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1 /*
2 * Copyright (c) 1998-2006 The TCPDUMP project
3 *
4 * Redistribution and use in source and binary forms, with or without
5 * modification, are permitted provided that: (1) source code
6 * distributions retain the above copyright notice and this paragraph
7 * in its entirety, and (2) distributions including binary code include
8 * the above copyright notice and this paragraph in its entirety in
9 * the documentation or other materials provided with the distribution.
10 * THIS SOFTWARE IS PROVIDED ``AS IS'' AND
11 * WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, WITHOUT
12 * LIMITATION, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
13 * FOR A PARTICULAR PURPOSE.
14 *
15 * Support for the IEEE Connectivity Fault Management Protocols as per 802.1ag.
16 *
17 * Original code by Hannes Gredler (hannes@juniper.net)
18 */
19
20 #define NETDISSECT_REWORKED
21 #ifdef HAVE_CONFIG_H
22 #include "config.h"
23 #endif
24
25 #include <tcpdump-stdinc.h>
26
27 #include <stdio.h>
28
29 #include "interface.h"
30 #include "extract.h"
31 #include "ether.h"
32 #include "addrtoname.h"
33 #include "oui.h"
34 #include "af.h"
35
36 struct cfm_common_header_t {
37 uint8_t mdlevel_version;
38 uint8_t opcode;
39 uint8_t flags;
40 uint8_t first_tlv_offset;
41 };
42
43 #define CFM_VERSION 0
44 #define CFM_EXTRACT_VERSION(x) (((x)&0x1f))
45 #define CFM_EXTRACT_MD_LEVEL(x) (((x)&0xe0)>>5)
46
47 #define CFM_OPCODE_CCM 1
48 #define CFM_OPCODE_LBR 2
49 #define CFM_OPCODE_LBM 3
50 #define CFM_OPCODE_LTR 4
51 #define CFM_OPCODE_LTM 5
52
53 static const struct tok cfm_opcode_values[] = {
54 { CFM_OPCODE_CCM, "Continouity Check Message"},
55 { CFM_OPCODE_LBR, "Loopback Reply"},
56 { CFM_OPCODE_LBM, "Loopback Message"},
57 { CFM_OPCODE_LTR, "Linktrace Reply"},
58 { CFM_OPCODE_LTM, "Linktrace Message"},
59 { 0, NULL}
60 };
61
62 /*
63 * Message Formats.
64 */
65 struct cfm_ccm_t {
66 uint8_t sequence[4];
67 uint8_t ma_epi[2];
68 uint8_t md_nameformat;
69 uint8_t md_namelength;
70 uint8_t md_name[46]; /* md name and short ma name */
71 uint8_t reserved_itu[16];
72 uint8_t reserved[6];
73 };
74
75 /*
76 * Timer Bases for the CCM Interval field.
77 * Expressed in units of seconds.
78 */
79 const float ccm_interval_base[8] = {0, 0.003333, 0.01, 0.1, 1, 10, 60, 600};
80 #define CCM_INTERVAL_MIN_MULTIPLIER 3.25
81 #define CCM_INTERVAL_MAX_MULTIPLIER 3.5
82
83 #define CFM_CCM_RDI_FLAG 0x80
84 #define CFM_EXTRACT_CCM_INTERVAL(x) (((x)&0x07))
85
86 #define CFM_CCM_MD_FORMAT_8021 0
87 #define CFM_CCM_MD_FORMAT_NONE 1
88 #define CFM_CCM_MD_FORMAT_DNS 2
89 #define CFM_CCM_MD_FORMAT_MAC 3
90 #define CFM_CCM_MD_FORMAT_CHAR 4
91
92 static const struct tok cfm_md_nameformat_values[] = {
93 { CFM_CCM_MD_FORMAT_8021, "IEEE 802.1"},
94 { CFM_CCM_MD_FORMAT_NONE, "No MD Name present"},
95 { CFM_CCM_MD_FORMAT_DNS, "DNS string"},
96 { CFM_CCM_MD_FORMAT_MAC, "MAC + 16Bit Integer"},
97 { CFM_CCM_MD_FORMAT_CHAR, "Character string"},
