wireshark-filter(4) The Wireshark Network Analyzer wireshark-filter(4)

NAME

 wireshark-filter - Wireshark display filter syntax and reference

SYNOPSIS

 wireshark [other options]
 [ -Y "display filter expression" | b<--display-filter "display filter
 expression" ]>
 tshark [other options] [ -Y "display filter expression" ]

DESCRIPTION

 Wireshark and TShark share a powerful filter engine that helps remove
 the noise from a packet trace and lets you see only the packets that
 interest you. If a packet meets the requirements expressed in your
 filter, then it is displayed in the list of packets. Display filters
 let you compare the fields within a protocol against a specific value,
 compare fields against fields, and check the existence of specified
 fields or protocols.
 Filters are also used by other features such as statistics generation
 and packet list colorization (the latter is only available to
 Wireshark). This manual page describes their syntax. A comprehensive
 reference of filter fields can be found within Wireshark and in the
 display filter reference at <https://www.wireshark.org/docs/dfref/>.

FILTER SYNTAX

 Check whether a field or protocol exists
 The simplest filter allows you to check for the existence of a protocol
 or field. If you want to see all packets which contain the IP
 protocol, the filter would be "ip" (without the quotation marks). To
 see all packets that contain a Token-Ring RIF field, use "tr.rif".
 Think of a protocol or field in a filter as implicitly having the
 "exists" operator.
 Comparison operators
 Fields can also be compared against values. The comparison operators
 can be expressed either through English-like abbreviations or through
 C-like symbols:
 eq, == Equal
 ne, != Not Equal
 gt, > Greater Than
 lt, < Less Than
 ge, >= Greater than or Equal to
 le, <= Less than or Equal to
 Search and match operators
 Additional operators exist expressed only in English, not C-like
 syntax:
 contains Does the protocol, field or slice contain a value
 matches, ~ Does the protocol or text string match the given
 case-insensitive Perl-compatible regular expression
 The "contains" operator allows a filter to search for a sequence of
 characters, expressed as a string (quoted or unquoted), or bytes,
 expressed as a byte array, or for a single character, expressed as a
 C-style character constant. For example, to search for a given HTTP
 URL in a capture, the following filter can be used:
 http contains "https://www.wireshark.org"
 The "contains" operator cannot be used on atomic fields, such as
 numbers or IP addresses.
 The "matches" or "~" operator allows a filter to apply to a specified
 Perl-compatible regular expression (PCRE). The "matches" operator is
 only implemented for protocols and for protocol fields with a text
 string representation. Matches are case-insensitive by default. For
 example, to search for a given WAP WSP User-Agent, you can write:
 wsp.user_agent matches "cldc"
 This would match "cldc", "CLDC", "cLdC" or any other combination of
 upper and lower case letters.
 You can force case sensitivity using
 wsp.user_agent matches "(?-i)cldc"
 This is an example of PCRE's (?option) construct. (?-i) performs a
 case-sensitive pattern match but other options can be specified as
 well. More information can be found in the pcrepattern(3)  man page at
 <https://perldoc.perl.org/perlre.html >).
 Functions
 The filter language has the following functions:
 upper(string-field) - converts a string field to uppercase
 lower(string-field) - converts a string field to lowercase
 len(field) - returns the byte length of a string or bytes field
 count(field) - returns the number of field occurrences in a frame
 string(field) - converts a non-string field to string
 upper() and lower() are useful for performing case-insensitive string
 comparisons. For example:
 upper(ncp.nds_stream_name) contains "MACRO"
 lower(mount.dump.hostname) == "angel"
 string() converts a field value to a string, suitable for use with
 operators like "matches" or "contains". Integer fields are converted to
 their decimal representation. It can be used with IP/Ethernet
 addresses (as well as others), but not with string or byte fields. For
 example:
 string(frame.number) matches "[13579]$"
 gives you all the odd packets.
 Protocol field types
 Each protocol field is typed. The types are:
 ASN.1 object identifier
 Boolean
 Character string
 Compiled Perl-Compatible Regular Expression (GRegex) object
 Date and time
 Ethernet or other MAC address
 EUI64 address
 Floating point (double-precision)
 Floating point (single-precision)
 Frame number
 Globally Unique Identifier
 IPv4 address
 IPv6 address
 IPX network number
 Label
 Protocol
 Sequence of bytes
 Signed integer, 1, 2, 3, 4, or 8 bytes
