tcpdump/print-isoclns.c
Francois-Xavier Le Bail 94a3708f00 Include <config.h> unconditionally
Builds using Autotools or CMake generate config.h, thus remove the
'#ifdef HAVE_CONFIG_H'/'#endif'.

Remove also the 'add_definitions(-DHAVE_CONFIG_H)' in CMakeLists.txt.
2024-03-28 05:34:34 +00:00

3547 lines
118 KiB
C

/*
* Copyright (c) 1992, 1993, 1994, 1995, 1996
* The Regents of the University of California. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that: (1) source code distributions
* retain the above copyright notice and this paragraph in its entirety, (2)
* distributions including binary code include the above copyright notice and
* this paragraph in its entirety in the documentation or other materials
* provided with the distribution, and (3) all advertising materials mentioning
* features or use of this software display the following acknowledgement:
* ``This product includes software developed by the University of California,
* Lawrence Berkeley Laboratory and its contributors.'' Neither the name of
* the University nor the names of its contributors may be used to endorse
* or promote products derived from this software without specific prior
* written permission.
* THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
*
* Original code by Matt Thomas, Digital Equipment Corporation
*
* Extensively modified by Hannes Gredler (hannes@gredler.at) for more
* complete IS-IS & CLNP support.
*/
/* \summary: ISO CLNS, ESIS, and ISIS printer */
/*
* specification:
*
* CLNP: ISO 8473 (respective ITU version is at https://www.itu.int/rec/T-REC-X.233/en/)
* ES-IS: ISO 9542
* IS-IS: ISO 10589
*/
#include <config.h>
#include "netdissect-stdinc.h"
#include <string.h>
#include "netdissect.h"
#include "addrtoname.h"
#include "nlpid.h"
#include "extract.h"
#include "gmpls.h"
#include "oui.h"
#include "signature.h"
#include "af.h"
/*
* IS-IS is defined in ISO 10589. Look there for protocol definitions.
*/
#define SYSTEM_ID_LEN MAC48_LEN
#define NODE_ID_LEN (SYSTEM_ID_LEN+1)
#define LSP_ID_LEN (SYSTEM_ID_LEN+2)
#define ISIS_VERSION 1
#define ESIS_VERSION 1
#define CLNP_VERSION 1
#define ISIS_PDU_TYPE_MASK 0x1F
#define ESIS_PDU_TYPE_MASK 0x1F
#define CLNP_PDU_TYPE_MASK 0x1F
#define CLNP_FLAG_MASK 0xE0
#define ISIS_LAN_PRIORITY_MASK 0x7F
#define ISIS_PDU_L1_LAN_IIH 15
#define ISIS_PDU_L2_LAN_IIH 16
#define ISIS_PDU_PTP_IIH 17
#define ISIS_PDU_L1_LSP 18
#define ISIS_PDU_L2_LSP 20
#define ISIS_PDU_L1_CSNP 24
#define ISIS_PDU_L2_CSNP 25
#define ISIS_PDU_L1_PSNP 26
#define ISIS_PDU_L2_PSNP 27
static const struct tok isis_pdu_values[] = {
{ ISIS_PDU_L1_LAN_IIH, "L1 Lan IIH"},
{ ISIS_PDU_L2_LAN_IIH, "L2 Lan IIH"},
{ ISIS_PDU_PTP_IIH, "p2p IIH"},
{ ISIS_PDU_L1_LSP, "L1 LSP"},
{ ISIS_PDU_L2_LSP, "L2 LSP"},
{ ISIS_PDU_L1_CSNP, "L1 CSNP"},
{ ISIS_PDU_L2_CSNP, "L2 CSNP"},
{ ISIS_PDU_L1_PSNP, "L1 PSNP"},
{ ISIS_PDU_L2_PSNP, "L2 PSNP"},
{ 0, NULL}
};
/*
* A TLV is a tuple of a type, length and a value and is normally used for
* encoding information in all sorts of places. This is an enumeration of
* the well known types.
*
* list taken from rfc3359 plus some memory from veterans ;-)
*/
#define ISIS_TLV_AREA_ADDR 1 /* iso10589 */
#define ISIS_TLV_IS_REACH 2 /* iso10589 */
#define ISIS_TLV_ESNEIGH 3 /* iso10589 */
#define ISIS_TLV_PART_DIS 4 /* iso10589 */
#define ISIS_TLV_PREFIX_NEIGH 5 /* iso10589 */
#define ISIS_TLV_ISNEIGH 6 /* iso10589 */
#define ISIS_TLV_INSTANCE_ID 7 /* rfc8202 */
#define ISIS_TLV_PADDING 8 /* iso10589 */
#define ISIS_TLV_LSP 9 /* iso10589 */
#define ISIS_TLV_AUTH 10 /* iso10589, rfc3567 */
#define ISIS_TLV_CHECKSUM 12 /* rfc3358 */
#define ISIS_TLV_CHECKSUM_MINLEN 2
#define ISIS_TLV_POI 13 /* rfc6232 */
#define ISIS_TLV_LSP_BUFFERSIZE 14 /* iso10589 rev2 */
#define ISIS_TLV_EXT_IS_REACH 22 /* rfc5305 */
#define ISIS_TLV_IS_ALIAS_ID 24 /* rfc5311 */
#define ISIS_TLV_DECNET_PHASE4 42
#define ISIS_TLV_LUCENT_PRIVATE 66
#define ISIS_TLV_INT_IP_REACH 128 /* rfc1195, rfc2966 */
#define ISIS_TLV_PROTOCOLS 129 /* rfc1195 */
#define ISIS_TLV_EXT_IP_REACH 130 /* rfc1195, rfc2966 */
#define ISIS_TLV_IDRP_INFO 131 /* rfc1195 */
#define ISIS_TLV_IPADDR 132 /* rfc1195 */
#define ISIS_TLV_IPAUTH 133 /* rfc1195 */
#define ISIS_TLV_TE_ROUTER_ID 134 /* rfc5305 */
#define ISIS_TLV_EXTD_IP_REACH 135 /* rfc5305 */
#define ISIS_TLV_HOSTNAME 137 /* rfc2763 */
#define ISIS_TLV_SHARED_RISK_GROUP 138 /* draft-ietf-isis-gmpls-extensions */
#define ISIS_TLV_MT_PORT_CAP 143 /* rfc6165 */
#define ISIS_TLV_MT_CAPABILITY 144 /* rfc6329 */
#define ISIS_TLV_NORTEL_PRIVATE1 176
#define ISIS_TLV_NORTEL_PRIVATE2 177
#define ISIS_TLV_RESTART_SIGNALING 211 /* rfc3847 */
#define ISIS_TLV_RESTART_SIGNALING_FLAGLEN 1
#define ISIS_TLV_RESTART_SIGNALING_HOLDTIMELEN 2
#define ISIS_TLV_MT_IS_REACH 222 /* draft-ietf-isis-wg-multi-topology-05 */
#define ISIS_TLV_MT_SUPPORTED 229 /* draft-ietf-isis-wg-multi-topology-05 */
#define ISIS_TLV_IP6ADDR 232 /* draft-ietf-isis-ipv6-02 */
#define ISIS_TLV_MT_IP_REACH 235 /* draft-ietf-isis-wg-multi-topology-05 */
#define ISIS_TLV_IP6_REACH 236 /* draft-ietf-isis-ipv6-02 */
#define ISIS_TLV_MT_IP6_REACH 237 /* draft-ietf-isis-wg-multi-topology-05 */
#define ISIS_TLV_PTP_ADJ 240 /* rfc3373 */
#define ISIS_TLV_IIH_SEQNR 241 /* draft-shen-isis-iih-sequence-00 */
#define ISIS_TLV_ROUTER_CAPABILITY 242 /* rfc7981 */
#define ISIS_TLV_VENDOR_PRIVATE 250 /* draft-ietf-isis-experimental-tlv-01 */
#define ISIS_TLV_VENDOR_PRIVATE_MINLEN 3
static const struct tok isis_tlv_values[] = {
{ ISIS_TLV_AREA_ADDR, "Area address(es)"},
{ ISIS_TLV_IS_REACH, "IS Reachability"},
{ ISIS_TLV_ESNEIGH, "ES Neighbor(s)"},
{ ISIS_TLV_PART_DIS, "Partition DIS"},
{ ISIS_TLV_PREFIX_NEIGH, "Prefix Neighbors"},
{ ISIS_TLV_ISNEIGH, "IS Neighbor(s)"},
{ ISIS_TLV_INSTANCE_ID, "Instance Identifier"},
{ ISIS_TLV_PADDING, "Padding"},
{ ISIS_TLV_LSP, "LSP entries"},
{ ISIS_TLV_AUTH, "Authentication"},
{ ISIS_TLV_CHECKSUM, "Checksum"},
{ ISIS_TLV_POI, "Purge Originator Identifier"},
{ ISIS_TLV_LSP_BUFFERSIZE, "LSP Buffersize"},
{ ISIS_TLV_EXT_IS_REACH, "Extended IS Reachability"},
{ ISIS_TLV_IS_ALIAS_ID, "IS Alias ID"},
{ ISIS_TLV_DECNET_PHASE4, "DECnet Phase IV"},
{ ISIS_TLV_LUCENT_PRIVATE, "Lucent Proprietary"},
{ ISIS_TLV_INT_IP_REACH, "IPv4 Internal Reachability"},
{ ISIS_TLV_PROTOCOLS, "Protocols supported"},
{ ISIS_TLV_EXT_IP_REACH, "IPv4 External Reachability"},
{ ISIS_TLV_IDRP_INFO, "Inter-Domain Information Type"},
{ ISIS_TLV_IPADDR, "IPv4 Interface address(es)"},
{ ISIS_TLV_IPAUTH, "IPv4 authentication (deprecated)"},
{ ISIS_TLV_TE_ROUTER_ID, "Traffic Engineering Router ID"},
{ ISIS_TLV_EXTD_IP_REACH, "Extended IPv4 Reachability"},
{ ISIS_TLV_SHARED_RISK_GROUP, "Shared Risk Link Group"},
{ ISIS_TLV_MT_PORT_CAP, "Multi-Topology-Aware Port Capability"},
{ ISIS_TLV_MT_CAPABILITY, "Multi-Topology Capability"},
{ ISIS_TLV_NORTEL_PRIVATE1, "Nortel Proprietary"},
{ ISIS_TLV_NORTEL_PRIVATE2, "Nortel Proprietary"},
{ ISIS_TLV_HOSTNAME, "Hostname"},
{ ISIS_TLV_RESTART_SIGNALING, "Restart Signaling"},
{ ISIS_TLV_MT_IS_REACH, "Multi Topology IS Reachability"},
{ ISIS_TLV_MT_SUPPORTED, "Multi Topology"},
{ ISIS_TLV_IP6ADDR, "IPv6 Interface address(es)"},
{ ISIS_TLV_MT_IP_REACH, "Multi-Topology IPv4 Reachability"},
{ ISIS_TLV_IP6_REACH, "IPv6 reachability"},
{ ISIS_TLV_MT_IP6_REACH, "Multi-Topology IP6 Reachability"},
{ ISIS_TLV_PTP_ADJ, "Point-to-point Adjacency State"},
{ ISIS_TLV_IIH_SEQNR, "Hello PDU Sequence Number"},
{ ISIS_TLV_ROUTER_CAPABILITY, "IS-IS Router Capability"},
{ ISIS_TLV_VENDOR_PRIVATE, "Vendor Private"},
{ 0, NULL }
};
#define ESIS_OPTION_PROTOCOLS 129
#define ESIS_OPTION_QOS_MAINTENANCE 195 /* iso9542 */
#define ESIS_OPTION_SECURITY 197 /* iso9542 */
#define ESIS_OPTION_ES_CONF_TIME 198 /* iso9542 */
#define ESIS_OPTION_PRIORITY 205 /* iso9542 */
#define ESIS_OPTION_ADDRESS_MASK 225 /* iso9542 */
#define ESIS_OPTION_SNPA_MASK 226 /* iso9542 */
static const struct tok esis_option_values[] = {
{ ESIS_OPTION_PROTOCOLS, "Protocols supported"},
{ ESIS_OPTION_QOS_MAINTENANCE, "QoS Maintenance" },
{ ESIS_OPTION_SECURITY, "Security" },
{ ESIS_OPTION_ES_CONF_TIME, "ES Configuration Time" },
{ ESIS_OPTION_PRIORITY, "Priority" },
{ ESIS_OPTION_ADDRESS_MASK, "Address Mask" },
{ ESIS_OPTION_SNPA_MASK, "SNPA Mask" },
{ 0, NULL }
};
#define CLNP_OPTION_DISCARD_REASON 193
#define CLNP_OPTION_QOS_MAINTENANCE 195 /* iso8473 */
#define CLNP_OPTION_SECURITY 197 /* iso8473 */
#define CLNP_OPTION_SOURCE_ROUTING 200 /* iso8473 */
#define CLNP_OPTION_ROUTE_RECORDING 203 /* iso8473 */
#define CLNP_OPTION_PADDING 204 /* iso8473 */
#define CLNP_OPTION_PRIORITY 205 /* iso8473 */
static const struct tok clnp_option_values[] = {
{ CLNP_OPTION_DISCARD_REASON, "Discard Reason"},
{ CLNP_OPTION_PRIORITY, "Priority"},
{ CLNP_OPTION_QOS_MAINTENANCE, "QoS Maintenance"},
{ CLNP_OPTION_SECURITY, "Security"},
{ CLNP_OPTION_SOURCE_ROUTING, "Source Routing"},
{ CLNP_OPTION_ROUTE_RECORDING, "Route Recording"},
{ CLNP_OPTION_PADDING, "Padding"},
{ 0, NULL }
};
static const struct tok clnp_option_rfd_class_values[] = {
{ 0x0, "General"},
{ 0x8, "Address"},
{ 0x9, "Source Routeing"},
{ 0xa, "Lifetime"},
{ 0xb, "PDU Discarded"},
{ 0xc, "Reassembly"},
{ 0, NULL }
};
static const struct tok clnp_option_rfd_general_values[] = {
{ 0x0, "Reason not specified"},
{ 0x1, "Protocol procedure error"},
{ 0x2, "Incorrect checksum"},
{ 0x3, "PDU discarded due to congestion"},
{ 0x4, "Header syntax error (cannot be parsed)"},
{ 0x5, "Segmentation needed but not permitted"},
{ 0x6, "Incomplete PDU received"},
{ 0x7, "Duplicate option"},
{ 0, NULL }
};
static const struct tok clnp_option_rfd_address_values[] = {
{ 0x0, "Destination address unreachable"},
{ 0x1, "Destination address unknown"},
{ 0, NULL }
};
static const struct tok clnp_option_rfd_source_routeing_values[] = {
{ 0x0, "Unspecified source routeing error"},
{ 0x1, "Syntax error in source routeing field"},
{ 0x2, "Unknown address in source routeing field"},
{ 0x3, "Path not acceptable"},
{ 0, NULL }
};
static const struct tok clnp_option_rfd_lifetime_values[] = {
{ 0x0, "Lifetime expired while data unit in transit"},
{ 0x1, "Lifetime expired during reassembly"},
{ 0, NULL }
};
static const struct tok clnp_option_rfd_pdu_discard_values[] = {
{ 0x0, "Unsupported option not specified"},
{ 0x1, "Unsupported protocol version"},
{ 0x2, "Unsupported security option"},
{ 0x3, "Unsupported source routeing option"},
{ 0x4, "Unsupported recording of route option"},
{ 0, NULL }
};
