/* keygen.c - generate a key pair * Copyright (C) 1998, 1999, 2000, 2001, 2002 Free Software Foundation, Inc. * * This file is part of GnuPG. * * GnuPG 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 of the License, or * (at your option) any later version. * * GnuPG 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 this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA */ #include #include #include #include #include #include #include #include "util.h" #include "main.h" #include "packet.h" #include "cipher.h" #include "ttyio.h" #include "options.h" #include "keydb.h" #include "trustdb.h" #include "status.h" #include "i18n.h" #define MAX_PREFS 30 enum para_name { pKEYTYPE, pKEYLENGTH, pKEYUSAGE, pSUBKEYTYPE, pSUBKEYLENGTH, pSUBKEYUSAGE, pNAMEREAL, pNAMEEMAIL, pNAMECOMMENT, pPREFERENCES, pREVOKER, pUSERID, pEXPIREDATE, pKEYEXPIRE, /* in n seconds */ pSUBKEYEXPIRE, /* in n seconds */ pPASSPHRASE, pPASSPHRASE_DEK, pPASSPHRASE_S2K }; struct para_data_s { struct para_data_s *next; int lnr; enum para_name key; union { DEK *dek; STRING2KEY *s2k; u32 expire; unsigned int usage; struct revocation_key revkey; char value[1]; } u; }; struct output_control_s { int lnr; int dryrun; int use_files; struct { char *fname; char *newfname; IOBUF stream; armor_filter_context_t afx; } pub; struct { char *fname; char *newfname; IOBUF stream; armor_filter_context_t afx; } sec; }; struct opaque_data_usage_and_pk { unsigned int usage; PKT_public_key *pk; }; static int prefs_initialized = 0; static byte sym_prefs[MAX_PREFS]; static int nsym_prefs; static byte hash_prefs[MAX_PREFS]; static int nhash_prefs; static byte zip_prefs[MAX_PREFS]; static int nzip_prefs; static int mdc_available; static void do_generate_keypair( struct para_data_s *para, struct output_control_s *outctrl ); static int write_keyblock( IOBUF out, KBNODE node ); static void write_uid( KBNODE root, const char *s ) { PACKET *pkt = m_alloc_clear(sizeof *pkt ); size_t n = strlen(s); pkt->pkttype = PKT_USER_ID; pkt->pkt.user_id = m_alloc_clear( sizeof *pkt->pkt.user_id + n - 1 ); pkt->pkt.user_id->len = n; pkt->pkt.user_id->ref = 1; strcpy(pkt->pkt.user_id->name, s); add_kbnode( root, new_kbnode( pkt ) ); } static void do_add_key_flags (PKT_signature *sig, unsigned int use) { byte buf[1]; if (!use) return; buf[0] = 0; if (use & PUBKEY_USAGE_SIG) buf[0] |= 0x01 | 0x02; if (use & PUBKEY_USAGE_ENC) buf[0] |= 0x04 | 0x08; build_sig_subpkt (sig, SIGSUBPKT_KEY_FLAGS, buf, 1); } int keygen_add_key_expire( PKT_signature *sig, void *opaque ) { PKT_public_key *pk = opaque; byte buf[8]; u32 u; if( pk->expiredate ) { u = pk->expiredate > pk->timestamp? pk->expiredate - pk->timestamp : pk->timestamp; buf[0] = (u >> 24) & 0xff; buf[1] = (u >> 16) & 0xff; buf[2] = (u >> 8) & 0xff; buf[3] = u & 0xff; build_sig_subpkt( sig, SIGSUBPKT_KEY_EXPIRE, buf, 4 ); } return 0; } static int keygen_add_key_flags_and_expire (PKT_signature *sig, void *opaque) { struct opaque_data_usage_and_pk *oduap = opaque; do_add_key_flags (sig, oduap->usage); return keygen_add_key_expire (sig, oduap->pk); } static int set_one_pref (ulong val, int type, int (*cf)(int), byte *buf, int *nbuf) { int i; if (cf (val)) { log_info (_("preference %c%lu is not valid\n"), type, val); if(type=='S' && val==CIPHER_ALGO_IDEA) idea_cipher_warn(1); return -1; } for (i=0; i < *nbuf; i++ ) { if (buf[i] == val) { log_info (_("preference %c%lu duplicated\n"), type, val); return -1; } } if (*nbuf >= MAX_PREFS) { log_info (_("too many `%c' preferences\n"), type); return -1; } buf[(*nbuf)++] = val; return 0; } static int check_zip_algo (int algo) { return algo < 0 || algo > 2; } /* * Parse the supplied string and use it to set the standard preferences. * The String is expected to be in a forma like the one printed by "prefs", * something like: "S10 S3 H3 H2 Z2 Z1". Use NULL to set the default * preferences. * Returns: 0 = okay */ int keygen_set_std_prefs (const char *string,int personal) { byte sym[MAX_PREFS], hash[MAX_PREFS], zip[MAX_PREFS]; int nsym=0, nhash=0, nzip=0, mdc=1; /* mdc defaults on */ ulong val; const char *s, *s2; int rc = 0; if (!string || !ascii_strcasecmp (string, "default")) { if (opt.def_preference_list) string=opt.def_preference_list; else if ( !check_cipher_algo(CIPHER_ALGO_IDEA) ) string = "S7 S3 S2 S1 H2 H3 Z2 Z1"; else string = "S7 S3 S2 H2 H3 Z2 Z1"; /* If we have it, IDEA goes *after* 3DES so it won't be used unless we're encrypting along with a V3 key. Ideally, we would only put the S1 preference in if the key was RSA and <=2048 bits, as that is what won't break PGP2, but that is difficult with the current code, and not really worth checking as a non-RSA <=2048 bit key wouldn't be usable by PGP2 anyway -dms */ } else if (!ascii_strcasecmp (string, "none")) string = ""; for (s=string; *s; s = s2) { if ((*s=='s' || *s == 'S') && isdigit(s[1]) ) { val = strtoul (++s, (char**)&s2, 10); if (set_one_pref (val, 'S', check_cipher_algo, sym, &nsym)) rc = -1; } else if ((*s=='h' || *s == 'H') && isdigit(s[1]) ) { val = strtoul (++s, (char**)&s2, 10); if (set_one_pref (val, 'H', check_digest_algo, hash, &nhash)) rc = -1; } else if ((*s=='z' || *s == 'Z') && isdigit(s[1]) ) { val = strtoul (++s, (char**)&s2, 10); if (set_one_pref (val, 'Z', check_zip_algo, zip, &nzip)) rc = -1; } else if (ascii_strcasecmp(s,"mdc")==0) { mdc=1; s2=s+3; } else if (ascii_strcasecmp(s,"no-mdc")==0) { mdc=0; s2=s+6; } else if (isspace (*s)) s2 = s+1; else { log_info (_("invalid character in preference string\n")); return -1; } } if (!rc) { if(personal) { m_free(opt.personal_prefs); if((nsym+nhash+nzip)==0) opt.personal_prefs=NULL; else { int i,n=0; opt.personal_prefs=m_alloc(sizeof(prefitem_t *)*(nsym+nhash+nzip+1)); for (i=0; ihashed, SIGSUBPKT_FEATURES, &n ); /* Already set or cleared */ if (s && n && ((enabled && (s[0] & 0x01)) || (!enabled && !