A sister class to org.scalatest.FreeSpec
that isolates tests by running each test in its own
instance of the test class, and for each test, only executing the path leading to that test.
Implementation trait for class path.FreeSpec
, which is
a sister class to org.scalatest.FreeSpec
that isolates
tests by running each test in its own instance of the test class, and
for each test, only executing the path leading to that test.
Implementation trait for class path.FreeSpec
, which is
a sister class to org.scalatest.FreeSpec
that isolates
tests by running each test in its own instance of the test class, and
for each test, only executing the path leading to that test.
path.FreeSpec
is a class, not a trait,
to minimize compile time given there is a slight compiler overhead to
mixing in traits compared to extending classes. If you need to mix the
behavior of path.FreeSpec
into some other class, you can use this
trait instead, because class path.FreeSpec
does nothing more than
extend this trait and add a nice toString
implementation.
See the documentation of the class for a detailed
overview of path.FreeSpec
.
A sister class to org.scalatest.FunSpec
that isolates tests by running each test in its own
instance of the test class, and for each test, only executing the path leading to that test.
A sister class to org.scalatest.FunSpec
that isolates tests by running each test in its own
instance of the test class, and for each test, only executing the path leading to that test.
Class path.FunSpec
behaves similarly to class org.scalatest.FunSpec
, except that tests
are isolated based on their path. The purpose of path.FunSpec
is to facilitate writing
specification-style tests for mutable objects in a clear, boilerpate-free way. To test mutable objects, you need to
mutate them. Using a path class, you can make a statement in text, then implement that statement in code (including
mutating state), and nest and combine these test/code pairs in any way you wish. Each test will only see
the side effects of code that is in blocks that enclose the test. Here's an example:
import org.scalatest.path import org.scalatest.matchers.Matchers import scala.collection.mutable.ListBuffer class ExampleSpec extends path.FunSpec with Matchers { describe("A ListBuffer") { val buf = ListBuffer.empty[Int] // This implements "A ListBuffer" it("should be empty when created") { // This test sees: // val buf = ListBuffer.empty[Int] // So buf is: ListBuffer() buf should be ('empty) } describe("when 1 is appended") { buf += 1 // This implements "when 1 is appended", etc... it("should contain 1") { // This test sees: // val buf = ListBuffer.empty[Int] // buf += 1 // So buf is: ListBuffer(1) buf.remove(0) should equal (1) buf should be ('empty) } describe("when 2 is appended") { buf += 2 it("should contain 1 and 2") { // This test sees: // val buf = ListBuffer.empty[Int] // buf += 1 // buf += 2 // So buf is: ListBuffer(1, 2) buf.remove(0) should equal (1) buf.remove(0) should equal (2) buf should be ('empty) } describe("when 2 is removed") { buf -= 2 it("should contain only 1 again") { // This test sees: // val buf = ListBuffer.empty[Int] // buf += 1 // buf += 2 // buf -= 2 // So buf is: ListBuffer(1) buf.remove(0) should equal (1) buf should be ('empty) } } describe("when 3 is appended") { buf += 3 it("should contain 1, 2, and 3") { // This test sees: // val buf = ListBuffer.empty[Int] // buf += 1 // buf += 2 // buf += 3 // So buf is: ListBuffer(1, 2, 3) buf.remove(0) should equal (1) buf.remove(0) should equal (2) buf.remove(0) should equal (3) buf should be ('empty) } } } describe("when 88 is appended") { buf += 88 it("should contain 1 and 88") { // This test sees: // val buf = ListBuffer.empty[Int] // buf += 1 // buf += 88 // So buf is: ListBuffer(1, 88) buf.remove(0) should equal (1) buf.remove(0) should equal (88) buf should be ('empty) } } } it("should have size 0 when created") { // This test sees: // val buf = ListBuffer.empty[Int] // So buf is: ListBuffer() buf should have size 0 } } }
Note that the above class is organized by writing a bit of specification text that opens a new block followed
