[[wsluarm]]

// Attributes
:build_dir: .

== Lua Support in Wireshark

[[wsluarm_intro]]

=== Introduction

Wireshark has an embedded Lua interpreter. Lua is a powerful light-weight
programming language designed for extending applications. Lua is designed and
implemented by a team at PUC-Rio, the Pontifical Catholic University of Rio de
Janeiro in Brazil. Lua was born and raised at Tecgraf, the Computer Graphics
Technology Group of PUC-Rio, and is now housed at
link:http://www.lua.org[Lua.org]. Both Tecgraf and Lua.org are laboratories of
the Department of Computer Science.

In Wireshark Lua can be used to write dissectors, taps, and capture file readers
and writers.

Wireshark's Lua interpreter starts by loading `init.lua` that is located in the
global configuration directory of Wireshark. Lua is enabled by default. To
disable Lua the line variable _$$disable_lua$$_ should be set to _true_ in
`init.lua`.

After loading _init.lua_ from the data directory if Lua is enabled Wireshark
will try to load a file named `init.lua` in the user's directory.

Wireshark will also load all files with `.lua` suffix from both the global and
the personal plugins directory.

The command line option _$$-X lua_script:$$++file.lua++_ can be used to load
Lua scripts as well.

The Lua code will be executed once after all the protocol dissectors have being
initialized and before reading any file.

[[wslua_dissector_example]]

=== Example of Dissector written in Lua

[source,lua]
----
local p_multi = Proto("multi", "MultiProto");

local vs_protos = {
        [2] = "mtp2",
        [3] = "mtp3",
        [4] = "alcap",
        [5] = "h248",
        [6] = "ranap",
        [7] = "rnsap",
        [8] = "nbap"
}

local f_proto = ProtoField.uint8("multi.protocol", "Protocol", base.DEC, vs_protos)
local f_dir = ProtoField.uint8("multi.direction", "Direction", base.DEC, { [1] = "incoming", [0] = "outgoing"})
local f_text = ProtoField.string("multi.text", "Text")

p_multi.fields = { f_proto, f_dir, f_text }

local data_dis = Dissector.get("data")

local protos = {
        [2] = Dissector.get("mtp2"),
        [3] = Dissector.get("mtp3"),
        [4] = Dissector.get("alcap"),
        [5] = Dissector.get("h248"),
        [6] = Dissector.get("ranap"),
        [7] = Dissector.get("rnsap"),
        [8] = Dissector.get("nbap"),
        [9] = Dissector.get("rrc"),
        [10] = DissectorTable.get("sctp.ppi"):get_dissector(3), -- m3ua
        [11] = DissectorTable.get("ip.proto"):get_dissector(132), -- sctp
}

function p_multi.dissector(buf, pkt, tree)

        local subtree = tree:add(p_multi, buf(0,2))
        subtree:add(f_proto, buf(0,1))
        subtree:add(f_dir, buf(1,1))

        local proto_id = buf(0,1):uint()

        local dissector = protos[proto_id]

        if dissector ~= nil then
                -- Dissector was found, invoke subdissector with a new Tvb,
                -- created from the current buffer (skipping first two bytes).
                dissector:call(buf(2):tvb(), pkt, tree)
        elseif proto_id < 2 then
                subtree:add(f_text, buf(2))
                -- pkt.cols.info:set(buf(2, buf:len() - 3):string())
        else
                -- fallback dissector that just shows the raw data.
                data_dis:call(buf(2):tvb(), pkt, tree)
        end

end

local wtap_encap_table = DissectorTable.get("wtap_encap")
local udp_encap_table = DissectorTable.get("udp.port")

wtap_encap_table:add(wtap.USER15, p_multi)
wtap_encap_table:add(wtap.USER12, p_multi)
udp_encap_table:add(7555, p_multi)
----

[[wslua_tap_example]]

=== Example of Listener written in Lua

[source,lua]
----
-- This program will register a menu that will open a window with a count of occurrences
-- of every address in the capture

local function menuable_tap()
	-- Declare the window we will use
	local tw = TextWindow.new("Address Counter")

	-- This will contain a hash of counters of appearances of a certain address
	local ips = {}

