/* * Copyright (C) 2000, 2001, 2004, 2005, 2007, 2008, 2010, 2011 Free Software * Foundation, Inc. * * Author: Nikos Mavrogiannopoulos * * This file is part of GnuTLS. * * The GnuTLS 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 3 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 program. If not, see * */ /* This file handles all the internal functions that cope with hashes * and HMACs. */ #include #include #include static int digest_length (int algo) { switch (algo) { case GNUTLS_DIG_NULL: case GNUTLS_MAC_AEAD: return 0; case GNUTLS_DIG_MD5: case GNUTLS_DIG_MD2: return 16; case GNUTLS_DIG_SHA1: case GNUTLS_DIG_RMD160: return 20; case GNUTLS_DIG_SHA256: return 32; case GNUTLS_DIG_SHA384: return 48; case GNUTLS_DIG_SHA512: return 64; case GNUTLS_DIG_SHA224: return 28; default: gnutls_assert (); return GNUTLS_E_INTERNAL_ERROR; } } int _gnutls_hash_init (digest_hd_st * dig, gnutls_digest_algorithm_t algorithm) { int result; const gnutls_crypto_digest_st *cc = NULL; dig->algorithm = algorithm; /* check if a digest has been registered */ cc = _gnutls_get_crypto_digest (algorithm); if (cc != NULL && cc->init) { if (cc->init (algorithm, &dig->handle) < 0) { gnutls_assert (); return GNUTLS_E_HASH_FAILED; } dig->hash = cc->hash; dig->copy = cc->copy; dig->reset = cc->reset; dig->output = cc->output; dig->deinit = cc->deinit; return 0; } result = _gnutls_digest_ops.init (algorithm, &dig->handle); if (result < 0) { gnutls_assert (); return result; } dig->hash = _gnutls_digest_ops.hash; dig->copy = _gnutls_digest_ops.copy; dig->reset = _gnutls_digest_ops.reset; dig->output = _gnutls_digest_ops.output; dig->deinit = _gnutls_digest_ops.deinit; return 0; } void _gnutls_hash_deinit (digest_hd_st * handle, void *digest) { if (handle->handle == NULL) { return; } if (digest != NULL) _gnutls_hash_output (handle, digest); handle->deinit (handle->handle); handle->handle = NULL; } /* returns the output size of the given hash/mac algorithm */ int _gnutls_hash_get_algo_len (gnutls_digest_algorithm_t algorithm) { return digest_length (algorithm); } int _gnutls_hash_copy (digest_hd_st * dst, digest_hd_st * src) { memset (dst, 0, sizeof (*dst)); dst->algorithm = src->algorithm; dst->hash = src->hash; dst->copy = src->copy; dst->output = src->output; dst->deinit = src->deinit; return src->copy (&dst->handle, src->handle); } int _gnutls_hash_fast (gnutls_digest_algorithm_t algorithm, const void *text, size_t textlen, void *digest) { int ret; const gnutls_crypto_digest_st *cc = NULL; /* check if a digest has been registered */ cc = _gnutls_get_crypto_digest (algorithm); if (cc != NULL) { if (cc->fast (algorithm, text, textlen, digest) < 0) { gnutls_assert (); return GNUTLS_E_HASH_FAILED; } return 0; } ret = _gnutls_digest_ops.fast (algorithm, text, textlen, digest); if (ret < 0) { gnutls_assert (); return ret; } return 0; } /* HMAC interface */ int _gnutls_hmac_fast (gnutls_mac_algorithm_t algorithm, const void *key, int keylen, const void *text, size_t textlen, void *digest) { int ret; const gnutls_crypto_mac_st *cc = NULL; /* check if a digest has been registered */ cc = _gnutls_get_crypto_mac (algorithm); if (cc != NULL) { if (cc->fast (algorithm, key, keylen, text, textlen, digest) < 0) { gnutls_assert (); return