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|
/*
Miranda IM: the free IM client for Microsoft* Windows*
Copyright 2000-12 Miranda IM, 2012-13 Miranda NG project,
all portions of this codebase are copyrighted to the people
listed in contributors.txt.
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
#include "..\..\core\commonheaders.h"
#include <m_popup.h>
#include "netlib.h"
#define SECURITY_WIN32
#include <security.h>
#include <schannel.h>
//#include <SCHNLSP.H>
typedef BOOL (* SSL_EMPTY_CACHE_FN_M)(VOID);
static HMODULE g_hSchannel;
static PSecurityFunctionTableA g_pSSPI;
static HANDLE g_hSslMutex;
static SSL_EMPTY_CACHE_FN_M MySslEmptyCache;
static CredHandle hCreds;
static bool bSslInitDone;
typedef BOOL (WINAPI *pfnCertGetCertificateChain)(HCERTCHAINENGINE, PCCERT_CONTEXT, LPFILETIME, HCERTSTORE, PCERT_CHAIN_PARA, DWORD, LPVOID, PCCERT_CHAIN_CONTEXT*);
static pfnCertGetCertificateChain fnCertGetCertificateChain;
typedef VOID (WINAPI *pfnCertFreeCertificateChain)(PCCERT_CHAIN_CONTEXT);
static pfnCertFreeCertificateChain fnCertFreeCertificateChain;
typedef BOOL (WINAPI *pfnCertFreeCertificateContext)(PCCERT_CONTEXT);
static pfnCertFreeCertificateContext fnCertFreeCertificateContext;
typedef BOOL (WINAPI *pfnCertVerifyCertificateChainPolicy)(LPCSTR, PCCERT_CHAIN_CONTEXT, PCERT_CHAIN_POLICY_PARA, PCERT_CHAIN_POLICY_STATUS);
static pfnCertVerifyCertificateChainPolicy fnCertVerifyCertificateChainPolicy;
typedef enum
{
sockOpen,
sockClosed,
sockError
} SocketState;
struct SslHandle
{
SOCKET s;
CtxtHandle hContext;
BYTE *pbRecDataBuf;
int cbRecDataBuf;
int sbRecDataBuf;
BYTE *pbIoBuffer;
int cbIoBuffer;
int sbIoBuffer;
SocketState state;
};
static void ReportSslError(SECURITY_STATUS scRet, int line, bool showPopup = false)
{
TCHAR szMsgBuf[256];
switch (scRet)
{
case 0:
case ERROR_NOT_READY:
return;
case SEC_E_INVALID_TOKEN:
_tcscpy(szMsgBuf, TranslateT("Client cannot decode host message. Possible causes: Host does not support SSL or requires not existing security package"));
break;
case CERT_E_CN_NO_MATCH:
case SEC_E_WRONG_PRINCIPAL:
_tcscpy(szMsgBuf, TranslateT("Host we are connecting to is not the one certificate was issued for"));
break;
default:
FormatMessage(FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS,
NULL, scRet, LANG_USER_DEFAULT, szMsgBuf, SIZEOF(szMsgBuf), NULL);
}
TCHAR szMsgBuf2[512];
mir_sntprintf(szMsgBuf2, SIZEOF(szMsgBuf2), _T("SSL connection failure (%x %u): %s"), scRet, line, szMsgBuf);
char* szMsg = Utf8EncodeT(szMsgBuf2);
NetlibLogf(NULL, szMsg);
mir_free(szMsg);
SetLastError(scRet);
PUShowMessageT(szMsgBuf2, SM_WARNING);
}
static bool AcquireCredentials(void)
{
SCHANNEL_CRED SchannelCred;
TimeStamp tsExpiry;
SECURITY_STATUS scRet;
ZeroMemory(&SchannelCred, sizeof(SchannelCred));
SchannelCred.dwVersion = SCHANNEL_CRED_VERSION;
SchannelCred.grbitEnabledProtocols = SP_PROT_SSL3TLS1_CLIENTS /*| 0xA00 TLS1.1 & 1.2*/;
SchannelCred.dwFlags |= SCH_CRED_NO_DEFAULT_CREDS | SCH_CRED_MANUAL_CRED_VALIDATION;
// Create an SSPI credential.
