The WiFiMon Analysis StationServer (WAS) is the core component of WiFiMon which gathers and processes all the measurement data. The WAS receives the following data:
- Results of crowdsourced measurements streamed from End Users in the monitored WiFi networks.
- Results of deterministic measurements streamed from WiFiMon Hardware Probes in the monitored WiFi networks.
- RADIUS Logsand DHCP logs from RADIUS Serversand DHCP servers respectively.
- Wireless network performance metrics streamed from WiFiMon from WiFiMon Hardware Probes.
The WAS mainly WAS mainly consists of two software components: (i1) the WiFiMon Agent and (ii2) the WiFiMon GUI.
(1) WiFiMon Agent
The WiFiMon Agent is Agent is responsible for performing the following actions:
- The analysis of crowdsourced of crowdsourced measurements. These measurements are received from End Users and the Users and WAS correlates them with information received from RADIUS and DHCP Logs when/if this information is available.
- The analysis of deterministic of deterministic measurements. These measurements are received from WiFiMon Hardware Probes and the and WAS correlates them with information received from RADIUS and DHCP Logs when/if this information is available.
- The analysis of wireless of wireless network performance metrics received from WiFiMon Hardware Probes.
- Storing the results of analysis and correlation.
The WiFiMon GUI depicts the results of the WiFiMon Agent analysis as described above.
In the sequel, we refer to the WiFiMon Agent as Non-Secure WiFiMon Agent if crowdsourced and WiFiMon Agent can operate in a non-secure manner (non-secure WiFiMon Agent) when the crowdsourced and deterministic measurements are streamed over HTTP or in a secure manner (Secure WiFiMon Agent) if measurements are streamed over HTTPS.
(2) WiFiMon GUI
The WiFiMon GUI provides a graphical representation of the measurement results and various anayses as described above.
WAS Installation and Configuration Guide
This guide given below presents the commands required to install the WAS in WAS in a Debian-based distribution (Debian, Ubuntu, etc.). Other distributions may also be considered by adjusting the included commands appropriately.
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Our installation was tested in Ubuntu 18.04 LTS.
Prerequisites for the WiFiMon Analysis Station (WAS) Installation
To install WiFiMon Analysis Station (WAS) successfully, the following software components are required:
- WiFiMon Agent package (version 1.3.0)
- PostgreSQL (tested on version 10.1216)
- Java 811
- Elasticsearch (tested on version 7.49.23)
- Kibana (tested on version 7.49.23)
- Logstash (required in case of correlation with RADIUS and DHCP Logs, tested on version 7.49.23)
The following ports must be available on the WAS. However, the ports may be changed manually depending on your needs:
- 5044: for Logstash
- 5432: for PostgreSQL
- 5601: for Kibana
- 8441: for WiFiMon GUI
- 8443: for WiFiMon Secure Agent
- 9000: for WiFiMon Non-secure Agent (optional)
- 9200: for communication with Elasticsearch
1. Overview of the WiFiMon Analysis Station (WAS) Installation
A summary of the mandatory steps for the installation (detailed in the linked sections below):
- Installation of PostgreSQLof PostgreSQL
- Installation of Javaof Java
- Installation of Elasticsearchof Elasticsearch
- Installation of Kibanaof Kibana
- Configuration of Elasticsearchof Elasticsearch
- Configuration of Kibanaof Kibana
- Installation of WiFiMon of WiFiMon Agent and WiFiMon GUI
There are also some optional steps:
- Configuration of the WiFiMon Secure the WiFiMon Secure Agent certificate
Anchor PostgreSQL PostgreSQL
2. PostgreSQL
PostgreSQL | |
PostgreSQL |
Installing PostgreSQL Installing PostgreSQL from a package manager requires using the following commands:
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sudo apt-get install -y postgresql postgresql-contrib
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By default, PostgreSQL is configured to listen on localhost. We suggest that this default configuration is not modified.
After the installation of PostgreSQLof PostgreSQL, the database and tables required by WiFiMon should be created. Detailed instructions are included in the following subsections.
Anchor database database
2.1. Database and User Creation
database | |
database |
The following code block includes the appropriate SQL commands required to create (i) a database that will store information related to Subnets and Access Points monitored by WiFiMon as well as accounts of users that can access the WiFiMon GUI and GUI and (ii) a user that will be able to access this database. The following commands create the (i) database "wifimon_database" and (ii) the user "wifimon_user" with password "wifimonpass". We strongly suggest that these example names are changed in production environments.
