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//========================================================================== // // ./lib/current/src/keytools.c // // //========================================================================== //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos is free software; you can redistribute it and/or modify it under // the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 or (at your option) any later version. // // eCos 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 General Public License // for more details. // // You should have received a copy of the GNU General Public License along // with eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //####UCDSNMPCOPYRIGHTBEGIN#### // // ------------------------------------------- // // Portions of this software may have been derived from the UCD-SNMP // project, <http://ucd-snmp.ucdavis.edu/> from the University of // California at Davis, which was originally based on the Carnegie Mellon // University SNMP implementation. Portions of this software are therefore // covered by the appropriate copyright disclaimers included herein. // // The release used was version 4.1.2 of May 2000. "ucd-snmp-4.1.2" // ------------------------------------------- // //####UCDSNMPCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): hmt // Contributors: hmt // Date: 2000-05-30 // Purpose: Port of UCD-SNMP distribution to eCos. // Description: // // //####DESCRIPTIONEND#### // //========================================================================== /******************************************************************** Copyright 1989, 1991, 1992 by Carnegie Mellon University Derivative Work - Copyright 1996, 1998, 1999, 2000 The Regents of the University of California All Rights Reserved Permission to use, copy, modify and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appears in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of CMU and The Regents of the University of California not be used in advertising or publicity pertaining to distribution of the software without specific written permission. CMU AND THE REGENTS OF THE UNIVERSITY OF CALIFORNIA DISCLAIM ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL CMU OR THE REGENTS OF THE UNIVERSITY OF CALIFORNIA BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM THE LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. *********************************************************************/ /* * keytools.c */ #include <config.h> #ifdef CYGPKG_SNMPAGENT_V3_SUPPORT #include <stdio.h> #include <sys/types.h> #if HAVE_WINSOCK_H #include <winsock.h> #endif #ifdef HAVE_NETINET_IN_H #include <netinet/in.h> #endif #ifdef HAVE_STDLIB_H #include <stdlib.h> #endif #if HAVE_STRING_H #include <string.h> #else #include <strings.h> #endif #if HAVE_DMALLOC_H #include <dmalloc.h> #endif #include "asn1.h" #include "snmp_api.h" #ifdef USE_OPENSSL # include <openssl/hmac.h> #else #ifdef USE_INTERNAL_MD5 #include "md5.h" #endif #endif #include "scapi.h" #include "keytools.h" #include "tools.h" #include "snmp_debug.h" #include "snmp_logging.h" #include "transform_oids.h" /*******************************************************************-o-****** * generate_Ku * * Parameters: * *hashtype MIB OID for the transform type for hashing. * hashtype_len Length of OID value. * *P Pre-allocated bytes of passpharase. * pplen Length of passphrase. * *Ku Buffer to contain Ku. * *kulen Length of Ku buffer. * * Returns: * SNMPERR_SUCCESS Success. * SNMPERR_GENERR All errors. * * * Convert a passphrase into a master user key, Ku, according to the * algorithm given in RFC 2274 concerning the SNMPv3 User Security Model (USM) * as follows: * * Expand the passphrase to fill the passphrase buffer space, if necessary, * concatenation as many duplicates as possible of P to itself. If P is * larger than the buffer space, truncate it to fit. * * Then hash the result with the given hashtype transform. Return * the result as Ku. * * If successful, kulen contains the size