scRet = g_pSSPI->AcquireCredentialsHandleA(
NULL, // Name of principal
UNISP_NAME_A, // Name of package
SECPKG_CRED_OUTBOUND, // Flags indicating use
NULL, // Pointer to logon ID
&SchannelCred, // Package specific data
NULL, // Pointer to GetKey() func
NULL, // Value to pass to GetKey()
&hCreds, // (out) Cred Handle
&tsExpiry); // (out) Lifetime (optional)
ReportSslError(scRet, __LINE__);
return scRet == SEC_E_OK;
}
static bool SSL_library_init(void)
{
if (bSslInitDone) return true;
WaitForSingleObject(g_hSslMutex, INFINITE);
if ( !bSslInitDone)
{
g_hSchannel = LoadLibraryA("schannel.dll");
if (g_hSchannel)
{
INIT_SECURITY_INTERFACE_A pInitSecurityInterface;
pInitSecurityInterface = (INIT_SECURITY_INTERFACE_A)GetProcAddress(g_hSchannel, SECURITY_ENTRYPOINT_ANSIA);
if (pInitSecurityInterface != NULL)
g_pSSPI = pInitSecurityInterface();
if (g_pSSPI)
{
HINSTANCE hCrypt = LoadLibraryA("crypt32.dll");
if (hCrypt)
{
fnCertGetCertificateChain = (pfnCertGetCertificateChain)GetProcAddress(hCrypt, "CertGetCertificateChain");
fnCertFreeCertificateChain = (pfnCertFreeCertificateChain)GetProcAddress(hCrypt, "CertFreeCertificateChain");
fnCertFreeCertificateContext = (pfnCertFreeCertificateContext)GetProcAddress(hCrypt, "CertFreeCertificateContext");
fnCertVerifyCertificateChainPolicy = (pfnCertVerifyCertificateChainPolicy)GetProcAddress(hCrypt, "CertVerifyCertificateChainPolicy");
}
MySslEmptyCache = (SSL_EMPTY_CACHE_FN_M)GetProcAddress(g_hSchannel, "SslEmptyCache");
AcquireCredentials();
bSslInitDone = true;
}
else
{
FreeLibrary(g_hSchannel);
g_hSchannel = NULL;
}
}
}
ReleaseMutex(g_hSslMutex);
return bSslInitDone;
}
void NetlibSslFree(SslHandle *ssl)
{
if (ssl == NULL) return;
g_pSSPI->DeleteSecurityContext(&ssl->hContext);
mir_free(ssl->pbRecDataBuf);
mir_free(ssl->pbIoBuffer);
memset(ssl, 0, sizeof(SslHandle));
mir_free(ssl);
}
BOOL NetlibSslPending(SslHandle *ssl)
{
return ssl != NULL && (ssl->cbRecDataBuf != 0 || ssl->cbIoBuffer != 0);
}
static bool VerifyCertificate(SslHandle *ssl, PCSTR pszServerName, DWORD dwCertFlags)
{
if ( !fnCertGetCertificateChain)
return true;
static LPSTR rgszUsages[] =
{
szOID_PKIX_KP_SERVER_AUTH,
szOID_SERVER_GATED_CRYPTO,
szOID_SGC_NETSCAPE
};
CERT_CHAIN_PARA ChainPara = {0};
HTTPSPolicyCallbackData polHttps = {0};
CERT_CHAIN_POLICY_PARA PolicyPara = {0};
CERT_CHAIN_POLICY_STATUS PolicyStatus = {0};
PCCERT_CHAIN_CONTEXT pChainContext = NULL;
PCCERT_CONTEXT pServerCert = NULL;
DWORD scRet;
PWSTR pwszServerName = mir_a2u(pszServerName);
scRet = g_pSSPI->QueryContextAttributesA(&ssl->hContext,
SECPKG_ATTR_REMOTE_CERT_CONTEXT, &pServerCert);
if (scRet != SEC_E_OK)
goto cleanup;
if (pServerCert == NULL)
{
scRet = SEC_E_WRONG_PRINCIPAL;
goto cleanup;
}
ChainPara.cbSize = sizeof(ChainPara);
ChainPara.RequestedUsage.dwType = USAGE_MATCH_TYPE_OR;
ChainPara.RequestedUsage.Usage.cUsageIdentifier = SIZEOF(rgszUsages);
ChainPara.RequestedUsage.Usage.rgpszUsageIdentifier = rgszUsages;
