/* packet-pgm.c * Routines for pgm packet disassembly * * $Id: packet-pgm.c,v 1.7 2001/08/06 19:05:14 guy Exp $ * * Copyright (c) 2000 by Talarian Corp * * Ethereal - Network traffic analyzer * By Gerald Combs * Copyright 1999 Gerald Combs * * This program 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. * * This program 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. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #ifdef HAVE_SYS_TYPES_H #include #endif #ifdef HAVE_SYS_SOCKET_H #include #endif #ifdef HAVE_NETINET_IN_H #include #endif #include #include #include #include #include #include "packet.h" #include "packet-pgm.h" #include "afn.h" #include "ipproto.h" #include "resolv.h" #include "strutil.h" #include "conversation.h" #include "prefs.h" #include "proto.h" void proto_reg_handoff_pgm(void); void proto_rereg_pgm(void); static int udp_encap_ucast_port = 0; static int udp_encap_mcast_port = 0; static int old_encap_ucast_port = 0; static int old_encap_mcast_port = 0; static int proto_pgm = -1; static int ett_pgm = -1; static int ett_pgm_optbits = -1; static int ett_pgm_opts = -1; static int ett_pgm_spm = -1; static int ett_pgm_data = -1; static int ett_pgm_nak = -1; static int ett_pgm_ack = -1; static int ett_pgm_opts_join = -1; static int ett_pgm_opts_parityprm = -1; static int ett_pgm_opts_paritygrp = -1; static int ett_pgm_opts_naklist = -1; static int ett_pgm_opts_ccdata = -1; static int hf_pgm_main_sport = -1; static int hf_pgm_main_dport = -1; static int hf_pgm_main_type = -1; static int hf_pgm_main_opts = -1; static int hf_pgm_main_opts_opt = -1; static int hf_pgm_main_opts_netsig = -1; static int hf_pgm_main_opts_varlen = -1; static int hf_pgm_main_opts_parity = -1; static int hf_pgm_main_cksum = -1; static int hf_pgm_main_gsi = -1; static int hf_pgm_main_tsdulen = -1; static int hf_pgm_spm_sqn = -1; static int hf_pgm_spm_lead = -1; static int hf_pgm_spm_trail = -1; static int hf_pgm_spm_pathafi = -1; static int hf_pgm_spm_res = -1; static int hf_pgm_spm_path = -1; static int hf_pgm_data_sqn = -1; static int hf_pgm_data_trail = -1; static int hf_pgm_nak_sqn = -1; static int hf_pgm_nak_srcafi = -1; static int hf_pgm_nak_srcres = -1; static int hf_pgm_nak_src = -1; static int hf_pgm_nak_grpafi = -1; static int hf_pgm_nak_grpres = -1; static int hf_pgm_nak_grp = -1; static int hf_pgm_ack_sqn = -1; static int hf_pgm_ack_bitmap = -1; static int hf_pgm_opt_type = -1; static int hf_pgm_opt_len = -1; static int hf_pgm_opt_tlen = -1; static int hf_pgm_genopt = -1; static int hf_pgm_genopt_type = -1; static int hf_pgm_genopt_len = -1; static int hf_pgm_genopt_opx = -1; static int hf_pgm_opt_join_res = -1; static int hf_pgm_opt_join_minjoin = -1; static int hf_pgm_opt_parity_prm_po = -1; static int hf_pgm_opt_parity_prm_prmtgsz = -1; static int hf_pgm_opt_parity_grp_res = -1; static int hf_pgm_opt_parity_grp_prmgrp = -1; static int hf_pgm_opt_curr_tgsize_type = -1; static int hf_pgm_opt_curr_tgsize_len = -1; static int hf_pgm_opt_curr_tgsize_opx = -1; static int hf_pgm_opt_curr_tgsize_res = -1; static int hf_pgm_opt_curr_tgsize_prmatgsz = -1; static int hf_pgm_opt_nak_res = -1; static int hf_pgm_opt_nak_list = -1; static int hf_pgm_opt_ccdata_res = -1; static int hf_pgm_opt_ccdata_tsp = -1; static int hf_pgm_opt_ccdata_afi = -1; static int hf_pgm_opt_ccdata_res2 = -1; static int hf_pgm_opt_ccdata_acker = -1; static int hf_pgm_opt_ccfeedbk_res = -1; static int hf_pgm_opt_ccfeedbk_tsp = -1; static int hf_pgm_opt_ccfeedbk_afi = -1; static int hf_pgm_opt_ccfeedbk_lossrate = -1; static int hf_pgm_opt_ccfeedbk_acker = -1; static dissector_table_t subdissector_table; static