/* USER CODE BEGIN Header */ /** ****************************************************************************** * @file : main.c * @brief : Main program body ****************************************************************************** * @attention * * Copyright (c) 2025 STMicroelectronics. * All rights reserved. * * This software is licensed under terms that can be found in the LICENSE file * in the root directory of this software component. * If no LICENSE file comes with this software, it is provided AS-IS. * ****************************************************************************** */ /* USER CODE END Header */ /* Includes ------------------------------------------------------------------*/ #include "main.h" #include "adc.h" #include "can.h" #include "i2c.h" #include "rtc.h" #include "spi.h" #include "tim.h" #include "usart.h" #include "gpio.h" /* Private includes ----------------------------------------------------------*/ /* USER CODE BEGIN Includes */ #include "dallas_tools.h" #include "def.h" #include #include "modbus.h" #include "eeprom_emul.h" #include "stdio.h" #include "flash_ring.h" #include "string.h" /* USER CODE END Includes */ /* Private typedef -----------------------------------------------------------*/ /* USER CODE BEGIN PTD */ /* USER CODE END PTD */ /* Private define ------------------------------------------------------------*/ /* USER CODE BEGIN PD */ uint16_t iter, cnt = 5; uint8_t init_retries = 5; uint8_t ralay_5v_on_var = 0; /* USER CODE END PD */ /* Private macro -------------------------------------------------------------*/ /* USER CODE BEGIN PM */ float temperature; uint8_t roms[MAX_DEVICES][8]; Flags_TypeDef flag; //extern uint8_t devices_found ; uint8_t _debug_init = 0; TEMP_TypeDef temp_sense[30]; float set_temp_old[30]; char rx_buffer[64]; uint8_t rx_index = 0; char command_ready = 0; uint8_t uart_byte = 0; uint8_t first_in = 1; DALLAS_SensorHandleTypeDef sens[30]; int init_sens = 0; FlashRecord_t* record; uint8_t flash_buff[RECORD_SIZE - 4]; RS_HandleTypeDef hmodbus_master; RS_MsgTypeDef MODBUS_MASTER_MSG; static uint8_t hmodbus_master_buffer[MSG_SIZE_MAX]; static uint8_t rtc_modbus_hold_initialized = 0U; /* USER CODE END PM */ /* Private variables ---------------------------------------------------------*/ /* USER CODE BEGIN PV */ int last_page_addr = LAST_PAGE_ADDR; /* USER CODE END PV */ /* Private function prototypes -----------------------------------------------*/ void SystemClock_Config(void); /* USER CODE BEGIN PFP */ static void RTC_ModbusService(MB_DataStructureTypeDef* mb_data); static void RTC_ReadCalendarFromRegs(const MB_RtcCalendarRegsTypeDef* regs, RTC_CalendarTypeDef* calendar); static void RTC_WriteCalendarToRegs(MB_RtcCalendarRegsTypeDef* regs, const RTC_CalendarTypeDef* calendar, uint16_t status); /* USER CODE END PFP */ /* Private user code ---------------------------------------------------------*/ /* USER CODE BEGIN 0 */ HAL_StatusTypeDef ModbusMaster_Request(RS_MsgTypeDef *request, void (*callback)(RS_HandleTypeDef *, RS_MsgTypeDef *)) { return MODBUS_MasterRequest(&hmodbus_master, request, callback); } /* USER CODE END 0 */ /** * @brief The