98 { 0, NULL}
99 };
100
101 #define CFM_CCM_MA_FORMAT_8021 0
102 #define CFM_CCM_MA_FORMAT_VID 1
103 #define CFM_CCM_MA_FORMAT_CHAR 2
104 #define CFM_CCM_MA_FORMAT_INT 3
105 #define CFM_CCM_MA_FORMAT_VPN 4
106
107 static const struct tok cfm_ma_nameformat_values[] = {
108 { CFM_CCM_MA_FORMAT_8021, "IEEE 802.1"},
109 { CFM_CCM_MA_FORMAT_VID, "Primary VID"},
110 { CFM_CCM_MA_FORMAT_CHAR, "Character string"},
111 { CFM_CCM_MA_FORMAT_INT, "16Bit Integer"},
112 { CFM_CCM_MA_FORMAT_VPN, "RFC2685 VPN-ID"},
113 { 0, NULL}
114 };
115
116 struct cfm_lbm_t {
117 uint8_t transaction_id[4];
118 uint8_t reserved[4];
119 };
120
121 struct cfm_ltm_t {
122 uint8_t transaction_id[4];
123 uint8_t egress_id[8];
124 uint8_t ttl;
125 uint8_t original_mac[ETHER_ADDR_LEN];
126 uint8_t target_mac[ETHER_ADDR_LEN];
127 uint8_t reserved[3];
128 };
129
130 static const struct tok cfm_ltm_flag_values[] = {
131 { 0x80, "Use Forwarding-DB only"},
132 { 0, NULL}
133 };
134
135 struct cfm_ltr_t {
136 uint8_t transaction_id[4];
137 uint8_t last_egress_id[8];
138 uint8_t next_egress_id[8];
139 uint8_t ttl;
140 uint8_t replay_action;
141 uint8_t reserved[6];
142 };
143
144 static const struct tok cfm_ltr_flag_values[] = {
145 { 0x80, "UseFDB Only"},
146 { 0x40, "FwdYes"},
147 { 0x20, "Terminal MEP"},
148 { 0, NULL}
149 };
150
151 static const struct tok cfm_ltr_replay_action_values[] = {
152 { 1, "Exact Match"},
153 { 2, "Filtering DB"},
154 { 3, "MIP CCM DB"},
155 { 0, NULL}
156 };
157
158
159 #define CFM_TLV_END 0
160 #define CFM_TLV_SENDER_ID 1
161 #define CFM_TLV_PORT_STATUS 2
162 #define CFM_TLV_INTERFACE_STATUS 3
163 #define CFM_TLV_DATA 4
164 #define CFM_TLV_REPLY_INGRESS 5
165 #define CFM_TLV_REPLY_EGRESS 6
166 #define CFM_TLV_PRIVATE 31
167
168 static const struct tok cfm_tlv_values[] = {
169 { CFM_TLV_END, "End"},
170 { CFM_TLV_SENDER_ID, "Sender ID"},
171 { CFM_TLV_PORT_STATUS, "Port status"},
172 { CFM_TLV_INTERFACE_STATUS, "Interface status"},
173 { CFM_TLV_DATA, "Data"},
174 { CFM_TLV_REPLY_INGRESS, "Reply Ingress"},
175 { CFM_TLV_REPLY_EGRESS, "Reply Egress"},
176 { CFM_TLV_PRIVATE, "Organization Specific"},
177 { 0, NULL}
178 };
179
180 /*
181 * TLVs
182 */
183
184 struct cfm_tlv_header_t {
185 uint8_t type;
186 uint8_t length[2];
187 };
188
189 /* FIXME define TLV formats */
190
191 static const struct tok cfm_tlv_port_status_values[] = {
192 { 1, "Blocked"},
193 { 2, "Up"},
194 { 0, NULL}
195 };
196
197 static const struct tok cfm_tlv_interface_status_values[] = {
198 { 1, "Up"},
199 { 2, "Down"},
200 { 3, "Testing"},
201 { 5, "Dormant"},
202 { 6, "not present"},
203 { 7, "lower Layer down"},
204 { 0, NULL}
205 };
206
207 #define CFM_CHASSIS_ID_CHASSIS_COMPONENT 1
208 #define CFM_CHASSIS_ID_INTERFACE_ALIAS 2
209 #define CFM_CHASSIS_ID_PORT_COMPONENT 3
210 #define CFM_CHASSIS_ID_MAC_ADDRESS 4
211 #define CFM_CHASSIS_ID_NETWORK_ADDRESS 5
212 #define CFM_CHASSIS_ID_INTERFACE_NAME 6
213 #define CFM_CHASSIS_ID_LOCAL 7
214
215 static const struct tok cfm_tlv_senderid_chassisid_values[] = {