heur_dissector_list_t heur_subdissector_list; /* * As of the time this comment was typed * * http://search.ietf.org/internet-drafts/draft-speakman-pgm-spec-06.txt * * was the URL for the PGM draft. */ static char * optsstr(nchar_t opts) { static char msg[256]; char *p = msg, *str; if (opts == 0) return(""); if (opts & PGM_OPT){ sprintf(p, "Present"); p += strlen("Present"); } if (opts & PGM_OPT_NETSIG){ if (p != msg) str = ",NetSig"; else str = "NetSig"; sprintf(p, str); p += strlen(str); } if (opts & PGM_OPT_VAR_PKTLEN){ if (p != msg) str = ",VarLen"; else str = "VarLen"; sprintf(p, str); p += strlen(str); } if (opts & PGM_OPT_PARITY){ if (p != msg) str = ",Parity"; else str = "Parity"; sprintf(p, str); p += strlen(str); } if (p == msg) { sprintf(p, "0x%x", opts); } return(msg); } static char * paritystr(nchar_t parity) { static char msg[256]; char *p = msg, *str; if (parity == 0) return(""); if (parity & PGM_OPT_PARITY_PRM_PRO){ sprintf(p, "Pro-active"); p += strlen("Pro-active"); } if (parity & PGM_OPT_PARITY_PRM_OND){ if (p != msg) str = ",On-demand"; else str = "On-demand"; sprintf(p, str); p += strlen(str); } if (p == msg) { sprintf(p, "0x%x", parity); } return(msg); } static const value_string opt_vals[] = { { PGM_OPT_LENGTH, "Length" }, { PGM_OPT_END, "End" }, { PGM_OPT_FRAGMENT, "Fragment" }, { PGM_OPT_NAK_LIST, "NakList" }, { PGM_OPT_JOIN, "Join" }, { PGM_OPT_REDIRECT, "ReDirect" }, { PGM_OPT_SYN, "Syn" }, { PGM_OPT_FIN, "Fin" }, { PGM_OPT_RST, "Rst" }, { PGM_OPT_PARITY_PRM, "ParityPrm" }, { PGM_OPT_PARITY_GRP, "ParityGrp" }, { PGM_OPT_CURR_TGSIZE, "CurrTgsiz" }, { PGM_OPT_PGMCC_DATA, "CcData" }, { PGM_OPT_PGMCC_FEEDBACK, "CcFeedBack" }, { 0, NULL } }; static const value_string opx_vals[] = { { PGM_OPX_IGNORE, "Ignore" }, { PGM_OPX_INVAL, "Inval" }, { PGM_OPX_DISCARD, "DisCard" }, { 0, NULL } }; static void dissect_pgmopts(tvbuff_t *tvb, int offset, proto_tree *tree, const char *pktname) { proto_item *tf; proto_tree *opts_tree = NULL; proto_tree *opt_tree = NULL; pgm_opt_length_t opts; pgm_opt_generic_t genopts; int theend = 0, firsttime = 1; tvb_memcpy(tvb, (guint8 *)&opts, offset, sizeof(opts)); opts.total_len = ntohs(opts.total_len); tf = proto_tree_add_text(tree, tvb, offset, opts.total_len, "%s Options (Total Length %d)", pktname, opts.total_len); opts_tree = proto_item_add_subtree(tf, ett_pgm_opts); proto_tree_add_uint(opts_tree, hf_pgm_opt_type, tvb, offset, 1, opts.type); proto_tree_add_uint(opts_tree, hf_pgm_opt_len, tvb, offset+1, 1, opts.len); proto_tree_add_uint(opts_tree, hf_pgm_opt_tlen, tvb, offset+2, 2, opts.total_len); offset += 4; for (opts.total_len -= 4; opts.total_len > 0;){ tvb_memcpy(tvb, (guint8 *)&genopts, offset, sizeof(genopts)); if (genopts.type & PGM_OPT_END) { genopts.type &= ~PGM_OPT_END; theend = 1; } tf = proto_tree_add_text(opts_tree, tvb, offset, genopts.len, "Option: %s, Length: %u", val_to_str(genopts.type, opt_vals, "Unknown (0x%02x)"), genopts.len); if (genopts.len == 0) break; switch(genopts.type) { case PGM_OPT_JOIN:{ pgm_opt_join_t optdata; tvb_memcpy(tvb, (guint8 *)&optdata, offset, sizeof(optdata)); opt_tree = proto_item_add_subtree(tf, ett_pgm_opts_join); proto_tree_add_uint(opt_tree, hf_pgm_genopt_type, tvb, offset, 1, genopts.type); proto_tree_add_uint(opt_tree, hf_pgm_genopt_len, tvb, offset+1, 1, genopts.len); proto_tree_add_uint(opt_tree, hf_pgm_genopt_opx, tvb, offset+2, 1, genopts.opx); proto_tree_add_uint(opt_tree, hf_pgm_opt_join_res, tvb, offset+3, 1, optdata.res); proto_tree_add_uint(opt_tree, hf_pgm_opt_join_minjoin, tvb, offset+4, 4, ntohl(optdata.opt_join_min)); break; } case PGM_OPT_PARITY_PRM:{ pgm_opt_parity_prm_t