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This artifact provides a single jar that contains all classes required to use remote EJB and JMS, including all dependencies. It is intended for use by those not using maven, maven users should just import the EJB and JMS BOM's instead (shaded JAR's cause lots of problems with maven, as it is very easy to inadvertently end up with different versions on classes on the class path).

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/*
 * Copyright (C) 2008 The Guava Authors
 *
 * 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.
 */

package com.google.common.base;

import static com.google.common.base.NullnessCasts.uncheckedCastNullableTToT;
import static com.google.common.base.Preconditions.checkNotNull;

import com.google.common.annotations.GwtCompatible;
import com.google.errorprone.annotations.CheckReturnValue;
import com.google.errorprone.annotations.ForOverride;
import com.google.errorprone.annotations.InlineMe;
import com.google.errorprone.annotations.concurrent.LazyInit;
import com.google.j2objc.annotations.RetainedWith;
import java.io.Serializable;
import java.util.Iterator;
import javax.annotation.CheckForNull;

/**
 * A function from {@code A} to {@code B} with an associated reverse function from {@code B}
 * to {@code A}; used for converting back and forth between different representations of the same
 * information.
 *
 * 

Invertibility

* *

The reverse operation may be a strict inverse (meaning that {@code * converter.reverse().convert(converter.convert(a)).equals(a)} is always true). However, it is very * common (perhaps more common) for round-trip conversion to be lossy. Consider an * example round-trip using {@link com.google.common.primitives.Doubles#stringConverter}: * *

    *
  1. {@code stringConverter().convert("1.00")} returns the {@code Double} value {@code 1.0} *
  2. {@code stringConverter().reverse().convert(1.0)} returns the string {@code "1.0"} -- * not the same string ({@code "1.00"}) we started with *
* *

Note that it should still be the case that the round-tripped and original objects are * similar. * *

Nullability

* *

A converter always converts {@code null} to {@code null} and non-null references to non-null * references. It would not make sense to consider {@code null} and a non-null reference to be * "different representations of the same information", since one is distinguishable from * missing information and the other is not. The {@link #convert} method handles this null * behavior for all converters; implementations of {@link #doForward} and {@link #doBackward} are * guaranteed to never be passed {@code null}, and must never return {@code null}. * *

Common ways to use

* *

Getting a converter: * *

    *
  • Use a provided converter implementation, such as {@link Enums#stringConverter}, {@link * com.google.common.primitives.Ints#stringConverter Ints.stringConverter} or the {@linkplain * #reverse reverse} views of these. *
  • Convert between specific preset values using {@link * com.google.common.collect.Maps#asConverter Maps.asConverter}. For example, use this to * create a "fake" converter for a unit test. It is unnecessary (and confusing) to mock * the {@code Converter} type using a mocking framework. *
  • Extend this class and implement its {@link #doForward} and {@link #doBackward} methods. *
  • Java 8 users: you may prefer to pass two lambda expressions or method references to * the {@link #from from} factory method. *
* *

Using a converter: * *

    *
  • Convert one instance in the "forward" direction using {@code converter.convert(a)}. *
  • Convert multiple instances "forward" using {@code converter.convertAll(as)}. *
  • Convert in the "backward" direction using {@code converter.reverse().convert(b)} or {@code * converter.reverse().convertAll(bs)}. *
  • Use {@code converter} or {@code converter.reverse()} anywhere a {@link * java.util.function.Function} is accepted (for example {@link java.util.stream.Stream#map * Stream.map}). *
  • Do not call {@link #doForward} or {@link #doBackward} directly; these exist only to * be overridden. *
* *

Example

* *
 *   return new Converter<Integer, String>() {
 *     protected String doForward(Integer i) {
 *       return Integer.toHexString(i);
 *     }
 *
 *     protected Integer doBackward(String s) {
 *       return parseUnsignedInt(s, 16);
 *     }
 *   };
* *

