Java tutorial
/* * Copyright (c) 2016 Gridtec. 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. */ package at.gridtec.lambda4j.operator.binary; import at.gridtec.lambda4j.Lambda; import at.gridtec.lambda4j.consumer.ThrowableFloatConsumer; import at.gridtec.lambda4j.consumer.bi.ThrowableBiFloatConsumer; import at.gridtec.lambda4j.core.exception.ThrownByFunctionalInterfaceException; import at.gridtec.lambda4j.core.util.ThrowableUtils; import at.gridtec.lambda4j.function.ThrowableFloatFunction; import at.gridtec.lambda4j.function.ThrowableFunction; import at.gridtec.lambda4j.function.bi.ThrowableBiFloatFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiBooleanToFloatFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiByteToFloatFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiCharToFloatFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiDoubleToFloatFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiFloatToByteFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiFloatToCharFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiFloatToDoubleFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiFloatToIntFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiFloatToLongFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiFloatToShortFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiIntToFloatFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiLongToFloatFunction; import at.gridtec.lambda4j.function.bi.conversion.ThrowableBiShortToFloatFunction; import at.gridtec.lambda4j.function.bi.to.ThrowableToFloatBiFunction; import at.gridtec.lambda4j.function.conversion.ThrowableBooleanToFloatFunction; import at.gridtec.lambda4j.function.conversion.ThrowableByteToFloatFunction; import at.gridtec.lambda4j.function.conversion.ThrowableCharToFloatFunction; import at.gridtec.lambda4j.function.conversion.ThrowableDoubleToFloatFunction; import at.gridtec.lambda4j.function.conversion.ThrowableFloatToByteFunction; import at.gridtec.lambda4j.function.conversion.ThrowableFloatToCharFunction; import at.gridtec.lambda4j.function.conversion.ThrowableFloatToDoubleFunction; import at.gridtec.lambda4j.function.conversion.ThrowableFloatToIntFunction; import at.gridtec.lambda4j.function.conversion.ThrowableFloatToLongFunction; import at.gridtec.lambda4j.function.conversion.ThrowableFloatToShortFunction; import at.gridtec.lambda4j.function.conversion.ThrowableIntToFloatFunction; import at.gridtec.lambda4j.function.conversion.ThrowableLongToFloatFunction; import at.gridtec.lambda4j.function.conversion.ThrowableShortToFloatFunction; import at.gridtec.lambda4j.function.to.ThrowableToFloatFunction; import at.gridtec.lambda4j.operator.unary.ThrowableFloatUnaryOperator; import at.gridtec.lambda4j.predicate.ThrowableFloatPredicate; import at.gridtec.lambda4j.predicate.bi.ThrowableBiFloatPredicate; import org.apache.commons.lang3.tuple.Pair; import javax.annotation.Nonnegative; import javax.annotation.Nonnull; import javax.annotation.Nullable; import java.util.Comparator; import java.util.Map; import java.util.Objects; import java.util.concurrent.ConcurrentHashMap; import java.util.function.BinaryOperator; import java.util.function.Function; /** * Represents an operation that accepts two {@code float}-valued input arguments and produces a * {@code float}-valued result which is able to throw any {@link Throwable}. * This is a primitive specialization of {@link ThrowableBinaryOperator}. * <p> * This is a {@link FunctionalInterface} whose functional method is {@link #applyAsFloatThrows(float, float)}. * * @param <X> The type of the throwable to be thrown by this operator * @see ThrowableBinaryOperator */ @SuppressWarnings("unused") @FunctionalInterface public interface ThrowableFloatBinaryOperator<X extends Throwable> extends Lambda { /** * Constructs a {@link ThrowableFloatBinaryOperator} based on a lambda expression or a method reference. Thereby the * given lambda expression or method reference is returned on an as-is basis to implicitly transform it to the * desired type. With this method, it is possible to ensure that correct type is used from lambda expression or * method reference. * * @param <X> The type of the throwable to be thrown by this operator * @param expression A lambda expression or (typically) a method reference, e.g. {@code this::method} * @return A {@code ThrowableFloatBinaryOperator} from given lambda expression or method reference. * @implNote This implementation allows the given argument to be {@code null}, but only if {@code null} given, * {@code null} will be returned. * @see <a href="https://docs.oracle.com/javase/tutorial/java/javaOO/lambdaexpressions.html#syntax">Lambda * Expression</a> * @see <a href="https://docs.oracle.com/javase/tutorial/java/javaOO/methodreferences.html">Method Reference</a> */ static <X extends Throwable> ThrowableFloatBinaryOperator<X> of( @Nullable final ThrowableFloatBinaryOperator<X> expression) { return expression; } /** * Calls the given {@link ThrowableFloatBinaryOperator} with the given arguments and returns its result. * * @param <X> The type of the throwable to be thrown by this operator * @param operator The operator to be called * @param value1 The first argument to the operator * @param value2 The second argument to the operator * @return The result from the given {@code ThrowableFloatBinaryOperator}. * @throws NullPointerException If given argument is {@code null} * @throws X Any throwable from this operators action */ static <X extends Throwable> float call(@Nonnull final ThrowableFloatBinaryOperator<? extends X> operator, float value1, float value2) throws X { Objects.requireNonNull(operator); return