STM32F103——esp8266

代码

#include "esp8266.h"
#include "delay.h"
#include <stdarg.h>



struct STRUCT_USART_Fram ESP8266_Fram_Record_Struct = { 0 };  //定义了一个数据帧结构体
//void ESP8266_Init(u32 bound)
//{
//    GPIO_InitTypeDef GPIO_InitStructure;

//    RCC_APB2PeriphClockCmd(ESP8266_RST_Pin_Periph_Clock|ESP8266_CH_PD_Pin_Periph_Clock, ENABLE);

//    GPIO_InitStructure.GPIO_Pin = ESP8266_RST_Pin;             
//    GPIO_InitStructure.GPIO_Mode = GPIO_Mode_Out_PP;     //复用推挽输出
//    GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz;    
//    GPIO_Init(ESP8266_RST_Pin_Port, &GPIO_InitStructure);

//    GPIO_InitStructure.GPIO_Pin = ESP8266_CH_PD_Pin;               
//    GPIO_Init(ESP8266_CH_PD_Pin_Port, &GPIO_InitStructure);

//    uart2_Init(bound); 
//	  ESP8266_Rst();
//}
//对ESP8266模块发送AT指令
// cmd 待发送的指令
// ack1,ack2;期待的响应，为NULL表不需响应，两者为或逻辑关系
// time 等待响应时间
//返回1发送成功， 0失败
bool ESP8266_Send_AT_Cmd(char *cmd,char *ack1,char *ack2,u32 time)
{ 
    ESP8266_Fram_Record_Struct .InfBit .FramLength = 0; //重新接收新的数据包
    ESP8266_USART("%s\r\n", cmd);
    if(ack1==0&&ack2==0)     //不需要接收数据
    {
    return true;
    }
    delay_ms(time);   //延时
		delay_ms(1000);
    ESP8266_Fram_Record_Struct.Data_RX_BUF[ESP8266_Fram_Record_Struct.InfBit.FramLength ] = '\0';
		
    printf("%s",ESP8266_Fram_Record_Struct .Data_RX_BUF);
    if(ack1!=0&&ack2!=0)
    {
        return ( ( bool ) strstr ( ESP8266_Fram_Record_Struct .Data_RX_BUF, ack1 ) || 
                         ( bool ) strstr ( ESP8266_Fram_Record_Struct .Data_RX_BUF, ack2 ) );
    }
    else if( ack1 != 0 )  //strstr(s1,s2);检测s2是否为s1的一部分，是返回该位置，否则返回false，它强制转换为bool类型了
        return ( ( bool ) strstr ( ESP8266_Fram_Record_Struct .Data_RX_BUF, ack1 ) );

    else
        return ( ( bool ) strstr ( ESP8266_Fram_Record_Struct .Data_RX_BUF, ack2 ) );

}


//复位重启
void ESP8266_Rst(void)
{
    ESP8266_RST_Pin_SetL;
    delay_ms(500); 
    ESP8266_RST_Pin_SetH;
}


//发送恢复出厂默认设置指令将模块恢复成出厂设置
void ESP8266_AT_Test(void)
{
    char count=0;
    delay_ms(1000); 
    while(count < 10)
    {
        if(ESP8266_Send_AT_Cmd("AT+RESTORE","OK",NULL,500)) 
        {
            printf("OK\r\n");
            return;
        }
        ++ count;
    }
}


//选择ESP8266的工作模式
// enumMode 模式类型
//成功返回true，失败返回false
bool ESP8266_Net_Mode_Choose(ENUM_Net_ModeTypeDef enumMode)
{
    switch ( enumMode )
    {
        case STA:
            return ESP8266_Send_AT_Cmd ( "AT+CWMODE=1", "OK", "no change", 2500 ); 

        case AP:
            return ESP8266_Send_AT_Cmd ( "AT+CWMODE=2", "OK", "no change", 2500 ); 

        case STA_AP:
            return ESP8266_Send_AT_Cmd ( "AT+CWMODE=3", "OK", "no change", 2500 ); 

        default:
          return false;
    }       
}


//ESP8266连接外部的WIFI
//pSSID WiFi帐号
//pPassWord WiFi密码
//设置成功返回true 反之false
bool ESP8266_JoinAP( char * pSSID, char * pPassWord)
{
    char cCmd [120];
	
    sprintf ( cCmd, "AT+CWJAP=\"%s\",\"%s\"", pSSID, pPassWord );
    return ESP8266_Send_AT_Cmd( cCmd, "OK", NULL, 5000 );
}

