61

Exceptions, especially checked ones, can severely interrupt the flow of program logic when the FP idiom is used in Java 8. Here is an arbitrary example:

String s1 = "oeu", s2 = "2";
Stream.of(s1, s2).forEach(s -> 
    System.out.println(Optional.of(s).map(Integer::parseInt).get()));

The above code breaks when there's an exception for an unparseable string. But say I just want to replace that with a default value, much like I can with Optional:

Stream.of(s1, s2).forEach(s -> 
   System.out.println(Optional.of(s)
                              .map(Integer::parseInt)
                              .orElse(-1)));

Of course, this still fails because Optional only handles nulls. I would like something as follows:

Stream.of(s1, s2).forEach(s ->
    System.out.println(
        Exceptional.of(s)
                   .map(Integer::parseInt)
                   .handle(NumberFormatException.class, swallow())
                   .orElse(-1)));

Note: this is a self-answered question.

2
  • For the orElse part, instead of returning -1, is there a way to just omit the element. So that the resulting stream would have fewer elements if there are exceptional elements.
    – hrzafer
    Feb 22, 2018 at 22:52
  • In the provided example, Exceptional enters the picture in the terminal operation, where the stream's contents are already settled. You can write a different expression that involves a flatMap stage, and you can add a .stream() method to Exceptional: Stream<T> stream() { return isPresent() ? Stream.of(value) : Stream.empty(); } Then you can say stream.flatMap(Exceptional::stream) Feb 23, 2018 at 7:27

4 Answers 4

57

Presented below is the full code of the Exceptional class. It has a quite large API which is a pure extension of the Optional API so it can be a drop-in replacement for it in any existing code—except that it isn't a subtype of the final Optional class. The class can be seen as being in the same relationship with the Try monad as Optional is with the Maybe monad: it draws inspiration from it, but is adapted to the Java idiom (such as actually throwing exceptions, even from non-terminal operations).

These are some key guidelines followed by the class:

  • as opposed to the monadic approach, doesn't ignore Java's exception mechanism;

  • instead it relieves the impedance mismatch between exceptions and higher-order functions;

  • exception handling not statically typesafe (due to sneaky throwing), but always safe at runtime (never swallows an exception except on explicit request).

The class tries to cover all the typical ways to handle an exception:

  • recover with some handling code which provides a substitute value;
  • flatRecover which, analogous to flatMap, allows to return a new Exceptional instance which will be unwrapped and the state of the current instance suitably updated;
  • propagate an exception, throwing it from the Exceptional expression and making the propagate call declare this exception type;
  • propagate it after wrapping into another exception (translate it);
  • handle it, resulting in an empty Exceptional;
  • as a special case of handling, swallow it with an empty handler block.

The propagate approach allows one to selectively pick which checked exceptions he wants to expose from his code. Exceptions which remain unhandled at the time a terminal operation is called (like get) will be sneakily thrown without declaration. This is often considered as an advanced and dangerous approach, but is nevertheless often employed as a way to somewhat alleviate the nuisance of checked exceptions in combination with lambda shapes which do not declare them. The Exceptional class hopes to offer a cleaner and more selective alternative to sneaky throw.


/*
 * Copyright (c) 2015, Marko Topolnik. All Rights Reserved.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
import java.util.NoSuchElementException;
import java.util.Objects;
import java.util.function.Consumer;
import java.util.function.Function;
import java.util.function.Predicate;
import java.util.function.Supplier;

public final class Exceptional<T>
{
  private final T value;
  private final Throwable exception;

  private Exceptional(T value, Throwable exc) {
    this.value = value;
    this.exception = exc;
  }

  public static <T> Exceptional<T> empty() {
    return new Exceptional<>(null, null);
  }

  public static <T> Exceptional<T> ofNullable(T value) {
    return value != null ? of(value) : empty();
  }

  public static <T> Exceptional<T> of(T value) {
    return new Exceptional<>(Objects.requireNonNull(value), null);
  }

  public static <T> Exceptional<T> ofNullableException(Throwable exception) {
    return exception != null? new Exceptional<>(null, exception) : empty();
  }

  public static <T> Exceptional<T> ofException(Throwable exception) {
    return new Exceptional<>(null, Objects.requireNonNull(exception));
  }

  public static <T> Exceptional<T> from(TrySupplier<T> supplier) {
    try {
      return ofNullable(supplier.tryGet());
    } catch (Throwable t) {
      return new Exceptional<>(null, t);
    }
  }

  public static Exceptional<Void> fromVoid(TryRunnable task) {
    try {
      task.run();
      return new Exceptional<>(null, null);
    } catch (Throwable t) {
      return new Exceptional<>(null, t);
    }
  }

  public static <E extends Throwable> Consumer<? super E> swallow() {
    return e -> {};
  }

  public T get() {
    if (value != null) return value;
    if (exception != null) sneakyThrow(exception);
    throw new NoSuchElementException("No value present");
  }

