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fteqw/engine/common/net_ssl_winsspi.c
Spoike 432bc96456 Add r_meshroll, like r_meshpitch (hexen2 requires it set to -1 - they made the bug worse).
HTTP client code now tracks the reason for failure better (so we can distinguish between dns, no response, disconnects, and tls cert issues).
Downloads menu shows reasons for failure for its various sources.
make hexen2's +infoplaque button work even when tab isn't held! Yes! usability! who'd a thought it?
Try to clean up some client-only build issues.
Added 'librequake' as a recognised game name (mostly so that we can reuse the quake-specific engine compat settings.
.map support now supports patches enough to query+create(+network)+select them. Collisions are basically defective though.
qcc: Remove char as default keyword.
qcc: Fix some recent regressions.
sv: Add 'sv_protocol csqc' setting to force csqc protocols on clients that disabled handshakes, for mods that NEED csqc support. other options include 'fte1' and 'fte2', if you want to force extra stuff. Engines that don't support the selected protocols will crash out so only set these if your mod/map always requires it.
sv: default to qw physics whenever a mod defines the SV_RunClientCommand, even if its an nq mod.


git-svn-id: https://svn.code.sf.net/p/fteqw/code/trunk@5775 fc73d0e0-1445-4013-8a0c-d673dee63da5
2020-10-06 03:17:28 +00:00

1380 lines
41 KiB
C

#include "quakedef.h"
#if defined(HAVE_WINSSPI)
/*regarding HAVE_DTLS
DTLS1.0 is supported from win8 onwards
Its also meant to be supported from some RDP server patch on win7, but I can't get it to work.
I've given up for now.
*/
#include "winquake.h"
#include "netinc.h"
#define SECURITY_WIN32
#include <security.h>
#include <sspi.h>
#include <schannel.h>
#define SP_PROT_TLS1_1_SERVER 0x00000100
#define SP_PROT_TLS1_1_CLIENT 0x00000200
#define SP_PROT_TLS1_2_SERVER 0x00000400
#define SP_PROT_TLS1_2_CLIENT 0x00000800
#define SP_PROT_DTLS_SERVER 0x00010000
#define SP_PROT_DTLS_CLIENT 0x00020000
//avoid the use of outdated/insecure protocols
//so no ssl2/ssl3
#define USE_PROT_SERVER (SP_PROT_TLS1_SERVER | SP_PROT_TLS1_1_SERVER | SP_PROT_TLS1_2_SERVER)
#define USE_PROT_CLIENT (SP_PROT_TLS1_CLIENT | SP_PROT_TLS1_1_CLIENT | SP_PROT_TLS1_2_CLIENT)
#define USE_PROT_DGRAM_SERVER (SP_PROT_DTLS_SERVER)
#define USE_PROT_DGRAM_CLIENT (SP_PROT_DTLS_CLIENT)
#ifndef szOID_RSA_SHA512RSA
#define szOID_RSA_SHA512RSA "1.2.840.113549.1.1.13"
#endif
#ifndef SCH_CRED_SNI_CREDENTIAL
#define SCH_CRED_SNI_CREDENTIAL 0x00080000
#endif
#ifndef SEC_I_MESSAGE_FRAGMENT
#define SEC_I_MESSAGE_FRAGMENT 0x00090364L
#endif
#ifndef SEC_E_INVALID_PARAMETER
#define SEC_E_INVALID_PARAMETER 0x8009035DL
#endif
//hungarian ensures we hit no macros.
static struct
{
dllhandle_t *lib;
SECURITY_STATUS (WINAPI *pDecryptMessage) (PCtxtHandle,PSecBufferDesc,ULONG,PULONG);
SECURITY_STATUS (WINAPI *pEncryptMessage) (PCtxtHandle,ULONG,PSecBufferDesc,ULONG);
SECURITY_STATUS (WINAPI *pAcquireCredentialsHandleA) (SEC_CHAR*,SEC_CHAR*,ULONG,PLUID,PVOID,SEC_GET_KEY_FN,PVOID,PCredHandle,PTimeStamp);
// SECURITY_STATUS (WINAPI *pInitializeSecurityContextA) (PCredHandle,PCtxtHandle,SEC_CHAR*,ULONG,ULONG,ULONG,PSecBufferDesc,ULONG,PCtxtHandle,PSecBufferDesc,PULONG,PTimeStamp);
SECURITY_STATUS (WINAPI *pInitializeSecurityContextW) (PCredHandle,PCtxtHandle,SEC_WCHAR*,ULONG,ULONG,ULONG,PSecBufferDesc,ULONG,PCtxtHandle,PSecBufferDesc,PULONG,PTimeStamp);
SECURITY_STATUS (WINAPI *pAcceptSecurityContext) (PCredHandle,PCtxtHandle,PSecBufferDesc,unsigned long,unsigned long,PCtxtHandle,PSecBufferDesc,unsigned long SEC_FAR *,PTimeStamp);
SECURITY_STATUS (WINAPI *pCompleteAuthToken) (PCtxtHandle,PSecBufferDesc);
SECURITY_STATUS (WINAPI *pQueryContextAttributesA) (PCtxtHandle,ULONG,PVOID);
SECURITY_STATUS (WINAPI *pFreeCredentialsHandle) (PCredHandle);
SECURITY_STATUS (WINAPI *pDeleteSecurityContext) (PCtxtHandle);
} secur;
static struct
{
dllhandle_t *lib;
BOOL (WINAPI *pCertGetCertificateChain) (HCERTCHAINENGINE,PCCERT_CONTEXT,LPFILETIME,HCERTSTORE,PCERT_CHAIN_PARA,DWORD,LPVOID,PCCERT_CHAIN_CONTEXT*);
BOOL (WINAPI *pCertVerifyCertificateChainPolicy) (LPCSTR,PCCERT_CHAIN_CONTEXT,PCERT_CHAIN_POLICY_PARA,PCERT_CHAIN_POLICY_STATUS);
void (WINAPI *pCertFreeCertificateChain) (PCCERT_CHAIN_CONTEXT);
DWORD (WINAPI *pCertNameToStrA) (DWORD dwCertEncodingType, PCERT_NAME_BLOB pName, DWORD dwStrType, LPCSTR psz, DWORD csz);
PCCERT_CONTEXT (WINAPI *pCertCreateSelfSignCertificate) (HCRYPTPROV,PCERT_NAME_BLOB,DWORD,PCRYPT_KEY_PROV_INFO,PCRYPT_ALGORITHM_IDENTIFIER,PSYSTEMTIME,PSYSTEMTIME,PCERT_EXTENSIONS);
BOOL (WINAPI *pCertStrToNameA) (DWORD,LPCSTR,DWORD,void *,BYTE *,DWORD *,LPCSTR *);
} crypt;
void SSL_Init(void)
{
dllfunction_t secur_functable[] =
