重启路由器:qt5.8
#include <stdio.h>
#include <winsock2.h>
#include <QDebug>
#pragma comment( lib , "ws2_32" )
int main()
{
char Fs[1000];
char Js[1000];
WSADATA wsadata;
SOCKET Socket;
SOCKADDR_IN Local, to;
{
WSAStartup( 0x0202, &wsadata );
}
Socket = socket( AF_INET, SOCK_STREAM, 0 );
if (!Socket)
{
return -1;
}
Local.sin_family = AF_INET;
Local.sin_port = htons(102);
Local.sin_addr.S_un.S_addr = htonl(INADDR_ANY);
to.sin_family = AF_INET;
to.sin_port = htons(80);
to.sin_addr.S_un.S_addr = inet_addr("192.168.1.1");
if (bind(Socket, (SOCKADDR*)&Local, sizeof(Local)) == SOCKET_ERROR)
{
return -1;
}
if (connect(Socket, (SOCKADDR*)&to, sizeof(SOCKADDR)) == SOCKET_ERROR)
{
return -1;
}
{
memset(Fs, 0, 1000);
memset(Js, 0, 1000);
strcpy(Fs, "GET /userRpm/SysRebootRpm.htm?Reboot=%D6%D8%C6%F4%C2%B7%D3%C9%C6%F7 HTTP/1.1\r\n" );
strcat(Fs, "Host: 192.168.1.1\r\n" );
strcat(Fs, "Authorization: Basic YWRtaW46YWRtaW4=\r\n" );
strcat(Fs, "\r\n");
}
if (send(Socket, Fs, strlen(Fs), 0) == SOCKET_ERROR)
{
return -1;
}
closesocket(Socket);
WSACleanup();
qDebug()<<"sssss";
return 0;
}
c++获取路由表:
// libnet.cpp : 定义控制台应用程序的入口点。
//
#include "stdafx.h"
#include <stdio.h>
#include <windows.h>
#include <Iphlpapi.h>
#pragma comment(lib, "Iphlpapi.lib")
#pragma comment(lib, "WS2_32.lib")
PMIB_IPFORWARDTABLE MyGetIpForwardTable(BOOL bOrder);
void MyFreeIpForwardTable(PMIB_IPFORWARDTABLE pIpRouteTab);
void PrintIpForwardTable();
int main()
{
PrintIpForwardTable();
getchar();
return 0;
}
void PrintIpForwardTable()
{
PMIB_IPFORWARDTABLE pIpRouteTable = MyGetIpForwardTable(TRUE);
if (pIpRouteTable != NULL)
{
DWORD i, dwCurrIndex;
struct in_addr inadDest;
struct in_addr inadMask;
struct in_addr inadGateway;
PMIB_IPADDRTABLE pIpAddrTable = NULL;
char szDestIp[128];
char szMaskIp[128];
char szGatewayIp[128];
printf("Active Routes:\n\n");
printf(" Network Address Netmask Gateway Address Interface Metric\n");
for (i = 0; i < pIpRouteTable->dwNumEntries; i++)
{
dwCurrIndex = pIpRouteTable->table[i].dwForwardIfIndex;
// 目的地址
inadDest.s_addr = pIpRouteTable->table[i].dwForwardDest;
// 子网掩码
inadMask.s_addr = pIpRouteTable->table[i].dwForwardMask;
// 网关地址
inadGateway.s_addr = pIpRouteTable->table[i].dwForwardNextHop;
strcpy(szDestIp, inet_ntoa(inadDest));
strcpy(szMaskIp, inet_ntoa(inadMask));
strcpy(szGatewayIp, inet_ntoa(inadGateway));
printf(" %15s %16s %16s %16d %7d\n",
szDestIp,
szMaskIp,
szGatewayIp,
pIpRouteTable->table[i].dwForwardIfIndex, // 可以在此调用GetIpAddrTable获取索引对应的IP地址
pIpRouteTable->table[i].dwForwardMetric1);
}
MyFreeIpForwardTable(pIpRouteTable);
}
}
PMIB_IPFORWARDTABLE MyGetIpForwardTable(BOOL bOrder)
{
PMIB_IPFORWARDTABLE pIpRouteTab = NULL;
DWORD dwActualSize = 0;
// 查询所需缓冲区的大小
if (::GetIpForwardTable(pIpRouteTab, &dwActualSize, bOrder) == ERROR_INSUFFICIENT_BUFFER)
{
// 为MIB_IPFORWARDTABLE结构申请内存
pIpRouteTab = (PMIB_IPFORWARDTABLE)::GlobalAlloc(GPTR, dwActualSize);
