Uso di SSPI con un server Windows Sockets
Questo programma di esempio funziona con il programma client Using SSPI with a Windows Sockets Client .This sample program works with the client using SSPI with a Windows Sockets Client. Entrambi i programmi di esempio usano il file di intestazione SspiExample.h, disponibile in File di intestazione per esempi di client SSPI e server.
Questo programma include chiamate alle funzioni in Secur32.lib e Ws2_32.lib, che devono essere incluse tra le librerie di collegamento.
Questo programma illustra quanto segue:
- Stabilire una connessione Windows Sockets con un client.
- Inizializzazione di una sessione.
- Connessione con un client e creazione di una sessione di comunicazione sicura. Il server offre il provider di servizi condivisi Negotiate che può rispondere al client con NTLM o Kerberos.
- Usa la rappresentazione client e il ripristino in modo autonomo.
- Invia al client un messaggio crittografato.
Questo programma di esempio usa una gestione degli errori limitata.
//--------------------------------------------------------------------
// This is a server-side SSPI Windows Sockets program.
#define usPort 2000
#define SECURITY_WIN32
#define SEC_SUCCESS(Status) ((Status) >= 0)
#include <windows.h>
#include <winsock.h>
#include <stdio.h>
#include <stdlib.h>
#include "Sspiexample.h"
CredHandle hcred;
struct _SecHandle hctxt;
static PBYTE g_pInBuf = NULL;
static PBYTE g_pOutBuf = NULL;
static DWORD g_cbMaxMessage;
static TCHAR g_lpPackageName[1024];
BOOL AcceptAuthSocket (SOCKET *ServerSocket);
void main ()
{
CHAR pMessage[200];
DWORD cbMessage;
PBYTE pDataToClient = NULL;
DWORD cbDataToClient = 0;
PCHAR pUserName = NULL;
DWORD cbUserName = 0;
SOCKET Server_Socket;
WSADATA wsaData;
SECURITY_STATUS ss;
PSecPkgInfo pkgInfo;
SecPkgContext_Sizes SecPkgContextSizes;
SecPkgContext_NegotiationInfo SecPkgNegInfo;
ULONG cbMaxSignature;
ULONG cbSecurityTrailer;
//-----------------------------------------------------------------
// Set the default package to negotiate.
strcpy_s(g_lpPackageName, 1024 * sizeof(TCHAR), "Negotiate");
//-----------------------------------------------------------------
// Initialize the socket interface and the security package.
if( WSAStartup (0x0101, &wsaData))
{
fprintf (stderr, "Could not initialize winsock: \n");
cleanup();
}
ss = QuerySecurityPackageInfo (
g_lpPackageName,
&pkgInfo);
if (!SEC_SUCCESS(ss))
{
fprintf (stderr,
"Could not query package info for %s, error 0x%08x\n",
g_lpPackageName, ss);
cleanup();
}
g_cbMaxMessage = pkgInfo->cbMaxToken;
FreeContextBuffer(pkgInfo);
g_pInBuf = (PBYTE) malloc (g_cbMaxMessage);
g_pOutBuf = (PBYTE) malloc (g_cbMaxMessage);
if (NULL == g_pInBuf || NULL == g_pOutBuf)
{
fprintf (stderr, "Memory allocation error.\n");
cleanup();
}
//-----------------------------------------------------------------
// Start looping for clients.
while(TRUE)
{
printf("Waiting for client to connect...\n");
//-----------------------------------------------------------------
// Make an authenticated connection with client.
if (!AcceptAuthSocket (&Server_Socket))
{
fprintf (stderr, "Could not authenticate the socket.\n");
cleanup();
}
ss = QueryContextAttributes(
&hctxt,
SECPKG_ATTR_SIZES,
&SecPkgContextSizes );
if (!SEC_SUCCESS(ss))
{
fprintf (stderr, "QueryContextAttributes failed: 0x%08x\n", ss);
exit(1);
}
//----------------------------------------------------------------
// The following values are used for encryption and signing.