{
{(void**)&secur.pDecryptMessage, "DecryptMessage"},
{(void**)&secur.pEncryptMessage, "EncryptMessage"},
{(void**)&secur.pAcquireCredentialsHandleA, "AcquireCredentialsHandleA"},
// {(void**)&secur.pInitializeSecurityContextA, "InitializeSecurityContextA"},
{(void**)&secur.pInitializeSecurityContextW, "InitializeSecurityContextW"},
{(void**)&secur.pAcceptSecurityContext, "AcceptSecurityContext"},
{(void**)&secur.pCompleteAuthToken, "CompleteAuthToken"},
{(void**)&secur.pQueryContextAttributesA, "QueryContextAttributesA"},
{(void**)&secur.pFreeCredentialsHandle, "FreeCredentialsHandle"},
{(void**)&secur.pDeleteSecurityContext, "DeleteSecurityContext"},
{NULL, NULL}
};
dllfunction_t crypt_functable[] =
{
{(void**)&crypt.pCertGetCertificateChain, "CertGetCertificateChain"},
{(void**)&crypt.pCertVerifyCertificateChainPolicy, "CertVerifyCertificateChainPolicy"},
{(void**)&crypt.pCertFreeCertificateChain, "CertFreeCertificateChain"},
{(void**)&crypt.pCertNameToStrA, "CertNameToStrA"},
{(void**)&crypt.pCertCreateSelfSignCertificate, "CertCreateSelfSignCertificate"},
{(void**)&crypt.pCertStrToNameA, "CertStrToNameA"},
{NULL, NULL}
};
if (!secur.lib)
secur.lib = Sys_LoadLibrary("secur32.dll", secur_functable);
if (!crypt.lib)
crypt.lib = Sys_LoadLibrary("crypt32.dll", crypt_functable);
}
qboolean SSL_Inited(void)
{
return !!secur.lib && !!crypt.lib;
}
#define MessageAttribute (ISC_REQ_SEQUENCE_DETECT | ISC_REQ_REPLAY_DETECT | ISC_REQ_CONFIDENTIALITY | ISC_REQ_EXTENDED_ERROR | ISC_REQ_ALLOCATE_MEMORY | ISC_REQ_MANUAL_CRED_VALIDATION)
struct sslbuf
{
size_t datasize;
char *data;
size_t avail;
};
typedef struct {
vfsfile_t funcs;
vfsfile_t *stream;
wchar_t wpeername[256];
qboolean datagram;
enum
{
HS_ESTABLISHED,
HS_ERROR,
HS_STARTCLIENT,
HS_CLIENT,
HS_STARTSERVER,
HS_SERVER
} handshaking;
struct sslbuf outraw;
struct sslbuf outcrypt;
struct sslbuf inraw;
struct sslbuf incrypt;
CredHandle cred;
SecHandle sechnd;
int headersize, footersize;
char headerdata[1024], footerdata[1024];
#ifdef HAVE_DTLS
void *cbctx;
neterr_t (*transmit)(void *cbctx, const qbyte *data, size_t datasize);
#endif
} sslfile_t;
static int SSPI_ExpandBuffer(struct sslbuf *buf, size_t bytes)
{
if (bytes < buf->datasize)
return buf->datasize;
Z_ReallocElements((void**)&buf->data, &buf->datasize, bytes, 1);
return bytes;
}
static int SSPI_CopyIntoBuffer(struct sslbuf *buf, const void *data, unsigned int bytes, qboolean expand)
{
if (bytes > buf->datasize - buf->avail)
{
if (!expand || SSPI_ExpandBuffer(buf, buf->avail + bytes + 1024) < buf->avail + bytes)
bytes = buf->datasize - buf->avail;
}
memcpy(buf->data + buf->avail, data, bytes);
buf->avail += bytes;
return bytes;
}
static void SSPI_Error(sslfile_t *f, const char *error, ...)
{
va_list argptr;
char string[1024];
va_start (argptr, error);
vsnprintf (string,sizeof(string)-1, error,argptr);
va_end (argptr);
f->handshaking = HS_ERROR;
if (*string)
{
if (f->datagram)
Con_Printf(CON_ERROR "%s", string);
else
Sys_Printf(CON_ERROR "%s", string);
}
if (f->stream)
VFS_CLOSE(f->stream);
secur.pDeleteSecurityContext(&f->sechnd);
secur.pFreeCredentialsHandle(&f->cred);
f->stream = NULL;
}
static void SSPI_TryFlushCryptOut(sslfile_t *f)
{
int sent;
if (f->outcrypt.avail)
{
#ifdef HAVE_DTLS
if (f->transmit)
{
f->transmit(f->cbctx, f->outcrypt.data, f->outcrypt.avail);
f->outcrypt.avail = 0;
return;
}
#endif
sent = VFS_WRITE(f->stream, f->outcrypt.data, f->outcrypt.avail);
}
else
return;
if (sent > 0)
{
memmove(f->outcrypt.data, f->outcrypt.data + sent, f->outcrypt.avail - sent);
f->outcrypt.avail -= sent;
}
}
static int SSPI_CheckNewInCrypt(sslfile_t *f)
{
int newd;
if (!f->stream)
return VFS_ERROR_EOF;
newd = VFS_READ(f->stream, f->incrypt.data+f->incrypt.avail, f->incrypt.datasize - f->incrypt.avail);
if (newd < 0)
return newd;
else
f->incrypt.avail += newd;
return 0;
}
//convert inbound crypt->data
static void SSPI_Decode(sslfile_t *f)
{
SECURITY_STATUS ss;
SecBufferDesc BuffDesc;
SecBuffer SecBuff[4];
ULONG ulQop = 0;
SecBuffer *extra = NULL;
int i;
if (!f->incrypt.avail)
return;
BuffDesc.ulVersion = SECBUFFER_VERSION;
BuffDesc.cBuffers = countof(SecBuff);
BuffDesc.pBuffers = SecBuff;
SecBuff[0].BufferType = SECBUFFER_DATA;
SecBuff[0].cbBuffer = f->incrypt.avail;
SecBuff[0].pvBuffer = f->incrypt.data;
SecBuff[1].BufferType = SECBUFFER_EMPTY; //space for header
SecBuff[2].BufferType = SECBUFFER_EMPTY; //space for footer
SecBuff[3].BufferType = SECBUFFER_EMPTY; //space for extra marker
ss = secur.pDecryptMessage(&f->sechnd, &BuffDesc, 0, &ulQop);
if (ss < 0)
{
if (ss == SEC_E_INCOMPLETE_MESSAGE)
{
if (f->incrypt.avail == f->incrypt.datasize)
SSPI_ExpandBuffer(&f->incrypt, f->incrypt.datasize+1024);
return; //no error if its incomplete, we can just get more data later on.