static const struct tok clnp_option_rfd_reassembly_values[] = {
{ 0x0, "Reassembly interference"},
{ 0, NULL }
};
/* array of 16 error-classes */
static const struct tok *clnp_option_rfd_error_class[] = {
clnp_option_rfd_general_values,
NULL,
NULL,
NULL,
NULL,
NULL,
NULL,
NULL,
clnp_option_rfd_address_values,
clnp_option_rfd_source_routeing_values,
clnp_option_rfd_lifetime_values,
clnp_option_rfd_pdu_discard_values,
clnp_option_rfd_reassembly_values,
NULL,
NULL,
NULL
};
#define CLNP_OPTION_OPTION_QOS_MASK 0x3f
#define CLNP_OPTION_SCOPE_MASK 0xc0
#define CLNP_OPTION_SCOPE_SA_SPEC 0x40
#define CLNP_OPTION_SCOPE_DA_SPEC 0x80
#define CLNP_OPTION_SCOPE_GLOBAL 0xc0
static const struct tok clnp_option_scope_values[] = {
{ CLNP_OPTION_SCOPE_SA_SPEC, "Source Address Specific"},
{ CLNP_OPTION_SCOPE_DA_SPEC, "Destination Address Specific"},
{ CLNP_OPTION_SCOPE_GLOBAL, "Globally unique"},
{ 0, NULL }
};
static const struct tok clnp_option_sr_rr_values[] = {
{ 0x0, "partial"},
{ 0x1, "complete"},
{ 0, NULL }
};
static const struct tok clnp_option_sr_rr_string_values[] = {
{ CLNP_OPTION_SOURCE_ROUTING, "source routing"},
{ CLNP_OPTION_ROUTE_RECORDING, "recording of route in progress"},
{ 0, NULL }
};
static const struct tok clnp_option_qos_global_values[] = {
{ 0x20, "reserved"},
{ 0x10, "sequencing vs. delay"},
{ 0x08, "congested"},
{ 0x04, "delay vs. cost"},
{ 0x02, "error vs. delay"},
{ 0x01, "error vs. cost"},
{ 0, NULL }
};
static const struct tok isis_tlv_router_capability_flags[] = {
{ 0x01, "S bit"},
{ 0x02, "D bit"},
{ 0, NULL }
};
#define ISIS_SUBTLV_ROUTER_CAP_SR 2 /* rfc 8667 */
static const struct tok isis_router_capability_subtlv_values[] = {
{ ISIS_SUBTLV_ROUTER_CAP_SR, "SR-Capabilities"},
{ 0, NULL }
};
static const struct tok isis_router_capability_sr_flags[] = {
{ 0x80, "ipv4"},
{ 0x40, "ipv6"},
{ 0, NULL }
};
#define ISIS_SUBTLV_EXT_IS_REACH_ADMIN_GROUP 3 /* rfc5305 */
#define ISIS_SUBTLV_EXT_IS_REACH_LINK_LOCAL_REMOTE_ID 4 /* rfc4205 */
#define ISIS_SUBTLV_EXT_IS_REACH_LINK_REMOTE_ID 5 /* rfc5305 */
#define ISIS_SUBTLV_EXT_IS_REACH_IPV4_INTF_ADDR 6 /* rfc5305 */
#define ISIS_SUBTLV_EXT_IS_REACH_IPV4_NEIGHBOR_ADDR 8 /* rfc5305 */
#define ISIS_SUBTLV_EXT_IS_REACH_MAX_LINK_BW 9 /* rfc5305 */
#define ISIS_SUBTLV_EXT_IS_REACH_RESERVABLE_BW 10 /* rfc5305 */
#define ISIS_SUBTLV_EXT_IS_REACH_UNRESERVED_BW 11 /* rfc4124 */
#define ISIS_SUBTLV_EXT_IS_REACH_BW_CONSTRAINTS_OLD 12 /* draft-ietf-tewg-diff-te-proto-06 */
#define ISIS_SUBTLV_EXT_IS_REACH_TE_METRIC 18 /* rfc5305 */
#define ISIS_SUBTLV_EXT_IS_REACH_LINK_ATTRIBUTE 19 /* draft-ietf-isis-link-attr-01 */
#define ISIS_SUBTLV_EXT_IS_REACH_LINK_PROTECTION_TYPE 20 /* rfc4205 */
#define ISIS_SUBTLV_EXT_IS_REACH_INTF_SW_CAP_DESCR 21 /* rfc4205 */
#define ISIS_SUBTLV_EXT_IS_REACH_BW_CONSTRAINTS 22 /* rfc4124 */
#define ISIS_SUBTLV_EXT_IS_REACH_LAN_ADJ_SEGMENT_ID 32 /* rfc8667 */
#define ISIS_SUBTLV_SPB_METRIC 29 /* rfc6329 */
static const struct tok isis_ext_is_reach_subtlv_values[] = {
{ ISIS_SUBTLV_EXT_IS_REACH_ADMIN_GROUP, "Administrative groups" },
{ ISIS_SUBTLV_EXT_IS_REACH_LINK_LOCAL_REMOTE_ID, "Link Local/Remote Identifier" },
{ ISIS_SUBTLV_EXT_IS_REACH_LINK_REMOTE_ID, "Link Remote Identifier" },
{ ISIS_SUBTLV_EXT_IS_REACH_IPV4_INTF_ADDR, "IPv4 interface address" },
{ ISIS_SUBTLV_EXT_IS_REACH_IPV4_NEIGHBOR_ADDR, "IPv4 neighbor address" },
{ ISIS_SUBTLV_EXT_IS_REACH_MAX_LINK_BW, "Maximum link bandwidth" },
{ ISIS_SUBTLV_EXT_IS_REACH_RESERVABLE_BW, "Reservable link bandwidth" },
{ ISIS_SUBTLV_EXT_IS_REACH_UNRESERVED_BW, "Unreserved bandwidth" },
{ ISIS_SUBTLV_EXT_IS_REACH_TE_METRIC, "Traffic Engineering Metric" },
{ ISIS_SUBTLV_EXT_IS_REACH_LINK_ATTRIBUTE, "Link Attribute" },
{ ISIS_SUBTLV_EXT_IS_REACH_LINK_PROTECTION_TYPE, "Link Protection Type" },
{ ISIS_SUBTLV_EXT_IS_REACH_INTF_SW_CAP_DESCR, "Interface Switching Capability" },
{ ISIS_SUBTLV_EXT_IS_REACH_BW_CONSTRAINTS_OLD, "Bandwidth Constraints (old)" },
{ ISIS_SUBTLV_EXT_IS_REACH_BW_CONSTRAINTS, "Bandwidth Constraints" },
{ ISIS_SUBTLV_EXT_IS_REACH_LAN_ADJ_SEGMENT_ID, "LAN Adjacency Segment Identifier" },
{ ISIS_SUBTLV_SPB_METRIC, "SPB Metric" },
{ 250, "Reserved for cisco specific extensions" },
{ 251, "Reserved for cisco specific extensions" },
{ 252, "Reserved for cisco specific extensions" },
{ 253, "Reserved for cisco specific extensions" },
{ 254, "Reserved for cisco specific extensions" },
{ 255, "Reserved for future expansion" },
{ 0, NULL }
};
#define ISIS_SUBTLV_EXTD_IP_REACH_ADMIN_TAG32 1 /* draft-ietf-isis-admin-tags-01 */
#define ISIS_SUBTLV_EXTD_IP_REACH_ADMIN_TAG64 2 /* draft-ietf-isis-admin-tags-01 */
#define ISIS_SUBTLV_EXTD_IP_REACH_PREFIX_SID 3 /* rfc8667 */
#define ISIS_SUBTLV_EXTD_IP_REACH_MGMT_PREFIX_COLOR 117 /* draft-ietf-isis-wg-multi-topology-05 */
static const struct tok isis_ext_ip_reach_subtlv_values[] = {
{ ISIS_SUBTLV_EXTD_IP_REACH_ADMIN_TAG32, "32-Bit Administrative tag" },
{ ISIS_SUBTLV_EXTD_IP_REACH_ADMIN_TAG64, "64-Bit Administrative tag" },
{ ISIS_SUBTLV_EXTD_IP_REACH_PREFIX_SID, "Prefix SID" },
{ ISIS_SUBTLV_EXTD_IP_REACH_MGMT_PREFIX_COLOR, "Management Prefix Color" },
{ 0, NULL }
};
#define ISIS_PREFIX_SID_FLAG_R 0x80 /* rfc 8667 */
#define ISIS_PREFIX_SID_FLAG_N 0x40 /* rfc 8667 */
#define ISIS_PREFIX_SID_FLAG_P 0x20 /* rfc 8667 */
#define ISIS_PREFIX_SID_FLAG_E 0x10 /* rfc 8667 */
#define ISIS_PREFIX_SID_FLAG_V 0x08 /* rfc 8667 */
#define ISIS_PREFIX_SID_FLAG_L 0x04 /* rfc 8667 */
static const struct tok prefix_sid_flag_values[] = {
{ ISIS_PREFIX_SID_FLAG_R, "Readvertisement"},
{ ISIS_PREFIX_SID_FLAG_N, "Node"},
{ ISIS_PREFIX_SID_FLAG_P, "No-PHP"},
{ ISIS_PREFIX_SID_FLAG_E, "Explicit NULL"},
{ ISIS_PREFIX_SID_FLAG_V, "Value"},
{ ISIS_PREFIX_SID_FLAG_L, "Local"},
{ 0, NULL}
};
/* rfc 8667 */
static const struct tok prefix_sid_algo_values[] = {
{ 0, "SPF"},
{ 1, "strict-SPF"},
{ 0, NULL}
};
static const struct tok isis_subtlv_link_attribute_values[] = {
{ 0x01, "Local Protection Available" },
{ 0x02, "Link excluded from local protection path" },
{ 0x04, "Local maintenance required"},
{ 0, NULL }
};
static const struct tok isis_lan_adj_sid_flag_values[] = {
{ 0x80, "Address family IPv6" },
{ 0x40, "Backup" },
{ 0x20, "Value" },
{ 0x10, "Local significance" },
{ 0x08, "Set of adjacencies" },
{ 0x04, "Persistent" },
{ 0, NULL }
};
#define ISIS_SUBTLV_AUTH_SIMPLE 1
#define ISIS_SUBTLV_AUTH_GENERIC 3 /* rfc 5310 */
#define ISIS_SUBTLV_AUTH_MD5 54
#define ISIS_SUBTLV_AUTH_MD5_LEN 16
#define ISIS_SUBTLV_AUTH_PRIVATE 255
static const struct tok isis_subtlv_auth_values[] = {
{ ISIS_SUBTLV_AUTH_SIMPLE, "simple text password"},
{ ISIS_SUBTLV_AUTH_GENERIC, "Generic Crypto key-id"},
{ ISIS_SUBTLV_AUTH_MD5, "HMAC-MD5 password"},
{ ISIS_SUBTLV_AUTH_PRIVATE, "Routing Domain private password"},
{ 0, NULL }
};
#define ISIS_SUBTLV_IDRP_RES 0
#define ISIS_SUBTLV_IDRP_LOCAL 1
#define ISIS_SUBTLV_IDRP_ASN 2
static const struct tok isis_subtlv_idrp_values[] = {
{ ISIS_SUBTLV_IDRP_RES, "Reserved"},
{ ISIS_SUBTLV_IDRP_LOCAL, "Routing-Domain Specific"},
{ ISIS_SUBTLV_IDRP_ASN, "AS Number Tag"},
{ 0, NULL}
};
#define ISIS_SUBTLV_SPB_MCID 4
#define ISIS_SUBTLV_SPB_DIGEST 5
#define ISIS_SUBTLV_SPB_BVID 6
#define ISIS_SUBTLV_SPB_INSTANCE 1
#define ISIS_SUBTLV_SPBM_SI 3
#define ISIS_SPB_MCID_LEN 51
#define ISIS_SUBTLV_SPB_MCID_MIN_LEN 102
#define ISIS_SUBTLV_SPB_DIGEST_MIN_LEN 33
#define ISIS_SUBTLV_SPB_BVID_MIN_LEN 6
#define ISIS_SUBTLV_SPB_INSTANCE_MIN_LEN 19
#define ISIS_SUBTLV_SPB_INSTANCE_VLAN_TUPLE_LEN 8
static const struct tok isis_mt_port_cap_subtlv_values[] = {
{ ISIS_SUBTLV_SPB_MCID, "SPB MCID" },
{ ISIS_SUBTLV_SPB_DIGEST, "SPB Digest" },
{ ISIS_SUBTLV_SPB_BVID, "SPB BVID" },
{ 0, NULL }
};
static const struct tok isis_mt_capability_subtlv_values[] = {
{ ISIS_SUBTLV_SPB_INSTANCE, "SPB Instance" },
{ ISIS_SUBTLV_SPBM_SI, "SPBM Service Identifier and Unicast Address" },
{ 0, NULL }
};
struct isis_spb_mcid {
nd_uint8_t format_id;
nd_byte name[32];
nd_uint16_t revision_lvl;
nd_byte digest[16];
};
struct isis_subtlv_spb_mcid {
struct isis_spb_mcid mcid;
struct isis_spb_mcid aux_mcid;
};
struct isis_subtlv_spb_instance {
nd_byte cist_root_id[8];
nd_uint32_t cist_external_root_path_cost;
nd_uint16_t bridge_priority;
nd_uint32_t spsourceid;
nd_uint8_t no_of_trees;
};
#define CLNP_SEGMENT_PART 0x80
#define CLNP_MORE_SEGMENTS 0x40
#define CLNP_REQUEST_ER 0x20
static const struct tok clnp_flag_values[] = {
{ CLNP_SEGMENT_PART, "Segmentation permitted"},
{ CLNP_MORE_SEGMENTS, "more Segments"},
{ CLNP_REQUEST_ER, "request Error Report"},
{ 0, NULL}
};
#define ISIS_MASK_LSP_OL_BIT(x) (GET_U_1(x)&0x4)
#define ISIS_MASK_LSP_ISTYPE_BITS(x) (GET_U_1(x)&0x3)
#define ISIS_MASK_LSP_PARTITION_BIT(x) (GET_U_1(x)&0x80)
#define ISIS_MASK_LSP_ATT_BITS(x) (GET_U_1(x)&0x78)
#define ISIS_MASK_LSP_ATT_ERROR_BIT(x) (GET_U_1(x)&0x40)
#define ISIS_MASK_LSP_ATT_EXPENSE_BIT(x) (GET_U_1(x)&0x20)
#define ISIS_MASK_LSP_ATT_DELAY_BIT(x) (GET_U_1(x)&0x10)
#define ISIS_MASK_LSP_ATT_DEFAULT_BIT(x) (GET_U_1(x)&0x8)
#define ISIS_MASK_MTID(x) ((x)&0x0fff)
#define ISIS_MASK_MTFLAGS(x) ((x)&0xf000)
static const struct tok isis_mt_flag_values[] = {
{ 0x4000, "ATT bit set"},
{ 0x8000, "Overload bit set"},
{ 0, NULL}
};
#define ISIS_MASK_TLV_EXTD_IP_UPDOWN(x) ((x)&0x80)
#define ISIS_MASK_TLV_EXTD_IP_SUBTLV(x) ((x)&0x40)
#define ISIS_MASK_TLV_EXTD_IP6_IE(x) ((x)&0x40)
#define ISIS_MASK_TLV_EXTD_IP6_SUBTLV(x) ((x)&0x20)
#define ISIS_LSP_TLV_METRIC_SUPPORTED(x) (GET_U_1(x)&0x80)
#define ISIS_LSP_TLV_METRIC_IE(x) (GET_U_1(x)&0x40)
#define ISIS_LSP_TLV_METRIC_UPDOWN(x) (GET_U_1(x)&0x80)
#define ISIS_LSP_TLV_METRIC_VALUE(x) (GET_U_1(x)&0x3f)
#define ISIS_MASK_TLV_SHARED_RISK_GROUP(x) ((x)&0x1)
static const struct tok isis_mt_values[] = {
{ 0, "IPv4 unicast"},
{ 1, "In-Band Management"},
{ 2, "IPv6 unicast"},
{ 3, "Multicast"},
{ 4095, "Development, Experimental or Proprietary"},
{ 0, NULL }
};
static const struct tok isis_iih_circuit_type_values[] = {
{ 1, "Level 1 only"},
{ 2, "Level 2 only"},
{ 3, "Level 1, Level 2"},
{ 0, NULL}
};
#define ISIS_LSP_TYPE_UNUSED0 0
#define ISIS_LSP_TYPE_LEVEL_1 1
#define ISIS_LSP_TYPE_UNUSED2 2
#define ISIS_LSP_TYPE_LEVEL_2 3
static const struct tok isis_lsp_istype_values[] = {
{ ISIS_LSP_TYPE_UNUSED0, "Unused 0x0 (invalid)"},
{ ISIS_LSP_TYPE_LEVEL_1, "L1 IS"},
{ ISIS_LSP_TYPE_UNUSED2, "Unused 0x2 (invalid)"},
{ ISIS_LSP_TYPE_LEVEL_2, "L2 IS"},
{ 0, NULL }
};
/*
* Katz's point to point adjacency TLV uses codes to tell us the state of
* the remote adjacency. Enumerate them.
