/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "plarena.h" #include "seccomon.h" #include "secitem.h" #include "secport.h" #include "hasht.h" #include "pkcs11t.h" #include "blapi.h" #include "hasht.h" #include "secasn1.h" #include "secder.h" #include "lowpbe.h" #include "secoid.h" #include "alghmac.h" #include "softoken.h" #include "secerr.h" SEC_ASN1_MKSUB(SECOID_AlgorithmIDTemplate) /* template for PKCS 5 PBE Parameter. This template has been expanded * based upon the additions in PKCS 12. This should eventually be moved * if RSA updates PKCS 5. */ static const SEC_ASN1Template NSSPKCS5PBEParameterTemplate[] = { { SEC_ASN1_SEQUENCE, 0, NULL, sizeof(NSSPKCS5PBEParameter) }, { SEC_ASN1_OCTET_STRING, offsetof(NSSPKCS5PBEParameter, salt) }, { SEC_ASN1_INTEGER, offsetof(NSSPKCS5PBEParameter, iteration) }, { 0 } }; static const SEC_ASN1Template NSSPKCS5PKCS12V2PBEParameterTemplate[] = { { SEC_ASN1_SEQUENCE, 0, NULL, sizeof(NSSPKCS5PBEParameter) }, { SEC_ASN1_OCTET_STRING, offsetof(NSSPKCS5PBEParameter, salt) }, { SEC_ASN1_INTEGER, offsetof(NSSPKCS5PBEParameter, iteration) }, { 0 } }; /* PKCS5 v2 */ struct nsspkcs5V2PBEParameterStr { SECAlgorithmID keyParams; /* parameters of the key generation */ SECAlgorithmID algParams; /* parameters for the encryption or mac op */ }; typedef struct nsspkcs5V2PBEParameterStr nsspkcs5V2PBEParameter; #define PBKDF2 #ifdef PBKDF2 static const SEC_ASN1Template NSSPKCS5V2PBES2ParameterTemplate[] = { { SEC_ASN1_SEQUENCE, 0, NULL, sizeof(nsspkcs5V2PBEParameter) }, { SEC_ASN1_INLINE | SEC_ASN1_XTRN, offsetof(nsspkcs5V2PBEParameter, keyParams), SEC_ASN1_SUB(SECOID_AlgorithmIDTemplate) }, { SEC_ASN1_INLINE | SEC_ASN1_XTRN, offsetof(nsspkcs5V2PBEParameter, algParams), SEC_ASN1_SUB(SECOID_AlgorithmIDTemplate) }, { 0 } }; static const SEC_ASN1Template NSSPKCS5V2PBEParameterTemplate[] = { { SEC_ASN1_SEQUENCE, 0, NULL, sizeof(NSSPKCS5PBEParameter) }, /* this is really a choice, but since we don't understand any other *choice, just inline it. */ { SEC_ASN1_OCTET_STRING, offsetof(NSSPKCS5PBEParameter, salt) }, { SEC_ASN1_INTEGER, offsetof(NSSPKCS5PBEParameter, iteration) }, { SEC_ASN1_INTEGER, offsetof(NSSPKCS5PBEParameter, keyLength) }, { SEC_ASN1_INLINE | SEC_ASN1_XTRN, offsetof(NSSPKCS5PBEParameter, prfAlg), SEC_ASN1_SUB(SECOID_AlgorithmIDTemplate) }, { 0 } }; #endif SECStatus nsspkcs5_HashBuf(const SECHashObject *hashObj, unsigned char *dest, unsigned char *src, int len) { void *ctx; unsigned int retLen; ctx = hashObj->create(); if(ctx == NULL) { return SECFailure; } hashObj->begin(ctx); hashObj->update(ctx, src, len); hashObj->end(ctx, dest, &retLen, hashObj->length); hashObj->destroy(ctx, PR_TRUE); return SECSuccess; } /* generate bits using any hash */ static SECItem * nsspkcs5_PBKDF1(const SECHashObject *hashObj, SECItem *salt, SECItem *pwd, int iter, PRBool faulty3DES) { SECItem *hash = NULL, *pre_hash = NULL; SECStatus rv = SECFailure; if((salt == NULL) || (pwd == NULL) || (iter < 0)) { return NULL; } hash = (SECItem *)PORT_ZAlloc(sizeof(SECItem)); pre_hash = (SECItem *)PORT_ZAlloc(sizeof(SECItem)); if((hash != NULL) && (pre_hash != NULL)) { int i, ph_len; ph_len = hashObj->length; if((salt->len + pwd->len) > hashObj->length) { ph_len = salt->len + pwd->len; } rv = SECFailure; /* allocate buffers */ hash->len = hashObj->length; hash->data = (unsigned char *)PORT_ZAlloc(hash->len); pre_hash->data = (unsigned char *)PORT_ZAlloc(ph_len); /* in pbeSHA1TripleDESCBC there was an allocation error that made * it into the caller. We do not want to propagate those errors * further, so we are doing it correctly, but reading the old method. */ if (faulty3DES) { pre_hash->len = ph_len; } else { pre_hash->len = salt->len + pwd->len; } /* preform hash */ if ((hash->data != NULL) && (pre_hash->data != NULL)) { rv = SECSuccess; /* check for 0 length password */ if(pwd->len > 0) { PORT_Memcpy(pre_hash->data, pwd->data, pwd->len); } if(salt->len > 0) { PORT_Memcpy((pre_hash->data+pwd->len), salt->data, salt->len); } for(i = 0; ((i < iter) && (rv == SECSuccess)); i++) { rv = nsspkcs5_HashBuf(hashObj, hash->data, pre_hash->data, pre_hash->len); if(rv != SECFailure) { pre_hash->len = hashObj->length; PORT_Memcpy(pre_hash->data, hash->data, hashObj->length); } } } } if(pre_hash != NULL) { SECITEM_FreeItem(pre_hash, PR_TRUE); } if((rv != SECSuccess) && (hash != NULL)) { SECITEM_FreeItem(hash, PR_TRUE); hash = NULL; } return hash; } /* this bit generation routine is described in PKCS 12 and the proposed * extensions to PKCS 5. an initial hash is generated following the * instructions laid out in PKCS 5. If the number of bits generated is * insufficient, then the method discussed in the proposed extensions to * PKCS 5 in PKCS 12 are used. This extension makes use of the HMAC * function. And the P_Hash function from the TLS standard. */ static SECItem * nsspkcs5_PFXPBE(const SECHashObject *hashObj, NSSPKCS5PBEParameter *pbe_param, SECItem *init_hash, unsigned int bytes_needed) { SECItem *ret_bits = NULL; int hash_size = 0; unsigned int i; unsigned int hash_iter; unsigned int dig_len; SECStatus rv = SECFailure; unsigned char *state = NULL; unsigned int state_len; HMACContext *cx = NULL; hash_size = hashObj->length; hash_iter = (bytes_needed + (unsigned int)hash_size - 1) / hash_size; /* allocate return buffer */ ret_bits = (SECItem *)PORT_ZAlloc(sizeof(SECItem)); if(ret_bits == NULL) return NULL; ret_bits->data = (unsigned char *)PORT_ZAlloc((hash_iter * hash_size) + 1); ret_bits->len = (hash_iter * hash_size); if(ret_bits->data == NULL) { PORT_Free(ret_bits); return NULL; } /* allocate intermediate hash buffer. 8 is for the 8 bytes of * data which are added based on iteration number */ if ((unsigned int)hash_size > pbe_param->salt.len) { state_len = hash_size; } else { state_len = pbe_param->salt.len; } state = (unsigned char *)PORT_ZAlloc(state_len); if(state == NULL) { rv = SECFailure; goto loser; } if(pbe_param->salt.len > 0) { PORT_Memcpy(state, pbe_param->salt.data, pbe_param->salt.len); } cx = HMAC_Create(hashObj, init_hash->data, init_hash->len, PR_TRUE); if (cx == NULL) { rv = SECFailure; goto loser; } for(i = 0; i < hash_iter; i++) { /* generate output bits */ HMAC_Begin(cx); HMAC_Update(cx, state, state_len); HMAC_Update(cx, pbe_param->salt.data, pbe_param->salt.len); rv = HMAC_Finish(cx, ret_bits->data + (i * hash_size), &dig_len, hash_size); if (rv != SECSuccess) goto loser; PORT_Assert((unsigned int)hash_size == dig_len); /* generate new state */ HMAC_Begin(cx); HMAC_Update(cx, state, state_len); rv = HMAC_Finish(cx, state, &state_len, state_len); if (rv != SECSuccess) goto loser; PORT_Assert(state_len == dig_len); } loser: if (state != NULL) PORT_ZFree(state, state_len); HMAC_Destroy(cx, PR_TRUE); if(rv != SECSuccess) { SECITEM_ZfreeItem(ret_bits, PR_TRUE); ret_bits = NULL; } return ret_bits; } /* generate bits for the key and iv determination. if enough bits * are not generated using PKCS 5, then we need to generate more bits * based on the extension proposed in PKCS 12 */ static SECItem * nsspkcs5_PBKDF1Extended(const SECHashObject *hashObj, NSSPKCS5PBEParameter *pbe_param, SECItem *pwitem, PRBool faulty3DES) { SECItem * hash = NULL; SECItem * newHash = NULL; int bytes_needed; int bytes_available; bytes_needed = pbe_param->ivLen + pbe_param->keyLen; bytes_available = hashObj->length; hash = nsspkcs5_PBKDF1(hashObj, &pbe_param->salt, pwitem, pbe_param->iter, faulty3DES); if(hash == NULL) { return NULL; } if(bytes_needed <= bytes_available) { return hash; } newHash = nsspkcs5_PFXPBE(hashObj, pbe_param, hash, bytes_needed); if (hash != newHash) SECITEM_FreeItem(hash, PR_TRUE); return newHash; } #ifdef PBKDF2 /* * PBDKDF2 is PKCS #5 v2.0 it's currently not used by NSS */ static void do_xor(unsigned char *dest, unsigned char *src, int len) { /* use byt xor, not