by, at the top of the new block, some code that "implements" or "performs" what is described in the text. This is repeated as
the mutable object (here, a ListBuffer
), is prepared for the enclosed tests. For example:
describe("A ListBuffer") { val buf = ListBuffer.empty[Int]
Or:
describe("when 2 is appended") { buf += 2
Note also that although each test mutates the ListBuffer
, none of the other tests observe those
side effects:
it("should contain 1") { buf.remove(0) should equal (1) // ... } describe("when 2 is appended") { buf += 2 it("should contain 1 and 2") { // This test does not see the buf.remove(0) from the previous test, // so the first element in the ListBuffer is again 1 buf.remove(0) should equal (1) buf.remove(0) should equal (2)
This kind of isolation of tests from each other is a consequence of running each test in its own instance of the test
class, and can also be achieved by simply mixing OneInstancePerTest
into a regular
org.scalatest.FunSpec
. However, path.FunSpec
takes isolation one step further: a test
in a path.FunSpec
does not observe side effects performed outside tests in earlier blocks that do not
enclose it. Here's an example:
describe("when 2 is removed") { buf -= 2 // ... } describe("when 3 is appended") { buf += 3 it("should contain 1, 2, and 3") { // This test does not see the buf -= 2 from the earlier "when 2 is removed" block, // because that block does not enclose this test, so the second element in the // ListBuffer is still 2 buf.remove(0) should equal (1) buf.remove(0) should equal (2) buf.remove(0) should equal (3)
Running the full ExampleSpec
, shown above, in the Scala interpeter would give you:
scala> import org.scalatest._
import org.scalatest._
scala> run(new ExampleSpec)
ExampleSpec:
A ListBuffer
- should be empty when created
when 1 is appended
- should contain 1
when 2 is appended
- should contain 1 and 2
when 2 is removed
- should contain only 1 again
when 3 is appended
- should contain 1, 2, and 3
when 88 is appended
- should contain 1 and 88
- should have size 0 when created
Note: class path.FunSpec
's approach to isolation was inspired in part by the
specsy framework, written by Esko Luontola.
A test fixture is objects or other artifacts (such as files, sockets, database
connections, etc.) used by tests to do their work.
If a fixture is used by only one test, then the definitions of the fixture objects can
be local to the method. If multiple tests need to share an immutable fixture, you can simply
assign them to instance variables. If multiple tests need to share mutable fixture objects or var
s,
there's one and only one way to do it in a path.FunSpec
: place the mutable objects lexically before
the test. Any mutations needed by the test must be placed lexically before and/or after the test.
As used here, "Lexically before" means that the code needs to be executed during construction of that test's
instance of the test class to reach the test (or put another way, the
code is along the "path to the test.") "Lexically after" means that the code needs to be executed to exit the
constructor after the test has been executed.
The reason lexical placement is the one and only one way to share fixtures in a path.FunSpec
is because
all of its lifecycle methods are overridden and declared final
. Thus you can't mix in BeforeAndAfter
or
BeforeAndAfterEach
, because both override runTest
, which is final
in
a path.FunSpec
. You also can't override withFixture
, because path.FreeSpec
extends Suite
not TestSuite
,
where withFixture
is defined. In short:
In a path.FunSpec , if you need some code to execute before a test, place that code lexically before
the test. If you need some code to execute after a test, place that code lexically after the test.
|
---|
The reason the life cycle methods are final, by the way, is to prevent users from attempting to combine
a path.FunSpec
's approach to isolation with other ways ScalaTest provides to share fixtures or
execute tests, because doing so could make the resulting test code hard to reason about. A
path.FunSpec
's execution model is a bit magical, but because it executes in one and only one
way, users should be able to reason about the code.
