Servidor de Pipe Multithreaded
O exemplo a seguir é um servidor de pipe multithreaded. Ele tem um thread main com um loop que cria uma instância de pipe e aguarda a conexão de um cliente de pipe. Quando um cliente de pipe se conecta, o servidor de pipe cria um thread para atender a esse cliente e, em seguida, continua a executar o loop no thread main. É possível que um cliente de pipe se conecte com êxito à instância de pipe no intervalo entre chamadas para as funções CreateNamedPipe e ConnectNamedPipe . Se isso acontecer, ConnectNamedPipe retornará zero e GetLastError retornará ERROR_PIPE_CONNECTED.
O thread criado para atender a cada instância de pipe lê solicitações do pipe e grava respostas no pipe até que o cliente de pipe feche seu identificador. Quando isso acontece, o thread libera o pipe, desconecta, fecha a alça do pipe e termina. O thread main será executado até que ocorra um erro ou o processo seja encerrado.
Esse servidor de pipe pode ser usado com o cliente de pipe descrito em Cliente de Pipe Nomeado.
#include <windows.h>
#include <stdio.h>
#include <tchar.h>
#include <strsafe.h>
#define BUFSIZE 512
DWORD WINAPI InstanceThread(LPVOID);
VOID GetAnswerToRequest(LPTSTR, LPTSTR, LPDWORD);
int _tmain(VOID)
{
BOOL fConnected = FALSE;
DWORD dwThreadId = 0;
HANDLE hPipe = INVALID_HANDLE_VALUE, hThread = NULL;
LPCTSTR lpszPipename = TEXT("\\\\.\\pipe\\mynamedpipe");
// The main loop creates an instance of the named pipe and
// then waits for a client to connect to it. When the client
// connects, a thread is created to handle communications
// with that client, and this loop is free to wait for the
// next client connect request. It is an infinite loop.
for (;;)
{
_tprintf( TEXT("\nPipe Server: Main thread awaiting client connection on %s\n"), lpszPipename);
hPipe = CreateNamedPipe(
lpszPipename, // pipe name
PIPE_ACCESS_DUPLEX, // read/write access
PIPE_TYPE_MESSAGE | // message type pipe
PIPE_READMODE_MESSAGE | // message-read mode
PIPE_WAIT, // blocking mode
PIPE_UNLIMITED_INSTANCES, // max. instances
BUFSIZE, // output buffer size
BUFSIZE, // input buffer size
0, // client time-out
NULL); // default security attribute
if (hPipe == INVALID_HANDLE_VALUE)
{
_tprintf(TEXT("CreateNamedPipe failed, GLE=%d.\n"), GetLastError());
return -1;
}
// Wait for the client to connect; if it succeeds,
// the function returns a nonzero value. If the function
// returns zero, GetLastError returns ERROR_PIPE_CONNECTED.
fConnected = ConnectNamedPipe(hPipe, NULL) ?
TRUE : (GetLastError() == ERROR_PIPE_CONNECTED);
if (fConnected)
{
printf("Client connected, creating a processing thread.\n");
// Create a thread for this client.
hThread = CreateThread(
NULL, // no security attribute
0, // default stack size
InstanceThread, // thread proc
(LPVOID) hPipe, // thread parameter
0, // not suspended
&dwThreadId); // returns thread ID
if (hThread == NULL)
{
_tprintf(TEXT("CreateThread failed, GLE=%d.\n"), GetLastError());
return -1;
}
else CloseHandle(hThread);
}
else
// The client could not connect, so close the pipe.
CloseHandle(hPipe);
}
return 0;
}
DWORD WINAPI InstanceThread(LPVOID lpvParam)
// This routine is a thread processing function to read from and reply to a client
// via the open pipe connection passed from the main loop. Note this allows
// the main loop to continue executing, potentially creating more threads of
// of this procedure to run concurrently, depending on the number of incoming
// client connections.
