在两个客户端套接字之间发送数据

我必须在Mac-OS上使用C套接字创建一个应用程序,它将数据从一个套接字发送到其他套接字,就像这样。

  1. 服务器等待连接
  2. 客户端连接到服务器(从1开始)。 – > socket1
  3. 服务器连接到外部服务器并获取套接字。 – > socket2

从现在开始,服务器工作就完成了。 数据交换应仅在客户端套接字(从2)和从3获得的套接字之间进行。

当前实现:服务器建立连接,然后从一个套接字读取数据并发送给其他套接字。

任何想法如何在第3步之后管道两个套接字socket1和socket2。

那么你的问题可以通过两种方式解决:

1)您需要编写与客户端和外部服务器之间的连接形成相关的部分。 但这会给客户端带来额外的过载,因为它需要与两台服务器建立两个连接(我强烈感觉中间服务器在这种情况下是无用的)。

2)解决它的第二种方法是在服务器之间传递套接字 :客户端连接到服务器,这个中间服务器将此套接字发送到外部服务器。 现在外部服务器开始与客户端通信。 仅当两个服务器进程在同一台机器上运行时,才能执行此操作。 文件描述符通常使用Unix Domain Sockets传递。

这是我的代码。 您可以使用这两个函数来发送或接收文件描述符。 它适用于我的Linux机器。 我不知道Mac-OS。

#include  #include  #include  #include  #include  #include  #include  #include  /* this function passes 'fd_to_send' file descriptor via a unix domain socket 'sfd'... */ void pass_fd(int sfd, int fd_to_send) { struct msghdr msg; /*allocate memory to 'msg_control' field in msghdr struct */ char buf[CMSG_SPACE(sizeof(int))]; /*the memory to be allocated should include data + header.. this is calculated by the above macro...(it merely adds some no. of bytes and returs that number..*/ struct cmsghdr *cmsg; struct iovec ve; /*must send/receive atleast one byte... main purpose is to have some error checking.. but this is completely irrelevant in the current context..*/ char *st ="I"; /*jst let us allocate 1 byte for formality and leave it that way...*/ ve.iov_base = st; ve.iov_len =1; /*attach this memory to our main msghdr struct...*/ msg.msg_iov = &ve; msg.msg_iovlen = 1; /*these are optional fields .. leave these fields with zeros.. to prevent unnecessary SIGSEGVs..*/ msg.msg_name = NULL; msg.msg_namelen = 0; /*here starts the main part..*/ /*attach the 'buf' to msg_control.. and fill in the size field correspondingly.. */ msg.msg_control = buf; msg.msg_controllen = sizeof(buf); /*actually msg_control field must point to a struct of type 'cmsghdr' we just allocated the memory, yet we need to set all the corresponding fields.. It is done as follows: */ cmsg = CMSG_FIRSTHDR(&msg); /* this macro returns the address in the buffer.. from where the first header starts.. */ /*set all the fields appropriately..*/ cmsg->cmsg_level = SOL_SOCKET; cmsg->cmsg_type = SCM_RIGHTS; cmsg->cmsg_len = CMSG_LEN(sizeof(fd_to_send)); /*in the above field we need to store the size of header + data(in this case 4 bytes(int) for our fd.. this is returned by the 'CMSG_LEN' macro..*/ *(int*)CMSG_DATA(cmsg) = fd_to_send; /*after the above three fields we keep the actual data.. the macro 'CMSG_DATA' returns pointer to this location and we set it to the file descriptor to be sent.. */ msg.msg_controllen = cmsg->cmsg_len; /*now that we have filled the 'cmsg' struct we store the size of this struct..*/ /*this one isn't required when you pass a single fd.. but useful when u pass multiple fds.*/ msg.msg_flags = 0; /*leave the flags field zeroed..*/ if(sendmsg( sfd, &msg, 0)==-1){ perror("snd:\n"); exit(1); } /*send this over the UNIX deomain socoket..*/ printf("sent fd:%d\n", fd_to_send); close(fd_to_send); /*close the fd which was sent..*/ } /*returns the received fd over the unix domain socket 'sfd'..*/ int recv_fd(int sfd) { struct msghdr msg; /*do all the unwanted things first... same as the send_fd function..*/ struct iovec io; char ptr[1]; io.iov_base = ptr; io.iov_len = 1; msg.msg_name = 0; msg.msg_namelen = 0; msg.msg_iov = &io; msg.msg_iovlen = 1; /*-----------------------*/ char buf[CMSG_SPACE(sizeof(int))]; msg.msg_control = buf; msg.msg_controllen = sizeof(buf); /*reasoning is same..as above*/ /*now here comes the main part..*/ if(recvmsg( sfd, &msg, 0)==-1) { /*some shit has happened*/ perror("recv\n"); exit(1); } struct cmsghdr *cm; cm = CMSG_FIRSTHDR(&msg); /*get the first message header..*/ if(cm->cmsg_type != SCM_RIGHTS) { /*again some shit has happened..*/ perror("unknown type..\n"); exit(1); } /*if control has reached here.. this means we have got the correct message..and when you extract the fd out of this message this need not be same as the one which was sent.. allocating a new fd is all done by the kernel and our job is jst to use it..*/ printf("received fd:%d\n", *(int*)CMSG_DATA(cm)); return *(int*)CMSG_DATA(cm); } 

