Recog is a framework for identifying products, services, operating systems, and hardware by matching fingerprints against data returned from various network probes. Recog makes it simple to extract useful information from web server banners, snmp system description fields, and a whole lot more.
Recog is open source, please see the LICENSE file for more information.
- Repository split
- Recog library language implementations
- Installation
- Maturity
- Fingerprints
- Testing matches
- Contributing
On March 31, 2022, the Recog content - XML fingerprint files and utilities - were split from the Recog framework library implementation. The original Recog repository now contains the Recog content and the Recog-Ruby repository contains the Ruby language implementation. The Recog content is included in Recog-Ruby as a git submodule and is nested under the recog
directory. All post-split Recog gem versions equal or greater than 3.0.0 will: 1. contain the XML fingerprint directory under the recog
directory, and 2. only include the recog_match
tool since the other tools are focused on fingerprint management.
Along with the repository split the default branch was renamed from master
to main
. Any clones created prior to these changes will have to be manually updated in your local environment. If you have a fork, navigate to your fork's settings and follow the instructions on renaming a branch to change the default branch to main
.
git branch -m master main
git fetch origin
git branch -u origin/main main
git remote set-head origin -a
Optionally, run the following command to remove tracking references to the old branch name.
# dry-run to confirm stale references that will be deleted before proceeding
git remote prune origin --dry-run
git remote prune origin
If you previously used the upstream tracking branch upstream-master
run the following commands to remove the old branch and create a new upstream tracking branch.
git branch -d upstream-master
git checkout -b upstream-main --track upstream/main
Optionally, run the following command to remove the tracking references to the old upstream branch name.
# dry-run to confirm stale references that will be deleted before proceeding
git remote prune upstream --dry-run
git remote prune upstream
- Ruby: rapid7/recog-ruby
- Java: rapid7/recog-java
- Go: runZeroInc/recog-go
Feature ✨ | rapid7/recog-ruby | rapid7/recog-java | runZeroInc/recog-go |
---|---|---|---|
Fingerprint verification CLI tool | âś… | âś… | âś… |
Fingerprint match CLI tool | âś… | âś… | |
Supports base64 encoded examples | âś… | âś… | âś… |
Supports filesystem-based external examples | âś… | âś… | âś… |
Fingerprint match CPE param interpolation | âś… | âś… | âś… |
Recog consists of both XML fingerprint files and an assortment of code, mostly in Ruby, that makes it easy to develop, test, and use the contained fingerprints. In order to use the included ruby code, a recent version of Ruby (2.31+) is required, along with Rubygems and the bundler
gem. Once these dependencies are in place, use the following commands to grab the latest source code and install any additional dependencies.
$ git clone git@github.com:rapid7/recog.git
$ cd recog
$ bundle install
Please note that while the XML fingerprints themselves are quite stable and well-tested, the Ruby codebase is still fairly new and subject to change quickly. Please contact us (research[at]rapid7.com) before leveraging the Recog code within any production projects.
The fingerprints within Recog are stored in XML files, each of which is designed to match a specific protocol response string or field. For example, the file ssh_banners.xml can determine the os, vendor, and sometimes hardware product by matching the initial SSH daemon banner string.
A fingerprint file consists of an XML document like the following:
<fingerprints matches="ssh.banner">
<fingerprint pattern="^RomSShell_([\d\.]+)$">
<description>Allegro RomSShell SSH</description>
<example service.version="4.62">RomSShell_4.62</example>
<param pos="0" name="service.vendor" value="Allegro"/>
<param pos="0" name="service.product" value="RomSShell"/>
<param pos="1" name="service.version"/>
</fingerprint>
</fingerprints>
The first line should always consist of the XML version declaration. The first element should always be a fingerprints
block with a matches
attribute indicating what data this fingerprint file is supposed to match. The matches
attribute is normally in the form of protocol.field
.
Inside of the fingerprints
element there should be one or more fingerprint
elements. Every fingerprint
must contain a pattern
attribute, which contains the regular expression to be used to match against the data. An optional flags
attribute can be specified to control how the regular expression is to be interpreted. See the Recog documentation for FLAG_MAP
for more information.
Inside of the fingerprint, a description
element should contain a human-readable string describing this fingerprint.
