1. Introduction
The Groovy programming language comes with great support for writing tests. In addition to the language features and test integration with state-of-the-art testing libraries and frameworks, the Groovy ecosystem has born a rich set of testing libraries and frameworks.
This chapter will start with language specific testing features and continue with a closer look at JUnit integration, Spock for specifications and Geb for functional tests. Finally, we an overview of other testing libraries known to be working with Groovy.
2. Language Features
Besides integrated support for JUnit, the Groovy programming language comes with features that have proven to be very valuable for test-driven development. This section gives insight on them.
2.1. Power Assertions
Writing tests means formulating assumptions by using assertions. In Java this can be done by using the assert
keyword that has been added in J2SE 1.4. In Java, assert
statements can be enabled via the JVM parameters -ea
(or -enableassertions
) and -da
(or -disableassertions
). Assertion statements in Java are disabled by default.
Groovy comes with a rather powerful variant of assert
also known as power assertion statement. Groovy’s power
assert
differs from the Java version in its output given the boolean expression validates to false
:
def x = 1
assert x == 2
// Output: (1)
//
// Assertion failed:
// assert x == 2
// | |
// 1 false
1 | This section shows the std-err output |
The java.lang.AssertionError
that is thrown whenever the assertion can not be validated successfully, contains
an extended version of the original exception message. The power assertion output shows evaluation results from
the outer to the inner expression.
The power assertion statements true power unleashes in complex Boolean statements, or statements with
collections or other toString
-enabled classes:
def x = [1,2,3,4,5]
assert (x << 6) == [6,7,8,9,10]
// Output:
//
// Assertion failed:
// assert (x << 6) == [6,7,8,9,10]
// | | |
// | | false
// | [1, 2, 3, 4, 5, 6]
// [1, 2, 3, 4, 5, 6]
Another important difference from Java is that in Groovy assertions are enabled by default. It has been a language design decision to remove the possibility to deactivate assertions. Or, as Bertrand Meyer stated, ``it makes no sense to take off your swim ring if you put your feet into real water``.
One thing to be aware of are methods with side-effects inside Boolean expressions in power assertion statements. As the internal error message construction mechanism does only store references to instances under target, it happens that the error message text is invalid at rendering time in case of side-effecting methods involved:
assert [[1,2,3,3,3,3,4]].first().unique() == [1,2,3]
// Output:
//
// Assertion failed:
// assert [[1,2,3,3,3,3,4]].first().unique() == [1,2,3]
// | | |
// | | false
// | [1, 2, 3, 4]
// [1, 2, 3, 4] (1)
1 | The error message shows the actual state of the collection, not the state before the unique method was applied |
If you choose to provide a custom assertion error message this can be done by using the Java syntax assert
expression1 : expression2 where expression1 is the Boolean expression and expression2 is the custom error message.
Be aware though that this will disable the power assert and will fully fallback to custom
error messages on assertion errors.
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2.2. Mocking and Stubbing
Groovy has excellent built-in support for a range of mocking and stubbing alternatives. When using Java, dynamic mocking frameworks are very popular. A key reason for this is that it is hard work creating custom hand-crafted mocks using Java. Such frameworks can be used easily with Groovy if you choose but creating custom mocks is much easier in Groovy. You can often get away with simple maps or closures to build your custom mocks.
The following sections show ways to create mocks and stubs with Groovy language features only.
2.2.1. Map Coercion
By using maps or expandos, we can incorporate desired behaviour of a collaborator very easily as shown here:
class TranslationService {
String convert(String key) {
return "test"
}
}
def service = [convert: { String key -> 'some text' }] as TranslationService
assert 'some text' == service.convert('key.text')
The as
operator can be used to coerce a map to a particular class. The given map keys are interpreted as
method names and the values, being groovy.lang.Closure
blocks, are interpreted as method code blocks.
Be aware that map coercion can get into the way if you deal with custom java.util.Map descendant classes in combination
with the as operator. The map coercion mechanism is targeted directly at certain collection classes, it doesn’t take
custom classes into account.
