Trait that facilitates a “behavior-driven” style of development (BDD), in which tests
are combined with text that specifies the behavior the tests verify.
(In BDD, the word example is usually used instead of test. The word test will not appear
in your code if you use FlatSpec, so if you prefer the word example you can use it. However, in this documentation
the word test will be used, for clarity and to be consistent with the rest of ScalaTest.)
Trait FlatSpec is so named because
your specification text and tests line up flat against the left-side indentation level, with no nesting needed.
FlatSpec's no-nesting approach contrasts with traits Spec and WordSpec, which use nesting
to reduce duplication of specification text. Although nesting does have the advantage of reducing text duplication,
figuring out the full specification text for one test can require back-tracking out of several levels of nesting, mentally prepending
each fragment of text encountered. Thus the tradeoff with the nesting approach of Spec and WordSpec is that
they have less duplicated text at the cost of being a bit challenging to read. Trait FlatSpec offers the opposite
tradeoff. In a FlatSpec text is duplicated more, but figuring out the full specification text for a particular test is
easier. Here's an example FlatSpec:
import org.scalatest.FlatSpec import scala.collection.mutable.Stackclass StackSpec extends FlatSpec {
behavior of "A Stack"
it should "pop values in last-in-first-out order" in { val stack = new Stack[Int] stack.push(1) stack.push(2) assert(stack.pop() === 2) assert(stack.pop() === 1) }
it should "throw NoSuchElementException if an empty stack is popped" in { val emptyStack = new Stack[String] intercept[NoSuchElementException] { emptyStack.pop() } } }
Note: you can you must or can as well as should in a FlatSpec. For example, instead of
it should "pop..., you could write it must "pop... or it can "pop....
Instead of using a behavior of clause, you can alternatively use a shorthand syntax in which you replace
the first it with the subject string, like this:
import org.scalatest.FlatSpec import scala.collection.mutable.Stackclass StackSpec extends FlatSpec {
"A Stack" should "pop values in last-in-first-out order" in { val stack = new Stack[Int] stack.push(1) stack.push(2) assert(stack.pop() === 2) assert(stack.pop() === 1) }
it should "throw NoSuchElementException if an empty stack is popped" in { val emptyStack = new Stack[String] intercept[NoSuchElementException] { emptyStack.pop() } } }
Running either of the two previous three versions of StackSpec in the Scala interpreter would yield:
A Stack - should pop values in last-in-first-out order - should throw NoSuchElementException if an empty stack is popped
In a FlatSpec you write a one (or more) sentence specification for each bit of behavior you wish to
specify and test. Each specification sentence has a
"subject," which is sometimes called the system under test (or SUT). The
subject is the entity being specified and tested and also serves as the subject of the sentences you write for each test.
Often you will want to write multiple tests for the same subject. In a FlatSpec, you name the subject once,
with a behavior of clause or its shorthand, then write tests for that subject with it should/mustcan "do something" phrases.
Each it refers to the most recently declared subject. For example, the four tests shown in this snippet are all testing
a stack that contains one item:
behavior of "A Stack (with one item)"it should "be non-empty" in {}
it should "return the top item on peek" in {}
it should "not remove the top item on peek" in {}
it should "remove the top item on pop" in {}
The same is true if the tests are written using the shorthand notation:
"A Stack (with one item)" should "be non-empty" in {}it should "return the top item on peek" in {}
it should "not remove the top item on peek" in {}
it should "remove the top item on pop" in {}
In a FlatSpec, therefore, to figure out what "it" means, you just scan vertically until you find the most
recent use of behavior of or the shorthand notation.
A FlatSpec's lifecycle has two phases: the registration phase and the
ready phase. It starts in registration phase and enters ready phase the first time
run is called on it. It then remains in ready phase for the remainder of its lifetime.
Tests can only be registered while the FlatSpec is
in its registration phase. Any attempt to register a test after the FlatSpec has
entered its ready phase, i.e., after run has been invoked on the FlatSpec,
will be met with a thrown TestRegistrationClosedException. The recommended style
of using FlatSpec is to register tests during object construction as is done in all
the examples shown here. If you keep to the recommended style, you should never see a
TestRegistrationClosedException.
A test fixture is objects or other artifacts (such as files, sockets, database
connections, etc.) used by tests to do their work. You can use fixtures in
FlatSpecs with the same approaches suggested for Suite in
its documentation. The same text that appears in the test fixture
section of Suite's documentation is repeated here, with examples changed from
Suite to FlatSpec.
If a fixture is used by only one test, then the definitions of the fixture objects can
be local to the test function, such as the objects assigned to stack and emptyStack in the
previous StackSpec examples. If multiple tests need to share an immutable fixture, one approach
is to assign them to instance variables. Here's a (very contrived) example, in which the object assigned
to shared is used by multiple test functions:
import org.scalatest.FlatSpecclass ArithmeticSpec extends FlatSpec {
// Sharing immutable fixture objects via instance variables val shared = 5
"The Scala language" must "add correctly" in { val sum = 2 + 3 assert(sum === shared) }
it must "subtract correctly" in { val diff = 7 - 2 assert(diff === shared) } }
In some cases, however, shared mutable fixture objects may be changed by tests such that
they need to be recreated or reinitialized before each test. Shared resources such
as files or database connections may also need to be created and initialized before, and
cleaned up after, each test. JUnit offers methods setUp and
tearDown for this purpose. In ScalaTest, you can use the BeforeAndAfterEach trait,
which will be described later, to implement an approach similar to JUnit's setUp
and tearDown, however, this approach often involves reassigning vars
between tests. Before going that route, you should consider some approaches that
avoid vars. One approach is to write one or more create-fixture methods
that return a new instance of a needed object (or a tuple or case class holding new instances of
multiple objects) each time it is called. You can then call a create-fixture method at the beginning of each
test that needs the fixture, storing the fixture object or objects in local variables. Here's an example:
import org.scalatest.FlatSpec import scala.collection.mutable.ListBufferclass MySuite extends FlatSpec {
// create objects needed by tests and return as a tuple def createFixture = ( new StringBuilder("ScalaTest is "), new ListBuffer[String] )
"ScalaTest" can "be easy " in { val (builder, lbuf) = createFixture builder.append("easy!") assert(builder.toString === "ScalaTest is easy!") assert(lbuf.isEmpty) lbuf += "sweet" }
it can "be fun" in { val (builder, lbuf) = createFixture builder.append("fun!") assert(builder.toString === "ScalaTest is fun!") assert(lbuf.isEmpty) } }
If different tests in the same FlatSpec require different fixtures, you can create multiple create-fixture methods and
call the method (or methods) needed by each test at the begining of the test. If every test requires the same set of
mutable fixture objects, one other approach you can take is make them simply vals and mix in trait
OneInstancePerTest. If you mix in OneInstancePerTest, each test
will be run in its own instance of the FlatSpec, similar to the way JUnit tests are executed.
Although the create-fixture and OneInstancePerTest approaches take care of setting up a fixture before each
test, they don't address the problem of cleaning up a fixture after the test completes. In this situation,
one option is to mix in the BeforeAndAfterEach trait.
BeforeAndAfterEach's beforeEach method will be run before, and its afterEach
method after, each test (like JUnit's setUp and tearDown
methods, respectively).
For example, you could create a temporary file before each test, and delete it afterwords, like this:
import org.scalatest.FlatSpec import org.scalatest.BeforeAndAfterEach import java.io.FileReader import java.io.FileWriter import java.io.Fileclass MySuite extends FlatSpec with BeforeAndAfterEach {
private val FileName = "TempFile.txt" private var reader: FileReader = _
// Set up the temp file needed by the test override def beforeEach() { val writer = new FileWriter(FileName) try { writer.write("Hello, test!") } finally { writer.close() }
// Create the reader needed by the test reader = new FileReader(FileName) }
// Close and delete the temp file override def afterEach() { reader.close() val file = new File(FileName) file.delete() }
"A FileReader" should "read in the contents of a file correctly" in { var builder = new StringBuilder var c = reader.read() while (c != -1) { builder.append(c.toChar) c = reader.read() } assert(builder.toString === "Hello, test!") }
it should "read in the first character of a file correctly" in { assert(reader.read() === 'H') }
it should "work without a fixture" in { assert(1 + 1 === 2) } }
In this example, the instance variable reader is a var, so
it can be reinitialized between tests by the beforeEach method.
Although the BeforeAndAfterEach approach should be familiar to the users of most
test other frameworks, ScalaTest provides another alternative that also allows you to perform cleanup
after each test: overriding withFixture(NoArgTest).
To execute each test, Suite's implementation of the runTest method wraps an invocation
of the appropriate test method in a no-arg function. runTest passes that test function to the withFixture(NoArgTest)
method, which is responsible for actually running the test by invoking the function. Suite's
implementation of withFixture(NoArgTest) simply invokes the function, like this:
// Default implementation
protected def withFixture(test: NoArgTest) {
test()
}
The withFixture(NoArgTest) method exists so that you can override it and set a fixture up before, and clean it up after, each test.
Thus, the previous temp file example could also be implemented without mixing in BeforeAndAfterEach, like this:
import org.scalatest.FlatSpec import org.scalatest.BeforeAndAfterEach import java.io.FileReader import java.io.FileWriter import java.io.Fileclass MySuite extends FlatSpec {
private var reader: FileReader = _
override def withFixture(test: NoArgTest) {
val FileName = "TempFile.txt"
// Set up the temp file needed by the test val writer = new FileWriter(FileName) try { writer.write("Hello, test!") } finally { writer.close() }
// Create the reader needed by the test reader = new FileReader(FileName)
try { test() // Invoke the test function } finally { // Close and delete the temp file reader.close() val file = new File(FileName) file.delete() } }
"A FileReader" should "read in the contents of a file correctly" in { var builder = new StringBuilder var c = reader.read() while (c != -1) { builder.append(c.toChar) c = reader.read() } assert(builder.toString === "Hello, test!") }
it should "read in the first character of a file correctly" in { assert(reader.read() === 'H') }
it should "work without a fixture" in { assert(1 + 1 === 2) } }
If you prefer to keep your test classes immutable, one final variation is to use the
FixtureFlatSpec trait from the
org.scalatest.fixture package. Tests in an org.scalatest.fixture.FixtureFlatSpec can have a fixture
object passed in as a parameter. You must indicate the type of the fixture object
by defining the Fixture type member and define a withFixture method that takes a one-arg test function.
