1tcprewrite(1) User Commands tcprewrite(1)
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6 tcprewrite - Rewrite the packets in a pcap file.
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9 tcprewrite [-flags] [-flag [value]] [--option-name[[=| ]value]]
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11 All arguments must be options.
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13
15 Tcprewrite is a tool to rewrite packets stored in pcap(3) file format,
16 such as created by tools such as tcpdump(1) and wireshark(1). Once a
17 pcap file has had it's packets rewritten, they can be replayed back out
18 on the network using tcpreplay(1).
19
20 tcprewrite currently supports reading the following DLT types:
21
22 DLT_C_HDLC aka Cisco HDLC
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24 DLT_EN10MB aka Ethernet
25
26 DLT_LINUX_SLL aka Linux Cooked Socket
27
28 DLT_RAW aka RAW IP
29
30 DLT_NULL aka BSD Loopback
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32 DLT_LOOP aka OpenBSD Loopback
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34 DLT_IEEE802_11 aka 802.11a/b/g
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36 DLT_IEEE802_11_RADIO aka 802.11a/b/g with Radiotap headers
37
38 DLT_JUNIPER_ETHER aka Juniper Encapsulated Ethernet
39
40 DLT_PPP_SERIAL aka PPP over Serial
41
42 Please see the --dlt option for supported DLT types for writing.
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44 The packet editing features of tcprewrite which distinguish between
45 "client" and "server" traffic requires a tcpprep(1) cache file.
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47 For more details, please see the Tcpreplay Manual at: http://tcpre‐
48 play.appneta.com
49
51
52 -r string, --portmap=string
53 Rewrite TCP/UDP ports. This option may appear up to 9999 times.
54
55 Specify a list of comma delimited port mappings consisting of
56 colon delimited port number pairs. Each colon delimited port
57 pair consists of the port to match followed by the port number
58 to rewrite.
59
60 Examples:
61 --portmap=80:8000 --portmap=8080:80 # 80->8000 and 8080->80
62 --portmap=8000,8080,88888:80 # 3 different ports become 80
63 --portmap=8000-8999:80 # ports 8000 to 8999 become 80
64
65 -s number, --seed=number
66 Randomize src/dst IPv4/v6 addresses w/ given seed. This option
67 may appear up to 1 times. This option must not appear in combi‐
68 nation with any of the following options: fuzz-seed. This op‐
69 tion takes an integer number as its argument.
70
71 Causes the source and destination IPv4/v6 addresses to be pseudo
72 randomized but still maintain client/server relationships.
73 Since the randomization is deterministic based on the seed, you
74 can reuse the same seed value to recreate the traffic.
75
76 -N string, --pnat=string
77 Rewrite IPv4/v6 addresses using pseudo-NAT. This option may ap‐
78 pear up to 2 times. This option must not appear in combination
79 with any of the following options: srcipmap.
80
81 Takes a comma delimited series of colon delimited CIDR netblock
82 pairs. Each netblock pair is evaluated in order against the IP
83 addresses. If the IP address in the packet matches the first
84 netblock, it is rewritten using the second netblock as a mask
85 against the high order bits.
86
87 IPv4 Example:
88 --pnat=192.168.0.0/16:10.77.0.0/16,172.16.0.0/12:10.1.0.0/24
89 IPv6 Example:
90 --pnat=[2001:db8::/32]:[dead::/16],[2001:db8::/32]:[::ffff:0:0/96]
91
92 -S string, --srcipmap=string
93 Rewrite source IPv4/v6 addresses using pseudo-NAT. This option
94 may appear up to 1 times. This option must not appear in combi‐
95 nation with any of the following options: pnat.
96
97 Works just like the --pnat option, but only affects the source
98 IP addresses in the IPv4/v6 header.
99
100 -D string, --dstipmap=string
101 Rewrite destination IPv4/v6 addresses using pseudo-NAT. This
102 option may appear up to 1 times. This option must not appear in
103 combination with any of the following options: pnat.
104
105 Works just like the --pnat option, but only affects the destina‐
106 tion IP addresses in the IPv4/v6 header.
