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564 lines
15 KiB
C
564 lines
15 KiB
C
/* keygen.c - generate a key pair
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* Copyright (c) 1997 by Werner Koch (dd9jn)
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*
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* This file is part of G10.
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*
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* G10 is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* G10 is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA
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*/
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#include <config.h>
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <errno.h>
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#include <assert.h>
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#include "util.h"
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#include "main.h"
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#include "packet.h"
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#include "cipher.h"
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#include "ttyio.h"
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#include "options.h"
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#include "keydb.h"
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#if 0
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#define TEST_ALGO 1
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#define TEST_NBITS 256
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#define TEST_UID "Karl Test"
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#endif
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static u16
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checksum_u16( unsigned n )
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{
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u16 a;
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a = (n >> 8) & 0xff;
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a |= n & 0xff;
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return a;
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}
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static u16
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checksum( byte *p, unsigned n )
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{
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u16 a;
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for(a=0; n; n-- )
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a += *p++;
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return a;
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}
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static u16
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checksum_mpi( MPI a )
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{
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u16 csum;
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byte *buffer;
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unsigned nbytes;
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buffer = mpi_get_buffer( a, &nbytes, NULL );
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csum = checksum_u16( nbytes*8 );
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csum += checksum( buffer, nbytes );
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m_free( buffer );
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return csum;
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}
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static void
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write_uid( KBNODE root, const char *s )
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{
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PACKET *pkt = m_alloc_clear(sizeof *pkt );
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size_t n = strlen(s);
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pkt->pkttype = PKT_USER_ID;
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pkt->pkt.user_id = m_alloc( sizeof *pkt->pkt.user_id + n - 1 );
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pkt->pkt.user_id->len = n;
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strcpy(pkt->pkt.user_id->name, s);
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add_kbnode( root, new_kbnode( pkt ) );
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}
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static int
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write_selfsig( KBNODE root, KBNODE pub_root, PKT_secret_cert *skc )
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{
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PACKET *pkt;
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PKT_signature *sig;
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PKT_user_id *uid;
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int rc=0;
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KBNODE kbctx, node;
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PKT_public_cert *pkc;
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if( opt.verbose )
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log_info("writing self signature\n");
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/* get the uid packet from the tree */
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for( kbctx=NULL; (node=walk_kbtree( root, &kbctx)) ; ) {
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if( node->pkt->pkttype == PKT_USER_ID )
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break;
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}
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if( !node )
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log_bug(NULL); /* no user id packet in tree */
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uid = node->pkt->pkt.user_id;
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/* get the pkc packet from the pub_tree */
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for( kbctx=NULL; (node=walk_kbtree( pub_root, &kbctx)) ; ) {
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if( node->pkt->pkttype == PKT_PUBLIC_CERT )
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break;
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}
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if( !node )
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log_bug(NULL);
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pkc = node->pkt->pkt.public_cert;
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/* and make the signature */
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rc = make_keysig_packet( &sig, pkc, uid, skc, 0x13, DIGEST_ALGO_RMD160 );
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if( rc ) {
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log_error("make_keysig_packet failed: %s\n", g10_errstr(rc) );
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return rc;
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}
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pkt = m_alloc_clear( sizeof *pkt );
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pkt->pkttype = PKT_SIGNATURE;
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pkt->pkt.signature = sig;
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add_kbnode( root, new_kbnode( pkt ) );
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return rc;
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}
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static int
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gen_elg(unsigned nbits, KBNODE pub_root, KBNODE sec_root, DEK *dek,
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PKT_secret_cert **ret_skc )