// 获取路由表
if (::GetIpForwardTable(pIpRouteTab, &dwActualSize, bOrder) == NO_ERROR)
return pIpRouteTab;
::GlobalFree(pIpRouteTab);
}
return NULL;
}
void MyFreeIpForwardTable(PMIB_IPFORWARDTABLE pIpRouteTab)
{
if (pIpRouteTab != NULL)
::GlobalFree(pIpRouteTab);
}
本机流量监控类:
MFNetTraffic.h
#ifndef MFNetTraffic_H
#define MFNetTraffic_H
#if !defined(AFX_MFNETTRAFFIC_H__9CA9C41F_F929_4F26_BD1F_2B5827090494__INCLUDED_)
#define AFX_MFNETTRAFFIC_H__9CA9C41F_F929_4F26_BD1F_2B5827090494__INCLUDED_
#if _MSC_VER > 1000
#pragma once
#endif // _MSC_VER > 1000
#include <afxtempl.h>
class MFNetTraffic
{
public:
enum TrafficType //流量类型
{
AllTraffic = 388,//总的流量
IncomingTraffic = 264,//输入流量
OutGoingTraffic = 506 //输出流量
};
void SetTrafficType(int trafficType); //设置流量类型
DWORD GetInterfaceTotalTraffic(int index); //得到index索引接口的总流量
BOOL GetNetworkInterfaceName(CString *InterfaceName, int index);//得到网络接口名字
int GetNetworkInterfacesCount(); //得到接口的数目
double GetTraffic(int interfaceNumber); //得到流量
DWORD GetInterfaceBandwidth(int index); //得到index索引接口的带宽
MFNetTraffic();
virtual ~MFNetTraffic();
private:
BOOL GetInterfaces();
double lasttraffic;
CStringList Interfaces;
CList < DWORD, DWORD &> Bandwidths; //带宽
CList < DWORD, DWORD &> TotalTraffics;//总的流量
int CurrentInterface;
int CurrentTrafficType;
};
#endif // !defined(AFX_MFNETTRAFFIC_H__9CA9C41F_F929_4F26_BD1F_2B5827090494__INCLUDED_)
#endif // CARMODEL_H
MFNetTraffic.cpp
#include "stdafx.h"
#include "MFNetTraffic.h"
#include "float.h"
#ifdef _DEBUG
#undef THIS_FILE
static char THIS_FILE[] = __FILE__;
#define new DEBUG_NEW
#endif
#include "winperf.h"
MFNetTraffic::MFNetTraffic()
{
lasttraffic = 0.0;
CurrentInterface = -1;
CurrentTrafficType = AllTraffic;
GetInterfaces();
}
MFNetTraffic::~MFNetTraffic()
{
}
PERF_OBJECT_TYPE *FirstObject(PERF_DATA_BLOCK *dataBlock)
{
return (PERF_OBJECT_TYPE *)((BYTE *)dataBlock + dataBlock->HeaderLength);
}
PERF_OBJECT_TYPE *NextObject(PERF_OBJECT_TYPE *act)
{
return (PERF_OBJECT_TYPE *)((BYTE *)act + act->TotalByteLength);
}
PERF_COUNTER_DEFINITION *FirstCounter(PERF_OBJECT_TYPE *perfObject)
{
return (PERF_COUNTER_DEFINITION *)((BYTE *)perfObject + perfObject->HeaderLength);
}
PERF_COUNTER_DEFINITION *NextCounter(PERF_COUNTER_DEFINITION *perfCounter)
{
return (PERF_COUNTER_DEFINITION *)((BYTE *)perfCounter + perfCounter->ByteLength);
}
PERF_COUNTER_BLOCK *GetCounterBlock(PERF_INSTANCE_DEFINITION *pInstance)
{
return (PERF_COUNTER_BLOCK *)((BYTE *)pInstance + pInstance->ByteLength);
}
PERF_INSTANCE_DEFINITION *FirstInstance(PERF_OBJECT_TYPE *pObject)
{
return (PERF_INSTANCE_DEFINITION *)((BYTE *)pObject + pObject->DefinitionLength);
}
PERF_INSTANCE_DEFINITION *NextInstance(PERF_INSTANCE_DEFINITION *pInstance)
{
PERF_COUNTER_BLOCK *pCtrBlk = GetCounterBlock(pInstance);
return (PERF_INSTANCE_DEFINITION *)((BYTE *)pInstance + pInstance->ByteLength + pCtrBlk->ByteLength);
}
