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/* packet-aarp.c
* Routines for Appletalk ARP packet disassembly
*
* Simon Wilkinson <sxw@dcs.ed.ac.uk>
*
* Wireshark - Network traffic analyzer
* By Gerald Combs <gerald@wireshark.org>
* Copyright 1998
*
* SPDX-License-Identifier: GPL-2.0-or-later
*/
#include "config.h"
#include <epan/packet.h>
#include <epan/etypes.h>
#include <epan/expert.h>
#include <epan/to_str.h>
/* Forward declarations */
void proto_register_aarp(void);
void proto_reg_handoff_aarp(void);
static int proto_aarp;
static int hf_aarp_hard_type;
static int hf_aarp_proto_type;
static int hf_aarp_hard_size;
static int hf_aarp_proto_size;
static int hf_aarp_opcode;
static int hf_aarp_src_hw;
static int hf_aarp_src_hw_mac;
static int hf_aarp_src_proto;
static int hf_aarp_src_proto_id;
static int hf_aarp_dst_hw;
static int hf_aarp_dst_hw_mac;
static int hf_aarp_dst_proto;
static int hf_aarp_dst_proto_id;
static int ett_aarp;
static expert_field ei_aarp_length_invalid;
#ifndef AARP_REQUEST
#define AARP_REQUEST 0x0001
#endif
#ifndef AARP_REPLY
#define AARP_REPLY 0x0002
#endif
#ifndef AARP_PROBE
#define AARP_PROBE 0x0003
#endif
/* The following is screwed up shit to deal with the fact that
the linux kernel edits the packet inline. */
#define AARP_REQUEST_SWAPPED 0x0100
#define AARP_REPLY_SWAPPED 0x0200
#define AARP_PROBE_SWAPPED 0x0300
static const value_string op_vals[] = {
{AARP_REQUEST, "request" },
{AARP_REPLY, "reply" },
{AARP_PROBE, "probe" },
{AARP_REQUEST_SWAPPED, "request" },
{AARP_REPLY_SWAPPED, "reply" },
{AARP_PROBE_SWAPPED, "probe" },
{0, NULL } };
/* AARP protocol HARDWARE identifiers. */
#define AARPHRD_ETHER 1 /* Ethernet 10Mbps */
#define AARPHRD_TR 2 /* Token Ring */
static const value_string hrd_vals[] = {
{AARPHRD_ETHER, "Ethernet" },
{AARPHRD_TR, "Token Ring" },
{0, NULL } };
/*
* Given the hardware address type and length, check whether an address
* is an Ethernet address - the address must be of type "Ethernet" or
* "Token Ring", and the length must be 6 bytes.
*/
#define AARP_HW_IS_ETHER(ar_hrd, ar_hln) \
(((ar_hrd) == AARPHRD_ETHER || (ar_hrd) == AARPHRD_TR) \
&& (ar_hln) == 6)
/*
* Given the protocol address type and length, check whether an address
* is an Appletalk address - the address must be of type "Appletalk",
* and the length must be 4 bytes.
*/
#define AARP_PRO_IS_ATALK(ar_pro, ar_pln) \
((ar_pro) == ETHERTYPE_ATALK && (ar_pln) == 4)
static char *
tvb_atalkid_to_str(wmem_allocator_t *scope, tvbuff_t *tvb, int offset)
{
int node;
char *cur;
cur=(char *)wmem_alloc(scope, 16);
node=tvb_get_uint8(tvb, offset+1)<<8|tvb_get_uint8(tvb, offset+2);
snprintf(cur, 16, "%d.%d",node,tvb_get_uint8(tvb, offset+3));
return cur;
}
static const char *
tvb_aarphrdaddr_to_str(wmem_allocator_t *scope, tvbuff_t *tvb, int offset, int ad_len, uint16_t type)
{
if (AARP_HW_IS_ETHER(type, ad_len)) {
/* Ethernet address (or Token Ring address, which is the same type
of address). */
return tvb_ether_to_str(scope, tvb, offset);
}
return tvb_bytes_to_str(scope, tvb, offset, ad_len);
}
static char *
tvb_aarpproaddr_to_str(wmem_allocator_t *scope, tvbuff_t *tvb, int offset, int ad_len, uint16_t type)
{
if (AARP_PRO_IS_ATALK(type, ad_len)) {
/* Appletalk address. */
return tvb_atalkid_to_str(scope, tvb, offset);
}
return tvb_bytes_to_str(scope, tvb, offset, ad_len);