107
108 -e string, --endpoints=string
109 Rewrite IP addresses to be between two endpoints. This option
110 may appear up to 1 times. This option must appear in combina‐
111 tion with the following options: cachefile.
112
113 Takes a pair of colon delimited IPv4/v6 addresses which will be
114 used to rewrite all traffic to appear to be between the two IP
115 addresses.
116
117 IPv4 Example:
118 --endpoints=172.16.0.1:172.16.0.2
119 IPv6 Example:
120 --endpoints=[2001:db8::dead:beef]:[::ffff:0:0:ac:f:0:2]
121
122 --tcp-sequence=number
123 Change TCP Sequence (and ACK) numbers /w given seed. This op‐
124 tion takes an integer number as its argument. The value of num‐
125 ber is constrained to being:
126 greater than or equal to 1
127 The default number for this option is:
128 0
129
130 Change all TCP sequence numbers, and related sequence-acknowl‐
131 edgement numbers. They will be shifted by a random amount based
132 on the provided seed.
133
134 -b, --skipbroadcast
135 Skip rewriting broadcast/multicast IPv4/v6 addresses.
136
137 By default --seed, --pnat and --endpoints will rewrite broadcast
138 and multicast IPv4/v6 and MAC addresses. Setting this flag will
139 keep broadcast/multicast IPv4/v6 and MAC addresses from being
140 rewritten.
141
142 -C, --fixcsum
143 Force recalculation of IPv4/TCP/UDP header checksums.
144
145 Causes each IPv4/v6 packet to have their checksums recalculated
146 and fixed. Automatically enabled for packets modified with
147 --seed, --pnat, --endpoints or --fixlen.
148
149 -m number, --mtu=number
150 Override default MTU length (1500 bytes). This option may ap‐
151 pear up to 1 times. This option takes an integer number as its
152 argument. The value of number is constrained to being:
153 in the range 1 through MAX_SNAPLEN
154
155 Override the default 1500 byte MTU size for determining the max‐
156 imum padding length (--fixlen=pad) or when truncating (--mtu-
157 trunc).
158
159 --mtu-trunc
160 Truncate packets larger then specified MTU. This option may ap‐
161 pear up to 1 times.
162
163 Similar to --fixlen, this option will truncate data in packets
164 from Layer 3 and above to be no larger then the MTU.
165
166 -E, --efcs
167 Remove Ethernet checksums (FCS) from end of frames.
168
169 Note, this option is pretty dangerous! We do not actually check
170 to see if a FCS actually exists in the frame, we just blindly
171 delete the last 4 bytes. Hence, you should only use this if you
172 know know that your OS provides the FCS when reading raw pack‐
173 ets.
174
175 --ttl=string
176 Modify the IPv4/v6 TTL/Hop Limit.
177
178 Allows you to modify the TTL/Hop Limit of all the IPv4/v6 pack‐
179 ets. Specify a number to hard-code the value or +/-value to in‐
180 crease or decrease by the value provided (limited to 1-255).
181
182 Examples:
183 --ttl=10
184 --ttl=+7
185 --ttl=-64
186
187 --tos=number
188 Set the IPv4 TOS/DiffServ/ECN byte. This option may appear up
189 to 1 times. This option takes an integer number as its argu‐
190 ment. The value of number is constrained to being:
191 in the range 0 through 255
192
193 Allows you to override the TOS (also known as DiffServ/ECN)
194 value in IPv4.
195
196 --tclass=number
197 Set the IPv6 Traffic Class byte. This option may appear up to 1
198 times. This option takes an integer number as its argument.
199 The value of number is constrained to being:
200 in the range 0 through 255
201
202 Allows you to override the IPv6 Traffic Class field.
203
204 --flowlabel=number
205 Set the IPv6 Flow Label. This option may appear up to 1 times.
206 This option takes an integer number as its argument. The value
207 of number is constrained to being:
208 in the range 0 through 1048575
209
210 Allows you to override the 20bit IPv6 Flow Label field. Has no
211 effect on IPv4 packets.
212
213 -F string, --fixlen=string
214 Pad or truncate packet data to match header length. This option
215 may appear up to 1 times.
