#include "system.h" #include #include #include #include #include #include #include #include #include "rpmio/digest.h" #include "debug.h" static int _crypto_initialized = 0; static int _new_process = 1; #if HAVE_NSS_INITCONTEXT static NSSInitContext * _nss_ctx = NULL; #endif /** * MD5/SHA1 digest private data. */ struct DIGEST_CTX_s { rpmDigestFlags flags; /*!< Bit(s) to control digest operation. */ HASHContext *hashctx; /*!< Internal NSS hash context. */ int algo; /*!< Used hash algorithm */ }; /* * Only flag for re-initialization here, in the common case the child * exec()'s something else shutting down NSS here would be waste of time. */ static void at_forkchild(void) { _new_process = 1; } int rpmInitCrypto(void) { int rc = 0; /* Lazy NSS shutdown for re-initialization after fork() */ if (_new_process && _crypto_initialized) { rpmFreeCrypto(); } /* * Initialize NSS if not already done. * NSS prior to 3.12.5 only supports a global context which can cause * trouble when an API user wants to use NSS for their own purposes, use * a private context if possible. */ if (!_crypto_initialized) { /* NSPR sets SIGPIPE to ignore behind our back, save and restore */ struct sigaction oact; sigaction(SIGPIPE, NULL, &oact); #if HAVE_NSS_INITCONTEXT PRUint32 flags = (NSS_INIT_READONLY|NSS_INIT_NOCERTDB| NSS_INIT_NOMODDB|NSS_INIT_FORCEOPEN| NSS_INIT_NOROOTINIT|NSS_INIT_OPTIMIZESPACE); _nss_ctx = NSS_InitContext(NULL, NULL, NULL, NULL, NULL, flags); if (_nss_ctx == NULL) { #else if (NSS_NoDB_Init(NULL) != SECSuccess) { #endif rpmlog(RPMLOG_ERR, _("Failed to initialize NSS library\n")); rc = -1; } else { _crypto_initialized = 1; } sigaction(SIGPIPE, &oact, NULL); } /* Register one post-fork handler per process */ if (_new_process) { if (pthread_atfork(NULL, NULL, at_forkchild) != 0) { rpmlog(RPMLOG_WARNING, _("Failed to register fork handler: %m\n")); } _new_process = 0; } return rc; } int rpmFreeCrypto(void) { int rc = 0; if (_crypto_initialized) { #if HAVE_NSS_INITCONTEXT rc = (NSS_ShutdownContext(_nss_ctx) != SECSuccess); _nss_ctx = NULL; #else rc = (NSS_Shutdown() != SECSuccess); #endif _crypto_initialized = 0; } return rc; } DIGEST_CTX rpmDigestDup(DIGEST_CTX octx) { DIGEST_CTX nctx = NULL; if (octx) { HASHContext *hctx = HASH_Clone(octx->hashctx); if (hctx) { nctx = memcpy(xcalloc(1, sizeof(*nctx)), octx, sizeof(*nctx)); nctx->hashctx = hctx; } } return nctx; } RPM_GNUC_PURE static HASH_HashType getHashType(int hashalgo) { switch (hashalgo) { case PGPHASHALGO_MD5: return HASH_AlgMD5; case PGPHASHALGO_SHA1: return HASH_AlgSHA1; #ifdef SHA224_LENGTH case PGPHASHALGO_SHA224: return HASH_AlgSHA224; #endif case PGPHASHALGO_SHA256: return HASH_AlgSHA256; case PGPHASHALGO_SHA384: return HASH_AlgSHA384; case PGPHASHALGO_SHA512: return HASH_AlgSHA512; } return HASH_AlgNULL; } size_t rpmDigestLength(int hashalgo) { return HASH_ResultLen(getHashType(hashalgo)); } DIGEST_CTX rpmDigestInit(int hashalgo, rpmDigestFlags flags) { HASH_HashType type = getHashType(hashalgo); HASHContext *hashctx = NULL; DIGEST_CTX ctx = NULL; if (type == HASH_AlgNULL || rpmInitCrypto() < 0) goto exit; if ((hashctx = HASH_Create(type)) != NULL) { ctx = xcalloc(1, sizeof(*ctx)); ctx->flags = flags; ctx->algo = hashalgo; ctx->hashctx = hashctx; HASH_Begin(ctx->hashctx); } exit: return ctx; } int rpmDigestUpdate(DIGEST_CTX ctx, const void * data, size_t len) { size_t partlen; const unsigned char *ptr = data; if (ctx == NULL) return -1; partlen = ~(unsigned int)0xFF; while (len > 0) { if (len < partlen) { partlen = len; } HASH_Update(ctx->hashctx, ptr, partlen); ptr += partlen; len -= partlen; } return 0; } int rpmDigestFinal(DIGEST_CTX