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{
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int rc;
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PACKET *pkt;
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PKT_secret_cert *skc;
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PKT_public_cert *pkc;
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ELG_public_key pk;
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ELG_secret_key sk;
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unsigned nbytes;
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elg_generate( &pk, &sk, nbits );
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skc = m_alloc( sizeof *skc );
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pkc = m_alloc( sizeof *pkc );
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skc->timestamp = pkc->timestamp = make_timestamp();
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skc->valid_days = pkc->valid_days = 0; /* fixme: make it configurable*/
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skc->pubkey_algo = pkc->pubkey_algo = PUBKEY_ALGO_ELGAMAL;
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memset(&pkc->mfx, 0, sizeof pkc->mfx);
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pkc->d.elg.p = pk.p;
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pkc->d.elg.g = pk.g;
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pkc->d.elg.y = pk.y;
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skc->d.elg.p = sk.p;
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skc->d.elg.g = sk.g;
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skc->d.elg.y = sk.y;
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skc->d.elg.x = sk.x;
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skc->d.elg.is_protected = 0;
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skc->d.elg.protect_algo = 0;
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skc->d.elg.csum = checksum_mpi( skc->d.elg.x );
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/* return an unprotected version of the skc */
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*ret_skc = copy_secret_cert( NULL, skc );
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if( dek ) {
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skc->d.elg.protect_algo = CIPHER_ALGO_BLOWFISH;
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randomize_buffer(skc->d.elg.protect.blowfish.iv, 8, 1);
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rc = protect_secret_key( skc, dek );
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if( rc ) {
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log_error("protect_secret_key failed: %s\n", g10_errstr(rc) );
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free_public_cert(pkc);
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free_secret_cert(skc);
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return rc;
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}
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}
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pkt = m_alloc_clear(sizeof *pkt);
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pkt->pkttype = PKT_PUBLIC_CERT;
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pkt->pkt.public_cert = pkc;
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add_kbnode(pub_root, new_kbnode( pkt ));
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pkt = m_alloc_clear(sizeof *pkt);
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pkt->pkttype = PKT_SECRET_CERT;
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pkt->pkt.secret_cert = skc;
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add_kbnode(sec_root, new_kbnode( pkt ));
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return 0;
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}
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#ifdef HAVE_RSA_CIPHER
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static int
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gen_rsa(unsigned nbits, IOBUF pub_io, IOBUF sec_io, DEK *dek,
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PKT_public_cert **ret_pkc, PKT_secret_cert **ret_skc )
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{
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int rc;
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PACKET pkt1, pkt2;
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PKT_secret_cert *skc;
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PKT_public_cert *pkc;
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RSA_public_key pk;
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RSA_secret_key sk;
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init_packet(&pkt1);
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init_packet(&pkt2);
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rsa_generate( &pk, &sk, nbits );
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skc = m_alloc( sizeof *skc );
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pkc = m_alloc( sizeof *pkc );
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skc->timestamp = pkc->timestamp = make_timestamp();
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skc->valid_days = pkc->valid_days = 0; /* fixme: make it configurable*/
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skc->pubkey_algo = pkc->pubkey_algo = PUBKEY_ALGO_RSA;
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memset(&pkc->mfx, 0, sizeof pkc->mfx);
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pkc->d.rsa.rsa_n = pk.n;
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pkc->d.rsa.rsa_e = pk.e;
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skc->d.rsa.rsa_n = sk.n;
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skc->d.rsa.rsa_e = sk.e;
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skc->d.rsa.rsa_d = sk.d;
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skc->d.rsa.rsa_p = sk.p;
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skc->d.rsa.rsa_q = sk.q;
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skc->d.rsa.rsa_u = sk.u;
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skc->d.rsa.csum = checksum_mpi( skc->d.rsa.rsa_d );
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skc->d.rsa.csum += checksum_mpi( skc->d.rsa.rsa_p );
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skc->d.rsa.csum += checksum_mpi( skc->d.rsa.rsa_q );
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skc->d.rsa.csum += checksum_mpi( skc->d.rsa.rsa_u );
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if( !dek ) {
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skc->d.rsa.is_protected = 0;
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skc->d.rsa.protect_algo = 0;
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}
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else {
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skc->d.rsa.is_protected = 1;
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skc->d.rsa.protect_algo = CIPHER_ALGO_BLOWFISH;
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randomize_buffer( skc->d.rsa.protect.blowfish.iv, 8, 1);
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skc->d.rsa.csum += checksum( skc->d.rsa.protect.blowfish.iv, 8 );
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rc = protect_secret_key( skc, dek );
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if( rc ) {
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log_error("protect_secret_key failed: %s\n", g10_errstr(rc) );
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goto leave;
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}
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}
