/* * dlls/rsaenh/rsaenh.c * RSAENH - RSA encryption for Wine * * Copyright 2002 TransGaming Technologies (David Hammerton) * Copyright 2004 Mike McCormack for CodeWeavers * Copyright 2004, 2005 Michael Jung * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "config.h" #include "wine/port.h" #include "wine/library.h" #include "wine/debug.h" #include #include #include "windef.h" #include "winbase.h" #include "winreg.h" #include "wincrypt.h" #include "lmcons.h" #include "handle.h" #include "implglue.h" WINE_DEFAULT_DEBUG_CHANNEL(crypt); /****************************************************************************** * CRYPTHASH - hash objects */ #define RSAENH_MAGIC_HASH 0x85938417u #define RSAENH_MAX_HASH_SIZE 104 #define RSAENH_HASHSTATE_IDLE 0 #define RSAENH_HASHSTATE_HASHING 1 #define RSAENH_HASHSTATE_FINISHED 2 typedef struct _RSAENH_TLS1PRF_PARAMS { CRYPT_DATA_BLOB blobLabel; CRYPT_DATA_BLOB blobSeed; } RSAENH_TLS1PRF_PARAMS; typedef struct tagCRYPTHASH { OBJECTHDR header; ALG_ID aiAlgid; HCRYPTKEY hKey; HCRYPTPROV hProv; DWORD dwHashSize; DWORD dwState; HASH_CONTEXT context; BYTE abHashValue[RSAENH_MAX_HASH_SIZE]; PHMAC_INFO pHMACInfo; RSAENH_TLS1PRF_PARAMS tpPRFParams; } CRYPTHASH; /****************************************************************************** * CRYPTKEY - key objects */ #define RSAENH_MAGIC_KEY 0x73620457u #define RSAENH_MAX_KEY_SIZE 48 #define RSAENH_MAX_BLOCK_SIZE 24 #define RSAENH_KEYSTATE_IDLE 0 #define RSAENH_KEYSTATE_ENCRYPTING 1 #define RSAENH_KEYSTATE_DECRYPTING 2 #define RSAENH_KEYSTATE_MASTERKEY 3 typedef struct _RSAENH_SCHANNEL_INFO { SCHANNEL_ALG saEncAlg; SCHANNEL_ALG saMACAlg; CRYPT_DATA_BLOB blobClientRandom; CRYPT_DATA_BLOB blobServerRandom; } RSAENH_SCHANNEL_INFO; typedef struct tagCRYPTKEY { OBJECTHDR header; ALG_ID aiAlgid; HCRYPTPROV hProv; DWORD dwMode; DWORD dwModeBits; DWORD dwPermissions; DWORD dwKeyLen; DWORD dwSaltLen; DWORD dwBlockLen; DWORD dwState; KEY_CONTEXT context; BYTE abKeyValue[RSAENH_MAX_KEY_SIZE]; BYTE abInitVector[RSAENH_MAX_BLOCK_SIZE]; BYTE abChainVector[RSAENH_MAX_BLOCK_SIZE]; RSAENH_SCHANNEL_INFO siSChannelInfo; } CRYPTKEY; /****************************************************************************** * KEYCONTAINER - key containers */ #define RSAENH_PERSONALITY_BASE 0u #define RSAENH_PERSONALITY_STRONG 1u #define RSAENH_PERSONALITY_ENHANCED 2u #define RSAENH_PERSONALITY_SCHANNEL 3u #define RSAENH_MAGIC_CONTAINER 0x26384993u typedef struct tagKEYCONTAINER { OBJECTHDR header; DWORD dwFlags; DWORD dwPersonality; DWORD dwEnumAlgsCtr; CHAR szName[MAX_PATH]; CHAR szProvName[MAX_PATH]; HCRYPTKEY hKeyExchangeKeyPair; HCRYPTKEY hSignatureKeyPair; } KEYCONTAINER; /****************************************************************************** * Some magic constants */ #define RSAENH_ENCRYPT 1 #define RSAENH_DECRYPT 0 #define RSAENH_HMAC_DEF_IPAD_CHAR 0x36 #define RSAENH_HMAC_DEF_OPAD_CHAR 0x5c #define RSAENH_HMAC_DEF_PAD_LEN 64 #define RSAENH_DES_EFFECTIVE_KEYLEN 56 #define RSAENH_DES_STORAGE_KEYLEN 64 #define RSAENH_3DES112_EFFECTIVE_KEYLEN 112 #define RSAENH_3DES112_STORAGE_KEYLEN 128 #define RSAENH_3DES_EFFECTIVE_KEYLEN 168 #define RSAENH_3DES_STORAGE_KEYLEN 192 #define RSAENH_MAGIC_RSA2 0x32415352 #define RSAENH_MAGIC_RSA1 0x31415352 #define RSAENH_PKC_BLOCKTYPE 0x02 #define RSAENH_SSL3_VERSION_MAJOR 3 #define RSAENH_SSL3_VERSION_MINOR 0 #define RSAENH_TLS1_VERSION_MAJOR 3 #define RSAENH_TLS1_VERSION_MINOR 1 #define RSAENH_REGKEY "Software\\Wine\\Crypto\\RSA\\%s" #define RSAENH_MIN(a,b) ((a)<(b)?(a):(b)) /****************************************************************************** * aProvEnumAlgsEx - Defines the capabilities of the CSP personalities. */ #define RSAENH_MAX_ENUMALGS 20 #define RSAENH_PCT1_SSL2_SSL3_TLS1 (CRYPT_FLAG_PCT1|CRYPT_FLAG_SSL2|CRYPT_FLAG_SSL3|CRYPT_FLAG_TLS1) PROV_ENUMALGS_EX aProvEnumAlgsEx[4][RSAENH_MAX_ENUMALGS+1] = { { {CALG_RC2, 40, 40, 56,0, 4,"RC2", 24,"RSA Data Security's RC2"}, {CALG_RC4, 40, 40, 56,0, 4,"RC4", 24,"RSA Data Security's RC4"}, {CALG_DES, 56, 56, 56,0, 4,"DES", 31,"Data Encryption Standard (DES)"}, {CALG_SHA, 160,160, 160,CRYPT_FLAG_SIGNING, 6,"SHA-1", 30,"Secure Hash Algorithm (SHA-1)"}, {CALG_MD2, 128,128, 128,CRYPT_FLAG_SIGNING, 4,"MD2", 23,"Message Digest 2 (MD2)"}, {CALG_MD4, 128,128, 128,CRYPT_FLAG_SIGNING, 4,"MD4", 23,"Message Digest 4 (MD4)"}, {CALG_MD5, 128,128, 128,CRYPT_FLAG_SIGNING, 4,"MD5", 23,"Message Digest 5 (MD5)"}, {CALG_SSL3_SHAMD5,288,288,288,0, 12,"SSL3 SHAMD5",12,"SSL3 SHAMD5"}, {CALG_MAC, 0, 0, 0,0, 4,"MAC", 28,"Message Authentication Code"}, {CALG_RSA_SIGN, 512,384,16384,CRYPT_FLAG_SIGNING|CRYPT_FLAG_IPSEC,9,"RSA_SIGN",14,"RSA Signature"}, {CALG_RSA_KEYX, 512,384, 1024,CRYPT_FLAG_SIGNING|CRYPT_FLAG_IPSEC,9,"RSA_KEYX",17,"RSA Key Exchange"}, {CALG_HMAC, 0, 0, 0,0, 5,"HMAC", 18,"Hugo's MAC (HMAC)"}, {0, 0, 0, 0,0, 1,"", 1,""} }, { {CALG_RC2, 128, 40, 128,0, 4,"RC2", 24,"RSA Data Security's RC2"}, {CALG_RC4, 128, 40, 128,0, 4,"RC4", 24,"RSA Data Security's RC4"}, {CALG_DES, 56, 56, 56,0, 4,"DES", 31,"Data Encryption Standard (DES)"}, {CALG_3DES_112, 112,112, 112,0, 13,"3DES TWO KEY",19,"Two Key Triple DES"}, {CALG_3DES, 168,168, 168,0, 5,"3DES", 21,"Three Key Triple DES"}, {CALG_SHA, 160,160, 160,CRYPT_FLAG_SIGNING, 6,"SHA-1", 30,"Secure Hash Algorithm (SHA-1)"}, {CALG_MD2, 128,128, 128,CRYPT_FLAG_SIGNING, 4,"MD2", 23,"Message Digest 2 (MD2)"}, {CALG_MD4, 128,128, 128,CRYPT_FLAG_SIGNING, 4,"MD4", 23,"Message Digest 4 (MD4)"}, {CALG_MD5, 128,128, 128,CRYPT_FLAG_SIGNING, 4,"MD5", 23,"Message Digest 5 (MD5)"}, {CALG_SSL3_SHAMD5,288,288,288,0, 12,"SSL3 SHAMD5",12,"SSL3 SHAMD5"}, {CALG_MAC, 0, 0, 0,0, 4,"MAC", 28,"Message Authentication Code"}, {CALG_RSA_SIGN,1024,384,16384,CRYPT_FLAG_SIGNING|CRYPT_FLAG_IPSEC,9,"RSA_SIGN",14,"RSA Signature"}, {CALG_RSA_KEYX,1024,384,16384,CRYPT_FLAG_SIGNING|CRYPT_FLAG_IPSEC,9,"RSA_KEYX",17,"RSA Key Exchange"}, {CALG_HMAC, 0, 0, 0,0, 5,"HMAC", 18,"Hugo's MAC (HMAC)"}, {0, 0, 0, 0,0, 1,"", 1,""} }, { {CALG_RC2, 128, 40, 128,0, 4,"RC2", 24,"RSA Data Security's RC2"}, {CALG_RC4, 128, 40, 128,0, 4,"RC4", 24,"RSA Data Security's RC4"}, {CALG_DES, 56, 56, 56,0, 4,"DES", 31,"Data Encryption Standard (DES)"}, {CALG_3DES_112, 112,112, 112,0, 13,"3DES TWO KEY",19,"Two Key Triple DES"}, {CALG_3DES, 168,168, 168,0, 5,"3DES", 21,"Three Key Triple DES"}, {CALG_SHA, 160,160, 160,CRYPT_FLAG_SIGNING, 6,"SHA-1", 30,"Secure Hash Algorithm (SHA-1)"}, {CALG_MD2, 128,128, 128,CRYPT_FLAG_SIGNING, 4,"MD2", 23,"Message Digest 2 (MD2)"}, {CALG_MD4, 128,128, 128,CRYPT_FLAG_SIGNING, 4,"MD4", 23,"Message Digest 4 (MD4)"}, {CALG_MD5, 128,128, 128,CRYPT_FLAG_SIGNING, 4,"MD5", 23,"Message Digest 5 (MD5)"}, {CALG_SSL3_SHAMD5,288,288,288,0, 12,"SSL3 SHAMD5",12,"SSL3 SHAMD5"}, {CALG_MAC, 0, 0, 0,0, 4,"MAC", 28,"Message Authentication Code"}, {CALG_RSA_SIGN,1024,384,16384,CRYPT_FLAG_SIGNING|CRYPT_FLAG_IPSEC,9,"RSA_SIGN",14,"RSA Signature"}, {CALG_RSA_KEYX,1024,384,16384,CRYPT_FLAG_SIGNING|CRYPT_FLAG_IPSEC,9,"RSA_KEYX",17,"RSA Key Exchange"}, {CALG_HMAC, 0, 0, 0,0, 5,"HMAC", 18,"Hugo's MAC (HMAC)"}, {0, 0, 0, 0,0, 1,"", 1,""} }, { {CALG_RC2, 128, 40, 128,RSAENH_PCT1_SSL2_SSL3_TLS1, 4,"RC2", 24,"RSA Data Security's RC2"}, {CALG_RC4, 128, 40, 128,RSAENH_PCT1_SSL2_SSL3_TLS1, 4,"RC4", 24,"RSA Data Security's RC4"}, {CALG_DES, 56, 56, 56,RSAENH_PCT1_SSL2_SSL3_TLS1, 4,"DES", 31,"Data Encryption Standard (DES)"}, {CALG_3DES_112, 112,112, 112,RSAENH_PCT1_SSL2_SSL3_TLS1,13,"3DES TWO KEY",19,"Two Key Triple DES"}, {CALG_3DES, 168,168, 168,RSAENH_PCT1_SSL2_SSL3_TLS1, 5,"3DES", 21,"Three Key Triple DES"}, {CALG_SHA,160,160,160,CRYPT_FLAG_SIGNING|RSAENH_PCT1_SSL2_SSL3_TLS1,6,"SHA-1",30,"Secure Hash Algorithm (SHA-1)"}, {CALG_MD5,128,128,128,CRYPT_FLAG_SIGNING|RSAENH_PCT1_SSL2_SSL3_TLS1,4,"MD5",23,"Message Digest 5 (MD5)"}, {CALG_SSL3_SHAMD5,288,288,288,0, 12,"SSL3 SHAMD5",12,"SSL3 SHAMD5"}, {CALG_MAC, 0, 0, 0,0, 4,"MAC", 28,"Message Authentication Code"}, {CALG_RSA_SIGN,1024,384,16384,CRYPT_FLAG_SIGNING|RSAENH_PCT1_SSL2_SSL3_TLS1,9,"RSA_SIGN",14,"RSA Signature"}, {CALG_RSA_KEYX,1024,384,16384,CRYPT_FLAG_SIGNING|RSAENH_PCT1_SSL2_SSL3_TLS1,9,"RSA_KEYX",17,"RSA Key Exchange"}, {CALG_HMAC, 0, 0, 0,0, 5,"HMAC", 18,"Hugo's MAC (HMAC)"}, {CALG_PCT1_MASTER,128,128,128,CRYPT_FLAG_PCT1, 12,"PCT1 MASTER",12,"PCT1 Master"}, {CALG_SSL2_MASTER,40,40, 192,CRYPT_FLAG_SSL2, 12,"SSL2 MASTER",12,"SSL2 Master"}, {CALG_SSL3_MASTER,384,384,384,CRYPT_FLAG_SSL3, 12,"SSL3 MASTER",12,"SSL3 Master"}, {CALG_TLS1_MASTER,384,384,384,CRYPT_FLAG_TLS1, 12,"TLS1 MASTER",12,"TLS1 Master"}, {CALG_SCHANNEL_MASTER_HASH,0,0,-1,0, 16,"SCH MASTER HASH",21,"SChannel Master Hash"}, {CALG_SCHANNEL_MAC_KEY,0,0,-1,0, 12,"SCH MAC KEY",17,"SChannel MAC Key"}, {CALG_SCHANNEL_ENC_KEY,0,0,-1,0, 12,"SCH ENC KEY",24,"SChannel Encryption Key"}, {CALG_TLS1PRF, 0, 0, -1,0, 9,"TLS1 PRF", 28,"TLS1 Pseudo Random Function"}, {0, 0, 0, 0,0, 1,"", 1,""} } }; /****************************************************************************** * API forward declarations */ BOOL WINAPI RSAENH_CPGetKeyParam( HCRYPTPROV hProv, HCRYPTKEY hKey, DWORD dwParam, BYTE *pbData, DWORD *pdwDataLen, DWORD dwFlags ); BOOL WINAPI RSAENH_CPEncrypt( HCRYPTPROV hProv, HCRYPTKEY hKey, HCRYPTHASH hHash, BOOL Final, DWORD dwFlags, BYTE *pbData, DWORD *pdwDataLen, DWORD dwBufLen ); BOOL WINAPI RSAENH_CPCreateHash( HCRYPTPROV hProv, ALG_ID Algid, HCRYPTKEY hKey, DWORD dwFlags, HCRYPTHASH *phHash ); BOOL WINAPI RSAENH_CPSetHashParam( HCRYPTPROV hProv, HCRYPTHASH hHash, DWORD dwParam, BYTE *pbData, DWORD dwFlags ); BOOL WINAPI RSAENH_CPGetHashParam( HCRYPTPROV hProv, HCRYPTHASH hHash, DWORD dwParam, BYTE *pbData, DWORD *pdwDataLen, DWORD dwFlags ); BOOL WINAPI RSAENH_CPDestroyHash( HCRYPTPROV hProv, HCRYPTHASH hHash ); BOOL WINAPI RSAENH_CPExportKey( HCRYPTPROV hProv, HCRYPTKEY hKey, HCRYPTKEY hPubKey, DWORD dwBlobType, DWORD dwFlags, BYTE *pbData, DWORD *pdwDataLen ); BOOL WINAPI RSAENH_CPImportKey( HCRYPTPROV hProv, CONST BYTE *pbData, DWORD dwDataLen, HCRYPTKEY hPubKey, DWORD dwFlags, HCRYPTKEY *phKey ); BOOL WINAPI RSAENH_CPHashData( HCRYPTPROV hProv, HCRYPTHASH hHash, CONST BYTE *pbData, DWORD dwDataLen, DWORD dwFlags ); /****************************************************************************** * CSP's handle table (used by all acquired key containers) */ static HANDLETABLE handle_table; /****************************************************************************** * DllMain (RSAENH.@) * * Initializes and destroys the handle table for the CSP's handles. */ int WINAPI DllMain(HINSTANCE hInstance, DWORD fdwReason, PVOID pvReserved) { switch (fdwReason) { case DLL_PROCESS_ATTACH: init_handle_table(&handle_table); break; case DLL_PROCESS_DETACH: destroy_handle_table(&handle_table); break; } return 1; } /****************************************************************************** * copy_param [Internal] * * Helper function that supports the standard WINAPI protocol for querying data * of dynamic size. * * PARAMS * pbBuffer [O] Buffer where the queried parameter is copied to, if it is large enough. * May be NUL if the required buffer size is to be queried only. * pdwBufferSize [I/O] In: Size of the buffer at pbBuffer * Out: Size of parameter pbParam * pbParam [I] Parameter value. * dwParamSize [I] Size of pbParam * * RETURN * Success: TRUE (pbParam was copied into pbBuffer or pbBuffer is NULL) * Failure: FALSE (pbBuffer is not large enough to hold pbParam). Last error: ERROR_MORE_DATA */ static inline BOOL copy_param( BYTE *pbBuffer, DWORD *pdwBufferSize, CONST BYTE *pbParam, DWORD dwParamSize) { if (pbBuffer) { if (dwParamSize > *pdwBufferSize) { SetLastError(ERROR_MORE_DATA); *pdwBufferSize = dwParamSize; return FALSE; } memcpy(pbBuffer, pbParam, dwParamSize); } *pdwBufferSize = dwParamSize; return TRUE; } /****************************************************************************** * get_algid_info [Internal] * * Query CSP capabilities for a given crypto algorithm. * * PARAMS * hProv [I] Handle to a key container of the CSP whose capabilities are to be queried. * algid [I] Identifier of the crypto algorithm about which information is requested. * * RETURNS * Success: Pointer to a PROV_ENUMALGS_EX struct containing information about the crypto algorithm. * Failure: NULL (algid not supported) */ static inline const PROV_ENUMALGS_EX* get_algid_info(HCRYPTPROV hProv, ALG_ID algid) { PROV_ENUMALGS_EX *iterator; KEYCONTAINER *pKeyContainer; if (!lookup_handle(&handle_table, hProv, RSAENH_MAGIC_CONTAINER, (OBJECTHDR**)&pKeyContainer)) { SetLastError(NTE_BAD_UID); return NULL; } for (iterator = aProvEnumAlgsEx[pKeyContainer->dwPersonality]; iterator->aiAlgid; iterator++) { if (iterator->aiAlgid == algid) return iterator; } SetLastError(NTE_BAD_ALGID); return