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2.2.2. Closure Coercion
The as operator can be used with closures in a neat way which is great for developer testing in simple scenarios. We haven’t found this technique to be so powerful that we want to do away with dynamic mocking, but it can be very useful in simple cases none-the-less.
Classes or interfaces holding a single method, including SAM (single abstract method) classes, can be used to coerce a closure block to be an object of the given type. Be aware that for doing this, Groovy internally create a proxy object descending for the given class. So the object will not be a direct instance of the given class. This important if, for example, the generated proxy object’s meta-class is altered afterwards.
Let’s have an example on coercing a closure to be of a specific type:
def service = { String key -> 'some text' } as TranslationService
assert 'some text' == service.convert('key.text')
Groovy supports a feature called implicit SAM coercion. This means that the as
operator is not necessary in situations
where the runtime can infer the target SAM type. This type of coercion might be useful in tests to mock entire SAM
classes:
abstract class BaseService {
abstract void doSomething()
}
BaseService service = { -> println 'doing something' }
service.doSomething()
2.2.3. MockFor and StubFor
The Groovy mocking and stubbing classes can be found in the groovy.mock.interceptor
package.
The MockFor
class supports (typically unit) testing of classes in isolation by allowing a strictly ordered expectation
of the behavior of collaborators to be defined. A typical test scenario involves a class under test and one or more collaborators. In such a scenario it is
often desirable to just test the business logic of the class under test. One strategy for doing that is to replace
the collaborator instances with simplified mock objects to help isolate out the logic in the test target. MockFor
allows such mocks to be created using meta-programming. The desired behavior of collaborators is defined as a behavior
specification. The behavior is enforced and checked automatically.
Let’s assume our target classes looked like this:
class Person {
String first, last
}
class Family {
Person father, mother
def nameOfMother() { "$mother.first $mother.last" }
}
With MockFor
, a mock expectation is always sequence dependent and its use automatically ends with a call to verify
:
def mock = new MockFor(Person) (1)
mock.demand.getFirst{ 'dummy' }
mock.demand.getLast{ 'name' }
mock.use { (2)
def mary = new Person(first:'Mary', last:'Smith')
def f = new Family(mother:mary)
assert f.nameOfMother() == 'dummy name'
}
mock.expect.verify() (3)
1 | a new mock is created by a new instance of MockFor |
2 | a Closure is passed to use which enables the mocking functionality |
3 | a call to verify checks whether the sequence and number of method calls is as expected |
The StubFor
class supports (typically unit) testing of classes in isolation by allowing a loosely-ordered expectation
of the behavior of collaborators to be defined. A typical test scenario involves a class under test and one or more
collaborators. In such a scenario it is often desirable to just test the business logic of the CUT. One strategy for
doing that is to replace the collaborator instances with simplified stub objects to help isolate out the logic
in the target class. StubFor
allows such stubs to be created using meta-programming. The desired behavior of
collaborators is defined as a behavior specification.
In contrast to MockFor
the stub expectation checked with verify
is sequence independent and its use is optional:
def stub = new StubFor(Person) (1)
stub.demand.with { (2)
getLast{ 'name' }
getFirst{ 'dummy' }
}
stub.use { (3)
def john = new Person(first:'John', last:'Smith')
def f = new Family(father:john)
assert f.father.first == 'dummy'
assert f.father.last == 'name'
}
stub.expect.verify() (4)
1 | a new stub is created by a new instance of StubFor |
2 | the with method is used for delegating all calls inside the closure to the StubFor instance |
3 | a Closure is passed to use which enables the stubbing functionality |
4 | a call to verify (optional) checks whether the number of method calls is as expected |
MockFor
and StubFor
can not be used to test statically compiled classes e.g for Java classes or Groovy classes that
make use of @CompileStatic
. To stub and/or mock these classes you can use Spock or one of the Java mocking libraries.
