/* parse-packet.c - read packets * Copyright (C) 1998 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 "packet.h" #include "iobuf.h" #include "mpi.h" #include "util.h" #include "cipher.h" #include "memory.h" #include "filter.h" #include "options.h" static mpi_print_mode = 0; static list_mode = 0; static int parse( IOBUF inp, PACKET *pkt, int reqtype, ulong *retpos, int *skip, IOBUF out, int do_skip ); static int copy_packet( IOBUF inp, IOBUF out, int pkttype, unsigned long pktlen ); static void skip_packet( IOBUF inp, int pkttype, unsigned long pktlen ); static void skip_rest( IOBUF inp, unsigned long pktlen ); static int parse_publickey( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *packet ); static int parse_signature( IOBUF inp, int pkttype, unsigned long pktlen, PKT_signature *sig ); static int parse_onepass_sig( IOBUF inp, int pkttype, unsigned long pktlen, PKT_onepass_sig *ops ); static int parse_certificate( IOBUF inp, int pkttype, unsigned long pktlen, byte *hdr, int hdrlen, PACKET *packet ); static int parse_user_id( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *packet ); static int parse_comment( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *packet ); static void parse_trust( IOBUF inp, int pkttype, unsigned long pktlen ); static int parse_plaintext( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *pkt ); static int parse_compressed( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *packet ); static int parse_encrypted( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *packet ); static unsigned short read_16(IOBUF inp) { unsigned short a; a = iobuf_get_noeof(inp) << 8; a |= iobuf_get_noeof(inp); return a; } static unsigned long read_32(IOBUF inp) { unsigned long a; a = iobuf_get_noeof(inp) << 24; a |= iobuf_get_noeof(inp) << 16; a |= iobuf_get_noeof(inp) << 8; a |= iobuf_get_noeof(inp); return a; } static unsigned long buffer_to_u32( const byte *buffer ) { unsigned long a; a = *buffer << 24; a |= buffer[1] << 16; a |= buffer[2] << 8; a |= buffer[3]; return a; } int set_packet_list_mode( int mode ) { int old = list_mode; list_mode = mode; mpi_print_mode = DBG_MPI; return old; } /**************** * Parse a Packet and return it in packet * Returns: 0 := valid packet in pkt * -1 := no more packets * >0 := error * Note: The function may return an error and a partly valid packet; * caller must free this packet. */ int parse_packet( IOBUF inp, PACKET *pkt ) { int skip, rc; do { rc = parse( inp, pkt, 0, NULL, &skip, NULL, 0 ); } while( skip ); return rc; } /**************** * Like parse packet, but do only return packets of the given type. */ int search_packet( IOBUF inp, PACKET *pkt, int pkttype, ulong *retpos ) { int skip, rc; do { rc = parse( inp, pkt, pkttype, retpos, &skip, NULL, 0 ); } while( skip ); return rc; } /**************** * Copy all packets from INP to OUT, thereby removing unused spaces. */ int copy_all_packets( IOBUF inp, IOBUF out ) { PACKET pkt; int skip, rc=0; do { init_packet(&pkt); } while( !(rc = parse( inp, &pkt, 0, NULL, &skip, out, 0 ))); return rc; } /**************** * Copy some packets from INP to OUT, thereby removing unused spaces. * Stop after at offset STOPoff (i.e. don't copy the packet at this offset) */ int copy_some_packets( IOBUF inp, IOBUF out, ulong stopoff ) { PACKET pkt; int skip, rc=0; do { if( iobuf_tell(inp) >= stopoff ) return 0; init_packet(&pkt); } while( !(rc = parse( inp, &pkt, 0, NULL, &skip, out, 0 )) ); return rc; } /**************** * Skip over N packets */ int skip_some_packets( IOBUF inp, unsigned n ) { int skip, rc=0; PACKET pkt; for( ;n && !rc; n--) { init_packet(&pkt); rc = parse( inp, &pkt, 0, NULL, &skip, NULL, 1 ); } return rc; } /**************** * Parse packet. Set the variable skip points to to 1 if the packet * should be skipped; this is the case if either there is a * requested packet type and the parsed packet doesn't match or the * packet-type is 0, indicating deleted stuff. * if OUT is not NULL, a special copymode is used. */ static int parse( IOBUF inp, PACKET *pkt, int reqtype, ulong *retpos, int *skip, IOBUF out, int do_skip ) { int rc, c, ctb, pkttype, lenbytes; unsigned long pktlen; byte hdr[5]; int hdrlen; int pgp3 = 0; *skip = 0; assert( !pkt->pkt.generic ); if( retpos ) *retpos = iobuf_tell(inp); if( (ctb = iobuf_get(inp)) == -1 ) return -1; hdrlen=0; hdr[hdrlen++] = ctb; if( !