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QDAC-firmware/libraries/zf_device/zf_device_wifi_uart.c
CaoWangrenbo eaa7cc0eea first commit
2023-12-11 21:45:06 +08:00

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/*********************************************************************************************************************
* CH32V307VCT6 Opensourec Library 即CH32V307VCT6 开源库)是一个基于官方 SDK 接口的第三方开源库
* Copyright (c) 2022 SEEKFREE 逐飞科技
*
* 本文件是CH32V307VCT6 开源库的一部分
*
* CH32V307VCT6 开源库 是免费软件
* 您可以根据自由软件基金会发布的 GPLGNU General Public License即 GNU通用公共许可证的条款
* 即 GPL 的第3版即 GPL3.0)或(您选择的)任何后来的版本,重新发布和/或修改它
*
* 本开源库的发布是希望它能发挥作用,但并未对其作任何的保证
* 甚至没有隐含的适销性或适合特定用途的保证
* 更多细节请参见 GPL
*
* 您应该在收到本开源库的同时收到一份 GPL 的副本
* 如果没有,请参阅<https://www.gnu.org/licenses/>
*
* 额外注明:
* 本开源库使用 GPL3.0 开源许可证协议 以上许可申明为译文版本
* 许可申明英文版在 libraries/doc 文件夹下的 GPL3_permission_statement.txt 文件中
* 许可证副本在 libraries 文件夹下 即该文件夹下的 LICENSE 文件
* 欢迎各位使用并传播本程序 但修改内容时必须保留逐飞科技的版权声明(即本声明)
*
* 文件名称 zf_device_wifi_uart
* 公司名称 成都逐飞科技有限公司
* 版本信息 查看 libraries/doc 文件夹内 version 文件 版本说明
* 开发环境 MounRiver Studio V1.8.1
* 适用平台 CH32V307VCT6
* 店铺链接 https://seekfree.taobao.com/
*
* 修改记录
* 日期 作者 备注
* 2022-09-15 大W first version
********************************************************************************************************************/
/*********************************************************************************************************************
* 接线定义:
* ------------------------------------
* 模块管脚 单片机管脚
* RX 查看 zf_device_wifi_uart.h 中 WRIELESS_UART_RX_PINx 宏定义
* TX 查看 zf_device_wifi_uart.h 中 WRIELESS_UART_TX_PINx 宏定义
* RTS 查看 zf_device_wifi_uart.h 中 WRIELESS_UART_RTS_PINx 宏定义
* RST 查看 zf_device_wifi_uart.h 中 WRIELESS_UART_RST_PINx 宏定义
* VCC 5V 电源
* GND 电源地
* 其余引脚悬空
* ------------------------------------
*********************************************************************************************************************/
#include "zf_common_clock.h"
#include "zf_common_debug.h"
#include "zf_common_fifo.h"
#include "zf_common_function.h"
#include "zf_driver_delay.h"
#include "zf_driver_gpio.h"
#include "zf_driver_uart.h"
#include "zf_device_type.h"
#include "zf_device_wifi_uart.h"
#define WAIT_TIME_OUT (10000) // 单指令等待时间 单位ms
wifi_uart_information_struct wifi_uart_information; // 模块自身参数
static fifo_struct wifi_uart_fifo;
static uint8 wifi_uart_buffer[WIFI_UART_BUFFER_SIZE]; // 数据存放数组
static uint8 wifi_uart_data;
//--------------------------------------------------------------------------------------------------
// 函数简介 等待模块响应
// 参数说明 *wait_buffer 等待的响应的字符串
// 参数说明 timeout 超时时间
// 返回参数 uint8 0模块响应指定数据 1模块未响应指定数据或超时
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_wait_ack (char *wait_buffer, uint32 timeout)
{
uint8 return_state = 1;
char receiver_buffer[8] = {0, 0, 0, 0, 0, 0, 0, 0};
uint32 receiver_len = 8;
do
{
system_delay_ms(1);
// 判断接收缓冲区内是否有需要响应的指定数据 如果有 则跳出循环并且返回0
receiver_len = 8;
fifo_read_tail_buffer(&wifi_uart_fifo, (uint8 *)receiver_buffer, &receiver_len, FIFO_READ_ONLY);
if(strstr(receiver_buffer, wait_buffer))
{
return_state = 0;
break;
}
else if(strstr(receiver_buffer, "ERROR") || strstr(receiver_buffer, "busy"))
{
// 如果接收到报错或者模块忙 则跳出循环并且返回1
return_state = 1;
break;
}
}while(timeout --);
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 清除WiFi接收缓冲区内容
// 参数说明 void
// 返回参数 void
// 使用示例 wifi_uart_clear_receive_buffer();
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static void wifi_uart_clear_receive_buffer (void)
{
// 清空WiFi接收缓冲区
fifo_clear(&wifi_uart_fifo);
}
//--------------------------------------------------------------------------------------------------
// 函数简介 模块数据解析
// 参数说明 *target_buffer 目标存放地址指针 字符串数组
// 参数说明 *origin_buffer 数据来源地址指针 字符串数组
// 参数说明 start_char 起始提取字节 例如从 "1234" 中从 '2' 开始提取 就应该填入 '2'
