Bro internally provides a plugin API that enables extending the system dynamically, without modifying the core code base. That way custom code remains self-contained and can be maintained, compiled, and installed independently. Currently, plugins can add the following functionality to Bro:
- Bro scripts.
- Builtin functions/events/types for the scripting language.
- Protocol analyzers.
- File analyzers.
- Packet sources and packet dumpers.
- Logging framework backends.
- Input framework readers.
A plugin’s functionality is available to the user just as if Bro had the corresponding code built-in. Indeed, internally many of Bro’s pieces are structured as plugins as well, they are just statically compiled into the binary rather than loaded dynamically at runtime.
Writing a basic plugin is quite straight-forward as long as one
follows a few conventions. In the following we create a simple example
plugin that adds a new built-in function (bif) to Bro: we’ll add
rot13(s: string) : string
, a function that rotates every character
in a string by 13 places.
Generally, a plugin comes in the form of a directory following a
certain structure. To get started, Bro’s distribution provides a
helper script aux/bro-aux/plugin-support/init-plugin
that creates
a skeleton plugin that can then be customized. Let’s use that:
# init-plugin ./rot13-plugin Demo Rot13
As you can see, the script takes three arguments. The first is a
directory inside which the plugin skeleton will be created. The second
is the namespace the plugin will live in, and the third is a descriptive
name for the plugin itself relative to the namespace. Bro uses the
combination of namespace and name to identify a plugin. The namespace
serves to avoid naming conflicts between plugins written by independent
developers; pick, e.g., the name of your organisation. The namespace
Bro
is reserved for functionality distributed by the Bro Project. In
our example, the plugin will be called Demo::Rot13
.
The init-plugin
script puts a number of files in place. The full
layout is described later. For now, all we need is
src/rot13.bif
. It’s initially empty, but we’ll add our new bif
there as follows:
# cat src/rot13.bif
module Demo;
function rot13%(s: string%) : string
%{
char* rot13 = copy_string(s->CheckString());
for ( char* p = rot13; *p; p++ )
{
char b = islower(*p) ? 'a' : 'A';
*p = (*p - b + 13) % 26 + b;
}
BroString* bs = new BroString(1, reinterpret_cast<byte_vec>(rot13),
strlen(rot13));
return new StringVal(bs);
%}
The syntax of this file is just like any other *.bif
file; we
won’t go into it here.
Now we can already compile our plugin, we just need to tell the
configure script (that init-plugin
created) where the Bro
source tree is located (Bro needs to have been built there first):
# cd rot13-plugin
# ./configure --bro-dist=/path/to/bro/dist && make
[... cmake output ...]
This builds the plugin in a subdirectory build/
. In fact, that
subdirectory becomes the plugin: when make
finishes, build/
has everything it needs for Bro to recognize it as a dynamic plugin.
Let’s try that. Once we point Bro to the build/
directory, it will
pull in our new plugin automatically, as we can check with the -N
option:
# export BRO_PLUGIN_PATH=/path/to/rot13-plugin/build
# bro -N
[...]
Demo::Rot13 - <Insert description> (dynamic, version 0.1)
[...]
That looks quite good, except for the dummy description that we should
replace with something nicer so that users will know what our plugin
is about. We do this by editing the config.description
line in
src/Plugin.cc
, like this:
[...]
plugin::Configuration Plugin::Configure()
{
plugin::Configuration config;
config.name = "Demo::Rot13";
config.description = "Caesar cipher rotating a string's characters by 13 places.";
config.version.major = 0;
config.version.minor = 1;
return config;
}
[...]
Now rebuild and verify that the description is visible:
# make
[...]
# bro -N | grep Rot13
Demo::Rot13 - Caesar cipher rotating a string's characters by 13 places. (dynamic, version 0.1)
Bro can also show us what exactly the plugin provides with the
more verbose option -NN
:
# bro -NN
[...]
Demo::Rot13 - Caesar cipher rotating a string's characters by 13 places. (dynamic, version 0.1)
[Function] Demo::rot13
[...]
There’s our function. Now let’s use it:
# bro -e 'print Demo::rot13("Hello")'
Uryyb
It works. We next install the plugin along with Bro itself, so that it
will find it directly without needing the BRO_PLUGIN_PATH
environment variable. If we first unset the variable, the function
will no longer be available:
# unset BRO_PLUGIN_PATH
# bro -e 'print Demo::rot13("Hello")'
error in <command line>, line 1: unknown identifier Demo::rot13, at or near "Demo::rot13"
Once we install it, it works again:
# make install
# bro -e 'print Demo::rot13("Hello")'
Uryyb
The installed version went into
<bro-install-prefix>/lib/bro/plugins/Demo_Rot13
.