(ctb & 0x80) ) { log_error("%s: invalid packet (ctb=%02x)\n", iobuf_where(inp), ctb ); return G10ERR_INVALID_PACKET; } pktlen = 0; pgp3 = !!(ctb & 0x40); if( pgp3 ) { pkttype = ctb & 0x3f; if( (c = iobuf_get(inp)) == -1 ) { log_error("%s: 1st length byte missing\n", iobuf_where(inp) ); return G10ERR_INVALID_PACKET; } hdr[hdrlen++] = c; if( c < 192 ) pktlen = c; else if( c < 224 ) { pktlen = (c - 192) * 256; if( (c = iobuf_get(inp)) == -1 ) { log_error("%s: 2nd length byte missing\n", iobuf_where(inp) ); return G10ERR_INVALID_PACKET; } hdr[hdrlen++] = c; pktlen += c + 192; } else { /* partial body length */ pktlen = 1 << (c & 0x1f); log_debug("partial body length of %lu bytes\n", pktlen ); iobuf_set_partial_block_mode(inp, pktlen); pktlen = 0;/* to indicate partial length */ } } else { pkttype = (ctb>>2)&0xf; lenbytes = ((ctb&3)==3)? 0 : (1<<(ctb & 3)); if( !lenbytes ) { pktlen = 0; /* don't know the value */ if( pkttype != PKT_COMPRESSED ) iobuf_set_block_mode(inp, 1); } else { for( ; lenbytes; lenbytes-- ) { pktlen <<= 8; pktlen |= hdr[hdrlen++] = iobuf_get_noeof(inp); } } } if( out && pkttype ) { if( iobuf_write( out, hdr, hdrlen ) == -1 ) rc = G10ERR_WRITE_FILE; else rc = copy_packet(inp, out, pkttype, pktlen ); return rc; } if( do_skip || !pkttype || (reqtype && pkttype != reqtype) ) { skip_packet(inp, pkttype, pktlen); *skip = 1; return 0; } if( DBG_PACKET ) log_debug("parse_packet(iob=%d): type=%d length=%lu%s\n", iobuf_id(inp), pkttype, pktlen, pgp3?" (pgp3)":"" ); pkt->pkttype = pkttype; rc = G10ERR_UNKNOWN_PACKET; /* default error */ switch( pkttype ) { case PKT_PUBLIC_CERT: case PKT_PUBKEY_SUBCERT: pkt->pkt.public_cert = m_alloc_clear(sizeof *pkt->pkt.public_cert ); rc = parse_certificate(inp, pkttype, pktlen, hdr, hdrlen, pkt ); break; case PKT_SECRET_CERT: case PKT_SECKEY_SUBCERT: pkt->pkt.secret_cert = m_alloc_clear(sizeof *pkt->pkt.secret_cert ); rc = parse_certificate(inp, pkttype, pktlen, hdr, hdrlen, pkt ); break; case PKT_PUBKEY_ENC: rc = parse_publickey(inp, pkttype, pktlen, pkt ); break; case PKT_SIGNATURE: pkt->pkt.signature = m_alloc_clear(sizeof *pkt->pkt.signature ); rc = parse_signature(inp, pkttype, pktlen, pkt->pkt.signature ); break; case PKT_ONEPASS_SIG: pkt->pkt.onepass_sig = m_alloc_clear(sizeof *pkt->pkt.onepass_sig ); rc = parse_onepass_sig(inp, pkttype, pktlen, pkt->pkt.onepass_sig ); break; case PKT_USER_ID: rc = parse_user_id(inp, pkttype, pktlen, pkt ); break; case PKT_COMMENT: rc = parse_comment(inp, pkttype, pktlen, pkt); break; case PKT_RING_TRUST: parse_trust(inp, pkttype, pktlen); break; case PKT_PLAINTEXT: rc = parse_plaintext(inp, pkttype, pktlen, pkt ); break; case PKT_COMPRESSED: rc = parse_compressed(inp, pkttype, pktlen, pkt ); break; case PKT_ENCRYPTED: rc = parse_encrypted(inp, pkttype, pktlen, pkt ); break; default: skip_packet(inp, pkttype, pktlen); break; } return rc; } static void dump_hex_line( int c, int *i ) { if( *i && !(*i%8) ) { if( *i && !(*i%24) ) printf("\n%4d:", *i ); else putchar(' '); } if( c == -1 ) printf(" EOF" ); else printf(" %02x", c ); ++*i; } static int copy_packet( IOBUF inp, IOBUF out, int pkttype, unsigned long pktlen ) { int n; char buf[100]; if( iobuf_in_block_mode(inp) ) { while( (n = iobuf_read( inp, buf, 100 )) != -1 ) if( iobuf_write(out, buf, n ) ) return G10ERR_WRITE_FILE; /* write error */ } else if( !pktlen && pkttype == PKT_COMPRESSED ) { /* compressed packet, copy till EOF */ while( (n = iobuf_read( inp, buf, 100 )) != -1 ) if( iobuf_write(out, buf, n ) ) return G10ERR_WRITE_FILE; /* write error */ } else { for( ; pktlen; pktlen -= n ) { n = pktlen > 100 ? 