To help you visualize how a path.FunSpec
is executed, consider the following variant of
ExampleSpec
that includes print statements:
import org.scalatest.path import org.scalatest.matchers.Matchers import scala.collection.mutable.ListBuffer class ExampleSpec extends path.FunSpec with Matchers { println("Start of: ExampleSpec") describe("A ListBuffer") { println("Start of: A ListBuffer") val buf = ListBuffer.empty[Int] it("should be empty when created") { println("In test: should be empty when created; buf is: " + buf) buf should be ('empty) } describe("when 1 is appended") { println("Start of: when 1 is appended") buf += 1 it("should contain 1") { println("In test: should contain 1; buf is: " + buf) buf.remove(0) should equal (1) buf should be ('empty) } describe("when 2 is appended") { println("Start of: when 2 is appended") buf += 2 it("should contain 1 and 2") { println("In test: should contain 1 and 2; buf is: " + buf) buf.remove(0) should equal (1) buf.remove(0) should equal (2) buf should be ('empty) } describe("when 2 is removed") { println("Start of: when 2 is removed") buf -= 2 it("should contain only 1 again") { println("In test: should contain only 1 again; buf is: " + buf) buf.remove(0) should equal (1) buf should be ('empty) } println("End of: when 2 is removed") } describe("when 3 is appended") { println("Start of: when 3 is appended") buf += 3 it("should contain 1, 2, and 3") { println("In test: should contain 1, 2, and 3; buf is: " + buf) buf.remove(0) should equal (1) buf.remove(0) should equal (2) buf.remove(0) should equal (3) buf should be ('empty) } println("End of: when 3 is appended") } println("End of: when 2 is appended") } describe("when 88 is appended") { println("Start of: when 88 is appended") buf += 88 it("should contain 1 and 88") { println("In test: should contain 1 and 88; buf is: " + buf) buf.remove(0) should equal (1) buf.remove(0) should equal (88) buf should be ('empty) } println("End of: when 88 is appended") } println("End of: when 1 is appended") } it("should have size 0 when created") { println("In test: should have size 0 when created; buf is: " + buf) buf should have size 0 } println("End of: A ListBuffer") } println("End of: ExampleSpec") println() }
Running the above version of ExampleSpec
in the Scala interpreter will give you output similar to:
scala> import org.scalatest._ import org.scalatest._ scala> run(new ExampleSpec) ExampleSpec: Start of: ExampleSpec Start of: A ListBuffer In test: should be empty when created; buf is: ListBuffer() End of: A ListBuffer End of: ExampleSpec Start of: ExampleSpec Start of: A ListBuffer Start of: when 1 is appended In test: should contain 1; buf is: ListBuffer(1) ExampleSpec: End of: when 1 is appended End of: A ListBuffer End of: ExampleSpec Start of: ExampleSpec Start of: A ListBuffer Start of: when 1 is appended Start of: when 2 is appended In test: should contain 1 and 2; buf is: ListBuffer(1, 2) End of: when 2 is appended End of: when 1 is appended End of: A ListBuffer End of: ExampleSpec Start of: ExampleSpec Start of: A ListBuffer Start of: when 1 is appended Start of: when 2 is appended Start of: when 2 is removed In test: should contain only 1 again; buf is: ListBuffer(1) End of: when 2 is removed End of: when 2 is appended End of: when 1 is appended End of: A ListBuffer End of: ExampleSpec Start of: ExampleSpec Start of: A ListBuffer Start of: when 1 is appended Start of: when 2 is appended Start of: when 3 is appended In test: should contain 1, 2, and 3; buf is: ListBuffer(1, 2, 3) End of: when 3 is appended End of: when 2 is appended End of: when 1 is appended End of: A ListBuffer End of: ExampleSpec Start of: ExampleSpec Start of: A ListBuffer Start of: when 1 is appended Start of: when 88 is appended In test: should contain 1 and 88; buf is: ListBuffer(1, 88) End of: when 88 is appended End of: when 1 is appended End of: A ListBuffer End of: ExampleSpec Start of: ExampleSpec Start of: A ListBuffer In test: should have size 0 when created; buf is: ListBuffer() End of: A ListBuffer End of: ExampleSpec A ListBuffer - should be empty when created when 1 is appended - should contain 1 when 2 is appended - should contain 1 and 2 when 2 is removed - should contain only 1 again when 3 is appended - should contain 1, 2, and 3 when 88 is appended - should contain 1 and 88 - should have size 0 when created
Note that each test is executed in order of appearance in the path.FunSpec
, and that only
those println
statements residing in blocks that enclose the test being run are executed. Any
println
statements in blocks that do not form the "path" to a test are not executed in the
instance of the class that executes that test.
To provide its special brand of test isolation, path.FunSpec
executes quite differently from its
sister class in org.scalatest
. An org.scalatest.FunSpec
registers tests during construction and executes them when run
is invoked. An
org.scalatest.path.FunSpec
, by contrast, runs each test in its own instance while that
instance is being constructed. During construction, it registers not the tests to run, but the results of
running those tests. When run
is invoked on a path.FunSpec
, it reports the registered
results and does not run the tests again. If run
is invoked a second or third time, in fact,
a path.FunSpec
will each time report the same results registered during construction. If you want
to run the tests of a path.FunSpec
anew, you'll need to create a new instance and invoke
run
on that.