application entry point. * @retval int */ int main(void) { /* USER CODE BEGIN 1 */ /* USER CODE END 1 */ /* MCU Configuration--------------------------------------------------------*/ /* Reset of all peripherals, Initializes the Flash interface and the Systick. */ HAL_Init(); /* USER CODE BEGIN Init */ /* USER CODE END Init */ /* Configure the system clock */ SystemClock_Config(); /* USER CODE BEGIN SysInit */ /* USER CODE END SysInit */ /* Initialize all configured peripherals */ MX_GPIO_Init(); MX_TIM1_Init(); MX_USART1_UART_Init(); MX_USART2_UART_Init(); MX_TIM2_Init(); MX_TIM4_Init(); MX_ADC1_Init(); MX_CAN_Init(); MX_I2C1_Init(); MX_RTC_Init(); MX_SPI1_Init(); /* USER CODE BEGIN 2 */ led_blink(GPIOC, 13, rest_iter, reset_blink_delay); MODBUS_FirstInit(&hmodbus1, &mb_huart, &mb_htim); MODBUS_Config(&hmodbus1, MODBUS_DEVICE_ID, MODBUS_TIMEOUT, MODBUS_MODE_SLAVE); // Запуск приема Modbus MODBUS_SlaveStart(&hmodbus1, NULL); if (MODBUS_FirstInit(&hmodbus_master, &huart2, &htim4) != HAL_OK) { Error_Handler(); } hmodbus_master.pBufferPtr = hmodbus_master_buffer; if (MODBUS_Config(&hmodbus_master, 0, MODBUS_TIMEOUT, MODBUS_MODE_MASTER) != HAL_OK) { Error_Handler(); } uint8_t uart_byte = 0; Dallas_BusFirstInit(&htim1); // ������������� �� ������� ��������� �������� // ������������� �� ������� (����������� ������ ���������� �������) reinit_t_sens(); init_setpoint_all_T_sense(temp_sense, hdallas.onewire->RomCnt); MB_DATA.InRegs.num_Tsens = hdallas.onewire->RomCnt; RTC_ModbusService(&MB_DATA); // BufferState_t buffer_state = buffer_init(); for(int i=0;iODR |= 1 << 13; // } // } temp_sense[0].t_close = 1; Field_modbus(&MB_DATA, &flag); Check_Tconnect(&MB_DATA, &flag, &hdallas, 0); value_control(); init_setpoint_all_T_sense(temp_sense, hdallas.onewire->RomCnt); // handle_valves(temp_sense[]); Dallas_StartConvertTAll(&hdallas, DALLAS_WAIT_BUS, 0); for(int i = 0; i < hdallas.onewire->RomCnt; i++) { if(sens[i].isLost) { sens[i].lost_cnt ++; } Dallas_ReadTemperature(&sens[i]); MB_DATA.InRegs.sens_Temp[i] = sens[i].temperature * 10; /////////////////////////заменить на define ralay_5v_on_var GPIOA->ODR|=1<<10; ralay_5v_on_var = MB_DATA.Coils.coils[1].state_val_bit.state_val_05; if (ralay_5v_on_var) { GPIOA->ODR |= 1 << 10; } else { GPIOA->ODR &= ~(1 << 10); } } /* USER CODE END WHILE */ /* USER CODE BEGIN 3 */ //iwdg_refresh(); //HAL_Delay(200); } /* USER CODE END 3 */ } /** * @brief System Clock Configuration * @retval None */ void SystemClock_Config(void) { RCC_OscInitTypeDef RCC_OscInitStruct = {0}; RCC_ClkInitTypeDef RCC_ClkInitStruct = {0}; RCC_PeriphCLKInitTypeDef PeriphClkInit = {0}; /** Initializes the RCC Oscillators according to the specified parameters * in the RCC_OscInitTypeDef structure. */ RCC_OscInitStruct.OscillatorType = RCC_OSCILLATORTYPE_LSI|RCC_OSCILLATORTYPE_HSE; RCC_OscInitStruct.HSEState = RCC_HSE_ON; RCC_OscInitStruct.HSEPredivValue = RCC_HSE_PREDIV_DIV1; RCC_OscInitStruct.HSIState = RCC_HSI_ON; RCC_OscInitStruct.LSIState = RCC_LSI_ON; RCC_OscInitStruct.PLL.PLLState = RCC_PLL_ON; RCC_OscInitStruct.PLL.PLLSource = RCC_PLLSOURCE_HSE; RCC_OscInitStruct.PLL.PLLMUL = RCC_PLL_MUL9; if (HAL_RCC_OscConfig(&RCC_OscInitStruct) != HAL_OK) { Error_Handler(); } /** Initializes the CPU, AHB and APB buses clocks */ RCC_ClkInitStruct.ClockType = RCC_CLOCKTYPE_HCLK|RCC_CLOCKTYPE_SYSCLK |RCC_CLOCKTYPE_PCLK1|RCC_CLOCKTYPE_PCLK2; RCC_ClkInitStruct.SYSCLKSource = RCC_SYSCLKSOURCE_PLLCLK; RCC_ClkInitStruct.AHBCLKDivider = RCC_SYSCLK_DIV1; RCC_ClkInitStruct.APB1CLKDivider = RCC_HCLK_DIV2; RCC_ClkInitStruct.APB2CLKDivider = RCC_HCLK_DIV1; if (HAL_RCC_ClockConfig(&RCC_ClkInitStruct, FLASH_LATENCY_2) != HAL_OK) { Error_Handler(); } PeriphClkInit.PeriphClockSelection = RCC_PERIPHCLK_RTC|RCC_PERIPHCLK_ADC; PeriphClkInit.RTCClockSelection = RCC_RTCCLKSOURCE_LSI; PeriphClkInit.AdcClockSelection = RCC_ADCPCLK2_DIV6; if (HAL_RCCEx_PeriphCLKConfig(&PeriphClkInit) != HAL_OK) { Error_Handler(); } } /* USER CODE BEGIN 4 */ static void RTC_ReadCalendarFromRegs(const MB_RtcCalendarRegsTypeDef* regs, RTC_CalendarTypeDef* calendar) { if ((regs == NULL) || (calendar == NULL)) { return; } calendar->hours = regs->hours; calendar->minutes = regs->minutes; calendar->seconds = regs->seconds; calendar->date = regs->date; calendar->month = regs->month; calendar->year = regs->year; calendar->weekday = regs->weekday; } static void RTC_WriteCalendarToRegs(MB_RtcCalendarRegsTypeDef* regs, const RTC_CalendarTypeDef* calendar, uint16_t status) { if ((regs == NULL) || (calendar == NULL)) { return; } regs->hours = calendar->hours; regs->minutes = calendar->minutes; regs->seconds = calendar->seconds; regs->date = calendar->date; regs->month = calendar->month; regs->year = calendar->year; regs->weekday = calendar->weekday; regs->apply = 0U; regs->status = status; } static void RTC_ModbusService(MB_DataStructureTypeDef* mb_data) { RTC_CalendarTypeDef calendar = {0}; uint16_t hold_status = MB_RTC_STATUS_IDLE; uint8_t copy_current_to_holding = 0U; if (mb_data == NULL) { return; } hold_status = mb_data->HoldRegs.rtc.status; if (mb_data->HoldRegs.rtc.apply == MB_RTC_APPLY_SET) { RTC_ReadCalendarFromRegs(&mb_data->HoldRegs.rtc, &calendar); mb_data->HoldRegs.rtc.apply = 0U; if (RTC_CalendarIsValid(&calendar) == 0U) { hold_status = MB_RTC_STATUS_VALUE_ERROR; } else if (RTC_CalendarSet(&calendar) != HAL_OK) { hold_status = MB_RTC_STATUS_HAL_ERROR; } else { hold_status = MB_RTC_STATUS_SET_OK; copy_current_to_holding = 1U; } } if (RTC_CalendarGet(&calendar) != HAL_OK) { mb_data->InRegs.rtc.status = MB_RTC_STATUS_HAL_ERROR; mb_data->HoldRegs.rtc.status = MB_RTC_STATUS_HAL_ERROR; return; } RTC_WriteCalendarToRegs(&mb_data->InRegs.rtc, &calendar, MB_RTC_STATUS_IDLE); if ((rtc_modbus_hold_initialized == 0U) || (copy_current_to_holding != 0U)) { RTC_WriteCalendarToRegs(&mb_data->HoldRegs.rtc, &calendar, hold_status); rtc_modbus_hold_initialized = 1U; } else { mb_data->HoldRegs.rtc.status = hold_status; } } void iwdg_refresh(void) { IWDG->KR = 0xAAAA; // �������� ������ } void led_blink(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin, uint8_t iter, uint16_t delay) { for(int i = 0; i < iter; i++) { GPIOx->ODR ^= (1 << GPIO_Pin); HAL_Delay(delay); } } void Check_Tconnect(MB_DataStructureTypeDef* MB_DATA, Flags_TypeDef* flag, DALLAS_HandleTypeDef* hdallas, int a[0]) { for(int i = 0; i < hdallas->onewire->RomCnt; i++) { if(sens[i].isLost) { //init_sens=1; } } if (init_sens || flag->init_tsens) { init_sens = 0; flag->init_tsens = 0; //Dallas_BusFirstInit(&htim1); DS18B20_Search(&DS, &OW) ; reinit_t_sens(); MB_DATA->InRegs.num_Tsens = hdallas->onewire->RomCnt; } } void reinit_t_sens(void) { for ( int i = 0; i < hdallas.onewire->RomCnt; i++) { // ������������� �� ROM-������ //sens[i].Init.init_func = &Dallas_SensorInitByROM; // sens[i].Init.InitParam.ROM = rom_address; sens[i].Init.InitParam.Ind = i; sens[i].Init.init_func = &Dallas_SensorInitByInd; sens[i].Init.Resolution = DALLAS_CONFIG_9_BITS; sens[i].set_temp = 20.; sens[i].hyst = 1; MB_DATA.HoldRegs.set_Temp[i] = (uint16_t)(sens[i].set_temp * MB_ROOM_TEMP_SCALE); MB_DATA.HoldRegs.set_hyst[i] = (uint16_t)(sens[i].hyst * MB_ROOM_TEMP_SCALE); MB_DATA.HoldRegs.room_cfg[i].setpoint_x10 = MB_DATA.HoldRegs.set_Temp[i]; MB_DATA.HoldRegs.room_cfg[i].hysteresis_x10 = MB_DATA.HoldRegs.set_hyst[i]; MB_DATA.HoldRegs.room_cfg[i].valve_position_pct = 0; MB_DATA.HoldRegs.room_cfg[i].valve_angle_max_deg = MB_ROOM_VALVE_ANGLE_MAX_DEFAULT; MB_DATA.HoldRegs.room_cfg[i].mode = ROOM_MODE_AUTO; MB_DATA.HoldRegs.room_cfg[i].command = ROOM_COMMAND_STOP; MB_DATA.HoldRegs.room_cfg[i].location = 1; MB_DATA.HoldRegs.room_cfg[i].apply = 0; Dallas_AddNewSensors(&hdallas, &sens[i]); } } FuncStat packStruct(MB_DataStructureTypeDef* MB_DATA, int sizeARR) { for(int i = 0; i < sizeARR; i++) { for(int sens_num = 0; sens_num < hdallas.onewire->RomCnt; sens_num++) { switch(sens_num) { case 0: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp1_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 1: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp2_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 2: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp3_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 3: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp4_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 4: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp5_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 5: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp6_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 6: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp7_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 7: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp8_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 8: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp9_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 9: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp10_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 10: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp11_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 11: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp12_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 12: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp13_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 13: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp14_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 14: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp15_isConnected = sens[i * 16 + sens_num ].isConnected; break; case 15: MB_DATA->Coils.status_tSens[i].state_val_bit.Temp16_isConnected = sens[i * 16 + sens_num ].isConnected; break; } } } return FuncOK; } static uint16_t clamp_room_percent(uint16_t value) { return value > 100U ? 