1. About the Documentation

This section provides a brief overview of Reactor reference documentation. You do not need to read this guide in a linear fashion. Each piece stands on its own, though they often refer to other pieces.

The Reactor reference guide is available as HTML documents. The latest copy is available at http://projectreactor.io/docs/core/release/reference/docs/index.html

Copies of this document may be made for your own use and for distribution to others, provided that you do not charge any fee for such copies and further provided that each copy contains this Copyright Notice, whether distributed in print or electronically.

1.2. Contributing to the Documentation

The reference guide is written in Asciidoc format and sources can be found at https://github.com/reactor/reactor-core/tree/master/src/docs/asciidoc.

If you have an improvement, we will be happy to get a pull request from you!

We recommend that you check out a local copy of the repository, so that you can generate the documentation using the asciidoctor gradle task and check the rendering. Some of the sections rely on included files, so GitHub rendering is not always complete.

To facilitate documentation edits, most sections have a link at the end that opens an edit UI directly on GitHub for the main source file for that section. These links are only present in the HTML5 version of this reference guide. They look like the following Suggest Edit to About the Documentation. == Getting Help There are several ways to reach out for help with Reactor.
  • Get in touch with the community on Gitter.

  • Ask a question on stackoverflow.com at project-reactor.

  • Report bugs in Github issues. The following repositories are closely monitored: reactor-core (which covers the essential features) and reactor-addons (which covers reactor-test and adapters issues).

All of Reactor is open source, including this documentation. If you find problems with the docs or if you just want to improve them, please get involved.

1.3. Where to Go from Here

2. Getting Started

This section contains information that should help you get going with Reactor. It includes the following information:

2.1. Introducing Reactor

Reactor is a fully non-blocking reactive programming foundation for the JVM, with efficient demand management (in the form of managing "backpressure"). It integrates directly with the Java 8 functional APIs, notably CompletableFuture, Stream, and Duration. It offers composable asynchronous sequence APIs Flux (for [N] elements) and Mono (for [0|1] elements), extensively implementing the Reactive Extensions specification.

Reactor also supports non-blocking inter-process communication (IPC) with the reactor-ipc components. Suited for Microservices Architecture, Reactor IPC offers backpressure-ready network engines for HTTP (including Websockets), TCP, and UDP. Reactive Encoding and Decoding are fully supported.

2.2. Prerequisites

Reactor Core runs on Java 8 and above.

It has a transitive dependency on org.reactive-streams:reactive-streams:1.0.2.

Android support:

  • Reactor 3 does not officially support or target Android (consider using RxJava 2 if such support is a strong requirement).

  • However, it should work fine with Android SDK 26 (Android O) and above.

  • We are open to evaluating changes that benefit Android support in a best-effort fashion. However, we cannot make guarantees. Each decision must be made on a case-by-case basis.

2.3. Understanding the BOM

Reactor 3 uses a BOM (Bill of Materials - a standard Maven artifact) model (since reactor-core 3.0.4, with the Aluminium release train).

The BOM lets you group artifacts that are meant to work well together without having to wonder about the sometimes divergent versioning schemes of these artifacts.

The BOM is a list of versioned artifacts that is itself versioned, using a release train scheme with a codename followed by a qualifier. Here are a few examples:

Aluminium-RELEASE
Carbon-BUILD-SNAPSHOT
Aluminium-SR1
Bismuth-RELEASE
Carbon-SR32

The codenames represent what would traditionally be the MAJOR.MINOR number. They (mostly) come from the Periodic Table of Elements, in increasing alphabetical order.

The qualifiers are (in chronological order):

  • BUILD-SNAPSHOT

  • M1..N: Milestones or developer previews

  • RELEASE: The first GA (General Availability) release in a codename series

  • SR1..N: The subsequent GA releases in a codename series (equivalent to PATCH number, SR stands for "Service Release").

2.4. Getting Reactor

As mentioned earlier, the easiest way to use Reactor in your core is to use the BOM and add the relevant dependencies to your project. Note that, when adding such a dependency, you must omit the version so that the version gets picked up from the BOM.

However, if you want to force the use of a specific artifact’s version, you can specify it when adding your dependency, as you usually would. You can also forgo the BOM entirely and specify dependencies by their artifact versions.

2.4.1. Maven Installation

The BOM concept is natively supported by Maven. First, you need to import the BOM by adding the following snippet to your pom.xml. If the top section (dependencyManagement) already exists in your pom, add only the contents.

<dependencyManagement> (1)
    <dependencies>
        <dependency>
            <groupId>io.projectreactor</groupId>
            <artifactId>reactor-bom</artifactId>
            <version>Bismuth-RELEASE</version>
            <type>pom</type>
            <scope>import</scope>
        </dependency>
    </dependencies>
</dependencyManagement>
1 Notice the dependencyManagement tag. This is in addition to the regular dependencies section.

Next, add your dependencies to the relevant reactor projects, as usual, except without a <version>, as shown here:

<dependencies>
    <dependency>
        <groupId>io.projectreactor</groupId>
        <artifactId>reactor-core</artifactId> (1)
        (2)
    </dependency>
    <dependency>
        <groupId>io.projectreactor</groupId>
        <artifactId>reactor-test</artifactId> (3)
        <scope>test</scope>
    </dependency>
</dependencies>
1 Dependency on the core library
2 No version tag here
3 reactor-test provides facilities to unit test reactive streams

2.4.2. Gradle installation

Gradle has no core support for Maven BOMs, but you can use Spring’s gradle-dependency-management plugin.

First, apply the plugin from the Gradle Plugin Portal:

plugins {
    id "io.spring.dependency-management" version "1.0.1.RELEASE" (1)
}
1 as of this writing, 1.0.1.RELEASE is the latest version of the plugin. Check for updates.

Then use it to import the BOM:

dependencyManagement {
     imports {
          mavenBom "io.projectreactor:reactor-bom:Bismuth-RELEASE"
     }
}

Finally add a dependency to your project, without a version number:

dependencies {
     compile 'io.projectreactor:reactor-core' (1)
}
1 There is no third : separated section for the version. It is taken from the BOM.

2.4.3. Milestones and Snapshots

Milestones and developer previews are distributed through the Spring Milestones repository rather than Maven Central. To add it to your build configuration file, use the following snippet:

Milestones in Maven
<repositories>
        <repository>
                <id>spring-milestones</id>
                <name>Spring Milestones Repository</name>
                <url>https://repo.spring.io/milestone</url>
        </repository>
</repositories>

For Gradle, use the following snippet:

Milestones in Gradle
repositories {
  maven { url 'http://repo.spring.io/milestone' }
  mavenCentral()
}

Similarly, snapshots are also available in a separate dedicated repository:

BUILD-SNAPSHOTs in Maven
<repositories>
        <repository>
                <id>spring-snapshots</id>
                <name>Spring Snapshot Repository</name>
                <url>https://repo.spring.io/snapshot</url>
        </repository>
</repositories>
BUILD-SNAPSHOTs in Gradle
repositories {
  maven { url 'http://repo.spring.io/snapshot' }
  mavenCentral()
}

3. Introduction to Reactive Programming

Reactor is an implementation of the Reactive Programming paradigm, which can be summed up as:

Reactive programming is an asynchronous programming paradigm concerned with data streams and the propagation of change. This means that it becomes possible to express static (e.g. arrays) or dynamic (e.g. event emitters) data streams with ease via the employed programming language(s).
— https://en.wikipedia.org/wiki/Reactive_programming

As a first step in the direction of reactive programming, Microsoft created the Reactive Extensions (Rx) library in the .NET ecosystem. Then RxJava implemented reactive programming on the JVM. As time went on, a standardization for Java emerged through the Reactive Streams effort, a specification that defines a set of interfaces and interaction rules for reactive libraries on the JVM. It will be integrated into Java 9 (with the Flow class).

The reactive programming paradigm is often presented in object-oriented languages as an extension of the Observer design pattern. One can also compare the main reactive streams pattern with the familiar Iterator design pattern, as there is a duality to the Iterable-Iterator pair in all of these libraries. One major difference is that, while an Iterator is pull-based, reactive streams are push-based.

Using an iterator is an imperative programming pattern, even though the method of accessing values is solely the responsibility of the Iterable. Indeed, it is up to the developer to choose when to access the next() item in the sequence. In reactive streams, the equivalent of the above pair is Publisher-Subscriber. But it is the Publisher that notifies the Subscriber of newly available values as they come, and this push aspect is the key to being reactive. Also, operations applied to pushed values are expressed declaratively rather than imperatively: the programmer expresses the logic of the computation rather than describing its exact control flow.

In addition to pushing values, the error handling and completion aspects are also covered in a well defined manner. A Publisher can push new values to its Subscriber (by calling onNext) but can also signal an error (by calling onError) or completion (by calling onComplete). Both errors and completion terminate the sequence. The following descriptor shows the possibilities:

onNext x 0..N [onError | onComplete]

This approach is very flexible. The pattern supports use cases where there is no value, one value, or n values (including an infinite sequence of values, such as the continuing ticks of a clock).

Consider why we would need such an asynchronous reactive library in the first place.

3.1. Blocking Can Be Wasteful

Modern applications can reach huge numbers of concurrent users, and, even though the capabilities of modern hardware have continued to improve, performance of modern software is still a key concern.

There are broadly two ways one can improve a program’s performance:

  1. parallelize: use more threads and more hardware resources.

  2. seek more efficiency in how current resources are used.

Usually, Java developers write programs using blocking code. This practice is fine until there is a performance bottleneck, at which point the time comes to introduce additional threads, running similar blocking code. But this scaling in resource utilization can quickly introduce contention and concurrency problems.

Worse still, blocking wastes resources. If you look closely, as soon as a program involves some latency (notably I/O, such as a database request or a network call), resources are wasted because a thread (or many threads) now sits idle, waiting for data.

So the parallelization approach is not a silver bullet. It is necessary in order to access the full power of the hardware, but it is also complex to reason about and susceptible to resource wasting.

3.2. Asynchronicity to the Rescue?

The second approach (mentioned earlier), seeking more efficiency, can be a solution to the resource wasting problem. By writing asynchronous, non-blocking code, you let the execution switch to another active task using the same underlying resources and later come back to the current process when the asynchronous processing has finished.

But how can you produce asynchronous code on the JVM? Java offers two models of asynchronous programming:

  • Callbacks: Asynchronous methods do not have a return value but take an extra callback parameter (a lambda or anonymous class) that gets called when the result is available. A well known example is Swing’s EventListener hierarchy.

  • Futures: Asynchronous methods return a Future<T> immediately. The asynchronous process computes a T value, but the Future object wraps access to it. The value is not immediately available, and the object can be polled until the value is available. For instance, ExecutorService running Callable<T> tasks use Future objects.

Are these techniques good enough? Not for every use case, and both approaches have limitations.

Callbacks are hard to compose together, quickly leading to code that is difficult to read and maintain (known as "Callback Hell").

Consider an example: showing the top five favorites from a user on the UI or suggestions if she doesn’t have a favorite. This goes through three services (one gives favorite IDs, the second fetches favorite details, and the third offers suggestions with details):

Example of Callback Hell
userService.getFavorites(userId, new Callback<List<String>>() { (1)
  public void onSuccess(List<String> list) { (2)
    if (list.isEmpty()) { (3)
      suggestionService.getSuggestions(new Callback<List<Favorite>>() {
        public void onSuccess(List<Favorite> list) { (4)
          UiUtils.submitOnUiThread(() -> { (5)
            list.stream()
                .limit(5)
                .forEach(uiList::show); (6)
            });
        }

        public void onError(Throwable error) { (7)
          UiUtils.errorPopup(error);
        }
      });
    } else {
      list.stream() (8)
          .limit(5)
          .forEach(favId -> favoriteService.getDetails(favId, (9)
            new Callback<Favorite>() {
              public void onSuccess(Favorite details) {
                UiUtils.submitOnUiThread(() -> uiList.show(details));
              }

              public void onError(Throwable error) {
                UiUtils.errorPopup(error);
              }
            }
          ));
    }
  }

  public void onError(Throwable error) {
    UiUtils.errorPopup(error);
  }
});
1 We have callback-based services: a Callback interface with a method invoked when the async process was successful and one invoked in case of an error.
2 The first service invokes its callback with the list of favorite IDs.
3 If the list is empty, we must go to the suggestionService.
4 The suggestionService gives a List<Favorite> to a second callback.
5 Since we deal with a UI, we need to ensure our consuming code will run in the UI thread.
6 We use Java 8 Stream to limit the number of suggestions processed to five, and we show them in a graphical list in the UI.
7 At each level, we deal with errors the same way: show them in a popup.
8 Back to the favorite ID level. If the service returned a full list, then we need to go to the favoriteService to get detailed Favorite objects. Since we want only five, we first stream the list of IDs to limit it to five.
9 Once again, a callback. This time we get a fully-fledged Favorite object that we push to the UI inside the UI thread.

That is a lot of code, and it is a bit hard to follow and has repetitive parts. Consider its equivalent in Reactor:

Example of Reactor code equivalent to callback code
userService.getFavorites(userId) (1)
           .flatMap(favoriteService::getDetails) (2)
           .switchIfEmpty(suggestionService.getSuggestions()) (3)
           .take(5) (4)
           .publishOn(UiUtils.uiThreadScheduler()) (5)
           .subscribe(uiList::show, UiUtils::errorPopup); (6)
1 We start with a flow of favorite IDs.
2 We asynchronously transform these into detailed Favorite objects (flatMap). We now have a flow of Favorite.
3 In case the flow of Favorite is empty, we switch to a fallback through the suggestionService.
4 We are only interested in, at most, five elements from the resulting flow.
5 At the end, we want to process each piece of data in the UI thread.
6 We trigger the flow by describing what to do with the final form of the data (show it in a UI list) and what to do in case of an error (show a popup).

What if you want to ensure the favorite IDs are retrieved in less than 800ms or, if it takes longer, get them from a cache? In the callback-based code, that is a complicated task. In Reactor it becomes as easy as adding a timeout operator in the chain:

Example of Reactor code with timeout and fallback
userService.getFavorites(userId)
           .timeout(Duration.ofMillis(800)) (1)
           .onErrorResume(cacheService.cachedFavoritesFor(userId)) (2)
           .flatMap(favoriteService::getDetails) (3)
           .switchIfEmpty(suggestionService.getSuggestions())
           .take(5)
           .publishOn(UiUtils.uiThreadScheduler())
           .subscribe(uiList::show, UiUtils::errorPopup);
1 If the part above emits nothing for more than 800ms, propagate an error.
2 In case of an error, fall back to the cacheService.
3 The rest of the chain is similar to the previous example.

Futures are a bit better than callbacks, but they still do not do well at composition, despite the improvements brought in Java 8 by CompletableFuture. Orchestrating multiple futures together is doable but not easy. Also, Future has other problems: It is easy to end up with another blocking situation with Future objects by calling the get() method, and they lack support for multiple values and advanced error handling.

Consider another example: We get a list of IDs from which we want to fetch a name and a statistic and combine these pair-wise, all of it asynchronously.

Example of CompletableFuture combination
CompletableFuture<List<String>> ids = ifhIds(); (1)

CompletableFuture<List<String>> result = ids.thenComposeAsync(l -> { (2)
        Stream<CompletableFuture<String>> zip =
                        l.stream().map(i -> { (3)
                                                 CompletableFuture<String> nameTask = ifhName(i); (4)
                                                 CompletableFuture<Integer> statTask = ifhStat(i); (5)

                                                 return nameTask.thenCombineAsync(statTask, (name, stat) -> "Name " + name + " has stats " + stat); (6)
                                         });
        List<CompletableFuture<String>> combinationList = zip.collect(Collectors.toList()); (7)
        CompletableFuture<String>[] combinationArray = combinationList.toArray(new CompletableFuture[combinationList.size()]);

        CompletableFuture<Void> allDone = CompletableFuture.allOf(combinationArray); (8)
        return allDone.thenApply(v -> combinationList.stream()
                                                                                                 .map(CompletableFuture::join) (9)
                                                                                                 .collect(Collectors.toList()));
});

List<String> results = result.join(); (10)
assertThat(results).contains(
                                "Name NameJoe has stats 103",
                                "Name NameBart has stats 104",
                                "Name NameHenry has stats 105",
                                "Name NameNicole has stats 106",
                                "Name NameABSLAJNFOAJNFOANFANSF has stats 121");
1 We start off with a future that gives us a list of id values to process.
2 We want to start some deeper asynchronous processing once we get the list.
3 For each element in the list:
4 Asynchronously get the associated name.
5 Asynchronously get the associated task.
6 Combine both results.
7 We now have a list of futures that represent all the combination tasks. In order to execute these tasks, we need to convert the list to an array.
8 Pass the array to CompletableFuture.allOf, which outputs a Future that completes when all tasks have completed.
9 The tricky bit is that allOf returns CompletableFuture<Void>, so we reiterate over the list of futures, collecting their results via join() (which here doesn’t block since allOf ensures the futures are all done).
10 Once the whole asynchronous pipeline has been triggered, we wait for it to be processed and return the list of results that we can assert.

Since Reactor has more combination operators out of the box, this process can be simplified:

Example of Reactor code equivalent to future code
Flux<String> ids = ifhrIds(); (1)

Flux<String> combinations =
                ids.flatMap(id -> { (2)
                        Mono<String> nameTask = ifhrName(id); (3)
                        Mono<Integer> statTask = ifhrStat(id); (4)

                        return nameTask.zipWith(statTask, (5)
                                        (name, stat) -> "Name " + name + " has stats " + stat);
                });

Mono<List<String>> result = combinations.collectList(); (6)

List<String> results = result.block(); (7)
assertThat(results).containsExactly( (8)
                "Name NameJoe has stats 103",
                "Name NameBart has stats 104",
                "Name NameHenry has stats 105",
                "Name NameNicole has stats 106",
                "Name NameABSLAJNFOAJNFOANFANSF has stats 121"
);
1 This time, we start from an asynchronously provided sequence of ids (a Flux<String>).
2 For each element in the sequence, we asynchronously process it (inside the function that is the body flatMap call) twice.
3 Get the associated name.
4 Get the associated statistic.
5 Asynchronously combine the 2 values.
6 Aggregate the values into a List as they become available.
7 In production, we would continue working with the Flux asynchronously by further combining it or subscribing to it. Most probably, we would return the result Mono. Since we are in a test, we block, waiting for the processing to finish instead, and then directly return the aggregated list of values.
8 Assert the result.

These perils of Callback and Future are similar and are what reactive programming addresses with the Publisher-Subscriber pair.

3.3. From Imperative to Reactive Programming

Reactive libraries such as Reactor aim to address these drawbacks of "classic" asynchronous approaches on the JVM while also focusing on a few additional aspects:

  • Composability and readability

  • Data as a flow manipulated with a rich vocabulary of operators

  • Nothing happens until you subscribe

  • Backpressure or the ability for the consumer to signal the producer that the rate of emission is too high

  • High level but high value abstraction that is concurrency-agnostic

3.3.1. Composability and Readability

By composability, we mean the ability to orchestrate multiple asynchronous tasks, using results from previous tasks to feed input to subsequent ones or executing several tasks in a fork-join style, as well as reusing asynchronous tasks as discrete components in a higher-level system.

The ability to orchestrate tasks is tightly coupled to the readability and maintainability of code. As the layers of asynchronous processes increase in both number and complexity, being able to compose and read code becomes increasingly difficult. As we saw, the callback model is simple, but one of its main drawbacks is that, for complex processes, you need to have a callback executed from a callback, itself nested inside another callback, and so on. That mess is known as Callback Hell. As you can guess (or know from experience), such code is pretty hard to go back to and reason about.