// 参数说明 end_char 结束提取字节 例如从 "1234" 中在 '4' 结束提取 就应该填入 '\0'(0x00 空字符 一般是字符串结尾)
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_data_parse(wifi_uart_information.mac, wifi_uart_receive_buffer, '"', '"'); // 调用获取本机mac地址后调用此函数提取mac地址
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_data_parse (uint8 *target_buffer, uint8 *origin_buffer, char start_char, char end_char)
{
uint8 return_state = 0;
char *location1 = NULL;
char *location2 = NULL;
location1 = strchr((char *)origin_buffer, start_char);
if(location1)
{
location1 ++;
location2 = strchr(location1, end_char);
if(location2)
{
memcpy(target_buffer, location1, location2-location1);
}
else
{
return_state = 1;
}
}
else
{
return_state = 1;
}
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 查看模块版本信息
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_get_version();
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_get_version (void)
{
char *location1 = NULL;
uint8 return_state = 0;
uint8 receiver_buffer[256];
uint32 receiver_len = 256;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+GMR\r\n");
do
{
if(wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
return_state = 1;
break;
}
fifo_read_buffer(&wifi_uart_fifo, receiver_buffer, &receiver_len, FIFO_READ_ONLY);
location1 = strrchr((char *)receiver_buffer, ':');
if(wifi_data_parse(wifi_uart_information.wifi_uart_version, (uint8 *)location1, ':', '('))
{
return_state = 1;
break;
}
}while(0);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 模块回显设置
// 参数说明 model 0:关闭模块的回写功能 其他:开启模块回写
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_echo_set("1");//开启模块回写功能
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_echo_set (char *model)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "ATE");
uart_write_string(WIFI_UART_INDEX, model);
uart_write_string(WIFI_UART_INDEX, "\r\n");
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 设置模块的串口配置
// 参数说明 baudrate 波特率 支持范围为 80 ~ 5000000
// 参数说明 databits 数据位 55 bit 数据位----66 bit 数据位----77 bit 数据位----88 bit 数据位
// 参数说明 stopbits 停止位 11 bit 停止位----21.5 bit 停止位----32 bit 停止位
// 参数说明 parity 校验位 0None----1Odd----2Even
// 参数说明 flow_control 流控 0不使能流控----1使能 RTS----2使能 CTS----3同时使能 RTS 和 CTS
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_uart_config_set("115200", "8", "1", "0", "1");
// 备注信息 内部调用 临时设置 掉电不保存
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_uart_config_set (char *baudrate, char *databits, char *stopbits, char *parity, char *flow_control)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+UART_CUR=");
uart_write_string(WIFI_UART_INDEX, baudrate);
uart_write_string(WIFI_UART_INDEX, ",");
uart_write_string(WIFI_UART_INDEX, databits);
uart_write_string(WIFI_UART_INDEX, ",");
uart_write_string(WIFI_UART_INDEX, stopbits);
uart_write_string(WIFI_UART_INDEX, ",");
uart_write_string(WIFI_UART_INDEX, parity);
uart_write_string(WIFI_UART_INDEX, ",");
uart_write_string(WIFI_UART_INDEX, flow_control);
uart_write_string(WIFI_UART_INDEX, "\r\n");
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 查询模块自身 的 MAC 地址
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 if(wifi_uart_get_mac()){}
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_get_mac (void)
{
uint8 return_state = 0;
uint8 receiver_buffer[64];
uint32 receiver_len = 64;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPAPMAC?\r\n");
do
{
if(wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
return_state = 1;
break;
}
fifo_read_buffer(&wifi_uart_fifo, receiver_buffer, &receiver_len, FIFO_READ_ONLY);
if(wifi_data_parse(wifi_uart_information.wifi_uart_mac, receiver_buffer, '"', '"'))
{
return_state = 1;
break;
}
}while(0);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 查询模块或者目标WIFI 的 IP 地址(取决于模块当前的工作模式)