100 : pktlen; n = iobuf_read( inp, buf, n ); if( n == -1 ) return G10ERR_READ_FILE; if( iobuf_write(out, buf, n ) ) return G10ERR_WRITE_FILE; /* write error */ } } return 0; } static void skip_packet( IOBUF inp, int pkttype, unsigned long pktlen ) { if( list_mode ) { printf(":unknown packet: type %2d, length %lu\n", pkttype, pktlen ); if( pkttype ) { int c, i=0 ; printf("dump:"); if( iobuf_in_block_mode(inp) ) { while( (c=iobuf_get(inp)) != -1 ) dump_hex_line(c, &i); } else { for( ; pktlen; pktlen-- ) dump_hex_line(iobuf_get(inp), &i); } putchar('\n'); return; } } skip_rest(inp,pktlen); } static void skip_rest( IOBUF inp, unsigned long pktlen ) { if( iobuf_in_block_mode(inp) ) { while( iobuf_get(inp) != -1 ) ; } else { for( ; pktlen; pktlen-- ) iobuf_get(inp); } } static int parse_publickey( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *packet ) { unsigned n; PKT_pubkey_enc *k; k = packet->pkt.pubkey_enc = m_alloc(sizeof *packet->pkt.pubkey_enc ); if( pktlen < 12 ) { log_error("packet(%d) too short\n", pkttype); goto leave; } k->version = iobuf_get_noeof(inp); pktlen--; if( k->version != 2 && k->version != 3 ) { log_error("packet(%d) with unknown version %d\n", pkttype, k->version); goto leave; } k->keyid[0] = read_32(inp); pktlen -= 4; k->keyid[1] = read_32(inp); pktlen -= 4; k->pubkey_algo = iobuf_get_noeof(inp); pktlen--; if( list_mode ) printf(":public key encoded packet: version %d, keyid %08lX%08lX\n", k->version, (ulong)k->keyid[0], (ulong)k->keyid[1]); if( k->pubkey_algo == PUBKEY_ALGO_ELGAMAL ) { n = pktlen; k->d.elg.a = mpi_read(inp, &n, 0); pktlen -=n; n = pktlen; k->d.elg.b = mpi_read(inp, &n, 0 ); pktlen -=n; if( list_mode ) { printf("\telg a: "); mpi_print(stdout, k->d.elg.a, mpi_print_mode ); printf("\n\telg b: "); mpi_print(stdout, k->d.elg.b, mpi_print_mode ); putchar('\n'); } } else if( k->pubkey_algo == PUBKEY_ALGO_RSA ) { n = pktlen; k->d.rsa.rsa_integer = mpi_read(inp, &n, 0 ); pktlen -=n; if( list_mode ) { printf("\trsa integer: "); mpi_print(stdout, k->d.rsa.rsa_integer, mpi_print_mode ); putchar('\n'); } } else if( list_mode ) printf("\tunknown algorithm %d\n", k->pubkey_algo ); leave: skip_rest(inp, pktlen); return 0; } static const byte * parse_subpkt( const byte *buffer, int reqtype ) { int buflen = (*buffer << 8) | buffer[1]; int type; int critical; size_t n; buffer += 2; for(;;) { if( !buflen ) return NULL; /* end of packets; not found */ n = *buffer++; buflen--; if( n >= 192 ) { if( buflen < 2 ) goto too_short; n = (( n - 192 ) << 8) + *buffer + 192; buflen--; } if( buflen < n ) goto too_short; type = *buffer; if( type & 0x80 ) { type &= 0x7f; critical = 1; } else critical = 0; if( reqtype < 0 ) { /* list packets */ printf("\t%ssubpacket %d of length %u (%s)\n", reqtype == -1 ? "hashed ":"", type, n, type == 2 ? "signature creation time" : type == 3 ? "signature expiration time" : type == 4 ? "exportable" : type == 5 ? "trust signature" : type == 6 ? "regular expression" : type == 7 ? "revocable" : type == 9 ? "key expiration time" : type ==10 ? "additional recipient request" : type ==11 ? "preferred symmetric algorithms" : type ==12 ? "revocation key" : type ==16 ? "issuer key ID" : type ==20 ? "notation data" : type ==21 ? "preferred hash algorithms" : type ==22 ? "preferred compression algorithms" : type ==23 ? "key server preferences" : type ==24 ? "preferred key server" : "?"); } else if( type == reqtype ) break; /* found */ buffer += n; buflen -=n; } buffer++; n--; if( n > buflen ) goto too_short; switch( type ) { case 2: /* signature creation time */ if( n < 4 ) break; return buffer; case 16:/* issuer key ID */ if( n < 8 ) break; return buffer; case 3: /* signature expiration time */ case 4: /* exportable */ case 5: /* trust signature */ case 6: /* regular expression */ case 7: /* revocable */ case 9: /* key expiration time */ case 10:/* additional recipient request */ case 11:/* preferred symmetric algorithms */ case 12:/* revocation key */ case 20:/* notation data */ case 21:/* preferred hash algorithms */ case 22:/* preferred compression algorithms */ case 23:/* key server preferences */ case 24:/* preferred key server */ default: BUG(); /* not yet needed */ } log_error("subpacket of type %d too short\n", type); return NULL; too_short: log_error("buffer shorter than subpacket\n"); return NULL; } static int parse_signature( IOBUF inp, int pkttype, unsigned long pktlen, PKT_signature *sig ) { int md5_len=0; unsigned n; int is_v4=0; int rc=0; if( pktlen < 16 ) { log_error("packet(%d) too short\n", pkttype); goto leave; } sig->version = iobuf_get_noeof(inp); pktlen--; if( sig->version == 4 ) is_v4=1; else if( sig->version != 2 && sig->version != 3 ) { log_error("packet(%d) with unknown version %d\n", pkttype, sig->version); goto leave; } if( !is_v4 ) { md5_len = iobuf_get_noeof(inp); pktlen--; } sig->sig_class = iobuf_get_noeof(inp); pktlen--; if( !is_v4 ) { sig->timestamp = read_32(inp); pktlen -= 4; sig->keyid[0] = read_32(inp); pktlen -= 4; sig->keyid[1] = read_32(inp); pktlen -= 4; } sig->pubkey_algo = iobuf_get_noeof(inp); pktlen--; sig->digest_algo = iobuf_get_noeof(inp); pktlen--; if( is_v4 ) { /* read subpackets */ n = read_16(inp); pktlen -= 2; /* length of hashed data */ if( n > 10000 ) { log_error("signature packet: hashed data too long\n"); rc = G10ERR_INVALID_PACKET; goto leave; } if( n ) { sig->hashed_data = m_alloc( n + 2 ); sig->hashed_data[0] = n << 8; sig->hashed_data[1] = n; if( iobuf_read(inp, sig->hashed_data+2, n ) != n ) { log_error("premature eof while reading hashed signature data\n"); rc = -1; goto leave; } pktlen -= n; } n = read_16(inp); pktlen -= 2; /* length of unhashed data */ if( n > 10000 ) { log_error("signature packet: unhashed data too long\n"); rc = G10ERR_INVALID_PACKET; goto leave; } if( n ) { sig->unhashed_data = m_alloc( n + 2 ); sig->unhashed_data[0] = n << 8; sig->unhashed_data[1] = n; if( iobuf_read(inp, sig->unhashed_data+2, n ) != n ) { log_error("premature eof while reading unhashed signature data\n"); rc = -1; goto leave; } pktlen -= n; } } if( pktlen < 5 ) { /* sanity check */ log_error("packet(%d) too short\n", pkttype); rc = G10ERR_INVALID_PACKET; goto leave; } sig->digest_start[0] = iobuf_get_noeof(inp); pktlen--; sig->digest_start[1] = iobuf_get_noeof(inp); pktlen--; if( is_v4 ) { /*extract required informations */ const byte *p; p = parse_subpkt( sig->hashed_data, 2 ); if( !p ) log_error("signature packet without timestamp\n"); else sig->timestamp = buffer_to_u32(p); p = parse_subpkt( sig->unhashed_data, 16 ); if( !p ) log_error("signature packet without keyid\n"); else { sig->keyid[0] = buffer_to_u32(p); sig->keyid[1] = buffer_to_u32(p+4); } } if( list_mode ) { printf(":signature packet: keyid %08lX%08lX\n" "\tversion %d, created %lu, md5len %d, sigclass %02x\n" "\tdigest algo %d, begin of digest %02x %02x\n", (ulong)sig->keyid[0], (ulong)sig->keyid[1], sig->version, (ulong)sig->timestamp, md5_len, sig->sig_class, sig->digest_algo, sig->digest_start[0], sig->digest_start[1] ); if( is_v4 ) { parse_subpkt( sig->hashed_data, -1 ); parse_subpkt( sig->unhashed_data, -2 ); } } if( sig->pubkey_algo == PUBKEY_ALGO_ELGAMAL ) { n = pktlen; sig->d.elg.a = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; sig->d.elg.b = mpi_read(inp, &n, 0 ); pktlen -=n; if( list_mode ) { printf("\telg a: "); mpi_print(stdout, sig->d.elg.a, mpi_print_mode ); printf("\n\telg b: "); mpi_print(stdout, sig->d.elg.b, mpi_print_mode ); putchar('\n'); } } else if( sig->pubkey_algo == PUBKEY_ALGO_DSA ) { n = pktlen; sig->d.dsa.r = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; sig->d.dsa.s = mpi_read(inp, &n, 0 ); pktlen -=n; if( list_mode ) { printf("\tdsa