GNUTLS_E_HASH_FAILED; } return 0; } ret = _gnutls_mac_ops.fast (algorithm, key, keylen, text, textlen, digest); if (ret < 0) { gnutls_assert (); return ret; } return 0; } int _gnutls_hmac_init (digest_hd_st * dig, gnutls_mac_algorithm_t algorithm, const void *key, int keylen) { int result; const gnutls_crypto_mac_st *cc = NULL; dig->algorithm = algorithm; dig->key = key; dig->keysize = keylen; /* check if a digest has been registered */ cc = _gnutls_get_crypto_mac (algorithm); if (cc != NULL && cc->init != NULL) { if (cc->init (algorithm, &dig->handle) < 0) { gnutls_assert (); return GNUTLS_E_HASH_FAILED; } if (cc->setkey (dig->handle, key, keylen) < 0) { gnutls_assert (); cc->deinit (dig->handle); return GNUTLS_E_HASH_FAILED; } dig->hash = cc->hash; dig->output = cc->output; dig->deinit = cc->deinit; dig->reset = cc->reset; return 0; } result = _gnutls_mac_ops.init (algorithm, &dig->handle); if (result < 0) { gnutls_assert (); return result; } dig->hash = _gnutls_mac_ops.hash; dig->output = _gnutls_mac_ops.output; dig->deinit = _gnutls_mac_ops.deinit; dig->reset = _gnutls_mac_ops.reset; if (_gnutls_mac_ops.setkey (dig->handle, key, keylen) < 0) { gnutls_assert(); dig->deinit(dig->handle); return GNUTLS_E_HASH_FAILED; } return 0; } void _gnutls_hmac_deinit (digest_hd_st * handle, void *digest) { if (handle->handle == NULL) { return; } if (digest) _gnutls_hmac_output (handle, digest); handle->deinit (handle->handle); handle->handle = NULL; } inline static int get_padsize (gnutls_mac_algorithm_t algorithm) { switch (algorithm) { case GNUTLS_MAC_MD5: return 48; case GNUTLS_MAC_SHA1: return 40; default: return 0; } } /* Special functions for SSL3 MAC */ int _gnutls_mac_init_ssl3 (digest_hd_st * ret, gnutls_mac_algorithm_t algorithm, void *key, int keylen) { opaque ipad[48]; int padsize, result; padsize = get_padsize (algorithm); if (padsize == 0) { gnutls_assert (); return GNUTLS_E_HASH_FAILED; } memset (ipad, 0x36, padsize); result = _gnutls_hash_init (ret, algorithm); if (result < 0) { gnutls_assert (); return result; } ret->key = key; ret->keysize = keylen; if (keylen > 0) _gnutls_hash (ret, key, keylen); _gnutls_hash (ret, ipad, padsize); return 0; } void _gnutls_mac_reset_ssl3 (digest_hd_st * handle) { opaque ipad[48]; int padsize; padsize = get_padsize (handle->algorithm); memset (ipad, 0x36, padsize); _gnutls_hash_reset(handle); if (handle->keysize > 0) _gnutls_hash (handle, handle->key, handle->keysize); _gnutls_hash (handle, ipad, padsize); return; } int _gnutls_mac_output_ssl3 (digest_hd_st * handle, void *digest) { opaque ret[MAX_HASH_SIZE]; digest_hd_st td; opaque opad[48]; int padsize; int block, rc; padsize = get_padsize (handle->algorithm); if (padsize == 0) { gnutls_assert (); return GNUTLS_E_INTERNAL_ERROR; } memset (opad, 0x5C, padsize); rc = _gnutls_hash_init (&td, handle->algorithm); if (rc < 0) { gnutls_assert (); return rc; } if (handle->keysize > 0) _gnutls_hash (&td, handle->key, handle->keysize); _gnutls_hash (&td, opad, padsize); block = _gnutls_hmac_get_algo_len (handle->algorithm); _gnutls_hash_output (handle, ret); /* get the previous hash */ _gnutls_hash (&td, ret, block); _gnutls_hash_deinit (&td, digest); return 0; } int _gnutls_mac_deinit_ssl3 (digest_hd_st * handle, void *digest) { int ret = 