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 if(wifi_uart_get_ip()){}
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_get_ip (void)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
if(WIFI_UART_STATION == wifi_uart_information.wifi_uart_mode)
{
uart_write_string(WIFI_UART_INDEX, "AT+CIPSTA?\r\n");
}
else if(WIFI_UART_SOFTAP == wifi_uart_information.wifi_uart_mode)
{
uart_write_string(WIFI_UART_INDEX, "AT+CIPAP?\r\n");
}
do
{
if(wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
return_state = 1;
break;
}
uint8 receiver_buffer[128];
uint32 receiver_len = 128;
fifo_read_buffer(&wifi_uart_fifo, receiver_buffer, &receiver_len, FIFO_READ_ONLY);
if(wifi_data_parse(wifi_uart_information.wifi_uart_local_ip, receiver_buffer, '"', '"'))
{
return_state = 1;
break;
}
}while(0);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 查询模块的相关信息
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 if(wifi_uart_get_information()){}
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_get_information (void)
{
uint8 return_state = 0;
do
{
// 获取模块版本号
if(wifi_uart_get_version())
{
return_state = 1;
break;
}
// 获取模块IP地址
if(wifi_uart_get_ip())
{
return_state = 1;
break;
}
// 获取模块MAC信息
if(wifi_uart_get_mac())
{
return_state = 1;
break;
}
memcpy(wifi_uart_information.wifi_uart_local_port, "no port", 7);
}while(0);
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 连接 WiFi
// 参数说明 wifi_ssid WiFi名称
// 参数说明 pass_word WiFi密码
// 参数说明 model 0:查询WiFi连接情况 其他连接WiFi
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_get_or_connect_wifi("WiFi_name", "Pass_word", 1);
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_set_wifi (char *wifi_ssid, char *pass_word)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
if(WIFI_UART_SOFTAP == wifi_uart_information.wifi_uart_mode)
{
uart_write_string(WIFI_UART_INDEX, "AT+CWSAP=\"");
uart_write_string(WIFI_UART_INDEX, wifi_ssid);
uart_write_string(WIFI_UART_INDEX, "\",\"");
uart_write_string(WIFI_UART_INDEX, pass_word);
uart_write_string(WIFI_UART_INDEX, "\",5,3\r\n");
}
else
{
uart_write_string(WIFI_UART_INDEX, "AT+CWJAP=\"");
uart_write_string(WIFI_UART_INDEX, wifi_ssid);
uart_write_string(WIFI_UART_INDEX, "\",\"");
uart_write_string(WIFI_UART_INDEX, pass_word);
uart_write_string(WIFI_UART_INDEX, "\"\r\n");
}
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 上电是否自动连接WiFi
// 参数说明 model 0:上电不自动连接wifi 其他上电自动连接wifi
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_auto_connect_wifi(0); //上电不自动连接wifi
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_auto_connect_wifi (char *model)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CWAUTOCONN=");
uart_write_string(WIFI_UART_INDEX, model);
uart_write_string(WIFI_UART_INDEX, "\r\n");
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 设置连接模式
// 参数说明 model 0: 单连接模式 1多连接模式
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_set_connect_model("1");
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_set_connect_model (char *model)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPMUX=");
uart_write_string(WIFI_UART_INDEX, model);
uart_write_string(WIFI_UART_INDEX, "\r\n");
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 设置传输模式
// 参数说明 model 0: 普通传输模式 IP断开后不重新连接
// 1: Wi-Fi 透传接收模式,仅支持 TCP 单连接、UDP 固定通信对端、SSL 单连接的情况 IP断开后会不断尝试重新连接
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_set_transfer_model("1");
// 备注信息 内部调用
//--------------------------------------------------------------------------------------------------
static uint8 wifi_uart_set_transfer_model (char *model)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPMODE=");
uart_write_string(WIFI_UART_INDEX, model);
uart_write_string(WIFI_UART_INDEX, "\r\n");
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 模块软件复位
