This project consists of a container image containing a Robot Framework installation.
This installation also contains Firefox, Chrome, Microsoft Edge, along with the Selenium and Playwright/RFBrowser library for Robot Framework.
The versioning of this image follows the one of Robot Framework:
The versions used are:
As stated by the official GitHub project, starting from version 3.0, Selenium2Library is renamed to SeleniumLibrary and this project exists mainly to help with transitioning. The Selenium2Library 3.0.0 is also the last release and for new releases, please look at the SeleniumLibrary project.
This container can be run using the following command:
docker run \
-v <local path to the reports' folder>:/opt/robotframework/reports:Z \
-v <local path to the test suites' folder>:/opt/robotframework/tests:Z \
ppodgorsek/robot-framework:<version>
Browsers can be easily switched. It is recommended to define ${BROWSER} %{BROWSER}
in your Robot variables and to use ${BROWSER}
in your test cases. This allows to set the browser in a single place if needed.
When running your tests, simply add -e BROWSER=chrome
, -e BROWSER=firefox
or -e BROWSER=edge
to the run command.
Please note: edge
will work with Selenium but not the Browser Library, as the latter currently doesn't have an easy mechanism to install additional browsers. Playwright, on which the Browser library relies, cannot install additional browsers on Linux platforms other than Ubuntu/Debian and suggests using Chromium to test Microsoft Edge scenarios, unless you require Edge-specific capabilities.
It is possible to define the settings of the virtual screen in which the browser is run by changing several environment variables:
SCREEN_COLOUR_DEPTH
(default: 24)SCREEN_HEIGHT
(default: 1080)SCREEN_WIDTH
(default: 1920)It is possible to use different directories to read tests from and to generate reports to. This is useful when using a complex test file structure. To change the defaults, set the following environment variables:
ROBOT_REPORTS_DIR
(default: /opt/robotframework/reports)ROBOT_TESTS_DIR
(default: /opt/robotframework/tests)It is possible to parallelise the execution of your test suites. Simply define the ROBOT_THREADS
environment variable, for example:
docker run \
-e ROBOT_THREADS=4 \
ppodgorsek/robot-framework:latest
By default, there is no parallelisation.
When using parallelisation, it is possible to pass additional pabot options, such as --testlevelsplit
, --argumentfile
, --ordering
, etc. These can be passed by using the PABOT_OPTIONS
environment variable, for example:
docker run \
-e ROBOT_THREADS=4 \
-e PABOT_OPTIONS="--testlevelsplit" \
ppodgorsek/robot-framework:latest
RobotFramework supports many options such as --exclude
, --variable
, --loglevel
, etc. These can be passed by using the ROBOT_OPTIONS
environment variable, for example:
docker run \
-e ROBOT_OPTIONS="--loglevel DEBUG" \
ppodgorsek/robot-framework:latest
This project includes the IMAP library which allows Robot Framework to connect to email servers.
A suggestion to automate email testing is to run a Mailcatcher instance in Docker which allows IMAP connections. This will ensure emails are discarded once the tests have been run.
This project is meant to allow your tests to run anywhere. Sometimes that can be in a different timezone than your local one or of the location under test. To help solve such issues, this image includes the DateTimeTZ Library.
To set the timezone used inside the Docker image, you can set the TZ
environment variable:
docker run \
-e TZ=America/New_York \
ppodgorsek/robot-framework:latest
It is possible to install additional dependencies dynamically at runtime rather than having to extend this image.
To do so, simply mount a text file containing the list of dependencies you would like to install using pip
: (by default, this file is empty if not mounted)
docker run \
-v <local path to the dependency file>:/opt/robotframework/pip-requirements.txt:Z \
-v <local path to the test suites' folder>:/opt/robotframework/tests:Z \
ppodgorsek/robot-framework:latest
The file must follow Pip's official requirements file format.