NULL; } /****************************************************************************** * copy_data_blob [Internal] * * deeply copies a DATA_BLOB * * PARAMS * dst [O] That's where the blob will be copied to * src [I] Source blob * * RETURNS * Success: TRUE * Failure: FALSE (GetLastError() == NTE_NO_MEMORY * * NOTES * Use free_data_blob to release resources occupied by copy_data_blob. */ static inline BOOL copy_data_blob(PCRYPT_DATA_BLOB dst, CONST PCRYPT_DATA_BLOB src) { dst->pbData = (BYTE*)HeapAlloc(GetProcessHeap(), 0, src->cbData); if (!dst->pbData) { SetLastError(NTE_NO_MEMORY); return FALSE; } dst->cbData = src->cbData; memcpy(dst->pbData, src->pbData, src->cbData); return TRUE; } /****************************************************************************** * concat_data_blobs [Internal] * * Concatenates two blobs * * PARAMS * dst [O] The new blob will be copied here * src1 [I] Prefix blob * src2 [I] Appendix blob * * RETURNS * Success: TRUE * Failure: FALSE (GetLastError() == NTE_NO_MEMORY) * * NOTES * Release resources occupied by concat_data_blobs with free_data_blobs */ static inline BOOL concat_data_blobs(PCRYPT_DATA_BLOB dst, CONST PCRYPT_DATA_BLOB src1, CONST PCRYPT_DATA_BLOB src2) { dst->cbData = src1->cbData + src2->cbData; dst->pbData = (BYTE*)HeapAlloc(GetProcessHeap(), 0, dst->cbData); if (!dst->pbData) { SetLastError(NTE_NO_MEMORY); return FALSE; } memcpy(dst->pbData, src1->pbData, src1->cbData); memcpy(dst->pbData + src1->cbData, src2->pbData, src2->cbData); return TRUE; } /****************************************************************************** * free_data_blob [Internal] * * releases resource occupied by a dynamically allocated CRYPT_DATA_BLOB * * PARAMS * pBlob [I] Heap space occupied by pBlob->pbData is released */ static inline void free_data_blob(PCRYPT_DATA_BLOB pBlob) { HeapFree(GetProcessHeap(), 0, pBlob->pbData); } /****************************************************************************** * init_data_blob [Internal] */ static inline void init_data_blob(PCRYPT_DATA_BLOB pBlob) { pBlob->pbData = NULL; pBlob->cbData = 0; } /****************************************************************************** * free_hmac_info [Internal] * * Deeply free an HMAC_INFO struct. * * PARAMS * hmac_info [I] Pointer to the HMAC_INFO struct to be freed. * * NOTES * See Internet RFC 2104 for details on the HMAC algorithm. */ static inline void free_hmac_info(PHMAC_INFO hmac_info) { if (!hmac_info) return; HeapFree(GetProcessHeap(), 0, hmac_info->pbInnerString); HeapFree(GetProcessHeap(), 0, hmac_info->pbOuterString); HeapFree(GetProcessHeap(), 0, hmac_info); } /****************************************************************************** * copy_hmac_info [Internal] * * Deeply copy an HMAC_INFO struct * * PARAMS * dst [O] Pointer to a location where the pointer to the HMAC_INFO copy will be stored. * src [I] Pointer to the HMAC_INFO struct to be copied. * * RETURNS * Success: TRUE * Failure: FALSE * * NOTES * See Internet RFC 2104 for details on the HMAC algorithm. */ static BOOL copy_hmac_info(PHMAC_INFO *dst, PHMAC_INFO src) { if (!src) return FALSE; *dst = (PHMAC_INFO)HeapAlloc(GetProcessHeap(), 0, sizeof(HMAC_INFO)); if (!*dst) return FALSE; memcpy(*dst, src, sizeof(HMAC_INFO)); (*dst)->pbInnerString = NULL; (*dst)->pbOuterString = NULL; if ((*dst)->cbInnerString == 0) (*dst)->cbInnerString = RSAENH_HMAC_DEF_PAD_LEN; (*dst)->pbInnerString = (BYTE*)HeapAlloc(GetProcessHeap(), 0, (*dst)->cbInnerString); if (!(*dst)->pbInnerString) { free_hmac_info(*dst); return FALSE; } if (src->cbInnerString) memcpy((*dst)->pbInnerString, src->pbInnerString, src->cbInnerString); else memset((*dst)->pbInnerString, RSAENH_HMAC_DEF_IPAD_CHAR, RSAENH_HMAC_DEF_PAD_LEN); if ((*dst)->cbOuterString == 0) (*dst)->cbOuterString = RSAENH_HMAC_DEF_PAD_LEN; (*dst)->pbOuterString = (BYTE*)HeapAlloc(GetProcessHeap(), 0, (*dst)->cbOuterString); if (!(*dst)->pbOuterString) { free_hmac_info(*dst); return FALSE; } if (src->cbOuterString) memcpy((*dst)->pbOuterString, src->pbOuterString, src->cbOuterString); else memset((*dst)->pbOuterString, RSAENH_HMAC_DEF_OPAD_CHAR, RSAENH_HMAC_DEF_PAD_LEN); return TRUE; } /****************************************************************************** * destroy_hash [Internal] * * Destructor for hash objects * * PARAMS * pCryptHash [I] Pointer to the hash object to be destroyed. * Will be invalid after function returns! */ static void destroy_hash(OBJECTHDR *pObject) { CRYPTHASH *pCryptHash = (CRYPTHASH*)pObject; free_hmac_info(pCryptHash->pHMACInfo); free_data_blob(&pCryptHash->tpPRFParams.blobLabel); free_data_blob(&pCryptHash->tpPRFParams.blobSeed); HeapFree(GetProcessHeap(), 0, pCryptHash); } /****************************************************************************** * init_hash [Internal] * * Initialize (or reset) a hash object * * PARAMS * pCryptHash [I] The hash object to be initialized. */ static inline BOOL init_hash(CRYPTHASH *pCryptHash) { DWORD dwLen; switch (pCryptHash->aiAlgid) { case CALG_HMAC: if (pCryptHash->pHMACInfo) { const PROV_ENUMALGS_EX *pAlgInfo; pAlgInfo = get_algid_info(pCryptHash->hProv, pCryptHash->pHMACInfo->HashAlgid); if (!pAlgInfo) return FALSE; pCryptHash->dwHashSize = pAlgInfo->dwDefaultLen >> 3; init_hash_impl(pCryptHash->pHMACInfo->HashAlgid, &pCryptHash->context); update_hash_impl(pCryptHash->pHMACInfo->HashAlgid, &pCryptHash->context, pCryptHash->pHMACInfo->pbInnerString, pCryptHash->pHMACInfo->cbInnerString); } return TRUE; case CALG_MAC: dwLen = sizeof(DWORD); RSAENH_CPGetKeyParam(pCryptHash->hProv, pCryptHash->hKey, KP_BLOCKLEN, (BYTE*)&pCryptHash->dwHashSize, &dwLen, 0); pCryptHash->dwHashSize >>= 3; return TRUE; default: return init_hash_impl(pCryptHash->aiAlgid, &pCryptHash->context); } } /****************************************************************************** * update_hash [Internal] * * Hashes the given data and updates the hash object's state accordingly * * PARAMS * pCryptHash [I] Hash object to be updated. * pbData [I] Pointer to data stream to be hashed. * dwDataLen [I] Length of data stream. */ static inline void update_hash(CRYPTHASH *pCryptHash, CONST BYTE *pbData, DWORD dwDataLen) { BYTE *pbTemp; switch (pCryptHash->aiAlgid) { case CALG_HMAC: if (pCryptHash->pHMACInfo) update_hash_impl(pCryptHash->pHMACInfo->HashAlgid, &pCryptHash->context, pbData, dwDataLen); break; case CALG_MAC: pbTemp = (BYTE*)HeapAlloc(GetProcessHeap(), 0, dwDataLen); if (!pbTemp) return; memcpy(pbTemp, pbData, dwDataLen); RSAENH_CPEncrypt(pCryptHash->hProv, pCryptHash->hKey, (HCRYPTHASH)NULL, FALSE, 0, pbTemp, &dwDataLen, dwDataLen); HeapFree(GetProcessHeap(), 0, pbTemp); break; default: update_hash_impl(pCryptHash->aiAlgid, &pCryptHash->context, pbData, dwDataLen); } } /****************************************************************************** * finalize_hash [Internal] * * Finalizes the hash, after all data has been hashed with update_hash. * No additional data can be hashed afterwards until the hash gets initialized again. * * PARAMS * pCryptHash [I] Hash object to be finalized. */ static inline void finalize_hash(CRYPTHASH *pCryptHash) { DWORD dwDataLen; switch (pCryptHash->aiAlgid) { case CALG_HMAC: if (pCryptHash->pHMACInfo) { BYTE abHashValue[RSAENH_MAX_HASH_SIZE]; finalize_hash_impl(pCryptHash->pHMACInfo->HashAlgid, &pCryptHash->context, pCryptHash->abHashValue); memcpy(abHashValue, pCryptHash->abHashValue, pCryptHash->dwHashSize); init_hash_impl(pCryptHash->pHMACInfo->HashAlgid, &pCryptHash->context); update_hash_impl(pCryptHash->pHMACInfo->HashAlgid, &pCryptHash->context, pCryptHash->pHMACInfo->pbOuterString, pCryptHash->pHMACInfo->cbOuterString); update_hash_impl(pCryptHash->pHMACInfo->HashAlgid, &pCryptHash->context, abHashValue, pCryptHash->dwHashSize); finalize_hash_impl(pCryptHash->pHMACInfo->HashAlgid, &pCryptHash->context, pCryptHash->abHashValue); } break; case CALG_MAC: dwDataLen = 0; RSAENH_CPEncrypt(pCryptHash->hProv, pCryptHash->hKey, (HCRYPTHASH)NULL, TRUE, 0, pCryptHash->abHashValue, &dwDataLen, pCryptHash->dwHashSize); break; default: finalize_hash_impl(pCryptHash->aiAlgid, &pCryptHash->context, pCryptHash->abHashValue); } } /****************************************************************************** * destroy_key [Internal] * * Destructor for key objects * * PARAMS * pCryptKey [I] Pointer to the key object to be destroyed. * Will be invalid after function returns! */ static void destroy_key(OBJECTHDR *pObject) { CRYPTKEY *pCryptKey = (CRYPTKEY*)pObject; free_key_impl(pCryptKey->aiAlgid, &pCryptKey->context); free_data_blob(&pCryptKey->siSChannelInfo.blobClientRandom); free_data_blob(&pCryptKey->siSChannelInfo.blobServerRandom); HeapFree(GetProcessHeap(), 0, pCryptKey); } /****************************************************************************** * setup_key [Internal] * * Initialize (or reset) a key object * * PARAMS * pCryptKey [I] The key object to be initialized. */ static inline void setup_key(CRYPTKEY *pCryptKey) { pCryptKey->dwState = RSAENH_KEYSTATE_IDLE; memcpy(pCryptKey->abChainVector, pCryptKey->abInitVector, sizeof(pCryptKey->abChainVector)); setup_key_impl(pCryptKey->aiAlgid, &pCryptKey->context, pCryptKey->dwKeyLen, pCryptKey->dwSaltLen, pCryptKey->abKeyValue); } /****************************************************************************** * new_key [Internal] * * Creates a new key object without assigning the actual binary key value. * This is done by CPDeriveKey, CPGenKey or CPImportKey, which call this function. * * PARAMS * hProv [I] Handle to the provider to which the created key will belong. * aiAlgid [I] The new key shall use the crypto algorithm idenfied by aiAlgid. * dwFlags [I] Upper 16 bits give the key length. * Lower 16 bits: CRYPT_CREATE_SALT, CRYPT_NO_SALT * ppCryptKey [O] Pointer to the created key * * RETURNS * Success: Handle to the created key. * Failure: INVALID_HANDLE_VALUE */ static HCRYPTKEY new_key(HCRYPTPROV hProv, ALG_ID aiAlgid, DWORD dwFlags, CRYPTKEY **ppCryptKey) { HCRYPTKEY hCryptKey; CRYPTKEY *pCryptKey; DWORD dwKeyLen = HIWORD(dwFlags); const PROV_ENUMALGS_EX *peaAlgidInfo; *ppCryptKey = NULL; /* * Retrieve the CSP's capabilities for the given ALG_ID value */ peaAlgidInfo = get_algid_info(hProv, aiAlgid); if (!peaAlgidInfo) return (HCRYPTKEY)INVALID_HANDLE_VALUE; /* * Assume the default key length, if none is specified explicitly */ if (dwKeyLen == 0) dwKeyLen = peaAlgidInfo->dwDefaultLen; /* * Check if the requested key length is supported by the current CSP. * Adjust key length's for DES algorithms. */ switch (aiAlgid) { case CALG_DES: if (dwKeyLen == RSAENH_DES_EFFECTIVE_KEYLEN) { dwKeyLen = RSAENH_DES_STORAGE_KEYLEN; } if (dwKeyLen != RSAENH_DES_STORAGE_KEYLEN) { SetLastError(NTE_BAD_FLAGS); return (HCRYPTKEY)INVALID_HANDLE_VALUE; } break; case CALG_3DES_112: if (dwKeyLen == RSAENH_3DES112_EFFECTIVE_KEYLEN) { dwKeyLen = RSAENH_3DES112_STORAGE_KEYLEN; } if (dwKeyLen != RSAENH_3DES112_STORAGE_KEYLEN) { SetLastError(NTE_BAD_FLAGS); return (HCRYPTKEY)INVALID_HANDLE_VALUE; } break; case CALG_3DES: if (dwKeyLen == RSAENH_3DES_EFFECTIVE_KEYLEN) { dwKeyLen = RSAENH_3DES_STORAGE_KEYLEN; } if (dwKeyLen != RSAENH_3DES_STORAGE_KEYLEN) { SetLastError(NTE_BAD_FLAGS); return (HCRYPTKEY)INVALID_HANDLE_VALUE; } break; default: if (dwKeyLen % 8 || dwKeyLen > peaAlgidInfo->dwMaxLen || dwKeyLen < peaAlgidInfo->dwMinLen) { SetLastError(NTE_BAD_FLAGS); return (HCRYPTKEY)INVALID_HANDLE_VALUE; } } hCryptKey = (HCRYPTKEY)new_object(&handle_table, sizeof(CRYPTKEY), RSAENH_MAGIC_KEY, destroy_key, (OBJECTHDR**)&pCryptKey); if (hCryptKey != (HCRYPTKEY)INVALID_HANDLE_VALUE) { pCryptKey->aiAlgid = aiAlgid; pCryptKey->hProv = hProv; pCryptKey->dwModeBits = 0; pCryptKey->dwPermissions = CRYPT_ENCRYPT | CRYPT_DECRYPT | CRYPT_READ | CRYPT_WRITE | CRYPT_MAC; pCryptKey->dwKeyLen = dwKeyLen >> 3; if ((dwFlags & CRYPT_CREATE_SALT) || (dwKeyLen == 40 && !(dwFlags & CRYPT_NO_SALT))) pCryptKey->dwSaltLen = 16 /*FIXME*/ - pCryptKey->dwKeyLen; else pCryptKey->dwSaltLen = 0; memset(pCryptKey->abKeyValue, 0, sizeof(pCryptKey->abKeyValue)); memset(pCryptKey->abInitVector, 0, sizeof(pCryptKey->abInitVector)); init_data_blob(&pCryptKey->siSChannelInfo.blobClientRandom); init_data_blob(&pCryptKey->siSChannelInfo.blobServerRandom); switch(aiAlgid) { case CALG_PCT1_MASTER: case CALG_SSL2_MASTER: case CALG_SSL3_MASTER: case CALG_TLS1_MASTER: case CALG_RC4: pCryptKey->dwBlockLen = 0; pCryptKey->dwMode = 0; break; case CALG_RC2: case CALG_DES: case CALG_3DES_112: case CALG_3DES: pCryptKey->dwBlockLen = 8; pCryptKey->dwMode = CRYPT_MODE_CBC; break; case CALG_RSA_KEYX: case CALG_RSA_SIGN: pCryptKey->dwBlockLen = dwKeyLen >> 3; pCryptKey->dwMode = 0; break; } *ppCryptKey = pCryptKey; } return hCryptKey; } /****************************************************************************** * destroy_key_container [Internal] * * Destructor for key containers. The user's signature and key exchange private * keys are stored in the registry _IN_PLAINTEXT_. * * PARAMS * pObjectHdr [I] Pointer to the key container to be destroyed. */ static void destroy_key_container(OBJECTHDR *pObjectHdr) { KEYCONTAINER *pKeyContainer = (KEYCONTAINER*)pObjectHdr; CRYPTKEY *pKey; CHAR szRSABase[MAX_PATH]; HKEY hKey, hRootKey; DWORD dwLen; BYTE *pbKey; if (!