}
switch(ss)
{
case SEC_E_DECRYPT_FAILURE: SSPI_Error(f, "DecryptMessage failed: SEC_E_DECRYPT_FAILURE\n", ss); break;
case SEC_E_INVALID_HANDLE: SSPI_Error(f, "DecryptMessage failed: SEC_E_INVALID_HANDLE\n"); break;
default: SSPI_Error(f, "DecryptMessage failed: %0#lx\n", ss); break;
}
return;
}
for (i = 0; i < BuffDesc.cBuffers; i++)
{
switch(SecBuff[i].BufferType)
{
case SECBUFFER_DATA:
if (SSPI_CopyIntoBuffer(&f->inraw, SecBuff[i].pvBuffer, SecBuff[i].cbBuffer, true) != SecBuff[i].cbBuffer)
SSPI_Error(f, "outraw buffer overflowed\n");
break;
case SECBUFFER_EXTRA:
if (extra)
SSPI_Error(f, "multiple extra buffers\n");
extra = &SecBuff[i];
break;
case SECBUFFER_EMPTY:
case SECBUFFER_MISSING:
case SECBUFFER_STREAM_TRAILER:
case SECBUFFER_STREAM_HEADER:
break;
default:
SSPI_Error(f, "got unexpected buffer type\n");
break;
}
}
//retain the extra. if there's no extra then mark it so.
if (extra)
{
memmove(f->incrypt.data, f->incrypt.data + (f->incrypt.avail - extra->cbBuffer), extra->cbBuffer);
f->incrypt.avail = extra->cbBuffer;
}
else
f->incrypt.avail = 0;
}
//convert outgoing data->crypt
static void SSPI_Encode(sslfile_t *f)
{
SECURITY_STATUS ss;
SecBufferDesc BuffDesc;
SecBuffer SecBuff[4];
ULONG ulQop = 0;
if (f->outcrypt.avail)
{
SSPI_TryFlushCryptOut(f);
if (f->outcrypt.avail)
return; //don't flood too much
}
//don't corrupt the handshake data.
if (f->handshaking)
return;
if (!f->outraw.avail)
return;
BuffDesc.ulVersion = SECBUFFER_VERSION;
BuffDesc.cBuffers = 4;
BuffDesc.pBuffers = SecBuff;
SecBuff[0].BufferType = SECBUFFER_STREAM_HEADER;
SecBuff[0].cbBuffer = f->headersize;
SecBuff[0].pvBuffer = f->headerdata;
SecBuff[1].BufferType = SECBUFFER_DATA;
SecBuff[1].cbBuffer = f->outraw.avail;
SecBuff[1].pvBuffer = f->outraw.data;
SecBuff[2].BufferType = SECBUFFER_STREAM_TRAILER;
SecBuff[2].cbBuffer = f->footersize;
SecBuff[2].pvBuffer = f->footerdata;
SecBuff[3].BufferType = SECBUFFER_EMPTY;
SecBuff[3].cbBuffer = 0;
SecBuff[3].pvBuffer = NULL;
ss = secur.pEncryptMessage(&f->sechnd, ulQop, &BuffDesc, 0);
if (ss < 0)
{
SSPI_Error(f, "EncryptMessage failed\n");
return;
}
f->outraw.avail = 0;
//fixme: these should be made non-fatal.
if (SSPI_CopyIntoBuffer(&f->outcrypt, SecBuff[0].pvBuffer, SecBuff[0].cbBuffer, true) < SecBuff[0].cbBuffer)
{
SSPI_Error(f, "crypt buffer overflowed\n");
return;
}
if (SSPI_CopyIntoBuffer(&f->outcrypt, SecBuff[1].pvBuffer, SecBuff[1].cbBuffer, true) < SecBuff[1].cbBuffer)
{
SSPI_Error(f, "crypt buffer overflowed\n");
return;
}
if (SSPI_CopyIntoBuffer(&f->outcrypt, SecBuff[2].pvBuffer, SecBuff[2].cbBuffer, true) < SecBuff[2].cbBuffer)
{
SSPI_Error(f, "crypt buffer overflowed\n");
return;
}
SSPI_TryFlushCryptOut(f);
}
char *narrowen(char *out, size_t outlen, wchar_t *wide);
static DWORD VerifyKnownCertificates(DWORD status, wchar_t *domain, qbyte *data, size_t datasize, qboolean datagram)
{
size_t knownsize;
void *knowncert;
char realdomain[256];
unsigned int probs = 0;
if (datagram)
{
if (status == CERT_E_UNTRUSTEDROOT || status == CERT_E_UNTRUSTEDTESTROOT)
probs |= CERTLOG_MISSINGCA;
if (status == CERT_E_EXPIRED)
probs |= CERTLOG_EXPIRED;
if (status == SEC_E_WRONG_PRINCIPAL)
probs |= CERTLOG_WRONGHOST;
if (status == CERT_E_UNTRUSTEDROOT || SUCCEEDED(status))
{
#ifndef SERVERONLY
if (CertLog_ConnectOkay(narrowen(realdomain, sizeof(realdomain), domain), data, datasize, probs))
status = SEC_E_OK;
else
#endif
status = TRUST_E_FAIL;
}
return status;
}
narrowen(realdomain, sizeof(realdomain), domain);
knowncert = TLS_GetKnownCertificate(realdomain, &knownsize);
if (knowncert)
{
if (knownsize == datasize && !memcmp(data, knowncert, datasize))
{ //what we know about matched
if (status == CERT_E_UNTRUSTEDROOT || status == CERT_E_EXPIRED)
status = SEC_E_OK;
}
else
{
if (status != CERT_E_EXPIRED)
Con_Printf("%ls has an unexpected certificate\n", domain);
if (status == SEC_E_OK) //we (think) we know better.
status = TRUST_E_FAIL;
}
BZ_Free(knowncert);
}
#ifndef SERVERONLY
//self-signed and expired certs are understandable in many situations.
//prompt and cache (although this connection attempt will fail).
if (status == CERT_E_UNTRUSTEDROOT || status == CERT_E_UNTRUSTEDTESTROOT)
probs |= CERTLOG_MISSINGCA;
else if (status == CERT_E_EXPIRED)
probs |= CERTLOG_EXPIRED;
else if (status == SEC_E_WRONG_PRINCIPAL)
probs |= CERTLOG_WRONGHOST;
else if (status != SEC_E_OK)
probs |= CERTLOG_UNKNOWN;
if (status == CERT_E_UNTRUSTEDROOT || status == CERT_E_UNTRUSTEDTESTROOT || status == CERT_E_EXPIRED)
if (CertLog_ConnectOkay(realdomain, data, datasize, probs))
return SEC_E_OK;
#endif
return status;
}
static DWORD VerifyServerCertificate(PCCERT_CONTEXT pServerCert, PWSTR pwszServerName, DWORD dwCertFlags, qboolean datagram)
{
HTTPSPolicyCallbackData polHttps;
CERT_CHAIN_POLICY_PARA PolicyPara;
CERT_CHAIN_POLICY_STATUS PolicyStatus;
CERT_CHAIN_PARA ChainPara;
PCCERT_CHAIN_CONTEXT pChainContext;
DWORD Status;
LPSTR rgszUsages[] =
{
szOID_PKIX_KP_SERVER_AUTH,
szOID_SERVER_GATED_CRYPTO,
szOID_SGC_NETSCAPE
};
DWORD cUsages = sizeof(rgszUsages) / sizeof(LPSTR);
if(pServerCert == NULL)
return SEC_E_WRONG_PRINCIPAL;
if(!*pwszServerName)
return SEC_E_WRONG_PRINCIPAL;
// Build certificate chain.