(A FixtureFlatSpec has two overloaded withFixture methods, therefore, one that takes a OneArgTest
and the other, inherited from Suite, that takes a NoArgTest.)
Inside the withFixture(OneArgTest) method, you create the fixture, pass it into the test function, then perform any
necessary cleanup after the test function returns. Instead of invoking each test directly, a FixtureFlatSpec will
pass a function that invokes the code of a test to withFixture(OneArgTest). Your withFixture(OneArgTest) method, therefore,
is responsible for actually running the code of the test by invoking the test function.
For example, you could pass the temp file reader fixture to each test that needs it
by overriding the withFixture(OneArgTest) method of a FixtureFlatSpec, like this:
import org.scalatest.fixture.FixtureFlatSpec import java.io.FileReader import java.io.FileWriter import java.io.Fileclass MySuite extends FixtureFlatSpec {
type FixtureParam = FileReader
def withFixture(test: OneArgTest) {
val FileName = "TempFile.txt"
// Set up the temp file needed by the test val writer = new FileWriter(FileName) try { writer.write("Hello, test!") } finally { writer.close() }
// Create the reader needed by the test val reader = new FileReader(FileName)
try { // Run the test using the temp file test(reader) } finally { // Close and delete the temp file reader.close() val file = new File(FileName) file.delete() } }
"A FileReader" should "read in the contents of a file correctly" in { reader => var builder = new StringBuilder var c = reader.read() while (c != -1) { builder.append(c.toChar) c = reader.read() } assert(builder.toString === "Hello, test!") }
it should "read in the first character of a file correctly" in { reader => assert(reader.read() === 'H') }
it should "work without a fixture" in { () => assert(1 + 1 === 2) } }
It is worth noting that the only difference in the test code between the mutable
BeforeAndAfterEach approach shown here and the immutable FixtureFlatSpec
approach shown previously is that two of the FixtureFlatSpec's test functions take a FileReader as
a parameter via the "reader =>" at the beginning of the function. Otherwise the test code is identical.
One benefit of the explicit parameter is that, as demonstrated
by the "it should work without a fixture" test, a FixtureFlatSpec
test need not take the fixture. So you can have some tests that take a fixture, and others that don't.
In this case, the FixtureFlatSpec provides documentation indicating which
tests use the fixture and which don't, whereas the BeforeAndAfterEach approach does not.
(If you have want to combine tests that take different fixture types in the same FlatSpec, you can
use MultipleFixtureFlatSpec.)
If you want to execute code before and after all tests (and nested suites) in a suite, such
as you could do with @BeforeClass and @AfterClass
annotations in JUnit 4, you can use the beforeAll and afterAll
methods of BeforeAndAfterAll. See the documentation for BeforeAndAfterAll for
an example.
Sometimes you may want to run the same test code on different fixture objects. In other words, you may want to write tests that are "shared"
by different fixture objects. To accomplish this in a FlatSpec, you first place shared tests in behavior functions.
These behavior functions will be invoked during the construction phase of any FlatSpec that uses them, so that the tests they
contain will be registered as tests in that FlatSpec. For example, given this stack class:
import scala.collection.mutable.ListBufferclass Stack[T] {
val MAX = 10 private var buf = new ListBuffer[T]
def push(o: T) { if (!full) o +: buf else throw new IllegalStateException("can't push onto a full stack") }
def pop(): T = { if (!empty) buf.remove(0) else throw new IllegalStateException("can't pop an empty stack") }
def peek: T = { if (!empty) buf(0) else throw new IllegalStateException("can't pop an empty stack") }
def full: Boolean = buf.size == MAX def empty: Boolean = buf.size == 0 def size = buf.size
override def toString = buf.mkString("Stack(", ", ", ")") }
You may want to test the Stack class in different states: empty, full, with one item, with one item less than capacity,
etc. You may find you have several tests that make sense any time the stack is non-empty. Thus you'd ideally want to run
those same tests for three stack fixture objects: a full stack, a stack with a one item, and a stack with one item less than
capacity. With shared tests, you can factor these tests out into a behavior function, into which you pass the
stack fixture to use when running the tests. So in your FlatSpec for stack, you'd invoke the
behavior function three times, passing in each of the three stack fixtures so that the shared tests are run for all three fixtures. You
can define a behavior function that encapsulates these shared tests inside the FlatSpec that uses them. If they are shared
between different FlatSpecs, however, you could also define them in a separate trait that is mixed into each FlatSpec
that uses them.
For example, here the nonEmptyStack behavior function (in this case, a behavior method) is
defined in a trait along with another method containing shared tests for non-full stacks:
trait StackBehaviors { this: FlatSpec => def nonEmptyStack(stack: Stack[Int], lastItemAdded: Int) {
it should "be non-empty" in {
assert(!stack.empty)
}
it should "return the top item on peek" in {
assert(stack.peek === lastItemAdded)
}
it should "not remove the top item on peek" in {
val size = stack.size
assert(stack.peek === lastItemAdded)
assert(stack.size === size)
}
it should "remove the top item on pop" in {
val size = stack.size
assert(stack.pop === lastItemAdded)
assert(stack.size === size - 1)
}
}
def nonFullStack(stack: Stack[Int]) {
it should "not be full" in {
assert(!stack.full)
}
it should "add to the top on push" in {
val size = stack.size
stack.push(7)
assert(stack.size === size + 1)
assert(stack.peek === 7)
}
}
}
Given these behavior functions, you could invoke them directly, but FlatSpec offers a DSL for the purpose,
which looks like this:
it should behave like nonEmptyStack(stackWithOneItem, lastValuePushed) it should behave like nonFullStack(stackWithOneItem)
If you prefer to use an imperative style to change fixtures, for example by mixing in BeforeAndAfterEach and
reassigning a stack var in beforeEach, you could write your behavior functions
in the context of that var, which means you wouldn't need to pass in the stack fixture because it would be
in scope already inside the behavior function. In that case, your code would look like this:
it should behave like nonEmptyStack // assuming lastValuePushed is also in scope inside nonEmptyStack it should behave like nonFullStack
The recommended style, however, is the functional, pass-all-the-needed-values-in style. Here's an example:
class SharedTestExampleSpec extends FlatSpec with StackBehaviors { // Stack fixture creation methods
def emptyStack = new Stack[Int]
def fullStack = {
val stack = new Stack[Int]
for (i <- 0 until stack.MAX)
stack.push(i)
stack
}
def stackWithOneItem = {
val stack = new Stack[Int]
stack.push(9)
stack
}
def stackWithOneItemLessThanCapacity = {
val stack = new Stack[Int]
for (i <- 1 to 9)
stack.push(i)
stack
}
val lastValuePushed = 9
"A Stack (when empty)" should "be empty" in {
assert(emptyStack.empty)
}
it should "complain on peek" in {
intercept[IllegalStateException] {
emptyStack.peek
}
}
it should "complain on pop" in {
intercept[IllegalStateException] {
emptyStack.pop
}
}
"A Stack (with one item)" should behave like nonEmptyStack(stackWithOneItem, lastValuePushed)
it should behave like nonFullStack(stackWithOneItem)
"A Stack (with one item less than capacity)" should behave like nonEmptyStack(stackWithOneItemLessThanCapacity, lastValuePushed)
it should behave like nonFullStack(stackWithOneItemLessThanCapacity)
"A Stack (full)" should "be full" in {
assert(fullStack.full)
}
it should behave like nonEmptyStack(fullStack, lastValuePushed)
it should "complain on a push" in {
intercept[IllegalStateException] {
fullStack.push(10)
}
}
}
If you load these classes into the Scala interpreter (with scalatest's JAR file on the class path), and execute it, you'll see:
scala> (new SharedTestExampleSpec).execute() A Stack (when empty) - should be empty - should complain on peek - should complain on pop A Stack (with one item) - should be non-empty - should return the top item on peek - should not remove the top item on peek - should remove the top item on pop - should not be full - should add to the top on push A Stack (with one item less than capacity) - should be non-empty - should return the top item on peek - should not remove the top item on peek - should remove the top item on pop - should not be full - should add to the top on push A Stack (full) - should be full - should be non-empty - should return the top item on peek - should not remove the top item on peek - should remove the top item on pop - should complain on a push
One thing to keep in mind when using shared tests is that in ScalaTest, each test in a suite must have a unique name.
If you register the same tests repeatedly in the same suite, one problem you may encounter is an exception at runtime
complaining that multiple tests are being registered with the same test name. A good way to solve this problem in a WordSpec is to make sure
each invocation of a behavior function is in the context of a different set of when, verb (should,
must, or can), and that clauses,
which will prepend a string to each test name.
For example, the following code in a WordSpec would register a test with the name "A Stack (when empty) should be empty":
behavior of "A Stack (when empty)"it should "be empty" in { assert(emptyStack.empty) } // ...
Or, using the shorthand notation:
"A Stack" when {
"empty" should {
"be empty" in {
assert(emptyStack.empty)
}
}
}
// ...
If the "should be empty" test was factored out into a behavior function, it could be called repeatedly so long
as each invocation of the behavior function is in the context of a different combination
of when, verb, and that clauses.
A FlatSpec's tests may be classified into groups by tagging them with string names.