optdata; tvb_memcpy(tvb, (guint8 *)&optdata, offset, sizeof(optdata)); opt_tree = proto_item_add_subtree(tf, ett_pgm_opts_parityprm); proto_tree_add_uint(opt_tree, hf_pgm_genopt_type, tvb, offset, 1, genopts.type); proto_tree_add_uint(opt_tree, hf_pgm_genopt_len, tvb, offset+1, 1, genopts.len); proto_tree_add_uint(opt_tree, hf_pgm_genopt_opx, tvb, offset+2, 1, genopts.opx); proto_tree_add_uint_format(opt_tree, hf_pgm_opt_parity_prm_po, tvb, offset+3, 1, optdata.po, "Parity Parameters: %s (0x%x)", paritystr(optdata.po), optdata.po); proto_tree_add_uint(opt_tree, hf_pgm_opt_parity_prm_prmtgsz, tvb, offset+4, 4, ntohl(optdata.prm_tgsz)); break; } case PGM_OPT_PARITY_GRP:{ pgm_opt_parity_grp_t optdata; tvb_memcpy(tvb, (guint8 *)&optdata, offset, sizeof(optdata)); opt_tree = proto_item_add_subtree(tf, ett_pgm_opts_paritygrp); proto_tree_add_uint(opt_tree, hf_pgm_genopt_type, tvb, offset, 1, genopts.type); proto_tree_add_uint(opt_tree, hf_pgm_genopt_len, tvb, offset+1, 1, genopts.len); proto_tree_add_uint(opt_tree, hf_pgm_genopt_opx, tvb, offset+2, 1, genopts.opx); proto_tree_add_uint(opt_tree, hf_pgm_opt_parity_grp_res, tvb, offset+3, 1, optdata.res); proto_tree_add_uint(opt_tree, hf_pgm_opt_parity_grp_prmgrp, tvb, offset+4, 4, ntohl(optdata.prm_grp)); break; } case PGM_OPT_NAK_LIST:{ pgm_opt_nak_list_t optdata; nlong_t naklist[PGM_MAX_NAK_LIST_SZ+1]; char nakbuf[8192], *ptr; int i, j, naks, soffset = 0; tvb_memcpy(tvb, (guint8 *)&optdata, offset, sizeof(optdata)); opt_tree = proto_item_add_subtree(tf, ett_pgm_opts_naklist); proto_tree_add_uint(opt_tree, hf_pgm_genopt_type, tvb, offset, 1, genopts.type); proto_tree_add_uint(opt_tree, hf_pgm_genopt_len, tvb, offset+1, 1, genopts.len); proto_tree_add_uint(opt_tree, hf_pgm_genopt_opx, tvb, offset+2, 1, genopts.opx); proto_tree_add_uint(opt_tree, hf_pgm_opt_nak_res, tvb, offset+3, 1, optdata.res); optdata.len -= sizeof(pgm_opt_nak_list_t); tvb_memcpy(tvb, (guint8 *)naklist, offset+4, optdata.len); naks = (optdata.len/sizeof(nlong_t)); ptr = nakbuf; j = 0; /* * Print out 8 per line */ for (i=0; i < naks; i++) { sprintf(nakbuf+soffset, "0x%lx ", (unsigned long)ntohl(naklist[i])); soffset = strlen(nakbuf); if ((++j % 8) == 0) { if (firsttime) { proto_tree_add_bytes_format(opt_tree, hf_pgm_opt_nak_list, tvb, offset+4, optdata.len, nakbuf, "List(%d): %s", naks, nakbuf); soffset = 0; } else { proto_tree_add_bytes_format(opt_tree, hf_pgm_opt_nak_list, tvb, offset+4, optdata.len, nakbuf, "List: %s", nakbuf); soffset = 0; } firsttime = 0; } } if (soffset) { if (firsttime) { proto_tree_add_bytes_format(opt_tree, hf_pgm_opt_nak_list, tvb, offset+4, optdata.len, nakbuf, "List(%d): %s", naks, nakbuf); soffset = 0; } else { proto_tree_add_bytes_format(opt_tree, hf_pgm_opt_nak_list, tvb, offset+4, optdata.len, nakbuf, "List: %s", nakbuf); soffset = 0; } } break; } case PGM_OPT_PGMCC_DATA:{ pgm_opt_pgmcc_data_t optdata; tvb_memcpy(tvb, (guint8 *)&optdata, offset, sizeof(optdata)); opt_tree = proto_item_add_subtree(tf, ett_pgm_opts_ccdata); proto_tree_add_uint(opt_tree, hf_pgm_genopt_type, tvb, offset, 1, genopts.type); proto_tree_add_uint(opt_tree, hf_pgm_genopt_len, tvb, offset+1, 1, genopts.len); proto_tree_add_uint(opt_tree, hf_pgm_genopt_opx, tvb, offset+2, 1, genopts.opx); proto_tree_add_uint(opt_tree, hf_pgm_opt_ccdata_res, tvb, offset+3, 1, optdata.res); proto_tree_add_uint(opt_tree, hf_pgm_opt_ccdata_tsp, tvb, offset+4, 4, optdata.tsp); proto_tree_add_uint(opt_tree, hf_pgm_opt_ccdata_afi, tvb, offset+8, 2, ntohs(optdata.acker_afi)); proto_tree_add_uint(opt_tree, hf_pgm_opt_ccdata_res2, tvb, offset+10, 2, ntohs(optdata.res2)); switch (ntohs(optdata.acker_afi)) { case AFNUM_INET: proto_tree_add_ipv4(opt_tree, hf_pgm_opt_ccdata_acker, tvb, offset+12, 4, optdata.acker); break; default: /* * XXX - the header is variable-length, * as the length of the NLA depends on * its AFI. * * However, our structure for it is * fixed-length, and assumes it's a 4-byte * IPv4 address. */ break; } break; } case PGM_OPT_PGMCC_FEEDBACK:{ pgm_opt_pgmcc_feedback_t optdata; tvb_memcpy(tvb, (guint8 *)&optdata, offset, sizeof(optdata)); opt_tree = proto_item_add_subtree(tf, ett_pgm_opts_ccdata); proto_tree_add_uint(opt_tree, hf_pgm_genopt_type, tvb, offset, 1, genopts.type); proto_tree_add_uint(opt_tree, hf_pgm_genopt_len, tvb, offset+1, 1, genopts.len); proto_tree_add_uint(opt_tree, hf_pgm_genopt_opx, tvb, offset+2, 1, genopts.opx); proto_tree_add_uint(opt_tree, hf_pgm_opt_ccfeedbk_res, tvb, offset+3, 1, optdata.res); proto_tree_add_uint(opt_tree, hf_pgm_opt_ccfeedbk_tsp, tvb, offset+4, 4, optdata.tsp); proto_tree_add_uint(opt_tree, hf_pgm_opt_ccfeedbk_afi, tvb, offset+8, 2, ntohs(optdata.acker_afi)); proto_tree_add_uint(opt_tree, hf_pgm_opt_ccfeedbk_lossrate, tvb, offset+10, 2, ntohs(optdata.loss_rate)); switch (ntohs(optdata.acker_afi)) { case AFNUM_INET: proto_tree_add_ipv4(opt_tree, hf_pgm_opt_ccfeedbk_acker, tvb, offset+12, 4, optdata.acker); break; default: /* * XXX - the header is variable-length, * as the length of the NLA depends on * its AFI. * * However, our structure for it is * fixed-length, and assumes it's a 4-byte * IPv4 address. */ break; } break; } } offset += genopts.len; opts.total_len -= genopts.len; } return ; } static const value_string type_vals[] = { { PGM_SPM_PCKT, "SPM" }, { PGM_RDATA_PCKT, "RDATA" }, { PGM_ODATA_PCKT, "ODATA" }, { PGM_NAK_PCKT, "NAK" }, { PGM_NNAK_PCKT, "NNAK" }, { PGM_NCF_PCKT, "NCF" }, { PGM_ACK_PCKT, "ACK" }, { 0, NULL } }; /* Determine if there is a sub-dissector and call it. This has been */ /* separated into a stand alone routine to other protocol dissectors */ /* can call to it, ie. socks */ void decode_pgm_ports(tvbuff_t *tvb, int offset, packet_info *pinfo, proto_tree *tree, pgm_type *pgmhdr) { tvbuff_t *next_tvb; int found = 0; next_tvb = tvb_new_subset(tvb, offset, -1, -1); /* do lookup with the subdissector table */ found = dissector_try_port(subdissector_table, pgmhdr->sport, next_tvb, pinfo, tree); if (found) return; found = dissector_try_port(subdissector_table, pgmhdr->dport, next_tvb, pinfo, tree); if (found) return; /* do lookup with the heuristic subdissector table */ if (dissector_try_heuristic(heur_subdissector_list, next_tvb, pinfo, tree)) return; /* Oh, well, we don't know this; dissect it as data. */ dissect_data(next_tvb, 0, pinfo, tree); } int total_size(tvbuff_t *tvb, pgm_type *hdr) { int bytes = sizeof(pgm_type); pgm_opt_length_t opts; switch(hdr->type) { case PGM_SPM_PCKT: bytes += sizeof(pgm_spm_t); break; case PGM_RDATA_PCKT: case PGM_ODATA_PCKT: bytes += sizeof(pgm_data_t); break; case PGM_NAK_PCKT: case PGM_NNAK_PCKT: case PGM_NCF_PCKT: bytes += sizeof(pgm_nak_t); break; case PGM_ACK_PCKT: bytes += sizeof(pgm_ack_t); break; } if ((hdr->opts & PGM_OPT)) { tvb_memcpy(tvb, (guint8 *)&opts, bytes, sizeof(opts)); bytes += ntohs(opts.total_len); } return(bytes); } /* * dissect_pgm - The dissector for Pragmatic General Multicast */ static void dissect_pgm(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree) { proto_tree *pgm_tree = NULL; proto_tree *opt_tree = NULL; proto_tree *type_tree = NULL; proto_item *tf; pgm_type pgmhdr; pgm_spm_t spm; pgm_data_t data; pgm_nak_t nak; pgm_ack_t ack; int offset = 0; guint hlen, plen; proto_item *ti; const char *pktname; char *gsi; int