  public T orElse(T other) {
    if (value != null) return value;
    if (exception != null) sneakyThrow(exception);
    return other;
  }

  public T orElseGet(Supplier<? extends T> other) {
    if (value != null) return value;
    if (exception != null) sneakyThrow(exception);
    return other.get();
  }

  public Stream<T> stream() { 
      return value == null ? Stream.empty() : Stream.of(value); 
  }

  public<U> Exceptional<U> map(Function<? super T, ? extends U> mapper) {
    Objects.requireNonNull(mapper);
    if (value == null) return new Exceptional<>(null, exception);
    final U u;
    try {
      u = mapper.apply(value);
    } catch (Throwable exc) {
      return new Exceptional<>(null, exc);
    }
    return ofNullable(u);
  }

  public<U> Exceptional<U> flatMap(Function<? super T, Exceptional<U>> mapper) {
    Objects.requireNonNull(mapper);
    return value != null ? Objects.requireNonNull(mapper.apply(value)) : empty();
  }

  public Exceptional<T> filter(Predicate<? super T> predicate) {
    Objects.requireNonNull(predicate);
    if (value == null) return this;
    final boolean b;
    try {
      b = predicate.test(value);
    } catch (Throwable t) {
      return ofException(t);
    }
    return b ? this : empty();
  }

  public <X extends Throwable> Exceptional<T> recover(
      Class<? extends X> excType, Function<? super X, T> mapper)
  {
    Objects.requireNonNull(mapper);
    return excType.isInstance(exception) ? ofNullable(mapper.apply(excType.cast(exception))) : this;
  }

  public <X extends Throwable> Exceptional<T> recover(
      Iterable<Class<? extends X>> excTypes, Function<? super X, T> mapper)
  {
    Objects.requireNonNull(mapper);
    for (Class<? extends X> excType : excTypes)
      if (excType.isInstance(exception))
        return ofNullable(mapper.apply(excType.cast(exception)));
    return this;
  }

  public <X extends Throwable> Exceptional<T> flatRecover(
      Class<? extends X> excType, Function<? super X, Exceptional<T>> mapper)
  {
    Objects.requireNonNull(mapper);
    return excType.isInstance(exception) ? Objects.requireNonNull(mapper.apply(excType.cast(exception))) : this;
  }

  public <X extends Throwable> Exceptional<T> flatRecover(
      Iterable<Class<? extends X>> excTypes, Function<? super X, Exceptional<T>> mapper)
  {
    Objects.requireNonNull(mapper);
    for (Class<? extends X> c : excTypes)
      if (c.isInstance(exception))
        return Objects.requireNonNull(mapper.apply(c.cast(exception)));
    return this;
  }

  public <E extends Throwable> Exceptional<T> propagate(Class<E> excType) throws E {
    if (excType.isInstance(exception))
      throw excType.cast(exception);
    return this;
  }

  public <E extends Throwable> Exceptional<T> propagate(Iterable<Class<? extends E>> excTypes) throws E {
    for (Class<? extends E> excType : excTypes)
      if (excType.isInstance(exception))
        throw excType.cast(exception);
    return this;
  }

  public <E extends Throwable, F extends Throwable> Exceptional<T> propagate(
      Class<E> excType, Function<? super E, ? extends F> translator)
  throws F
  {
    if (excType.isInstance(exception))
      throw translator.apply(excType.cast(exception));
    return this;
  }

  public <E extends Throwable, F extends Throwable> Exceptional<T> propagate(
      Iterable<Class<E>> excTypes, Function<? super E, ? extends F> translator)
  throws F
  {
    for (Class<? extends E> excType : excTypes)
      if (excType.isInstance(exception))
        throw translator.apply(excType.cast(exception));
    return this;
  }

  public <E extends Throwable> Exceptional<T> handle(Class<E> excType, Consumer<? super E> action) {
    if (excType.isInstance(exception)) {
      action.accept(excType.cast(exception));
      return empty();
    }
    return this;
  }

  public <E extends Throwable> Exceptional<T> handle(Iterable<Class<E>> excTypes, Consumer<? super E> action) {
    for (Class<? extends E> excType : excTypes)
      if (excType.isInstance(exception)) {
        action.accept(excType.cast(exception));
        return empty();
      }
    return this;
  }

  public <X extends Throwable> T orElseThrow(Supplier<? extends X> exceptionSupplier) throws X {
    if (value != null) return value;
    if (exception != null) sneakyThrow(exception);
    throw exceptionSupplier.get();
  }

  public boolean isPresent() {
    return value != null;
  }

  public void ifPresent(Consumer<? super T> consumer) {
    if (value != null)
      consumer.accept(value);
    if (exception != null) sneakyThrow(exception);
  }

  public boolean isException() {
    return exception != null;
  }

  @Override
  public boolean equals(Object obj) {
    if (this == obj) return true;
    return obj instanceof Exceptional && Objects.equals(value, ((Exceptional)obj).value);
  }

  @Override
  public int hashCode() {
    return Objects.hashCode(value);
  }

  @SuppressWarnings("unchecked")
  private static <T extends Throwable> void sneakyThrow(Throwable t) throws T {
    throw (T) t;
  }
}

@FunctionalInterface
public interface TrySupplier<T> {
  T tryGet() throws Throwable;
}

@FunctionalInterface
public interface TryRunnable {
  void run() throws Throwable;
}
19
10

What if every functional interface provided by java.util.function was allowed to throw an exception?

public interface ThrowingSupplier<R, X extends Throwable> {
    public R get() throws X;
}

We could use some default methods to provide the behavior you want.