*/
#define ISIS_PTP_ADJ_UP 0
#define ISIS_PTP_ADJ_INIT 1
#define ISIS_PTP_ADJ_DOWN 2
static const struct tok isis_ptp_adjacency_values[] = {
{ ISIS_PTP_ADJ_UP, "Up" },
{ ISIS_PTP_ADJ_INIT, "Initializing" },
{ ISIS_PTP_ADJ_DOWN, "Down" },
{ 0, NULL}
};
struct isis_tlv_ptp_adj {
nd_uint8_t adjacency_state;
nd_uint32_t extd_local_circuit_id;
nd_byte neighbor_sysid[SYSTEM_ID_LEN];
nd_uint32_t neighbor_extd_local_circuit_id;
};
static void osi_print_cksum(netdissect_options *, const uint8_t *pptr,
uint16_t checksum, int checksum_offset, u_int length);
static int clnp_print(netdissect_options *, const uint8_t *, u_int);
static void esis_print(netdissect_options *, const uint8_t *, u_int);
static int isis_print(netdissect_options *, const uint8_t *, u_int);
struct isis_metric_block {
nd_uint8_t metric_default;
nd_uint8_t metric_delay;
nd_uint8_t metric_expense;
nd_uint8_t metric_error;
};
struct isis_tlv_is_reach {
struct isis_metric_block isis_metric_block;
nd_byte neighbor_nodeid[NODE_ID_LEN];
};
struct isis_tlv_es_reach {
struct isis_metric_block isis_metric_block;
nd_byte neighbor_sysid[SYSTEM_ID_LEN];
};
struct isis_tlv_ip_reach {
struct isis_metric_block isis_metric_block;
nd_ipv4 prefix;
nd_ipv4 mask;
};
static const struct tok isis_is_reach_virtual_values[] = {
{ 0, "IsNotVirtual"},
{ 1, "IsVirtual"},
{ 0, NULL }
};
static const struct tok isis_restart_flag_values[] = {
{ 0x1, "Restart Request"},
{ 0x2, "Restart Acknowledgement"},
{ 0x4, "Suppress adjacency advertisement"},
{ 0, NULL }
};
struct isis_common_header {
nd_uint8_t nlpid;
nd_uint8_t fixed_len;
nd_uint8_t version; /* Protocol version */
nd_uint8_t id_length;
nd_uint8_t pdu_type; /* 3 MSbits are reserved */
nd_uint8_t pdu_version; /* Packet format version */
nd_byte reserved;
nd_uint8_t max_area;
};
struct isis_iih_lan_header {
nd_uint8_t circuit_type;
nd_byte source_id[SYSTEM_ID_LEN];
nd_uint16_t holding_time;
nd_uint16_t pdu_len;
nd_uint8_t priority;
nd_byte lan_id[NODE_ID_LEN];
};
struct isis_iih_ptp_header {
nd_uint8_t circuit_type;
nd_byte source_id[SYSTEM_ID_LEN];
nd_uint16_t holding_time;
nd_uint16_t pdu_len;
nd_uint8_t circuit_id;
};
struct isis_lsp_header {
nd_uint16_t pdu_len;
nd_uint16_t remaining_lifetime;
nd_byte lsp_id[LSP_ID_LEN];
nd_uint32_t sequence_number;
nd_uint16_t checksum;
nd_uint8_t typeblock;
};
struct isis_csnp_header {
nd_uint16_t pdu_len;
nd_byte source_id[NODE_ID_LEN];
nd_byte start_lsp_id[LSP_ID_LEN];
nd_byte end_lsp_id[LSP_ID_LEN];
};
struct isis_psnp_header {
nd_uint16_t pdu_len;
nd_byte source_id[NODE_ID_LEN];
};
struct isis_tlv_lsp {
nd_uint16_t remaining_lifetime;
nd_byte lsp_id[LSP_ID_LEN];
nd_uint32_t sequence_number;
nd_uint16_t checksum;
};
#define ISIS_COMMON_HEADER_SIZE (sizeof(struct isis_common_header))
#define ISIS_IIH_LAN_HEADER_SIZE (sizeof(struct isis_iih_lan_header))
#define ISIS_IIH_PTP_HEADER_SIZE (sizeof(struct isis_iih_ptp_header))
#define ISIS_LSP_HEADER_SIZE (sizeof(struct isis_lsp_header))
#define ISIS_CSNP_HEADER_SIZE (sizeof(struct isis_csnp_header))
#define ISIS_PSNP_HEADER_SIZE (sizeof(struct isis_psnp_header))
void
isoclns_print(netdissect_options *ndo, const u_char *p, u_int length)
{
ndo->ndo_protocol = "isoclns";
if (ndo->ndo_eflag)
ND_PRINT("OSI NLPID %s (0x%02x): ",
tok2str(nlpid_values, "Unknown", GET_U_1(p)),
GET_U_1(p));
switch (GET_U_1(p)) {
case NLPID_CLNP:
if (!clnp_print(ndo, p, length))
print_unknown_data(ndo, p, "\n\t", length);
break;
case NLPID_ESIS:
esis_print(ndo, p, length);
return;
case NLPID_ISIS:
if (!isis_print(ndo, p, length))
print_unknown_data(ndo, p, "\n\t", length);
break;
case NLPID_NULLNS:
ND_PRINT("%slength: %u", ndo->ndo_eflag ? "" : ", ", length);
break;
case NLPID_Q933:
q933_print(ndo, p + 1, length - 1);
break;
case NLPID_IP:
ip_print(ndo, p + 1, length - 1);
break;
case NLPID_IP6:
ip6_print(ndo, p + 1, length - 1);
break;
case NLPID_PPP:
ppp_print(ndo, p + 1, length - 1);
break;
default:
if (!ndo->ndo_eflag)
ND_PRINT("OSI NLPID 0x%02x unknown", GET_U_1(p));
ND_PRINT("%slength: %u", ndo->ndo_eflag ? "" : ", ", length);
if (length > 1)
print_unknown_data(ndo, p, "\n\t", length);
break;
}
}
#define CLNP_PDU_ER 1
#define CLNP_PDU_DT 28
#define CLNP_PDU_MD 29
#define CLNP_PDU_ERQ 30
#define CLNP_PDU_ERP 31
static const struct tok clnp_pdu_values[] = {
{ CLNP_PDU_ER, "Error Report"},
{ CLNP_PDU_MD, "MD"},
{ CLNP_PDU_DT, "Data"},
{ CLNP_PDU_ERQ, "Echo Request"},
{ CLNP_PDU_ERP, "Echo Response"},
{ 0, NULL }
};
struct clnp_header_t {
nd_uint8_t nlpid;
nd_uint8_t length_indicator;
nd_uint8_t version;
nd_uint8_t lifetime; /* units of 500ms */
nd_uint8_t type;
nd_uint16_t segment_length;
nd_uint16_t cksum;
};
struct clnp_segment_header_t {
nd_uint16_t data_unit_id;
nd_uint16_t segment_offset;
nd_uint16_t total_length;
};
/*
* clnp_print
* Decode CLNP packets. Return 0 on error.
*/
static int
clnp_print(netdissect_options *ndo,
const uint8_t *pptr, u_int length)
{
const uint8_t *optr,*source_address,*dest_address;
u_int li,li_remaining,tlen,nsap_offset,source_address_length,dest_address_length, clnp_pdu_type, clnp_flags;
const struct clnp_header_t *clnp_header;
const struct clnp_segment_header_t *clnp_segment_header;
uint8_t rfd_error,rfd_error_major,rfd_error_minor;
ndo->ndo_protocol = "clnp";
clnp_header = (const struct clnp_header_t *) pptr;
ND_TCHECK_SIZE(clnp_header);
li = GET_U_1(clnp_header->length_indicator);
li_remaining = li;
optr = pptr;
if (!ndo->ndo_eflag)
nd_print_protocol_caps(ndo);
/*
* Sanity checking of the header.
*/
if (GET_U_1(clnp_header->version) != CLNP_VERSION) {
ND_PRINT("version %u packet not supported",
GET_U_1(clnp_header->version));
return (0);
}
if (li > length) {
ND_PRINT(" length indicator(%u) > PDU size (%u)!", li, length);
return (0);
}
if (li < sizeof(struct clnp_header_t)) {
ND_PRINT(" length indicator %u < min PDU size:", li);
while (pptr < ndo->ndo_snapend) {
ND_PRINT("%02X", GET_U_1(pptr));
pptr++;
}
return (0);
}
/* FIXME further header sanity checking */
clnp_pdu_type = GET_U_1(clnp_header->type) & CLNP_PDU_TYPE_MASK;
clnp_flags = GET_U_1(clnp_header->type) & CLNP_FLAG_MASK;
pptr += sizeof(struct clnp_header_t);
li_remaining -= sizeof(struct clnp_header_t);
if (li_remaining < 1) {
ND_PRINT("li < size of fixed part of CLNP header and addresses");
return (0);
}
dest_address_length = GET_U_1(pptr);
pptr += 1;
li_remaining -= 1;
if (li_remaining < dest_address_length) {
ND_PRINT("li < size of fixed part of CLNP header and addresses");
return (0);
}
ND_TCHECK_LEN(pptr, dest_address_length);
dest_address = pptr;
pptr += dest_address_length;
li_remaining -= dest_address_length;
if (li_remaining < 1) {
ND_PRINT("li < size of fixed part of CLNP header and addresses");
return (0);
}
source_address_length = GET_U_1(pptr);
pptr += 1;
li_remaining -= 1;
if (li_remaining < source_address_length) {
ND_PRINT("li < size of fixed part of CLNP header and addresses");
return (0);
}
ND_TCHECK_LEN(pptr, source_address_length);
source_address = pptr;
pptr += source_address_length;
li_remaining -= source_address_length;
if (ndo->ndo_vflag < 1) {
ND_PRINT("%s%s > %s, %s, length %u",
ndo->ndo_eflag ? "" : ", ",
GET_ISONSAP_STRING(source_address, source_address_length),
GET_ISONSAP_STRING(dest_address, dest_address_length),
tok2str(clnp_pdu_values,"unknown (%u)",clnp_pdu_type),
length);
return (1);
}
ND_PRINT("%slength %u", ndo->ndo_eflag ? "" : ", ", length);
ND_PRINT("\n\t%s PDU, hlen: %u, v: %u, lifetime: %u.%us, Segment PDU length: %u, checksum: 0x%04x",
tok2str(clnp_pdu_values, "unknown (%u)",clnp_pdu_type),
GET_U_1(clnp_header->length_indicator),
GET_U_1(clnp_header->version),
GET_U_1(clnp_header->lifetime)/2,
(GET_U_1(clnp_header->lifetime)%2)*5,
GET_BE_U_2(clnp_header->segment_length),
GET_BE_U_2(clnp_header->cksum));
osi_print_cksum(ndo, optr, GET_BE_U_2(clnp_header->cksum), 7,
GET_U_1(clnp_header->length_indicator));
ND_PRINT("\n\tFlags [%s]",
bittok2str(clnp_flag_values, "none", clnp_flags));
ND_PRINT("\n\tsource address (length %u): %s\n\tdest address (length %u): %s",
source_address_length,
GET_ISONSAP_STRING(source_address, source_address_length),
dest_address_length,
GET_ISONSAP_STRING(dest_address, dest_address_length));
if (clnp_flags & CLNP_SEGMENT_PART) {
if (li_remaining < sizeof(struct clnp_segment_header_t)) {
ND_PRINT("li < size of fixed part of CLNP header, addresses, and segment part");
return (0);
}
clnp_segment_header = (const struct clnp_segment_header_t *) pptr;
ND_TCHECK_SIZE(clnp_segment_header);
ND_PRINT("\n\tData Unit ID: 0x%04x, Segment Offset: %u, Total PDU Length: %u",
GET_BE_U_2(clnp_segment_header->data_unit_id),
GET_BE_U_2(clnp_segment_header->segment_offset),
GET_BE_U_2(clnp_segment_header->total_length));
pptr+=sizeof(struct clnp_segment_header_t);
li_remaining-=sizeof(struct clnp_segment_header_t);
}
/* now walk the options */
while (li_remaining != 0) {
u_int op, opli;
const uint8_t *tptr;
if (li_remaining < 2) {
ND_PRINT(", bad opts/li");
return (0);
}
op = GET_U_1(pptr);
opli = GET_U_1(pptr + 1);
pptr += 2;
li_remaining -= 2;
if (opli > li_remaining) {
ND_PRINT(", opt (%u) too long", op);
return (0);
}
ND_TCHECK_LEN(pptr, opli);
li_remaining -= opli;
tptr = pptr;
tlen = opli;
ND_PRINT("\n\t %s Option #%u, length %u, value: ",
tok2str(clnp_option_values,"Unknown",op),
op,
opli);
/*
* We've already checked that the entire option is present
* in the captured packet with the ND_TCHECK_LEN() call.
* Therefore, we don't need to do ND_TCHECK()/ND_TCHECK_LEN()
* checks.
* We do, however, need to check tlen, to make sure we
* don't run past the end of the option.
*/
switch (op) {
case CLNP_OPTION_ROUTE_RECORDING: /* those two options share the format */
case CLNP_OPTION_SOURCE_ROUTING:
if (tlen < 2) {
ND_PRINT(", bad opt len");
return (0);
}
ND_PRINT("%s %s",
tok2str(clnp_option_sr_rr_values,"Unknown",GET_U_1(tptr)),
tok2str(clnp_option_sr_rr_string_values, "Unknown Option %u", op));
nsap_offset=GET_U_1(tptr + 1);
if (nsap_offset == 0) {
ND_PRINT(" Bad NSAP offset (0)");
break;
}
nsap_offset-=1; /* offset to nsap list */
if (nsap_offset > tlen) {
ND_PRINT(" Bad NSAP offset (past end of option)");
break;
}
tptr+=nsap_offset;
tlen-=nsap_offset;
while (tlen != 0) {
source_address_length=GET_U_1(tptr);
if (tlen < source_address_length+1) {
ND_PRINT("\n\t NSAP address goes past end of option");
break;
}
if (source_address_length > 0) {
source_address=(tptr+1);
ND_PRINT("\n\t NSAP address (length %u): %s",
source_address_length,
GET_ISONSAP_STRING(source_address, source_address_length));
}
tlen-=source_address_length+1;
}
break;
case CLNP_OPTION_PRIORITY:
if (tlen < 1) {
ND_PRINT(", bad opt len");
return (0);
}
ND_PRINT("0x%1x", GET_U_1(tptr)&0x0f);
break;
case CLNP_OPTION_QOS_MAINTENANCE:
if (tlen < 1) {
ND_PRINT(", bad opt len");
return (0);
}
ND_PRINT("\n\t Format Code: %s",
tok2str(clnp_option_scope_values, "Reserved", GET_U_1(tptr) & CLNP_OPTION_SCOPE_MASK));
if ((GET_U_1(tptr)&CLNP_OPTION_SCOPE_MASK) == CLNP_OPTION_SCOPE_GLOBAL)
ND_PRINT("\n\t QoS Flags [%s]",
bittok2str(clnp_option_qos_global_values,
"none",
GET_U_1(tptr)&CLNP_OPTION_OPTION_QOS_MASK));
break;
case CLNP_OPTION_SECURITY:
if (tlen < 2) {
ND_PRINT(", bad opt len");
return (0);
}
ND_PRINT("\n\t Format Code: %s, Security-Level %u",
tok2str(clnp_option_scope_values,"Reserved",GET_U_1(tptr)&CLNP_OPTION_SCOPE_MASK),
GET_U_1(tptr + 1));
break;
case CLNP_OPTION_DISCARD_REASON:
if (tlen < 1) {
ND_PRINT(", bad opt len");
return (0);
}
rfd_error = GET_U_1(tptr);
rfd_error_major = (rfd_error&0xf0) >> 4;
rfd_error_minor = rfd_error&0x0f;
ND_PRINT("\n\t Class: %s Error (0x%01x), %s (0x%01x)",
tok2str(clnp_option_rfd_class_values,"Unknown",rfd_error_major),
rfd_error_major,
tok2str(clnp_option_rfd_error_class[rfd_error_major],"Unknown",rfd_error_minor),
rfd_error_minor);
break;
case CLNP_OPTION_PADDING:
ND_PRINT("padding data");
break;
/*
* FIXME those are the defined Options that lack a decoder
* you are welcome to contribute code ;-)
*/
default:
print_unknown_data(ndo, tptr, "\n\t ", opli);
break;
}
if (ndo->ndo_vflag > 1)
print_unknown_data(ndo, pptr, "\n\t ", opli);
pptr += opli;
}
switch (clnp_pdu_type) {
case CLNP_PDU_ER: /* fall through */
case CLNP_PDU_ERP:
if (GET_U_1(pptr) == NLPID_CLNP) {
ND_PRINT("\n\t-----original packet-----\n\t");
/* FIXME recursion protection */
clnp_print(ndo, pptr, length - li);
break;
}
/* The cases above break from the switch block if they see and print
* a CLNP header in the Data part. For an Error Report PDU this is
* described in Section 7.9.6 of ITU X.233 (1997 E), also known as
* ISO/IEC 8473-1:1998(E). It is not clear why in this code the same
* applies to an Echo Response PDU, as the standard does not specify
* the contents -- could be a proprietary extension or a bug. In either
* case, if the Data part does not contain a CLNP header, its structure
* is considered unknown and the decoding falls through to print the
* contents as-is.
*/
ND_FALL_THROUGH;
case CLNP_PDU_DT:
case CLNP_PDU_MD:
case CLNP_PDU_ERQ:
default:
/* dump the PDU specific data */
if (length > ND_BYTES_BETWEEN(optr, pptr)) {
ND_PRINT("\n\t undecoded non-header data, length %u", length-li);
print_unknown_data(ndo, pptr, "\n\t ",
length - ND_BYTES_BETWEEN(optr, pptr));
}
}
return (1);
trunc:
nd_print_trunc(ndo);
return (1);
}
#define ESIS_PDU_REDIRECT 6
#define ESIS_PDU_ESH 2
#define ESIS_PDU_ISH 4
static const struct tok esis_pdu_values[] = {
{ ESIS_PDU_REDIRECT, "redirect"},
{ ESIS_PDU_ESH, "ESH"},
{ ESIS_PDU_ISH, "ISH"},
{ 0, NULL }
};
struct esis_header_t {
nd_uint8_t nlpid;
nd_uint8_t length_indicator;
nd_uint8_t version;
nd_byte reserved;
nd_uint8_t type;
nd_uint16_t holdtime;
nd_uint16_t cksum;
};
static void
esis_print(netdissect_options *ndo,
const uint8_t *pptr, u_int length)
{
const uint8_t *optr;
u_int li, version, esis_pdu_type, source_address_length, source_address_number;
const struct esis_header_t *esis_header;
ndo->ndo_protocol = "esis";
if (!ndo->ndo_eflag)
ND_PRINT("ES-IS");
if (length <= 2) {
ND_PRINT(ndo->ndo_qflag ? "bad pkt!" : "no header at all!");
return;
}
esis_header = (const struct esis_header_t *) pptr;
ND_TCHECK_SIZE(esis_header);
li = GET_U_1(esis_header->length_indicator);
optr = pptr;
/*
* Sanity checking of the header.