Accessing PostgreSQL requires PostgreSQL requires becoming user "postgres". This is possible from the "root" user using the command “su postgres”. Afterwards, the terminal-based front-end of PostgreSQL is PostgreSQL is accessed using the command "psql".
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CREATE USER wifimon_user WITH PASSWORD 'wifimonpass'; CREATE DATABASE wifimon_database OWNER wifimon_user; |
After the creation of the database "wifimon_database", selecting this database is possible via the following command:
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The following subsections include the commands that are necessary for the creation of the required tables.
2.2. Creation of "subnets" Table
WiFiMon measures WiFiMon measures the performance of WiFi networks by embedding JavaScript code in frequently visited websites. Performance tests are triggered when End when End Users visit these websites and, in particular, after a web page is loaded so that browsing experience is not impacted by WiFiMon. Notably, these websites are not only visited by End Users residing in the monitored Subnets, but also from End Users outside them. Thus, alleviating the WAS from WAS from processing excessive traffic requires that performance tests consider measurements originating only from the WiFi networks that are monitored. To that end, a list of the registered Subnets from which End User measurements are processed by the WAS are maintained in "subnets" table. The creation of this table is detailed in the following code block.
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CREATE TABLE subnets ( subnet text, subnet_id serial PRIMARY KEY ); |
2.3. Creation of "accesspoints" Table
Table "accesspoints" is used to store information related to the Access Points monitored by WiFiMon. This information includes the latitude and longitude of Access Points, the building and floor in which they are installed and additional notes about them. This information is later used to depict performance results of End User measurements per Access Point. The creation of the "accespoints" table is detailed in the following code block.
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CREATE TABLE accesspoints ( apid serial PRIMARY KEY, mac text NOT NULL, latitude text, longitude text, building text, floor text, notes text); |
2.4. Creation of "users" Table
Table "users" is is used to store information related to WiFiMon Users. WiFiMon GUI can GUI can be accessed by two types of WiFiMon Users: ADMIN and USER. ADMIN has full privileges to the WiFiMon GUI. An ADMIN is capable of adding/removing registered Subnets and Access Points as well as adding/removing WiFiMon UsersWiFiMon Users. In contrast, a USER can navigate through the WiFiMon GUI dashboards, but is incapable of performing administration actions. The creation of the "users" table is detailed in the following code block.
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CREATE TABLE users ( id serial PRIMARY KEY, email text NOT NULL, password_hash text NOT NULL, role text NOT NULL); |
2.5. Creation of "options" Table
Table "optionsoptions" stores information related to privacy settings, e.g. hiding/showing End User specific data in the WiFiMon GUI. Correlation options are also included in this table. The creation of the "options" table is detailed in the following code block.
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Exiting the database is possible using the command "\q" within the terminal-based front-end of PostgreSQL.
Setting Privileges in PostgreSQL
Setting SELECT, INSERT, DELETE, UPDATE privileges for the database user, e.g. "wifimon_user" requires requires the following commands issued within the terminal-based front-end of PostgreSQL:
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GRANT USAGE ON SCHEMA public to wifimon_user; GRANT CONNECT ON DATABASE wifimon_database to wifimon_user; \c wifimon_database GRANT USAGE ON SCHEMA public to wifimon_user; GRANT SELECT ON subnets, users, accesspoints, options TO wifimon_user; GRANT INSERT ON subnets, users, accesspoints, options TO wifimon_user; GRANT DELETE ON subnets, users, accesspoints, options TO wifimon_user; GRANT UPDATE ON accesspoints, options TO wifimon_user; GRANT USAGE, SELECT ON SEQUENCE subnets_subnet_id_seq TO wifimon_user; GRANT USAGE, SELECT ON SEQUENCE users_id_seq TO wifimon_user; GRANT USAGE, SELECT, UPDATE ON SEQUENCE options_optionsid_seq TO wifimon_user; GRANT USAGE, SELECT, UPDATE ON SEQUENCE accesspoints_apid_seq TO wifimon_user; |
Exiting the database is possible using the command "\q" within the terminal-based front-end of PostgreSQL.
Create an admin account to login
An initial ADMIN WiFiMon User should be created for accessing the WiFiMon GUI. Within the terminal-based front-end of PostgreSQL, an ADMIN WiFiMon User is created using the commands in the following code block after connection to the WiFiMon database. Notably, passwords are stored hashed within the database.
