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/*
* Copyright (c) 1992, 1993, 1994, 1995, 1996, 1997
* 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.
*
* OSPF support contributed by Jeffrey Honig (jch@mitchell.cit.cornell.edu)
*/
/* \summary: Open Shortest Path First (OSPF) printer */
#include <config.h>
#include "netdissect-stdinc.h"
#include "netdissect.h"
#include "addrtoname.h"
#include "extract.h"
#include "gmpls.h"
#include "ospf.h"
static const struct tok ospf_option_values[] = {
{ OSPF_OPTION_MT, "MultiTopology" }, /* draft-ietf-ospf-mt-09 */
{ OSPF_OPTION_E, "External" },
{ OSPF_OPTION_MC, "Multicast" },
{ OSPF_OPTION_NP, "NSSA" },
{ OSPF_OPTION_L, "LLS" },
{ OSPF_OPTION_DC, "Demand Circuit" },
{ OSPF_OPTION_O, "Opaque" },
{ OSPF_OPTION_DN, "Up/Down" },
{ 0, NULL }
};
static const struct tok ospf_authtype_values[] = {
{ OSPF_AUTH_NONE, "none" },
{ OSPF_AUTH_SIMPLE, "simple" },
{ OSPF_AUTH_MD5, "MD5" },
{ 0, NULL }
};
static const struct tok ospf_rla_flag_values[] = {
{ RLA_FLAG_B, "ABR" },
{ RLA_FLAG_E, "ASBR" },
{ RLA_FLAG_V, "Virtual" },
{ RLA_FLAG_W, "Wildcard" },
{ RLA_FLAG_NT, "Nt" },
{ RLA_FLAG_H, "Host" },
{ 0, NULL }
};
static const struct tok type2str[] = {
{ OSPF_TYPE_HELLO, "Hello" },
{ OSPF_TYPE_DD, "Database Description" },
{ OSPF_TYPE_LS_REQ, "LS-Request" },
{ OSPF_TYPE_LS_UPDATE, "LS-Update" },
{ OSPF_TYPE_LS_ACK, "LS-Ack" },
{ 0, NULL }
};
static const struct tok lsa_values[] = {
{ LS_TYPE_ROUTER, "Router" },
{ LS_TYPE_NETWORK, "Network" },
{ LS_TYPE_SUM_IP, "Summary" },
{ LS_TYPE_SUM_ABR, "ASBR Summary" },
{ LS_TYPE_ASE, "External" },
{ LS_TYPE_GROUP, "Multicast Group" },
{ LS_TYPE_NSSA, "NSSA" },
{ LS_TYPE_OPAQUE_LL, "Link Local Opaque" },
{ LS_TYPE_OPAQUE_AL, "Area Local Opaque" },
{ LS_TYPE_OPAQUE_DW, "Domain Wide Opaque" },
{ 0, NULL }
};
static const struct tok ospf_dd_flag_values[] = {
{ OSPF_DB_INIT, "Init" },
{ OSPF_DB_MORE, "More" },
{ OSPF_DB_MASTER, "Master" },
{ OSPF_DB_RESYNC, "OOBResync" },
{ 0, NULL }
};
static const struct tok lsa_opaque_values[] = {
{ LS_OPAQUE_TYPE_TE, "Traffic Engineering" },
{ LS_OPAQUE_TYPE_GRACE, "Graceful restart" },
{ LS_OPAQUE_TYPE_RI, "Router Information" },
{ LS_OPAQUE_TYPE_EP, "Extended Prefix" },
{ LS_OPAQUE_TYPE_EL, "Extended Link" },
{ 0, NULL }
};
static const struct tok lsa_opaque_ri_sid_subtlv_values[] = {
{ LS_OPAQUE_RI_SUBTLV_SID_LABEL, "SID/Label" },
{ 0, NULL }
};
static const struct tok lsa_opaque_te_tlv_values[] = {
{ LS_OPAQUE_TE_TLV_ROUTER, "Router Address" },
{ LS_OPAQUE_TE_TLV_LINK, "Link" },
{ 0, NULL }
};
static const struct tok lsa_opaque_ep_extd_prefix_subtlv_values[] = {
{ LS_OPAQUE_EP_SUBTLV_PREFIX_SID, "Prefix-SID" },
{ 0, NULL }
};
static const struct tok ep_range_tlv_prefix_sid_subtlv_flag_values[] = {
{ 0x40, "No-PHP"},
{ 0x20, "Mapping-Server"},
{ 0x10, "Explicit-NULL"},
{ 0x08, "Value"},
{ 0x04, "Local"},
{ 0, NULL}
};
static const struct tok lsa_opaque_ep_route_type_values[] = {
{ 0, "Unspecified" },
{ 1, "Intra-Area" },
{ 3, "Inter-Area" },
{ 5, "AS External" },
{ 7, "NSSA External" },
{ 0, NULL }
};
static const struct tok lsa_opaque_ep_tlv_values[] = {
{ LS_OPAQUE_EP_EXTD_PREFIX_TLV, "Extended Prefix" },
{ LS_OPAQUE_EP_EXTD_PREFIX_RANGE_TLV, "Extended Prefix Range" },
{ 0, NULL }
};
static const struct tok ep_tlv_flag_values[] = {
{ 0x80, "Inter-Area"},
{ 0, NULL}
};
static const struct tok lsa_opaque_te_link_tlv_subtlv_values[] = {
{ LS_OPAQUE_TE_LINK_SUBTLV_LINK_TYPE, "Link Type" },
{ LS_OPAQUE_TE_LINK_SUBTLV_LINK_ID, "Link ID" },
{ LS_OPAQUE_TE_LINK_SUBTLV_LOCAL_IP, "Local Interface IP address" },
{ LS_OPAQUE_TE_LINK_SUBTLV_REMOTE_IP, "Remote Interface IP address" },
{ LS_OPAQUE_TE_LINK_SUBTLV_TE_METRIC, "Traffic Engineering Metric" },
{ LS_OPAQUE_TE_LINK_SUBTLV_MAX_BW, "Maximum Bandwidth" },
{ LS_OPAQUE_TE_LINK_SUBTLV_MAX_RES_BW, "Maximum Reservable Bandwidth" },
{ LS_OPAQUE_TE_LINK_SUBTLV_UNRES_BW, "Unreserved Bandwidth" },
{ LS_OPAQUE_TE_LINK_SUBTLV_ADMIN_GROUP, "Administrative Group" },
{ LS_OPAQUE_TE_LINK_SUBTLV_LINK_LOCAL_REMOTE_ID, "Link Local/Remote Identifier" },
{ LS_OPAQUE_TE_LINK_SUBTLV_LINK_PROTECTION_TYPE, "Link Protection Type" },
{ LS_OPAQUE_TE_LINK_SUBTLV_INTF_SW_CAP_DESCR, "Interface Switching Capability" },
{ LS_OPAQUE_TE_LINK_SUBTLV_SHARED_RISK_GROUP, "Shared Risk Link Group" },
{ LS_OPAQUE_TE_LINK_SUBTLV_BW_CONSTRAINTS, "Bandwidth Constraints" },
{ 0, NULL }
};
static const struct tok lsa_opaque_grace_tlv_values[] = {
{ LS_OPAQUE_GRACE_TLV_PERIOD, "Grace Period" },
{ LS_OPAQUE_GRACE_TLV_REASON, "Graceful restart Reason" },
{ LS_OPAQUE_GRACE_TLV_INT_ADDRESS, "IPv4 interface address" },