(pKeyContainer->dwFlags & CRYPT_VERIFYCONTEXT)) { /* On WinXP, persistent keys are stored in a file located at: * $AppData$\\Microsoft\\Crypto\\RSA\\$SID$\\some_hex_string */ sprintf(szRSABase, RSAENH_REGKEY, pKeyContainer->szName); if (pKeyContainer->dwFlags & CRYPT_MACHINE_KEYSET) { hRootKey = HKEY_LOCAL_MACHINE; } else { hRootKey = HKEY_CURRENT_USER; } if (RegCreateKeyExA(hRootKey, szRSABase, 0, NULL, REG_OPTION_NON_VOLATILE, KEY_WRITE, NULL, &hKey, NULL) == ERROR_SUCCESS) { if (lookup_handle(&handle_table, pKeyContainer->hKeyExchangeKeyPair, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pKey)) { if (RSAENH_CPExportKey(pKey->hProv, pKeyContainer->hKeyExchangeKeyPair, 0, PRIVATEKEYBLOB, 0, 0, &dwLen)) { pbKey = (BYTE*)HeapAlloc(GetProcessHeap(), 0, dwLen); if (pbKey) { if (RSAENH_CPExportKey(pKey->hProv, pKeyContainer->hKeyExchangeKeyPair, 0, PRIVATEKEYBLOB, 0, pbKey, &dwLen)) { RegSetValueExA(hKey, "KeyExchangeKeyPair", 0, REG_BINARY, pbKey, dwLen); } HeapFree(GetProcessHeap(), 0, pbKey); } } release_handle(&handle_table, (unsigned int)pKeyContainer->hKeyExchangeKeyPair, RSAENH_MAGIC_KEY); } if (lookup_handle(&handle_table, pKeyContainer->hSignatureKeyPair, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pKey)) { if (RSAENH_CPExportKey(pKey->hProv, pKeyContainer->hSignatureKeyPair, 0, PRIVATEKEYBLOB, 0, 0, &dwLen)) { pbKey = (BYTE*)HeapAlloc(GetProcessHeap(), 0, dwLen); if (pbKey) { if (RSAENH_CPExportKey(pKey->hProv, pKeyContainer->hSignatureKeyPair, 0, PRIVATEKEYBLOB, 0, pbKey, &dwLen)) { RegSetValueExA(hKey, "SignatureKeyPair", 0, REG_BINARY, pbKey, dwLen); } HeapFree(GetProcessHeap(), 0, pbKey); } } release_handle(&handle_table, (unsigned int)pKeyContainer->hSignatureKeyPair, RSAENH_MAGIC_KEY); } RegCloseKey(hKey); } } HeapFree( GetProcessHeap(), 0, pKeyContainer ); } /****************************************************************************** * new_key_container [Internal] * * Create a new key container. The personality (RSA Base, Strong or Enhanced CP) * of the CSP is determined via the pVTable->pszProvName string. * * PARAMS * pszContainerName [I] Name of the key container. * pVTable [I] Callback functions and context info provided by the OS * * RETURNS * Success: Handle to the new key container. * Failure: INVALID_HANDLE_VALUE */ static HCRYPTPROV new_key_container(PCHAR pszContainerName, DWORD dwFlags, PVTableProvStruc pVTable) { KEYCONTAINER *pKeyContainer; HCRYPTPROV hKeyContainer; hKeyContainer = (HCRYPTPROV)new_object(&handle_table, sizeof(KEYCONTAINER), RSAENH_MAGIC_CONTAINER, destroy_key_container, (OBJECTHDR**)&pKeyContainer); if (hKeyContainer != (HCRYPTPROV)INVALID_HANDLE_VALUE) { strncpy(pKeyContainer->szName, pszContainerName, MAX_PATH); pKeyContainer->szName[MAX_PATH-1] = '\0'; pKeyContainer->dwFlags = dwFlags; pKeyContainer->dwEnumAlgsCtr = 0; pKeyContainer->hKeyExchangeKeyPair = (HCRYPTKEY)INVALID_HANDLE_VALUE; pKeyContainer->hSignatureKeyPair = (HCRYPTKEY)INVALID_HANDLE_VALUE; if (pVTable && pVTable->pszProvName) { strncpy(pKeyContainer->szProvName, pVTable->pszProvName, MAX_PATH); pKeyContainer->szProvName[MAX_PATH-1] = '\0'; if (!strcmp(pVTable->pszProvName, MS_DEF_PROV_A)) { pKeyContainer->dwPersonality = RSAENH_PERSONALITY_BASE; } else if (!strcmp(pVTable->pszProvName, MS_ENHANCED_PROV_A)) { pKeyContainer->dwPersonality = RSAENH_PERSONALITY_ENHANCED; } else if (!strcmp(pVTable->pszProvName, MS_DEF_RSA_SCHANNEL_PROV_A)) { pKeyContainer->dwPersonality = RSAENH_PERSONALITY_SCHANNEL; } else { pKeyContainer->dwPersonality = RSAENH_PERSONALITY_STRONG; } } } return hKeyContainer; } /****************************************************************************** * read_key_container [Internal] * * Tries to read the persistent state of the key container (mainly the signature * and key exchange private keys) given by pszContainerName. * * PARAMS * pszContainerName [I] Name of the key container to read from the registry * pVTable [I] Pointer to context data provided by the operating system * * RETURNS * Success: Handle to the key container read from the registry * Failure: INVALID_HANDLE_VALUE */ static HCRYPTPROV read_key_container(PCHAR pszContainerName, DWORD dwFlags, PVTableProvStruc pVTable) { CHAR szRSABase[MAX_PATH]; BYTE *pbKey; HKEY hKey, hRootKey; DWORD dwValueType, dwLen; KEYCONTAINER *pKeyContainer; HCRYPTPROV hKeyContainer; sprintf(szRSABase, RSAENH_REGKEY, pszContainerName); if (dwFlags & CRYPT_MACHINE_KEYSET) { hRootKey = HKEY_LOCAL_MACHINE; } else { hRootKey = HKEY_CURRENT_USER; } if (RegOpenKeyExA(hRootKey, szRSABase, 0, KEY_READ, &hKey) != ERROR_SUCCESS) { SetLastError(NTE_BAD_KEYSET); return (HCRYPTPROV)INVALID_HANDLE_VALUE; } hKeyContainer = new_key_container(pszContainerName, dwFlags, pVTable); if (hKeyContainer != (HCRYPTPROV)INVALID_HANDLE_VALUE) { if (!lookup_handle(&handle_table, hKeyContainer, RSAENH_MAGIC_CONTAINER, (OBJECTHDR**)&pKeyContainer)) return (HCRYPTPROV)INVALID_HANDLE_VALUE; if (RegQueryValueExA(hKey, "KeyExchangeKeyPair", 0, &dwValueType, NULL, &dwLen) == ERROR_SUCCESS) { pbKey = (BYTE*)HeapAlloc(GetProcessHeap(), 0, dwLen); if (pbKey) { if (RegQueryValueExA(hKey, "KeyExchangeKeyPair", 0, &dwValueType, pbKey, &dwLen) == ERROR_SUCCESS) { RSAENH_CPImportKey(hKeyContainer, pbKey, dwLen, 0, 0, &pKeyContainer->hKeyExchangeKeyPair); } HeapFree(GetProcessHeap(), 0, pbKey); } } if (RegQueryValueExA(hKey, "SignatureKeyPair", 0, &dwValueType, NULL, &dwLen) == ERROR_SUCCESS) { pbKey = (BYTE*)HeapAlloc(GetProcessHeap(), 0, dwLen); if (pbKey) { if (RegQueryValueExA(hKey, "SignatureKeyPair", 0, &dwValueType, pbKey, &dwLen) == ERROR_SUCCESS) { RSAENH_CPImportKey(hKeyContainer, pbKey, dwLen, 0, 0, &pKeyContainer->hSignatureKeyPair); } HeapFree(GetProcessHeap(), 0, pbKey); } } } return hKeyContainer; } /****************************************************************************** * build_hash_signature [Internal] * * Builds a padded version of a hash to match the length of the RSA key modulus. * * PARAMS * pbSignature [O] The padded hash object is stored here. * dwLen [I] Length of the pbSignature buffer. * aiAlgid [I] Algorithm identifier of the hash to be padded. * abHashValue [I] The value of the hash object. * dwHashLen [I] Length of the hash value. * dwFlags [I] Selection of padding algorithm. * * RETURNS * Success: TRUE * Failure: FALSE (NTE_BAD_ALGID) */ static BOOL build_hash_signature(BYTE *pbSignature, DWORD dwLen, ALG_ID aiAlgid, CONST BYTE *abHashValue, DWORD dwHashLen, DWORD dwFlags) { /* These prefixes are meant to be concatenated with hash values of the * respective kind to form a PKCS #7 DigestInfo. */ static const struct tagOIDDescriptor { ALG_ID aiAlgid; DWORD dwLen; CONST BYTE abOID[18]; } aOIDDescriptor[5] = { { CALG_MD2, 18, { 0x30, 0x20, 0x30, 0x0c, 0x06, 0x08, 0x2a, 0x86, 0x48, 0x86, 0xf7, 0x0d, 0x02, 0x02, 0x05, 0x00, 0x04, 0x10 } }, { CALG_MD4, 18, { 0x30, 0x20, 0x30, 0x0c, 0x06, 0x08, 0x2a, 0x86, 0x48, 0x86, 0xf7, 0x0d, 0x02, 0x04, 0x05, 0x00, 0x04, 0x10 } }, { CALG_MD5, 18, { 0x30, 0x20, 0x30, 0x0c, 0x06, 0x08, 0x2a, 0x86, 0x48, 0x86, 0xf7, 0x0d, 0x02, 0x05, 0x05, 0x00, 0x04, 0x10 } }, { CALG_SHA, 15, { 0x30, 0x21, 0x30, 0x09, 0x06, 0x05, 0x2b, 0x0e, 0x03, 0x02, 0x1a, 0x05, 0x00, 0x04, 0x14 } }, { 0, 0, {} } }; DWORD dwIdxOID, i, j; for (dwIdxOID = 0; aOIDDescriptor[dwIdxOID].aiAlgid; dwIdxOID++) { if (aOIDDescriptor[dwIdxOID].aiAlgid == aiAlgid) break; } if (!aOIDDescriptor[dwIdxOID].aiAlgid) { SetLastError(NTE_BAD_ALGID); return FALSE; } /* Build the padded signature */ if (dwFlags & CRYPT_X931_FORMAT) { pbSignature[0] = 0x6b; for (i=1; i < dwLen - dwHashLen - 3; i++) { pbSignature[i] = 0xbb; } pbSignature[i++] = 0xba; for (j=0; j < dwHashLen; j++, i++) { pbSignature[i] = abHashValue[j]; } pbSignature[i++] = 0x33; pbSignature[i++] = 0xcc; } else { pbSignature[0] = 0x00; pbSignature[1] = 0x01; if (dwFlags & CRYPT_NOHASHOID) { for (i=2; i < dwLen - 1 - dwHashLen; i++) { pbSignature[i] = 0xff; } pbSignature[i++] = 0x00; } else { for (i=2; i < dwLen - 1 - aOIDDescriptor[dwIdxOID].dwLen - dwHashLen; i++) { pbSignature[i] = 0xff; } pbSignature[i++] = 0x00; for (j=0; j < aOIDDescriptor[dwIdxOID].dwLen; j++) { pbSignature[i++] = aOIDDescriptor[dwIdxOID].abOID[j]; } } for (j=0; j < dwHashLen; j++) { pbSignature[i++] = abHashValue[j]; } } return TRUE; } /****************************************************************************** * tls1_p [Internal] * * This is an implementation of the 'P_hash' helper function for TLS1's PRF. * It is used exclusively by tls1_prf. For details see RFC 2246, chapter 5. * The pseudo random stream generated by this function is exclusive or'ed with * the data in pbBuffer. * * PARAMS * hHMAC [I] HMAC object, which will be used in pseudo random generation * pblobSeed [I] Seed value * pbBuffer [I/O] Pseudo random stream will be xor'ed to the provided data * dwBufferLen [I] Number of pseudo random bytes desired * * RETURNS * Success: TRUE * Failure: FALSE */ static BOOL tls1_p(HCRYPTHASH hHMAC, CONST PCRYPT_DATA_BLOB pblobSeed, PBYTE pbBuffer, DWORD dwBufferLen) { CRYPTHASH *pHMAC; BYTE abAi[RSAENH_MAX_HASH_SIZE]; DWORD i = 0; if (!lookup_handle(&handle_table, hHMAC, RSAENH_MAGIC_HASH, (OBJECTHDR**)&pHMAC)) { SetLastError(NTE_BAD_HASH); return FALSE; } /* compute A_1 = HMAC(seed) */ init_hash(pHMAC); update_hash(pHMAC, pblobSeed->pbData, pblobSeed->cbData); finalize_hash(pHMAC); memcpy(abAi, pHMAC->abHashValue, pHMAC->dwHashSize); do { /* compute HMAC(A_i + seed) */ init_hash(pHMAC); update_hash(pHMAC, abAi, pHMAC->dwHashSize); update_hash(pHMAC, pblobSeed->pbData, pblobSeed->cbData); finalize_hash(pHMAC); /* pseudo random stream := CONCAT_{i=1..n} ( HMAC(A_i + seed) ) */ do { if (i >= dwBufferLen) break; pbBuffer[i] ^= pHMAC->abHashValue[i % pHMAC->dwHashSize]; i++; } while (i % pHMAC->dwHashSize); /* compute A_{i+1} = HMAC(A_i) */ init_hash(pHMAC); update_hash(pHMAC, abAi, pHMAC->dwHashSize); finalize_hash(pHMAC); memcpy(abAi, pHMAC->abHashValue, pHMAC->dwHashSize); } while (i < dwBufferLen); return TRUE; } /****************************************************************************** * tls1_prf [Internal] * * TLS1 pseudo random function as specified in RFC 2246, chapter 5 * * PARAMS * hProv [I] Key container used to compute the pseudo random stream * hSecret [I] Key that holds the (pre-)master secret * pblobLabel [I] Descriptive label * pblobSeed [I] Seed value * pbBuffer [O] Pseudo random numbers will be stored here * dwBufferLen [I] Number of pseudo random bytes desired * * RETURNS * Success: TRUE * Failure: FALSE */ static BOOL tls1_prf(HCRYPTPROV hProv, HCRYPTPROV hSecret, CONST PCRYPT_DATA_BLOB pblobLabel, CONST PCRYPT_DATA_BLOB pblobSeed, PBYTE pbBuffer, DWORD dwBufferLen) { HMAC_INFO hmacInfo = { 0, NULL, 0, NULL, 0 }; HCRYPTHASH hHMAC = (HCRYPTHASH)INVALID_HANDLE_VALUE; HCRYPTKEY hHalfSecret = (HCRYPTKEY)INVALID_HANDLE_VALUE; CRYPTKEY *pHalfSecret, *pSecret; DWORD dwHalfSecretLen; BOOL result = FALSE; CRYPT_DATA_BLOB blobLabelSeed; TRACE("(hProv=%08lx, hSecret=%08lx, pblobLabel=%p, pblobSeed=%p, pbBuffer=%p, dwBufferLen=%ld)\n", hProv, hSecret, pblobLabel, pblobSeed, pbBuffer, dwBufferLen); if (!lookup_handle(&handle_table, hSecret, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pSecret)) { SetLastError(NTE_FAIL); return FALSE; } dwHalfSecretLen = (pSecret->dwKeyLen+1)/2; /* concatenation of the label and the seed */ if (!concat_data_blobs(&blobLabelSeed, pblobLabel, pblobSeed)) goto exit; /* zero out the buffer, since two random streams will be xor'ed into it. */ memset(pbBuffer, 0, dwBufferLen); /* build a 'fake' key, to hold the secret. CALG_SSL2_MASTER is used since it provides * the biggest range of valid key lengths. */ hHalfSecret = new_key(hProv, CALG_SSL2_MASTER, MAKELONG(0,dwHalfSecretLen*8), &pHalfSecret); if (hHalfSecret == (HCRYPTKEY)INVALID_HANDLE_VALUE) goto exit; /* Derive an HMAC_MD5 hash and call the helper function. */ memcpy(pHalfSecret->abKeyValue, pSecret->abKeyValue, dwHalfSecretLen); if (!RSAENH_CPCreateHash(hProv, CALG_HMAC, hHalfSecret, 0, &hHMAC)) goto exit; hmacInfo.HashAlgid = CALG_MD5; if (!RSAENH_CPSetHashParam(hProv, hHMAC, HP_HMAC_INFO, (BYTE*)&hmacInfo, 0)) goto exit; if (!tls1_p(hHMAC, &blobLabelSeed, pbBuffer, dwBufferLen)) goto exit; /* Reconfigure to HMAC_SHA hash and call helper function