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Inserting this entry to the "users" table creates an ADMIN WiFiMon User that is able to login in the WiFiMon GUI using GUI using the following credentials:
Email: admin@test.com
Password: admin1
This account can be later deleted from the WiFiMon GUI (after step 5). However, an ADMIN account should always be present in order to access the WiFiMon GUI and manage the WiFiMon Users, Access Points and Subnets. We strongly suggest that the password is changed from the WiFiMon GUI when the installation is complete (step 5).
Anchor java java
3. Java Installation
java | |
java |
WiFiMon currently supports Java 8. Installing Java 8 is detailed in the sequel for the Debian 10 Operating System. These instructions are taken from HERE.Installing the OpenJDK 8 in Debian 10 requires using the AdoptOpenJDK repository. The 11. The required commands are the following:
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sudo apt update sudo apt-get install -y aptopenjdk-transport11-httpsjdk ca-certificates wget dirmngr gnupg software-properties-common wget -qO - https://adoptopenjdk.jfrog.io/adoptopenjdk/api/gpg/key/public | sudo apt-key add - sudo add-apt-repository --yes https://adoptopenjdk.jfrog.io/adoptopenjdk/deb/ sudo apt update sudo apt install -y adoptopenjdk-8-hotspotopenjdk-11-jre |
Java installation can be verified with the following command:
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java -version |
Setting the JAVA_HOME variable requires (i) finding the installed Java alternatives using the following command "sudo update-alternatives --config java" and (ii) modifying the /etc/environment configuration file based on the output of the previous command. In our case, JAVA_HOME requires the following value:
JAVA_HOME="/usr/lib/jvm/java-11-openjdk-amd64"
Changes are applied Java installation can be verified with the following command:
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java -version |
Setting the JAVA_HOME variable requires (i) finding the installed Java alternatives using the following command "sudo update-alternatives --config java" and (ii) modifying the /etc/environment configuration file based on the output of the previous command. For the adoptojdk-8-hotspot, JAVA_HOME requires the following value:
JAVA_HOME="/usr/lib/jvm/adoptopenjdk-8-hotspot-amd64"
Changes are applied with the following command:
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source /etc/environment |
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Installing Elasticsearch 7.4.2 and Kibana 7.4.2, requires executing the following commands:
- Elasticsearch 7.4.2
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source /etc/environment |
Anchor elasticsearch elasticsearch
4. Elasticsearch and Kibana
elasticsearch | |
elasticsearch |
Installing Elasticsearch 7.9.3 and Kibana 7.9.3, requires executing the following commands:
- Elasticsearch 7.9.3
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wget https://artifacts.elastic.co/downloads/elasticsearch/elasticsearch-7. |
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3-amd64.deb |
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sudo dpkg -i elasticsearch-7. |
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3-amd64.deb |
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- Kibana 7.
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- 9.
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- 3
Anchor kibana kibana
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wget https://artifacts.elastic.co/downloads/kibana/kibana-7. |
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9. |
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3-amd64.deb |
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sudo dpkg -i kibana-7. |
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9. |
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3-amd64.deb |
Anchor elasticsearch_configure elasticsearch_configure
Elasticsearch Configuration
elasticsearch_configure | |
elasticsearch_configure |
In the configuration file of Elasticsearch (/etc/elasticsearch/elasticsearch.yml), the following lines should be inserted/changed. Notably, bold parts must be adjusted to the particular configuration of the reader. In the following, we configure Elasticsearch to be publicly accessible:
cluster.name: elasticsearch node.name: ${HOSTNAME} node.master: true node.voting_only: false node.data: true node.ingest: true node.ml: false cluster.remote.connect: false path.data: /var/lib/elasticsearch path.logs: /var/log/elasticsearch network.host: INSERT the Fully Qualified Domain Name (WAS_FQDN) to which the server listens discovery.seed_hosts: [“"INSERT the WAS_FQDN to which the server listens”"] cluster.initial_master_nodes: INSERT the HOSTNAME (not WAS_FQDN) of the server xpack.ml.enabled: false xpack.security.enabled: false |
The Elasticsearch cluster should be started with the following command:
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service elasticsearch restart |
Verifying that Elasticsearch is running is possible via: netstat -tlnpu (ports 9200, 9300)
Notably, "cluster.initial_master_nodes" must be commented out after the first initialization of the Elasticsearch the Elasticsearch cluster. The above configuration assumes that the setup includes a single Elasticsearch single Elasticsearch node. Configuration for more advanced setups is available in the following WiFiMon guide "Streaming Logs Into ELK Cluster".