{ 0, NULL }
};
static const struct tok lsa_opaque_grace_tlv_reason_values[] = {
{ LS_OPAQUE_GRACE_TLV_REASON_UNKNOWN, "Unknown" },
{ LS_OPAQUE_GRACE_TLV_REASON_SW_RESTART, "Software Restart" },
{ LS_OPAQUE_GRACE_TLV_REASON_SW_UPGRADE, "Software Reload/Upgrade" },
{ LS_OPAQUE_GRACE_TLV_REASON_CP_SWITCH, "Control Processor Switch" },
{ 0, NULL }
};
static const struct tok lsa_opaque_te_tlv_link_type_sub_tlv_values[] = {
{ LS_OPAQUE_TE_LINK_SUBTLV_LINK_TYPE_PTP, "Point-to-point" },
{ LS_OPAQUE_TE_LINK_SUBTLV_LINK_TYPE_MA, "Multi-Access" },
{ 0, NULL }
};
static const struct tok lsa_opaque_ri_tlv_values[] = {
{ LS_OPAQUE_RI_TLV_CAP, "Router Capabilities" },
{ LS_OPAQUE_RI_TLV_SR_ALGO, "SR-Algorithm" },
{ LS_OPAQUE_RI_TLV_HOSTNAME, "Hostname" },
{ LS_OPAQUE_RI_TLV_SID_LABEL_RANGE, "SID/Label Range" },
{ LS_OPAQUE_RI_TLV_SR_LOCAL_BLOCK, "SR Local Block" },
{ LS_OPAQUE_RI_TLV_SRMS_PREFERENCE, "SRMS Preference" },
{ 0, NULL }
};
static const struct tok lsa_opaque_ri_tlv_cap_values[] = {
{ 1, "Reserved" },
{ 2, "Reserved" },
{ 4, "Reserved" },
{ 8, "Reserved" },
{ 16, "graceful restart capable" },
{ 32, "graceful restart helper" },
{ 64, "Stub router support" },
{ 128, "Traffic engineering" },
{ 256, "p2p over LAN" },
{ 512, "path computation server" },
{ 0, NULL }
};
static const struct tok lsa_opaque_ri_tlv_sr_algos[] = {
{ 0, "Shortest Path First" },
{ 1, "Strict Shortest Path First" },
{ 0, NULL }
};
static const struct tok ospf_lls_tlv_values[] = {
{ OSPF_LLS_EO, "Extended Options" },
{ OSPF_LLS_MD5, "MD5 Authentication" },
{ 0, NULL }
};
static const struct tok ospf_lls_eo_options[] = {
{ OSPF_LLS_EO_LR, "LSDB resync" },
{ OSPF_LLS_EO_RS, "Restart" },
{ 0, NULL }
};
int
ospf_grace_lsa_print(netdissect_options *ndo,
const u_char *tptr, u_int ls_length)
{
u_int tlv_type, tlv_length;
while (ls_length != 0) {
ND_TCHECK_4(tptr);
if (ls_length < 4) {
ND_PRINT("\n\t Remaining LS length %u < 4", ls_length);
return -1;
}
tlv_type = GET_BE_U_2(tptr);
tlv_length = GET_BE_U_2(tptr + 2);
tptr+=4;
ls_length-=4;
ND_PRINT("\n\t %s TLV (%u), length %u, value: ",
tok2str(lsa_opaque_grace_tlv_values,"unknown",tlv_type),
tlv_type,
tlv_length);
if (tlv_length > ls_length) {
ND_PRINT("\n\t Bogus length %u > %u", tlv_length,
ls_length);
return -1;
}
/* Infinite loop protection. */
if (tlv_type == 0 || tlv_length ==0) {
nd_print_invalid(ndo);
return -1;
}
ND_TCHECK_LEN(tptr, tlv_length);
switch(tlv_type) {
case LS_OPAQUE_GRACE_TLV_PERIOD:
if (tlv_length != 4) {
ND_PRINT("\n\t Bogus length %u != 4", tlv_length);
return -1;
}
ND_PRINT("%us", GET_BE_U_4(tptr));
break;
case LS_OPAQUE_GRACE_TLV_REASON:
if (tlv_length != 1) {
ND_PRINT("\n\t Bogus length %u != 1", tlv_length);
return -1;
}
ND_PRINT("%s (%u)",
tok2str(lsa_opaque_grace_tlv_reason_values, "Unknown", GET_U_1(tptr)),
GET_U_1(tptr));
break;
case LS_OPAQUE_GRACE_TLV_INT_ADDRESS:
if (tlv_length != 4) {
ND_PRINT("\n\t Bogus length %u != 4", tlv_length);
return -1;
}
ND_PRINT("%s", GET_IPADDR_STRING(tptr));
break;
default:
if (ndo->ndo_vflag <= 1) {
if (!print_unknown_data(ndo, tptr, "\n\t ", tlv_length))
return -1;
}
break;
}
/* in OSPF everything has to be 32-bit aligned, including TLVs */
if (tlv_length%4 != 0) {
tlv_length+=4-(tlv_length%4);
if (tlv_length > ls_length) {
ND_PRINT("\n\t Bogus padded length %u > %u", tlv_length,
ls_length);
return -1;
}
}
ls_length-=tlv_length;
tptr+=tlv_length;
}
return 0;
trunc:
nd_print_trunc(ndo);
return -1;
}
static int
ospf_te_tlv_link_print(netdissect_options *ndo,
const u_char *tptr, u_int tlv_length)
{
u_int subtlv_type, subtlv_length;
u_int priority_level, te_class, count_srlg;
while (tlv_length != 0) {
if (tlv_length < 4) {
ND_PRINT("\n\t Remaining TLV length %u < 4",
tlv_length);
return -1;
}
subtlv_type = GET_BE_U_2(tptr);
subtlv_length = GET_BE_U_2(tptr + 2);
tptr+=4;
tlv_length-=4;
/* Infinite loop protection */
if (subtlv_type == 0 || subtlv_length == 0)
goto invalid;
ND_PRINT("\n\t %s subTLV (%u), length: %u",
tok2str(lsa_opaque_te_link_tlv_subtlv_values,"unknown",subtlv_type),
subtlv_type,
subtlv_length);
if (tlv_length < subtlv_length) {
ND_PRINT("\n\t Remaining TLV length %u < %u",
tlv_length, subtlv_length);
return -1;
}
ND_TCHECK_LEN(tptr, subtlv_length);
switch(subtlv_type) {
case LS_OPAQUE_TE_LINK_SUBTLV_ADMIN_GROUP:
if (subtlv_length != 4) {
ND_PRINT(" != 4");
goto invalid;
}
ND_PRINT(", 0x%08x", GET_BE_U_4(tptr));
break;
case LS_OPAQUE_TE_LINK_SUBTLV_LINK_ID:
case LS_OPAQUE_TE_LINK_SUBTLV_LINK_LOCAL_REMOTE_ID:
if (subtlv_length != 4 && subtlv_length != 8) {
ND_PRINT(" != 4 && != 8");
goto invalid;
}
