_
| \
,---------------------------------, _/ >
| 1 \____ __/ /
| \ \ _/ \
| \ 3 '-, | ,-'
______ | \_ / \ \_/ /
/ ____/_| ____ / / ____ ___/ _\__ ____ ____ / /_ ____|_ ___ _____
/ / __/ _ \/ __ \/ / \ / __ \/ __ \/ __ \/ __ \/ __ \/ / / / /_ / / _ \/ ___/
/ /_/ / __/ /_/ / /___/ /_/ / /_/ / /_/ / / / / /_/ / / /_/ / / /_/ __/ /
\____/\___/\____/_____/\____/\__, /\____/_/ /_/\__,_/_/\__, / /___/\___/_/
\ \ /____/ \ /____/ /
|_ \ / \ /
\ 2 \ /
----. \ /
'-,_ 4 \
`-----, ,-------, \
\,~. ,---^---' | \
\ / \ |
\ | \_|
`-'
GeoLogonalyzer is a utility to perform location and metadata lookups on source IP addresses of remote access logs. This analysis can identify anomalies based on speed of required travel, distance, hostname changes, ASN changes, VPN client changes, etc.
GeoLogonalyzer extracts and processes changes in logon characteristics to reduce analysis requirements. For example, if a user logs on 500 times from 1.1.1.1 and then 1 time from 2.2.2.2, GeoLogonalyzer will create one line of output that shows information related to the change such as:
- Detected anomalies
- Data Center Hosting information identified
- Location information
- ASN information
- Time and distance metrics
For Windows users, we recommend running the compiled executable due to the number of python dependencies required for GeoLogonalyzer:
https://github.com/fireeye/GeoLogonalyzer/releases
Note that the provided Windows Executable will not allow you to add custom log parsing or change the following constants described below.
If you need to use the python source code (such as for modifiying configurations, adding custom log parsing, or running on *nix/OSX), you will need to install the following dependencies which you may not already have:
netaddr
python-geoip
win_inet_pton
geopy
geoip2
A pip requirements.txt is provided for your convenience.
pip install -r requirements.txt
The following constants can be modified when running the Python source code to suite your analysis needs:
Constant Name | Default Value | Description |
---|---|---|
RESERVED_IP_COORDINATES | (0, 0) | Default Lat\Long coordinates for IP addresses identified as reserved |
FAR_DISTANCE | 500 | Threshold in miles for determining if two logons are "far" away from eachother |
FAST_MPH | 500 | Threshold in miles per hour for determining if two logons are "geoinfeasible" based on distance and time |
By default, Geologonalyzer supports time sorted remote access logs in the following CSV format:
YYYY-MM-DD HH:MM:SS,user,10.10.10.10,hostname(optional),VPN client (optional)
Example CSV input.csv file (created entirely for demonstration purposes):
2017-11-23 10:05:02, Meghan, 72.229.28.185, Meghan-Laptop, CorpVPNClient
2017-11-23 11:06:03, Meghan, 72.229.28.185, Meghan-Laptop, CorpVPNClient
2017-11-23 12:00:00, Meghan, 72.229.28.185, Meghan-Laptop, CorpVPNClient
2017-11-23 13:00:00, Meghan, 72.229.28.185, Meghan-Laptop, CorpVPNClient
2017-11-24 10:07:05, Meghan, 72.229.28.185, Meghan-Tablet, OpenSourceVPNClient
2017-11-24 17:00:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-24 17:15:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-24 17:30:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-24 20:00:00, Meghan, 104.175.79.199, android, AndroidVPNClient
2017-11-24 21:00:00, Meghan, 104.175.79.199, android, AndroidVPNClient
2017-11-25 17:00:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-25 17:05:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-25 17:10:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-25 17:11:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-25 19:00:00, Harry, 101.0.64.1, andy-pc, OpenSourceVPNClient
2017-11-26 10:00:00, Meghan, 72.229.28.185, Meghan-Laptop, CorpVPNClient
2017-11-26 17:00:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-27 10:00:00, Meghan, 72.229.28.185, Meghan-Laptop, CorpVPNClient
2017-11-27 17:00:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-28 10:00:00, Meghan, 72.229.28.185, Meghan-Laptop, CorpVPNClient
2017-11-28 17:00:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
2017-11-29 10:00:00, Meghan, 72.229.28.185, Meghan-Laptop, CorpVPNClient
2017-11-29 17:00:00, Harry, 97.105.140.66, Harry-Laptop, CorpVPNClient
If you have a log format that is difficult to convert to CSV, GeoLogonalyzer supports custom log format parsing through modification of the "get_custom_details" function.