isdata = 0; if (check_col(pinfo->fd, COL_PROTOCOL)) col_set_str(pinfo->fd, COL_PROTOCOL, "PGM"); /* Clear out the Info column. */ if (check_col(pinfo->fd, COL_INFO)) col_clear(pinfo->fd, COL_INFO); tvb_memcpy(tvb, (guint8 *)&pgmhdr, offset, sizeof(pgm_type)); hlen = sizeof(pgm_type); pgmhdr.sport = ntohs(pgmhdr.sport); pgmhdr.dport = ntohs(pgmhdr.dport); pgmhdr.tsdulen = ntohs(pgmhdr.tsdulen); pktname = val_to_str(pgmhdr.type, type_vals, "Unknown (0x%02x)"); gsi = bytes_to_str(pgmhdr.gsi, 6); switch(pgmhdr.type) { case PGM_SPM_PCKT: plen = sizeof(pgm_spm_t); tvb_memcpy(tvb, (guint8 *)&spm, sizeof(pgm_type), plen); spm_ntoh(&spm); if (check_col(pinfo->fd, COL_INFO)) { col_add_fstr(pinfo->fd, COL_INFO, "%-5s sqn 0x%x gsi %s", pktname, spm.sqn, gsi); } break; case PGM_RDATA_PCKT: case PGM_ODATA_PCKT: plen = sizeof(pgm_data_t); tvb_memcpy(tvb, (guint8 *)&data, sizeof(pgm_type), plen); data_ntoh(&data); if (check_col(pinfo->fd, COL_INFO)) { col_add_fstr(pinfo->fd, COL_INFO, "%-5s sqn 0x%x gsi %s tsdulen %d", pktname, data.sqn, gsi, pgmhdr.tsdulen); } isdata = 1; break; case PGM_NAK_PCKT: case PGM_NNAK_PCKT: case PGM_NCF_PCKT: plen = sizeof(pgm_nak_t); tvb_memcpy(tvb, (guint8 *)&nak, sizeof(pgm_type), plen); nak_ntoh(&nak); if (check_col(pinfo->fd, COL_INFO)) { col_add_fstr(pinfo->fd, COL_INFO, "%-5s sqn 0x%x gsi %s", pktname, nak.sqn, gsi); } break; case PGM_ACK_PCKT: plen = sizeof(pgm_ack_t); tvb_memcpy(tvb, (guint8 *)&ack, sizeof(pgm_type), plen); ack_ntoh(&ack); if (check_col(pinfo->fd, COL_INFO)) { col_add_fstr(pinfo->fd, COL_INFO, "%-5s sqn 0x%x gsi %s", pktname, ack.rx_max_sqn, gsi); } break; default: return; } if (tree) { ti = proto_tree_add_protocol_format(tree, proto_pgm, tvb, offset, total_size(tvb, &pgmhdr), "Pragmatic General Multicast: Type %s" " SrcPort %u, DstPort %u, GSI %s", pktname, pgmhdr.sport, pgmhdr.dport, bytes_to_str(pgmhdr.gsi, 6)); pgm_tree = proto_item_add_subtree(ti, ett_pgm); proto_tree_add_uint(pgm_tree, hf_pgm_main_sport, tvb, offset, 2, pgmhdr.sport); proto_tree_add_uint(pgm_tree, hf_pgm_main_dport, tvb, offset+2, 2, pgmhdr.dport); proto_tree_add_uint(pgm_tree, hf_pgm_main_type, tvb, offset+4, 1, pgmhdr.type); tf = proto_tree_add_uint_format(pgm_tree, hf_pgm_main_opts, tvb, offset+5, 1, pgmhdr.opts, "Options: %s (0x%x)", optsstr(pgmhdr.opts), pgmhdr.opts); opt_tree = proto_item_add_subtree(tf, ett_pgm_optbits); proto_tree_add_boolean(opt_tree, hf_pgm_main_opts_opt, tvb, offset+5, 1, (pgmhdr.opts & PGM_OPT)); proto_tree_add_boolean(opt_tree, hf_pgm_main_opts_netsig, tvb, offset+5, 1, (pgmhdr.opts & PGM_OPT_NETSIG)); proto_tree_add_boolean(opt_tree, hf_pgm_main_opts_varlen, tvb, offset+5, 1, (pgmhdr.opts & PGM_OPT_VAR_PKTLEN)); proto_tree_add_boolean(opt_tree, hf_pgm_main_opts_parity, tvb, offset+5, 1, (pgmhdr.opts & PGM_OPT_PARITY)); proto_tree_add_uint(pgm_tree, hf_pgm_main_cksum, tvb, offset+6, 2, pgmhdr.cksum); proto_tree_add_bytes(pgm_tree, hf_pgm_main_gsi, tvb, offset+8, 6, pgmhdr.gsi); proto_tree_add_uint(pgm_tree, hf_pgm_main_tsdulen, tvb, offset+14, 2, pgmhdr.tsdulen); offset = sizeof(pgm_type); tf = proto_tree_add_text(pgm_tree, tvb, offset, plen, "%s Packet", pktname); switch(pgmhdr.type) { case PGM_SPM_PCKT: type_tree = proto_item_add_subtree(tf, ett_pgm_spm); proto_tree_add_uint(type_tree, hf_pgm_spm_sqn, tvb, offset, 4, spm.sqn); proto_tree_add_uint(type_tree, hf_pgm_spm_trail, tvb, offset+4, 4, spm.trail); proto_tree_add_uint(type_tree, hf_pgm_spm_lead, tvb, offset+8, 4, spm.lead); proto_tree_add_uint(type_tree, hf_pgm_spm_pathafi, tvb, offset+10, 2, spm.path_afi); proto_tree_add_uint(type_tree, hf_pgm_spm_res, tvb, offset+12, 2, spm.res); switch (spm.path_afi) { case AFNUM_INET: proto_tree_add_ipv4(type_tree, hf_pgm_spm_path, tvb, offset+14, 4, spm.path); break; default: /* * XXX - the header is variable-length, * as the length of the NLA depends on * its AFI. * * However, our structure for it is * fixed-length, and assumes it's a 4-byte * IPv4 address. */ return; } if ((pgmhdr.opts & PGM_OPT) == FALSE) break; offset += plen; dissect_pgmopts(tvb, offset, type_tree, pktname); break; case PGM_RDATA_PCKT: case PGM_ODATA_PCKT: { tvbuff_t *next_tvb; type_tree = proto_item_add_subtree(tf, ett_pgm_data); proto_tree_add_uint(type_tree, hf_pgm_spm_sqn, tvb, offset, 4, data.sqn); proto_tree_add_uint(type_tree, hf_pgm_spm_trail, tvb, offset+4, 4, data.trail); if ((pgmhdr.opts & PGM_OPT) == FALSE) break; offset += plen; dissect_pgmopts(tvb, offset, type_tree, pktname); break; } case PGM_NAK_PCKT: case PGM_NNAK_PCKT: case PGM_NCF_PCKT: type_tree = proto_item_add_subtree(tf, ett_pgm_nak); proto_tree_add_uint(type_tree, hf_pgm_nak_sqn, tvb, offset, 4, nak.sqn); proto_tree_add_uint(type_tree, hf_pgm_nak_srcafi, tvb, offset+4, 2, nak.src_afi); proto_tree_add_uint(type_tree, hf_pgm_nak_srcres, tvb, offset+6, 2, nak.src_res); switch (nak.src_afi) { case AFNUM_INET: proto_tree_add_ipv4(type_tree, hf_pgm_nak_src, tvb, offset+8, 4, nak.src); break; default: /* * XXX - the header is variable-length, * as the length of the NLA depends on * its AFI. * * However, our structure for it is * fixed-length, and assumes it's a 4-byte * IPv4 address. */ break; } proto_tree_add_uint(type_tree, hf_pgm_nak_grpafi, tvb, offset+12, 2, nak.grp_afi); proto_tree_add_uint(type_tree, hf_pgm_nak_grpres, tvb, offset+14, 2, nak.grp_res); switch (nak.grp_afi) { case AFNUM_INET: proto_tree_add_ipv4(type_tree, hf_pgm_nak_grp, tvb, offset+16, 4, nak.grp); break; default: /* * XXX - the header is variable-length, * as the length of the NLA depends on * its AFI. * * However, our structure for it is * fixed-length, and assumes it's a 4-byte * IPv4 address. */ return; } if ((pgmhdr.opts & PGM_OPT) == FALSE) break; offset += plen; dissect_pgmopts(tvb, offset, type_tree, pktname); break; case PGM_ACK_PCKT: type_tree = proto_item_add_subtree(tf, ett_pgm_ack); proto_tree_add_uint(type_tree, hf_pgm_ack_sqn, tvb, offset, 4, ack.rx_max_sqn); proto_tree_add_uint(type_tree, hf_pgm_ack_bitmap, tvb, offset+4, 4, ack.bitmap); if ((pgmhdr.opts & PGM_OPT) == FALSE) break; offset += plen; dissect_pgmopts(tvb, offset, type_tree, pktname); break; } } if (isdata) { /* * Now see if there are any sub-dissectors, if so call them */ offset = total_size(tvb, &pgmhdr); decode_pgm_ports(tvb, offset, pinfo, tree, &pgmhdr); } pktname = NULL; } static const true_false_string opts_present = { "Present", "Not Present" }; /* Register all the bits needed with the filtering engine */ void proto_register_pgm(void) { static hf_register_info hf[] = { { &hf_pgm_main_sport, { "Source Port", "pgm.hdr.sport", FT_UINT16, BASE_DEC, NULL, 0x0, "", HFILL }}, { &hf_pgm_main_dport, { "Destination Port", "pgm.hdr.dport", FT_UINT16, BASE_DEC, NULL, 0x0, "", HFILL }}, { &hf_pgm_main_type, { "Type", "pgm.hdr.type", FT_UINT8, BASE_HEX, VALS(type_vals), 0x0, "", HFILL }}, { &hf_pgm_main_opts, { "Options", "pgm.hdr.opts", FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_main_opts_opt, { "Options", "pgm.hdr.opts.opt", FT_BOOLEAN, BASE_NONE, TFS(&opts_present), PGM_OPT, "", HFILL }}, { &hf_pgm_main_opts_netsig, { "Network Significant Options", "pgm.hdr.opts.netsig", FT_BOOLEAN, BASE_NONE, TFS(&opts_present), PGM_OPT_NETSIG, "", HFILL }}, { &hf_pgm_main_opts_varlen, { "Variable length Parity Packet