cbMaxSignature = SecPkgContextSizes.cbMaxSignature;
cbSecurityTrailer = SecPkgContextSizes.cbSecurityTrailer;
ss = QueryContextAttributes(
&hctxt,
SECPKG_ATTR_NEGOTIATION_INFO,
&SecPkgNegInfo );
if (!SEC_SUCCESS(ss))
{
fprintf (stderr, "QueryContextAttributes failed: 0x%08x\n", ss);
exit(1);
}
else
{
printf("Package Name: %s\n", SecPkgNegInfo.PackageInfo->Name);
}
//----------------------------------------------------------------
// Free the allocated buffer.
FreeContextBuffer(SecPkgNegInfo.PackageInfo);
//-----------------------------------------------------------------
// Impersonate the client.
ss = ImpersonateSecurityContext (&hctxt);
if (!SEC_SUCCESS(ss))
{
fprintf (stderr, "Impersonate failed: 0x%08x\n", ss);
cleanup();
}
else
{
printf("Impersonation worked. \n");
}
GetUserName (NULL, &cbUserName);
pUserName = (PCHAR) malloc (cbUserName);
if (!pUserName)
{
fprintf (stderr, "Memory allocation error. \n");
cleanup();
}
if (!GetUserName (
pUserName,
&cbUserName))
{
fprintf (stderr, "Could not get the client name. \n");
cleanup();
}
else
{
printf ("Client connected as : %s\n", pUserName);
}
//-----------------------------------------------------------------
// Revert to self.
ss = RevertSecurityContext (&hctxt);
if (!SEC_SUCCESS(ss))
{
fprintf (stderr, "Revert failed: 0x%08x\n", ss);
cleanup();
}
else
{
printf("Reverted to self.\n");
}
//-----------------------------------------------------------------
// Send the client an encrypted message.
strcpy_s(pMessage, sizeof(pMessage),
"This is your server speaking");
cbMessage = strlen(pMessage);
EncryptThis (
(PBYTE) pMessage,
cbMessage,
&pDataToClient,
&cbDataToClient,
cbSecurityTrailer);
//-----------------------------------------------------------------
// Send the encrypted data to client.
if (!SendBytes(
Server_Socket,
pDataToClient,
cbDataToClient))
{
printf("send message failed. \n");
cleanup();
}
printf(" %d encrypted bytes sent. \n", cbDataToClient);
if (Server_Socket)
{
DeleteSecurityContext (&hctxt);
FreeCredentialHandle (&hcred);
shutdown (Server_Socket, 2) ;
closesocket (Server_Socket);
Server_Socket = 0;
}
if (pUserName)
{
free (pUserName);
pUserName = NULL;
cbUserName = 0;
}
if(pDataToClient)
{
free (pDataToClient);
pDataToClient = NULL;
cbDataToClient = 0;
}
} // end while loop
printf("Server ran to completion without error.\n");
cleanup();
} // end main
BOOL AcceptAuthSocket (SOCKET *ServerSocket)
{
SOCKET sockListen;
SOCKET sockClient;
SOCKADDR_IN sockIn;
//-----------------------------------------------------------------
// Create listening socket.
sockListen = socket (
PF_INET,
SOCK_STREAM,
0);
if (INVALID_SOCKET == sockListen)
{
fprintf (stderr, "Failed to create socket: %u\n", GetLastError ());
return(FALSE);
}
//-----------------------------------------------------------------
// Bind to local port.
sockIn.sin_family = AF_INET;
sockIn.sin_addr.s_addr = 0;
sockIn.sin_port = htons(usPort);
if (SOCKET_ERROR == bind (
sockListen,
(LPSOCKADDR) &sockIn,
sizeof (sockIn)))
{
fprintf (stderr, "bind failed: %u\n", GetLastError ());
return(FALSE);
}
//-----------------------------------------------------------------
// Listen for client.