  • You could fallback to some default value or action
  • Or you could try to perform another action which may throw an exception

I've written a library which redefines most of the interfaces in java.util.function this way. I even provide a ThrowingStream which let's you use these new interfaces with the same API as a regular Stream.

@FunctionalInterface
public interface ThrowingSupplier<R, X extends Throwable> {
    public R get() throws X;

    default public Supplier<R> fallbackTo(Supplier<? extends R> supplier) {
        ThrowingSupplier<R, Nothing> t = supplier::get;
        return orTry(t)::get;
    }

    default public <Y extends Throwable> ThrowingSupplier<R, Y> orTry(
            ThrowingSupplier<? extends R, ? extends Y> supplier) {
        Objects.requireNonNull(supplier, "supplier");
        return () -> {
            try {
                return get();
            } catch (Throwable x) {
                try {
                    return supplier.get();
                } catch (Throwable y) {
                    y.addSuppressed(x);
                    throw y;
                }
            }
        };
    }
}

(Nothing is a RuntimeException that can never be thrown.)


Your original example would become

ThrowingFunction<String, Integer, NumberFormatException> parse = Integer::parseInt;
Function<String, Optional<Integer>> safeParse = parse.fallbackTo(s -> null)
    .andThen(Optional::ofNullable);
Stream.of(s1, s2)
    .map(safeParse)
    .map(i -> i.orElse(-1))
    .forEach(System.out::println);
6

Here's some discussions I had previously on this topic.

I made an interface Result<T> along the reasonings. A Result<T> is either a success with a value of type T, or a failure with an Exception. It's a subtype of Async<T>, as an immediately completed async action, but that is not important here.

To create a result -

Result.success( value )
Result.failure( exception )
Result.call( callable )

Result can then be transformed in various ways - transform, map, then, peek, catch_, finally_ etc. For example

Async<Integer> rInt = Result.success( s )
      .map( Integer::parseInt )
      .peek( System.out::println )
      .catch_( NumberFormatException.class, ex->42 ) // default
      .catch_( Exception.class, ex-> { ex.printStacktrace(); throw ex; } )
      .finally_( ()->{...} )

Unfortunately the API is focusing on Async, so some methods return Async. Some of them can be overridden by Result to return Result; but some cannot, e.g. then() (which is flatmap). However, if interested, it's easy to extract a standalone Result API that has nothing to do with Async.

22
  • 1
    This looks very well aligned with my goals. One thing that would definitely not work, though, is finally_() because any previous step may have already thrown an exception. To make this work the whole implementation would have to be lazy, just remembering the steps you asked for and then replaying them on a terminal operation. I'm also quite sure that sneaky throwing will never find its way into an API like this one :) Jul 7, 2015 at 20:48
  • 1
    Ah, OK. Then it may not be the same idea as mine, which is to actually throw the exceptions (more precisely, to have both choices in the API). Jul 7, 2015 at 20:57
  • 1
    One of my key ideas is the selective declaration of checked exceptions---so I need more than a blanket getOrThrow. I need to throw with a type filter applied. Jul 7, 2015 at 20:59
  • 1
    My main use case here is using Exceptional internally inside a method, or inside a lambda body. You call a method, get a bunch of checked exceptions. You want to propagate an IOException as a checked one, but a bunch of reflection exceptions you just want to treat as failures. Jul 7, 2015 at 21:12
  • 2
    @Jeffrey - more specifically, what I don't like about it - cancellation mechanism; mutability(!); no checked exceptions in lambda body; bloated APIs, long class/method names; too many methods instead of fewer composable methods; lack of some convenience methods.
    – ZhongYu
    Jul 7, 2015 at 21:51
5

There's a third-party library called better-java-monads. It has the Try monad which provides the necessary functions. It also has TryMapFunction and TrySupplier functional interfaces to use the Try monad with checked exceptions.

1
  • 3
    I actually designed my class as a response to what I saw in Either and Try. They just regurgitate the same well-known theme of monads which I don't find particularly practical outside Haskell. They strictly adhere to the religion of pure FP, statelessness and immutability. Almost everything is expressed as a type transformation, which suits a powerful type system like Haskell's much better than Java. Also, they don't mesh well with the rest of the standard library and existing code; for example by completely sidestepping the exception system. Jul 7, 2015 at 17:52

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