memset(&ChainPara, 0, sizeof(ChainPara));
ChainPara.cbSize = sizeof(ChainPara);
ChainPara.RequestedUsage.dwType = USAGE_MATCH_TYPE_OR;
ChainPara.RequestedUsage.Usage.cUsageIdentifier = cUsages;
ChainPara.RequestedUsage.Usage.rgpszUsageIdentifier = rgszUsages;
if (!crypt.pCertGetCertificateChain(NULL, pServerCert, NULL, pServerCert->hCertStore, &ChainPara, 0, NULL, &pChainContext))
{
Status = GetLastError();
Sys_Printf("Error %#lx returned by CertGetCertificateChain!\n", Status);
}
else
{
// Validate certificate chain.
memset(&polHttps, 0, sizeof(HTTPSPolicyCallbackData));
polHttps.cbStruct = sizeof(HTTPSPolicyCallbackData);
polHttps.dwAuthType = AUTHTYPE_SERVER;
polHttps.fdwChecks = dwCertFlags;
polHttps.pwszServerName = pwszServerName;
memset(&PolicyPara, 0, sizeof(PolicyPara));
PolicyPara.cbSize = sizeof(PolicyPara);
PolicyPara.pvExtraPolicyPara = &polHttps;
memset(&PolicyStatus, 0, sizeof(PolicyStatus));
PolicyStatus.cbSize = sizeof(PolicyStatus);
if (!crypt.pCertVerifyCertificateChainPolicy(CERT_CHAIN_POLICY_SSL, pChainContext, &PolicyPara, &PolicyStatus))
{
Status = GetLastError();
Sys_Printf("Error %#lx returned by CertVerifyCertificateChainPolicy!\n", Status);
}
else
{
Status = VerifyKnownCertificates(PolicyStatus.dwError, pwszServerName, pServerCert->pbCertEncoded, pServerCert->cbCertEncoded, datagram);
if (Status)
{
char fmsg[512];
char *err;
switch (Status)
{
case CERT_E_EXPIRED: err = "CERT_E_EXPIRED"; break;
case CERT_E_VALIDITYPERIODNESTING: err = "CERT_E_VALIDITYPERIODNESTING"; break;
case CERT_E_ROLE: err = "CERT_E_ROLE"; break;
case CERT_E_PATHLENCONST: err = "CERT_E_PATHLENCONST"; break;
case CERT_E_CRITICAL: err = "CERT_E_CRITICAL"; break;
case CERT_E_PURPOSE: err = "CERT_E_PURPOSE"; break;
case CERT_E_ISSUERCHAINING: err = "CERT_E_ISSUERCHAINING"; break;
case CERT_E_MALFORMED: err = "CERT_E_MALFORMED"; break;
case CERT_E_UNTRUSTEDROOT: err = "CERT_E_UNTRUSTEDROOT"; break;
case CERT_E_CHAINING: err = "CERT_E_CHAINING"; break;
case TRUST_E_FAIL: err = "TRUST_E_FAIL"; break;
case CERT_E_REVOKED: err = "CERT_E_REVOKED"; break;
case CERT_E_UNTRUSTEDTESTROOT: err = "CERT_E_UNTRUSTEDTESTROOT"; break;
case CERT_E_REVOCATION_FAILURE: err = "CERT_E_REVOCATION_FAILURE"; break;
case CERT_E_CN_NO_MATCH:
err = fmsg;
Q_strncpyz(fmsg, "Certificate is for ", sizeof(fmsg));
crypt.pCertNameToStrA(X509_ASN_ENCODING, &pServerCert->pCertInfo->Subject, 0, fmsg+strlen(fmsg), sizeof(fmsg)-strlen(fmsg));
break;
case CERT_E_WRONG_USAGE: err = "CERT_E_WRONG_USAGE"; break;
default: err = "(unknown)"; break;
}
Con_Printf(CON_ERROR "Error verifying certificate for '%ls': %s\n", pwszServerName, err);
if (tls_ignorecertificateerrors.ival)
{
Con_Printf(CON_WARNING "pretending it didn't happen... (tls_ignorecertificateerrors is set)\n");
Status = SEC_E_OK;
}
}
else
Status = SEC_E_OK;
}
crypt.pCertFreeCertificateChain(pChainContext);
}
return Status;
}
static PCCERT_CONTEXT SSPI_GetServerCertificate(void)
{
static PCCERT_CONTEXT ret;
char *issuertext = "CN=127.0.0.1, O=\"FTE QuakeWorld\", OU=Testing, C=TR";
CERT_NAME_BLOB issuerblob;
CRYPT_ALGORITHM_IDENTIFIER sigalg;
SYSTEMTIME expiredate;
if (ret)
return ret;
memset(&sigalg, 0, sizeof(sigalg));
sigalg.pszObjId = szOID_RSA_SHA512RSA;
GetSystemTime(&expiredate);
expiredate.wYear += 2; //2 years hence. woo
memset(&issuerblob, 0, sizeof(issuerblob));
crypt.pCertStrToNameA(X509_ASN_ENCODING, issuertext, CERT_X500_NAME_STR, NULL, issuerblob.pbData, &issuerblob.cbData, NULL);
issuerblob.pbData = Z_Malloc(issuerblob.cbData);
crypt.pCertStrToNameA(X509_ASN_ENCODING, issuertext, CERT_X500_NAME_STR, NULL, issuerblob.pbData, &issuerblob.cbData, NULL);
ret = crypt.pCertCreateSelfSignCertificate(
0,
&issuerblob,
0,
NULL,
&sigalg,
NULL,
&expiredate,
NULL
);
if (!ret)
{ //try and downgrade the signature algo if it failed.