For this function, input will be a line of text, and output must contain:
return time, ip_string, user, hostname, client
Here is a Juniper PulseSecure log format and the sample code to extract required fields:
# Example Juniper Firewall Input line (wrapped on new lines):
# Mar 12 10:59:33 FW_JUNIPER <FW_IP> PulseSecure: id=firewall time="2018-03-12 10:59:33" pri=6
# fw=<FW_IP> vpn=<VPN_NAME> user=System realm="" roles="" type=mgmt proto= src=<SRC_IP> dst=
# Example function to fill in for "get_custom_details(line):
# Create regex match object to find data
juniper_2_ip_user_mo = re.compile("(time=\")([\d\ \-\:]{19})(\" .*)( user\=)(.*?)"
"( realm.*? src=)(.*?)( )")
# Match the regex
ip_user_match = re.search(juniper_2_ip_user_mo, line)
# Extract timestamp and convert to datetime object from "2017-03-30 00:22:42" format
time = datetime.strptime(ip_user_match.group(2).strip(), '%Y-%m-%d %H:%M:%S')
# Extract username and source IP (not the <FW_IP>
user = ip_user_match.group(5).strip()
ip_string = ip_user_match.group(7).strip()
# Set empty hostname and client since they were not included in input
hostname = ""
client = ""
return time, ip_string, user, hostname, client
The following command will parse the input.csv shown above and save results to output.csv:
GeoLogonalyzer --csv input.csv --output.csv
The output.csv file will include the following column headers:
Column Header | Description |
---|---|
User | Username of logons compared |
Anomalies | Flags for anomalies detailed in "Automatic Anomaly Detection" section below |
1st Time | Time of 1st compared logon |
1st IP | IP Address of 1st compared logon |
1st DCH | Datacenter hosting information of 1st compared logon |
1st Country | Country associated with IP address of 1st compared logon |
1st Region | Region associated with IP address of 1st compared logon |
1st Coords | Lat/Long coordinates associated with IP address of 1st compared logon |
1st ASN # | ASN number associated with IP address of 1st compared logon |
1st ASN Name | ASN name associated with IP address of 1st compared logon |
1st VPN Client | VPN client name associated with 1st compared logon |
1st Hostname | Hostname associated with 1st compared logon |
1st Streak | Count of logons by user from 1st compared source IP address before change |
2nd Time | Time of 2nd compared logon |
2nd IP | IP Address of 2nd compared logon |
2nd DCH | Datacenter hosting information of 2nd compared logon |
2nd Country | Country associated with IP address of 2nd compared logon |
2nd Region | Region associated with IP address of 2nd compared logon |
2nd Coords | Lat/Long coordinates associated with IP address of 2nd compared logon |
2nd ASN # | ASN number associated with IP address of 2nd compared logon |
2nd ASN Name | ASN name associated with IP address of 2nd compared logon |
2nd VPN Client | VPN client name associated with 2nd compared logon |
2nd Hostname | Hostname associated with 2nd compared logon |
Miles Diff | Difference in miles between two associated coordinates of two compared IP addresses |
Seconds Diff | Difference in time between two compared authentications |
Miles/Hour | Speed required to physically move from 1st logon location to 2nd logon location by time difference between compared logons. Miles Diff / Seconds Diff |
-
Unless otherwise configured (as described above), RFC1918 and other reserved IP addresses are assigned a geolocation of (0,0) which is located in the Atlantic Ocean near Africa which will skew results. a. Use the --skip_rfc1918 command line parameter to completely skip any reserved source IP address such as RFC1918. This is useful to reduce false positives if your data includes connections from internal networks such as 10.10.10.10 or 192.168.1.100.
-
Use the Automatic Anomaly Detection flags listed below to quickly identify anomalies. Examples include changes in logons that: a. require require an infeasible rate of travel (FAST) b. involve a large change in distance (DISTANCE) c. involvce a source IP address registered to a datacenter hosting provider such as Digital Ocean or AWS (DCH) d. changes in ASN (ASN), VPN client name (CLIENT), or source system hostname (HOSTNAME)
-
Look for IP addresses registered to unexpected countries.