As with any suite, when executing a FlatSpec, groups of tests can
optionally be included and/or excluded. To tag a FlatSpec's tests,
you pass objects that extend abstract class org.scalatest.Tag to taggedAs method
invoked on the string that describes the test you want to tag. Class Tag takes one parameter,
a string name. If you have
created Java annotation interfaces for use as group names in direct subclasses of org.scalatest.Suite,
then you will probably want to use group names on your FlatSpecs that match. To do so, simply
pass the fully qualified names of the Java interfaces to the Tag constructor. For example, if you've
defined Java annotation interfaces with fully qualified names, com.mycompany.groups.SlowTest and com.mycompany.groups.DbTest, then you could
create matching groups for Specs like this:
import org.scalatest.Tagobject SlowTest extends Tag("com.mycompany.groups.SlowTest") object DbTest extends Tag("com.mycompany.groups.DbTest")
Given these definitions, you could place FlatSpec tests into groups like this:
import org.scalatest.FlatSpecclass MySuite extends FlatSpec {
"The Scala language" must "add correctly" taggedAs(SlowTest) in { val sum = 1 + 1 assert(sum === 2) assert(sum + 2 === 4) }
it must "subtract correctly" taggedAs(SlowTest, DbTest) in { val diff = 4 - 1 assert(diff === 3) assert(diff - 2 === 1) } }
This code marks both tests with the com.mycompany.groups.SlowTest tag,
and test "The Scala language should subtract correctly" with the com.mycompany.groups.DbTest tag.
The primary run method takes a Filter, whose constructor takes an optional
Set[String]s called tagsToInclude and a Set[String] called
tagsToExclude. If tagsToInclude is None, all tests will be run
except those those belonging to tags listed in the
tagsToExclude Set. If tagsToInclude is defined, only tests
belonging to tags mentioned in the tagsToInclude set, and not mentioned in tagsToExclude,
will be run.
To support the common use case of “temporarily” disabling a test, with the
good intention of resurrecting the test at a later time, FlatSpec provides a method
ignore that can be used instead of it to register a test. For example, to temporarily
disable the test with the name "A Stack should throw NoSuchElementException if an empty stack is popped", just
change “it” into “ignore,” like this:
import org.scalatest.FlatSpec import scala.collection.mutable.Stackclass StackSpec extends FlatSpec {
"A Stack" should "pop values in last-in-first-out order" in { val stack = new Stack[Int] stack.push(1) stack.push(2) assert(stack.pop() === 2) assert(stack.pop() === 1) }
ignore should "throw NoSuchElementException if an empty stack is popped" in { val emptyStack = new Stack[String] intercept[NoSuchElementException] { emptyStack.pop() } } }
If you run this version of StackSpec with:
scala> (new StackSpec).execute()
It will run only the first test and report that the second test was ignored:
A Stack - should pop values in last-in-first-out order - should throw NoSuchElementException if an empty stack is popped !!! IGNORED !!!
When using shorthand notation, you won't have an it to change into ignore for
the first test of each new subject. To ignore such tests, you must instead change in to ignore.
For example, to temporarily disable the test with the name "A Stack should pop values in last-in-first-out order",
change “in” into “ignore” like this:
import org.scalatest.FlatSpec import scala.collection.mutable.Stackclass StackSpec extends FlatSpec {
"A Stack" should "pop values in last-in-first-out order" ignore { val stack = new Stack[Int] stack.push(1) stack.push(2) assert(stack.pop() === 2) assert(stack.pop() === 1) }
it should "throw NoSuchElementException if an empty stack is popped" in { val emptyStack = new Stack[String] intercept[NoSuchElementException] { emptyStack.pop() } } }
If you run this version of StackSpec with:
scala> (new StackSpec).execute()
It will run only the second test and report that the first test was ignored:
A Stack - should pop values in last-in-first-out order !!! IGNORED !!! - should throw NoSuchElementException if an empty stack is popped
One of the parameters to the primary run method is a Reporter, which
will collect and report information about the running suite of tests.
Information about suites and tests that were run, whether tests succeeded or failed,
and tests that were ignored will be passed to the Reporter as the suite runs.
Most often the reporting done by default by FlatSpec's methods will be sufficient, but
occasionally you may wish to provide custom information to the Reporter from a test.
For this purpose, an Informer that will forward information to the current Reporter
is provided via the info parameterless method.
You can pass the extra information to the Informer via its apply method.
The Informer will then pass the information to the Reporter via an InfoProvided event.
Here's an example:
import org.scalatest.FlatSpecclass ArithmeticSpec extends FlatSpec {
"The Scala language" must "add correctly" in { val sum = 2 + 3 assert(sum === 5) info("addition seems to work") }
it must "subtract correctly" in { val diff = 7 - 2 assert(diff === 5) } }
If you run this FlatSpec from the interpreter, you will see the following message
included in the printed report:
scala> (new ArithmeticSpec).execute() The Scala language - must add correctly + addition seems to work - must subtract correctly
One use case for the Informer is to pass more information about a specification to the reporter. For example,
the GivenWhenThen trait provides methods that use the implicit info provided by FlatSpec
to pass such information to the reporter. Here's an example:
import org.scalatest.FlatSpec import org.scalatest.GivenWhenThenclass ArithmeticSpec extends FlatSpec with GivenWhenThen {
"The Scala language" must "add correctly" in {
given("two integers") val x = 2 val y = 3
when("they are added") val sum = x + y
then("the result is the sum of the two numbers") assert(sum === 5) }
it must "subtract correctly" in {
given("two integers") val x = 7 val y = 2
when("one is subtracted from the other") val diff = x - y
then("the result is the difference of the two numbers") assert(diff === 5) } }
scala> (new ArithmeticSpec).execute() The Scala language - must add correctly + Given two integers + When they are added + Then the result is the sum of the two numbers - must subtract correctly + Given two integers + When one is subtracted from the other + Then the result is the difference of the two numbers
A pending test is one that has been given a name but is not yet implemented. The purpose of pending tests is to facilitate a style of testing in which documentation of behavior is sketched out before tests are written to verify that behavior (and often, the before the behavior of the system being tested is itself implemented). Such sketches form a kind of specification of what tests and functionality to implement later.
To support this style of testing, a test can be given a name that specifies one
bit of behavior required by the system being tested. The test can also include some code that
sends more information about the behavior to the reporter when the tests run. At the end of the test,
it can call method pending, which will cause it to complete abruptly with TestPendingException.
Because tests in ScalaTest can be designated as pending with TestPendingException, both the test name and any information
sent to the reporter when running the test can appear in the report of a test run. (In other words,
the code of a pending test is executed just like any other test.) However, because the test completes abruptly
with TestPendingException, the test will be reported as pending, to indicate
the actual test, and possibly the functionality it is intended to test, has not yet been implemented.
You can mark tests as pending in FlatSpec like this:
import org.scalatest.FlatSpecclass ArithmeticSpec extends FlatSpec {
// Sharing fixture objects via instance variables val shared = 5
"The Scala language" must "add correctly" in { val sum = 2 + 3 assert(sum === shared) }
it must "subtract correctly" is (pending) }
If you run this version of ArithmeticSpec with:
scala> (new ArithmeticSpec).execute()
It will run both tests but report that The Scala language must subtract correctly is pending. You'll see:
The Scala language - must add correctly - must subtract correctly (pending)
One difference between an ignored test and a pending one is that an ignored test is intended to be used during a significant refactorings of the code under test, when tests break and you don't want to spend the time to fix all of them immediately. You can mark some of those broken tests as ignored temporarily, so that you can focus the red bar on just failing tests you actually want to fix immediately. Later you can go back and fix the ignored tests. In other words, by ignoring some failing tests temporarily, you can more easily notice failed tests that you actually want to fix. By contrast, a pending test is intended to be used before a test and/or the code under test is written. Pending indicates you've decided to write a test for a bit of behavior, but either you haven't written the test yet, or have only written part of it, or perhaps you've written the test but don't want to implement the behavior it tests until after you've implemented a different bit of behavior you realized you need first. Thus ignored tests are designed to facilitate refactoring of existing code whereas pending tests are designed to facilitate the creation of new code.
One other difference between ignored and pending tests is that ignored tests are implemented as a test tag that is
excluded by default. Thus an ignored test is never executed. By contrast, a pending test is implemented as a
test that throws TestPendingException (which is what calling the pending method does). Thus
the body of pending tests are executed up until they throw TestPendingException. The reason for this difference
is that it enables your unfinished test to send InfoProvided messages to the reporter before it completes
abruptly with TestPendingException, as shown in the previous example on Informers
that used the GivenWhenThen trait. For example, the following snippet in a FlatSpec:
"The Scala language" must "add correctly" in {
given("two integers")
when("they are added")
then("the result is the sum of the two numbers")
pending
}
// ...
Would yield the following output when run in the interpreter:
The Scala language - must add correctly (pending) + Given two integers + When they are added + Then the result is the sum of the two numbers
Class that supports the registration of a “subject” being specified and tested via the
instance referenced from FlatSpec's behavior field.
Class used via an implicit conversion to enable any two objects to be compared with
=== in assertions in tests.
Class that supports registration of ignored tests via the IgnoreWord instance referenced
from FlatSpec's ignore field.
Class that supports registration of ignored, tagged tests via the IgnoreWord instance referenced
from FlatSpec's ignore field.
Class that supports registration of ignored tests via the ItWord instance
referenced from FlatSpec's ignore field.
Class that supports test registration in shorthand form.
Class that supports tagged test registration in shorthand form.
Class that supports test registration via the ItWord instance referenced from FlatSpec's it field.
Class that supports the registration of tagged tests via the ItWord instance
referenced from FlatSpec's it field.
Class that supports test (and shared test) registration via the instance referenced from FlatSpec's it field.
A test function taking no arguments, which also provides a test name and config map.
This class supports the syntax of FlatSpec, WordSpec, FixtureFlatSpec,
and FixtureWordSpec.
This class supports the syntax of FlatSpec, WordSpec, FixtureFlatSpec,
and FixtureWordSpec.