sigalg.pszObjId = szOID_RSA_SHA1RSA;
ret = crypt.pCertCreateSelfSignCertificate(
0,
&issuerblob,
0,
NULL,
&sigalg,
NULL,
&expiredate,
NULL
);
}
Z_Free(issuerblob.pbData);
return ret;
}
static void SSPI_GenServerCredentials(sslfile_t *f)
{
SECURITY_STATUS ss;
TimeStamp Lifetime;
SCHANNEL_CRED SchannelCred;
PCCERT_CONTEXT cred;
memset(&SchannelCred, 0, sizeof(SchannelCred));
SchannelCred.dwVersion = SCHANNEL_CRED_VERSION;
SchannelCred.grbitEnabledProtocols = f->datagram?USE_PROT_DGRAM_SERVER:USE_PROT_SERVER;
SchannelCred.dwFlags |= SCH_CRED_NO_SYSTEM_MAPPER|SCH_CRED_DISABLE_RECONNECTS; /*don't use windows login info or anything*/
cred = SSPI_GetServerCertificate();
SchannelCred.cCreds = 1;
SchannelCred.paCred = &cred;
if (!cred)
{
SSPI_Error(f, localtext("Unable to load/generate certificate\n"));
return;
}
ss = secur.pAcquireCredentialsHandleA (NULL, UNISP_NAME_A, SECPKG_CRED_INBOUND, NULL, &SchannelCred, NULL, NULL, &f->cred, &Lifetime);
if (ss < 0)
{
SSPI_Error(f, localtext("WinSSPI: AcquireCredentialsHandle failed\n"));
return;
}
}
static void SSPI_Handshake (sslfile_t *f)
{
SECURITY_STATUS ss;
TimeStamp Lifetime;
SecBufferDesc OutBuffDesc;
SecBuffer OutSecBuff[8];
SecBufferDesc InBuffDesc;
SecBuffer InSecBuff[8];
ULONG ContextAttributes;
SCHANNEL_CRED SchannelCred;
int i;
qboolean retries = 5;
// char buf1[128];
// char buf2[128];
retry:
if (f->outcrypt.avail)
{
//don't let things build up too much
SSPI_TryFlushCryptOut(f);
if (f->outcrypt.avail)
return;
}
//FIXME: skip this if we've had no new data since last time
OutBuffDesc.ulVersion = SECBUFFER_VERSION;
OutBuffDesc.cBuffers = countof(OutSecBuff);
OutBuffDesc.pBuffers = OutSecBuff;
OutSecBuff[0].BufferType = SECBUFFER_TOKEN;
OutSecBuff[0].cbBuffer = f->outcrypt.datasize - f->outcrypt.avail;
OutSecBuff[0].pvBuffer = f->outcrypt.data + f->outcrypt.avail;
for (i = 0; i < OutBuffDesc.cBuffers; i++)
{
OutSecBuff[i].BufferType = SECBUFFER_EMPTY;
OutSecBuff[i].pvBuffer = NULL;
OutSecBuff[i].cbBuffer = 0;
}
if (f->handshaking == HS_ERROR)
return; //gave up.
else if (f->handshaking == HS_STARTCLIENT)
{
//no input data yet.
f->handshaking = HS_CLIENT;
memset(&SchannelCred, 0, sizeof(SchannelCred));
SchannelCred.dwVersion = SCHANNEL_CRED_VERSION;
SchannelCred.grbitEnabledProtocols = f->datagram?USE_PROT_DGRAM_CLIENT:USE_PROT_CLIENT;
SchannelCred.dwFlags |= SCH_CRED_SNI_CREDENTIAL | SCH_CRED_NO_DEFAULT_CREDS; /*don't use windows login info or anything*/
ss = secur.pAcquireCredentialsHandleA (NULL, UNISP_NAME_A, SECPKG_CRED_OUTBOUND, NULL, &SchannelCred, NULL, NULL, &f->cred, &Lifetime);
if (ss < 0)
{
SSPI_Error(f, localtext("WINSSPI: AcquireCredentialsHandle failed\n"));
return;
}
ss = secur.pInitializeSecurityContextW (&f->cred, NULL, f->wpeername, MessageAttribute|(f->datagram?ISC_REQ_DATAGRAM:ISC_REQ_STREAM), 0, SECURITY_NATIVE_DREP, NULL, 0, &f->sechnd, &OutBuffDesc, &ContextAttributes, &Lifetime);
}
else if (f->handshaking == HS_CLIENT)
{
//only if we actually have data.
if (!f->incrypt.avail && !f->datagram)
return;
InBuffDesc.ulVersion = SECBUFFER_VERSION;
InBuffDesc.cBuffers = 4;
InBuffDesc.pBuffers = InSecBuff;
i = 0;
if (f->incrypt.avail)
{
InSecBuff[i].BufferType = SECBUFFER_TOKEN;
InSecBuff[i].cbBuffer = f->incrypt.avail;
InSecBuff[i].pvBuffer = f->incrypt.data;
i++;
}
for (; i < InBuffDesc.cBuffers; i++)
{
InSecBuff[i].BufferType = SECBUFFER_EMPTY;
InSecBuff[i].pvBuffer = NULL;
InSecBuff[i].cbBuffer = 0;
}
ss = secur.pInitializeSecurityContextW (&f->cred, &f->sechnd, NULL, MessageAttribute|(f->datagram?ISC_REQ_DATAGRAM:ISC_REQ_STREAM), 0, SECURITY_NETWORK_DREP, &InBuffDesc, 0, &f->sechnd, &OutBuffDesc, &ContextAttributes, &Lifetime);
if (ss == SEC_E_INCOMPLETE_MESSAGE)
{
// Con_Printf("SEC_E_INCOMPLETE_MESSAGE\n");
if (!f->datagram && f->incrypt.avail == f->incrypt.datasize)
SSPI_ExpandBuffer(&f->incrypt, f->incrypt.datasize+1024);
return;
}
else if (ss == SEC_E_INVALID_TOKEN)
{
// Con_Printf("SEC_E_INVALID_TOKEN\n");
if (f->datagram)
return; //our udp protocol may have non-dtls packets mixed in. besides, we don't want to die from spoofed packets.
}
// else if (ss == SEC_I_MESSAGE_FRAGMENT)
// Con_Printf("SEC_I_MESSAGE_FRAGMENT\n");
// else if (ss == SEC_I_CONTINUE_NEEDED)
// Con_Printf("SEC_I_CONTINUE_NEEDED\n");
// else
// Con_Printf("InitializeSecurityContextA %x\n", ss);
//any extra data should still remain for the next time around. this might be more handshake data or payload data.
if (InSecBuff[1].BufferType == SECBUFFER_EXTRA)
{
memmove(f->incrypt.data, f->incrypt.data + (f->incrypt.avail - InSecBuff[1].cbBuffer), InSecBuff[1].cbBuffer);
f->incrypt.avail = InSecBuff[1].cbBuffer;
}
else f->incrypt.avail = 0;
}
else if (f->handshaking == HS_STARTSERVER || f->handshaking == HS_SERVER)
{
//only if we actually have data.
if (!f->incrypt.avail)
return;
InBuffDesc.ulVersion = SECBUFFER_VERSION;
InBuffDesc.cBuffers = countof(InSecBuff);
InBuffDesc.pBuffers = InSecBuff;
i = 0;
if (f->incrypt.avail)
{
InSecBuff[i].BufferType = SECBUFFER_TOKEN;
InSecBuff[i].cbBuffer = f->incrypt.avail;
InSecBuff[i].pvBuffer = f->incrypt.data;
i++;
}
for (; i < InBuffDesc.cBuffers; i++)
{
InSecBuff[i].BufferType = SECBUFFER_EMPTY;
InSecBuff[i].pvBuffer = NULL;
InSecBuff[i].cbBuffer = 0;
}
i = 1;
OutSecBuff[i++].BufferType = SECBUFFER_EXTRA;
OutSecBuff[i++].BufferType = 17/*SECBUFFER_ALERT*/;
#define ServerMessageAttribute (ASC_REQ_SEQUENCE_DETECT | ASC_REQ_REPLAY_DETECT | ASC_REQ_CONFIDENTIALITY /*| ASC_REQ_EXTENDED_ERROR*/ | ASC_REQ_ALLOCATE_MEMORY)
ss = secur.pAcceptSecurityContext(&f->cred, (f->handshaking==HS_SERVER)?&f->sechnd:NULL, &InBuffDesc,
ServerMessageAttribute|(f->datagram?ASC_REQ_DATAGRAM:ASC_REQ_STREAM), SECURITY_NETWORK_DREP, &f->sechnd,
&OutBuffDesc, &ContextAttributes, NULL);
if (ss == SEC_E_INVALID_TOKEN)
{
// Con_Printf("SEC_E_INVALID_TOKEN\n");
if (f->datagram)
return;
}
else if (ss == SEC_E_INCOMPLETE_MESSAGE)
{
// Con_Printf("SEC_E_INCOMPLETE_MESSAGE\n");
if (!f->datagram && f->incrypt.avail == f->incrypt.datasize)
SSPI_ExpandBuffer(&f->incrypt, f->incrypt.datasize+1024);
return;
}
// else
// Con_Printf("InitializeSecurityContextA %x\n", ss);
f->handshaking = HS_SERVER;
//any extra data should still remain for the next time around. this might be more handshake data or payload data.