*/
if (GET_U_1(esis_header->nlpid) != NLPID_ESIS) {
ND_PRINT(" nlpid 0x%02x packet not supported",
GET_U_1(esis_header->nlpid));
return;
}
version = GET_U_1(esis_header->version);
if (version != ESIS_VERSION) {
ND_PRINT(" version %u packet not supported", version);
return;
}
if (li > length) {
ND_PRINT(" length indicator(%u) > PDU size (%u)!", li, length);
return;
}
if (li < sizeof(struct esis_header_t) + 2) {
ND_PRINT(" length indicator %u < min PDU size:", li);
while (pptr < ndo->ndo_snapend) {
ND_PRINT("%02X", GET_U_1(pptr));
pptr++;
}
return;
}
esis_pdu_type = GET_U_1(esis_header->type) & ESIS_PDU_TYPE_MASK;
if (ndo->ndo_vflag < 1) {
ND_PRINT("%s%s, length %u",
ndo->ndo_eflag ? "" : ", ",
tok2str(esis_pdu_values,"unknown type (%u)",esis_pdu_type),
length);
return;
} else
ND_PRINT("%slength %u\n\t%s (%u)",
ndo->ndo_eflag ? "" : ", ",
length,
tok2str(esis_pdu_values,"unknown type: %u", esis_pdu_type),
esis_pdu_type);
ND_PRINT(", v: %u%s", version, version == ESIS_VERSION ? "" : "unsupported" );
ND_PRINT(", checksum: 0x%04x", GET_BE_U_2(esis_header->cksum));
osi_print_cksum(ndo, pptr, GET_BE_U_2(esis_header->cksum), 7,
li);
ND_PRINT(", holding time: %us, length indicator: %u",
GET_BE_U_2(esis_header->holdtime), li);
if (ndo->ndo_vflag > 1)
print_unknown_data(ndo, optr, "\n\t", sizeof(struct esis_header_t));
pptr += sizeof(struct esis_header_t);
li -= sizeof(struct esis_header_t);
switch (esis_pdu_type) {
case ESIS_PDU_REDIRECT: {
const uint8_t *dst, *snpa, *neta;
u_int dstl, snpal, netal;
ND_TCHECK_1(pptr);
if (li < 1) {
ND_PRINT(", bad redirect/li");
return;
}
dstl = GET_U_1(pptr);
pptr++;
li--;
ND_TCHECK_LEN(pptr, dstl);
if (li < dstl) {
ND_PRINT(", bad redirect/li");
return;
}
dst = pptr;
pptr += dstl;
li -= dstl;
ND_PRINT("\n\t %s", GET_ISONSAP_STRING(dst, dstl));
ND_TCHECK_1(pptr);
if (li < 1) {
ND_PRINT(", bad redirect/li");
return;
}
snpal = GET_U_1(pptr);
pptr++;
li--;
ND_TCHECK_LEN(pptr, snpal);
if (li < snpal) {
ND_PRINT(", bad redirect/li");
return;
}
snpa = pptr;
pptr += snpal;
li -= snpal;
ND_TCHECK_1(pptr);
if (li < 1) {
ND_PRINT(", bad redirect/li");
return;
}
netal = GET_U_1(pptr);
pptr++;
ND_TCHECK_LEN(pptr, netal);
if (li < netal) {
ND_PRINT(", bad redirect/li");
return;
}
neta = pptr;
pptr += netal;
li -= netal;
if (snpal == MAC48_LEN)
ND_PRINT("\n\t SNPA (length: %u): %s",
snpal,
GET_MAC48_STRING(snpa));
else
ND_PRINT("\n\t SNPA (length: %u): %s",
snpal,
GET_LINKADDR_STRING(snpa, LINKADDR_OTHER, snpal));
if (netal != 0)
ND_PRINT("\n\t NET (length: %u) %s",
netal,
GET_ISONSAP_STRING(neta, netal));
break;
}
case ESIS_PDU_ESH:
ND_TCHECK_1(pptr);
if (li < 1) {
ND_PRINT(", bad esh/li");
return;
}
source_address_number = GET_U_1(pptr);
pptr++;
li--;
ND_PRINT("\n\t Number of Source Addresses: %u", source_address_number);
while (source_address_number != 0) {
ND_TCHECK_1(pptr);
if (li < 1) {
ND_PRINT(", bad esh/li");
return;
}
source_address_length = GET_U_1(pptr);
pptr++;
li--;
ND_TCHECK_LEN(pptr, source_address_length);
if (li < source_address_length) {
ND_PRINT(", bad esh/li");
return;
}
ND_PRINT("\n\t NET (length: %u): %s",
source_address_length,
GET_ISONSAP_STRING(pptr, source_address_length));
pptr += source_address_length;
li -= source_address_length;
source_address_number--;
}
break;
case ESIS_PDU_ISH: {
ND_TCHECK_1(pptr);
if (li < 1) {
ND_PRINT(", bad ish/li");
return;
}
source_address_length = GET_U_1(pptr);
pptr++;
li--;
ND_TCHECK_LEN(pptr, source_address_length);
if (li < source_address_length) {
ND_PRINT(", bad ish/li");
return;
}
ND_PRINT("\n\t NET (length: %u): %s", source_address_length, GET_ISONSAP_STRING(pptr, source_address_length));
pptr += source_address_length;
li -= source_address_length;
break;
}
default:
if (ndo->ndo_vflag <= 1) {
/*
* If there's at least one byte to print, print
* it/them.
*/
if (ND_TTEST_LEN(pptr, 1))
print_unknown_data(ndo, pptr, "\n\t ", ND_BYTES_AVAILABLE_AFTER(pptr));
}
return;
}
/* now walk the options */
while (li != 0) {
u_int op, opli;
const uint8_t *tptr;
if (li < 2) {
ND_PRINT(", bad opts/li");
return;
}
op = GET_U_1(pptr);
opli = GET_U_1(pptr + 1);
pptr += 2;
li -= 2;
if (opli > li) {
ND_PRINT(", opt (%u) too long", op);
return;
}
li -= opli;
tptr = pptr;
ND_PRINT("\n\t %s Option #%u, length %u, value: ",
tok2str(esis_option_values,"Unknown",op),
op,
opli);
switch (op) {
case ESIS_OPTION_ES_CONF_TIME:
if (opli == 2) {
ND_TCHECK_2(pptr);
ND_PRINT("%us", GET_BE_U_2(tptr));
} else
ND_PRINT("(bad length)");
break;
case ESIS_OPTION_PROTOCOLS:
while (opli != 0) {
ND_PRINT("%s (0x%02x)",
tok2str(nlpid_values,
"unknown",
GET_U_1(tptr)),
GET_U_1(tptr));
if (opli>1) /* further NPLIDs ? - put comma */
ND_PRINT(", ");
tptr++;
opli--;
}
break;
/*
* FIXME those are the defined Options that lack a decoder
* you are welcome to contribute code ;-)
*/
case ESIS_OPTION_QOS_MAINTENANCE:
case ESIS_OPTION_SECURITY:
case ESIS_OPTION_PRIORITY:
case ESIS_OPTION_ADDRESS_MASK:
case ESIS_OPTION_SNPA_MASK:
default:
print_unknown_data(ndo, tptr, "\n\t ", opli);
break;
}
if (ndo->ndo_vflag > 1)
print_unknown_data(ndo, pptr, "\n\t ", opli);
pptr += opli;
}
return;
trunc:
nd_print_trunc(ndo);
}
static void
isis_print_mcid(netdissect_options *ndo,
const struct isis_spb_mcid *mcid)
{
int i;
ND_TCHECK_SIZE(mcid);
ND_PRINT("ID: %u, Name: ", GET_U_1(mcid->format_id));
nd_printjnp(ndo, mcid->name, sizeof(mcid->name));
ND_PRINT("\n\t Lvl: %u", GET_BE_U_2(mcid->revision_lvl));
ND_PRINT(", Digest: ");
for(i=0;i<16;i++)
ND_PRINT("%.2x ", mcid->digest[i]);
return;
trunc:
nd_print_trunc(ndo);
}
static int
isis_print_mt_port_cap_subtlv(netdissect_options *ndo,
const uint8_t *tptr, u_int len)
{
u_int stlv_type, stlv_len;
const struct isis_subtlv_spb_mcid *subtlv_spb_mcid;
int i;
while (len > 2) {
stlv_type = GET_U_1(tptr);
stlv_len = GET_U_1(tptr + 1);
/* first lets see if we know the subTLVs name*/
ND_PRINT("\n\t %s subTLV #%u, length: %u",
tok2str(isis_mt_port_cap_subtlv_values, "unknown", stlv_type),
stlv_type,
stlv_len);
tptr += 2;
/*len -= TLV_TYPE_LEN_OFFSET;*/
len -= 2;
/* Make sure the subTLV fits within the space left */
if (len < stlv_len)
goto subtlv_too_long;
/* Make sure the entire subTLV is in the captured data */
ND_TCHECK_LEN(tptr, stlv_len);
switch (stlv_type) {
case ISIS_SUBTLV_SPB_MCID:
{
if (stlv_len < ISIS_SUBTLV_SPB_MCID_MIN_LEN)
goto subtlv_too_short;
subtlv_spb_mcid = (const struct isis_subtlv_spb_mcid *)tptr;
ND_PRINT("\n\t MCID: ");
isis_print_mcid(ndo, &(subtlv_spb_mcid->mcid));
/*tptr += SPB_MCID_MIN_LEN;
len -= SPB_MCID_MIN_LEN; */
ND_PRINT("\n\t AUX-MCID: ");
isis_print_mcid(ndo, &(subtlv_spb_mcid->aux_mcid));
/*tptr += SPB_MCID_MIN_LEN;
len -= SPB_MCID_MIN_LEN; */
tptr += ISIS_SUBTLV_SPB_MCID_MIN_LEN;
len -= ISIS_SUBTLV_SPB_MCID_MIN_LEN;
stlv_len -= ISIS_SUBTLV_SPB_MCID_MIN_LEN;
break;
}
case ISIS_SUBTLV_SPB_DIGEST:
{
if (stlv_len < ISIS_SUBTLV_SPB_DIGEST_MIN_LEN)
goto subtlv_too_short;
ND_PRINT("\n\t RES: %u V: %u A: %u D: %u",
(GET_U_1(tptr) >> 5),
((GET_U_1(tptr) >> 4) & 0x01),
((GET_U_1(tptr) >> 2) & 0x03),
(GET_U_1(tptr) & 0x03));
tptr++;
ND_PRINT("\n\t Digest: ");
for(i=1;i<=8; i++) {
ND_PRINT("%08x ", GET_BE_U_4(tptr));
if (i%4 == 0 && i != 8)
ND_PRINT("\n\t ");
tptr += 4;
}
len -= ISIS_SUBTLV_SPB_DIGEST_MIN_LEN;
stlv_len -= ISIS_SUBTLV_SPB_DIGEST_MIN_LEN;
break;
}
case ISIS_SUBTLV_SPB_BVID:
{
while (stlv_len != 0) {
if (stlv_len < 4)
goto subtlv_too_short;
ND_PRINT("\n\t ECT: %08x",
GET_BE_U_4(tptr));
tptr += 4;
len -= 4;
stlv_len -= 4;
if (stlv_len < 2)
goto subtlv_too_short;
ND_PRINT(" BVID: %u, U:%01x M:%01x ",
(GET_BE_U_2(tptr) >> 4) ,
(GET_BE_U_2(tptr) >> 3) & 0x01,
(GET_BE_U_2(tptr) >> 2) & 0x01);
tptr += 2;
len -= 2;
stlv_len -= 2;
}
break;
}
default:
break;
}
tptr += stlv_len;
len -= stlv_len;
}
return (0);
trunc:
nd_print_trunc(ndo);
return (1);
subtlv_too_long:
ND_PRINT(" (> containing TLV length)");
return (1);
subtlv_too_short:
ND_PRINT(" (too short)");
return (1);
}
static int
isis_print_mt_capability_subtlv(netdissect_options *ndo,
const uint8_t *tptr, u_int len)
{
u_int stlv_type, stlv_len, treecount;
while (len > 2) {
stlv_type = GET_U_1(tptr);
stlv_len = GET_U_1(tptr + 1);
tptr += 2;
len -= 2;
/* first lets see if we know the subTLVs name*/
ND_PRINT("\n\t %s subTLV #%u, length: %u",
tok2str(isis_mt_capability_subtlv_values, "unknown", stlv_type),
stlv_type,
stlv_len);
/* Make sure the subTLV fits within the space left */
if (len < stlv_len)
goto subtlv_too_long;
/* Make sure the entire subTLV is in the captured data */
ND_TCHECK_LEN(tptr, stlv_len);
switch (stlv_type) {
case ISIS_SUBTLV_SPB_INSTANCE:
if (stlv_len < ISIS_SUBTLV_SPB_INSTANCE_MIN_LEN)
goto subtlv_too_short;
ND_PRINT("\n\t CIST Root-ID: %08x", GET_BE_U_4(tptr));
tptr += 4;
ND_PRINT(" %08x", GET_BE_U_4(tptr));
tptr += 4;
ND_PRINT(", Path Cost: %08x", GET_BE_U_4(tptr));
tptr += 4;
ND_PRINT(", Prio: %u", GET_BE_U_2(tptr));
tptr += 2;
ND_PRINT("\n\t RES: %u",
GET_BE_U_2(tptr) >> 5);
ND_PRINT(", V: %u",
(GET_BE_U_2(tptr) >> 4) & 0x0001);
ND_PRINT(", SPSource-ID: %u",
(GET_BE_U_4(tptr) & 0x000fffff));
tptr += 4;
ND_PRINT(", No of Trees: %x", GET_U_1(tptr));
treecount = GET_U_1(tptr);
tptr++;
len -= ISIS_SUBTLV_SPB_INSTANCE_MIN_LEN;
stlv_len -= ISIS_SUBTLV_SPB_INSTANCE_MIN_LEN;
while (treecount) {
if (stlv_len < ISIS_SUBTLV_SPB_INSTANCE_VLAN_TUPLE_LEN)
goto trunc;
ND_PRINT("\n\t U:%u, M:%u, A:%u, RES:%u",
GET_U_1(tptr) >> 7,
(GET_U_1(tptr) >> 6) & 0x01,
(GET_U_1(tptr) >> 5) & 0x01,
(GET_U_1(tptr) & 0x1f));
tptr++;
ND_PRINT(", ECT: %08x", GET_BE_U_4(tptr));
tptr += 4;
ND_PRINT(", BVID: %u, SPVID: %u",
(GET_BE_U_3(tptr) >> 12) & 0x000fff,
GET_BE_U_3(tptr) & 0x000fff);
tptr += 3;
len -= ISIS_SUBTLV_SPB_INSTANCE_VLAN_TUPLE_LEN;
stlv_len -= ISIS_SUBTLV_SPB_INSTANCE_VLAN_TUPLE_LEN;
treecount--;
}
break;
case ISIS_SUBTLV_SPBM_SI:
if (stlv_len < 8)
goto trunc;
ND_PRINT("\n\t BMAC: %08x", GET_BE_U_4(tptr));
tptr += 4;
ND_PRINT("%04x", GET_BE_U_2(tptr));
tptr += 2;
ND_PRINT(", RES: %u, VID: %u", GET_BE_U_2(tptr) >> 12,
(GET_BE_U_2(tptr)) & 0x0fff);
tptr += 2;
len -= 8;
stlv_len -= 8;
while (stlv_len >= 4) {
ND_PRINT("\n\t T: %u, R: %u, RES: %u, ISID: %u",
(GET_BE_U_4(tptr) >> 31),
(GET_BE_U_4(tptr) >> 30) & 0x01,
(GET_BE_U_4(tptr) >> 24) & 0x03f,
(GET_BE_U_4(tptr)) & 0x0ffffff);
tptr += 4;
len -= 4;
stlv_len -= 4;
}
break;
default:
break;
}
tptr += stlv_len;
len -= stlv_len;
}
return (0);
trunc:
nd_print_trunc(ndo);
return (1);
subtlv_too_long:
ND_PRINT(" (> containing TLV length)");
return (1);
subtlv_too_short:
ND_PRINT(" (too short)");
return (1);
}
/* shared routine for printing system, node and lsp-ids */
static char *
isis_print_id(netdissect_options *ndo, const uint8_t *cp, u_int id_len)
{
u_int i;
static char id[sizeof("xxxx.xxxx.xxxx.yy-zz")];
char *pos = id;
u_int sysid_len;
sysid_len = SYSTEM_ID_LEN;
if (sysid_len > id_len)
sysid_len = id_len;
for (i = 1; i <= sysid_len; i++) {
snprintf(pos, sizeof(id) - (pos - id), "%02x", GET_U_1(cp));
cp++;
pos += strlen(pos);
if (i == 2 || i == 4)
*pos++ = '.';
}
if (id_len >= NODE_ID_LEN) {
snprintf(pos, sizeof(id) - (pos - id), ".%02x", GET_U_1(cp));
cp++;
pos += strlen(pos);
}
if (id_len == LSP_ID_LEN)
snprintf(pos, sizeof(id) - (pos - id), "-%02x", GET_U_1(cp));
return (id);
}