if (SOCKET_ERROR == listen (sockListen, 1))
{
fprintf (stderr, "Listen failed: %u\n", GetLastError ());
return(FALSE);
}
else
{
printf("Listening ! \n");
}
//-----------------------------------------------------------------
// Accept client.
sockClient = accept (
sockListen,
NULL,
NULL);
if (INVALID_SOCKET == sockClient)
{
fprintf (stderr, "accept failed: %u\n", GetLastError ());
return(FALSE);
}
closesocket (sockListen);
*ServerSocket = sockClient;
return(DoAuthentication (sockClient));
} // end AcceptAuthSocket
BOOL DoAuthentication (SOCKET AuthSocket)
{
SECURITY_STATUS ss;
DWORD cbIn, cbOut;
BOOL done = FALSE;
TimeStamp Lifetime;
BOOL fNewConversation;
fNewConversation = TRUE;
ss = AcquireCredentialsHandle (
NULL,
g_lpPackageName,
SECPKG_CRED_INBOUND,
NULL,
NULL,
NULL,
NULL,
&hcred,
&Lifetime);
if (!SEC_SUCCESS (ss))
{
fprintf (stderr, "AcquireCreds failed: 0x%08x\n", ss);
return(FALSE);
}
while(!done)
{
if (!ReceiveMsg (
AuthSocket,
g_pInBuf,
g_cbMaxMessage,
&cbIn))
{
return(FALSE);
}
cbOut = g_cbMaxMessage;
if (!GenServerContext (
g_pInBuf,
cbIn,
g_pOutBuf,
&cbOut,
&done,
fNewConversation))
{
fprintf(stderr,"GenServerContext failed.\n");
return(FALSE);
}
fNewConversation = FALSE;
if (!SendMsg (
AuthSocket,
g_pOutBuf,
cbOut))
{
fprintf(stderr,"Sending message failed.\n");
return(FALSE);
}
}
return(TRUE);
} // end DoAuthentication
BOOL GenServerContext (
BYTE *pIn,
DWORD cbIn,
BYTE *pOut,
DWORD *pcbOut,
BOOL *pfDone,
BOOL fNewConversation)
{
SECURITY_STATUS ss;
TimeStamp Lifetime;
SecBufferDesc OutBuffDesc;
SecBuffer OutSecBuff;
SecBufferDesc InBuffDesc;
SecBuffer InSecBuff;
ULONG Attribs = 0;
//----------------------------------------------------------------
// Prepare output buffers.
OutBuffDesc.ulVersion = 0;
OutBuffDesc.cBuffers = 1;
OutBuffDesc.pBuffers = &OutSecBuff;
OutSecBuff.cbBuffer = *pcbOut;
OutSecBuff.BufferType = SECBUFFER_TOKEN;
OutSecBuff.pvBuffer = pOut;
//----------------------------------------------------------------
// Prepare input buffers.
InBuffDesc.ulVersion = 0;
InBuffDesc.cBuffers = 1;
InBuffDesc.pBuffers = &InSecBuff;
InSecBuff.cbBuffer = cbIn;
InSecBuff.BufferType = SECBUFFER_TOKEN;
InSecBuff.pvBuffer = pIn;
printf ("Token buffer received (%lu bytes):\n", InSecBuff.cbBuffer);
PrintHexDump (InSecBuff.cbBuffer, (PBYTE)InSecBuff.pvBuffer);
ss = AcceptSecurityContext (
&hcred,
fNewConversation ? NULL : &hctxt,
&InBuffDesc,
Attribs,
SECURITY_NATIVE_DREP,
&hctxt,
&OutBuffDesc,
&Attribs,
&Lifetime);
if (!SEC_SUCCESS (ss))
{
fprintf (stderr, "AcceptSecurityContext failed: 0x%08x\n", ss);
return FALSE;
}
//----------------------------------------------------------------
// Complete token if applicable.
