bt-67xx_universal_hw/modules/onewire_sensor/AM2301.c

#include "common_config.h"
#include "stm32f4xx.h"
#include "gpio.h"
#include "AM2301.h"
#ifdef PRINTF_STDLIB
#include <stdio.h>
#endif
#ifdef PRINTF_CUSTOM
#include "tinystdio.h"
#endif

#include "FreeRTOS.h"
#include "task.h"
#include "semphr.h"

#define AM2301_ERRORS_LIMIT    5

/* Force remove debug output */
#undef DBG
#define DBG if(0)

static void one_wire_delay_us(uint16_t time);
static void am2301_pin_as_output(at2301_sensor *sensor);
static void am2301_pin_as_input(at2301_sensor *sensor);
AM2301_t am2301_reset(at2301_sensor *sensor);

at2301_data_t sAM2301Sensorsdata[MAX_T_SENSORS];
at2301_sensor sAM2301Sensors[MAX_T_SENSORS];
TIM_TypeDef *timer = TIM2;

static bool dht_present = false;
static bool dht_finish = false;
static bool new_hum_request = false;
static uint8_t rawData[50];

static void am2301_pin_as_output(at2301_sensor *sensor) {
	gpio_pindef_t *pin = &gpio_pins[sensor->ow_pin];
    gpio_hw_config_pin(pin->port, pin->pin, (GPIO_MODE_OUT_CFG | GPIO_SPEED_HIGH_CFG));
    gpio_set(sensor->ow_pin, GPIO_SET);
}

static void am2301_pin_as_input(at2301_sensor *sensor) {
  gpio_pindef_t *pin = &gpio_pins[sensor->ow_pin];
    gpio_hw_config_pin(pin->port, pin->pin, (GPIO_MODE_IN_CFG | GPIO_PU_CFG));
}

AM2301_t am2301_reset(at2301_sensor *sensor)
{
    uint8_t flag_err = 0;

	new_hum_request = true;
    
    /* Запрос данных у датчика */
	//Перевод пина "на выход"
	am2301_pin_as_output(sensor);
	//Опускание линии данных на 500 мкс
	gpio_set(sensor->ow_pin, 0);
	one_wire_delay_us(500);
	//Подъём линии, перевод порта "на вход"
	gpio_set(sensor->ow_pin, 1);
	am2301_pin_as_input(sensor);
	for(uint8_t i = 0; i < 120; i++);
	NVIC_EnableIRQ(sensor->irq);
	flag_err = 0;
	while(!dht_present) {
		vTaskDelay(1);
		flag_err ++;
		if(flag_err > 5) {
			break;
		}
	}
	if (flag_err > 5) {
		DBG printf("CONNECT ERR\r\n\r\n");
		return CONNECTION_ERR;
	}

    return CONNECTION_OK;
}

AM2301_t am2301_get_data(at2301_sensor *sensor, at2301_data_t *data) {
	uint8_t flag_err = 0;
	dht_present = false;
	dht_finish = false;

	if (am2301_reset(sensor) != CONNECTION_OK) {
		dht_present = false;
		dht_finish = false;
		NVIC_DisableIRQ(sensor->irq);
        return CONNECTION_ERR;
    }
	flag_err = 0;
	while(!dht_finish) {
		vTaskDelay(1);
		if(flag_err > 5) {
			break;
		}
		flag_err ++;
	}

	if (flag_err > 5) {
		dht_present = false;
		dht_finish = false;
		NVIC_DisableIRQ(sensor->irq);
		return READ_ERR;
	}

	dht_present = false;
	dht_finish = false;
	NVIC_DisableIRQ(sensor->irq);

	uint8_t data_sensor[5] = {0, 0, 0, 0, 0};
	for(uint8_t a = 0; a < 5; a++) {
		for(uint8_t b = 0; b < 8;  b ++) {
			if(rawData[a*8 + b] > 100) data_sensor[a] |= (1<<(7 - b));
		}
	}
	memset(rawData, 0, sizeof(rawData));
	/* Проверка целостности данных */
	if((uint8_t)(data_sensor[0] + data_sensor[1] + data_sensor[2] + data_sensor[3]) == data_sensor[4]) {
		//Если контрольная сумма совпадает, то конвертация и возврат полученных значений
		data->hum = (float)(((uint16_t)data_sensor[0]<<8) | data_sensor[1])*0.1f;
		//Проверка на отрицательность температуры
		if(!(rawData[2] & (1<<7))) {
			data->temp = (float)(((uint16_t)data_sensor[2]<<8) | data_sensor[3])*0.1f;
		}	else {
			rawData[2] &= ~(1<<7);
			data->temp = (float)(((uint16_t)data_sensor[2]<<8) | data_sensor[3])*-0.1f;
		}
	} else {
		DBG printf("TEMP ERR\r\n\r\n");
		return PARITY_ERR;
	}
	DBG printf("TEMP = %.1f\r\n\r\n", data->temp);
	DBG printf("HUM = %.1f\r\n\r\n", data->hum);

	return DATA_OK;	
}

void am2301_init_port(void)
{
	 // Setup clock
    if (timer == TIM2)
        RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM2, ENABLE);
    else if (timer == TIM3)
        RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM3, ENABLE);
    else
        while(1){} // not implemented