	-- this is our tap
	local tap = Listener.new();

	function remove()
		-- this way we remove the listener that otherwise will remain running indefinitely
		tap:remove();
	end

	-- we tell the window to call the remove() function when closed
	tw:set_atclose(remove)

	-- this function will be called once for each packet
	function tap.packet(pinfo,tvb)
		local src = ips[tostring(pinfo.src)] or 0
		local dst = ips[tostring(pinfo.dst)] or 0

		ips[tostring(pinfo.src)] = src + 1
		ips[tostring(pinfo.dst)] = dst + 1
	end

	-- this function will be called once every few seconds to update our window
	function tap.draw(t)
		tw:clear()
		for ip,num in pairs(ips) do
			tw:append(ip .. "\t" .. num .. "\n");
		end
	end

	-- this function will be called whenever a reset is needed
	-- e.g. when reloading the capture file
	function tap.reset()
		tw:clear()
		ips = {}
	end
end

-- using this function we register our function
-- to be called when the user selects the Tools->Test->Packets menu
register_menu("Test/Packets", menuable_tap, MENU_TOOLS_UNSORTED)
----

[[wsluarm_modules]]

== Wireshark's Lua API Reference Manual

This Part of the User Guide describes the Wireshark specific functions in the embedded Lua.

Classes group certain functionality, the following notational conventions are
used:

* 'Class.function()' represents a class method (named 'function') on class
  'Class', taking no arguments.

* 'Class.function(a)' represents a class method taking one argument.

* 'Class.function(...)' represents a class method taking a variable number of
  arguments.

* 'class:method()' represents an instance method (named 'method') on an instance
  of class 'Class', taking no arguments. Note the lowercase notation in the
  documentation to clarify an instance.

* 'class.prop' represents a property 'prop' on the instance of class 'Class'.

Trying to access a non-existing property, function or method currently gives an
error, but do not rely on it as the behavior may change in the future.


include::{build_dir}/wsluarm_src/wslua_dumper.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_field.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_gui.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_listener.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_pinfo.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_proto.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_tree.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_tvb.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_file.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_dir.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_util.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_int64.asciidoc[]
include::{build_dir}/wsluarm_src/wslua_struct.asciidoc[]

[[lua_module_GRegex]]

=== GLib Regular Expressions

Lua has its own native 'pattern' syntax in the string library, but sometimes a
real regex engine is more useful. Wireshark comes with GLib's Regex
implementation, which itself is based on Perl Compatible Regular Expressions
(PCRE). This engine is exposed into Wireshark's Lua engine through the
well-known Lrexlib library, following the same syntax and semantics as the
Lrexlib PCRE implementation, with a few differences as follows:

* There is no support for using custom locale/chartables

* 'dfa_exec()' doesn't take 'ovecsize' nor 'wscount' arguments

* 'dfa_exec()' returns boolean true for partial match, without subcapture info

* Named subgroups do not return name-keyed entries in the return table (i.e., in
  match/tfind/exec)

* The 'flags()' function still works, returning all flags, but two new functions
  'compile_flags()' and 'match_flags()' return just their respective flags,
  since GLib has a different and smaller set of such flags, for regex compile
  vs. match functions

* Using some assertions and POSIX character classes against strings with
  non-ASCII characters might match high-order characters, because glib always
  sets PCRE_UCP even if G_REGEX_RAW is set. For example, '[:alpha;]' matches
  certain non-ASCII bytes. The following assertions have this issue: '\b', '\B',
  '\s', '\S', '\w', '\W'. The following character classes have this issue:
  [:alpha:], [:alnum:], [:lower:], [:upper:], [:space:], [:word:], and
  [:graph:].

* The compile flag G_REGEX_RAW is always set/used, even if you didn't specify
  it. This is because GLib runs PCRE in UTF-8 mode by default, whereas Lua
  strings are not UTF-aware.


