Mercurial > dropbear
view rsa.c @ 70:b0316ce64e4b
Merging in the changes from 0.41-0.43 main Dropbear tree
author | Matt Johnston <matt@ucc.asn.au> |
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date | Thu, 12 Aug 2004 16:41:58 +0000 |
parents | e2a1eaa19f22 |
children | 29a5c7c62350 |
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/* * Dropbear - a SSH2 server * * Copyright (c) 2002,2003 Matt Johnston * All rights reserved. * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ /* Perform RSA operations on data, including reading keys, signing and * verification. * * The format is specified in rfc2437, Applied Cryptography or The Handbook of * Applied Cryptography detail the general algorithm. */ #include "includes.h" #include "dbutil.h" #include "bignum.h" #include "rsa.h" #include "buffer.h" #include "ssh.h" #include "random.h" #ifdef DROPBEAR_RSA static mp_int * rsa_pad_em(rsa_key * key, const unsigned char * data, unsigned int len); /* Load a public rsa key from a buffer, initialising the values. * The key will have the same format as buf_put_rsa_key. * These should be freed with rsa_key_free. * Returns DROPBEAR_SUCCESS or DROPBEAR_FAILURE */ int buf_get_rsa_pub_key(buffer* buf, rsa_key *key) { TRACE(("enter buf_get_rsa_pub_key")); assert(key != NULL); key->e = m_malloc(sizeof(mp_int)); key->n = m_malloc(sizeof(mp_int)); m_mp_init_multi(key->e, key->n, NULL); key->d = NULL; key->p = NULL; key->q = NULL; buf_incrpos(buf, 4+SSH_SIGNKEY_RSA_LEN); /* int + "ssh-rsa" */ if (buf_getmpint(buf, key->e) == DROPBEAR_FAILURE || buf_getmpint(buf, key->n) == DROPBEAR_FAILURE) { TRACE(("leave buf_get_rsa_pub_key: failure")); return DROPBEAR_FAILURE; } if (mp_count_bits(key->n) < MIN_RSA_KEYLEN) { dropbear_log(LOG_WARNING, "rsa key too short"); return DROPBEAR_FAILURE; } TRACE(("leave buf_get_rsa_pub_key: success")); return DROPBEAR_SUCCESS; } /* Same as buf_get_rsa_pub_key, but reads a private "x" key at the end. * Loads a private rsa key from a buffer * Returns DROPBEAR_SUCCESS or DROPBEAR_FAILURE */ int buf_get_rsa_priv_key(buffer* buf, rsa_key *key) { assert(key != NULL); TRACE(("enter buf_get_rsa_priv_key")); if (buf_get_rsa_pub_key(buf, key) == DROPBEAR_FAILURE) { TRACE(("leave buf_get_rsa_priv_key: pub: ret == DROPBEAR_FAILURE")); return DROPBEAR_FAILURE; } key->d = m_malloc(sizeof(mp_int)); m_mp_init(key->d); if (buf_getmpint(buf, key->d) == DROPBEAR_FAILURE) { TRACE(("leave buf_get_rsa_priv_key: d: ret == DROPBEAR_FAILURE")); return DROPBEAR_FAILURE; } /* old Dropbear private keys didn't keep p and q, so we will ignore them*/ if (buf->pos == buf->len) { key->p = NULL; key->q = NULL; } else { key->p = m_malloc(sizeof(mp_int)); key->q = m_malloc(sizeof(mp_int)); m_mp_init_multi(key->p, key->q, NULL); if (buf_getmpint(buf, key->p) == DROPBEAR_FAILURE) { TRACE(("leave buf_get_rsa_priv_key: p: ret == DROPBEAR_FAILURE")); return DROPBEAR_FAILURE; } if (buf_getmpint(buf, key->q) == DROPBEAR_FAILURE) { TRACE(("leave buf_get_rsa_priv_key: q: ret == DROPBEAR_FAILURE")); return DROPBEAR_FAILURE; } } TRACE(("leave buf_get_rsa_priv_key")); return DROPBEAR_SUCCESS; } /* Clear and free the memory used by a public or private key */ void rsa_key_free(rsa_key *key) { TRACE(("enter rsa_key_free")); if (key == NULL) { TRACE(("leave rsa_key_free: key == NULL")); return; } if (key->d) { mp_clear(key->d); m_free(key->d); } if (key->e) { mp_clear(key->e); m_free(key->e); } if (key->n) { mp_clear(key->n); m_free(key->n); } if (key->p) { mp_clear(key->p); m_free(key->p); } if (key->q) { mp_clear(key->q); m_free(key->q); } m_free(key); TRACE(("leave rsa_key_free")); } /* Put the public rsa key into the buffer in the required format: * * string "ssh-rsa" * mp_int e * mp_int n */ void buf_put_rsa_pub_key(buffer* buf, rsa_key *key) { TRACE(("enter buf_put_rsa_pub_key")); assert(key != NULL); buf_putstring(buf, SSH_SIGNKEY_RSA, SSH_SIGNKEY_RSA_LEN); buf_putmpint(buf, key->e); buf_putmpint(buf, key->n); TRACE(("leave buf_put_rsa_pub_key")); } /* Same as buf_put_rsa_pub_key, but with the private "x" key appended */ void buf_put_rsa_priv_key(buffer* buf, rsa_key *key) { TRACE(("enter buf_put_rsa_priv_key")); assert(key != NULL); buf_put_rsa_pub_key(buf, key); buf_putmpint(buf, key->d); /* new versions have p and q, old versions don't */ if (key->p) { buf_putmpint(buf, key->p); } if (key->q) { buf_putmpint(buf, key->q); } TRACE(("leave buf_put_rsa_priv_key")); } #ifdef DROPBEAR_SIGNKEY_VERIFY /* Verify a signature in buf, made on data by the key given. * Returns DROPBEAR_SUCCESS or DROPBEAR_FAILURE */ int buf_rsa_verify(buffer * buf, rsa_key *key, const unsigned char* data, unsigned int len) { unsigned int slen; mp_int rsa_s, rsa_mdash; mp_int *rsa_em = NULL; int ret = DROPBEAR_FAILURE; TRACE(("enter buf_rsa_verify")); assert(key != NULL); m_mp_init_multi(&rsa_mdash, &rsa_s, NULL); slen = buf_getint(buf); if (slen != (unsigned int)mp_unsigned_bin_size(key->n)) { TRACE(("bad size")); goto out; } if (mp_read_unsigned_bin(&rsa_s, buf_getptr(buf, buf->len - buf->pos), buf->len - buf->pos) != MP_OKAY) { TRACE(("failed reading rsa_s")); goto out; } /* check that s <= n-1 */ if (mp_cmp(&rsa_s, key->n) != MP_LT) { TRACE(("s > n-1")); goto out; } /* create the magic PKCS padded value */ rsa_em = rsa_pad_em(key, data, len); if (mp_exptmod(&rsa_s, key->e, key->n, &rsa_mdash) != MP_OKAY) { TRACE(("failed exptmod rsa_s")); goto out; } if (mp_cmp(rsa_em, &rsa_mdash) == MP_EQ) { /* signature is valid */ TRACE(("success!")); ret = DROPBEAR_SUCCESS; } out: if (rsa_em) { mp_clear(rsa_em); m_free(rsa_em); } mp_clear_multi(&rsa_mdash, &rsa_s, NULL); TRACE(("leave buf_rsa_verify: ret %d", ret)); return ret; } #endif /* DROPBEAR_SIGNKEY_VERIFY */ /* Sign the