}
/* Offsets of fields within an AARP packet. */
#define AR_HRD 0
#define AR_PRO 2
#define AR_HLN 4
#define AR_PLN 5
#define AR_OP 6
#define MIN_AARP_HEADER_SIZE 8
static int
dissect_aarp(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree, void* data _U_) {
uint16_t ar_hrd;
uint16_t ar_pro;
uint8_t ar_hln;
uint8_t ar_pln;
uint16_t ar_op;
proto_tree *aarp_tree;
proto_item *ti;
const char *op_str;
int sha_offset, spa_offset, tha_offset, tpa_offset;
const char *sha_str, *spa_str, /* *tha_str, */ *tpa_str;
col_set_str(pinfo->cinfo, COL_PROTOCOL, "AARP");
col_clear(pinfo->cinfo, COL_INFO);
ar_hrd = tvb_get_ntohs(tvb, AR_HRD);
ar_pro = tvb_get_ntohs(tvb, AR_PRO);
ar_hln = tvb_get_uint8(tvb, AR_HLN);
ar_pln = tvb_get_uint8(tvb, AR_PLN);
ar_op = tvb_get_ntohs(tvb, AR_OP);
/* Get the offsets of the addresses. */
sha_offset = MIN_AARP_HEADER_SIZE;
spa_offset = sha_offset + ar_hln;
tha_offset = spa_offset + ar_pln;
tpa_offset = tha_offset + ar_hln;
/* Extract the addresses. */
if (ar_hln < 1) {
expert_add_info_format(pinfo, tree, &ei_aarp_length_invalid,
"Invalid hardware address length: %d", ar_hln);
sha_str = "Unknown";
#if 0
tha_str = "Unknown";
#endif
} else {
sha_str = tvb_aarphrdaddr_to_str(pinfo->pool, tvb, sha_offset, ar_hln, ar_hrd);
#if 0
/* TODO: tha_str is currently not shown nor parsed */
tha_str = tvb_aarphrdaddr_to_str(pinfo->pool, tvb, tha_offset, ar_hln, ar_hrd);
#endif
}
if (ar_pln < 1) {
expert_add_info_format(pinfo, tree, &ei_aarp_length_invalid,
"Invalid protocol address length: %d", ar_pln);
spa_str = "Unknown";
tpa_str = "Unknown";
} else {
spa_str = tvb_aarpproaddr_to_str(pinfo->pool, tvb, spa_offset, ar_pln, ar_pro);
tpa_str = tvb_aarpproaddr_to_str(pinfo->pool, tvb, tpa_offset, ar_pln, ar_pro);
}
switch (ar_op) {
case AARP_REQUEST:
case AARP_REQUEST_SWAPPED:
col_add_fstr(pinfo->cinfo, COL_INFO, "Who has %s? Tell %s", tpa_str, spa_str);
break;
case AARP_REPLY:
case AARP_REPLY_SWAPPED:
col_add_fstr(pinfo->cinfo, COL_INFO, "%s is at %s", spa_str, sha_str);
break;
case AARP_PROBE:
case AARP_PROBE_SWAPPED:
col_add_fstr(pinfo->cinfo, COL_INFO, "Is there a %s", tpa_str);
break;
default:
col_add_fstr(pinfo->cinfo, COL_INFO, "Unknown AARP opcode 0x%04x", ar_op);
break;
}
if (tree) {
if ((op_str = try_val_to_str(ar_op, op_vals)))
ti = proto_tree_add_protocol_format(tree, proto_aarp, tvb, 0,
MIN_AARP_HEADER_SIZE + 2*ar_hln +
2*ar_pln, "AppleTalk Address Resolution Protocol (%s)", op_str);
else
ti = proto_tree_add_protocol_format(tree, proto_aarp, tvb, 0,
MIN_AARP_HEADER_SIZE + 2*ar_hln +
2*ar_pln,
"AppleTalk Address Resolution Protocol (opcode 0x%04x)", ar_op);
aarp_tree = proto_item_add_subtree(ti, ett_aarp);
proto_tree_add_uint(aarp_tree, hf_aarp_hard_type, tvb, AR_HRD, 2,
ar_hrd);
proto_tree_add_uint(aarp_tree, hf_aarp_proto_type, tvb, AR_PRO, 2,
ar_pro);
proto_tree_add_uint(aarp_tree, hf_aarp_hard_size, tvb, AR_HLN, 1,
ar_hln);
proto_tree_add_uint(aarp_tree, hf_aarp_proto_size, tvb, AR_PLN, 1,
ar_pln);
proto_tree_add_uint(aarp_tree, hf_aarp_opcode, tvb, AR_OP, 2,
ar_op);
if (ar_hln != 0) {
proto_tree_add_item(aarp_tree,
AARP_HW_IS_ETHER(ar_hrd, ar_hln) ? hf_aarp_src_hw_mac : hf_aarp_src_hw,
tvb, sha_offset, ar_hln, ENC_NA);
}
if (ar_pln != 0) {
if (AARP_PRO_IS_ATALK(ar_pro, ar_pln)) {
proto_tree_add_bytes_format_value(aarp_tree, hf_aarp_src_proto_id, tvb,