-
Analyze the "Streak" count to develop a pattern of logon behavior from a source IP address before a change occurs.
-
Analyze all hostnames to ensure they match standard naming conventions.
-
Analyze all software client names to identify unapproved software.
GeoLogonalyzer will try to automatically flag on the following anomalies:
Flag | Description |
---|---|
DISTANCE | This flag indicates the distance between the two compared source IP addresses exceeded the configured FAR_DISTANCE constant. This is 500 miles by default. |
FAST | This flag indicates the speed required to travel between the two compared source IP addresses in the time between the two compared authentications exceeded the configured IMPOSSIBLE_MPH constant. This is 500 MPH by default. Estimate source: https://www.flightdeckfriend.com/how-fast-do-commercial-aeroplanes-fly |
DCH | This flag indicates that one of the compared IP Addresses is registered to a datacenter hosting provider. |
ASN | This flag indicates the ASN of the two compared source IP addresses was not identical. Filtering out source IP address changes _that do not have this flag_ may cut down on legitimate logons from nearby locations to review. |
CLIENT | If VPN client information is processed by GeoLogonalyzer, this flag indicates a change in VPN client name between the two compared authentications. This can help identify use of unapproved VPN client software. |
HOSTNAME | If hostname information is processed by GeoLogonalyzer, this flag indicates a change in hostname between the two compared authentications. This can help identify use of unapproved systems connecting to your remote access solution. |
GeoLogonalyzer can be used to provide metadata lookups on a text file that lists IP addresses one per line. Example ip-input.txt file (created entirely for demonstration purposes):
1.3.5.7
10.39.4.5
127.9.4.5
34.78.32.14
192.4.4.3
asdffasdf
2.4.5.0
Example execution syntax:
GeoLogonalyzer --ip_only ip-input.txt --output ip-output.csv
Example ip-output.csv:
ip,location,country,subdivisions,dch_company,asn_number,asn_name
1.3.5.7,"(23.1167, 113.25)",CN,GD, , ,
10.39.4.5,"(0, 0)",PRIVATE,PRIVATE,,,
127.9.4.5,"(0, 0)",RESERVED,RESERVED,,,
34.78.32.14,"(29.9668, -95.3454)",US,TX, , ,
192.4.4.3,"(40.6761, -74.573)",US,NJ, ,54735,"TT Government Solutions, Inc."
asdffasdf,"(0, 0)",INVALID,INVALID,,,
2.4.5.0,"(43.6109, 3.8772)",FR,"OCC, 34", ,3215,Orange
This product is licensed under the Apache License, Version 2.0 and is
Copyright <C> 2018 FireEye, Inc. You may obtain a copy of the License
at: http://www.apache.org/licenses/LICENSE-2.0. Unless required by
applicable law or agreed to in writing, software distributed under the
License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR
CONDITIONS OF ANY KIND, either express or implied. See the License for
the specific language governing permissions and limitations under the
License.
This product includes GeoLite2 data created by MaxMind, available from
http://www.maxmind.com provided under the Creative Commons Attribution-
ShareAlike 4.0 International License. Copyright (C) 2012-2018 Maxmind, Inc.
Copyright (C) 2012-2018 Maxmind, Inc.
This product retrieves and operates on data including datacenter
categorizations retrieved from https://github.com/client9/ipcat/ which
are Copyright <C> 2018 Client9. This data comes with ABSOLUTELY NO
WARRANTY; for details go to:
https://raw.githubusercontent.com/client9/ipcat/master/LICENSE
The data is free software, and you are welcome to redistribute it under
certain conditions. See LICENSE for details.
- All GeoIP lookups are dependent on the accuracy of MaxMind database values
- All DCH lookups are dependent on the accuracy of open source data
- VPN or network tunneling services may skew results
GeoLogonalyzer was created by David Pany. The project was inspired by research performed by FireEye's data science team including Christopher Schmitt, Seth Summersett, Jeff Johns, Alexander Mulfinger, and more whose work supports live remote access processing in FireEye Helix - https://www.fireeye.com/solutions/helix.html.
Please comment [email protected] or @davidpany on Twitter for bugs, comments, or suggestions.