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_soft_reset();
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_soft_reset (void)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "+++");
system_delay_ms(100);
uart_write_string(WIFI_UART_INDEX, "\r\n");
system_delay_ms(100);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+RST\r\n");
return_state = wifi_uart_wait_ack("ready", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 模块硬件复位
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_reset();
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_reset (void)
{
#if WIFI_UART_HARDWARE_RST
uint8 return_state = 0;
gpio_set_level(WIFI_UART_RST_PIN, 0);
system_delay_ms(50);
gpio_set_level(WIFI_UART_RST_PIN, 1);
system_delay_ms(200);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return_state = wifi_uart_wait_ack("ready", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
#else
return wifi_uart_soft_reset();
#endif
}
//--------------------------------------------------------------------------------------------------
// 函数简介 设置模块模式 (Station/SoftAP/Station+SoftAP)
// 参数说明 state 0:无 Wi-Fi 模式,并且关闭 Wi-Fi RF----1: Station 模式----2: SoftAP 模式----3: SoftAP+Station 模式
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_set_model("1");
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_set_model (wifi_uart_mode_enum mode)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
if(WIFI_UART_SOFTAP == mode)
{
uart_write_string(WIFI_UART_INDEX, "AT+CWMODE=2\r\n");
}
else
{
uart_write_string(WIFI_UART_INDEX, "AT+CWMODE=1\r\n");
}
// 设置模块工作模式
wifi_uart_information.wifi_uart_mode = mode;
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 断开与wifi的连接
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_disconnected_wifi();
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_disconnected_wifi (void)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CWQAP\r\n");
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 进入打开透传模式
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_entry_serianet();
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_entry_serianet (void)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPSEND\r\n");
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 退出透传模式
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_exit_serianet();
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_exit_serianet (void)
{
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
system_delay_ms(20);
uart_write_string(WIFI_UART_INDEX, "+++");
system_delay_ms(1000);
return 0;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 建立TCP连接
// 参数说明 ip 远端 IPv4 地址、IPv6 地址,或域名
// 参数说明 port 远端端口值
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_connect_tcp_servers("192.168.101.110", "8080");
// 备注信息 如果总是连接不上电脑的TCP服务器 可以尝试使用网线连接电脑
// 如果是使用WiFi连接 可能会导致模块连接TCP服务器等待较长时间
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_connect_tcp_servers (char *ip, char *port, wifi_uart_transfer_mode_enum mode)
{
zf_assert(NULL != ip);
zf_assert(NULL != port);
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
do
{
if(wifi_uart_set_connect_model("0"))
{
return_state = 1;
break;
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPSTARTEX=\"TCP\",\"");
uart_write_string(WIFI_UART_INDEX, ip);
uart_write_string(WIFI_UART_INDEX, "\",");
uart_write_string(WIFI_UART_INDEX, port);
uart_write_string(WIFI_UART_INDEX, "\r\n");
if(wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
return_state = 1;
wifi_uart_information.wifi_uart_connect_state = WIFI_UART_SERVER_OFF;
break;
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
// 设置传输模式
if(wifi_uart_set_transfer_model(WIFI_UART_COMMAND == mode ? "0" : "1"))
{
return_state = 1;
break;