if ( !fnCertGetCertificateChain(NULL, pServerCert, NULL, pServerCert->hCertStore,
&ChainPara, 0, NULL, &pChainContext))
{
scRet = GetLastError();
goto cleanup;
}
polHttps.cbStruct = sizeof(HTTPSPolicyCallbackData);
polHttps.dwAuthType = AUTHTYPE_SERVER;
polHttps.fdwChecks = dwCertFlags;
polHttps.pwszServerName = pwszServerName;
PolicyPara.cbSize = sizeof(PolicyPara);
PolicyPara.pvExtraPolicyPara = &polHttps;
PolicyStatus.cbSize = sizeof(PolicyStatus);
if ( !fnCertVerifyCertificateChainPolicy(CERT_CHAIN_POLICY_SSL, pChainContext,
&PolicyPara, &PolicyStatus))
{
scRet = GetLastError();
goto cleanup;
}
if (PolicyStatus.dwError)
{
scRet = PolicyStatus.dwError;
goto cleanup;
}
scRet = SEC_E_OK;
cleanup:
if (pChainContext)
fnCertFreeCertificateChain(pChainContext);
if (pServerCert)
fnCertFreeCertificateContext(pServerCert);
mir_free(pwszServerName);
ReportSslError(scRet, __LINE__, true);
return scRet == SEC_E_OK;
}
static SECURITY_STATUS ClientHandshakeLoop(SslHandle *ssl, BOOL fDoInitialRead)
{
SecBufferDesc InBuffer;
SecBuffer InBuffers[2];
SecBufferDesc OutBuffer;
SecBuffer OutBuffers[1];
DWORD dwSSPIFlags;
DWORD dwSSPIOutFlags;
TimeStamp tsExpiry;
SECURITY_STATUS scRet;
DWORD cbData;
BOOL fDoRead;
dwSSPIFlags =
ISC_REQ_SEQUENCE_DETECT |
ISC_REQ_REPLAY_DETECT |
ISC_REQ_CONFIDENTIALITY |
ISC_REQ_EXTENDED_ERROR |
ISC_REQ_ALLOCATE_MEMORY |
ISC_REQ_STREAM;
ssl->cbIoBuffer = 0;
fDoRead = fDoInitialRead;
scRet = SEC_I_CONTINUE_NEEDED;
// Loop until the handshake is finished or an error occurs.
while (scRet == SEC_I_CONTINUE_NEEDED || scRet == SEC_E_INCOMPLETE_MESSAGE || scRet == SEC_I_INCOMPLETE_CREDENTIALS)
{
// Read server data
if (0 == ssl->cbIoBuffer || scRet == SEC_E_INCOMPLETE_MESSAGE)
{
if (fDoRead)
{
static const TIMEVAL tv = {6, 0};
fd_set fd;
// If buffer not large enough reallocate buffer
if (ssl->sbIoBuffer <= ssl->cbIoBuffer)
{
ssl->sbIoBuffer += 4096;
ssl->pbIoBuffer = (PUCHAR)mir_realloc(ssl->pbIoBuffer, ssl->sbIoBuffer);
}
FD_ZERO(&fd);
FD_SET(ssl->s, &fd);
if (select(1, &fd, NULL, NULL, &tv) != 1)
{
NetlibLogf(NULL, "SSL Negotiation failure recieving data (timeout) (bytes %u)", ssl->cbIoBuffer);
scRet = ERROR_NOT_READY;
break;
}
cbData = recv(ssl->s, (char*)ssl->pbIoBuffer + ssl->cbIoBuffer, ssl->sbIoBuffer - ssl->cbIoBuffer, 0);
if (cbData == SOCKET_ERROR)
{
NetlibLogf(NULL, "SSL Negotiation failure recieving data (%d)", WSAGetLastError());
scRet = ERROR_NOT_READY;
break;
}
if (cbData == 0)
{
NetlibLogf(NULL, "SSL Negotiation connection gracefully closed");
scRet = ERROR_NOT_READY;
break;
}
NetlibDumpData(NULL, ssl->pbIoBuffer + ssl->cbIoBuffer, cbData, 0, MSG_DUMPSSL);
ssl->cbIoBuffer += cbData;
}
else fDoRead = TRUE;
}
// Set up the input buffers. Buffer 0 is used to pass in data
// received from the server. Schannel will consume some or all
// of this. Leftover data (if any) will be placed in buffer 1 and
// given a buffer type of SECBUFFER_EXTRA.