(s[0] & 0x01)))) return; if (!s || !n) { /* create a new one */ n = 1; buf = m_alloc_clear (n); } else { buf = m_alloc (n); memcpy (buf, s, n); } if(enabled) buf[0] |= 0x01; /* MDC feature */ else buf[0] &= ~0x01; /* Are there any bits set? */ for(i=0;ihashed, SIGSUBPKT_FEATURES); else build_sig_subpkt (sig, SIGSUBPKT_FEATURES, buf, n); m_free (buf); } int keygen_upd_std_prefs( PKT_signature *sig, void *opaque ) { if (!prefs_initialized) keygen_set_std_prefs (NULL, 0); if (nsym_prefs) build_sig_subpkt (sig, SIGSUBPKT_PREF_SYM, sym_prefs, nsym_prefs); else { delete_sig_subpkt (sig->hashed, SIGSUBPKT_PREF_SYM); delete_sig_subpkt (sig->unhashed, SIGSUBPKT_PREF_SYM); } if (nhash_prefs) build_sig_subpkt (sig, SIGSUBPKT_PREF_HASH, hash_prefs, nhash_prefs); else { delete_sig_subpkt (sig->hashed, SIGSUBPKT_PREF_HASH); delete_sig_subpkt (sig->unhashed, SIGSUBPKT_PREF_HASH); } if (nzip_prefs) build_sig_subpkt (sig, SIGSUBPKT_PREF_COMPR, zip_prefs, nzip_prefs); else { delete_sig_subpkt (sig->hashed, SIGSUBPKT_PREF_COMPR); delete_sig_subpkt (sig->unhashed, SIGSUBPKT_PREF_COMPR); } /* Make sure that the MDC feature flag is set if needed */ add_feature_mdc (sig,mdc_available); return 0; } /**************** * Add preference to the self signature packet. * This is only called for packets with version > 3. */ int keygen_add_std_prefs( PKT_signature *sig, void *opaque ) { PKT_public_key *pk = opaque; byte buf[8]; do_add_key_flags (sig, pk->pubkey_usage); keygen_add_key_expire( sig, opaque ); keygen_upd_std_prefs (sig, opaque); buf[0] = 0x80; /* no modify - It is reasonable that a key holder * has the possibility to reject signatures from users * who are known to sign everything without any * validation - so a signed key should be send * to the holder who in turn can put it on a keyserver */ build_sig_subpkt( sig, SIGSUBPKT_KS_FLAGS, buf, 1 ); return 0; } int keygen_add_revkey(PKT_signature *sig, void *opaque) { struct revocation_key *revkey=opaque; byte buf[2+MAX_FINGERPRINT_LEN]; buf[0]=revkey->class; buf[1]=revkey->algid; memcpy(&buf[2],revkey->fpr,MAX_FINGERPRINT_LEN); build_sig_subpkt(sig,SIGSUBPKT_REV_KEY,buf,2+MAX_FINGERPRINT_LEN); sig->revkey=m_realloc(sig->revkey, sizeof(struct revocation_key *)*(sig->numrevkeys+1)); /* All sigs with revocation keys set are nonrevocable */ sig->flags.revocable=0; buf[0] = 0; build_sig_subpkt( sig, SIGSUBPKT_REVOCABLE, buf, 1 ); parse_revkeys(sig); return 0; } static int write_direct_sig( KBNODE root, KBNODE pub_root, PKT_secret_key *sk, struct revocation_key *revkey ) { PACKET *pkt; PKT_signature *sig; int rc=0; KBNODE node; PKT_public_key *pk; if( opt.verbose ) log_info(_("writing direct signature\n")); /* get the pk packet from the pub_tree */ node = find_kbnode( pub_root, PKT_PUBLIC_KEY ); if( !node ) BUG(); pk = node->pkt->pkt.public_key; /* we have to cache the key, so that the verification of the signature * creation is able to retrieve the public key */ cache_public_key (pk); /* and make the signature */ rc = make_keysig_packet(&sig,pk,NULL,NULL,sk,0x1F,0,0,0,0, keygen_add_revkey,revkey); if( rc ) { log_error("make_keysig_packet failed: %s\n", g10_errstr(rc) ); return rc; } pkt = m_alloc_clear( sizeof *pkt ); pkt->pkttype = PKT_SIGNATURE; pkt->pkt.signature = sig; add_kbnode( root, new_kbnode( pkt ) ); return rc; } static int write_selfsig( KBNODE root, KBNODE pub_root, PKT_secret_key *sk, unsigned int use ) { PACKET *pkt; PKT_signature *sig; PKT_user_id *uid; int rc=0; KBNODE node; PKT_public_key *pk; if( opt.verbose ) log_info(_("writing self signature\n")); /* get the uid packet from the list */ node = find_kbnode( root, PKT_USER_ID ); if( !node ) BUG(); /* no user id packet in tree */ uid = node->pkt->pkt.user_id; /* get the pk packet from the pub_tree */ node = find_kbnode( pub_root, PKT_PUBLIC_KEY ); if( !node ) BUG(); pk = node->pkt->pkt.public_key; pk->pubkey_usage = use; /* we have to cache the key, so that the verification of the signature * creation is able to retrieve the public key */ cache_public_key (pk); /* and make the signature */ rc = make_keysig_packet( &sig, pk, uid, NULL, sk, 0x13, 0, 0, 0, 0, keygen_add_std_prefs, pk ); if( rc ) { log_error("make_keysig_packet failed: %s\n", g10_errstr(rc) ); return rc; } pkt = m_alloc_clear( sizeof *pkt ); pkt->pkttype = PKT_SIGNATURE; pkt->pkt.signature = sig; add_kbnode( root, new_kbnode( pkt ) ); return rc; } static int write_keybinding( KBNODE root, KBNODE pub_root, PKT_secret_key *sk, unsigned int use ) { PACKET *pkt; PKT_signature *sig; int rc=0; KBNODE node; PKT_public_key *pk, *subpk; struct opaque_data_usage_and_pk oduap; if( opt.verbose ) log_info(_("writing key binding signature\n")); /* get the pk packet from the pub_tree */ node = find_kbnode( pub_root, PKT_PUBLIC_KEY ); if( !node ) BUG(); pk = node->pkt->pkt.public_key; /* we have to cache the key, so that the verification of the signature * creation is able to retrieve the public key */ cache_public_key (pk); /* find the last subkey */ subpk = NULL; for(node=pub_root; node; node = node->next ) { if( node->pkt->pkttype == PKT_PUBLIC_SUBKEY ) subpk = node->pkt->pkt.public_key; } if( !subpk ) BUG(); /* and make the signature */ oduap.usage = use; oduap.pk = subpk; rc = make_keysig_packet( &sig, pk, NULL, subpk, sk, 0x18, 0, 0, 0, 0, keygen_add_key_flags_and_expire, &oduap ); if( rc ) { log_error("make_keysig_packet failed: %s\n", g10_errstr(rc) ); return rc; } pkt = m_alloc_clear( sizeof *pkt ); pkt->pkttype = PKT_SIGNATURE; pkt->pkt.signature = sig; add_kbnode( root, new_kbnode( pkt ) ); return rc; } static int gen_elg(int algo, unsigned nbits, KBNODE pub_root, KBNODE sec_root, DEK *dek, STRING2KEY *s2k, PKT_secret_key **ret_sk, u32 expireval ) { int rc; int i; PACKET *pkt; PKT_secret_key *sk; PKT_public_key *pk; MPI skey[4]; MPI *factors; assert( is_ELGAMAL(algo) ); if( nbits < 512 ) { nbits = 1024; log_info(_("keysize invalid; using %u bits\n"), nbits ); } if( (nbits % 32) ) { nbits = ((nbits + 31) / 32) * 32; log_info(_("keysize rounded up to %u bits\n"), nbits ); } rc = pubkey_generate( algo, nbits, skey, &factors ); if( rc ) { log_error("pubkey_generate failed: %s\n", g10_errstr(rc) ); return rc; } sk = m_alloc_clear( sizeof *sk ); pk = m_alloc_clear( sizeof *pk ); sk->timestamp = pk->timestamp = make_timestamp(); sk->version = pk->version = 4; if( expireval ) { sk->expiredate = pk->expiredate = sk->timestamp + expireval; } sk->pubkey_algo = pk->pubkey_algo = algo; pk->pkey[0] = mpi_copy( skey[0] ); pk->pkey[1] = mpi_copy( skey[1] ); pk->pkey[2] = mpi_copy( skey[2] ); sk->skey[0] = skey[0]; sk->skey[1] = skey[1]; sk->skey[2] = skey[2]; sk->skey[3] = skey[3]; sk->is_protected = 0; sk->protect.algo = 0; sk->csum = checksum_mpi_counted_nbits( sk->skey[3] ); if( ret_sk ) /* not a subkey: return an unprotected version of the sk */ *ret_sk = copy_secret_key( NULL, sk ); if( dek ) { sk->protect.algo = dek->algo; sk->protect.s2k = *s2k; rc = protect_secret_key( sk, dek ); if( rc ) { log_error("protect_secret_key failed: %s\n", g10_errstr(rc) ); free_public_key(pk); free_secret_key(sk); return rc; } } pkt = m_alloc_clear(sizeof *pkt); pkt->pkttype = ret_sk ? PKT_PUBLIC_KEY : PKT_PUBLIC_SUBKEY; pkt->pkt.public_key = pk; add_kbnode(pub_root, new_kbnode( pkt )); /* don't know whether it