An alternative using Java 8: * *

{@code
 * return Converter.from(
 *     Integer::toHexString,
 *     s -> parseUnsignedInt(s, 16));
 * }
* * @author Mike Ward * @author Kurt Alfred Kluever * @author Gregory Kick * @since 16.0 */ @GwtCompatible @ElementTypesAreNonnullByDefault /* * 1. The type parameter is rather than so that we can use T in the * doForward and doBackward methods to indicate that the parameter cannot be null. (We also take * advantage of that for convertAll, as discussed on that method.) * * 2. The supertype of this class could be `Function<@Nullable A, @Nullable B>`, since * Converter.apply (like Converter.convert) is capable of accepting null inputs. However, a * supertype of `Function` turns out to be massively more useful to callers in practice: They * want their output to be non-null in operations like `stream.map(myConverter)`, and we can * guarantee that as long as we also require the input type to be non-null[*] (which is a * requirement that existing callers already fulfill). * * Disclaimer: Part of the reason that callers are so well adapted to `Function` may be that * that is how the signature looked even prior to this comment! So naturally any change can break * existing users, but it can't *fix* existing users because any users who needed * `Function<@Nullable A, @Nullable B>` already had to find a workaround. Still, there is a *ton* of * fallout from trying to switch. I would be shocked if the switch would offer benefits to anywhere * near enough users to justify the costs. * * Fortunately, if anyone does want to use a Converter as a `Function<@Nullable A, @Nullable B>`, * it's easy to get one: `converter::convert`. * * [*] In annotating this class, we're ignoring LegacyConverter. */ public abstract class Converter implements Function { private final boolean handleNullAutomatically; // We lazily cache the reverse view to avoid allocating on every call to reverse(). @LazyInit @RetainedWith @CheckForNull private transient Converter reverse; /** Constructor for use by subclasses. */ protected Converter() { this(true); } /** Constructor used only by {@code LegacyConverter} to suspend automatic null-handling. */ Converter(boolean handleNullAutomatically) { this.handleNullAutomatically = handleNullAutomatically; } // SPI methods (what subclasses must implement) /** * Returns a representation of {@code a} as an instance of type {@code B}. If {@code a} cannot be * converted, an unchecked exception (such as {@link IllegalArgumentException}) should be thrown. * * @param a the instance to convert; will never be null * @return the converted instance; must not be null */ @ForOverride protected abstract B doForward(A a); /** * Returns a representation of {@code b} as an instance of type {@code A}. If {@code b} cannot be * converted, an unchecked exception (such as {@link IllegalArgumentException}) should be thrown. * * @param b the instance to convert; will never be null * @return the converted instance; must not be null * @throws UnsupportedOperationException if backward conversion is not implemented; this should be * very rare. Note that if backward conversion is not only unimplemented but * unimplementable (for example, consider a {@code Converter}), * then this is not logically a {@code Converter} at all, and should just implement {@link * Function}. */ @ForOverride protected abstract A doBackward(B b); // API (consumer-side) methods /** * Returns a representation of {@code a} as an instance of type {@code B}. * * @return the converted value; is null if and only if {@code a} is null */ @CheckForNull public final B convert(@CheckForNull A a) { return correctedDoForward(a); } @CheckForNull B correctedDoForward(@CheckForNull A a) { if (handleNullAutomatically) { // TODO(kevinb): we shouldn't be checking for a null result at runtime. Assert? return a == null ? null : checkNotNull(doForward(a)); } else { return unsafeDoForward(a); } } @CheckForNull A correctedDoBackward(@CheckForNull B b) { if (handleNullAutomatically) { // TODO(kevinb): we shouldn't be checking for a null result at runtime. Assert? return b == null ? null : checkNotNull(doBackward(b)); } else { return unsafeDoBackward(b); } } /* * LegacyConverter violates the contract of Converter by allowing its doForward and doBackward * methods to accept null. We could avoid having unchecked casts in Converter.java itself if we * could perform a cast to LegacyConverter, but we can't because it's an internal-only class. * * TODO(cpovirk): So make it part of the open-source build, albeit package-private there? * * So we use uncheckedCastNullableTToT here. This is a weird usage of that method: The method is * documented as being for use with type parameters that have parametric nullness. But Converter's * type parameters do not. Still, we use it here so that we can suppress a warning at a smaller * level than the whole method but without performing a runtime null check. That way, we can still * pass null inputs to LegacyConverter, and it can violate the contract of Converter. * * TODO(cpovirk): Could this be simplified if we modified implementations of LegacyConverter to * override methods (probably called "unsafeDoForward" and "unsafeDoBackward") with the same * signatures as the methods below, rather than overriding the same doForward and doBackward * methods as implementations of normal converters do? * * But no matter what we do, it's worth remembering that the resulting code is going to be unsound * in the presence of LegacyConverter, at least in the case of users who view the converter as a * Function or who call convertAll (and for any checkers that apply @PolyNull-like semantics * to Converter.convert). So maybe we don't want to think too hard about how to prevent our * checkers from issuing errors related to LegacyConverter, since it turns out that * LegacyConverter does violate the assumptions we make elsewhere. */ @CheckForNull private B unsafeDoForward(@CheckForNull A a) { return doForward(uncheckedCastNullableTToT(a)); } @CheckForNull private A unsafeDoBackward(@CheckForNull B b) { return doBackward(uncheckedCastNullableTToT(b)); } /** * Returns an iterable that applies {@code convert} to each element of {@code fromIterable}. The * conversion is done lazily. * *

