Battery-Emulator/Software/Software.ino

/* Do not change any code below this line unless you are sure what you are doing */
/* Only change battery specific settings in "USER_SETTINGS.h" */
#include "HardwareSerial.h"
#include "USER_SECRETS.h"
#include "USER_SETTINGS.h"
#include "esp_system.h"
#include "esp_task_wdt.h"
#include "esp_timer.h"
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"

#include "src/communication/can/comm_can.h"
#include "src/communication/contactorcontrol/comm_contactorcontrol.h"
#include "src/communication/equipmentstopbutton/comm_equipmentstopbutton.h"
#include "src/communication/nvm/comm_nvm.h"
#include "src/communication/precharge_control/precharge_control.h"
#include "src/communication/rs485/comm_rs485.h"
#include "src/datalayer/datalayer.h"
#include "src/devboard/sdcard/sdcard.h"
#include "src/devboard/utils/events.h"
#include "src/devboard/utils/led_handler.h"
#include "src/devboard/utils/logging.h"
#include "src/devboard/utils/timer.h"
#include "src/devboard/utils/value_mapping.h"
#include "src/include.h"
#ifndef AP_PASSWORD
#error \
    "Initial setup not completed, USER_SECRETS.h is missing. Please rename the file USER_SECRETS.TEMPLATE.h to USER_SECRETS.h and fill in the required credentials. This file is ignored by version control to keep sensitive information private."
#endif
#ifdef WIFI
#include "src/devboard/wifi/wifi.h"
#ifdef WEBSERVER
#include "src/devboard/webserver/webserver.h"
#ifdef MDNSRESPONDER
#include <ESPmDNS.h>
#endif  // MDNSRESONDER
#else   // WEBSERVER
#ifdef MDNSRESPONDER
#error WEBSERVER needs to be enabled for MDNSRESPONDER!
#endif  // MDNSRSPONDER
#endif  // WEBSERVER
#ifdef MQTT
#include "src/devboard/mqtt/mqtt.h"
#endif  // MQTT
#endif  // WIFI
#ifdef PERIODIC_BMS_RESET_AT
#include "src/devboard/utils/ntp_time.h"
#endif
volatile unsigned long long bmsResetTimeOffset = 0;

// The current software version, shown on webserver
const char* version_number = "8.14.dev";

// Interval timers
volatile unsigned long currentMillis = 0;
unsigned long previousMillis10ms = 0;
unsigned long previousMillisUpdateVal = 0;
unsigned long lastMillisOverflowCheck = 0;
#ifdef FUNCTION_TIME_MEASUREMENT
// Task time measurement for debugging
MyTimer core_task_timer_10s(INTERVAL_10_S);
#endif
TaskHandle_t main_loop_task;
TaskHandle_t connectivity_loop_task;
TaskHandle_t logging_loop_task;
TaskHandle_t mqtt_loop_task;

Logging logging;

// Initialization
void setup() {
  init_serial();

  // We print this after setting up serial, such that is also printed to serial with DEBUG_VIA_USB set.
  logging.printf("Battery emulator %s build " __DATE__ " " __TIME__ "\n", version_number);

  init_events();

  init_stored_settings();

#ifdef WIFI
  xTaskCreatePinnedToCore((TaskFunction_t)&connectivity_loop, "connectivity_loop", 4096, NULL, TASK_CONNECTIVITY_PRIO,
                          &connectivity_loop_task, WIFI_CORE);
#endif

#if defined(LOG_CAN_TO_SD) || defined(LOG_TO_SD)
  xTaskCreatePinnedToCore((TaskFunction_t)&logging_loop, "logging_loop", 4096, NULL, TASK_CONNECTIVITY_PRIO,
                          &logging_loop_task, WIFI_CORE);
#endif

#ifdef MQTT
  xTaskCreatePinnedToCore((TaskFunction_t)&mqtt_loop, "mqtt_loop", 4096, NULL, TASK_MQTT_PRIO, &mqtt_loop_task,
                          WIFI_CORE);
#endif

  init_CAN();

  init_contactors();

#ifdef PRECHARGE_CONTROL
  init_precharge_control();
#endif  // PRECHARGE_CONTROL

  setup_charger();
  setup_inverter();
  setup_battery();

  init_rs485();