makes sense to have the factors, so for now * we store them in the secret keyring (but they are not secret) */ pkt = m_alloc_clear(sizeof *pkt); pkt->pkttype = ret_sk ? PKT_SECRET_KEY : PKT_SECRET_SUBKEY; pkt->pkt.secret_key = sk; add_kbnode(sec_root, new_kbnode( pkt )); for(i=0; factors[i]; i++ ) add_kbnode( sec_root, make_mpi_comment_node("#:ELG_factor:", factors[i] )); return 0; } /**************** * Generate a DSA key */ static int gen_dsa(unsigned int nbits, KBNODE pub_root, KBNODE sec_root, DEK *dek, STRING2KEY *s2k, PKT_secret_key **ret_sk, u32 expireval ) { int rc; int i; PACKET *pkt; PKT_secret_key *sk; PKT_public_key *pk; MPI skey[5]; MPI *factors; if( nbits > 1024 || nbits < 512 ) { nbits = 1024; log_info(_("keysize invalid; using %u bits\n"), nbits ); } if( (nbits % 64) ) { nbits = ((nbits + 63) / 64) * 64; log_info(_("keysize rounded up to %u bits\n"), nbits ); } rc = pubkey_generate( PUBKEY_ALGO_DSA, nbits, skey, &factors ); if( rc ) { log_error("pubkey_generate failed: %s\n", g10_errstr(rc) ); return rc; } sk = m_alloc_clear( sizeof *sk ); pk = m_alloc_clear( sizeof *pk ); sk->timestamp = pk->timestamp = make_timestamp(); sk->version = pk->version = 4; if( expireval ) { sk->expiredate = pk->expiredate = sk->timestamp + expireval; } sk->pubkey_algo = pk->pubkey_algo = PUBKEY_ALGO_DSA; pk->pkey[0] = mpi_copy( skey[0] ); pk->pkey[1] = mpi_copy( skey[1] ); pk->pkey[2] = mpi_copy( skey[2] ); pk->pkey[3] = mpi_copy( skey[3] ); sk->skey[0] = skey[0]; sk->skey[1] = skey[1]; sk->skey[2] = skey[2]; sk->skey[3] = skey[3]; sk->skey[4] = skey[4]; sk->is_protected = 0; sk->protect.algo = 0; sk->csum = checksum_mpi_counted_nbits( sk->skey[4] ); if( ret_sk ) /* not a subkey: return an unprotected version of the sk */ *ret_sk = copy_secret_key( NULL, sk ); if( dek ) { sk->protect.algo = dek->algo; sk->protect.s2k = *s2k; rc = protect_secret_key( sk, dek ); if( rc ) { log_error("protect_secret_key failed: %s\n", g10_errstr(rc) ); free_public_key(pk); free_secret_key(sk); return rc; } } pkt = m_alloc_clear(sizeof *pkt); pkt->pkttype = ret_sk ? PKT_PUBLIC_KEY : PKT_PUBLIC_SUBKEY; pkt->pkt.public_key = pk; add_kbnode(pub_root, new_kbnode( pkt )); /* don't know whether it makes sense to have the factors, so for now * we store them in the secret keyring (but they are not secret) * p = 2 * q * f1 * f2 * ... * fn * We store only f1 to f_n-1; fn can be calculated because p and q * are known. */ pkt = m_alloc_clear(sizeof *pkt); pkt->pkttype = ret_sk ? PKT_SECRET_KEY : PKT_SECRET_SUBKEY; pkt->pkt.secret_key = sk; add_kbnode(sec_root, new_kbnode( pkt )); for(i=1; factors[i]; i++ ) /* the first one is q */ add_kbnode( sec_root, make_mpi_comment_node("#:DSA_factor:", factors[i] )); return 0; } /* * Generate an RSA key. */ static int gen_rsa(int algo, unsigned nbits, KBNODE pub_root, KBNODE sec_root, DEK *dek, STRING2KEY *s2k, PKT_secret_key **ret_sk, u32 expireval ) { int rc; PACKET *pkt; PKT_secret_key *sk; PKT_public_key *pk; MPI skey[6]; MPI *factors; assert( is_RSA(algo) ); if( nbits < 1024 ) { nbits = 1024; log_info(_("keysize invalid; using %u bits\n"), nbits ); } if( (nbits % 32) ) { nbits = ((nbits + 31) / 32) * 32; log_info(_("keysize rounded up to %u bits\n"), nbits ); } rc = pubkey_generate( algo, nbits, skey, &factors ); if( rc ) { log_error("pubkey_generate failed: %s\n", g10_errstr(rc) ); return rc; } sk = m_alloc_clear( sizeof *sk ); pk = m_alloc_clear( sizeof *pk ); sk->timestamp = pk->timestamp = make_timestamp(); sk->version = pk->version = 4; if( expireval ) { sk->expiredate = pk->expiredate = sk->timestamp + expireval; } sk->pubkey_algo = pk->pubkey_algo = algo; pk->pkey[0] = mpi_copy( skey[0] ); pk->pkey[1] = mpi_copy( skey[1] ); sk->skey[0] = skey[0]; sk->skey[1] = skey[1]; sk->skey[2] = skey[2]; sk->skey[3] = skey[3]; sk->skey[4] = skey[4]; sk->skey[5] = skey[5]; sk->is_protected = 0; sk->protect.algo = 0; sk->csum = checksum_mpi_counted_nbits( sk->skey[2] ); sk->csum += checksum_mpi_counted_nbits( sk->skey[3] ); sk->csum += checksum_mpi_counted_nbits( sk->skey[4] ); sk->csum += checksum_mpi_counted_nbits( sk->skey[5] ); if( ret_sk ) /* not a subkey: return an unprotected version of the sk */ *ret_sk = copy_secret_key( NULL, sk ); if( dek ) { sk->protect.algo = dek->algo; sk->protect.s2k = *s2k; rc = protect_secret_key( sk, dek ); if( rc ) { log_error("protect_secret_key failed: %s\n", g10_errstr(rc) ); free_public_key(pk); free_secret_key(sk); return rc; } } pkt = m_alloc_clear(sizeof *pkt); pkt->pkttype = ret_sk ? PKT_PUBLIC_KEY : PKT_PUBLIC_SUBKEY; pkt->pkt.public_key = pk; add_kbnode(pub_root, new_kbnode( pkt )); pkt = m_alloc_clear(sizeof *pkt); pkt->pkttype = ret_sk ? PKT_SECRET_KEY : PKT_SECRET_SUBKEY; pkt->pkt.secret_key = sk; add_kbnode(sec_root, new_kbnode( pkt )); return 0; } /**************** * check valid days: * return 0 on error or the multiplier */ static int check_valid_days( const char *s ) { if( !isdigit(*s) ) return 0; for( s++; *s; s++) if( !isdigit(*s) ) break; if( !*s ) return 1; if( s[1] ) return 0; /* e.g. "2323wc" */ if( *s == 'd' || *s == 'D' ) return 1; if( *s == 'w' || *s == 'W' ) return 7; if( *s == 'm' || *s == 'M' ) return 30; if( *s == 'y' || *s == 'Y' ) return 365; return 0; } /**************** * Returns: 0 to create both a DSA and a ElGamal key. * and only if key flags are to be written the desired usage. */ static int ask_algo (int addmode, unsigned int *r_usage) { char *answer; int algo; *r_usage = 0; tty_printf(_("Please select what kind of key you want:\n")); if( !addmode ) tty_printf(_(" (%d) DSA and ElGamal (default)\n"), 1 ); tty_printf( _(" (%d) DSA (sign only)\n"), 2 ); if( addmode ) tty_printf( _(" (%d) ElGamal (encrypt only)\n"), 3 ); if (opt.expert) tty_printf( _(" (%d) ElGamal (sign and encrypt)\n"), 4 ); tty_printf( _(" (%d) RSA (sign only)\n"), 5 ); if (addmode) tty_printf( _(" (%d) RSA (encrypt only)\n"), 6 ); if (opt.expert) tty_printf( _(" (%d) RSA (sign and encrypt)\n"), 7 ); for(;;) { answer = cpr_get("keygen.algo",_("Your selection? ")); cpr_kill_prompt(); algo = *answer? atoi(answer): 1; m_free(answer); if( algo == 1 && !addmode ) { algo = 0; /* create both keys */ break; } else if( algo == 7 && opt.expert ) { if (cpr_get_answer_is_yes ("keygen.algo.rsa_se",_( "The use of this algorithm is deprecated - create anyway? "))){ algo = PUBKEY_ALGO_RSA; *r_usage = PUBKEY_USAGE_ENC | PUBKEY_USAGE_SIG; break; } } else if( algo == 6 && addmode ) { algo = PUBKEY_ALGO_RSA; *r_usage = PUBKEY_USAGE_ENC; break; } else if( algo == 5 ) { algo = PUBKEY_ALGO_RSA; *r_usage = PUBKEY_USAGE_SIG; break; } else if( algo == 4 && opt.expert) { if( cpr_get_answer_is_yes("keygen.algo.elg_se",_( "The use of this algorithm is deprecated - create anyway? "))){ algo = PUBKEY_ALGO_ELGAMAL; break; } } else if( algo == 3 && addmode ) { algo = PUBKEY_ALGO_ELGAMAL_E; break; } else if( algo == 2 ) { algo = PUBKEY_ALGO_DSA; break; } else tty_printf(_("Invalid selection.