Since: 1.11.3

This page is based on the full documentation for Lrexlib at
link:http://rrthomas.github.io/lrexlib/manual.html[http://rrthomas.github.io/lrexlib/manual.html]

The GLib Regular expression syntax (which is essentially PCRE syntax) can be
found at
link:https://developer.gnome.org/glib/2.38/glib-regex-syntax.html[https://developer.gnome.org/glib/2.38/glib-regex-syntax.html]

[[lua_class_GRegex]]

==== GRegex

GLib Regular Expressions based on PCRE.

Since: 1.11.3

[[lua_class_GRegex_notes]]

===== Notes

All functions that take a regular expression pattern as an argument will
generate an error if that pattern is found invalid by the regex library.

All functions that take a string-type regex argument accept a compiled regex
too. In this case, the compile flags argument is ignored (should be either
supplied as nils or omitted).

The capture flag argument 'cf' may also be supplied as a string, whose
characters stand for compilation flags. Combinations of the following characters
(case sensitive) are supported:

* '__i__' = G_REGEX_CASELESS - Letters in the pattern match both upper- and
  lowercase letters. This option can be changed within a pattern by a ``(?i)''
  option setting.

* '__m__' = G_REGEX_MULTILINE - By default, GRegex treats the strings as
  consisting of a single line of characters (even if it actually contains
  newlines). The ``start of line'' metacharacter (``^'') matches only at the start
  of the string, while the ``end of line'' metacharacter (``$'') matches only at
  the end of the string, or before a terminating newline (unless
  G_REGEX_DOLLAR_ENDONLY is set). When G_REGEX_MULTILINE is set, the ``start of
  line'' and ``end of line'' constructs match immediately following or
  immediately before any newline in the string, respectively, as well as at the
  very start and end. This can be changed within a pattern by a ``(?m)'' option
  setting.

* '__s__' = G_REGEX_DOTALL - A dot metacharater (``.'') in the pattern matches
  all characters, including newlines. Without it, newlines are excluded. This
  option can be changed within a pattern by a ("?s") option setting.

* '__x__' = G_REGEX_EXTENDED - Whitespace data characters in the pattern are
  totally ignored except when escaped or inside a character class. Whitespace
  does not include the VT character (code 11). In addition, characters between
  an unescaped ``$$#$$'' outside a character class and the next newline character,
  inclusive, are also ignored. This can be changed within a pattern by a
  ``(?x)'' option setting.

* '__U__' = G_REGEX_UNGREEDY - Inverts the ``greediness'' of the quantifiers so
  that they are not greedy by default, but become greedy if followed by ``?''.
  It can also be set by a ``(?U)'' option setting within the pattern.

[[lua_fn_GRegex_new_pattern_]]

===== GRegex.new(pattern)

Compiles regular expression pattern into a regular expression object whose
internal representation is corresponding to the library used. The returned
result then can be used by the methods, e.g. match, exec, etc. Regular
expression objects are automatically garbage collected.

Since: 1.11.3

[float]
===== Arguments

pattern:: A Perl-compatible regular expression pattern string

[float]
===== Returns

The compiled regular expression (a userdata object)

[float]
===== Errors

* A malformed pattern generates a Lua error

[[lua_fn_GRegex_flags__table__]]

===== GRegex.flags([table])

Returns a table containing the numeric values of the constants defined by the
regex library, with the keys being the (string) names of the constants. If the
table argument is supplied then it is used as the output table, otherwise a new
table is created. The constants contained in the returned table can then be used
in most functions and methods where compilation flags or execution flags can be
specified. They can also be used for comparing with return codes of some
functions and methods for determining the reason of failure.

Since: 1.11.3

[float]
===== Arguments

table (optional):: A table for placing results into

[float]
===== Returns

A table filled with the results.

[[lua_fn_GRegex_compile_flags__table__]]


===== GRegex.compile_flags([table])

Returns a table containing the numeric values of the constants defined by the
regex library for compile flags, with the keys being the (string) names of the
constants. If the table argument is supplied then it is used as the output
table, otherwise a new table is created.

Since: 1.11.3

[float]
===== Arguments

table (optional):: A table for placing results into

[float]
===== Returns

A table filled with the results.

[[lua_fn_GRegex_match_flags__table__]]

===== GRegex.match_flags([table])

Returns a table containing the numeric values of the constants defined by the
regex library for match flags, with the keys being the (string) names of the
constants. If the table argument is supplied then it is used as the output
table, otherwise a new table is created.