Option", "pgm.hdr.opts.varlen", FT_BOOLEAN, BASE_NONE, TFS(&opts_present), PGM_OPT_VAR_PKTLEN, "", HFILL }}, { &hf_pgm_main_opts_parity, { "Parity", "pgm.hdr.opts.parity", FT_BOOLEAN, BASE_NONE, TFS(&opts_present), PGM_OPT_PARITY, "", HFILL }}, { &hf_pgm_main_cksum, { "Checksum", "pgm.hdr.cksum", FT_UINT16, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_main_gsi, { "Global Source Identifier", "pgm.hdr.gsi", FT_BYTES, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_main_tsdulen, { "Transport Service Data Unit Length", "pgm.hdr.tsdulen", FT_UINT16, BASE_DEC, NULL, 0x0, "", HFILL }}, { &hf_pgm_spm_sqn, { "Sequence number", "pgm.spm.sqn", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_spm_trail, { "Trailing Edge Sequence Number", "pgm.spm.trail", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_spm_lead, { "Leading Edge Sequence Number", "pgm.spm.lead", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_spm_pathafi, { "Path NLA AFI", "pgm.spm.pathafi", FT_UINT16, BASE_DEC, VALS(afn_vals), 0x0, "", HFILL }}, { &hf_pgm_spm_res, { "Reserved", "pgm.spm.res", FT_UINT16, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_spm_path, { "Path NLA", "pgm.spm.path", FT_IPv4, BASE_NONE, NULL, 0x0, "", HFILL }}, { &hf_pgm_data_sqn, { "Data Packet Sequence Number", "pgm.data.sqn", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_data_trail, { "Trailing Edge Sequence Number", "pgm.data.trail", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_nak_sqn, { "Requested Sequence Number", "pgm.nak.sqn", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_nak_srcafi, { "Source NLA AFI", "pgm.nak.srcafi", FT_UINT16, BASE_DEC, VALS(afn_vals), 0x0, "", HFILL }}, { &hf_pgm_nak_srcres, { "Reserved", "pgm.nak.srcres", FT_UINT16, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_nak_src, { "Source NLA", "pgm.nak.src", FT_IPv4, BASE_NONE, NULL, 0x0, "", HFILL }}, { &hf_pgm_nak_grpafi, { "Multicast Group AFI", "pgm.nak.grpafi", FT_UINT16, BASE_DEC, VALS(afn_vals), 0x0, "", HFILL }}, { &hf_pgm_nak_grpres, { "Reserved", "pgm.nak.grpres", FT_UINT16, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_nak_grp, { "Multicast Group NLA", "pgm.nak.grp", FT_IPv4, BASE_NONE, NULL, 0x0, "", HFILL }}, { &hf_pgm_ack_sqn, { "Maximum Received Sequence Number", "pgm.ack.maxsqn", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_ack_bitmap, { "Packet Bitmap", "pgm.ack.bitmap", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_type, { "Type", "pgm.opts.type", FT_UINT8, BASE_HEX, VALS(opt_vals), 0x0, "", HFILL }}, { &hf_pgm_opt_len, { "Length", "pgm.opts.len", FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_tlen, { "Total Length", "pgm.opts.tlen", FT_UINT16, BASE_DEC, NULL, 0x0, "", HFILL }}, { &hf_pgm_genopt_type, { "Type", "pgm.genopts.type", FT_UINT8, BASE_HEX, VALS(opt_vals), 0x0, "", HFILL }}, { &hf_pgm_genopt_len, { "Length", "pgm.genopts.len", FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }}, { &hf_pgm_genopt_opx, { "Option Extensibility Bits", "pgm.genopts.opx", FT_UINT8, BASE_HEX, VALS(opx_vals), 0x0, "", HFILL }}, { &hf_pgm_opt_parity_prm_po, { "Parity Parameters", "pgm.opts.parity_prm.op", FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_parity_prm_prmtgsz, { "Transmission Group Size", "pgm.opts.parity_prm.prm_grp", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_join_res, { "Reserved", "pgm.opts.join.res", FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_join_minjoin, { "Minimum Sequence Number", "pgm.opts.join.min_join", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_parity_grp_res, { "Reserved", "pgm.opts.parity_prm.op", FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_parity_grp_prmgrp, { "Transmission