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPSTATE?\r\n");
if(wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
return_state = 1;
break;
}
else
{
uint8 receiver_buffer[128];
uint32 receiver_len = 128;
fifo_read_buffer(&wifi_uart_fifo, receiver_buffer, &receiver_len, FIFO_READ_ONLY);
char* buffer_index = (char *)receiver_buffer;
char* end_index = NULL;
buffer_index += 22;
buffer_index += strlen(ip);
buffer_index += strlen(port);
end_index = strchr(buffer_index, ',');
memcpy(wifi_uart_information.wifi_uart_local_port, " ", 7);
memcpy(wifi_uart_information.wifi_uart_local_port, buffer_index, (end_index - buffer_index));
}
wifi_uart_information.wifi_uart_connect_state = WIFI_UART_SERVER_ON;
wifi_uart_information.wifi_uart_connect_mode = WIFI_UART_TCP_CLIENT;
wifi_uart_information.wifi_uart_transfer_mode = mode;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
if(WIFI_UART_SERIANET == mode) // 透传模式下直接开启透传
{
if(wifi_uart_entry_serianet())
{
return_state = 1;
break;
}
}
}while(0);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 建立UDP连接
// 参数说明 *ip 远端 IPv4 地址、IPv6 地址 或域名 字符串形式
// 参数说明 *port 远端端口值 字符串形式
// 参数说明 *local_port 远端 IPv4 地址、IPv6 地址 或域名 字符串形式
// 参数说明 mode 模块数据通信模式
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_connect_udp_client("192.168.101.110", "8080", "8080", WIFI_UART_COMMAND);
// 备注信息 自动分配ID
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_connect_udp_client (char *ip, char *port, char *local_port, wifi_uart_transfer_mode_enum mode)
{
zf_assert(NULL != ip);
zf_assert(NULL != port);
zf_assert(NULL != local_port);
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
do
{
if(wifi_uart_set_connect_model("0"))
{
return_state = 1;
break;
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPSTARTEX=\"UDP\",\"");
uart_write_string(WIFI_UART_INDEX, ip);
uart_write_string(WIFI_UART_INDEX, "\",");
uart_write_string(WIFI_UART_INDEX, port);
uart_write_string(WIFI_UART_INDEX, ",");
uart_write_string(WIFI_UART_INDEX, local_port);
uart_write_string(WIFI_UART_INDEX, "\r\n");
if(wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
return_state = 1;
wifi_uart_information.wifi_uart_connect_state = WIFI_UART_SERVER_OFF;
break;
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
if(wifi_uart_set_transfer_model(WIFI_UART_COMMAND == mode ? "0" : "1")) // 设置传输模式
{
return_state = 1;
break;
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
if(WIFI_UART_SERIANET == mode) // 透传模式下直接开启透传
{
if(wifi_uart_entry_serianet())
{
return_state = 1;
break;
}
}
memcpy(wifi_uart_information.wifi_uart_local_port, " ", 7);
memcpy(wifi_uart_information.wifi_uart_local_port, local_port, strlen(local_port));
wifi_uart_information.wifi_uart_connect_state = WIFI_UART_SERVER_ON;
wifi_uart_information.wifi_uart_connect_mode = WIFI_UART_UDP_CLIENT;
wifi_uart_information.wifi_uart_transfer_mode = mode;
}while(0);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 断开连接 TCP Server 使用本接口将会断开所有连接
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_disconnect_link();
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_disconnect_link (void)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
do
{
if(WIFI_UART_TCP_SERVER == wifi_uart_information.wifi_uart_connect_mode)
{
uart_write_string(WIFI_UART_INDEX, "AT+CIPCLOSE=5\r\n");
}
else
{
uart_write_string(WIFI_UART_INDEX, "AT+CIPCLOSE\r\n");
}
if(wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
return_state = 1;
wifi_uart_information.wifi_uart_connect_state = WIFI_UART_SERVER_OFF;
break;
}
}while(0);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 TCP Server 断开指定连接 TCP/UDP Client 将不会有反应
// 参数说明 link_id 将要断开的目标连接
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_disconnect_link_with_id(WIFI_UART_LINK_0);