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pkt1.pkttype = PKT_PUBLIC_CERT;
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pkt1.pkt.public_cert = pkc;
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pkt2.pkttype = PKT_SECRET_CERT;
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pkt2.pkt.secret_cert = skc;
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if( (rc = build_packet( pub_io, &pkt1 )) ) {
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log_error("build public_cert packet failed: %s\n", g10_errstr(rc) );
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goto leave;
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}
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if( (rc = build_packet( sec_io, &pkt2 )) ) {
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log_error("build secret_cert packet failed: %s\n", g10_errstr(rc) );
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goto leave;
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}
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*ret_pkc = pkt1.pkt.public_cert;
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pkt1.pkt.public_cert = NULL;
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*ret_skc = pkt1.pkt.secret_cert;
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pkt1.pkt.secret_cert = NULL;
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leave:
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free_packet(&pkt1);
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free_packet(&pkt2);
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return rc;
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}
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#endif /*HAVE_RSA_CIPHER*/
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static int
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gen_dsa(unsigned nbits, KBNODE pub_root, KBNODE sec_root, DEK *dek,
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PKT_secret_cert **ret_skc )
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{
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return G10ERR_GENERAL;
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}
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/****************
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* Generate a keypair
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*/
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void
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generate_keypair()
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{
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char *answer;
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unsigned nbits;
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char *pub_fname = NULL;
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char *sec_fname = NULL;
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char *uid = NULL;
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IOBUF pub_io = NULL;
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IOBUF sec_io = NULL;
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KBNODE pub_root = NULL;
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KBNODE sec_root = NULL;
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PKT_secret_cert *skc = NULL;
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DEK *dek = NULL;
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int rc;
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int algo;
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const char *algo_name;
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#ifndef TEST_ALGO
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if( opt.batch || opt.answer_yes || opt.answer_no )
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log_fatal("Key generation can only be used in interactive mode\n");
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tty_printf("Please select the algorithm to use:\n"
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" (1) ElGamal is the suggested one.\n"
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#ifdef HAVE_RSA_CIPHER
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" (2) RSA cannot be used in the U.S.\n"
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#endif
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" (3) DSA can only be used for signatures.\n"
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);
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#endif
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for(;;) {
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#ifdef TEST_ALGO
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algo = TEST_ALGO;
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#else
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answer = tty_get("Your selection? (1"
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#ifdef HAVE_RSA_CIPHER
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",2"
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#endif
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",3) ");
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tty_kill_prompt();
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algo = *answer? atoi(answer): 1;
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m_free(answer);
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#endif
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if( algo == 1 ) {
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algo = PUBKEY_ALGO_ELGAMAL;
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algo_name = "ElGamal";
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break;
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}
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#ifdef HAVE_RSA_CIPHER
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else if( algo == 2 ) {
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algo = PUBKEY_ALGO_RSA;
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algo_name = "RSA";
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break;
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}
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#endif
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else if( algo == 3 ) {
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algo = PUBKEY_ALGO_DSA;
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algo_name = "DSA";
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tty_printf("Sorry; DSA is not yet supported.\n");
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}
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}
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tty_printf("About to generate a new %s keypair.\n"
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#ifndef TEST_NBITS
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" minimum keysize is 768 bits\n"
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" default keysize is 1024 bits\n"
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" highest suggested keysize is 2048 bits\n"
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#endif
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, algo_name );
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for(;;) {
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#ifdef TEST_NBITS
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nbits = TEST_NBITS;
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#else
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answer = tty_get("What keysize do you want? (1024) ");
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tty_kill_prompt();
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nbits = *answer? atoi(answer): 1024;
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m_free(answer);