ND_PRINT(", %s (0x%08x)",
GET_IPADDR_STRING(tptr),
GET_BE_U_4(tptr));
if (subtlv_length == 8) /* rfc4203 */
ND_PRINT(", %s (0x%08x)",
GET_IPADDR_STRING(tptr+4),
GET_BE_U_4(tptr + 4));
break;
case LS_OPAQUE_TE_LINK_SUBTLV_LOCAL_IP:
case LS_OPAQUE_TE_LINK_SUBTLV_REMOTE_IP:
if (subtlv_length != 4) {
ND_PRINT(" != 4");
goto invalid;
}
ND_PRINT(", %s", GET_IPADDR_STRING(tptr));
break;
case LS_OPAQUE_TE_LINK_SUBTLV_MAX_BW:
case LS_OPAQUE_TE_LINK_SUBTLV_MAX_RES_BW:
if (subtlv_length != 4) {
ND_PRINT(" != 4");
goto invalid;
}
ND_PRINT(", %.3f Mbps", GET_BE_F_4(tptr) * 8 / 1000000);
break;
case LS_OPAQUE_TE_LINK_SUBTLV_UNRES_BW:
if (subtlv_length != 32) {
ND_PRINT(" != 32");
goto invalid;
}
for (te_class = 0; te_class < 8; te_class++) {
ND_PRINT("\n\t\tTE-Class %u: %.3f Mbps",
te_class,
GET_BE_F_4(tptr + te_class * 4) * 8 / 1000000);
}
break;
case LS_OPAQUE_TE_LINK_SUBTLV_BW_CONSTRAINTS:
if (subtlv_length < 4) {
ND_PRINT(" < 4");
goto invalid;
}
/* BC Model Id (1 octet) + Reserved (3 octets) */
ND_PRINT("\n\t\tBandwidth Constraints Model ID: %s (%u)",
tok2str(diffserv_te_bc_values, "unknown", GET_U_1(tptr)),
GET_U_1(tptr));
if (subtlv_length % 4 != 0) {
ND_PRINT("\n\t\tlength %u != N x 4", subtlv_length);
goto invalid;
}
if (subtlv_length > 36) {
ND_PRINT("\n\t\tlength %u > 36", subtlv_length);
goto invalid;
}
/* decode BCs until the subTLV ends */
for (te_class = 0; te_class < (subtlv_length-4)/4; te_class++) {
ND_PRINT("\n\t\t Bandwidth constraint CT%u: %.3f Mbps",
te_class,
GET_BE_F_4(tptr + 4 + te_class * 4) * 8 / 1000000);
}
break;
case LS_OPAQUE_TE_LINK_SUBTLV_TE_METRIC:
if (subtlv_length != 4) {
ND_PRINT(" != 4");
goto invalid;
}
ND_PRINT(", Metric %u", GET_BE_U_4(tptr));
break;
case LS_OPAQUE_TE_LINK_SUBTLV_LINK_PROTECTION_TYPE:
/* Protection Cap (1 octet) + Reserved ((3 octets) */
if (subtlv_length != 4) {
ND_PRINT(" != 4");
goto invalid;
}
ND_PRINT(", %s",
bittok2str(gmpls_link_prot_values, "none", GET_U_1(tptr)));
break;
case LS_OPAQUE_TE_LINK_SUBTLV_INTF_SW_CAP_DESCR:
if (subtlv_length < 36) {
ND_PRINT(" < 36");
goto invalid;
}
/* Switching Cap (1 octet) + Encoding (1) + Reserved (2) */
ND_PRINT("\n\t\tInterface Switching Capability: %s",
tok2str(gmpls_switch_cap_values, "Unknown", GET_U_1((tptr))));
ND_PRINT("\n\t\tLSP Encoding: %s\n\t\tMax LSP Bandwidth:",
tok2str(gmpls_encoding_values, "Unknown", GET_U_1((tptr + 1))));
for (priority_level = 0; priority_level < 8; priority_level++) {
ND_PRINT("\n\t\t priority level %u: %.3f Mbps",
priority_level,
GET_BE_F_4(tptr + 4 + (priority_level * 4)) * 8 / 1000000);
}
break;
case LS_OPAQUE_TE_LINK_SUBTLV_LINK_TYPE:
if (subtlv_length != 1) {
ND_PRINT(" != 1");
goto invalid;
}
ND_PRINT(", %s (%u)",
tok2str(lsa_opaque_te_tlv_link_type_sub_tlv_values,"unknown",GET_U_1(tptr)),
GET_U_1(tptr));
break;
case LS_OPAQUE_TE_LINK_SUBTLV_SHARED_RISK_GROUP:
if (subtlv_length % 4 != 0) {
ND_PRINT(" != N x 4");
goto invalid;
}
count_srlg = subtlv_length / 4;
if (count_srlg != 0)
ND_PRINT("\n\t\t Shared risk group: ");
while (count_srlg != 0) {
ND_PRINT("%u", GET_BE_U_4(tptr));
tptr+=4;
count_srlg--;
if (count_srlg > 0)
ND_PRINT(", ");
}
break;
default:
if (ndo->ndo_vflag <= 1) {
if (!print_unknown_data(ndo, tptr, "\n\t\t", subtlv_length))
return -1;
}
break;
}
/* in OSPF everything has to be 32-bit aligned, including subTLVs */
if (subtlv_length%4 != 0) {
subtlv_length+=4-(subtlv_length%4);
if (tlv_length < subtlv_length) {
ND_PRINT("\n\t Remaining TLV length %u < %u",
tlv_length, subtlv_length);
return -1;
}
}
tlv_length-=subtlv_length;
tptr+=subtlv_length;
}
return 0;
trunc:
nd_print_trunc(ndo);
return -1;
invalid:
nd_print_invalid(ndo);
return -1;
}
int
ospf_te_lsa_print(netdissect_options *ndo,
const u_char *tptr, u_int ls_length)
{
u_int tlv_type, tlv_length;
while (ls_length != 0) {
ND_TCHECK_4(tptr);
if (ls_length < 4) {
ND_PRINT("\n\t Remaining LS length %u < 4", ls_length);
return -1;
}
tlv_type = GET_BE_U_2(tptr);
tlv_length = GET_BE_U_2(tptr + 2);
tptr+=4;
ls_length-=4;
ND_PRINT("\n\t %s TLV (%u), length: %u",
tok2str(lsa_opaque_te_tlv_values,"unknown",tlv_type),
tlv_type,
tlv_length);
if (tlv_length > ls_length) {
ND_PRINT("\n\t Bogus length %u > %u", tlv_length,
ls_length);
goto invalid;
}
/* Infinite loop protection. */
if (tlv_type == 0 || tlv_length ==0) {
nd_print_invalid(ndo);
goto invalid;
}
switch(tlv_type) {
case LS_OPAQUE_TE_TLV_LINK:
if (ospf_te_tlv_link_print(ndo, tptr, tlv_length) == -1)
return -1;
break;
case LS_OPAQUE_TE_TLV_ROUTER:
if (tlv_length < 4) {
ND_PRINT("\n\t TLV length %u < 4", tlv_length);
goto invalid;
}
ND_PRINT(", %s", GET_IPADDR_STRING(tptr));