#ifdef EQUIPMENT_STOP_BUTTON
  init_equipment_stop_button();
#endif
#ifdef CAN_SHUNT_SELECTED
  setup_can_shunt();
#endif
  // BOOT button at runtime is used as an input for various things
  pinMode(0, INPUT_PULLUP);

  check_reset_reason();

  // Initialize Task Watchdog for subscribed tasks
  esp_task_wdt_config_t wdt_config = {
      .timeout_ms = INTERVAL_5_S,                                      // If task hangs for longer than this, reboot
      .idle_core_mask = (1 << CORE_FUNCTION_CORE) | (1 << WIFI_CORE),  // Watch both cores
      .trigger_panic = true                                            // Enable panic reset on timeout
  };

  // Start tasks
  xTaskCreatePinnedToCore((TaskFunction_t)&core_loop, "core_loop", 4096, NULL, TASK_CORE_PRIO, &main_loop_task,
                          CORE_FUNCTION_CORE);
#ifdef PERIODIC_BMS_RESET_AT
  bmsResetTimeOffset = getTimeOffsetfromNowUntil(PERIODIC_BMS_RESET_AT);
  if (bmsResetTimeOffset == 0) {
    set_event(EVENT_PERIODIC_BMS_RESET_AT_INIT_FAILED, 0);
  } else {
    set_event(EVENT_PERIODIC_BMS_RESET_AT_INIT_SUCCESS, 0);
  }
#endif
}

// Loop empty, all functionality runs in tasks
void loop() {}

#if defined(LOG_CAN_TO_SD) || defined(LOG_TO_SD)
void logging_loop(void*) {

  init_logging_buffers();
  init_sdcard();

  while (true) {
#ifdef LOG_TO_SD
    write_log_to_sdcard();
#endif
#ifdef LOG_CAN_TO_SD
    write_can_frame_to_sdcard();
#endif
  }
}
#endif

#ifdef WIFI
void connectivity_loop(void*) {
  esp_task_wdt_add(NULL);  // Register this task with WDT
  // Init wifi
  init_WiFi();

#ifdef WEBSERVER
  // Init webserver
  init_webserver();
#endif
#ifdef MDNSRESPONDER
  init_mDNS();
#endif

  while (true) {
    START_TIME_MEASUREMENT(wifi);
    wifi_monitor();
#ifdef WEBSERVER
    ota_monitor();
#endif
    END_TIME_MEASUREMENT_MAX(wifi, datalayer.system.status.wifi_task_10s_max_us);

    esp_task_wdt_reset();  // Reset watchdog
    delay(1);
  }
}
#endif

#ifdef MQTT
void mqtt_loop(void*) {
  esp_task_wdt_add(NULL);  // Register this task with WDT

  init_mqtt();

  while (true) {
    START_TIME_MEASUREMENT(mqtt);
    mqtt_loop();
    END_TIME_MEASUREMENT_MAX(mqtt, datalayer.system.status.mqtt_task_10s_max_us);
    esp_task_wdt_reset();  // Reset watchdog
    delay(1);
  }
}
#endif

void core_loop(void*) {
  esp_task_wdt_add(NULL);  // Register this task with WDT
  TickType_t xLastWakeTime = xTaskGetTickCount();
  const TickType_t xFrequency = pdMS_TO_TICKS(1);  // Convert 1ms to ticks
  led_init();

  while (true) {

    START_TIME_MEASUREMENT(all);
    START_TIME_MEASUREMENT(comm);
#ifdef EQUIPMENT_STOP_BUTTON
    monitor_equipment_stop_button();
#endif

    // Input, Runs as fast as possible
    receive_can();  // Receive CAN messages
#if defined(RS485_INVERTER_SELECTED) || defined(RS485_BATTERY_SELECTED)
    receive_RS485();  // Process serial2 RS485 interface
#endif                // RS485_INVERTER_SELECTED
    END_TIME_MEASUREMENT_MAX(comm, datalayer.system.status.time_comm_us);
#ifdef WEBSERVER
    START_TIME_MEASUREMENT(ota);
    ElegantOTA.loop();
    END_TIME_MEASUREMENT_MAX(ota, datalayer.system.status.time_ota_us);
#endif  // WEBSERVER