One can distribute the plugin independently of Bro for others to use.
To distribute in source form, just remove the build/
directory
(make distclean
does that) and then tar up the whole rot13-plugin/
directory. Others then follow the same process as above after
unpacking.
To distribute the plugin in binary form, the build process
conveniently creates a corresponding tarball in build/dist/
. In
this case, it’s called Demo_Rot13-0.1.tar.gz
, with the version
number coming out of the VERSION
file that init-plugin
put
into place. The binary tarball has everything needed to run the
plugin, but no further source files. Optionally, one can include
further files by specifying them in the plugin’s CMakeLists.txt
through the bro_plugin_dist_files
macro; the skeleton does that
for README
, VERSION
, CHANGES
, and COPYING
. To use the
plugin through the binary tarball, just unpack it into
<bro-install-prefix>/lib/bro/plugins/
. Alternatively, if you unpack
it in another location, then you need to point BRO_PLUGIN_PATH
there.
Before distributing your plugin, you should edit some of the meta
files that init-plugin
puts in place. Edit README
and
VERSION
, and update CHANGES
when you make changes. Also put a
license file in place as COPYING
; if BSD is fine, you will find a
template in COPYING.edit-me
.
A plugin’s directory needs to follow a set of conventions so that Bro
(1) recognizes it as a plugin, and (2) knows what to load. While
init-plugin
takes care of most of this, the following is the full
story. We’ll use <base>
to represent a plugin’s top-level
directory. With the skeleton, <base>
corresponds to build/
.
<base>/__bro_plugin__
<base>/lib/<plugin-name>.<os>-<arch>.so
scripts/
BROPATH
, so that any scripts/modules inside can be
“@load”ed.scripts
/__load__.broscripts
/__preload__.brolib/bif/
bifcl
.Any other files in <base>
are ignored by Bro.
By convention, a plugin should put its custom scripts into sub folders
of scripts/
, i.e., scripts/<plugin-namespace>/<plugin-name>/<script>.bro
to avoid conflicts. As usual, you can then put a __load__.bro
in
there as well so that, e.g., @load Demo/Rot13
could load a whole
module in the form of multiple individual scripts.
Note that in addition to the paths above, the init-plugin
helper
puts some more files and directories in place that help with
development and installation (e.g., CMakeLists.txt
, Makefile
,
and source code in src/
). However, all these do not have a special
meaning for Bro at runtime and aren’t necessary for a plugin to
function.
init-plugin
¶init-plugin
puts a basic plugin structure in place that follows
the above layout and augments it with a CMake build and installation
system. Plugins with this structure can be used both directly out of
their source directory (after make
and setting Bro’s
BRO_PLUGIN_PATH
), and when installed alongside Bro (after make
install
).
make install
copies over the lib
and scripts
directories,
as well as the __bro_plugin__
magic file and any further
distribution files specified in CMakeLists.txt
(e.g., README,
VERSION). You can find a full list of files installed in
build/MANIFEST
. Behind the scenes, make install
really just
unpacks the binary tarball from build/dist
into the destination
directory.
init-plugin
will never overwrite existing files. If its target
directory already exists, it will by default decline to do anything.
You can run it with -u
instead to update an existing plugin,
however it will never overwrite any existing files; it will only put
in place files it doesn’t find yet. To revert a file back to what
init-plugin
created originally, delete it first and then rerun
with -u
.
init-plugin
puts a configure
script in place that wraps
cmake
with a more familiar configure-style configuration. By
default, the script provides two options for specifying paths to the
Bro source (--bro-dist
) and to the plugin’s installation directory
(--install-root
). To extend configure
with plugin-specific
options (such as search paths for its dependencies) don’t edit the
script directly but instead extend configure.plugin
, which
configure
includes. That way you will be able to more easily
update configure
in the future when the distribution version
changes. In configure.plugin
you can use the predefined shell
function append_cache_entry
to seed values into the CMake cache;
see the installed skeleton version and existing plugins for examples.
A plugin needs to be activated to make it available to the user. Activating a plugin will:
- Load the dynamic module
- Make any bif items available
- Add the
scripts/
directory toBROPATH
- Load
scripts/__preload__.bro
- Make BiF elements available to scripts.