if (InSecBuff[1].BufferType == SECBUFFER_EXTRA)
{
memmove(f->incrypt.data, f->incrypt.data + (f->incrypt.avail - InSecBuff[1].cbBuffer), InSecBuff[1].cbBuffer);
f->incrypt.avail = InSecBuff[1].cbBuffer;
}
else f->incrypt.avail = 0;
}
else
return;
if (ss == SEC_I_INCOMPLETE_CREDENTIALS)
{
SSPI_Error(f, localtext("server requires credentials\n"));
return;
}
if (ss < 0)
{
switch(ss)
{
case SEC_E_ALGORITHM_MISMATCH: SSPI_Error(f, "InitializeSecurityContext failed: SEC_E_ALGORITHM_MISMATCH\n"); break;
case SEC_E_INVALID_HANDLE: SSPI_Error(f, "InitializeSecurityContext failed: SEC_E_INVALID_HANDLE\n"); break;
case SEC_E_ILLEGAL_MESSAGE: SSPI_Error(f, "InitializeSecurityContext failed: SEC_E_ILLEGAL_MESSAGE\n"); break;
case SEC_E_INVALID_TOKEN: SSPI_Error(f, "InitializeSecurityContext failed: SEC_E_INVALID_TOKEN\n"); break;
case SEC_E_INVALID_PARAMETER: SSPI_Error(f, "InitializeSecurityContext failed: SEC_E_INVALID_PARAMETER\n"); break;
default: SSPI_Error(f, "InitializeSecurityContext failed: %lx\n", (long)ss); break;
}
return;
}
if ((SEC_I_COMPLETE_NEEDED == ss) || (SEC_I_COMPLETE_AND_CONTINUE == ss))
{
ss = secur.pCompleteAuthToken (&f->sechnd, &OutBuffDesc);
if (ss < 0)
{
SSPI_Error(f, "CompleteAuthToken failed\n");
return;
}
}
//its all okay and established if we get this far.
if (ss == SEC_E_OK)
{
SecPkgContext_StreamSizes strsizes;
CERT_CONTEXT *remotecert;
secur.pQueryContextAttributesA(&f->sechnd, SECPKG_ATTR_STREAM_SIZES, &strsizes);
f->headersize = strsizes.cbHeader;
f->footersize = strsizes.cbTrailer;
if (f->handshaking != HS_SERVER)
{ //server takes an annonymous client. client expects a proper certificate.
if (*f->wpeername)
{
ss = secur.pQueryContextAttributesA(&f->sechnd, SECPKG_ATTR_REMOTE_CERT_CONTEXT, &remotecert);
if (ss != SEC_E_OK)
{
SSPI_Error(f, localtext("unable to read server's certificate\n"));
return;
}
if (VerifyServerCertificate(remotecert, f->wpeername, 0, f->datagram))
{
SSPI_Error(f, localtext("Error validating certificante\n"));
return;
}
}
else
Sys_Printf("SSL/TLS Server name not specified, skipping verification\n");
}
f->handshaking = HS_ESTABLISHED;
}
//send early, send often.
#ifdef HAVE_DTLS
if (f->transmit)
{
for (i = 0; i < OutBuffDesc.cBuffers; i++)
if (OutSecBuff[i].BufferType == SECBUFFER_TOKEN && OutSecBuff[i].cbBuffer)
f->transmit(f->cbctx, OutSecBuff[i].pvBuffer, OutSecBuff[i].cbBuffer);
}
else
#endif
{
i = 0;
if (SSPI_CopyIntoBuffer(&f->outcrypt, OutSecBuff[i].pvBuffer, OutSecBuff[i].cbBuffer, true) < OutSecBuff[i].cbBuffer)
{
SSPI_Error(f, "crypt overflow\n");
return;
}
SSPI_TryFlushCryptOut(f);
}
if (f->handshaking == HS_ESTABLISHED)
SSPI_Encode(f);
else if (ss == SEC_I_MESSAGE_FRAGMENT) //looks like we can connect faster if we loop when we get this result.
if (retries --> 0)
goto retry;
}
static int QDECL SSPI_ReadBytes (struct vfsfile_s *file, void *buffer, int bytestoread)
{
sslfile_t *f = (sslfile_t *)file;
int err = SSPI_CheckNewInCrypt(f);
if (f->handshaking)
{
SSPI_Handshake(f);
return err;
}
SSPI_Encode(f);
SSPI_Decode(f);
bytestoread = min(bytestoread, f->inraw.avail);
if (bytestoread)
{
memcpy(buffer, f->inraw.data, bytestoread);
f->inraw.avail -= bytestoread;
memmove(f->inraw.data, f->inraw.data + bytestoread, f->inraw.avail);
}
else
{
if (err)
return err;
}
return bytestoread;
}
static int QDECL SSPI_WriteBytes (struct vfsfile_s *file, const void *buffer, int bytestowrite)
{
sslfile_t *f = (sslfile_t *)file;
//don't endlessly accept data faster than we can push it out.
//we'll buffer a little, but don't go overboard
if (f->outcrypt.avail > 8192)
return false;
bytestowrite = SSPI_CopyIntoBuffer(&f->outraw, buffer, bytestowrite, false);
if (f->handshaking)
{
SSPI_CheckNewInCrypt(f); //make sure its ticking over
SSPI_Handshake(f);
}
else
{
SSPI_Encode(f);
}
return bytestowrite;
}
static qboolean QDECL SSPI_Seek (struct vfsfile_s *file, qofs_t pos)
{
SSPI_Error((sslfile_t*)file, "unable to seek on streams\n");
return false;
}
static qofs_t QDECL SSPI_Tell (struct vfsfile_s *file)
{
SSPI_Error((sslfile_t*)file, "unable to seek on streams\n");
return 0;
}
static qofs_t QDECL SSPI_GetLen (struct vfsfile_s *file)
{
return 0;
}
static qboolean QDECL SSPI_Close (struct vfsfile_s *file)
{
sslfile_t *f = (sslfile_t *)file;
qboolean success = f->stream != NULL;
SSPI_Error(f, "");
Z_Free(f->outraw.data);
Z_Free(f->outcrypt.data);
Z_Free(f->inraw.data);
Z_Free(f->incrypt.data);
Z_Free(f);
return success;
}
#include <wchar.h>
vfsfile_t *SSPI_OpenVFS(const char *servername, vfsfile_t *source, qboolean server)
{
sslfile_t *newf;
int i = 0;
int err;
unsigned int c;
// const char *localname;
const char *peername;
if (!source || !SSL_Inited())
return NULL;
if (server)
{
// localname = servername;
peername = "";
}
else
{
// localname = "";
peername = servername;
}
/*
if (server) //unsupported
return NULL;
*/
newf = Z_Malloc(sizeof(*newf));
while(*peername)
{
c = utf8_decode(&err, peername, (void*)&peername);
if (c > WCHAR_MAX)
err = true; //no 16bit surrogates. they're evil.