Anchor kibana_configure kibana_configure
Kibana Configuration
kibana_configure | |
kibana_configure |
After installing Kibana, the following configurations are required in the Kibana configuration file (/etc/kibana/kibana.yml). The following changes should be made in the corresponding sections/fields of the configuration file. Notably, bold parts must be adjusted to the particular configuration of the reader.
server.port: 5601 server.host: “"INSERT the Fully Qualified Domain Name (WAS_FQDN) to which the server listens”" server.name: “wifimon"wifimon-kibana”kibana" elasticsearch.hosts: [“http"http://WAS_FQDN:9200”9200"] server.ssl.enabled: false |
Kibana should Kibana should be started with the following command:
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service kibana restart |
Verifying that kibana is running is possible via: netstat -tlnpu (port 5601)
Anchor wifimon wifimon
5. WiFiMon Installation
wifimon | |
wifimon |
Installing WiFiMon requires Installing WiFiMonrequires the following commands:
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wget |
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http:// |
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83.97.95.167/deb/wifimon-agent- |
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0.deb |
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sudo apt-get update |
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sudo apt-get install -y gdebi |
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sudo gdebi wifimon-agent- |
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3.0.deb |
Afterwards, the following files will show up in /usr/lib/wifimon/ directory:
elasticsearch.sh: Script to create Elasticsearch indices
kibana-import.ndjson: JSON file to be imported in Kibana to create the necessary visualizations and dashboards
start.sh: Script for starting WiFiMon GUI and Agent
secure-processor-0.1.13.war0war: This incorporates both the WiFiMon Secure and Non-Secure Agent
ui-01.13.10.war: This incorporates the WiFiMon GUI
config: Directory with configuration files. Their parameters must be filled in.
keystore: Directory where the Java Keystore should be stored in order to run WiFiMon Agent and GUI on HTTPS
Execution permissions are required for scripts elasticsearch.sh and start.sh. These are provided with the following commands: Anchor run run
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chmod +x elasticsearch.sh |
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chmod +x start.sh |
Before the execution of script elasticsearch.sh, “"curl” must " must be installed. This is possible using the following commands:
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sudo apt-get update |
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sudo apt-get install -y curl |
Script elasticsearch.sh must be edited to match the interface the Elasticsearch the Elasticsearch cluster listen listens to. The FQDN of the WAS should be provided or localhost if the WAS is configured to listen on localhost. Script elasticsearch.To that end, the variable FQDN with the elasticsearch.sh file should be substituted with the value of the "network.host" attribute in "/etc/elasticsearch/elasticsearch.yml" file. Script elasticsearch.sh will add the required indices and some initial data in the Elasticsearch cluster:
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./elasticsearch.sh |
In the sequel, Kibana index patterns should be configured from the Kibana User Interface. In Kibana, the "wifimon" index pattern can be created from from Management/Stack Management/Index Patterns. The following details should be provided:
Index pattern: wifimon
- Time Filter field name: timestamp
Index pattern ID: wifimon_v0.1 (advanced options should options should be selected to see this field)
and the following details are required to create "radiuslogs" index (for the correlation of RADIUS Logs with End User measurements):
Index pattern: radiuslogs
- Time Filter field name: Timestamp
Index pattern ID: radiuslogs_v0.1 (advanced options should be selected to see this field)
and the following details are required to create "probes" index (for the metrics collected from the WiFiMon Hardware Probes):
Index pattern: probes
- Time Filter field name: timestamp
Index pattern ID: probes_v0.1 (advanced options should options should be selected to see this field)
and the following to create "dhcplogs" index (for the correlation of DHCP Logs with End User measurements):
Index pattern: dhcplogs
- Time Filter field name: timestamp
Index pattern ID: dhcplogs_v0.1 (advanced options should be selected to see this field)
After the creation of index patterns, the necessary visualizations and dashboards should be imported. To that end, the kibana-import.ndjson file should be imported in the Management/Saved Objects tab.
After the creation of index patterns, the necessary visualizations and dashboards should be imported. To that end, the kibana-import.ndjson file should be imported in the Management/Stack Management/Saved Objects tab.