Reactor offers rich composition options, wherein code mirrors the organization of the abstract process, and everything is generally kept at the same level (nesting is minimized).

3.3.2. The Assembly Line Analogy

You can think of data processed by a reactive application as moving through an assembly line. Reactor is both the conveyor belt and the workstations. The raw material pours from a source (the original Publisher) and ends up as a finished product ready to be pushed to the consumer (or Subscriber).

The raw material can go through various transformations and other intermediary steps or be part of a larger assembly line that aggregates intermediate pieces together. If there is a glitch or clogging at one point (perhaps boxing the products takes a disproportionately long time), the afflicted workstation can signal upstream to limit the flow of raw material.

3.3.3. Operators

In Reactor, operators are the workstations in our assembly analogy. Each operator adds behavior to a Publisher and wraps the previous step’s Publisher into a new instance. The whole chain is thus linked, such that data originates from the first Publisher and moves down the chain, transformed by each link. Eventually, a Subscriber finishes the process. Remember that nothing happens until a Subscriber subscribes to a Publisher, as we see shortly.

Understanding that operators create new instances can help you avoid a common mistake that would lead you to believe that an operator you used in your chain is not being applied. See this item in the FAQ.

While the Reactive Streams specification does not specify operators at all, one of the best added values of reactive libraries such as Reactor is the rich vocabulary of operators that they provide. These cover a lot of ground, from simple transformation and filtering to complex orchestration and error handling.

3.3.4. Nothing Happens Until You subscribe()

In Reactor, when you write a Publisher chain, data does not start pumping into it by default. Instead, you create an abstract description of your asynchronous process (which can help with reusability and composition).

By the act of subscribing, you tie the Publisher to a Subscriber, which triggers the flow of data in the whole chain. This is achieved internally by a single request signal from the Subscriber that is propagated upstream, all the way back to the source Publisher.

3.3.5. Backpressure

Propagating signals upstream is also used to implement backpressure, which we described in the assembly line analogy as a feedback signal sent up the line when a workstation processes more slowly than an upstream workstation.

The real mechanism defined by the Reactive Streams specification is pretty close to the analogy: a subscriber can work in unbounded mode and let the source push all the data at its fastest achievable rate or it can use the request mechanism to signal the source that it is ready to process at most n elements.

Intermediate operators can also change the request in-transit. Imagine a buffer operator that groups elements in batches of 10. If the subscriber requests 1 buffer, it is acceptable for the source to produce 10 elements. Prefetching strategies can also be applied, if producing the elements before they are requested is not too costly.

This transforms the push model into a push-pull hybrid where the downstream can pull n elements from upstream if they are readily available, but, if the elements are not ready, they get pushed by the upstream whenever they are produced.

3.3.6. Hot vs Cold

In the Rx family of reactive libraries, one can distinguish two broad categories of reactive sequences: hot and cold. This distinction mainly has to do with how the reactive stream reacts to subscribers:

  • A Cold sequence starts anew for each Subscriber, including at the source of data. If the source wraps an HTTP call, a new HTTP request is made for each subscription.

  • A Hot sequence does not start from scratch for each Subscriber. Rather, late subscribers receive signals emitted after they subscribed. Note, however, that some hot reactive streams can cache or replay the history of emissions totally or partially. From a general perspective, a hot sequence can even emit when no subscriber is listening (an exception to the "nothing happens before you subscribe" rule).

For more information on hot vs cold in the context of Reactor, see this reactor-specific section.

4. Reactor Core Features

The Reactor project main artifact is reactor-core, a reactive library that focuses on the Reactive Streams specification and targets Java 8.

Reactor introduces composable reactive types that implement Publisher but also provide a rich vocabulary of operators, most notably Flux and Mono. A Flux object represents a reactive sequence of 0..N items, while a Mono object represents a single-value-or-empty (0..1) result.

This distinction carries a bit of semantic information into the type, indicating the rough cardinality of the asynchronous processing. For instance, an HTTP request produces only one response, so there is not much sense in doing a count operation. Expressing the result of such an HTTP call as a Mono<HttpResponse> thus makes more sense than expressing it as a Flux<HttpResponse>, as it offers only operators that are relevant to a context of zero items or one item.

Operators that change the maximum cardinality of the processing also switch to the relevant type. For instance, the count operator exists in Flux, but it returns a Mono<Long>.

4.1. Flux, an Asynchronous Sequence of 0-N Items

Flux

A Flux<T> is a standard Publisher<T> representing an asynchronous sequence of 0 to N emitted items, optionally terminated by either a completion signal or an error. Thus, the possible values of a flux are a value, a completion signal, or an error. As in the Reactive Streams spec, these 3 types of signal translate to calls to a downstream object’s onNext, onComplete or onError methods.

With this large scope of possible signals, Flux is the general-purpose reactive type. Note that all events, even terminating ones, are optional: no onNext event but an onComplete event represents an empty finite sequence, but remove the onComplete and you have an infinite empty sequence. Similarly, infinite sequences are not necessarily empty. For example, Flux.interval(Duration) produces a Flux<Long> that is infinite and emits regular ticks from a clock.

4.2. Mono, an Asynchronous 0-1 Result

Mono

A Mono<T> is a specialized Publisher<T> that emits at most one item and then optionally terminates with an onComplete signal or an onError signal.

It offers only a subset of the operators that are available for a Flux. For instance, combination operators can either ignore the right hand-side emissions and return another Mono or emit values from both sides. In the latter case, they switch to a Flux.

For example, Mono#concatWith(Publisher) returns a Flux while Mono#then(Mono) returns another Mono.

Note that a Mono can be used to represent no-value asynchronous processes that only have the concept of completion (such as Runnable). To create one, use an empty Mono<Void>.

4.3. Simple Ways to Create a Flux or Mono and Subscribe to It

The easiest way to get started with Flux and Mono is to use one of the numerous factory methods found in their respective classes.

For instance, to create a sequence of String, you can either enumerate them or put them in a collection and create the Flux from it, as follows:

Flux<String> seq1 = Flux.just("foo", "bar", "foobar");

List<String> iterable = Arrays.asList("foo", "bar", "foobar");
Flux<String> seq2 = Flux.fromIterable(iterable);

Other examples of factory methods include the following:

Mono<String> noData = Mono.empty(); (1)

Mono<String> data = Mono.just("foo");

Flux<Integer> numbersFromFiveToSeven = Flux.range(5, 3); (2)
1 Notice the factory method honors the generic type even though it has no value.
2 The first parameter is the start of the range, while the second parameter is the number of items to produce.

When it comes to subscribing, Flux and Mono make use of Java 8 lambdas. You have a wide choice of .subscribe() variants that take lambdas for different combinations of callbacks, as shown in the following method signatures:

Lambda-based subscribe variants for Flux
subscribe(); (1)

subscribe(Consumer<? super T> consumer); (2)

subscribe(Consumer<? super T> consumer,
          Consumer<? super Throwable> errorConsumer); (3)

subscribe(Consumer<? super T> consumer,
          Consumer<? super Throwable> errorConsumer,
          Runnable completeConsumer); (4)

subscribe(Consumer<? super T> consumer,
          Consumer<? super Throwable> errorConsumer,
          Runnable completeConsumer,
          Consumer<? super Subscription> subscriptionConsumer); (5)
1 Subscribe and trigger the sequence.
2 Do something with each produced value.
3 Deal with values but also react to an error.
4 Deal with values and errors but also execute some code when the sequence successfully completes.
5 Deal with values and errors and successful completion but also do something with the Subscription produced by this subscribe call.
These variants return a reference to the subscription that you can use to cancel the subscription when no more data is needed. Upon cancellation, the source should stop producing values and clean up any resources it created. This cancel and clean-up behavior is represented in Reactor by the general-purpose Disposable interface.

4.3.1. subscribe Method Examples

This section contains minimal examples of each of the five signatures for the subscribe method. The following code shows an example of the basic method with no arguments:

Flux<Integer> ints = Flux.range(1, 3); (1)
ints.subscribe(); (2)
1 Set up a Flux that produces three values when a subscriber attaches.
2 Subscribe in the simplest way.

The preceding code produces no visible output, but it does work. The Flux produces three values. If we provide a lambda, we can make the values visible. The next example for the subscribe method shows one way to make the values appear:

Flux<Integer> ints = Flux.range(1, 3); (1)
ints.subscribe(i -> System.out.println(i)); (2)
1 Set up a Flux that produces three values when a subscriber attaches.
2 Subscribe with a subscriber that will print the values.

The preceding code produces the following output:

1
2
3

To demonstrate the next signature, we intentionally introduce an error, as shown in the following example:

Flux<Integer> ints = Flux.range(1, 4) (1)
      .map(i -> { (2)
        if (i <= 3) return i; (3)
        throw new RuntimeException("Got to 4"); (4)
      });
ints.subscribe(i -> System.out.println(i), (5)
      error -> System.err.println("Error: " + error));
1 Set up a Flux that produces four values when a subscriber attaches.
2 We need a map so that we can handle some values differently.
3 For most values, return the value.
4 For one value, force an error.
5 Subscribe with a subscriber that includes an error handler.

We now have two lambda expressions: one for the content we expect and one for errors. The preceding code produces the following output:

1
2
3
Error: java.lang.RuntimeException: Got to 4

The next signature of the subscribe method includes both an error handler and a handler for completion events, as shown in the following example:

Flux<Integer> ints = Flux.range(1, 4); (1)
ints.subscribe(i -> System.out.println(i),
    error -> System.err.println("Error " + error),
    () -> {System.out.println("Done");}); (2)
1 Set up a Flux that produces four values when a Subscriber attaches.
2 Subscribe with a Subscriber that includes a handler for completion events.

Error signals and completion signals are both terminal events and are exclusive of one another (you never get both). To make the completion consumer work, we must take care not to trigger an error.

The completion matcher is a pair of empty parentheses because it matches the run method in the Runnable interface, which has no parameters. The preceding code produces the following output:

1
2
3
4
Done

The last signature of the subscribe method includes a custom Subscriber (shown later in this section), which shows how to attach a custom Subscriber, as shown in the following example:

SampleSubscriber<Integer> ss = new SampleSubscriber<Integer>();
Flux<Integer> ints = Flux.range(1, 4);
ints.subscribe(i -> System.out.println(i),
    error -> System.err.println("Error " + error),
    () -> {System.out.println("Done");},
    s -> ss.request(10));
ints.subscribe(ss);

In the preceding example, we provide a custom Subscriber as the last argument to the subscribe method. The following example shows that custom Subscriber object, which is the simplest possible implementation of a Subscriber:

package io.projectreactor.samples;

import org.reactivestreams.Subscription;

import reactor.core.publisher.BaseSubscriber;

public class SampleSubscriber<T> extends BaseSubscriber<T> {

        public void hookOnSubscribe(Subscription subscription) {
                System.out.println("Subscribed");
                request(1);
        }

        public void hookOnNext(T value) {
                System.out.println(value);
                request(1);
        }
}

The SampleSubscriber class extends BaseSubscriber, which is the recommended abstract class for user-defined Subscribers in Reactor. The class offers hooks that can be overridden to tune the subscriber’s behavior. By default, it will trigger an unbounded request and behave exactly like subscribe(). However, extending BaseSubscriber is much more useful when you want a custom request amount.

The bare minimum implementation is to implement both hookOnSubscribe(Subscription subscription) and hookOnNext(T value). In this case, the hookOnSubscribe method prints a statement to standard out and makes the first request. Then the hookOnNext method prints a statement and processes each of the remaining requests, one request at a time.

The SampleSubscriber class produces the following output:

Subscribed
1
2
3
4
You almost certainly want to implement the hookOnError, hookOnCancel, and hookOnComplete methods. You may also want to implement the hookFinally method. SampleSubscribe is the absolute minimum implementation of a Subscriber that performs bounded requests.

We return to BaseSubscriber later in this guide.

The Reactive Streams specification defines another variant of the subscribe method. It allows the attachment of a custom Subscriber without all the other options, as shown in the following method signature:

subscribe(Subscriber<? super T> subscriber);

This variant of the subscribe method is useful if you already have a Subscriber handy. More often, though, you need it because you want to do something subscription-related in the other callbacks. Most probably, you need to deal with backpressure and triggering the requests yourself.

In that case, you can make things easier by using the BaseSubscriber abstract class, which offers convenience methods for handling backpressure:

Using a BaseSubscriber to fine tune backpressure
Flux<String> source = someStringSource();

source.map(String::toUpperCase)
      .subscribe(new BaseSubscriber<String>() { (1)
          @Override
          protected void hookOnSubscribe(Subscription subscription) {
              (2)
              request(1); (3)
          }

          @Override
          protected void hookOnNext(String value) {
              request(1); (4)
          }

          (5)
      });
1 The BaseSubscriber is an abstract class, so we create an anonymous implementation and specify the generic type.
2 BaseSubscriber defines hooks for the various signal handling you can implement in a Subscriber. It also deals with the boilerplate of capturing the Subscription object so that you can manipulate it in other hooks.
3 request(n) is such a method. It propagates backpressure requests to the capture subscription from any of the hooks. Here we start the stream by requesting one element from the source.
4 Upon receiving a new value, we continue requesting new items from the source one by one.
5 Other hooks are hookOnComplete, hookOnError, hookOnCancel, and hookFinally (which is always called when the sequence terminates, with the type of termination passed in as a SignalType parameter).
When manipulating a request, you must be careful to produce enough demand for the sequence to advance or your Flux will get "stuck". That is why BaseSubscriber forces you to implement the subscription and onNext hooks, where you should usually call request at least once.

BaseSubscriber also offers a requestUnbounded() method to switch to unbounded mode (equivalent to request(Long.MAX_VALUE)).

4.4. Programmatically creating a sequence

In this section, we introduce the creation of a Flux or a Mono by programmatically defining its associated events (onNext, onError, and onComplete). All these methods share the fact that they expose an API to trigger the events that we call a sink. There are actually a few sink variants, which we’ll get to shortly.

4.4.1. Generate

The simplest form of programmatic creation of a Flux is through the generate method, which takes a generator function.

This is for synchronous and one-by-one emissions, meaning that the sink is a SynchronousSink and that its next() method can only be called at most once per callback invocation. You can then additionally call error(Throwable) or complete(), but this is optional.

The most useful variant is probably the one that also lets you keep a state that you can refer to in your sink usage to decide what to emit next. The generator function then becomes a BiFunction<S, SynchronousSink<T>, S>, with <S> the type of the state object. You have to provide a Supplier<S> for the initial state, and your generator function now returns a new state on each round.

For instance, you could use an int as the state:

Example of state-based generate
Flux<String> flux = Flux.generate(
    () -> 0, (1)
    (state, sink) -> {
      sink.next("3 x " + state + " = " + 3*state); (2)
      if (state == 10) sink.complete(); (3)
      return state + 1; (4)
    });
1 We supply the initial state value of 0.
2 We use the state to choose what to emit (a row in the multiplication table of 3).
3 We also use it to choose when to stop.
4 We return a new state that we use in the next invocation (unless the sequence terminated in this one).

The code above generates the table of 3, as the following sequence:

3 x 0 = 0
3 x 1 = 3
3 x 2 = 6
3 x 3 = 9
3 x 4 = 12
3 x 5 = 15
3 x 6 = 18
3 x 7 = 21
3 x 8 = 24
3 x 9 = 27
3 x 10 = 30

You can also use a mutable <S>. The example above could for instance be rewritten using a single AtomicLong as the state, mutating it on each round:

Mutable state variant
Flux<String> flux = Flux.generate(
    AtomicLong::new, (1)
    (state, sink) -> {
      long i = state.getAndIncrement(); (2)
      sink.next("3 x " + i + " = " + 3*i);
      if (i == 10) sink.complete();
      return state; (3)
    });
1 This time, we generate a mutable object as the state.
2 We mutate the state here.
3 We return the same instance as the new state.
If your state object needs to clean up some resources, use the generate(Supplier<S>, BiFunction, Consumer<S>) variant to clean up the last state instance.

Here is an example of using the generate method that includes a Consumer:

Flux<String> flux = Flux.generate(
    AtomicLong::new,
      (state, sink) -> { (1)
      long i = state.getAndIncrement(); (2)
      sink.next("3 x " + i + " = " + 3*i);
      if (i == 10) sink.complete();
      return state; (3)
    }, (state) -> System.out.println("state: " + state)); (4)
}
1 Again, we generate a mutable object as the state.
2 We mutate the state here.
3 We return the same instance as the new state.
4 We see the last state value (11) as the output of this Consumer lambda.

In the case of the state containing a database connection or other resource that needs to be handled at the end of the process, the Consumer lambda could close the connection or otherwise handle any tasks that should be done at the end of the process.

4.4.2. Create

The more advanced form of programmatic creation of a Flux, create can work asynchronously or synchronously and is suitable for multiple emissions per round.

It exposes a FluxSink, with its next, error, and complete methods. Contrary to generate, it doesn’t have a state-based variant. On the other hand, it can trigger multiple events in the callback (even from any thread at a later point in time).

create can be very useful to bridge an existing API with the reactive world - such as an asynchronous API based on listeners.

Imagine that you use a listener-based API. It processes data by chunks and has two events: (1) a chunk of data is ready and (2) the processing is complete (terminal event), as represented in the MyEventListener interface:

interface MyEventListener<T> {
    void onDataChunk(List<T> chunk);
    void processComplete();
}

You can use create to bridge this into a Flux<T>:

Flux<String> bridge = Flux.create(sink -> {
    myEventProcessor.register( (4)
      new MyEventListener<String>() { (1)

        public void onDataChunk(List<String> chunk) {
          for(String s : chunk) {
            sink.next(s); (2)
          }
        }

        public void processComplete() {
            sink.complete(); (3)
        }
    });
});
1 Bridge to the MyEventListener API
2 Each element in a chunk becomes an element in the Flux.
3 The processComplete event is translated to onComplete.
4 All of this is done asynchronously whenever the myEventProcessor executes.

Additionally, since create can be asynchronous and manages backpressure, you can refine how to behave backpressure-wise, by indicating an OverflowStrategy:

  • IGNORE to Completely ignore downstream backpressure requests. This may yield IllegalStateException when queues get full downstream.

  • ERROR to signal an IllegalStateException when the downstream can’t keep up.

  • DROP to drop the incoming signal if the downstream is not ready to receive it.

  • LATEST to let downstream only get the latest signals from upstream.

  • BUFFER (the default) to buffer all signals if the downstream can’t keep up. (this does unbounded buffering and may lead to OutOfMemoryError).

Mono also has a create generator. The MonoSink of Mono’s create doesn’t allow several emissions. It will drop all signals after the first one.
Push model

A variant of create is push, which is suitable for processing events from a single producer. Similar to create, push can also be asynchronous and can manage backpressure using any of the overflow strategies supported by create. Only one producing thread may invoke next, complete, or error at a time.

Flux<String> bridge = Flux.push(sink -> {
    myEventProcessor.register(
      new SingleThreadEventListener<String>() { (1)

        public void onDataChunk(List<String> chunk) {
          for(String s : chunk) {
            sink.next(s); (2)
          }
        }

        public void processComplete() {
            sink.complete(); (3)
        }

        public void processError(Throwable e) {
            sink.error(e); (4)
        }
    });
});
1 Bridge to the SingleThreadEventListener API.
2 Events are pushed to the sink using next from a single listener thread.
3 complete event generated from the same listener thread.
4 error event also generated from the same listener thread.
Hybrid push/pull model

Unlike push, create may be used in push or pull mode, making it suitable for bridging with listener-based APIs where data may be delivered asynchronously at any time. An onRequest callback can be registered on FluxSink to track requests. The callback may be used to request more data from the source if required and to manage backpressure by delivering data to the sink only when requests are pending. This enables a hybrid push/pull model where downstream can pull data that is already available from upstream and upstream can push data to downstream when data becomes available at a later time.