break;
default:
if (ndo->ndo_vflag <= 1) {
if (!print_unknown_data(ndo, tptr, "\n\t ", tlv_length))
goto invalid;
}
break;
}
/* in OSPF everything has to be 32-bit aligned, including TLVs */
if (tlv_length%4 != 0) {
tlv_length+=4-(tlv_length%4);
if (tlv_length > ls_length) {
ND_PRINT("\n\t Bogus padded length %u > %u", tlv_length,
ls_length);
goto invalid;
}
}
ls_length-=tlv_length;
tptr+=tlv_length;
}
return 0;
trunc:
nd_print_trunc(ndo);
return -1;
invalid:
nd_print_invalid(ndo);
return -1;
}
static int
ospf_print_lshdr(netdissect_options *ndo,
const struct lsa_hdr *lshp)
{
u_int ls_type;
u_int ls_length;
ls_length = GET_BE_U_2(lshp->ls_length);
if (ls_length < sizeof(struct lsa_hdr)) {
ND_PRINT("\n\t Bogus length %u < header (%zu)", ls_length,
sizeof(struct lsa_hdr));
return(-1);
}
ND_PRINT("\n\t Advertising Router %s, seq 0x%08x, age %us, length %zu",
GET_IPADDR_STRING(lshp->ls_router),
GET_BE_U_4(lshp->ls_seq),
GET_BE_U_2(lshp->ls_age),
ls_length - sizeof(struct lsa_hdr));
ls_type = GET_U_1(lshp->ls_type);
switch (ls_type) {
/* the LSA header for opaque LSAs was slightly changed */
case LS_TYPE_OPAQUE_LL:
case LS_TYPE_OPAQUE_AL:
case LS_TYPE_OPAQUE_DW:
ND_PRINT("\n\t %s LSA (%u), Opaque-Type %s LSA (%u), Opaque-ID %u",
tok2str(lsa_values,"unknown",ls_type),
ls_type,
tok2str(lsa_opaque_values,
"unknown",
GET_U_1(lshp->un_lsa_id.opaque_field.opaque_type)),
GET_U_1(lshp->un_lsa_id.opaque_field.opaque_type),
GET_BE_U_3(lshp->un_lsa_id.opaque_field.opaque_id)
);
break;
/* all other LSA types use regular style LSA headers */
default:
ND_PRINT("\n\t %s LSA (%u), LSA-ID: %s",
tok2str(lsa_values,"unknown",ls_type),
ls_type,
GET_IPADDR_STRING(lshp->un_lsa_id.lsa_id));
break;
}
ND_PRINT("\n\t Options: [%s]",
bittok2str(ospf_option_values, "none", GET_U_1(lshp->ls_options)));
return (ls_length);
}
/* draft-ietf-ospf-mt-09 */
static const struct tok ospf_topology_values[] = {
{ 0, "default" },
{ 1, "multicast" },
{ 2, "management" },
{ 0, NULL }
};
/*
* Print all the per-topology metrics.
*/
static void
ospf_print_tos_metrics(netdissect_options *ndo,
const union un_tos *tos)
{
u_int metric_count;
u_int toscount;
u_int tos_type;
toscount = GET_U_1(tos->link.link_tos_count)+1;
metric_count = 0;
/*
* All but the first metric contain a valid topology id.
*/
while (toscount != 0) {
tos_type = GET_U_1(tos->metrics.tos_type);
ND_PRINT("\n\t\ttopology %s (%u), metric %u",
tok2str(ospf_topology_values, "Unknown",
metric_count ? tos_type : 0),
metric_count ? tos_type : 0,
GET_BE_U_2(tos->metrics.tos_metric));
metric_count++;
tos++;
toscount--;
}
}
/*
* The SID/Label Range TLV
* https://datatracker.ietf.org/doc/html/rfc8665#section-3.2
* and the SR Local Block TLV
* https://datatracker.ietf.org/doc/html/rfc8665#section-3.3
* have the same contents, so this function is used to
* print both.
*/
static int
ospf_print_ri_lsa_sid_label_range_tlv(netdissect_options *ndo, const uint8_t *tptr,
u_int tlv_length)
{
u_int subtlv_type, subtlv_length;
while (tlv_length >= 4) {
subtlv_type = GET_BE_U_2(tptr);
subtlv_length = GET_BE_U_2(tptr+2);
tptr+=4;
tlv_length-=4;
/* Infinite loop protection. */
if (subtlv_type == 0 || subtlv_length == 0) {
nd_print_invalid(ndo);
return -1;
}
ND_PRINT("\n\t %s subTLV (%u), length: %u, value: ",
tok2str(lsa_opaque_ri_sid_subtlv_values,"unknown",subtlv_type),
subtlv_type,
subtlv_length);
if (tlv_length < subtlv_length) {
ND_PRINT("\n\t Remaining TLV length %u < %u",
tlv_length, subtlv_length);
return -1;
}
switch (subtlv_type) {
case LS_OPAQUE_RI_SUBTLV_SID_LABEL:
if (subtlv_length == 3) {
ND_PRINT("\n\t\tLabel: %u", GET_BE_U_3(tptr));
} else if (subtlv_length == 4) {
ND_PRINT("\n\t\tSID: %u", GET_BE_U_4(tptr));
} else {
ND_PRINT("\n\t\tBogus subTLV length %u", subtlv_length);
}
break;
default:
if (ndo->ndo_vflag <= 1) {
if (!print_unknown_data(ndo, tptr, "\n\t\t", subtlv_length))
return -1;
}
}
/* in OSPF everything has to be 32-bit aligned, including subTLVs */
if (subtlv_length % 4) {
subtlv_length += (4 - (subtlv_length % 4));
if (tlv_length < subtlv_length) {
ND_PRINT("\n\t Remaining TLV length %u < %u",
tlv_length, subtlv_length);
return -1;
}
}
tptr+=subtlv_length;
tlv_length-=subtlv_length;
}
return 0;
}
static int
ospf_print_ep_lsa_extd_prefix_tlv(netdissect_options *ndo, const uint8_t *tptr,
u_int tlv_length)
{
u_int subtlv_type, subtlv_length;
uint8_t flags, mt_id, algo;
while (tlv_length >= 4) {
subtlv_type = GET_BE_U_2(tptr);
subtlv_length = GET_BE_U_2(tptr+2);
tptr+=4;
tlv_length-=4;
/* Infinite loop protection. */
if (subtlv_type == 0 || subtlv_length == 0) {
nd_print_invalid(ndo);