0; if (digest != NULL) ret = _gnutls_mac_output_ssl3(handle, digest); _gnutls_hash_deinit(handle, NULL); return ret; } int _gnutls_mac_deinit_ssl3_handshake (digest_hd_st * handle, void *digest, opaque * key, uint32_t key_size) { opaque ret[MAX_HASH_SIZE]; digest_hd_st td; opaque opad[48]; opaque ipad[48]; int padsize; int block, rc; padsize = get_padsize (handle->algorithm); if (padsize == 0) { gnutls_assert (); rc = GNUTLS_E_INTERNAL_ERROR; goto cleanup; } memset (opad, 0x5C, padsize); memset (ipad, 0x36, padsize); rc = _gnutls_hash_init (&td, handle->algorithm); if (rc < 0) { gnutls_assert (); goto cleanup; } if (key_size > 0) _gnutls_hash (&td, key, key_size); _gnutls_hash (&td, opad, padsize); block = _gnutls_hmac_get_algo_len (handle->algorithm); if (key_size > 0) _gnutls_hash (handle, key, key_size); _gnutls_hash (handle, ipad, padsize); _gnutls_hash_deinit (handle, ret); /* get the previous hash */ _gnutls_hash (&td, ret, block); _gnutls_hash_deinit (&td, digest); return 0; cleanup: _gnutls_hash_deinit(handle, NULL); return rc; } static int ssl3_sha (int i, opaque * secret, int secret_len, opaque * rnd, int rnd_len, void *digest) { int j, ret; opaque text1[26]; digest_hd_st td; for (j = 0; j < i + 1; j++) { text1[j] = 65 + i; /* A==65 */ } ret = _gnutls_hash_init (&td, GNUTLS_MAC_SHA1); if (ret < 0) { gnutls_assert (); return ret; } _gnutls_hash (&td, text1, i + 1); _gnutls_hash (&td, secret, secret_len); _gnutls_hash (&td, rnd, rnd_len); _gnutls_hash_deinit (&td, digest); return 0; } #define SHA1_DIGEST_OUTPUT 20 #define MD5_DIGEST_OUTPUT 16 static int ssl3_md5 (int i, opaque * secret, int secret_len, opaque * rnd, int rnd_len, void *digest) { opaque tmp[MAX_HASH_SIZE]; digest_hd_st td; int ret; ret = _gnutls_hash_init (&td, GNUTLS_MAC_MD5); if (ret < 0) { gnutls_assert (); return ret; } _gnutls_hash (&td, secret, secret_len); ret = ssl3_sha (i, secret, secret_len, rnd, rnd_len, tmp); if (ret < 0) { gnutls_assert (); _gnutls_hash_deinit (&td, digest); return ret; } _gnutls_hash (&td, tmp, SHA1_DIGEST_OUTPUT); _gnutls_hash_deinit (&td, digest); return 0; } int _gnutls_ssl3_hash_md5 (const void *first, int first_len, const void *second, int second_len, int ret_len, opaque * ret) { opaque digest[MAX_HASH_SIZE]; digest_hd_st td; int block = MD5_DIGEST_OUTPUT; int rc; rc = _gnutls_hash_init (&td, GNUTLS_MAC_MD5); if (rc < 0) { gnutls_assert (); return rc; } _gnutls_hash (&td, first, first_len); _gnutls_hash (&td, second, second_len); _gnutls_hash_deinit (&td, digest); if (ret_len > block) { gnutls_assert (); return GNUTLS_E_INTERNAL_ERROR; } memcpy (ret, digest, ret_len); return 0; } int _gnutls_ssl3_generate_random (void *secret, int secret_len, void *rnd, int rnd_len, int ret_bytes, opaque * ret) { int i = 0, copy, output_bytes; opaque digest[MAX_HASH_SIZE]; int block = MD5_DIGEST_OUTPUT; int result, times; output_bytes = 0; do { output_bytes += block; } while (output_bytes < ret_bytes); times = output_bytes / block; for (i = 0; i < times; i++) { result = ssl3_md5 (i, secret, secret_len, rnd, rnd_len, digest); if (result < 0) { gnutls_assert (); return result; } if ((1 + i) * block < ret_bytes) { copy = block; } else { copy = ret_bytes - (i) * block; } memcpy (&ret[i * block], digest, copy); } return 0; }