At least one example
element should be present, however multiple example
elements are preferred. These elements are used as part of the test coverage present in rspec
which validates that the provided data matches the specified regular expression. Additionally, if the fingerprint is using the param
elements to extract field values from the data (described next), you can add these expected extractions as attributes for the example
elements. In the example above, this:
<example service.version="4.62">RomSShell_4.62</example>
tests that RomSShell_4.62
matches the provided regular expression and that the value of service.version
is 4.62.
The example
string can be base64 encoded to permit the use of unprintable characters. To signal this to Recog an _encoding
attribute with the value of base64
is added to the example
element. Based64 encoded text that is longer than 80 characters may be wrapped with newlines as shown below to aid in readability.
<example _encoding="base64">
dGllczGEAAAAlQQWMS4yLjg0MC4xMTM1NTYuMS40LjgwMAQuZGF0YS5yZW1vdmVkLjCEAAAAK
AQdZG9tYWluQ29udHJvbGxlckZ1bmN0aW9uYWxpdHkxhAAAAAMEATc=
</example>
Additionally, examples can be placed in a directory with the same base name as the XML file, in the same directory as the XML file:
xml/services.xml
xml/services/file1
xml/services/file2
...
They can then be loaded using the _filename
attribute:
<example _filename="file1"/>
This is useful for long examples.
The param
elements contain a pos
attribute, which indicates what capture field
from the pattern
should be extracted, or 0
for a static string. The name
attribute
is the key that will be reported in the case of a successful match and the value
will either be a static string for pos
values of 0
or missing and taken from the
captured field.
The value
attribute supports interpolation of data from other fields. This is
often useful when capturing the value for hw.product
via regex and re-using this
value in os.product
.
Here is an example fromhttp_servers.xml
where hw.product
is captured and reused.
<fingerprint pattern="^Eltex (TAU-\d+[A-Z]*(?:\.IP)?)$">
<description>Eltex TAU model VoIP gateway</description>
<example hw.product="TAU-72">Eltex TAU-72</example>
<example hw.product="TAU-1.IP">Eltex TAU-1.IP</example>
<param pos="0" name="os.vendor" value="Eltex"/>
<param pos="0" name="os.product" value="{hw.product} Firmware"/>
<param pos="0" name="os.device" value="VoIP Gateway"/>
<param pos="0" name="hw.vendor" value="Eltex"/>
<param pos="1" name="hw.product"/>
<param pos="0" name="hw.device" value="VoIP Gateway"/>
</fingerprint>
There is special handling for temporary attributes that have a name starting with
_tmp.
. These attributes can be used for interpolation but are not emitted in the
output. This is useful when a particular product name is inconsistent in various
banners, vendor marketing, or with NIST values when trying to generate CPEs. In
these cases the useful parts of the banner can be extracted and a new value
crafted without cluttering the data emitted by a match.
<fingerprint pattern="^foo baz switchThing-(\d{4})$">
<description>NetCorp NX series switches</description>
<example hw.product="NX8200">foo baz switchThing-8200</example>
<param pos="0" name="hw.vendor" value="NetCorp"/>
<param pos="0" name="hw.product" value="NX{_tmp.001}"/>
<param pos="2" name="_tmp.001"/>
</fingerprint>
These temporary attributes are not tracked in the identifiers/fields.txt
.
The following examples make use of bin/recog_match
, a simple Ruby command line tool that uses Recog's fingerprint data. Pre-processing is generally required before running Recog, i.e. extracting HTTP header values, etc. All fingerprint data can be found in xml/*.xml
.