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_disconnect_link_with_id (wifi_uart_link_id_enum link_id)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
do
{
if(WIFI_UART_TCP_SERVER == wifi_uart_information.wifi_uart_connect_mode)
{
uart_write_string(WIFI_UART_INDEX, "AT+CIPCLOSE=");
uart_write_byte(WIFI_UART_INDEX, link_id + 0x30);
uart_write_string(WIFI_UART_INDEX, "\r\n");
}
else
{
break;
}
if(wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
return_state = 1;
wifi_uart_information.wifi_uart_connect_state = WIFI_UART_SERVER_OFF;
break;
}
}while(0);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 建立 TCP 服务器
// 参数说明 *port 端口值 字符串形式
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_entry_tcp_servers("80");
// 备注信息 自动分配ID
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_entry_tcp_servers (char *port)
{
zf_assert(NULL != port);
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
do
{
if(wifi_uart_set_transfer_model("0")) // 设置传输模式为普通传输模式
{
return_state = 1;
break;
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
if(wifi_uart_set_connect_model("1")) // 设置连接模式为多连接模式
{
return_state = 1;
break;
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPSERVER=1,");
uart_write_string(WIFI_UART_INDEX, port);
uart_write_string(WIFI_UART_INDEX, "\r\n");
if(wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
return_state = 1;
wifi_uart_information.wifi_uart_connect_state = WIFI_UART_SERVER_OFF;
break;
}
memcpy(wifi_uart_information.wifi_uart_local_port, " ", 7);
memcpy(wifi_uart_information.wifi_uart_local_port, port, strlen(port));
wifi_uart_information.wifi_uart_connect_state = WIFI_UART_SERVER_ON;
wifi_uart_information.wifi_uart_transfer_mode = WIFI_UART_COMMAND;
wifi_uart_information.wifi_uart_connect_mode = WIFI_UART_TCP_SERVER;
}while(0);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 关闭 TCP 服务器
// 参数说明 void
// 返回参数 uint8 0成功 1失败
// 使用示例 wifi_uart_exit_tcp_servers();
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_exit_tcp_servers (void)
{
uint8 return_state = 0;
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPSERVER=0,1\r\n");
return_state = wifi_uart_wait_ack("OK", WAIT_TIME_OUT);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 TCP Server 模式下检查当前链接数量 并获取 IP
// 参数说明 void
// 返回参数 uint8 当前建立的连接数量
// 使用示例 wifi_uart_tcp_servers_check_link();
// 备注信息
//--------------------------------------------------------------------------------------------------
uint8 wifi_uart_tcp_servers_check_link (void)
{
uint8 return_value = 0;
uint8 loop_temp = 0;
uint8 linke_index = 0;
uint8 receiver_buffer[256];
uint32 receiver_len = 256;
char* buffer_index = NULL;
char* start_index = NULL;
char* end_index = NULL;
for(loop_temp = 0; 5 > loop_temp; loop_temp ++)
{
memset(wifi_uart_information.wifi_uart_remote_ip[loop_temp], 0, 15);
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_string(WIFI_UART_INDEX, "AT+CIPSTATE?\r\n");
if(0 == wifi_uart_wait_ack("OK", WAIT_TIME_OUT))
{
fifo_read_buffer(&wifi_uart_fifo, receiver_buffer, &receiver_len, FIFO_READ_ONLY);
buffer_index = (char *)receiver_buffer;
for(loop_temp = 0; 5 > loop_temp; loop_temp ++)
{
start_index = strchr(buffer_index, ':');
if(NULL == start_index)
{
break;
}
start_index ++;
linke_index = *(start_index) - 0x30;
start_index += 9;
end_index = strchr((const char *)(start_index), '"');
memset(wifi_uart_information.wifi_uart_remote_ip[linke_index], 0, 15);
memcpy(wifi_uart_information.wifi_uart_remote_ip[linke_index], start_index, (end_index - start_index));
buffer_index = end_index;
}
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_value;
}
//-------------------------------------------------------------------------------------------------------------------
// 函数简介 WiFi 模块 发送函数