if ((SEC_I_COMPLETE_NEEDED == ss)
|| (SEC_I_COMPLETE_AND_CONTINUE == ss))
{
ss = CompleteAuthToken (&hctxt, &OutBuffDesc);
if (!SEC_SUCCESS(ss))
{
fprintf (stderr, "complete failed: 0x%08x\n", ss);
return FALSE;
}
}
*pcbOut = OutSecBuff.cbBuffer;
// fNewConversation equals FALSE.
printf ("Token buffer generated (%lu bytes):\n",
OutSecBuff.cbBuffer);
PrintHexDump (
OutSecBuff.cbBuffer,
(PBYTE)OutSecBuff.pvBuffer);
*pfDone = !((SEC_I_CONTINUE_NEEDED == ss)
|| (SEC_I_COMPLETE_AND_CONTINUE == ss));
printf("AcceptSecurityContext result = 0x%08x\n", ss);
return TRUE;
} // end GenServerContext
BOOL EncryptThis (
PBYTE pMessage,
ULONG cbMessage,
BYTE ** ppOutput,
ULONG * pcbOutput,
ULONG cbSecurityTrailer)
{
SECURITY_STATUS ss;
SecBufferDesc BuffDesc;
SecBuffer SecBuff[2];
ULONG ulQop = 0;
ULONG SigBufferSize;
//-----------------------------------------------------------------
// The size of the trailer (signature + padding) block is
// determined from the global cbSecurityTrailer.
SigBufferSize = cbSecurityTrailer;
printf ("Data before encryption: %s\n", pMessage);
printf ("Length of data before encryption: %d \n",cbMessage);
//-----------------------------------------------------------------
// Allocate a buffer to hold the signature,
// encrypted data, and a DWORD
// that specifies the size of the trailer block.
* ppOutput = (PBYTE) malloc (
SigBufferSize + cbMessage + sizeof(DWORD));
//------------------------------------------------------------------
// Prepare buffers.
BuffDesc.ulVersion = 0;
BuffDesc.cBuffers = 2;
BuffDesc.pBuffers = SecBuff;
SecBuff[0].cbBuffer = SigBufferSize;
SecBuff[0].BufferType = SECBUFFER_TOKEN;
SecBuff[0].pvBuffer = *ppOutput + sizeof(DWORD);
SecBuff[1].cbBuffer = cbMessage;
SecBuff[1].BufferType = SECBUFFER_DATA;
SecBuff[1].pvBuffer = pMessage;
ss = EncryptMessage(
&hctxt,
ulQop,
&BuffDesc,
0);
if (!SEC_SUCCESS(ss))
{
fprintf (stderr, "EncryptMessage failed: 0x%08x\n", ss);
return(FALSE);
}
else
{
printf("The message has been encrypted. \n");
}
//------------------------------------------------------------------
// Indicate the size of the buffer in the first DWORD.
*((DWORD *) *ppOutput) = SecBuff[0].cbBuffer;
//-----------------------------------------------------------------
// Append the encrypted data to our trailer block
// to form a single block.
// Putting trailer at the beginning of the buffer works out
// better.