Fingerprint FTP servers based on the server's banner response after connecting:
# Example plaintext input
echo -n '220 Microsoft FTP Service' | bin/recog_match xml/ftp_banners.xml -
# Example command using nmap
nmap -sV -script=banner -p 21 192.168.123.13 | grep --color=never '_banner' | cut -d: -f2- | bin/recog_match xml/ftp_banners.xml -
# Example output
MATCH: {"matched"=>"Microsoft FTP Server on Windows XP, 2003 or later without version", "service.vendor"=>"Microsoft", "service.product"=>"IIS", "service.family"=>"IIS", "service.cpe23"=>"cpe:/a:microsoft:iis:-", "os.vendor"=>"Microsoft", "os.family"=>"Windows", "os.product"=>"Windows", "os.cpe23"=>"cpe:/o:microsoft:windows:-", "host.name"=>"220", "service.protocol"=>"ftp", "fingerprint_db"=>"ftp.banner", "data"=>"220 Microsoft FTP Service"}
Using the HTTP Set-Cookie
header value to fingerprint an HTTP server:
# Example plaintext input
echo 'laravel_session=eyJ...etc..etc...%3D; expires=Mon, 13-Mar-2023 16:48:58 GMT; Max-Age=7200; path=/; httponly; samesite=lax' | bin/recog_match xml/http_cookies.xml -
# Example cURL command
curl --silent -I http://localhost:9001 | grep --color=never -i '^Set-Cookie:' | cut -d: -f2- | bin/recog_match xml/http_cookies.xml -
# Example output
MATCH: {"matched"=>"Laravel PHP web application framework", "service.vendor"=>"Laravel", "service.product"=>"Laravel", "service.cpe23"=>"cpe:/a:laravel:laravel:-", "service.protocol"=>"http", "fingerprint_db"=>"http_header.cookie", "data"=>"laravel_session=eyJ...etc..etc...%3D; expires=Mon, 13-Mar-2023 16:48:58 GMT; Max-Age=7200; path=/; httponly; samesite=lax"}
Using the HTTP Server
header value to fingerprint an HTTP server:
# Example plaintext input
echo -n 'Apache/2.4.38 (Debian)' | bin/recog_match xml/http_servers.xml -
# Example cURL command
curl --silent -I http://localhost:9001 | grep --color=never -i '^Server:' | cut -d: -f2- | bin/recog_match xml/http_servers.xml -
# Example output
MATCH: {"matched"=>"Apache", "service.vendor"=>"Apache", "service.product"=>"HTTPD", "service.family"=>"Apache", "service.version"=>"2.4.38", "service.cpe23"=>"cpe:/a:apache:http_server:2.4.38", "apache.info"=>"(Debian)", "service.protocol"=>"http", "fingerprint_db"=>"http_header.server", "data"=>"Apache/2.4.38 (Debian)"}
Using the md5sum of a favicon to identify a running service:
# Example plaintext input
echo -n fe22dd2bb09daccf58256611ac491469 | bin/recog_match xml/favicons.xml -
# Example cURL command
curl --silent http://localhost:8000/favicon.ico | md5sum | awk '{ print $1 }' | bin/recog_match xml/favicons.xml -
# Example output
MATCH: {"matched"=>"Drupal CMS", "service.vendor"=>"Drupal", "service.product"=>"CMS", "service.certainty"=>"0.5", "service.cpe23"=>"cpe:/a:drupal:drupal:-", "service.protocol"=>"", "fingerprint_db"=>"favicon.md5", "data"=>"fe22dd2bb09daccf58256611ac491469"}
Using the HTTP WWW-Authenticate
header value to fingerprint an HTTP server:
# Example plaintext input
echo -n 'Basic realm="monit"' | bin/recog_match xml/http_wwwauth.xml -
# Example cURL command
curl --silent -I http://localhost:9001 | grep --color=never -i '^WWW-Authenticate:' | cut -d: -f2- | bin/recog_match xml/http_wwwauth.xml -
# Example output
MATCH: {"matched"=>"Minot", "service.vendor"=>"Tildeslash", "service.product"=>"Monit", "service.cpe23"=>"cpe:/a:tildeslash:monit:-", "service.protocol"=>"http", "fingerprint_db"=>"http_header.wwwauth", "data"=>"Basic realm=\"monit\""}
Fingerprint TLS servers based on the server's response to 10 TLS Client Hello packets. Fingerprint based on https://github.com/salesforce/jarm
# Example plaintext input
echo -n 07d14d16d21d21d07c42d43d000000f50d155305214cf247147c43c0f1a823 | bin/recog_match xml/jarm.xml -
# Example command using Salesforce's JARM against a running Metasploit listener
python3 $code/jarm/jarm.py -p 8443 192.168.123.1 | grep --color=never 'JARM: ' | awk -F: '{ print $2 }' | bin/recog_match xml/tls_jarm.xml -
# Example output
MATCH: {"matched"=>"Metasploit listener", "service.vendor"=>"Rapid7", "service.product"=>"Metasploit", "service.cpe23"=>"cpe:/a:rapid7:metasploit:-", "service.protocol"=>"tls", "fingerprint_db"=>"tls.jarm", "data"=>"07d14d16d21d21d07c42d43d000000f50d155305214cf247147c43c0f1a823"}
The users and maintainers of Recog would greatly appreciate any contributions you can make to the project. For guidelines and instructions please see CONTRIBUTING.MD