\n")); } return algo; } static unsigned ask_keysize( int algo ) { char *answer; unsigned nbits; if (algo != PUBKEY_ALGO_DSA && algo != PUBKEY_ALGO_RSA) { tty_printf (_("About to generate a new %s keypair.\n" " minimum keysize is 768 bits\n" " default keysize is 1024 bits\n" " highest suggested keysize is 2048 bits\n"), pubkey_algo_to_string(algo) ); } for(;;) { answer = cpr_get("keygen.size", _("What keysize do you want? (1024) ")); cpr_kill_prompt(); nbits = *answer? atoi(answer): 1024; m_free(answer); if( algo == PUBKEY_ALGO_DSA && (nbits < 512 || nbits > 1024) ) tty_printf(_("DSA only allows keysizes from 512 to 1024\n")); else if( algo == PUBKEY_ALGO_RSA && nbits < 1024 ) tty_printf(_("keysize too small;" " 1024 is smallest value allowed for RSA.\n")); else if( nbits < 768 ) tty_printf(_("keysize too small;" " 768 is smallest value allowed.\n")); else if( nbits > 4096 ) { /* It is ridiculous and an annoyance to use larger key sizes! * GnuPG can handle much larger sizes; but it takes an eternity * to create such a key (but less than the time the Sirius * Computer Corporation needs to process one of the usual * complaints) and {de,en}cryption although needs some time. * So, before you complain about this limitation, I suggest that * you start a discussion with Marvin about this theme and then * do whatever you want. */ tty_printf(_("keysize too large; %d is largest value allowed.\n"), 4096); } else if( nbits > 2048 && !cpr_enabled() ) { tty_printf( _("Keysizes larger than 2048 are not suggested because\n" "computations take REALLY long!\n")); if( cpr_get_answer_is_yes("keygen.size.huge.okay",_( "Are you sure that you want this keysize? ")) ) { tty_printf(_("Okay, but keep in mind that your monitor " "and keyboard radiation is also very vulnerable " "to attacks!\n")); break; } } else break; } tty_printf(_("Requested keysize is %u bits\n"), nbits ); if( algo == PUBKEY_ALGO_DSA && (nbits % 64) ) { nbits = ((nbits + 63) / 64) * 64; tty_printf(_("rounded up to %u bits\n"), nbits ); } else if( (nbits % 32) ) { nbits = ((nbits + 31) / 32) * 32; tty_printf(_("rounded up to %u bits\n"), nbits ); } return nbits; } /**************** * Parse an expire string and return it's value in days. * Returns -1 on error. */ static int parse_expire_string( const char *string ) { int mult; u32 abs_date=0; u32 curtime = make_timestamp(); int valid_days; if( !*string ) valid_days = 0; else if( (abs_date = scan_isodatestr(string)) && abs_date > curtime ) { /* This calculation is not perfectly okay because we * are later going to simply multiply by 86400 and don't * correct for leapseconds. A solution would be to change * the whole implemenation to work with dates and not intervals * which are required for v3 keys. */ valid_days = abs_date/86400-curtime/86400+1; } else if( (mult=check_valid_days(string)) ) { valid_days = atoi(string) * mult; if( valid_days < 0 || valid_days > 39447 ) valid_days = 0; } else { valid_days = -1; } return valid_days; } /* object == 0 for a key, and 1 for a sig */ u32 ask_expire_interval(int object) { char *answer; int valid_days=0; u32 interval = 0; switch(object) { case 0: tty_printf(_("Please specify how long the key should be valid.\n" " 0 = key does not expire\n" " = key expires in n days\n" " w = key expires in n weeks\n" " m = key expires in n months\n" " y = key expires in n years\n")); break; case 1: tty_printf(_("Please specify how long the signature should be valid.\n" " 0 = signature does not expire\n" " = signature expires in n days\n" " w = signature expires in n weeks\n" " m = signature expires in n months\n" " y = signature expires in n years\n")); break; default: BUG(); } /* Note: The elgamal subkey for DSA has no expiration date because * it must be signed with the DSA key and this one has the expiration * date */ answer = NULL; for(;;) { u32 curtime=make_timestamp(); m_free(answer); if(object==0) answer = cpr_get("keygen.valid",_("Key is valid for? (0) ")); else answer = cpr_get("siggen.valid",_("Signature is valid for? (0) ")); cpr_kill_prompt(); trim_spaces(answer); valid_days = parse_expire_string( answer ); if( valid_days < 0 ) { tty_printf(_("invalid value\n")); continue; } if( !valid_days ) { tty_printf(_("%s does not expire at all\n"), object==0?"Key":"Signature"); interval = 0; } else { interval = valid_days * 86400L; /* print the date when the key expires */ tty_printf(_("%s expires at %s\n"), object==0?"Key":"Signature", asctimestamp((ulong)(curtime + interval) ) ); /* FIXME: This check yields warning on alhas: write a configure check and to this check here only for 32 bit machines */ if( (time_t)((ulong)(curtime+interval)) < 0 ) tty_printf(_("Your system can't display dates beyond 2038.\n" "However, it will be correctly handled up to 2106.\n")); } if( cpr_enabled() || cpr_get_answer_is_yes("keygen.valid.okay", _("Is this correct (y/n)? ")) ) break; } m_free(answer); return interval; } u32 ask_expiredate() { u32 x = ask_expire_interval(0); return x? make_timestamp() + x : 0; } static int has_invalid_email_chars( const char *s ) { int at_seen=0; static char valid_chars[] = "01234567890_-." "abcdefghijklmnopqrstuvwxyz" "ABCDEFGHIJKLMNOPQRSTUVWXYZ"; for( ; *s; s++ ) { if( *s & 0x80 ) return 1; if( *s == '@' ) at_seen=1; else if( !at_seen && !( !!strchr( valid_chars, *s ) || *s == '+' ) ) return 1; else if( at_seen && !strchr( valid_chars, *s ) ) return 1; } return 0; } static char * ask_user_id( int mode ) { char *answer; char *aname, *acomment, *amail, *uid; if( !mode ) tty_printf( _("\n" "You need a User-ID to identify your key; the software constructs the user id\n" "from Real Name, Comment and Email Address in this form:\n" " \"Heinrich Heine (Der Dichter) \"\n\n") ); uid = aname = acomment = amail = NULL; for(;;) { char *p; int fail=0; if( !aname ) { for(;;) { m_free(aname); aname = cpr_get("keygen.name",_("Real name: ")); trim_spaces(aname); cpr_kill_prompt(); if( opt.allow_freeform_uid ) break; if( strpbrk( aname, "<>" ) ) tty_printf(_("Invalid character in name\n")); else if( isdigit(*aname) ) tty_printf(_("Name may not start with a digit\n")); else if( strlen(aname) < 5 ) tty_printf(_("Name must be at least 5 characters long\n")); else break; } } if( !amail ) { for(;;) { m_free(amail); amail = cpr_get("keygen.email",_("Email address: ")); trim_spaces(amail); cpr_kill_prompt(); if( !