Finally, WiFiMon properties should be configured in the files (secure-processor.properties, ui.properties) of the WiFiMon config directory. Notably, WiFiMon uses HMAC SHA-512 encryption to encrypt sensitive data (End User IP addresses, End User MAC addresses) that are stored in the Elasticsearch cluster and visualized by Kibana. In secure-processor.properties, the key of this algorithm must be defined (property "sha.key"). This key is of type String and the reader could select any well-formatted string, preferably of big length. This string is defined only in the secure-processor.properties configuration file.
Apart from the "sha.key" property, the WiFiMon administrator is required to provide the port on which the WAS listens (property "server.port"), i.e. 9000 for the case of the WiFiMon Non-Secure Agent. Later, this documentation demonstrates how to install the WiFiMon Secure Agent; the WiFiMon Administrator is then required to change the value of the "server.port" property to 8443 from 9000.
Moreover, the WiFiMon Administrator should set the value of the PostgreSQL properties according to what was provided in the 2nd step of this documentation. Based on the example values of our documentation, "spring.datasource.url" can be defined as "jdbc:postgresql://localhost:5432/wifimon_database" and "spring.datasource.username", "spring.datasource.password" properties can be defined as "wifimon_user", "wifimonpass" respectively. Please, make sure that you change the aforementioned password to secure your PostgreSQL database setup.
Afterwards, the WiFiMon Administrator is required to provide the name of the Elasticsearch cluster ("elasticsearch.clustername" property) that was provided in step 4 of this documentation (e.g. "elasticsearch" in this guide) and the FQDN Elasticsearch listens on for the "elasticsearch.host" property.
In ui.properties, the WiFiMon Administrator is expected to provide the values for the PostgreSQL properties (the same as in the secure-processor.properties file) as well as the Kibana properties. Specifically, the WiFiMon Administrator should insert the FQDN Kibana listens on ("server.host.name" property), the protocol used by Kibana ("kibana.protocol" property), which is "http" for the WiFiMon Non-Secure Agent (this step) or "https" for the WiFiMon Secure Agent (step 7 of this documentation) as well as the port Kibana listens to ("kibana.port" property), which is usually 5601. Finally, WiFiMon provides methods for checking if a new software version is available. To that end, the running version of the WiFiMon software is compared with the most recent version that is stored within a VM provided by GEANT. Moreover, this VM keeps some statistics of WiFiMon end users involving their IP address and running version. The purpose of this is to track how many users are currently utilizing WiFiMon and what versions. If the WiFiMon end user wants to be excluded from this process, "user.tracking" should be changed to "no"Finally, WiFiMon properties should be configured in the files (secure-processor.properties, ui.properties) of the WiFiMon config directory. Notably, WiFiMon uses HMAC SHA-512 encryption to encrypt sensitive data (End User IP addresses, End User MAC addresses) that are stored in the Elasticsearch cluster and visualized by Kibana. In secure-processor.properties, the key of this algorithm must be defined. This key is of type String and the reader could select any well-formatted string, preferably of big length. This string is defined only in the secure-processor.properties configuration file.
Starting the WiFiMon Secure Agent and WiFiMon GUI requires the following command:
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./start.sh |
Anchor compile compile
6. WiFiMon Code Compilation
compile | |
compile |
Note: This step is only required if the WiFiMon Code is modified by the reader to include new features.
The WiFiMon code can be obtained from the official repository (https://bitbucket.software.geant.org/projects/WFMON/repos/agent/browse). A requirement to compile WiFiMon code is Apache Maven. It can be installed via the following commands:
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sudo apt-get update |
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sudo apt-get install -y maven |
Within the WiFiMon the WiFiMon code folder (cd agent), the WiFiMon code ban be compiled using the following commands:
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mvn clean install |
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mvn package |
Afterwards, WiFiMon war files should be copied in the /usr/lib/wifimon directory:
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cp |
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agent/wifimon-assembly/target/wifimon-agent-bin/secure-processor- |
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0.war /usr/lib/wifimon/secure-processor- |
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0.war |
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cp |
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agent/wifimon-assembly/target/wifimon-agent-bin/ui- |
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0.war /usr/lib/wifimon/ui- |
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0.war |
Anchor letsencrypt letsencrypt
7. Configuration of the WiFiMon Secure Agent
letsencrypt | |
letsencrypt |
Configuration of the WiFiMon Secure Agent will Agent will be demonstrated using a Let’s encrypt certificate. Readers are free to use whatever certificate they prefer.