Flux<String> bridge = Flux.create(sink -> {
    myMessageProcessor.register(
      new MyMessageListener<String>() {

        public void onMessage(List<String> messages) {
          for(String s : messages) {
            sink.next(s); (3)
          }
        }
    });
    sink.onRequest(n -> {
        List<String> messages = myMessageProcessor.request(n); (1)
        for(String s : message) {
           sink.next(s); (2)
        }
    });
1 Poll for messages when requests are made.
2 If messages are available immediately, push them to the sink.
3 The remaining messages that arrive asynchronously later are also delivered.
Cleaning up

Two callbacks, onDispose and onCancel, perform any cleanup on cancellation or termination. onDispose can be used to perform cleanup when the Flux completes, errors out, or is cancelled. 'onCancel can be used to perform any action specific to cancellation prior to cleanup with onDispose.

Flux<String> bridge = Flux.create(sink -> {
    sink.onRequest(n -> channel.poll(n))
        .onCancel(() -> channel.cancel()) (1)
        .onDispose(() -> channel.close())  (2)
    });
1 onCancel is invoked for cancel signal.
2 onDispose is invoked for complete, error, or cancel.

4.4.3. Handle

The handle method is a bit different. It is present in both Mono and Flux. Also, it is an instance method, meaning that it is chained on an existing source (as are the common operators).

It is close to generate, in the sense that it uses a SynchronousSink and only allows one-by-one emissions. However, handle can be used to generate an arbitrary value out of each source element, possibly skipping some elements. In this way, it can serve as a combination of map and filter. The signature of handle is as follows:

handle(BiConsumer<T, SynchronousSink<R>>)

Let’s consider an example. The reactive streams specification disallows null values in a sequence. What if you want to perform a map but you want to use a preexisting method as the map function, and that method sometimes returns null?

For instance, the following method can be applied safely to a source of integers:

public String alphabet(int letterNumber) {
        if (letterNumber < 1 || letterNumber > 26) {
                return null;
        }
        int letterIndexAscii = 'A' + letterNumber - 1;
        return "" + (char) letterIndexAscii;
}

We can then use handle to remove any nulls:

Using handle for a "map and eliminate nulls" scenario
Flux<String> alphabet = Flux.just(-1, 30, 13, 9, 20)
    .handle((i, sink) -> {
        String letter = alphabet(i); (1)
        if (letter != null) (2)
            sink.next(letter); (3)
    });

alphabet.subscribe(System.out::println);
1 Map to letters.
2 If the "map function" returns null…​.
3 Filter it out by not calling sink.next.

Which will print out:

M
I
T

4.5. Schedulers

Reactor, like RxJava, can be considered concurrency agnostic. That is, it does not enforce a concurrency model. Rather it leaves you, the developer, in command. However, that does not prevent the library from helping you with concurrency.

In Reactor, the execution model and where the execution happens is determined by the Scheduler that is used. A Scheduler is an interface that can abstract a wide range of implementations. The Schedulers class has static methods that give access to the following execution contexts:

  • The current thread (Schedulers.immediate()).

  • A single, reusable thread (Schedulers.single()). Note that this method reuses the same thread for all callers, until the Scheduler is disposed. If you want a per-call dedicated thread, use Schedulers.newSingle() for each call.

  • An elastic thread pool (Schedulers.elastic()). It creates new worker pools as needed, and reuse idle ones. Worker pools that stay idle for too long (default is 60s) are disposed. This is a good choice for I/O blocking work for instance. Schedulers.elastic() is a handy way to give a blocking process its own thread, so that it does not tie up other resources. See How do I wrap a synchronous, blocking call?.

  • a fixed pool of workers that is tuned for parallel work (Schedulers.parallel()). It creates as many workers as you have CPU cores.

While elastic is made to help with legacy blocking code if it cannot be avoided, single and parallel are not. As a consequence, the use of Reactor blocking APIs (block(), blockFirst(), blockLast(), toIterable() and toStream()) inside the default single and parallel Schedulers will result in an IllegalStateException being thrown.

Custom Schedulers can also be marked as "non blocking only" by creating instances of Thread that implement the NonBlocking marker interface.

Additionally, you can create a Scheduler out of any pre-existing ExecutorService by using Schedulers.fromExecutorService(ExecutorService). (You can also create one from an Executor, although doing so is discouraged.) You can also create new instances of the various scheduler types by using the newXXX methods. For example, Schedulers.newElastic(yourScheduleName) creates a new elastic scheduler named yourScheduleName.

Operators are implemented using non-blocking algorithms tuned to facilitate the work stealing that can happen in some Schedulers.

Some operators use a specific Scheduler from Schedulers by default (and usually give you the option of providing a different one). For instance, calling the factory method Flux.interval(Duration.ofMillis(300)) produces a Flux<Long> that ticks every 300ms. By default, this is enabled by Schedulers.parallel(). The following line changes the Scheduler to a new instance similar to Schedulers.single():

Flux.interval(Duration.ofMillis(300), Schedulers.newSingle("test"))

Reactor offers two means of switching the execution context (or Scheduler) in a reactive chain: publishOn and subscribeOn. Both take a Scheduler and let you switch the execution context to that scheduler. But the placement of publishOn in the chain matters, while the placement of subscribeOn does not. To understand that difference, you first have to remember that nothing happens until you subscribe().

In Reactor, when you chain operators, you can wrap as many Flux and Mono implementations inside one another as you need. Once you subscribe, a chain of Subscriber objects is created, backward (up the chain) to the first publisher. This is effectively hidden from you. All you can see is the outer layer of Flux (or Mono) and Subscription, but these intermediate operator-specific subscribers are where the real work happens.

With that knowledge, we can have a closer look at the publishOn and subscribeOn operators:

  • publishOn applies in the same way as any other operator, in the middle of the subscriber chain. It takes signals from upstream and replays them downstream while executing the callback on a worker from the associated Scheduler. Consequently, it affects where the subsequent operators will execute (until another publishOn is chained in).

  • subscribeOn applies to the subscription process, when that backward chain is constructed. As a consequence, no matter where you place the subscribeOn in the chain, it always affects the context of the source emission. However, this does not affect the behavior of subsequent calls to publishOn. They still switch the execution context for the part of the chain after them.

Only the earliest subscribeOn call in the chain is actually taken into account.

4.6. Threading

Flux and Mono do not create threads. Some operators, such as publishOn, do create threads. Also, as a form of work sharing, these operators can "steal" threads from other work pools if the other pools are currently idle. Consequently, neither the Flux or Mono objects nor the Subscriber objects have to be smart about threads. They rely on the operators to manage the threads and work pools.

publishOn forces the next operator (and possibly subsequent operators after the next one) to run on a different thread. Similarly, subscribeOn forces the previous operator (and possibly operators prior to the previous one) to run on a different thread. Remember that, until you subscribe, you define a process but do not start it. For that reason, Reactor can use these rules to determine how the processing must proceed. Then, when you subscribe, the whole process starts working.

Consider an example showing that multiple threads can support work sharing:

Flux.range(1, 10000) (1)
    .publishOn(Schedulers.parallel()) (2)
    .subscribe(result) (3)
1 Create a Flux for 10,000 items
2 Create as many threads as there are CPUs (minimum 4).
3 Nothing Happens Until You subscribe().

Scheduler.parallel() creates a fixed pool of single-threaded ExecutorService-based workers. Because one or two threads may lead to problems, it always creates at least four threads. The publishOn method then shares these threaded workers, getting items from whichever thread is emitting when publishOn requests an item. In this fashion, we get work sharing (a form of resource sharing). Reactor enables several other ways to share for resources as well, as documented in Schedulers.

Scheduler.elastic() also creates threads and is a handy way to create a dedicated thread in the case of wrapping a blocking resource (such as a synchronous service). See How do I wrap a synchronous, blocking call?.

Behind the scenes, the operators ensure thread safety by using incremental counters and guard conditions. For instance, if we have four threads hitting a single stream (as shown in the preceding example) each request increments a counter, so that future requests from the threads get the right item.

4.7. Handling Errors

For a quick look at the available operators for error handling, see the relevant operator decision tree.

In Reactive Streams, errors are terminal events. As soon as an error occurs, it stops the sequence and gets propagated down the chain of operators to the last step, the Subscriber you defined and its onError method.

Such errors should still be dealt with at the application level. For instance, you might display an error notification in a UI or send a meaningful error payload in a REST endpoint. For this reason, the subscriber’s onError method should always be defined.

If not defined, onError throws an UnsupportedOperationException. You can further detect and triage it with the Exceptions.isErrorCallbackNotImplemented method.

Reactor also offers alternative means of dealing with errors in the middle of the chain, as error-handling operators.

Before you learn about error-handling operators, you must keep in mind that any error in a reactive sequence is a terminal event. Even if an error-handling operator is used, it does not allow the original sequence to continue. Rather, it converts the onError signal into the start of a new sequence (the fallback one). In other words, it replaces the terminated sequence upstream.

Now we can consider each means of error handling one-by-one. When relevant, we make a parallel with imperative programming’s try patterns.

4.7.1. Error Handling Operators

You may be familiar with several ways of dealing with exceptions in a try-catch block. Most notably, these include the following:

  1. Catch and return a static default value.

  2. Catch and execute an alternative path with a fallback method.

  3. Catch and dynamically compute a fallback value.

  4. Catch, wrap to a BusinessException, and re-throw.

  5. Catch, log an error-specific message, and re-throw.

  6. Use the finally block to clean up resources or a Java 7 "try-with-resource" construct.

All of these have equivalents in Reactor, in the form of error-handling operators.

Before looking into these operators, we first establish a parallel between a reactive chain and a try-catch block.

When subscribing, the onError callback at the end of the chain is akin to a catch block. There, execution skips to the catch in case an Exception is thrown:

Flux<String> s = Flux.range(1, 10)
    .map(v -> doSomethingDangerous(v)) (1)
    .map(v -> doSecondTransform(v)); (2)
s.subscribe(value -> System.out.println("RECEIVED " + value), (3)
            error -> System.err.println("CAUGHT " + error) (4)
);
1 A transformation is performed that can throw an exception.
2 If everything went well, a second transformation is performed.
3 Each successfully transformed value is printed out.
4 In case of an error, the sequence terminates and an error message is displayed.

This is conceptually similar to the following try/catch block:

try {
    for (int i = 1; i < 11; i++) {
        String v1 = doSomethingDangerous(i); (1)
        String v2 = doSecondTransform(v1); (2)
        System.out.println("RECEIVED " + v2);
    }
} catch (Throwable t) {
    System.err.println("CAUGHT " + t); (3)
}
1 If an exception is thrown here…​
2 …​the rest of the loop is skipped…​
3 …​the execution goes straight to here.

Now that we have established a parallel, we’ll look at the different error handling cases and their equivalent operators.

Static Fallback Value

The equivalent of (1) (catch and return a static default value) is onErrorReturn:

Flux.just(10)
    .map(this::doSomethingDangerous)
    .onErrorReturn("RECOVERED");

You also have the option of filtering (choosing) when to recover with a default value versus letting the error propagate, depending on the exception that occurred:

Flux.just(10)
    .map(this::doSomethingDangerous)
    .onErrorReturn(e -> e.getMessage().equals("boom10"), "recovered10");
Fallback Method

If you want more than a single default value and you have an alternative safer way of processing your data, you can use onErrorResume. This would be the equivalent of (2) (catch and execute an alternative path with a fallback method).

For example, if your nominal process is fetching data from an external and unreliable service, but you also keep a local cache of the same data that can be a bit more out of date but is more reliable, you could do the following:

Flux.just("key1", "key2")
    .flatMap(k -> callExternalService(k)) (1)
    .onErrorResume(e -> getFromCache(k)); (2)
1 For each key, we asynchronously call the external service.
2 If the external service call fails, we fallback to the cache for that key. Note that we always apply the same fallback, whatever the source error, e, is.

Like onErrorReturn, onErrorResume has variants that let you filter which exceptions to fallback on, based either on the exception’s class or a Predicate. The fact that it takes a Function also allows you to choose a different fallback sequence to switch to, depending on the error encountered:

Flux.just("timeout1", "unknown", "key2")
    .flatMap(k -> callExternalService(k))
    .onErrorResume(error -> { (1)
        if (error instanceof TimeoutException) (2)
            return getFromCache(k);
        else if (error instanceof UnknownKeyException)  (3)
            return registerNewEntry(k, "DEFAULT");
        else
            return Flux.error(error); (4)
    });
1 The function allows dynamically choosing how to continue.
2 If the source times out, hit the local cache.
3 If the source says the key is unknown, create a new entry.
4 In all other cases, "re-throw".
Dynamic Fallback Value

Even if you do not have an alternative safer way of processing your data, you might want to compute a fallback value out of the exception you received. This would be the equivalent of (3) (catch and dynamically compute a fallback value).

For instance, if your return type has a variant dedicated to holding an exception (think Future.complete(T success) vs Future.completeExceptionally(Throwable error)), you could instantiate the error-holding variant and pass the exception.

This can be done in the same way as the fallback method solution, using onErrorResume. You need a tiny bit of boilerplate:

erroringFlux.onErrorResume(error -> Mono.just( (1)
        myWrapper.fromError(error) (2)
));
1 The boilerplate creates a Mono from Mono.just with onErrorResume.
2 You then wrap the exception into the ad hoc class or otherwise compute the value out of the exception.
Catch and Rethrow

In the "fallback method" example, the last line inside the flatMap gives us a hint as to how item (4) (Catch, wrap to a BusinessException, and re-throw) could be achieved:

Flux.just("timeout1")
    .flatMap(k -> callExternalService(k))
    .onErrorResume(original -> Flux.error(
        new BusinessException("oops, SLA exceeded", original)
    );

However, there is a more straightforward way of achieving the same with onErrorMap:

Flux.just("timeout1")
    .flatMap(k -> callExternalService(k))
    .onErrorMap(original -> new BusinessException("oops, SLA exceeded", original));
Log or React on the Side

For cases where you want the error to continue propagating but you still want to react to it without modifying the sequence (logging it, for instance) there is the doOnError operator. This is the equivalent of (5) (Catch, log an error-specific message, and re-throw). This operator, as well as all operators prefixed with doOn , are sometimes referred to as a "side-effect". They let you peek inside the sequence’s events without modifying them.

The following example ensures that, when we fallback to the cache, we at least log that the external service had a failure. We can also imagine we have statistic counters to increment as an error side-effect.

LongAdder failureStat = new LongAdder();
Flux<String> flux =
Flux.just("unknown")
    .flatMap(k -> callExternalService(k)) (1)
    .doOnError(e -> {
        failureStat.increment();
        log("uh oh, falling back, service failed for key " + k); (2)
    })
    .onErrorResume(e -> getFromCache(k)); (3)
1 The external service call that can fail…​
2 …​is decorated with a logging side-effect…​
3 …​and then protected with the cache fallback.
Using Resources and the Finally Block

The last parallel to draw with imperative programming is the cleaning up that can be done either via a Java 7 "try-with-resources" construct or the use of the finally block. This is the equivalent of (6) (use the finally block to clean up resources or a Java 7 "try-with-resource" construct). Both have their Reactor equivalents, using and doFinally:

AtomicBoolean isDisposed = new AtomicBoolean();
Disposable disposableInstance = new Disposable() {
    @Override
    public void dispose() {
        isDisposed.set(true); (4)
    }

    @Override
    public String toString() {
        return "DISPOSABLE";
    }
};

Flux<String> flux =
Flux.using(
        () -> disposableInstance, (1)
        disposable -> Flux.just(disposable.toString()), (2)
        Disposable::dispose (3)
);
1 The first lambda generates the resource. Here we return our mock Disposable.
2 The second lambda processes the resource, returning a Flux<T>.
3 The third lambda is called when the Flux from 2) terminates or is cancelled, to clean up resources.
4 After subscription and execution of the sequence, the isDisposed atomic boolean would become true.

On the other hand, doFinally is about side-effects that you want to be executed whenever the sequence terminates, whether with onComplete, onError, or cancellation. It gives you a hint as to what kind of termination triggered the side-effect:

LongAdder statsCancel = new LongAdder(); (1)

Flux<String> flux =
Flux.just("foo", "bar")
    .doFinally(type -> {
        if (type == SignalType.CANCEL) (2)
          statsCancel.increment(); (3)
    })
    .take(1); (4)
1 We assume we want to gather statistics. Here we use a LongAdder.
2 doFinally consumes a SignalType for the type of termination.
3 Here we increment statistics in case of cancellation only.
4 take(1) will cancel after 1 item is emitted.
Demonstrating the Terminal Aspect of onError

In order to demonstrate that all these operators cause the upstream original sequence to terminate when the error happens, we can use a more visual example with a Flux.interval. The interval operator ticks every x units of time with an increasing Long value:

Flux<String> flux =
Flux.interval(Duration.ofMillis(250))
    .map(input -> {
        if (input < 3) return "tick " + input;
        throw new RuntimeException("boom");
    })
    .onErrorReturn("Uh oh");

flux.subscribe(System.out::println);
Thread.sleep(2100); (1)
1 Note that interval executes on a timer Scheduler by default. Assuming we want to run that example in a main class, we add a sleep call here so that the application does not exit immediately without any value being produced.

This prints out one line every 250ms, as follows:

tick 0
tick 1
tick 2
Uh oh

Even with one extra second of runtime, no more tick comes in from the interval. The sequence was indeed terminated by the error.

Retrying

There is another operator of interest with regards to error handling, and you might be tempted to use it in the case above. retry, as its name indicates, lets you retry an error-producing sequence.

The trouble is that it works by re-subscribing to the upstream Flux. This is really a different sequence, and the original one is still terminated. To verify that, we can re-use the previous example and append a retry(1) to retry once instead of using onErrorReturn:

Flux.interval(Duration.ofMillis(250))
    .map(input -> {
        if (input < 3) return "tick " + input;
        throw new RuntimeException("boom");
    })
    .elapsed() (1)
    .retry(1)
    .subscribe(System.out::println, System.err::println); (2)

Thread.sleep(2100); (3)
1 elapsed associates each value with the duration since previous value was emitted.
2 We also want to see when there is an onError.
3 Ensure we have enough time for our 4x2 ticks.

This produces the following output:

259,tick 0
249,tick 1
251,tick 2
506,tick 0 (1)
248,tick 1
253,tick 2
java.lang.RuntimeException: boom
1 A new interval started, from tick 0. The additional 250ms duration is coming from the 4th tick, the one that causes the exception and subsequent retry.

As you can see above, retry(1) merely re-subscribed to the original interval once, restarting the tick from 0. The second time around, since the exception still occurs, it gives up and propagates the error downstream.

There is a more advanced version of retry (called retryWhen) that uses a "companion" Flux to tell whether or not a particular failure should retry. This companion Flux is created by the operator but decorated by the user, in order to customize the retry condition.

The companion Flux is a Flux<Throwable> that gets passed to a Function, the sole parameter of retryWhen. As the user, you define that function and make it return a new Publisher<?>. Retry cycles will go like this:

  1. Each time an error happens (potential for a retry), the error is emitted into the companion Flux, which has been decorated by your function.

  2. If the companion Flux emits something, a retry happens.

  3. If the companion Flux completes, the retry cycle stops and the original sequence completes too.

  4. If the companion Flux produces an error, the retry cycle stops and the original sequence also stops or completes, and the error causes the original sequence to fail and terminate.