A path.FunSpec
will create one instance for each "leaf" node it contains. The main kind of leaf node is
a test, such as:
// One instance will be created for each test it("should be empty when created") { buf should be ('empty) }
However, an empty scope (a scope that contains no tests or nested scopes) is also a leaf node:
// One instance will be created for each empty scope describe("when 99 is added") { // A scope is "empty" and therefore a leaf node if it has no // tests or nested scopes, though it may have other code (which // will be executed in the instance created for that leaf node) buf += 99 }
The tests will be executed sequentially, in the order of appearance. The first test (or empty scope,
if that is first) will be executed when a class that mixes in path.FunSpec
is
instantiated. Only the first test will be executed during this initial instance, and of course, only
the path to that test. Then, the first time the client uses the initial instance (by invoking one of run
,
expectedTestsCount
, tags
, or testNames
on the instance), the initial instance will,
before doing anything else, ensure that any remaining tests are executed, each in its own instance.
To ensure that the correct path is taken in each instance, and to register its test results, the initial
path.FunSpec
instance must communicate with the other instances it creates for running any subsequent
leaf nodes. It does so by setting a thread-local variable prior to creating each instance (a technique
suggested by Esko Luontola). Each instance
of path.FunSpec
checks the thread-local variable. If the thread-local is not set, it knows it
is an initial instance and therefore executes every block it encounters until it discovers, and executes the
first test (or empty scope, if that's the first leaf node). It then discovers, but does not execute the next
leaf node, or discovers there are no other leaf nodes remaining to execute. It communicates the path to the next
leaf node, if any, and the result of running the test it did execute, if any, back to the initial instance. The
initial instance repeats this process until all leaf nodes have been executed and all test results registered.
You mark a test as ignored in an org.scalatest.path.FunSpec
in the same manner as in
an org.scalatest.FunSpec
. Please see the Ignored tests section
in its documentation for more information.
Note that a separate instance will be created for an ignored test,
and the path to the ignored test will be executed in that instance, but the test function itself will not
be executed. Instead, a TestIgnored
event will be fired.
You output information using Informer
s in an org.scalatest.path.FunSpec
in the same manner
as in an org.scalatest.FunSpec
. Please see the Informers
section in its documentation for more information.
You mark a test as pending in an org.scalatest.path.FunSpec
in the same manner as in
an org.scalatest.FunSpec
. Please see the Pending tests
section in its documentation for more information.
Note that a separate instance will be created for a pending test,
and the path to the ignored test will be executed in that instance, as well as the test function (up until it
completes abruptly with a TestPendingException
).
You can place tests into groups by tagging them in an org.scalatest.path.FunSpec
in the same manner
as in an org.scalatest.FunSpec
. Please see the Tagging tests
section in its documentation for more information.
Note that one difference between this class and its sister class
org.scalatest.FunSpec
is that because tests are executed at construction time, rather than each
time run is invoked, an org.scalatest.path.FunSpec
will always execute all non-ignored tests. When
run
is invoked on a path.FunSpec
, if some tests are excluded based on tags, the registered
results of running those tests will not be reported. (But those tests will have already run and the results
registered.) By contrast, because an org.scalatest.FunSpec
only executes tests after run
has been called, and at that time the tags to include and exclude are known, only tests selected by the tags
will be executed.
In short, in an org.scalatest.FunSpec
, tests not selected by the tags to include
and exclude specified for the run (via the Filter
passed to run
) will not be executed.
In an org.scalatest.path.FunSpec
, by contrast, all non-ignored tests will be executed, each
during the construction of its own instance, and tests not selected by the tags to include and exclude specified
for a run will not be reported. (One upshot of this is that if you have tests that you want to tag as being slow so
you can sometimes exclude them during a run, you probably don't want to put them in a path.FunSpec
. Because
in a path.Freespec
the slow tests will be run regardless, with only their registered results not being reported
if you exclude slow tests during a run.)