all platforms are happy about inaligned * integer fetches */ while (len--) { *dest = *dest ^ *src; dest++; src++; } } static SECStatus nsspkcs5_PBKDF2_F(const SECHashObject *hashobj, SECItem *pwitem, SECItem *salt, int iterations, unsigned int i, unsigned char *T) { int j; HMACContext *cx = NULL; unsigned int hLen = hashobj->length; SECStatus rv = SECFailure; unsigned char *last = NULL; unsigned int lastLength = salt->len + 4; unsigned int lastBufLength; cx=HMAC_Create(hashobj,pwitem->data,pwitem->len,PR_FALSE); if (cx == NULL) { goto loser; } PORT_Memset(T,0,hLen); lastBufLength = PR_MAX(lastLength, hLen); last = PORT_Alloc(lastBufLength); if (last == NULL) { goto loser; } PORT_Memcpy(last,salt->data,salt->len); last[salt->len ] = (i >> 24) & 0xff; last[salt->len+1] = (i >> 16) & 0xff; last[salt->len+2] = (i >> 8) & 0xff; last[salt->len+3] = i & 0xff; /* NOTE: we need at least one iteration to return success! */ for (j=0; j < iterations; j++) { HMAC_Begin(cx); HMAC_Update(cx,last,lastLength); rv =HMAC_Finish(cx,last,&lastLength,hLen); if (rv !=SECSuccess) { break; } do_xor(T,last,hLen); } loser: if (cx) { HMAC_Destroy(cx, PR_TRUE); } if (last) { PORT_ZFree(last,lastBufLength); } return rv; } static SECItem * nsspkcs5_PBKDF2(const SECHashObject *hashobj, NSSPKCS5PBEParameter *pbe_param, SECItem *pwitem) { int iterations = pbe_param->iter; int bytesNeeded = pbe_param->keyLen; unsigned int dkLen = bytesNeeded; unsigned int hLen = hashobj->length; unsigned int nblocks = (dkLen+hLen-1) / hLen; unsigned int i; unsigned char *rp; unsigned char *T = NULL; SECItem *result = NULL; SECItem *salt = &pbe_param->salt; SECStatus rv = SECFailure; result = SECITEM_AllocItem(NULL,NULL,nblocks*hLen); if (result == NULL) { return NULL; } T = PORT_Alloc(hLen); if (T == NULL) { goto loser; } for (i=1,rp=result->data; i <= nblocks ; i++, rp +=hLen) { rv = nsspkcs5_PBKDF2_F(hashobj, pwitem, salt, iterations, i, T); if (rv != SECSuccess) { break; } PORT_Memcpy(rp,T,hLen); } loser: if (T) { PORT_ZFree(T,hLen); } if (rv != SECSuccess) { SECITEM_FreeItem(result,PR_TRUE); result = NULL; } else { result->len = dkLen; } return result; } #endif #define HMAC_BUFFER 64 #define NSSPBE_ROUNDUP(x,y) ((((x)+((y)-1))/(y))*(y)) #define NSSPBE_MIN(x,y) ((x) < (y) ? (x) : (y)) /* * This is the extended PBE function defined by the final PKCS #12 spec. */ static SECItem * nsspkcs5_PKCS12PBE(const SECHashObject *hashObject, NSSPKCS5PBEParameter *pbe_param, SECItem *pwitem, PBEBitGenID bitGenPurpose, unsigned int bytesNeeded) { PLArenaPool *arena = NULL; unsigned int SLen,PLen; unsigned int hashLength = hashObject->length; unsigned char *S, *P; SECItem *A = NULL, B, D, I; SECItem *salt = &pbe_param->salt; unsigned int c,i = 0; unsigned int hashLen; int iter; unsigned char *iterBuf; void *hash = NULL; arena = PORT_NewArena(DER_DEFAULT_CHUNKSIZE); if(!arena) { return NULL; } /* how many hash object lengths are needed */ c = (bytesNeeded + (hashLength-1))/hashLength; /* initialize our buffers */ D.len = HMAC_BUFFER; /* B and D are the same length, use one alloc go get both */ D.data = (unsigned char*)PORT_ArenaZAlloc(arena, D.len*2); B.len = D.len; B.data = D.data + D.len; /* if all goes well, A will be returned, so don't use our temp arena */ A = SECITEM_AllocItem(NULL,NULL,c*hashLength); if (A == NULL) { goto loser; } SLen = NSSPBE_ROUNDUP(salt->len,HMAC_BUFFER); PLen = NSSPBE_ROUNDUP(pwitem->len,HMAC_BUFFER); I.len = SLen+PLen; I.data = (unsigned char*)PORT_ArenaZAlloc(arena, I.len); if (I.data == NULL) { goto loser; } /* S & P are only used to initialize I */ S = I.data; P = S + SLen; PORT_Memset(D.data, (char)bitGenPurpose, D.len); if (SLen) { for (i=0; i < SLen; i += salt->len) { PORT_Memcpy(S+i, salt->data, NSSPBE_MIN(SLen-i,salt->len)); } } if (PLen) { for (i=0; i < PLen; i += pwitem->len) { PORT_Memcpy(P+i, pwitem->data, NSSPBE_MIN(PLen-i,pwitem->len)); } } iterBuf = (unsigned