216
217 Packets may be truncated during capture if the snaplen is
218 smaller then the packet. This option allows you to modify the
219 packet to pad the packet back out to the size stored in the
220 IPv4/v6 header or rewrite the IP header total length to reflect
221 the stored packet length.
222
223 pad Truncated packets will be padded out so that the packet
224 length matches the IPv4 total length
225
226 trunc Truncated packets will have their IPv4 total length field
227 rewritten to match the actual packet length
228
229 del Delete the packet
230
231 --fuzz-seed=number
232 Fuzz 1 in X packets. Edit bytes, length, or emulate packet drop.
233 This option takes an integer number as its argument. The value
234 of number is constrained to being:
235 greater than or equal to 0
236 The default number for this option is:
237 0
238
239 This fuzzing was designed as to test layer 7 protocols such as
240 voip protocols. It modifies randomly 1 out of X packets (where
241 X = --fuzz-factor) in order for stateful protocols to cover more
242 of their code. The random fuzzing actions focus on data start
243 and end because it often is the part of the data application
244 protocols base their decisions on.
245
246 Possible fuzzing actions list:
247 * drop packet
248 * reduce packet size
249 * edit packet Bytes:
250 * Not all Bytes have the same probability of appearance in
251 real life.
252 Replace with 0x00, 0xFF, or a random byte with equal like‐
253 lihood.
254 * Not all Bytes have the same significance in a packet.
255 Replace the start, the end, or the middle of the packet
256 with equal likelihood.
257 * do nothing (7 out of 8 packets)
258
259 --fuzz-factor=number
260 Set the Fuzz 1 in X packet ratio (default 1 in 8 packets). This
261 option must appear in combination with the following options:
262 fuzz-seed. This option takes an integer number as its argument.
263 The value of number is constrained to being:
264 greater than or equal to 1
265 The default number for this option is:
266 8
267
268 Sets the ratio of for --fuzz-seed option. By default this value
269 is 8, which means 1 in 8 packets are modified by fuzzing. Note
270 that this ratio is based on the random number generated by the
271 supplied fuzz seed. Therefore by default you cannot expect that
272 exactly every eighth packet will be modified.
273
274 --skipl2broadcast
275 Skip rewriting broadcast/multicast Layer 2 addresses.
276
277 By default, editing Layer 2 addresses will rewrite broadcast and
278 multicast MAC addresses. Setting this flag will keep broad‐
279 cast/multicast MAC addresses from being rewritten.
280
281 --dlt=string
282 Override output DLT encapsulation. This option may appear up to
283 1 times.
284
285 By default, no DLT (data link type) conversion will be made. To
286 change the DLT type of the output pcap, select one of the fol‐
287 lowing values:
288
289 enet Ethernet aka DLT_EN10MB
290
291 hdlc Cisco HDLC aka DLT_C_HDLC
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293 jnpr_eth Juniper Ethernet DLT_C_JNPR_ETHER
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295 pppserial PPP Serial aka DLT_PPP_SERIAL
296
297 user User specified Layer 2 header and DLT type
298
299 --enet-dmac=string
300 Override destination ethernet MAC addresses. This option may
301 appear up to 1 times.
302
303 Takes a pair of comma deliminated ethernet MAC addresses which
304 will replace the destination MAC address of outbound packets.
305 The first MAC address will be used for the server to client
306 traffic and the optional second MAC address will be used for the
307 client to server traffic.
308
309 Example:
310 --enet-dmac=00:12:13:14:15:16,00:22:33:44:55:66
311
312 --enet-smac=string
313 Override source ethernet MAC addresses. This option may appear
314 up to 1 times.
315
316 Takes a pair of comma deliminated ethernet MAC addresses which
317 will replace the source MAC address of outbound packets. The
318 first MAC address will be used for the server to client traffic
319 and the optional second MAC address will be used for the client
320 to server traffic.
321
322 Example:
323 --enet-smac=00:12:13:14:15:16,00:22:33:44:55:66
324
325 --enet-subsmac=string
326 Substitute MAC addresses. This option may appear up to 9999
327 times.
328
329 Allows you to rewrite ethernet MAC addresses of packets. It
330 takes comma delimited pair or MACs address and rewrites all oc‐
331 currences of the first MAC with the value of the second MAC.