of the hash written to Ku. * * NOTE Passphrases less than USM_LENGTH_P_MIN characters in length * cause an error to be returned. * (Punt this check to the cmdline apps? XXX) */ int generate_Ku( oid *hashtype, u_int hashtype_len, u_char *P, size_t pplen, u_char *Ku, size_t *kulen) #if defined(USE_INTERNAL_MD5) || defined(USE_OPENSSL) { int rval = SNMPERR_SUCCESS, nbytes = USM_LENGTH_EXPANDED_PASSPHRASE; u_int i, pindex = 0; u_char buf[USM_LENGTH_KU_HASHBLOCK], *bufp; #ifdef USE_OPENSSL EVP_MD_CTX *ctx = malloc(sizeof(EVP_MD_CTX)); #else MDstruct MD; #endif /* * Sanity check. */ if ( !hashtype || !P || !Ku || !kulen || (*kulen<=0) || (hashtype_len != USM_LENGTH_OID_TRANSFORM) ) { QUITFUN(SNMPERR_GENERR, generate_Ku_quit); } if (pplen < USM_LENGTH_P_MIN) { #ifdef SNMP_TESTING_CODE snmp_log(LOG_WARNING, "Warning: passphrase chosen is below the length requiremnts of the USM.\n"); #else snmp_set_detail("Password length too short."); QUITFUN(SNMPERR_GENERR, generate_Ku_quit); #endif } /* * Setup for the transform type. */ #ifdef USE_OPENSSL if (ISTRANSFORM(hashtype, HMACMD5Auth)) EVP_DigestInit(ctx, EVP_md5()); else if (ISTRANSFORM(hashtype, HMACSHA1Auth)) EVP_DigestInit(ctx, EVP_sha1()); else { free(ctx); return (SNMPERR_GENERR); } #else MDbegin(&MD); #endif /* USE_OPENSSL */ while (nbytes > 0) { bufp = buf; for (i = 0; i < USM_LENGTH_KU_HASHBLOCK; i++) { *bufp++ = P[pindex++ % pplen]; } #ifdef USE_OPENSSL EVP_DigestUpdate(ctx, buf, USM_LENGTH_KU_HASHBLOCK); #else if (MDupdate(&MD, buf, USM_LENGTH_KU_HASHBLOCK*8)) { rval = SNMPERR_USM_ENCRYPTIONERROR; goto md5_fin; } #endif /* USE_OPENSSL */ nbytes -= USM_LENGTH_KU_HASHBLOCK; } #ifdef USE_OPENSSL EVP_DigestFinal(ctx, (unsigned char *) Ku, (unsigned int *) kulen); /* what about free() */ #else if (MDupdate(&MD, buf, 0)) { rval = SNMPERR_USM_ENCRYPTIONERROR; goto md5_fin; } *kulen = sc_get_properlength(hashtype, hashtype_len); MDget(&MD, Ku, *kulen); md5_fin: memset(&MD, 0, sizeof(MD)); #endif /* USE_OPENSSL */ #ifdef SNMP_TESTING_CODE DEBUGMSGTL(("generate_Ku", "generating Ku (from %s): ", P)); for(i=0; i < *kulen; i++) DEBUGMSG(("generate_Ku", "%02x",Ku[i])); DEBUGMSG(("generate_Ku","\n")); #endif /* SNMP_TESTING_CODE */ generate_Ku_quit: memset(buf, 0, sizeof(buf)); #ifdef USE_OPENSSL free(ctx); #endif return rval; } /* end generate_Ku() */ #else _KEYTOOLS_NOT_AVAILABLE #endif /* internal or openssl */ /*******************************************************************-o-****** * generate_kul * * Parameters: * *hashtype * hashtype_len * *engineID * engineID_len * *Ku Master key for a given user. * ku_len Length of Ku in bytes. * *Kul Localized key for a given user at engineID. * *kul_len Length of Kul buffer (IN); Length of Kul key (OUT). * * Returns: * SNMPERR_SUCCESS Success. * SNMPERR_GENERR All errors. * * * Ku MUST be the proper length (currently fixed) for the given hashtype. * * Upon successful return, Kul contains the localized form of Ku at * engineID, and the length of the key is stored in kul_len. * * The localized key method is defined in RFC2274, Sections 2.6 and A.2, and * originally documented in: * U. Blumenthal, N. C. Hien, B. Wijnen, * "Key Derivation for Network Management Applications", * IEEE Network Magazine, April/May issue, 1997. * * * ASSUMES SNMP_MAXBUF >= sizeof(Ku + engineID + Ku). * * NOTE Localized keys for privacy transforms are generated via * the authentication transform held by the same usmUser. * * XXX An engineID of any length is accepted, even if larger than * what is spec'ed for the textual convention. */ int generate_kul( oid *hashtype, u_int hashtype_len, u_char *engineID, size_t engineID_len, u_char *Ku, size_t ku_len, u_char *Kul, size_t *kul_len) #if defined(USE_OPENSSL) || defined(USE_INTERNAL_MD5) { int rval = SNMPERR_SUCCESS; u_int nbytes = 0; size_t properlength; u_char buf[SNMP_MAXBUF]; void *context = NULL; #ifdef SNMP_TESTING_CODE int i; #endif /* * Sanity check. */ if ( !hashtype || !engineID || !Ku || !Kul || !kul_len || (engineID_len<=0) || (ku_len<=0) || (*kul_len<=0) || (hashtype_len != USM_LENGTH_OID_TRANSFORM) ) { QUITFUN(SNMPERR_GENERR, generate_kul_quit); } properlength = sc_get_properlength(hashtype, hashtype_len); if (properlength == SNMPERR_GENERR) QUITFUN(SNMPERR_GENERR, generate_kul_quit); if (((int)*kul_len < properlength) || ((int)ku_len < properlength) ) { QUITFUN(SNMPERR_GENERR, generate_kul_quit); } /* * Concatenate Ku and engineID properly, then hash the result. * Store it in Kul. */ nbytes = 0; memcpy(buf, Ku, properlength); nbytes += properlength; memcpy(buf+nbytes, engineID, engineID_len); nbytes += engineID_len; memcpy(buf+nbytes, Ku, properlength); nbytes += properlength; rval = sc_hash(hashtype, hashtype_len, buf, nbytes, Kul, kul_len); #ifdef SNMP_TESTING_CODE DEBUGMSGTL(("generate_kul", "generating Kul (from Ku): ")); for(i=0; i < *kul_len; i++) DEBUGMSG(("generate_kul", "%02x",Kul[i])); DEBUGMSG(("generate_kul", "keytools\n")); #endif /* SNMP_TESTING_CODE */ QUITFUN(rval, generate_kul_quit); generate_kul_quit: SNMP_FREE(context); return rval; } /* end generate_kul() */ #else _KEYTOOLS_NOT_AVAILABLE #endif /* internal or openssl */ /*******************************************************************-o-****** * encode_keychange * * Parameters: * *hashtype MIB OID for the hash transform type. * hashtype_len Length of the MIB OID hash transform type. * *oldkey Old key that is used to encodes the new key. * oldkey_len Length of oldkey in bytes. * *newkey New key that is encoded using the old key. * newkey_len Length of new key in bytes. * *kcstring Buffer to contain the KeyChange TC string. * *kcstring_len Length of kcstring buffer. * * Returns: * SNMPERR_SUCCESS Success. * SNMPERR_GENERR All errors. * * * Uses oldkey and acquired random bytes to encode newkey into kcstring * according to the rules of the KeyChange TC described in RFC 2274, Section 5. * * Upon successful return, *kcstring_len contains the length of the * encoded string. * * ASSUMES Old and new key are always equal to each other, although * this may be less than the transform type hash output * output length (eg, using KeyChange for a DESPriv key when * the user also uses SHA1Auth). This also implies that the * hash placed in the second 1/2 of the key change string * will be truncated before the XOR'ing when the hash output is * larger than that 1/2 of the key change string. * * *kcstring_len will be returned as exactly twice that same * length though the input buffer may be larger. * * XXX FIX: Does not handle varibable length keys. * XXX FIX: Does not handle keys larger than the hash algorithm used. */ int encode_keychange( oid *hashtype, u_int hashtype_len, u_char *oldkey, size_t oldkey_len, u_char *newkey, size_t newkey_len, u_char *kcstring, size_t *kcstring_len) #if defined(USE_OPENSSL) || defined(USE_INTERNAL_MD5) { int rval = SNMPERR_SUCCESS; size_t properlength; size_t nbytes = 0; u_char *tmpbuf = NULL; void *context = NULL; /* * Sanity check. */ if ( !hashtype || !oldkey || !newkey || !kcstring || !kcstring_len || (oldkey_len<=0) || (newkey_len<=0) || (*kcstring_len<=0) || (hashtype_len != USM_LENGTH_OID_TRANSFORM) ) { QUITFUN(SNMPERR_GENERR, encode_keychange_quit); } /* * Setup for the transform type. */ properlength = sc_get_properlength(hashtype, hashtype_len); if (properlength == SNMPERR_GENERR) QUITFUN(SNMPERR_GENERR, encode_keychange_quit); if ( (oldkey_len != newkey_len) || (*kcstring_len < (2*oldkey_len)) ) { QUITFUN(SNMPERR_GENERR, encode_keychange_quit); } properlength = SNMP_MIN((int)oldkey_len, properlength); /* * Use the old key and some random bytes to encode the new key * in the KeyChange TC format: * . Get random bytes (store in first half of kcstring), * . Hash (oldkey | random_bytes) (into second half of kcstring), * . XOR hash and newkey (into second half of kcstring). * * Getting the wrong number of random bytes is considered an error. */ nbytes = properlength; #if defined(SNMP_TESTING_CODE) && defined(RANDOMZEROS) memset(kcstring, 0, nbytes); DEBUGMSG(("encode_keychange", "** Using all zero bits for \"random\" delta of )" "the keychange