    // Process
    currentMillis = millis();
    if (currentMillis - previousMillis10ms >= INTERVAL_10_MS) {
      if ((currentMillis - previousMillis10ms >= INTERVAL_10_MS_DELAYED) && (currentMillis > BOOTUP_TIME)) {
        set_event(EVENT_TASK_OVERRUN, (currentMillis - previousMillis10ms));
      }
      previousMillis10ms = currentMillis;
#ifdef FUNCTION_TIME_MEASUREMENT
      START_TIME_MEASUREMENT(time_10ms);
#endif
      led_exe();
      handle_contactors();  // Take care of startup precharge/contactor closing
#ifdef PRECHARGE_CONTROL
      handle_precharge_control(currentMillis);
#endif  // PRECHARGE_CONTROL
#ifdef FUNCTION_TIME_MEASUREMENT
      END_TIME_MEASUREMENT_MAX(time_10ms, datalayer.system.status.time_10ms_us);
#endif
    }

    if (currentMillis - previousMillisUpdateVal >= INTERVAL_1_S) {
      previousMillisUpdateVal = currentMillis;  // Order matters on the update_loop!
#ifdef FUNCTION_TIME_MEASUREMENT
      START_TIME_MEASUREMENT(time_values);
#endif
      update_pause_state();     // Check if we are OK to send CAN or need to pause
      update_values_battery();  // Fetch battery values
#ifdef DOUBLE_BATTERY
      update_values_battery2();
      check_interconnect_available();
#endif  // DOUBLE_BATTERY
      update_calculated_values();
      update_machineryprotection();  // Check safeties
      update_values_inverter();      // Update values heading towards inverter
#ifdef FUNCTION_TIME_MEASUREMENT
      END_TIME_MEASUREMENT_MAX(time_values, datalayer.system.status.time_values_us);
#endif
    }
#ifdef FUNCTION_TIME_MEASUREMENT
    START_TIME_MEASUREMENT(cantx);
#endif
    // Output
    transmit_can(currentMillis);  // Send CAN messages to all components

#ifdef RS485_BATTERY_SELECTED
    transmit_rs485(currentMillis);
#endif  // RS485_BATTERY_SELECTED
#ifdef FUNCTION_TIME_MEASUREMENT
    END_TIME_MEASUREMENT_MAX(cantx, datalayer.system.status.time_cantx_us);
    END_TIME_MEASUREMENT_MAX(all, datalayer.system.status.core_task_10s_max_us);
#endif
#ifdef FUNCTION_TIME_MEASUREMENT
    if (datalayer.system.status.core_task_10s_max_us > datalayer.system.status.core_task_max_us) {
      // Update worst case total time
      datalayer.system.status.core_task_max_us = datalayer.system.status.core_task_10s_max_us;
      // Record snapshots of task times
      datalayer.system.status.time_snap_comm_us = datalayer.system.status.time_comm_us;
      datalayer.system.status.time_snap_10ms_us = datalayer.system.status.time_10ms_us;
      datalayer.system.status.time_snap_values_us = datalayer.system.status.time_values_us;
      datalayer.system.status.time_snap_cantx_us = datalayer.system.status.time_cantx_us;
      datalayer.system.status.time_snap_ota_us = datalayer.system.status.time_ota_us;
    }

    datalayer.system.status.core_task_max_us =
        MAX(datalayer.system.status.core_task_10s_max_us, datalayer.system.status.core_task_max_us);
    if (core_task_timer_10s.elapsed()) {
      datalayer.system.status.time_ota_us = 0;
      datalayer.system.status.time_comm_us = 0;
      datalayer.system.status.time_10ms_us = 0;
      datalayer.system.status.time_values_us = 0;
      datalayer.system.status.time_cantx_us = 0;
      datalayer.system.status.core_task_10s_max_us = 0;
      datalayer.system.status.wifi_task_10s_max_us = 0;
      datalayer.system.status.mqtt_task_10s_max_us = 0;
    }
#endif                     // FUNCTION_TIME_MEASUREMENT
    esp_task_wdt_reset();  // Reset watchdog to prevent reset
    vTaskDelayUntil(&xLastWakeTime, xFrequency);
  }
}