2.2.4. Expando Meta-Class (EMC)
Groovy includes a special MetaClass
the so-called ExpandoMetaClass
(EMC). It allows to dynamically add methods,
constructors, properties and static methods using a neat closure syntax.
Every java.lang.Class
is supplied with a special metaClass
property that will give a reference to an
ExpandoMetaClass
instance. The expando meta-class is not restricted to custom classes, it can be used for
JDK classes like for example java.lang.String
as well:
String.metaClass.swapCase = {->
def sb = new StringBuffer()
delegate.each {
sb << (Character.isUpperCase(it as char) ? Character.toLowerCase(it as char) :
Character.toUpperCase(it as char))
}
sb.toString()
}
def s = "heLLo, worLD!"
assert s.swapCase() == 'HEllO, WORld!'
The ExpandoMetaClass
is a rather good candidate for mocking functionality as it allows for more advanced stuff
like mocking static methods
class Book {
String title
}
Book.metaClass.static.create << { String title -> new Book(title:title) }
def b = Book.create("The Stand")
assert b.title == 'The Stand'
or even constructors
Book.metaClass.constructor << { String title -> new Book(title:title) }
def b = new Book("The Stand")
assert b.title == 'The Stand'
Mocking constructors might seem like a hack that’s better not even to be considered but even there might be valid
use cases. An example can be found in Grails where domain class constructors are added at run-time with the
help of ExpandoMetaClass . This lets the domain object register itself in the Spring application context and allows
for injection of services or other beans controlled by the dependency-injection container.
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If you want to change the metaClass
property on a per test method level you need to remove the changes that were
done to the meta-class, otherwise those changes would be persistent across test method calls. Changes are removed by
replacing the meta-class in the GroovyMetaClassRegistry
:
GroovySystem.metaClassRegistry.setMetaClass(java.lang.String, null)
Another alternative is to register a MetaClassRegistryChangeEventListener
, track the changed classes and remove
the changes in the cleanup method of your chosen testing runtime. A good example can be found
in the Grails web
development framework.
Besides using the ExpandoMetaClass
on a class-level, there is also support for using the meta-class on a per-object
level:
def b = new Book(title: "The Stand")
b.metaClass.getTitle {-> 'My Title' }
assert b.title == 'My Title'
In this case the meta-class change is related to the instance only. Depending on the test scenario this might be a better fit than the global meta-class change.
2.3. GDK Methods
The following section gives a brief overview on GDK methods that can be leveraged in test case scenarios, for example for test data generation.
2.3.1. Iterable#combinations
The combinations
method that is added on java.lang.Iterable
compliant classes can be used to get a list of
combinations from a list containing two or more sub-lists:
void testCombinations() {
def combinations = [[2, 3],[4, 5, 6]].combinations()
assert combinations == [[2, 4], [3, 4], [2, 5], [3, 5], [2, 6], [3, 6]]
}
The method could be used in test case scenarios to generate all possible argument combinations for a specific method call.
2.3.2. Iterable#eachCombination
The eachCombination
method that is added on java.lang.Iterable
can be used to apply a function (or in this
case a groovy.lang.Closure
) to each if the combinations that has been built by the combinations
method:
eachCombination
is a GDK method that is added to all classes conforming to the java.lang.Iterable
interface.
It applies a function on each combination of the input lists:
void testEachCombination() {
[[2, 3],[4, 5, 6]].eachCombination { println it[0] + it[1] }
}
The method could be used in the testing context to call methods with each of the generated combinations.
2.4. Tool Support
2.4.1. Test Code Coverage
Code coverage is a useful measure of the effectiveness of (unit) tests. A program with high code coverage has a lower chance to hold critical bugs than a program with no or low coverage. To get code coverage metrics, the generated byte-code usually needs to be instrumented before the tests are executed. One tool with Groovy support for this task is Cobertura.