InBuffers[0].pvBuffer = ssl->pbIoBuffer;
InBuffers[0].cbBuffer = ssl->cbIoBuffer;
InBuffers[0].BufferType = SECBUFFER_TOKEN;
InBuffers[1].pvBuffer = NULL;
InBuffers[1].cbBuffer = 0;
InBuffers[1].BufferType = SECBUFFER_EMPTY;
InBuffer.cBuffers = 2;
InBuffer.pBuffers = InBuffers;
InBuffer.ulVersion = SECBUFFER_VERSION;
// Set up the output buffers. These are initialized to NULL
// so as to make it less likely we'll attempt to free random
// garbage later.
OutBuffers[0].pvBuffer = NULL;
OutBuffers[0].BufferType = SECBUFFER_TOKEN;
OutBuffers[0].cbBuffer = 0;
OutBuffer.cBuffers = 1;
OutBuffer.pBuffers = OutBuffers;
OutBuffer.ulVersion = SECBUFFER_VERSION;
scRet = g_pSSPI->InitializeSecurityContextA(
&hCreds,
&ssl->hContext,
NULL,
dwSSPIFlags,
0,
SECURITY_NATIVE_DREP,
&InBuffer,
0,
NULL,
&OutBuffer,
&dwSSPIOutFlags,
&tsExpiry);
// If success (or if the error was one of the special extended ones),
// send the contents of the output buffer to the server.
if (scRet == SEC_E_OK ||
scRet == SEC_I_CONTINUE_NEEDED ||
(FAILED(scRet) && (dwSSPIOutFlags & ISC_RET_EXTENDED_ERROR)))
{
if (OutBuffers[0].cbBuffer != 0 && OutBuffers[0].pvBuffer != NULL)
{
NetlibDumpData(NULL, (unsigned char*)(OutBuffers[0].pvBuffer), OutBuffers[0].cbBuffer, 1, MSG_DUMPSSL);
cbData = send(ssl->s, (char*)OutBuffers[0].pvBuffer, OutBuffers[0].cbBuffer, 0);
if (cbData == SOCKET_ERROR || cbData == 0)
{
NetlibLogf(NULL, "SSL Negotiation failure sending data (%d)", WSAGetLastError());
g_pSSPI->FreeContextBuffer(OutBuffers[0].pvBuffer);
return SEC_E_INTERNAL_ERROR;
}
// Free output buffer.
g_pSSPI->FreeContextBuffer(OutBuffers[0].pvBuffer);
OutBuffers[0].pvBuffer = NULL;
}
}
// we need to read more data from the server and try again.
if (scRet == SEC_E_INCOMPLETE_MESSAGE) continue;
// handshake completed successfully.
if (scRet == SEC_E_OK)
{
// Store remaining data for further use
if (InBuffers[1].BufferType == SECBUFFER_EXTRA)
{
memmove(ssl->pbIoBuffer,
ssl->pbIoBuffer + (ssl->cbIoBuffer - InBuffers[1].cbBuffer),
InBuffers[1].cbBuffer);
ssl->cbIoBuffer = InBuffers[1].cbBuffer;
}
else
ssl->cbIoBuffer = 0;
break;
}
// Check for fatal error.
if (FAILED(scRet)) break;
// server just requested client authentication.
if (scRet == SEC_I_INCOMPLETE_CREDENTIALS)
{
// Server has requested client authentication and
// GetNewClientCredentials(ssl);
// Go around again.
fDoRead = FALSE;
scRet = SEC_I_CONTINUE_NEEDED;
continue;
}
// Copy any leftover data from the buffer, and go around again.
if (InBuffers[1].BufferType == SECBUFFER_EXTRA)
{
memmove(ssl->pbIoBuffer,
ssl->pbIoBuffer + (ssl->cbIoBuffer - InBuffers[1].cbBuffer),
InBuffers[1].cbBuffer);
ssl->cbIoBuffer = InBuffers[1].cbBuffer;
}
else ssl->cbIoBuffer = 0;
}
// Delete the security context in the case of a fatal error.