return -1;
}
ND_PRINT("\n\t\t%s subTLV (%u), length: %u, value: ",
tok2str(lsa_opaque_ep_extd_prefix_subtlv_values,"unknown",subtlv_type),
subtlv_type,
subtlv_length);
if (tlv_length < subtlv_length) {
ND_PRINT("\n\t Remaining TLV length %u < %u",
tlv_length, subtlv_length);
return -1;
}
switch (subtlv_type) {
case LS_OPAQUE_EP_SUBTLV_PREFIX_SID:
flags = GET_U_1(tptr);
mt_id = GET_U_1(tptr+2);
algo = GET_U_1(tptr+3);
if (subtlv_length == 7) {
ND_PRINT("\n\t\t Label: %u", GET_BE_U_3(tptr+4));
} else if (subtlv_length == 8) {
ND_PRINT("\n\t\t Index: %u", GET_BE_U_4(tptr+4));
} else {
ND_PRINT("\n\t\tBogus subTLV length %u", subtlv_length);
break;
}
ND_PRINT( ", MT-ID: %u, Algorithm: %s (%u), Flags [%s]",
mt_id, tok2str(lsa_opaque_ri_tlv_sr_algos, "Unknown", algo), algo,
bittok2str(ep_range_tlv_prefix_sid_subtlv_flag_values, "none", flags));
break;
default:
if (ndo->ndo_vflag <= 1) {
if (!print_unknown_data(ndo, tptr, "\n\t\t", subtlv_length))
return -1;
}
}
/* in OSPF everything has to be 32-bit aligned, including subTLVs */
if (subtlv_length % 4) {
subtlv_length += (4 - (subtlv_length % 4));
if (tlv_length < subtlv_length) {
ND_PRINT("\n\t Remaining TLV length %u < %u",
tlv_length, subtlv_length);
return -1;
}
}
tptr+=subtlv_length;
tlv_length-=subtlv_length;
}
return 0;
}
static int
ospf_ep_lsa_print(netdissect_options *ndo, const uint8_t *tptr, u_int lsa_length)
{
u_int tlv_type, tlv_length;
uint16_t range_size;
uint8_t af, prefix_length, route_type, flags;
while (lsa_length >= 4) {
tlv_type = GET_BE_U_2(tptr);
tlv_length = GET_BE_U_2(tptr+2);
tptr+=4;
lsa_length-=4;
/* Infinite loop protection. */
if (tlv_type == 0 || tlv_length == 0) {
nd_print_invalid(ndo);
return -1;
}
ND_PRINT("\n\t %s TLV (%u), length: %u, value: ",
tok2str(lsa_opaque_ep_tlv_values,"unknown",tlv_type),
tlv_type,
tlv_length);
if (tlv_length > lsa_length) {
ND_PRINT("\n\t Bogus length %u > %u",
tlv_length, lsa_length);
return -1;
}
switch (tlv_type) {
case LS_OPAQUE_EP_EXTD_PREFIX_TLV:
prefix_length = GET_U_1(tptr+1);
af = GET_U_1(tptr+2);
route_type = GET_U_1(tptr);
flags = GET_U_1(tptr+3);
if (af != 0) {
ND_PRINT("\n\t Bogus AF %u", af);
return -1;
}
if (prefix_length > 32) {
ND_PRINT("\n\t IPv4 prefix: bad bit length %u", prefix_length);
return -1;
}
ND_PRINT("\n\t IPv4 prefix: %15s/%u, Route Type: %s, Flags [%s]",
GET_IPADDR_STRING(tptr+4), prefix_length,
tok2str(lsa_opaque_ep_route_type_values, "Unknown", route_type),
bittok2str(ep_tlv_flag_values, "none", flags));
/* subTLVs present ? */
if (tlv_length > 12) {
if (ospf_print_ep_lsa_extd_prefix_tlv(ndo, tptr+8, tlv_length-8) == -1) {
return -1;
}
}
break;
case LS_OPAQUE_EP_EXTD_PREFIX_RANGE_TLV:
prefix_length = GET_U_1(tptr);
af = GET_U_1(tptr+1);
range_size = GET_BE_U_2(tptr+2);
flags = GET_U_1(tptr+4);
if (af != 0) {
ND_PRINT("\n\t Bogus AF %u", af);
return -1;
}
if (prefix_length > 32) {
ND_PRINT("\n\t IPv4 prefix: bad bit length %u", prefix_length);
return -1;
}
ND_PRINT("\n\t IPv4 prefix: %15s/%u, Range size: %u, Flags [%s]",
GET_IPADDR_STRING(tptr+8), prefix_length,
range_size,
bittok2str(ep_tlv_flag_values, "none", flags));
/* subTLVs present ? */
if (tlv_length > 12) {
if (ospf_print_ep_lsa_extd_prefix_tlv(ndo, tptr+12, tlv_length-12) == -1) {
return -1;
}
}
break;
default:
if (ndo->ndo_vflag <= 1) {
if (!print_unknown_data(ndo, tptr, "\n\t\t", tlv_length))
return -1;
}
}
/* in OSPF everything has to be 32-bit aligned, including TLVs */
if (tlv_length % 4) {
tlv_length += (4 - (tlv_length % 4));
if (tlv_length > lsa_length) {
ND_PRINT("\n\t Bogus padded length %u > %u", tlv_length,
lsa_length);
return -1;
}
}
tptr+=tlv_length;
lsa_length-=tlv_length;
}
return 0;
}
/*
* Print a single link state advertisement. If truncated or if LSA length
* field is less than the length of the LSA header, return NULl, else
* return pointer to data past end of LSA.
*/
static const uint8_t *
ospf_print_lsa(netdissect_options *ndo,
const struct lsa *lsap)
{
const uint8_t *ls_end;
const struct rlalink *rlp;
const nd_ipv4 *ap;
const struct aslametric *almp;
const struct mcla *mcp;
const uint8_t *lp;
u_int tlv_type, tlv_length, rla_count, topology, num_tlv;
int ospf_print_lshdr_ret;
u_int ls_length;
const uint8_t *tptr;
tptr = (const uint8_t *)lsap->lsa_un.un_unknown; /* squelch compiler warnings */
ospf_print_lshdr_ret = ospf_print_lshdr(ndo, &lsap->ls_hdr);
if (ospf_print_lshdr_ret < 0)
return(NULL);
ls_length = (u_int)ospf_print_lshdr_ret;
ls_end = (const uint8_t *)lsap + ls_length;
/*
* ospf_print_lshdr() returns -1 if the length is too short,
* so we know ls_length is >= sizeof(struct lsa_hdr).