Various frameworks and build tools come with Cobertura integration. For Grails, there is the code coverage plugin based on Cobertura, for Gradle there is the gradle-cobertura plugin, to name only two of them.
The following code listing shows an example on how to enable Cobertura test coverage reports in a Gradle build script from a Groovy project:
def pluginVersion = '<plugin version>'
def groovyVersion = '<groovy version>'
def junitVersion = '<junit version>'
buildscript {
repositories {
mavenCentral()
}
dependencies {
classpath 'com.eriwen:gradle-cobertura-plugin:${pluginVersion}'
}
}
apply plugin: 'groovy'
apply plugin: 'cobertura'
repositories {
mavenCentral()
}
dependencies {
compile "org.codehaus.groovy:groovy-all:${groovyVersion}"
testCompile "junit:junit:${junitVersion}"
}
cobertura {
format = 'html'
includes = ['**/*.java', '**/*.groovy']
excludes = ['com/thirdparty/**/*.*']
}
Several output formats can be chosen for Cobertura coverage reports and test code coverage reports can be added to continuous integration build tasks.
3. Unit Tests with JUnit 3 and 4
Groovy simplifies JUnit testing, making it more Groovy. In the following sections we will have a closer look at JUnit 3/4 Groovy integration.
3.1. JUnit 3
Maybe one of the most prominent Groovy classes supporting JUnit 3 tests is the GroovyTestCase
class. Being
derived from junit.framework.TestCase
it offers a bunch of additional methods that make testing in Groovy a breeze.
Although GroovyTestCase inherits from TestCase doesn’t mean you can’t use JUnit 4 features in your project. In fact,
the most recent Groovy versions come with a bundled JUnit 4 and that comes with a backwards compatible TestCase
implementation. There have been some discussion on the Groovy mailing-list on whether to use GroovyTestCase or JUnit 4
with the result that it is mostly a matter of taste, but with GroovyTestCase you get a bunch of methods for free that
make certain types of tests easier to write.
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In this section, we will have a look at some of the methods provided by GroovyTestCase
. A full list of these can be
found in the JavaDoc documentation for groovy.util.GroovyTestCase,
don’t forget it is inherited from junit.framework.TestCase
which inherits all the assert*
methods.
3.1.1. Assertion Methods
GroovyTestCase
is inherited from junit.framework.TestCase
therefore it inherits a large number of assertion methods
being available to be called in every test method:
class MyTestCase extends GroovyTestCase {
void testAssertions() {
assertTrue(1 == 1)
assertEquals("test", "test")
def x = "42"
assertNotNull "x must not be null", x
assertNull null
assertSame x, x
}
}
As can be seen above, in contrast to Java it is possible to leave out the parenthesis in most situations which leads to even more readability of JUnit assertion method call expressions.
An interesting assertion method that is added by GroovyTestCase
is assertScript
. It ensures that the given Groovy
code string succeeds without any exception:
void testScriptAssertions() {
assertScript '''
def x = 1
def y = 2
assert x + y == 3
'''
}
3.1.2. shouldFail Methods
shouldFail
can be used to check whether the given code block fails or not. In case it fails, the assertion does hold,
otherwise the assertion fails:
void testInvalidIndexAccess1() {
def numbers = [1,2,3,4]
shouldFail {
numbers.get(4)
}
}
The example above uses the basic shouldFail
method interface that takes a groovy.lang.Closure
as a single argument.
The Closure
instance holds the code that is supposed to be breaking during run-time.
If we wanted to assert shouldFail
on a specific java.lang.Exception
type we could have done so by using the shouldFail
implementation that takes the Exception
class as first argument and the Closure
as second argument:
void testInvalidIndexAccess2() {
def numbers = [1,2,3,4]
shouldFail IndexOutOfBoundsException, {
numbers.get(4)
}
}
If anything other than IndexOutOfBoundsException
(or a descendant class of it) is thrown, the test case will fail.