This class supports the syntax of FlatSpec, WordSpec, FixtureFlatSpec,
and FixtureWordSpec.
o != arg0 is the same as !(o == (arg0)).
o != arg0 is the same as !(o == (arg0)).
the object to compare against this object for dis-equality.
false if the receiver object is equivalent to the argument; true otherwise.
o == arg0 is the same as if (o eq null) arg0 eq null else o.equals(arg0).
o == arg0 is the same as if (o eq null) arg0 eq null else o.equals(arg0).
the object to compare against this object for equality.
true if the receiver object is equivalent to the argument; false otherwise.
o == arg0 is the same as o.equals(arg0).
o == arg0 is the same as o.equals(arg0).
the object to compare against this object for equality.
true if the receiver object is equivalent to the argument; false otherwise.
This method is used to cast the receiver object to be of type T0.
This method is used to cast the receiver object to be of type T0.
Note that the success of a cast at runtime is modulo Scala's erasure semantics. Therefore the expression
1.asInstanceOf[String] will throw a ClassCastException at runtime, while the expression
List(1).asInstanceOf[List[String]] will not. In the latter example, because the type argument is erased as
part of compilation it is not possible to check whether the contents of the list are of the requested typed.
the receiver object.
Assert that an Option[String] is None.
Assert that an Option[String] is None.
If the condition is None, this method returns normally.
Else, it throws TestFailedException with the String
value of the Some included in the TestFailedException's
detail message.
This form of assert is usually called in conjunction with an
implicit conversion to Equalizer, using a === comparison, as in:
assert(a === b)
For more information on how this mechanism works, see the documentation for
Equalizer.
the Option[String] to assert
Assert that an Option[String] is None.
Assert that an Option[String] is None.
If the condition is None, this method returns normally.
Else, it throws TestFailedException with the String
value of the Some, as well as the
String obtained by invoking toString on the
specified message,
included in the TestFailedException's detail message.
This form of assert is usually called in conjunction with an
implicit conversion to Equalizer, using a === comparison, as in:
assert(a === b, "extra info reported if assertion fails")
For more information on how this mechanism works, see the documentation for
Equalizer.
the Option[String] to assert
An objects whose toString method returns a message to include in a failure report.
Assert that a boolean condition, described in String
message, is true.
Assert that a boolean condition, described in String
message, is true.
If the condition is true, this method returns normally.
Else, it throws TestFailedException with the
String obtained by invoking toString on the
specified message as the exception's detail message.
the boolean condition to assert
An objects whose toString method returns a message to include in a failure report.
Assert that a boolean condition is true.
Assert that a boolean condition is true.
If the condition is true, this method returns normally.
Else, it throws TestFailedException.
the boolean condition to assert
Supports shared test registration in FlatSpecs.
Supports shared test registration in FlatSpecs.
This field supports syntax such as the following:
it should behave like nonFullStack(stackWithOneItem)
For more information and examples of the use of behave, see the Shared tests section
in the main documentation for this trait.
Supports the registration of a “subject” being specified and tested.
Supports the registration of a “subject” being specified and tested.
This field enables syntax such as the following subject registration:
behavior of "A Stack"
For more information and examples of the use of the behavior field, see the main documentation
for this trait.
This method creates and returns a copy of the receiver object.
This method creates and returns a copy of the receiver object.
The default implementation of the clone method is platform dependent.
a copy of the receiver object.
Implicit conversion from Any to Equalizer, used to enable
assertions with === comparisons.
Implicit conversion from Any to Equalizer, used to enable
assertions with === comparisons.
For more information on this mechanism, see the documentation for </code>Equalizer</code>.
Because trait Suite mixes in Assertions, this implicit conversion will always be
available by default in ScalaTest Suites. This is the only implicit conversion that is in scope by default in every
ScalaTest Suite. Other implicit conversions offered by ScalaTest, such as those that support the matchers DSL
or invokePrivate, must be explicitly invited into your test code, either by mixing in a trait or importing the
members of its companion object. The reason ScalaTest requires you to invite in implicit conversions (with the exception of the
implicit conversion for === operator) is because if one of ScalaTest's implicit conversions clashes with an
implicit conversion used in the code you are trying to test, your program won't compile. Thus there is a chance that if you
are ever trying to use a library or test some code that also offers an implicit conversion involving a === operator,
you could run into the problem of a compiler error due to an ambiguous implicit conversion. If that happens, you can turn off
the implicit conversion offered by this convertToEqualizer method simply by overriding the method in your
Suite subclass, but not marking it as implicit:
// In your Suite subclass override def convertToEqualizer(left: Any) = new Equalizer(left)
the object whose type to convert to Equalizer.
Implicitly converts an object of type ResultOfStringPassedToVerb to an
InAndIgnoreMethods, to enable in and ignore
methods to be invokable on that object.
Implicitly converts an object of type ResultOfStringPassedToVerb to an
InAndIgnoreMethods, to enable in and ignore
methods to be invokable on that object.
Implicitly converts an object of type ResultOfTaggedAsInvocation to an
InAndIgnoreMethodsAfterTaggedAs, to enable in and ignore
methods to be invokable on that object.
Implicitly converts an object of type ResultOfTaggedAsInvocation to an
InAndIgnoreMethodsAfterTaggedAs, to enable in and ignore
methods to be invokable on that object.
Implicitly converts an object of type String to a StringCanWrapper,
to enable can methods to be invokable on that object.
Implicitly converts an object of type String to a StringCanWrapper,
to enable can methods to be invokable on that object.
Implicitly converts an object of type String to a StringMustWrapper,
to enable must methods to be invokable on that object.
Implicitly converts an object of type String to a StringMustWrapper,
to enable must methods to be invokable on that object.
Implicitly converts an object of type String to a StringShouldWrapperForVerb,
to enable should methods to be invokable on that object.
Implicitly converts an object of type String to a StringShouldWrapperForVerb,
to enable should methods to be invokable on that object.
This method is used to test whether the argument (arg0) is a reference to the
receiver object (this).
This method is used to test whether the argument (arg0) is a reference to the
receiver object (this).
The eq method implements an [http://en.wikipedia.org/wiki/Equivalence_relation equivalence relation] on
non-null instances of AnyRef:
* It is reflexive: for any non-null instance x of type AnyRef, x.eq(x) returns true.
* It is symmetric: for any non-null instances x and y of type AnyRef, x.eq(y) returns true if and
only if y.eq(x) returns true.
* It is transitive: for any non-null instances x, y, and z of type AnyRef if x.eq(y) returns true
and y.eq(z) returns true, then x.eq(z) returns true.
Additionally, the eq method has three other properties.
* It is consistent: for any non-null instances x and y of type AnyRef, multiple invocations of
x.eq(y) consistently returns true or consistently returns false.
* For any non-null instance x of type AnyRef, x.eq(null) and null.eq(x) returns false.
* null.eq(null) returns true.
When overriding the equals or hashCode methods, it is important to ensure that their behavior is
consistent with reference equality. Therefore, if two objects are references to each other (o1 eq o2), they
should be equal to each other (o1 == o2) and they should hash to the same value (o1.hashCode == o2.hashCode).
the object to compare against this object for reference equality.
true if the argument is a reference to the receiver object; false otherwise.
This method is used to compare the receiver object (this) with the argument object (arg0) for equivalence.
This method is used to compare the receiver object (this) with the argument object (arg0) for equivalence.
The default implementations of this method is an [http://en.wikipedia.org/wiki/Equivalence_relation equivalence
relation]:
* It is reflexive: for any instance x of type Any, x.equals(x) should return true.
* It is symmetric: for any instances x and y of type Any, x.equals(y) should return true if and
only if y.equals(x) returns true.
* It is transitive: for any instances x, y, and z of type AnyRef if x.equals(y) returns true and
y.equals(z) returns true, then x.equals(z) should return true.
If you override this method, you should verify that your implementation remains an equivalence relation.
Additionally, when overriding this method it is often necessary to override hashCode to ensure that objects
that are "equal" (o1.equals(o2) returns true) hash to the same scala.Int
(o1.hashCode.equals(o2.hashCode)).
the object to compare against this object for equality.
true if the receiver object is equivalent to the argument; false otherwise.
Executes the test specified as testName in this Suite with the specified configMap, printing
results to the standard output.
Executes the test specified as testName in this Suite with the specified configMap, printing
results to the standard output.
This method implementation calls run on this Suite, passing in:
testName - Some(testName)reporter - a reporter that prints to the standard outputstopper - a Stopper whose apply method always returns falsefilter - a Filter constructed with None for tagsToInclude and Set()
for tagsToExcludeconfigMap - the specified configMap Map[String, Any]distributor - Nonetracker - a new TrackerThis method serves as a convenient way to execute a single test, passing in some objects via the configMap, especially from
within the Scala interpreter.
Note: In ScalaTest, the terms "execute" and "run" basically mean the same thing and
can be used interchangably. The reason this convenience method and its three overloaded forms
aren't named run is described the documentation of the overloaded form that
takes no parameters: execute().
the name of one test to run.
a Map of key-value pairs that can be used by the executing Suite of tests.
Executes the test specified as testName in this Suite, printing results to the standard output.
Executes the test specified as testName in this Suite, printing results to the standard output.
This method implementation calls run on this Suite, passing in:
testName - Some(testName)reporter - a reporter that prints to the standard outputstopper - a Stopper whose apply method always returns falsefilter - a Filter constructed with None for tagsToInclude and Set()
for tagsToExcludeconfigMap - an empty Map[String, Any]distributor - Nonetracker - a new TrackerThis method serves as a convenient way to run a single test, especially from within the Scala interpreter.
Note: In ScalaTest, the terms "execute" and "run" basically mean the same thing and
can be used interchangably. The reason this convenience method and its three overloaded forms
aren't named run is described the documentation of the overloaded form that
takes no parameters: execute().
the name of one test to run.
Executes this Suite with the specified configMap, printing results to the standard output.
Executes this Suite with the specified configMap, printing results to the standard output.
This method implementation calls run on this Suite, passing in:
testName - Nonereporter - a reporter that prints to the standard outputstopper - a Stopper whose apply method always returns falsefilter - a Filter constructed with None for tagsToInclude and Set()
for tagsToExcludeconfigMap - the specified configMap Map[String, Any]distributor - Nonetracker - a new TrackerThis method serves as a convenient way to execute a Suite, passing in some objects via the configMap, especially from within the Scala interpreter.