216 { 0, "Reserved"},
217 { CFM_CHASSIS_ID_CHASSIS_COMPONENT, "Chassis component"},
218 { CFM_CHASSIS_ID_INTERFACE_ALIAS, "Interface alias"},
219 { CFM_CHASSIS_ID_PORT_COMPONENT, "Port component"},
220 { CFM_CHASSIS_ID_MAC_ADDRESS, "MAC address"},
221 { CFM_CHASSIS_ID_NETWORK_ADDRESS, "Network address"},
222 { CFM_CHASSIS_ID_INTERFACE_NAME, "Interface name"},
223 { CFM_CHASSIS_ID_LOCAL, "Locally assigned"},
224 { 0, NULL}
225 };
226
227
228 static int
229 cfm_mgmt_addr_print(netdissect_options *ndo,
230 register const u_char *tptr) {
231
232 u_int mgmt_addr_type;
233 u_int hexdump = FALSE;
234
235 /*
236 * Altough AFIs are tpically 2 octects wide,
237 * 802.1ab specifies that this field width
238 * is only once octet
239 */
240 mgmt_addr_type = *tptr;
241 ND_PRINT((ndo, "\n\t Management Address Type %s (%u)",
242 tok2str(af_values, "Unknown", mgmt_addr_type),
243 mgmt_addr_type));
244
245 /*
246 * Resolve the passed in Address.
247 */
248 switch(mgmt_addr_type) {
249 case AFNUM_INET:
250 ND_PRINT((ndo, ", %s", ipaddr_string(ndo, tptr + 1)));
251 break;
252
253 #ifdef INET6
254 case AFNUM_INET6:
255 ND_PRINT((ndo, ", %s", ip6addr_string(ndo, tptr + 1)));
256 break;
257 #endif
258
259 default:
260 hexdump = TRUE;
261 break;
262 }
263
264 return hexdump;
265 }
266
267 /*
268 * The egress-ID string is a 16-Bit string plus a MAC address.
269 */
270 static const char *
271 cfm_egress_id_string(netdissect_options *ndo, register const u_char *tptr) {
272 static char egress_id_buffer[80];
273
274 snprintf(egress_id_buffer, sizeof(egress_id_buffer),
275 "MAC 0x%4x-%s",
276 EXTRACT_16BITS(tptr),
277 etheraddr_string(ndo, tptr+2));
278
279 return egress_id_buffer;
280 }
281
282 void
283 cfm_print(netdissect_options *ndo,
284 register const u_char *pptr, register u_int length) {
285
286 const struct cfm_common_header_t *cfm_common_header;
287 const struct cfm_tlv_header_t *cfm_tlv_header;
288 const uint8_t *tptr, *tlv_ptr, *ma_name, *ma_nameformat, *ma_namelength;
289 u_int hexdump, tlen, cfm_tlv_len, cfm_tlv_type, ccm_interval;
290
291
292 union {
293 const struct cfm_ccm_t *cfm_ccm;
294 const struct cfm_lbm_t *cfm_lbm;
295 const struct cfm_ltm_t *cfm_ltm;
296 const struct cfm_ltr_t *cfm_ltr;
297 } msg_ptr;
298
299 tptr=pptr;
300 cfm_common_header = (const struct cfm_common_header_t *)pptr;
301 ND_TCHECK(*cfm_common_header);
302
303 /*
304 * Sanity checking of the header.
305 */
306 if (CFM_EXTRACT_VERSION(cfm_common_header->mdlevel_version) != CFM_VERSION) {
307 ND_PRINT((ndo, "CFMv%u not supported, length %u",
308 CFM_EXTRACT_VERSION(cfm_common_header->mdlevel_version), length));
309 return;
310 }
311
312 ND_PRINT((ndo, "CFMv%u %s, MD Level %u, length %u",
313 CFM_EXTRACT_VERSION(cfm_common_header->mdlevel_version),
314 tok2str(cfm_opcode_values, "unknown (%u)", cfm_common_header->opcode),
315 CFM_EXTRACT_MD_LEVEL(cfm_common_header->mdlevel_version),
316 length));
317
318 /*
319 * In non-verbose mode just print the opcode and md-level.