In the sequel, we assume that both the WAS and the WiFiMon WAS and the WiFiMon Test Server (WTS) are installed within the same machine and thus, they depend on the same certificate. Notably, the WAS and the WTS could be installed in separate machines. Moreover, the configuration is demonstrated for an Apache web server. However, any web server could be selected.
Firstly, installation of certbot is of certbot is required:
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sudo apt-get update |
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sudo apt-get install -y certbot |
A certificate must be requested for the FQDN of the WAS/WTS, referred as WAS_FQDN:
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certbot certonly --webroot -w /var/www/html -d WAS_FQDN |
Note: Prior to this step, connections to port 80 must be allowed. If a web server is already installed on the machine, it should be temporarily stopped.
Issued certificates should be renewed regularly using the following command:
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certbot renew |
Next, generated certificates/keys will be inserted in the Apache configuration files. File /etc/apache2/sites-available/default-ssl.conf should conf should be edited and the following lines should be changed based on the FQDN of the WAS/WTS, referred as WAS_FQDN.
SSLCertificateFile /etc/letsencrypt/live/WAS_FQDN/cert.pem SSLCertificateKeyFile /etc/letsencrypt/live/WAS_FQDN/privkey.pem SSLCertificateChainFile /etc/letsencrypt/live/WAS_FQDN/chain.pem |
Changes should be applied and SSL should be enabled using the following commands:
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a2ensite default-ssl |
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a2enmod ssl |
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systemctl restart apache2 |
More information is available in the following links from which the above commands are taken:
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The following files should be copied in /usr/lib/wifimon/keystore:
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cp /etc/letsencrypt/live/WAS_FQDN/cert.pem /usr/lib/wifimon/keystore/cert.pem |
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cp /etc/letsencrypt/live/WAS_FQDN/privkey.pem /usr/lib/wifimon/keystore/privkey.pem |
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cp /etc/letsencrypt/live/WAS_FQDN/chain.pem /usr/lib/wifimon/keystore/chain.pem |
Within /usr/lib/wifimon/keystore folder, PEM PEM certificates should be converted to Java Keystore (JKS) format using the following commands:openssl pkcs12
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openssl pkcs12 -export -in cert.pem -inkey privkey.pem -certfile cert.pem -out testkeystore.p12 |
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keytool -importkeystore -srckeystore testkeystore.p12 -srcstoretype pkcs12 -destkeystore wifimon.jks -deststoretype JKS |
Passwords should be provided when prompted and noted.
In /usr/lib/wifimon/config/secure-processor.properties, the following changes should be made:
server.port=8443 server.ssl.key-store=./keystore/wifimon.jks server.ssl.key-store-password=[PASSWORD_keystore] server.ssl.key-password=[PASSWORD_key] |
In /usr/lib/wifimon/config/ui.properties, the following changes should be made:
...
Furthermore, the following parameters of the file /etc/kibana/kibana.yml should be changed:
server.ssl.enabled: true server.ssl.certificate: /usr/lib/wifimon/keystore/cert.pem server.ssl.key: /usr/lib/wifimon/keystore/privkey.pem |
Moreover, in the WTS the WTS test pages, the agentPort should agentPort should be agent from 9000 to 8443 in every testtool HTML page as well as http to https. Moreover, http should http should be changed to https in /var/www/html/wifimon/js/nettest/nettest-swfobject.js. This is a file related to the NetTest testtool. More information about these parameters is included in the WiFiMon Test Server (WTS) installation guide.
WiFiMon is now configured to use HTTPS for WiFiMon GUI and Agent.
Anchor xpack xpack
8. Configuring ELK Stack Security (X-Pack)
xpack | |
xpack |
In the sequel, we will secure the ELK stack using a self-signed certificate. First, the file “/usr/share/elasticsearch/instances.yml” yml” should be created with the following contents:
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instances: |
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- name: elasticsearch |
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dns: WAS_FQDN |
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ip: WAS_IP |
Important Note: In case of correlation with RADIUS and DHCP Logs, Logstash is Logstash is also required. In this case, instances instances.yml requires additional information. More information is available in the following WiFiMon guide "Streaming Logs Into ELK Cluster". The WAS guide mainly focuses on the integration of the previous guide with the WiFiMon code setup.