 Time offset
 Unsigned integer, 1, 2, 3, 4, or 8 bytes
 1-byte ASCII character
 An integer may be expressed in decimal, octal, or hexadecimal notation,
 or as a C-style character constant. The following six display filters
 are equivalent:
 frame.pkt_len > 10
 frame.pkt_len > 012
 frame.pkt_len > 0xa
 frame.pkt_len > '\n'
 frame.pkt_len > '\xa'
 frame.pkt_len > '012円'
 Boolean values are either true or false. In a display filter
 expression testing the value of a Boolean field, "true" is expressed as
 1 or any other non-zero value, and "false" is expressed as zero. For
 example, a token-ring packet's source route field is Boolean. To find
 any source-routed packets, a display filter would be:
 tr.sr == 1
 Non source-routed packets can be found with:
 tr.sr == 0
 Ethernet addresses and byte arrays are represented by hex digits. The
 hex digits may be separated by colons, periods, or hyphens:
 eth.dst eq ff:ff:ff:ff:ff:ff
 aim.data == 0.1.0.d
 fddi.src == aa-aa-aa-aa-aa-aa
 echo.data == 7a
 IPv4 addresses can be represented in either dotted decimal notation or
 by using the hostname:
 ip.dst eq www.mit.edu
 ip.src == 192.168.1.1
 IPv4 addresses can be compared with the same logical relations as
 numbers: eq, ne, gt, ge, lt, and le. The IPv4 address is stored in
 host order, so you do not have to worry about the endianness of an IPv4
 address when using it in a display filter.
 Classless InterDomain Routing (CIDR) notation can be used to test if an
 IPv4 address is in a certain subnet. For example, this display filter
 will find all packets in the 129.111 Class-B network:
 ip.addr == 129.111.0.0/16
 Remember, the number after the slash represents the number of bits used
 to represent the network. CIDR notation can also be used with
 hostnames, as in this example of finding IP addresses on the same Class
 C network as 'sneezy':
 ip.addr eq sneezy/24
 The CIDR notation can only be used on IP addresses or hostnames, not in
 variable names. So, a display filter like "ip.src/24 == ip.dst/24" is
 not valid (yet).
 IPX networks are represented by unsigned 32-bit integers. Most likely
 you will be using hexadecimal when testing IPX network values:
 ipx.src.net == 0xc0a82c00
 Strings are enclosed in double quotes:
 http.request.method == "POST"
 Inside double quotes, you may use a backslash to embed a double quote
 or an arbitrary byte represented in either octal or hexadecimal.
 browser.comment == "An embedded \" double-quote"
 Use of hexadecimal to look for "HEAD":
 http.request.method == "\x48EAD"
 Use of octal to look for "HEAD":
 http.request.method == "110円EAD"
 This means that you must escape backslashes with backslashes inside
 double quotes.
 smb.path contains "\\\\SERVER\\SHARE"
 looks for \\SERVER\SHARE in "smb.path".
 The slice operator
 You can take a slice of a field if the field is a text string or a byte
 array. For example, you can filter on the vendor portion of an
 ethernet address (the first three bytes) like this:
 eth.src[0:3] == 00:00:83
 Another example is:
 http.content_type[0:4] == "text"
 You can use the slice operator on a protocol name, too. The "frame"
 protocol can be useful, encompassing all the data captured by Wireshark
 or TShark.
 token[0:5] ne 0.0.0.1.1
 llc[0] eq aa
 frame[100-199] contains "wireshark"
 The following syntax governs slices:
 [i:j] i = start_offset, j = length
 [i-j] i = start_offset, j = end_offset, inclusive.
 [i] i = start_offset, length = 1
 [:j] start_offset = 0, length = j
 [i:] start_offset = i, end_offset = end_of_field
 Offsets can be negative, in which case they indicate the offset from
 the end of the field. The last byte of the field is at offset -1, the
 last but one byte is at offset -2, and so on. Here's how to check the
 last four bytes of a frame:
 frame[-4:4] == 0.1.2.3
 or
 frame[-4:] == 0.1.2.3
 A slice is always compared against either a string or a byte sequence.
 As a special case, when the slice is only 1 byte wide, you can compare
 it against a hex integer that 0xff or less (which means it fits inside
 one byte). This is not allowed for byte sequences greater than one
 byte, because then one would need to specify the endianness of the
 multi-byte integer. Also, this is not allowed for decimal numbers,
 since they would be confused with hex numbers that are already allowed
 as byte strings. Nevertheless, single-byte hex integers can be
 convenient:
 frame[4] == 0xff
 Slices can be combined. You can concatenate them using the comma
 operator:
 ftp[1,3-5,9:] == 01:03:04:05:09:0a:0b
 This concatenates offset 1, offsets 3-5, and offset 9 to the end of the
 ftp data.
 The membership operator
 A field may be checked for matches against a set of values simply with
 the membership operator. For instance, you may find traffic on common
