Are there any means in xUnit.net framework similar to the following features of NUnit?

[Test, TestCaseSource("CurrencySamples")]
public void Format_Currency(decimal value, string expected){}

static object[][] CurrencySamples = new object[][]
    new object[]{ 0m, "0,00"},
    new object[]{ 0.0004m, "0,00"},
    new object[]{ 5m, "5,00"},
    new object[]{ 5.1m, "5,10"},
    new object[]{ 5.12m, "5,12"},
    new object[]{ 5.1234m, "5,12"},
    new object[]{ 5.1250m, "5,13"}, // round
    new object[]{ 5.1299m, "5,13"}, // round

This will generate 8 separate tests in NUnit GUI

[TestCase((string)null, Result = "1")]
[TestCase("", Result = "1")]
[TestCase(" ", Result = "1")]
[TestCase("1", Result = "2")]
[TestCase(" 1 ", Result = "2")]
public string IncrementDocNumber(string lastNum) { return "some"; }

This will generate 5 separate tests and automatically compare the results (Assert.Equal()).

public void StateTest(
    [Values(1, 10)]
    int input,
    [Values(State.Initial, State.Rejected, State.Stopped)]
    DocumentType docType

This will generate 6 combinatorial tests. Priceless.

Few years ago I tried xUnit and loved it but it lacked these features. Can't live without them. Has something changed?


6 Answers 6


xUnit offers a way to run parameterized tests through something called data theories. The concept is equivalent to the one found in NUnit but the functionality you get out of the box is not as complete.

Here's an example:

public void Should_be_assigned_different_values(object value)

In this example xUnit will run the Should_be_assigned_different_values test once for every InlineDataAttribute each time passing the specified value as argument.

Data theories are an extensibility point that you can use to create new ways to run your parameterized tests. The way this is done is by creating new attributes that inspect and optionally act upon the arguments and return value of the test methods.

You can find a good practical example of how xUnit's data theories can be extended in AutoFixture's AutoData and InlineAutoData theories.


Let me throw one more sample here, just in case it saves some time to someone.

[InlineData("goodnight moon", "moon", true)]
[InlineData("hello world", "hi", false)]
public void Contains(string input, string sub, bool expected)
    var actual = input.Contains(sub);
    Assert.Equal(expected, actual);

According to this article in xUnit you have three "parametrization" options:

  1. InlineData
  2. ClassData
  3. MemberData

InlineData example

[InlineData(1, 2)]
[InlineData(-4, -6)]
[InlineData(2, 4)]
public void FooTest(int value1, int value2)
    Assert.True(value1 + value2 < 7)

ClassData example

public class BarTestData : IEnumerable<object[]>
    public IEnumerator<object[]> GetEnumerator()
        yield return new object[] { 1, 2 };
        yield return new object[] { -4, -6 };
        yield return new object[] { 2, 4 };

    IEnumerator IEnumerable.GetEnumerator() => GetEnumerator();

public void BarTest(int value1, int value2)
    Assert.True(value1 + value2 < 7)

MemberData example

public void BazTest(int value1, int value2)
    Assert.True(value1 + value2 < 7)

public static IEnumerable<object[]> BazTestData => new List<object[]>
        new object[] { 1, 2 },
        new object[] { -4, -6 },
        new object[] { 2, 4 },

On your first request, you can follow the examples found here.

You can construct a static class containing the data necessary for a collection of tests

using System.Collections.Generic;

namespace PropertyDataDrivenTests
    public static class DemoPropertyDataSource
        private static readonly List<object[]> _data = new List<object[]>
                new object[] {1, true},
                new object[] {2, false},
                new object[] {-1, false},
                new object[] {0, false}

        public static IEnumerable<object[]> TestData
            get { return _data; }

Then, using the MemberData attribute, define the test as such

public class TestFile1
    [MemberData("TestData", MemberType = typeof(DemoPropertyDataSource))]
    public void SampleTest1(int number, bool expectedResult)
        var sut = new CheckThisNumber(1);
        var result = sut.CheckIfEqual(number);
        Assert.Equal(result, expectedResult);

or if you're using C# 6.0,

[MemberData(nameof(PropertyDataDrivenTests.TestData), MemberType = typeof(DemoPropertyDataSource))]

The first argument of MemberDataAttribute allows you to define the member you use as a datasource, so you have a fair amount of flexibility on reuse.


I took on-board all the answers here and additionally made use of XUnit's TheoryData<,> generic types to give me simple, easy to read and type safe data definitions for the 'MemberData' attribute on my test, as per this example:

/// must be public & static for MemberDataAttr to use
public static TheoryData<int, bool, string> DataForTest1 = new TheoryData<int, bool, string> {
    { 1, true, "First" },
    { 2, false, "Second" },
    { 3, true, "Third" }

[Theory(DisplayName = "My First Test"), MemberData(nameof(DataForTest1))]
public void Test1(int valA, bool valB, string valC)
    Debug.WriteLine($"Running {nameof(Test1)} with values: {valA}, {valB} & {valC} ");

Three tests runs observed from test explorer for 'My First Test'

NB Using VS2017(15.3.3), C#7, & XUnit 2.2.0 for .NET Core

  • 1
    This is lovely. Commented May 14, 2019 at 3:55

I found a library that produces equivalent functionality to NUnit's [Values] attribute called Xunit.Combinatorial:

It allows you to specify parameter-level values:

[Theory, CombinatorialData]
public void CheckValidAge([CombinatorialValues(5, 18, 21, 25)] int age, 
    bool friendlyOfficer)
    // This will run with all combinations:
    // 5  true
    // 18 true
    // 21 true
    // 25 true
    // 5  false
    // 18 false
    // 21 false
    // 25 false

Or you can implicitly have it figure out the minimal number of invocations to cover all possible combinations:

[Theory, PairwiseData]
public void CheckValidAge(bool p1, bool p2, bool p3)
    // Pairwise generates these 4 test cases:
    // false false false
    // false true  true
    // true  false true
    // true  true  false
  • note that pariwise covers all possible combinations of any two parameters, not all possible combinations of all the parameters. so the possible pairs in this ex are: [p1, p2] [p1, p3] [p2, p3]. So in this example, no case is generated where all 3 are true, if that happens to matter to you.
    – Thedudxo
    Commented Jun 18 at 22:19

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