else if (i == sizeof(newf->wpeername)/sizeof(newf->wpeername[0]) - 1)
err = true; //no space to store it
else
newf->wpeername[i++] = c;
if (err)
{
Z_Free(newf);
return NULL;
}
}
newf->wpeername[i] = 0;
newf->handshaking = server?HS_STARTSERVER:HS_STARTCLIENT;
newf->stream = source;
newf->funcs.Close = SSPI_Close;
newf->funcs.Flush = NULL;
newf->funcs.GetLen = SSPI_GetLen;
newf->funcs.ReadBytes = SSPI_ReadBytes;
newf->funcs.Seek = SSPI_Seek;
newf->funcs.Tell = SSPI_Tell;
newf->funcs.WriteBytes = SSPI_WriteBytes;
newf->funcs.seekstyle = SS_UNSEEKABLE;
SSPI_ExpandBuffer(&newf->outraw, 8192);
SSPI_ExpandBuffer(&newf->outcrypt, 8192);
SSPI_ExpandBuffer(&newf->inraw, 8192);
SSPI_ExpandBuffer(&newf->incrypt, 8192);
if (server)
SSPI_GenServerCredentials(newf);
return &newf->funcs;
}
#ifndef SECPKG_ATTR_UNIQUE_BINDINGS
#define SECPKG_ATTR_UNIQUE_BINDINGS 25
typedef struct _SecPkgContext_Bindings
{
unsigned long BindingsLength;
SEC_CHANNEL_BINDINGS *Bindings;
} SecPkgContext_Bindings, *PSecPkgContext_Bindings;
#endif
int SSPI_GetChannelBinding(vfsfile_t *vf, qbyte *binddata, size_t *bindsize)
{
int ret;
sslfile_t *f = (sslfile_t*)vf;
SecPkgContext_Bindings bindings;
if (vf->Close != SSPI_Close)
return -2; //not one of ours.
bindings.BindingsLength = 0;
bindings.Bindings = NULL;
ret = 0;
switch(secur.pQueryContextAttributesA(&f->sechnd, SECPKG_ATTR_UNIQUE_BINDINGS, &bindings))
{
case SEC_E_OK:
if (bindings.Bindings->cbApplicationDataLength <= *bindsize)
{
//will contain 'tls-unique:BINARYDATA'
*bindsize = bindings.Bindings->cbApplicationDataLength-11;
memcpy(binddata, ((unsigned char*) bindings.Bindings) + bindings.Bindings->dwApplicationDataOffset+11, bindings.Bindings->cbApplicationDataLength-11);
ret = 1;
}
//FIXME: leak
//secur.pFreeContextBuffer(bindings.Bindings);
break;
case SEC_E_UNSUPPORTED_FUNCTION:
ret = -1; //schannel doesn't support it. too old an OS, I guess.
break;
default:
break;
}
return ret;
}
#include "netinc.h"
#if 0
struct fakedtls_s
{
void *cbctx;
neterr_t(*push)(void *cbctx, const qbyte *data, size_t datasize);
};
static void *FAKEDTLS_CreateContext(const char *remotehost, void *cbctx, neterr_t(*push)(void *cbctx, const qbyte *data, size_t datasize), qboolean isserver)
{
struct fakedtls_s *ctx = Z_Malloc(sizeof(*ctx));
ctx->cbctx = cbctx;
ctx->push = push;
return ctx;
}
static void FAKEDTLS_DestroyContext(void *vctx)
{
Z_Free(vctx);
}
static neterr_t FAKEDTLS_Transmit(void *vctx, const qbyte *data, size_t datasize)
{
struct fakedtls_s *ctx = vctx;
neterr_t r;
*(int*)data ^= 0xdeadbeef;
r = ctx->push(ctx->cbctx, data, datasize);
*(int*)data ^= 0xdeadbeef;
return r;
}
static neterr_t FAKEDTLS_Received(void *ctx, qbyte *data, size_t datasize)
{
*(int*)data ^= 0xdeadbeef;
return NETERR_SENT;
}
static neterr_t FAKEDTLS_Timeouts(void *ctx)
{
// fakedtls_s *f = (fakedtls_s *)ctx;
return NETERR_SENT;
}
static const dtlsfuncs_t dtlsfuncs_fakedtls =
{
FAKEDTLS_CreateContext,
FAKEDTLS_DestroyContext,
FAKEDTLS_Transmit,
FAKEDTLS_Received,
FAKEDTLS_Timeouts,
};
const dtlsfuncs_t *FAKEDTLS_InitServer(void)
{
return &dtlsfuncs_fakedtls;
}
const dtlsfuncs_t *FAKEDTLS_InitClient(void)
{
return &dtlsfuncs_fakedtls;
}
#elif defined(HAVE_DTLS)
static void *SSPI_DTLS_CreateContext(const char *remotehost, void *cbctx, neterr_t(*push)(void *cbctx, const qbyte *data, size_t datasize), qboolean isserver)
{
int i = 0;
sslfile_t *ctx;
if (!SSL_Inited())
return NULL;
ctx = Z_Malloc(sizeof(*ctx));
ctx->datagram = true;
ctx->handshaking = isserver?HS_STARTSERVER:HS_STARTCLIENT;
ctx->cbctx = cbctx;
ctx->transmit = push;
while(*remotehost)
{
int err;
int c = utf8_decode(&err, remotehost, (void*)&remotehost);
if (c > WCHAR_MAX)
err = true; //no 16bit surrogates. they're evil.
else if (i == sizeof(ctx->wpeername)/sizeof(ctx->wpeername[0]) - 1)
err = true; //no space to store it
else
ctx->wpeername[i++] = c;
if (err)
{
Z_Free(ctx);
return NULL;
}
}
ctx->wpeername[i] = 0;
SSPI_ExpandBuffer(&ctx->outraw, 8192);
SSPI_ExpandBuffer(&ctx->outcrypt, 65536);
SSPI_ExpandBuffer(&ctx->inraw, 8192);
SSPI_ExpandBuffer(&ctx->incrypt, 65536);
if (isserver)
SSPI_GenServerCredentials(ctx);
else
SSPI_Handshake(ctx); //begin the initial handshake now
return ctx;
}
static void SSPI_DTLS_DestroyContext(void *vctx)
{
SSPI_Close(vctx);
}
static neterr_t SSPI_DTLS_Transmit(void *ctx, const qbyte *data, size_t datasize)
{
int ret;
sslfile_t *f = (sslfile_t *)ctx;
//Con_Printf("DTLS_Transmit: %i\n", datasize);
//sspi likes writing over the source data. make sure nothing is hurt by copying it out first.