// Initialization functions
void init_serial() {
  // Init Serial monitor
  Serial.begin(115200);
  while (!Serial) {}
#ifdef DEBUG_VIA_USB
  Serial.println("__ OK __");
#endif  // DEBUG_VIA_USB
}

void check_interconnect_available() {
  if (datalayer.battery.status.voltage_dV == 0 || datalayer.battery2.status.voltage_dV == 0) {
    return;  // Both voltage values need to be available to start check
  }

  uint16_t voltage_diff = abs(datalayer.battery.status.voltage_dV - datalayer.battery2.status.voltage_dV);

  if (voltage_diff <= 30) {  // If we are within 3.0V between the batteries
    clear_event(EVENT_VOLTAGE_DIFFERENCE);
    if (datalayer.battery.status.bms_status == FAULT) {
      // If main battery is in fault state, disengage the second battery
      datalayer.system.status.battery2_allowed_contactor_closing = false;
    } else {  // If main battery is OK, allow second battery to join
      datalayer.system.status.battery2_allowed_contactor_closing = true;
    }
  } else {  //Voltage between the two packs is too large
    set_event(EVENT_VOLTAGE_DIFFERENCE, (uint8_t)(voltage_diff / 10));
  }
}

void update_calculated_values() {
  /* Update CPU temperature*/
  datalayer.system.info.CPU_temperature = temperatureRead();

  /* Calculate allowed charge/discharge currents*/
  if (datalayer.battery.status.voltage_dV > 10) {
    // Only update value when we have voltage available to avoid div0. TODO: This should be based on nominal voltage
    datalayer.battery.status.max_charge_current_dA =
        ((datalayer.battery.status.max_charge_power_W * 100) / datalayer.battery.status.voltage_dV);
    datalayer.battery.status.max_discharge_current_dA =
        ((datalayer.battery.status.max_discharge_power_W * 100) / datalayer.battery.status.voltage_dV);
  }
  /* Restrict values from user settings if needed*/
  if (datalayer.battery.status.max_charge_current_dA > datalayer.battery.settings.max_user_set_charge_dA) {
    datalayer.battery.status.max_charge_current_dA = datalayer.battery.settings.max_user_set_charge_dA;
    datalayer.battery.settings.user_settings_limit_charge = true;
  } else {
    datalayer.battery.settings.user_settings_limit_charge = false;
  }
  if (datalayer.battery.status.max_discharge_current_dA > datalayer.battery.settings.max_user_set_discharge_dA) {
    datalayer.battery.status.max_discharge_current_dA = datalayer.battery.settings.max_user_set_discharge_dA;
    datalayer.battery.settings.user_settings_limit_discharge = true;
  } else {
    datalayer.battery.settings.user_settings_limit_discharge = false;
  }
  /* Calculate active power based on voltage and current*/
  datalayer.battery.status.active_power_W =
      (datalayer.battery.status.current_dA * (datalayer.battery.status.voltage_dV / 100));
  /* Calculate if battery or inverter is limiting factor*/

  if (datalayer.battery.status.current_dA == 0) {  //Battery idle
    if (datalayer.battery.status.max_discharge_current_dA > 0) {
      //We allow discharge, but inverter does nothing. Inverter is limiting
      datalayer.battery.settings.inverter_limits_discharge = true;
    } else {
      datalayer.battery.settings.inverter_limits_discharge = false;
    }
    if (datalayer.battery.status.max_charge_current_dA > 0) {
      //We allow charge, but inverter does nothing. Inverter is limiting
      datalayer.battery.settings.inverter_limits_charge = true;
    } else {
      datalayer.battery.settings.inverter_limits_charge = false;
    }
  } else if (datalayer.battery.status.current_dA < 0) {  //Battery discharging
    if (-datalayer.battery.status.current_dA < datalayer.battery.status.max_discharge_current_dA) {
      datalayer.battery.settings.inverter_limits_discharge = true;
    } else {
      datalayer.battery.settings.inverter_limits_discharge = false;
    }
  } else {  // > 0 Battery charging
    //If actual current is smaller than max we allow, inverter is limiting factor
    if (datalayer.battery.status.current_dA < datalayer.battery.status.max_charge_current_dA) {
      datalayer.battery.settings.inverter_limits_charge = true;
    } else {
      datalayer.battery.settings.inverter_limits_charge = false;
    }
  }