You can factor out shared tests in an org.scalatest.path.FunSpec
in the same manner as in
an org.scalatest.FunSpec
. Please see the Shared tests
section in its documentation for more information.
Nested suites are not allowed in a path.FunSpec
. Because
a path.FunSpec
executes tests eagerly at construction time, registering the results of those test runs
and reporting them later when run
is invoked, the order of nested suites versus test runs would be
different in a org.scalatest.path.FunSpec
than in an org.scalatest.FunSpec
. In
org.scalatest.FunSpec
's implementation of run
, nested suites are executed then tests
are executed. A org.scalatest.path.FunSpec
with nested suites would execute these in the opposite
order: first tests then nested suites. To help make path.FunSpec
code easier to
reason about by giving readers of one less difference to think about, nested suites are not allowed. If you want
to add nested suites to a path.FunSpec
, you can instead wrap them all in a
Suites
object. They will
be executed in the order of appearance (unless a Distributor is passed, in which case
they will execute in parallel).
Many ScalaTest events include a duration that indicates how long the event being reported took to execute. For
example, a TestSucceeded
event provides a duration indicating how long it took for that test
to execute. A SuiteCompleted
event provides a duration indicating how long it took for that entire
suite of tests to execute.
In the test completion events fired by a path.FunSpec
(TestSucceeded
,
TestFailed
, or TestPending
), the durations reported refer
to the time it took for the tests to run. This time is registered with the test results and reported along
with the test results each time run
is invoked.
By contrast, the suite completion events fired for a path.FunSpec
represent the amount of time
it took to report the registered results. (These events are not fired by path.FunSpec
, but instead
by the entity that invokes run
on the path.FunSpec
.) As a result, the total time
for running the tests of a path.FunSpec
, calculated by summing the durations of all the individual
test completion events, may be greater than the duration reported for executing the entire suite.
Implementation trait for class path.FunSpec
, which is
a sister class to org.scalatest.FunSpec
that isolates
tests by running each test in its own instance of the test class,
and for each test, only executing the path leading to that test.
Implementation trait for class path.FunSpec
, which is
a sister class to org.scalatest.FunSpec
that isolates
tests by running each test in its own instance of the test class,
and for each test, only executing the path leading to that test.
path.FunSpec
is a class, not a trait,
to minimize compile time given there is a slight compiler overhead to
mixing in traits compared to extending classes. If you need to mix the
behavior of path.FunSpec
into some other class, you can use this
trait instead, because class path.FunSpec
does nothing more than
extend this trait and add a nice toString
implementation.
See the documentation of the class for a detailed
overview of path.FunSpec
.
A sister class to
org.scalatest.FreeSpec
that isolates tests by running each test in its own instance of the test class, and for each test, only executing the path leading to that test.Class
path.FreeSpec
behaves similarly to classorg.scalatest.FreeSpec
, except that tests are isolated based on their path. The purpose ofpath.FreeSpec
is to facilitate writing specification-style tests for mutable objects in a clear, boilerpate-free way. To test mutable objects, you need to mutate them. Using a path class, you can make a statement in text, then implement that statement in code (including mutating state), and nest and combine these test/code pairs in any way you wish. Each test will only see the side effects of code that is in blocks that enclose the test. Here's an example:Note that the above class is organized by writing a bit of specification text that opens a new block followed by, at the top of the new block, some code that "implements" or "performs" what is described in the text. This is repeated as the mutable object (here, a
ListBuffer
), is prepared for the enclosed tests. For example:Or:
Note also that although each test mutates the
ListBuffer
, none of the other tests observe those side effects:This kind of isolation of tests from each other is a consequence of running each test in its own instance of the test class, and can also be achieved by simply mixing
OneInstancePerTest
into a regularorg.scalatest.FreeSpec
. However,path.FreeSpec
takes isolation one step further: a test in apath.FreeSpec
does not observe side effects performed outside tests in earlier blocks that do not enclose it. Here's an example:Running the full
ExampleSpec
, shown above, in the Scala interpeter would give you:scala> import org.scalatest._ import org.scalatest._ scala> run(new ExampleSpec) ExampleSpec: A ListBuffer - should be empty when created when 1 is appended - should contain 1 when 2 is appended - should contain 1 and 2 when 2 is removed - should contain only 1 again when 3 is appended - should contain 1, 2, and 3 when 88 is appended - should contain 1 and 88 - should have size 0 when created