*amail ) break; /* no email address is okay */ else if( has_invalid_email_chars(amail) || string_count_chr(amail,'@') != 1 || *amail == '@' || amail[strlen(amail)-1] == '@' || amail[strlen(amail)-1] == '.' || strstr(amail, "..") ) tty_printf(_("Not a valid email address\n")); else break; } } if( !acomment ) { for(;;) { m_free(acomment); acomment = cpr_get("keygen.comment",_("Comment: ")); trim_spaces(acomment); cpr_kill_prompt(); if( !*acomment ) break; /* no comment is okay */ else if( strpbrk( acomment, "()" ) ) tty_printf(_("Invalid character in comment\n")); else break; } } m_free(uid); uid = p = m_alloc(strlen(aname)+strlen(amail)+strlen(acomment)+12+10); p = stpcpy(p, aname ); if( *acomment ) p = stpcpy(stpcpy(stpcpy(p," ("), acomment),")"); if( *amail ) p = stpcpy(stpcpy(stpcpy(p," <"), amail),">"); /* append a warning if we do not have dev/random * or it is switched into quick testmode */ if( quick_random_gen(-1) ) strcpy(p, " (INSECURE!)" ); /* print a note in case that UTF8 mapping has to be done */ for(p=uid; *p; p++ ) { if( *p & 0x80 ) { tty_printf(_("You are using the `%s' character set.\n"), get_native_charset() ); break; } } tty_printf(_("You selected this USER-ID:\n \"%s\"\n\n"), uid); /* fixme: add a warning if this user-id already exists */ if( !*amail && (strchr( aname, '@' ) || strchr( acomment, '@'))) { fail = 1; tty_printf(_("Please don't put the email address " "into the real name or the comment\n") ); } for(;;) { const char *ansstr = _("NnCcEeOoQq"); if( strlen(ansstr) != 10 ) BUG(); if( cpr_enabled() ) { answer = m_strdup(ansstr+6); answer[1] = 0; } else { answer = cpr_get("keygen.userid.cmd", fail? _("Change (N)ame, (C)omment, (E)mail or (Q)uit? ") : _("Change (N)ame, (C)omment, (E)mail or (O)kay/(Q)uit? ")); cpr_kill_prompt(); } if( strlen(answer) > 1 ) ; else if( *answer == ansstr[0] || *answer == ansstr[1] ) { m_free(aname); aname = NULL; break; } else if( *answer == ansstr[2] || *answer == ansstr[3] ) { m_free(acomment); acomment = NULL; break; } else if( *answer == ansstr[4] || *answer == ansstr[5] ) { m_free(amail); amail = NULL; break; } else if( *answer == ansstr[6] || *answer == ansstr[7] ) { if( fail ) { tty_printf(_("Please correct the error first\n")); } else { m_free(aname); aname = NULL; m_free(acomment); acomment = NULL; m_free(amail); amail = NULL; break; } } else if( *answer == ansstr[8] || *answer == ansstr[9] ) { m_free(aname); aname = NULL; m_free(acomment); acomment = NULL; m_free(amail); amail = NULL; m_free(uid); uid = NULL; break; } m_free(answer); } m_free(answer); if( !amail && !acomment && !amail ) break; m_free(uid); uid = NULL; } if( uid ) { char *p = native_to_utf8( uid ); m_free( uid ); uid = p; } return uid; } static DEK * ask_passphrase( STRING2KEY **ret_s2k ) { DEK *dek = NULL; STRING2KEY *s2k; const char *errtext = NULL; tty_printf(_("You need a Passphrase to protect your secret key.\n\n") ); s2k = m_alloc_secure( sizeof *s2k ); for(;;) { s2k->mode = opt.s2k_mode; s2k->hash_algo = opt.s2k_digest_algo; dek = passphrase_to_dek( NULL, 0, opt.s2k_cipher_algo, s2k,2,errtext); if( !dek ) { errtext = _("passphrase not correctly repeated; try again"); tty_printf(_("%s.\n"), errtext); } else if( !dek->keylen ) { m_free(dek); dek = NULL; m_free(s2k); s2k = NULL; tty_printf(_( "You don't want a passphrase - this is probably a *bad* idea!\n" "I will do it anyway. You can change your passphrase at any time,\n" "using this program with the option \"--edit-key\".\n\n")); break; } else break; /* okay */ } *ret_s2k = s2k; return dek; } static int do_create( int algo, unsigned int nbits, KBNODE pub_root, KBNODE sec_root, DEK *dek, STRING2KEY *s2k, PKT_secret_key **sk, u32 expiredate ) { int rc=0; if( !opt.batch ) tty_printf(_( "We need to generate a lot of random bytes. It is a good idea to perform\n" "some other action (type on the keyboard, move the mouse, utilize the\n" "disks) during the prime generation; this gives the random number\n" "generator a better chance to gain enough entropy.\n") ); if( algo == PUBKEY_ALGO_ELGAMAL || algo == PUBKEY_ALGO_ELGAMAL_E ) rc = gen_elg(algo, nbits, pub_root, sec_root, dek, s2k, sk, expiredate); else if( algo == PUBKEY_ALGO_DSA ) rc = gen_dsa(nbits, pub_root, sec_root, dek, s2k, sk, expiredate); else if( algo == PUBKEY_ALGO_RSA ) rc = gen_rsa(algo, nbits, pub_root, sec_root, dek, s2k, sk, expiredate); else BUG(); #ifdef ENABLE_COMMENT_PACKETS if( !rc ) { add_kbnode( pub_root, make_comment_node("#created by GNUPG v" VERSION " (" PRINTABLE_OS_NAME ")")); add_kbnode( sec_root, make_comment_node("#created by GNUPG v" VERSION " (" PRINTABLE_OS_NAME ")")); } #endif return rc; } /**************** * Generate a new user id packet, or return NULL if canceled */ PKT_user_id * generate_user_id() { PKT_user_id *uid; char *p; size_t n; p = ask_user_id( 1 ); if( !p ) return NULL; n = strlen(p); uid = m_alloc_clear( sizeof *uid + n - 1 ); uid->len = n; strcpy(uid->name, p); uid->ref = 1; return uid; } static void release_parameter_list( struct para_data_s *r ) { struct para_data_s *r2; for( ; r ; r = r2 ) { r2 = r->next; if( r->key == pPASSPHRASE_DEK ) m_free( r->u.dek ); else if( r->key == pPASSPHRASE_S2K ) m_free( r->u.s2k ); m_free(r); } } static struct para_data_s * get_parameter( struct para_data_s *para, enum para_name key ) { struct para_data_s *r; for( r = para; r && r->key != key; r = r->next ) ; return r; } static const char * get_parameter_value( struct para_data_s *para, enum para_name key ) { struct para_data_s *r = get_parameter( para, key ); return (r && *r->u.value)? r->u.value : NULL; } static int get_parameter_algo( struct para_data_s *para, enum para_name key ) { int i; struct para_data_s *r = get_parameter( para, key ); if( !r ) return -1; if( isdigit( *r->u.value ) ) i = atoi( r->u.value ); else i = string_to_pubkey_algo( r->u.value ); if (i == PUBKEY_ALGO_RSA_E || i == PUBKEY_ALGO_RSA_S) i = 0; /* we don't want to allow generation of these algorithms */ return i; } /* * parse the usage parameter and set the keyflags. Return true on error. */ static int parse_parameter_usage (const char *fname, struct para_data_s *para, enum para_name key) { struct para_data_s *r = get_parameter( para, key ); char *p, *pn; unsigned int use; if( !r ) return 0; /* none (this is an optional parameter)*/ use = 0; pn = r->u.value; while ( (p = strsep (&pn, " \t,")) ) { if ( !