332 Example:
333 --enet-subsmac=00:12:13:14:15:16,00:22:33:44:55:66
334
335 --enet-mac-seed=number
336 Randomize MAC addresses. This option may appear up to 1 times.
337 This option must not appear in combination with any of the fol‐
338 lowing options: enet-smac, enet-dmac, enet-subsmac. This option
339 takes an integer number as its argument.
340
341 Allows you to randomize ethernet MAC addresses of packets,
342 mostly like what --seed option does for IPv4/IPv6 addresses.
343
344 --enet-mac-seed-keep-bytes=number
345 Randomize MAC addresses. This option may appear up to 1 times.
346 This option must appear in combination with the following op‐
347 tions: enet-mac-seed. This option takes an integer number as
348 its argument. The value of number is constrained to being:
349 in the range 1 through 6
350
351 Keep some bytes untouched when usinging --enet-mac-seed option.
352
353 --enet-vlan=string
354 Specify ethernet 802.1q VLAN tag mode. This option may appear
355 up to 1 times.
356
357 Allows you to rewrite ethernet frames to add a 802.1q header to
358 standard 802.3 ethernet headers or remove the 802.1q VLAN tag
359 information.
360
361 add Rewrites the existing 802.3 ethernet header as an 802.1q
362 VLAN header
363
364 del Rewrites the existing 802.1q VLAN header as an 802.3 ether‐
365 net header
366
367 --enet-vlan-tag=number
368 Specify the new ethernet 802.1q VLAN tag value. This option may
369 appear up to 1 times. This option must appear in combination
370 with the following options: enet-vlan. This option takes an in‐
371 teger number as its argument. The value of number is con‐
372 strained to being:
373 in the range 0 through 4095
374
375
376 --enet-vlan-cfi=number
377 Specify the ethernet 802.1q VLAN CFI value. This option may ap‐
378 pear up to 1 times. This option must appear in combination with
379 the following options: enet-vlan. This option takes an integer
380 number as its argument. The value of number is constrained to
381 being:
382 in the range 0 through 1
383
384
385 --enet-vlan-pri=number
386 Specify the ethernet 802.1q VLAN priority. This option may ap‐
387 pear up to 1 times. This option must appear in combination with
388 the following options: enet-vlan. This option takes an integer
389 number as its argument. The value of number is constrained to
390 being:
391 in the range 0 through 7
392
393
394 --hdlc-control=number
395 Specify HDLC control value. This option may appear up to 1
396 times. This option takes an integer number as its argument.
397
398 The Cisco HDLC header has a 1 byte "control" field. Apparently
399 this should always be 0, but if you can use any 1 byte value.
400
401 --hdlc-address=number
402 Specify HDLC address. This option may appear up to 1 times.
403 This option takes an integer number as its argument.
404
405 The Cisco HDLC header has a 1 byte "address" field which has two
406 valid values:
407
408 0x0F Unicast
409
410 0xBF Broadcast
411 You can however specify any single byte value.
412
413 --user-dlt=number
414 Set output file DLT type. This option may appear up to 1 times.
415 This option takes an integer number as its argument.
416
417 Set the DLT value of the output pcap file.
418
419 --user-dlink=string
420 Rewrite Data-Link layer with user specified data. This option
421 may appear up to 2 times.
422
423 Provide a series of comma deliminated hex values which will be
424 used to rewrite or create the Layer 2 header of the packets.
425 The first instance of this argument will rewrite both server and
426 client traffic, but if this argument is specified a second time,
427 it will be used for the client traffic.
428
429 Example:
430 --user-dlink=01,02,03,04,05,06,00,1A,2B,3C,4D,5E,6F,08,00
431
432 -d number, --dbug=number
433 Enable debugging output. This option may appear up to 1 times.
434 This option takes an integer number as its argument. The value
435 of number is constrained to being:
436 in the range 0 through 5
437 The default number for this option is:
438 0
439
440 If configured with --enable-debug, then you can specify a ver‐
441 bosity level for debugging output. Higher numbers increase ver‐
442 bosity.
443
444 -i string, --infile=string
445 Input pcap file to be processed. This option may appear up to 1
446 times.