ctx, void ** datap, size_t *lenp, int asAscii) { unsigned char * digest; unsigned int digestlen; if (ctx == NULL) return -1; digestlen = HASH_ResultLenContext(ctx->hashctx); digest = xmalloc(digestlen); /* FIX: check rc */ HASH_End(ctx->hashctx, digest, (unsigned int *) &digestlen, digestlen); /* Return final digest. */ if (!asAscii) { if (lenp) *lenp = digestlen; if (datap) { *datap = digest; digest = NULL; } } else { if (lenp) *lenp = (2*digestlen) + 1; if (datap) { const uint8_t * s = (const uint8_t *) digest; *datap = pgpHexStr(s, digestlen); } } if (digest) { memset(digest, 0, digestlen); /* In case it's sensitive */ free(digest); } HASH_Destroy(ctx->hashctx); memset(ctx, 0, sizeof(*ctx)); /* In case it's sensitive */ free(ctx); return 0; } RPM_GNUC_PURE static SECOidTag getHashAlg(unsigned int hashalgo) { switch (hashalgo) { case PGPHASHALGO_MD5: return SEC_OID_MD5; case PGPHASHALGO_SHA1: return SEC_OID_SHA1; #ifdef SHA224_LENGTH case PGPHASHALGO_SHA224: return SEC_OID_SHA224; #endif case PGPHASHALGO_SHA256: return SEC_OID_SHA256; case PGPHASHALGO_SHA384: return SEC_OID_SHA384; case PGPHASHALGO_SHA512: return SEC_OID_SHA512; } return SEC_OID_UNKNOWN; } static int pgpMpiSet(unsigned int lbits, uint8_t *dest, const uint8_t * p) { unsigned int mbits = pgpMpiBits(p); unsigned int nbits; size_t nbytes; uint8_t *t = dest; unsigned int ix; if (mbits > lbits) return 1; nbits = (lbits > mbits ? lbits : mbits); nbytes = ((nbits + 7) >> 3); ix = (nbits - mbits) >> 3; if (ix > 0) memset(t, '\0', ix); memcpy(t+ix, p+2, nbytes-ix); return 0; } static SECItem *pgpMpiItem(PRArenaPool *arena, SECItem *item, const uint8_t *p) { size_t nbytes = pgpMpiLen(p)-2; if (item == NULL) { if ((item=SECITEM_AllocItem(arena, item, nbytes)) == NULL) return item; } else { if (arena != NULL) item->data = PORT_ArenaGrow(arena, item->data, item->len, nbytes); else item->data = PORT_Realloc(item->data, nbytes); if (item->data == NULL) { if (arena == NULL) SECITEM_FreeItem(item, PR_TRUE); return NULL; } } memcpy(item->data, p+2, nbytes); item->len = nbytes; return item; } static SECKEYPublicKey *pgpNewPublicKey(KeyType type) { PRArenaPool *arena; SECKEYPublicKey *key; arena = PORT_NewArena(DER_DEFAULT_CHUNKSIZE); if (arena == NULL) return NULL; key = PORT_ArenaZAlloc(arena, sizeof(SECKEYPublicKey)); if (key == NULL) { PORT_FreeArena(arena, PR_FALSE); return NULL; } key->keyType = type; key->pkcs11ID = CK_INVALID_HANDLE; key->pkcs11Slot = NULL; key->arena = arena; return key; } /* compatibility with nss < 3.14 */ #ifndef DSA1_SUBPRIME_LEN #define DSA1_SUBPRIME_LEN DSA_SUBPRIME_LEN #endif #ifndef DSA1_SIGNATURE_LEN #define DSA1_SIGNATURE_LEN DSA_SIGNATURE_LEN #endif #ifndef DSA1_Q_BITS #define DSA1_Q_BITS DSA_Q_BITS #endif static int pgpSetSigMpiDSA(pgpDigAlg pgpsig, int num, const uint8_t *p) { SECItem *sig = pgpsig->data; unsigned int qbits = DSA1_Q_BITS; unsigned int subprlen = DSA1_SUBPRIME_LEN; unsigned int siglen = DSA1_SIGNATURE_LEN; int rc = 1; /* assume failure */ switch (num) { case 0: sig = pgpsig->data = SECITEM_AllocItem(NULL, NULL, siglen); if (sig) { memset(sig->data, 0, siglen); rc = pgpMpiSet(qbits, sig->data, p); } break; case 1: if (sig && pgpMpiSet(qbits, sig->data+subprlen, p) == 0) { SECItem *signew = SECITEM_AllocItem(NULL, NULL, 0); if (signew == NULL) break; if (DSAU_EncodeDerSigWithLen(signew, sig, siglen) == SECSuccess) { SECITEM_FreeItem(sig, PR_TRUE); pgpsig->data = signew; rc = 0; } } break; } return rc; } static int pgpSetKeyMpiDSA(pgpDigAlg pgpkey, int num, const uint8_t *p) { SECItem *mpi = NULL; SECKEYPublicKey *key = pgpkey->data; if (key == NULL) key = pgpkey->data = pgpNewPublicKey(dsaKey); if (key) { switch (num) { case 0: mpi = pgpMpiItem(key->arena, &key->u.dsa.params.prime, p); break; case 1: mpi = pgpMpiItem(key->arena, &key->u.dsa.params.subPrime, p); break; case 2: mpi = pgpMpiItem(key->arena, &key->u.dsa.params.base, p); break; case 3: mpi = pgpMpiItem(key->arena, &key->u.dsa.publicValue, p); break; } } return (mpi == NULL); } static int pgpVerifySigDSA(pgpDigAlg pgpkey, pgpDigAlg pgpsig, uint8_t *hash, size_t hashlen, int hash_algo) { SECItem digest = { .type = siBuffer, .data = hash, .len = hashlen }; SECOidTag encAlg = SEC_OID_ANSIX9_DSA_SIGNATURE; SECOidTag hashAlg = getHashAlg(hash_algo); SECStatus rc; if (hashAlg == SEC_OID_UNKNOWN) return 1; rc = VFY_VerifyDigestDirect(&digest, pgpkey->data, pgpsig->data, encAlg, hashAlg, NULL); return (rc != SECSuccess); } static int pgpSetSigMpiRSA(pgpDigAlg pgpsig, int num, const uint8_t *p) { SECItem *sigitem = NULL; if (num == 0) { sigitem = pgpMpiItem(NULL, pgpsig->data, p); if (sigitem) pgpsig->data = sigitem; } return (sigitem == NULL); } static int pgpSetKeyMpiRSA(pgpDigAlg pgpkey, int num, const uint8_t *p) { SECItem *kitem = NULL; SECKEYPublicKey *key = pgpkey->data; if (key == NULL) key = pgpkey->data = pgpNewPublicKey(rsaKey); if (key) { switch (num) { case 0: kitem = pgpMpiItem(key->arena, &key->u.rsa.modulus, p); break; case 1: kitem = pgpMpiItem(key->arena, &key->u.rsa.publicExponent, p); break; } } return (kitem == NULL); } static int pgpVerifySigRSA(pgpDigAlg pgpkey, pgpDigAlg pgpsig, uint8_t *hash, size_t hashlen, int hash_algo) { SECItem digest = { .type = siBuffer, .data = hash, .len = hashlen }; SECItem *sig = pgpsig->data; SECKEYPublicKey *key = pgpkey->data; SECItem *padded = NULL; SECOidTag encAlg = SEC_OID_PKCS1_RSA_ENCRYPTION; SECOidTag hashAlg = getHashAlg(hash_algo); SECStatus rc = SECFailure; size_t siglen, padlen; if (hashAlg == SEC_OID_UNKNOWN) return 1; /* Zero-pad signature to expected size if necessary */ siglen = SECKEY_SignatureLen(key); padlen = siglen - sig->len; if (padlen) { padded = SECITEM_AllocItem(NULL, NULL, siglen); if (padded == NULL) return 1; memset(padded->data, 0, padlen); memcpy(padded->data + padlen, sig->data, sig->len); sig = padded; } rc = VFY_VerifyDigestDirect(&digest, key, sig, encAlg, hashAlg, NULL); if (padded) SECITEM_ZfreeItem(padded, PR_TRUE); return (rc != SECSuccess); } static void pgpFreeSigRSADSA(pgpDigAlg sa) { SECITEM_ZfreeItem(sa->data, PR_TRUE); sa->data = NULL; } static void pgpFreeKeyRSADSA(pgpDigAlg ka) { SECKEY_DestroyPublicKey(ka->data); ka->data = NULL; } static int pgpSetMpiNULL(pgpDigAlg pgpkey, int num, const uint8_t *p) { return 1; } static int pgpVerifyNULL(pgpDigAlg pgpkey, pgpDigAlg pgpsig, uint8_t *hash, size_t hashlen, int hash_algo) { return 1; } pgpDigAlg pgpPubkeyNew(int algo) { pgpDigAlg ka = xcalloc(1, sizeof(*ka));; switch (algo) { case PGPPUBKEYALGO_RSA: ka->setmpi = pgpSetKeyMpiRSA; ka->free = pgpFreeKeyRSADSA; ka->mpis = 2; break; case PGPPUBKEYALGO_DSA: ka->setmpi = pgpSetKeyMpiDSA; ka->free = pgpFreeKeyRSADSA; ka->mpis = 4; break; default: ka->setmpi = pgpSetMpiNULL; ka->mpis = -1; break; } ka->verify = pgpVerifyNULL; /* keys can't be verified */ return ka; } pgpDigAlg pgpSignatureNew(int algo) { pgpDigAlg sa = xcalloc(1, sizeof(*sa)); switch (algo) { case PGPPUBKEYALGO_RSA: sa->setmpi = pgpSetSigMpiRSA; sa->free = pgpFreeSigRSADSA; sa->verify = pgpVerifySigRSA; sa->mpis = 1; break; case PGPPUBKEYALGO_DSA: sa->setmpi = pgpSetSigMpiDSA; sa->free = pgpFreeSigRSADSA; sa->verify = pgpVerifySigDSA; sa->mpis = 2; break; default: sa->setmpi = pgpSetMpiNULL; sa->verify = pgpVerifyNULL; sa->mpis = -1; break; } return sa; }