A pretty nice feature of shouldFail
hasn’t been visible so far: it returns the exception message. This is really
useful if you want to assert on the exception error message:
void testInvalidIndexAccess3() {
def numbers = [1,2,3,4]
def msg = shouldFail IndexOutOfBoundsException, {
numbers.get(4)
}
assert msg.contains('Index: 4, Size: 4')
}
3.1.3. notYetImplemented Method
The notYetImplemented
method has been greatly influenced by HtmlUnit. It allows to write a test method but mark it
as not yet implemented. As long as the test method fails and is marked with notYetImplemented
the test goes green:
void testNotYetImplemented1() {
if (notYetImplemented()) return (1)
assert 1 == 2 (2)
}
1 | a call to notYetImplemented is necessary for GroovyTestCase to get the current method stack. |
2 | as long as the test evaluates to false the test execution will be successful. |
An alternative to the notYetImplemented
method is the @NotYetImplemented
annotation. It allows for annotating a
method as not yet implemented, with the exact same behavior as GroovyTestCase#notYetImplemented
but without the need
for the notYetImplemented
method call:
@NotYetImplemented
void testNotYetImplemented2() {
assert 1 == 2
}
3.2. JUnit 4
Groovy can be used to write JUnit 4 test cases without any restrictions. The groovy.test.GroovyAssert
holds
various static methods that can be used as replacement for the GroovyTestCase
methods in JUnit 4 tests:
import org.junit.Test
import static groovy.test.GroovyAssert.shouldFail
class JUnit4ExampleTests {
@Test
void indexOutOfBoundsAccess() {
def numbers = [1,2,3,4]
shouldFail {
numbers.get(4)
}
}
}
As can be seen in the example above, the static methods found in GroovyAssert
are imported at the beginning of the
class definition thus shouldFail
can be used the same way it can be used in a GroovyTestCase
.
groovy.test.GroovyAssert descends from org.junit.Assert that means it inherits all JUnit assertion methods. However,
with the introduction of the power assertion statement, it turned out to be good practice to rely on assertion statements
instead of using the JUnit assertion methods with the improved message being the main reason.
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4. Testing with Spock
Spock is a testing and specification framework for Java and Groovy applications. What makes it stand out from the crowd is its beautiful and highly expressive specification DSL. In practice, Spock specifications are written as Groovy classes. Although written in Groovy they can be used to test Java classes. Spock can be used for unit, integration or BDD (behavior-driven-development) testing, it doesn’t put itself into a specific category of testing frameworks or libraries.
Beside these awesome features Spock is a good example on how to leverage advanced Groovy programming language features in third party libraries, for example, by using Groovy AST transformations. |
This section should not serve as detailed guide on how to use Spock, it should rather give an impression what Spock is about and how it can be leveraged for unit, integration, functional or any other type of testing. |
The next section we will have an first look at the anatomy of a Spock specification. It should give a pretty good feeling on what Spock is up to.
4.1. Specifications
Spock lets you write specifications that describe features (properties, aspects) exhibited by a system of interest. The "system" can be anything between a single class and an entire application, a more advanced term for it is system under specification. The feature description starts from a specific snapshot of the system and its collaborators, this snapshot is called the feature’s fixture.
Spock specification classes are derived from spock.lang.Specification
. A concrete specification class might consist
of fields, fixture methods, features methods and helper methods.
Let’s have a look at a simple specification with a single feature method for an imaginary Stack
class:
class StackSpec extends Specification {
def "adding an element leads to size increase"() { (1)
setup: "a new stack instance is created" (2)
def stack = new Stack()
when: (3)
stack.push 42
then: (4)
stack.size() == 1
}
}
1 | Feature method, is by convention named with a String literal. |
2 | Setup block, here is where any setup work for this feature needs to be done. |
3 | When block describes a stimulus, a certain action under target by this feature specification. |
4 | Then block any expressions that can be used to validate the result of the code that was triggered by the when block. |
Spock feature specifications are defined as methods inside a spock.lang.Specification
class. They describe the feature
by using a String literal instead of a method name.