Here is a example of what such a file could contain:
robotframework-docker==1.4.2
rpa==1.50.0
For large dependencies, it is still recommended to extend the project's image and to add them there, to avoid delaying the CI/CD pipelines with repeated dependency installations.
By default, containers are implicitly run using --user=1000:1000
, please remember to adjust that command-line setting accordingly, for example:
docker run \
--user=1001:1001 \
ppodgorsek/robot-framework:latest
Remember that that UID/GID should be allowed to access the mounted volumes in order to read the test suites and to write the output.
Additionally, it is possible to rely on user namespaces to further secure the execution. This is well described in the official container documentation:
This is a good security practice to make sure containers cannot perform unwanted changes on the host. In that sense, Podman is probably well ahead of Docker by not relying on a root daemon to run its containers.
Azure DevOps provides a Docker@2
task but it only allows a limited number of commands, it is therefore required to use a script
instead:
- job: FunctionalRegressionTests
displayName: Robot Framework tests
steps:
- script: |
set -x
mkdir -p $(Build.Repository.LocalPath)/robot-framework-reports
chmod -R ugo+rwx $(Build.Repository.LocalPath)/robot-framework-reports
# The ROBOT_OPTIONS allow to generate a specific output file that can be
# used to publish test results in the Azure DevOps pipeline run
# Remember to replace ${{ parameters.robotFrameworkFolder }} by the correct
# folder name in your repository
docker run --rm \
--shm-size=1g \
-v $(Build.Repository.LocalPath)/robot-framework-reports:/opt/robotframework/reports:Z \
-v $(Build.Repository.LocalPath)/${{ parameters.robotFrameworkFolder }}:/opt/robotframework/tests:Z \
-e ROBOT_OPTIONS="-x outputxunit.xml" \
-t docker.io/ppodgorsek/robot-framework:latest
displayName: Run Robot Framework tests
- task: PublishTestResults@2
condition: always()
displayName: Publish Robot Framework test results
inputs:
testResultsFormat: 'JUnit'
testResultsFiles: '**/outputxunit.xml'
searchFolder: '$(Build.Repository.LocalPath)/robot-framework-reports'
failTaskOnFailedTests: true
failTaskOnFailureToPublishResults: true
failTaskOnMissingResultsFile: true
It is possible to run the project from within a Jenkins pipeline by relying on the shell command line directly:
pipeline {
agent any
stages {
stage('Functional regression tests') {
steps {
sh "docker run --shm-size=1g -e BROWSER=firefox -v $WORKSPACE/robot-tests:/opt/robotframework/tests:Z -v $WORKSPACE/robot-reports:/opt/robotframework/reports:Z ppodgorsek/robot-framework:latest"
}
}
}
}
The pipeline stage can also rely on a Docker agent, as shown in the example below:
pipeline {
agent none
stages {
stage('Functional regression tests') {
agent { docker {
image 'ppodgorsek/robot-framework:latest'
args '--shm-size=1g -u root' }
}
environment {
BROWSER = 'firefox'
ROBOT_TESTS_DIR = "$WORKSPACE/robot-tests"
ROBOT_REPORTS_DIR = "$WORKSPACE/robot-reports"
}
steps {
sh '''
/opt/robotframework/bin/run-tests-in-virtual-screen.sh
'''
}
}
}
}
When relying on Continuous Integration tools, it can be useful to define a test run ID such as the build number or branch name to avoid overwriting consecutive execution reports.
For that purpose, the ROBOT_TEST_RUN_ID
variable was introduced:
${ROBOT_REPORTS_DIR}/
${ROBOT_REPORTS_DIR}/${ROBOT_TEST_RUN_ID}/
It can simply be passed during the execution, such as:
docker run \
-e ROBOT_TEST_RUN_ID="feature/branch-name" \
ppodgorsek/robot-framework:latest
By default, the test run ID is empty.