// 参数说明 buff 需要发送的数据地址
// 参数说明 len 发送长度
// 返回参数 uint32 剩余未发送数据长度
// 使用示例 wifi_uart_send_buffer("123", 3);
// 备注信息 当模块作为TCP服务器时发送数据函数默认将数据发送至第一个连接模块的客户端
//-------------------------------------------------------------------------------------------------------------------
uint32 wifi_uart_send_buffer (const uint8 *buffer, uint32 len)
{
zf_assert(NULL != buffer);
int32 timeout = WAIT_TIME_OUT;
char lenth[32] = {0};
if(WIFI_UART_SERVER_ON == wifi_uart_information.wifi_uart_connect_state)
{
if(WIFI_UART_COMMAND == wifi_uart_information.wifi_uart_transfer_mode)
{
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
func_int_to_str(lenth,len);
if(8192 < len)
{
uart_write_string(WIFI_UART_INDEX, "AT+CIPSENDL=");
}
else
{
uart_write_string(WIFI_UART_INDEX, "AT+CIPSEND=");
}
if(WIFI_UART_TCP_SERVER == wifi_uart_information.wifi_uart_connect_mode)
{
uart_write_string(WIFI_UART_INDEX, "0,");
}
uart_write_string(WIFI_UART_INDEX, lenth);
uart_write_string(WIFI_UART_INDEX, "\r\n");
if(0 == wifi_uart_wait_ack("OK", WAIT_TIME_OUT)) // 等待模块响应
{
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_buffer(WIFI_UART_INDEX, buffer, len);
if(0 == wifi_uart_wait_ack("OK", WAIT_TIME_OUT)) // 等待模块响应
{
len = 0;
}
}
}
else
{
while(len --)
{
while(gpio_get_level(WIFI_UART_RTS_PIN) && 0 < timeout -- ); // 如果RTS为低电平则发送数据
if(0 >= timeout)
{
break;
}
uart_write_byte(WIFI_UART_INDEX, *buffer); // 发送最后的数据
buffer ++;
}
}
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return len;
}
//-------------------------------------------------------------------------------------------------------------------
// 函数简介 WiFi 模块作为 TCP 服务器 向指定目标设备发送函数
// 参数说明 buff 需要发送的数据地址
// 参数说明 len 发送长度
// 参数说明 id 目标 client id
// 返回参数 uint32 剩余未发送数据长度
// 使用示例 wifi_uart_tcp_servers_send_buffer("123", 3, WIFI_UART_LINK_0);
// 备注信息 当模块作为TCP服务器时发送数据函数默认将数据发送至第一个连接模块的客户端
//-------------------------------------------------------------------------------------------------------------------
uint32 wifi_uart_tcp_servers_send_buffer (uint8 *buff, uint32 len, wifi_uart_link_id_enum id)
{
zf_assert(NULL != buff);
char lenth[32] = {0};
if( WIFI_UART_COMMAND == wifi_uart_information.wifi_uart_transfer_mode && \
WIFI_UART_TCP_SERVER == wifi_uart_information.wifi_uart_connect_mode)
{
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
func_int_to_str(lenth,len);
if(8192 < len)
{
uart_write_string(WIFI_UART_INDEX, "AT+CIPSENDL=");
}
else
{
uart_write_string(WIFI_UART_INDEX, "AT+CIPSEND=");
}
uart_write_byte(WIFI_UART_INDEX, (id + '0'));
uart_write_string(WIFI_UART_INDEX, ",");
uart_write_string(WIFI_UART_INDEX, lenth);
uart_write_string(WIFI_UART_INDEX, "\r\n");
if(0 == wifi_uart_wait_ack("OK", WAIT_TIME_OUT)) // 等待模块响应
{
// 模块允许发送数据
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
uart_write_buffer(WIFI_UART_INDEX, buff, len);
if(0 == wifi_uart_wait_ack("OK", WAIT_TIME_OUT)) // 等待模块响应
{
len = 0;
}
}
}
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return len;
}
//-------------------------------------------------------------------------------------------------------------------
// 函数简介 WiFi 模块数据接收函数
// 参数说明 buffer 接收数据的存放地址
// 参数说明 len 数组长度可直接填写或者使用sizeof求得
// 返回参数 uint16 返回实际接收到的数据长度
// 使用示例 uint8 test_buffer[256]; wifi_uart_read_buffer(&test_buffer[0], sizeof(test_buffer));
// 备注信息
//-------------------------------------------------------------------------------------------------------------------
uint32 wifi_uart_read_buffer (uint8 *buffer, uint32 len)
{
zf_assert(NULL != buffer);
uint32 read_len = len;
fifo_read_buffer(&wifi_uart_fifo, buffer, &read_len, FIFO_READ_AND_CLEAN);
return read_len;
}
//--------------------------------------------------------------------------------------------------
// 函数简介 WiFi 串口回调函数
// 参数说明 void
// 返回参数 void