ReportSslError(scRet, __LINE__);
if (ssl->cbIoBuffer == 0)
{
mir_free(ssl->pbIoBuffer);
ssl->pbIoBuffer = NULL;
ssl->sbIoBuffer = 0;
}
return scRet;
}
static bool ClientConnect(SslHandle *ssl, const char *host)
{
SecBufferDesc OutBuffer;
SecBuffer OutBuffers[1];
DWORD dwSSPIFlags;
DWORD dwSSPIOutFlags;
TimeStamp tsExpiry;
SECURITY_STATUS scRet;
DWORD cbData;
if (SecIsValidHandle(&ssl->hContext))
{
g_pSSPI->DeleteSecurityContext(&ssl->hContext);
SecInvalidateHandle(&ssl->hContext);
}
if (MySslEmptyCache) MySslEmptyCache();
dwSSPIFlags = ISC_REQ_SEQUENCE_DETECT |
ISC_REQ_REPLAY_DETECT |
ISC_REQ_CONFIDENTIALITY |
ISC_REQ_EXTENDED_ERROR |
ISC_REQ_ALLOCATE_MEMORY |
ISC_REQ_STREAM;
// Initiate a ClientHello message and generate a token.
OutBuffers[0].pvBuffer = NULL;
OutBuffers[0].BufferType = SECBUFFER_TOKEN;
OutBuffers[0].cbBuffer = 0;
OutBuffer.cBuffers = 1;
OutBuffer.pBuffers = OutBuffers;
OutBuffer.ulVersion = SECBUFFER_VERSION;
scRet = g_pSSPI->InitializeSecurityContextA(
&hCreds,
NULL,
(SEC_CHAR*)host,
dwSSPIFlags,
0,
SECURITY_NATIVE_DREP,
NULL,
0,
&ssl->hContext,
&OutBuffer,
&dwSSPIOutFlags,
&tsExpiry);
if (scRet != SEC_I_CONTINUE_NEEDED)
{
ReportSslError(scRet, __LINE__);
return 0;
}
// Send response to server if there is one.
if (OutBuffers[0].cbBuffer != 0 && OutBuffers[0].pvBuffer != NULL)
{
NetlibDumpData(NULL, (unsigned char*)(OutBuffers[0].pvBuffer), OutBuffers[0].cbBuffer, 1, MSG_DUMPSSL);
cbData = send(ssl->s, (char*)OutBuffers[0].pvBuffer, OutBuffers[0].cbBuffer, 0);
if (cbData == SOCKET_ERROR || cbData == 0)
{
NetlibLogf(NULL, "SSL failure sending connection data (%d %d)", ssl->s, WSAGetLastError());
g_pSSPI->FreeContextBuffer(OutBuffers[0].pvBuffer);
return 0;
}
// Free output buffer.
g_pSSPI->FreeContextBuffer(OutBuffers[0].pvBuffer);
OutBuffers[0].pvBuffer = NULL;
}
return ClientHandshakeLoop(ssl, TRUE) == SEC_E_OK;
}
SslHandle *NetlibSslConnect(SOCKET s, const char* host, int verify)
{
SslHandle *ssl = (SslHandle*)mir_calloc(sizeof(SslHandle));
ssl->s = s;
SecInvalidateHandle(&ssl->hContext);
DWORD dwFlags = 0;
if ( !host || inet_addr(host) != INADDR_NONE)
dwFlags |= 0x00001000;
bool res = SSL_library_init();
if (res) res = ClientConnect(ssl, host);
if (res && verify) res = VerifyCertificate(ssl, host, dwFlags);
if ( !res)
{
NetlibSslFree(ssl);
ssl = NULL;
}
return ssl;
}
void NetlibSslShutdown(SslHandle *ssl)
{
DWORD dwType;
SecBufferDesc OutBuffer;
SecBuffer OutBuffers[1];
DWORD dwSSPIFlags;
DWORD dwSSPIOutFlags;
TimeStamp tsExpiry;
DWORD scRet;
if (ssl == NULL || !SecIsValidHandle(&ssl->hContext))
return;
dwType = SCHANNEL_SHUTDOWN;
OutBuffers[0].pvBuffer = &dwType;
OutBuffers[0].BufferType = SECBUFFER_TOKEN;
OutBuffers[0].cbBuffer = sizeof(dwType);
OutBuffer.cBuffers = 1;
OutBuffer.pBuffers = OutBuffers;
OutBuffer.ulVersion = SECBUFFER_VERSION;
scRet = g_pSSPI->ApplyControlToken(&ssl->hContext, &OutBuffer);
if (FAILED(scRet)) return;
//
// Build an SSL close notify message.