r: "); mpi_print(stdout, sig->d.elg.a, mpi_print_mode ); printf("\n\tdsa s: "); mpi_print(stdout, sig->d.elg.b, mpi_print_mode ); putchar('\n'); } } else if( sig->pubkey_algo == PUBKEY_ALGO_RSA ) { n = pktlen; sig->d.rsa.rsa_integer = mpi_read(inp, &n, 0 ); pktlen -=n; if( list_mode ) { printf("\trsa integer: "); mpi_print(stdout, sig->d.rsa.rsa_integer, mpi_print_mode ); putchar('\n'); } } else if( list_mode ) printf("\tunknown algorithm %d\n", sig->pubkey_algo ); leave: skip_rest(inp, pktlen); return rc; } static int parse_onepass_sig( IOBUF inp, int pkttype, unsigned long pktlen, PKT_onepass_sig *ops ) { int version; if( pktlen < 13 ) { log_error("packet(%d) too short\n", pkttype); goto leave; } version = iobuf_get_noeof(inp); pktlen--; if( version != 3 ) { log_error("onepass_sig with unknown version %d\n", version); goto leave; } ops->sig_class = iobuf_get_noeof(inp); pktlen--; ops->digest_algo = iobuf_get_noeof(inp); pktlen--; ops->pubkey_algo = iobuf_get_noeof(inp); pktlen--; ops->keyid[0] = read_32(inp); pktlen -= 4; ops->keyid[1] = read_32(inp); pktlen -= 4; ops->last = iobuf_get_noeof(inp); pktlen--; if( list_mode ) printf(":onepass_sig packet: keyid %08lX%08lX\n" "\tversion %d, sigclass %02x, digest %d, pubkey %d, last=%d\n", (ulong)ops->keyid[0], (ulong)ops->keyid[1], version, ops->sig_class, ops->digest_algo, ops->pubkey_algo, ops->last ); leave: skip_rest(inp, pktlen); return 0; } static int parse_certificate( IOBUF inp, int pkttype, unsigned long pktlen, byte *hdr, int hdrlen, PACKET *pkt ) { int i, version, algorithm; unsigned n; unsigned long timestamp; unsigned short valid_period; int is_v4=0; int rc=0; version = iobuf_get_noeof(inp); pktlen--; if( pkttype == PKT_PUBKEY_SUBCERT && version == '#' ) { /* early versions of G10 use old comments packets; luckily all those * comments are started by a hash */ if( list_mode ) { printf(":old comment packet: \"" ); for( ; pktlen; pktlen-- ) { int c; c = iobuf_get_noeof(inp); if( c >= ' ' && c <= 'z' ) putchar(c); else printf("\\x%02x", c ); } printf("\"\n"); } skip_rest(inp, pktlen); return 0; } else if( version == 4 ) is_v4=1; else if( version != 2 && version != 3 ) { log_error("packet(%d) with unknown version %d\n", pkttype, version); goto leave; } if( pktlen < 11 ) { log_error("packet(%d) too short\n", pkttype); goto leave; } timestamp = read_32(inp); pktlen -= 4; if( is_v4 ) valid_period = 0; else { valid_period = read_16(inp); pktlen -= 2; } algorithm = iobuf_get_noeof(inp); pktlen--; if( list_mode ) printf(":%s key packet:\n" "\tversion %d, created %lu, valid for %hu days\n", pkttype == PKT_PUBLIC_CERT? "public" : pkttype == PKT_SECRET_CERT? "secret" : pkttype == PKT_PUBKEY_SUBCERT? "public sub" : pkttype == PKT_SECKEY_SUBCERT? "secret sub" : "??", version, timestamp, valid_period ); if( pkttype == PKT_SECRET_CERT || pkttype == PKT_SECKEY_SUBCERT ) { pkt->pkt.secret_cert->timestamp = timestamp; pkt->pkt.secret_cert->valid_days = valid_period; pkt->pkt.secret_cert->hdrbytes = hdrlen; pkt->pkt.secret_cert->version = version; pkt->pkt.secret_cert->pubkey_algo = algorithm; } else { pkt->pkt.public_cert->timestamp = timestamp; pkt->pkt.public_cert->valid_days = valid_period; pkt->pkt.public_cert->hdrbytes = hdrlen; pkt->pkt.public_cert->version = version; pkt->pkt.public_cert->pubkey_algo = algorithm; } if( algorithm == PUBKEY_ALGO_ELGAMAL ) { MPI elg_p, elg_g, elg_y; n = pktlen; elg_p = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; elg_g = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; elg_y = mpi_read(inp, &n, 0 ); pktlen -=n; if( list_mode ) { printf( "\telg p: "); mpi_print(stdout, elg_p, mpi_print_mode ); printf("\n\telg g: "); mpi_print(stdout, elg_g, mpi_print_mode ); printf("\n\telg y: "); mpi_print(stdout, elg_y, mpi_print_mode ); putchar('\n'); } if( pkttype == PKT_PUBLIC_CERT || pkttype == PKT_PUBKEY_SUBCERT ) { pkt->pkt.public_cert->d.elg.p = elg_p; pkt->pkt.public_cert->d.elg.g = elg_g; pkt->pkt.public_cert->d.elg.y = elg_y; } else { PKT_secret_cert *cert = pkt->pkt.secret_cert; byte temp[8]; pkt->pkt.secret_cert->d.elg.p = elg_p; pkt->pkt.secret_cert->d.elg.g = elg_g; pkt->pkt.secret_cert->d.elg.y = elg_y; cert->protect.algo = iobuf_get_noeof(inp); pktlen--; if( cert->protect.algo ) { cert->is_protected = 1; cert->protect.count = 0; if( cert->protect.algo == 255 ) { if( pktlen < 3 ) { rc = G10ERR_INVALID_PACKET; goto leave; } cert->protect.algo = iobuf_get_noeof(inp); pktlen--; cert->protect.s2k = iobuf_get_noeof(inp); pktlen--; cert->protect.hash = iobuf_get_noeof(inp); pktlen--; switch( cert->protect.s2k ) { case 1: case 3: for(i=0; i < 8 && pktlen; i++, pktlen-- ) temp[i] = iobuf_get_noeof(inp); memcpy(cert->protect.salt, temp, 8 ); break; } switch( cert->protect.s2k ) { case 0: if( list_mode ) printf( "\tsimple S2K" ); break; case 1: if( list_mode ) printf( "\tsalted S2K" ); break; case 3: if( list_mode ) printf( "\titer+salt S2K" ); break; default: if( list_mode ) printf( "\tunknown S2K %d\n", cert->protect.s2k ); rc = G10ERR_INVALID_PACKET; goto leave; } if( list_mode ) { printf(", algo: %d, hash: %d", cert->protect.algo, cert->protect.hash ); if( cert->protect.s2k == 1 || cert->protect.s2k == 3 ) { printf(", salt: "); for(i=0; i < 8; i++ ) printf("%02x", cert->protect.salt[i]); } putchar('\n'); } if( cert->protect.s2k == 3 ) { if( !pktlen ) { rc = G10ERR_INVALID_PACKET; goto leave; } cert->protect.count = iobuf_get_noeof(inp); pktlen--; } } else { if( list_mode ) printf( "\tprotect algo: %d\n", cert->protect.algo); /* old version, we don't have a S2K, so we fake one */ cert->protect.s2k = 0; /* We need this kludge to cope with old GNUPG versions */ cert->protect.hash = cert->protect.algo == CIPHER_ALGO_BLOWFISH? DIGEST_ALGO_RMD160 : DIGEST_ALGO_MD5; } if( pktlen < 8 ) { rc = G10ERR_INVALID_PACKET; goto leave; } for(i=0; i < 8 && pktlen; i++, pktlen-- ) temp[i] = iobuf_get_noeof(inp); if( list_mode ) { printf( "\tprotect IV: "); for(i=0; i < 8; i++ ) printf(" %02x", temp[i] ); putchar('\n'); } memcpy(cert->protect.iv, temp, 8 ); } else cert->is_protected = 0; /* It does not make sense to read it into secure memory. * If the user is so careless, not to protect his secret key, * we can assume, that he operates an open system :=(. * So we put the key into secure memory when we unprotect him. */ n = pktlen; cert->d.elg.x = mpi_read(inp, &n, 0 ); pktlen -=n; cert->csum = read_16(inp); pktlen -= 2; if( list_mode ) { printf("\telg x: "); mpi_print(stdout, cert->d.elg.x, mpi_print_mode ); putchar('\n'); printf("\t[secret value x is not shown]\n" "\tchecksum: %04hx\n", cert->csum); } /*log_mpidump("elg p=", cert->d.elg.p ); log_mpidump("elg g=", cert->d.elg.g ); log_mpidump("elg y=", cert->d.elg.y ); log_mpidump("elg x=", cert->d.elg.x ); */ } } else if( algorithm == PUBKEY_ALGO_DSA ) { MPI dsa_p, dsa_q, dsa_g, dsa_y; n = pktlen; dsa_p = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; dsa_q = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; dsa_g = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; dsa_y = mpi_read(inp, &n, 0 ); pktlen -=n; if( list_mode ) { printf( "\tdsa p: "); mpi_print(stdout, dsa_p, mpi_print_mode ); printf("\n\tdsa q: "); mpi_print(stdout, dsa_q, mpi_print_mode ); printf("\n\tdsa g: "); mpi_print(stdout, dsa_g, mpi_print_mode ); printf("\n\tdsa y: "); mpi_print(stdout, dsa_y, mpi_print_mode ); putchar('\n'); } if( pkttype == PKT_PUBLIC_CERT || pkttype == PKT_PUBKEY_SUBCERT ) { pkt->pkt.public_cert->d.dsa.p = dsa_p; pkt->pkt.public_cert->d.dsa.q = dsa_q; pkt->pkt.public_cert->d.dsa.g = dsa_g; pkt->pkt.public_cert->d.dsa.y = dsa_y; } else { PKT_secret_cert *cert = pkt->pkt.secret_cert; byte temp[8]; pkt->pkt.secret_cert->d.dsa.p = dsa_p; pkt->pkt.secret_cert->d.dsa.q = dsa_q; pkt->pkt.secret_cert->d.dsa.g = dsa_g; pkt->pkt.secret_cert->d.dsa.y = dsa_y; cert->protect.algo = iobuf_get_noeof(inp); pktlen--; if( cert->protect.algo ) { cert->is_protected = 1; cert->protect.count = 0; if( cert->protect.algo == 255 ) { if( pktlen < 3 ) { rc = G10ERR_INVALID_PACKET; goto leave; } cert->protect.algo = iobuf_get_noeof(inp); pktlen--; cert->protect.s2k = iobuf_get_noeof(inp); pktlen--; cert->protect.hash = iobuf_get_noeof(inp); pktlen--; switch( cert->protect.s2k ) { case 1: case 3: for(i=0; i < 8 && pktlen; i++, pktlen-- ) temp[i] = iobuf_get_noeof(inp); memcpy(cert->protect.salt, temp, 8 ); break; } switch( cert->protect.s2k ) { case 0: if( list_mode ) printf( "\tsimple S2K" ); break; case 1: if( list_mode ) printf( "\tsalted S2K" ); break; case 3: if( list_mode ) printf( "\titer+salt S2K" ); break; default: if( list_mode ) printf( "\tunknown S2K %d\n", cert->protect.s2k ); rc = G10ERR_INVALID_PACKET; goto leave; } if( list_mode ) { printf(", algo: %d, hash: %d", cert->protect.algo, cert->protect.hash ); if( cert->protect.s2k == 1 || cert->protect.s2k == 3 ){ printf(", salt: "); for(i=0; i < 8; i++ ) printf("%02x", cert->protect.salt[i]); } putchar('\n'); } if( cert->protect.s2k == 3 ) { if( !pktlen ) { rc = G10ERR_INVALID_PACKET; goto leave; } cert->protect.count = iobuf_get_noeof(inp); pktlen--; } } else { if( list_mode ) printf( "\tprotect algo: %d\n", cert->protect.algo); /* old version, we don't have a S2K, so we fake one */ cert->protect.s2k = 0; cert->protect.hash = DIGEST_ALGO_MD5; } if( pktlen < 8 ) { rc = G10ERR_INVALID_PACKET; goto leave; } for(i=0; i < 8 && pktlen; i++, pktlen-- ) temp[i] = iobuf_get_noeof(inp); if( list_mode ) { printf( "\tprotect IV: "); for(i=0; i < 8; i++ ) printf(" %02x", temp[i] ); putchar('\n'); } memcpy(cert->protect.iv, temp, 8 ); } else cert->is_protected = 0; /* It does not make sense to read it into secure memory. * If the user is so careless, not to protect his secret key, * we can assume, that he operates an open system :=(. * So we put the key into secure memory when we unprotect him. */ n = pktlen; cert->d.dsa.x = mpi_read(inp, &n, 0 ); pktlen -=n; cert->csum = read_16(inp); pktlen -= 2; if( list_mode ) { printf("\t[secret value x is not shown]\n" "\tchecksum: %04hx\n", cert->csum); } /*log_mpidump("dsa p=", cert->d.dsa.p ); log_mpidump("dsa q=", cert->d.dsa.q ); log_mpidump("dsa g=", cert->d.dsa.g ); log_mpidump("dsa y=", cert->d.dsa.y ); log_mpidump("dsa x=", cert->d.dsa.x ); */ } } else if( algorithm == PUBKEY_ALGO_RSA ) { MPI rsa_pub_mod, rsa_pub_exp; n = pktlen; rsa_pub_mod = mpi_read(inp, &n, 0); pktlen -=n; n = pktlen; rsa_pub_exp = mpi_read(inp, &n, 0 ); pktlen -=n; if( list_mode ) { printf( "\tpublic modulus n: "); mpi_print(stdout, rsa_pub_mod, mpi_print_mode ); printf("\n\tpublic exponent e: "); mpi_print(stdout, rsa_pub_exp, mpi_print_mode ); putchar('\n'); } if( pkttype == PKT_PUBLIC_CERT || pkttype == PKT_PUBKEY_SUBCERT ) { pkt->pkt.public_cert->d.rsa.rsa_n = rsa_pub_mod; pkt->pkt.public_cert->d.rsa.rsa_e = rsa_pub_exp; } else { PKT_secret_cert *cert = pkt->pkt.secret_cert; byte temp[8]; pkt->pkt.secret_cert->d.rsa.rsa_n = rsa_pub_mod; pkt->pkt.secret_cert->d.rsa.rsa_e = rsa_pub_exp; cert->protect.algo = iobuf_get_noeof(inp); pktlen--; if( list_mode ) printf( "\tprotect algo: %d\n", cert->protect.algo); if( cert->protect.algo ) { cert->is_protected = 1; for(i=0; i < 8 && pktlen; i++, pktlen-- ) temp[i] = iobuf_get_noeof(inp); if( list_mode ) { printf( "\tprotect IV: "); for(i=0; i < 8; i++ ) printf(" %02x", temp[i] ); putchar('\n'); } if( cert->protect.algo == CIPHER_ALGO_BLOWFISH ) memcpy(cert->protect.iv, temp, 8 ); } else cert->is_protected = 0; /* (See comments at the code for elg keys) */ n = pktlen; cert->d.rsa.rsa_d = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; cert->d.rsa.rsa_p = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; cert->d.rsa.rsa_q = mpi_read(inp, &n, 0 ); pktlen -=n; n = pktlen; cert->d.rsa.rsa_u = mpi_read(inp, &n, 0 ); pktlen -=n; cert->csum = read_16(inp); pktlen -= 2; if( list_mode ) { printf("\t[secret values d,p,q,u are not shown]\n" "\tchecksum: %04hx\n", cert->csum); } /* log_mpidump("rsa n=", cert->d.rsa.rsa_n ); log_mpidump("rsa e=", cert->d.rsa.rsa_e ); log_mpidump("rsa d=", cert->d.rsa.rsa_d ); log_mpidump("rsa p=", cert->d.rsa.rsa_p ); log_mpidump("rsa q=", cert->d.rsa.rsa_q ); log_mpidump("rsa u=", cert->d.rsa.rsa_u ); */ } } else if( list_mode ) printf("\tunknown algorithm %d\n", algorithm ); leave: skip_rest(inp, pktlen); return rc; } static int parse_user_id( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *packet ) { byte *p; packet->pkt.user_id = m_alloc(sizeof *packet->pkt.user_id + pktlen - 1); packet->pkt.user_id->len = pktlen; p = packet->pkt.user_id->name; for( ; pktlen; pktlen--, p++ ) *p = iobuf_get_noeof(inp); if( list_mode ) { int n = packet->pkt.user_id->len; printf(":user id packet: \""); for(p=packet->pkt.user_id->name; n; p++, n-- ) { if( *p >= ' ' && *p <= 'z' ) putchar(*p); else printf("\\x%02x", *p ); } printf("\"\n"); } return 0; } static int parse_comment( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *packet ) { byte *p; packet->pkt.comment = m_alloc(sizeof *packet->pkt.comment + pktlen - 1); packet->pkt.comment->len = pktlen; p = packet->pkt.comment->data; for( ; pktlen; pktlen--, p++ ) *p = iobuf_get_noeof(inp); if( list_mode ) { int n = packet->pkt.comment->len; printf(":comment packet: \""); for(p=packet->pkt.comment->data; n; p++, n-- ) { if( *p >= ' ' && *p <= 'z' ) putchar(*p); else printf("\\x%02x", *p ); } printf("\"\n"); } return 0; } static void parse_trust( IOBUF inp, int pkttype, unsigned long pktlen ) { int c; c = iobuf_get_noeof(inp); if( list_mode ) printf(":trust packet: flag=%02x\n", c ); } static int parse_plaintext( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *pkt ) { int mode, namelen; PKT_plaintext *pt; byte *p; int c, i; if( pktlen && pktlen < 6 ) { log_error("packet(%d) too short (%lu)\n", pkttype, (ulong)pktlen); goto leave; } mode = iobuf_get_noeof(inp); if( pktlen ) pktlen--; namelen = iobuf_get_noeof(inp); if( pktlen ) pktlen--; pt = pkt->pkt.plaintext = m_alloc(sizeof *pkt->pkt.plaintext + namelen -1); pt->mode = mode; pt->namelen = namelen; if( pktlen ) { for( i=0; pktlen > 4 && i < namelen; pktlen--, i++ ) pt->name[i] = iobuf_get_noeof(inp); } else { for( i=0; i < namelen; i++ ) if( (c=iobuf_get(inp)) == -1 ) break; else pt->name[i] = c; } pt->timestamp = read_32(inp); if( pktlen) pktlen -= 4; pt->len = pktlen; pt->buf = inp; pktlen = 0; if( list_mode ) { printf(":literal data packet:\n" "\tmode %c, created %lu, name=\"", mode >= ' ' && mode <'z'? mode : '?', (ulong)pt->timestamp ); for(p=pt->name,i=0; i < namelen; p++, i++ ) { if( *p >= ' ' && *p <= 'z' ) putchar(*p); else printf("\\x%02x", *p ); } printf("\",\n\traw data: %lu bytes\n", (ulong)pt->len ); } leave: return 0; } static int parse_compressed( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *pkt ) { PKT_compressed *zd; /* pktlen is here 0, but data follows * (this should be the last object in a file or * the compress algorithm should know the length) */ zd = pkt->pkt.compressed = m_alloc(sizeof *pkt->pkt.compressed ); zd->len = 0; /* not yet used */ zd->algorithm = iobuf_get_noeof(inp); zd->buf = inp; if( list_mode ) printf(":compressed packet: algo=%d\n", zd->algorithm); return 0; } static int parse_encrypted( IOBUF inp, int pkttype, unsigned long pktlen, PACKET *pkt ) { PKT_encrypted *ed; ed = pkt->pkt.encrypted = m_alloc(sizeof *pkt->pkt.encrypted ); ed->len = pktlen; ed->buf = NULL; if( pktlen && pktlen < 10 ) { log_error("packet(%d) too short\n", pkttype); skip_rest(inp, pktlen); goto leave; } if( list_mode ) if( pktlen ) printf(":encrypted data packet:\n\tlength: %lu\n", pktlen-10); else printf(":encrypted data packet:\n\tlength: unknown\n"); ed->buf = inp; pktlen = 0; leave: return 0; }