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#endif
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if( algo == PUBKEY_ALGO_DSA && (nbits < 512 || nbits > 1024) )
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tty_printf("DSA does only allow keysizes from 512 to 1024\n");
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else if( nbits < 768 )
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tty_printf("keysize too small; 768 is smallest value allowed.\n");
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else if( nbits > 2048 ) {
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tty_printf("Keysizes larger than 2048 are not suggested, because "
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"computations take REALLY long!\n");
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answer = tty_get("Are you sure, that you want this keysize? ");
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tty_kill_prompt();
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if( answer_is_yes(answer) ) {
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m_free(answer);
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tty_printf("Okay, but keep in mind that your monitor "
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"and keyboard radiation is also very vulnerable "
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"to attacks!\n");
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break;
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}
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m_free(answer);
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}
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else
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break;
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}
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tty_printf("Requested keysize is %u bits\n", nbits );
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if( algo == PUBKEY_ALGO_DSA && (nbits % 64) ) {
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nbits = ((nbits + 63) / 64) * 64;
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tty_printf("rounded up to %u bits\n", nbits );
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}
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else if( (nbits % 32) ) {
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nbits = ((nbits + 31) / 32) * 32;
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tty_printf("rounded up to %u bits\n", nbits );
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}
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#ifdef TEST_UID
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uid = m_alloc(strlen(TEST_UID)+1);
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strcpy(uid, TEST_UID);
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#else
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tty_printf( "\nYou need a User-ID to identify your key; please use your name and your\n"
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"email address in this suggested format:\n"
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" \"Heinrich Heine <heinrichh@uni-duesseldorf.de>\n" );
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uid = NULL;
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for(;;) {
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m_free(uid);
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tty_printf("\n");
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uid = tty_get("Your User-ID: ");
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tty_kill_prompt();
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if( strlen(uid) < 5 )
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tty_printf("Please enter a string of at least 5 characters\n");
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else {
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tty_printf("You selected this USER-ID:\n \"%s\"\n\n", uid);
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answer = tty_get("Is this correct? ");
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tty_kill_prompt();
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if( answer_is_yes(answer) ) {
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m_free(answer);
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break;
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}
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m_free(answer);
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}
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}
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#endif
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tty_printf( "You need a Passphrase to protect your secret key.\n\n" );
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dek = m_alloc_secure( sizeof *dek );
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for(;;) {
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dek->algo = CIPHER_ALGO_BLOWFISH;
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rc = make_dek_from_passphrase( dek , 2 );
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if( rc == -1 ) {
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m_free(dek); dek = NULL;
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tty_printf(
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"You don't what a passphrase - this is probably a *bad* idea!\n"
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"I will do it anyway. You can change your passphrase at anytime,\n"
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"using this program with the option \"--change-passphrase\"\n\n" );
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break;
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}
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else if( rc == G10ERR_PASSPHRASE ) {
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tty_printf("passphrase not correctly repeated; try again.\n");
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}
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else if( rc ) {
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m_free(dek); dek = NULL;
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m_free(uid);
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log_error("Error getting the passphrase: %s\n", g10_errstr(rc) );
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return;
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}
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else
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break; /* okay */
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}
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/* now check wether we a are allowed to write to the keyrings */
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pub_fname = make_filename("~/.g10", "pubring.g10", NULL );
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sec_fname = make_filename("~/.g10", "secring.g10", NULL );
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if( opt.verbose ) {
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tty_printf("writing public certificate to '%s'\n", pub_fname );
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tty_printf("writing secret certificate to '%s'\n", sec_fname );
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}
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/* we create the packets as a tree of kbnodes. Because the structure
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* we create is known in advance we simply generate a linked list
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* The first packet is a comment packet, followed by the userid and
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* the self signature.