//
dwSSPIFlags = ISC_REQ_SEQUENCE_DETECT |
ISC_REQ_REPLAY_DETECT |
ISC_REQ_CONFIDENTIALITY |
ISC_RET_EXTENDED_ERROR |
ISC_REQ_ALLOCATE_MEMORY |
ISC_REQ_STREAM;
OutBuffers[0].pvBuffer = NULL;
OutBuffers[0].BufferType = SECBUFFER_TOKEN;
OutBuffers[0].cbBuffer = 0;
OutBuffer.cBuffers = 1;
OutBuffer.pBuffers = OutBuffers;
OutBuffer.ulVersion = SECBUFFER_VERSION;
scRet = g_pSSPI->InitializeSecurityContextA(
&hCreds,
&ssl->hContext,
NULL,
dwSSPIFlags,
0,
SECURITY_NATIVE_DREP,
NULL,
0,
&ssl->hContext,
&OutBuffer,
&dwSSPIOutFlags,
&tsExpiry);
if (FAILED(scRet)) return;
// Send the close notify message to the server.
if (OutBuffers[0].pvBuffer != NULL && OutBuffers[0].cbBuffer != 0)
{
NetlibDumpData(NULL, (unsigned char*)(OutBuffers[0].pvBuffer), OutBuffers[0].cbBuffer, 1, MSG_DUMPSSL);
send(ssl->s, (char*)OutBuffers[0].pvBuffer, OutBuffers[0].cbBuffer, 0);
g_pSSPI->FreeContextBuffer(OutBuffers[0].pvBuffer);
}
}
static int NetlibSslReadSetResult(SslHandle *ssl, char *buf, int num, int peek)
{
if (ssl->cbRecDataBuf == 0)
{
return (ssl->state == sockClosed ? 0: SOCKET_ERROR);
}
int bytes = min(num, ssl->cbRecDataBuf);
int rbytes = ssl->cbRecDataBuf - bytes;
memcpy(buf, ssl->pbRecDataBuf, bytes);
if ( !peek)
{
memmove(ssl->pbRecDataBuf, ssl->pbRecDataBuf + bytes, rbytes);
ssl->cbRecDataBuf = rbytes;
}
return bytes;
}
int NetlibSslRead(SslHandle *ssl, char *buf, int num, int peek)
{
SECURITY_STATUS scRet;
DWORD cbData;
DWORD resNum = 0;
int i;
SecBufferDesc Message;
SecBuffer Buffers[4];
SecBuffer * pDataBuffer;
SecBuffer * pExtraBuffer;
if (ssl == NULL) return SOCKET_ERROR;
if (num <= 0) return 0;
if (ssl->state != sockOpen || (ssl->cbRecDataBuf != 0 && ( !peek || ssl->cbRecDataBuf >= num)))
{
return NetlibSslReadSetResult(ssl, buf, num, peek);
}
scRet = SEC_E_OK;
for (;;)
{
if (0 == ssl->cbIoBuffer || scRet == SEC_E_INCOMPLETE_MESSAGE)
{
if (ssl->sbIoBuffer <= ssl->cbIoBuffer)
{
ssl->sbIoBuffer += 2048;
ssl->pbIoBuffer = (PUCHAR)mir_realloc(ssl->pbIoBuffer, ssl->sbIoBuffer);
}
if (peek)
{
static const TIMEVAL tv = {0};
fd_set fd;
FD_ZERO(&fd);
FD_SET(ssl->s, &fd);
cbData = select(1, &fd, NULL, NULL, &tv);
if (cbData == SOCKET_ERROR)
{
ssl->state = sockError;
return NetlibSslReadSetResult(ssl, buf, num, peek);
}
if (cbData == 0 && ssl->cbRecDataBuf)
return NetlibSslReadSetResult(ssl, buf, num, peek);
}
cbData = recv(ssl->s, (char*)ssl->pbIoBuffer + ssl->cbIoBuffer, ssl->sbIoBuffer - ssl->cbIoBuffer, 0);
if (cbData == SOCKET_ERROR)
{
NetlibLogf(NULL, "SSL failure recieving data (%d)", WSAGetLastError());
ssl->state = sockError;
return NetlibSslReadSetResult(ssl, buf, num, peek);
}
if (cbData == 0)
{
NetlibLogf(NULL, "SSL connection gracefully closed");
if (peek && ssl->cbRecDataBuf)
{
ssl->state = sockClosed;
return NetlibSslReadSetResult(ssl, buf, num, peek);
}
// Server disconnected.
if (ssl->cbIoBuffer)
{
ssl->state = sockError;
return NetlibSslReadSetResult(ssl, buf, num, peek);
}
return 0;
}
else
{
NetlibDumpData(NULL, ssl->pbIoBuffer + ssl->cbIoBuffer, cbData, 0, MSG_DUMPSSL);
ssl->cbIoBuffer += cbData;
}
}
// Attempt to decrypt the received data.