 HTTP/HTTPS ports with the following filter:
 tcp.port in {80 443 8080}
 as opposed to the more verbose:
 tcp.port == 80 or tcp.port == 443 or tcp.port == 8080
 To find HTTP requests using the HEAD or GET methods:
 http.request.method in {"HEAD" "GET"}
 The set of values can also contain ranges:
 tcp.port in {443 4430..4434}
 ip.addr in {10.0.0.5 .. 10.0.0.9 192.168.1.1..192.168.1.9}
 frame.time_delta in {10 .. 10.5}
 Type conversions
 If a field is a text string or a byte array, it can be expressed in
 whichever way is most convenient.
 So, for instance, the following filters are equivalent:
 http.request.method == "GET"
 http.request.method == 47.45.54
 A range can also be expressed in either way:
 frame[60:2] gt 50.51
 frame[60:2] gt "PQ"
 Bit field operations
 It is also possible to define tests with bit field operations.
 Currently the following bit field operation is supported:
 bitwise_and, & Bitwise AND
 The bitwise AND operation allows testing to see if one or more bits are
 set. Bitwise AND operates on integer protocol fields and slices.
 When testing for TCP SYN packets, you can write:
 tcp.flags & 0x02
 That expression will match all packets that contain a "tcp.flags" field
 with the 0x02 bit, i.e. the SYN bit, set.
 Similarly, filtering for all WSP GET and extended GET methods is
 achieved with:
 wsp.pdu_type & 0x40
 When using slices, the bit mask must be specified as a byte string, and
 it must have the same number of bytes as the slice itself, as in:
 ip[42:2] & 40:ff
 Logical expressions
 Tests can be combined using logical expressions. These too are
 expressible in C-like syntax or with English-like abbreviations:
 and, && Logical AND
 or, || Logical OR
 not, ! Logical NOT
 Expressions can be grouped by parentheses as well. The following are
 all valid display filter expressions:
 tcp.port == 80 and ip.src == 192.168.2.1
 not llc
 http and frame[100-199] contains "wireshark"
 (ipx.src.net == 0xbad && ipx.src.node == 0.0.0.0.0.1) || ip
 Remember that whenever a protocol or field name occurs in an
 expression, the "exists" operator is implicitly called. The "exists"
 operator has the highest priority. This means that the first filter
 expression must be read as "show me the packets for which tcp.port
 exists and equals 80, and ip.src exists and equals 192.168.2.1". The
 second filter expression means "show me the packets where not (llc
 exists)", or in other words "where llc does not exist" and hence will
 match all packets that do not contain the llc protocol. The third
 filter expression includes the constraint that offset 199 in the frame
 exists, in other words the length of the frame is at least 200.
 A special caveat must be given regarding fields that occur more than
 once per packet. "ip.addr" occurs twice per IP packet, once for the
 source address, and once for the destination address. Likewise,
 "tr.rif.ring" fields can occur more than once per packet. The
 following two expressions are not equivalent:
 ip.addr ne 192.168.4.1
 not ip.addr eq 192.168.4.1
 The first filter says "show me packets where an ip.addr exists that
 does not equal 192.168.4.1". That is, as long as one ip.addr in the
 packet does not equal 192.168.4.1, the packet passes the display
 filter. The other ip.addr could equal 192.168.4.1 and the packet would
 still be displayed. The second filter says "don't show me any packets
 that have an ip.addr field equal to 192.168.4.1". If one ip.addr is
 192.168.4.1, the packet does not pass. If neither ip.addr field is
 192.168.4.1, then the packet is displayed.
 It is easy to think of the 'ne' and 'eq' operators as having an
 implicit "exists" modifier when dealing with multiply-recurring fields.
 "ip.addr ne 192.168.4.1" can be thought of as "there exists an ip.addr
 that does not equal 192.168.4.1". "not ip.addr eq 192.168.4.1" can be
 thought of as "there does not exist an ip.addr equal to 192.168.4.1".
 Be careful with multiply-recurring fields; they can be confusing.
 Care must also be taken when using the display filter to remove noise
 from the packet trace. If, for example, you want to filter out all IP
 multicast packets to address 224.1.2.3, then using:
 ip.dst ne 224.1.2.3
 may be too restrictive. Filtering with "ip.dst" selects only those IP
 packets that satisfy the rule. Any other packets, including all non-IP
 packets, will not be displayed. To display the non-IP packets as well,
 you can use one of the following two expressions:
 not ip or ip.dst ne 224.1.2.3
 not ip.addr eq 224.1.2.3
 The first filter uses "not ip" to include all non-IP packets and then
 lets "ip.dst ne 224.1.2.3" filter out the unwanted IP packets. The
 second filter has already been explained above where filtering with
 multiply occurring fields was discussed.