*p) ; else if ( !ascii_strcasecmp (p, "sign") ) use |= PUBKEY_USAGE_SIG; else if ( !ascii_strcasecmp (p, "encrypt") ) use |= PUBKEY_USAGE_ENC; else { log_error("%s:%d: invalid usage list\n", fname, r->lnr ); return -1; /* error */ } } r->u.usage = use; return 0; } static int parse_revocation_key (const char *fname, struct para_data_s *para, enum para_name key) { struct para_data_s *r = get_parameter( para, key ); struct revocation_key revkey; char *pn; int i; if( !r ) return 0; /* none (this is an optional parameter) */ pn = r->u.value; revkey.class=0x80; revkey.algid=atoi(pn); if(!revkey.algid) goto fail; /* Skip to the fpr */ while(*pn && *pn!=':') pn++; if(*pn!=':') goto fail; pn++; for(i=0;iu.revkey,&revkey,sizeof(struct revocation_key)); return 0; fail: log_error("%s:%d: invalid revocation key\n", fname, r->lnr ); return -1; /* error */ } static u32 get_parameter_u32( struct para_data_s *para, enum para_name key ) { struct para_data_s *r = get_parameter( para, key ); if( !r ) return 0; if( r->key == pKEYEXPIRE || r->key == pSUBKEYEXPIRE ) return r->u.expire; if( r->key == pKEYUSAGE || r->key == pSUBKEYUSAGE ) return r->u.usage; return (unsigned int)strtoul( r->u.value, NULL, 10 ); } static unsigned int get_parameter_uint( struct para_data_s *para, enum para_name key ) { return get_parameter_u32( para, key ); } static DEK * get_parameter_dek( struct para_data_s *para, enum para_name key ) { struct para_data_s *r = get_parameter( para, key ); return r? r->u.dek : NULL; } static STRING2KEY * get_parameter_s2k( struct para_data_s *para, enum para_name key ) { struct para_data_s *r = get_parameter( para, key ); return r? r->u.s2k : NULL; } static struct revocation_key * get_parameter_revkey( struct para_data_s *para, enum para_name key ) { struct para_data_s *r = get_parameter( para, key ); return r? &r->u.revkey : NULL; } static int proc_parameter_file( struct para_data_s *para, const char *fname, struct output_control_s *outctrl ) { struct para_data_s *r; const char *s1, *s2, *s3; size_t n; char *p; int i; /* check that we have all required parameters */ assert( get_parameter( para, pKEYTYPE ) ); i = get_parameter_algo( para, pKEYTYPE ); if( i < 1 || check_pubkey_algo2( i, PUBKEY_USAGE_SIG ) ) { r = get_parameter( para, pKEYTYPE ); log_error("%s:%d: invalid algorithm\n", fname, r->lnr ); return -1; } if (parse_parameter_usage (fname, para, pKEYUSAGE)) return -1; i = get_parameter_algo( para, pSUBKEYTYPE ); if( i > 0 && check_pubkey_algo( i ) ) { r = get_parameter( para, pSUBKEYTYPE ); log_error("%s:%d: invalid algorithm\n", fname, r->lnr ); return -1; } if (i > 0 && parse_parameter_usage (fname, para, pSUBKEYUSAGE)) return -1; if( !get_parameter_value( para, pUSERID ) ) { /* create the formatted user ID */ s1 = get_parameter_value( para, pNAMEREAL ); s2 = get_parameter_value( para, pNAMECOMMENT ); s3 = get_parameter_value( para, pNAMEEMAIL ); if( s1 || s2 || s3 ) { n = (s1?strlen(s1):0) + (s2?strlen(s2):0) + (s3?strlen(s3):0); r = m_alloc_clear( sizeof *r + n + 20 ); r->key = pUSERID; p = r->u.value; if( s1 ) p = stpcpy(p, s1 ); if( s2 ) p = stpcpy(stpcpy(stpcpy(p," ("), s2 ),")"); if( s3 ) p = stpcpy(stpcpy(stpcpy(p," <"), s3 ),">"); r->next = para; para = r; } } /* Set preferences, if any. */ keygen_set_std_prefs(get_parameter_value( para, pPREFERENCES ), 0); /* Set revoker, if any. */ if (parse_revocation_key (fname, para, pREVOKER)) return -1; /* make DEK and S2K from the Passphrase */ r = get_parameter( para, pPASSPHRASE ); if( r && *r->u.value ) { /* we have a plain text passphrase - create a DEK from it. * It is a little bit ridiculous to keep it ih secure memory * but becuase we do this alwasy, why not here */ STRING2KEY *s2k; DEK *dek; s2k = m_alloc_secure( sizeof *s2k ); s2k->mode = opt.s2k_mode; s2k->hash_algo = opt.s2k_digest_algo; set_next_passphrase( r->u.value ); dek = passphrase_to_dek( NULL, 0, opt.s2k_cipher_algo, s2k, 2, NULL ); set_next_passphrase( NULL ); assert( dek ); memset( r->u.value, 0, strlen(r->u.value) ); r = m_alloc_clear( sizeof *r ); r->key = pPASSPHRASE_S2K; r->u.s2k = s2k; r->next = para; para = r; r = m_alloc_clear( sizeof *r ); r->key = pPASSPHRASE_DEK; r->u.dek = dek; r->next = para; para = r; } /* make KEYEXPIRE from Expire-Date */ r = get_parameter( para, pEXPIREDATE ); if( r && *r->u.value ) { i = parse_expire_string( r->u.value ); if( i < 0 ) { log_error("%s:%d: invalid expire date\n", fname, r->lnr ); return -1; } r->u.expire = i * 86400L; r->key = pKEYEXPIRE; /* change hat entry */ /* also set it for the subkey */ r = m_alloc_clear( sizeof *r + 20 ); r->key = pSUBKEYEXPIRE; r->u.expire = i * 86400L; r->next = para; para = r; } if( !!outctrl->pub.newfname ^ !!outctrl->sec.newfname ) { log_error("%s:%d: only one ring name is set\n", fname, outctrl->lnr ); return -1; } do_generate_keypair( para, outctrl ); return 0; } /**************** * Kludge to allow non interactive key generation controlled * by a parameter file (which currently is only stdin) * Note, that string parameters are expected to be in UTF-8 */ static void read_parameter_file( const char *fname ) { static struct { const char *name; enum para_name key; } keywords[] = { { "Key-Type", pKEYTYPE}, { "Key-Length", pKEYLENGTH }, { "Key-Usage", pKEYUSAGE }, { "Subkey-Type", pSUBKEYTYPE }, { "Subkey-Length", pSUBKEYLENGTH }, { "Subkey-Usage", pSUBKEYUSAGE }, { "Name-Real", pNAMEREAL }, { "Name-Email", pNAMEEMAIL }, { "Name-Comment", pNAMECOMMENT }, { "Expire-Date", pEXPIREDATE }, { "Passphrase", pPASSPHRASE }, { "Preferences", pPREFERENCES }, { "Revoker", pREVOKER }, { NULL, 0 } }; FILE *fp; char line[1024], *p; int lnr; const char *err = NULL; struct para_data_s *para, *r; int i; struct output_control_s outctrl; memset( &outctrl, 0, sizeof( outctrl ) ); if( !fname || !*fname || !strcmp(fname,"-") ) { fp = stdin; fname = "-"; } else { fp = fopen( fname, "r" ); if( !fp ) { log_error(_("can't open `%s': %s\n"), fname, strerror(errno) ); return; } } lnr = 0; err = NULL; para = NULL; while( fgets( line, DIM(line)-1, fp ) ) { char *keyword, *value; lnr++; if( *line && line[strlen(line)-1] != '\n' ) { err = "line too long"; break; } for( p = line; isspace(*(byte*)p); p++ ) ; if( !