/* print the 4-byte metric block which is common found in the old-style TLVs */
static int
isis_print_metric_block(netdissect_options *ndo,
const struct isis_metric_block *isis_metric_block)
{
ND_PRINT(", Default Metric: %u, %s",
ISIS_LSP_TLV_METRIC_VALUE(isis_metric_block->metric_default),
ISIS_LSP_TLV_METRIC_IE(isis_metric_block->metric_default) ? "External" : "Internal");
if (!ISIS_LSP_TLV_METRIC_SUPPORTED(isis_metric_block->metric_delay))
ND_PRINT("\n\t\t Delay Metric: %u, %s",
ISIS_LSP_TLV_METRIC_VALUE(isis_metric_block->metric_delay),
ISIS_LSP_TLV_METRIC_IE(isis_metric_block->metric_delay) ? "External" : "Internal");
if (!ISIS_LSP_TLV_METRIC_SUPPORTED(isis_metric_block->metric_expense))
ND_PRINT("\n\t\t Expense Metric: %u, %s",
ISIS_LSP_TLV_METRIC_VALUE(isis_metric_block->metric_expense),
ISIS_LSP_TLV_METRIC_IE(isis_metric_block->metric_expense) ? "External" : "Internal");
if (!ISIS_LSP_TLV_METRIC_SUPPORTED(isis_metric_block->metric_error))
ND_PRINT("\n\t\t Error Metric: %u, %s",
ISIS_LSP_TLV_METRIC_VALUE(isis_metric_block->metric_error),
ISIS_LSP_TLV_METRIC_IE(isis_metric_block->metric_error) ? "External" : "Internal");
return(1); /* everything is ok */
}
static int
isis_print_tlv_ip_reach(netdissect_options *ndo,
const uint8_t *cp, const char *indent, u_int length)
{
int prefix_len;
const struct isis_tlv_ip_reach *tlv_ip_reach;
tlv_ip_reach = (const struct isis_tlv_ip_reach *)cp;
while (length != 0) {
if ((size_t)length < sizeof(*tlv_ip_reach)) {
ND_PRINT("short IPv4 Reachability (%u vs %zu)",
length,
sizeof(*tlv_ip_reach));
return (0);
}
ND_TCHECK_SIZE(tlv_ip_reach);
prefix_len = mask2plen(GET_IPV4_TO_HOST_ORDER(tlv_ip_reach->mask));
if (prefix_len == -1)
ND_PRINT("%sIPv4 prefix: %s mask %s",
indent,
GET_IPADDR_STRING(tlv_ip_reach->prefix),
GET_IPADDR_STRING(tlv_ip_reach->mask));
else
ND_PRINT("%sIPv4 prefix: %15s/%u",
indent,
GET_IPADDR_STRING(tlv_ip_reach->prefix),
prefix_len);
ND_PRINT(", Distribution: %s, Metric: %u, %s",
ISIS_LSP_TLV_METRIC_UPDOWN(tlv_ip_reach->isis_metric_block.metric_default) ? "down" : "up",
ISIS_LSP_TLV_METRIC_VALUE(tlv_ip_reach->isis_metric_block.metric_default),
ISIS_LSP_TLV_METRIC_IE(tlv_ip_reach->isis_metric_block.metric_default) ? "External" : "Internal");
if (!ISIS_LSP_TLV_METRIC_SUPPORTED(tlv_ip_reach->isis_metric_block.metric_delay))
ND_PRINT("%s Delay Metric: %u, %s",
indent,
ISIS_LSP_TLV_METRIC_VALUE(tlv_ip_reach->isis_metric_block.metric_delay),
ISIS_LSP_TLV_METRIC_IE(tlv_ip_reach->isis_metric_block.metric_delay) ? "External" : "Internal");
if (!ISIS_LSP_TLV_METRIC_SUPPORTED(tlv_ip_reach->isis_metric_block.metric_expense))
ND_PRINT("%s Expense Metric: %u, %s",
indent,
ISIS_LSP_TLV_METRIC_VALUE(tlv_ip_reach->isis_metric_block.metric_expense),
ISIS_LSP_TLV_METRIC_IE(tlv_ip_reach->isis_metric_block.metric_expense) ? "External" : "Internal");
if (!ISIS_LSP_TLV_METRIC_SUPPORTED(tlv_ip_reach->isis_metric_block.metric_error))
ND_PRINT("%s Error Metric: %u, %s",
indent,
ISIS_LSP_TLV_METRIC_VALUE(tlv_ip_reach->isis_metric_block.metric_error),
ISIS_LSP_TLV_METRIC_IE(tlv_ip_reach->isis_metric_block.metric_error) ? "External" : "Internal");
length -= sizeof(struct isis_tlv_ip_reach);
tlv_ip_reach++;
}
return (1);
trunc:
return 0;
}
/*
* this is the common IP-REACH subTLV decoder it is called
* from various EXTD-IP REACH TLVs (135,235,236,237)
*/
static int
isis_print_ip_reach_subtlv(netdissect_options *ndo,
const uint8_t *tptr, u_int subt, u_int subl,
const char *indent)
{
/* first lets see if we know the subTLVs name*/
ND_PRINT("%s%s subTLV #%u, length: %u",
indent, tok2str(isis_ext_ip_reach_subtlv_values, "unknown", subt),
subt, subl);
ND_TCHECK_LEN(tptr, subl);
switch(subt) {
case ISIS_SUBTLV_EXTD_IP_REACH_MGMT_PREFIX_COLOR: /* fall through */
case ISIS_SUBTLV_EXTD_IP_REACH_ADMIN_TAG32:
while (subl >= 4) {
ND_PRINT(", 0x%08x (=%u)",
GET_BE_U_4(tptr),
GET_BE_U_4(tptr));
tptr+=4;
subl-=4;
}
break;
case ISIS_SUBTLV_EXTD_IP_REACH_ADMIN_TAG64:
while (subl >= 8) {
ND_PRINT(", 0x%08x%08x",
GET_BE_U_4(tptr),
GET_BE_U_4(tptr + 4));
tptr+=8;
subl-=8;
}
break;
case ISIS_SUBTLV_EXTD_IP_REACH_PREFIX_SID:
{
uint8_t algo, flags;
uint32_t sid;
flags = GET_U_1(tptr);
algo = GET_U_1(tptr+1);
if (flags & ISIS_PREFIX_SID_FLAG_V) {
if (subl < 5)
goto trunc;
sid = GET_BE_U_3(tptr+2);
tptr+=5;
subl-=5;
} else {
if (subl < 6)
goto trunc;
sid = GET_BE_U_4(tptr+2);
tptr+=6;
subl-=6;
}
ND_PRINT(", Flags [%s], Algo %s (%u), %s %u",
bittok2str(prefix_sid_flag_values, "None", flags),
tok2str(prefix_sid_algo_values, "Unknown", algo), algo,
flags & ISIS_PREFIX_SID_FLAG_V ? "label" : "index",
sid);
}
break;
default:
if (!print_unknown_data(ndo, tptr, "\n\t\t ", subl))
return(0);
break;
}
return(1);
trunc:
nd_print_trunc(ndo);
return(0);
}
/*
* this is the common IS-REACH decoder it is called
* from various EXTD-IS REACH style TLVs (22,24,222)
*/
static int
isis_print_ext_is_reach(netdissect_options *ndo,
const uint8_t *tptr, const char *indent, u_int tlv_type,
u_int tlv_remaining)
{
char indent_buffer[20];
u_int subtlv_type,subtlv_len,subtlv_sum_len;
int proc_bytes = 0; /* how many bytes did we process ? */
u_int te_class,priority_level,gmpls_switch_cap;
ND_TCHECK_LEN(tptr, NODE_ID_LEN);
if (tlv_remaining < NODE_ID_LEN)
return(0);
ND_PRINT("%sIS Neighbor: %s", indent, isis_print_id(ndo, tptr, NODE_ID_LEN));
tptr+=NODE_ID_LEN;
tlv_remaining-=NODE_ID_LEN;
proc_bytes+=NODE_ID_LEN;
if (tlv_type != ISIS_TLV_IS_ALIAS_ID) { /* the Alias TLV Metric field is implicit 0 */
ND_TCHECK_3(tptr);
if (tlv_remaining < 3)
return(0);
ND_PRINT(", Metric: %u", GET_BE_U_3(tptr));
tptr+=3;
tlv_remaining-=3;
proc_bytes+=3;
}
ND_TCHECK_1(tptr);
if (tlv_remaining < 1)
return(0);
subtlv_sum_len=GET_U_1(tptr); /* read out subTLV length */
tptr++;
tlv_remaining--;
proc_bytes++;
ND_PRINT(", %ssub-TLVs present",subtlv_sum_len ? "" : "no ");
if (subtlv_sum_len) {
ND_PRINT(" (%u)", subtlv_sum_len);
/* prepend the indent string */
snprintf(indent_buffer, sizeof(indent_buffer), "%s ", indent);
indent = indent_buffer;
while (subtlv_sum_len != 0) {
ND_TCHECK_2(tptr);
if (tlv_remaining < 2) {
ND_PRINT("%sRemaining data in TLV shorter than a subTLV header", indent);
proc_bytes += tlv_remaining;
break;
}
if (subtlv_sum_len < 2) {
ND_PRINT("%sRemaining data in subTLVs shorter than a subTLV header", indent);
proc_bytes += subtlv_sum_len;
break;
}
subtlv_type=GET_U_1(tptr);
subtlv_len=GET_U_1(tptr + 1);
tptr += 2;
tlv_remaining -= 2;
subtlv_sum_len -= 2;
proc_bytes += 2;
ND_PRINT("%s%s subTLV #%u, length: %u",
indent, tok2str(isis_ext_is_reach_subtlv_values, "unknown", subtlv_type),
subtlv_type, subtlv_len);
if (subtlv_sum_len < subtlv_len) {
ND_PRINT(" (remaining data in subTLVs shorter than the current subTLV)");
proc_bytes += subtlv_sum_len;
break;
}
if (tlv_remaining < subtlv_len) {
ND_PRINT(" (> remaining tlv length)");
proc_bytes += tlv_remaining;
break;
}
ND_TCHECK_LEN(tptr, subtlv_len);
switch(subtlv_type) {
case ISIS_SUBTLV_EXT_IS_REACH_ADMIN_GROUP:
case ISIS_SUBTLV_EXT_IS_REACH_LINK_LOCAL_REMOTE_ID:
case ISIS_SUBTLV_EXT_IS_REACH_LINK_REMOTE_ID:
if (subtlv_len >= 4) {
ND_PRINT(", 0x%08x", GET_BE_U_4(tptr));
if (subtlv_len == 8) /* rfc4205 */
ND_PRINT(", 0x%08x", GET_BE_U_4(tptr + 4));
}
break;
case ISIS_SUBTLV_EXT_IS_REACH_IPV4_INTF_ADDR:
case ISIS_SUBTLV_EXT_IS_REACH_IPV4_NEIGHBOR_ADDR:
if (subtlv_len >= sizeof(nd_ipv4))
ND_PRINT(", %s", GET_IPADDR_STRING(tptr));
break;
case ISIS_SUBTLV_EXT_IS_REACH_MAX_LINK_BW :
case ISIS_SUBTLV_EXT_IS_REACH_RESERVABLE_BW:
if (subtlv_len >= 4)
ND_PRINT(", %.3f Mbps", GET_BE_F_4(tptr) * 8 / 1000000);
break;
case ISIS_SUBTLV_EXT_IS_REACH_UNRESERVED_BW :
if (subtlv_len >= 32) {
for (te_class = 0; te_class < 8; te_class++) {
ND_PRINT("%s TE-Class %u: %.3f Mbps",
indent,
te_class,
GET_BE_F_4(tptr) * 8 / 1000000);
tptr += 4;
subtlv_len -= 4;
subtlv_sum_len -= 4;
proc_bytes += 4;
}
}
break;
case ISIS_SUBTLV_EXT_IS_REACH_BW_CONSTRAINTS: /* fall through */
case ISIS_SUBTLV_EXT_IS_REACH_BW_CONSTRAINTS_OLD:
if (subtlv_len == 0)
break;
ND_PRINT("%sBandwidth Constraints Model ID: %s (%u)",
indent,
tok2str(diffserv_te_bc_values, "unknown", GET_U_1(tptr)),
GET_U_1(tptr));
tptr++;
subtlv_len--;
subtlv_sum_len--;
proc_bytes++;
/* decode BCs until the subTLV ends */
for (te_class = 0; subtlv_len != 0; te_class++) {
if (subtlv_len < 4)
break;
ND_PRINT("%s Bandwidth constraint CT%u: %.3f Mbps",
indent,
te_class,
GET_BE_F_4(tptr) * 8 / 1000000);
tptr += 4;
subtlv_len -= 4;
subtlv_sum_len -= 4;
proc_bytes += 4;
}
break;
case ISIS_SUBTLV_EXT_IS_REACH_TE_METRIC:
if (subtlv_len >= 3)
ND_PRINT(", %u", GET_BE_U_3(tptr));
break;
case ISIS_SUBTLV_EXT_IS_REACH_LINK_ATTRIBUTE:
if (subtlv_len == 2) {
ND_PRINT(", [ %s ] (0x%04x)",
bittok2str(isis_subtlv_link_attribute_values,
"Unknown",
GET_BE_U_2(tptr)),
GET_BE_U_2(tptr));
}
break;
case ISIS_SUBTLV_EXT_IS_REACH_LINK_PROTECTION_TYPE:
if (subtlv_len >= 2) {
ND_PRINT(", %s, Priority %u",
bittok2str(gmpls_link_prot_values, "none", GET_U_1(tptr)),
GET_U_1(tptr + 1));
}
break;
case ISIS_SUBTLV_SPB_METRIC:
if (subtlv_len >= 6) {
ND_PRINT(", LM: %u", GET_BE_U_3(tptr));
tptr += 3;
subtlv_len -= 3;
subtlv_sum_len -= 3;
proc_bytes += 3;
ND_PRINT(", P: %u", GET_U_1(tptr));
tptr++;
subtlv_len--;
subtlv_sum_len--;
proc_bytes++;
ND_PRINT(", P-ID: %u", GET_BE_U_2(tptr));
}
break;
case ISIS_SUBTLV_EXT_IS_REACH_INTF_SW_CAP_DESCR:
if (subtlv_len >= 36) {
gmpls_switch_cap = GET_U_1(tptr);
ND_PRINT("%s Interface Switching Capability:%s",
indent,
tok2str(gmpls_switch_cap_values, "Unknown", gmpls_switch_cap));
ND_PRINT(", LSP Encoding: %s",
tok2str(gmpls_encoding_values, "Unknown", GET_U_1((tptr + 1))));
tptr += 4;
subtlv_len -= 4;
subtlv_sum_len -= 4;
proc_bytes += 4;
ND_PRINT("%s Max LSP Bandwidth:", indent);
for (priority_level = 0; priority_level < 8; priority_level++) {
ND_PRINT("%s priority level %u: %.3f Mbps",
indent,
priority_level,
GET_BE_F_4(tptr) * 8 / 1000000);
tptr += 4;
subtlv_len -= 4;
subtlv_sum_len -= 4;
proc_bytes += 4;
}
switch (gmpls_switch_cap) {
case GMPLS_PSC1:
case GMPLS_PSC2:
case GMPLS_PSC3:
case GMPLS_PSC4:
if (subtlv_len < 6)
break;
ND_PRINT("%s Min LSP Bandwidth: %.3f Mbps",
indent,
GET_BE_F_4(tptr) * 8 / 1000000);
ND_PRINT("%s Interface MTU: %u", indent,
GET_BE_U_2(tptr + 4));
break;
case GMPLS_TSC:
if (subtlv_len < 8)
break;
ND_PRINT("%s Min LSP Bandwidth: %.3f Mbps", indent,
GET_BE_F_4(tptr) * 8 / 1000000);
ND_PRINT("%s Indication %s", indent,
tok2str(gmpls_switch_cap_tsc_indication_values, "Unknown (%u)", GET_U_1((tptr + 4))));
break;
default:
/* there is some optional stuff left to decode but this is as of yet
not specified so just lets hexdump what is left */
if (subtlv_len != 0) {
if (!print_unknown_data(ndo, tptr, "\n\t\t ", subtlv_len))
return(0);
}
}
}
break;
case ISIS_SUBTLV_EXT_IS_REACH_LAN_ADJ_SEGMENT_ID:
if (subtlv_len >= 8) {
ND_PRINT("%s Flags: [%s]", indent,
bittok2str(isis_lan_adj_sid_flag_values,
"none",
GET_U_1(tptr)));
int vflag = (GET_U_1(tptr) & 0x20) ? 1:0;
int lflag = (GET_U_1(tptr) & 0x10) ? 1:0;
tptr++;
subtlv_len--;
subtlv_sum_len--;
proc_bytes++;
ND_PRINT("%s Weight: %u", indent, GET_U_1(tptr));
tptr++;
subtlv_len--;
subtlv_sum_len--;
proc_bytes++;
if(subtlv_len>=SYSTEM_ID_LEN) {