string! **\n")); #else /* !SNMP_TESTING_CODE */ rval = sc_random(kcstring, &nbytes); QUITFUN(rval, encode_keychange_quit); if ((int)nbytes != properlength) { QUITFUN(SNMPERR_GENERR, encode_keychange_quit); } #endif /* !SNMP_TESTING_CODE */ tmpbuf = (u_char *)malloc(properlength*2); if (tmpbuf) { memcpy(tmpbuf, oldkey, properlength); memcpy(tmpbuf+properlength, kcstring, properlength); *kcstring_len -= properlength; rval = sc_hash(hashtype, hashtype_len, tmpbuf, properlength*2, kcstring+properlength, kcstring_len); QUITFUN(rval, encode_keychange_quit); *kcstring_len = (properlength*2); kcstring += properlength; nbytes = 0; while ((int)(nbytes++) < properlength) { u_char kcs = *kcstring; *kcstring++ = kcs ^ *newkey++; } } encode_keychange_quit: if (rval != SNMPERR_SUCCESS) memset(kcstring, 0, *kcstring_len); SNMP_FREE(tmpbuf); SNMP_FREE(context); return rval; } /* end encode_keychange() */ #else _KEYTOOLS_NOT_AVAILABLE #endif /* internal or openssl */ /*******************************************************************-o-****** * decode_keychange * * Parameters: * *hashtype MIB OID of the hash transform to use. * hashtype_len Length of the hash transform MIB OID. * *oldkey Old key that is used to encode the new key. * oldkey_len Length of oldkey in bytes. * *kcstring Encoded KeyString buffer containing the new key. * kcstring_len Length of kcstring in bytes. * *newkey Buffer to hold the extracted new key. * *newkey_len Length of newkey in bytes. * * Returns: * SNMPERR_SUCCESS Success. * SNMPERR_GENERR All errors. * * * Decodes a string of bits encoded according to the KeyChange TC described * in RFC 2274, Section 5. The new key is extracted from *kcstring with * the aid of the old key. * * Upon successful return, *newkey_len contains the length of the new key. * * * ASSUMES Old key is exactly 1/2 the length of the KeyChange buffer, * although this length may be less than the hash transform * output. Thus the new key length will be equal to the old * key length. */ /* XXX: if the newkey is not long enough, it should be freed and remalloced */ int decode_keychange( oid *hashtype, u_int hashtype_len, u_char *oldkey, size_t oldkey_len, u_char *kcstring, size_t kcstring_len, u_char *newkey, size_t *newkey_len) #if defined(USE_OPENSSL) || defined(USE_INTERNAL_MD5) { int rval = SNMPERR_SUCCESS; size_t properlength = 0; u_int nbytes = 0; u_char *bufp, tmp_buf[SNMP_MAXBUF]; size_t tmp_buf_len = SNMP_MAXBUF; void *context = NULL; u_char *tmpbuf = NULL; /* * Sanity check. */ if ( !hashtype || !oldkey || !kcstring || !newkey || !newkey_len || (oldkey_len<=0) || (kcstring_len<=0) || (*newkey_len<=0) || (hashtype_len != USM_LENGTH_OID_TRANSFORM) ) { QUITFUN(SNMPERR_GENERR, decode_keychange_quit); } /* * Setup for the transform type. */ properlength = sc_get_properlength(hashtype, hashtype_len); if (properlength == SNMPERR_GENERR) QUITFUN(SNMPERR_GENERR, decode_keychange_quit); if ( ((oldkey_len*2) != kcstring_len) || (*newkey_len < oldkey_len) ) { QUITFUN(SNMPERR_GENERR, decode_keychange_quit); } properlength = oldkey_len; *newkey_len = properlength; /* * Use the old key and the given KeyChange TC string to recover * the new key: * . Hash (oldkey | random_bytes) (into newkey), * . XOR hash and encoded (second) half of kcstring (into newkey). */ tmpbuf = (u_char *)malloc(properlength*2); if (tmpbuf) { memcpy(tmpbuf, oldkey, properlength); memcpy(tmpbuf+properlength, kcstring, properlength); rval = sc_hash(hashtype, hashtype_len, tmpbuf, properlength*2, tmp_buf, &tmp_buf_len); QUITFUN(rval, decode_keychange_quit); memcpy(newkey, tmp_buf, properlength); bufp = kcstring+properlength; nbytes = 0; while ((int)(nbytes++) < properlength) { u_char nk = *newkey; *newkey++ = nk ^ *bufp++; } } decode_keychange_quit: if (rval != SNMPERR_SUCCESS) { memset(newkey, 0, properlength); } memset(tmp_buf, 0, SNMP_MAXBUF); SNMP_FREE(context); if (tmpbuf != NULL) SNMP_FREE(tmpbuf); return rval; } /* end decode_keychange() */ #else _KEYTOOLS_NOT_AVAILABLE #endif /* internal or openssl */ #endif /* CYGPKG_SNMPAGENT_V3_SUPPORT */