100U : value; } static void update_room_modbus(MB_DataStructureTypeDef* MB_DATA) { for (int i = 0; i < MAX_SENSE; i++) { MB_RoomInputRegsTypeDef* room = &MB_DATA->InRegs.room[i]; MB_RoomHoldingRegsTypeDef* cfg = &MB_DATA->HoldRegs.room_cfg[i]; uint16_t open_state = 0U; uint16_t close_state = 0U; uint16_t position_pct; uint16_t angle_max; if (cfg->valve_angle_max_deg == 0U) { cfg->valve_angle_max_deg = MB_ROOM_VALVE_ANGLE_MAX_DEFAULT; } if (i < 16) { open_state = (MB_DATA->Coils.relay_struct_on.all >> i) & 0x1U; close_state = (MB_DATA->Coils.relay_struct_off.all >> i) & 0x1U; } position_pct = clamp_room_percent(cfg->valve_position_pct); if (cfg->mode == ROOM_MODE_AUTO) { if (open_state) { position_pct = 100U; } else if (close_state) { position_pct = 0U; } } cfg->valve_position_pct = position_pct; angle_max = cfg->valve_angle_max_deg; room->channel = (uint16_t)(i + 1); room->location = cfg->location; for (int reg = 0; reg < 4; reg++) { room->ds18b20_id[reg] = ((uint16_t)MB_DATA->InRegs.ID.DevAddr[i][reg * 2]) | ((uint16_t)MB_DATA->InRegs.ID.DevAddr[i][reg * 2 + 1] << 8); } room->temperature_x10 = (i < hdallas.onewire->RomCnt) ? (uint16_t)((int16_t)(sens[i].temperature * MB_ROOM_TEMP_SCALE)) : 0U; room->setpoint_x10 = MB_DATA->HoldRegs.set_Temp[i]; room->hysteresis_x10 = MB_DATA->HoldRegs.set_hyst[i]; room->valve_position_pct = position_pct; room->valve_angle_deg = (uint16_t)((position_pct * angle_max) / 100U); room->valve_angle_max_deg = angle_max; room->is_connected = (i < hdallas.onewire->RomCnt) ? (uint16_t)sens[i].isConnected : 0U; room->valve_open = open_state; room->valve_close = close_state; room->mode = cfg->mode; room->command_state = cfg->command; room->reserved = 0U; } } FuncStat Field_modbus(MB_DataStructureTypeDef* MB_DATA, Flags_TypeDef* flag) { MB_DATA->InRegs.ID = *hdallas.ds_devices; RTC_ModbusService(MB_DATA); flag->init_tsens = MB_DATA->Coils.init_Tsens; packStruct(MB_DATA, MAX_SENSE / 16); if (_debug_init || MB_DATA->Coils.init_param) { _debug_init = 0; MB_DATA->Coils.init_param = 0; for(int i = 0; i < hdallas.onewire->RomCnt; i++) { if (MB_DATA->HoldRegs.room_cfg[i].apply) { MB_DATA->HoldRegs.set_Temp[i] = MB_DATA->HoldRegs.room_cfg[i].setpoint_x10; MB_DATA->HoldRegs.set_hyst[i] = MB_DATA->HoldRegs.room_cfg[i].hysteresis_x10; MB_DATA->HoldRegs.room_cfg[i].apply = 0U; } MB_DATA->HoldRegs.room_cfg[i].setpoint_x10 = MB_DATA->HoldRegs.set_Temp[i]; MB_DATA->HoldRegs.room_cfg[i].hysteresis_x10 = MB_DATA->HoldRegs.set_hyst[i]; sens[i].set_temp = ((float)MB_DATA->HoldRegs.set_Temp[i]) / MB_ROOM_TEMP_SCALE; sens[i].hyst = ((float)MB_DATA->HoldRegs.set_hyst[i]) / MB_ROOM_TEMP_SCALE; } } update_room_modbus(MB_DATA); return FuncOK; }; FuncStat value_control(void ) { for(int i = 0; i < hdallas.onewire->RomCnt; i++) { if (i < 16 && MB_DATA.HoldRegs.room_cfg[i].mode == ROOM_MODE_MANUAL) { uint16_t manual_pct = clamp_room_percent(MB_DATA.HoldRegs.room_cfg[i].valve_position_pct); if (MB_DATA.HoldRegs.room_cfg[i].command == ROOM_COMMAND_CLOSE) { manual_pct = 0U; } else if (MB_DATA.HoldRegs.room_cfg[i].command == ROOM_COMMAND_OPEN && manual_pct == 0U) { manual_pct = 100U; } MB_DATA.HoldRegs.room_cfg[i].valve_position_pct = manual_pct; if (manual_pct > 0U) { MB_DATA.Coils.relay_struct_off.all &= ~(1 << i); MB_DATA.Coils.relay_struct_on.all |= 1 << i; } else { MB_DATA.Coils.relay_struct_on.all &= ~(1 << i); MB_DATA.Coils.relay_struct_off.all |= 1 << i; } continue; } if (sens[i].temperature < sens[i].set_temp - sens[i].hyst) { MB_DATA.Coils.relay_struct_off.all |= 1 << i; MB_DATA.Coils.relay_struct_on.all &= ~(1 << i); } else if (sens[i].temperature > sens[i].set_temp + sens[i].hyst) { MB_DATA.Coils.relay_struct_off.all &= ~(1 << i); MB_DATA.Coils.relay_struct_on.all |= 1 << i; } else if (sens[i].temperature == sens[i].set_temp ) { MB_DATA.Coils.relay_struct_on.all &= ~(1 << i); MB_DATA.Coils.relay_struct_off.all &= ~(1 << i); } } return FuncOK; } uint16_t handle_valves(TEMP_TypeDef* temp_sense[MAX_SENSE] ) { if (temp_sense[0]->state == STATE_OPEN_VALVE) { GPIOC->ODR |= 1 << 14; } else if (temp_sense[0]->state == STATE_CLOSE_VALVE) { GPIOC->ODR &= ~(1 << 14); } return 1; } void init_setpoint_all_T_sense(TEMP_TypeDef* temp_sense, int size_array) { //ds_search_devices(); for(int i = 0; i < size_array ; i++) { temp_sense[i].id[0] = roms[i][0] << 0 | roms[i][1] << 8 | roms[i][2] << 16 | roms[i][3] << 24; temp_sense[i].id[1] = roms[i][4] << 0 | roms[i][5] << 8 | roms[i][6] << 16 | roms[i][7] << 24; temp_sense[i].count = i + 1; temp_sense[i].location = 1; temp_sense[i].t_open = 22; temp_sense[i].t_close = 18; temp_sense[i].status_T_sense = 1; } } /* USER CODE END 4 */ /** * @brief Period elapsed callback in non blocking mode * @note This function is called when TIM3 interrupt took place, inside * HAL_TIM_IRQHandler(). It makes a direct call to HAL_IncTick() to increment * a global variable "uwTick" used as application time base. * @param htim : TIM handle * @retval None */ void HAL_TIM_PeriodElapsedCallback(TIM_HandleTypeDef *htim) { /* USER CODE BEGIN Callback 0 */ /* USER CODE END Callback 0 */ if (htim->Instance == TIM3) { HAL_IncTick(); } /* USER CODE BEGIN Callback 1 */ /* USER CODE END Callback 1 */ } /** * @brief This function is executed in case of error occurrence. * @retval None */ void Error_Handler(void) { /* USER CODE BEGIN Error_Handler_Debug */ /* User can add his own implementation to report the HAL error return state */ __disable_irq(); while (1) { } /* USER CODE END Error_Handler_Debug */ } #ifdef USE_FULL_ASSERT /** * @brief Reports the name of the source file and the source line number * where the assert_param error has occurred. * @param file: pointer to the source file name * @param line: assert_param error line source number * @retval None */ void assert_failed(uint8_t *file, uint32_t line) { /* USER CODE BEGIN 6 */ /* User can add his own implementation to report the file name and line number, ex: printf("Wrong parameters value: file %s on line %d\r\n", file, line) */ /* USER CODE END 6 */ } #endif /* USE_FULL_ASSERT */