320 */
321 if (ndo->ndo_vflag < 1) {
322 return;
323 }
324
325 ND_PRINT((ndo, "\n\tFirst TLV offset %u", cfm_common_header->first_tlv_offset));
326
327 tptr += sizeof(const struct cfm_common_header_t);
328 tlen = length - sizeof(struct cfm_common_header_t);
329
330 switch (cfm_common_header->opcode) {
331 case CFM_OPCODE_CCM:
332 msg_ptr.cfm_ccm = (const struct cfm_ccm_t *)tptr;
333
334 ccm_interval = CFM_EXTRACT_CCM_INTERVAL(cfm_common_header->flags);
335 ND_PRINT((ndo, ", Flags [CCM Interval %u%s]",
336 ccm_interval,
337 cfm_common_header->flags & CFM_CCM_RDI_FLAG ?
338 ", RDI" : ""));
339
340 /*
341 * Resolve the CCM interval field.
342 */
343 if (ccm_interval) {
344 ND_PRINT((ndo, "\n\t CCM Interval %.3fs"
345 ", min CCM Lifetime %.3fs, max CCM Lifetime %.3fs",
346 ccm_interval_base[ccm_interval],
347 ccm_interval_base[ccm_interval] * CCM_INTERVAL_MIN_MULTIPLIER,
348 ccm_interval_base[ccm_interval] * CCM_INTERVAL_MAX_MULTIPLIER));
349 }
350
351 ND_PRINT((ndo, "\n\t Sequence Number 0x%08x, MA-End-Point-ID 0x%04x",
352 EXTRACT_32BITS(msg_ptr.cfm_ccm->sequence),
353 EXTRACT_16BITS(msg_ptr.cfm_ccm->ma_epi)));
354
355
356 /*
357 * Resolve the MD fields.
358 */
359 ND_PRINT((ndo, "\n\t MD Name Format %s (%u), MD Name length %u",
360 tok2str(cfm_md_nameformat_values, "Unknown",
361 msg_ptr.cfm_ccm->md_nameformat),
362 msg_ptr.cfm_ccm->md_nameformat,
363 msg_ptr.cfm_ccm->md_namelength));
364
365 if (msg_ptr.cfm_ccm->md_nameformat != CFM_CCM_MD_FORMAT_NONE) {
366 ND_PRINT((ndo, "\n\t MD Name: "));
367 switch (msg_ptr.cfm_ccm->md_nameformat) {
368 case CFM_CCM_MD_FORMAT_DNS:
369 case CFM_CCM_MD_FORMAT_CHAR:
370 safeputs(ndo, msg_ptr.cfm_ccm->md_name, msg_ptr.cfm_ccm->md_namelength);
371 break;
372
373 case CFM_CCM_MD_FORMAT_MAC:
374 ND_PRINT((ndo, "\n\t MAC %s", etheraddr_string(ndo,
375 msg_ptr.cfm_ccm->md_name)));
376 break;
377
378 /* FIXME add printers for those MD formats - hexdump for now */
379 case CFM_CCM_MA_FORMAT_8021:
380 default:
381 print_unknown_data(ndo, msg_ptr.cfm_ccm->md_name, "\n\t ",
382 msg_ptr.cfm_ccm->md_namelength);
383 }
384 }
385
386
387 /*
388 * Resolve the MA fields.