Then, the certificate of the Certificate Authority (CA) and its corresponding key should be generated using the following command:
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/usr/share/elasticsearch/bin/elasticsearch-certutil ca --ca-dn CN=’WiFiMon CA’ --days 3650 --keysize 4096 --out wifimon-ca.zip --pass --pem |
This command will create the file “wifimon“wifimon-ca.zip” zip” in /usr/share/elasticsearch directory. The file contents should be unzipped using the following command:
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unzip /usr/share/elasticsearch/wifimon-ca.zip |
Then, the self-signed certificate and the corresponding key should be generated using the following command:
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/usr/share/elasticsearch/bin/elasticsearch-certutil cert --ca-cert /usr/share/elasticsearch/ca/ca.crt --ca-key /usr/share/elasticsearch/ca/ca.key --days 1234 --in /usr/share/elasticsearch/instances.yml --keysize 4096 --out wifimon-certs.zip --pass --pem |
This command will create wifimon-certs.zip file in /usr/share/elasticsearch directory. The contents of this file should be unzipped using the following command:
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unzip /usr/share/elasticsearch/wifimon-certs.zip |
Directories /etc/elasticsearch/certs and /etc/kibana/certs should certs should then be created. Files ca.crt, elasticsearch.key and elasticsearch.crt should crt should be copied in the aforementioned directories and in /usr/lib/wifimon/keystore using keystore using the following commands:
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mkdir /etc/elasticsearch/certs |
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mkdir /etc/kibana/certs |
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cp /usr/share/elasticsearch/ca/* /etc/elasticsearch/certs/ |
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cp /usr/share/elasticsearch/ca/* /etc/kibana/certs/ |
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cp /usr/share/elasticsearch/elasticsearch/* /etc/elasticsearch/certs/ |
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cp /usr/share/elasticsearch/elasticsearch/* /etc/kibana/certs/ |
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cp /usr/share/elasticsearch/ca/* /usr/lib/wifimon/keystore/ |
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cp /usr/share/elasticsearch/elasticsearch/* /usr/lib/wifimon/keystore/ |
Then, the elasticsearch keystore should be configured using the following command:
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/usr/share/elasticsearch/bin/elasticsearch-keystore create |
Adding certificate key passphrase for HTTP communication protocol requires using the following command and entering the elasticsearch certificate key passphrase when prompted:
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/usr/share/elasticsearch/bin/elasticsearch-keystore add xpack.security.http.ssl.secure_key_passphrase |
Adding certificate key for transport communication protocol and entering the elasticsearch certificate key passphrase when prompted is possible via the following command:
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/usr/share/elasticsearch/bin/elasticsearch-keystore add xpack.security.transport.ssl.secure_key_passphrase |
The following command is required for setup verification:
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/usr/share/elasticsearch/bin/elasticsearch-keystore list |
The following information should be present:
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keystore.seed |
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xpack.security.http.ssl.secure_key_passphrase |
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xpack.security.transport.ssl.secure_key_passphrase |
In /etc/elasticsearch/elasticsearch.yml the yml the following information should be added and the Εlasticsearch cluster should be then restarted:
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Next, passwords for the built-in users should be generated. These passwords are not provided again and should be noted. Inside directory /usr/share/elasticsearch/bin/, the following command should be used:
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./elasticsearch-setup-passwords auto -u "https://WAS_FQDN:9200" |
Kibana keystore is configured using the following command:
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sudo -u kibana /usr/share/kibana/bin/kibana-keystore create |
The following command should be used and “kibana” should be provided as the username:
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sudo -u kibana /usr/share/kibana/bin/kibana-keystore add elasticsearch.username |
The following command should be used the password of the “kibana” built-in user should be provided:
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sudo -u kibana /usr/share/kibana/bin/kibana-keystore add elasticsearch.password |
The following command should be, then, used and the elasticsearch.key passphrase should be provided:
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sudo -u kibana /usr/share/kibana/bin/kibana-keystore add server.ssl.keyPassphrase |
The following command is required for setup verification:
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sudo -u kibana /usr/share/kibana/bin/kibana-keystore list |
The following information should be present:
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elasticsearch.username |
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elasticsearch.password |
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server.ssl.keyPassphrase |
In /etc/kibana/kibana.yml, the following details should be added and Kibana should and Kibana should be restarted:
elasticsearch.hosts: [“https://WAS_FQDN:9200”] elasticsearch.ssl.certificateAuthorities: [ “/etc/kibana/certs/ca.crt” ] elasticsearch.ssl.verificationMode: full |
Note: Make sure that certificates and keys in /etc/elasticsearch/certs/, /etc/kibana/certs/ and /usr/lib/wifimon/keystore/ are accessible by both Εlasticsearch and Kibana.