ND_TCHECK_LEN(tptr, SYSTEM_ID_LEN);
ND_PRINT("%s Neighbor System-ID: %s", indent,
isis_print_id(ndo, tptr, SYSTEM_ID_LEN));
}
/* RFC 8667 section 2.2.2 */
/* if V-flag is set to 1 and L-flag is set to 1 ==> 3 octet label */
/* if V-flag is set to 0 and L-flag is set to 0 ==> 4 octet index */
if (vflag && lflag) {
ND_PRINT("%s Label: %u",
indent, GET_BE_U_3(tptr+SYSTEM_ID_LEN));
} else if ((!vflag) && (!lflag)) {
ND_PRINT("%s Index: %u",
indent, GET_BE_U_4(tptr+SYSTEM_ID_LEN));
} else
nd_print_invalid(ndo);
}
break;
default:
if (!print_unknown_data(ndo, tptr, "\n\t\t ", subtlv_len))
return(0);
break;
}
tptr += subtlv_len;
tlv_remaining -= subtlv_len;
subtlv_sum_len -= subtlv_len;
proc_bytes += subtlv_len;
}
}
return(proc_bytes);
trunc:
return(0);
}
/*
* this is the common Multi Topology ID decoder
* it is called from various MT-TLVs (222,229,235,237)
*/
static uint8_t
isis_print_mtid(netdissect_options *ndo,
const uint8_t *tptr, const char *indent, u_int tlv_remaining)
{
if (tlv_remaining < 2)
goto trunc;
ND_PRINT("%s%s",
indent,
tok2str(isis_mt_values,
"Reserved for IETF Consensus",
ISIS_MASK_MTID(GET_BE_U_2(tptr))));
ND_PRINT(" Topology (0x%03x), Flags: [%s]",
ISIS_MASK_MTID(GET_BE_U_2(tptr)),
bittok2str(isis_mt_flag_values, "none",ISIS_MASK_MTFLAGS(GET_BE_U_2(tptr))));
return(2);
trunc:
return 0;
}
/*
* this is the common extended IP reach decoder
* it is called from TLVs (135,235,236,237)
* we process the TLV and optional subTLVs and return
* the amount of processed bytes
*/
static u_int
isis_print_extd_ip_reach(netdissect_options *ndo,
const uint8_t *tptr, const char *indent, uint16_t afi)
{
char indent_buffer[20];
uint8_t prefix[sizeof(nd_ipv6)]; /* shared copy buffer for IPv4 and IPv6 prefixes */
u_int metric, status_byte, bit_length, byte_length, sublen, processed, subtlvtype, subtlvlen;
metric = GET_BE_U_4(tptr);
processed=4;
tptr+=4;
if (afi == AFNUM_IP) {
status_byte=GET_U_1(tptr);
tptr++;
bit_length = status_byte&0x3f;
if (bit_length > 32) {
ND_PRINT("%sIPv4 prefix: bad bit length %u",
indent,
bit_length);
return (0);
}
processed++;
} else if (afi == AFNUM_IP6) {
status_byte=GET_U_1(tptr);
bit_length=GET_U_1(tptr + 1);
if (bit_length > 128) {
ND_PRINT("%sIPv6 prefix: bad bit length %u",
indent,
bit_length);
return (0);
}
tptr+=2;
processed+=2;
} else
return (0); /* somebody is fooling us */
byte_length = (bit_length + 7) / 8; /* prefix has variable length encoding */
memset(prefix, 0, sizeof(prefix)); /* clear the copy buffer */
GET_CPY_BYTES(prefix,tptr,byte_length); /* copy as much as is stored in the TLV */
tptr+=byte_length;
processed+=byte_length;
if (afi == AFNUM_IP)
ND_PRINT("%sIPv4 prefix: %15s/%u",
indent,
ipaddr_string(ndo, prefix), /* local buffer, not packet data; don't use GET_IPADDR_STRING() */
bit_length);
else if (afi == AFNUM_IP6)
ND_PRINT("%sIPv6 prefix: %s/%u",
indent,
ip6addr_string(ndo, prefix), /* local buffer, not packet data; don't use GET_IP6ADDR_STRING() */
bit_length);
ND_PRINT(", Distribution: %s, Metric: %u",
ISIS_MASK_TLV_EXTD_IP_UPDOWN(status_byte) ? "down" : "up",
metric);
if (afi == AFNUM_IP && ISIS_MASK_TLV_EXTD_IP_SUBTLV(status_byte))
ND_PRINT(", sub-TLVs present");
else if (afi == AFNUM_IP6)
ND_PRINT(", %s%s",
ISIS_MASK_TLV_EXTD_IP6_IE(status_byte) ? "External" : "Internal",
ISIS_MASK_TLV_EXTD_IP6_SUBTLV(status_byte) ? ", sub-TLVs present" : "");
if ((afi == AFNUM_IP && ISIS_MASK_TLV_EXTD_IP_SUBTLV(status_byte))
|| (afi == AFNUM_IP6 && ISIS_MASK_TLV_EXTD_IP6_SUBTLV(status_byte))
) {
/* assume that one prefix can hold more
than one subTLV - therefore the first byte must reflect
the aggregate bytecount of the subTLVs for this prefix
*/
sublen=GET_U_1(tptr);
tptr++;
processed+=sublen+1;
ND_PRINT(" (%u)", sublen); /* print out subTLV length */
while (sublen != 0) {
subtlvtype=GET_U_1(tptr);
subtlvlen=GET_U_1(tptr + 1);
tptr+=2;
/* prepend the indent string */
snprintf(indent_buffer, sizeof(indent_buffer), "%s ", indent);
if (!isis_print_ip_reach_subtlv(ndo, tptr, subtlvtype, subtlvlen, indent_buffer))
return(0);
tptr+=subtlvlen;
sublen-=(subtlvlen+2);
}
}
return (processed);
}
static void
isis_print_router_cap_subtlv(netdissect_options *ndo, const uint8_t *tptr, uint8_t tlen)
{
uint8_t subt, subl;
while (tlen >= 2) {
subt = GET_U_1(tptr);
subl = GET_U_1(tptr+1);
tlen -= 2;
tptr += 2;
/* first lets see if we know the subTLVs name*/
ND_PRINT("\n\t\t%s subTLV #%u, length: %u",
tok2str(isis_router_capability_subtlv_values, "unknown", subt),
subt, subl);
/*
* Boundary check.
*/
if (subl > tlen) {
break;
}
ND_TCHECK_LEN(tptr, subl);
switch (subt) {
case ISIS_SUBTLV_ROUTER_CAP_SR:
{
uint8_t flags, sid_tlen, sid_type, sid_len;
uint32_t range;
const uint8_t *sid_ptr;
flags = GET_U_1(tptr);
range = GET_BE_U_3(tptr+1);
ND_PRINT(", Flags [%s], Range %u",
bittok2str(isis_router_capability_sr_flags, "None", flags),
range);
sid_ptr = tptr + 4;
sid_tlen = subl - 4;
while (sid_tlen >= 5) {
sid_type = GET_U_1(sid_ptr);
sid_len = GET_U_1(sid_ptr+1);
sid_tlen -= 2;
sid_ptr += 2;
/*
* Boundary check.
*/
if (sid_len > sid_tlen) {
break;
}
switch (sid_type) {
case 1:
if (sid_len == 3) {
ND_PRINT(", SID value %u", GET_BE_U_3(sid_ptr));
} else if (sid_len == 4) {
ND_PRINT(", SID value %u", GET_BE_U_4(sid_ptr));
} else {
ND_PRINT(", Unknown SID length%u", sid_len);
}
break;
default:
print_unknown_data(ndo, sid_ptr, "\n\t\t ", sid_len);
}
sid_ptr += sid_len;
sid_tlen -= sid_len;
}
}
break;
default:
print_unknown_data(ndo, tptr, "\n\t\t", subl);
break;
}
tlen -= subl;
tptr += subl;
}
trunc:
return;
}
/*
* Clear checksum and lifetime prior to signature verification.
*/
static void
isis_clear_checksum_lifetime(void *header)
{
struct isis_lsp_header *header_lsp = (struct isis_lsp_header *) header;
header_lsp->checksum[0] = 0;
header_lsp->checksum[1] = 0;
header_lsp->remaining_lifetime[0] = 0;
header_lsp->remaining_lifetime[1] = 0;
}
/*
* isis_print
* Decode IS-IS packets. Return 0 on error.
*/
#define INVALID_OR_DECREMENT(length,decr) \
if ((length) < (decr)) { \
ND_PRINT(" [packet length %u < %zu]", (length), (decr)); \
nd_print_invalid(ndo); \
return 1; \
} \
length -= (decr);
static int
isis_print(netdissect_options *ndo,
const uint8_t *p, u_int length)
{
const struct isis_common_header *isis_header;
const struct isis_iih_lan_header *header_iih_lan;
const struct isis_iih_ptp_header *header_iih_ptp;
const struct isis_lsp_header *header_lsp;
const struct isis_csnp_header *header_csnp;
const struct isis_psnp_header *header_psnp;
const struct isis_tlv_lsp *tlv_lsp;
const struct isis_tlv_ptp_adj *tlv_ptp_adj;
const struct isis_tlv_is_reach *tlv_is_reach;
const struct isis_tlv_es_reach *tlv_es_reach;
uint8_t version, pdu_version, fixed_len;
uint8_t pdu_type, pdu_max_area, max_area, pdu_id_length, id_length, tlv_type, tlv_len, tlen, alen, prefix_len;
u_int ext_is_len, ext_ip_len;
uint8_t mt_len;
uint8_t isis_subtlv_idrp;
const uint8_t *optr, *pptr, *tptr;
u_int packet_len;
u_short pdu_len, key_id;
u_int i,vendor_id, num_vals;
uint8_t auth_type;
uint8_t num_system_ids;
int sigcheck;
ndo->ndo_protocol = "isis";
packet_len=length;
optr = p; /* initialize the _o_riginal pointer to the packet start -
need it for parsing the checksum TLV and authentication
TLV verification */
isis_header = (const struct isis_common_header *)p;
ND_TCHECK_SIZE(isis_header);
if (length < ISIS_COMMON_HEADER_SIZE)
goto trunc;
pptr = p+(ISIS_COMMON_HEADER_SIZE);
header_iih_lan = (const struct isis_iih_lan_header *)pptr;
header_iih_ptp = (const struct isis_iih_ptp_header *)pptr;
header_lsp = (const struct isis_lsp_header *)pptr;
header_csnp = (const struct isis_csnp_header *)pptr;
header_psnp = (const struct isis_psnp_header *)pptr;
if (!ndo->ndo_eflag)
ND_PRINT("IS-IS");
/*
* Sanity checking of the header.
*/
version = GET_U_1(isis_header->version);
if (version != ISIS_VERSION) {
ND_PRINT("version %u packet not supported", version);
return (0);
}
pdu_id_length = GET_U_1(isis_header->id_length);
if ((pdu_id_length != SYSTEM_ID_LEN) && (pdu_id_length != 0)) {
ND_PRINT("system ID length of %u is not supported",
pdu_id_length);
return (0);
}
pdu_version = GET_U_1(isis_header->pdu_version);
if (pdu_version != ISIS_VERSION) {
ND_PRINT("version %u packet not supported", pdu_version);
return (0);
}
fixed_len = GET_U_1(isis_header->fixed_len);
if (length < fixed_len) {
ND_PRINT("fixed header length %u > packet length %u", fixed_len, length);
return (0);
}
if (fixed_len < ISIS_COMMON_HEADER_SIZE) {
ND_PRINT("fixed header length %u < minimum header size %u", fixed_len, (u_int)ISIS_COMMON_HEADER_SIZE);
return (0);
}
pdu_max_area = GET_U_1(isis_header->max_area);
switch(pdu_max_area) {
case 0:
max_area = 3; /* silly shit */
break;
case 255:
ND_PRINT("bad packet -- 255 areas");
return (0);
default:
max_area = pdu_max_area;
break;
}
switch(pdu_id_length) {
case 0:
id_length = 6; /* silly shit again */
break;
case 1: /* 1-8 are valid sys-ID lengths */
case 2:
case 3:
case 4:
case 5:
case 6:
case 7:
case 8:
id_length = pdu_id_length;
break;
case 255:
id_length = 0; /* entirely useless */
break;
default:
id_length = pdu_id_length;
break;
}
/* toss any non 6-byte sys-ID len PDUs */
if (id_length != 6 ) {
ND_PRINT("bad packet -- illegal sys-ID length (%u)", id_length);
return (0);
}
pdu_type = GET_U_1(isis_header->pdu_type);
/* in non-verbose mode print the basic PDU Type plus PDU specific brief information*/
if (ndo->ndo_vflag == 0) {
ND_PRINT("%s%s",
ndo->ndo_eflag ? "" : ", ",
tok2str(isis_pdu_values, "unknown PDU-Type %u", pdu_type));
} else {
/* ok they seem to want to know everything - lets fully decode it */
ND_PRINT("%slength %u", ndo->ndo_eflag ? "" : ", ", length);
ND_PRINT("\n\t%s, hlen: %u, v: %u, pdu-v: %u, sys-id-len: %u (%u), max-area: %u (%u)",
tok2str(isis_pdu_values,
"unknown, type %u",
pdu_type),
fixed_len,
version,
pdu_version,
id_length,
pdu_id_length,
max_area,
pdu_max_area);
if (ndo->ndo_vflag > 1) {
if (!print_unknown_data(ndo, optr, "\n\t", 8)) /* provide the _o_riginal pointer */
return (0); /* for optionally debugging the common header */
}
}
switch (pdu_type) {
case ISIS_PDU_L1_LAN_IIH:
case ISIS_PDU_L2_LAN_IIH:
if (fixed_len != (ISIS_COMMON_HEADER_SIZE+ISIS_IIH_LAN_HEADER_SIZE)) {
ND_PRINT(", bogus fixed header length %u should be %zu",
fixed_len, ISIS_COMMON_HEADER_SIZE+ISIS_IIH_LAN_HEADER_SIZE);
return (0);
}
ND_TCHECK_SIZE(header_iih_lan);
if (length < ISIS_COMMON_HEADER_SIZE+ISIS_IIH_LAN_HEADER_SIZE)
goto trunc;
if (ndo->ndo_vflag == 0) {
ND_PRINT(", src-id %s",
isis_print_id(ndo, header_iih_lan->source_id, SYSTEM_ID_LEN));
ND_PRINT(", lan-id %s, prio %u",
isis_print_id(ndo, header_iih_lan->lan_id,NODE_ID_LEN),
GET_U_1(header_iih_lan->priority));
ND_PRINT(", length %u", length);
return (1);
}
pdu_len=GET_BE_U_2(header_iih_lan->pdu_len);
if (packet_len>pdu_len) {
packet_len=pdu_len; /* do TLV decoding as long as it makes sense */
length=pdu_len;
}
ND_PRINT("\n\t source-id: %s, holding time: %us, Flags: [%s]",
isis_print_id(ndo, header_iih_lan->source_id,SYSTEM_ID_LEN),
GET_BE_U_2(header_iih_lan->holding_time),
tok2str(isis_iih_circuit_type_values,
"unknown circuit type 0x%02x",
GET_U_1(header_iih_lan->circuit_type)));
ND_PRINT("\n\t lan-id: %s, Priority: %u, PDU length: %u",