A feature method holds multiple blocks, in our example we used setup
, when
and then
. The setup
block is special
in that it is optional and allows to configure local variables visible inside the feature method. The when
block
defines the stimulus and is a companion of the then
block which describes the response to the stimulus.
Note that the setup
method in the StackSpec
above additionally
has a description String. Description Strings are optional and can be added after block labels (like setup
, when
,
then
).
4.2. More Spock
Spock provides much more features like data tables or advanced mocking capabilities. Feel free to consult the Spock GitHub page for more documentation and download information.
5. Functional Tests with Geb
Geb is a functional web testing and scraper library that integrates with JUnit and Spock. It is based upon the Selenium web drivers and, like Spock, provides a Groovy DSL to write functional tests for web applications.
Geb has great features that make it a good fit for a functional testing library:
-
DOM access via a JQuery-like
$
function -
implements the page pattern
-
support for modularization of certain web components (e.g. menu-bars, etc.) with modules
-
integration with JavaScript via the JS variable
This section should not serve as detailed guide on how to use Geb, it should rather give an impression what Geb is about and how it can be leveraged functional testing. |
The next section will give an example on how Geb can be used to write a functional test for a simple web page with a single search field.
5.1. A Geb Script
Although Geb can be used standalone in a Groovy script, in many scenarios it’s used in combination with other testing frameworks. Geb comes with various base classes that can be used in JUnit 3, 4, TestNG or Spock tests. The base classes are part of additional Geb modules that need to be added as a dependency.
For example, the following @Grab
dependencies have to be used to run Geb with the Selenium Firefox driver in
JUnit4 tests. The module that is needed for JUnit 3/4 support is geb-junit
:
@Grapes([
@Grab("org.gebish:geb-core:0.9.2"),
@Grab("org.gebish:geb-junit:0.9.2"),
@Grab("org.seleniumhq.selenium:selenium-firefox-driver:2.26.0"),
@Grab("org.seleniumhq.selenium:selenium-support:2.26.0")
])
The central class in Geb is the geb.Browser
class. As its name implies it is used
to browse pages and access DOM elements:
def browser = new Browser(driver: new FirefoxDriver(), baseUrl: 'http://myhost:8080/myapp') (1)
browser.drive {
go "/login" (2)
$("#username").text = 'John' (3)
$("#password").text = 'Doe'
$("#loginButton").click()
assert title == "My Application - Dashboard"
}
1 | A new Browser instance is created. In this case it uses the Selenium FirefoxDriver and sets the baseUrl . |
2 | go is used to navigate to an URL or relative URI |
3 | $ together with CSS selectors is used to access the username and password DOM fields. |
The Browser
class comes with a drive
method that delegates all method/property calls to the current
browser
instance. The Browser
configuration must not be done inline, it can also be externalized in a
GebConfig.groovy
configuration file for example. In practice, the usage of the Browser
class is mostly hidden
by Geb test base classes. They delegate all missing properties and method calls to the current browser
instance
that exists in the background:
class SearchTests extends geb.junit4.GebTest {
@Test
void executeSeach() {
go 'http://somehost/mayapp/search' (1)
$('#searchField').text = 'John Doe' (2)
$('#searchButton').click() (3)
assert $('.searchResult a').first().text() == 'Mr. John Doe' (4)
}
}
1 | Browser#go takes a relative or absolute link and calls the page. |
2 | Browser#$ is used to access DOM content. Any CSS selectors supported by the underlying Selenium drivers are allowed |
3 | click is used to click a button. |
4 | $ is used to get the first link out of the searchResult block |
The example above shows a simple Geb web test with the JUnit 4 base class geb.junit4.GebTest
. Note that in this case
the Browser
configuration is externalized. GebTest
delegates methods like go
and $
to the underlying browser
instance.
5.2. More Geb
In the previous section we only scratched the surface of the available Geb features. More information on Geb can be found at the project homepage.