  if (battery2) {
    /* Calculate active power based on voltage and current for battery 2*/
    datalayer.battery2.status.active_power_W =
        (datalayer.battery2.status.current_dA * (datalayer.battery2.status.voltage_dV / 100));
  }

  if (datalayer.battery.settings.soc_scaling_active) {
    /** SOC Scaling
   * A static version of a stochastic oscillator. The scaled SoC is calculated as:
   * 
   *     10000 * (real_soc - min_percentage)
   * ---------------------------------------
   *     (max_percentage - min_percentage)
   * 
   * And scaled capacity is:
   * 
   *     reported_total_capacity_Wh = total_capacity_Wh * (max - min) / 10000
   *     reported_remaining_capacity_Wh = reported_total_capacity_Wh * scaled_soc / 10000
   */
    // Compute delta_pct and clamped_soc
    int32_t delta_pct = datalayer.battery.settings.max_percentage - datalayer.battery.settings.min_percentage;
    int32_t clamped_soc = CONSTRAIN(datalayer.battery.status.real_soc, datalayer.battery.settings.min_percentage,
                                    datalayer.battery.settings.max_percentage);
    int32_t scaled_soc = 0;
    int32_t scaled_total_capacity = 0;
    if (delta_pct != 0) {  //Safeguard against division by 0
      scaled_soc = 10000 * (clamped_soc - datalayer.battery.settings.min_percentage) / delta_pct;
    }

    datalayer.battery.status.reported_soc = scaled_soc;

    // If battery info is valid
    if (datalayer.battery.info.total_capacity_Wh > 0 && datalayer.battery.status.real_soc > 0) {
      // Scale total usable capacity
      scaled_total_capacity = (datalayer.battery.info.total_capacity_Wh * delta_pct) / 10000;
      datalayer.battery.info.reported_total_capacity_Wh = scaled_total_capacity;

      // Scale remaining capacity based on scaled SOC
      datalayer.battery.status.reported_remaining_capacity_Wh = (scaled_total_capacity * scaled_soc) / 10000;

    } else {
      // Fallback if scaling cannot be performed
      datalayer.battery.info.reported_total_capacity_Wh = datalayer.battery.info.total_capacity_Wh;
      datalayer.battery.status.reported_remaining_capacity_Wh = datalayer.battery.status.remaining_capacity_Wh;
    }

    if (battery2) {
      // If battery info is valid
      if (datalayer.battery2.info.total_capacity_Wh > 0 && datalayer.battery.status.real_soc > 0) {

        datalayer.battery2.info.reported_total_capacity_Wh = scaled_total_capacity;
        // Scale remaining capacity based on scaled SOC
        datalayer.battery2.status.reported_remaining_capacity_Wh = (scaled_total_capacity * scaled_soc) / 10000;

      } else {
        // Fallback if scaling cannot be performed
        datalayer.battery2.info.reported_total_capacity_Wh = datalayer.battery2.info.total_capacity_Wh;
        datalayer.battery2.status.reported_remaining_capacity_Wh = datalayer.battery2.status.remaining_capacity_Wh;
      }

      //Since we are running double battery, the scaled value of battery1 becomes the sum of battery1+battery2
      //This way the inverter connected to the system sees both batteries as one large battery
      datalayer.battery.info.reported_total_capacity_Wh += datalayer.battery2.info.reported_total_capacity_Wh;
      datalayer.battery.status.reported_remaining_capacity_Wh +=
          datalayer.battery2.status.reported_remaining_capacity_Wh;
    }

  } else {  // soc_scaling_active == false. No SOC window wanted. Set scaled to same as real.
    datalayer.battery.status.reported_soc = datalayer.battery.status.real_soc;
    datalayer.battery.status.reported_remaining_capacity_Wh = datalayer.battery.status.remaining_capacity_Wh;
    datalayer.battery.info.reported_total_capacity_Wh = datalayer.battery.info.total_capacity_Wh;

    if (battery2) {
      datalayer.battery2.status.reported_soc = datalayer.battery2.status.real_soc;
      datalayer.battery2.status.reported_remaining_capacity_Wh = datalayer.battery2.status.remaining_capacity_Wh;
      datalayer.battery2.info.reported_total_capacity_Wh = datalayer.battery2.info.total_capacity_Wh;
    }
  }