again. */ memcpy(pHalfSecret->abKeyValue, pSecret->abKeyValue + (pSecret->dwKeyLen/2), dwHalfSecretLen); hmacInfo.HashAlgid = CALG_SHA; if (!RSAENH_CPSetHashParam(hProv, hHMAC, HP_HMAC_INFO, (BYTE*)&hmacInfo, 0)) goto exit; if (!tls1_p(hHMAC, &blobLabelSeed, pbBuffer, dwBufferLen)) goto exit; result = TRUE; exit: release_handle(&handle_table, hHalfSecret, RSAENH_MAGIC_KEY); if (hHMAC != (HCRYPTHASH)INVALID_HANDLE_VALUE) RSAENH_CPDestroyHash(hProv, hHMAC); free_data_blob(&blobLabelSeed); return result; } /****************************************************************************** * pad_data [Internal] * * Helper function for data padding according to PKCS1 #2 * * PARAMS * abData [I] The data to be padded * dwDataLen [I] Length of the data * abBuffer [O] Padded data will be stored here * dwBufferLen [I] Length of the buffer (also length of padded data) * dwFlags [I] Padding format (CRYPT_SSL2_FALLBACK) * * RETURN * Success: TRUE * Failure: FALSE (NTE_BAD_LEN, too much data to pad) */ static BOOL pad_data(CONST BYTE *abData, DWORD dwDataLen, BYTE *abBuffer, DWORD dwBufferLen, DWORD dwFlags) { DWORD i; /* Ensure there is enough space for PKCS1 #2 padding */ if (dwDataLen > dwBufferLen-11) { SetLastError(NTE_BAD_LEN); return FALSE; } memmove(abBuffer + dwBufferLen - dwDataLen, abData, dwDataLen); abBuffer[0] = 0x00; abBuffer[1] = RSAENH_PKC_BLOCKTYPE; for (i=2; i < dwBufferLen - dwDataLen - 1; i++) do gen_rand_impl(&abBuffer[i], 1); while (!abBuffer[i]); if (dwFlags & CRYPT_SSL2_FALLBACK) for (i-=8; i < dwBufferLen - dwDataLen - 1; i++) abBuffer[i] = 0x03; abBuffer[i] = 0x00; return TRUE; } /****************************************************************************** * unpad_data [Internal] * * Remove the PKCS1 padding from RSA decrypted data * * PARAMS * abData [I] The padded data * dwDataLen [I] Length of the padded data * abBuffer [O] Data without padding will be stored here * dwBufferLen [I/O] I: Length of the buffer, O: Length of unpadded data * dwFlags [I] Currently none defined * * RETURNS * Success: TRUE * Failure: FALSE, (NTE_BAD_DATA, no valid PKCS1 padding or buffer too small) */ static BOOL unpad_data(CONST BYTE *abData, DWORD dwDataLen, BYTE *abBuffer, DWORD *dwBufferLen, DWORD dwFlags) { DWORD i; for (i=2; i= MAX_PATH) { SetLastError(NTE_BAD_KEYSET_PARAM); return FALSE; } else { RegDeleteKeyA(HKEY_CURRENT_USER, szRegKey); SetLastError(ERROR_SUCCESS); return TRUE; } break; case CRYPT_NEWKEYSET: *phProv = read_key_container(szKeyContainerName, dwFlags, pVTable); if (*phProv != (HCRYPTPROV)INVALID_HANDLE_VALUE) { release_handle(&handle_table, (unsigned int)*phProv, RSAENH_MAGIC_CONTAINER); SetLastError(NTE_EXISTS); return FALSE; } *phProv = new_key_container(szKeyContainerName, dwFlags, pVTable); break; case CRYPT_VERIFYCONTEXT: if (pszContainer) { SetLastError(NTE_BAD_FLAGS); return FALSE; } *phProv = new_key_container("", dwFlags, pVTable); break; default: *phProv = (unsigned int)INVALID_HANDLE_VALUE; SetLastError(NTE_BAD_FLAGS); return FALSE; } if (*phProv != (unsigned int)INVALID_HANDLE_VALUE) { SetLastError(ERROR_SUCCESS); return TRUE; } else { return FALSE; } } /****************************************************************************** * CPCreateHash (RSAENH.@) * * CPCreateHash creates and initalizes a new hash object. * * PARAMS * hProv [I] Handle to the key container to which the new hash will belong. * Algid [I] Identifies the hash algorithm, which will be used for the hash. * hKey [I] Handle to a session key applied for keyed hashes. * dwFlags [I] Currently no flags defined. Must be zero. * phHash [O] Points to the location where a handle to the new hash will be stored. * * RETURNS * Success: TRUE * Failure: FALSE * * NOTES * hKey is a handle to a session key applied in keyed hashes like MAC and HMAC. * If a normal hash object is to be created (like e.g. MD2 or SHA1) hKey must be zero. */ BOOL WINAPI RSAENH_CPCreateHash(HCRYPTPROV hProv, ALG_ID Algid, HCRYPTKEY hKey, DWORD dwFlags, HCRYPTHASH *phHash) { CRYPTKEY *pCryptKey; CRYPTHASH *pCryptHash; const PROV_ENUMALGS_EX *peaAlgidInfo; TRACE("(hProv=%08lx, Algid=%08x, hKey=%08lx, dwFlags=%08lx, phHash=%p)\n", hProv, Algid, hKey, dwFlags, phHash); peaAlgidInfo = get_algid_info(hProv, Algid); if (!peaAlgidInfo) return FALSE; if (dwFlags) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (Algid == CALG_MAC || Algid == CALG_HMAC || Algid == CALG_SCHANNEL_MASTER_HASH || Algid == CALG_TLS1PRF) { if (!lookup_handle(&handle_table, hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pCryptKey)) { SetLastError(NTE_BAD_KEY); return FALSE; } if ((Algid == CALG_MAC) && (GET_ALG_TYPE(pCryptKey->aiAlgid) != ALG_TYPE_BLOCK)) { SetLastError(NTE_BAD_KEY); return FALSE; } if ((Algid == CALG_SCHANNEL_MASTER_HASH || Algid == CALG_TLS1PRF) && (pCryptKey->aiAlgid != CALG_TLS1_MASTER)) { SetLastError(NTE_BAD_KEY); return FALSE; } if ((Algid == CALG_TLS1PRF) && (pCryptKey->dwState != RSAENH_KEYSTATE_MASTERKEY)) { SetLastError(NTE_BAD_KEY_STATE); return FALSE; } } *phHash = (HCRYPTHASH)new_object(&handle_table, sizeof(CRYPTHASH), RSAENH_MAGIC_HASH, destroy_hash, (OBJECTHDR**)&pCryptHash); if (!pCryptHash) return FALSE; pCryptHash->aiAlgid = Algid; pCryptHash->hKey = hKey; pCryptHash->hProv = hProv; pCryptHash->dwState = RSAENH_HASHSTATE_IDLE; pCryptHash->pHMACInfo = (PHMAC_INFO)NULL; pCryptHash->dwHashSize = peaAlgidInfo->dwDefaultLen >> 3; init_data_blob(&pCryptHash->tpPRFParams.blobLabel); init_data_blob(&pCryptHash->tpPRFParams.blobSeed); if (Algid == CALG_SCHANNEL_MASTER_HASH) { CRYPT_DATA_BLOB blobRandom, blobKeyExpansion = { 13, "key expansion" }; if (pCryptKey->dwState != RSAENH_KEYSTATE_MASTERKEY) { CRYPT_DATA_BLOB blobLabel = { 13, "master secret" }; BYTE abKeyValue[48]; /* See RFC 2246, chapter 8.1 */ if (!concat_data_blobs(&blobRandom, &pCryptKey->siSChannelInfo.blobClientRandom, &pCryptKey->siSChannelInfo.blobServerRandom)) { return FALSE; } tls1_prf(hProv, hKey, &blobLabel, &blobRandom, abKeyValue, 48); pCryptKey->dwState = RSAENH_KEYSTATE_MASTERKEY; memcpy(pCryptKey->abKeyValue, abKeyValue, 48); free_data_blob(&blobRandom); } /* See RFC 2246, chapter 6.3 */ if (!concat_data_blobs(&blobRandom, &pCryptKey->siSChannelInfo.blobServerRandom, &pCryptKey->siSChannelInfo.blobClientRandom)) { return FALSE; } tls1_prf(hProv, hKey, &blobKeyExpansion, &blobRandom, pCryptHash->abHashValue, RSAENH_MAX_HASH_SIZE); free_data_blob(&blobRandom); } return init_hash(pCryptHash); } /****************************************************************************** * CPDestroyHash (RSAENH.@) * * Releases the handle to a hash object. The object is destroyed if it's reference * count reaches zero. * * PARAMS * hProv [I] Handle to the key container to which the hash object belongs. * hHash [I] Handle to the hash object to be released. * * RETURNS * Success: TRUE * Failure: FALSE */ BOOL WINAPI RSAENH_CPDestroyHash(HCRYPTPROV hProv, HCRYPTHASH hHash) { TRACE("(hProv=%08lx, hHash=%08lx)\n", hProv, hHash); if (!is_valid_handle(&handle_table, hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (!release_handle(&handle_table, hHash, RSAENH_MAGIC_HASH)) { SetLastError(NTE_BAD_HASH); return FALSE; } return TRUE; } /****************************************************************************** * CPDestroyKey (RSAENH.@) * * Releases the handle to a key object. The object is destroyed if it's reference * count reaches zero. * * PARAMS * hProv [I] Handle to the key container to which the key object belongs. * hKey [I] Handle to the key object to be released. * * RETURNS * Success: TRUE * Failure: FALSE */ BOOL WINAPI RSAENH_CPDestroyKey(HCRYPTPROV hProv, HCRYPTKEY hKey) { TRACE("(hProv=%08lx, hKey=%08lx)\n", hProv, hKey); if (!is_valid_handle(&handle_table, hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (!release_handle(&handle_table, hKey, RSAENH_MAGIC_KEY)) { SetLastError(NTE_BAD_KEY); return FALSE; } return TRUE; } /****************************************************************************** * CPDuplicateHash (RSAENH.@) * * Clones a hash object including it's current state. * * PARAMS * hUID [I] Handle to the key container the hash belongs to. * hHash [I] Handle to the hash object to be cloned. * pdwReserved [I] Reserved. Must be NULL. * dwFlags [I] No flags are currently defined. Must be 0. * phHash [O] Handle to the cloned hash object. * * RETURNS * Success: TRUE. * Failure: FALSE. */ BOOL WINAPI RSAENH_CPDuplicateHash(HCRYPTPROV hUID, HCRYPTHASH hHash, DWORD *pdwReserved, DWORD dwFlags, HCRYPTHASH *phHash) { CRYPTHASH *pSrcHash, *pDestHash; TRACE("(hUID=%08lx, hHash=%08lx, pdwReserved=%p, dwFlags=%08lx, phHash=%p)\n", hUID, hHash, pdwReserved, dwFlags, phHash); if (!is_valid_handle(&handle_table, hUID, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (!lookup_handle(&handle_table, hHash, RSAENH_MAGIC_HASH, (OBJECTHDR**)&pSrcHash)) { SetLastError(NTE_BAD_HASH); return FALSE; } if (!phHash || pdwReserved || dwFlags) { SetLastError(ERROR_INVALID_PARAMETER); return FALSE; } *phHash = (HCRYPTHASH)new_object(&handle_table, sizeof(CRYPTHASH), RSAENH_MAGIC_HASH, destroy_hash, (OBJECTHDR**)&pDestHash); if (*phHash != (HCRYPTHASH)INVALID_HANDLE_VALUE) { memcpy(pDestHash, pSrcHash, sizeof(CRYPTHASH)); duplicate_hash_impl(pSrcHash->aiAlgid, &pSrcHash->context, &pDestHash->context); copy_hmac_info(&pDestHash->pHMACInfo, pSrcHash->pHMACInfo); copy_data_blob(&pDestHash->tpPRFParams.blobLabel, &pSrcHash->tpPRFParams.blobLabel); copy_data_blob(&pDestHash->tpPRFParams.blobSeed, &pSrcHash->tpPRFParams.blobSeed); } return *phHash != (HCRYPTHASH)INVALID_HANDLE_VALUE; } /****************************************************************************** * CPDuplicateKey (RSAENH.@) * * Clones a key object including it's current state. * * PARAMS * hUID [I] Handle to the key container the hash belongs to. * hKey [I] Handle to the key object to be cloned. * pdwReserved [I] Reserved. Must be NULL. * dwFlags [I] No flags are currently defined. Must be 0. * phHash [O] Handle to the cloned key object. * * RETURNS * Success: TRUE. * Failure: FALSE. */ BOOL WINAPI RSAENH_CPDuplicateKey(HCRYPTPROV hUID, HCRYPTKEY hKey, DWORD *pdwReserved, DWORD dwFlags, HCRYPTKEY *phKey) { CRYPTKEY *pSrcKey, *pDestKey; TRACE("(hUID=%08lx, hKey=%08lx, pdwReserved=%p, dwFlags=%08lx, phKey=%p)\n", hUID, hKey, pdwReserved, dwFlags, phKey); if (!is_valid_handle(&handle_table, hUID, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (!lookup_handle(&handle_table, hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pSrcKey)) { SetLastError(NTE_BAD_KEY); return FALSE; } if (!phKey || pdwReserved || dwFlags) { SetLastError(ERROR_INVALID_PARAMETER); return FALSE; } *phKey = (HCRYPTKEY)new_object(&handle_table, sizeof(CRYPTKEY), RSAENH_MAGIC_KEY, destroy_key, (OBJECTHDR**)&pDestKey); if (*phKey != (HCRYPTKEY)INVALID_HANDLE_VALUE) { memcpy(pDestKey, pSrcKey, sizeof(CRYPTKEY)); copy_data_blob(&pDestKey->siSChannelInfo.blobServerRandom, &pSrcKey->siSChannelInfo.blobServerRandom); copy_data_blob(&pDestKey->siSChannelInfo.blobClientRandom, &pSrcKey->siSChannelInfo.blobClientRandom); duplicate_key_impl(pSrcKey->aiAlgid, &pSrcKey->context, &pDestKey->context); return TRUE; } else { return FALSE; } } /****************************************************************************** * CPEncrypt (RSAENH.