Since: 1.11.3

[float]
===== Arguments

table (optional):: A table for placing results into

[float]
===== Returns

A table filled with the results.

[[lua_fn_GRegex_match_subject__pattern___init____cf____ef__]]

===== GRegex.match(subject, pattern, [init], [cf], [ef])

Searches for the first match of the regexp pattern in the string subject,
starting from offset init, subject to flags cf and ef. The pattern is compiled
each time this is called, unlike the class method 'match' function.

Since: 1.11.3

[float]
===== Arguments

subject:: Subject string to search

pattern:: A Perl-compatible regular expression pattern string or GRegex object

init (optional):: start offset in the subject (can be negative)

cf (optional):: compilation flags (bitwise OR)

ef (optional):: match execution flags (bitwise OR)

[float]
===== Returns

On success, returns all substring matches ("captures"), in the order they appear
in the pattern. false is returned for sub-patterns that did not participate in
the match. If the pattern specified no captures then the whole matched substring
is returned. On failure, returns nil.

[[lua_fn_GRegex_find_subject__pattern___init____cf____ef__]]

===== GRegex.find(subject, pattern, [init], [cf], [ef])

Searches for the first match of the regexp pattern in the string subject,
starting from offset init, subject to flags ef. The pattern is compiled each
time this is called, unlike the class method 'find' function.

Since: 1.11.3

[float]
===== Arguments

subject:: Subject string to search

pattern:: A Perl-compatible regular expression pattern string or GRegex object

init (optional):: start offset in the subject (can be negative)

cf (optional):: compilation flags (bitwise OR)

ef (optional):: match execution flags (bitwise OR)

[float]
===== Returns

On success, returns the start point of the match (a number), the end point of
the match (a number), and all substring matches ("captures"), in the order they
appear in the pattern. false is returned for sub-patterns that did not
participate in the match. On failure, returns nil.

[[lua_fn_GRegex_gmatch_subject__pattern___init____cf____ef__]]


===== GRegex.gmatch(subject, pattern, [init], [cf], [ef])

Returns an iterator for repeated matching of the pattern patt in the string
subj, subject to flags cf and ef. The function is intended for use in the
generic for Lua construct. The pattern can be a string or a GRegex object
previously compiled with GRegex.new().

Since: 1.11.3

[float]
===== Arguments

subject:: Subject string to search

pattern:: A Perl-compatible regular expression pattern string or GRegex object

init (optional):: start offset in the subject (can be negative)

cf (optional):: compilation flags (bitwise OR)

ef (optional):: match execution flags (bitwise OR)

[float]
===== Returns

The iterator function is called by Lua. On every iteration (that is, on every
match), it returns all captures in the order they appear in the pattern (or the
entire match if the pattern specified no captures). The iteration will continue
till the subject fails to match.

[[lua_fn_GRegex_gsub_subject__pattern___repl____max____cf____ef__]]

===== GRegex.gsub(subject, pattern, [repl], [max], [cf], [ef])

Searches for all matches of the pattern in the string subject and replaces them
according to the parameters repl and max. The pattern can be a string or a
GRegex object previously compiled with GRegex.new().

Since: 1.11.3

For details see:
link:http://rrthomas.github.io/lrexlib/manual.html#gsub[http://rrthomas.github.io/lrexlib/manual.html#gsub]

[float]
===== Arguments

subject:: Subject string to search

pattern:: A Perl-compatible regular expression pattern string or GRegex object

repl (optional):: Substitution source string, function, table, false or nil

max (optional):: Maximum number of matches to search for, or control function, or nil

cf (optional):: Compilation flags (bitwise OR)

ef (optional):: Match execution flags (bitwise OR)

[float]
===== Returns

On success, returns the subject string with the substitutions made, the number
of matches found, and the number of substitutions made.