f->outraw.avail = 0;
SSPI_CopyIntoBuffer(&f->outraw, data, datasize, true);
if (f->handshaking)
{
SSPI_Handshake(f);
if (f->handshaking == HS_ERROR)
ret = NETERR_DISCONNECTED;
else
ret = NETERR_CLOGGED; //not ready yet
}
else
{
SSPI_Encode(f);
ret = NETERR_SENT;
}
return ret;
}
static neterr_t SSPI_DTLS_Received(void *ctx, qbyte *data, size_t datasize)
{
int ret;
sslfile_t *f = (sslfile_t *)ctx;
//Con_Printf("DTLS_Received: %i\n", datasize);
f->incrypt.data = data;
f->incrypt.avail = f->incrypt.datasize = datasize;
if (f->handshaking)
{
SSPI_Handshake(f);
ret = NETERR_CLOGGED; //not ready yet
if (f->handshaking == HS_ERROR)
ret = NETERR_DISCONNECTED;
}
else
{
SSPI_Decode(f);
ret = NETERR_SENT;
memcpy(net_message_buffer, f->inraw.data, f->inraw.avail);
net_message.cursize = f->inraw.avail;
f->inraw.avail = 0;
net_message_buffer[net_message.cursize] = 0;
// Con_Printf("returning %i bytes: %s\n", net_message.cursize, net_message_buffer);
}
f->incrypt.data = NULL;
return ret;
}
static neterr_t SSPI_DTLS_Timeouts(void *ctx)
{
sslfile_t *f = (sslfile_t *)ctx;
if (f->handshaking)
{
// SSPI_Handshake(f);
return NETERR_CLOGGED;
}
return NETERR_SENT;
}
static const dtlsfuncs_t dtlsfuncs_schannel =
{
SSPI_DTLS_CreateContext,
SSPI_DTLS_DestroyContext,
SSPI_DTLS_Transmit,
SSPI_DTLS_Received,
SSPI_DTLS_Timeouts,
};
const dtlsfuncs_t *SSPI_DTLS_InitServer(void)
{
//FIXME: at this point, schannel is still returning errors when I try acting as a server.
//so just block any attempt to use this as a server.
//clients don't need/get certs.
return NULL;
}
const dtlsfuncs_t *SSPI_DTLS_InitClient(void)
{
return &dtlsfuncs_schannel;
}
#endif
//#include <ntstatus.h> //windows sucks too much to actually include this. oh well.
#define STATUS_SUCCESS ((NTSTATUS)0x00000000)
#define STATUS_INVALID_SIGNATURE ((NTSTATUS)0xC000A000)
enum hashvalidation_e SSPI_VerifyHash(qbyte *hashdata, size_t hashsize, const char *authority, qbyte *signdata, size_t signsize)
{
NTSTATUS status;
BCRYPT_KEY_HANDLE pubkey;
size_t sz;
const char *pem = Auth_GetKnownCertificate(authority, &sz);
const char *pemend;
qbyte *der;
size_t dersize;
static const void *(WINAPI *pCertCreateContext) (DWORD dwContextType, DWORD dwEncodingType, const BYTE *pbEncoded, DWORD cbEncoded, DWORD dwFlags, PCERT_CREATE_CONTEXT_PARA pCreatePara);
static BOOL (WINAPI *pCryptImportPublicKeyInfoEx2) (DWORD dwCertEncodingType, PCERT_PUBLIC_KEY_INFO pInfo, DWORD dwFlags, void *pvAuxInfo, BCRYPT_KEY_HANDLE *phKey);
static BOOL (WINAPI *pCertFreeCertificateContext) (PCCERT_CONTEXT pCertContext);
static dllhandle_t *crypt32;
static dllfunction_t crypt32funcs[] = {
{(void**)&pCertCreateContext, "CertCreateContext"},
{(void**)&pCryptImportPublicKeyInfoEx2, "CryptImportPublicKeyInfoEx2"}, //WARNING: fails on wine.
{(void**)&pCertFreeCertificateContext, "CertFreeCertificateContext"},
{NULL,NULL}
};
static NTSTATUS (WINAPI *pBCryptVerifySignature) (BCRYPT_KEY_HANDLE hKey, VOID *pPaddingInfo, PUCHAR pbHash, ULONG cbHash, PUCHAR pbSignature, ULONG cbSignature, ULONG dwFlags);
static NTSTATUS (WINAPI *pBCryptDestroyKey) (BCRYPT_KEY_HANDLE hKey);
static dllhandle_t *bcrypt;
static dllfunction_t bcryptfuncs[] = {
{(void**)&pBCryptVerifySignature, "BCryptVerifySignature"},
{(void**)&pBCryptDestroyKey, "BCryptDestroyKey"},
{NULL,NULL}
};
if (!crypt32)
crypt32 = Sys_LoadLibrary("crypt32.dll", crypt32funcs);
if (!bcrypt)
bcrypt = Sys_LoadLibrary("bcrypt.dll", bcryptfuncs);
if (!crypt32 || !bcrypt)
{
Con_Printf("Unable to obtain required crypto functions\n");
return VH_UNSUPPORTED;
}
if (!pem)
return VH_AUTHORITY_UNKNOWN; //no public cert/key for authority.
pem = strstr(pem, "-----BEGIN CERTIFICATE-----");
if (!pem)
return VH_UNSUPPORTED; //not a pem
pem += strlen("-----BEGIN CERTIFICATE-----");
pemend = strstr(pem, "-----END CERTIFICATE-----");
if (!pemend)
return VH_UNSUPPORTED;
dersize = Base64_DecodeBlock(pem, pemend, NULL, 0); //guess
der = alloca(dersize);
dersize = Base64_DecodeBlock(pem, pemend, der, dersize);
//okay, now its in binary der format.
//make sense of the cert and pull out its public key...
{
const CERT_CONTEXT* cert = pCertCreateContext(CERT_STORE_CERTIFICATE_CONTEXT, X509_ASN_ENCODING, der, dersize, 0, NULL);
if (!pCryptImportPublicKeyInfoEx2(X509_ASN_ENCODING, &cert->pCertInfo->SubjectPublicKeyInfo, 0, NULL, &pubkey))
return VH_UNSUPPORTED;
pCertFreeCertificateContext(cert);
}
//yay, now we can do what we actually wanted in the first place.
status = pBCryptVerifySignature(pubkey, NULL, hashdata, hashsize, signdata, signsize, 0);
pBCryptDestroyKey(pubkey);
if (status == STATUS_SUCCESS)
return VH_CORRECT; //its okay
else if (status == STATUS_INVALID_SIGNATURE)
return VH_INCORRECT; //its bad
return VH_UNSUPPORTED; //some weird transient error...?
}
#endif