) { if (currentMillis - previousLEDmillis >= LEDInterval) { LEDState = HIGH; previousLEDmillis += LEDInterval; } } else { if (currentMillis - previousLEDmillis >= LEDBlinkduration) { LEDState = LOW; previousLEDmillis += LEDBlinkduration; } } }; // updateLEDstatus() void refreshLED() { static bool previousLEDState; // led need to change state? avoid digitalWrite() for nothing if (LEDState != previousLEDState) { #ifdef LED_ACTIVE_LOW digitalWrite(HAS_LED, LEDState); #else digitalWrite(HAS_LED, !LEDState); #endif #ifdef HAS_RGB_LED rgb_set_color(color); #endif previousLEDState = LEDState; } }; // refreshLED() #endif /* begin Aruino SETUP ------------------------------------------------------------ */ void setup() { // disable brownout detection #ifdef DISABLE_BROWNOUT // register with brownout is at address DR_REG_RTCCNTL_BASE + 0xd4 (*((volatile uint32_t *)ETS_UNCACHED_ADDR((DR_REG_RTCCNTL_BASE+0xd4)))) = 0; #endif // setup debug output or silence device #ifdef VERBOSE Serial.begin(115200); esp_log_level_set("*", ESP_LOG_VERBOSE); #else // mute logs completely by redirecting them to silence function esp_log_level_set("*", ESP_LOG_NONE); esp_log_set_vprintf(redirect_log); #endif ESP_LOGI(TAG, "Starting %s %s", PROGNAME, PROGVERSION); rgb_set_color(COLOR_NONE); // initialize system event handler for wifi task, needed for wifi_sniffer_init() esp_event_loop_init(NULL, NULL); // print chip information on startup if in verbose mode #ifdef VERBOSE esp_chip_info_t chip_info; esp_chip_info(&chip_info); ESP_LOGI(TAG, "This is ESP32 chip with %d CPU cores, WiFi%s%s, silicon revision %d, %dMB %s Flash", chip_info.cores, (chip_info.features & CHIP_FEATURE_BT) ? "/BT" : "", (chip_info.features & CHIP_FEATURE_BLE) ? "/BLE" : "", chip_info.revision, spi_flash_get_chip_size() / (1024 * 1024), (chip_info.features & CHIP_FEATURE_EMB_FLASH) ? "embedded" : "external"); ESP_LOGI(TAG, "ESP32 SDK: %s", ESP.getSdkVersion()); #endif // read settings from NVRAM loadConfig(); // includes initialize if necessary // initialize led if needed #ifdef HAS_LED LEDState = 0; color = COLOR_NONE; pinMode(HAS_LED, OUTPUT); #ifdef LED_ACTIVE_LOW digitalWrite(HAS_LED, LEDState); #else digitalWrite(HAS_LED, !LEDState); #endif #ifdef HAS_RBG_LED rgb_set_color (color); #endif #endif // initialize button handling if needed #ifdef HAS_BUTTON #ifdef BUTTON_PULLUP // install button interrupt (pullup mode) pinMode(HAS_BUTTON, INPUT_PULLUP); attachInterrupt(digitalPinToInterrupt(HAS_BUTTON), isr_button_pressed, RISING); #else // install button interrupt (pulldown mode) pinMode(HAS_BUTTON, INPUT_PULLDOWN); attachInterrupt(digitalPinToInterrupt(HAS_BUTTON), isr_button_pressed, FALLING); #endif #endif // initialize wifi antenna if needed #ifdef HAS_ANTENNA_SWITCH antenna_init(); #endif #ifdef HAS_DISPLAY // initialize display init_display(PROGNAME, PROGVERSION); DisplayState = cfg.screenon; u8x8.setPowerSave(!cfg.screenon); // set display off if disabled u8x8.draw2x2String(0, 0, "PAX:0"); u8x8.setCursor(0,4); u8x8.printf("WIFI: 0"); #ifdef BLECOUNTER u8x8.setCursor(0,3); u8x8.printf("BLTH: 0"); #endif u8x8.setCursor(0,5); u8x8.printf(!cfg.rssilimit ? "RLIM: off" : "RLIM: %d", cfg.rssilimit); sprintf(display_lora, "Join wait"); #endif // output LoRaWAN keys to console #ifdef VERBOSE printKeys(); #endif os_init(); // setup LMIC os_setCallback(&initjob, lora_init); // setup initial job & join network wifi_sniffer_init(); // setup wifi in monitor mode and start MAC counting // initialize salt value using esp_random() called by random() in arduino-esp32 core // note: do this *after* wifi has started, since gets it's seed from RF noise salt_reset(); // get new 16bit for salting hashes // run wifi task on core 0 and lora task on core 1 and bt task on core 0 ESP_LOGI(TAG, "Starting Lora task on core 1"); xTaskCreatePinnedToCore(lorawan_loop, "loratask", 2048, ( void * ) 1, ( 5 | portPRIVILEGE_BIT ), NULL, 1); ESP_LOGI(TAG, "Starting Wifi task on core 0"); xTaskCreatePinnedToCore(sniffer_loop, "wifisniffer", 16384, ( void * ) 1, 1, NULL, 0); #ifdef BLECOUNTER if (cfg.blescan) { // start BLE task only if BLE function is enabled in NVRAM configuration ESP_LOGI(TAG, "Starting Bluetooth task on core 0"); xTaskCreatePinnedToCore(bt_loop, "btscan", 16384, NULL, 5, NULL, 0); } #endif // Finally: kickoff first sendjob and join, then send initial payload "0000" uint8_t mydata[] = "0000"; do_send(&sendjob); } /* end Aruino SETUP ------------------------------------------------------------ */ /* begin Aruino LOOP ------------------------------------------------------------ */ // Arduino main moop, runs on core 1 // https://techtutorialsx.com/2017/05/09/esp32-get-task-execution-core/ void loop() { // state machine for central control of all timimg based features currentMillis = uptime() / 1000; // count uptime seconds #ifdef HAS_BUTTON readButton(); #endif #ifdef HAS_DISPLAY updateDisplay(); #endif #ifdef HAS_LED updateLEDstatus(); refreshLED(); #endif //sendPayload(); } /* end Aruino LOOP ------------------------------------------------------------ */