Note: In ScalaTest, the terms "execute" and "run" basically mean the same thing and
can be used interchangably. The reason this convenience method and its three overloaded forms
aren't named run is described the documentation of the overloaded form that
takes no parameters: execute().
a Map of key-value pairs that can be used by the executing Suite of tests.
Executes this Suite, printing results to the standard output.
Executes this Suite, printing results to the standard output.
This method implementation calls run on this Suite, passing in:
testName - Nonereporter - a reporter that prints to the standard outputstopper - a Stopper whose apply method always returns falsefilter - a Filter constructed with None for tagsToInclude and Set()
for tagsToExcludeconfigMap - an empty Map[String, Any]distributor - Nonetracker - a new TrackerThis method serves as a convenient way to execute a Suite, especially from
within the Scala interpreter.
Note: In ScalaTest, the terms "execute" and "run" basically mean the same thing and
can be used interchangably. The reason this convenience method and its three overloaded forms
aren't named run
is because junit.framework.TestCase declares a run method
that takes no arguments but returns a junit.framework.TestResult. That
run method would not overload with this method if it were named run,
because it would have the same parameters but a different return type than the one
defined in TestCase. To facilitate integration with JUnit 3, therefore,
these convenience "run" methods are named execute. In particular, this allows trait
org.scalatest.junit.JUnit3Suite to extend both org.scalatest.Suite and
junit.framework.TestCase, which enables the creating of classes that
can be run with either ScalaTest or JUnit 3.
Expect that the value passed as expected equals the value passed as actual.
Expect that the value passed as expected equals the value passed as actual.
If the actual value equals the expected value
(as determined by ==), expect returns
normally. Else, expect throws an
TestFailedException whose detail message includes the expected and actual values.
the expected value
the actual value, which should equal the passed expected value
Expect that the value passed as expected equals the value passed as actual.
Expect that the value passed as expected equals the value passed as actual.
If the actual equals the expected
(as determined by ==), expect returns
normally. Else, if actual is not equal to expected, expect throws an
TestFailedException whose detail message includes the expected and actual values, as well as the String
obtained by invoking toString on the passed message.
the expected value
An object whose toString method returns a message to include in a failure report.
the actual value, which should equal the passed expected value
The total number of tests that are expected to run when this Suite's run method is invoked.
The total number of tests that are expected to run when this Suite's run method is invoked.
This trait's implementation of this method returns the sum of:
testNames List, minus the number of tests marked as ignoredexpectedTestCount on every nested Suite contained in
nestedSuitesa Filter with which to filter tests to count based on their tags
Throws TestFailedException, with the passed
Throwable cause, to indicate a test failed.
Throws TestFailedException, with the passed
Throwable cause, to indicate a test failed.
The getMessage method of the thrown TestFailedException
will return cause.toString().
a Throwable that indicates the cause of the failure.
Throws TestFailedException, with the passed
String message as the exception's detail
message and Throwable cause, to indicate a test failed.
Throws TestFailedException, with the passed
String message as the exception's detail
message and Throwable cause, to indicate a test failed.
A message describing the failure.
A Throwable that indicates the cause of the failure.
Throws TestFailedException, with the passed
String message as the exception's detail
message, to indicate a test failed.
Throws TestFailedException, with the passed
String message as the exception's detail
message, to indicate a test failed.
A message describing the failure.
Throws TestFailedException to indicate a test failed.
Throws TestFailedException to indicate a test failed.
This method is called by the garbage collector on the receiver object when garbage collection determines that there are no more references to the object.
This method is called by the garbage collector on the receiver object when garbage collection determines that there are no more references to the object.
The details of when and if the finalize method are invoked, as well as the interaction between finalize
and non-local returns and exceptions, are all platform dependent.
Returns a representation that corresponds to the dynamic class of the receiver object.
Returns a representation that corresponds to the dynamic class of the receiver object.
The nature of the representation is platform dependent.
a representation that corresponds to the dynamic class of the receiver object.
The groups methods has been deprecated and will be removed in a future version of ScalaTest.
The groups methods has been deprecated and will be removed in a future version of ScalaTest.
Please call (and override) tags instead.
Returns a hash code value for the object.
Returns a hash code value for the object.
The default hashing algorithm is platform dependent.
Note that it is allowed for two objects to have identical hash codes (o1.hashCode.equals(o2.hashCode)) yet
not be equal (o1.equals(o2) returns false). A degenerate implementation could always return 0.
However, it is required that if two objects are equal (o1.equals(o2) returns true) that they have
identical hash codes (o1.hashCode.equals(o2.hashCode)). Therefore, when overriding this method, be sure
to verify that the behavior is consistent with the equals method.
the hash code value for the object.
Supports registration of ignored tests in FlatSpecs.
Supports registration of ignored tests in FlatSpecs.
This field enables syntax such as the following registration of an ignored test:
ignore should "pop values in last-in-first-out order" in { ... }
For more information and examples of the use of the ignore field, see the Ignored tests section
in the main documentation for this trait.
Returns an Informer that during test execution will forward strings (and other objects) passed to its
apply method to the current reporter.
Returns an Informer that during test execution will forward strings (and other objects) passed to its
apply method to the current reporter. If invoked in a constructor, it
will register the passed string for forwarding later during test execution. If invoked while this
FlatSpec is being executed, such as from inside a test function, it will forward the information to
the current reporter immediately. If invoked at any other time, it will
throw an exception. This method can be called safely by any thread.
Intercept and return an exception that's expected to be thrown by the passed function value.
Intercept and return an exception that's expected to
be thrown by the passed function value. The thrown exception must be an instance of the
type specified by the type parameter of this method. This method invokes the passed
function. If the function throws an exception that's an instance of the specified type,
this method returns that exception. Else, whether the passed function returns normally
or completes abruptly with a different exception, this method throws TestFailedException.
Note that the type specified as this method's type parameter may represent any subtype of
AnyRef, not just Throwable or one of its subclasses. In
Scala, exceptions can be caught based on traits they implement, so it may at times make sense
to specify a trait that the intercepted exception's class must mix in. If a class instance is
passed for a type that could not possibly be used to catch an exception (such as String,
for example), this method will complete abruptly with a TestFailedException.
the function value that should throw the expected exception
an implicit Manifest representing the type of the specified
type parameter.
the intercepted exception, if it is of the expected type
This method is used to test whether the dynamic type of the receiver object is T0.
This method is used to test whether the dynamic type of the receiver object is T0.
Note that the test result of the test is modulo Scala's erasure semantics. Therefore the expression
1.isInstanceOf[String] will return false, while the expression List(1).isInstanceOf[List[String]] will
return true. In the latter example, because the type argument is erased as part of compilation it is not
possible to check whether the contents of the list are of the requested typed.
true if the receiver object is an instance of erasure of type T0; false otherwise.
Supports test (and shared test) registration in FlatSpecs.
Supports test (and shared test) registration in FlatSpecs.
This field enables syntax such as the following test registration:
it should "pop values in last-in-first-out order" in { ... }
It also enables syntax such as the following shared test registration:
it should behave like nonEmptyStack(lastItemPushed)
For more information and examples of the use of the it field, see the main documentation
for this trait.
o.ne(arg0) is the same as !(o.eq(arg0)).
o.ne(arg0) is the same as !(o.eq(arg0)).
the object to compare against this object for reference dis-equality.
false if the argument is not a reference to the receiver object; true otherwise.
A List of this Suite object's nested Suites. If this Suite contains no nested Suites,
this method returns an empty List. This trait's implementation of this method returns an empty List.
A List of this Suite object's nested Suites. If this Suite contains no nested Suites,
this method returns an empty List. This trait's implementation of this method returns an empty List.
Wakes up a single thread that is waiting on the receiver object's monitor.
Wakes up a single thread that is waiting on the receiver object's monitor.
Wakes up all threads that are waiting on the receiver object's monitor.
Wakes up all threads that are waiting on the receiver object's monitor.
Throws TestPendingException to indicate a test is pending.
Throws TestPendingException to indicate a test is pending.
A pending test is one that has been given a name but is not yet implemented. The purpose of pending tests is to facilitate a style of testing in which documentation of behavior is sketched out before tests are written to verify that behavior (and often, the before the behavior of the system being tested is itself implemented). Such sketches form a kind of specification of what tests and functionality to implement later.
To support this style of testing, a test can be given a name that specifies one
bit of behavior required by the system being tested. The test can also include some code that
sends more information about the behavior to the reporter when the tests run. At the end of the test,
it can call method pending, which will cause it to complete abruptly with TestPendingException.
Because tests in ScalaTest can be designated as pending with TestPendingException, both the test name and any information
sent to the reporter when running the test can appear in the report of a test run. (In other words,
the code of a pending test is executed just like any other test.) However, because the test completes abruptly
with TestPendingException, the test will be reported as pending, to indicate
the actual test, and possibly the functionality it is intended to test, has not yet been implemented.
Note: This method always completes abruptly with a TestPendingException. Thus it always has a side
effect. Methods with side effects are usually invoked with parentheses, as in pending(). This
method is defined as a parameterless method, in flagrant contradiction to recommended Scala style, because it
forms a kind of DSL for pending tests. It enables tests in suites such as FunSuite or Spec
to be denoted by placing "(pending)" after the test name, as in:
test("that style rules are not laws") (pending)
Readers of the code see "pending" in parentheses, which looks like a little note attached to the test name to indicate
it is pending. Whereas "(pending()) looks more like a method call, "(pending)" lets readers
stay at a higher level, forgetting how it is implemented and just focusing on the intent of the programmer who wrote the code.
Execute the passed block of code, and if it completes abruptly, throw TestPendingException, else
throw TestFailedException.
Execute the passed block of code, and if it completes abruptly, throw TestPendingException, else
throw TestFailedException.
This method can be used to temporarily change a failing test into a pending test in such a way that it will
automatically turn back into a failing test once the problem originally causing the test to fail has been fixed.
