f1bb0e1735
Added support new multicore header in the LINX Ethernet protocol. Added linx/tcp. svn path=/trunk/; revision=37777
377 lines
14 KiB
C
377 lines
14 KiB
C
/* packet-ethertype.c
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* Routines for processing Ethernet payloads and payloads like Ethernet
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* payloads (i.e., payloads when there could be an Ethernet trailer and
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* possibly an FCS).
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*
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* $Id$
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*
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* Gilbert Ramirez <gram@alumni.rice.edu>
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*
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* Wireshark - Network traffic analyzer
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* By Gerald Combs <gerald@wireshark.org>
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* Copyright 1998 Gerald Combs
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*/
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#ifdef HAVE_CONFIG_H
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# include "config.h"
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#endif
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#include <glib.h>
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#include <epan/packet.h>
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#include "packet-eth.h"
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#include "packet-frame.h"
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#include "packet-ip.h"
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#include "packet-ipv6.h"
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#include "packet-ipx.h"
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#include "packet-ieee8021ah.h"
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#include "packet-vines.h"
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#include <epan/etypes.h>
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#include <epan/ppptypes.h>
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static dissector_table_t ethertype_dissector_table;
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static dissector_handle_t data_handle;
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const value_string etype_vals[] = {
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{ ETHERTYPE_IP, "IP" },
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{ ETHERTYPE_IPv6, "IPv6" },
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{ ETHERTYPE_VLAN, "802.1Q Virtual LAN" },
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{ ETHERTYPE_ARP, "ARP" },
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{ ETHERTYPE_WLCCP, "Cisco Wireless Lan Context Control Protocol" },
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{ ETHERTYPE_CENTRINO_PROMISC, "IEEE 802.11 (Centrino promiscuous)" },
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{ ETHERTYPE_XNS_IDP, "XNS Internet Datagram Protocol" },
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{ ETHERTYPE_X25L3, "X.25 Layer 3" },
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{ ETHERTYPE_WOL, "Wake on LAN" },
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{ ETHERTYPE_WMX_M2M, "WiMax Mac-to-Mac" },
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{ ETHERTYPE_EPL_V1, "EPL_V1" },
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{ ETHERTYPE_REVARP, "RARP" },
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{ ETHERTYPE_DEC_LB, "DEC LanBridge" },
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{ ETHERTYPE_ATALK, "Appletalk" },
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{ ETHERTYPE_SNA, "SNA-over-Ethernet" },
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{ ETHERTYPE_DLR, "EtherNet/IP Device Level Ring" },
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{ ETHERTYPE_AARP, "AARP" },
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{ ETHERTYPE_IPX, "Netware IPX/SPX" },
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{ ETHERTYPE_VINES_IP, "Vines IP" },
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{ ETHERTYPE_VINES_ECHO, "Vines Echo" },
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{ ETHERTYPE_TRAIN, "Netmon Train" },
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/* Ethernet Loopback */
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{ ETHERTYPE_LOOP, "Loopback" },
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{ ETHERTYPE_FOUNDRY, "Foundry proprietary" },
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{ ETHERTYPE_WCP, "Wellfleet Compression Protocol" },
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{ ETHERTYPE_STP, "Spanning Tree Protocol" },
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/* for ISMP, see RFC 2641, RFC 2642, RFC 2643 */
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{ ETHERTYPE_ISMP, "Cabletron Interswitch Message Protocol" },
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{ ETHERTYPE_ISMP_TBFLOOD, "Cabletron SFVLAN 1.8 Tag-Based Flood" },
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/* In www.iana.org/assignments/ethernet-numbers, 8203-8205 description is
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* Quantum Software. Now the company is called QNX Software Systems. */
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{ ETHERTYPE_QNX_QNET6, "QNX 6 QNET protocol" },
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{ ETHERTYPE_PPPOED, "PPPoE Discovery" },
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{ ETHERTYPE_PPPOES, "PPPoE Session" },
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{ ETHERTYPE_INTEL_ANS, "Intel ANS probe" },