Buffers[0].pvBuffer = ssl->pbIoBuffer;
Buffers[0].cbBuffer = ssl->cbIoBuffer;
Buffers[0].BufferType = SECBUFFER_DATA;
Buffers[1].BufferType = SECBUFFER_EMPTY;
Buffers[2].BufferType = SECBUFFER_EMPTY;
Buffers[3].BufferType = SECBUFFER_EMPTY;
Message.ulVersion = SECBUFFER_VERSION;
Message.cBuffers = 4;
Message.pBuffers = Buffers;
if (g_pSSPI->DecryptMessage != NULL && g_pSSPI->DecryptMessage != PVOID(0x80000000))
scRet = g_pSSPI->DecryptMessage(&ssl->hContext, &Message, 0, NULL);
else
scRet = ((DECRYPT_MESSAGE_FN)g_pSSPI->Reserved4)(&ssl->hContext, &Message, 0, NULL);
// The input buffer contains only a fragment of an
// encrypted record. Loop around and read some more
// data.
if (scRet == SEC_E_INCOMPLETE_MESSAGE)
continue;
if (scRet != SEC_E_OK && scRet != SEC_I_RENEGOTIATE && scRet != SEC_I_CONTEXT_EXPIRED)
{
ReportSslError(scRet, __LINE__);
ssl->state = sockError;
return NetlibSslReadSetResult(ssl, buf, num, peek);
}
// Locate data and (optional) extra buffers.
pDataBuffer = NULL;
pExtraBuffer = NULL;
for (i = 1; i < 4; i++)
{
if (pDataBuffer == NULL && Buffers[i].BufferType == SECBUFFER_DATA)
pDataBuffer = &Buffers[i];
if (pExtraBuffer == NULL && Buffers[i].BufferType == SECBUFFER_EXTRA)
pExtraBuffer = &Buffers[i];
}
// Return decrypted data.
if (pDataBuffer)
{
DWORD bytes, rbytes;
bytes = peek ? 0 : min((DWORD)num, pDataBuffer->cbBuffer);
rbytes = pDataBuffer->cbBuffer - bytes;
NetlibDumpData(NULL, (PBYTE)pDataBuffer->pvBuffer, pDataBuffer->cbBuffer, 0, MSG_DUMPSSL);
if (rbytes > 0)
{
int nbytes = ssl->cbRecDataBuf + rbytes;
if (ssl->sbRecDataBuf < nbytes)
{
ssl->sbRecDataBuf = nbytes;
ssl->pbRecDataBuf = (PUCHAR)mir_realloc(ssl->pbRecDataBuf, nbytes);
}
memcpy(ssl->pbRecDataBuf + ssl->cbRecDataBuf, (char*)pDataBuffer->pvBuffer + bytes, rbytes);
ssl->cbRecDataBuf = nbytes;
}
if (peek)
{
resNum = bytes = min(num, ssl->cbRecDataBuf);
memcpy(buf, ssl->pbRecDataBuf, bytes);
}
else
{
resNum = bytes;
memcpy(buf, pDataBuffer->pvBuffer, bytes);
}
}
// Move any "extra" data to the input buffer.
if (pExtraBuffer)
{
memmove(ssl->pbIoBuffer, pExtraBuffer->pvBuffer, pExtraBuffer->cbBuffer);
ssl->cbIoBuffer = pExtraBuffer->cbBuffer;
}
else ssl->cbIoBuffer = 0;
if (pDataBuffer && resNum)
return resNum;
// Server signaled end of session
if (scRet == SEC_I_CONTEXT_EXPIRED)
{
NetlibLogf(NULL, "SSL Server signaled SSL Shutdown");
ssl->state = sockClosed;
return NetlibSslReadSetResult(ssl, buf, num, peek);
}
if (scRet == SEC_I_RENEGOTIATE)
{
// The server wants to perform another handshake
// sequence.