// 使用示例 wireless_uart_callback();
// 备注信息 该函数在 ISR 文件 串口中断程序被调用
// 由串口中断服务函数调用 wireless_module_uart_handler() 函数
// 再由 wireless_module_uart_handler() 函数调用本函数
//--------------------------------------------------------------------------------------------------
void wifi_uart_callback (void)
{
uart_query_byte(WIFI_UART_INDEX, &wifi_uart_data); // 读取串口数据
fifo_write_buffer(&wifi_uart_fifo, &wifi_uart_data, 1); // 存入 FIFO
}
//-------------------------------------------------------------------------------------------------------------------
// 函数简介 WiFi 模块初始化
// 参数说明 *wifi_ssid 目标连接的 WiFi 的名称 字符串形式
// 参数说明 *pass_word 目标连接的 WiFi 的密码 字符串形式
// 参数说明 wifi_mode 模块的工作模式 参照 zf_device_wireless_uart.h 中 wifi_uart_mode_enum 枚举
// 返回参数 uint8 模块初始化状态 0-成功 1-错误
// 使用示例 wifi_uart_init("SEEKFREE_2.4G", "SEEKFREEV2", WIFI_UART_STATION);
// 备注信息 初始化会首先设置串口配置,之后会对模块进行基本参数配置
// 具体的配置信息可以在 zf_device_wireless_uart.h 文件中修改
//-------------------------------------------------------------------------------------------------------------------
uint8 wifi_uart_init (char *wifi_ssid, char *pass_word, wifi_uart_mode_enum wifi_mode)
{
zf_assert(NULL != wifi_ssid);
zf_assert(NULL != pass_word);
char uart_baud[32] = {0};
uint8 return_state = 0;
// 设置模块类型
set_wireless_type(WIFI_UART, wifi_uart_callback);
fifo_init(&wifi_uart_fifo, FIFO_DATA_8BIT, wifi_uart_buffer, WIFI_UART_BUFFER_SIZE);
gpio_init(WIFI_UART_RTS_PIN, GPI, 0, GPI_PULL_UP); // 初始化流控引脚
#if WIFI_UART_HARDWARE_RST
gpio_init(WIFI_UART_RST_PIN, GPO, 1, GPO_PUSH_PULL); // 初始化复位引脚
#endif
uart_init(WIFI_UART_INDEX, 115200, WIFI_UART_RX_PIN, WIFI_UART_TX_PIN); // 初始化WiFi模块所使用的串口
uart_rx_interrupt(WIFI_UART_INDEX, 1);
do
{
if(wifi_uart_reset()) // 重启模块
{
// 检查一下 RST 引脚的连接
// 如果没有接 RST 引脚又启用了硬件复位
// 就会一直报错
// 如果禁用了硬件复位 使用软件复位
// 反复报错无法复位的话就断电重启一下
zf_log(0, "reset failed");
return_state = 1;
break;
}
func_int_to_str(uart_baud, WIFI_UART_BAUD); // 更改WiFi模块所使用的波尔率参数
if(wifi_uart_uart_config_set(uart_baud, "8", "1", "0", "1")) // 调用接口重设模块的工作串口参数
{
zf_log(0, "set config failed");
return_state = 1;
break;
}
// 重新初始化WiFi模块所使用的串口
uart_init(WIFI_UART_INDEX, WIFI_UART_BAUD, WIFI_UART_RX_PIN, WIFI_UART_TX_PIN);
uart_rx_interrupt(WIFI_UART_INDEX, 1);
system_delay_ms(100);
if(wifi_uart_echo_set("0")) // 关闭模块回写
{
zf_log(0, "exit echo failed");
return_state = 1;
break;
}
if(wifi_uart_auto_connect_wifi("0")) // 关闭自动连接
{
zf_log(0, "close auto connect failed");
return_state = 1;
break;
}
if(wifi_uart_set_model(wifi_mode)) // 设置运行模式
{
zf_log(0, "set run mode failed");
return_state = 1;
break;
}
if(wifi_uart_set_wifi((char *)wifi_ssid, (char *)pass_word)) // 连接 wifi 或者开启热点
{
zf_log(0, "wifi set failed");
return_state = 1;
break;
}
if(wifi_uart_get_information()) // 模块基本参数获取
{
zf_log(0, "get module information failed");
return_state = 1;
break;
}
// zf_log(0, "seekfree wifi uart init succeed");
#if WIFI_UART_AUTO_CONNECT == 1
if(wifi_uart_connect_tcp_servers(WIFI_UART_TARGET_IP, WIFI_UART_TARGET_PORT,WIFI_UART_COMMAND)) // 连接TCP服务器
{
zf_log(0, "connect TCP server failed");
return_state = 1;
break;
}
// zf_log(0, "connect TCP client succeed");
#endif
#if WIFI_UART_AUTO_CONNECT == 2
if(wifi_uart_connect_udp_transfer(WIFI_UART_TARGET_IP, WIFI_UART_TARGET_PORT, WIFI_UART_LOCAL_PORT, WIFI_UART_SERIANET))// 建立UDP连接
{
zf_log(0, "connect UDP server failed");
return_state = 1;
break;
}
// zf_log(0, "connect UDP server succeed");
#endif
#if WIFI_UART_AUTO_CONNECT == 3
if(wifi_uart_entry_tcp_servers(WIFI_UART_LOCAL_PORT)) // 建立TCP服务器
{
zf_log(0, "build TCP server failed");
return_state = 1;
break;
}
// zf_log(0, "build TCP server succeed");
#endif
}while(0);
wifi_uart_clear_receive_buffer(); // 清空WiFi接收缓冲区
return return_state;
}
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