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{ ETHERTYPE_MS_NLB_HEARTBEAT, "MS NLB heartbeat" },
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{ ETHERTYPE_JUMBO_LLC, "Jumbo LLC" },
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{ ETHERTYPE_HOMEPLUG, "Homeplug" },
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{ ETHERTYPE_HOMEPLUG_AV, "Homeplug AV" },
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{ ETHERTYPE_IEEE_802_1AD, "802.1ad Provider Bridge (Q-in-Q)" },
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{ ETHERTYPE_IEEE_802_1AH, "802.1ah Provider Backbone Bridge (mac-in-mac)" },
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{ ETHERTYPE_EAPOL, "802.1X Authentication" },
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{ ETHERTYPE_RSN_PREAUTH, "802.11i Pre-Authentication" },
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{ ETHERTYPE_MPLS, "MPLS label switched packet" },
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{ ETHERTYPE_MPLS_MULTI, "MPLS multicast label switched packet" },
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{ ETHERTYPE_3C_NBP_DGRAM, "3Com NBP Datagram" },
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{ ETHERTYPE_DEC, "DEC proto" },
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{ ETHERTYPE_DNA_DL, "DEC DNA Dump/Load" },
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{ ETHERTYPE_DNA_RC, "DEC DNA Remote Console" },
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{ ETHERTYPE_DNA_RT, "DEC DNA Routing" },
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{ ETHERTYPE_LAT, "DEC LAT" },
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{ ETHERTYPE_DEC_DIAG, "DEC Diagnostics" },
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{ ETHERTYPE_DEC_CUST, "DEC Customer use" },
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{ ETHERTYPE_DEC_SCA, "DEC LAVC/SCA" },
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{ ETHERTYPE_DEC_LAST, "DEC LAST" },
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{ ETHERTYPE_ETHBRIDGE, "Transparent Ethernet bridging" },
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{ ETHERTYPE_CGMP, "Cisco Group Management Protocol" },
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{ ETHERTYPE_GIGAMON, "Gigamon Header" },
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{ ETHERTYPE_MSRP, "802.1Qat Multiple Stream Reservation Protocol" },
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{ ETHERTYPE_MMRP, "802.1ak Multiple Mac Registration Protocol" },
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{ ETHERTYPE_AVBTP, "IEEE 1722 Audio Video Bridging Transport Protocol" },
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{ ETHERTYPE_ROHC, "Robust Header Compression(RoHC)" },
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{ ETHERTYPE_MAC_CONTROL, "MAC Control" },
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{ ETHERTYPE_SLOW_PROTOCOLS, "Slow Protocols" },
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{ ETHERTYPE_RTMAC, "Real-Time Media Access Control" },
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{ ETHERTYPE_RTCFG, "Real-Time Configuration Protocol" },
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{ ETHERTYPE_CDMA2000_A10_UBS, "CDMA2000 A10 Unstructured byte stream" },
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{ ETHERTYPE_PROFINET, "PROFINET"},
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{ ETHERTYPE_AOE, "ATA over Ethernet" },
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{ ETHERTYPE_ECATF, "EtherCAT frame" },
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{ ETHERTYPE_TELKONET, "Telkonet powerline" },
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{ ETHERTYPE_EPL_V2, "ETHERNET Powerlink v2" },
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{ ETHERTYPE_XIMETA, "XiMeta Technology" },
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{ ETHERTYPE_CSM_ENCAPS, "CSM_ENCAPS Protocol" },
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{ ETHERTYPE_IEEE802_OUI_EXTENDED, "IEEE 802a OUI Extended Ethertype" },
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{ ETHERTYPE_IEC61850_GOOSE, "IEC 61850/GOOSE" },
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{ ETHERTYPE_IEC61850_GSE, "IEC 61850/GSE management services" },
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{ ETHERTYPE_IEC61850_SV, "IEC 61850/SV (Sampled Value Transmission" },
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{ ETHERTYPE_TIPC, "Transparent Inter Process Communication" },
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{ ETHERTYPE_LLDP, "802.1 Link Layer Discovery Protocol (LLDP)" },
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{ ETHERTYPE_3GPP2, "CDMA2000 A10 3GPP2 Packet" },
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{ ETHERTYPE_TTE_PCF, "TTEthernet Protocol Control Frame" },
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{ ETHERTYPE_LLTD, "Link Layer Topology Discovery (LLTD)" },
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{ ETHERTYPE_WSMP, "(WAVE) Short Message Protocol (WSM)" },
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{ ETHERTYPE_VMLAB, "VMware Lab Manager" },
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{ ETHERTYPE_COBRANET, "Cirrus Cobranet Packet" },
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{ ETHERTYPE_NSRP, "Juniper Netscreen Redundant Protocol" },
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/*
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* NDISWAN on Windows translates Ethernet frames from higher-level
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* protocols into PPP frames to hand to the PPP driver, and translates
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* PPP frames from the PPP driver to hand to the higher-level protocols.
