Erik Lindblom
Posted on May 30, 2018
This entry was originally published on my blog at blog.baens.net
I have a blog post about setting up a JAX-RS with Kotlin and one thing I neglected to show was how to test. So, let's go back and fix this. For this, I will be using JUnit 5 for the test runner, AssertJ as the assertion library, and Mockito as the mocking framework.
Let's go over quickly what tests I've found valuable as I've created JAX-RS services. Well, in reality, there's only two: one that exercises the HTTP interface (so, "integration test") and one that tests the class and methods in isolation (so, "unit tests"). I find it more valuable to tell which parts of the system are being exercised in the tests rather than trying to identify what type of common test level they are at. Just a weird quirk, as you will see I have plenty of them.
Setting up the dependencies in gradle
First, we need to make sure we are on gradle 4.6 or greater. I personally use the wrapper version, but just verify that you have it somehow. To get that specific wrapper version, you can run gradle wrapper --gradle-version 4.6
and then all things should be good there.
For the actual code dependencies, here is what you will need in the build.gradle
file:
def junitVersion = "5.1.0"
dependencies {
// junit dependencies
testCompile "org.junit.jupiter:junit-jupiter-api:${junitVersion}"
testRuntime "org.junit.vintage:junit-vintage-engine:${junitVersion}"
testRuntime "org.junit.jupiter:junit-jupiter-engine:${junitVersion}"
// jersey test dependencies for HTTP testing
testCompile "org.glassfish.jersey.test-framework.providers:jersey-test-framework-provider-grizzly2:${jerseyVersion}"
// assertJ
testCompile 'org.assertj:assertj-core:3.10.0'
// mockito
testCompile 'org.mockito:mockito-core:2.18.3'
testCompile 'org.mockito:mockito-junit-jupiter:2.18.3'
testCompile 'com.nhaarman:mockito-kotlin:1.5.0'
}
Kind of messy isn't it? So a note on some of these. Any of the org.junit
ones are the core JUnit libraries you include for JUnit 5. We've include the junit-vintage-engine
because for our tests which exercise the HTTP tests are still based upon the older JUnit 4 tests from the jersey-test-framework-provider
. We will get into that more later.
I've included AssertJ as the assertion library because I like the syntax better than the out of the box JUnit 5 style.
Mockito is the mocking framework, along with a few nice to have from mockito-kotlin
that turn the any()
option into an actual instance instead of a null
object. And mockito-junit-jupiter
which allows us to run Mockito with JUnit 5.
Setting up the structure
First, let's do a little bit of work to setup the inversion of control system that is used the JAX-RS version I used (Jersey), which happens to be H2. We are going to create a place we can inject bindings and determine if these are test bindings, or if they are production bindings. This gives us a layer of control of which systems to use and makes it easier for testing.
A basic binding implementation for H2 looks like this:
class Bindings : AbstractBinder() {
override fun configure() {
// bind(<implementation class>).to(<interface>)
}
}
This is where we will house all of our bindings inside of that configure
method. We will get into more of what that looks like a little bit later.
Now, let's actually get something useful. Let's create an interface that will hand back a list of data. So, something like this:
data class HelloJson(val prop1: Int, val prop2: String)
interface DataService {
fun all() : List<HelloJson>
}
Nothing fancy, just a method that would give us back a list of data objects.
Notes on how to make IntelliJ work with this
So, IntelliJ doesn't like the source along side the tests files. And honestly, I've found that to be a much better project structure in every language I'ved used. So, to make this work (though very kludgy) here is the special stuff you need to add to the build.gradle
file:
apply plugin: 'idea'
// This is here to fix the intellij's issues with
// the complicated source mappings. Use the 'idea' job
// to generate a intellij project
// Ticket to make this just work out of the box: https://youtrack.jetbrains.com/issue/IDEA-188436
idea {
module {
scopes.COMPILE.plus += [ configurations.testCompile ]
}
}
This is intended only for IntelliJ. I will try and test Eclipse here soon and report back but I've honestly haven't touched that in years.
HTTP Tests
One of the very first tests I write when creating end points is that I can get a 200 back from the end point and get JSON back as the content-type. These tests will be my happy path test, so it should always pass. As requirements grow for this end point I will go back and add things that may be required to make this test pass by default. This is what these tests may look like:
class `HTTP HelloWorldResource should` : JerseyTest(Application()) {
@Test
fun `returns 200`() {
val statusCode = target("helloWorld").request().get().status
assertThat(statusCode).isEqualTo(200)
}
@Test
fun `returns JSON type`() {
val mediaType = target("helloWorld").request().get().mediaType
assertThat(mediaType).isEqualTo(MediaType.APPLICATION_JSON_TYPE)
}
}
Note: that @Test
annotation is from the JUnit 4 namepsace, the import looks like this: import org.junit.Test
. If you don't have this and instead use the newer JUnit 5 namespace, the test will not run. That is because the JerseyTest
base class assumes that certain things run that JUnit 5 doesn't do anymore (think static class setup process and such). You can be really neat and rename the JUnit 4 import like this: import org.junit.Test as TestV4
to avoid confusion if you put these types of tests in the same file.