Note: class
path.FreeSpec
's approach to isolation was inspired in part by the specsy framework, written by Esko Luontola.Shared fixtures
A test fixture is objects or other artifacts (such as files, sockets, database connections, etc.) used by tests to do their work. If a fixture is used by only one test, then the definitions of the fixture objects can be local to the method. If multiple tests need to share an immutable fixture, you can simply assign them to instance variables. If multiple tests need to share mutable fixture objects or
var
s, there's one and only one way to do it in apath.FreeSpec
: place the mutable objects lexically before the test. Any mutations needed by the test must be placed lexically before and/or after the test. As used here, "Lexically before" means that the code needs to be executed during construction of that test's instance of the test class to reach the test (or put another way, the code is along the "path to the test.") "Lexically after" means that the code needs to be executed to exit the constructor after the test has been executed.The reason lexical placement is the one and only one way to share fixtures in a
path.FreeSpec
is because all of its lifecycle methods are overridden and declaredfinal
. Thus you can't mix inBeforeAndAfter
orBeforeAndAfterEach
, because both overriderunTest
, which isfinal
in apath.FreeSpec
. You also can't overridewithFixture
, becausepath.FreeSpec
extendsSuite
notTestSuite
, wherewithFixture
is defined. In short:path.FreeSpec
, if you need some code to execute before a test, place that code lexically before the test. If you need some code to execute after a test, place that code lexically after the test.The reason the life cycle methods are final, by the way, is to prevent users from attempting to combine a
path.FreeSpec
's approach to isolation with other ways ScalaTest provides to share fixtures or execute tests, because doing so could make the resulting test code hard to reason about. Apath.FreeSpec
's execution model is a bit magical, but because it executes in one and only one way, users should be able to reason about the code. To help you visualize how apath.FreeSpec
is executed, consider the following variant ofExampleSpec
that includes print statements:Running the above version of
ExampleSpec
in the Scala interpreter will give you output similar to:Note that each test is executed in order of appearance in the
path.FreeSpec
, and that only thoseprintln
statements residing in blocks that enclose the test being run are executed. Anyprintln
statements in blocks that do not form the "path" to a test are not executed in the instance of the class that executes that test.How it executes
To provide its special brand of test isolation,
path.FreeSpec
executes quite differently from its sister class inorg.scalatest
. Anorg.scalatest.FreeSpec
registers tests during construction and executes them whenrun
is invoked. Anorg.scalatest.path.FreeSpec
, by contrast, runs each test in its own instance while that instance is being constructed. During construction, it registers not the tests to run, but the results of running those tests. Whenrun
is invoked on apath.FreeSpec
, it reports the registered results and does not run the tests again. Ifrun
is invoked a second or third time, in fact, apath.FreeSpec
will each time report the same results registered during construction. If you want to run the tests of apath.FreeSpec
anew, you'll need to create a new instance and invokerun
on that.A
path.FreeSpec
will create one instance for each "leaf" node it contains. The main kind of leaf node is a test, such as:However, an empty scope (a scope that contains no tests or nested scopes) is also a leaf node:
The tests will be executed sequentially, in the order of appearance. The first test (or empty scope, if that is first) will be executed when a class that mixes in
path.FreeSpec
is instantiated. Only the first test will be executed during this initial instance, and of course, only the path to that test. Then, the first time the client uses the initial instance (by invoking one ofrun
,expectedTestsCount
,tags
, ortestNames
on the instance), the initial instance will, before doing anything else, ensure that any remaining tests are executed, each in its own instance.To ensure that the correct path is taken in each instance, and to register its test results, the initial
path.FreeSpec
instance must communicate with the other instances it creates for running any subsequent leaf nodes. It does so by setting a thread-local variable prior to creating each instance (a technique suggested by Esko Luontola). Each instance ofpath.FreeSpec
checks the thread-local variable. If the thread-local is not set, it knows it is an initial instance and therefore executes every block it encounters until it discovers, and executes the first test (or empty scope, if that's the first leaf node). It then discovers, but does not execute the next leaf node, or discovers there are no other leaf nodes remaining to execute. It communicates the path to the next leaf node, if any, and the result of running the test it did execute, if any, back to the initial instance. The initial instance repeats this process until all leaf nodes have been executed and all test results registered.Ignored tests