At that point, you need only remove the pendingUntilFixed call. In other words, a
pendingUntilFixed surrounding a block of code that isn't broken is treated as a test failure.
The motivation for this behavior is to encourage people to remove pendingUntilFixed calls when
there are no longer needed.
This method facilitates a style of testing in which tests are written before the code they test. Sometimes you may
encounter a test failure that requires more functionality than you want to tackle without writing more tests. In this
case you can mark the bit of test code causing the failure with pendingUntilFixed. You can then write more
tests and functionality that eventually will get your production code to a point where the original test won't fail anymore.
At this point the code block marked with pendingUntilFixed will no longer throw an exception (because the
problem has been fixed). This will in turn cause pendingUntilFixed to throw TestFailedException
with a detail message explaining you need to go back and remove the pendingUntilFixed call as the problem orginally
causing your test code to fail has been fixed.
a block of code, which if it completes abruptly, should trigger a TestPendingException
Runs this suite of tests.
Runs this suite of tests.
If testName is None, this trait's implementation of this method
calls these two methods on this object in this order:
runNestedSuites(report, stopper, tagsToInclude, tagsToExclude, configMap, distributor)runTests(testName, report, stopper, tagsToInclude, tagsToExclude, configMap)If testName is defined, then this trait's implementation of this method
calls runTests, but does not call runNestedSuites. This behavior
is part of the contract of this method. Subclasses that override run must take
care not to call runNestedSuites if testName is defined. (The
OneInstancePerTest trait depends on this behavior, for example.)
Subclasses and subtraits that override this run method can implement them without
invoking either the runTests or runNestedSuites methods, which
are invoked by this trait's implementation of this method. It is recommended, but not required,
that subclasses and subtraits that override run in a way that does not
invoke runNestedSuites also override runNestedSuites and make it
final. Similarly it is recommended, but not required,
that subclasses and subtraits that override run in a way that does not
invoke runTests also override runTests (and runTest,
which this trait's implementation of runTests calls) and make it
final. The implementation of these final methods can either invoke the superclass implementation
of the method, or throw an UnsupportedOperationException if appropriate. The
reason for this recommendation is that ScalaTest includes several traits that override
these methods to allow behavior to be mixed into a Suite. For example, trait
BeforeAndAfterEach overrides runTestss. In a Suite
subclass that no longer invokes runTests from run, the
BeforeAndAfterEach trait is not applicable. Mixing it in would have no effect.
By making runTests final in such a Suite subtrait, you make
the attempt to mix BeforeAndAfterEach into a subclass of your subtrait
a compiler error. (It would fail to compile with a complaint that BeforeAndAfterEach
is trying to override runTests, which is a final method in your trait.)
an optional name of one test to run. If None, all relevant tests should be run.
I.e., None acts like a wildcard that means run all relevant tests in this Suite.
the Reporter to which results will be reported
the Stopper that will be consulted to determine whether to stop execution early.
a Filter with which to filter tests based on their tags
a Map of key-value pairs that can be used by the executing Suite of tests.
an optional Distributor, into which to put nested Suites to be run
by another entity, such as concurrently by a pool of threads. If None, nested Suites will be run sequentially.
a Tracker tracking Ordinals being fired by the current thread.
Run zero to many of this Suite's nested Suites.
Run zero to many of this Suite's nested Suites.
If the passed distributor is None, this trait's
implementation of this method invokes run on each
nested Suite in the List obtained by invoking nestedSuites.
If a nested Suite's run
method completes abruptly with an exception, this trait's implementation of this
method reports that the Suite aborted and attempts to run the
next nested Suite.
If the passed distributor is defined, this trait's implementation
puts each nested Suite
into the Distributor contained in the Some, in the order in which the
Suites appear in the List returned by nestedSuites, passing
in a new Tracker obtained by invoking nextTracker on the Tracker
passed to this method.
Implementations of this method are responsible for ensuring SuiteStarting events
are fired to the Reporter before executing any nested Suite, and either SuiteCompleted
or SuiteAborted after executing any nested Suite.
the Reporter to which results will be reported
the Stopper that will be consulted to determine whether to stop execution early.
a Filter with which to filter tests based on their tags
a Map of key-value pairs that can be used by the executing Suite of tests.
an optional Distributor, into which to put nested Suites to be run
by another entity, such as concurrently by a pool of threads. If None, nested Suites will be run sequentially.
a Tracker tracking Ordinals being fired by the current thread.
Run a test.
Run a test. This trait's implementation runs the test registered with the name specified by
testName. Each test's name is a concatenation of the text of all describers surrounding a test,
from outside in, and the test's spec text, with one space placed between each item. (See the documenation
for testNames for an example.)
the name of one test to execute.
the Reporter to which results will be reported
the Stopper that will be consulted to determine whether to stop execution early.
a Map of properties that can be used by this Spec's executing tests.
a Tracker tracking Ordinals being fired by the current thread.
Run zero to many of this FlatSpec's tests.
Run zero to many of this FlatSpec's tests.
This method takes a testName parameter that optionally specifies a test to invoke.
If testName is Some, this trait's implementation of this method
invokes runTest on this object, passing in:
testName - the String value of the testName Option passed
to this methodreporter - the Reporter passed to this method, or one that wraps and delegates to itstopper - the Stopper passed to this method, or one that wraps and delegates to itconfigMap - the configMap passed to this method, or one that wraps and delegates to itThis method takes a Set of tag names that should be included (tagsToInclude), and a Set
that should be excluded (tagsToExclude), when deciding which of this Suite's tests to execute.
If tagsToInclude is empty, all tests will be executed
except those those belonging to tags listed in the tagsToExclude Set. If tagsToInclude is non-empty, only tests
belonging to tags mentioned in tagsToInclude, and not mentioned in tagsToExclude
will be executed. However, if testName is Some, tagsToInclude and tagsToExclude are essentially ignored.
Only if testName is None will tagsToInclude and tagsToExclude be consulted to
determine which of the tests named in the testNames Set should be run. For more information on trait tags, see the main documentation for this trait.
If testName is None, this trait's implementation of this method
invokes testNames on this Suite to get a Set of names of tests to potentially execute.
(A testNames value of None essentially acts as a wildcard that means all tests in
this Suite that are selected by tagsToInclude and tagsToExclude should be executed.)
For each test in the testName Set, in the order
they appear in the iterator obtained by invoking the elements method on the Set, this trait's implementation
of this method checks whether the test should be run based on the tagsToInclude and tagsToExclude Sets.
If so, this implementation invokes runTest, passing in:
testName - the String name of the test to run (which will be one of the names in the testNames Set)reporter - the Reporter passed to this method, or one that wraps and delegates to itstopper - the Stopper passed to this method, or one that wraps and delegates to itconfigMap - the configMap passed to this method, or one that wraps and delegates to itan optional name of one test to execute. If None, all relevant tests should be executed.
I.e., None acts like a wildcard that means execute all relevant tests in this Spec.
the Reporter to which results will be reported
the Stopper that will be consulted to determine whether to stop execution early.
a Filter with which to filter tests based on their tags
a Map of key-value pairs that can be used by this Spec's executing tests.
an optional Distributor, into which to put nested Suites to be run
by another entity, such as concurrently by a pool of threads. If None, nested Suites will be run sequentially.
a Tracker tracking Ordinals being fired by the current thread.
Supports the shorthand form of shared test registration.
Supports the shorthand form of shared test registration.
For example, this method enables syntax such as the following in:
"A Stack (with one item)" should behave like nonEmptyStack(stackWithOneItem, lastValuePushed)
This function is passed as an implicit parameter to a should method
provided in ShouldVerb, a must method
provided in MustVerb, and a can method
provided in CanVerb. When invoked, this function registers the
subject description (the parameter to the function) and returns a BehaveWord.
Supports the shorthand form of test registration.
Supports the shorthand form of test registration.
For example, this method enables syntax such as the following:
"A Stack (when empty)" should "be empty" in { ... }
This function is passed as an implicit parameter to a should method
provided in ShouldVerb, a must method
provided in MustVerb, and a can method
provided in CanVerb. When invoked, this function registers the
subject description (the first parameter to the function) and returns a ResultOfStringPassedToVerb
initialized with the verb and rest parameters (the second and third parameters to
the function, respectively).
A user-friendly suite name for this Suite.
A user-friendly suite name for this Suite.
This trait's
implementation of this method returns the simple name of this object's class. This
trait's implementation of runNestedSuites calls this method to obtain a
name for Reports to pass to the suiteStarting, suiteCompleted,
and suiteAborted methods of the Reporter.
this Suite object's suite name.
A Map whose keys are String tag names to which tests in this Spec belong, and values
the Set of test names that belong to each tag. If this FlatSpec contains no tags, this method returns an empty Map.
A Map whose keys are String tag names to which tests in this Spec belong, and values
the Set of test names that belong to each tag. If this FlatSpec contains no tags, this method returns an empty Map.
This trait's implementation returns tags that were passed as strings contained in Tag objects passed to
methods test and ignore.
An immutable Set of test names. If this FlatSpec contains no tests, this method returns an
empty Set.
An immutable Set of test names. If this FlatSpec contains no tests, this method returns an
empty Set.
This trait's implementation of this method will return a set that contains the names of all registered tests. The set's
iterator will return those names in the order in which the tests were registered. Each test's name is composed
of the concatenation of the text of each surrounding describer, in order from outside in, and the text of the
example itself, with all components separated by a space. For example, consider this FlatSpec:
import org.scalatest.FlatSpecclass StackSpec extends FlatSpec {
"A Stack (when not empty)" must "allow me to pop" in {} it must "not be empty" in {}
"A Stack (when not full)" must "allow me to push" in {} it must "not be full" in {} }
Invoking testNames on this Spec will yield a set that contains the following
two test name strings:
"A Stack (when not empty) must allow me to pop" "A Stack (when not empty) must not be empty" "A Stack (when not full) must allow me to push" "A Stack (when not full) must not be full"
Returns a string representation of the object.