[[lua_fn_GRegex_split_subject__sep___cf____ef__]]

===== GRegex.split(subject, sep, [cf], [ef])

Splits a subject string subj into parts (sections). The sep parameter is a
regular expression pattern representing separators between the sections. The
function is intended for use in the generic for Lua construct. The function
returns an iterator for repeated matching of the pattern sep in the string subj,
subject to flags cf and ef. The sep pattern can be a string or a GRegex object
previously compiled with GRegex.new(). Unlike gmatch, there will always be at
least one iteration pass, even if there are no matches in the subject.

Since: 1.11.3

[float]
===== Arguments

subject:: Subject string to search

sep:: A Perl-compatible regular expression pattern string or GRegex object

cf (optional):: compilation flags (bitwise OR)

ef (optional):: match execution flags (bitwise OR)

[float]
===== Returns

The iterator function is called by Lua. On every iteration, it returns a subject
section (can be an empty string), followed by all captures in the order they
appear in the sep pattern (or the entire match if the sep pattern specified no
captures). If there is no match (this can occur only in the last iteration),
then nothing is returned after the subject section. The iteration will continue
till the end of the subject.

[[lua_fn_GRegex_version__]]

===== GRegex.version()

Returns a returns a string containing the version of the used library.

Since: 1.11.3

[float]
===== Returns

The version string

[[lua_fn_gregex_match_subject___init____ef__]]

===== gregex:match(subject, [init], [ef])

Searches for the first match of the regexp pattern in the string subject,
starting from offset init, subject to flags ef.

Since: 1.11.3

[float]
===== Arguments

subject:: Subject string to search

init (optional):: start offset in the subject (can be negative)

ef (optional):: match execution flags (bitwise OR)

[float]
===== Returns

On success, returns all substring matches (``captures''), in the order they appear
in the pattern. false is returned for sub-patterns that did not participate in
the match. If the pattern specified no captures then the whole matched substring
is returned. nil is returned if the pattern did not match.

[[lua_fn_gregex_find_subject___init____ef__]]

===== gregex:find(subject, [init], [ef])

Searches for the first match of the regexp pattern in the string subject,
starting from offset init, subject to flags ef.

Since: 1.11.3

[float]
===== Arguments

subject:: Subject string to search

init (optional):: start offset in the subject (can be negative)

ef (optional):: match execution flags (bitwise OR)

[float]
===== Returns

On success, returns the start point of the match (a number), the end point of
the match (a number), and all substring matches ("captures"), in the order they
appear in the pattern. false is returned for sub-patterns that did not
participate in the match. On failure, returns nil.

[[lua_fn_gregex_exec_subject___init____ef__]]

===== gregex:exec(subject, [init], [ef])

Searches for the first match of the compiled GRegex object in the string
subject, starting from offset init, subject to the execution match flags ef.

Since: 1.11.3

[float]
===== Arguments

subject:: Subject string to search

init (optional):: start offset in the subject (can be negative)

ef (optional):: match execution flags (bitwise OR)

[float]
===== Returns

On success, returns the start point of the first match (a number), the end point
of the first match (a number), and the offsets of substring matches (``captures''
in Lua terminology) are returned as a third result, in a table. This table
contains false in the positions where the corresponding sub-pattern did not
participate in the match. On failure, returns nil. Example: If the whole match
is at offsets 10,20 and substring matches are at offsets 12,14 and 16,19 then
the function returns the following: 10, 20, { 12,14,16,19 }.

[[lua_fn_gregex_dfa_exec_subject___init____ef__]]

===== gregex:dfa_exec(subject, [init], [ef])

Matches a compiled regular expression GRegex object against a given subject
string subj, using a DFA matching algorithm.

Since: 1.11.3

[float]
===== Arguments

subject:: Subject string to search

init (optional):: start offset in the subject (can be negative)

ef (optional):: match execution flags (bitwise OR)

[float]
===== Returns

On success, returns the start point of the matches found (a number), a table
containing the end points of the matches found, the longer matches first, and
the number of matches found as the third return value. On failure, returns nil.
Example: If there are 3 matches found starting at offset 10 and ending at
offsets 15, 20 and 25 then the function returns the following: 10, { 25,20,15 },
3

[[lua_fn_gregex___tostring__]]

===== gregex:__tostring()

Returns a string containing debug information about the GRegex object.

Since: 1.11.3

[float]
===== Returns

The debug string