关于c:Linux网络开发必学教程20物联网设备-WIFI-模块实现非必要

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问题:如何在设施上进行 WIFI 编程?

Lwip (Light weight IP) 简介

  • Lwip 是轻量化的 TCP/IP,是一个小型开源的 TCP/IP 协定栈
  • LwIP 的设计指标是用较少的资源实现实现的 TCP/IP 协定栈
  • Lwip 能在操作系统中运行,也能在无操作系统的状况下独立运行
  • Lwip 提供了 Socket API 和 Netconn API

Lwip 的次要个性

  • 反对 ARP, ICMP, IGMP
  • 反对 UDP, TCP, IP(可执行网络通讯框架)
  • 反对 DNS, PPP, SNMP
  • 直至 DHCP, 可动态分配 IP(WIFI 反对)
  • 。。。

BearPi-Nano 联网能力

  • BearPi-Nano 基于 Hi3861 芯片构建,而 Hi3861 本身具备 Wifi 能力

    • AP 模式:工作于 WIFI 热点模式,可被其它设施以 WIFI 形式连贯
    • STA 模式:工作于 WIFI 连贯模式,可连贯到指定 WIFI 热点

WIFI 模块接口设计

init Wifi_Init(void);
init Wifi_Connect(const char *id, const char *pwd);
int Wifi_Start(void);
int Wifi_IsOk(void);
void Wifi_Stop(void);
char *Wifi_IpAddr(void);

波及的 OH 零碎接口

WifiErrorCode RegisterWifiEvent(WifiEvent *event);
WifiErrorCode EnableWifi(void);
WifiErrorCode AddDeviceConfig(const WifiDeviceConfig *config, int result);
WifiErrorCode ConnetTo(int networkid);  // 通过网络标识连贯到指标热点
struct netif *netifapi_netif_find(const char *name);  // 获取 netif 构造体用于后续 dhcp 操作
err_t dhcp_start(struct netif *netif);  // 启动 hdcp, 获取 ip

WIFI 热点连贯流程

WIFI 联网要害参数实现

int Wifi_Init(void)
{
    g_WifiEventHandler.OnWifiScanStateChanged = OnWifiScanStateChanged;
    g_WifiEventHandler.OnWifiConnectionChanged = OnWifiConnectionChanged;
    g_WifiEventHandler.OnHotspotStaJoin = OnHotspotStaJoin;
    g_WifiEventHandler.OnHotspotStaLeave = OnHotspotStaLeave;
    g_WifiEventHandler.OnHotspotStateChanged = OnHotspotStateChanged;

    return RegisterWifiEvent(&g_WifiEventHandler);
}
int Wifi_Connect(const char* id, const char* pwd)
{
    int ret = WIFI_SUCCESS;

    if(!Wifi_IsOk() )
    {ret = id && pwd ? EnableWifi() : ERROR_WIFI_UNKNOWN;
        // ret = (ret == WIFI_SUCCESS) ? && IsWifiActive() ? WIFI_SUCCESS : ERROR_WIFI_NOT_AVAILABLE;

        if(ret == WIFI_SUCCESS)
        {WifiDeviceConfig config = {0};
            int result = 0;

            config.securityType = WIFI_SEC_TYPE_PSK;

            strcpy(config.ssid, id);
            strcpy(config.preSharedKey, pwd);

            ret += AddDeviceConfig(&config, &result);
            ret += ConnectTo(result);

            if(ret == WIFI_SUCCESS)
            {ClearWaitResult();

                ToWait(WIFI_TIMEOUT);

                ret = (GetWaitResult() > 0) ? WIFI_SUCCESS : ERROR_WIFI_UNKNOWN;
            }
        }
    }

    return ret;
}
int Wifi_Start(void)
{
    int ret = WIFI_SUCCESS;

    if(!Wifi_IsOk() )
    {g_LwipNetif = netifapi_netif_find(WLAN_PORT);

        if(g_LwipNetif)
        {
            int i = WIFI_TIMEOUT;

            if(dhcp_start(g_LwipNetif) == ERR_OK )
            {while( ((ret = dhcp_is_bound(g_LwipNetif)) != ERR_OK) && i-- )
                {usleep(200 * 1000);
                }
            }

            if(ret != WIFI_SUCCESS)
            {Wifi_Stop();
            }
        }
        else
        {ret = ERROR_WIFI_UNKNOWN;}
    }

    return ret;
}

编程试验

main_entry.c

#include <stdio.h>
#include <unistd.h>
#include "ohos_init.h"
#include "cmsis_os2.h"
#include "wifi_connect.h"

static void* Init_Task(const char* arg)
{Wifi_Init();
    Wifi_Connect("Py4OH-Test", "12345678");
    Wifi_Start();

    if(Wifi_IsOk() )
    {printf("IP: %s\n", Wifi_IpAddr());
    }

    return arg;
}

static void Main_Entry(void)
{osThreadAttr_t attr = {0};
    
    attr.name = "Init Task";
    attr.stack_size = 1024 * 4;
    attr.priority = 20;

    if(osThreadNew((osThreadFunc_t)Init_Task, NULL, &attr) == NULL )
    {printf("[dt4sw] Failed to create task!\n");
    }
}