*/
ls_length -= sizeof(struct lsa_hdr);
switch (GET_U_1(lsap->ls_hdr.ls_type)) {
case LS_TYPE_ROUTER:
ND_PRINT("\n\t Router LSA Options: [%s]",
bittok2str(ospf_rla_flag_values, "none", GET_U_1(lsap->lsa_un.un_rla.rla_flags)));
rla_count = GET_BE_U_2(lsap->lsa_un.un_rla.rla_count);
ND_TCHECK_SIZE(lsap->lsa_un.un_rla.rla_link);
rlp = lsap->lsa_un.un_rla.rla_link;
for (u_int i = rla_count; i != 0; i--) {
ND_TCHECK_SIZE(rlp);
switch (GET_U_1(rlp->un_tos.link.link_type)) {
case RLA_TYPE_VIRTUAL:
ND_PRINT("\n\t Virtual Link: Neighbor Router-ID: %s, Interface Address: %s",
GET_IPADDR_STRING(rlp->link_id),
GET_IPADDR_STRING(rlp->link_data));
break;
case RLA_TYPE_ROUTER:
ND_PRINT("\n\t Neighbor Router-ID: %s, Interface Address: %s",
GET_IPADDR_STRING(rlp->link_id),
GET_IPADDR_STRING(rlp->link_data));
break;
case RLA_TYPE_TRANSIT:
ND_PRINT("\n\t Neighbor Network-ID: %s, Interface Address: %s",
GET_IPADDR_STRING(rlp->link_id),
GET_IPADDR_STRING(rlp->link_data));
break;
case RLA_TYPE_STUB:
ND_PRINT("\n\t Stub Network: %s, Mask: %s",
GET_IPADDR_STRING(rlp->link_id),
GET_IPADDR_STRING(rlp->link_data));
break;
default:
ND_PRINT("\n\t Unknown Router Link Type (%u)",
GET_U_1(rlp->un_tos.link.link_type));
return (ls_end);
}
ospf_print_tos_metrics(ndo, &rlp->un_tos);
rlp = (const struct rlalink *)((const u_char *)(rlp + 1) +
(GET_U_1(rlp->un_tos.link.link_tos_count) * sizeof(union un_tos)));
}
break;
case LS_TYPE_NETWORK:
ND_PRINT("\n\t Mask %s\n\t Connected Routers:",
GET_IPADDR_STRING(lsap->lsa_un.un_nla.nla_mask));
ap = lsap->lsa_un.un_nla.nla_router;
while ((const u_char *)ap < ls_end) {
ND_PRINT("\n\t %s", GET_IPADDR_STRING(ap));
++ap;
}
break;
case LS_TYPE_SUM_IP:
ND_TCHECK_4(lsap->lsa_un.un_nla.nla_mask);
ND_PRINT("\n\t Mask %s",
GET_IPADDR_STRING(lsap->lsa_un.un_sla.sla_mask));
ND_TCHECK_SIZE(lsap->lsa_un.un_sla.sla_tosmetric);
lp = (const uint8_t *)lsap->lsa_un.un_sla.sla_tosmetric;
while (lp < ls_end) {
uint32_t ul;
ul = GET_BE_U_4(lp);
topology = (ul & SLA_MASK_TOS) >> SLA_SHIFT_TOS;
ND_PRINT("\n\t\ttopology %s (%u) metric %u",
tok2str(ospf_topology_values, "Unknown", topology),
topology,
ul & SLA_MASK_METRIC);
lp += 4;
}
break;
case LS_TYPE_SUM_ABR:
ND_TCHECK_SIZE(lsap->lsa_un.un_sla.sla_tosmetric);
lp = (const uint8_t *)lsap->lsa_un.un_sla.sla_tosmetric;
while (lp < ls_end) {
uint32_t ul;
ul = GET_BE_U_4(lp);
topology = (ul & SLA_MASK_TOS) >> SLA_SHIFT_TOS;
ND_PRINT("\n\t\ttopology %s (%u) metric %u",
tok2str(ospf_topology_values, "Unknown", topology),
topology,
ul & SLA_MASK_METRIC);
lp += 4;
}
break;
case LS_TYPE_ASE:
case LS_TYPE_NSSA: /* fall through - those LSAs share the same format */
ND_TCHECK_4(lsap->lsa_un.un_nla.nla_mask);
ND_PRINT("\n\t Mask %s",
GET_IPADDR_STRING(lsap->lsa_un.un_asla.asla_mask));
ND_TCHECK_SIZE(lsap->lsa_un.un_sla.sla_tosmetric);
almp = lsap->lsa_un.un_asla.asla_metric;
while ((const u_char *)almp < ls_end) {
uint32_t ul;
ul = GET_BE_U_4(almp->asla_tosmetric);
topology = ((ul & ASLA_MASK_TOS) >> ASLA_SHIFT_TOS);
ND_PRINT("\n\t\ttopology %s (%u), type %u, metric",
tok2str(ospf_topology_values, "Unknown", topology),
topology,
(ul & ASLA_FLAG_EXTERNAL) ? 2 : 1);
if ((ul & ASLA_MASK_METRIC) == 0xffffff)
ND_PRINT(" infinite");
else
ND_PRINT(" %u", (ul & ASLA_MASK_METRIC));
if (GET_IPV4_TO_NETWORK_ORDER(almp->asla_forward) != 0) {
ND_PRINT(", forward %s", GET_IPADDR_STRING(almp->asla_forward));
}
if (GET_IPV4_TO_NETWORK_ORDER(almp->asla_tag) != 0) {
ND_PRINT(", tag %s", GET_IPADDR_STRING(almp->asla_tag));
}
++almp;
}
break;
case LS_TYPE_GROUP:
/* Multicast extensions as of 23 July 1991 */
mcp = lsap->lsa_un.un_mcla;
while ((const u_char *)mcp < ls_end) {
switch (GET_BE_U_4(mcp->mcla_vtype)) {
case MCLA_VERTEX_ROUTER:
ND_PRINT("\n\t Router Router-ID %s",
GET_IPADDR_STRING(mcp->mcla_vid));
break;
case MCLA_VERTEX_NETWORK:
ND_PRINT("\n\t Network Designated Router %s",
GET_IPADDR_STRING(mcp->mcla_vid));
break;
default:
ND_PRINT("\n\t unknown VertexType (%u)",
GET_BE_U_4(mcp->mcla_vtype));
break;
}
++mcp;
}
break;
case LS_TYPE_OPAQUE_LL: /* fall through */
case LS_TYPE_OPAQUE_AL:
case LS_TYPE_OPAQUE_DW:
switch (GET_U_1(lsap->ls_hdr.un_lsa_id.opaque_field.opaque_type)) {
case LS_OPAQUE_TYPE_RI:
tptr = (const uint8_t *)(lsap->lsa_un.un_ri_tlv);
u_int ls_length_remaining = ls_length;
while (ls_length_remaining != 0) {
ND_TCHECK_4(tptr);
if (ls_length_remaining < 4) {
ND_PRINT("\n\t Remaining LS length %u < 4", ls_length_remaining);
return(ls_end);
}
tlv_type = GET_BE_U_2(tptr);
tlv_length = GET_BE_U_2(tptr + 2);
tptr+=4;
ls_length_remaining-=4;
ND_PRINT("\n\t %s TLV (%u), length: %u, value: ",
tok2str(lsa_opaque_ri_tlv_values,"unknown",tlv_type),
tlv_type,
tlv_length);
if (tlv_length > ls_length_remaining) {