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*/
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pub_root = make_comment_node("#created by G10 pre-release " VERSION );
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sec_root = make_comment_node("#created by G10 pre-release " VERSION );
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tty_printf(
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"We need to generate a lot of random bytes. It is a good idea to perform\n"
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"some other action (work in another window, move the mouse, utilize the\n"
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"network and the disks) during the prime generation; this gives the random\n"
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"number generator a better chance to gain enough entropy.\n" );
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if( algo == PUBKEY_ALGO_ELGAMAL )
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rc = gen_elg(nbits, pub_root, sec_root, dek, &skc );
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#ifdef HAVE_RSA_CIPHER
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else if( algo == PUBKEY_ALGO_RSA )
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rc = gen_rsa(nbits, pub_io, sec_io, dek, &skc );
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#endif
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else if( algo == PUBKEY_ALGO_DSA )
|
|
rc = gen_dsa(nbits, pub_root, sec_root, dek, &skc );
|
|
else
|
|
log_bug(NULL);
|
|
if( !rc )
|
|
write_uid(pub_root, uid );
|
|
if( !rc )
|
|
write_uid(sec_root, uid );
|
|
if( !rc )
|
|
rc = write_selfsig(pub_root, pub_root, skc);
|
|
if( !rc )
|
|
rc = write_selfsig(sec_root, pub_root, skc);
|
|
|
|
if( !rc ) {
|
|
KBPOS pub_kbpos;
|
|
KBPOS sec_kbpos;
|
|
int rc1 = -1;
|
|
int rc2 = -1;
|
|
|
|
/* we can now write the certificates */
|
|
/* FIXME: should we check wether the user-id already exists? */
|
|
|
|
if( get_keyblock_handle( pub_fname, &pub_kbpos ) ) {
|
|
if( add_keyblock_resource( pub_fname, 1 ) ) {
|
|
log_error("can add keyblock file '%s'\n", pub_fname );
|
|
rc = G10ERR_CREATE_FILE;
|
|
}
|
|
else if( get_keyblock_handle( pub_fname, &pub_kbpos ) ) {
|
|
log_error("can get keyblock handle for '%s'\n", pub_fname );
|
|
rc = G10ERR_CREATE_FILE;
|
|
}
|
|
}
|
|
if( rc )
|
|
;
|
|
else if( get_keyblock_handle( sec_fname, &sec_kbpos ) ) {
|
|
if( add_keyblock_resource( sec_fname, 1 ) ) {
|
|
log_error("can add keyblock file '%s'\n", sec_fname );
|
|
rc = G10ERR_CREATE_FILE;
|
|
}
|
|
else if( get_keyblock_handle( sec_fname, &sec_kbpos ) ) {
|
|
log_error("can get keyblock handle for '%s'\n", sec_fname );
|
|
rc = G10ERR_CREATE_FILE;
|
|
}
|
|
}
|
|
|
|
if( rc )
|
|
;
|
|
else if( (rc=rc1=lock_keyblock( &pub_kbpos )) )
|
|
log_error("can't lock public keyring: %s\n", g10_errstr(rc) );
|
|
else if( (rc=rc2=lock_keyblock( &sec_kbpos )) )
|
|
log_error("can't lock secret keyring: %s\n", g10_errstr(rc) );
|
|
else if( (rc=insert_keyblock( &pub_kbpos, pub_root )) )
|
|
log_error("can't write public key: %s\n", g10_errstr(rc) );
|
|
else if( (rc=insert_keyblock( &sec_kbpos, sec_root )) )
|
|
log_error("can't write secret key: %s\n", g10_errstr(rc) );
|
|
else {
|
|
tty_printf("public and secret key created and signed.\n" );
|
|
}
|
|
|
|
if( !rc1 )
|
|
unlock_keyblock( &pub_kbpos );
|
|
if( !rc2 )
|
|
unlock_keyblock( &sec_kbpos );
|
|
}
|
|
|
|
|
|
if( rc )
|
|
tty_printf("Key generation failed: %s\n", g10_errstr(rc) );
|
|
release_kbnode( pub_root );
|
|
release_kbnode( sec_root );
|
|
if( skc ) /* the unprotected secret certificate */
|
|
free_secret_cert(skc);
|
|
m_free(uid);
|
|
m_free(dek);
|
|
m_free(pub_fname);
|
|
m_free(sec_fname);
|
|
}
|
|
|