As you can see, this test isn't that horrible. It is fairly straight forward and the boilerplate around the test isn't bad. Let's go into a more complicated example with bindings.
Setting up a null binding as your first implementation
When I start adding layers to my application, I usually start with drilling down from my "upper" layers to the "lower" layers. Because of that I usually don't have an implementation per say to use for testing or for anything much else. I kind of like this approach because I can test out the API to see if I indeed want this abstraction and what kind of behavior I expect. With all of that in mind, usually when I create an interface I will always have a null object right along side it. This will make it easier to start off with some default behavior and makes it easier to test the system down the road.
For example, a the null object for the DataService
defined above may look like this:
class NullDataService : DataService {
override fun all(): List<HelloJson> = emptyList()
}
Method level testing
Now that we have our interface and it's null object, let's say we need to add functionality to our helloWorld
method so that it returns the data from this service. With a TDD approach, the first test maybe will just check that the method returns the same number of items. The next test may ensure that we actually have an item contained in the returning list. These tests are fairly straight forward so let's look at the code for it:
@ExtendWith(MockitoExtension::class)
class `HelloWorldResource Should` {
fun createHelloJson(prop1: Int = 1, prop2: String = "test") = HelloJson(prop1, prop2)
@Mock
lateinit var mockDataService: DataService
@InjectMocks
lateinit var helloWorldResource: HelloWorldResource
@Test
fun `returns same number of elements as DataService`() {
whenever(mockDataService.all()).thenReturn(listOf(createHelloJson(), createHelloJson()))
assertThat(helloWorldResource.helloWorld()).hasSize(2)
}
@Test
fun `contains item from returned list`() {
val expectedObject = createHelloJson(prop1 = 2)
whenever(mockDataService.all()).thenReturn(listOf(expectedObject))
assertThat(helloWorldResource.helloWorld()).contains(expectedObject)
}
}
Few things to point out here. I am using the MockitoExtension
that allows us to reduce on the setup parts of the tests. This allows us to create properties with the @Mock
and @InjectMocks
annotations. This makes reuse in the test class VERY easy. The lateinit
part is because Kotlin really wants classes to show when they will be initialized. This statement flags to the compiler that we will be doing it behind the scenes later and not to worry about things.
I've also added a helper method to make creating test data easier. As you see at the top, we have a createHelloJson
function that creates the data object. Then if we want to override different properties, we can easily (as demonstrated in the 2nd test) add just the property we want to override. This allows the objects to have sane defaults, and if that object grows, makes it easy to add more fields without having to change 30 tests.
Making the HTTP tests work after we add the DataService constructor dependency
Now, if you are following along you will notice that the above two tests work just fine, but if you run the HTTP test now, things break. That's because we now require the DataService
to be injected at runtime from H2. To fix that we need to make sure we have our bindings correct, so here is what the test binding and injection will look like
// in our Application.kt file
class TestBindings : AbstractBinder() {
override fun configure() {
bind(NullDataService()).to(DataService::class.java)
}
}
// in our HelloWorldResource.kt file
class HelloWorldResource
@Inject constructor(private val dataService: DataService)
// in our HelloWorldResource.tests.kt file
class `HTTP HelloWorldResource should` : JerseyTest(Application(TestBindings()))
First we needed to add the @Inject
property to the constructor of our resource. This will signal to Jersey that this constructor will need outside dependencies and to use H2 to find them. Our dependency is defined in our TestBindings
class, with the NullDataService
as our default. Then we add that test binding to our JerseyTest
creation making this all work.
Wrapping up
Now, if any of this didn't make sense and you want to see it all put together, go over to the github repository where this is housed and you should be able to take a look at the full thing working. I've created a static list implementation of that data service for one to look at what an actual implementation may look like.
Bonus: How to log exceptions in Jersey
If you check out the code on github, you will notice another class way down in the Application.kt
file. This class hooks into Jersey's event system so if a request errors out in an exception, we can observe it. Take note this is just for observing if an exception has happened, not actually doing anything with the request. If we wanted to handle that, we could create a request mapper, but that is outside of the scope of this particular blog post.
Posted on May 30, 2018
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