447
448
449 -o string, --outfile=string
450 Output pcap file. This option may appear up to 1 times.
451
452
453 -c string, --cachefile=string
454 Split traffic via tcpprep cache file. This option may appear up
455 to 1 times.
456
457 Use tcpprep cache file to split traffic based upon client/server
458 relationships.
459
460 -v, --verbose
461 Print decoded packets via tcpdump to STDOUT. This option may
462 appear up to 1 times.
463
464
465 -A string, --decode=string
466 Arguments passed to tcpdump decoder. This option may appear up
467 to 1 times. This option must appear in combination with the
468 following options: verbose.
469
470 When enabling verbose mode (-v) you may also specify one or more
471 additional arguments to pass to tcpdump to modify the way pack‐
472 ets are decoded. By default, -n and -l are used. Be sure to
473 quote the arguments so that they are not interpreted by
474 tcprewrite. Please see the tcpdump(1) man page for a complete
475 list of options.
476
477 --fragroute=string
478 Parse fragroute configuration file. This option may appear up
479 to 1 times.
480
481 Enable advanced evasion techniques using the built-in fra‐
482 groute(8) engine. See the fragroute(8) man page for more de‐
483 tails. Important: tcprewrite does not support the delay, echo
484 or print commands.
485
486 --fragdir=string
487 Which flows to apply fragroute to: c2s, s2c, both. This option
488 may appear up to 1 times. This option must appear in combina‐
489 tion with the following options: cachefile.
490
491 Apply the fragroute engine to packets going c2s, s2c or both
492 when using a cache file.
493
494 --skip-soft-errors
495 Skip writing packets with soft errors. This option may appear
496 up to 1 times.
497
498 In some cases, packets can not be decoded or the requested edit‐
499 ing is not possible. Normally these packets are written to the
500 output file unedited so that tcpprep cache files can still be
501 used, but if you wish, these packets can be suppressed.
502
503 One example of this is 802.11 management frames which contain no
504 data.
505
506 -V, --version
507 Print version information.
508
509
510 -h, --less-help
511 Display less usage information and exit.
512
513
514 -H, --help
515 Display usage information and exit.
516
517 -!, --more-help
518 Pass the extended usage information through a pager.
519
520 --save-opts [=cfgfile]
521 Save the option state to cfgfile. The default is the last con‐
522 figuration file listed in the OPTION PRESETS section, below.
523 The command will exit after updating the config file.
524
525 --load-opts=cfgfile, --no-load-opts
526 Load options from cfgfile. The no-load-opts form will disable
527 the loading of earlier config/rc/ini files. --no-load-opts is
528 handled early, out of order.
529
531 Any option that is not marked as not presettable may be preset by load‐
532 ing values from configuration ("RC" or ".INI") file(s). The homerc
533 file is "$$/", unless that is a directory. In that case, the file
534 ".tcprewriterc" is searched for within that directory.
535
537 See OPTION PRESETS for configuration files.
538
540 One of the following exit values will be returned:
541
542 0 (EXIT_SUCCESS)
543 Successful program execution.
544
545 1 (EXIT_FAILURE)
546 The operation failed or the command syntax was not valid.
547
548 66 (EX_NOINPUT)
549 A specified configuration file could not be loaded.
550
551 70 (EX_SOFTWARE)
552 libopts had an internal operational error. Please report it to
553 autogen-users@lists.sourceforge.net. Thank you.
554
556 Copyright 2013-2018 Fred Klassen - AppNeta Copyright 2000-2012 Aaron
557 Turner For support please use the tcpreplay-users@lists.sourceforge.net
558 mailing list. The latest version of this software is always available
559 from: http://tcpreplay.appneta.com/
560
562 Copyright (C) 2000-2018 Aaron Turner and Fred Klassen all rights re‐
563 served. This program is released under the terms of the GNU General
564 Public License, version 3 or later.
565
567 Please send bug reports to: tcpreplay-users@lists.sourceforge.net
568
570 This manual page was AutoGen-erated from the tcprewrite option defini‐
571 tions.
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575tcprewrite 01 May 2021 tcprewrite(1)