ND_PRINT("\n\t Bogus length %u > remaining LS length %u", tlv_length,
ls_length_remaining);
return(ls_end);
}
ND_TCHECK_LEN(tptr, tlv_length);
switch(tlv_type) {
case LS_OPAQUE_RI_TLV_CAP:
if (tlv_length != 4) {
ND_PRINT("\n\t Bogus length %u != 4", tlv_length);
return(ls_end);
}
ND_PRINT("Capabilities: %s",
bittok2str(lsa_opaque_ri_tlv_cap_values, "Unknown", GET_BE_U_4(tptr)));
break;
case LS_OPAQUE_RI_TLV_HOSTNAME:
ND_PRINT("\n\t Hostname: ");
nd_printjnp(ndo, tptr, tlv_length);
break;
case LS_OPAQUE_RI_TLV_SR_ALGO:
num_tlv = tlv_length;
while (num_tlv >= 1) {
ND_PRINT("\n\t %s (%u)",
tok2str(lsa_opaque_ri_tlv_sr_algos, "Unknown", GET_U_1(tptr+tlv_length-num_tlv)), GET_U_1(tptr+tlv_length-num_tlv));
num_tlv--;
}
break;
case LS_OPAQUE_RI_TLV_SID_LABEL_RANGE:
case LS_OPAQUE_RI_TLV_SR_LOCAL_BLOCK:
ND_TCHECK_4(tptr);
ND_PRINT("\n\t Range size: %u", GET_BE_U_3(tptr));
if (ospf_print_ri_lsa_sid_label_range_tlv(ndo, tptr+4, tlv_length-4) == -1) {
return(ls_end);
}
break;
case LS_OPAQUE_RI_TLV_SRMS_PREFERENCE:
if (tlv_length != 4) {
ND_PRINT("\n\t Bogus SRMS Preference TLV length %u != 4", tlv_length);
return(ls_end);
}
ND_PRINT("\n\t SRMS Preference: %u", GET_U_1(tptr));
break;
default:
if (ndo->ndo_vflag <= 1) {
if (!print_unknown_data(ndo, tptr, "\n\t ", tlv_length))
return(ls_end);
}
break;
}
/* in OSPF everything has to be 32-bit aligned, including TLVs */
if (tlv_length % 4) {
tlv_length += (4 - (tlv_length % 4));
if (tlv_length > ls_length_remaining) {
ND_PRINT("\n\t Bogus padded length %u > %u", tlv_length,
ls_length_remaining);
return(NULL);
}
}
tptr+=tlv_length;
ls_length_remaining-=tlv_length;
}
break;
case LS_OPAQUE_TYPE_GRACE:
if (ospf_grace_lsa_print(ndo, (const u_char *)(lsap->lsa_un.un_grace_tlv),
ls_length) == -1) {
return(ls_end);
}
break;
case LS_OPAQUE_TYPE_TE:
if (ospf_te_lsa_print(ndo, (const u_char *)(lsap->lsa_un.un_te_lsa_tlv),
ls_length) == -1) {
return(ls_end);
}
break;
case LS_OPAQUE_TYPE_EP:
if (ospf_ep_lsa_print(ndo, (const u_char *)(lsap->lsa_un.un_ep_tlv),
ls_length) == -1) {
return(ls_end);
}
break;
default:
if (ndo->ndo_vflag <= 1) {
if (!print_unknown_data(ndo, (const uint8_t *)lsap->lsa_un.un_unknown,
"\n\t ", ls_length))
return(ls_end);
}
break;
}
}
/* do we want to see an additionally hexdump ? */
if (ndo->ndo_vflag> 1)
if (!print_unknown_data(ndo, (const uint8_t *)lsap->lsa_un.un_unknown,
"\n\t ", ls_length)) {
return(ls_end);
}
return (ls_end);
trunc:
nd_print_trunc(ndo);
return (NULL);
}
static void
ospf_decode_lls(netdissect_options *ndo,
const struct ospfhdr *op, u_int length)
{
const u_char *dptr;
const u_char *dataend;
u_int length2;
uint16_t lls_type, lls_len;
uint32_t lls_flags;
switch (GET_U_1(op->ospf_type)) {
case OSPF_TYPE_HELLO:
if (!(GET_U_1(op->ospf_hello.hello_options) & OSPF_OPTION_L))
return;
break;
case OSPF_TYPE_DD:
if (!(GET_U_1(op->ospf_db.db_options) & OSPF_OPTION_L))
return;
break;
default:
return;
}
/* dig deeper if LLS data is available; see RFC4813 */
length2 = GET_BE_U_2(op->ospf_len);
dptr = (const u_char *)op + length2;
dataend = (const u_char *)op + length;
if (GET_BE_U_2(op->ospf_authtype) == OSPF_AUTH_MD5) {
dptr = dptr + GET_U_1(op->ospf_authdata + 3);
length2 += GET_U_1(op->ospf_authdata + 3);
}
if (length2 >= length) {
ND_PRINT("\n\t[LLS truncated]");
return;
}
ND_PRINT("\n\t LLS: checksum: 0x%04x", (u_int) GET_BE_U_2(dptr));
dptr += 2;
length2 = GET_BE_U_2(dptr);
ND_PRINT(", length: %u", length2);
dptr += 2;
while (dptr < dataend) {
lls_type = GET_BE_U_2(dptr);
ND_PRINT("\n\t %s (%u)",
tok2str(ospf_lls_tlv_values,"Unknown TLV",lls_type),
lls_type);
dptr += 2;
lls_len = GET_BE_U_2(dptr);
ND_PRINT(", length: %u", lls_len);
dptr += 2;
switch (lls_type) {
case OSPF_LLS_EO:
if (lls_len != 4) {
ND_PRINT(" [should be 4]");
lls_len = 4;
}
lls_flags = GET_BE_U_4(dptr);
ND_PRINT("\n\t Options: 0x%08x [%s]", lls_flags,
bittok2str(ospf_lls_eo_options, "?", lls_flags));
break;
case OSPF_LLS_MD5:
if (lls_len != 20) {
ND_PRINT(" [should be 20]");
lls_len = 20;
}
ND_PRINT("\n\t Sequence number: 0x%08x", GET_BE_U_4(dptr));
break;
}
dptr += lls_len;
}
}
static int
ospf_decode_v2(netdissect_options *ndo,
const struct ospfhdr *op, const u_char *dataend)
{
const nd_ipv4 *ap;
const struct lsr *lsrp;
const struct lsa_hdr *lshp;
const struct lsa *lsap;
uint32_t lsa_count,lsa_count_max;
switch (GET_U_1(op->ospf_type)) {
case OSPF_TYPE_HELLO:
ND_PRINT("\n\tOptions [%s]",
bittok2str(ospf_option_values,"none",GET_U_1(op->ospf_hello.hello_options)));
ND_PRINT("\n\t Hello Timer %us, Dead Timer %us, Mask %s, Priority %u",
GET_BE_U_2(op->ospf_hello.hello_helloint),
GET_BE_U_4(op->ospf_hello.hello_deadint),
GET_IPADDR_STRING(op->ospf_hello.hello_mask),
GET_U_1(op->ospf_hello.hello_priority));
if (GET_IPV4_TO_NETWORK_ORDER(op->ospf_hello.hello_dr) != 0)