char*)PORT_ArenaZAlloc(arena,hashLength); if (iterBuf == NULL) { goto loser; } hash = hashObject->create(); if(!hash) { goto loser; } /* calculate the PBE now */ for(i = 0; i < c; i++) { int Bidx; /* must be signed or the for loop won't terminate */ unsigned int k, j; unsigned char *Ai = A->data+i*hashLength; for(iter = 0; iter < pbe_param->iter; iter++) { hashObject->begin(hash); if (iter) { hashObject->update(hash, iterBuf, hashLen); } else { hashObject->update(hash, D.data, D.len); hashObject->update(hash, I.data, I.len); } hashObject->end(hash, iterBuf, &hashLen, hashObject->length); if(hashLen != hashObject->length) { break; } } PORT_Memcpy(Ai, iterBuf, hashLength); for (Bidx = 0; Bidx < (int)B.len; Bidx += hashLength) { PORT_Memcpy(B.data+Bidx,iterBuf,NSSPBE_MIN(B.len-Bidx,hashLength)); } k = I.len/B.len; for(j = 0; j < k; j++) { unsigned int q, carryBit; unsigned char *Ij = I.data + j*B.len; /* (Ij = Ij+B+1) */ for (Bidx = (B.len-1), q=1, carryBit=0; Bidx >= 0; Bidx--,q=0) { q += (unsigned int)Ij[Bidx]; q += (unsigned int)B.data[Bidx]; q += carryBit; carryBit = (q > 0xff); Ij[Bidx] = (unsigned char)(q & 0xff); } } } loser: if (hash) { hashObject->destroy(hash, PR_TRUE); } if(arena) { PORT_FreeArena(arena, PR_TRUE); } if (A) { /* if i != c, then we didn't complete the loop above and must of failed * somwhere along the way */ if (i != c) { SECITEM_ZfreeItem(A,PR_TRUE); A = NULL; } else { A->len = bytesNeeded; } } return A; } /* * generate key as per PKCS 5 */ SECItem * nsspkcs5_ComputeKeyAndIV(NSSPKCS5PBEParameter *pbe_param, SECItem *pwitem, SECItem *iv, PRBool faulty3DES) { SECItem *hash = NULL, *key = NULL; const SECHashObject *hashObj; PRBool getIV = PR_FALSE; if((pbe_param == NULL) || (pwitem == NULL)) { return NULL; } key = SECITEM_AllocItem(NULL,NULL,pbe_param->keyLen); if (key == NULL) { return NULL; } if (iv && (pbe_param->ivLen) && (iv->data == NULL)) { getIV = PR_TRUE; iv->data = (unsigned char *)PORT_Alloc(pbe_param->ivLen); if (iv->data == NULL) { goto loser; } iv->len = pbe_param->ivLen; } hashObj = HASH_GetRawHashObject(pbe_param->hashType); switch (pbe_param->pbeType) { case NSSPKCS5_PBKDF1: hash = nsspkcs5_PBKDF1Extended(hashObj,pbe_param,pwitem,faulty3DES); if (hash == NULL) { goto loser; } PORT_Assert(hash->len >= key->len+(getIV ? iv->len : 0)); if (getIV) { PORT_Memcpy(iv->data, hash->data+(hash->len - iv->len),iv->len); } break; #ifdef PBKDF2 case NSSPKCS5_PBKDF2: hash = nsspkcs5_PBKDF2(hashObj,pbe_param,pwitem); if (getIV) { PORT_Memcpy(iv->data, pbe_param->ivData, iv->len); } break; #endif case NSSPKCS5_PKCS12_V2: if (getIV) { hash = nsspkcs5_PKCS12PBE(hashObj,pbe_param,pwitem, pbeBitGenCipherIV,iv->len); if (hash == NULL) { goto loser; } PORT_Memcpy(iv->data,hash->data,iv->len); SECITEM_ZfreeItem(hash,PR_TRUE); hash = NULL; } hash = nsspkcs5_PKCS12PBE(hashObj,pbe_param,pwitem, pbe_param->keyID,key->len); default: break; } if (hash == NULL) { goto loser; } if (pbe_param->is2KeyDES) { PORT_Memcpy(key->data, hash->data, (key->len * 2) / 3); PORT_Memcpy(&(key->data[(key->len * 2) / 3]), key->data, key->len / 3); } else { PORT_Memcpy(key->data, hash->data, key->len); } SECITEM_ZfreeItem(hash, PR_TRUE); return key; loser: if (getIV && iv->data) { PORT_ZFree(iv->data,iv->len); iv->data = NULL; } SECITEM_ZfreeItem(key, PR_TRUE); return NULL; } static SECStatus nsspkcs5_FillInParam(SECOidTag algorithm, NSSPKCS5PBEParameter *pbe_param) { PRBool skipType = PR_FALSE; pbe_param->keyLen = 5; pbe_param->ivLen = 8; pbe_param->hashType = HASH_AlgSHA1; pbe_param->pbeType = NSSPKCS5_PBKDF1; pbe_param->encAlg = SEC_OID_RC2_CBC; pbe_param->is2KeyDES = PR_FALSE; switch(algorithm) { /* DES3 Algorithms */ case SEC_OID_PKCS12_V2_PBE_WITH_SHA1_AND_2KEY_TRIPLE_DES_CBC: pbe_param->is2KeyDES = PR_TRUE; /* fall through */ case SEC_OID_PKCS12_V2_PBE_WITH_SHA1_AND_3KEY_TRIPLE_DES_CBC: pbe_param->pbeType = NSSPKCS5_PKCS12_V2; /* fall through */ case SEC_OID_PKCS12_PBE_WITH_SHA1_AND_TRIPLE_DES_CBC: pbe_param->keyLen = 24; pbe_param->encAlg = SEC_OID_DES_EDE3_CBC; break; /* DES Algorithms */ case SEC_OID_PKCS5_PBE_WITH_MD2_AND_DES_CBC: pbe_param->hashType = HASH_AlgMD2; goto finish_des; case SEC_OID_PKCS5_PBE_WITH_MD5_AND_DES_CBC: pbe_param->hashType = HASH_AlgMD5; /* fall through */ case SEC_OID_PKCS5_PBE_WITH_SHA1_AND_DES_CBC: finish_des: pbe_param->keyLen = 8; pbe_param->encAlg = SEC_OID_DES_CBC; break; /* RC2 Algorithms */ case SEC_OID_PKCS12_V2_PBE_WITH_SHA1_AND_128_BIT_RC2_CBC: pbe_param->keyLen = 16; /* fall through */ case SEC_OID_PKCS12_V2_PBE_WITH_SHA1_AND_40_BIT_RC2_CBC: pbe_param->pbeType = NSSPKCS5_PKCS12_V2; break; case SEC_OID_PKCS12_PBE_WITH_SHA1_AND_128_BIT_RC2_CBC: pbe_param->keyLen = 16; /* fall through */ case SEC_OID_PKCS12_PBE_WITH_SHA1_AND_40_BIT_RC2_CBC: break; /* RC4 algorithms */ case SEC_OID_PKCS12_PBE_WITH_SHA1_AND_128_BIT_RC4: skipType = PR_TRUE; /* fall through */ case SEC_OID_PKCS12_V2_PBE_WITH_SHA1_AND_128_BIT_RC4: pbe_param->keyLen = 16; /* fall through */ case SEC_OID_PKCS12_V2_PBE_WITH_SHA1_AND_40_BIT_RC4: if (!skipType) { pbe_param->pbeType = NSSPKCS5_PKCS12_V2; } /* fall through */ case SEC_OID_PKCS12_PBE_WITH_SHA1_AND_40_BIT_RC4: pbe_param->ivLen = 0; pbe_param->encAlg = SEC_OID_RC4; break; #ifdef PBKDF2 case SEC_OID_PKCS5_PBKDF2: case SEC_OID_PKCS5_PBES2: case SEC_OID_PKCS5_PBMAC1: /* everything else will be filled in by the template */ pbe_param->ivLen = 0; pbe_param->pbeType = NSSPKCS5_PBKDF2; pbe_param->encAlg = SEC_OID_PKCS5_PBKDF2; pbe_param->keyLen = 0; /* needs to be set by caller after return */ break; #endif default: return SECFailure; } return SECSuccess; } /* decode the algid and generate a PKCS 5 parameter from it */ NSSPKCS5PBEParameter * nsspkcs5_NewParam(SECOidTag alg, SECItem *salt, int iterator) { PLArenaPool *arena = NULL; NSSPKCS5PBEParameter *pbe_param = NULL; SECStatus rv = SECFailure; arena = PORT_NewArena(SEC_ASN1_DEFAULT_ARENA_SIZE); if (arena == NULL) return NULL; /* allocate memory for the parameter */ pbe_param = (NSSPKCS5PBEParameter *)PORT_ArenaZAlloc(arena, sizeof(NSSPKCS5PBEParameter)); if (pbe_param == NULL) { goto loser; } pbe_param->poolp = arena; rv = nsspkcs5_FillInParam(alg, pbe_param); if (rv != SECSuccess) { goto loser; } pbe_param->iter = iterator; if (salt) { rv = SECITEM_CopyItem(arena,&pbe_param->salt,salt); } /* default key gen */ pbe_param->keyID = pbeBitGenCipherKey; loser: if (rv != SECSuccess) { PORT_FreeArena(arena, PR_TRUE); pbe_param = NULL; } return pbe_param; } /* * find the hash type needed to implement a specific HMAC. * OID definitions are from pkcs 5 v2.0 and 2.1 */ HASH_HashType HASH_FromHMACOid(SECOidTag hmac) { switch (hmac) { case SEC_OID_HMAC_SHA1: return HASH_AlgSHA1; case SEC_OID_HMAC_SHA256: return HASH_AlgSHA256; case SEC_OID_HMAC_SHA384: return HASH_AlgSHA384; case SEC_OID_HMAC_SHA512: return HASH_AlgSHA512; case SEC_OID_HMAC_SHA224: default: break; } return HASH_AlgNULL; } /* decode the algid and generate a PKCS 5 parameter from it */ NSSPKCS5PBEParameter * nsspkcs5_AlgidToParam(SECAlgorithmID *algid) { NSSPKCS5PBEParameter *pbe_param = NULL; nsspkcs5V2PBEParameter pbev2_param; SECOidTag algorithm; SECStatus rv = SECFailure; if (algid == NULL) { return NULL; } algorithm = SECOID_GetAlgorithmTag(algid); if (algorithm == SEC_OID_UNKNOWN) { goto loser; } pbe_param = nsspkcs5_NewParam(algorithm, NULL, 1); if (pbe_param == NULL) { goto loser; } /* decode parameter */ rv = SECFailure; switch (pbe_param->pbeType) { case NSSPKCS5_PBKDF1: rv = SEC_ASN1DecodeItem(pbe_param->poolp, pbe_param, NSSPKCS5PBEParameterTemplate, &algid->parameters); break; case NSSPKCS5_PKCS12_V2: rv = SEC_ASN1DecodeItem(pbe_param->poolp, pbe_param, NSSPKCS5PKCS12V2PBEParameterTemplate, &algid->parameters); break; #ifdef PBKDF2 case NSSPKCS5_PBKDF2: PORT_Memset(&pbev2_param,0, sizeof(pbev2_param)); /* just