Group Size", "pgm.opts.parity_prm.prm_grp", FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_nak_res, { "Reserved", "pgm.opts.nak.op", FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_nak_list, { "List", "pgm.opts.nak.list", FT_BYTES, BASE_NONE, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_ccdata_res, { "Reserved", "pgm.opts.ccdata.res", FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_ccdata_tsp, { "Time Stamp", "pgm.opts.ccdata.tstamp", FT_UINT16, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_ccdata_afi, { "Acker AFI", "pgm.opts.ccdata.afi", FT_UINT16, BASE_DEC, VALS(afn_vals), 0x0, "", HFILL }}, { &hf_pgm_opt_ccdata_res2, { "Reserved", "pgm.opts.ccdata.res2", FT_UINT16, BASE_DEC, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_ccdata_acker, { "Acker", "pgm.opts.ccdata.acker", FT_IPv4, BASE_NONE, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_ccfeedbk_res, { "Reserved", "pgm.opts.ccdata.res", FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_ccfeedbk_tsp, { "Time Stamp", "pgm.opts.ccdata.tstamp", FT_UINT16, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_ccfeedbk_afi, { "Acker AFI", "pgm.opts.ccdata.afi", FT_UINT16, BASE_DEC, VALS(afn_vals), 0x0, "", HFILL }}, { &hf_pgm_opt_ccfeedbk_lossrate, { "Loss Rate", "pgm.opts.ccdata.lossrate", FT_UINT16, BASE_HEX, NULL, 0x0, "", HFILL }}, { &hf_pgm_opt_ccfeedbk_acker, { "Acker", "pgm.opts.ccdata.acker", FT_IPv4, BASE_NONE, NULL, 0x0, "", HFILL }}, }; static gint *ett[] = { &ett_pgm, &ett_pgm_optbits, &ett_pgm_spm, &ett_pgm_data, &ett_pgm_nak, &ett_pgm_ack, &ett_pgm_opts, &ett_pgm_opts_join, &ett_pgm_opts_parityprm, &ett_pgm_opts_paritygrp, &ett_pgm_opts_naklist, &ett_pgm_opts_ccdata, }; module_t *pgm_module; proto_pgm = proto_register_protocol("Pragmatic General Multicast", "PGM", "pgm"); proto_register_field_array(proto_pgm, hf, array_length(hf)); proto_register_subtree_array(ett, array_length(ett)); /* subdissector code */ subdissector_table = register_dissector_table("pgm.port"); register_heur_dissector_list("pgm", &heur_subdissector_list); /* * Register configuration preferences for UDP encapsulation * (Note: Initially the ports are set to zero so the * dissecting of PGM encapsulated in UPD packets * is off by default) */ pgm_module = prefs_register_protocol(proto_pgm, proto_rereg_pgm); prefs_register_uint_preference(pgm_module, "udp.encap_ucast_port", "PGM Encap Unicast Port (Default 3055)", "PGM Encap is PGM packets encapsulated in UDP packets" " (Note: This is option is off by default", 10, &udp_encap_ucast_port); old_encap_ucast_port = udp_encap_ucast_port; prefs_register_uint_preference(pgm_module, "udp.encap_mcast_port", "PGM Encap Multicast Port (Default 3056)", "PGM Encap is PGM packets encapsulated in UDP packets" " (Note: This is option is off by default", 10, &udp_encap_mcast_port); old_encap_mcast_port = udp_encap_mcast_port; } /* The registration hand-off routine */ void proto_reg_handoff_pgm(void) { /* * Set up PGM Encap dissecting, which is off by default */ dissector_add("udp.port", udp_encap_ucast_port, dissect_pgm, proto_pgm); dissector_add("udp.port", udp_encap_mcast_port, dissect_pgm, proto_pgm); dissector_add("ip.proto", IP_PROTO_PGM, dissect_pgm, proto_pgm); } void proto_rereg_pgm(void) { /* * Remove the old ones */ dissector_delete("udp.port", old_encap_ucast_port, dissect_pgm); dissector_delete("udp.port", old_encap_mcast_port, dissect_pgm); /* * Set the new ones */ dissector_add("udp.port", udp_encap_ucast_port, dissect_pgm, proto_pgm); dissector_add("udp.port", udp_encap_mcast_port, dissect_pgm, proto_pgm); }