	TIM_TimeBaseInitTypeDef TIM_InitStructure;
    TIM_InitStructure.TIM_CounterMode = TIM_CounterMode_Up;
    TIM_InitStructure.TIM_Prescaler = 84 - 1; // For 84 MHz APB1 timer clock
    TIM_InitStructure.TIM_Period = 0xFFFF;
    TIM_InitStructure.TIM_ClockDivision = TIM_CKD_DIV1;
    TIM_InitStructure.TIM_RepetitionCounter = 0;
    TIM_TimeBaseInit(timer, &TIM_InitStructure);
    //TIM_ITConfig(timer, TIM_IT_Update, ENABLE);
    TIM_Cmd(timer, ENABLE);

	RCC_APB2PeriphClockCmd(RCC_APB2Periph_SYSCFG, ENABLE);

	// Selects the GPIOA pin 0 used as external interrupt source
    SYSCFG_EXTILineConfig(EXTI_PortSourceGPIOA, EXTI_PinSource0);

	// Selects the GPIOC pin 12 used as external interrupt source
    SYSCFG_EXTILineConfig(EXTI_PortSourceGPIOC, EXTI_PinSource12);

    // External interrupt settings
    EXTI_InitTypeDef EXTI_InitStruct;
    EXTI_InitStruct.EXTI_Line = EXTI_Line0 | EXTI_Line12;
    EXTI_InitStruct.EXTI_LineCmd = ENABLE;
    EXTI_InitStruct.EXTI_Mode = EXTI_Mode_Interrupt;
    EXTI_InitStruct.EXTI_Trigger = EXTI_Trigger_Falling;
    EXTI_Init(&EXTI_InitStruct);

    // Nested vectored interrupt settings
    NVIC_InitTypeDef NVIC_InitStruct;
    NVIC_InitStruct.NVIC_IRQChannel = EXTI0_IRQn | EXTI15_10_IRQn;
    NVIC_InitStruct.NVIC_IRQChannelCmd = DISABLE;
    // EXTI0_IRQn has Most important interrupt
    NVIC_InitStruct.NVIC_IRQChannelPreemptionPriority = 0x00;
    NVIC_InitStruct.NVIC_IRQChannelSubPriority = 0x00;
    NVIC_Init(&NVIC_InitStruct);
}

void am2301_init_sensors(void)
{
	uint8_t i;
	for (i = 0; i < MAX_T_SENSORS; i++) {
		sAM2301Sensorsdata[i].hum  = 0.0;
		sAM2301Sensorsdata[i].temp  = 0.0;
    	sAM2301Sensorsdata[i].ErrorCycle   = 0;
    	sAM2301Sensorsdata[i].SensorState  = 1;  // По умолчанию устанавливаем признак неисправности
	}
	sAM2301Sensors[0].ow_pin = WDATA1;
	sAM2301Sensors[0].irq = EXTI0_IRQn;
	sAM2301Sensors[1].ow_pin = WDATA2;
	sAM2301Sensors[1].irq = EXTI15_10_IRQn;
}


/**
  * @brief  Задача чтения температуры 1-wire
  */
void vTaskDHT(void *pvParameters)
{
  	(void)pvParameters;
  	
	am2301_init_port();
	am2301_init_sensors();
	vTaskDelay(1000);
	for (;;)
	{
		for(uint8_t i = 0; i < MAX_T_SENSORS; i++) {
			if (am2301_get_data(&sAM2301Sensors[i], &sAM2301Sensorsdata[i]) != DATA_OK) {
				sAM2301Sensorsdata[i].ErrorCycle ++;
			} else {
				sAM2301Sensorsdata[i].ErrorCycle = 0;
				sAM2301Sensorsdata[i].SensorState = 0;
			}
			if (sAM2301Sensorsdata[i].ErrorCycle == AM2301_ERRORS_LIMIT) {
				sAM2301Sensorsdata[i].SensorState = 1;
				sAM2301Sensorsdata[i].ErrorCycle = 0;
			}
		}
		vTaskDelay(2000);
	}
}

void DHT_Task_Init(void) {
    xTaskCreate(vTaskDHT, "vTaskDHT", configMINIMAL_STACK_SIZE, NULL, tskIDLE_PRIORITY, NULL);
}

void TIM2_IRQHandler(void)
{
    TIM_ClearITPendingBit(TIM2, TIM_IT_Update);
   // gpio_invert_output(LED_GREEN);
}

void one_wire_delay_us(uint16_t time) {
    timer->CNT = 0;
    time -= 1;
    while (timer->CNT <= time) {
        ;
    }
}

 
void EXTI_IRQHandler(void)
{
    static bool start_meas = false;
	static uint8_t cnt_bit = 0;
	// Checks whether the interrupt from EXTI0 or not
    if (EXTI_GetITStatus(EXTI_Line0) || EXTI_GetITStatus(EXTI_Line12))
    {
       if(!dht_present) {
		   cnt_bit = 0;
		   if(new_hum_request) {
			   start_meas = false;
			   new_hum_request = false;
		   }
		   if (!start_meas) {
			   timer->CNT = 0;
			   start_meas = true;
		   } else {
			   if (timer->CNT >= 120){
					dht_present = true;
				  	start_meas = false;
				  	timer->CNT = 0;
			   }
		   }
		   
	   } else {
			rawData[cnt_bit++] = timer->CNT;			   
			if (cnt_bit == 40){
				dht_finish = true;
			}
			timer->CNT = 0;
	   }
        
        // Clears the EXTI line pending bit
		EXTI_ClearITPendingBit(EXTI_Line0);
        EXTI_ClearITPendingBit(EXTI_Line12);
    }
}