include test in source file java - java

I Want to write my unit test in the same source file being tested (like you can do in D http://dlang.org/unittest.html).
I also want to be able to run the test in eclipse as i usually do with a dedicated test file.
In this example Junit complains if there is no public zero argument constructor:
public class Dummy {
private String _name;
public Dummy(String name) {
_name = name;
}
public String name () {
return _name;
}
#Test
public void testName() throws Exception {
assertEquals("dummy", new Dummy("dummy").name());
}
}
Any suggestions on how to put the test method in the "real" source code and be able to run the test (in other words how to fool the no arg constructor restriction)?
Thanks

You could consider classical TDD (based on Kent Beck's book "Test Driven Development By Example"), where the idea is not to write tests for specific classes/methods, but rather for features that you want to implement.
That way, it really doesn't make sense to put tests in production classes.

To run the JUnit Test framework, it internally requires a zero argument constructor to instantiate it. Generally it creates by default, if you don't have any constructor. But since you have one constructor with argument, the framework will not be able to instantiate the respective class to execute the test case. To avoid it create a blank no argument constructor.

Having test methods in the same class is not possible with JUnit and is also a quite strange design choice. Well, it would be possible if you had a zero argument constructor, but still, a test class is not meant to be the class that is tested. However, you can create a test class in the same file to carry out your test cases.

You can create a second constructor without parameters if you really want to put your JUnit tests inside the same class. Nevertheless this is not the way you do it according to the java conventions.
Also it bloats the class with unnecessary test cases (unnecessary for the actual task the class should do). You should maybe think about it if it would not be better to put the test cases in a separate class.

You can write your own Runner instead of using JUnit's default BlockJUnit4ClassRunner. Please let me know if you need help.

Related

How to write jUnit test case for method with private variable [duplicate]

How do I use JUnit to test a class that has internal private methods, fields or nested classes?
It seems bad to change the access modifier for a method just to be able to run a test.
If you have somewhat of a legacy Java application, and you're not allowed to change the visibility of your methods, the best way to test private methods is to use reflection.
Internally we're using helpers to get/set private and private static variables as well as invoke private and private static methods. The following patterns will let you do pretty much anything related to the private methods and fields. Of course, you can't change private static final variables through reflection.
Method method = TargetClass.getDeclaredMethod(methodName, argClasses);
method.setAccessible(true);
return method.invoke(targetObject, argObjects);
And for fields:
Field field = TargetClass.getDeclaredField(fieldName);
field.setAccessible(true);
field.set(object, value);
Notes:
TargetClass.getDeclaredMethod(methodName, argClasses) lets you look into private methods. The same thing applies for
getDeclaredField.
The setAccessible(true) is required to play around with privates.
The best way to test a private method is via another public method. If this cannot be done, then one of the following conditions is true:
The private method is dead code
There is a design smell near the class that you are testing
The method that you are trying to test should not be private
When I have private methods in a class that are sufficiently complicated that I feel the need to test the private methods directly, that is a code smell: my class is too complicated.
My usual approach to addressing such issues is to tease out a new class that contains the interesting bits. Often, this method and the fields it interacts with, and maybe another method or two can be extracted in to a new class.
The new class exposes these methods as 'public', so they're accessible for unit testing. The new and old classes are now both simpler than the original class, which is great for me (I need to keep things simple, or I get lost!).
Note that I'm not suggesting that people create classes without using their brain! The point here is to use the forces of unit testing to help you find good new classes.
I have used reflection to do this for Java in the past, and in my opinion it was a big mistake.
Strictly speaking, you should not be writing unit tests that directly test private methods. What you should be testing is the public contract that the class has with other objects; you should never directly test an object's internals. If another developer wants to make a small internal change to the class, which doesn't affect the classes public contract, he/she then has to modify your reflection based test to ensure that it works. If you do this repeatedly throughout a project, unit tests then stop being a useful measurement of code health, and start to become a hindrance to development, and an annoyance to the development team.
What I recommend doing instead is using a code coverage tool, such as Cobertura, to ensure that the unit tests you write provide decent coverage of the code in private methods. That way, you indirectly test what the private methods are doing, and maintain a higher level of agility.
From this article: Testing Private Methods with JUnit and SuiteRunner (Bill Venners), you basically have 4 options:
Don't test private methods.
Give the methods package access.
Use a nested test class.
Use reflection.
Generally a unit test is intended to exercise the public interface of a class or unit. Therefore, private methods are implementation detail that you would not expect to test explicitly.
Just two examples of where I would want to test a private method:
Decryption routines - I would not
want to make them visible to anyone to see just for
the sake of testing, else anyone can
use them to decrypt. But they are
intrinsic to the code, complicated,
and need to always work (the obvious exception is reflection which can be used to view even private methods in most cases, when SecurityManager is not configured to prevent this).
Creating an SDK for community
consumption. Here public takes on a
wholly different meaning, since this
is code that the whole world may see
(not just internal to my application). I put
code into private methods if I don't
want the SDK users to see it - I
don't see this as code smell, merely
as how SDK programming works. But of
course I still need to test my
private methods, and they are where
the functionality of my SDK actually
lives.
I understand the idea of only testing the "contract". But I don't see one can advocate actually not testing code—your mileage may vary.
So my trade-off involves complicating the JUnit tests with reflection, rather than compromising my security and SDK.
The private methods are called by a public method, so the inputs to your public methods should also test private methods that are called by those public methods. When a public method fails, then that could be a failure in the private method.
In the Spring Framework you can test private methods using this method:
ReflectionTestUtils.invokeMethod()
For example:
ReflectionTestUtils.invokeMethod(TestClazz, "createTest", "input data");
Another approach I have used is to change a private method to package private or protected then complement it with the #VisibleForTesting annotation of the Google Guava library.
This will tell anybody using this method to take caution and not access it directly even in a package. Also a test class need not be in same package physically, but in the same package under the test folder.
For example, if a method to be tested is in src/main/java/mypackage/MyClass.java then your test call should be placed in src/test/java/mypackage/MyClassTest.java. That way, you got access to the test method in your test class.
To test legacy code with large and quirky classes, it is often very helpful to be able to test the one private (or public) method I'm writing right now.
I use the junitx.util.PrivateAccessor-package for Java. It has lots of helpful one-liners for accessing private methods and private fields.
import junitx.util.PrivateAccessor;
PrivateAccessor.setField(myObjectReference, "myCrucialButHardToReachPrivateField", myNewValue);
PrivateAccessor.invoke(myObjectReference, "privateMethodName", java.lang.Class[] parameterTypes, java.lang.Object[] args);
Having tried Cem Catikkas' solution using reflection for Java, I'd have to say his was a more elegant solution than I have described here. However, if you're looking for an alternative to using reflection, and have access to the source you're testing, this will still be an option.
There is possible merit in testing private methods of a class, particularly with test-driven development, where you would like to design small tests before you write any code.
Creating a test with access to private members and methods can test areas of code which are difficult to target specifically with access only to public methods. If a public method has several steps involved, it can consist of several private methods, which can then be tested individually.
Advantages:
Can test to a finer granularity
Disadvantages:
Test code must reside in the same
file as source code, which can be
more difficult to maintain
Similarly with .class output files, they must remain within the same package as declared in source code
However, if continuous testing requires this method, it may be a signal that the private methods should be extracted, which could be tested in the traditional, public way.
Here is a convoluted example of how this would work:
// Import statements and package declarations
public class ClassToTest
{
private int decrement(int toDecrement) {
toDecrement--;
return toDecrement;
}
// Constructor and the rest of the class
public static class StaticInnerTest extends TestCase
{
public StaticInnerTest(){
super();
}
public void testDecrement(){
int number = 10;
ClassToTest toTest= new ClassToTest();
int decremented = toTest.decrement(number);
assertEquals(9, decremented);
}
public static void main(String[] args) {
junit.textui.TestRunner.run(StaticInnerTest.class);
}
}
}
The inner class would be compiled to ClassToTest$StaticInnerTest.
See also: Java Tip 106: Static inner classes for fun and profit
As others have said... don't test private methods directly. Here are a few thoughts:
Keep all methods small and focused (easy to test, easy to find what is wrong)
Use code coverage tools. I like Cobertura (oh happy day, it looks like a new version is out!)
Run the code coverage on the unit tests. If you see that methods are not fully tested add to the tests to get the coverage up. Aim for 100% code coverage, but realize that you probably won't get it.
If using Spring, ReflectionTestUtils provides some handy tools that help out here with minimal effort. For example, to set up a mock on a private member without being forced to add an undesirable public setter:
ReflectionTestUtils.setField(theClass, "theUnsettableField", theMockObject);
Private methods are consumed by public ones. Otherwise, they're dead code. That's why you test the public method, asserting the expected results of the public method and thereby, the private methods it consumes.
Testing private methods should be tested by debugging before running your unit tests on public methods.
They may also be debugged using test-driven development, debugging your unit tests until all your assertions are met.
I personally believe it is better to create classes using TDD; creating the public method stubs, then generating unit tests with all the assertions defined in advance, so the expected outcome of the method is determined before you code it. This way, you don't go down the wrong path of making the unit test assertions fit the results. Your class is then robust and meets requirements when all your unit tests pass.
If you're trying to test existing code that you're reluctant or unable to change, reflection is a good choice.
If the class's design is still flexible, and you've got a complicated private method that you'd like to test separately, I suggest you pull it out into a separate class and test that class separately. This doesn't have to change the public interface of the original class; it can internally create an instance of the helper class and call the helper method.
If you want to test difficult error conditions coming from the helper method, you can go a step further. Extract an interface from the helper class, add a public getter and setter to the original class to inject the helper class (used through its interface), and then inject a mock version of the helper class into the original class to test how the original class responds to exceptions from the helper. This approach is also helpful if you want to test the original class without also testing the helper class.
Testing private methods breaks the encapsulation of your class because every time you change the internal implementation you break client code (in this case, the tests).
So don't test private methods.
The answer from JUnit.org FAQ page:
But if you must...
If you are using JDK 1.3 or higher, you can use reflection to subvert
the access control mechanism with the aid of the PrivilegedAccessor.
For details on how to use it, read this article.
If you are using JDK 1.6 or higher and you annotate your tests with
#Test, you can use Dp4j to inject reflection in your test methods. For
details on how to use it, see this test script.
P.S. I'm the main contributor to Dp4j. Ask me if you need help. :)
If you want to test private methods of a legacy application where you can't change the code, one option for Java is jMockit, which will allow you to create mocks to an object even when they're private to the class.
PowerMockito is made for this.
Use a Maven dependency:
<dependency>
<groupId>org.powermock</groupId>
<artifactId>powermock-core</artifactId>
<version>2.0.7</version>
<scope>test</scope>
</dependency>
Then you can do
import org.powermock.reflect.Whitebox;
...
MyClass sut = new MyClass();
SomeType rval = Whitebox.invokeMethod(sut, "myPrivateMethod", params, moreParams);
I tend not to test private methods. There lies madness. Personally, I believe you should only test your publicly exposed interfaces (and that includes protected and internal methods).
If you're using JUnit, have a look at junit-addons. It has the ability to ignore the Java security model and access private methods and attributes.
Here is my generic function to test private fields:
protected <F> F getPrivateField(String fieldName, Object obj)
throws NoSuchFieldException, IllegalAccessException {
Field field =
obj.getClass().getDeclaredField(fieldName);
field.setAccessible(true);
return (F)field.get(obj);
}
Please see below for an example;
The following import statement should be added:
import org.powermock.reflect.Whitebox;
Now you can directly pass the object which has the private method, method name to be called, and additional parameters as below.
Whitebox.invokeMethod(obj, "privateMethod", "param1");
I would suggest you refactoring your code a little bit. When you have to start thinking about using reflection or other kind of stuff, for just testing your code, something is going wrong with your code.
You mentioned different types of problems. Let's start with private fields. In case of private fields I would have added a new constructor and injected fields into that. Instead of this:
public class ClassToTest {
private final String first = "first";
private final List<String> second = new ArrayList<>();
...
}
I'd have used this:
public class ClassToTest {
private final String first;
private final List<String> second;
public ClassToTest() {
this("first", new ArrayList<>());
}
public ClassToTest(final String first, final List<String> second) {
this.first = first;
this.second = second;
}
...
}
This won't be a problem even with some legacy code. Old code will be using an empty constructor, and if you ask me, refactored code will look cleaner, and you'll be able to inject necessary values in test without reflection.
Now about private methods. In my personal experience when you have to stub a private method for testing, then that method has nothing to do in that class. A common pattern, in that case, would be to wrap it within an interface, like Callable and then you pass in that interface also in the constructor (with that multiple constructor trick):
public ClassToTest() {
this(...);
}
public ClassToTest(final Callable<T> privateMethodLogic) {
this.privateMethodLogic = privateMethodLogic;
}
Mostly all that I wrote looks like it's a dependency injection pattern. In my personal experience it's really useful while testing, and I think that this kind of code is cleaner and will be easier to maintain. I'd say the same about nested classes. If a nested class contains heavy logic it would be better if you'd moved it as a package private class and have injected it into a class needing it.
There are also several other design patterns which I have used while refactoring and maintaining legacy code, but it all depends on cases of your code to test. Using reflection mostly is not a problem, but when you have an enterprise application which is heavily tested and tests are run before every deployment everything gets really slow (it's just annoying and I don't like that kind of stuff).
There is also setter injection, but I wouldn't recommended using it. I'd better stick with a constructor and initialize everything when it's really necessary, leaving the possibility for injecting necessary dependencies.
A private method is only to be accessed within the same class. So there is no way to test a “private” method of a target class from any test class. A way out is that you can perform unit testing manually or can change your method from “private” to “protected”.
And then a protected method can only be accessed within the same package where the class is defined. So, testing a protected method of a target class means we need to define your test class in the same package as the target class.
If all the above does not suits your requirement, use the reflection way to access the private method.
As many above have suggested, a good way is to test them via your public interfaces.
If you do this, it's a good idea to use a code coverage tool (like EMMA) to see if your private methods are in fact being executed from your tests.
Today, I pushed a Java library to help testing private methods and fields. It has been designed with Android in mind, but it can really be used for any Java project.
If you got some code with private methods or fields or constructors, you can use BoundBox. It does exactly what you are looking for.
Here below is an example of a test that accesses two private fields of an Android activity to test it:
#UiThreadTest
public void testCompute() {
// Given
boundBoxOfMainActivity = new BoundBoxOfMainActivity(getActivity());
// When
boundBoxOfMainActivity.boundBox_getButtonMain().performClick();
// Then
assertEquals("42", boundBoxOfMainActivity.boundBox_getTextViewMain().getText());
}
BoundBox makes it easy to test private/protected fields, methods and constructors. You can even access stuff that is hidden by inheritance. Indeed, BoundBox breaks encapsulation. It will give you access to all that through reflection, but everything is checked at compile time.
It is ideal for testing some legacy code. Use it carefully. ;)
First, I'll throw this question out: Why do your private members need isolated testing? Are they that complex, providing such complicated behaviors as to require testing apart from the public surface? It's unit testing, not 'line-of-code' testing. Don't sweat the small stuff.
If they are that big, big enough that these private members are each a 'unit' large in complexity—consider refactoring such private members out of this class.
If refactoring is inappropriate or infeasible, can you use the strategy pattern to replace access to these private member functions / member classes when under unit test? Under unit test, the strategy would provide added validation, but in release builds it would be simple passthrough.
I want to share a rule I have about testing which particularly is related to this topic:
I think that you should never adapt production code in order to
indulge easer writing of tests.
There are a few suggestions in other posts saying you should adapt the original class in order to test a private method - please red this warning first.
If we change the accessibility of a method/field to package private or protected, just in order to have it accessible to tests, then we defeat the purpose of existence of private access directive.
Why should we have private fields/methods/classes at all when we want to have test-driven development? Should we declare everything as package private, or even public then, so we can test without any effort?—I don't think so.
From another point of view: Tests should not burden performance and execution of the production application.
If we change production code just for the sake of easier testing, that may burden performance and the execution of the application in some way.
If someone starts to change private access to package private, then a developer may eventually come up to other "ingenious ideas" about adding even more code to the original class. This would make additional noise to readability and can burden the performance of the application.
With changing of a private access to some less restrictive, we are opening the possibility to a developer for misusing the new situation in the future development of the application. Instead of enforcing him/her to develop in the proper way, we are tempting him/her with new possibilities and giving him ability to make wrong choices in the future.
Of course there might be a few exceptions to this rule, but with clear understanding, what is the rule and what is the exception? We need to be absolutely sure we know why that kind of exception is introduced.

How to check if there are any invocations of a method in the code base

Let's say I have a class Foo and a method evilMethod:
class Foo {
public void evilMethod() {
// do sth
}
}
Is there a way to write a test that would fail any time there is any invocation of this method in any class on the classpath? I mean, not when the method is invoked at runtime, but when it's declared in the code.
For example, the precense of this code in any class on the classpath should make the test fail:
if(false) {
Foo f = new Foo();
f.evilMethod(); // test fails because of that
}
What I want to achieve: I would like to annotate methods that should not be called in certain project, but need to be placed there for the use in another, and then write a test that makes sure annotated methods are not invoked anywhere indeed.
I don't know if it is fixes your problem but FindBugs does a static code analysis for Java projects. Maybe you can define a rule there that covers your issue...
Despite you asking for it not to be tested at runtime (unless you just meant in production), personally I'd want to include the check as part of a unit test. Using Mockito it would look like this:
verify(mockFoo, never()).evilMethod();
Based on the answer:
https://stackoverflow.com/a/12863072/575766
If you're project code coverage is good, that should resolve the issue for you.

What's the best way to unit test classes that delegate the work to others?

I have a question about how best to tackle JUnit testing of a top level class. Imagine I have a class, SomeWriter, that has a method that reformats a String and writes it to a stream. The method doesn't actually do the work but instead delegates it to a member object that actually does the real work. I've summarised this in the class below.
public class SomeWriter {
public void writeReformattedDataToStream(OutputStream outStream, String message) {
myReformatter.DoTheActualWorkAndWriteDataToStream(outStream, message);
}
}
Now in this hypothetical example, I've already written my unit tests for the myReformatter class and I've demonstrated that myReformatter works. My question is, how should I tackle the unit testing of the writeReformattedDataToStream in SomeWriter?
If I were black box testing, I would need to write the same test as I applied to the myReformatter class because I wouldn't know how it implements the task. However, unit testing is really white box testing, so is it valid for the test merely to ensure that myReformatter is being correctly called?
The bottom line is should my test of writeReformattedDataToStream effectively repeat the test of myReformatter, or mock myReformatter and just check it's being called correctly?
I appreciated this is similar to JUnit Test - Class invokes methods in other class
Immediate delegation like this usually falls under the heading of "too simple to test", but if you have some absolute requirement for it, then you need to mock your OutputStream (using EasyMock or a similar tool) and myReformatter and verify that the delegate calls the appropriate method.
As chrylis says, you should not test this method.
There is actually nothing to test.
If you write a test case that tests that the delegate / service is called, then your test is bound to the implementation of the tested method.
So any change in the implementation of the method would require to change the test; and I am sure that you do not want that.
Try injection. For testing purposes you could inject your own implementation of the myReformater class that simply checks that the method was called correctly and returns. Then you are testing your test class in isolation.

Junit testing for following scenario

Consider the following class
public class Validator {
boolean startValiadation(UserBean user){
//This method is visible inside this package only
return validateUser(user);
}
private static boolean validateUser(UserBean user){
//This method is visible inside this class only
boolean result=false;
//validations here
return result;
}
}
Due to security requirement of above method I did code in above way. Now I want to wrote test cases using Junit. But generally a unit test is intended to exercise the public interface of a class or unit. Still I can use reflection to do some thing what I am expecting here. But I want to know is there any other way to achieve my goal?
But generally a unit test is intended to exercise the public interface of a class or unit.
Well, I don't get too dogmatic about that. I find that often you can get much better testing depth if you're willing to be "white box" about it, and test non-public members. There's a sliding scale though - testing private members directly is relatively ugly, but you can test package private methods easily, just by making sure your test is in the same package as the class.
(This approach also encourages package private classes - I find that if you're rigidly sticking to testing just the public API, you often end up getting into the habit of making all classes public and many methods public when actually they should be package private.)
In this case, I would suggest you test via the startValiadation method. Currently that calls validateUser but ignores the result - I would assume that in the real code it calls the method and does something useful with the result, which would be visible from the test. In that case, you can just call startValiadation with various different User objects and assert which ones should be valid.
You don't need reflection. Just put your test class in the same package as this class. It doesn't need to be in the same folder or the same project to do that.
No you have only three choices to test a private method:
If you are in control of the code, then change the access specifier to public just to test the method
Otherwise use reflection.
This may be of your interest:
3 . Use a public method to test your private method.
Don't test this class in isolation. A unit test, at least in the spirit of TDD as envisioned by Kent Beck, is not a test for a single class or method, but is simply a test that cannot have side effects on other tests.
This Validator class is used in other classes within the same package. First write a failing test using the public interface of those classes, then make it pass by implementing the validation. No reflection needed.
If you would test this class in isolation, you would probably mock this class in the other classes and verify that startValiadation() is really called. This has the disadvantage of coupling your test code to your implementation code. I would say: don't do that.
I recently wrote a post about this, at the bottom there's a link to a presentation by Ian Cooper that goes deeper into this.

How to write a UT to mock an internal object in one method?

For example , I have a java class as below. I am going to write a unit test for doWork(), so I would like to control obj's behavior. But it is obvious that obj is instantiated internally.
How can I write this UT? Now I am using Junit+Mockito.
class ToBeTest{
public ToBeTest(){}
public boolean doWork(){
OtherObject obj=new OtherObject();
return obj.work();
}
}
Thanks in advance. :)
BTW, The reality is I am writing UT for other person's class. So I don't want to change it. It has been fully tested by integration test.
If you can't change the code, you can use Powermock along with junit and Mockito to mock the construction of new objects.
#Test
public void testDoWork() throws Exception{
MyTest mytest = new MyTest();
OtherObj obj = new OtherObj();
obj.test="mocked Test"; //here you can add any other needed values to obj
PowerMockito.whenNew(OtherObj.class).withNoArguments().thenReturn(obj);
String result = mytest.doWork();
Assert.assertTrue(result.equalsIgnoreCase("mocked Test"));
}
The best way is to write code to support testing (Test-Driven Development is emphasizing this). At the moment, your code is written in the way which makes it difficult to test.
Please consider using dependency injection, because it helps you mock the dependent object.
This is a classical example where you should use dependency injection.
In short, instead of creating the object (dependency) internally, you pass it in the constructor or use a factory to create what you want (the factory returns the real implementation in production code and another in test). This gives you the possibility to change the implementation when you test.
Look at the examples following the like I provided or google for "Java dependency injection example".
You can't easily. I can think of two ways you can do this and neither are supported out of the box by Mockito or jUnit as far as I'm aware:
1) Byte code manipulation using cglib or similar library which would be moderately difficult to do and likely pretty fragile.
2) Alternate classloader. You can build a classloader that looks for an attempt to load the OtherObject class and replaces it with an anonymous OtherObject class that gives you the mocking behavior that you are looking for.
Most of the time you should be treating it as a dependency though. If you want to test opening a file, you probably actually want to test with a file so using the concrete class is probably fine. If you want to test a method's behavior that has opening a file as a part of it's logic, you could easily move that out to a dependency and then mock it out. In fact, that usually makes sense because what you store in a file one day, may need to be stored in a database another or be pulled down from the cloud on a third day, so segregating the logic around what you do with the file from the actual process of opening a retrieving the contents is often a logical separation of concerns anyway.
It's very easy:
import org.junit.*;
import mockit.*;
#Test
public void justMockIt()
{
new NonStrictExpectations() { OtherObject o; { o.work(); result = true; }};
assert new ToBeTest().doWork();
}
... when using JMockit.
You have written your code, and now you want to unit test it. This is the fundamental cause of your difficulty. I suggest a different approach.
Express what the doWork() method is meant to do in terms of behaviour that can be observed only through public and protected (getter) methods of the ToBeTest class, or the public and protected methods of any objectys associated-with ToBeTest objects. Take a look at the Javadoc provided with the Java library: that describes what all those classes do without stating the bodies of the methods. When does yor method return true? When does it return false? What side effects does it have? You might find you need to add some getter methods to do this. You could express these in the Javadoc for your own code.
Use the required behaviour to decide what kinds of assertions you can place in your unit-tests.

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