The distinction between the previous two cases is important. Simply completing the companion would effectively swallow an error. Consider the following way of emulating retry(3) using retryWhen:

Flux<String> flux = Flux
    .<String>error(new IllegalArgumentException()) (1)
    .doOnError(System.out::println) (2)
    .retryWhen(companion -> companion.take(3)); (3)
1 This continuously produces errors, calling for retry attempts.
2 doOnError before the retry will let us see all failures.
3 Here, we consider the first 3 errors as retry-able (take(3)) and then give up.

In effect, this results in an empty Flux, but it completes successfully. Since retry(3) on the same Flux would have terminated with the latest error, this retryWhen example is not exactly the same as a retry(3).

Getting to the same behavior involves a few additional tricks:

Flux<String> flux =
Flux.<String>error(new IllegalArgumentException())
    .retryWhen(companion -> companion
    .zipWith(Flux.range(1, 4), (1)
          (error, index) -> { (2)
            if (index < 4) return index; (3)
            else throw Exceptions.propagate(error); (4)
          })
    );
1 Trick one: use zip and a range of "number of acceptable retries + 1".
2 The zip function lets you count the retries while keeping track of the original error.
3 To allow for three retries, indexes before 4 return a value to emit.
4 In order to terminate the sequence in error, we throw the original exception after these three retries.
Similar code can be used to implement an exponential backoff and retry pattern, as shown in the FAQ.

4.7.2. Handling Exceptions in Operators or Functions

In general, all operators can themselves contain code that potentially trigger an exception or calls to a user-defined callback that can similarly fail, so they all contain some form of error handling.

As a rule of thumb, an Unchecked Exception is always propagated through onError. For instance, throwing a RuntimeException inside a map function translates to an onError event, as shown in the following code:

Flux.just("foo")
    .map(s -> { throw new IllegalArgumentException(s); })
    .subscribe(v -> System.out.println("GOT VALUE"),
               e -> System.out.println("ERROR: " + e));

The preceding code prints out:

ERROR: java.lang.IllegalArgumentException: foo
The Exception can be tuned before it is passed to onError, through the use of a hook.

Reactor, however, defines a set of exceptions (such as OutOfMemoryError) that are always deemed fatal. See the Exceptions.throwIfFatal method. These errors mean that Reactor cannot keep operating and are thrown rather than propagated.

Internally, there are also cases where an unchecked exception still cannot be propagated (most notably during the subscribe and request phases), due to concurrency races that could lead to double onError or onComplete conditions. When these races happen, the error that cannot be propagated is "dropped". These cases can still be managed to some extent via customizable hooks, see Dropping Hooks.

You may ask: "What about Checked Exceptions?"

If, for example, you need to call some method that declares it throws exceptions, you still have to deal with those exceptions in a try-catch block. You have several options, though:

  1. Catch the exception and recover from it. The sequence continues normally.

  2. Catch the exception and wrap it into an unchecked exception, then throw it (interrupting the sequence). The Exceptions utility class can help you with that (we get to that next).

  3. If you are expected to return a Flux (for example, you are in a flatMap), wrap the exception in an error-producing Flux: return Flux.error(checkedException). (The sequence also terminates.)

Reactor has an Exceptions utility class that you can use to ensure that exceptions are wrapped only if they are checked exceptions:

  • Use the Exceptions.propagate method to wrap exceptions, if necessary. It also calls throwIfFatal first and does not wrap RuntimeException.

  • Use the Exceptions.unwrap method to get the original unwrapped exception (going back to the root cause of a hierarchy of reactor-specific exceptions).

Consider an example of a map that uses a conversion method that can throw an IOException:

public String convert(int i) throws IOException {
    if (i > 3) {
        throw new IOException("boom " + i);
    }
    return "OK " + i;
}

Now imagine that you want to use that method in a map. You must now explicitly catch the exception, and your map function cannot re-throw it. So you can propagate it to the map’s onError method as a RuntimeException:

Flux<String> converted = Flux
    .range(1, 10)
    .map(i -> {
        try { return convert(i); }
        catch (IOException e) { throw Exceptions.propagate(e); }
    });

Later on, when subscribing to the above Flux and reacting to errors (such as in the UI), you could revert back to the original exception in case you want to do something special for IOExceptions, as shown in the following example:

converted.subscribe(
    v -> System.out.println("RECEIVED: " + v),
    e -> {
        if (Exceptions.unwrap(e) instanceof IOException) {
            System.out.println("Something bad happened with I/O");
        } else {
            System.out.println("Something bad happened");
        }
    }
);

4.8. Processors

Processors are a special kind of Publisher that are also a Subscriber. That means that you can subscribe to a Processor (generally, they implement Flux), but you can also call methods to manually inject data into the sequence or terminate it.

There are several kinds of Processors, each with a few particular semantics, but before you start looking into these, you need to ask yourself the following question:

4.8.1. Do I Need a Processor?

Most of the time, you should try to avoid using a Processor. They are harder to use correctly and prone to some corner cases.

If you think a Processor could be a good match for your use case, ask yourself if you have tried these two alternatives:

  1. Could an operator or combination of operators fit the bill? (See Which operator do I need?)

  2. Could a "generator" operator work instead? (Generally, these operators are made to bridge APIs that are not reactive, providing a "sink" that is similar in concept to a Processor in the sense that it lets you populate the sequence with data or terminate it).

If, after exploring the above alternatives, you still think you need a Processor, read the Overview of Available Processors section below to learn about the different implementations.

4.8.2. Safely Produce from Multiple Threads by Using the Sink Facade

Rather than directly using Reactor Processors, it is a good practice to obtain a Sink for the Processor by calling sink() once.

FluxProcessor sinks safely gate multi-threaded producers and can be used by applications that generate data from multiple threads concurrently. For example, a thread-safe serialized sink can be created for UnicastProcessor:

UnicastProcessor<Integer> processor = UnicastProcessor.create();
FluxSink<Integer> sink = processor.sink(overflowStrategy);

Multiple producer threads may concurrently generate data on the following serialized sink:

sink.next(n);

Overflow from next behaves in two possible ways, depending on the Processor and its configuration:

  • An unbounded processor handles the overflow itself by dropping or buffering.

  • A bounded processor blocks or "spins" on the IGNORE strategy or applies the overflowStrategy behavior specified for the sink.

4.8.3. Overview of Available Processors

Reactor Core comes with several flavors of Processor. Not all processors have the same semantics but are roughly split into three categories. The following list briefly describes the three kinds of processors:

  • direct (DirectProcessor and UnicastProcessor): These processors can only push data through direct user action (calling their Sink's methods directly).

  • synchronous (EmitterProcessor and ReplayProcessor): These processors can push data both through user action and by subscribing to an upstream Publisher and synchronously draining it.

  • asynchronous (WorkQueueProcessor and TopicProcessor): These processors can push data obtained from multiple upstream Publishers. They are more robust and are backed by a RingBuffer data structure in order to deal with their multiple upstreams.

The asynchronous processors are the most complex to instantiate, with a lot of different options. Consequently, they expose a Builder interface. The simpler processors have static factory methods instead.

DirectProcessor

A DirectProcessor is a processor that can dispatch signals to zero to many Subscribers. It is the simplest one to instantiate, with a single create() static factory method. On the other hand, it has the limitation of not handling backpressure. As a consequence, a DirectProcessor signals an IllegalStateException to its subscribers if you push N elements through it but at least one of its subscribers has requested less than N.

Once the Processor has terminated (usually through its Sink error(Throwable) or complete() methods being called), it lets more subscribers subscribe but replays the termination signal to them immediately.

UnicastProcessor

A UnicastProcessor can deal with backpressure using an internal buffer. The trade-off is that it can have at most one Subscriber.

A UnicastProcessor has a few more options, reflected by a few create static factory methods. For instance, by default it is unbounded: if you push any amount of data through it while its Subscriber has not yet requested data, it will buffer all of the data.

This can be changed by providing a custom Queue implementation for the internal buffering in the create factory method. If that queue is bounded, the processor could reject the push of a value when the buffer is full and not enough requests from downstream have been received.

In that bounded case, the processor can also be built with a callback that is invoked on each rejected element, allowing for cleanup of these rejected elements.

EmitterProcessor

An EmitterProcessor is capable of emitting to several subscribers, while honoring backpressure for each of its subscribers. It can also subscribe to a Publisher and relay its signals synchronously.

Initially, when it has no subscriber, it can still accept a few data pushes up to a configurable bufferSize. After that point, if no Subscriber has come in and consumed the data, calls to onNext block until the processor is drained (which can only happen concurrently by then).

Thus, the first Subscriber to subscribe receives up to bufferSize elements upon subscribing. However, after that, the processor stops replaying signals to additional subscribers. These subsequent subscribers instead only receive the signals pushed through the processor after they have subscribed. The internal buffer is still used for backpressure purposes.

By default, if all of its subscribers are cancelled (which basically means they have all un-subscribed), it will clear its internal buffer and stop accepting new subscribers. This can be tuned by the autoCancel parameter in the create static factory methods.

ReplayProcessor

A ReplayProcessor caches elements that are either pushed directly through its Sink or elements from an upstream Publisher and replays them to late subscribers.

It can be created in multiple configurations:

  • Caching a single element (cacheLast).

  • Caching a limited history (create(int)), unbounded history (create()).

  • Caching time-based replay window (createTimeout(Duration)).

  • Caching combination of history size and time window (createSizeOrTimeout(int, Duration)).

TopicProcessor

A TopicProcessor is an asynchronous processor capable of relaying elements from multiple upstream Publishers when created in the shared configuration (see the share(boolean) option of the builder()).

Note that the share option is mandatory if you intend to concurrently call TopicProcessor's onNext, onComplete, or onError methods directly or from a concurrent upstream Publisher.

Otherwise, such concurrent calls are illegal, as the processor is then fully compliant with the Reactive Streams specification.

A TopicProcessor is capable of fanning out to multiple Subscribers. It does so by associating a Thread to each Subscriber, which will run until an onError or onComplete signal is pushed through the processor or until the associated Subscriber is cancelled. The maximum number of downstream subscribers is driven by the executor builder option. Provide a bounded ExecutorService to limit it to a specific number.

The processor is backed by a RingBuffer data structure that stores pushed signals. Each Subscriber thread keeps track of its associated demand and the correct indexes in the RingBuffer.

This processor also has an autoCancel builder option: If set to true (the default), it results in the source Publisher(s) being cancelled when all subscribers are cancelled.

WorkQueueProcessor

A WorkQueueProcessor is also an asynchronous processor capable of relaying elements from multiple upstream Publishers when created in the shared configuration (it shares most of its builder options with TopicProcessor).

It relaxes its compliance with the Reactive Streams specification, but it acquires the benefit of requiring fewer resources than the TopicProcessor. It is still based on a RingBuffer but avoids the overhead of creating one consumer Thread per Subscriber. As a result, it scales better than the TopicProcessor.

The trade-off is that its distribution pattern is a little bit different: Requests from each subscriber all add up together, and the processor relays signals to only one Subscriber at a time, in a kind of round-robin distribution rather than fan-out pattern.

A fair round-robin distribution is not guaranteed.

The WorkQueueProcessor mostly has the same builder options as the TopicProcessor, such as autoCancel, share, and waitStrategy. The maximum number of downstream subscribers is also driven by a configurable ExecutorService with the executor option.

You should take care not to subscribe too many Subscribers to a WorkQueueProcessor, as doing so could lock the processor. If you need to limit the number of possible subscribers, prefer doing so by using a ThreadPoolExecutor or a ForkJoinPool. The processor can detect their capacity and throw an exception if you subscribe one too many times.

5. Kotlin support

5.1. Introduction

Kotlin is a statically-typed language targeting the JVM (and other platforms) which allows writing concise and elegant code while providing a very good interoperability with existing libraries written in Java.

Reactor 3.1 introduces first-class support for Kotlin which is described in this section.

5.2. Requirements

Reactor supports Kotlin 1.1+ and requires kotlin-stdlib (or one of its kotlin-stdlib-jre7 / kotlin-stdlib-jre8 variants).

5.3. Extensions

Thanks to its great Java interoperability and to Kotlin extensions, Reactor Kotlin APIs leverage regular Java APIs and are additionally enhanced by a few Kotlin specific APIs available out of the box within Reactor artifacts.

Keep in mind that Kotlin extensions need to be imported to be used. This means for example that the Throwable.toFlux Kotlin extension will only be available if import reactor.core.publisher.toFlux is imported. That said, similar to static imports, an IDE should automatically suggest the import in most cases.

For example, Kotlin reified type parameters provide a workaround for JVM generics type erasure, and Reactor provides some extensions to take advantage of this feature.

You can see bellow a quick comparison of Reactor with Java versus Reactor with Kotlin + extensions.

Java

Kotlin with extensions

Mono.just("foo")

"foo".toMono()

Flux.fromIterable(list)

list.toFlux()

Mono.error(new RuntimeException())

RuntimeException().toMono()

Flux.error(new RuntimeException())

RuntimeException().toFlux()

flux.ofType(Foo.class)

flux.ofType<Foo>() or flux.ofType(Foo::class)

StepVerifier.create(flux).verifyComplete()

flux.test().verifyComplete()

Reactor KDoc API lists and documents all the Kotlin extensions available.

5.4. Null-safety

One of Kotlin’s key features is null-safety - which cleanly deals with null values at compile time rather than bumping into the famous NullPointerException at runtime. This makes applications safer through nullability declarations and expressing "value or no value" semantics without paying the cost of wrappers like Optional. (Kotlin allows using functional constructs with nullable values; check out this comprehensive guide to Kotlin null-safety.)

Although Java does not allow one to express null-safety in its type-system, Reactor now provides null-safety of the whole Reactor API via tooling-friendly annotations declared in the reactor.util.annotation package. By default, types from Java APIs used in Kotlin are recognized as platform types for which null-checks are relaxed. Kotlin support for JSR 305 annotations + Reactor nullability annotations provide null-safety for the whole Reactor API to Kotlin developers, with the advantage of dealing with null related issues at compile time.

The JSR 305 checks can be configured by adding the -Xjsr305 compiler flag with the following options: -Xjsr305={strict|warn|ignore}.

For kotlin versions 1.1.50+, the default behavior is the same to -Xjsr305=warn. The strict value is required to have Reactor API full null-safety taken in account but should be considered experimental since Reactor API nullability declaration could evolve even between minor releases and more checks may be added in the future).

Generic type arguments, varargs and array elements nullability are not supported yet, but should be in an upcoming release, see this dicussion for up-to-date information.

6. Testing

Whether you have written a simple chain of Reactor operators or your own operator, automated testing is always a good idea.

Reactor comes with a few elements dedicated to testing, gathered into their own artifact: reactor-test. You can find that project on Github, inside of the reactor-core repository.

To use it in your tests, add it as a test dependency:

reactor-test in Maven, in <dependencies>
<dependency>
    <groupId>io.projectreactor</groupId>
    <artifactId>reactor-test</artifactId>
    <scope>test</scope>
    (1)
</dependency>
1 If you use the BOM, you do not need to specify a <version>.
reactor-test in Gradle, amend the dependencies block
dependencies {
   testCompile 'io.projectreactor:reactor-test'
}

The two main uses of reactor-test are:

  • Testing that a sequence follows a given scenario, step-by-step, with StepVerifier.

  • Producing data in order to test the behavior of operators (including you own operators) downstream with TestPublisher.

6.1. Testing a Scenario with StepVerifier

The most common case for testing a Reactor sequence is to have a Flux or Mono defined in your code (for example, it might be returned by a method) and wanting to test how it behaves when subscribed to.

This situation translates well to defining a "test scenario", where you define your expectations in terms of events, step-by-step: what is the next expected event? Do you expect the Flux to emit a particular value? Or maybe to do nothing for the next 300ms? All of that can be expressed through the StepVerifier API.

For instance, you could have the following utility method in your codebase that decorates a Flux:

public <T> Flux<T> appendBoomError(Flux<T> source) {
  return source.concatWith(Mono.error(new IllegalArgumentException("boom")));
}

In order to test it, you want to verify the following scenario:

I expect this Flux to first emit foo, then emit bar, and then produce an error with the message, boom. Subscribe and verify these expectations.

In the StepVerifier API, this translates to the following test:

@Test
public void testAppendBoomError() {
  Flux<String> source = Flux.just("foo", "bar"); (1)

  StepVerifier.create( (2)
    appendBoomError(source)) (3)
    .expectNext("foo") (4)
    .expectNext("bar")
    .expectErrorMessage("boom") (5)
    .verify(); (6)
}
1 Since our method needs a source Flux, define a simple one for testing purposes.
2 Create a StepVerifier builder that wraps and verifies a Flux.
3 Pass the Flux to be tested (the result of calling our utility method).
4 The first signal we expect to happen upon subscription is an onNext, with a value of foo.
5 The last signal we expect to happen is a termination of the sequence with an onError. The exception should have boom as a message.
6 It is important to trigger the test by calling verify().

The API is a builder. You start by creating a StepVerifier and passing the sequence to be tested. This offers a choice of methods that allow you to:

  • Express expectations about the next signals to occur. If any other signal is received (or the content of the signal does not match the expectation), the whole test fails with a meaningful AssertionError. For example, you might use expectNext(T...) and expectNextCount(long).

  • Consume the next signal. This is used when you want to skip part of the sequence or when you want to apply a custom assertion on the content of the signal (for example, to check that there is an onNext event and assert that the emitted item is a list of size 5). For example, you might use consumeNextWith(Consumer<T>).

  • Take miscellaneous actions such as pausing or running arbitrary code. For example, if you want to manipulate a test-specific state or context. To that effect, you might use thenAwait(Duration) and then(Runnable).

For terminal events, the corresponding expectation methods (expectComplete() and expectError() and all their variants) switch to an API where you cannot express expectations anymore. In that last step, all you can do is perform some additional configuration on the StepVerifier and then trigger the verification, often with verify() or one of its variants.

What happens at this point is that the StepVerifier subscribes to the tested Flux or Mono and plays the sequence, comparing each new signal with the next step in the scenario. As long as these match, the test is considered a success. As soon as there is a discrepancy, an AssertionError is thrown.

Remember the verify() step, which triggers the verification. In order to help, the API includes a few shortcut methods that combine the terminal expectations with a call to verify(): verifyComplete(), verifyError(), verifyErrorMessage(String), and others.

Note that, if one of the lambda-based expectations throws an AssertionError, it is reported as is, failing the test. This is useful for custom assertions.

By default, the verify() method and derived shortcut methods (verifyThenAssertThat, verifyComplete(), etc.) has no timeout. It can block indefinitely. You can use StepVerifier.setDefaultTimeout(Duration) to globally set a timeout for these methods, or specify one on a per-call basis with verify(Duration).

6.1.1. Better identifying test failures

StepVerifier provides two options to better identify exactly which expectation step caused a test to fail:

  • as(String): this method can be used after most expect* methods to give a description to the preceding expectation. If the expectation fails, its error message will contain the description. Terminal expectations and verify cannot be described that way.

  • StepVerifierOptions.create().scenarioName(String): Using StepVerifierOptions to create you StepVerifier, you can use the scenarioName method to give the whole scenario a name, which will also be used in assertion error messages.

Note that in both cases, the use of the description/name in messages is only guaranteed for StepVerifier methods that produce their own AssertionError (eg. throwing an exception manually or through an assertion library in assertNext won’t add the description/name to said error’s message).

6.2. Manipulating Time

StepVerifier can be used with time-based operators to avoid long run times for corresponding tests. This is done through the StepVerifier.withVirtualTime builder.

It looks like the following example:

StepVerifier.withVirtualTime(() -> Mono.delay(Duration.ofDays(1)))
//... continue expectations here

This virtual time feature plugs in a custom Scheduler in Reactor’s Schedulers factory. Since these timed operators usually use the default Schedulers.parallel() scheduler, replacing it with a VirtualTimeScheduler does the trick. However, an important prerequisite is that the operator be instantiated after the virtual time scheduler has been activated.