To upload the report of a test run to an S3 bucket, you need to define the following environment variables:
docker run \
-e AWS_ACCESS_KEY_ID=<your AWS key> \
-e AWS_SECRET_ACCESS_KEY=<your AWS secret> \
-e AWS_DEFAULT_REGION=<your AWS region e.g. eu-central-1> \
-e AWS_BUCKET_NAME=<name of your S3 bucket> \
ppodgorsek/robot-framework:latest
Not convinced yet? Simple tests have been prepared in the test/
folder, you can run them using the following commands:
# Using Chromium
docker run \
-v `pwd`/reports:/opt/robotframework/reports:Z \
-v `pwd`/test:/opt/robotframework/tests:Z \
-e BROWSER=chrome \
ppodgorsek/robot-framework:latest
# Using Firefox
docker run \
-v `pwd`/reports:/opt/robotframework/reports:Z \
-v `pwd`/test:/opt/robotframework/tests:Z \
-e BROWSER=firefox \
ppodgorsek/robot-framework:latest
For Windows users who use PowerShell, the commands are slightly different:
# Using Chromium
docker run \
-v ${PWD}/reports:/opt/robotframework/reports:Z \
-v ${PWD}/test:/opt/robotframework/tests:Z \
-e BROWSER=chrome \
ppodgorsek/robot-framework:latest
# Using Firefox
docker run \
-v ${PWD}/reports:/opt/robotframework/reports:Z \
-v ${PWD}/test:/opt/robotframework/tests:Z \
-e BROWSER=firefox \
ppodgorsek/robot-framework:latest
Screenshots of the results will be available in the reports/
folder.
Chrome drivers might crash due to the small size of /dev/shm
in the docker container:
UnknownError: session deleted because of page crash
This is a known bug of Chromium.
To avoid this error, please change the shm size when starting the container by adding the following parameter: --shm-size=1g
(or any other size more suited to your tests)
In case further investigation is required, the logs can be accessed by mounting their folder. Simply add the following parameter to your run
command:
-v `pwd`/logs:/var/log:Z
-v ${PWD}/logs:/var/log:Z
Chromium allows to set additional environment properties, which can be useful when debugging:
webdriver.chrome.verboseLogging=true
: enables the verbose logging modewebdriver.chrome.logfile=/path/to/chromedriver.log
: sets the path to Chromium's log fileWhen running tests, an unexpected error sometimes occurs:
[Error] Suite contains no tests.
There are two main causes to this:
As there can sometimes be issues as to where the tests are run from, make sure the correct folder is used by trying the following actions:
`pwd`
or ${PWD}
by the full path to the folder.It is also important to check if Robot Framework is allowed to access the resources it needs, i.e.:
As per their official project page, the Robot Framework DatabaseLibrary contains utilities meant for Robot Framework's usage. This can allow you to query your database after an action has been made to verify the results. This is compatible with any Database API Specification 2.0 module.
It is anyway mandatory to extend the container image to install the specific database module relevant to your tests, such as:
pip install pymssql
pip install pymysql
pip install py2oracle
pip install pg8000
As mentioned on the Docker Hub, the project has been built and uploaded as a linux/amd64
image only. This means ARM devices such as MacBook M1/M2 and Amazon EC2 Graviton won't be able to run the image with the default configuration.
As mentioned in the official documentation, Podman and Docker provide a --platform
option which selects a given application architecture, such as:
docker run \
--platform linux/amd64 \
-v <local path to the reports' folder>:/opt/robotframework/reports:Z \
-v <local path to the test suites' folder>:/opt/robotframework/tests:Z \
ppodgorsek/robot-framework:<version>
Please note: builds and automated tests of this project will remain performed on a linux/amd64
architecture so such emulation might not work, depending on your device and operating system.
If this does not solve your platform-related issues, you will have to rebuild the image for your device/platform, specifying that --platform
option during the build and run.
Have you found an issue? Do you have an idea for an improvement? Feel free to contribute by submitting it on the GitHub project.