ND_PRINT("\n\t Designated Router %s",
GET_IPADDR_STRING(op->ospf_hello.hello_dr));
if (GET_IPV4_TO_NETWORK_ORDER(op->ospf_hello.hello_bdr) != 0)
ND_PRINT(", Backup Designated Router %s",
GET_IPADDR_STRING(op->ospf_hello.hello_bdr));
ap = op->ospf_hello.hello_neighbor;
if ((const u_char *)ap < dataend)
ND_PRINT("\n\t Neighbor List:");
while ((const u_char *)ap < dataend) {
ND_PRINT("\n\t %s", GET_IPADDR_STRING(ap));
++ap;
}
break; /* HELLO */
case OSPF_TYPE_DD:
ND_PRINT("\n\tOptions [%s]",
bittok2str(ospf_option_values, "none", GET_U_1(op->ospf_db.db_options)));
ND_PRINT(", DD Flags [%s]",
bittok2str(ospf_dd_flag_values, "none", GET_U_1(op->ospf_db.db_flags)));
if (GET_BE_U_2(op->ospf_db.db_ifmtu)) {
ND_PRINT(", MTU: %u",
GET_BE_U_2(op->ospf_db.db_ifmtu));
}
ND_PRINT(", Sequence: 0x%08x", GET_BE_U_4(op->ospf_db.db_seq));
/* Print all the LS adv's */
lshp = op->ospf_db.db_lshdr;
while (((const u_char *)lshp < dataend) && ospf_print_lshdr(ndo, lshp) != -1) {
++lshp;
}
break;
case OSPF_TYPE_LS_REQ:
lsrp = op->ospf_lsr;
while ((const u_char *)lsrp < dataend) {
ND_TCHECK_SIZE(lsrp);
ND_PRINT("\n\t Advertising Router: %s, %s LSA (%u)",
GET_IPADDR_STRING(lsrp->ls_router),
tok2str(lsa_values,"unknown",GET_BE_U_4(lsrp->ls_type)),
GET_BE_U_4(lsrp->ls_type));
switch (GET_BE_U_4(lsrp->ls_type)) {
/* the LSA header for opaque LSAs was slightly changed */
case LS_TYPE_OPAQUE_LL:
case LS_TYPE_OPAQUE_AL:
case LS_TYPE_OPAQUE_DW:
ND_PRINT(", Opaque-Type: %s LSA (%u), Opaque-ID: %u",
tok2str(lsa_opaque_values, "unknown",GET_U_1(lsrp->un_ls_stateid.opaque_field.opaque_type)),
GET_U_1(lsrp->un_ls_stateid.opaque_field.opaque_type),
GET_BE_U_3(lsrp->un_ls_stateid.opaque_field.opaque_id));
break;
default:
ND_PRINT(", LSA-ID: %s",
GET_IPADDR_STRING(lsrp->un_ls_stateid.ls_stateid));
break;
}
++lsrp;
}
break;
case OSPF_TYPE_LS_UPDATE:
lsap = op->ospf_lsu.lsu_lsa;
lsa_count_max = GET_BE_U_4(op->ospf_lsu.lsu_count);
ND_PRINT(", %u LSA%s", lsa_count_max, PLURAL_SUFFIX(lsa_count_max));
for (lsa_count=1;lsa_count <= lsa_count_max;lsa_count++) {
ND_PRINT("\n\t LSA #%u", lsa_count);
lsap = (const struct lsa *)ospf_print_lsa(ndo, lsap);
if (lsap == NULL)
goto trunc;
}
break;
case OSPF_TYPE_LS_ACK:
lshp = op->ospf_lsa.lsa_lshdr;
while ((const u_char *)lshp < dataend) {
ospf_print_lshdr(ndo, lshp);
++lshp;
}
break;
default:
break;
}
return (0);
trunc:
return (1);
}
void
ospf_print(netdissect_options *ndo,
const u_char *bp, u_int length,
const u_char *bp2 _U_)
{
const struct ospfhdr *op;
const u_char *dataend;
const char *cp;
ndo->ndo_protocol = "ospf2";
op = (const struct ospfhdr *)bp;
/* XXX Before we do anything else, strip off the MD5 trailer */
if (GET_BE_U_2(op->ospf_authtype) == OSPF_AUTH_MD5) {
length -= OSPF_AUTH_MD5_LEN;
ndo->ndo_snapend -= OSPF_AUTH_MD5_LEN;
}
/* If the type is valid translate it, or just print the type */
/* value. If it's not valid, say so and return */
cp = tok2str(type2str, "unknown LS-type %u", GET_U_1(op->ospf_type));
ND_PRINT("OSPFv%u, %s, length %u", GET_U_1(op->ospf_version), cp,
length);
if (*cp == 'u')
return;
if (!ndo->ndo_vflag) { /* non verbose - so lets bail out here */
return;
}
if (length != GET_BE_U_2(op->ospf_len)) {
ND_PRINT(" [len %u]", GET_BE_U_2(op->ospf_len));
}
if (length > GET_BE_U_2(op->ospf_len)) {
dataend = bp + GET_BE_U_2(op->ospf_len);
} else {
dataend = bp + length;
}
ND_PRINT("\n\tRouter-ID %s", GET_IPADDR_STRING(op->ospf_routerid));
if (GET_IPV4_TO_NETWORK_ORDER(op->ospf_areaid) != 0)
ND_PRINT(", Area %s", GET_IPADDR_STRING(op->ospf_areaid));
else
ND_PRINT(", Backbone Area");
if (ndo->ndo_vflag) {
/* Print authentication data (should we really do this?) */
ND_TCHECK_LEN(op->ospf_authdata, sizeof(op->ospf_authdata));
ND_PRINT(", Authentication Type: %s (%u)",
tok2str(ospf_authtype_values, "unknown", GET_BE_U_2(op->ospf_authtype)),
GET_BE_U_2(op->ospf_authtype));
switch (GET_BE_U_2(op->ospf_authtype)) {
case OSPF_AUTH_NONE:
break;
case OSPF_AUTH_SIMPLE:
ND_PRINT("\n\tSimple text password: ");
nd_printjnp(ndo, op->ospf_authdata, OSPF_AUTH_SIMPLE_LEN);
break;
case OSPF_AUTH_MD5:
ND_PRINT("\n\tKey-ID: %u, Auth-Length: %u, Crypto Sequence Number: 0x%08x",
GET_U_1(op->ospf_authdata + 2),
GET_U_1(op->ospf_authdata + 3),
GET_BE_U_4((op->ospf_authdata) + 4));
break;
default:
return;
}
}
/* Do rest according to version. */
switch (GET_U_1(op->ospf_version)) {
case 2:
/* ospf version 2 */
if (ospf_decode_v2(ndo, op, dataend))
goto trunc;
if (length > GET_BE_U_2(op->ospf_len))
ospf_decode_lls(ndo, op, length);
break;
default:
ND_PRINT(" ospf [version %u]", GET_U_1(op->ospf_version));
break;
} /* end switch on version */
return;
trunc:
nd_trunc_longjmp(ndo);
}
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