spa_offset, ar_pln, NULL,
"%s", spa_str);
} else {
proto_tree_add_bytes_format_value(aarp_tree, hf_aarp_src_proto, tvb,
spa_offset, ar_pln, NULL,
"%s", spa_str);
}
}
if (ar_hln != 0) {
proto_tree_add_item(aarp_tree,
AARP_HW_IS_ETHER(ar_hrd, ar_hln) ? hf_aarp_dst_hw_mac : hf_aarp_dst_hw,
tvb, tha_offset, ar_hln, ENC_NA);
}
if (ar_pln != 0) {
if (AARP_PRO_IS_ATALK(ar_pro, ar_pln)) {
proto_tree_add_bytes_format_value(aarp_tree, hf_aarp_dst_proto_id, tvb,
tpa_offset, ar_pln,
NULL, "%s", tpa_str);
} else {
proto_tree_add_bytes_format_value(aarp_tree, hf_aarp_dst_proto, tvb,
tpa_offset, ar_pln,
NULL, "%s", tpa_str);
}
}
}
return tvb_captured_length(tvb);
}
void
proto_register_aarp(void)
{
static hf_register_info hf[] = {
{ &hf_aarp_hard_type,
{ "Hardware type", "aarp.hard.type",
FT_UINT16, BASE_HEX, VALS(hrd_vals), 0x0,
NULL, HFILL }},
{ &hf_aarp_proto_type,
{ "Protocol type", "aarp.proto.type",
FT_UINT16, BASE_HEX, VALS(etype_vals), 0x0,
NULL, HFILL }},
{ &hf_aarp_hard_size,
{ "Hardware size", "aarp.hard.size",
FT_UINT8, BASE_DEC, NULL, 0x0,
NULL, HFILL }},
{ &hf_aarp_proto_size,
{ "Protocol size", "aarp.proto.size",
FT_UINT8, BASE_DEC, NULL, 0x0,
NULL, HFILL }},
{ &hf_aarp_opcode,
{ "Opcode", "aarp.opcode",
FT_UINT16, BASE_DEC, VALS(op_vals), 0x0,
NULL, HFILL }},
{ &hf_aarp_src_hw,
{ "Sender hardware address", "aarp.src.hw",
FT_BYTES, BASE_NONE, NULL, 0x0,
NULL, HFILL }},
{ &hf_aarp_src_hw_mac,
{ "Sender MAC address", "aarp.src.hw_mac",
FT_ETHER, BASE_NONE, NULL, 0x0,
NULL, HFILL }},
{ &hf_aarp_src_proto,
{ "Sender protocol address", "aarp.src.proto",
FT_BYTES, BASE_NONE, NULL, 0x0,
NULL, HFILL }},
{ &hf_aarp_src_proto_id,
{ "Sender ID", "aarp.src.proto_id",
FT_BYTES, BASE_NONE, NULL, 0x0,
NULL, HFILL }},
{ &hf_aarp_dst_hw,
{ "Target hardware address", "aarp.dst.hw",
FT_BYTES, BASE_NONE, NULL, 0x0,
NULL, HFILL }},
{ &hf_aarp_dst_hw_mac,
{ "Target MAC address", "aarp.dst.hw_mac",
FT_ETHER, BASE_NONE, NULL, 0x0,
NULL, HFILL }},
{ &hf_aarp_dst_proto,
{ "Target protocol address", "aarp.dst.proto",
FT_BYTES, BASE_NONE, NULL, 0x0,
NULL, HFILL }},
{ &hf_aarp_dst_proto_id,
{ "Target ID", "aarp.dst.proto_id",
FT_BYTES, BASE_NONE, NULL, 0x0,
NULL, HFILL }},
};
static int *ett[] = {
&ett_aarp,
};
static ei_register_info ei[] = {
{ &ei_aarp_length_invalid, { "aarp.length.invalid", PI_PROTOCOL, PI_WARN, "Invalid length", EXPFILL }},
};
proto_aarp = proto_register_protocol("Appletalk Address Resolution Protocol",
"AARP",
"aarp");
register_dissector("aarp", dissect_aarp, proto_aarp);
proto_register_field_array(proto_aarp, hf, array_length(hf));
proto_register_subtree_array(ett, array_length(ett));
expert_module_t* expert_aarp = expert_register_protocol(proto_aarp);
expert_register_field_array(expert_aarp, ei, array_length(ei));
}
void
proto_reg_handoff_aarp(void)
{
dissector_handle_t aarp_handle = find_dissector("aarp");
dissector_add_uint("ethertype", ETHERTYPE_AARP, aarp_handle);
dissector_add_uint("chdlc.protocol", ETHERTYPE_AARP, aarp_handle);
}
/*
* Editor modelines - https://www.wireshark.org/tools/modelines.html
*
* Local Variables:
* c-basic-offset: 2
* tab-width: 8
* indent-tabs-mode: nil
* End:
*
* ex: set shiftwidth=2 tabstop=8 expandtab:
* :indentSize=2:tabSize=8:noTabs=true:
*/
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