在下面的例子中:

ClientOne和ClientTwo连接到服务器。 当服务器收到ClientOne和ClientTwo的套接字描述符时,它会将ClientOne的信息发送给ClientTwo,反之亦然。

它发送的信息是IP,客户端来自。 服务器关闭。

当每个客户端收到他们的信息时,会创建一个套接字并且它们彼此连接。 然后关闭服务器套接字。

套接字类:

 #include  #include  #include  #include  #include  #include  #include  #include  #include  class Socket { private: SOCKET socket; std::uint32_t Port; std::string Address; bool Listen, Initialized, Asynchronous; void Swap(Socket &S); void UnInitialized(); public: Socket(); Socket(std::uint32_t Port, std::string Address, bool Listen = false, bool Asynchronous = false); Socket(const Socket &S) = delete; Socket(Socket && S); ~Socket(); Socket& operator = (const Socket &S) = delete; Socket& operator = (Socket && S); int Recv(void* Buffer, std::uint32_t BufferLength); int Recv(SOCKET S, void* Buffer, std::uint32_t BufferLength); std::uint32_t RecvEx(void* Buffer, std::uint32_t BufferLength); std::uint32_t RecvEx(SOCKET S, void* Buffer, std::uint32_t BufferLength); int Send(void* Buffer, std::size_t BufferSize); int Send(SOCKET S, void* Buffer, std::size_t BufferSize); void Connect(); void Connect(std::uint32_t Port, std::string Address, bool Listen, bool Asynchronous); SOCKET Accept(sockaddr* ClientInfo, int* ClientInfoSize); void Close(); SOCKET GetSocket() const; }; Socket::~Socket() { Close(); } void Socket::Close() { if (socket) { shutdown(socket, SD_BOTH); closesocket(socket); socket = 0; } if (Initialized) { WSACleanup(); } } SOCKET Socket::GetSocket() const { return this->socket; } Socket::Socket(Socket && S) : socket(std::move(S.socket)), Port(std::move(S.Port)), Address(std::move(S.Address)), Listen(std::move(S.Listen)), Initialized(std::move(S.Initialized)), Asynchronous(std::move(S.Asynchronous)) {} Socket::Socket() : socket(0), Port(0), Address(std::string()), Listen(false), Initialized(false), Asynchronous(false) {} Socket::Socket(std::uint32_t Port, std::string Address, bool Listen, bool Asynchronous) : socket(0), Port(Port), Address(Address), Listen(Listen), Initialized(true), Asynchronous(Asynchronous) { Connect(Port, Address, Listen, Asynchronous); } void Socket::Connect() { UnInitialized(); Connect(Port, Address, Listen, Asynchronous); } void Socket::Connect(std::uint32_t Port, std::string Address, bool Listen, bool Asynchronous) { if (!socket) { this->Port = Port; this->Address = Address; this->Asynchronous = Asynchronous; this->Initialized = true; WSADATA wsaData; struct sockaddr_in* sockaddr_ipv4; if (WSAStartup(MAKEWORD(2, 2), &wsaData) != 0) { throw std::runtime_error("Error: WSAStartup Failed"); } if (Address != "INADDR_ANY") { if (Address.find("http://") != std::string::npos) { Address = Address.substr(7); } std::size_t Position = Address.find("/"); if (Position != std::string::npos) { Address = Address.substr(0, Position); } struct addrinfo *it = nullptr, *result = nullptr; getaddrinfo(Address.c_str(), nullptr, nullptr, &result); for (it = result; it != nullptr; it = it->ai_next) { sockaddr_ipv4 = reinterpret_cast(it->ai_addr); Address = inet_ntoa(sockaddr_ipv4->sin_addr); if (Address != "0.0.0.0") break; } freeaddrinfo(result); } if ((this->socket = ::socket(AF_INET, SOCK_STREAM, IPPROTO_TCP)) == INVALID_SOCKET) { this->Close(); throw std::runtime_error("Error: Failed to create socket"); } struct sockaddr_in SockAddr; memset(&SockAddr, 0, sizeof(SockAddr)); SockAddr.sin_port = htons(Port); SockAddr.sin_family = AF_INET; SockAddr.sin_addr.s_addr = (Address == "INADDR_ANY" ? htonl(INADDR_ANY) : inet_addr(Address.c_str())); if (Listen && (bind(this->socket, reinterpret_cast(&SockAddr), sizeof(SockAddr)) == SOCKET_ERROR)) { this->Close(); throw std::runtime_error("Error: Socket binding failed"); } if (Listen && (listen(this->socket, SOMAXCONN) == SOCKET_ERROR)) { this->Close(); throw std::runtime_error("Error: Socket Listening Failed"); } if(!Listen && (connect(this->socket, reinterpret_cast(&SockAddr), sizeof(SockAddr)) == SOCKET_ERROR)) { if(Asynchronous && WSAGetLastError() != WSAEWOULDBLOCK) { this->Close(); throw std::runtime_error("Error: Socket Connection failed"); } else if (!Asynchronous) { this->Close(); throw std::runtime_error("Error: Socket Connection failed"); } } } } SOCKET Socket::Accept(sockaddr* ClientInfo, int* ClientInfoSize) { static int Size = sizeof(sockaddr); return accept(this->socket, ClientInfo, (ClientInfo && ClientInfoSize ? ClientInfoSize : &Size)); } Socket& Socket::operator = (Socket && S) { S.Swap(*this); return *this; } int Socket::Recv(void* Buffer, std::uint32_t BufferLength) { return recv(this->socket, reinterpret_cast(Buffer), BufferLength, 0); } int Socket::Recv(SOCKET S, void* Buffer, std::uint32_t BufferLength) { return recv(S, reinterpret_cast(Buffer), BufferLength, 0); } std::uint32_t Socket::RecvEx(void* Buffer, std::uint32_t BufferLength) { return this->RecvEx(this->socket, Buffer, BufferLength); } std::uint32_t Socket::RecvEx(SOCKET S, void* Buffer, std::uint32_t BufferLength) { UnInitialized(); char* Pointer = reinterpret_cast(Buffer); std::uint32_t TotalRead = 0; while (BufferLength > 0) { int BytesRead = recv(S, Pointer, std::min(1024 * 1024, static_cast(BufferLength)), 0); if (BytesRead < 0) { if ((BytesRead == SOCKET_ERROR) && (WSAGetLastError() == WSAEWOULDBLOCK)) continue; throw std::runtime_error("Error! RecvEx: Failed To Read Bytes."); } if (BytesRead == 0) break; Pointer += BytesRead; BufferLength -= BytesRead; TotalRead += BytesRead; } return TotalRead; } int Socket::Send(void* Buffer, std::size_t BufferSize) { return send(this->socket, reinterpret_cast(Buffer), BufferSize, 0); } int Socket::Send(SOCKET S, void* Buffer, std::size_t BufferSize) { return send(S, reinterpret_cast(Buffer), BufferSize, 0); } void Socket::Swap(Socket &S) { using std::swap; swap(socket, S.socket); swap(Port, S.Port); swap(Address, S.Address); swap(Listen, S.Listen); swap(Initialized, S.Initialized); swap(Asynchronous, S.Asynchronous); } void Socket::UnInitialized() { if (!Initialized) { throw std::runtime_error("\nError! Socket Not Constructed!"); std::cout << "Socket Not Constructed!\n"; ExitProcess(0); } } 

Server.cpp:

 #include "Sockets.hpp" #define PORT 27015 #define ADDRESS INADDR_ANY #define CLIENTCOUNT 2 typedef struct { std::string ip; int port; SOCKET sock; } ClientInfo; template  inline T ReadPointer(TCHAR* &Pointer) { T Result = *(reinterpret_cast(Pointer)); Pointer += sizeof(T) / sizeof(TCHAR); return Result; } template  inline void WritePointer(TCHAR* &Pointer, const T& Value) { *(reinterpret_cast(Pointer)) = Value; Pointer += sizeof(T) / sizeof(TCHAR); } bool SendClient(ClientInfo* client, ClientInfo* receiver) { int datasize = sizeof(client->ip.size()) + client->ip.size() + sizeof(client->port); std::vector buffer(datasize, 0); char* ptr = &buffer[0]; WritePointer(ptr, client->ip.size()); for (std::size_t i = 0; i < client->ip.size(); ++i) WritePointer(ptr, client->ip[i]); WritePointer(ptr, client->port); std::cout << "Sending: " << &buffer[0] << "\n"; return send(receiver->sock, &buffer[0], datasize, 0) == datasize; } bool ReadClient(SOCKET sock, ClientInfo* client) { std::size_t ip_size = 0; recv(sock, (char*) &ip_size, sizeof(client->ip.size()), 0); client->ip.resize(ip_size); recv(sock, &client->ip[0], ip_size, 0); recv(sock, (char*) &client->port, sizeof(int), 0); std::cout<ip<<"\n"; return true; } int main() { Socket s; s.Connect(PORT, "localhost", true, false); char buffer[1024] = {0}; std::vector clients; while(true) { if (clients.size() < CLIENTCOUNT) { sockaddr_in ClientAddressInfo = {0}; SOCKET sock = s.Accept(reinterpret_cast(&ClientAddressInfo), nullptr); char* ip = inet_ntoa(ClientAddressInfo.sin_addr); int port = (int) ntohs(ClientAddressInfo.sin_port); ClientInfo info = {ip, port, sock}; clients.push_back(info); std::cout << "Client Connected From: " << ip << " on port: " << port << "\n"; } if (ReadAsync(s, buffer)) { std::cout << "Connected\n"; } std::this_thread::sleep_for(std::chrono::milliseconds(100)); if (clients.size() >= CLIENTCOUNT) { SendClient(&clients[0], &clients[1]); SendClient(&clients[1], &clients[0]); return 0; } } } 

Client.cpp:

 #define PORT 27015 #define ADDRESS INADDR_ANY #define CLIENTCOUNT 2 typedef struct { std::string ip; int port; SOCKET sock; } ClientInfo; template  inline T ReadPointer(TCHAR* &Pointer) { T Result = *(reinterpret_cast(Pointer)); Pointer += sizeof(T) / sizeof(TCHAR); return Result; } template  inline void WritePointer(TCHAR* &Pointer, const T& Value) { *(reinterpret_cast(Pointer)) = Value; Pointer += sizeof(T) / sizeof(TCHAR); } bool SendClient(ClientInfo* client, ClientInfo* receiver) { int datasize = sizeof(client->ip.size()) + client->ip.size() + sizeof(client->port); std::vector buffer(datasize, 0); char* ptr = &buffer[0]; WritePointer(ptr, client->ip.size()); for (std::size_t i = 0; i < client->ip.size(); ++i) WritePointer(ptr, client->ip[i]); WritePointer(ptr, client->port); std::cout << "Sending: " << &buffer[0] << "\n"; return send(receiver->sock, &buffer[0], datasize, 0) == datasize; } bool ReadClient(SOCKET sock, ClientInfo* client) { std::size_t ip_size = 0; recv(sock, (char*) &ip_size, sizeof(client->ip.size()), 0); client->ip.resize(ip_size); recv(sock, &client->ip[0], ip_size, 0); recv(sock, (char*) &client->port, sizeof(int), 0); return true; } bool ReadAsync(const Socket &sock, ClientInfo* client) { struct timeval tv; tv.tv_sec = 0; tv.tv_usec = 100000; fd_set rfds; FD_ZERO(&rfds); FD_SET(sock.GetSocket(), &rfds); for (int i = 0; i < 600; ++i) { if (select(sock.GetSocket(), &rfds, &rfds, NULL, &tv)) { return ReadClient(sock.GetSocket(), client); } tv.tv_sec = 0; tv.tv_usec = 100000; } return false; } int main() { Socket s; s.Connect(PORT, "localhost", false, false); std::vector clients; ClientInfo client = {}; while(true) { if (ReadAsync(s, &client)) { std::cout<<"IP: "<