WebTestClient is a thin shell around WebClient, using it to perform requests and exposing a dedicated, fluent API for verifying responses. WebTestClient binds to a WebFlux application by using a mock request and response, or it can test any web server over an HTTP connection.

Kotlin users: See this section related to use of the WebTestClient.

1. Setup

To create a WebTestClient you must choose one of several server setup options. Effectively you’re either configuring the WebFlux application to bind to, or using a URL to connect to a running server.

1.1. Bind to Controller

The following example shows how to create a server setup to test one @Controller at a time:

        client = WebTestClient.bindToController(new TestController()).build();

The preceding example loads the WebFlux Java configuration and registers the given controller. The resulting WebFlux application is tested without an HTTP server by using mock request and response objects. There are more methods on the builder to customize the default WebFlux Java configuration.

1.2. Bind to Router Function

The following example shows how to set up a server from a RouterFunction:

        RouterFunction<?> route = ...
        client = WebTestClient.bindToRouterFunction(route).build();

Internally, the configuration is passed to RouterFunctions.toWebHandler. The resulting WebFlux application is tested without an HTTP server by using mock request and response objects.

1.3. Bind to ApplicationContext

The following example shows how to setup a server from the Spring configuration of your application or some subset of it:

        @RunWith(SpringRunner.class)
        @ContextConfiguration(classes = WebConfig.class) (1)
        public class MyTests {

                @Autowired
                private ApplicationContext context; (2)

                private WebTestClient client;

                @Before
                public void setUp() {
                        client = WebTestClient.bindToApplicationContext(context).build(); (3)
                }
        }
1 Specify the configuration to load
2 Inject the configuration
3 Create the WebTestClient

Internally, the configuration is passed to WebHttpHandlerBuilder to set up the request processing chain. See WebHandler API for more details. The resulting WebFlux application is tested without an HTTP server by using mock request and response objects.

1.4. Bind to Server

The following server setup option lets you connect to a running server:

        client = WebTestClient.bindToServer().baseUrl("http://localhost:8080").build();

1.5. Client Builder

In addition to the server setup options described earlier, you can also configure client options, including base URL, default headers, client filters, and others. These options are readily available following bindToServer. For all others, you need to use configureClient() to transition from server to client configuration, as follows:

        client = WebTestClient.bindToController(new TestController())
                        .configureClient()
                        .baseUrl("/test")
                        .build();

2. Writing Tests

WebTestClient provides an API identical to WebClient up to the point of performing a request by using exchange(). What follows after exchange() is a chained API workflow to verify responses.

Typically, you start by asserting the response status and headers, as follows:

        client.get().uri("/persons/1")
                        .accept(MediaType.APPLICATION_JSON_UTF8)
                        .exchange()
                        .expectStatus().isOk()
                        .expectHeader().contentType(MediaType.APPLICATION_JSON_UTF8)
                        // ...

Then you specify how to decode and consume the response body:

  • expectBody(Class<T>): Decode to single object.

  • expectBodyList(Class<T>): Decode and collect objects to List<T>.

  • expectBody(): Decode to byte[] for JSON Content or an empty body.

Then you can use built-in assertions for the body. The following example shows one way to do so:

        client.get().uri("/persons")
                        .exchange()
                        .expectStatus().isOk()
                        .expectBodyList(Person.class).hasSize(3).contains(person);

You can also go beyond the built-in assertions and create your own, as the following example shows:

	client.get().uri("/persons/1")
			.exchange()
			.expectStatus().isOk()
			.expectBody(Person.class)
			.consumeWith(result -> {
				// custom assertions (e.g. AssertJ)...
			});

You can also exit the workflow and get a result, as follows:

	EntityExchangeResult<Person> result = client.get().uri("/persons/1")
			.exchange()
			.expectStatus().isOk()
			.expectBody(Person.class)
			.returnResult();
When you need to decode to a target type with generics, look for the overloaded methods that accept {api-spring-framework}/core/ParameterizedTypeReference.html[ParameterizedTypeReference] instead of Class<T>.

2.1. No Content

If the response has no content (or you do not care if it does) use Void.class, which ensures that resources are released. The following example shows how to do so:

        client.get().uri("/persons/123")
                        .exchange()
                        .expectStatus().isNotFound()
                        .expectBody(Void.class);

Alternatively, if you want to assert there is no response content, you can use code similar to the following:

        client.post().uri("/persons")
                        .body(personMono, Person.class)
                        .exchange()
                        .expectStatus().isCreated()
                        .expectBody().isEmpty();

2.2. JSON Content

When you use expectBody(), the response is consumed as a byte[]. This is useful for raw content assertions. For example, you can use JSONAssert to verify JSON content, as follows:

        client.get().uri("/persons/1")
                        .exchange()
                        .expectStatus().isOk()
                        .expectBody()
                        .json("{\"name\":\"Jane\"}")

You can also use JSONPath expressions, as follows:

        client.get().uri("/persons")
                        .exchange()
                        .expectStatus().isOk()
                        .expectBody()
                        .jsonPath("$[0].name").isEqualTo("Jane")
                        .jsonPath("$[1].name").isEqualTo("Jason");

2.3. Streaming Responses

To test infinite streams (for example, "text/event-stream" or "application/stream+json"), you need to exit the chained API (by using returnResult), immediately after the response status and header assertions, as the following example shows:

        FluxExchangeResult<MyEvent> result = client.get().uri("/events")
                        .accept(TEXT_EVENT_STREAM)
                        .exchange()
                        .expectStatus().isOk()
                        .returnResult(MyEvent.class);

Now you can consume the Flux<T>, assert decoded objects as they come, and then cancel at some point when test objectives are met. We recommend using the StepVerifier from the reactor-test module to do that, as the following example shows:

        Flux<Event> eventFux = result.getResponseBody();

        StepVerifier.create(eventFlux)
                        .expectNext(person)
                        .expectNextCount(4)
                        .consumeNextWith(p -> ...)
                        .thenCancel()
                        .verify();

2.4. Request Body

When it comes to building requests, the WebTestClient offers an API identical to the WebClient, and the implementation is mostly a simple pass-through. See the WebClient documentation for examples on how to prepare a request with a body, including submitting form data, multipart requests, and more.