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*
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* Apparently the PPP driver, on at least some versions of Windows,
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* passes frames for internal-to-PPP protocols up through NDISWAN;
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* the protocol type field appears to be passed through unchanged
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* (unlike what's done with, for example, the protocol type field
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* for IP, which is mapped from its PPP value to its Ethernet value).
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*
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* This means that we may see, on Ethernet captures, frames for
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* protocols internal to PPP, so we list as "Ethernet" protocol
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* types the PPP protocol types we've seen.
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*/
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{ PPP_IPCP, "PPP IP Control Protocol" },
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{ PPP_LCP, "PPP Link Control Protocol" },
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{ PPP_PAP, "PPP Password Authentication Protocol" },
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{ PPP_CCP, "PPP Compression Control Protocol" },
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{ ETHERTYPE_LLT, "Veritas Low Latency Transport (not officially registered)" },
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{ ETHERTYPE_CFM, "IEEE 802.1ag Connectivity Fault Management (CFM) protocol" },
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{ ETHERTYPE_FCOE, "Fibre Channel over Ethernet" },
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{ ETHERTYPE_IEEE80211_DATA_ENCAP, "IEEE 802.11 data encapsulation" },
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{ ETHERTYPE_LINX, "LINX IPC Protocol" },
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{ ETHERTYPE_FIP, "FCoE Initialization Protocol" },
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{ ETHERTYPE_PTP, "PTPv2 over Ethernet (IEEE1588)" },
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{ ETHERTYPE_PRP, "Parallel Redundancy Protocol (IEC62439 Chapter 6)" },
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{ ETHERTYPE_FLIP, "Flow Layer Internal Protocol" },
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{ ETHERTYPE_ROCE, "RDMA over Converged Ethernet" },
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{ ETHERTYPE_TDMOE, "Digium TDM over Ethernet Protocol" },
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{ ETHERTYPE_WAI, "WAI Authentication Protocol" },
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{ 0, NULL }
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};
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static void add_dix_trailer(packet_info *pinfo, proto_tree *tree, proto_tree *fh_tree,
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int trailer_id, tvbuff_t *tvb, tvbuff_t *next_tvb, int offset_after_etype,
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guint length_before, gint fcs_len);
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void
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capture_ethertype(guint16 etype, const guchar *pd, int offset, int len,
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packet_counts *ld)
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{
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switch (etype) {
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case ETHERTYPE_ARP:
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ld->arp++;
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break;
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case ETHERTYPE_IP:
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capture_ip(pd, offset, len, ld);
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break;
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case ETHERTYPE_IPv6:
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capture_ipv6(pd, offset, len, ld);
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break;
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case ETHERTYPE_IPX:
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capture_ipx(ld);
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break;
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case ETHERTYPE_VLAN:
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capture_eth(pd, offset, len, ld);
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break;
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case ETHERTYPE_IEEE_802_1AD:
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case ETHERTYPE_IEEE_802_1AH:
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capture_ieee8021ah(pd, offset, len, ld);
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break;
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case ETHERTYPE_VINES_IP:
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case ETHERTYPE_VINES_ECHO:
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capture_vines(ld);
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break;
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default:
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ld->other++;
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break;
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}
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}
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void
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ethertype(guint16 etype, tvbuff_t *tvb, int offset_after_etype,
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packet_info *pinfo, proto_tree *tree, proto_tree *fh_tree,
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int etype_id, int trailer_id, int fcs_len)
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{
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const char *description;
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tvbuff_t *volatile next_tvb;
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guint length_before;
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gint captured_length, reported_length;
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volatile gboolean dissector_found = FALSE;
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const char *volatile saved_proto;
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void *pd_save;
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/* Add the Ethernet type to the protocol tree */
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if (tree) {
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proto_tree_add_uint(fh_tree, etype_id, tvb,
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offset_after_etype - 2, 2, etype);
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}
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/* Get the captured length and reported length of the data
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after the Ethernet type. */
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captured_length = tvb_length_remaining(tvb, offset_after_etype);
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reported_length = tvb_reported_length_remaining(tvb,
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offset_after_etype);
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/* Remember how much data there is after the Ethernet type,
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including any trailer and FCS. */
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length_before = reported_length;
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/* Construct a tvbuff for the payload after the Ethernet type.
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If the FCS length is positive, remove the FCS.