the PBE */ if (algorithm == SEC_OID_PKCS5_PBKDF2) { rv = SEC_ASN1DecodeItem(pbe_param->poolp, pbe_param, NSSPKCS5V2PBEParameterTemplate, &algid->parameters); } else { /* PBE data an others */ rv = SEC_ASN1DecodeItem(pbe_param->poolp, &pbev2_param, NSSPKCS5V2PBES2ParameterTemplate, &algid->parameters); if (rv != SECSuccess) { break; } pbe_param->encAlg = SECOID_GetAlgorithmTag(&pbev2_param.algParams); rv = SEC_ASN1DecodeItem(pbe_param->poolp, pbe_param, NSSPKCS5V2PBEParameterTemplate, &pbev2_param.keyParams.parameters); if (rv != SECSuccess) { break; } pbe_param->keyLen = DER_GetInteger(&pbe_param->keyLength); } /* we we are encrypting, save any iv's */ if (algorithm == SEC_OID_PKCS5_PBES2) { pbe_param->ivLen = pbev2_param.algParams.parameters.len; pbe_param->ivData = pbev2_param.algParams.parameters.data; } pbe_param->hashType = HASH_FromHMACOid(SECOID_GetAlgorithmTag(&pbe_param->prfAlg)); if (pbe_param->hashType == HASH_AlgNULL) { PORT_SetError(SEC_ERROR_INVALID_ALGORITHM); rv = SECFailure; } break; #endif } loser: if (rv == SECSuccess) { pbe_param->iter = DER_GetInteger(&pbe_param->iteration); } else { nsspkcs5_DestroyPBEParameter(pbe_param); pbe_param = NULL; } return pbe_param; } /* destroy a pbe parameter. it assumes that the parameter was * generated using the appropriate create function and therefor * contains an arena pool. */ void nsspkcs5_DestroyPBEParameter(NSSPKCS5PBEParameter *pbe_param) { if (pbe_param != NULL) { PORT_FreeArena(pbe_param->poolp, PR_FALSE); } } /* crypto routines */ /* perform DES encryption and decryption. these routines are called * by nsspkcs5_CipherData. In the case of an error, NULL is returned. */ static SECItem * sec_pkcs5_des(SECItem *key, SECItem *iv, SECItem *src, PRBool triple_des, PRBool encrypt) { SECItem *dest; SECItem *dup_src; SECStatus rv = SECFailure; int pad; if((src == NULL) || (key == NULL) || (iv == NULL)) return NULL; dup_src = SECITEM_DupItem(src); if(dup_src == NULL) { return NULL; } if(encrypt != PR_FALSE) { void *dummy; dummy = CBC_PadBuffer(NULL, dup_src->data, dup_src->len, &dup_src->len, 8 /* DES_BLOCK_SIZE */); if(dummy == NULL) { SECITEM_FreeItem(dup_src, PR_TRUE); return NULL; } dup_src->data = (unsigned char*)dummy; } dest = (SECItem *)PORT_ZAlloc(sizeof(SECItem)); if(dest != NULL) { /* allocate with over flow */ dest->data = (unsigned char *)PORT_ZAlloc(dup_src->len + 64); if(dest->data != NULL) { DESContext *ctxt; ctxt = DES_CreateContext(key->data, iv->data, (triple_des ? NSS_DES_EDE3_CBC : NSS_DES_CBC), encrypt); if(ctxt != NULL) { rv = (encrypt ? DES_Encrypt : DES_Decrypt)( ctxt, dest->data, &dest->len, dup_src->len + 64, dup_src->data, dup_src->len); /* remove padding -- assumes 64 bit blocks */ if((encrypt == PR_FALSE) && (rv == SECSuccess)) { pad = dest->data[dest->len-1]; if((pad > 0) && (pad <= 8)) { if(dest->data[dest->len-pad] != pad) { rv = SECFailure; PORT_SetError(SEC_ERROR_BAD_PASSWORD); } else { dest->len -= pad; } } else { rv = SECFailure; PORT_SetError(SEC_ERROR_BAD_PASSWORD); } } DES_DestroyContext(ctxt, PR_TRUE); } } } if(rv == SECFailure) { if(dest != NULL) { SECITEM_FreeItem(dest, PR_TRUE); } dest = NULL; } if(dup_src != NULL) { SECITEM_FreeItem(dup_src, PR_TRUE); } return dest; } /* perform aes encryption/decryption if an error occurs, NULL is returned */ static SECItem * sec_pkcs5_aes(SECItem *key, SECItem *iv, SECItem *src, PRBool triple_des, PRBool encrypt) { SECItem *dest; SECItem *dup_src; SECStatus rv = SECFailure; int pad; if((src == NULL) || (key == NULL) || (iv == NULL)) return NULL; dup_src = SECITEM_DupItem(src); if(dup_src == NULL) { return NULL; } if(encrypt != PR_FALSE) { void *dummy; dummy = CBC_PadBuffer(NULL, dup_src->data, dup_src->len, &dup_src->len,AES_BLOCK_SIZE); if(dummy == NULL) { SECITEM_FreeItem(dup_src, PR_TRUE); return NULL; } dup_src->data = (unsigned char*)dummy; } dest = (SECItem *)PORT_ZAlloc(sizeof(SECItem)); if(dest != NULL) { /* allocate with over flow */ dest->data = (unsigned char *)PORT_ZAlloc(dup_src->len + 64); if(dest->data != NULL) { AESContext *ctxt; ctxt = AES_CreateContext(key->data, iv->data, NSS_AES_CBC, encrypt, key->len, 16); if(ctxt != NULL) { rv = (encrypt ? AES_Encrypt : AES_Decrypt)( ctxt, dest->data, &dest->len, dup_src->len + 64, dup_src->data, dup_src->len); /* remove padding -- assumes 64 bit blocks */ if((encrypt == PR_FALSE) && (rv == SECSuccess)) { pad = dest->data[dest->len-1]; if((pad > 0) && (pad <= 16)) { if(dest->data[dest->len-pad] != pad) { rv = SECFailure; PORT_SetError(SEC_ERROR_BAD_PASSWORD); } else { dest->len -= pad; } } else { rv = SECFailure; PORT_SetError(SEC_ERROR_BAD_PASSWORD); } } AES_DestroyContext(ctxt, PR_TRUE); } } } if(rv == SECFailure) { if(dest != NULL) { SECITEM_FreeItem(dest, PR_TRUE); } dest = NULL; } if(dup_src != NULL) { SECITEM_FreeItem(dup_src, PR_TRUE); } return dest; } /* perform rc2 encryption/decryption if an error occurs, NULL is returned */ static SECItem * sec_pkcs5_rc2(SECItem *key, SECItem *iv, SECItem *src, PRBool dummy, PRBool encrypt) { SECItem *dest; SECItem *dup_src; SECStatus rv = SECFailure; int pad; if((src == NULL) || (key == NULL) || (iv == NULL)) { return NULL; } dup_src = SECITEM_DupItem(src); if(dup_src == NULL) { return NULL; } if(encrypt != PR_FALSE) { void *dummy; dummy = CBC_PadBuffer(NULL, dup_src->data, dup_src->len, &dup_src->len, 8 /* RC2_BLOCK_SIZE */); if(dummy == NULL) { SECITEM_FreeItem(dup_src, PR_TRUE); return NULL; } dup_src->data = (unsigned char*)dummy; } dest = (SECItem *)PORT_ZAlloc(sizeof(SECItem)); if(dest != NULL) { dest->data = (unsigned char *)PORT_ZAlloc(dup_src->len + 64); if(dest->data != NULL) { RC2Context *ctxt; ctxt = RC2_CreateContext(key->data, key->len, iv->data, NSS_RC2_CBC, key->len); if(ctxt != NULL) { rv = (encrypt ? RC2_Encrypt: RC2_Decrypt)( ctxt, dest->data, &dest->len, dup_src->len + 64, dup_src->data, dup_src->len); /* assumes 8 byte blocks -- remove padding */ if((rv == SECSuccess) && (encrypt != PR_TRUE)) { pad = dest->data[dest->len-1]; if((pad > 0) && (pad <= 8)) { if(dest->data[dest->len-pad] != pad) { PORT_SetError(SEC_ERROR_BAD_PASSWORD); rv = SECFailure; } else { dest->len -= pad; } } else { PORT_SetError(SEC_ERROR_BAD_PASSWORD); rv = SECFailure; } } } } } if((rv != SECSuccess) && (dest != NULL)) { SECITEM_FreeItem(dest, PR_TRUE); dest = NULL; } if(dup_src != NULL) { SECITEM_FreeItem(dup_src, PR_TRUE); } return dest; } /* perform rc4 encryption and decryption */ static SECItem * sec_pkcs5_rc4(SECItem *key, SECItem *iv, SECItem *src, PRBool dummy_op, PRBool encrypt) { SECItem *dest; SECStatus rv = SECFailure; if((src == NULL) || (key == NULL) || (iv == NULL)) { return NULL; } dest = (SECItem *)PORT_ZAlloc(sizeof(SECItem)); if(dest != NULL) { dest->data = (unsigned char *)PORT_ZAlloc(sizeof(unsigned char) * (src->len + 64)); if(dest->data != NULL) { RC4Context *ctxt; ctxt = RC4_CreateContext(key->data, key->len); if(ctxt) { rv = (encrypt ? RC4_Encrypt : RC4_Decrypt)( ctxt, dest->data, &dest->len, src->len + 64, src->data, src->len); RC4_DestroyContext(ctxt, PR_TRUE); } } } if((rv != SECSuccess) && (dest)) { SECITEM_FreeItem(dest, PR_TRUE); dest = NULL; } return dest; } /* function pointer template for crypto functions */ typedef SECItem *(* pkcs5_crypto_func)(SECItem *key, SECItem *iv, SECItem *src, PRBool op1, PRBool op2); /* performs the cipher operation on the src and returns the result. * if an error occurs, NULL is returned. * * a null length password is allowed. this corresponds to encrypting * the data with ust the salt. */ /* change this to use PKCS 11? */ SECItem * nsspkcs5_CipherData(NSSPKCS5PBEParameter *pbe_param, SECItem *pwitem, SECItem *src, PRBool encrypt, PRBool *update) { SECItem *key = NULL, iv; SECItem *dest = NULL; PRBool tripleDES = PR_TRUE; pkcs5_crypto_func cryptof; iv.data = NULL; if (update) { *update = PR_FALSE; } if ((pwitem == NULL) || (src == NULL)) { return NULL; } /* get key, and iv */ key = nsspkcs5_ComputeKeyAndIV(pbe_param, pwitem, &iv, PR_FALSE); if(key == NULL) { return NULL; } switch(pbe_param->encAlg) { /* PKCS 5 v2 only */ case SEC_OID_AES_128_CBC: case SEC_OID_AES_192_CBC: case SEC_OID_AES_256_CBC: cryptof = sec_pkcs5_aes; break; case SEC_OID_DES_EDE3_CBC: cryptof = sec_pkcs5_des; tripleDES = PR_TRUE; break; case SEC_OID_DES_CBC: cryptof = sec_pkcs5_des; tripleDES = PR_FALSE; break; case SEC_OID_RC2_CBC: cryptof = sec_pkcs5_rc2; break; case SEC_OID_RC4: cryptof = sec_pkcs5_rc4; break; default: cryptof = NULL; break; } if (cryptof == NULL) { goto loser; } dest = (*cryptof)(key, &iv, src, tripleDES, encrypt); /* * it's possible for some keys and keydb's to claim to * be triple des when they're really des. In this case * we simply try des. If des works we set the update flag * so the key db knows it needs to update all it's entries. * The case can only happen on decrypted of a * SEC_OID_DES_EDE3_CBD. */ if ((dest == NULL) && (encrypt == PR_FALSE) && (pbe_param->encAlg == SEC_OID_DES_EDE3_CBC)) { dest = (*cryptof)(key, &iv, src, PR_FALSE, encrypt); if (update && (dest != NULL)) *update = PR_TRUE; } loser: if (key != NULL) { SECITEM_ZfreeItem(key, PR_TRUE); } if (iv.data != NULL) { SECITEM_ZfreeItem(&iv, PR_FALSE); } return dest; } /* creates a algorithm ID containing the PBE algorithm and appropriate * parameters. the required parameter is the algorithm. if salt is * not specified, it is generated randomly. if IV is specified, it overrides * the PKCS 5 generation of the IV. * * the returned SECAlgorithmID should be destroyed using * SECOID_DestroyAlgorithmID */ SECAlgorithmID * nsspkcs5_CreateAlgorithmID(PLArenaPool *arena, SECOidTag algorithm, NSSPKCS5PBEParameter *pbe_param) { SECAlgorithmID *algid, *ret_algid = NULL; SECItem der_param; nsspkcs5V2PBEParameter pkcs5v2_param; SECStatus rv = SECFailure; void *dummy = NULL; if (arena == NULL) { return NULL; } der_param.data = NULL; der_param.len = 0; /* generate the algorithm id */ algid = (SECAlgorithmID *)PORT_ArenaZAlloc(arena, sizeof(SECAlgorithmID)); if (algid == NULL) { goto loser; } if (pbe_param->iteration.data == NULL) { dummy = SEC_ASN1EncodeInteger(pbe_param->poolp,&pbe_param->iteration, pbe_param->iter); if (dummy == NULL) { goto loser; } } switch (pbe_param->pbeType) { case NSSPKCS5_PBKDF1: dummy = SEC_ASN1EncodeItem(arena, &der_param, pbe_param, NSSPKCS5PBEParameterTemplate); break; case NSSPKCS5_PKCS12_V2: dummy = SEC_ASN1EncodeItem(arena, &der_param, pbe_param, NSSPKCS5PKCS12V2PBEParameterTemplate); break; #ifdef PBKDF2 case NSSPKCS5_PBKDF2: if (pbe_param->keyLength.data == NULL) { dummy = SEC_ASN1EncodeInteger(pbe_param->poolp, &pbe_param->keyLength, pbe_param->keyLen); if (dummy == NULL) { goto loser; } } PORT_Memset(&pkcs5v2_param, 0, sizeof(pkcs5v2_param)); dummy = SEC_ASN1EncodeItem(arena, &der_param, pbe_param, NSSPKCS5V2PBEParameterTemplate); if (dummy == NULL) { break; } dummy = NULL; rv = SECOID_SetAlgorithmID(arena, &pkcs5v2_param.keyParams, SEC_OID_PKCS5_PBKDF2, &der_param); if (rv != SECSuccess) { break; } der_param.data = pbe_param->ivData; der_param.len = pbe_param->ivLen; rv = SECOID_SetAlgorithmID(arena, &pkcs5v2_param.algParams, pbe_param->encAlg, pbe_param->ivLen ? &der_param : NULL); if (rv != SECSuccess) { break; } dummy = SEC_ASN1EncodeItem(arena, &der_param, &pkcs5v2_param, NSSPKCS5V2PBES2ParameterTemplate); break; #endif default: break; } if (dummy == NULL) { goto loser; } rv = SECOID_SetAlgorithmID(arena, algid, algorithm, &der_param); if (rv != SECSuccess) { goto loser; } ret_algid = (SECAlgorithmID *)PORT_ZAlloc(sizeof(SECAlgorithmID)); if (ret_algid == NULL) { goto loser; } rv = SECOID_CopyAlgorithmID(NULL, ret_algid, algid); if (rv != SECSuccess) { SECOID_DestroyAlgorithmID(ret_algid, PR_TRUE); ret_algid = NULL; } loser: return ret_algid; }