  if (battery2) {
    // Perform extra SOC sanity checks on double battery setups
    if (datalayer.battery.status.real_soc < 100) {  //If this battery is under 1.00%, use this as SOC instead of average
      datalayer.battery.status.reported_soc = datalayer.battery.status.real_soc;
      datalayer.battery.status.reported_remaining_capacity_Wh = datalayer.battery.status.remaining_capacity_Wh;
    }
    if (datalayer.battery2.status.real_soc <
        100) {  //If this battery is under 1.00%, use this as SOC instead of average
      datalayer.battery.status.reported_soc = datalayer.battery2.status.real_soc;
      datalayer.battery.status.reported_remaining_capacity_Wh = datalayer.battery2.status.remaining_capacity_Wh;
    }

    if (datalayer.battery.status.real_soc >
        9900) {  //If this battery is over 99.00%, use this as SOC instead of average
      datalayer.battery.status.reported_soc = datalayer.battery.status.real_soc;
      datalayer.battery.status.reported_remaining_capacity_Wh = datalayer.battery.status.remaining_capacity_Wh;
    }
    if (datalayer.battery2.status.real_soc >
        9900) {  //If this battery is over 99.00%, use this as SOC instead of average
      datalayer.battery.status.reported_soc = datalayer.battery2.status.real_soc;
      datalayer.battery.status.reported_remaining_capacity_Wh = datalayer.battery2.status.remaining_capacity_Wh;
    }
  }
  // Check if millis has overflowed. Used in events to keep better track of time
  if (currentMillis < lastMillisOverflowCheck) {  // Overflow detected
    datalayer.system.status.millisrolloverCount++;
  }
  lastMillisOverflowCheck = currentMillis;
}

void update_values_inverter() {
  if (inverter) {
    inverter->update_values();
  }
}

void check_reset_reason() {
  esp_reset_reason_t reason = esp_reset_reason();
  switch (reason) {
    case ESP_RST_UNKNOWN:  //Reset reason can not be determined
      set_event(EVENT_RESET_UNKNOWN, reason);
      break;
    case ESP_RST_POWERON:  //OK Reset due to power-on event
      set_event(EVENT_RESET_POWERON, reason);
      break;
    case ESP_RST_EXT:  //Reset by external pin (not applicable for ESP32)
      set_event(EVENT_RESET_EXT, reason);
      break;
    case ESP_RST_SW:  //OK Software reset via esp_restart
      set_event(EVENT_RESET_SW, reason);
      break;
    case ESP_RST_PANIC:  //Software reset due to exception/panic
      set_event(EVENT_RESET_PANIC, reason);
      break;
    case ESP_RST_INT_WDT:  //Reset (software or hardware) due to interrupt watchdog
      set_event(EVENT_RESET_INT_WDT, reason);
      break;
    case ESP_RST_TASK_WDT:  //Reset due to task watchdog
      set_event(EVENT_RESET_TASK_WDT, reason);
      break;
    case ESP_RST_WDT:  //Reset due to other watchdogs
      set_event(EVENT_RESET_WDT, reason);
      break;
    case ESP_RST_DEEPSLEEP:  //Reset after exiting deep sleep mode
      set_event(EVENT_RESET_DEEPSLEEP, reason);
      break;
    case ESP_RST_BROWNOUT:  //Brownout reset (software or hardware)
      set_event(EVENT_RESET_BROWNOUT, reason);
      break;
    case ESP_RST_SDIO:  //Reset over SDIO
      set_event(EVENT_RESET_SDIO, reason);
      break;
    case ESP_RST_USB:  //Reset by USB peripheral
      set_event(EVENT_RESET_USB, reason);
      break;
    case ESP_RST_JTAG:  //Reset by JTAG
      set_event(EVENT_RESET_JTAG, reason);
      break;
    case ESP_RST_EFUSE:  //Reset due to efuse error
      set_event(EVENT_RESET_EFUSE, reason);
      break;
    case ESP_RST_PWR_GLITCH:  //Reset due to power glitch detected
      set_event(EVENT_RESET_PWR_GLITCH, reason);
      break;
    case ESP_RST_CPU_LOCKUP:  //Reset due to CPU lock up
      set_event(EVENT_RESET_CPU_LOCKUP, reason);
      break;
    default:
      break;
  }
}