memcpy (*ppOutput+SecBuff[0].cbBuffer+sizeof(DWORD), pMessage,
cbMessage);
*pcbOutput = cbMessage + SecBuff[0].cbBuffer + sizeof(DWORD);
printf ("data after encryption including trailer (%lu bytes):\n",
*pcbOutput);
PrintHexDump (*pcbOutput, *ppOutput);
return TRUE;
} // end EncryptThis
void PrintHexDump(DWORD length, PBYTE buffer)
{
DWORD i,count,index;
CHAR rgbDigits[]="0123456789abcdef";
CHAR rgbLine[100];
char cbLine;
for(index = 0; length;
length -= count, buffer += count, index += count)
{
count = (length > 16) ? 16:length;
sprintf_s(rgbLine, 100, "%4.4x ",index);
cbLine = 6;
for(i=0;i<count;i++)
{
rgbLine[cbLine++] = rgbDigits[buffer[i] >> 4];
rgbLine[cbLine++] = rgbDigits[buffer[i] & 0x0f];
if(i == 7)
{
rgbLine[cbLine++] = ':';
}
else
{
rgbLine[cbLine++] = ' ';
}
}
for(; i < 16; i++)
{
rgbLine[cbLine++] = ' ';
rgbLine[cbLine++] = ' ';
rgbLine[cbLine++] = ' ';
}
rgbLine[cbLine++] = ' ';
for(i = 0; i < count; i++)
{
if(buffer[i] < 32 || buffer[i] > 126)
{
rgbLine[cbLine++] = '.';
}
else
{
rgbLine[cbLine++] = buffer[i];
}
}
rgbLine[cbLine++] = 0;
printf("%s\n", rgbLine);
}
} // end PrintHexDump
BOOL SendMsg (
SOCKET s,
PBYTE pBuf,
DWORD cbBuf)
{
if (0 == cbBuf)
return(TRUE);
//----------------------------------------------------------------
// Send the size of the message.
if (!SendBytes (
s,
(PBYTE)&cbBuf,
sizeof (cbBuf)))
{
return(FALSE);
}
//----------------------------------------------------------------
// Send the body of the message.
if (!SendBytes (
s,
pBuf,
cbBuf))
{
return(FALSE);
}
return(TRUE);
} // end SendMsg
BOOL ReceiveMsg (
SOCKET s,
PBYTE pBuf,
DWORD cbBuf,
DWORD *pcbRead)
{
DWORD cbRead;
DWORD cbData;
//-----------------------------------------------------------------
// Retrieve the number of bytes in the message.
if (!ReceiveBytes (
s,
(PBYTE)&cbData,
sizeof (cbData),
&cbRead))
{
return(FALSE);
}
if (sizeof (cbData) != cbRead)
{
return(FALSE);
}
//----------------------------------------------------------------
// Read the full message.
if (!ReceiveBytes (
s,
pBuf,
cbData,
&cbRead))
{
return(FALSE);
}
if (cbRead != cbData)
{
return(FALSE);
}
*pcbRead = cbRead;
return(TRUE);
} // end ReceiveMsg
BOOL SendBytes (
SOCKET s,
PBYTE pBuf,
DWORD cbBuf)
{
PBYTE pTemp = pBuf;
int cbSent, cbRemaining = cbBuf;
if (0 == cbBuf)
{
return(TRUE);
}
while (cbRemaining)
{
cbSent = send (
s,
(const char *)pTemp,
cbRemaining,
0);
if (SOCKET_ERROR == cbSent)
{
fprintf (stderr, "send failed: %u\n", GetLastError ());
return FALSE;
}
pTemp += cbSent;
cbRemaining -= cbSent;
}
return TRUE;
} // end SendBytes
BOOL ReceiveBytes (
SOCKET s,
PBYTE pBuf,
DWORD cbBuf,
DWORD *pcbRead)
{
PBYTE pTemp = pBuf;
int cbRead, cbRemaining = cbBuf;
while (cbRemaining)
{
cbRead = recv (
s,
(char *)pTemp,
cbRemaining,
0);
if (0 == cbRead)
{
break;
}
if (SOCKET_ERROR == cbRead)
{
fprintf (stderr, "recv failed: %u\n", GetLastError ());
return FALSE;
}
cbRemaining -= cbRead;
pTemp += cbRead;
}
*pcbRead = cbBuf - cbRemaining;
return TRUE;
} // end ReceivesBytes
void cleanup()
{
if (g_pInBuf)
free (g_pInBuf);
if (g_pOutBuf)
free (g_pOutBuf);
WSACleanup ();
exit(0);
}