389 */
390 ma_nameformat = msg_ptr.cfm_ccm->md_name + msg_ptr.cfm_ccm->md_namelength;
391 ma_namelength = msg_ptr.cfm_ccm->md_name + msg_ptr.cfm_ccm->md_namelength + 1;
392 ma_name = msg_ptr.cfm_ccm->md_name + msg_ptr.cfm_ccm->md_namelength + 2;
393
394 ND_PRINT((ndo, "\n\t MA Name-Format %s (%u), MA name length %u",
395 tok2str(cfm_ma_nameformat_values, "Unknown",
396 *ma_nameformat),
397 *ma_nameformat,
398 *ma_namelength));
399
400 ND_PRINT((ndo, "\n\t MA Name: "));
401 switch (*ma_nameformat) {
402 case CFM_CCM_MA_FORMAT_CHAR:
403 safeputs(ndo, ma_name, *ma_namelength);
404 break;
405
406 /* FIXME add printers for those MA formats - hexdump for now */
407 case CFM_CCM_MA_FORMAT_8021:
408 case CFM_CCM_MA_FORMAT_VID:
409 case CFM_CCM_MA_FORMAT_INT:
410 case CFM_CCM_MA_FORMAT_VPN:
411 default:
412 print_unknown_data(ndo, ma_name, "\n\t ", *ma_namelength);
413 }
414 break;
415
416 case CFM_OPCODE_LTM:
417 msg_ptr.cfm_ltm = (const struct cfm_ltm_t *)tptr;
418
419 ND_PRINT((ndo, ", Flags [%s]",
420 bittok2str(cfm_ltm_flag_values, "none", cfm_common_header->flags)));
421
422 ND_PRINT((ndo, "\n\t Transaction-ID 0x%08x, Egress-ID %s, ttl %u",
423 EXTRACT_32BITS(msg_ptr.cfm_ltm->transaction_id),
424 cfm_egress_id_string(ndo, msg_ptr.cfm_ltm->egress_id),
425 msg_ptr.cfm_ltm->ttl));
426
427 ND_PRINT((ndo, "\n\t Original-MAC %s, Target-MAC %s",
428 etheraddr_string(ndo, msg_ptr.cfm_ltm->original_mac),
429 etheraddr_string(ndo, msg_ptr.cfm_ltm->target_mac)));
430 break;
431
432 case CFM_OPCODE_LTR:
433 msg_ptr.cfm_ltr = (const struct cfm_ltr_t *)tptr;
434
435 ND_PRINT((ndo, ", Flags [%s]",
436 bittok2str(cfm_ltr_flag_values, "none", cfm_common_header->flags)));
437
438 ND_PRINT((ndo, "\n\t Transaction-ID 0x%08x, Last-Egress-ID %s",
439 EXTRACT_32BITS(msg_ptr.cfm_ltr->transaction_id),
440 cfm_egress_id_string(ndo, msg_ptr.cfm_ltr->last_egress_id)));
441
442 ND_PRINT((ndo, "\n\t Next-Egress-ID %s, ttl %u",
443 cfm_egress_id_string(ndo, msg_ptr.cfm_ltr->next_egress_id),
444 msg_ptr.cfm_ltr->ttl));
445
446 ND_PRINT((ndo, "\n\t Replay-Action %s (%u)",
447 tok2str(cfm_ltr_replay_action_values,
448 "Unknown",
449 msg_ptr.cfm_ltr->replay_action),
450 msg_ptr.cfm_ltr->replay_action));
451 break;
452
453 /*
454 * No message decoder yet.
455 * Hexdump everything up until the start of the TLVs
456 */
457 case CFM_OPCODE_LBR:
458 case CFM_OPCODE_LBM:
459 default:
460 if (tlen > cfm_common_header->first_tlv_offset) {
461 print_unknown_data(ndo, tptr, "\n\t ",
462 tlen - cfm_common_header->first_tlv_offset);
463 }
464 break;
465 }
466
467 /*
468 * Sanity check for not walking off.
469 */
470 if (tlen <= cfm_common_header->first_tlv_offset) {
471 return;
472 }
473
474 tptr += cfm_common_header->first_tlv_offset;
475 tlen -= cfm_common_header->first_tlv_offset;
476
477 while (tlen > 0) {
478 cfm_tlv_header = (const struct cfm_tlv_header_t *)tptr;
479
480 /* Enough to read the tlv type ? */
481 ND_TCHECK2(*tptr, 1);
482 cfm_tlv_type=cfm_tlv_header->type;
483
484 if (cfm_tlv_type != CFM_TLV_END) {
485 /* did we capture enough for fully decoding the object header ? */
486 ND_TCHECK2(*tptr, sizeof(struct cfm_tlv_header_t));
487 cfm_tlv_len=EXTRACT_16BITS(&cfm_tlv_header->length);
488 } else {
489 cfm_tlv_len = 0;
490 }
491
492 ND_PRINT((ndo, "\n\t%s TLV (0x%02x), length %u",
493 tok2str(cfm_tlv_values, "Unknown", cfm_tlv_type),
494 cfm_tlv_type,