char *WideToMulti(wchar_t *source, char *dest, int size)
{
WideCharToMultiByte(CP_ACP, 0, source, -1, dest, size, 0, 0);
return dest;
}
//得到接口号为interfaceNumber的接口流量
double MFNetTraffic::GetTraffic(int interfaceNumber)
{
try
{
#define DEFAULT_BUFFER_SIZE 40960L
POSITION pos;
CString InterfaceName;
pos = Interfaces.FindIndex(interfaceNumber);
if (pos == NULL)
return 0.0;
//得到当前的接口名字
InterfaceName = Interfaces.GetAt(pos);
//为性能数据缓冲
unsigned char *data = new unsigned char[DEFAULT_BUFFER_SIZE];
// 从RegQueryValueEx返回的值:本例中忽略改变量
DWORD type;
// 缓冲的尺寸
DWORD size = DEFAULT_BUFFER_SIZE;
// RegQueryValueEx返回的值
DWORD ret;
// 从网络对象(索引是510)查询性能数据
while ((ret = RegQueryValueEx(HKEY_PERFORMANCE_DATA, L"510", NULL, &type, data, &size)) != ERROR_SUCCESS)
{
if (ret == ERROR_MORE_DATA)
{
// 缓冲尺寸太小,增加内存分配
size += DEFAULT_BUFFER_SIZE;
delete[] data;
data = new unsigned char[size];
}
else
{
// 未定义的错误
return 1;
}
}
//性能数据块
PERF_DATA_BLOCK *dataBlockPtr = (PERF_DATA_BLOCK *)data;
//枚举链表中第一个对象
PERF_OBJECT_TYPE *objectPtr = FirstObject(dataBlockPtr);
//遍历链表
for (int a = 0; a<(int)dataBlockPtr->NumObjectTypes; a++)
{
char nameBuffer[255];
// 判断是否是网络对象索引号是510
if (objectPtr->ObjectNameTitleIndex == 510)
{
// 偏移变量
DWORD processIdOffset = ULONG_MAX;
// 找到第一个计数器
PERF_COUNTER_DEFINITION *counterPtr = FirstCounter(objectPtr);
// 遍历链表
for (int b = 0; b<(int)objectPtr->NumCounters; b++)
{
// 判断接收的数据类型是否是我们需要的
if ((int)counterPtr->CounterNameTitleIndex == CurrentTrafficType)
processIdOffset = counterPtr->CounterOffset;
// 下一个计数器
counterPtr = NextCounter(counterPtr);
}
//数据类型不是我们需要的
if (processIdOffset == ULONG_MAX) {
delete[] data;
return 1;
}
// 找到第一个实列(instance)
PERF_INSTANCE_DEFINITION *instancePtr = FirstInstance(objectPtr);
DWORD fullTraffic;
DWORD traffic;
//遍历整个实列
for (int b = 0; b<objectPtr->NumInstances; b++)
{
wchar_t *namePtr = (wchar_t *)((BYTE *)instancePtr + instancePtr->NameOffset);
// 得到这个实列的PERF_COUNTER_BLOCK
PERF_COUNTER_BLOCK *counterBlockPtr = GetCounterBlock(instancePtr);
// 现在我们得到了接口的名字
char *pName = WideToMulti(namePtr, nameBuffer, sizeof(nameBuffer));
CString iName;
wchar_t str_s[20] = { L"%s" };
iName.Format(str_s, pName);
POSITION pos = TotalTraffics.FindIndex(b);
if (pos != NULL)
{
fullTraffic = *((DWORD *)((BYTE *)counterBlockPtr + processIdOffset));
TotalTraffics.SetAt(pos, fullTraffic);
}
// 如果当前的接口就是我们选择的接口
if (InterfaceName == iName)
{
traffic = *((DWORD *)((BYTE *)counterBlockPtr + processIdOffset));
double acttraffic = (double)traffic;
double trafficdelta;
// 判断处理的接口是否是新的
if (CurrentInterface != interfaceNumber)
{
lasttraffic = acttraffic;
trafficdelta = 0.0;
CurrentInterface = interfaceNumber;
}
else
{
trafficdelta = acttraffic - lasttraffic;
lasttraffic = acttraffic;
}
delete[] data;
return(trafficdelta);
}
//下一个实列
instancePtr = NextInstance(instancePtr);
}
}
// 下一个对象
objectPtr = NextObject(objectPtr);
}
delete[] data;
return 0;
}
catch (...)