You mark a test as ignored in an
org.scalatest.path.FreeSpec
in the same manner as in anorg.scalatest.FreeSpec
. Please see the Ignored tests section in its documentation for more information.Note that a separate instance will be created for an ignored test, and the path to the ignored test will be executed in that instance, but the test function itself will not be executed. Instead, a
TestIgnored
event will be fired.Informers
You output information using
Informer
s in anorg.scalatest.path.FreeSpec
in the same manner as in anorg.scalatest.FreeSpec
. Please see the Informers section in its documentation for more information.Pending tests
You mark a test as pending in an
org.scalatest.path.FreeSpec
in the same manner as in anorg.scalatest.FreeSpec
. Please see the Pending tests section in its documentation for more information.Note that a separate instance will be created for a pending test, and the path to the ignored test will be executed in that instance, as well as the test function (up until it completes abruptly with a
TestPendingException
).Tagging tests
You can place tests into groups by tagging them in an
org.scalatest.path.FreeSpec
in the same manner as in anorg.scalatest.FreeSpec
. Please see the Tagging tests section in its documentation for more information.Note that one difference between this class and its sister class
org.scalatest.FreeSpec
is that because tests are executed at construction time, rather than each time run is invoked, anorg.scalatest.path.FreeSpec
will always execute all non-ignored tests. Whenrun
is invoked on apath.FreeSpec
, if some tests are excluded based on tags, the registered results of running those tests will not be reported. (But those tests will have already run and the results registered.) By contrast, because anorg.scalatest.FreeSpec
only executes tests afterrun
has been called, and at that time the tags to include and exclude are known, only tests selected by the tags will be executed.In short, in an
org.scalatest.FreeSpec
, tests not selected by the tags to include and exclude specified for the run (via theFilter
passed torun
) will not be executed. In anorg.scalatest.path.FreeSpec
, by contrast, all non-ignored tests will be executed, each during the construction of its own instance, and tests not selected by the tags to include and exclude specified for a run will not be reported. (One upshot of this is that if you have tests that you want to tag as being slow so you can sometimes exclude them during a run, you probably don't want to put them in apath.FreeSpec
. Because in apath.Freespec
the slow tests will be run regardless, with only their registered results not being reported if you exclude slow tests during a run.)Shared tests
You can factor out shared tests in an
org.scalatest.path.FreeSpec
in the same manner as in anorg.scalatest.FreeSpec
. Please see the Shared tests section in its documentation for more information.Nested suites
Nested suites are not allowed in a
path.FreeSpec
. Because apath.FreeSpec
executes tests eagerly at construction time, registering the results of those test runs and reporting them later whenrun
is invoked, the order of nested suites versus test runs would be different in aorg.scalatest.path.FreeSpec
than in anorg.scalatest.FreeSpec
. Inorg.scalatest.FreeSpec
's implementation ofrun
, nested suites are executed then tests are executed. Aorg.scalatest.path.FreeSpec
with nested suites would execute these in the opposite order: first tests then nested suites. To help makepath.FreeSpec
code easier to reason about by giving readers of one less difference to think about, nested suites are not allowed. If you want to add nested suites to apath.FreeSpec
, you can instead wrap them all in aSuites
object. They will be executed in the order of appearance (unless a Distributor is passed, in which case they will execute in parallel).Durations
Many ScalaTest events include a duration that indicates how long the event being reported took to execute. For example, a
TestSucceeded
event provides a duration indicating how long it took for that test to execute. ASuiteCompleted
event provides a duration indicating how long it took for that entire suite of tests to execute.In the test completion events fired by a
path.FreeSpec
(TestSucceeded
,TestFailed
, orTestPending
), the durations reported refer to the time it took for the tests to run. This time is registered with the test results and reported along with the test results each timerun
is invoked. By contrast, the suite completion events fired for apath.FreeSpec
represent the amount of time it took to report the registered results. (These events are not fired bypath.FreeSpec
, but instead by the entity that invokesrun
on thepath.FreeSpec
.) As a result, the total time for running the tests of apath.FreeSpec
, calculated by summing the durations of all the individual test completion events, may be greater than the duration reported for executing the entire suite.