- Load
scripts/__load__.bro
By default, Bro will automatically activate all dynamic plugins found
in its search path BRO_PLUGIN_PATH
. However, in bare mode (bro
-b
), no dynamic plugins will be activated by default; instead the
user can selectively enable individual plugins in scriptland using the
@load-plugin <qualified-plugin-name>
directive (e.g.,
@load-plugin Demo::Rot13
). Alternatively, one can activate a
plugin from the command-line by specifying its full name
(Demo::Rot13
), or set the environment variable
BRO_PLUGIN_ACTIVATE
to a list of comma(!)-separated names of
plugins to unconditionally activate, even in bare mode.
bro -N
shows activated plugins separately from found but not yet
activated plugins. Note that plugins compiled statically into Bro are
always activated, and hence show up as such even in bare mode.
The following subsections detail providing individual types of functionality via plugins. Note that a single plugin can provide more than one component type. For example, a plugin could provide multiple protocol analyzers at once; or both a logging backend and input reader at the same time.
Todo
These subsections are mostly missing right now, as much of their
content isn’t actually plugin-specific, but concerns generally
writing such functionality for Bro. The best way to get started
right now is to look at existing code implementing similar
functionality, either as a plugin or inside Bro proper. Also, for
each component type there’s a unit test in
testing/btest/plugins
creating a basic plugin skeleton with a
corresponding component.
Scripts are easy: just put them into scripts/
, as described above.
The CMake infrastructure will automatically install them, as well
include them into the source and binary plugin distributions.
TODO.
TODO.
TODO.
TODO.
TODO.
TODO.
TODO.
A plugin should come with a test suite to exercise its functionality.
The init-plugin
script puts in place a basic
BTest setup
to start with. Initially, it comes with a single test that just checks
that Bro loads the plugin correctly. It won’t have a baseline yet, so
let’s get that in place:
# cd tests
# btest -d
[ 0%] rot13.show-plugin ... failed
% 'btest-diff output' failed unexpectedly (exit code 100)
% cat .diag
== File ===============================
Demo::Rot13 - Caesar cipher rotating a string's characters by 13 places. (dynamic, version 0.1)
[Function] Demo::rot13
== Error ===============================
test-diff: no baseline found.
=======================================
# btest -U
all 1 tests successful
# cd ..
# make test
make -C tests
make[1]: Entering directory `tests'
all 1 tests successful
make[1]: Leaving directory `tests'
Now let’s add a custom test that ensures that our bif works correctly:
# cd tests
# cat >rot13/bif-rot13.bro
# @TEST-EXEC: bro %INPUT >output
# @TEST-EXEC: btest-diff output
event bro_init()
{
print Demo::rot13("Hello");
}
Check the output:
# btest -d rot13/bif-rot13.bro
[ 0%] rot13.bif-rot13 ... failed
% 'btest-diff output' failed unexpectedly (exit code 100)
% cat .diag
== File ===============================
Uryyb
== Error ===============================
test-diff: no baseline found.
=======================================
% cat .stderr
1 of 1 test failed
Install the baseline:
# btest -U rot13/bif-rot13.bro
all 1 tests successful
Run the test-suite:
# btest
all 2 tests successful
If your plugin isn’t loading as expected, Bro’s debugging facilities
can help illuminate what’s going on. To enable, recompile Bro
with debugging support (./configure --enable-debug
), and
afterwards rebuild your plugin as well. If you then run Bro with -B
plugins
, it will produce a file debug.log
that records details
about the process for searching, loading, and activating plugins.
To generate your own debugging output from inside your plugin, you can
add a custom debug stream by using the PLUGIN_DBG_LOG(<plugin>,
<args>)
macro (defined in DebugLogger.h
), where <plugin>
is
the Plugin
instance and <args>
are printf-style arguments,
just as with Bro’s standard debugging macros (grep for DBG_LOG
in
Bro’s src/
to see examples). At runtime, you can then activate
your plugin’s debugging output with -B plugin-<name>
, where
<name>
is the name of the plugin as returned by its
Configure()
method, yet with the namespace-separator ::
replaced with a simple dash. Example: If the plugin is called
Demo::Rot13
, use -B plugin-Demo-Rot13
. As usual, the debugging
output will be recorded to debug.log
if Bro’s compiled in debug
mode.
Todo
Integrate all this with Broxygen.