scRet = ClientHandshakeLoop(ssl, FALSE);
if (scRet != SEC_E_OK)
{
ssl->state = sockError;
return NetlibSslReadSetResult(ssl, buf, num, peek);
}
}
}
}
int NetlibSslWrite(SslHandle *ssl, const char *buf, int num)
{
SecPkgContext_StreamSizes Sizes;
SECURITY_STATUS scRet;
DWORD cbData;
SecBufferDesc Message;
SecBuffer Buffers[4] = {0};
PUCHAR pbDataBuffer;
PUCHAR pbMessage;
DWORD cbMessage;
DWORD sendOff = 0;
if (ssl == NULL) return SOCKET_ERROR;
scRet = g_pSSPI->QueryContextAttributesA(&ssl->hContext, SECPKG_ATTR_STREAM_SIZES, &Sizes);
if (scRet != SEC_E_OK) return scRet;
pbDataBuffer = (PUCHAR)mir_calloc(Sizes.cbMaximumMessage + Sizes.cbHeader + Sizes.cbTrailer);
pbMessage = pbDataBuffer + Sizes.cbHeader;
while (sendOff < (DWORD)num)
{
cbMessage = min(Sizes.cbMaximumMessage, (DWORD)num - sendOff);
CopyMemory(pbMessage, buf+sendOff, cbMessage);
Buffers[0].pvBuffer = pbDataBuffer;
Buffers[0].cbBuffer = Sizes.cbHeader;
Buffers[0].BufferType = SECBUFFER_STREAM_HEADER;
Buffers[1].pvBuffer = pbMessage;
Buffers[1].cbBuffer = cbMessage;
Buffers[1].BufferType = SECBUFFER_DATA;
Buffers[2].pvBuffer = pbMessage + cbMessage;
Buffers[2].cbBuffer = Sizes.cbTrailer;
Buffers[2].BufferType = SECBUFFER_STREAM_TRAILER;
Buffers[3].BufferType = SECBUFFER_EMPTY;
Message.ulVersion = SECBUFFER_VERSION;
Message.cBuffers = 4;
Message.pBuffers = Buffers;
if (g_pSSPI->EncryptMessage != NULL)
scRet = g_pSSPI->EncryptMessage(&ssl->hContext, 0, &Message, 0);
else
scRet = ((ENCRYPT_MESSAGE_FN)g_pSSPI->Reserved3)(&ssl->hContext, 0, &Message, 0);
if (FAILED(scRet)) break;
// Calculate encrypted packet size
cbData = Buffers[0].cbBuffer + Buffers[1].cbBuffer + Buffers[2].cbBuffer;
// Send the encrypted data to the server.
NetlibDumpData(NULL, pbDataBuffer, cbData, 1, MSG_DUMPSSL);
cbData = send(ssl->s, (char*)pbDataBuffer, cbData, 0);
if (cbData == SOCKET_ERROR || cbData == 0)
{
NetlibLogf(NULL, "SSL failure sending data (%d)", WSAGetLastError());
scRet = SEC_E_INTERNAL_ERROR;
break;
}
sendOff += cbMessage;
}
mir_free(pbDataBuffer);
return scRet == SEC_E_OK ? num : SOCKET_ERROR;
}
static INT_PTR GetSslApi(WPARAM, LPARAM lParam)
{
SSL_API* si = (SSL_API*)lParam;
if (si == NULL) return FALSE;
if (si->cbSize != sizeof(SSL_API))
return FALSE;
si->connect = (HSSL (__cdecl *)(SOCKET, const char *, int))NetlibSslConnect;
si->pending = (BOOL (__cdecl *)(HSSL))NetlibSslPending;
si->read = (int (__cdecl *)(HSSL, char *, int, int))NetlibSslRead;
si->write = (int (__cdecl *)(HSSL, const char *, int))NetlibSslWrite;
si->shutdown = (void (__cdecl *)(HSSL))NetlibSslShutdown;
si->sfree = (void (__cdecl *)(HSSL))NetlibSslFree;
return TRUE;
}
int LoadSslModule(void)
{
CreateServiceFunction(MS_SYSTEM_GET_SI, GetSslApi);
g_hSslMutex = CreateMutex(NULL, FALSE, NULL);
SecInvalidateHandle(&hCreds);
return 0;
}
void UnloadSslModule(void)
{
if (g_pSSPI && SecIsValidHandle(&hCreds))
g_pSSPI->FreeCredentialsHandle(&hCreds);
CloseHandle(g_hSslMutex);
if (g_hSchannel) FreeLibrary(g_hSchannel);
}
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