mh
/
espurna-mirror
mirror of https://github.com/xoseperez/espurna


								/*


								SYSTEM MODULE


								Copyright (C) 2018 by Xose Pérez <xose dot perez at gmail dot com>


								*/


								#include <EEPROM_Rotate.h>


								// -----------------------------------------------------------------------------


								unsigned long _loop_delay = 0;

								bool _system_send_heartbeat = false;


								// Calculated load average 0 to 100;

								unsigned short int _load_average = 100;


								// -----------------------------------------------------------------------------


								#if SYSTEM_CHECK_ENABLED


								// Call this method on boot with start=true to increase the crash counter

								// Call it again once the system is stable to decrease the counter

								// If the counter reaches SYSTEM_CHECK_MAX then the system is flagged as unstable

								// setting _systemOK = false;

								//

								// An unstable system will only have serial access, WiFi in AP mode and OTA


								bool _systemStable = true;


								void systemCheck(bool stable) {

								    unsigned char value = EEPROMr.read(EEPROM_CRASH_COUNTER);

								    if (stable) {

								        value = 0;

								        DEBUG_MSG_P(PSTR("[MAIN] System OK\n"));

								    } else {

								        if (++value > SYSTEM_CHECK_MAX) {

								            _systemStable = false;

								            value = 0;

								            DEBUG_MSG_P(PSTR("[MAIN] System UNSTABLE\n"));

								        }

								    }

								    EEPROMr.write(EEPROM_CRASH_COUNTER, value);

								    EEPROMr.commit();

								}


								bool systemCheck() {

								    return _systemStable;

								}


								void systemCheckLoop() {

								    static bool checked = false;

								    if (!checked && (millis() > SYSTEM_CHECK_TIME)) {

								        // Check system as stable

								        systemCheck(true);

								        checked = true;

								    }

								}


								#endif


								// -----------------------------------------------------------------------------


								void systemSendHeartbeat() {

								    _system_send_heartbeat = true;

								}


								unsigned long systemLoopDelay() {

								    return _loop_delay;

								}


								unsigned long systemLoadAverage() {

								    return _load_average;

								}


								void systemLoop() {


								    // -------------------------------------------------------------------------

								    // Check system stability

								    // -------------------------------------------------------------------------


								    #if SYSTEM_CHECK_ENABLED

								        systemCheckLoop();

								    #endif


								    // -------------------------------------------------------------------------

								    // Heartbeat

								    // -------------------------------------------------------------------------


								    #if HEARTBEAT_MODE == HEARTBEAT_ONCE

								        if (_system_send_heartbeat) {

								            _system_send_heartbeat = false;

								            heartbeat();

								        }

								    #elif HEARTBEAT_MODE == HEARTBEAT_REPEAT

								        static unsigned long last_hbeat = 0;

								        if (_system_send_heartbeat || (last_hbeat == 0) || (millis() - last_hbeat > HEARTBEAT_INTERVAL)) {

								            _system_send_heartbeat = false;

								            last_hbeat = millis();

								            heartbeat();

								        }

								    #endif // HEARTBEAT_MODE == HEARTBEAT_REPEAT


								    // -------------------------------------------------------------------------

								    // Load Average calculation

								    // -------------------------------------------------------------------------


								    static unsigned long last_loadcheck = 0;

								    static unsigned long load_counter_temp = 0;

								    load_counter_temp++;


								    if (millis() - last_loadcheck > LOADAVG_INTERVAL) {


								        static unsigned long load_counter = 0;

								        static unsigned long load_counter_max = 1;


								        load_counter = load_counter_temp;

								        load_counter_temp = 0;

								        if (load_counter > load_counter_max) {

								            load_counter_max = load_counter;

								        }

								        _load_average = 100 - (100 * load_counter / load_counter_max);

								        last_loadcheck = millis();


								    }


								    // -------------------------------------------------------------------------

								    // Power saving delay

								    // -------------------------------------------------------------------------


								    delay(_loop_delay);


								}


								void _systemSetupSpecificHardware() {


								    //The ESPLive has an ADC MUX which needs to be configured.

								    #if defined(MANCAVEMADE_ESPLIVE)

								        pinMode(16, OUTPUT);

								        digitalWrite(16, HIGH); //Defualt CT input (pin B, solder jumper B)

								    #endif


								    // These devices use the hardware UART

								    // to communicate to secondary microcontrollers

								    #if defined(ITEAD_SONOFF_RFBRIDGE) || defined(ITEAD_SONOFF_DUAL) || (RELAY_PROVIDER == RELAY_PROVIDER_STM)

								        Serial.begin(SERIAL_BAUDRATE);

								    #endif


								}


								void systemSetup() {


								    #if SPIFFS_SUPPORT

								        SPIFFS.begin();

								    #endif


								    // Question system stability

								    #if SYSTEM_CHECK_ENABLED

								        systemCheck(false);

								    #endif


								    // Init device-specific hardware

								    _systemSetupSpecificHardware();


								    // Cache loop delay value to speed things (recommended max 250ms)

								    _loop_delay = atol(getSetting("loopDelay", LOOP_DELAY_TIME).c_str());

								    _loop_delay = constrain(_loop_delay, 0, 300);


								    // Register Loop

								    espurnaRegisterLoop(systemLoop);


								}