{
return 0;
}
}
//枚举安装的接口
BOOL MFNetTraffic::GetInterfaces()
{
try
{
#define DEFAULT_BUFFER_SIZE 40960L
Interfaces.RemoveAll();
unsigned char *data = (unsigned char*)malloc(DEFAULT_BUFFER_SIZE);
DWORD type;
DWORD size = DEFAULT_BUFFER_SIZE;
DWORD ret;
char s_key[4096];
sprintf(s_key, "%d", 510);
WCHAR wszClassName[256] = { 0 };//定义宽字符缓冲区
memset(wszClassName, 0, sizeof(wszClassName));
MultiByteToWideChar(CP_ACP, 0, s_key, strlen(s_key) + 1,
wszClassName,
sizeof(wszClassName) / sizeof(wszClassName[0]));
//RegQueryValueEx的固定调用格式
while ((ret = RegQueryValueEx(HKEY_PERFORMANCE_DATA, wszClassName, 0, &type, data, &size)) != ERROR_SUCCESS) {
while (ret == ERROR_MORE_DATA)
{
size += DEFAULT_BUFFER_SIZE;
data = (unsigned char*)realloc(data, size);
}
if (ret != ERROR_SUCCESS)
{
return FALSE;
}
}
//得到数据块
PERF_DATA_BLOCK *dataBlockPtr = (PERF_DATA_BLOCK *)data;
//得到第一个对象
PERF_OBJECT_TYPE *objectPtr = FirstObject(dataBlockPtr);
for (int a = 0; a<(int)dataBlockPtr->NumObjectTypes; a++)
{
char nameBuffer[255];
if (objectPtr->ObjectNameTitleIndex == 510)
{
DWORD processIdOffset = ULONG_MAX;
PERF_COUNTER_DEFINITION *counterPtr = FirstCounter(objectPtr);
for (int b = 0; b<(int)objectPtr->NumCounters; b++)
{
if (counterPtr->CounterNameTitleIndex == 520)
processIdOffset = counterPtr->CounterOffset;
counterPtr = NextCounter(counterPtr);
}
if (processIdOffset == ULONG_MAX) {
free(data);
return 1;
}
PERF_INSTANCE_DEFINITION *instancePtr = FirstInstance(objectPtr);
for (int b = 0; b<objectPtr->NumInstances; b++)
{
wchar_t *namePtr = (wchar_t *)((BYTE *)instancePtr + instancePtr->NameOffset);
PERF_COUNTER_BLOCK *counterBlockPtr = GetCounterBlock(instancePtr);
char *pName = WideToMulti(namePtr, nameBuffer, sizeof(nameBuffer));
DWORD bandwith = *((DWORD *)((BYTE *)counterBlockPtr + processIdOffset));
DWORD tottraff = 0;
Interfaces.AddTail(CString(pName));
Bandwidths.AddTail(bandwith);
TotalTraffics.AddTail(tottraff);
instancePtr = NextInstance(instancePtr);
}
}
objectPtr = NextObject(objectPtr);
}
free(data);
return TRUE;
}
catch (...)
{
return FALSE;
}
}
//返回安装的接口数
int MFNetTraffic::GetNetworkInterfacesCount()
{
return Interfaces.GetCount() - 1;
}
//返回接口名称
BOOL MFNetTraffic::GetNetworkInterfaceName(CString *InterfaceName, int index)
{
POSITION pos = Interfaces.FindIndex(index);
if (pos == NULL)
return FALSE;
wchar_t strname[20] = {L"%s"};
InterfaceName->Format(strname, Interfaces.GetAt(pos));
return TRUE;
}
//返回接口带宽
DWORD MFNetTraffic::GetInterfaceBandwidth(int index)
{
POSITION pos = Bandwidths.FindIndex(index);
if (pos == NULL)
return 0;
else
return Bandwidths.GetAt(pos) / 8;
}
//具体接口接收和发送的数据量
DWORD MFNetTraffic::GetInterfaceTotalTraffic(int index)
{
DWORD totaltraffic = 0;
POSITION pos;
pos = TotalTraffics.FindIndex(index);
if (pos != NULL)
{
totaltraffic = TotalTraffics.GetAt(pos);
if (totaltraffic == 0.0)
{
GetTraffic(index);
pos = TotalTraffics.FindIndex(index);
if (pos != NULL)
{
totaltraffic = TotalTraffics.GetAt(pos);
}
}
}
return(totaltraffic);
}
void MFNetTraffic::SetTrafficType(int trafficType)
{
CurrentTrafficType = trafficType;
}