Returns a string representation of the object.
The default representation is platform dependent.
a string representation of the object.
Executes the block of code passed as the second parameter, and, if it
completes abruptly with a ModifiableMessage exception,
prepends the "clue" string passed as the first parameter to the beginning of the detail message
of that thrown exception, then rethrows it.
Executes the block of code passed as the second parameter, and, if it
completes abruptly with a ModifiableMessage exception,
prepends the "clue" string passed as the first parameter to the beginning of the detail message
of that thrown exception, then rethrows it. If clue does not end in a white space
character, one space will be added
between it and the existing detail message (unless the detail message is
not defined).
This method allows you to add more information about what went wrong that will be reported when a test fails. Here's an example:
withClue("(Employee's name was: " + employee.name + ")") {
intercept[IllegalArgumentException] {
employee.getTask(-1)
}
}
If an invocation of intercept completed abruptly with an exception, the resulting message would be something like:
(Employee's name was Bob Jones) Expected IllegalArgumentException to be thrown, but no exception was thrown
Run the passed test function in the context of a fixture established by this method.
Run the passed test function in the context of a fixture established by this method.
This method should set up the fixture needed by the tests of the
current suite, invoke the test function, and if needed, perform any clean
up needed after the test completes. Because the NoArgTest function
passed to this method takes no parameters, preparing the fixture will require
side effects, such as reassigning instance vars in this Suite or initializing
a globally accessible external database. If you want to avoid reassigning instance vars
you can use FixtureSuite.
This trait's implementation of runTest invokes this method for each test, passing
in a NoArgTest whose apply method will execute the code of the test.
This trait's implementation of this method simply invokes the passed NoArgTest function.
the no-arg test function to run with a fixture
Trait that facilitates a “behavior-driven” style of development (BDD), in which tests are combined with text that specifies the behavior the tests verify. (In BDD, the word example is usually used instead of test. The word test will not appear in your code if you use
FlatSpec, so if you prefer the word example you can use it. However, in this documentation the word test will be used, for clarity and to be consistent with the rest of ScalaTest.) TraitFlatSpecis so named because your specification text and tests line up flat against the left-side indentation level, with no nesting needed.FlatSpec's no-nesting approach contrasts with traitsSpecandWordSpec, which use nesting to reduce duplication of specification text. Although nesting does have the advantage of reducing text duplication, figuring out the full specification text for one test can require back-tracking out of several levels of nesting, mentally prepending each fragment of text encountered. Thus the tradeoff with the nesting approach ofSpecandWordSpecis that they have less duplicated text at the cost of being a bit challenging to read. TraitFlatSpecoffers the opposite tradeoff. In aFlatSpectext is duplicated more, but figuring out the full specification text for a particular test is easier. Here's an exampleFlatSpec:Note: you can you
mustorcanas well asshouldin aFlatSpec. For example, instead ofit should "pop..., you could writeit must "pop... orit can "pop....Instead of using a
behavior ofclause, you can alternatively use a shorthand syntax in which you replace the firstitwith the subject string, like this:Running either of the two previous three versions of
StackSpecin the Scala interpreter would yield:In a
FlatSpecyou write a one (or more) sentence specification for each bit of behavior you wish to specify and test. Each specification sentence has a "subject," which is sometimes called the system under test (or SUT). The subject is the entity being specified and tested and also serves as the subject of the sentences you write for each test. Often you will want to write multiple tests for the same subject. In aFlatSpec, you name the subject once, with abehavior ofclause or its shorthand, then write tests for that subject withit should/mustcan "do something"phrases. Eachitrefers to the most recently declared subject. For example, the four tests shown in this snippet are all testing a stack that contains one item:The same is true if the tests are written using the shorthand notation:
"A Stack (with one item)" should "be non-empty" in {}it should "return the top item on peek" in {}
it should "not remove the top item on peek" in {}
it should "remove the top item on pop" in {}
In a
FlatSpec, therefore, to figure out what "it" means, you just scan vertically until you find the most recent use ofbehavior ofor the shorthand notation.A
FlatSpec's lifecycle has two phases: the registration phase and the ready phase. It starts in registration phase and enters ready phase the first timerunis called on it. It then remains in ready phase for the remainder of its lifetime.Tests can only be registered while the
FlatSpecis in its registration phase. Any attempt to register a test after theFlatSpechas entered its ready phase, i.e., afterrunhas been invoked on theFlatSpec, will be met with a thrownTestRegistrationClosedException. The recommended style of usingFlatSpecis to register tests during object construction as is done in all the examples shown here. If you keep to the recommended style, you should never see aTestRegistrationClosedException.Shared fixtures
A test fixture is objects or other artifacts (such as files, sockets, database connections, etc.) used by tests to do their work. You can use fixtures in
FlatSpecs with the same approaches suggested forSuitein its documentation. The same text that appears in the test fixture section ofSuite's documentation is repeated here, with examples changed fromSuitetoFlatSpec.If a fixture is used by only one test, then the definitions of the fixture objects can be local to the test function, such as the objects assigned to
stackandemptyStackin the previousStackSpecexamples. If multiple tests need to share an immutable fixture, one approach is to assign them to instance variables. Here's a (very contrived) example, in which the object assigned tosharedis used by multiple test functions:In some cases, however, shared mutable fixture objects may be changed by tests such that they need to be recreated or reinitialized before each test. Shared resources such as files or database connections may also need to be created and initialized before, and cleaned up after, each test. JUnit offers methods
setUpandtearDownfor this purpose. In ScalaTest, you can use theBeforeAndAfterEachtrait, which will be described later, to implement an approach similar to JUnit'ssetUpandtearDown, however, this approach often involves reassigningvars between tests. Before going that route, you should consider some approaches that avoidvars. One approach is to write one or more create-fixture methods that return a new instance of a needed object (or a tuple or case class holding new instances of multiple objects) each time it is called. You can then call a create-fixture method at the beginning of each test that needs the fixture, storing the fixture object or objects in local variables. Here's an example:If different tests in the same
FlatSpecrequire different fixtures, you can create multiple create-fixture methods and call the method (or methods) needed by each test at the begining of the test. If every test requires the same set of mutable fixture objects, one other approach you can take is make them simplyvals and mix in traitOneInstancePerTest. If you mix inOneInstancePerTest, each test will be run in its own instance of theFlatSpec, similar to the way JUnit tests are executed.Although the create-fixture and
OneInstancePerTestapproaches take care of setting up a fixture before each test, they don't address the problem of cleaning up a fixture after the test completes. In this situation, one option is to mix in theBeforeAndAfterEachtrait.BeforeAndAfterEach'sbeforeEachmethod will be run before, and itsafterEachmethod after, each test (like JUnit'ssetUpandtearDownmethods, respectively). For example, you could create a temporary file before each test, and delete it afterwords, like this:In this example, the instance variable
readeris avar, so it can be reinitialized between tests by thebeforeEachmethod.Although the
BeforeAndAfterEachapproach should be familiar to the users of most test other frameworks, ScalaTest provides another alternative that also allows you to perform cleanup after each test: overridingwithFixture(NoArgTest). To execute each test,Suite's implementation of therunTestmethod wraps an invocation of the appropriate test method in a no-arg function.runTestpasses that test function to thewithFixture(NoArgTest)method, which is responsible for actually running the test by invoking the function.Suite's implementation ofwithFixture(NoArgTest)simply invokes the function, like this:// Default implementation protected def withFixture(test: NoArgTest) { test() }The
withFixture(NoArgTest)method exists so that you can override it and set a fixture up before, and clean it up after, each test. Thus, the previous temp file example could also be implemented without mixing inBeforeAndAfterEach, like this:If you prefer to keep your test classes immutable, one final variation is to use the
FixtureFlatSpectrait from theorg.scalatest.fixturepackage. Tests in anorg.scalatest.fixture.FixtureFlatSpeccan have a fixture object passed in as a parameter. You must indicate the type of the fixture object by defining theFixturetype member and define awithFixturemethod that takes a one-arg test function. (AFixtureFlatSpechas two overloadedwithFixturemethods, therefore, one that takes aOneArgTestand the other, inherited fromSuite, that takes aNoArgTest.) Inside thewithFixture(OneArgTest)method, you create the fixture, pass it into the test function, then perform any necessary cleanup after the test function returns. Instead of invoking each test directly, aFixtureFlatSpecwill pass a function that invokes the code of a test towithFixture(OneArgTest). YourwithFixture(OneArgTest)method, therefore, is responsible for actually running the code of the test by invoking the test function. For example, you could pass the temp file reader fixture to each test that needs it by overriding thewithFixture(OneArgTest)method of aFixtureFlatSpec, like this:It is worth noting that the only difference in the test code between the mutable
BeforeAndAfterEachapproach shown here and the immutableFixtureFlatSpecapproach shown previously is that two of theFixtureFlatSpec's test functions take aFileReaderas a parameter via the "reader =>" at the beginning of the function. Otherwise the test code is identical. One benefit of the explicit parameter is that, as demonstrated by the "it should work without a fixture" test, aFixtureFlatSpectest need not take the fixture. So you can have some tests that take a fixture, and others that don't. In this case, theFixtureFlatSpecprovides documentation indicating which tests use the fixture and which don't, whereas theBeforeAndAfterEachapproach does not. (If you have want to combine tests that take different fixture types in the sameFlatSpec, you can use MultipleFixtureFlatSpec.)If you want to execute code before and after all tests (and nested suites) in a suite, such as you could do with
@BeforeClassand@AfterClassannotations in JUnit 4, you can use thebeforeAllandafterAllmethods ofBeforeAndAfterAll. See the documentation forBeforeAndAfterAllfor an example.Shared tests
Sometimes you may want to run the same test code on different fixture objects. In other words, you may want to write tests that are "shared" by different fixture objects. To accomplish this in a