{
HANDLE hHeap = GetProcessHeap();
TCHAR* pchRequest = (TCHAR*)HeapAlloc(hHeap, 0, BUFSIZE*sizeof(TCHAR));
TCHAR* pchReply = (TCHAR*)HeapAlloc(hHeap, 0, BUFSIZE*sizeof(TCHAR));
DWORD cbBytesRead = 0, cbReplyBytes = 0, cbWritten = 0;
BOOL fSuccess = FALSE;
HANDLE hPipe = NULL;
// Do some extra error checking since the app will keep running even if this
// thread fails.
if (lpvParam == NULL)
{
printf( "\nERROR - Pipe Server Failure:\n");
printf( " InstanceThread got an unexpected NULL value in lpvParam.\n");
printf( " InstanceThread exitting.\n");
if (pchReply != NULL) HeapFree(hHeap, 0, pchReply);
if (pchRequest != NULL) HeapFree(hHeap, 0, pchRequest);
return (DWORD)-1;
}
if (pchRequest == NULL)
{
printf( "\nERROR - Pipe Server Failure:\n");
printf( " InstanceThread got an unexpected NULL heap allocation.\n");
printf( " InstanceThread exitting.\n");
if (pchReply != NULL) HeapFree(hHeap, 0, pchReply);
return (DWORD)-1;
}
if (pchReply == NULL)
{
printf( "\nERROR - Pipe Server Failure:\n");
printf( " InstanceThread got an unexpected NULL heap allocation.\n");
printf( " InstanceThread exitting.\n");
if (pchRequest != NULL) HeapFree(hHeap, 0, pchRequest);
return (DWORD)-1;
}
// Print verbose messages. In production code, this should be for debugging only.
printf("InstanceThread created, receiving and processing messages.\n");
// The thread's parameter is a handle to a pipe object instance.
hPipe = (HANDLE) lpvParam;
// Loop until done reading
while (1)
{
// Read client requests from the pipe. This simplistic code only allows messages
// up to BUFSIZE characters in length.
fSuccess = ReadFile(
hPipe, // handle to pipe
pchRequest, // buffer to receive data
BUFSIZE*sizeof(TCHAR), // size of buffer
&cbBytesRead, // number of bytes read
NULL); // not overlapped I/O
if (!fSuccess || cbBytesRead == 0)
{
if (GetLastError() == ERROR_BROKEN_PIPE)
{
_tprintf(TEXT("InstanceThread: client disconnected.\n"));
}
else
{
_tprintf(TEXT("InstanceThread ReadFile failed, GLE=%d.\n"), GetLastError());
}
break;
}
// Process the incoming message.
GetAnswerToRequest(pchRequest, pchReply, &cbReplyBytes);
// Write the reply to the pipe.
fSuccess = WriteFile(
hPipe, // handle to pipe
pchReply, // buffer to write from
cbReplyBytes, // number of bytes to write
&cbWritten, // number of bytes written
NULL); // not overlapped I/O
if (!fSuccess || cbReplyBytes != cbWritten)
{
_tprintf(TEXT("InstanceThread WriteFile failed, GLE=%d.\n"), GetLastError());
break;
}
}
// Flush the pipe to allow the client to read the pipe's contents
// before disconnecting. Then disconnect the pipe, and close the
// handle to this pipe instance.
FlushFileBuffers(hPipe);
DisconnectNamedPipe(hPipe);
CloseHandle(hPipe);
HeapFree(hHeap, 0, pchRequest);
HeapFree(hHeap, 0, pchReply);
printf("InstanceThread exiting.\n");
return 1;
}
VOID GetAnswerToRequest( LPTSTR pchRequest,
LPTSTR pchReply,
LPDWORD pchBytes )
// This routine is a simple function to print the client request to the console
// and populate the reply buffer with a default data string. This is where you
// would put the actual client request processing code that runs in the context
// of an instance thread. Keep in mind the main thread will continue to wait for
// and receive other client connections while the instance thread is working.
{
_tprintf( TEXT("Client Request String:\"%s\"\n"), pchRequest );
// Check the outgoing message to make sure it's not too long for the buffer.
if (FAILED(StringCchCopy( pchReply, BUFSIZE, TEXT("default answer from server") )))
{
*pchBytes = 0;
pchReply[0] = 0;
printf("StringCchCopy failed, no outgoing message.\n");
return;
}
*pchBytes = (lstrlen(pchReply)+1)*sizeof(TCHAR);
}
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