Next, the WiFiMon Agent properties should be configured. The truststore for X-Pack will Pack will be created using the following command:
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keytool -import -trustcacerts -alias root -file /usr/lib/wifimon/keystore/ca.crt -keystore /usr/lib/wifimon/keystore/truststore.jks |
The keystore for X-Pack Pack will be created using the following commands:
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cat /usr/lib/wifimon/keystore/elasticsearch.crt /usr/lib/wifimon/keystore/elasticsearch.key > /usr/lib/wifimon/keystore/combined.crt |
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keytool -import -trustcacerts -alias yourdomain -file /usr/lib/wifimon/keystore/combined.crt -keystore /usr/lib/wifimon/keystore/keystore.jks |
File /usr/lib/wifimon/config/secure-processor.properties should be edited and the following lines should be added:
xpack.security.enabled=true ssl.certificate.type=keystore ssl.http.user.username=elastic ssl.http.user.password=[elastic built-in user password] ssl.http.keystore.filepath=/usr/lib/wifimon/keystore/keystore.jks ssl.http.keystore.password=[keystore.jks password] ssl.http.truststore.filepath=/usr/lib/wifimon/keystore/truststore.jks ssl.http.truststore.password=[truststore password] ssl.http.key.password=[elasticsearch.key password] |
Anchor links links
9. The WiFiMon GUI
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The installation is now complete. The WiFiMon GUI can be accessed at: https://WAS_FQDN:8441/login (see Figure 1)
The Kibana UI is available at https://WAS_FQDN:5601
Figure 1: WiFiMon login page
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The following tabs are available from the WiFiMon the WiFiMon GUI:
Overview: Overview of the measurements for the current day, automatically updated every 30 seconds
Measurements: Measurements for the current day, automatically updated every 30 seconds
Subnets: This tab includes performance measurements for WiFiMon End Users Users (not WiFiMon Hardware Probes) in the monitored Subnets. By default, the measurements of all WiFiMon End Users are Users are depicted regardless of the Subnet they reside. Visualizing measurements for a specific Subnet requires adding a Kibana filter (along with the existing one) from the "Add filter" option on top. For the example subnet a.b.c.d/xx, the Kibana filter is "requesterSubnet is a.b.c.d/xx".
HWProbes: This tab includes measurements from the monitored WiFiMon Hardware Probes (not WiFiMon End Users) in the monitored Subnets. By default, the measurements of all WiFiMon Hardware Probes are depicted. Visualizing measurements for a specific WiFiMon Hardware Probe requires Probe requires adding a Kibana filter (along with the existing one) from the "Add filter" option on top. Each WiFiMon Hardware Probe is assigned a number. For the measurements of the WiFiMon Hardware Probe assigned the number "1", the required Kibana filter is "probeNo is 1". Assigning a number in each WiFiMon Hardware Probe is possible via the "testtool" attribute of the WiFiMon monitored test pages. More information is available in the WiFiMon Test Server installation guide.
Statistics:
Pie Statistics for current day, automatically updated every 30 seconds
Table Statistics for current day, automatically updated every 30 seconds
Maps:
Clients Maps, map withthe measurement count from clients location in current day, automatically updated every 30 seconds
APs Maps, map withthe measurement count from APs location in current day, automatically updated every 30 seconds
Configuration:
Subnets: Add/remove Subnets that are allowed to perform measurements
Access Points: Add remove information (MAC, latitude, longitude, etc.) about Access Points (necessary to depict measurements in APs Maps page)
Users: Add/remove users to login to the WiFiMon GUI (role "USER" does not have access "Configuration" and "Guide" tabs)
Privacy / Correlation: Hide/show user-related data, select the method to allow the correlation between measurements, client IP and AP MAC
Guide: Instruction on how to embed scripts (to perform measurements) to websites and locally install the available performance tests (NetTest, boomerang, speedtest/HTML5)
Help: Instruction on how to get help
- Check for updates: Check for newer versions of WiFiMon software.
As a first step you should add the Subnet of your WiFi network to allow measurements.
Figure 2: Overview tab of WiFiMon GUI
Figure 3: Subnet Subnets tab of WiFiMon GUI
Figure 4: HWProbes tab (Performance metrics)
Figure 5: HWProbes tab (Wireless network metrics)