In order to increase the chances this happens correctly, the StepVerifier does not take a simple Flux as input. withVirtualTime takes a Supplier, which allows for lazily creating the instance of the tested flux after having done the scheduler set up.

Take extra care to ensure the Supplier<Publisher<T>> can be used in a lazy fashion. Otherwise, virtual time is not guaranteed. Especially avoid instantiating the Flux earlier in the test code and having the Supplier return that variable. Instead, always instantiate the Flux inside the lambda.

There are two expectation methods that deal with time, and they are both valid with or without virtual time:

  • thenAwait(Duration) pauses the evaluation of steps (allowing a few signals to occur or delays to run out).

  • expectNoEvent(Duration) also lets the sequence play out for a given duration but fails the test if any signal occurs during that time.

Both methods pause the thread for the given duration in classic mode and advance the virtual clock instead in virtual mode.

expectNoEvent also considers the subscription as an event. If you use it as a first step, it usually fails because the subscription signal is detected. Use expectSubscription().expectNoEvent(duration) instead.

In order to quickly evaluate the behavior of our Mono.delay above, we can finish writing our code like this:

StepVerifier.withVirtualTime(() -> Mono.delay(Duration.ofDays(1)))
    .expectSubscription() (1)
    .expectNoEvent(Duration.ofDays(1)) (2)
    .expectNext(0) (3)
    .verifyComplete(); (4)
1 See the tip above.
2 Expect nothing to happen during a full day.
3 Then expect a delay that emits 0.
4 Then expect completion (and trigger the verification).

We could have used thenAwait(Duration.ofDays(1)) above, but expectNoEvent has the benefit of guaranteeing that nothing happened earlier than it should have.

Note that verify() returns a Duration value. This is the real-time duration of the entire test.

Virtual time is not a silver bullet. Keep in mind that all Schedulers are replaced with the same VirtualTimeScheduler. In some cases, you can lock the verification process because the virtual clock has not moved forward before an expectation is expressed, resulting in the expectation waiting on data that can only be produced by advancing time. In most cases, you need to advance the virtual clock for sequences to emit. Virtual time also gets very limited with infinite sequences, which might hog the thread on which both the sequence and its verification run.

6.3. Performing Post-execution Assertions with StepVerifier

After having described the final expectation of your scenario, you can switch to a complementary assertion API instead of triggering verify(). To do so, use verifyThenAssertThat() instead.

verifyThenAssertThat() returns a StepVerifier.Assertions object, which you can use to assert a few elements of state once the whole scenario has played out successfully (because it also calls verify()). Typical (albeit advanced) usage is to capture elements that have been dropped by some operator and assert them (see the section on Hooks).

6.4. Testing the Context

For more information about the Context, see Adding a Context to a Reactive Sequence.

StepVerifier comes with a couple of expectations around the propagation of a Context:

  • expectAccessibleContext: returns a ContextExpectations object that you can use to set up expectations on the propagated Context. Be sure to call then() to return to the set up of sequence expectations.

  • expectNoAccessibleContext: set up an expectation that NO Context can be propagated up the chain of operators under test. This most likely occurs when the Publisher under test is not a Reactor one, or doesn’t have any operator that can propagate the Context (e.g. just a generator source).

Additionally, one can associate a test-specific initial Context to a StepVerifier by using StepVerifierOptions to create the verifier.

These features are demonstrated in the following snippet:

StepVerifier.create(Mono.just(1).map(i -> i + 10),
                                StepVerifierOptions.create().withInitialContext(Context.of("foo", "bar"))) (1)
                            .expectAccessibleContext() (2)
                            .contains("foo", "bar") (3)
                            .then() (4)
                            .expectNext(11)
                            .verifyComplete(); (5)
1 Create the StepVerifier using StepVerifierOptions and pass in an initial Context
2 Start setting up expectations about Context propagation. This alone ensures that a Context was propagated.
3 An example of a Context-specific expectation: it must contain value "bar" for key "foo".
4 We then() switch back to setting up normal expectations on the data.
5 Let’s not forget to verify() the whole set of expectations.

6.5. Manually Emitting with TestPublisher

For more advanced test cases, it might be useful to have complete mastery over the source of data, in order to trigger finely chosen signals that closely match the particular situation you want to test.

Another situation is when you have implemented your own operator and you want to verify how it behaves with regards to the Reactive Streams specification, especially if its source is not well behaved.

For both cases, reactor-test offers the TestPublisher class. This is a Publisher<T> that lets you programmatically trigger various signals:

  • next(T) and next(T, T...) triggers 1-n onNext signals.

  • emit(T...) does the same and does complete().

  • complete() terminates with an onComplete signal.

  • error(Throwable) terminates with an onError signal.

A well behaved TestPublisher can be obtained through the create factory method. Also, a misbehaving TestPublisher can be created using the createNonCompliant factory method. The latter takes a value or multiple values from the TestPublisher.Violation enum. The values define which parts of the specification the publisher can overlook. These enum values include:

  • REQUEST_OVERFLOW: Allows next calls to be made despite an insufficient request, without triggering an IllegalStateException.

  • ALLOW_NULL: Allows next calls to be made with a null value without triggering a NullPointerException.

  • CLEANUP_ON_TERMINATE: Allows termination signals to be sent several times in a row. This includes complete(), error() and emit().

Finally, the TestPublisher keeps track of internal state after subscription, which can be asserted through its various assert* methods.

It can be used as a Flux or Mono by using the conversion methods flux() and mono().

6.6. Checking the Execution Path with PublisherProbe

When building complex chains of operators, you could come across cases where there are several possible execution paths, materialized by distinct sub-sequences.

Most of the time, these sub-sequences produce a specific-enough onNext signal that you can assert it was executed by looking at the end result.

For instance, consider the following method, which builds a chain of operators from a source and uses a switchIfEmpty to fallback to a particular alternative if the source is empty:

public Flux<String> processOrFallback(Mono<String> source, Publisher<String> fallback) {
    return source
            .flatMapMany(phrase -> Flux.fromArray(phrase.split("\\s+")))
            .switchIfEmpty(fallback);
}

It is easy enough to test which logical branch of the switchIfEmpty was used, as follows:

@Test
public void testSplitPathIsUsed() {
    StepVerifier.create(processOrFallback(Mono.just("just a  phrase with    tabs!"),
            Mono.just("EMPTY_PHRASE")))
                .expectNext("just", "a", "phrase", "with", "tabs!")
                .verifyComplete();
}

@Test
public void testEmptyPathIsUsed() {
    StepVerifier.create(processOrFallback(Mono.empty(), Mono.just("EMPTY_PHRASE")))
                .expectNext("EMPTY_PHRASE")
                .verifyComplete();
}

But think about an example where the method produces a Mono<Void> instead. It waits for the source to complete, performs an additional task, and completes. If the source is empty, a fallback Runnable-like task must be performed instead, as follows:

private Mono<String> executeCommand(String command) {
    return Mono.just(command + " DONE");
}

public Mono<Void> processOrFallback(Mono<String> commandSource, Mono<Void> doWhenEmpty) {
    return commandSource
            .flatMap(command -> executeCommand(command).then()) (1)
            .switchIfEmpty(doWhenEmpty); (2)
}
1 The then() forgets about the command result. It cares only that it was completed.
2 How to distinguish between two cases that both are empty sequences?

In order to verify that your processOrFallback indeed goes through the doWhenEmpty path, you need to write a bit of boilerplate. Namely you need a Mono<Void> that:

  • Captures the fact that it has been subscribed to

  • Lets you assert that fact after the whole processing has terminated.

Before version 3.1, you would need to manually maintain one AtomicBoolean per state you wanted to assert and attach a corresponding doOn* callback to the publisher you wanted to evaluate. This could be a lot of boilerplate when having to apply this pattern regularly. Fortunately, since 3.1.0 there’s an alternative with PublisherProbe, as follows:

@Test
public void testCommandEmptyPathIsUsed() {
    PublisherProbe<Void> probe = PublisherProbe.empty(); (1)

    StepVerifier.create(processOrFallback(Mono.empty(), probe.mono())) (2)
                .verifyComplete();

    probe.assertWasSubscribed(); (3)
    probe.assertWasRequested(); (4)
    probe.assertWasNotCancelled(); (5)
}
1 Create a probe that translates to an empty sequence.
2 Use the probe in place of Mono<Void> by calling probe.mono().
3 After completion of the sequence, the probe lets you assert that it was used. You can check that is was subscribed to…​
4 …​as well as actually requested for data…​
5 …​and whether or not it was cancelled.

You can also use the probe in place of a Flux<T> by calling .flux() instead of .mono(). For cases where you need to probe an execution path but also need the probe to emit data, you can wrap any Publisher<T> using PublisherProbe.of(Publisher).

7. Debugging Reactor

Switching from an imperative and synchronous programming paradigm to a reactive and asynchronous one can sometimes be daunting. One of the steepest steps in the learning curve is how to analyze and debug when something goes wrong.

In the imperative world, debugging is usually pretty straightforward: just read the stacktrace and you see where the problem originated and more: Was it entirely a failure of your code? Did the failure occur in some library code? If so, what part of your code called the library, potentially passing in improper parameters that ultimately caused the failure?

7.1. The Typical Reactor Stack Trace

When you shift to asynchronous code, things can get much more complicated.

Consider the following stack trace:

A typically Reactor stack trace
java.lang.IndexOutOfBoundsException: Source emitted more than one item
	at reactor.core.publisher.MonoSingle$SingleSubscriber.onNext(MonoSingle.java:129)
	at reactor.core.publisher.FluxFlatMap$FlatMapMain.tryEmitScalar(FluxFlatMap.java:445)
	at reactor.core.publisher.FluxFlatMap$FlatMapMain.onNext(FluxFlatMap.java:379)
	at reactor.core.publisher.FluxMapFuseable$MapFuseableSubscriber.onNext(FluxMapFuseable.java:121)
	at reactor.core.publisher.FluxRange$RangeSubscription.slowPath(FluxRange.java:154)
	at reactor.core.publisher.FluxRange$RangeSubscription.request(FluxRange.java:109)
	at reactor.core.publisher.FluxMapFuseable$MapFuseableSubscriber.request(FluxMapFuseable.java:162)
	at reactor.core.publisher.FluxFlatMap$FlatMapMain.onSubscribe(FluxFlatMap.java:332)
	at reactor.core.publisher.FluxMapFuseable$MapFuseableSubscriber.onSubscribe(FluxMapFuseable.java:90)
	at reactor.core.publisher.FluxRange.subscribe(FluxRange.java:68)
	at reactor.core.publisher.FluxMapFuseable.subscribe(FluxMapFuseable.java:63)
	at reactor.core.publisher.FluxFlatMap.subscribe(FluxFlatMap.java:97)
	at reactor.core.publisher.MonoSingle.subscribe(MonoSingle.java:58)
	at reactor.core.publisher.Mono.subscribe(Mono.java:3096)
	at reactor.core.publisher.Mono.subscribeWith(Mono.java:3204)
	at reactor.core.publisher.Mono.subscribe(Mono.java:3090)
	at reactor.core.publisher.Mono.subscribe(Mono.java:3057)
	at reactor.core.publisher.Mono.subscribe(Mono.java:3029)
	at reactor.guide.GuideTests.debuggingCommonStacktrace(GuideTests.java:995)

There is a lot going on there. We get an IndexOutOfBoundsException, which tells us that a "source emitted more than one item".

We can probably quickly come to assume that this source is a Flux/Mono, as confirmed by the line below that mentions MonoSingle. So it appears to be some sort of complaint from a single operator.

Referring to the Javadoc for Mono#single operator, we see that single has a contract: The source must emit exactly one element. It appears we had a source that emitted more than one and thus violated that contract.

Can we dig deeper and identify that source? The following rows are not very helpful. They take us on a travel inside the internals of what seems to be a reactive chain, through multiple calls to subscribe and request.

By skimming over these rows, we can at least start to form a picture of the kind of chain that went wrong: It seems to involve a MonoSingle, a FluxFlatMap, and a FluxRange (each gets several rows in the trace, but overall these three classes are involved). So a range().flatMap().single() chain maybe?

But what if we use that pattern a lot in our application? This still does not tell us much, and simply searching for single isn’t going to find the problem. Then the last line refers to some of our code. Finally, we are getting close.

Hold on, though. When we go to the source file, all we see is that a pre-existing Flux is subscribed to, as follows:

toDebug.subscribe(System.out::println, Throwable::printStackTrace);

All of this happened at subscription time, but the Flux itself was not declared there. Worse, when we go to where the variable is declared, we see:

public Mono<String> toDebug; //please overlook the public class attribute

The variable is not instantiated where it is declared. We must assume a worst-case scenario where we find out that there could be a few different code paths that set it in the application. We remain unsure of which one caused the issue.

This is kind of the Reactor equivalent of a runtime error, as opposed to a compilation error.

What we want to find out more easily is where the operator was added into the chain - that is, where the Flux was declared. We usually refer to that as the assembly of the Flux.

7.2. Activating Debug Mode

Even though the stacktrace was still able to convey some information for someone with a bit of experience, we can see that it is not ideal by itself in more advanced cases.

Fortunately, Reactor comes with a debugging-oriented capability of assembly-time instrumentation.

This is done by customizing the Hook.onOperator hook at application start (or at least before the incriminated Flux or Mono can be instantiated), as follows:

Hooks.onOperatorDebug();

This starts instrumenting the calls to the Flux (and Mono) operator methods (where they are assembled into the chain) by wrapping the construction of the operator and capturing a stacktrace there. Since this is done when the operator chain is declared, the hook should be activated before that, so the safest way is to activate it right at the start of your application.

Later on, if an exception occurs, the failing operator is able to refer to that capture and append it to the stack trace.

In the next section, we see how the stack trace differs and how to interpret that new information.

7.3. Reading a Stack Trace in Debug Mode

When we reuse our initial example but activate the operatorStacktrace debug feature, the stack trace is as follows:

java.lang.IndexOutOfBoundsException: Source emitted more than one item
	at reactor.core.publisher.MonoSingle$SingleSubscriber.onNext(MonoSingle.java:129)
	at reactor.core.publisher.FluxOnAssembly$OnAssemblySubscriber.onNext(FluxOnAssembly.java:375) (1)
...
(2)
...
	at reactor.core.publisher.Mono.subscribeWith(Mono.java:3204)
	at reactor.core.publisher.Mono.subscribe(Mono.java:3090)
	at reactor.core.publisher.Mono.subscribe(Mono.java:3057)
	at reactor.core.publisher.Mono.subscribe(Mono.java:3029)
	at reactor.guide.GuideTests.debuggingActivated(GuideTests.java:1000)
	Suppressed: reactor.core.publisher.FluxOnAssembly$OnAssemblyException: (3)
Assembly trace from producer [reactor.core.publisher.MonoSingle] : (4)
	reactor.core.publisher.Flux.single(Flux.java:6676)
	reactor.guide.GuideTests.scatterAndGather(GuideTests.java:949)
	reactor.guide.GuideTests.populateDebug(GuideTests.java:962)
	org.junit.rules.TestWatcher$1.evaluate(TestWatcher.java:55)
	org.junit.rules.RunRules.evaluate(RunRules.java:20)
Error has been observed by the following operator(s): (5)
	|_	Flux.single ⇢ reactor.guide.GuideTests.scatterAndGather(GuideTests.java:949) (6)
1 This is new: We see the wrapper operator that captures the stack.
2 Apart from that, the first section of the stack trace is still the same for the most part, showing a bit of the operator’s internals (so we removed a bit of the snippet here).
3 This is where the new stuff from debugging mode starts to appear.
4 First, we get some details on where the operator was assembled.
5 We also get a traceback of the error as it propagated through the operator chain, from first to last (error site to subscribe site).
6 Each operator that saw the error is mentioned along with the user class and line where it was used.

As you can see, the captured stack trace is appended to the original error as a suppressed OnAssemblyException. There are two parts to it, but the first section is the most interesting. It shows the path of construction for the operator that triggered the exception. Here it shows that the single that caused our issue was created in the scatterAndGather method, itself called from a populateDebug method that got executed through JUnit.

Now that we are armed with enough information to find the culprit, we can have a meaningful look at that scatterAndGather method:

private Mono<String> scatterAndGather(Flux<String> urls) {
    return urls.flatMap(url -> doRequest(url))
           .single(); (1)
}
1 Sure enough, here is our single.

Now we can see what the root cause of the error was a flatMap that performs several HTTP calls to a few URLs is chained with single, which is too restrictive. After a short git blame and a quick discussion with the author of that line, we find out he meant to use the less restrictive take(1) instead.

We have solved our problem.

Error has been observed by the following operator(s):

That second part of the debug stack trace was not necessarily interesting in this particular example, because the error was actually happening in the last operator in the chain (the one closest to subscribe). Considering another example might make it more clear:

FakeRepository.findAllUserByName(Flux.just("pedro", "simon", "stephane"))
              .transform(FakeUtils1.applyFilters)
              .transform(FakeUtils2.enrichUser)
              .blockLast();

Now imagine that, inside findAllUserByName, there is a map that fails. Here we would see the following final traceback:

Error has been observed by the following operator(s):
        |_        Flux.map  reactor.guide.FakeRepository.findAllUserByName(FakeRepository.java:27)
        |_        Flux.map  reactor.guide.FakeRepository.findAllUserByName(FakeRepository.java:28)
        |_        Flux.filter  reactor.guide.FakeUtils1.lambda$static$1(FakeUtils1.java:29)
        |_        Flux.transform  reactor.guide.GuideDebuggingExtraTests.debuggingActivatedWithDeepTraceback(GuideDebuggingExtraTests.java:40)
        |_        Flux.elapsed  reactor.guide.FakeUtils2.lambda$static$0(FakeUtils2.java:30)
        |_        Flux.transform  reactor.guide.GuideDebuggingExtraTests.debuggingActivatedWithDeepTraceback(GuideDebuggingExtraTests.java:41)

This corresponds to the section of the chain of operators that gets notified of the error:

  1. The exception originates in the first map.

  2. It is seen by a second map (both in fact correspond to the findAllUserByName method).

  3. It is then seen by a filter and a transform, which indicate that part of the chain is constructed via a reusable transformation function (here, the applyFilters utility method).

  4. Finally, it is seen by an elapsed and a transform. Once again, elapsed is applied by the transformation function of that second transform.

We deal with a form of instrumentation here, and creating a stack trace is costly. That is why this debugging feature should only be activated in a controlled manner, as a last resort.

7.3.1. The checkpoint() Alternative

The debug mode is global and affects every single operator assembled into a Flux or Mono inside the application. This has the benefit of allowing after-the-fact debugging: whatever the error, we will obtain additional info to debug it.

As we saw earlier, this global knowledge comes at the cost of an impact on performance (due to the number of populated stack traces). That cost can be reduced if we have an idea of likely problematic operators. However, we usually do not know which operators are likely to be problematic unless we observed an error in the wild, saw we were missing assembly information, and then modified the code to activate assembly tracking, hoping to observe the same error again.

In that scenario, we have to switch into debugging mode and make preparations in order to better observe a second occurrence of the error, this time capturing all the additional information.

If you can identify reactive chains that you assemble in your application for which serviceability is critical, a mix of both techniques can be achieved with the checkpoint() operator.

You can chain this operator into a method chain. The checkpoint operator works like the hook version, but only for its link of that particular chain.