The returned iterable's iterator supports {@code remove()} if the input iterator does. After * a successful {@code remove()} call, {@code fromIterable} no longer contains the corresponding * element. */ /* * Just as Converter could implement `Function<@Nullable A, @Nullable B>` instead of `Function`, convertAll could accept and return iterables with nullable element types. In both cases, * we've chosen to instead use a signature that benefits existing users -- and is still safe. * * For convertAll, I haven't looked as closely at *how* much existing users benefit, so we should * keep an eye out for problems that new users encounter. Note also that convertAll could support * both use cases by using @PolyNull. (By contrast, we can't use @PolyNull for our superinterface * (`implements Function<@PolyNull A, @PolyNull B>`), at least as far as I know.) */ public Iterable convertAll(Iterable fromIterable) { checkNotNull(fromIterable, "fromIterable"); return new Iterable() { @Override public Iterator iterator() { return new Iterator() { private final Iterator fromIterator = fromIterable.iterator(); @Override public boolean hasNext() { return fromIterator.hasNext(); } @Override public B next() { return convert(fromIterator.next()); } @Override public void remove() { fromIterator.remove(); } }; } }; } /** * Returns the reversed view of this converter, which converts {@code this.convert(a)} back to a * value roughly equivalent to {@code a}. * *

The returned converter is serializable if {@code this} converter is. * *

Note: you should not override this method. It is non-final for legacy reasons. */ @CheckReturnValue public Converter reverse() { Converter result = reverse; return (result == null) ? reverse = new ReverseConverter<>(this) : result; } private static final class ReverseConverter extends Converter implements Serializable { final Converter original; ReverseConverter(Converter original) { this.original = original; } /* * These gymnastics are a little confusing. Basically this class has neither legacy nor * non-legacy behavior; it just needs to let the behavior of the backing converter shine * through. So, we override the correctedDo* methods, after which the do* methods should never * be reached. */ @Override protected A doForward(B b) { throw new AssertionError(); } @Override protected B doBackward(A a) { throw new AssertionError(); } @Override @CheckForNull A correctedDoForward(@CheckForNull B b) { return original.correctedDoBackward(b); } @Override @CheckForNull B correctedDoBackward(@CheckForNull A a) { return original.correctedDoForward(a); } @Override public Converter reverse() { return original; } @Override public boolean equals(@CheckForNull Object object) { if (object instanceof ReverseConverter) { ReverseConverter that = (ReverseConverter) object; return this.original.equals(that.original); } return false; } @Override public int hashCode() { return ~original.hashCode(); } @Override public String toString() { return original + ".reverse()"; } private static final long serialVersionUID = 0L; } /** * Returns a converter whose {@code convert} method applies {@code secondConverter} to the result * of this converter. Its {@code reverse} method applies the converters in reverse order. * *

The returned converter is serializable if {@code this} converter and {@code secondConverter} * are. */ public final Converter andThen(Converter secondConverter) { return doAndThen(secondConverter); } /** Package-private non-final implementation of andThen() so only we can override it. */ Converter doAndThen(Converter secondConverter) { return new ConverterComposition<>(this, checkNotNull(secondConverter)); } private static final class ConverterComposition extends Converter implements Serializable { final Converter first; final Converter second; ConverterComposition(Converter first, Converter second) { this.first = first; this.second = second; } /* * These gymnastics are a little confusing. Basically this class has neither legacy nor * non-legacy behavior; it just needs to let the behaviors of the backing converters shine * through (which might even differ from each other!). So, we override the correctedDo* methods, * after which the do* methods should never be reached. */ @Override protected C doForward(A a) { throw new AssertionError(); } @Override protected A doBackward(C c) { throw new AssertionError(); } @Override @CheckForNull C correctedDoForward(@CheckForNull A a) { return second.correctedDoForward(first.correctedDoForward(a)); } @Override @CheckForNull A correctedDoBackward(@CheckForNull C c) { return first.correctedDoBackward(second.correctedDoBackward(c)); } @Override public boolean equals(@CheckForNull Object object) { if (object instanceof ConverterComposition) { ConverterComposition that = (ConverterComposition) object; return this.first.equals(that.first) && this.second.equals(that.second); } return false; } @Override public int hashCode() { return 31 * first.hashCode() + second.hashCode(); } @Override public String toString() { return first + ".andThen(" + second + ")"; } private static final long serialVersionUID = 0L; } /** * @deprecated Provided to satisfy the {@code Function} interface; use {@link #convert} instead. */ @Deprecated @Override @InlineMe(replacement = "this.convert(a)") public final B apply(A a) { /* * Given that we declare this method as accepting and returning non-nullable values (because we * implement Function, as discussed in a class-level comment), it would make some sense to * perform runtime null checks on the input and output. (That would also make NullPointerTester * happy!) However, since we didn't do that for many years, we're not about to start now. * (Runtime checks could be particularly bad for users of LegacyConverter.) * * Luckily, our nullness checker is smart enough to realize that `convert` has @PolyNull-like * behavior, so it knows that `convert(a)` returns a non-nullable value, and we don't need to * perform even a cast, much less a runtime check. * * All that said, don't forget that everyone should call converter.convert() instead of * converter.apply(), anyway. If clients use only converter.convert(), then their nullness * checkers are unlikely to ever look at the annotations on this declaration. * * Historical note: At one point, we'd declared this method as accepting and returning nullable * values. For details on that, see earlier revisions of this file. */ return convert(a); } /** * Indicates whether another object is equal to this converter. * *