data presented with key, writing the signature contents * to the buffer */ void buf_put_rsa_sign(buffer* buf, rsa_key *key, const unsigned char* data, unsigned int len) { unsigned int nsize, ssize; unsigned int i; mp_int rsa_s; mp_int *rsa_em = NULL; TRACE(("enter buf_put_rsa_sign")); assert(key != NULL); rsa_em = rsa_pad_em(key, data, len); m_mp_init(&rsa_s); /* the actual signing of the padded data */ /* s = em^d mod n */ if (mp_exptmod(rsa_em, key->d, key->n, &rsa_s) != MP_OKAY) { dropbear_exit("rsa error"); } mp_clear(rsa_em); m_free(rsa_em); /* create the signature to return */ buf_putstring(buf, SSH_SIGNKEY_RSA, SSH_SIGNKEY_RSA_LEN); nsize = mp_unsigned_bin_size(key->n); /* string rsa_signature_blob length */ buf_putint(buf, nsize); /* pad out s to same length as n */ ssize = mp_unsigned_bin_size(&rsa_s); assert(ssize <= nsize); for (i = 0; i < nsize-ssize; i++) { buf_putbyte(buf, 0x00); } if (mp_to_unsigned_bin(&rsa_s, buf_getwriteptr(buf, ssize)) != MP_OKAY) { dropbear_exit("rsa error"); } buf_incrwritepos(buf, ssize); mp_clear(&rsa_s); #if defined(DEBUG_RSA) && defined(DEBUG_TRACE) printhex(buf->data, buf->len); #endif TRACE(("leave buf_put_rsa_sign")); } /* Creates the message value as expected by PKCS, see rfc2437 etc */ /* format to be padded to is: * EM = 01 | FF* | 00 | prefix | hash * * where FF is repeated enough times to make EM one byte * shorter than the size of key->n * * prefix is the ASN1 designator prefix, * hex 30 21 30 09 06 05 2B 0E 03 02 1A 05 00 04 14 */ static mp_int * rsa_pad_em(rsa_key * key, const unsigned char * data, unsigned int len) { /* ASN1 designator (including the 0x00 preceding) */ const char rsa_asn1_magic[] = {0x00, 0x30, 0x21, 0x30, 0x09, 0x06, 0x05, 0x2b, 0x0e, 0x03, 0x02, 0x1a, 0x05, 0x00, 0x04, 0x14}; #define RSA_ASN1_MAGIC_LEN 16 buffer * rsa_EM = NULL; hash_state hs; unsigned int nsize; mp_int * rsa_em = NULL; assert(key != NULL); assert(data != NULL); nsize = mp_unsigned_bin_size(key->n); rsa_EM = buf_new(nsize-1); /* type byte */ buf_putbyte(rsa_EM, 0x01); /* Padding with 0xFF bytes */ while(rsa_EM->pos != rsa_EM->size - RSA_ASN1_MAGIC_LEN - SHA1_HASH_SIZE) { buf_putbyte(rsa_EM, 0xff); } /* Magic ASN1 stuff */ memcpy(buf_getwriteptr(rsa_EM, RSA_ASN1_MAGIC_LEN), rsa_asn1_magic, RSA_ASN1_MAGIC_LEN); buf_incrwritepos(rsa_EM, RSA_ASN1_MAGIC_LEN); /* The hash of the data */ sha1_init(&hs); sha1_process(&hs, data, len); sha1_done(&hs, buf_getwriteptr(rsa_EM, SHA1_HASH_SIZE)); buf_incrwritepos(rsa_EM, SHA1_HASH_SIZE); assert(rsa_EM->pos == rsa_EM->size); /* Create the mp_int from the encoded bytes */ buf_setpos(rsa_EM, 0); rsa_em = (mp_int*)m_malloc(sizeof(mp_int)); m_mp_init(rsa_em); if (mp_read_unsigned_bin(rsa_em, buf_getptr(rsa_EM, rsa_EM->size), rsa_EM->size) != MP_OKAY) { dropbear_exit("rsa error"); } buf_free(rsa_EM); return rsa_em; } #endif /* DROPBEAR_RSA */