@) * * Encrypt data. * * PARAMS * hProv [I] The key container hKey and hHash belong to. * hKey [I] The key used to encrypt the data. * hHash [I] An optional hash object for parallel hashing. See notes. * Final [I] Indicates if this is the last block of data to encrypt. * dwFlags [I] Currently no flags defined. Must be zero. * pbData [I/O] Pointer to the data to encrypt. Encrypted data will also be stored there. * pdwDataLen [I/O] I: Length of data to encrypt, O: Length of encrypted data. * dwBufLen [I] Size of the buffer at pbData. * * RETURNS * Success: TRUE. * Failure: FALSE. * * NOTES * If a hash object handle is provided in hHash, it will be updated with the plaintext. * This is useful for message signatures. * * This function uses the standard WINAPI protocol for querying data of dynamic length. */ BOOL WINAPI RSAENH_CPEncrypt(HCRYPTPROV hProv, HCRYPTKEY hKey, HCRYPTHASH hHash, BOOL Final, DWORD dwFlags, BYTE *pbData, DWORD *pdwDataLen, DWORD dwBufLen) { CRYPTKEY *pCryptKey; BYTE *in, out[RSAENH_MAX_BLOCK_SIZE], o[RSAENH_MAX_BLOCK_SIZE]; DWORD dwEncryptedLen, i, j, k; TRACE("(hProv=%08lx, hKey=%08lx, hHash=%08lx, Final=%d, dwFlags=%08lx, pbData=%p, " "pdwDataLen=%p, dwBufLen=%ld)\n", hProv, hKey, hHash, Final, dwFlags, pbData, pdwDataLen, dwBufLen); if (!is_valid_handle(&handle_table, hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (dwFlags) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (!lookup_handle(&handle_table, hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pCryptKey)) { SetLastError(NTE_BAD_KEY); return FALSE; } if (pCryptKey->dwState == RSAENH_KEYSTATE_IDLE) pCryptKey->dwState = RSAENH_KEYSTATE_ENCRYPTING; if (pCryptKey->dwState != RSAENH_KEYSTATE_ENCRYPTING) { SetLastError(NTE_BAD_DATA); return FALSE; } if (is_valid_handle(&handle_table, hHash, RSAENH_MAGIC_HASH)) { if (!RSAENH_CPHashData(hProv, hHash, pbData, *pdwDataLen, 0)) return FALSE; } if (GET_ALG_TYPE(pCryptKey->aiAlgid) == ALG_TYPE_BLOCK) { if (!Final && (*pdwDataLen % pCryptKey->dwBlockLen)) { SetLastError(NTE_BAD_DATA); return FALSE; } dwEncryptedLen = (*pdwDataLen/pCryptKey->dwBlockLen+(Final?1:0))*pCryptKey->dwBlockLen; for (i=*pdwDataLen; i dwBufLen) { SetLastError(ERROR_MORE_DATA); return FALSE; } for (i=0, in=pbData; i<*pdwDataLen; i+=pCryptKey->dwBlockLen, in+=pCryptKey->dwBlockLen) { switch (pCryptKey->dwMode) { case CRYPT_MODE_ECB: encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, in, out, RSAENH_ENCRYPT); break; case CRYPT_MODE_CBC: for (j=0; jdwBlockLen; j++) in[j] ^= pCryptKey->abChainVector[j]; encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, in, out, RSAENH_ENCRYPT); memcpy(pCryptKey->abChainVector, out, pCryptKey->dwBlockLen); break; case CRYPT_MODE_CFB: for (j=0; jdwBlockLen; j++) { encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, pCryptKey->abChainVector, o, RSAENH_ENCRYPT); out[j] = in[j] ^ o[0]; for (k=0; kdwBlockLen-1; k++) pCryptKey->abChainVector[k] = pCryptKey->abChainVector[k+1]; pCryptKey->abChainVector[k] = out[j]; } break; default: SetLastError(NTE_BAD_ALGID); return FALSE; } memcpy(in, out, pCryptKey->dwBlockLen); } } else if (GET_ALG_TYPE(pCryptKey->aiAlgid) == ALG_TYPE_STREAM) { encrypt_stream_impl(pCryptKey->aiAlgid, &pCryptKey->context, pbData, *pdwDataLen); } else if (GET_ALG_TYPE(pCryptKey->aiAlgid) == ALG_TYPE_RSA) { if (pCryptKey->aiAlgid == CALG_RSA_SIGN) { SetLastError(NTE_BAD_KEY); return FALSE; } if (dwBufLen < pCryptKey->dwBlockLen) { SetLastError(ERROR_MORE_DATA); return FALSE; } if (!pad_data(pbData, *pdwDataLen, pbData, pCryptKey->dwBlockLen, dwFlags)) return FALSE; encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, pbData, pbData, RSAENH_ENCRYPT); *pdwDataLen = pCryptKey->dwBlockLen; Final = TRUE; } else { SetLastError(NTE_BAD_TYPE); return FALSE; } if (Final) setup_key(pCryptKey); return TRUE; } /****************************************************************************** * CPDecrypt (RSAENH.@) * * Decrypt data. * * PARAMS * hProv [I] The key container hKey and hHash belong to. * hKey [I] The key used to decrypt the data. * hHash [I] An optional hash object for parallel hashing. See notes. * Final [I] Indicates if this is the last block of data to decrypt. * dwFlags [I] Currently no flags defined. Must be zero. * pbData [I/O] Pointer to the data to decrypt. Plaintext will also be stored there. * pdwDataLen [I/O] I: Length of ciphertext, O: Length of plaintext. * * RETURNS * Success: TRUE. * Failure: FALSE. * * NOTES * If a hash object handle is provided in hHash, it will be updated with the plaintext. * This is useful for message signatures. * * This function uses the standard WINAPI protocol for querying data of dynamic length. */ BOOL WINAPI RSAENH_CPDecrypt(HCRYPTPROV hProv, HCRYPTKEY hKey, HCRYPTHASH hHash, BOOL Final, DWORD dwFlags, BYTE *pbData, DWORD *pdwDataLen) { CRYPTKEY *pCryptKey; BYTE *in, out[RSAENH_MAX_BLOCK_SIZE], o[RSAENH_MAX_BLOCK_SIZE]; DWORD i, j, k; TRACE("(hProv=%08lx, hKey=%08lx, hHash=%08lx, Final=%d, dwFlags=%08lx, pbData=%p, " "pdwDataLen=%p)\n", hProv, hKey, hHash, Final, dwFlags, pbData, pdwDataLen); if (!is_valid_handle(&handle_table, hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (dwFlags) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (!lookup_handle(&handle_table, hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pCryptKey)) { SetLastError(NTE_BAD_KEY); return FALSE; } if (pCryptKey->dwState == RSAENH_KEYSTATE_IDLE) pCryptKey->dwState = RSAENH_KEYSTATE_DECRYPTING; if (pCryptKey->dwState != RSAENH_KEYSTATE_DECRYPTING) { SetLastError(NTE_BAD_DATA); return FALSE; } if (GET_ALG_TYPE(pCryptKey->aiAlgid) == ALG_TYPE_BLOCK) { for (i=0, in=pbData; i<*pdwDataLen; i+=pCryptKey->dwBlockLen, in+=pCryptKey->dwBlockLen) { switch (pCryptKey->dwMode) { case CRYPT_MODE_ECB: encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, in, out, RSAENH_DECRYPT); break; case CRYPT_MODE_CBC: encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, in, out, RSAENH_DECRYPT); for (j=0; jdwBlockLen; j++) out[j] ^= pCryptKey->abChainVector[j]; memcpy(pCryptKey->abChainVector, in, pCryptKey->dwBlockLen); break; case CRYPT_MODE_CFB: for (j=0; jdwBlockLen; j++) { encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, pCryptKey->abChainVector, o, RSAENH_ENCRYPT); out[j] = in[j] ^ o[0]; for (k=0; kdwBlockLen-1; k++) pCryptKey->abChainVector[k] = pCryptKey->abChainVector[k+1]; pCryptKey->abChainVector[k] = in[j]; } break; default: SetLastError(NTE_BAD_ALGID); return FALSE; } memcpy(in, out, pCryptKey->dwBlockLen); } if (Final) *pdwDataLen -= pbData[*pdwDataLen-1]; } else if (GET_ALG_TYPE(pCryptKey->aiAlgid) == ALG_TYPE_STREAM) { encrypt_stream_impl(pCryptKey->aiAlgid, &pCryptKey->context, pbData, *pdwDataLen); } else if (GET_ALG_TYPE(pCryptKey->aiAlgid) == ALG_TYPE_RSA) { if (pCryptKey->aiAlgid == CALG_RSA_SIGN) { SetLastError(NTE_BAD_KEY); return FALSE; } encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, pbData, pbData, RSAENH_DECRYPT); if (!unpad_data(pbData, pCryptKey->dwBlockLen, pbData, pdwDataLen, dwFlags)) return FALSE; Final = TRUE; } else { SetLastError(NTE_BAD_TYPE); return FALSE; } if (Final) setup_key(pCryptKey); if (is_valid_handle(&handle_table, hHash, RSAENH_MAGIC_HASH)) { if (!RSAENH_CPHashData(hProv, hHash, pbData, *pdwDataLen, 0)) return FALSE; } return TRUE; } /****************************************************************************** * CPExportKey (RSAENH.@) * * Export a key into a binary large object (BLOB). * * PARAMS * hProv [I] Key container from which a key is to be exported. * hKey [I] Key to be exported. * hPubKey [I] Key used to encrypt sensitive BLOB data. * dwBlobType [I] SIMPLEBLOB, PUBLICKEYBLOB or PRIVATEKEYBLOB. * dwFlags [I] Currently none defined. * pbData [O] Pointer to a buffer where the BLOB will be written to. * pdwDataLen [I/O] I: Size of buffer at pbData, O: Size of BLOB * * RETURNS * Success: TRUE. * Failure: FALSE. */ BOOL WINAPI RSAENH_CPExportKey(HCRYPTPROV hProv, HCRYPTKEY hKey, HCRYPTKEY hPubKey, DWORD dwBlobType, DWORD dwFlags, BYTE *pbData, DWORD *pdwDataLen) { CRYPTKEY *pCryptKey, *pPubKey; BLOBHEADER *pBlobHeader = (BLOBHEADER*)pbData; RSAPUBKEY *pRSAPubKey = (RSAPUBKEY*)(pBlobHeader+1); ALG_ID *pAlgid = (ALG_ID*)(pBlobHeader+1); DWORD dwDataLen; TRACE("(hProv=%08lx, hKey=%08lx, hPubKey=%08lx, dwBlobType=%08lx, dwFlags=%08lx, pbData=%p," "pdwDataLen=%p)\n", hProv, hKey, hPubKey, dwBlobType, dwFlags, pbData, pdwDataLen); if (!is_valid_handle(&handle_table, hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (!lookup_handle(&handle_table, hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pCryptKey)) { SetLastError(NTE_BAD_KEY); return FALSE; } if (dwFlags & CRYPT_SSL2_FALLBACK) { if (pCryptKey->aiAlgid != CALG_SSL2_MASTER) { SetLastError(NTE_BAD_KEY); return FALSE; } } switch ((BYTE)dwBlobType) { case SIMPLEBLOB: if (!lookup_handle(&handle_table, hPubKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pPubKey)){ SetLastError(NTE_BAD_PUBLIC_KEY); /* FIXME: error_code? */ return FALSE; } if (!(GET_ALG_CLASS(pCryptKey->aiAlgid)&(ALG_CLASS_DATA_ENCRYPT|ALG_CLASS_MSG_ENCRYPT))) { SetLastError(NTE_BAD_KEY); /* FIXME: error code? */ return FALSE; } dwDataLen = sizeof(BLOBHEADER) + sizeof(ALG_ID) + pPubKey->dwBlockLen; if (pbData) { if (*pdwDataLen < dwDataLen) { SetLastError(ERROR_MORE_DATA); *pdwDataLen = dwDataLen; return FALSE; } pBlobHeader->bType = SIMPLEBLOB; pBlobHeader->bVersion = CUR_BLOB_VERSION; pBlobHeader->reserved = 0; pBlobHeader->aiKeyAlg = pCryptKey->aiAlgid; *pAlgid = pPubKey->aiAlgid; if (!pad_data(pCryptKey->abKeyValue, pCryptKey->dwKeyLen, (BYTE*)(pAlgid+1), pPubKey->dwBlockLen, dwFlags)) { return FALSE; } encrypt_block_impl(pPubKey->aiAlgid, &pPubKey->context, (BYTE*)(pAlgid+1), (BYTE*)(pAlgid+1), RSAENH_ENCRYPT); } *pdwDataLen = dwDataLen; return TRUE; case PUBLICKEYBLOB: if (is_valid_handle(&handle_table, hPubKey, RSAENH_MAGIC_KEY)) { SetLastError(NTE_BAD_KEY); /* FIXME: error code? */ return FALSE; } if ((pCryptKey->aiAlgid != CALG_RSA_KEYX) && (pCryptKey->aiAlgid != CALG_RSA_SIGN)) { SetLastError(NTE_BAD_KEY); return FALSE; } dwDataLen = sizeof(BLOBHEADER) + sizeof(RSAPUBKEY) + pCryptKey->dwKeyLen; if (pbData) { if (*pdwDataLen < dwDataLen) { SetLastError(ERROR_MORE_DATA); *pdwDataLen = dwDataLen; return FALSE; } pBlobHeader->bType = PUBLICKEYBLOB; pBlobHeader->bVersion = CUR_BLOB_VERSION; pBlobHeader->reserved = 0; pBlobHeader->aiKeyAlg = pCryptKey->aiAlgid; pRSAPubKey->magic = RSAENH_MAGIC_RSA1; pRSAPubKey->bitlen = pCryptKey->dwKeyLen << 3; export_public_key_impl((BYTE*)(pRSAPubKey+1), &pCryptKey->context, pCryptKey->dwKeyLen, &pRSAPubKey->pubexp); } *pdwDataLen = dwDataLen; return TRUE; case PRIVATEKEYBLOB: if ((pCryptKey->aiAlgid != CALG_RSA_KEYX) && (pCryptKey->aiAlgid != CALG_RSA_SIGN)) { SetLastError(NTE_BAD_KEY); return FALSE; } dwDataLen = sizeof(BLOBHEADER) + sizeof(RSAPUBKEY) + 2 * pCryptKey->dwKeyLen + 5 * ((pCryptKey->dwKeyLen + 1) >> 1); if (pbData) { if (*pdwDataLen < dwDataLen) { SetLastError(ERROR_MORE_DATA); *pdwDataLen = dwDataLen; return FALSE; } pBlobHeader->bType = PRIVATEKEYBLOB; pBlobHeader->bVersion = CUR_BLOB_VERSION; pBlobHeader->reserved = 0; pBlobHeader->aiKeyAlg = pCryptKey->aiAlgid; pRSAPubKey->magic = RSAENH_MAGIC_RSA2; pRSAPubKey->bitlen = pCryptKey->dwKeyLen << 3; export_private_key_impl((BYTE*)(pRSAPubKey+1), &pCryptKey->context, pCryptKey->dwKeyLen, &pRSAPubKey->pubexp); } *pdwDataLen = dwDataLen; return TRUE; default: SetLastError(NTE_BAD_TYPE); /* FIXME: error code? */ return FALSE; } } /****************************************************************************** * CPImportKey (RSAENH.@) * * Import a BLOB'ed key into a key container. * * PARAMS * hProv [I] Key container into which the key is to be imported. * pbData [I] Pointer to a buffer which holds the BLOB. * dwDataLen [I] Length of data in buffer at pbData. * hPubKey [I] Key used to decrypt sensitive BLOB data. * dwFlags [I] Currently none defined. * phKey [O] Handle to the imported key. * * RETURNS * Success: TRUE. * Failure: FALSE. */ BOOL WINAPI RSAENH_CPImportKey(HCRYPTPROV hProv, CONST BYTE *pbData, DWORD dwDataLen, HCRYPTKEY hPubKey, DWORD dwFlags, HCRYPTKEY *phKey) { CRYPTKEY *pCryptKey, *pPubKey; CONST BLOBHEADER *pBlobHeader = (CONST BLOBHEADER*)pbData; CONST RSAPUBKEY *pRSAPubKey = (CONST RSAPUBKEY*)(pBlobHeader+1); CONST ALG_ID *pAlgid = (CONST ALG_ID*)(pBlobHeader+1); CONST BYTE *pbKeyStream = (CONST BYTE*)(pAlgid + 1); BYTE *pbDecrypted; DWORD dwKeyLen; TRACE("(hProv=%08lx, pbData=%p, dwDataLen=%ld, hPubKey=%08lx, dwFlags=%08lx, phKey=%p)\n", hProv, pbData, dwDataLen, hPubKey, dwFlags, phKey); if (!is_valid_handle(&handle_table, hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (dwDataLen < sizeof(BLOBHEADER) || pBlobHeader->bVersion != CUR_BLOB_VERSION || pBlobHeader->reserved != 0) { SetLastError(NTE_BAD_DATA); return FALSE; } switch (pBlobHeader->bType) { case PRIVATEKEYBLOB: if ((dwDataLen < sizeof(BLOBHEADER) + sizeof(RSAPUBKEY)) || (pRSAPubKey->magic != RSAENH_MAGIC_RSA2) || (dwDataLen < sizeof(BLOBHEADER) + sizeof(RSAPUBKEY) + (2 * pRSAPubKey->bitlen >> 3) + (5 * ((pRSAPubKey->bitlen+8)>>4)))) { SetLastError(NTE_BAD_DATA); return FALSE; } *phKey = new_key(hProv, pBlobHeader->aiKeyAlg, MAKELONG(0,pRSAPubKey->bitlen), &pCryptKey); if (*phKey == (HCRYPTKEY)INVALID_HANDLE_VALUE) return FALSE; setup_key(pCryptKey); return import_private_key_impl((CONST BYTE*)(pRSAPubKey+1), &pCryptKey->context, pRSAPubKey->bitlen/8, pRSAPubKey->pubexp); case PUBLICKEYBLOB: if ((dwDataLen < sizeof(BLOBHEADER) + sizeof(RSAPUBKEY)) || (pRSAPubKey->magic != RSAENH_MAGIC_RSA1) || (dwDataLen < sizeof(BLOBHEADER) + sizeof(RSAPUBKEY) + (pRSAPubKey->bitlen >> 3))) { SetLastError(NTE_BAD_DATA); return FALSE; } *phKey = new_key(hProv, pBlobHeader->aiKeyAlg, MAKELONG(0,pRSAPubKey->bitlen), &pCryptKey); if (*phKey == (HCRYPTKEY)INVALID_HANDLE_VALUE) return FALSE; setup_key(pCryptKey); return import_public_key_impl((CONST BYTE*)(pRSAPubKey+1), &pCryptKey->context, pRSAPubKey->bitlen >> 3, pRSAPubKey->pubexp); case SIMPLEBLOB: if (!lookup_handle(&handle_table, hPubKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pPubKey) || pPubKey->aiAlgid != CALG_RSA_KEYX) { SetLastError(NTE_BAD_PUBLIC_KEY); /* FIXME: error code? */ return FALSE; } if (dwDataLen < sizeof(BLOBHEADER)+sizeof(ALG_ID)+pPubKey->dwBlockLen) { SetLastError(NTE_BAD_DATA); /* FIXME: error code */ return FALSE; } pbDecrypted = (BYTE*)HeapAlloc(GetProcessHeap(), 0, pPubKey->dwBlockLen); if (!pbDecrypted) return FALSE; encrypt_block_impl(pPubKey->aiAlgid, &pPubKey->context, pbKeyStream, pbDecrypted, RSAENH_DECRYPT); dwKeyLen = RSAENH_MAX_KEY_SIZE; if (!unpad_data(pbDecrypted, pPubKey->dwBlockLen, pbDecrypted, &dwKeyLen, dwFlags)) { HeapFree(GetProcessHeap(), 0, pbDecrypted); return FALSE; } *phKey = new_key(hProv, pBlobHeader->aiKeyAlg, dwKeyLen<<19, &pCryptKey); if (*phKey == (HCRYPTKEY)INVALID_HANDLE_VALUE) { HeapFree(GetProcessHeap(), 0, pbDecrypted); return FALSE; } memcpy(pCryptKey->abKeyValue, pbDecrypted, dwKeyLen); HeapFree(GetProcessHeap(), 0, pbDecrypted); setup_key(pCryptKey); return TRUE; default: SetLastError(NTE_BAD_TYPE); /* FIXME: error code? */ return FALSE; } } /****************************************************************************** * CPGenKey (RSAENH.