SYS_RUN(Main_Entry);

wifi_connect.h


#ifndef WIFI_CONNECT_H
#define WIFI_CONNECT_H

int Wifi_Init(void);
int Wifi_Connect(const char* id, const char* pwd);
int Wifi_Start(void);
int Wifi_IsOk(void);
void Wifi_Stop(void);
char* Wifi_IpAddr(void);

#endif

wifi_connect.c

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

#include "wifi_connect.h"
#include "wifi_device.h"
#include "lwip/netif.h"
#include "lwip/netifapi.h"
#include "lwip/ip4_addr.h"
#include "lwip/api_shell.h"
#include "lwip/dhcp.h"

#define WIFI_TIMEOUT 20
#define WLAN_PORT    "wlan0"

static int g_WaitResult = 0;
static WifiEvent g_WifiEventHandler = {0};
static struct netif* g_LwipNetif = NULL;

static void ClearWaitResult(void)
{g_WaitResult = 0;}

static void SetWaitResult(int result)
{g_WaitResult = result;}

static int GetWaitResult(void)
{return g_WaitResult;}

static void ToWait(unsigned int sec)
{while( sec-- && !GetWaitResult() )
    {sleep(1);
    }
}

static void OnWifiScanStateChanged(int state, int size)
{(void)state;
    (void)size;
}

static void OnWifiConnectionChanged(int state, WifiLinkedInfo *info)
{(void)info;

    SetWaitResult(state);
}

static void OnHotspotStaJoin(StationInfo *info)
{(void)info;
}

static void OnHotspotStateChanged(int state)
{(void)state;
}

static void OnHotspotStaLeave(StationInfo *info)
{(void)info;
}

int Wifi_Init(void)
{
    g_WifiEventHandler.OnWifiScanStateChanged = OnWifiScanStateChanged;
    g_WifiEventHandler.OnWifiConnectionChanged = OnWifiConnectionChanged;
    g_WifiEventHandler.OnHotspotStaJoin = OnHotspotStaJoin;
    g_WifiEventHandler.OnHotspotStaLeave = OnHotspotStaLeave;
    g_WifiEventHandler.OnHotspotStateChanged = OnHotspotStateChanged;

    return RegisterWifiEvent(&g_WifiEventHandler);
}

int Wifi_Connect(const char* id, const char* pwd)
{
    int ret = WIFI_SUCCESS;

    if(!Wifi_IsOk() )
    {ret = id && pwd ? EnableWifi() : ERROR_WIFI_UNKNOWN;
        // ret = (ret == WIFI_SUCCESS) ? && IsWifiActive() ? WIFI_SUCCESS : ERROR_WIFI_NOT_AVAILABLE;

        if(ret == WIFI_SUCCESS)
        {WifiDeviceConfig config = {0};
            int result = 0;

            config.securityType = WIFI_SEC_TYPE_PSK;

            strcpy(config.ssid, id);
            strcpy(config.preSharedKey, pwd);

            ret += AddDeviceConfig(&config, &result);
            ret += ConnectTo(result);

            if(ret == WIFI_SUCCESS)
            {ClearWaitResult();

                ToWait(WIFI_TIMEOUT);

                ret = (GetWaitResult() > 0) ? WIFI_SUCCESS : ERROR_WIFI_UNKNOWN;
            }
        }
    }

    return ret;
}

int Wifi_Start(void)
{
    int ret = WIFI_SUCCESS;

    if(!Wifi_IsOk() )
    {g_LwipNetif = netifapi_netif_find(WLAN_PORT);

        if(g_LwipNetif)
        {
            int i = WIFI_TIMEOUT;

            if(dhcp_start(g_LwipNetif) == ERR_OK )
            {while( ((ret = dhcp_is_bound(g_LwipNetif)) != ERR_OK) && i-- )
                {usleep(200 * 1000);
                }
            }

            if(ret != WIFI_SUCCESS)
            {Wifi_Stop();
            }
        }
        else
        {ret = ERROR_WIFI_UNKNOWN;}
    }

    return ret;
}

int Wifi_IsOk(void)
{return !!g_LwipNetif;}

void Wifi_Stop(void)
{dhcp_stop(g_LwipNetif);

    g_LwipNetif = NULL;
}

char* Wifi_IpAddr(void)
{
    char* ret = NULL;
    
    if(Wifi_IsOk() )
    {ip4_addr_t addr = {0};
        ip4_addr_t mask = {0};
        ip4_addr_t gw = {0};

        netif_get_addr(g_LwipNetif, &addr, &mask, &gw);

        if((addr.addr != 0) && (addr.addr != -1) )
        {ret = ip4addr_ntoa(&addr);
        }
        else
        {Wifi_Stop();
        }
    }

    return ret;
}

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