isis_print_id(ndo, header_iih_lan->lan_id, NODE_ID_LEN),
GET_U_1(header_iih_lan->priority) & ISIS_LAN_PRIORITY_MASK,
pdu_len);
if (ndo->ndo_vflag > 1) {
if (!print_unknown_data(ndo, pptr, "\n\t ", ISIS_IIH_LAN_HEADER_SIZE))
return (0);
}
INVALID_OR_DECREMENT(packet_len,ISIS_COMMON_HEADER_SIZE+ISIS_IIH_LAN_HEADER_SIZE);
pptr = p + (ISIS_COMMON_HEADER_SIZE+ISIS_IIH_LAN_HEADER_SIZE);
break;
case ISIS_PDU_PTP_IIH:
if (fixed_len != (ISIS_COMMON_HEADER_SIZE+ISIS_IIH_PTP_HEADER_SIZE)) {
ND_PRINT(", bogus fixed header length %u should be %zu",
fixed_len, ISIS_COMMON_HEADER_SIZE+ISIS_IIH_PTP_HEADER_SIZE);
return (0);
}
ND_TCHECK_SIZE(header_iih_ptp);
if (length < ISIS_COMMON_HEADER_SIZE+ISIS_IIH_PTP_HEADER_SIZE)
goto trunc;
if (ndo->ndo_vflag == 0) {
ND_PRINT(", src-id %s", isis_print_id(ndo, header_iih_ptp->source_id, SYSTEM_ID_LEN));
ND_PRINT(", length %u", length);
return (1);
}
pdu_len=GET_BE_U_2(header_iih_ptp->pdu_len);
if (packet_len>pdu_len) {
packet_len=pdu_len; /* do TLV decoding as long as it makes sense */
length=pdu_len;
}
ND_PRINT("\n\t source-id: %s, holding time: %us, Flags: [%s]",
isis_print_id(ndo, header_iih_ptp->source_id,SYSTEM_ID_LEN),
GET_BE_U_2(header_iih_ptp->holding_time),
tok2str(isis_iih_circuit_type_values,
"unknown circuit type 0x%02x",
GET_U_1(header_iih_ptp->circuit_type)));
ND_PRINT("\n\t circuit-id: 0x%02x, PDU length: %u",
GET_U_1(header_iih_ptp->circuit_id),
pdu_len);
if (ndo->ndo_vflag > 1) {
if (!print_unknown_data(ndo, pptr, "\n\t ", ISIS_IIH_PTP_HEADER_SIZE))
return (0);
}
INVALID_OR_DECREMENT(packet_len,ISIS_COMMON_HEADER_SIZE+ISIS_IIH_PTP_HEADER_SIZE);
pptr = p + (ISIS_COMMON_HEADER_SIZE+ISIS_IIH_PTP_HEADER_SIZE);
break;
case ISIS_PDU_L1_LSP:
case ISIS_PDU_L2_LSP:
if (fixed_len != (ISIS_COMMON_HEADER_SIZE+ISIS_LSP_HEADER_SIZE)) {
ND_PRINT(", bogus fixed header length %u should be %zu",
fixed_len, ISIS_LSP_HEADER_SIZE);
return (0);
}
ND_TCHECK_SIZE(header_lsp);
if (length < ISIS_COMMON_HEADER_SIZE+ISIS_LSP_HEADER_SIZE)
goto trunc;
if (ndo->ndo_vflag == 0) {
ND_PRINT(", lsp-id %s, seq 0x%08x, lifetime %5us",
isis_print_id(ndo, header_lsp->lsp_id, LSP_ID_LEN),
GET_BE_U_4(header_lsp->sequence_number),
GET_BE_U_2(header_lsp->remaining_lifetime));
ND_PRINT(", length %u", length);
return (1);
}
pdu_len=GET_BE_U_2(header_lsp->pdu_len);
if (packet_len>pdu_len) {
packet_len=pdu_len; /* do TLV decoding as long as it makes sense */
length=pdu_len;
}
ND_PRINT("\n\t lsp-id: %s, seq: 0x%08x, lifetime: %5us\n\t chksum: 0x%04x",
isis_print_id(ndo, header_lsp->lsp_id, LSP_ID_LEN),
GET_BE_U_4(header_lsp->sequence_number),
GET_BE_U_2(header_lsp->remaining_lifetime),
GET_BE_U_2(header_lsp->checksum));
osi_print_cksum(ndo, (const uint8_t *)header_lsp->lsp_id,
GET_BE_U_2(header_lsp->checksum),
12, length-12);
ND_PRINT(", PDU length: %u, Flags: [ %s",
pdu_len,
ISIS_MASK_LSP_OL_BIT(header_lsp->typeblock) ? "Overload bit set, " : "");
if (ISIS_MASK_LSP_ATT_BITS(header_lsp->typeblock)) {
ND_PRINT("%s", ISIS_MASK_LSP_ATT_DEFAULT_BIT(header_lsp->typeblock) ? "default " : "");
ND_PRINT("%s", ISIS_MASK_LSP_ATT_DELAY_BIT(header_lsp->typeblock) ? "delay " : "");
ND_PRINT("%s", ISIS_MASK_LSP_ATT_EXPENSE_BIT(header_lsp->typeblock) ? "expense " : "");
ND_PRINT("%s", ISIS_MASK_LSP_ATT_ERROR_BIT(header_lsp->typeblock) ? "error " : "");
ND_PRINT("ATT bit set, ");
}
ND_PRINT("%s", ISIS_MASK_LSP_PARTITION_BIT(header_lsp->typeblock) ? "P bit set, " : "");
ND_PRINT("%s ]", tok2str(isis_lsp_istype_values, "Unknown(0x%x)",
ISIS_MASK_LSP_ISTYPE_BITS(header_lsp->typeblock)));
if (ndo->ndo_vflag > 1) {
if (!print_unknown_data(ndo, pptr, "\n\t ", ISIS_LSP_HEADER_SIZE))
return (0);
}
INVALID_OR_DECREMENT(packet_len,ISIS_COMMON_HEADER_SIZE+ISIS_LSP_HEADER_SIZE);
pptr = p + (ISIS_COMMON_HEADER_SIZE+ISIS_LSP_HEADER_SIZE);
break;
case ISIS_PDU_L1_CSNP:
case ISIS_PDU_L2_CSNP:
if (fixed_len != (ISIS_COMMON_HEADER_SIZE+ISIS_CSNP_HEADER_SIZE)) {
ND_PRINT(", bogus fixed header length %u should be %zu",
fixed_len, ISIS_COMMON_HEADER_SIZE+ISIS_CSNP_HEADER_SIZE);
return (0);
}
ND_TCHECK_SIZE(header_csnp);
if (length < ISIS_COMMON_HEADER_SIZE+ISIS_CSNP_HEADER_SIZE)
goto trunc;
if (ndo->ndo_vflag == 0) {
ND_PRINT(", src-id %s", isis_print_id(ndo, header_csnp->source_id, NODE_ID_LEN));
ND_PRINT(", length %u", length);
return (1);
}
pdu_len=GET_BE_U_2(header_csnp->pdu_len);
if (packet_len>pdu_len) {
packet_len=pdu_len; /* do TLV decoding as long as it makes sense */
length=pdu_len;
}
ND_PRINT("\n\t source-id: %s, PDU length: %u",
isis_print_id(ndo, header_csnp->source_id, NODE_ID_LEN),
pdu_len);
ND_PRINT("\n\t start lsp-id: %s",
isis_print_id(ndo, header_csnp->start_lsp_id, LSP_ID_LEN));
ND_PRINT("\n\t end lsp-id: %s",
isis_print_id(ndo, header_csnp->end_lsp_id, LSP_ID_LEN));
if (ndo->ndo_vflag > 1) {
if (!print_unknown_data(ndo, pptr, "\n\t ", ISIS_CSNP_HEADER_SIZE))
return (0);
}
INVALID_OR_DECREMENT(packet_len,ISIS_COMMON_HEADER_SIZE+ISIS_CSNP_HEADER_SIZE);
pptr = p + (ISIS_COMMON_HEADER_SIZE+ISIS_CSNP_HEADER_SIZE);
break;
case ISIS_PDU_L1_PSNP:
case ISIS_PDU_L2_PSNP:
if (fixed_len != (ISIS_COMMON_HEADER_SIZE+ISIS_PSNP_HEADER_SIZE)) {
ND_PRINT("- bogus fixed header length %u should be %zu",
fixed_len, ISIS_COMMON_HEADER_SIZE+ISIS_PSNP_HEADER_SIZE);
return (0);
}
ND_TCHECK_SIZE(header_psnp);
if (length < ISIS_COMMON_HEADER_SIZE+ISIS_PSNP_HEADER_SIZE)
goto trunc;
if (ndo->ndo_vflag == 0) {
ND_PRINT(", src-id %s", isis_print_id(ndo, header_psnp->source_id, NODE_ID_LEN));
ND_PRINT(", length %u", length);
return (1);
}
pdu_len=GET_BE_U_2(header_psnp->pdu_len);
if (packet_len>pdu_len) {
packet_len=pdu_len; /* do TLV decoding as long as it makes sense */
length=pdu_len;
}
ND_PRINT("\n\t source-id: %s, PDU length: %u",
isis_print_id(ndo, header_psnp->source_id, NODE_ID_LEN),
pdu_len);
if (ndo->ndo_vflag > 1) {
if (!print_unknown_data(ndo, pptr, "\n\t ", ISIS_PSNP_HEADER_SIZE))
return (0);
}
INVALID_OR_DECREMENT(packet_len,ISIS_COMMON_HEADER_SIZE+ISIS_PSNP_HEADER_SIZE);
pptr = p + (ISIS_COMMON_HEADER_SIZE+ISIS_PSNP_HEADER_SIZE);
break;
default:
if (ndo->ndo_vflag == 0) {
ND_PRINT(", length %u", length);
return (1);
}
(void)print_unknown_data(ndo, pptr, "\n\t ", length);
return (0);
}
/*
* Now print the TLV's.
*/
while (packet_len != 0) {
ND_TCHECK_2(pptr);
if (packet_len < 2)
goto trunc;
tlv_type = GET_U_1(pptr);
tlv_len = GET_U_1(pptr + 1);
pptr += 2;
packet_len -= 2;
tlen = tlv_len; /* copy temporary len & pointer to packet data */
tptr = pptr;
/* first lets see if we know the TLVs name*/
ND_PRINT("\n\t %s TLV #%u, length: %u",
tok2str(isis_tlv_values,
"unknown",
tlv_type),
tlv_type,
tlv_len);
if (packet_len < tlv_len)
goto trunc;
/* now check if we have a decoder otherwise do a hexdump at the end*/
switch (tlv_type) {
case ISIS_TLV_AREA_ADDR:
while (tlen != 0) {
alen = GET_U_1(tptr);
tptr++;
tlen--;
if (tlen < alen)
goto tlv_trunc;
ND_PRINT("\n\t Area address (length: %u): %s",
alen,
GET_ISONSAP_STRING(tptr, alen));
tptr += alen;
tlen -= alen;
}
break;
case ISIS_TLV_ISNEIGH:
while (tlen != 0) {
if (tlen < MAC48_LEN)
goto tlv_trunc;
ND_TCHECK_LEN(tptr, MAC48_LEN);
ND_PRINT("\n\t SNPA: %s", isis_print_id(ndo, tptr, MAC48_LEN));
tlen -= MAC48_LEN;
tptr += MAC48_LEN;
}
break;
case ISIS_TLV_INSTANCE_ID:
if (tlen < 4)
goto tlv_trunc;
num_vals = (tlen-2)/2;
ND_PRINT("\n\t Instance ID: %u, ITIDs(%u)%s ",
GET_BE_U_2(tptr), num_vals,
num_vals ? ":" : "");
tptr += 2;
tlen -= 2;
for (i=0; i < num_vals; i++) {
ND_PRINT("%u", GET_BE_U_2(tptr));
if (i < (num_vals - 1)) {
ND_PRINT(", ");
}
tptr += 2;
tlen -= 2;
}
break;
case ISIS_TLV_PADDING:
break;
case ISIS_TLV_MT_IS_REACH:
mt_len = isis_print_mtid(ndo, tptr, "\n\t ", tlen);
if (mt_len == 0) /* did something go wrong ? */
goto trunc;
tptr+=mt_len;
tlen-=mt_len;
while (tlen != 0) {
ext_is_len = isis_print_ext_is_reach(ndo, tptr, "\n\t ", tlv_type, tlen);
if (ext_is_len == 0) /* did something go wrong ? */
goto trunc;
if (tlen < ext_is_len) {
ND_PRINT(" [remaining tlv length %u < %u]", tlen, ext_is_len);
nd_print_invalid(ndo);
break;
}
tlen-=(uint8_t)ext_is_len;
tptr+=(uint8_t)ext_is_len;
}
break;
case ISIS_TLV_IS_ALIAS_ID:
while (tlen != 0) {
ext_is_len = isis_print_ext_is_reach(ndo, tptr, "\n\t ", tlv_type, tlen);
if (ext_is_len == 0) /* did something go wrong ? */
goto trunc;
if (tlen < ext_is_len) {
ND_PRINT(" [remaining tlv length %u < %u]", tlen, ext_is_len);
nd_print_invalid(ndo);
break;
}
tlen-=(uint8_t)ext_is_len;
tptr+=(uint8_t)ext_is_len;
}
break;
case ISIS_TLV_EXT_IS_REACH:
while (tlen != 0) {
ext_is_len = isis_print_ext_is_reach(ndo, tptr, "\n\t ", tlv_type, tlen);
if (ext_is_len == 0) /* did something go wrong ? */
goto trunc;
if (tlen < ext_is_len) {
ND_PRINT(" [remaining tlv length %u < %u]", tlen, ext_is_len);
nd_print_invalid(ndo);
break;
}
tlen-=(uint8_t)ext_is_len;
tptr+=(uint8_t)ext_is_len;
}
break;
case ISIS_TLV_IS_REACH:
if (tlen < 1)
goto tlv_trunc;
ND_PRINT("\n\t %s",
tok2str(isis_is_reach_virtual_values,
"bogus virtual flag 0x%02x",
GET_U_1(tptr)));
tptr++;
tlen--;
tlv_is_reach = (const struct isis_tlv_is_reach *)tptr;
while (tlen != 0) {
if (tlen < sizeof(struct isis_tlv_is_reach))
goto tlv_trunc;
ND_TCHECK_SIZE(tlv_is_reach);
ND_PRINT("\n\t IS Neighbor: %s",
isis_print_id(ndo, tlv_is_reach->neighbor_nodeid, NODE_ID_LEN));
isis_print_metric_block(ndo, &tlv_is_reach->isis_metric_block);
tlen -= sizeof(struct isis_tlv_is_reach);
tlv_is_reach++;
}
break;
case ISIS_TLV_ESNEIGH:
tlv_es_reach = (const struct isis_tlv_es_reach *)tptr;
while (tlen != 0) {
if (tlen < sizeof(struct isis_tlv_es_reach))
goto tlv_trunc;
ND_TCHECK_SIZE(tlv_es_reach);
ND_PRINT("\n\t ES Neighbor: %s",
isis_print_id(ndo, tlv_es_reach->neighbor_sysid, SYSTEM_ID_LEN));
isis_print_metric_block(ndo, &tlv_es_reach->isis_metric_block);
tlen -= sizeof(struct isis_tlv_es_reach);
tlv_es_reach++;
}
break;
/* those two TLVs share the same format */
case ISIS_TLV_INT_IP_REACH:
case ISIS_TLV_EXT_IP_REACH:
if (!isis_print_tlv_ip_reach(ndo, pptr, "\n\t ", tlv_len))
return (1);
break;
case ISIS_TLV_EXTD_IP_REACH:
while (tlen != 0) {
ext_ip_len = isis_print_extd_ip_reach(ndo, tptr, "\n\t ", AFNUM_IP);
if (ext_ip_len == 0) /* did something go wrong ? */
goto trunc;
if (tlen < ext_ip_len) {
ND_PRINT(" [remaining tlv length %u < %u]", tlen, ext_ip_len);
nd_print_invalid(ndo);
break;
}
tlen-=(uint8_t)ext_ip_len;
tptr+=(uint8_t)ext_ip_len;
}
break;
case ISIS_TLV_MT_IP_REACH:
mt_len = isis_print_mtid(ndo, tptr, "\n\t ", tlen);
if (mt_len == 0) { /* did something go wrong ? */
goto trunc;
}
tptr+=mt_len;
tlen-=mt_len;
while (tlen != 0) {
ext_ip_len = isis_print_extd_ip_reach(ndo, tptr, "\n\t ", AFNUM_IP);
if (ext_ip_len == 0) /* did something go wrong ? */
goto trunc;
if (tlen < ext_ip_len) {
ND_PRINT(" [remaining tlv length %u < %u]", tlen, ext_ip_len);
nd_print_invalid(ndo);
break;
}
tlen-=(uint8_t)ext_ip_len;
tptr+=(uint8_t)ext_ip_len;
}
break;
case ISIS_TLV_IP6_REACH:
while (tlen != 0) {
ext_ip_len = isis_print_extd_ip_reach(ndo, tptr, "\n\t ", AFNUM_IP6);
if (ext_ip_len == 0) /* did something go wrong ? */
goto trunc;
if (tlen < ext_ip_len) {
ND_PRINT(" [remaining tlv length %u < %u]", tlen, ext_ip_len);
nd_print_invalid(ndo);
break;
}
tlen-=(uint8_t)ext_ip_len;
tptr+=(uint8_t)ext_ip_len;