@) * * Generate a key in the key container * * PARAMS * hProv [I] Key container for which a key is to be generated. * Algid [I] Crypto algorithm identifier for the key to be generated. * dwFlags [I] Upper 16 bits: Binary length of key. Lower 16 bits: Flags. See Notes * phKey [O] Handle to the generated key. * * RETURNS * Success: TRUE. * Failure: FALSE. * * FIXME * Flags currently not considered. * * NOTES * Private key-exchange- and signature-keys can be generated with Algid AT_KEYEXCHANGE * and AT_SIGNATURE values. */ BOOL WINAPI RSAENH_CPGenKey(HCRYPTPROV hProv, ALG_ID Algid, DWORD dwFlags, HCRYPTKEY *phKey) { KEYCONTAINER *pKeyContainer; CRYPTKEY *pCryptKey; TRACE("(hProv=%08lx, aiAlgid=%d, dwFlags=%08lx, phKey=%p)\n", hProv, Algid, dwFlags, phKey); if (!lookup_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER, (OBJECTHDR**)&pKeyContainer)) { /* MSDN: hProv not containing valid context handle */ SetLastError(NTE_BAD_UID); return FALSE; } switch (Algid) { case AT_SIGNATURE: case CALG_RSA_SIGN: *phKey = new_key(hProv, CALG_RSA_SIGN, dwFlags, &pCryptKey); if (pCryptKey) { new_key_impl(pCryptKey->aiAlgid, &pCryptKey->context, pCryptKey->dwKeyLen); setup_key(pCryptKey); if (Algid == AT_SIGNATURE) { RSAENH_CPDestroyKey(hProv, pKeyContainer->hSignatureKeyPair); copy_handle(&handle_table, *phKey, RSAENH_MAGIC_KEY, (unsigned int*)&pKeyContainer->hSignatureKeyPair); } } break; case AT_KEYEXCHANGE: case CALG_RSA_KEYX: *phKey = new_key(hProv, CALG_RSA_KEYX, dwFlags, &pCryptKey); if (pCryptKey) { new_key_impl(pCryptKey->aiAlgid, &pCryptKey->context, pCryptKey->dwKeyLen); setup_key(pCryptKey); if (Algid == AT_KEYEXCHANGE) { RSAENH_CPDestroyKey(hProv, pKeyContainer->hKeyExchangeKeyPair); copy_handle(&handle_table, *phKey, RSAENH_MAGIC_KEY, (unsigned int*)&pKeyContainer->hKeyExchangeKeyPair); } } break; case CALG_RC2: case CALG_RC4: case CALG_DES: case CALG_3DES_112: case CALG_3DES: case CALG_PCT1_MASTER: case CALG_SSL2_MASTER: case CALG_SSL3_MASTER: case CALG_TLS1_MASTER: *phKey = new_key(hProv, Algid, dwFlags, &pCryptKey); if (pCryptKey) { gen_rand_impl(pCryptKey->abKeyValue, RSAENH_MAX_KEY_SIZE); switch (Algid) { case CALG_SSL3_MASTER: pCryptKey->abKeyValue[0] = RSAENH_SSL3_VERSION_MAJOR; pCryptKey->abKeyValue[1] = RSAENH_SSL3_VERSION_MINOR; break; case CALG_TLS1_MASTER: pCryptKey->abKeyValue[0] = RSAENH_TLS1_VERSION_MAJOR; pCryptKey->abKeyValue[1] = RSAENH_TLS1_VERSION_MINOR; break; } setup_key(pCryptKey); } break; default: /* MSDN: Algorithm not supported specified by Algid */ SetLastError(NTE_BAD_ALGID); return FALSE; } return *phKey != (unsigned int)INVALID_HANDLE_VALUE; } /****************************************************************************** * CPGenRandom (RSAENH.@) * * Generate a random byte stream. * * PARAMS * hProv [I] Key container that is used to generate random bytes. * dwLen [I] Specifies the number of requested random data bytes. * pbBuffer [O] Random bytes will be stored here. * * RETURNS * Success: TRUE * Failure: FALSE */ BOOL WINAPI RSAENH_CPGenRandom(HCRYPTPROV hProv, DWORD dwLen, BYTE *pbBuffer) { TRACE("(hProv=%08lx, dwLen=%ld, pbBuffer=%p)\n", hProv, dwLen, pbBuffer); if (!is_valid_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER)) { /* MSDN: hProv not containing valid context handle */ SetLastError(NTE_BAD_UID); return FALSE; } return gen_rand_impl(pbBuffer, dwLen); } /****************************************************************************** * CPGetHashParam (RSAENH.@) * * Query parameters of an hash object. * * PARAMS * hProv [I] The kea container, which the hash belongs to. * hHash [I] The hash object that is to be queried. * dwParam [I] Specifies the parameter that is to be queried. * pbData [I] Pointer to the buffer where the parameter value will be stored. * pdwDataLen [I/O] I: Buffer length at pbData, O: Length of the parameter value. * dwFlags [I] None currently defined. * * RETURNS * Success: TRUE * Failure: FALSE * * NOTES * Valid dwParams are: HP_ALGID, HP_HASHSIZE, HP_HASHVALUE. The hash will be * finalized if HP_HASHVALUE is queried. */ BOOL WINAPI RSAENH_CPGetHashParam(HCRYPTPROV hProv, HCRYPTHASH hHash, DWORD dwParam, BYTE *pbData, DWORD *pdwDataLen, DWORD dwFlags) { CRYPTHASH *pCryptHash; TRACE("(hProv=%08lx, hHash=%08lx, dwParam=%08lx, pbData=%p, pdwDataLen=%p, dwFlags=%08lx)\n", hProv, hHash, dwParam, pbData, pdwDataLen, dwFlags); if (!is_valid_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (dwFlags) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (!lookup_handle(&handle_table, (unsigned int)hHash, RSAENH_MAGIC_HASH, (OBJECTHDR**)&pCryptHash)) { SetLastError(NTE_BAD_HASH); return FALSE; } if (!pdwDataLen) { SetLastError(ERROR_INVALID_PARAMETER); return FALSE; } switch (dwParam) { case HP_ALGID: return copy_param(pbData, pdwDataLen, (CONST BYTE*)&pCryptHash->aiAlgid, sizeof(ALG_ID)); case HP_HASHSIZE: return copy_param(pbData, pdwDataLen, (CONST BYTE*)&pCryptHash->dwHashSize, sizeof(DWORD)); case HP_HASHVAL: if (pCryptHash->aiAlgid == CALG_TLS1PRF) { return tls1_prf(hProv, pCryptHash->hKey, &pCryptHash->tpPRFParams.blobLabel, &pCryptHash->tpPRFParams.blobSeed, pbData, *pdwDataLen); } if (pCryptHash->dwState == RSAENH_HASHSTATE_IDLE) { SetLastError(NTE_BAD_HASH_STATE); return FALSE; } if (pbData && (pCryptHash->dwState != RSAENH_HASHSTATE_FINISHED)) { finalize_hash(pCryptHash); pCryptHash->dwState = RSAENH_HASHSTATE_FINISHED; } return copy_param(pbData, pdwDataLen, (CONST BYTE*)pCryptHash->abHashValue, pCryptHash->dwHashSize); default: SetLastError(NTE_BAD_TYPE); return FALSE; } } /****************************************************************************** * CPSetKeyParam (RSAENH.@) * * Set a parameter of a key object * * PARAMS * hProv [I] The key container to which the key belongs. * hKey [I] The key for which a parameter is to be set. * dwParam [I] Parameter type. See Notes. * pbData [I] Pointer to the parameter value. * dwFlags [I] Currently none defined. * * RETURNS * Success: TRUE. * Failure: FALSE. * * NOTES: * Defined dwParam types are: * - KP_MODE: Values MODE_CBC, MODE_ECB, MODE_CFB. * - KP_MODE_BITS: Shift width for cipher feedback mode. (Currently ignored by MS CSP's) * - KP_PERMISSIONS: Or'ed combination of CRYPT_ENCRYPT, CRYPT_DECRYPT, * CRYPT_EXPORT, CRYPT_READ, CRYPT_WRITE, CRYPT_MAC * - KP_IV: Initialization vector */ BOOL WINAPI RSAENH_CPSetKeyParam(HCRYPTPROV hProv, HCRYPTKEY hKey, DWORD dwParam, BYTE *pbData, DWORD dwFlags) { CRYPTKEY *pCryptKey; TRACE("(hProv=%08lx, hKey=%08lx, dwParam=%08lx, pbData=%p, dwFlags=%08lx)\n", hProv, hKey, dwParam, pbData, dwFlags); if (!is_valid_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (dwFlags) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (!lookup_handle(&handle_table, (unsigned int)hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pCryptKey)) { SetLastError(NTE_BAD_KEY); return FALSE; } switch (dwParam) { case KP_MODE: pCryptKey->dwMode = *(DWORD*)pbData; return TRUE; case KP_MODE_BITS: pCryptKey->dwModeBits = *(DWORD*)pbData; return TRUE; case KP_PERMISSIONS: pCryptKey->dwPermissions = *(DWORD*)pbData; return TRUE; case KP_IV: memcpy(pCryptKey->abInitVector, pbData, pCryptKey->dwBlockLen); return TRUE; case KP_SCHANNEL_ALG: switch (((PSCHANNEL_ALG)pbData)->dwUse) { case SCHANNEL_ENC_KEY: memcpy(&pCryptKey->siSChannelInfo.saEncAlg, pbData, sizeof(SCHANNEL_ALG)); break; case SCHANNEL_MAC_KEY: memcpy(&pCryptKey->siSChannelInfo.saMACAlg, pbData, sizeof(SCHANNEL_ALG)); break; default: SetLastError(NTE_FAIL); /* FIXME: error code */ return FALSE; } return TRUE; case KP_CLIENT_RANDOM: return copy_data_blob(&pCryptKey->siSChannelInfo.blobClientRandom, (PCRYPT_DATA_BLOB)pbData); case KP_SERVER_RANDOM: return copy_data_blob(&pCryptKey->siSChannelInfo.blobServerRandom, (PCRYPT_DATA_BLOB)pbData); default: SetLastError(NTE_BAD_TYPE); return FALSE; } } /****************************************************************************** * CPGetKeyParam (RSAENH.@) * * Query a key parameter. * * PARAMS * hProv [I] The key container, which the key belongs to. * hHash [I] The key object that is to be queried. * dwParam [I] Specifies the parameter that is to be queried. * pbData [I] Pointer to the buffer where the parameter value will be stored. * pdwDataLen [I/O] I: Buffer length at pbData, O: Length of the parameter value. * dwFlags [I] None currently defined. * * RETURNS * Success: TRUE * Failure: FALSE * * NOTES * Defined dwParam types are: * - KP_MODE: Values MODE_CBC, MODE_ECB, MODE_CFB. * - KP_MODE_BITS: Shift width for cipher feedback mode. * (Currently ignored by MS CSP's - always eight) * - KP_PERMISSIONS: Or'ed combination of CRYPT_ENCRYPT, CRYPT_DECRYPT, * CRYPT_EXPORT, CRYPT_READ, CRYPT_WRITE, CRYPT_MAC * - KP_IV: Initialization vector. * - KP_KEYLEN: Bitwidth of the key. * - KP_BLOCKLEN: Size of a block cipher block. * - KP_SALT: Salt value. */ BOOL WINAPI RSAENH_CPGetKeyParam(HCRYPTPROV hProv, HCRYPTKEY hKey, DWORD dwParam, BYTE *pbData, DWORD *pdwDataLen, DWORD dwFlags) { CRYPTKEY *pCryptKey; DWORD dwBitLen; TRACE("(hProv=%08lx, hKey=%08lx, dwParam=%08lx, pbData=%p, pdwDataLen=%p dwFlags=%08lx)\n", hProv, hKey, dwParam, pbData, pdwDataLen, dwFlags); if (!is_valid_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (dwFlags) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (!lookup_handle(&handle_table, (unsigned int)hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pCryptKey)) { SetLastError(NTE_BAD_KEY); return FALSE; } switch (dwParam) { case KP_IV: return copy_param(pbData, pdwDataLen, (CONST BYTE*)pCryptKey->abInitVector, pCryptKey->dwBlockLen); case KP_SALT: return copy_param(pbData, pdwDataLen, (CONST BYTE*)&pCryptKey->abKeyValue[pCryptKey->dwKeyLen], pCryptKey->dwSaltLen); case KP_KEYLEN: dwBitLen = pCryptKey->dwKeyLen << 3; return copy_param(pbData, pdwDataLen, (CONST BYTE*)&dwBitLen, sizeof(DWORD)); case KP_BLOCKLEN: dwBitLen = pCryptKey->dwBlockLen << 3; return copy_param(pbData, pdwDataLen, (CONST BYTE*)&dwBitLen, sizeof(DWORD)); case KP_MODE: return copy_param(pbData, pdwDataLen, (CONST BYTE*)&pCryptKey->dwMode, sizeof(DWORD)); case KP_MODE_BITS: return copy_param(pbData, pdwDataLen, (CONST BYTE*)&pCryptKey->dwModeBits, sizeof(DWORD)); case KP_PERMISSIONS: return copy_param(pbData, pdwDataLen, (CONST BYTE*)&pCryptKey->dwPermissions, sizeof(DWORD)); case KP_ALGID: return copy_param(pbData, pdwDataLen, (CONST BYTE*)&pCryptKey->aiAlgid, sizeof(DWORD)); default: SetLastError(NTE_BAD_TYPE); return FALSE; } } /****************************************************************************** * CPGetProvParam (RSAENH.