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(If it's zero, there's no FCS; if it's negative,
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we don't know whether there's an FCS, so we'll
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guess based on the length of the trailer.) */
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if (fcs_len > 0) {
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if (captured_length >= 0 && reported_length >= 0) {
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if (reported_length >= fcs_len)
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reported_length -= fcs_len;
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if (captured_length > reported_length)
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captured_length = reported_length;
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}
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}
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next_tvb = tvb_new_subset(tvb, offset_after_etype, captured_length,
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reported_length);
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pinfo->ethertype = etype;
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/* Look for sub-dissector, and call it if found.
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Catch exceptions, so that if the reported length of "next_tvb"
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was reduced by some dissector before an exception was thrown,
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we can still put in an item for the trailer. */
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saved_proto = pinfo->current_proto;
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pd_save = pinfo->private_data;
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TRY {
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dissector_found = dissector_try_uint(ethertype_dissector_table,
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etype, next_tvb, pinfo, tree);
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}
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CATCH(BoundsError) {
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/* Somebody threw BoundsError, which means that:
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1) a dissector was found, so we don't need to
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dissect the payload as data or update the
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protocol or info columns;
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2) dissecting the payload found that the packet was
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cut off by a snapshot length before the end of
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the payload. The trailer comes after the payload,
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so *all* of the trailer is cut off, and we'll
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just get another BoundsError if we add the trailer.
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Therefore, we just rethrow the exception so it gets
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reported; we don't dissect the trailer or do anything
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else. */
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RETHROW;
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}
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CATCH(OutOfMemoryError) {
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RETHROW;
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}
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CATCH_ALL {
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/* Somebody threw an exception other than BoundsError, which
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means that a dissector was found, so we don't need to
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dissect the payload as data or update the protocol or info
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columns. We just show the exception and then drive on
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to show the trailer, after noting that a dissector was
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found and restoring the protocol value that was in effect
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before we called the subdissector. */
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show_exception(next_tvb, pinfo, tree, EXCEPT_CODE, GET_MESSAGE);
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/* Restore the private_data structure in case one of the
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* called dissectors modified it (and, due to the exception,
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* was unable to restore it).
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*/
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pinfo->private_data = pd_save;
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dissector_found = TRUE;
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pinfo->current_proto = saved_proto;
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}
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ENDTRY;
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if (!dissector_found) {
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/* No sub-dissector found.
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Label rest of packet as "Data" */
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call_dissector(data_handle,next_tvb, pinfo, tree);
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/* Label protocol */
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col_add_fstr(pinfo->cinfo, COL_PROTOCOL, "0x%04x", etype);
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description = match_strval(etype, etype_vals);
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if (description) {
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col_add_str(pinfo->cinfo, COL_INFO, description);
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}
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}
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add_dix_trailer(pinfo, tree, fh_tree, trailer_id, tvb, next_tvb, offset_after_etype,
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length_before, fcs_len);
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}
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static void
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add_dix_trailer(packet_info *pinfo, proto_tree *tree, proto_tree *fh_tree, int trailer_id,
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tvbuff_t *tvb, tvbuff_t *next_tvb, int offset_after_etype,
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guint length_before, gint fcs_len)
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{
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guint length;
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tvbuff_t *trailer_tvb;
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if (fh_tree == NULL)
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return; /* we're not building a protocol tree */
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/* OK, how much is there in that tvbuff now? */
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length = tvb_reported_length(next_tvb);
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/* If there's less than there was before, what's left is
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a trailer. */
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if (length < length_before) {
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/*
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* Is any of the padding present in the tvbuff?
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*/
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if (tvb_offset_exists(tvb, offset_after_etype + length)) {
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/*
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* Yes - create a tvbuff for the padding.
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*/
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trailer_tvb = tvb_new_subset_remaining(tvb,
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offset_after_etype + length);
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} else {
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/*
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* No - don't bother showing the trailer.
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* XXX - show a Short Frame indication?
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*/
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trailer_tvb = NULL;
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}
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} else
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trailer_tvb = NULL; /* no trailer */
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add_ethernet_trailer(pinfo, tree, fh_tree, trailer_id, tvb, trailer_tvb, fcs_len);
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}
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void
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proto_register_ethertype(void)
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{
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/* subdissector code */
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ethertype_dissector_table = register_dissector_table("ethertype",
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"Ethertype", FT_UINT16, BASE_HEX);
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}
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void
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proto_reg_handoff_ethertype(void)
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{
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data_handle = find_dissector("data");
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}
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