495 cfm_tlv_len));
496
497 /* sanity check for not walking off and infinite loop check. */
498 if ((cfm_tlv_type != CFM_TLV_END) &&
499 ((cfm_tlv_len + sizeof(struct cfm_tlv_header_t) > tlen) ||
500 (!cfm_tlv_len))) {
501 print_unknown_data(ndo, tptr, "\n\t ", tlen);
502 return;
503 }
504
505 tptr += sizeof(struct cfm_tlv_header_t);
506 tlen -= sizeof(struct cfm_tlv_header_t);
507 tlv_ptr = tptr;
508
509 /* did we capture enough for fully decoding the object ? */
510 if (cfm_tlv_type != CFM_TLV_END) {
511 ND_TCHECK2(*tptr, cfm_tlv_len);
512 }
513 hexdump = FALSE;
514
515 switch(cfm_tlv_type) {
516 case CFM_TLV_END:
517 /* we are done - bail out */
518 return;
519
520 case CFM_TLV_PORT_STATUS:
521 ND_PRINT((ndo, ", Status: %s (%u)",
522 tok2str(cfm_tlv_port_status_values, "Unknown", *tptr),
523 *tptr));
524 break;
525
526 case CFM_TLV_INTERFACE_STATUS:
527 ND_PRINT((ndo, ", Status: %s (%u)",
528 tok2str(cfm_tlv_interface_status_values, "Unknown", *tptr),
529 *tptr));
530 break;
531
532 case CFM_TLV_PRIVATE:
533 ND_PRINT((ndo, ", Vendor: %s (%u), Sub-Type %u",
534 tok2str(oui_values,"Unknown", EXTRACT_24BITS(tptr)),
535 EXTRACT_24BITS(tptr),
536 *(tptr + 3)));
537 hexdump = TRUE;
538 break;
539
540 case CFM_TLV_SENDER_ID:
541 {
542 u_int chassis_id_type, chassis_id_length;
543 u_int mgmt_addr_length;
544
545 /*
546 * Check if there is a Chassis-ID.
547 */
548 chassis_id_length = *tptr;
549 if (chassis_id_length > tlen) {
550 hexdump = TRUE;
551 break;
552 }
553
554 tptr++;
555 tlen--;
556
557 if (chassis_id_length) {
558 chassis_id_type = *tptr;
559 ND_PRINT((ndo, "\n\t Chassis-ID Type %s (%u), Chassis-ID length %u",
560 tok2str(cfm_tlv_senderid_chassisid_values,
561 "Unknown",
562 chassis_id_type),
563 chassis_id_type,
564 chassis_id_length));
565
566 switch (chassis_id_type) {
567 case CFM_CHASSIS_ID_MAC_ADDRESS:
568 ND_PRINT((ndo, "\n\t MAC %s", etheraddr_string(ndo, tptr + 1)));
569 break;
570
571 case CFM_CHASSIS_ID_NETWORK_ADDRESS:
572 hexdump |= cfm_mgmt_addr_print(ndo, tptr);
573 break;
574
575 case CFM_CHASSIS_ID_INTERFACE_NAME: /* fall through */
576 case CFM_CHASSIS_ID_INTERFACE_ALIAS:
577 case CFM_CHASSIS_ID_LOCAL:
578 case CFM_CHASSIS_ID_CHASSIS_COMPONENT:
579 case CFM_CHASSIS_ID_PORT_COMPONENT:
580 safeputs(ndo, tptr + 1, chassis_id_length);
581 break;
582
583 default:
584 hexdump = TRUE;
585 break;
586 }
587 }
588
589 tptr += chassis_id_length;
590 tlen -= chassis_id_length;
591
592 /*
593 * Check if there is a Management Address.
594 */
595 mgmt_addr_length = *tptr;
596 if (mgmt_addr_length > tlen) {
597 hexdump = TRUE;
598 break;
599 }
600
601 tptr++;
602 tlen--;
603
604 if (mgmt_addr_length) {
605 hexdump |= cfm_mgmt_addr_print(ndo, tptr);
606 }
607
608 tptr += mgmt_addr_length;
609 tlen -= mgmt_addr_length;
610
611 }
612 break;
613
614 /*
615 * FIXME those are the defined TLVs that lack a decoder
616 * you are welcome to contribute code ;-)
617 */
618
619 case CFM_TLV_DATA:
620 case CFM_TLV_REPLY_INGRESS:
621 case CFM_TLV_REPLY_EGRESS:
622 default:
623 hexdump = TRUE;
624 break;
625 }
626 /* do we want to see an additional hexdump ? */
627 if (hexdump || ndo->ndo_vflag > 1)
628 print_unknown_data(ndo, tlv_ptr, "\n\t ", cfm_tlv_len);
629
630 tptr+=cfm_tlv_len;
631 tlen-=cfm_tlv_len;
632 }
633 return;
634 trunc:
635 ND_PRINT((ndo, "\n\t\t packet exceeded snapshot"));
636 }
[mirror] the TCPdump network dissector