@) * * Query a CSP parameter. * * PARAMS * hProv [I] The key container that is to be queried. * dwParam [I] Specifies the parameter that is to be queried. * pbData [I] Pointer to the buffer where the parameter value will be stored. * pdwDataLen [I/O] I: Buffer length at pbData, O: Length of the parameter value. * dwFlags [I] CRYPT_FIRST: Start enumeration (for PP_ENUMALGS{_EX}). * * RETURNS * Success: TRUE * Failure: FALSE * NOTES: * Defined dwParam types: * - PP_CONTAINER: Name of the key container. * - PP_NAME: Name of the cryptographic service provider. * - PP_SIG_KEYSIZE_INC: RSA signature keywidth granularity in bits. * - PP_KEYX_KEYSIZE_INC: RSA key-exchange keywidth granularity in bits. * - PP_ENUMALGS{_EX}: Query provider capabilities. */ BOOL WINAPI RSAENH_CPGetProvParam(HCRYPTPROV hProv, DWORD dwParam, BYTE *pbData, DWORD *pdwDataLen, DWORD dwFlags) { KEYCONTAINER *pKeyContainer; PROV_ENUMALGS provEnumalgs; DWORD dwTemp; /* This is for dwParam 41, which does not seem to be documented * on MSDN. IE6 SP1 asks for it in the 'About' dialog, however. * Returning this BLOB seems to satisfy IE. The marked 0x00 seem * to be 'don't care's. If you know anything more specific about * provider parameter 41, please report to wine-devel@winehq.org */ static CONST BYTE abWTF[96] = { 0xb0, 0x25, 0x63, 0x86, 0x9c, 0xab, 0xb6, 0x37, 0xe8, 0x82, /**/0x00,/**/ 0x72, 0x06, 0xb2, /**/0x00,/**/ 0x3b, 0x60, 0x35, /**/0x00,/**/ 0x3b, 0x88, 0xce, /**/0x00,/**/ 0x82, 0xbc, 0x7a, /**/0x00,/**/ 0xb7, 0x4f, 0x7e, /**/0x00,/**/ 0xde, 0x92, 0xf1, /**/0x00,/**/ 0x83, 0xea, 0x5e, /**/0x00,/**/ 0xc8, 0x12, 0x1e, 0xd4, 0x06, 0xf7, 0x66, /**/0x00,/**/ 0x01, 0x29, 0xa4, /**/0x00,/**/ 0xf8, 0x24, 0x0c, /**/0x00,/**/ 0x33, 0x06, 0x80, /**/0x00,/**/ 0x02, 0x46, 0x0b, /**/0x00,/**/ 0x6d, 0x5b, 0xca, /**/0x00,/**/ 0x9a, 0x10, 0xf0, /**/0x00,/**/ 0x05, 0x19, 0xd0, /**/0x00,/**/ 0x2c, 0xf6, 0x27, /**/0x00,/**/ 0xaa, 0x7c, 0x6f, /**/0x00,/**/ 0xb9, 0xd8, 0x72, /**/0x00,/**/ 0x03, 0xf3, 0x81, /**/0x00,/**/ 0xfa, 0xe8, 0x26, /**/0x00,/**/ 0xca }; TRACE("(hProv=%08lx, dwParam=%08lx, pbData=%p, pdwDataLen=%p, dwFlags=%08lx)\n", hProv, dwParam, pbData, pdwDataLen, dwFlags); if (!lookup_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER, (OBJECTHDR**)&pKeyContainer)) { /* MSDN: hProv not containing valid context handle */ SetLastError(NTE_BAD_UID); return FALSE; } switch (dwParam) { case PP_CONTAINER: return copy_param(pbData, pdwDataLen, (CONST BYTE*)pKeyContainer->szName, strlen(pKeyContainer->szName)+1); case PP_NAME: return copy_param(pbData, pdwDataLen, (CONST BYTE*)pKeyContainer->szProvName, strlen(pKeyContainer->szProvName)+1); case PP_SIG_KEYSIZE_INC: case PP_KEYX_KEYSIZE_INC: dwTemp = 8; return copy_param(pbData, pdwDataLen, (CONST BYTE*)&dwTemp, sizeof(dwTemp)); case PP_ENUMALGS: case PP_ENUMALGS_EX: if (((pKeyContainer->dwEnumAlgsCtr >= RSAENH_MAX_ENUMALGS-1) || (!aProvEnumAlgsEx[pKeyContainer->dwPersonality] [pKeyContainer->dwEnumAlgsCtr+1].aiAlgid)) && ((dwFlags & CRYPT_FIRST) != CRYPT_FIRST)) { SetLastError(ERROR_NO_MORE_ITEMS); return FALSE; } if (dwParam == PP_ENUMALGS) { if (pbData && (*pdwDataLen >= sizeof(PROV_ENUMALGS))) pKeyContainer->dwEnumAlgsCtr = ((dwFlags & CRYPT_FIRST) == CRYPT_FIRST) ? 0 : pKeyContainer->dwEnumAlgsCtr+1; provEnumalgs.aiAlgid = aProvEnumAlgsEx [pKeyContainer->dwPersonality][pKeyContainer->dwEnumAlgsCtr].aiAlgid; provEnumalgs.dwBitLen = aProvEnumAlgsEx [pKeyContainer->dwPersonality][pKeyContainer->dwEnumAlgsCtr].dwDefaultLen; provEnumalgs.dwNameLen = aProvEnumAlgsEx [pKeyContainer->dwPersonality][pKeyContainer->dwEnumAlgsCtr].dwNameLen; memcpy(provEnumalgs.szName, aProvEnumAlgsEx [pKeyContainer->dwPersonality][pKeyContainer->dwEnumAlgsCtr].szName, 20*sizeof(CHAR)); return copy_param(pbData, pdwDataLen, (CONST BYTE*)&provEnumalgs, sizeof(PROV_ENUMALGS)); } else { if (pbData && (*pdwDataLen >= sizeof(PROV_ENUMALGS_EX))) pKeyContainer->dwEnumAlgsCtr = ((dwFlags & CRYPT_FIRST) == CRYPT_FIRST) ? 0 : pKeyContainer->dwEnumAlgsCtr+1; return copy_param(pbData, pdwDataLen, (CONST BYTE*)&aProvEnumAlgsEx [pKeyContainer->dwPersonality][pKeyContainer->dwEnumAlgsCtr], sizeof(PROV_ENUMALGS_EX)); } case 41: /* Undocumented. Asked for by IE About dialog */ return copy_param(pbData, pdwDataLen, abWTF, sizeof(abWTF)); default: /* MSDN: Unknown parameter number in dwParam */ SetLastError(NTE_BAD_TYPE); return FALSE; } } /****************************************************************************** * CPDeriveKey (RSAENH.@) * * Derives a key from a hash value. * * PARAMS * hProv [I] Key container for which a key is to be generated. * Algid [I] Crypto algorithm identifier for the key to be generated. * hBaseData [I] Hash from whose value the key will be derived. * dwFlags [I] See Notes. * phKey [O] The generated key. * * RETURNS * Success: TRUE * Failure: FALSE * * NOTES * Defined flags: * - CRYPT_EXPORTABLE: Key can be exported. * - CRYPT_NO_SALT: No salt is used for 40 bit keys. * - CRYPT_CREATE_SALT: Use remaining bits as salt value. */ BOOL WINAPI RSAENH_CPDeriveKey(HCRYPTPROV hProv, ALG_ID Algid, HCRYPTHASH hBaseData, DWORD dwFlags, HCRYPTKEY *phKey) { CRYPTKEY *pCryptKey, *pMasterKey; CRYPTHASH *pCryptHash; BYTE abHashValue[RSAENH_MAX_HASH_SIZE*2]; DWORD dwLen; TRACE("(hProv=%08lx, Algid=%d, hBaseData=%08lx, dwFlags=%08lx phKey=%p)\n", hProv, Algid, hBaseData, dwFlags, phKey); if (!is_valid_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (!lookup_handle(&handle_table, (unsigned int)hBaseData, RSAENH_MAGIC_HASH, (OBJECTHDR**)&pCryptHash)) { SetLastError(NTE_BAD_HASH); return FALSE; } if (!phKey) { SetLastError(ERROR_INVALID_PARAMETER); return FALSE; } switch (GET_ALG_CLASS(Algid)) { case ALG_CLASS_DATA_ENCRYPT: *phKey = new_key(hProv, Algid, dwFlags, &pCryptKey); if (*phKey == (HCRYPTKEY)INVALID_HANDLE_VALUE) return FALSE; /* * We derive the key material from the hash. * If the hash value is not large enough for the claimed key, we have to construct * a larger binary value based on the hash. This is documented in MSDN: CryptDeriveKey. */ dwLen = RSAENH_MAX_HASH_SIZE; RSAENH_CPGetHashParam(pCryptHash->hProv, hBaseData, HP_HASHVAL, abHashValue, &dwLen, 0); if (dwLen < pCryptKey->dwKeyLen) { BYTE pad1[RSAENH_HMAC_DEF_PAD_LEN], pad2[RSAENH_HMAC_DEF_PAD_LEN]; BYTE old_hashval[RSAENH_MAX_HASH_SIZE]; DWORD i; memcpy(old_hashval, pCryptHash->abHashValue, RSAENH_MAX_HASH_SIZE); for (i=0; iabHashValue, pCryptHash->dwHashSize); init_hash(pCryptHash); update_hash(pCryptHash, pad2, RSAENH_HMAC_DEF_PAD_LEN); finalize_hash(pCryptHash); memcpy(abHashValue+pCryptHash->dwHashSize, pCryptHash->abHashValue, pCryptHash->dwHashSize); memcpy(pCryptHash->abHashValue, old_hashval, RSAENH_MAX_HASH_SIZE); } memcpy(pCryptKey->abKeyValue, abHashValue, RSAENH_MIN(pCryptKey->dwKeyLen, sizeof(pCryptKey->abKeyValue))); break; case ALG_CLASS_MSG_ENCRYPT: if (!lookup_handle(&handle_table, pCryptHash->hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pMasterKey)) { SetLastError(NTE_FAIL); /* FIXME error code */ return FALSE; } switch (Algid) { /* See RFC 2246, chapter 6.3 Key calculation */ case CALG_SCHANNEL_ENC_KEY: *phKey = new_key(hProv, pMasterKey->siSChannelInfo.saEncAlg.Algid, MAKELONG(LOWORD(dwFlags),pMasterKey->siSChannelInfo.saEncAlg.cBits), &pCryptKey); if (*phKey == (HCRYPTKEY)INVALID_HANDLE_VALUE) return FALSE; memcpy(pCryptKey->abKeyValue, pCryptHash->abHashValue + ( 2 * (pMasterKey->siSChannelInfo.saMACAlg.cBits / 8) + ((dwFlags & CRYPT_SERVER) ? (pMasterKey->siSChannelInfo.saEncAlg.cBits / 8) : 0)), pMasterKey->siSChannelInfo.saEncAlg.cBits / 8); memcpy(pCryptKey->abInitVector, pCryptHash->abHashValue + ( 2 * (pMasterKey->siSChannelInfo.saMACAlg.cBits / 8) + 2 * (pMasterKey->siSChannelInfo.saEncAlg.cBits / 8) + ((dwFlags & CRYPT_SERVER) ? pCryptKey->dwBlockLen : 0)), pCryptKey->dwBlockLen); break; case CALG_SCHANNEL_MAC_KEY: *phKey = new_key(hProv, Algid, MAKELONG(LOWORD(dwFlags),pMasterKey->siSChannelInfo.saMACAlg.cBits), &pCryptKey); if (*phKey == (HCRYPTKEY)INVALID_HANDLE_VALUE) return FALSE; memcpy(pCryptKey->abKeyValue, pCryptHash->abHashValue + ((dwFlags & CRYPT_SERVER) ? pMasterKey->siSChannelInfo.saMACAlg.cBits / 8 : 0), pMasterKey->siSChannelInfo.saMACAlg.cBits / 8); break; default: SetLastError(NTE_BAD_ALGID); return FALSE; } break; default: SetLastError(NTE_BAD_ALGID); return FALSE; } setup_key(pCryptKey); return TRUE; } /****************************************************************************** * CPGetUserKey (RSAENH.@) * * Returns a handle to the user's private key-exchange- or signature-key. * * PARAMS * hProv [I] The key container from which a user key is requested. * dwKeySpec [I] AT_KEYEXCHANGE or AT_SIGNATURE * phUserKey [O] Handle to the requested key or INVALID_HANDLE_VALUE in case of failure. * * RETURNS * Success: TRUE. * Failure: FALSE. * * NOTE * A newly created key container does not contain private user key. Create them with CPGenKey. */ BOOL WINAPI RSAENH_CPGetUserKey(HCRYPTPROV hProv, DWORD dwKeySpec, HCRYPTKEY *phUserKey) { KEYCONTAINER *pKeyContainer; TRACE("(hProv=%08lx, dwKeySpec=%08lx, phUserKey=%p)\n", hProv, dwKeySpec, phUserKey); if (!lookup_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER, (OBJECTHDR**)&pKeyContainer)) { /* MSDN: hProv not containing valid context handle */ SetLastError(NTE_BAD_UID); return FALSE; } switch (dwKeySpec) { case AT_KEYEXCHANGE: copy_handle(&handle_table, pKeyContainer->hKeyExchangeKeyPair, RSAENH_MAGIC_KEY, (unsigned int*)phUserKey); break; case AT_SIGNATURE: copy_handle(&handle_table, pKeyContainer->hSignatureKeyPair, RSAENH_MAGIC_KEY, (unsigned int*)phUserKey); break; default: *phUserKey = (HCRYPTKEY)INVALID_HANDLE_VALUE; } if (*phUserKey == (HCRYPTKEY)INVALID_HANDLE_VALUE) { /* MSDN: dwKeySpec parameter specifies non existent key */ SetLastError(NTE_NO_KEY); return FALSE; } return TRUE; } /****************************************************************************** * CPHashData (RSAENH.@) * * Updates a hash object with the given data. * * PARAMS * hProv [I] Key container to which the hash object belongs. * hHash [I] Hash object which is to be updated. * pbData [I] Pointer to data with which the hash object is to be updated. * dwDataLen [I] Length of the data. * dwFlags [I] Currently none defined. * * RETURNS * Success: TRUE. * Failure: FALSE. * * NOTES * The actual hash value is queried with CPGetHashParam, which will finalize * the hash. Updating a finalized hash will fail with a last error NTE_BAD_HASH_STATE. */ BOOL WINAPI RSAENH_CPHashData(HCRYPTPROV hProv, HCRYPTHASH hHash, CONST BYTE *pbData, DWORD dwDataLen, DWORD dwFlags) { CRYPTHASH *pCryptHash; TRACE("(hProv=%08lx, hHash=%08lx, pbData=%p, dwDataLen=%ld, dwFlags=%08lx)\n", hProv, hHash, pbData, dwDataLen, dwFlags); if (dwFlags) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (!lookup_handle(&handle_table, (unsigned int)hHash, RSAENH_MAGIC_HASH, (OBJECTHDR**)&pCryptHash)) { SetLastError(NTE_BAD_HASH); return FALSE; } if (!get_algid_info(hProv, pCryptHash->aiAlgid) || pCryptHash->aiAlgid == CALG_SSL3_SHAMD5) { SetLastError(NTE_BAD_ALGID); return FALSE; } if (pCryptHash->dwState == RSAENH_HASHSTATE_IDLE) pCryptHash->dwState = RSAENH_HASHSTATE_HASHING; if (pCryptHash->dwState != RSAENH_HASHSTATE_HASHING) { SetLastError(NTE_BAD_HASH_STATE); return FALSE; } update_hash(pCryptHash, pbData, dwDataLen); return TRUE; } /****************************************************************************** * CPHashSessionKey (RSAENH.@) * * Updates a hash object with the binary representation of a symmetric key. * * PARAMS * hProv [I] Key container to which the hash object belongs. * hHash [I] Hash object which is to be updated. * hKey [I] The symmetric key, whose binary value will be added to the hash. * dwFlags [I] CRYPT_LITTLE_ENDIAN, if the binary key value shall be interpreted as little endian. * * RETURNS * Success: TRUE. * Failure: FALSE. */ BOOL WINAPI RSAENH_CPHashSessionKey(HCRYPTPROV hProv, HCRYPTHASH hHash, HCRYPTKEY hKey, DWORD dwFlags) { BYTE abKeyValue[RSAENH_MAX_KEY_SIZE], bTemp; CRYPTKEY *pKey; DWORD i; TRACE("(hProv=%08lx, hHash=%08lx, hKey=%08lx, dwFlags=%08lx)\n", hProv, hHash, hKey, dwFlags); if (!lookup_handle(&handle_table, (unsigned int)hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pKey) || (GET_ALG_CLASS(pKey->aiAlgid) != ALG_CLASS_DATA_ENCRYPT)) { SetLastError(NTE_BAD_KEY); return FALSE; } if (dwFlags & ~CRYPT_LITTLE_ENDIAN) { SetLastError(NTE_BAD_FLAGS); return FALSE; } memcpy(abKeyValue, pKey->abKeyValue, pKey->dwKeyLen); if (!(dwFlags & CRYPT_LITTLE_ENDIAN)) { for (i=0; idwKeyLen/2; i++) { bTemp = abKeyValue[i]; abKeyValue[i] = abKeyValue[pKey->dwKeyLen-i-1]; abKeyValue[pKey->dwKeyLen-i-1] = bTemp; } } return RSAENH_CPHashData(hProv, hHash, abKeyValue, pKey->dwKeyLen, 0); } /****************************************************************************** * CPReleaseContext (RSAENH.@) * * Release a key container. * * PARAMS * hProv [I] Key container to be released. * dwFlags [I] Currently none defined. * * RETURNS * Success: TRUE * Failure: FALSE */ BOOL WINAPI RSAENH_CPReleaseContext(HCRYPTPROV hProv, DWORD dwFlags) { TRACE("(hProv=%08lx, dwFlags=%08lx)\n", hProv, dwFlags); if (!release_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER)) { /* MSDN: hProv not containing valid context handle */ SetLastError(NTE_BAD_UID); return FALSE; } if (dwFlags) { SetLastError(NTE_BAD_FLAGS); return FALSE; } return TRUE; } /****************************************************************************** * CPSetHashParam (RSAENH.