FILTER FIELD REFERENCE

 The entire list of display filters is too large to list here. You can
 can find references and examples at the following locations:
 o The online Display Filter Reference:
 <https://www.wireshark.org/docs/dfref/ >
 o View:Internals:Supported Protocols in Wireshark
 o "tshark -G fields" on the command line
 o The Wireshark wiki:
 <https://gitlab.com/wireshark/wireshark/-/wikis/DisplayFilters >

NOTES

 The wireshark-filters manpage is part of the Wireshark distribution.
 The latest version of Wireshark can be found at
 <https://www.wireshark.org >.
 Regular expressions in the "matches" operator are provided by GRegex in
 GLib. See
 <https://developer.gnome.org/glib/2.32/glib-regex-syntax.html > or
 <https://www.pcre.org/ > for more information.
 This manpage does not describe the capture filter syntax, which is
 different. See the manual page of pcap-filter(7)  or, if that doesn't
 exist, tcpdump(8), or, if that doesn't exist,
 <https://wiki.wireshark.org/CaptureFilters > for a description of
 capture filters.
 Display Filters are also described in the User's Guide:
 <https://www.wireshark.org/docs/wsug_html_chunked/ChWorkBuildDisplayFilterSection.html >

SEE ALSO

 wireshark(1) , tshark(1) , editcap(1) , pcap(3) , pcap-filter(7)  or
 tcpdump(8) if it doesn't exist.

AUTHORS

 See the list of authors in the Wireshark man page for a list of authors
 of that code.
3.4.9 2021年10月06日 wireshark-filter(4)