If you search for a description of what Page Object is, you’ll find that The Page Object Pattern gives us a common sense way to model content in a reusable and maintainable way.
And also points that: Within your web app’s UI there are areas that your tests interact with. A Page Object simply models these as objects within the test code.
This reduces the amount of duplicated code and means that if the UI changes, the fix need only be applied in one place.
This reduces the amount of duplicated code and means that if the UI changes, the fix need only be applied in one place.
As you can see, Page Object applies to UI elements. We (the Arquillian community) has coined a new pattern following Page Object pattern logic called Container Object pattern.
You can think about Container Object as areas of a container (for now Docker container) that your test might interact with. For example some of these areas could be:
You can think about Container Object as areas of a container (for now Docker container) that your test might interact with. For example some of these areas could be:
- To get the host IP where container is running.
- The bounded port for a given exposed port.
- Any parameter configured inside the configuration file (Dockerfile) like a user or password to access to the service which the container exposes.
- Definition of the containers.
A Container Object might contain an aggregation of more than one Container Object inside it. This effectively builds a relation ship (link) between containers.
Notice that nothing prevents you to generate the correct URL for accessing to the service from the test, or execute commands against container like retrieving an internal file.
And of course as Page Object does, Container Object gives you a way to build a model content that can be reused for several projects.
Before looking at how this pattern is implemented in Arquillian Cube, let’s go thorough an example:
Suppose all of your applications need to send a file to an FTP server. To write an integration/component test you might need a FTP server to send the file and check that the file was correctly sent.
One way to do this is using Docker to start a FTP server just before executing the test, then execute the test using this Docker container for FTP server, before stopping the container check that the file is there, and finally stop the container.
One way to do this is using Docker to start a FTP server just before executing the test, then execute the test using this Docker container for FTP server, before stopping the container check that the file is there, and finally stop the container.
So all these operations that involves the FTP server and container could be joined inside a Container Object. This container object might contain information of:
- Which image is used
- IP and bounded port of host where this FTP server is running
- Username and password to access to the FTP server
- Methods for asserting the existence of a file
Then from the point of view of test, it only communicate with this object instead of directly hard coding all information inside the test.
Again as in Page Object, any change on the container only affects the Container Object and not the test itself.
Again as in Page Object, any change on the container only affects the Container Object and not the test itself.
Now let’s see how Arquillian Cube implements Container Object pattern with a very simple example:
Arquillian Cube and Container Object
Let’s see a simple example on how you can implement a Container Object in Cube. Suppose you want to create a container object that encapsulates a ping pong server running inside Docker.
The Container Object will be like a simple POJO with special annotations:
The Container Object will be like a simple POJO with special annotations:
In previous example you must pay attention at next lines:
- @Cube annotation configures Container Object.
- A Container Object can be enriched with Arquillian enrichers.
- Bounded port is injected for given exposed port.
- Container Object hides how to connect to PingPong server.
@Cube annotation is used to configure this Container Object. Initially you set that the started container will be named pingpong and the port binding information for the container instance, in this case 5000→8080/tcp.
Notice that this can be an array to set more than one port binding definition.
Next annotation is @CubeDockerFile which configure how Container is created. In this case using a Dockerfile located at default classpath location. The default location is the package+classname, so for example in previous case, Dockerfile should be placed at org/superbiz/containerobject/PingPongContainer directory.
Of course you can set any other class path location by passing as value of the annotation. CubeDockerFile annotation sets the location where the Dockerfile is found and not the file itself.
Also this location should be reachable from ClassLoader, so it means it should be loaded from classpath in order to find it.
Any Cube can be enriched with any client side enricher, in this case with @HostIp enricher, but it could be enriched with DockerClient using @ArquillianResource as well.
Finally the @HostPort is used to translate the exposed port to bound port.
So in this example port value will be 5000. You are going to learn briefly why this annotation is important.
And then you can start using this container object in your test:
Notice that this can be an array to set more than one port binding definition.
Next annotation is @CubeDockerFile which configure how Container is created. In this case using a Dockerfile located at default classpath location. The default location is the package+classname, so for example in previous case, Dockerfile should be placed at org/superbiz/containerobject/PingPongContainer directory.
Of course you can set any other class path location by passing as value of the annotation. CubeDockerFile annotation sets the location where the Dockerfile is found and not the file itself.
Also this location should be reachable from ClassLoader, so it means it should be loaded from classpath in order to find it.
Any Cube can be enriched with any client side enricher, in this case with @HostIp enricher, but it could be enriched with DockerClient using @ArquillianResource as well.
Finally the @HostPort is used to translate the exposed port to bound port.
So in this example port value will be 5000. You are going to learn briefly why this annotation is important.
And then you can start using this container object in your test:
The most important thing here is that you need to set Container Object as a field of the class and annotate with @Cube.
It is very important to annotate the field with Cube, so before Arquillian runs the test, it can detect that it needs to start a new Cube (Docker container), create the Container Object and inject it in the test.
Notice that this annotation is exactly the same as used when you defined the Container Object.
And it is in this way because you can override any property of the Container Object from the test side. This is why @HostPort annotation is important, since port can be changed from the test definition, you need to find a way to inject the correct port inside the container object.
In this post I have introduced Container Object pattern and how can be used in Arquillian Cube. But this is only an small taste, you can read more about Arquillian Cube and Container Object integration at https://github.com/arquillian/arquillian-cube#arquillian-cube-and-container-object
Also a running examples can be found at https://github.com/arquillian/arquillian-cube/tree/master/docker/ftest-docker-containerobject
We keep learning,
Alex.
Music: https://www.youtube.com/watch?v=moSFlvxnbgk
It is very important to annotate the field with Cube, so before Arquillian runs the test, it can detect that it needs to start a new Cube (Docker container), create the Container Object and inject it in the test.
Notice that this annotation is exactly the same as used when you defined the Container Object.
And it is in this way because you can override any property of the Container Object from the test side. This is why @HostPort annotation is important, since port can be changed from the test definition, you need to find a way to inject the correct port inside the container object.
In this post I have introduced Container Object pattern and how can be used in Arquillian Cube. But this is only an small taste, you can read more about Arquillian Cube and Container Object integration at https://github.com/arquillian/arquillian-cube#arquillian-cube-and-container-object
Also a running examples can be found at https://github.com/arquillian/arquillian-cube/tree/master/docker/ftest-docker-containerobject
We keep learning,
Alex.
It's time to see what I can do, To test the limits and break through, No right, no wrong, no rules for me, I'm free! (Let It Go - Idina Menzel)
Music: https://www.youtube.com/watch?v=moSFlvxnbgk