}
break;
case ISIS_TLV_MT_IP6_REACH:
mt_len = isis_print_mtid(ndo, tptr, "\n\t ", tlen);
if (mt_len == 0) { /* did something go wrong ? */
goto trunc;
}
tptr+=mt_len;
tlen-=mt_len;
while (tlen != 0) {
ext_ip_len = isis_print_extd_ip_reach(ndo, tptr, "\n\t ", AFNUM_IP6);
if (ext_ip_len == 0) /* did something go wrong ? */
goto trunc;
if (tlen < ext_ip_len) {
ND_PRINT(" [remaining tlv length %u < %u]", tlen, ext_ip_len);
nd_print_invalid(ndo);
break;
}
tlen-=(uint8_t)ext_ip_len;
tptr+=(uint8_t)ext_ip_len;
}
break;
case ISIS_TLV_IP6ADDR:
while (tlen != 0) {
if (tlen < sizeof(nd_ipv6))
goto tlv_trunc;
ND_PRINT("\n\t IPv6 interface address: %s",
GET_IP6ADDR_STRING(tptr));
tptr += sizeof(nd_ipv6);
tlen -= sizeof(nd_ipv6);
}
break;
case ISIS_TLV_AUTH:
if (tlen < 1)
goto tlv_trunc;
auth_type = GET_U_1(tptr);
tptr++;
tlen--;
ND_PRINT("\n\t %s: ",
tok2str(isis_subtlv_auth_values,
"unknown Authentication type 0x%02x",
auth_type));
switch (auth_type) {
case ISIS_SUBTLV_AUTH_SIMPLE:
nd_printjnp(ndo, tptr, tlen);
break;
case ISIS_SUBTLV_AUTH_MD5:
for(i=0;i<tlen;i++) {
ND_PRINT("%02x", GET_U_1(tptr + i));
}
if (tlen != ISIS_SUBTLV_AUTH_MD5_LEN)
ND_PRINT(", (invalid subTLV) ");
sigcheck = signature_verify(ndo, optr, length, tptr,
isis_clear_checksum_lifetime,
header_lsp);
ND_PRINT(" (%s)", tok2str(signature_check_values, "Unknown", sigcheck));
break;
case ISIS_SUBTLV_AUTH_GENERIC:
if (tlen < 2)
goto tlv_trunc;
key_id = GET_BE_U_2(tptr);
ND_PRINT("%u, password: ", key_id);
tptr += 2;
tlen -= 2;
for(i=0;i<tlen;i++) {
ND_PRINT("%02x", GET_U_1(tptr + i));
}
break;
case ISIS_SUBTLV_AUTH_PRIVATE:
default:
if (!print_unknown_data(ndo, tptr, "\n\t\t ", tlen))
return(0);
break;
}
break;
case ISIS_TLV_PTP_ADJ:
tlv_ptp_adj = (const struct isis_tlv_ptp_adj *)tptr;
if(tlen>=1) {
ND_PRINT("\n\t Adjacency State: %s (%u)",
tok2str(isis_ptp_adjacency_values, "unknown", GET_U_1(tptr)),
GET_U_1(tptr));
tlen--;
}
if(tlen>sizeof(tlv_ptp_adj->extd_local_circuit_id)) {
ND_PRINT("\n\t Extended Local circuit-ID: 0x%08x",
GET_BE_U_4(tlv_ptp_adj->extd_local_circuit_id));
tlen-=sizeof(tlv_ptp_adj->extd_local_circuit_id);
}
if(tlen>=SYSTEM_ID_LEN) {
ND_TCHECK_LEN(tlv_ptp_adj->neighbor_sysid, SYSTEM_ID_LEN);
ND_PRINT("\n\t Neighbor System-ID: %s",
isis_print_id(ndo, tlv_ptp_adj->neighbor_sysid, SYSTEM_ID_LEN));
tlen-=SYSTEM_ID_LEN;
}
if(tlen>=sizeof(tlv_ptp_adj->neighbor_extd_local_circuit_id)) {
ND_PRINT("\n\t Neighbor Extended Local circuit-ID: 0x%08x",
GET_BE_U_4(tlv_ptp_adj->neighbor_extd_local_circuit_id));
}
break;
case ISIS_TLV_PROTOCOLS:
ND_PRINT("\n\t NLPID(s): ");
while (tlen != 0) {
ND_PRINT("%s (0x%02x)",
tok2str(nlpid_values,
"unknown",
GET_U_1(tptr)),
GET_U_1(tptr));
if (tlen>1) /* further NPLIDs ? - put comma */
ND_PRINT(", ");
tptr++;
tlen--;
}
break;
case ISIS_TLV_MT_PORT_CAP:
{
if (tlen < 2)
goto tlv_trunc;
ND_PRINT("\n\t RES: %u, MTID(s): %u",
(GET_BE_U_2(tptr) >> 12),
(GET_BE_U_2(tptr) & 0x0fff));
tptr += 2;
tlen -= 2;
if (tlen)
isis_print_mt_port_cap_subtlv(ndo, tptr, tlen);
break;
}
case ISIS_TLV_MT_CAPABILITY:
if (tlen < 2)
goto tlv_trunc;
ND_PRINT("\n\t O: %u, RES: %u, MTID(s): %u",
(GET_BE_U_2(tptr) >> 15) & 0x01,
(GET_BE_U_2(tptr) >> 12) & 0x07,
GET_BE_U_2(tptr) & 0x0fff);
tptr += 2;
tlen -= 2;
if (tlen)
isis_print_mt_capability_subtlv(ndo, tptr, tlen);
break;
case ISIS_TLV_TE_ROUTER_ID:
if (tlen < sizeof(nd_ipv4))
goto tlv_trunc;
ND_PRINT("\n\t Traffic Engineering Router ID: %s", GET_IPADDR_STRING(pptr));
break;
case ISIS_TLV_IPADDR:
while (tlen != 0) {
if (tlen < sizeof(nd_ipv4))
goto tlv_trunc;
ND_PRINT("\n\t IPv4 interface address: %s", GET_IPADDR_STRING(tptr));
tptr += sizeof(nd_ipv4);
tlen -= sizeof(nd_ipv4);
}
break;
case ISIS_TLV_HOSTNAME:
ND_PRINT("\n\t Hostname: ");
nd_printjnp(ndo, tptr, tlen);
break;
case ISIS_TLV_SHARED_RISK_GROUP:
if (tlen < NODE_ID_LEN)
break;
ND_TCHECK_LEN(tptr, NODE_ID_LEN);
ND_PRINT("\n\t IS Neighbor: %s", isis_print_id(ndo, tptr, NODE_ID_LEN));
tptr+=NODE_ID_LEN;
tlen-=NODE_ID_LEN;
if (tlen < 1)
break;
ND_PRINT(", Flags: [%s]",
ISIS_MASK_TLV_SHARED_RISK_GROUP(GET_U_1(tptr)) ? "numbered" : "unnumbered");
tptr++;
tlen--;
if (tlen < sizeof(nd_ipv4))
break;
ND_PRINT("\n\t IPv4 interface address: %s", GET_IPADDR_STRING(tptr));
tptr+=sizeof(nd_ipv4);
tlen-=sizeof(nd_ipv4);
if (tlen < sizeof(nd_ipv4))
break;
ND_PRINT("\n\t IPv4 neighbor address: %s", GET_IPADDR_STRING(tptr));
tptr+=sizeof(nd_ipv4);
tlen-=sizeof(nd_ipv4);
while (tlen != 0) {
if (tlen < 4)
goto tlv_trunc;
ND_PRINT("\n\t Link-ID: 0x%08x", GET_BE_U_4(tptr));
tptr+=4;
tlen-=4;
}
break;
case ISIS_TLV_LSP:
tlv_lsp = (const struct isis_tlv_lsp *)tptr;
while (tlen != 0) {
if (tlen < sizeof(struct isis_tlv_lsp))
goto tlv_trunc;
ND_TCHECK_1(tlv_lsp->lsp_id + LSP_ID_LEN - 1);
ND_PRINT("\n\t lsp-id: %s",
isis_print_id(ndo, tlv_lsp->lsp_id, LSP_ID_LEN));
ND_PRINT(", seq: 0x%08x",
GET_BE_U_4(tlv_lsp->sequence_number));
ND_PRINT(", lifetime: %5ds",
GET_BE_U_2(tlv_lsp->remaining_lifetime));
ND_PRINT(", chksum: 0x%04x", GET_BE_U_2(tlv_lsp->checksum));
tlen-=sizeof(struct isis_tlv_lsp);
tlv_lsp++;
}
break;
case ISIS_TLV_CHECKSUM:
if (tlen < ISIS_TLV_CHECKSUM_MINLEN)
break;
ND_TCHECK_LEN(tptr, ISIS_TLV_CHECKSUM_MINLEN);
ND_PRINT("\n\t checksum: 0x%04x ", GET_BE_U_2(tptr));
/* do not attempt to verify the checksum if it is zero
* most likely a HMAC-MD5 TLV is also present and
* to avoid conflicts the checksum TLV is zeroed.
* see rfc3358 for details
*/
osi_print_cksum(ndo, optr, GET_BE_U_2(tptr), (int)(tptr-optr),
length);
break;
case ISIS_TLV_POI:
if (tlen < 1)
goto tlv_trunc;
num_system_ids = GET_U_1(tptr);
tptr++;
tlen--;
if (num_system_ids == 0) {
/* Not valid */
ND_PRINT(" No system IDs supplied");
} else {
if (tlen < SYSTEM_ID_LEN)
goto tlv_trunc;
ND_TCHECK_LEN(tptr, SYSTEM_ID_LEN);
ND_PRINT("\n\t Purge Originator System-ID: %s",
isis_print_id(ndo, tptr, SYSTEM_ID_LEN));
tptr += SYSTEM_ID_LEN;
tlen -= SYSTEM_ID_LEN;
if (num_system_ids > 1) {
if (tlen < SYSTEM_ID_LEN)
goto tlv_trunc;
ND_TCHECK_LEN(tptr, SYSTEM_ID_LEN);
ND_TCHECK_LEN(tptr, 2 * SYSTEM_ID_LEN + 1);
ND_PRINT("\n\t Received from System-ID: %s",
isis_print_id(ndo, tptr, SYSTEM_ID_LEN));
}
}
break;
case ISIS_TLV_MT_SUPPORTED:
while (tlen != 0) {
/* length can only be a multiple of 2, otherwise there is
something broken -> so decode down until length is 1 */
if (tlen!=1) {
mt_len = isis_print_mtid(ndo, tptr, "\n\t ", tlen);
if (mt_len == 0) /* did something go wrong ? */
goto trunc;
tptr+=mt_len;
tlen-=mt_len;
} else {
ND_PRINT("\n\t invalid MT-ID");
break;
}
}
break;
case ISIS_TLV_RESTART_SIGNALING:
/* first attempt to decode the flags */
if (tlen < ISIS_TLV_RESTART_SIGNALING_FLAGLEN)
break;
ND_TCHECK_LEN(tptr, ISIS_TLV_RESTART_SIGNALING_FLAGLEN);
ND_PRINT("\n\t Flags [%s]",
bittok2str(isis_restart_flag_values, "none", GET_U_1(tptr)));
tptr+=ISIS_TLV_RESTART_SIGNALING_FLAGLEN;
tlen-=ISIS_TLV_RESTART_SIGNALING_FLAGLEN;
/* is there anything other than the flags field? */
if (tlen == 0)
break;
if (tlen < ISIS_TLV_RESTART_SIGNALING_HOLDTIMELEN)
break;
ND_TCHECK_LEN(tptr, ISIS_TLV_RESTART_SIGNALING_HOLDTIMELEN);
ND_PRINT(", Remaining holding time %us", GET_BE_U_2(tptr));
tptr+=ISIS_TLV_RESTART_SIGNALING_HOLDTIMELEN;
tlen-=ISIS_TLV_RESTART_SIGNALING_HOLDTIMELEN;
/* is there an additional sysid field present ?*/
if (tlen == SYSTEM_ID_LEN) {
ND_TCHECK_LEN(tptr, SYSTEM_ID_LEN);
ND_PRINT(", for %s", isis_print_id(ndo, tptr,SYSTEM_ID_LEN));
}
break;
case ISIS_TLV_IDRP_INFO:
if (tlen < 1)
break;
isis_subtlv_idrp = GET_U_1(tptr);
ND_PRINT("\n\t Inter-Domain Information Type: %s",
tok2str(isis_subtlv_idrp_values,
"Unknown (0x%02x)",
isis_subtlv_idrp));
tptr++;
tlen--;
switch (isis_subtlv_idrp) {
case ISIS_SUBTLV_IDRP_ASN:
if (tlen < 2)
goto tlv_trunc;
ND_PRINT("AS Number: %u", GET_BE_U_2(tptr));
break;
case ISIS_SUBTLV_IDRP_LOCAL:
case ISIS_SUBTLV_IDRP_RES:
default:
if (!print_unknown_data(ndo, tptr, "\n\t ", tlen))
return(0);
break;
}
break;
case ISIS_TLV_LSP_BUFFERSIZE:
if (tlen < 2)
break;
ND_PRINT("\n\t LSP Buffersize: %u", GET_BE_U_2(tptr));
break;
case ISIS_TLV_PART_DIS:
while (tlen != 0) {
if (tlen < SYSTEM_ID_LEN)
goto tlv_trunc;
ND_TCHECK_LEN(tptr, SYSTEM_ID_LEN);
ND_PRINT("\n\t %s", isis_print_id(ndo, tptr, SYSTEM_ID_LEN));
tptr+=SYSTEM_ID_LEN;
tlen-=SYSTEM_ID_LEN;
}
break;
case ISIS_TLV_PREFIX_NEIGH:
if (tlen < sizeof(struct isis_metric_block))
break;
ND_TCHECK_LEN(tptr, sizeof(struct isis_metric_block));
ND_PRINT("\n\t Metric Block");
isis_print_metric_block(ndo, (const struct isis_metric_block *)tptr);
tptr+=sizeof(struct isis_metric_block);
tlen-=sizeof(struct isis_metric_block);
while (tlen != 0) {
prefix_len=GET_U_1(tptr); /* read out prefix length in semioctets*/
tptr++;
tlen--;
if (prefix_len < 2) {
ND_PRINT("\n\t\tAddress: prefix length %u < 2", prefix_len);
break;
}
if (tlen < prefix_len/2)
break;
ND_PRINT("\n\t\tAddress: %s/%u",
GET_ISONSAP_STRING(tptr, prefix_len / 2), prefix_len * 4);
tptr+=prefix_len/2;
tlen-=prefix_len/2;
}
break;
case ISIS_TLV_IIH_SEQNR:
if (tlen < 4)
break;
ND_PRINT("\n\t Sequence number: %u", GET_BE_U_4(tptr));
break;
case ISIS_TLV_ROUTER_CAPABILITY:
if (tlen < 5) {
ND_PRINT(" [object length %u < 5]", tlen);
nd_print_invalid(ndo);
break;
}
ND_PRINT("\n\t Router-ID %s", GET_IPADDR_STRING(tptr));
ND_PRINT(", Flags [%s]",
bittok2str(isis_tlv_router_capability_flags, "none", GET_U_1(tptr+4)));
/* Optional set of sub-TLV */
if (tlen > 5) {
isis_print_router_cap_subtlv(ndo, tptr+5, tlen-5);
}
break;
case ISIS_TLV_VENDOR_PRIVATE:
if (tlen < 3)
break;
vendor_id = GET_BE_U_3(tptr);
ND_PRINT("\n\t Vendor: %s (%u)",
tok2str(oui_values, "Unknown", vendor_id),
vendor_id);
tptr+=3;
tlen-=3;
if (tlen != 0) /* hexdump the rest */
if (!print_unknown_data(ndo, tptr, "\n\t\t", tlen))
return(0);
break;
/*
* FIXME those are the defined TLVs that lack a decoder
* you are welcome to contribute code ;-)
*/
case ISIS_TLV_DECNET_PHASE4:
case ISIS_TLV_LUCENT_PRIVATE:
case ISIS_TLV_IPAUTH:
case ISIS_TLV_NORTEL_PRIVATE1:
case ISIS_TLV_NORTEL_PRIVATE2:
default:
if (ndo->ndo_vflag <= 1) {
if (!print_unknown_data(ndo, pptr, "\n\t\t", tlv_len))
return(0);
}
break;
}
tlv_trunc:
/* do we want to see an additionally hexdump ? */
if (ndo->ndo_vflag> 1) {
if (!print_unknown_data(ndo, pptr, "\n\t ", tlv_len))
return(0);
}
pptr += tlv_len;
packet_len -= tlv_len;
}
if (packet_len != 0) {
ND_PRINT("\n\t %u straggler bytes", packet_len);
}
return (1);
trunc:
nd_print_trunc(ndo);
return (1);
}
static void
osi_print_cksum(netdissect_options *ndo, const uint8_t *pptr,
uint16_t checksum, int checksum_offset, u_int length)
{
uint16_t calculated_checksum;
/* do not attempt to verify the checksum if it is zero,
* if the offset is nonsense,
* or the base pointer is not sane
*/
if (!checksum
|| checksum_offset < 0
|| !ND_TTEST_2(pptr + checksum_offset)
|| (u_int)checksum_offset > length
|| !ND_TTEST_LEN(pptr, length)) {
ND_PRINT(" (unverified)");
} else {
#if 0
ND_PRINT("\nosi_print_cksum: %p %d %u\n", pptr, checksum_offset, length);
#endif
calculated_checksum = create_osi_cksum(pptr, checksum_offset, length);
if (checksum == calculated_checksum) {
ND_PRINT(" (correct)");
} else {
ND_PRINT(" (incorrect should be 0x%04x)", calculated_checksum);
}
}
}