Most implementations will have no reason to override the behavior of {@link Object#equals}. * However, an implementation may also choose to return {@code true} whenever {@code object} is a * {@link Converter} that it considers interchangeable with this one. "Interchangeable" * typically means that {@code Objects.equal(this.convert(a), that.convert(a))} is true for * all {@code a} of type {@code A} (and similarly for {@code reverse}). Note that a {@code false} * result from this method does not imply that the converters are known not to be * interchangeable. */ @Override public boolean equals(@CheckForNull Object object) { return super.equals(object); } // Static converters /** * Returns a converter based on separate forward and backward functions. This is useful if the * function instances already exist, or so that you can supply lambda expressions. If those * circumstances don't apply, you probably don't need to use this; subclass {@code Converter} and * implement its {@link #doForward} and {@link #doBackward} methods directly. * *

These functions will never be passed {@code null} and must not under any circumstances * return {@code null}. If a value cannot be converted, the function should throw an unchecked * exception (typically, but not necessarily, {@link IllegalArgumentException}). * *

The returned converter is serializable if both provided functions are. * * @since 17.0 */ public static Converter from( Function forwardFunction, Function backwardFunction) { return new FunctionBasedConverter<>(forwardFunction, backwardFunction); } private static final class FunctionBasedConverter extends Converter implements Serializable { private final Function forwardFunction; private final Function backwardFunction; private FunctionBasedConverter( Function forwardFunction, Function backwardFunction) { this.forwardFunction = checkNotNull(forwardFunction); this.backwardFunction = checkNotNull(backwardFunction); } @Override protected B doForward(A a) { return forwardFunction.apply(a); } @Override protected A doBackward(B b) { return backwardFunction.apply(b); } @Override public boolean equals(@CheckForNull Object object) { if (object instanceof FunctionBasedConverter) { FunctionBasedConverter that = (FunctionBasedConverter) object; return this.forwardFunction.equals(that.forwardFunction) && this.backwardFunction.equals(that.backwardFunction); } return false; } @Override public int hashCode() { return forwardFunction.hashCode() * 31 + backwardFunction.hashCode(); } @Override public String toString() { return "Converter.from(" + forwardFunction + ", " + backwardFunction + ")"; } } /** Returns a serializable converter that always converts or reverses an object to itself. */ @SuppressWarnings("unchecked") // implementation is "fully variant" public static Converter identity() { return (IdentityConverter) IdentityConverter.INSTANCE; } /** * A converter that always converts or reverses an object to itself. Note that T is now a * "pass-through type". */ private static final class IdentityConverter extends Converter implements Serializable { static final Converter INSTANCE = new IdentityConverter<>(); @Override protected T doForward(T t) { return t; } @Override protected T doBackward(T t) { return t; } @Override public IdentityConverter reverse() { return this; } @Override Converter doAndThen(Converter otherConverter) { return checkNotNull(otherConverter, "otherConverter"); } /* * We *could* override convertAll() to return its input, but it's a rather pointless * optimization and opened up a weird type-safety problem. */ @Override public String toString() { return "Converter.identity()"; } private Object readResolve() { return INSTANCE; } private static final long serialVersionUID = 0L; } }