There is also a checkpoint(String) variant that lets you add a unique String identifier to the assembly traceback. This way, the stack trace is omitted and you rely on the description to identify the assembly site. A checkpoint(String) imposes less processing cost than a regular checkpoint.

checkpoint(String) includes "light" in its output (which can be handy when searching), as shown in the following example:

...
	Suppressed: reactor.core.publisher.FluxOnAssembly$OnAssemblyException:
Assembly site of producer [reactor.core.publisher.ParallelSource] is identified by light checkpoint [light checkpoint identifier].

Last but not least, if you want to add a more generic description to the checkpoint but still rely on the stack trace mechanism to identify the assembly site, you can force that behavior by using the checkpoint("description", true) version. We are now back to the initial message for the traceback, augmented with a description, as shown in the following example:

Assembly trace from producer [reactor.core.publisher.ParallelSource], described as [descriptionCorrelation1234] : (1)
	reactor.core.publisher.ParallelFlux.checkpoint(ParallelFlux.java:215)
	reactor.core.publisher.FluxOnAssemblyTest.parallelFluxCheckpointDescriptionAndForceStack(FluxOnAssemblyTest.java:225)
Error has been observed by the following operator(s):
	|_	ParallelFlux.checkpoint ⇢ reactor.core.publisher.FluxOnAssemblyTest.parallelFluxCheckpointDescriptionAndForceStack(FluxOnAssemblyTest.java:225)
1 descriptionCorrelation1234 is the description provided in the checkpoint.

The description could be a static identifier or user-readable description or a wider correlation ID (for instance, coming from a header in the case of an HTTP request).

When both global debugging and local checkpoint() are enabled, checkpointed snapshot stacks are appended as suppressed error output after the observing operator graph and following the same declarative order.

7.4. Logging a Stream

In addition to stack trace debugging and analysis, another powerful tool to have in your toolkit is the ability to trace and log events in an asynchronous sequence.

The log() operator can do just that. Chained inside a sequence, it will peek at every event of the Flux or Mono upstream of it (including onNext, onError, and onComplete and subscriptions, cancellations, and requests).

Side note on logging implementation

The log operator uses the Loggers utility class, which picks up common logging frameworks like Log4J and Logback through SLF4J and defaults to logging to the console in case SLF4J is unavailable.

The Console fallback uses System.err for the WARN and ERROR log levels and System.out for everything else.

If you prefer a JDK java.util.logging fallback, as in 3.0.x, you can get it by setting the reactor.logging.fallback System property to JDK.

For instance, suppose we have logback activated and configured and a chain like range(1,10).take(3). By placing a log() just before the take, we can get some insight into how it works and what kind of events it propagates upstream to the range, as shown in the following example:

Flux<Integer> flux = Flux.range(1, 10)
                         .log()
                         .take(3);
flux.subscribe();

This prints out (through the logger’s console appender):

10:45:20.200 [main] INFO  reactor.Flux.Range.1 - | onSubscribe([Synchronous Fuseable] FluxRange.RangeSubscription) (1)
10:45:20.205 [main] INFO  reactor.Flux.Range.1 - | request(unbounded) (2)
10:45:20.205 [main] INFO  reactor.Flux.Range.1 - | onNext(1) (3)
10:45:20.205 [main] INFO  reactor.Flux.Range.1 - | onNext(2)
10:45:20.205 [main] INFO  reactor.Flux.Range.1 - | onNext(3)
10:45:20.205 [main] INFO  reactor.Flux.Range.1 - | cancel() (4)

Here, in addition to the logger’s own formatter (time, thread, level, message), the log() operator outputs a few things in its own format:

1 reactor.Flux.Range.1 is an automatic category for the log, in case you use the operator several times in a chain. It allows you to distinguish which operator’s events are logged (in this case, the range). The identifier can be overwritten with your own custom category by using the log(String) method signature. After a few separating characters, the actual event gets printed. Here we get an onSubscribe call, an request call, three onNext calls, and a cancel call. For the first line, onSubscribe, we get the implementation of the Subscriber, which usually corresponds to the operator-specific implementation. Between square brackets, we get additional information, including whether the operator can be automatically optimized via synchronous or asynchronous fusion (see the appendix on [microfusion]).
2 On the second line, we can see that an unbounded request was propagated up from downstream.
3 Then the range sends three values in a row.
4 On the last line, we see cancel().

The last line, (4), is the most interesting. We can see the take in action there. It operates by cutting the sequence short after it has seen enough elements emitted. In short, take() causes the source to cancel() once it has emitted the user-requested amount.

8. Advanced Features and Concepts

This chapter covers advanced features and concepts of Reactor, including the following:

8.1. Mutualizing Operator Usage

From a clean-code perspective, code reuse is generally a good thing. Reactor offers a few patterns that can help you reuse and mutualize code, notably for operators or combination of operators that you might want to apply regularly in your codebase. If you think of a chain of operators as a recipe, you can create a cookbook of operator recipes.

8.1.1. Using the transform Operator

The transform operator lets you encapsulate a piece of an operator chain into a function. That function is applied to an original operator chain at assembly time to augment it with the encapsulated operators. Doing so applies the same operations to all the subscribers of a sequence and is basically equivalent to chaining the operators directly. The following code shows an example:

Function<Flux<String>, Flux<String>> filterAndMap =
f -> f.filter(color -> !color.equals("orange"))
      .map(String::toUpperCase);

Flux.fromIterable(Arrays.asList("blue", "green", "orange", "purple"))
        .doOnNext(System.out::println)
        .transform(filterAndMap)
        .subscribe(d -> System.out.println("Subscriber to Transformed MapAndFilter: "+d));
Transform Operator : encapsulate flows

The preceding example produces the following output:

blue
Subscriber to Transformed MapAndFilter: BLUE
green
Subscriber to Transformed MapAndFilter: GREEN
orange
purple
Subscriber to Transformed MapAndFilter: PURPLE

8.1.2. Using the compose Operator

The compose operator is similar to transform and also lets you encapsulate operators in a function. The major difference is that this function is applied to the original sequence on a per-subscriber basis. It means that the function can actually produce a different operator chain for each subscription (by maintaining some state). The following code shows an example:

AtomicInteger ai = new AtomicInteger();
Function<Flux<String>, Flux<String>> filterAndMap = f -> {
        if (ai.incrementAndGet() == 1) {
return f.filter(color -> !color.equals("orange"))
        .map(String::toUpperCase);
        }
        return f.filter(color -> !color.equals("purple"))
                .map(String::toUpperCase);
};

Flux<String> composedFlux =
Flux.fromIterable(Arrays.asList("blue", "green", "orange", "purple"))
    .doOnNext(System.out::println)
    .compose(filterAndMap);

composedFlux.subscribe(d -> System.out.println("Subscriber 1 to Composed MapAndFilter :"+d));
composedFlux.subscribe(d -> System.out.println("Subscriber 2 to Composed MapAndFilter: "+d));
Compose Operator : Per Subscriber transformation

The preceding example produces the following output:

blue
Subscriber 1 to Composed MapAndFilter :BLUE
green
Subscriber 1 to Composed MapAndFilter :GREEN
orange
purple
Subscriber 1 to Composed MapAndFilter :PURPLE
blue
Subscriber 2 to Composed MapAndFilter: BLUE
green
Subscriber 2 to Composed MapAndFilter: GREEN
orange
Subscriber 2 to Composed MapAndFilter: ORANGE
purple

8.2. Hot vs Cold

So far, we have considered that all Flux (and Mono) are the same: They all represent an asynchronous sequence of data, and nothing happens before you subscribe.

Really, though, there are two broad families of publishers: hot and cold.

The description above applies to the cold family of publishers. They generate data anew for each subscription. If no subscription is created, then data never gets generated.

Think of an HTTP request: Each new subscriber will trigger an HTTP call, but no call is made if no one is interested in the result.

Hot publishers, on the other hand, do not depend on any number of subscribers. They might start publishing data right away and would continue doing so whenever a new Subscriber comes in (in which case said subscriber would only see new elements emitted after it subscribed). For hot publishers, something does indeed happen before you subscribe.

One example of the few hot operators in Reactor is just: It directly captures the value at assembly time and replays it to anybody subscribing to it later. To re-use the HTTP call analogy, if the captured data is the result of an HTTP call, then only one network call is made, when instantiating just.

To transform just into a cold publisher, you can use defer. It defers the HTTP request in our example to subscription time (and would result in a separate network call for each new subscription).

Most other hot publishers in Reactor extend Processor.

Consider two other examples. The following code shows the first example:

Flux<String> source = Flux.fromIterable(Arrays.asList("blue", "green", "orange", "purple"))
                          .doOnNext(System.out::println)
                          .filter(s -> s.startsWith("o"))
                          .map(String::toUpperCase);

source.subscribe(d -> System.out.println("Subscriber 1: "+d));
source.subscribe(d -> System.out.println("Subscriber 2: "+d));

This first example produces the following output:

blue
green
orange
Subscriber 1: ORANGE
purple
blue
green
orange
Subscriber 2: ORANGE
purple
Replaying behavior

Both subscribers catch all four colors, because each subscriber causes the process defined by the operators on the Flux to run.

Compare the first example to the second example, shown in the following code:

UnicastProcessor<String> hotSource = UnicastProcessor.create();

Flux<String> hotFlux = hotSource.publish()
                                .autoConnect()
                                .map(String::toUpperCase);


hotFlux.subscribe(d -> System.out.println("Subscriber 1 to Hot Source: "+d));

hotSource.onNext("blue");
hotSource.onNext("green");

hotFlux.subscribe(d -> System.out.println("Subscriber 2 to Hot Source: "+d));

hotSource.onNext("orange");
hotSource.onNext("purple");
hotSource.onComplete();

The second example produces the following output:

Subscriber 1 to Hot Source: BLUE
Subscriber 1 to Hot Source: GREEN
Subscriber 1 to Hot Source: ORANGE
Subscriber 2 to Hot Source: ORANGE
Subscriber 1 to Hot Source: PURPLE
Subscriber 2 to Hot Source: PURPLE
Broadcasting a subscription

Subscriber 1 catches all four colors. Subscriber 2, having been created after the first two colors were produced, catches only the last two colors. This difference accounts for the doubling of "ORANGE" and "PURPLE" in the output. The process described by the operators on this Flux runs regardless of when subscriptions have been attached.

8.3. Broadcasting to Multiple Subscribers with ConnectableFlux

Sometimes, you want to not only defer some processing to the subscription time of one subscriber, but you might actually want for several of them to rendezvous and then trigger the subscription and data generation.

This is what ConnectableFlux is made for. Two main patterns are covered in the Flux API that return a ConnectableFlux: publish and replay.

  • publish dynamically tries to respect the demand from its various subscribers, in terms of backpressure, by forwarding these requests to the source. Most notably, if any subscriber has a pending demand of 0, publish pauses its requesting to the source.

  • replay buffers data seen through the first subscription, up to configurable limits (in time and buffer size). It replays the data to subsequent subscribers.

A ConnectableFlux offers additional methods to manage subscriptions downstream versus subscriptions to the original source. These additional methods include the following:

  • connect can be called manually once you reach enough subscriptions to the flux. That triggers the subscription to the upstream source.

  • autoConnect(n) can do the same job automatically once n subscriptions have been made.

  • refCount(n) not only automatically tracks incoming subscriptions but also detects when these subscriptions are cancelled. If not enough subscribers are tracked, the source is "disconnected", causing a new subscription to the source later if additional subscribers appear.

  • refCount(int, Duration) adds a "grace period": Once the number of tracked subscribers becomes too low, it waits for the Duration before disconnecting the source, potentially allowing for enough new subscribers to come in and cross the connection threshold again.

Consider the following example:

Flux<Integer> source = Flux.range(1, 3)
                           .doOnSubscribe(s -> System.out.println("subscribed to source"));

ConnectableFlux<Integer> co = source.publish();

co.subscribe(System.out::println, e -> {}, () -> {});
co.subscribe(System.out::println, e -> {}, () -> {});

System.out.println("done subscribing");
Thread.sleep(500);
System.out.println("will now connect");

co.connect();

The preceding code produces the following output:

done subscribing
will now connect
subscribed to source
1
1
2
2
3
3

With autoConnect:

Flux<Integer> source = Flux.range(1, 3)
                           .doOnSubscribe(s -> System.out.println("subscribed to source"));

Flux<Integer> autoCo = source.publish().autoConnect(2);

autoCo.subscribe(System.out::println, e -> {}, () -> {});
System.out.println("subscribed first");
Thread.sleep(500);
System.out.println("subscribing second");
autoCo.subscribe(System.out::println, e -> {}, () -> {});

The preceding code produces the following output:

subscribed first
subscribing second
subscribed to source
1
1
2
2
3
3

8.4. Three Sorts of Batching

When you have lots of elements and you want to separate them into batches, you have three broad solutions in Reactor: grouping, windowing, and buffering. These three are conceptually close, because they redistribute a Flux<T> into an aggregate. Grouping and windowing create a Flux<Flux<T>>, while buffering aggregates into a Collection<T>.

8.4.1. Grouping with Flux<GroupedFlux<T>>

Grouping is the act of splitting the source Flux<T> into multiple batches by a key.

The associated operator is groupBy.

Each group is represented as a GroupedFlux<T>, which lets you retrieve the key via its key() method.

There is no necessary continuity in the content of the groups. Once a source element produces a new key, the group for this key is opened and elements that match the key end up in the group (several groups could be open at the same time).

This means that groups:

  1. Are always disjoint (a source element belongs to 1 and only 1 group).

  2. Can contain elements from different places in the original sequence.

  3. Are never empty.

StepVerifier.create(
        Flux.just(1, 3, 5, 2, 4, 6, 11, 12, 13)
                .groupBy(i -> i % 2 == 0 ? "even" : "odd")
                .concatMap(g -> g.defaultIfEmpty(-1) //if empty groups, show them
                                .map(String::valueOf) //map to string
                                .startWith(g.key())) //start with the group's key
        )
        .expectNext("odd", "1", "3", "5", "11", "13")
        .expectNext("even", "2", "4", "6", "12")
        .verifyComplete();
Grouping is best suited for when you have a medium to low number of groups. The groups must also imperatively be consumed (such as by a flatMap) so that groupBy continues fetching data from upstream and feeding more groups. Sometimes, these two constraints multiply and lead to hangs, such as when you have a high cardinality and the concurrency of the flatMap consuming the groups is too low.

8.4.2. Windowing with Flux<Flux<T>>

Windowing is the act of splitting the source Flux<T> into windows, by criteria of size, time, boundary-defining predicates, or boundary-defining Publisher.

The associated operators are window, windowTimeout, windowUntil, windowWhile, and windowWhen.

A major difference with groupBy is that windows are always sequential. No more than 2 windows can be open at the same time.

They can overlap, though. For instance, there is a variant with maxSize and skip parameters. The maxSize parameter is the number of elements after which a window closes, and the skip parameter is the number of elements in the source after which a new window is opened. So if maxSize > skip, a new window opens before the previous one closes and the two windows overlap.

The following example shows overlapping windows:

StepVerifier.create(
        Flux.range(1, 10)
                .window(5, 3) //overlapping windows
                .concatMap(g -> g.defaultIfEmpty(-1)) //show empty windows as -1
        )
                .expectNext(1, 2, 3, 4, 5)
                .expectNext(4, 5, 6, 7, 8)
                .expectNext(7, 8, 9, 10)
                .expectNext(10)
                .verifyComplete();
With the reverse configuration (maxSize < skip), some elements from the source are dropped and are not part of any window.

In the case of predicate-based windowing via windowUntil and windowWhile, having subsequent source elements that do not match the predicate can also lead to empty windows, as demonstrated in the following example:

StepVerifier.create(
        Flux.just(1, 3, 5, 2, 4, 6, 11, 12, 13)
                .windowWhile(i -> i % 2 == 0)
                .concatMap(g -> g.defaultIfEmpty(-1))
        )
                .expectNext(-1, -1, -1) //respectively triggered by odd 1 3 5
                .expectNext(2, 4, 6) // triggered by 11
                .expectNext(12) // triggered by 13
                // however, no empty completion window is emitted (would contain extra matching elements)
                .verifyComplete();

8.4.3. Buffering with Flux<List<T>>

Buffering is similar to windowing, with the following twist: instead of emitting windows (which are each a Flux<T>), it emits buffers (which are Collection<T> - by default, List<T>).

The operators for buffering mirror those for windowing: buffer, bufferTimeout, bufferUntil, bufferWhile, and bufferWhen.

Where the corresponding windowing operator opens a window, a buffering operator creates a new collection and start adding elements to it. Where a window closes, the buffering operator emits the collection.

Buffering can also lead to dropping source elements or having overlapping buffers, as shown here:

StepVerifier.create(
        Flux.range(1, 10)
                .buffer(5, 3) //overlapping buffers
        )
                .expectNext(Arrays.asList(1, 2, 3, 4, 5))
                .expectNext(Arrays.asList(4, 5, 6, 7, 8))
                .expectNext(Arrays.asList(7, 8, 9, 10))
                .expectNext(Collections.singletonList(10))
                .verifyComplete();

Unlike in windowing, bufferUntil and bufferWhile do not emit an empty buffer, as shown in the following example:

StepVerifier.create(
        Flux.just(1, 3, 5, 2, 4, 6, 11, 12, 13)
                .bufferWhile(i -> i % 2 == 0)
        )
        .expectNext(Arrays.asList(2, 4, 6)) // triggered by 11
        .expectNext(Collections.singletonList(12)) // triggered by 13
        .verifyComplete();

8.5. Parallelizing Work with ParallelFlux

With multi-core architectures being a commodity nowadays, being able to easily parallelize work is important. Reactor helps with that by providing a special type, ParallelFlux, that exposes operators that are optimized for parallelized work.

To obtain a ParallelFlux, you can use the parallel() operator on any Flux. By itself, this method does not parallelize the work. Rather, it divides the workload into "rails" (by default, as many rails as there are CPU cores).

In order to tell the resulting ParallelFlux where to execute each rail (and, by extension, to execute rails in parallel) you have to use runOn(Scheduler). Note that there is a recommended dedicated Scheduler for parallel work: Schedulers.parallel().

Compare the next two examples, the first of which is shown in the following code:

Flux.range(1, 10)
    .parallel(2) (1)
    .subscribe(i -> System.out.println(Thread.currentThread().getName() + " -> " + i));
1 We force a number of rails instead of relying on the number of CPU cores.

The following code shows the second example:

Flux.range(1, 10)
    .parallel(2)
    .runOn(Schedulers.parallel())
    .subscribe(i -> System.out.println(Thread.currentThread().getName() + " -> " + i));

The first example produces the following output:

main -> 1
main -> 2
main -> 3
main -> 4
main -> 5
main -> 6
main -> 7
main -> 8
main -> 9
main -> 10

The second correctly parallelizes on two threads, as shown in the following output:

parallel-1 -> 1
parallel-2 -> 2
parallel-1 -> 3
parallel-2 -> 4
parallel-1 -> 5
parallel-2 -> 6
parallel-1 -> 7
parallel-1 -> 9
parallel-2 -> 8
parallel-2 -> 10

If, once you process your sequence in parallel, you want to revert back to a "normal" Flux and apply the rest of the operator chain in a sequential manner, you can use the sequential() method on ParallelFlux.

Note that sequential() is implicitly applied if you subscribe to the ParallelFlux with a Subscriber but not when using the lambda-based variants of subscribe.

Note also that subscribe(Subscriber<T>) merges all the rails, while subscribe(Consumer<T>) runs all the rails. If the subscribe() method has a lambda, each lambda is executed as many times as there are rails.

You can also access individual rails or "groups" as a Flux<GroupedFlux<T>> through the groups() method and apply additional operators to them through the composeGroup() method.