@) * * Set a parameter of a hash object * * PARAMS * hProv [I] The key container to which the key belongs. * hHash [I] The hash object for which a parameter is to be set. * dwParam [I] Parameter type. See Notes. * pbData [I] Pointer to the parameter value. * dwFlags [I] Currently none defined. * * RETURNS * Success: TRUE. * Failure: FALSE. * * NOTES * Currently only the HP_HMAC_INFO dwParam type is defined. * The HMAC_INFO struct will be deep copied into the hash object. * See Internet RFC 2104 for details on the HMAC algorithm. */ BOOL WINAPI RSAENH_CPSetHashParam(HCRYPTPROV hProv, HCRYPTHASH hHash, DWORD dwParam, BYTE *pbData, DWORD dwFlags) { CRYPTHASH *pCryptHash; CRYPTKEY *pCryptKey; int i; TRACE("(hProv=%08lx, hHash=%08lx, dwParam=%08lx, pbData=%p, dwFlags=%08lx)\n", hProv, hHash, dwParam, pbData, dwFlags); if (!is_valid_handle(&handle_table, (unsigned int)hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (dwFlags) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (!lookup_handle(&handle_table, (unsigned int)hHash, RSAENH_MAGIC_HASH, (OBJECTHDR**)&pCryptHash)) { SetLastError(NTE_BAD_HASH); return FALSE; } switch (dwParam) { case HP_HMAC_INFO: free_hmac_info(pCryptHash->pHMACInfo); if (!copy_hmac_info(&pCryptHash->pHMACInfo, (PHMAC_INFO)pbData)) return FALSE; if (!lookup_handle(&handle_table, pCryptHash->hKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pCryptKey)) { SetLastError(NTE_FAIL); /* FIXME: correct error code? */ return FALSE; } for (i=0; idwKeyLen,pCryptHash->pHMACInfo->cbInnerString); i++) { pCryptHash->pHMACInfo->pbInnerString[i] ^= pCryptKey->abKeyValue[i]; } for (i=0; idwKeyLen,pCryptHash->pHMACInfo->cbOuterString); i++) { pCryptHash->pHMACInfo->pbOuterString[i] ^= pCryptKey->abKeyValue[i]; } init_hash(pCryptHash); return TRUE; case HP_HASHVAL: memcpy(pCryptHash->abHashValue, pbData, pCryptHash->dwHashSize); pCryptHash->dwState = RSAENH_HASHSTATE_FINISHED; return TRUE; case HP_TLS1PRF_SEED: return copy_data_blob(&pCryptHash->tpPRFParams.blobSeed, (PCRYPT_DATA_BLOB)pbData); case HP_TLS1PRF_LABEL: return copy_data_blob(&pCryptHash->tpPRFParams.blobLabel, (PCRYPT_DATA_BLOB)pbData); default: SetLastError(NTE_BAD_TYPE); return FALSE; } } /****************************************************************************** * CPSetProvParam (RSAENH.@) */ BOOL WINAPI RSAENH_CPSetProvParam(HCRYPTPROV hProv, DWORD dwParam, BYTE *pbData, DWORD dwFlags) { FIXME("(stub)\n"); return FALSE; } /****************************************************************************** * CPSignHash (RSAENH.@) * * Sign a hash object * * PARAMS * hProv [I] The key container, to which the hash object belongs. * hHash [I] The hash object to be signed. * dwKeySpec [I] AT_SIGNATURE or AT_KEYEXCHANGE: Key used to generate the signature. * sDescription [I] Should be NULL for security reasons. * dwFlags [I] 0, CRYPT_NOHASHOID or CRYPT_X931_FORMAT: Format of the signature. * pbSignature [O] Buffer, to which the signature will be stored. May be NULL to query SigLen. * pdwSigLen [I/O] Size of the buffer (in), Length of the signature (out) * * RETURNS * Success: TRUE * Failure: FALSE */ BOOL WINAPI RSAENH_CPSignHash(HCRYPTPROV hProv, HCRYPTHASH hHash, DWORD dwKeySpec, LPCWSTR sDescription, DWORD dwFlags, BYTE *pbSignature, DWORD *pdwSigLen) { HCRYPTKEY hCryptKey; CRYPTKEY *pCryptKey; DWORD dwHashLen; BYTE abHashValue[RSAENH_MAX_HASH_SIZE]; ALG_ID aiAlgid; TRACE("(hProv=%08lx, hHash=%08lx, dwKeySpec=%08lx, sDescription=%s, dwFlags=%08lx, " "pbSignature=%p, pdwSigLen=%p)\n", hProv, hHash, dwKeySpec, debugstr_w(sDescription), dwFlags, pbSignature, pdwSigLen); if (dwFlags & ~(CRYPT_NOHASHOID|CRYPT_X931_FORMAT)) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (!RSAENH_CPGetUserKey(hProv, dwKeySpec, &hCryptKey)) return FALSE; if (!lookup_handle(&handle_table, (unsigned int)hCryptKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pCryptKey)) { SetLastError(NTE_NO_KEY); return FALSE; } if (!pbSignature) { *pdwSigLen = pCryptKey->dwKeyLen; return TRUE; } if (pCryptKey->dwKeyLen > *pdwSigLen) { SetLastError(ERROR_MORE_DATA); *pdwSigLen = pCryptKey->dwKeyLen; return FALSE; } *pdwSigLen = pCryptKey->dwKeyLen; if (sDescription) { if (!RSAENH_CPHashData(hProv, hHash, (CONST BYTE*)sDescription, (DWORD)lstrlenW(sDescription)*sizeof(WCHAR), 0)) { return FALSE; } } dwHashLen = sizeof(DWORD); if (!RSAENH_CPGetHashParam(hProv, hHash, HP_ALGID, (BYTE*)&aiAlgid, &dwHashLen, 0)) return FALSE; dwHashLen = RSAENH_MAX_HASH_SIZE; if (!RSAENH_CPGetHashParam(hProv, hHash, HP_HASHVAL, abHashValue, &dwHashLen, 0)) return FALSE; if (!build_hash_signature(pbSignature, *pdwSigLen, aiAlgid, abHashValue, dwHashLen, dwFlags)) { return FALSE; } return encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, pbSignature, pbSignature, RSAENH_ENCRYPT); } /****************************************************************************** * CPVerifySignature (RSAENH.@) * * Verify the signature of a hash object. * * PARAMS * hProv [I] The key container, to which the hash belongs. * hHash [I] The hash for which the signature is verified. * pbSignature [I] The binary signature. * dwSigLen [I] Length of the signature BLOB. * hPubKey [I] Public key used to verify the signature. * sDescription [I] Should be NULL for security reasons. * dwFlags [I] 0, CRYPT_NOHASHOID or CRYPT_X931_FORMAT: Format of the signature. * * RETURNS * Success: TRUE (Signature is valid) * Failure: FALSE (GetLastError() == NTE_BAD_SIGNATURE, if signature is invalid) */ BOOL WINAPI RSAENH_CPVerifySignature(HCRYPTPROV hProv, HCRYPTHASH hHash, CONST BYTE *pbSignature, DWORD dwSigLen, HCRYPTKEY hPubKey, LPCWSTR sDescription, DWORD dwFlags) { BYTE *pbConstructed = NULL, *pbDecrypted = NULL; CRYPTKEY *pCryptKey; DWORD dwHashLen; ALG_ID aiAlgid; BYTE abHashValue[RSAENH_MAX_HASH_SIZE]; BOOL res = FALSE; TRACE("(hProv=%08lx, hHash=%08lx, pbSignature=%p, dwSigLen=%ld, hPubKey=%08lx, sDescription=%s, " "dwFlags=%08lx)\n", hProv, hHash, pbSignature, dwSigLen, hPubKey, debugstr_w(sDescription), dwFlags); if (dwFlags & ~(CRYPT_NOHASHOID|CRYPT_X931_FORMAT)) { SetLastError(NTE_BAD_FLAGS); return FALSE; } if (!is_valid_handle(&handle_table, hProv, RSAENH_MAGIC_CONTAINER)) { SetLastError(NTE_BAD_UID); return FALSE; } if (!lookup_handle(&handle_table, (unsigned int)hPubKey, RSAENH_MAGIC_KEY, (OBJECTHDR**)&pCryptKey)) { SetLastError(NTE_BAD_KEY); return FALSE; } if (sDescription) { if (!RSAENH_CPHashData(hProv, hHash, (CONST BYTE*)sDescription, (DWORD)lstrlenW(sDescription)*sizeof(WCHAR), 0)) { return FALSE; } } dwHashLen = sizeof(DWORD); if (!RSAENH_CPGetHashParam(hProv, hHash, HP_ALGID, (BYTE*)&aiAlgid, &dwHashLen, 0)) return FALSE; dwHashLen = RSAENH_MAX_HASH_SIZE; if (!RSAENH_CPGetHashParam(hProv, hHash, HP_HASHVAL, abHashValue, &dwHashLen, 0)) return FALSE; pbConstructed = HeapAlloc(GetProcessHeap(), 0, dwSigLen); if (!pbConstructed) { SetLastError(NTE_NO_MEMORY); goto cleanup; } pbDecrypted = HeapAlloc(GetProcessHeap(), 0, dwSigLen); if (!pbDecrypted) { SetLastError(NTE_NO_MEMORY); goto cleanup; } if (!encrypt_block_impl(pCryptKey->aiAlgid, &pCryptKey->context, pbSignature, pbDecrypted, RSAENH_DECRYPT)) { goto cleanup; } if (!build_hash_signature(pbConstructed, dwSigLen, aiAlgid, abHashValue, dwHashLen, dwFlags)) { goto cleanup; } if (memcmp(pbDecrypted, pbConstructed, dwSigLen)) { SetLastError(NTE_BAD_SIGNATURE); goto cleanup; } res = TRUE; cleanup: HeapFree(GetProcessHeap(), 0, pbConstructed); HeapFree(GetProcessHeap(), 0, pbDecrypted); return res; } static const WCHAR szProviderKeys[4][97] = { { 'S','o','f','t','w','a','r','e','\\', 'M','i','c','r','o','s','o','f','t','\\','C','r','y','p','t','o','g','r', 'a','p','h','y','\\','D','e','f','a','u','l','t','s','\\','P','r','o','v', 'i','d','e','r','\\','M','i','c','r','o','s','o','f','t',' ','B','a','s', 'e',' ','C','r','y','p','t','o','g','r','a','p','h','i','c',' ','P','r', 'o','v','i','d','e','r',' ','v','1','.','0',0 }, { 'S','o','f','t','w','a','r','e','\\', 'M','i','c','r','o','s','o','f','t','\\','C','r','y','p','t','o','g','r', 'a','p','h','y','\\','D','e','f','a','u','l','t','s','\\','P','r','o','v', 'i','d','e','r','\\','M','i','c','r','o','s','o','f','t',' ', 'E','n','h','a','n','c','e','d', ' ','C','r','y','p','t','o','g','r','a','p','h','i','c',' ','P','r', 'o','v','i','d','e','r',' ','v','1','.','0',0 }, { 'S','o','f','t','w','a','r','e','\\', 'M','i','c','r','o','s','o','f','t','\\','C','r','y','p','t','o','g','r', 'a','p','h','y','\\','D','e','f','a','u','l','t','s','\\','P','r','o','v', 'i','d','e','r','\\','M','i','c','r','o','s','o','f','t',' ','S','t','r','o','n','g', ' ','C','r','y','p','t','o','g','r','a','p','h','i','c',' ','P','r', 'o','v','i','d','e','r',0 }, { 'S','o','f','t','w','a','r','e','\\','M','i','c','r','o','s','o','f','t','\\', 'C','r','y','p','t','o','g','r','a','p','h','y','\\','D','e','f','a','u','l','t','s','\\', 'P','r','o','v','i','d','e','r','\\','M','i','c','r','o','s','o','f','t',' ', 'R','S','A',' ','S','C','h','a','n','n','e','l',' ', 'C','r','y','p','t','o','g','r','a','p','h','i','c',' ','P','r','o','v','i','d','e','r',0 } }; static const WCHAR szDefaultKeys[2][65] = { { 'S','o','f','t','w','a','r','e','\\', 'M','i','c','r','o','s','o','f','t','\\','C','r','y','p','t','o','g','r', 'a','p','h','y','\\','D','e','f','a','u','l','t','s','\\','P','r','o','v', 'i','d','e','r',' ','T','y','p','e','s','\\','T','y','p','e',' ','0','0','1',0 }, { 'S','o','f','t','w','a','r','e','\\', 'M','i','c','r','o','s','o','f','t','\\','C','r','y','p','t','o','g','r', 'a','p','h','y','\\','D','e','f','a','u','l','t','s','\\','P','r','o','v', 'i','d','e','r',' ','T','y','p','e','s','\\','T','y','p','e',' ','0','1','2',0 } }; /****************************************************************************** * DllRegisterServer (RSAENH.@) * * Dll self registration. * * PARAMS * * RETURNS * Success: S_OK. * Failure: != S_OK * * NOTES * Registers the following keys: * - HKLM\Software\Microsoft\Cryptography\Defaults\Provider\ * Microsoft Base Cryptographic Provider v1.0 * - HKLM\Software\Microsoft\Cryptography\Defaults\Provider\ * Microsoft Enhanced Cryptographic Provider * - HKLM\Software\Microsoft\Cryptography\Defaults\Provider\ * Microsoft Strong Cryptographpic Provider * - HKLM\Software\Microsoft\Cryptography\Defaults\Provider Types\Type 001 */ HRESULT WINAPI RSAENH_DllRegisterServer() { HKEY key; DWORD dp; long apiRet; int i; for (i=0; i<4; i++) { apiRet = RegCreateKeyExW(HKEY_LOCAL_MACHINE, szProviderKeys[i], 0, NULL, REG_OPTION_NON_VOLATILE, KEY_ALL_ACCESS, NULL, &key, &dp); if (apiRet == ERROR_SUCCESS) { if (dp == REG_CREATED_NEW_KEY) { static const WCHAR szImagePath[] = { 'I','m','a','g','e',' ','P','a','t','h',0 }; static const WCHAR szRSABase[] = { 'r','s','a','e','n','h','.','d','l','l',0 }; static const WCHAR szType[] = { 'T','y','p','e',0 }; static const WCHAR szSignature[] = { 'S','i','g','n','a','t','u','r','e',0 }; DWORD type = (i == 3) ? PROV_RSA_SCHANNEL : PROV_RSA_FULL; DWORD sign = 0xdeadbeef; RegSetValueExW(key, szImagePath, 0, REG_SZ, (LPBYTE)szRSABase, (lstrlenW(szRSABase) + 1) * sizeof(WCHAR)); RegSetValueExW(key, szType, 0, REG_DWORD, (LPBYTE)&type, sizeof(type)); RegSetValueExW(key, szSignature, 0, REG_BINARY, (LPBYTE)&sign, sizeof(sign)); } RegCloseKey(key); } } for (i=0; i<2; i++) { apiRet = RegCreateKeyExW(HKEY_LOCAL_MACHINE, szDefaultKeys[i], 0, NULL, REG_OPTION_NON_VOLATILE, KEY_ALL_ACCESS, NULL, &key, &dp); if (apiRet == ERROR_SUCCESS) { if (dp == REG_CREATED_NEW_KEY) { static const WCHAR szName[] = { 'N','a','m','e',0 }; static const WCHAR szRSAName[2][46] = { { 'M','i','c','r','o','s','o','f','t',' ', 'B','a','s','e',' ', 'C','r','y','p','t','o','g','r','a','p','h','i','c',' ', 'P','r','o','v','i','d','e','r',' ','v','1','.','0',0 }, { 'M','i','c','r','o','s','o','f','t',' ','R','S','A',' ', 'S','C','h','a','n','n','e','l',' ', 'C','r','y','p','t','o','g','r','a','p','h','i','c',' ', 'P','r','o','v','i','d','e','r',0 } }; static const WCHAR szTypeName[] = { 'T','y','p','e','N','a','m','e',0 }; static const WCHAR szRSATypeName[2][38] = { { 'R','S','A',' ','F','u','l','l',' ', '(','S','i','g','n','a','t','u','r','e',' ','a','n','d',' ', 'K','e','y',' ','E','x','c','h','a','n','g','e',')',0 }, { 'R','S','A',' ','S','C','h','a','n','n','e','l',0 } }; RegSetValueExW(key, szName, 0, REG_SZ, (LPBYTE)szRSAName[i], sizeof(szRSAName)); RegSetValueExW(key, szTypeName, 0, REG_SZ, (LPBYTE)szRSATypeName[i],sizeof(szRSATypeName)); } } RegCloseKey(key); } return HRESULT_FROM_WIN32(apiRet); } /****************************************************************************** * DllUnregisterServer (RSAENH.@) * * Dll self unregistration. * * PARAMS * * RETURNS * Success: S_OK * * NOTES * For the relevant keys see DllRegisterServer. */ HRESULT WINAPI RSAENH_DllUnregisterServer() { RegDeleteKeyW(HKEY_LOCAL_MACHINE, szProviderKeys[0]); RegDeleteKeyW(HKEY_LOCAL_MACHINE, szProviderKeys[1]); RegDeleteKeyW(HKEY_LOCAL_MACHINE, szProviderKeys[2]); RegDeleteKeyW(HKEY_LOCAL_MACHINE, szProviderKeys[3]); RegDeleteKeyW(HKEY_LOCAL_MACHINE, szDefaultKeys[0]); RegDeleteKeyW(HKEY_LOCAL_MACHINE, szDefaultKeys[1]); return S_OK; }