*p || *p == '#' ) continue; keyword = p; if( *keyword == '%' ) { for( ; !isspace(*(byte*)p); p++ ) ; if( *p ) *p++ = 0; for( ; isspace(*(byte*)p); p++ ) ; value = p; trim_trailing_ws( value, strlen(value) ); if( !ascii_strcasecmp( keyword, "%echo" ) ) log_info("%s\n", value ); else if( !ascii_strcasecmp( keyword, "%dry-run" ) ) outctrl.dryrun = 1; else if( !ascii_strcasecmp( keyword, "%commit" ) ) { outctrl.lnr = lnr; proc_parameter_file( para, fname, &outctrl ); release_parameter_list( para ); para = NULL; } else if( !ascii_strcasecmp( keyword, "%pubring" ) ) { if( outctrl.pub.fname && !strcmp( outctrl.pub.fname, value ) ) ; /* still the same file - ignore it */ else { m_free( outctrl.pub.newfname ); outctrl.pub.newfname = m_strdup( value ); outctrl.use_files = 1; } } else if( !ascii_strcasecmp( keyword, "%secring" ) ) { if( outctrl.sec.fname && !strcmp( outctrl.sec.fname, value ) ) ; /* still the same file - ignore it */ else { m_free( outctrl.sec.newfname ); outctrl.sec.newfname = m_strdup( value ); outctrl.use_files = 1; } } else log_info("skipping control `%s' (%s)\n", keyword, value ); continue; } if( !(p = strchr( p, ':' )) || p == keyword ) { err = "missing colon"; break; } if( *p ) *p++ = 0; for( ; isspace(*(byte*)p); p++ ) ; if( !*p ) { err = "missing argument"; break; } value = p; trim_trailing_ws( value, strlen(value) ); for(i=0; keywords[i].name; i++ ) { if( !ascii_strcasecmp( keywords[i].name, keyword ) ) break; } if( !keywords[i].name ) { err = "unknown keyword"; break; } if( keywords[i].key != pKEYTYPE && !para ) { err = "parameter block does not start with \"Key-Type\""; break; } if( keywords[i].key == pKEYTYPE && para ) { outctrl.lnr = lnr; proc_parameter_file( para, fname, &outctrl ); release_parameter_list( para ); para = NULL; } else { for( r = para; r; r = r->next ) { if( r->key == keywords[i].key ) break; } if( r ) { err = "duplicate keyword"; break; } } r = m_alloc_clear( sizeof *r + strlen( value ) ); r->lnr = lnr; r->key = keywords[i].key; strcpy( r->u.value, value ); r->next = para; para = r; } if( err ) log_error("%s:%d: %s\n", fname, lnr, err ); else if( ferror(fp) ) { log_error("%s:%d: read error: %s\n", fname, lnr, strerror(errno) ); } else if( para ) { outctrl.lnr = lnr; proc_parameter_file( para, fname, &outctrl ); } if( outctrl.use_files ) { /* close open streams */ iobuf_close( outctrl.pub.stream ); iobuf_close( outctrl.sec.stream ); m_free( outctrl.pub.fname ); m_free( outctrl.pub.newfname ); m_free( outctrl.sec.fname ); m_free( outctrl.sec.newfname ); } release_parameter_list( para ); if( strcmp( fname, "-" ) ) fclose(fp); } /**************** * Generate a keypair * (fname is only used in batch mode) */ void generate_keypair( const char *fname ) { unsigned int nbits; char *uid = NULL; DEK *dek; STRING2KEY *s2k; int algo; unsigned int use; int both = 0; u32 expire; struct para_data_s *para = NULL; struct para_data_s *r; struct output_control_s outctrl; memset( &outctrl, 0, sizeof( outctrl ) ); if( opt.batch ) { read_parameter_file( fname ); return; } algo = ask_algo( 0, &use ); if( !algo ) { /* default: DSA with ElG subkey of the specified size */ both = 1; r = m_alloc_clear( sizeof *r + 20 ); r->key = pKEYTYPE; sprintf( r->u.value, "%d", PUBKEY_ALGO_DSA ); r->next = para; para = r; tty_printf(_("DSA keypair will have 1024 bits.\n")); r = m_alloc_clear( sizeof *r + 20 ); r->key = pKEYLENGTH; strcpy( r->u.value, "1024" ); r->next = para; para = r; algo = PUBKEY_ALGO_ELGAMAL_E; r = m_alloc_clear( sizeof *r + 20 ); r->key = pSUBKEYTYPE; sprintf( r->u.value, "%d", algo ); r->next = para; para = r; } else { r = m_alloc_clear( sizeof *r + 20 ); r->key = pKEYTYPE; sprintf( r->u.value, "%d", algo ); r->next = para; para = r; if (use) { r = m_alloc_clear( sizeof *r + 20 ); r->key = pKEYUSAGE; sprintf( r->u.value, "%s%s", (use & PUBKEY_USAGE_SIG)? "sign ":"", (use & PUBKEY_USAGE_ENC)? "encrypt ":"" ); r->next = para; para = r; } } nbits = ask_keysize( algo ); r = m_alloc_clear( sizeof *r + 20 ); r->key = both? pSUBKEYLENGTH : pKEYLENGTH; sprintf( r->u.value, "%u", nbits); r->next = para; para = r; expire = ask_expire_interval(0); r = m_alloc_clear( sizeof *r + 20 ); r->key = pKEYEXPIRE; r->u.expire = expire; r->next = para; para = r; r = m_alloc_clear( sizeof *r + 20 ); r->key = pSUBKEYEXPIRE; r->u.expire = expire; r->next = para; para = r; uid = ask_user_id(0); if( !uid ) { log_error(_("Key generation canceled.\n")); release_parameter_list( para ); return; } r = m_alloc_clear( sizeof *r + strlen(uid) ); r->key = pUSERID; strcpy( r->u.value, uid ); r->next = para; para = r; dek = ask_passphrase( &s2k ); if( dek ) { r = m_alloc_clear( sizeof *r ); r->key = pPASSPHRASE_DEK; r->u.dek = dek; r->next = para; para = r; r = m_alloc_clear( sizeof *r ); r->key = pPASSPHRASE_S2K; r->u.s2k = s2k; r->next = para; para = r; } proc_parameter_file( para, "[internal]", &outctrl ); release_parameter_list( para ); } static void do_generate_keypair( struct para_data_s *para, struct output_control_s *outctrl ) { KBNODE pub_root = NULL; KBNODE sec_root = NULL; PKT_secret_key *sk = NULL; const char *s; struct revocation_key *revkey; int rc; int did_sub = 0; if( outctrl->dryrun ) { log_info("dry-run mode - key generation skipped\n"); return; } if( outctrl->use_files ) { if( outctrl->pub.newfname ) { iobuf_close(outctrl->pub.stream); outctrl->pub.stream = NULL; m_free( outctrl->pub.fname ); outctrl->pub.fname = outctrl->pub.newfname; outctrl->pub.newfname = NULL; outctrl->pub.stream = iobuf_create( outctrl->pub.fname ); if( !outctrl->pub.stream ) { log_error("can't create `%s': %s\n", outctrl->pub.newfname, strerror(errno) ); return; } if( opt.armor ) { outctrl->pub.afx.what = 1; iobuf_push_filter( outctrl->pub.stream, armor_filter, &outctrl->pub.afx ); } } if( outctrl->sec.newfname ) { iobuf_close(outctrl->sec.stream); outctrl->sec.stream = NULL; m_free( outctrl->sec.fname ); outctrl->sec.fname = outctrl->sec.newfname; outctrl->sec.newfname = NULL; outctrl->sec.stream = iobuf_create( outctrl->sec.fname ); if( !outctrl->sec.stream ) { log_error("can't create `%s': %s\n", outctrl->sec.newfname, strerror(errno) ); return; } if( opt.armor ) { outctrl->sec.afx.what = 5; iobuf_push_filter( outctrl->sec.stream, armor_filter, &outctrl->sec.afx ); } } assert( outctrl->pub.stream ); assert( outctrl->sec.stream ); if( opt.verbose ) { log_info(_("writing public key to `%s'\n"), outctrl->pub.fname ); log_info(_("writing secret key to `%s'\n"), outctrl->sec.fname ); } } /* we create the packets as a tree of kbnodes. Because the structure * we create is known in advance we simply generate a linked list * The first packet is a dummy comment packet which we flag * as deleted. The very first packet must always be a KEY packet. */ pub_root = make_comment_node("#"); delete_kbnode(pub_root); sec_root = make_comment_node("#"); delete_kbnode(sec_root); rc = do_create( get_parameter_algo( para, pKEYTYPE ), get_parameter_uint( para, pKEYLENGTH ), pub_root, sec_root, get_parameter_dek( para, pPASSPHRASE_DEK ), get_parameter_s2k( para, pPASSPHRASE_S2K ), &sk, get_parameter_u32( para, pKEYEXPIRE ) ); if(!rc && (revkey=get_parameter_revkey(para,pREVOKER))) { rc=write_direct_sig(pub_root,pub_root,sk,revkey); if(!rc) write_direct_sig(sec_root,pub_root,sk,revkey); } if( !rc && (s=get_parameter_value(para, pUSERID)) ) { write_uid(pub_root, s ); if( !rc ) write_uid(sec_root, s ); if( !rc ) rc = write_selfsig(pub_root, pub_root, sk, get_parameter_uint (para, pKEYUSAGE)); if( !rc ) rc = write_selfsig(sec_root, pub_root, sk, get_parameter_uint (para, pKEYUSAGE)); } if( get_parameter( para, pSUBKEYTYPE ) ) { rc = do_create( get_parameter_algo( para, pSUBKEYTYPE ), get_parameter_uint( para, pSUBKEYLENGTH ), pub_root, sec_root, get_parameter_dek( para, pPASSPHRASE_DEK ), get_parameter_s2k( para, pPASSPHRASE_S2K ), NULL, get_parameter_u32( para, pSUBKEYEXPIRE ) ); if( !rc ) rc = write_keybinding(pub_root, pub_root, sk, get_parameter_uint (para, pSUBKEYUSAGE)); if( !rc ) rc = write_keybinding(sec_root, pub_root, sk, get_parameter_uint (para, pSUBKEYUSAGE)); did_sub = 1; } if( !rc && outctrl->use_files ) { /* direct write to specified files */ rc = write_keyblock( outctrl->pub.stream, pub_root ); if( rc ) log_error("can't write public key: %s\n", g10_errstr(rc) ); if( !rc ) { rc = write_keyblock( outctrl->sec.stream, sec_root ); if( rc ) log_error("can't write secret key: %s\n", g10_errstr(rc) ); } } else if( !rc ) { /* write to the standard keyrings */ KEYDB_HANDLE pub_hd = keydb_new (0); KEYDB_HANDLE sec_hd = keydb_new (1); /* FIXME: we may have to create the keyring first */ rc = keydb_locate_writable (pub_hd, NULL); if (rc) log_error (_("no writable public keyring found: %s\n"), g10_errstr (rc)); if (!rc) { rc = keydb_locate_writable (sec_hd, NULL); if (rc) log_error (_("no writable secret keyring found: %s\n"), g10_errstr (rc)); } if (!rc && opt.verbose) { log_info(_("writing public key to `%s'\n"), keydb_get_resource_name (pub_hd)); log_info(_("writing secret key to `%s'\n"), keydb_get_resource_name (sec_hd)); } if (!rc) { rc = keydb_insert_keyblock (pub_hd, pub_root); if (rc) log_error (_("error writing public keyring `%s': %s\n"), keydb_get_resource_name (pub_hd), g10_errstr(rc)); } if (!rc) { rc = keydb_insert_keyblock (sec_hd, sec_root); if (rc) log_error (_("error writing secret keyring `%s': %s\n"), keydb_get_resource_name (pub_hd), g10_errstr(rc)); } keydb_release (pub_hd); keydb_release (sec_hd); if (!rc) { int no_enc_rsa = get_parameter_algo(para, pKEYTYPE) == PUBKEY_ALGO_RSA && get_parameter_uint( para, pKEYUSAGE ) && !(get_parameter_uint( para,pKEYUSAGE) & PUBKEY_USAGE_ENC); PKT_public_key *pk = find_kbnode (pub_root, PKT_PUBLIC_KEY)->pkt->pkt.public_key; update_ownertrust (pk, ((get_ownertrust (pk) & ~TRUST_MASK) | TRUST_ULTIMATE )); if (!opt.batch) { tty_printf(_("public and secret key created and signed.\n") ); tty_printf(_("key marked as ultimately trusted.\n") ); tty_printf("\n"); list_keyblock(pub_root,0,1,NULL); } if( !opt.batch && ( get_parameter_algo( para, pKEYTYPE ) == PUBKEY_ALGO_DSA || no_enc_rsa ) && !get_parameter( para, pSUBKEYTYPE ) ) { tty_printf(_("Note that this key cannot be used for " "encryption. You may want to use\n" "the command \"--edit-key\" to generate a " "secondary key for this purpose.\n") ); } } } if( rc ) { if( opt.batch ) log_error("key generation failed: %s\n", g10_errstr(rc) ); else tty_printf(_("Key generation failed: %s\n"), g10_errstr(rc) ); } else { write_status_text (STATUS_KEY_CREATED, did_sub? "B":"P"); } release_kbnode( pub_root ); release_kbnode( sec_root ); if( sk ) /* the unprotected secret key */ free_secret_key(sk); } /**************** * add a new subkey to an existing key. * Returns true if a new key has been generated and put into the keyblocks. */ int generate_subkeypair( KBNODE pub_keyblock, KBNODE sec_keyblock ) { int okay=0, rc=0; KBNODE node; PKT_secret_key *sk = NULL; /* this is the primary sk */ int algo; unsigned int use; u32 expire; unsigned nbits; char *passphrase = NULL; DEK *dek = NULL; STRING2KEY *s2k = NULL; u32 cur_time; /* break out the primary secret key */ node = find_kbnode( sec_keyblock, PKT_SECRET_KEY ); if( !node ) { log_error("Oops; secret key not found anymore!\n"); goto leave; } /* make a copy of the sk to keep the protected one in the keyblock */ sk = copy_secret_key( NULL, node->pkt->pkt.secret_key ); cur_time = make_timestamp(); if( sk->timestamp > cur_time ) { ulong d = sk->timestamp - cur_time; log_info( d==1 ? _("key has been created %lu second " "in future (time warp or clock problem)\n") : _("key has been created %lu seconds " "in future (time warp or clock problem)\n"), d ); if( !opt.ignore_time_conflict ) { rc = G10ERR_TIME_CONFLICT; goto leave; } } if (sk->version < 4) { log_info (_("NOTE: creating subkeys for v3 keys " "is not OpenPGP compliant\n")); goto leave; } /* unprotect to get the passphrase */ switch( is_secret_key_protected( sk ) ) { case -1: rc = G10ERR_PUBKEY_ALGO; break; case 0: tty_printf("This key is not protected.\n"); break; default: tty_printf("Key is protected.\n"); rc = check_secret_key( sk, 0 ); if( !rc ) passphrase = get_last_passphrase(); break; } if( rc ) goto leave; algo = ask_algo( 1, &use ); assert(algo); nbits = ask_keysize( algo ); expire = ask_expire_interval(0); if( !cpr_enabled() && !cpr_get_answer_is_yes("keygen.sub.okay", _("Really create? ") ) ) goto leave; if( passphrase ) { s2k = m_alloc_secure( sizeof *s2k ); s2k->mode = opt.s2k_mode; s2k->hash_algo = opt.s2k_digest_algo; set_next_passphrase( passphrase ); dek = passphrase_to_dek( NULL, 0, opt.s2k_cipher_algo, s2k, 2, NULL ); } rc = do_create( algo, nbits, pub_keyblock, sec_keyblock, dek, s2k, NULL, expire ); if( !rc ) rc = write_keybinding(pub_keyblock, pub_keyblock, sk, use); if( !rc ) rc = write_keybinding(sec_keyblock, pub_keyblock, sk, use); if( !rc ) { okay = 1; write_status_text (STATUS_KEY_CREATED, "S"); } leave: if( rc ) log_error(_("Key generation failed: %s\n"), g10_errstr(rc) ); m_free( passphrase ); m_free( dek ); m_free( s2k ); if( sk ) /* release the copy of the (now unprotected) secret key */ free_secret_key(sk); set_next_passphrase( NULL ); return okay; } /**************** * Write a keyblock to an output stream */ static int write_keyblock( IOBUF out, KBNODE node ) { for( ; node ; node = node->next ) { int rc = build_packet( out, node->pkt ); if( rc ) { log_error("build_packet(%d) failed: %s\n", node->pkt->pkttype, g10_errstr(rc) ); return G10ERR_WRITE_FILE; } } return 0; }