8.6. Replacing Default Schedulers

As we have seen in the Schedulers section, Reactor Core comes with several Scheduler implementations. While you can always create new instances through the new* factory methods, each Scheduler flavor also has a default singleton instance that is accessible through the direct factory method (such as Schedulers.elastic() versus Schedulers.newElastic()).

These default instances are the ones used by operators that need a Scheduler to work when you do not explicitly specify one. For example, Flux#delayElements(Duration) uses the Schedulers.parallel() instance.

In some cases, however, you might need to change these default instances with something else in a cross-cutting way, without having to make sure every single operator you call has your specific Scheduler as a parameter. An example is measuring the time every single scheduled task takes by wrapping the real schedulers, for instrumentation purposes. In other words, you might want to change the default Schedulers.

Changing the default schedulers is possible through the Schedulers.Factory class. By default, a Factory creates all the standard Scheduler through similarly named methods. Each of these can be overridden with your custom implementation.

Additionally, the Factory exposes one additional customization method: decorateExecutorService. It is invoked during the creation of every reactor-core Scheduler that is backed by a ScheduledExecutorService (even non-default instances, such as those created by calls to Schedulers.newParallel()).

This lets you tune the ScheduledExecutorService to be used: The default one is exposed as a Supplier and, depending on the type of Scheduler being configured, you can choose to entirely bypass that supplier and return your own instance or you can get() the default instance and wrap it.

Once you create a Factory that fits your needs, you must install it via Schedulers.setFactory(Factory).

Finally, there is a last customizable hook in Schedulers: onHandleError. This hook is invoked whenever a Runnable task submitted to a Scheduler throws an Exception (note that if there is an UncaughtExceptionHandler set for the Thread that ran the task, both the handler and the hook will be invoked).

8.7. Using Global Hooks

Reactor has another category of configurable callbacks that are invoked by Reactor operators in various situations. They are all set in the Hooks class, and fall into three categories:

8.7.1. Dropping Hooks

Dropping hooks are invoked when the source of an operator does not comply with the Reactive Streams specification. These kind of errors are outside of the normal execution path (that is, they cannot be propagated through onError).

Typically, a Publisher calls onNext on the operator despite having already called onCompleted on it previously. In that case, the onNext value is dropped. The same is true for an extraneous onError signal.

The corresponding hooks, onNextDropped and onErrorDropped, let you provide a global Consumer for these drops. For example, you can use it to log the drop and cleanup resources associated with a value if needed (as it never makes it to the rest of the reactive chain).

Setting the hooks twice in a row is additive: every consumer you provide is invoked. The hooks can be fully reset to their defaults by using Hooks.resetOn*Dropped() methods.

8.7.2. Internal Error Hook

One hook, onOperatorError, is invoked by operators when an unexpected Exception is thrown during the execution of their onNext, onError and onComplete methods.

Unlike the previous category, this is still within the normal execution path. A typical example is the map operator with a map function that throws an Exception (such as division by zero). It is still possible at this point to go through the usual channel of onError, and that is what the operator does.

First, it passes the Exception through onOperatorError. The hook lets you inspect the error (and the incriminating value, if relevant) and change the Exception. Of course, you can also do something on the side, such as log and return the original Exception.

Note that the onOperatorError hook can be set multiple times: you can provide a String identifier for a particular BiFunction, and subsequent calls with different keys concatenates the functions, which are all executed. On the other hand, reusing the same key twice lets you replace a function you previously set.

As a consequence, the default hook behavior can be both fully reset (using Hooks.resetOnOperatorError()) or partially reset for a specific key only (by using Hooks.resetOnOperatorError(String)).

8.7.3. Assembly Hooks

These hooks tie in the lifecycle of operators. They are invoked when a chain of operators is assembled (that is, instantiated). onEachOperator lets you dynamically change each operator as it is assembled in the chain, by returning a different Publisher. onLastOperator is similar, except that it is only invoked on the last operator in the chain before the subscribe call.

Like onOperatorError, these hooks are cumulative and can be identified with a key. They can also be reset partially or totally.

8.7.4. Hook Presets

The Hooks utility class provides a couple of preset hooks. These are alternatives to the default behaviors that you can use by calling their corresponding method, rather than coming up with the hook yourself:

  • onNextDroppedFail(): onNextDropped used to throw a Exceptions.failWithCancel() exception. It now defaults to logging the dropped value at the DEBUG level. To go back to the old default behavior of throwing, use onNextDroppedFail().

  • onOperatorDebug(): This method activates debug mode. It ties into the onOperatorError hook, so calling resetOnOperatorError() also resets it. It can be independently reset via resetOnOperatorDebug() as it uses a specific key internally.

8.8. Adding a Context to a Reactive Sequence

One of the big technical challenges encountered when switching from an imperative programming perspective to a reactive programming mindset lies in how you deal with threading.

Contrary to what you might be used to, in reactive programming, a Thread can be used to process several asynchronous sequences that run roughly at the same time (actually, in non-blocking locksteps). The execution can also easily and often jump from one thread to another.

This arrangement is especially hard for developers that use features dependent on the threading model being more "stable", such as ThreadLocal. As it lets you associate data with a thread, it becomes tricky to use in a reactive context. As a result, libraries that rely on ThreadLocal at least introduce new challenges when used with Reactor. At worst, they work badly or even fail. Using the MDC of Logback to store and log correlation IDs is a prime example of such a situation.

The usual workaround for ThreadLocal usage is to move the contextual data, C, along your business data, T, in the sequence, by using Tuple2<T, C> for instance. This does not look good and leaks an orthogonal concern (the contextual data) into your method and Flux signatures.

Since version 3.1.0, Reactor comes with an advanced feature that is somewhat comparable to ThreadLocal but applied to a Flux or a Mono instead of a Thread: the Context.

As an illustration of how it looks like, here is a very simple example of both writing to the Context and reading from it:

String key = "message";
Mono<String> r = Mono.just("Hello")
                .flatMap( s -> Mono.subscriberContext()
                                   .map( ctx -> s + " " + ctx.get(key)))
                .subscriberContext(ctx -> ctx.put(key, "World"));

StepVerifier.create(r)
            .expectNext("Hello World")
            .verifyComplete();

In the following sections, we’ll learn about the Context and how to use it, so that you will eventually understand the example above.

This is an advanced feature that is more targeted at library developers. It requires good understanding of the lifecycle of a Subscription and is intended for libraries that are responsible for the subscriptions.

8.8.1. The Context API

A Context is an interface reminiscent of Map: it stores key-value pairs and lets you fetch a value you stored by its key. More specifically:

  • Both key and values are of type Object, so a Context can contain any number of highly divergent values from different libraries and sources.

  • A Context is immutable.

  • Use put(Object key, Object value) to store a key-value pair, returning a new Context instance. You can also merge two contexts into a new one by using putAll(Context).

  • You can check if the key is present with hasKey(Object key).

  • Use getOrDefault(Object key, T defaultValue) to retrieve a value (cast to a T) or fall back to a default one if the Context does not have that key.

  • Use getOrEmpty(Object key) to get an Optional<T> (the context attempts to cast the stored value to T).

  • Use delete(Object key) to remove the value associated to a key, returning a new Context.

When creating a Context, you can create pre-valued contexts with up to five key-value pairs by using the static Context.of methods. They take 2, 4, 6, 8 or 10 Object instances, each couple of Object instances being a key-value pair to add to the Context.

Alternatively you can also create an empty Context by using Context.empty().

8.8.2. Tying the Context to a Flux and Writing

To make the context useful, it must be tied to a specific sequence and be accessible by each operator in a chain. Note that the operator must be a Reactor native operator, as Context is specific to Reactor.

Actually, a Context is tied to each Subscriber to a chain. It uses the Subscription propagation mechanism to make itself available to each operator, starting with the final subscribe and moving up the chain.

In order to populate the Context, which can only be done at subscription time, you need to use the subscriberContext operator.

Use subscriberContext(Context), which merges the Context you provide and the Context from downstream (remember, the Context is propagated from the bottom of the chain towards the top). This is done through a call to putAll, resulting in a new Context for upstream.

You can also use the more advanced subscriberContext(Function<Context, Context>). It receives the state of the Context from downstream and lets you put or delete values as you see fit, returning the new Context to use. You can even decide to return a completely different instance, although it is really not recommended (doing so might impact libraries that depend on the Context).

8.8.3. Reading the Context

Populating the Context is one aspect, but retrieving that data from it is equally important. Most of the time, the responsibility of putting information into the Context is on the end user’s side, while exploiting that information is on the library’s side, as the library is usually upstream of the client code.

The tool for reading data from the context is the static Mono.subscriberContext() method.

8.8.4. Simple Examples

The examples in this section are meant as ways to better understand some of the caveats of using a Context.

Let’s first look back at our simple example from the introduction in a bit more details:

String key = "message";
Mono<String> r = Mono.just("Hello")
                .flatMap( s -> Mono.subscriberContext() (2)
                                   .map( ctx -> s + " " + ctx.get(key))) (3)
                .subscriberContext(ctx -> ctx.put(key, "World")); (1)

StepVerifier.create(r)
            .expectNext("Hello World") (4)
            .verifyComplete();
1 The chain of operators ends with a call to subscriberContext(Function) that puts "World" into the Context under the key "message".
2 We flatMap on the source element, materializing the Context with Mono.subscriberContext().
3 We then use map to extract the data associated to "message" and concatenate that with the original word.
4 The resulting Mono<String> indeed emits "Hello World".
The numbering above vs the actual line order is not a mistake: it represents the execution order. Even though subscriberContext is the last piece of the chain, it is the one that gets executed first (due to its subscription time nature, and the fact that the subscription signal flows from bottom to top).

Note that in your chain of operators, the relative positions of where you write to the Context and where you read from it matters: the Context is immutable and its content can only be seen by operators above it, as demonstrated in the following code example:

String key = "message";
Mono<String> r = Mono.just("Hello")
                     .subscriberContext(ctx -> ctx.put(key, "World")) (1)
                     .flatMap( s -> Mono.subscriberContext()
                                        .map( ctx -> s + " " + ctx.getOrDefault(key, "Stranger")));  (2)

StepVerifier.create(r)
            .expectNext("Hello Stranger") (3)
            .verifyComplete();
1 The Context is written to too high in the chain…​
2 As a result, in the flatMap, there’s no value associated to our key. A default value is used instead.
3 The resulting Mono<String> thus emits "Hello Stranger".

The following example also demonstrates the immutable nature of the Context, and how Mono.subscriberContext() always returns the Context set by subscriberContext calls:

String key = "message";

Mono<String> r = Mono.subscriberContext() (1)
        .map( ctx -> ctx.put(key, "Hello")) (2)
        .flatMap( ctx -> Mono.subscriberContext()) (3)
        .map( ctx -> ctx.getOrDefault(key,"Default")); (4)

StepVerifier.create(r)
        .expectNext("Default") (5)
        .verifyComplete();
1 We materialize the Context
2 In a map we attempt to mutate it
3 We re-materialize the Context in a flatMap
4 We read the attempted key in the Context
5 The key was never set to "Hello".

Similarly, in case of several attempts to write the same key to the Context, the relative order of the writes matters too: operators reading the Context will see the value that was set closest to under them, as demonstrated in the following example:

String key = "message";
Mono<String> r = Mono.just("Hello")
                .flatMap( s -> Mono.subscriberContext()
                                   .map( ctx -> s + " " + ctx.get(key)))
                .subscriberContext(ctx -> ctx.put(key, "Reactor")) (1)
                .subscriberContext(ctx -> ctx.put(key, "World")); (2)

StepVerifier.create(r)
            .expectNext("Hello Reactor") (3)
            .verifyComplete();
1 A write attempt on key "message".
2 Another write attempt on key "message".
3 The map only saw the value set closest to it (and below it): "Reactor".

Here what happens is that the Context is populated during subscription with "World". Then the subscription signal moves upstream, and another write happens. This produces a second immutable Context with a value of "Reactor". After that, data starts flowing. The flatMap sees the Context closest to it, which is our second Context with the "Reactor" value.

You might wonder if the Context is propagated along with the data signal. If that was the case, putting another flatMap between these two writes would use the value from the top Context. But this is not the case, as demonstrated by the following example:

String key = "message";
Mono<String> r = Mono.just("Hello")
                     .flatMap( s -> Mono.subscriberContext()
                                        .map( ctx -> s + " " + ctx.get(key))) (3)
                     .subscriberContext(ctx -> ctx.put(key, "Reactor")) (2)
                     .flatMap( s -> Mono.subscriberContext()
                                        .map( ctx -> s + " " + ctx.get(key))) (4)
                     .subscriberContext(ctx -> ctx.put(key, "World")); (1)

StepVerifier.create(r)
            .expectNext("Hello Reactor World") (5)
            .verifyComplete();
1 This is the first write to happen.
2 This is the second write to happen.
3 First flatMap sees second write.
4 Second flatMap concatenates result from first one with the value from first write.
5 The Mono emits "Hello Reactor World".

The reason is that the Context is associated to the Subscriber and each operator accesses the Context by requesting it from its downstream Subscriber.

One last interesting propagation case is the one where the Context is also written to inside a flatMap, as in the following example:

String key = "message";
Mono<String> r =
        Mono.just("Hello")
            .flatMap( s -> Mono.subscriberContext()
                               .map( ctx -> s + " " + ctx.get(key))
            )
            .flatMap( s -> Mono.subscriberContext()
                               .map( ctx -> s + " " + ctx.get(key))
                               .subscriberContext(ctx -> ctx.put(key, "Reactor")) (1)
            )
            .subscriberContext(ctx -> ctx.put(key, "World")); (2)

StepVerifier.create(r)
            .expectNext("Hello World Reactor")
            .verifyComplete();
1 This subscriberContext does not impact anything outside of its flatMap
2 This subscriberContext impacts the main sequence’s Context

In the example above, the final emitted value is "Hello World Reactor" and not "Hello Reactor World", because the subscriberContext that writes "Reactor" does so as part of the inner sequence of the second flatMap. As a consequence, it is not visible / propagated through the main sequence and the first flatMap doesn’t see it. Propagation + immutability isolate the Context in operators that create intermediate inner sequences like flatMap.

8.8.5. Full Example

Let’s consider a more real life example of a library reading information from the Context: A reactive HTTP client that takes a Mono<String> as the source of data for a PUT but also looks for a particular Context key to add a correlation ID to the request’s headers.

From the user perspective, it is called as follows:

doPut("www.example.com", Mono.just("Walter"))

In order to propagate a correlation ID, it would be called as follows:

doPut("www.example.com", Mono.just("Walter"))
        .subscriberContext(Context.of(HTTP_CORRELATION_ID, "2-j3r9afaf92j-afkaf"))

As you can see in the snippets above, the user code uses subscriberContext to populate a Context with an HTTP_CORRELATION_ID key-value pair. The upstream of the operator is a Mono<Tuple2<Integer, String>> (a simplistic representation of an HTTP response) returned by the HTTP client library. So it is effectively passing information from the user code to the library code.

The following example shows mock code from the library’s perspective that reads the context and "augments the request" if it can find the correlation ID:

static final String HTTP_CORRELATION_ID = "reactive.http.library.correlationId";

Mono<Tuple2<Integer, String>> doPut(String url, Mono<String> data) {
        Mono<Tuple2<String, Optional<Object>>> dataAndContext =
                        data.zipWith(Mono.subscriberContext() (1)
                                         .map(c -> c.getOrEmpty(HTTP_CORRELATION_ID))); (2)

        return dataAndContext
                        .<String>handle((dac, sink) -> {
                                if (dac.getT2().isPresent()) { (3)
                                        sink.next("PUT <" + dac.getT1() + "> sent to " + url + " with header X-Correlation-ID = " + dac.getT2().get());
                                }
                                else {
                                        sink.next("PUT <" + dac.getT1() + "> sent to " + url);
                                }
                                sink.complete();
                        })
                        .map(msg -> Tuples.of(200, msg));
}
1 Materialize the Context through Mono.subscriberContext().
2 Extract a value for a the correlation ID key, as an Optional.
3 If the key was present in the context, use the correlation ID as a header.

In the library snippet, you can see how it zips the data Mono with Mono.subscriberContext(). This gives the library a Tuple2<String, Context>, and that context contains the HTTP_CORRELATION_ID entry from downstream (as it is on the direct path to the subscriber).

The library code then uses map to extract an Optional<String> for that key, and, if the entry is present, it uses the passed correlation ID as a X-Correlation-ID header. That last part is simulated by the handle above.

The whole test that validates the library code used the correlation ID can be written as follows:

@Test
public void contextForLibraryReactivePut() {
        Mono<String> put = doPut("www.example.com", Mono.just("Walter"))
                        .subscriberContext(Context.of(HTTP_CORRELATION_ID, "2-j3r9afaf92j-afkaf"))
                        .filter(t -> t.getT1() < 300)
                        .map(Tuple2::getT2);

        StepVerifier.create(put)
                    .expectNext("PUT <Walter> sent to www.example.com with header X-Correlation-ID = 2-j3r9afaf92j-afkaf")
                    .verifyComplete();
}

8.9. Null-safety

Although Java does not allow expressing null-safety with its type system, Reactor now provides annotations to declare nullability of APIs, similar to those provided by Spring Framework 5.

Reactor leverages these annotations, but they can also be used in any Reactor-based Java project to declare null-safe APIs. Nullability of types used inside method bodies is outside of the scope of this feature.

These annotations are meta-annotated with JSR 305 annotations (a dormant JSR that is supported by tools like IntelliJ IDEA) to provide useful warnings to Java developers related to null-safety in order to avoid NullPointerException at runtime. JSR 305 meta-annotations allows tooling vendors to provide null-safety support in a generic way, without having to hard-code support for Reactor annotations.

It is not necessary nor recommended with Kotlin 1.1.5+ to have a dependency on JSR 305 in your project classpath.

They are also used by Kotlin which natively supports null-safety. See this dedicated section for more details.

The following annotations are provided in the reactor.util.annotation package:

  • @NonNull indicates that a specific parameter, return value, or field cannot be null. (It is not needed on parameters and return value where @NonNullApi applies) .

  • @Nullable indicates that a parameter, return value, or field can be null.

  • @NonNullApi is a package level annotation that indicates non-null is the default behavior for parameters and return values.

Nullability for generic type arguments, varargs, and array elements is not supported yet. See issue #878 for up-to-date information.

Appendix A: Which operator do I need?

In this section, if an operator is specific to Flux or Mono it is prefixed accordingly. Common operators have no prefix. When a specific use case is covered by a combination of operators, it is presented as a method call, with leading dot and parameters in parentheses, like this: .methodCall(parameter).

I want to deal with:

A.1. Creating a New Sequence…​

  • that emits a T, and I already have: just

    • …​from an Optional<T>: Mono#justOrEmpty(Optional<T>)

    • …​from a potentially null T: Mono#justOrEmpty(T)

  • that emits a T returned by a method: just as well

    • …​but lazily captured: use Mono#fromSupplier or wrap just inside defer

  • that emits several T I can explicitly enumerate: Flux#just(T...)

  • that iterates over:

    • an array: Flux#fromArray

    • a collection or iterable: Flux#fromIterable

    • a range of integers: Flux#range

    • a Stream supplied for each Subscription: Flux#fromStream(Supplier<Stream>)

  • that emits from various single-valued sources such as:

    • a Supplier<T>: Mono#fromSupplier

    • a task: Mono#fromCallable, Mono#fromRunnable

    • a CompletableFuture<T>: Mono#fromFuture

  • that completes: empty

  • that errors immediately: error

    • …​but lazily build the Throwable: error(Supplier<Throwable>)

  • that never does anything: never

  • that is decided at subscription: defer

  • that depends on a disposable resource: using

  • that generates events programmatically (can use state):

    • synchronously and one-by-one: Flux#generate

    • asynchronously (can also be sync), multiple emissions possible in one pass: Flux#create (Mono#create as well, without the multiple emission aspect)

A.2. Transforming an Existing Sequence

  • I want to transform existing data:

    • on a 1-to-1 basis (eg. strings to their length): map

      • …​by just casting it: cast

      • …​in order to materialize each source value’s index: Flux#index

    • on a 1-to-n basis (eg. strings to their characters): flatMap + use a factory method

    • on a 1-to-n basis with programmatic behavior for each source element and/or state: handle

    • running an asynchronous task for each source item (eg. urls to http request): flatMap + an async Publisher-returning method

      • …​ignoring some data: conditionally return a Mono.empty() in the flatMap lambda

      • …​retaining the original sequence order: Flux#flatMapSequential (this triggers the async processes immediately but reorders the results)

      • …​where the async task can return multiple values, from a Mono source: Mono#flatMapMany

  • I want to add pre-set elements to an existing sequence:

    • at the start: Flux#startWith(T...)

    • at the end: Flux#concatWith(T...)

  • I want to aggregate a Flux: (the Flux# prefix is assumed below)

    • into a List: collectList, collectSortedList

    • into a Map: collectMap, collectMultiMap

    • into an arbitrary container: collect

    • into the size of the sequence: count

    • by applying a function between each element (eg. running sum): reduce

      • …​but emitting each intermediary value: scan

    • into a boolean value from a predicate:

      • applied to all values (AND): all

      • applied to at least one value (OR): any

      • testing the presence of any value: hasElements

      • testing the presence of a specific value: hasElement

  • I want to combine publishers…​

    • in sequential order: Flux#concat or .concatWith(other)

      • …​but delaying any error until remaining publishers have been emitted: Flux#concatDelayError

      • …​but eagerly subscribing to subsequent publishers: Flux#mergeSequential

    • in emission order (combined items emitted as they come): Flux#merge / .mergeWith(other)

      • …​with different types (transforming merge): Flux#zip / Flux#zipWith

    • by pairing values:

      • from 2 Monos into a Tuple2: Mono#zipWith

      • from n Monos when they all completed: Mono#zip

    • by coordinating their termination:

      • from 1 Mono and any source into a Mono<Void>: Mono#and

      • from n sources when they all completed: Mono#when

      • into an arbitrary container type:

        • each time all sides have emitted: Flux#zip (up to the smallest cardinality)

        • each time a new value arrives at either side: Flux#combineLatest

    • only considering the sequence that emits first: Flux#first, Mono#first, mono.or (otherMono).or(thirdMono), `flux.or(otherFlux).or(thirdFlux)

    • triggered by the elements in a source sequence: switchMap (each source element is mapped to a Publisher)

    • triggered by the start of the next publisher in a sequence of publishers: switchOnNext

  • I want to repeat an existing sequence: repeat

    • …​but at time intervals: Flux.interval(duration).flatMap(tick -> myExistingPublisher)

  • I have an empty sequence but…​

    • I want a value instead: defaultIfEmpty

    • I want another sequence instead: switchIfEmpty

  • I have a sequence but I am not interested in values: ignoreElements

    • …​and I want the completion represented as a Mono: then

    • …​and I want to wait for another task to complete at the end: thenEmpty

    • …​and I want to switch to another Mono at the end: Mono#then(mono)

    • …​and I want to emit a single value at the end: Mono#thenReturn(T)

    • …​and I want to switch to a Flux at the end: thenMany

  • I have a Mono for which I want to defer completion…​

    • …​only when 1-N other publishers have all emitted (or completed): Mono#delayUntilOther

      • …​and deriving these publishers from the Mono value: Mono#delayUntil(Function)

  • I want to expand elements recursively into a graph of sequences and emit the combination…​

    • …​expanding the graph breadth first: expand(Function)

    • …​expanding the graph depth first: expandDeep(Function)

A.3. Peeking into a Sequence

  • Without modifying the final sequence, I want to:

    • get notified of / execute additional behavior [1] on:

      • emissions: doOnNext

      • completion: Flux#doOnComplete, Mono#doOnSuccess (includes the result if any)

      • error termination: doOnError

      • cancellation: doOnCancel

      • subscription: doOnSubscribe

      • request: doOnRequest

      • completion or error: doOnTerminate (Mono version includes the result if any)

        • but after it has been propagated downstream: doAfterTerminate

      • any type of signal, represented as a Signal: Flux#doOnEach

      • any terminating condition (complete, error, cancel): doFinally

    • log what happens internally: log

  • I want to know of all events:

    • each represented as Signal object:

      • in a callback outside the sequence: doOnEach

      • instead of the original onNext emissions: materialize

        • …​and get back to the onNexts: dematerialize

    • as a line in a log: log

A.4. Filtering a Sequence

  • I want to filter a sequence:

    • based on an arbitrary criteria: filter

      • …​that is asynchronously computed: filterWhen

    • restricting on the type of the emitted objects: ofType

    • by ignoring the values altogether: ignoreElements

    • by ignoring duplicates:

      • in the whole sequence (logical set): Flux#distinct

      • between subsequently emitted items (deduplication): Flux#distinctUntilChanged

  • I want to keep only a subset of the sequence:

    • by taking N elements:

      • at the beginning of the sequence: Flux#take(long)

        • …​based on a duration: Flux#take(Duration)

        • …​only the first element, as a Mono: Flux#next()

        • …​using request(N) rather than cancellation: Flux#limitRequest(long)

      • at the end of the sequence: Flux#takeLast

      • until a criteria is met (inclusive): Flux#takeUntil (predicate-based), Flux#takeUntilOther (companion publisher-based)

      • while a criteria is met (exclusive): Flux#takeWhile

    • by taking at most 1 element:

      • at a specific position: Flux#elementAt

      • at the end: .takeLast(1)

        • …​and emit an error if empty: Flux#last()

        • …​and emit a default value if empty: Flux#last(T)

    • by skipping elements:

      • at the beginning of the sequence: Flux#skip(long)

        • …​based on a duration: Flux#skip(Duration)

      • at the end of the sequence: Flux#skipLast

      • until a criteria is met (inclusive): Flux#skipUntil (predicate-based), Flux#skipUntilOther (companion publisher-based)

      • while a criteria is met (exclusive): Flux#skipWhile

    • by sampling items:

      • by duration: Flux#sample(Duration)

        • but keeping the first element in the sampling window instead of the last: sampleFirst

      • by a publisher-based window: Flux#sample(Publisher)

      • based on a publisher "timing out": Flux#sampleTimeout (each element triggers a publisher, and is emitted if that publisher does not overlap with the next)

  • I expect at most 1 element (error if more than one)…​

    • and I want an error if the sequence is empty: Flux#single()

    • and I want a default value if the sequence is empty: Flux#single(T)

    • and I accept an empty sequence as well: Flux#singleOrEmpty

A.5. Handling Errors

  • I want to create an erroring sequence: error…​

    • …​to replace the completion of a successful Flux: .concat(Flux.error(e))

    • …​to replace the emission of a successful Mono: .then(Mono.error(e))

    • …​if too much time elapses between onNexts: timeout

    • …​lazily: error(Supplier<Throwable>)

  • I want the try/catch equivalent of:

    • throwing: error

    • catching an exception:

      • and falling back to a default value: onErrorReturn

      • and falling back to another Flux or Mono: onErrorResume

      • and wrapping and re-throwing: .onErrorMap(t -> new RuntimeException(t))

    • the finally block: doFinally

    • the using pattern from Java 7: using factory method

  • I want to recover from errors…​

    • by falling back:

      • to a value: onErrorReturn

      • to a Publisher or Mono, possibly different ones depending on the error: Flux#onErrorResume and Mono#onErrorResume

    • by retrying: retry

      • …​triggered by a companion control Flux: retryWhen

      • …​ using a standard backoff strategy (exponential backoff with jitter): retryBackoff

  • I want to deal with backpressure "errors"[2]…​

    • by throwing a special IllegalStateException: Flux#onBackpressureError

    • by dropping excess values: Flux#onBackpressureDrop

      • …​except the last one seen: Flux#onBackpressureLatest

    • by buffering excess values (bounded or unbounded): Flux#onBackpressureBuffer

      • …​and applying a strategy when bounded buffer also overflows: Flux#onBackpressureBuffer with a BufferOverflowStrategy

A.6. Working with Time

  • I want to associate emissions with a timing (Tuple2<Long, T>) measured…​

    • since subscription: elapsed

    • since the dawn of time (well, computer time): timestamp

  • I want my sequence to be interrupted if there is too much delay between emissions: timeout

  • I want to get ticks from a clock, regular time intervals: Flux#interval

  • I want to emit a single 0 after an initial delay: static Mono.delay.

  • I want to introduce a delay:

    • between each onNext signal: Mono#delayElement, Flux#delayElements

    • before the subscription happens: delaySubscription

A.7. Splitting a Flux

  • I want to split a Flux<T> into a Flux<Flux<T>>, by a boundary criteria:

    • of size: window(int)

      • …​with overlapping or dropping windows: window(int, int)

    • of time window(Duration)

      • …​with overlapping or dropping windows: window(Duration, Duration)

    • of size OR time (window closes when count is reached or timeout elapsed): windowTimeout(int, Duration)

    • based on a predicate on elements: windowUntil

      • …​…emitting the element that triggered the boundary in the next window (cutBefore variant): .windowUntil(predicate, true)

      • …​keeping the window open while elements match a predicate: windowWhile (non-matching elements are not emitted)

    • driven by an arbitrary boundary represented by onNexts in a control Publisher: window(Publisher), windowWhen

  • I want to split a Flux<T> and buffer elements within boundaries together…​

    • into List:

      • by a size boundary: buffer(int)

        • …​with overlapping or dropping buffers: buffer(int, int)

      • by a duration boundary: buffer(Duration)

        • …​with overlapping or dropping buffers: buffer(Duration, Duration)

      • by a size OR duration boundary: bufferTimeout(int, Duration)

      • by an arbitrary criteria boundary: bufferUntil(Predicate)

        • …​putting the element that triggered the boundary in the next buffer: .bufferUntil(predicate, true)

        • …​buffering while predicate matches and dropping the element that triggered the boundary: bufferWhile(Predicate)

      • driven by an arbitrary boundary represented by onNexts in a control Publisher: buffer(Publisher), bufferWhen

    • into an arbitrary "collection" type C: use variants like buffer(int, Supplier<C>)

  • I want to split a Flux<T> so that element that share a characteristic end up in the same sub-flux: groupBy(Function<T,K>) TIP: Note that this returns a Flux<GroupedFlux<K, T>>, each inner GroupedFlux shares the same K key accessible through key().

A.8. Going Back to the Synchronous World

Note: all of these methods except Mono#toFuture will throw an UnsupportedOperatorException if called from within a Scheduler marked as "non-blocking only" (by default parallel() and single()).

  • I have a Flux<T> and I want to:

    • block until I can get the first element: Flux#blockFirst

      • …​with a timeout: Flux#blockFirst(Duration)

    • block until I can get the last element (or null if empty): Flux#blockLast

      • …​with a timeout: Flux#blockLast(Duration)

    • synchronously switch to an Iterable<T>: Flux#toIterable

    • synchronously switch to a Java 8 Stream<T>: Flux#toStream

  • I have a Mono<T> and I want:

    • to block until I can get the value: Mono#block

      • …​with a timeout: Mono#block(Duration)

    • a CompletableFuture<T>: Mono#toFuture

Appendix B: FAQ, Best Practices, and "How do I…​?"

B.1. How do I wrap a synchronous, blocking call?

It’s often the case that a source of information is synchronous and blocking. To deal with such sources in your Reactor applications, apply the following pattern:

Mono blockingWrapper = Mono.fromCallable(() -> { (1)
    return /* make a remote synchronous call */ (2)
});
blockingWrapper = blockingWrapper.subscribeOn(Schedulers.elastic()); (3)
1 Create a new Mono by using fromCallable.
2 Return the asynchronous, blocking resource.
3 Ensure each subscription will happen on a dedicated single-threaded worker from Schedulers.elastic().

You should use a Mono because the source returns one value. You should use Schedulers.elastic because it creates a dedicated thread to wait for the blocking resource without tying up some other resource.

Note that subscribeOn does not subscribe to the Mono. It specifies what kind of Scheduler to use when a subscribe call happens.

B.2. I used an operator on my Flux but it doesn’t seem to apply. What gives?

Make sure that the variable you .subscribe() to has been affected by the operators you think should have been applied to it.

Reactor operators are decorators. They return a different instance that wraps the source sequence and add behavior. That is why the preferred way of using operators is to chain the calls.

Compare the following two examples:

without chaining (incorrect)
Flux<String> flux = Flux.just("foo", "chain");
flux.map(secret -> secret.replaceAll(".", "*")); (1)
flux.subscribe(next -> System.out.println("Received: " + next));
1 The mistake is here. The result isn’t attached to the flux variable.
without chaining (correct)
Flux<String> flux = Flux.just("foo", "chain");
flux = flux.map(secret -> secret.replaceAll(".", "*"));
flux.subscribe(next -> System.out.println("Received: " + next));

This sample is even better (because it’s simpler):

with chaining (best)
Flux<String> secrets = Flux
  .just("foo", "chain")
  .map(secret -> secret.replaceAll(".", "*"))
  .subscribe(next -> System.out.println("Received: " + next));

The first version will output:

Received: foo
Received: chain

Whereas the two other versions will output the expected:

Received: ***
Received: *****

B.3. My Mono zipWith/zipWhen is never called

example
myMethod.process("a") // this method returns Mono<Void>
        .zipWith(myMethod.process("b"), combinator) //this is never called
        .subscribe();

If the source Mono is either empty or a Mono<Void> (a Mono<Void> is empty for all intents and purposes), some combinations will never be called.

This is the typical case for any transformer like the zipWith operator, which by definition needs an element from each source to produce its output. If any of the sources are empty, and produces an empty sequence as well, so be careful of its usage. For example, using zipWith() after a then() may cause this problem.

This is even more true of the variants of and that take a Function, meaning that the associated Mono is chosen lazily depending on the incoming value (which never comes in the cases of empty or Void sequences).

You can use .defaultIfEmpty(T) to replace an empty sequence of T (not a Void sequence) with a default value, which could help avoid some of these situations. Here’s an example this:

use defaultIfEmpty before zipWhen
myMethod.emptySequenceForKey("a") // this method returns empty Mono<String>
        .defaultIfEmpty("") // this converts empty sequence to just the empty String
        .zipWhen(aString -> myMethod.process("b")) //this is called with the empty String
        .subscribe();

B.4. How to use retryWhen to emulate retry(3)?

The retryWhen operator can be quite complex. Hopefully this snippet of code can help you understand how it works by attempting to emulate a simpler retry(3):

Flux<String> flux =
Flux.<String>error(new IllegalArgumentException())
    .retryWhen(companion -> companion
    .zipWith(Flux.range(1, 4), (1)
          (error, index) -> { (2)
            if (index < 4) return index; (3)
            else throw Exceptions.propagate(error); (4)
          })
    );
1 Trick one: use zip and a range of "number of acceptable retries + 1".
2 The zip function lets you count the retries while keeping track of the original error.
3 To allow for three retries, indexes before 4 return a value to emit.
4 In order to terminate the sequence in error, we throw the original exception after these three retries.

B.5. How to use retryWhen for exponential backoff?

Exponential backoff produces retry attempts with a growing delay between each of the attempts, so as not to overload the source systems and risk an all out crash. The rationale is that if the source produces an error, it is already in an unstable state and not likely to immediately recover from it. So blindly retrying immediately is likely to produce yet another error and add to the instability.

Here is how to implement an exponential backoff that delays retries and increase the delay between each attempt (pseudocode: delay = attempt number * 100 milliseconds):

Flux<String> flux =
Flux.<String>error(new IllegalArgumentException())
    .retryWhen(companion -> companion
        .doOnNext(s -> System.out.println(s + " at " + LocalTime.now())) (1)
        .zipWith(Flux.range(1, 4), (error, index) -> { (2)
          if (index < 4) return index;
          else throw Exceptions.propagate(error);
        })
        .flatMap(index -> Mono.delay(Duration.ofMillis(index * 100))) (3)
        .doOnNext(s -> System.out.println("retried at " + LocalTime.now())) (4)
    );
1 We log the time of errors.
2 We use the retryWhen + zipWith trick to propagate the error after 3 retries.
3 Through flatMap, we cause a delay that depends on the attempt’s index.
4 We also log the time at which the retry happens.

When subscribed to, this fails and terminates after printing out:

java.lang.IllegalArgumentException at 18:02:29.338
retried at 18:02:29.459 (1)
java.lang.IllegalArgumentException at 18:02:29.460
retried at 18:02:29.663 (2)
java.lang.IllegalArgumentException at 18:02:29.663
retried at 18:02:29.964 (3)
java.lang.IllegalArgumentException at 18:02:29.964
1 first retry after about 100ms
2 second retry after about 200ms
3 third retry after about 300ms

B.6. How do I ensure thread affinity using publishOn()?

As described in Schedulers, publishOn() can be used to switch execution contexts. The publishOn operator influences the threading context where the rest of the operators in the chain below it will execute, up to a new occurrence of publishOn. So the placement of publishOn is significant.

For instance, in the example below, the transform function in map() is executed on a worker of scheduler1 and the processNext method in doOnNext() is executed on a worker of scheduler2. Single threaded schedulers may be used to ensure thread affinity for different stages in the chain or for different subscribers.

EmitterProcessor<Integer> processor = EmitterProcessor.create();
processor.publishOn(scheduler1)
         .map(i -> transform(i))
         .publishOn(scheduler2)
         .doOnNext(i -> processNext(i))
         .subscribe();

Appendix C: Reactor-Extra

The reactor-extra artifact contains additional operators and utilities that are for users of reactor-core with advanced needs.

As this is a separate artifact, you need to explicitly add it to your build:

dependencies {
     compile 'io.projectreactor:reactor-core'
     compile 'io.projectreactor.addons:reactor-extra' (1)
}
1 Add the reactor extra artifact in addition to core. See Getting Reactor for details about why you don’t need to specify a version if you use the BOM, usage in Maven, etc…​

C.1. TupleUtils and Functional Interfaces

The reactor.function package contains functional interfaces that complement the Java 8 Function, Predicate and Consumer interfaces, for 3 to 8 values.

TupleUtils offers static methods that act as a bridge between lambdas of these functional interfaces to a similar interface on the corresponding Tuple.

This allows to easily work with independent parts of any Tuple, for instance:

.map(tuple -> {
  String firstName = tuple.getT1();
  String lastName = tuple.getT2();
  String address = tuple.getT3();

  return new Customer(firstName, lastName, address);
});

Can be instead written as

.map(TupleUtils.function(Customer::new)); (1)
1 (as Customer constructor conforms to Consumer3 functional interface signature)

C.2. Math Operators With MathFlux

The reactor.math package contains a MathFlux specialized version of Flux that offers mathematical operators, like max, min, sumInt, averageDouble…​

C.3. Repeat and Retry Utilities

The reactor.retry package contains utilities to help in writing Flux#repeatWhen and Flux#retryWhen functions. The entry points are factory methods in respectively Repeat and Retry interfaces.

Both interfaces can be used as a mutative builder AND are implementing the correct Function signature to be used in their counterpart operators.

C.4. Schedulers

Reactor-extra comes with several specialized schedulers: - ForkJoinPoolScheduler in package reactor.scheduler.forkjoin - SwingScheduler in package reactor.swing - SwtScheduler in package reactor.swing


1. sometimes referred to as "side-effects"
2. request max from upstream and apply the strategy when downstream does not produce enough request