//ESP8266 透传使能
//enumEnUnvarnishTx  是否多连接，bool类型
//设置成功返回true，反之false
bool ESP8266_Enable_MultipleId (FunctionalState enumEnUnvarnishTx )
{
    char cStr [20];

    sprintf ( cStr, "AT+CIPMUX=%d", ( enumEnUnvarnishTx ? 1 : 0 ) );

    return ESP8266_Send_AT_Cmd ( cStr, "OK", 0, 500 );

}


//ESP8266 连接服务器
//enumE  网络类型
//ip ，服务器IP
//ComNum  服务器端口
//id，连接号，确保通信不受外界干扰
//设置成功返回true，反之fasle
bool ESP8266_Link_Server(ENUM_NetPro_TypeDef enumE, char * ip, char * ComNum, ENUM_ID_NO_TypeDef id)
{
    char cStr [100] = { 0 }, cCmd [120];

    switch (  enumE )
    {
        case enumTCP:
          sprintf ( cStr, "\"%s\",\"%s\",%s", "TCP", ip, ComNum );
          break;

        case enumUDP:
          sprintf ( cStr, "\"%s\",\"%s\",%s", "UDP", ip, ComNum );
          break;

        default:
            break;
    }

    if ( id < 5 )
        sprintf ( cCmd, "AT+CIPSTART=%d,%s", id, cStr);

    else
        sprintf ( cCmd, "AT+CIPSTART=%s", cStr );

    return ESP8266_Send_AT_Cmd ( cCmd, "OK", "ALREAY CONNECT", 4000 );

}


//透传使能
//设置成功返回true， 反之false
bool ESP8266_UnvarnishSend ( void )
{
    if (!ESP8266_Send_AT_Cmd ( "AT+CIPMODE=1", "OK", 0, 500 ))
        return false;

    return 
        ESP8266_Send_AT_Cmd( "AT+CIPSEND", "OK", ">", 500 );

}


//ESP8266发送字符串
//enumEnUnvarnishTx是否使能透传模式
//pStr字符串
//ulStrLength字符串长度
//ucId 连接号
//设置成功返回true， 反之false
bool ESP8266_SendString(FunctionalState enumEnUnvarnishTx, char * pStr, u32 ulStrLength, ENUM_ID_NO_TypeDef ucId )
{
    char cStr [20];
    bool bRet = false;


    if ( enumEnUnvarnishTx )
    {
        ESP8266_USART ( "%s", pStr );

        bRet = true;

    }

    else
    {
        if ( ucId < 5 )
            sprintf ( cStr, "AT+CIPSEND=%d,%d", ucId, ulStrLength + 2 );

        else
            sprintf ( cStr, "AT+CIPSEND=%d", ulStrLength + 2 );

        ESP8266_Send_AT_Cmd ( cStr, "> ", 0, 1000 );

        bRet = ESP8266_Send_AT_Cmd ( pStr, "SEND OK", 0, 1000 );
  }

    return bRet;

}


//ESP8266退出透传模式
void ESP8266_ExitUnvarnishSend ( void )
{
    delay_ms(1000);
    ESP8266_USART( "+++" );
    delay_ms( 500 );    
}


//ESP8266 检测连接状态
//返回0：获取状态失败
//返回2：获得ip
//返回3：建立连接 
//返回4：失去连接 
u8 ESP8266_Get_LinkStatus ( void )
{
    if (ESP8266_Send_AT_Cmd( "AT+CIPSTATUS", "OK", 0, 500 ) )
    {
        if ( strstr ( ESP8266_Fram_Record_Struct .Data_RX_BUF, "STATUS:2\r\n" ) )
            return 2;

        else if ( strstr ( ESP8266_Fram_Record_Struct .Data_RX_BUF, "STATUS:3\r\n" ) )
            return 3;

        else if ( strstr ( ESP8266_Fram_Record_Struct .Data_RX_BUF, "STATUS:4\r\n" ) )
            return 4;       

    }

    return 0;
}

static char *itoa( int value, char *string, int radix )
{
    int     i, d;
    int     flag = 0;
    char    *ptr = string;

    /* This implementation only works for decimal numbers. */
    if (radix != 10)
    {
        *ptr = 0;
        return string;
    }

    if (!value)
    {
        *ptr++ = 0x30;
        *ptr = 0;
        return string;
    }

    /* if this is a negative value insert the minus sign. */
    if (value < 0)
    {
        *ptr++ = '-';