FlatSpec, you first place shared tests in behavior functions. These behavior functions will be invoked during the construction phase of anyFlatSpecthat uses them, so that the tests they contain will be registered as tests in thatFlatSpec. For example, given this stack class:You may want to test the
Stackclass in different states: empty, full, with one item, with one item less than capacity, etc. You may find you have several tests that make sense any time the stack is non-empty. Thus you'd ideally want to run those same tests for three stack fixture objects: a full stack, a stack with a one item, and a stack with one item less than capacity. With shared tests, you can factor these tests out into a behavior function, into which you pass the stack fixture to use when running the tests. So in yourFlatSpecfor stack, you'd invoke the behavior function three times, passing in each of the three stack fixtures so that the shared tests are run for all three fixtures. You can define a behavior function that encapsulates these shared tests inside theFlatSpecthat uses them. If they are shared between differentFlatSpecs, however, you could also define them in a separate trait that is mixed into eachFlatSpecthat uses them.For example, here the
nonEmptyStackbehavior function (in this case, a behavior method) is defined in a trait along with another method containing shared tests for non-full stacks:trait StackBehaviors { this: FlatSpec =>def nonEmptyStack(stack: Stack[Int], lastItemAdded: Int) {
it should "be non-empty" in { assert(!stack.empty) }
it should "return the top item on peek" in { assert(stack.peek === lastItemAdded) }
it should "not remove the top item on peek" in { val size = stack.size assert(stack.peek === lastItemAdded) assert(stack.size === size) }
it should "remove the top item on pop" in { val size = stack.size assert(stack.pop === lastItemAdded) assert(stack.size === size - 1) } }
def nonFullStack(stack: Stack[Int]) {
it should "not be full" in { assert(!stack.full) }
it should "add to the top on push" in { val size = stack.size stack.push(7) assert(stack.size === size + 1) assert(stack.peek === 7) } } }
Given these behavior functions, you could invoke them directly, but
FlatSpecoffers a DSL for the purpose, which looks like this:If you prefer to use an imperative style to change fixtures, for example by mixing in
BeforeAndAfterEachand reassigning astackvarinbeforeEach, you could write your behavior functions in the context of thatvar, which means you wouldn't need to pass in the stack fixture because it would be in scope already inside the behavior function. In that case, your code would look like this:The recommended style, however, is the functional, pass-all-the-needed-values-in style. Here's an example:
class SharedTestExampleSpec extends FlatSpec with StackBehaviors {// Stack fixture creation methods def emptyStack = new Stack[Int]
def fullStack = { val stack = new Stack[Int] for (i <- 0 until stack.MAX) stack.push(i) stack }
def stackWithOneItem = { val stack = new Stack[Int] stack.push(9) stack }
def stackWithOneItemLessThanCapacity = { val stack = new Stack[Int] for (i <- 1 to 9) stack.push(i) stack }
val lastValuePushed = 9
"A Stack (when empty)" should "be empty" in { assert(emptyStack.empty) }
it should "complain on peek" in { intercept[IllegalStateException] { emptyStack.peek } }
it should "complain on pop" in { intercept[IllegalStateException] { emptyStack.pop } }
"A Stack (with one item)" should behave like nonEmptyStack(stackWithOneItem, lastValuePushed)
it should behave like nonFullStack(stackWithOneItem)
"A Stack (with one item less than capacity)" should behave like nonEmptyStack(stackWithOneItemLessThanCapacity, lastValuePushed)
it should behave like nonFullStack(stackWithOneItemLessThanCapacity)
"A Stack (full)" should "be full" in { assert(fullStack.full) }
it should behave like nonEmptyStack(fullStack, lastValuePushed)
it should "complain on a push" in { intercept[IllegalStateException] { fullStack.push(10) } } }
If you load these classes into the Scala interpreter (with scalatest's JAR file on the class path), and execute it, you'll see:
One thing to keep in mind when using shared tests is that in ScalaTest, each test in a suite must have a unique name. If you register the same tests repeatedly in the same suite, one problem you may encounter is an exception at runtime complaining that multiple tests are being registered with the same test name. A good way to solve this problem in a
WordSpecis to make sure each invocation of a behavior function is in the context of a different set ofwhen, verb (should,must, or can), andthatclauses, which will prepend a string to each test name. For example, the following code in aWordSpecwould register a test with the name"A Stack (when empty) should be empty":Or, using the shorthand notation:
"A Stack" when { "empty" should { "be empty" in { assert(emptyStack.empty) } } } // ...If the
"should be empty"test was factored out into a behavior function, it could be called repeatedly so long as each invocation of the behavior function is in the context of a different combination ofwhen, verb, andthatclauses.Tagging tests
A
FlatSpec's tests may be classified into groups by tagging them with string names. As with any suite, when executing aFlatSpec, groups of tests can optionally be included and/or excluded. To tag aFlatSpec's tests, you pass objects that extend abstract classorg.scalatest.TagtotaggedAsmethod invoked on the string that describes the test you want to tag. ClassTagtakes one parameter, a string name. If you have created Java annotation interfaces for use as group names in direct subclasses oforg.scalatest.Suite, then you will probably want to use group names on yourFlatSpecs that match. To do so, simply pass the fully qualified names of the Java interfaces to theTagconstructor. For example, if you've defined Java annotation interfaces with fully qualified names,com.mycompany.groups.SlowTestandcom.mycompany.groups.DbTest, then you could create matching groups forSpecs like this:Given these definitions, you could place
FlatSpectests into groups like this:This code marks both tests with the
com.mycompany.groups.SlowTesttag, and test"The Scala language should subtract correctly"with thecom.mycompany.groups.DbTesttag.The primary
runmethod takes aFilter, whose constructor takes an optionalSet[String]s calledtagsToIncludeand aSet[String]calledtagsToExclude. IftagsToIncludeisNone, all tests will be run except those those belonging to tags listed in thetagsToExcludeSet. IftagsToIncludeis defined, only tests belonging to tags mentioned in thetagsToIncludeset, and not mentioned intagsToExclude, will be run.Ignored tests
To support the common use case of “temporarily” disabling a test, with the good intention of resurrecting the test at a later time,
FlatSpecprovides a methodignorethat can be used instead ofitto register a test. For example, to temporarily disable the test with the name"A Stack should throw NoSuchElementException if an empty stack is popped", just change “it” into “ignore,” like this:If you run this version of
StackSpecwith:It will run only the first test and report that the second test was ignored:
When using shorthand notation, you won't have an
itto change intoignorefor the first test of each new subject. To ignore such tests, you must instead changeintoignore. For example, to temporarily disable the test with the name"A Stack should pop values in last-in-first-out order", change “in” into “ignore” like this:If you run this version of
StackSpecwith:It will run only the second test and report that the first test was ignored:
Informers
One of the parameters to the primary
runmethod is aReporter, which will collect and report information about the running suite of tests. Information about suites and tests that were run, whether tests succeeded or failed, and tests that were ignored will be passed to theReporteras the suite runs. Most often the reporting done by default byFlatSpec's methods will be sufficient, but occasionally you may wish to provide custom information to theReporterfrom a test. For this purpose, anInformerthat will forward information to the currentReporteris provided via theinfoparameterless method. You can pass the extra information to theInformervia itsapplymethod. TheInformerwill then pass the information to theReportervia anInfoProvidedevent. Here's an example:If you run this
FlatSpecfrom the interpreter, you will see the following message included in the printed report:One use case for the
Informeris to pass more information about a specification to the reporter. For example, theGivenWhenThentrait provides methods that use the implicitinfoprovided byFlatSpecto pass such information to the reporter. Here's an example:Pending tests
A pending test is one that has been given a name but is not yet implemented. The purpose of pending tests is to facilitate a style of testing in which documentation of behavior is sketched out before tests are written to verify that behavior (and often, the before the behavior of the system being tested is itself implemented). Such sketches form a kind of specification of what tests and functionality to implement later.
To support this style of testing, a test can be given a name that specifies one bit of behavior required by the system being tested. The test can also include some code that sends more information about the behavior to the reporter when the tests run. At the end of the test, it can call method
pending, which will cause it to complete abruptly withTestPendingException. Because tests in ScalaTest can be designated as pending withTestPendingException, both the test name and any information sent to the reporter when running the test can appear in the report of a test run. (In other words, the code of a pending test is executed just like any other test.) However, because the test completes abruptly withTestPendingException, the test will be reported as pending, to indicate the actual test, and possibly the functionality it is intended to test, has not yet been implemented. You can mark tests as pending inFlatSpeclike this:If you run this version of
ArithmeticSpecwith:It will run both tests but report that
The Scala language must subtract correctlyis pending. You'll see:One difference between an ignored test and a pending one is that an ignored test is intended to be used during a significant refactorings of the code under test, when tests break and you don't want to spend the time to fix all of them immediately. You can mark some of those broken tests as ignored temporarily, so that you can focus the red bar on just failing tests you actually want to fix immediately. Later you can go back and fix the ignored tests. In other words, by ignoring some failing tests temporarily, you can more easily notice failed tests that you actually want to fix. By contrast, a pending test is intended to be used before a test and/or the code under test is written. Pending indicates you've decided to write a test for a bit of behavior, but either you haven't written the test yet, or have only written part of it, or perhaps you've written the test but don't want to implement the behavior it tests until after you've implemented a different bit of behavior you realized you need first. Thus ignored tests are designed to facilitate refactoring of existing code whereas pending tests are designed to facilitate the creation of new code.
One other difference between ignored and pending tests is that ignored tests are implemented as a test tag that is excluded by default. Thus an ignored test is never executed. By contrast, a pending test is implemented as a test that throws
TestPendingException(which is what calling thependingmethod does). Thus the body of pending tests are executed up until they throwTestPendingException. The reason for this difference is that it enables your unfinished test to sendInfoProvidedmessages to the reporter before it completes abruptly withTestPendingException, as shown in the previous example onInformers that used theGivenWhenThentrait. For example, the following snippet in aFlatSpec:"The Scala language" must "add correctly" in { given("two integers") when("they are added") then("the result is the sum of the two numbers") pending } // ...Would yield the following output when run in the interpreter: