I have a Java class. How can I unit test it?

In my case, I have class does a binary sum. It takes two byte[] arrays, sums them, and returns a new binary array.

  • 7
    You can utilize a tool like jUnit and write test cases (test methods) for your java class. Then invoke the jUnit tests as part of the build process (ant/maven). Using jUnit is not hard at all, the tough part is coming up with as many test scenarios you can think of so that you catch the bugs early and often.
    – CoolBeans
    Commented Jan 5, 2012 at 23:46
  • Please mention "in Java" in the title (now I cannot do that, the edit queue is full) Commented Mar 30, 2023 at 16:15

5 Answers 5


I provide this post for both IntelliJ and Eclipse.


For making unit test for your project, please follow these steps (I am using Eclipse in order to write this test):

1- Click on New -> Java Project.

Create Project

2- Write down your project name and click on finish.

Create Project

3- Right click on your project. Then, click on New -> Class.

Create Class

4- Write down your class name and click on finish.

Create Class

Then, complete the class like this:

public class Math {
    int a, b;
    Math(int a, int b) {
        this.a = a;
        this.b = b;
    public int add() {
        return a + b;

5- Click on File -> New -> JUnit Test Case.

Create JUnite Test

6- Check setUp() and click on finish. SetUp() will be the place that you initialize your test.

Check SetUp()

7- Click on OK.

Add JUnit

8- Here, I simply add 7 and 10. So, I expect the answer to be 17. Complete your test class like this:

import org.junit.Assert;
import org.junit.Before;
import org.junit.Test;
public class MathTest {
    Math math;
    public void setUp() throws Exception {
        math = new Math(7, 10);
    public void testAdd() {
        Assert.assertEquals(17, math.add());

9- Write click on your test class in package explorer and click on Run as -> JUnit Test.

Run JUnit Test

10- This is the result of the test.

Result of The Test

IntelliJ: Note that I used IntelliJ IDEA community 2020.1 for the screenshots. Also, you need to set up your jre before these steps. I am using JDK 11.0.4.

1- Right-click on the main folder of your project-> new -> directory. You should call this 'test'. enter image description here 2- Right-click on the test folder and create the proper package. I suggest creating the same packaging names as the original class. Then, you right-click on the test directory -> mark directory as -> test sources root. enter image description here 3- In the right package in the test directory, you need to create a Java class (I suggest to use Test.java). enter image description here 4- In the created class, type '@Test'. Then, among the options that IntelliJ gives you, select Add 'JUnitx' to classpath. enter image description here enter image description here 5- Write your test method in your test class. The method signature is like:

public void test<name of original method>(){

You can do your assertions like below:

Assertions.assertTrue(f.flipEquiv(node1_1, node2_1));

These are the imports that I added:

import org.junit.jupiter.api.Assertions;
import org.junit.jupiter.api.Test;

enter image description here

This is the test that I wrote: enter image description here

You can check your methods like below:


For running your unit tests, right-click on the test and click on Run . enter image description here

If your test passes, the result will be like below: enter image description here

  1. Define the expected and desired output for a normal case, with correct input.

  2. Now, implement the test by declaring a class, name it anything (Usually something like TestAddingModule), and add the testAdd method to it (i.e. like the one below) :

    • Write a method, and above it add the @Test annotation.
    • In the method, run your binary sum and assertEquals(expectedVal,calculatedVal).
    • Test your method by running it (in Eclipse, right click, select Run as → JUnit test).

      //for normal addition 
      public void testAdd1Plus1() 
          int x  = 1 ; int y = 1;
          assertEquals(2, myClass.add(x,y));
  3. Add other cases as desired.

    • Test that your binary sum does not throw a unexpected exception if there is an integer overflow.
    • Test that your method handles Null inputs gracefully (example below).

      //if you are using 0 as default for null, make sure your class works in that case.
      public void testAdd1Plus1() 
          int y = 1;
          assertEquals(0, myClass.add(null,y));
  • 1. is the @Test notation required? 2. why not test for null input with with assertNotNull? 3. where are the results of the unit tests captured? how are the results indicated to the user?
    – user137717
    Commented Oct 12, 2014 at 3:06
  • 10
    Yes, @Test notation is required. This is done to signal the unit test runner that this method represents a unit test and should be executed. Methods that are not annotated with @Test are not executed by the test runner. Commented Oct 23, 2014 at 11:14
  • for the second test - shouldn't adding a null to y just give you y?
    – Adjit
    Commented Apr 27, 2018 at 11:49
  • Thanks! I wanna know why there is no need to add static to the modifier of the test method. Commented May 13, 2018 at 2:49

This is a very generic question and there is a lot of ways it can be answered.

If you want to use JUnit to create the tests, you need to create your testcase class, then create individual test methods that test specific functionality of your class/module under tests (single testcase classes are usually associated with a single "production" class that is being tested) and inside these methods execute various operations and compare the results with what would be correct. It is especially important to try and cover as many corner cases as possible.

In your specific example, you could for example test the following:

  1. A simple addition between two positive numbers. Add them, then verify the result is what you would expect.
  2. An addition between a positive and a negative number (which returns a result with the sign of the first argument).
  3. An addition between a positive and a negative number (which returns a result with the sign of the second argument).
  4. An addition between two negative numbers.
  5. An addition that results in an overflow.

To verify the results, you can use various assertXXX methods from the org.junit.Assert class (for convenience, you can do 'import static org.junit.Assert.*'). These methods test a particular condition and fail the test if it does not validate (with a specific message, optionally).

Example testcase class in your case (without the methods contents defined):

import static org.junit.Assert.*;

public class AdditionTests {
    public void testSimpleAddition() { ... }

    public void testPositiveNegativeAddition() { ... }

    public void testNegativePositiveAddition() { ... }

    public void testNegativeAddition() { ... }

    public void testOverflow() { ... }

If you are not used to writing unit tests but instead test your code by writing ad-hoc tests that you then validate "visually" (for example, you write a simple main method that accepts arguments entered using the keyboard and then prints out the results - and then you keep entering values and validating yourself if the results are correct), then you can start by writing such tests in the format above and validating the results with the correct assertXXX method instead of doing it manually. This way, you can re-run the test much easier then if you had to do manual tests.


Like @CoolBeans mentioned, take a look at jUnit. Here is a short tutorial to get you started as well with jUnit 4.x

Finally, if you really want to learn more about testing and test-driven development (TDD) I recommend you take a look at the following book by Kent Beck: Test-Driven Development By Example.


Other answers have shown you how to use JUnit to set up test classes. JUnit is not the only Java test framework. Concentrating on the technical details of using a framework however detracts from the most important concepts that should be guiding your actions, so I will talk about those.

  • Testing (of all kinds of all kinds of things) compares the actual behaviour of something (The System Under Test, SUT) with its expected behaviour.

  • Automated testing can be done using a computer program. Because that comparison is being done by an inflexible and unintelligent computer program, the expected behaviour must be precisely and unambiguously known.

  • What a program or part of a program (a class or method) is expected to do is its specification. Testing software therefore requires that you have a specification for the SUT. This might be an explicit description, or an implicit specification in your head of what is expected.

  • Automated unit testing therefore requires a precise and unambiguous specification of the class or method you are testing.

  • But you needed that specification when you set out to write that code. So part of what testing is about actually begins before you write even one line of the SUT. The testing technique of Test Driven Development (TDD) takes that idea to an extreme, and has you create the unit testing code before you write the code to be tested.

  • Unit testing frameworks test your SUT using assertions. An assertion is a logical expression (an expression with a boolean result type; a predicate) that must be true if the SUT is behaving correctly. The specification must therefore be expressed (or re-expressed) as assertions.

  • A useful technique for expressing a specification as assertions is Design by Contract. These specifications are in terms of postconditions. A postcondition is an assertion about the publicly visible state of the SUT after return from a method or a constructor. Some methods have postconditions that are invariants, which are predicates that are true before and after execution of the method. A class can also be said to have invariants, which are postconditions of every constructor and method of the class, and hence should always be true. Postconditions (And invariants) are expressed only in terms of publicity visible state: public and protected fields, the values returned by returned by public and protected methods (such as getters), and the publicly visible state of objects passed (by reference) to methods.

Many beginners post questions here asking how they can test some code, presenting the code but without stating the specification for that code. As this discussion shows, it is impossible for anyone to give a good answer to such a question, because at best potential answereres must guess the specification, and might do so incorrectly. The asker of the question evidently does not understand the importance of a specification, and is thus a novice who needs to understand the fundamentals I've described here before trying to write some test code.

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