        /* Make the value positive. */
        value *= -1;

    }

    for (i = 10000; i > 0; i /= 10)
    {
        d = value / i;

        if (d || flag)
        {
            *ptr++ = (char)(d + 0x30);
            value -= (d * i);
            flag = 1;
        }
    }

    /* Null terminate the string. */
    *ptr = 0;

    return string;

} /* NCL_Itoa */


void USART_printf ( USART_TypeDef * USARTx, char * Data, ... )
{
    const char *s;
    int d;   
    char buf[16];


    va_list ap;
    va_start(ap, Data);

    while ( * Data != 0 )     // 判断数据是否到达结束符
    {                                         
        if ( * Data == 0x5c )  //'\'
        {                                     
            switch ( *++Data )
            {
                case 'r':                                     //回车符
                USART_SendData(USARTx, 0x0d);
                Data ++;
                break;

                case 'n':                                     //换行符
                USART_SendData(USARTx, 0x0a);   
                Data ++;
                break;

                default:
                Data ++;
                break;
            }            
        }

        else if ( * Data == '%')
        {                                     
            switch ( *++Data )
            {               
                case 's':                                         //字符串
                s = va_arg(ap, const char *);
                for ( ; *s; s++) 
                {
                    USART_SendData(USARTx,*s);
                    while( USART_GetFlagStatus(USARTx, USART_FLAG_TXE) == RESET );
                }
                Data++;
                break;

                case 'd':           
                    //十进制
                d = va_arg(ap, int);
                itoa(d, buf, 10);
                for (s = buf; *s; s++) 
                {
                    USART_SendData(USARTx,*s);
                    while( USART_GetFlagStatus(USARTx, USART_FLAG_TXE) == RESET );
                }
                     Data++;
                     break;
                default:
                     Data++;
                     break;
            }        
        }
        else USART_SendData(USARTx, *Data++);
        while ( USART_GetFlagStatus ( USARTx, USART_FLAG_TXE ) == RESET );

    }
}



void ESP8266_STA_TCPClient_Test(void)
{
//    u8 res;
//	
//    char str[100]={0};.
    ESP8266_AT_Test();
		printf("正在配置ESP8266\r\n");
		//配置ESP8266模式
    ESP8266_Net_Mode_Choose(STA);		
		//连接WIFI
    while(!ESP8266_JoinAP(User_ESP8266_SSID, User_ESP8266_PWD));
    ESP8266_Enable_MultipleId ( DISABLE );
		//连接服务器
    while(!ESP8266_Link_Server(enumTCP, User_ESP8266_TCPServer_IP, User_ESP8266_TCPServer_PORT, Single_ID_0));
    while(!ESP8266_UnvarnishSend());
		printf("\r\n配置完成");
//    while ( 1 )
//    {       
//			  sprintf (str,"temp=32,hum=15,light=15,Co2=24");//格式化发送字符串到TCP服务器
//        ESP8266_SendString ( ENABLE, str, 0, Single_ID_0 );
//				
//        delay_ms(1000);
//        if(TcpClosedFlag) //判断是否失去连接
//        {
//            ESP8266_ExitUnvarnishSend(); //退出透传模式
//            do
//            {
//                res = ESP8266_Get_LinkStatus();     //获取连接状态
//            }   
//            while(!res);

//            if(res == 4)                     //确认失去连接，重连
//            {
//                
//                
//                while (!ESP8266_JoinAP(User_ESP8266_SSID, User_ESP8266_PWD ) );
//                while (!ESP8266_Link_Server(enumTCP, User_ESP8266_TCPServer_IP, User_ESP8266_TCPServer_PORT, Single_ID_0 ) );        
//            } 
//            while(!ESP8266_UnvarnishSend());                    
//        }
//    }   
}

#ifndef __ESP8266_H
#define __ESP8266_H 			   
#include "stm32f10x.h"

#include <stdio.h>
#include <string.h>
#include <stdbool.h>

#if defined ( __CC_ARM   )
#pragma anon_unions
#endif

//ESP8266模式选择
typedef enum
{
    STA,
    AP,
    STA_AP  
}ENUM_Net_ModeTypeDef;

//网络传输层协议，枚举类型
typedef enum{
     enumTCP,
     enumUDP,
} ENUM_NetPro_TypeDef;
//连接号，指定为该连接号可以防止其他计算机访问同一端口而发生错误
typedef enum{
    Multiple_ID_0 = 0,
    Multiple_ID_1 = 1,
    Multiple_ID_2 = 2,
    Multiple_ID_3 = 3,
    Multiple_ID_4 = 4,
    Single_ID_0 = 5,
} ENUM_ID_NO_TypeDef;

#define ESP8266_RST_Pin          GPIO_Pin_4    //复位管脚
#define ESP8266_RST_Pin_Port     GPIOA    //复位 
#define ESP8266_RST_Pin_Periph_Clock  RCC_APB2Periph_GPIOA       //复位时钟

#define ESP8266_CH_PD_Pin     GPIO_Pin_5   //使能管脚
#define ESP8266_CH_PD_Pin_Port     GPIOA   //使能端口
#define ESP8266_CH_PD_Pin_Periph_Clock  RCC_APB2Periph_GPIOA                     //使能时钟


#define ESP8266_RST_Pin_SetH     GPIO_SetBits(ESP8266_RST_Pin_Port,ESP8266_RST_Pin)
#define ESP8266_RST_Pin_SetL     GPIO_ResetBits(ESP8266_RST_Pin_Port,ESP8266_RST_Pin)


#define ESP8266_CH_PD_Pin_SetH     GPIO_SetBits(ESP8266_CH_PD_Pin_Port,ESP8266_CH_PD_Pin)
#define ESP8266_CH_PD_Pin_SetL     GPIO_ResetBits(ESP8266_CH_PD_Pin_Port,ESP8266_CH_PD_Pin)


#define ESP8266_USART(fmt, ...)  USART_printf (USART2, fmt, ##__VA_ARGS__)    
#define PC_USART(fmt, ...)       printf(fmt, ##__VA_ARGS__)       //这是串口打印函数，串口1，执行printf后会自动执行fput函数，重定向了printf。



#define User_ESP8266_SSID     "USER_509"          //wifi名
//#define User_ESP8266_SSID     "K"          //wifi名
#define User_ESP8266_PWD      "3643731ZSC"      //wifi密码
//#define User_ESP8266_PWD      "k12345678"      //wifi密码


//Wifi 连接服务器：电脑和ESP8266 连接的是同一个路由器
#define User_ESP8266_TCPServer_IP     "192.168.43.94"     //服务器IP
#define User_ESP8266_TCPServer_PORT   "8888"      				//服务器端口号


extern volatile uint8_t TcpClosedFlag;  //连接状态标志

void ESP8266_STA_TCPClient_Test(void);

#define RX_BUF_MAX_LEN 1024       //最大字节数
extern struct STRUCT_USART_Fram   //数据帧结构体
{
    char Data_RX_BUF[RX_BUF_MAX_LEN];
    union 
    {
        __IO u16 InfAll;
        struct 
        {
            __IO u16 FramLength       :15;                               // 14:0 
            __IO u16 FramFinishFlag   :1;                                // 15 
        }InfBit;
    }; 
	
}ESP8266_Fram_Record_Struct;


//初始化和TCP功能函数
void ESP8266_Init(u32 bound);
void ESP8266_AT_Test(void);
bool ESP8266_Send_AT_Cmd(char *cmd,char *ack1,char *ack2,u32 time);
void ESP8266_Rst(void);
bool ESP8266_Net_Mode_Choose(ENUM_Net_ModeTypeDef enumMode);
bool ESP8266_JoinAP( char * pSSID, char * pPassWord );
bool ESP8266_Enable_MultipleId ( FunctionalState enumEnUnvarnishTx );
bool ESP8266_Link_Server(ENUM_NetPro_TypeDef enumE, char * ip, char * ComNum, ENUM_ID_NO_TypeDef id);
bool ESP8266_SendString(FunctionalState enumEnUnvarnishTx, char * pStr, u32 ulStrLength, ENUM_ID_NO_TypeDef ucId );
bool ESP8266_UnvarnishSend ( void );
void ESP8266_ExitUnvarnishSend ( void );
u8 ESP8266_Get_LinkStatus ( void );
void USART_printf( USART_TypeDef * USARTx, char * Data, ... );

void ESP8266_STA_TCPClient_Test(void);

//MQTT功能函数
//bool ESP8266_MQTTUSERCFG( char * pClient_Id, char * pUserName,char * PassWord);
//bool ESP8266_MQTTCONN( char * Ip, int Num);
//bool ESP8266_MQTTSUB(char * Topic);
//bool ESP8266_MQTTPUB( char * Topic,char *temp);
//bool ESP8266_MQTTCLEAN(void);
//bool MQTT_SendString(char * pTopic,char *temp2);

#endif