operator.applyAsFloatThrows(value1, value2); } /** * Creates a {@link ThrowableFloatBinaryOperator} which uses the {@code first} parameter of this one as argument for * the given {@link ThrowableFloatUnaryOperator}. * * @param <X> The type of the throwable to be thrown by this operator * @param operator The operator which accepts the {@code first} parameter of this one * @return Creates a {@code ThrowableFloatBinaryOperator} which uses the {@code first} parameter of this one as * argument for the given {@code ThrowableFloatUnaryOperator}. * @throws NullPointerException If given argument is {@code null} */ @Nonnull static <X extends Throwable> ThrowableFloatBinaryOperator<X> onlyFirst( @Nonnull final ThrowableFloatUnaryOperator<? extends X> operator) { Objects.requireNonNull(operator); return (value1, value2) -> operator.applyAsFloatThrows(value1); } /** * Creates a {@link ThrowableFloatBinaryOperator} which uses the {@code second} parameter of this one as argument * for the given {@link ThrowableFloatUnaryOperator}. * * @param <X> The type of the throwable to be thrown by this operator * @param operator The operator which accepts the {@code second} parameter of this one * @return Creates a {@code ThrowableFloatBinaryOperator} which uses the {@code second} parameter of this one as * argument for the given {@code ThrowableFloatUnaryOperator}. * @throws NullPointerException If given argument is {@code null} */ @Nonnull static <X extends Throwable> ThrowableFloatBinaryOperator<X> onlySecond( @Nonnull final ThrowableFloatUnaryOperator<? extends X> operator) { Objects.requireNonNull(operator); return (value1, value2) -> operator.applyAsFloatThrows(value2); } /** * Creates a {@link ThrowableFloatBinaryOperator} which always returns a given value. * * @param <X> The type of the throwable to be thrown by this operator * @param ret The return value for the constant * @return A {@code ThrowableFloatBinaryOperator} which always returns a given value. */ @Nonnull static <X extends Throwable> ThrowableFloatBinaryOperator<X> constant(float ret) { return (value1, value2) -> ret; } /** * Returns a {@link ThrowableFloatBinaryOperator} which returns the lesser of two elements according to the * specified {@code Comparator}. * * @param <X> The type of the throwable to be thrown by this operator * @param comparator A {@code Comparator} for comparing the two values * @return A {@code ThrowableFloatBinaryOperator} which returns the lesser of its operands, according to the * supplied {@code Comparator}. * @throws NullPointerException If given argument is {@code null} * @see BinaryOperator#minBy(Comparator) */ @Nonnull static <X extends Throwable> ThrowableFloatBinaryOperator<X> minBy( @Nonnull final Comparator<Float> comparator) { Objects.requireNonNull(comparator); return (value1, value2) -> comparator.compare(value1, value2) <= 0 ? value1 : value2; } /** * Returns a {@link ThrowableFloatBinaryOperator} which returns the greater of two elements according to the * specified {@code Comparator}. * * @param <X> The type of the throwable to be thrown by this operator * @param comparator A {@code Comparator} for comparing the two values * @return A {@code ThrowableFloatBinaryOperator} which returns the greater of its operands, according to the * supplied {@code Comparator}. * @throws NullPointerException If given argument is {@code null} * @see BinaryOperator#maxBy(Comparator) */ @Nonnull static <X extends Throwable> ThrowableFloatBinaryOperator<X> maxBy( @Nonnull final Comparator<Float> comparator) { Objects.requireNonNull(comparator); return (value1, value2) -> comparator.compare(value1, value2) >= 0 ? value1 : value2; } /** * Applies this operator to the given arguments. * * @param value1 The first argument to the operator * @param value2 The second argument to the operator * @return The return value from the operator, which is its result. * @throws X Any throwable from this operators action */ float applyAsFloatThrows(float value1, float value2) throws X; /** * Applies this operator partially to some arguments of this one, producing a {@link ThrowableFloatUnaryOperator} as * result. * * @param value1 The first argument to this operator used to partially apply this function * @return A {@code ThrowableFloatUnaryOperator} that represents this operator partially applied the some arguments. */ @Nonnull default ThrowableFloatUnaryOperator<X> papplyAsFloatThrows(float value1) { return (value2) -> this.applyAsFloatThrows(value1, value2); } /** * Returns the number of arguments for this operator. * * @return The number of arguments for this operator. * @implSpec The default implementation always returns {@code 2}. */ @Nonnegative default int arity() { return 2; } /** * Returns a composed {@link ThrowableToFloatBiFunction} that first applies the {@code before} functions to its * input, and then applies this operator to the result. * * @param <A> The type of the argument to the first given function, and of composed function * @param <B> The type of the argument to the second given function, and of composed function * @param before1 The first function to apply before this operator is applied * @param before2 The second function to apply before this operator is applied * @return A composed {@code ThrowableToFloatBiFunction} that first applies the {@code before} functions to its * input, and then applies this operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is able to handle every type. */ @Nonnull default <A, B> ThrowableToFloatBiFunction<A, B, X> compose( @Nonnull final ThrowableToFloatFunction<? super A, ? extends X> before1, @Nonnull final ThrowableToFloatFunction<? super B, ? extends X> before2) { Objects.requireNonNull(before1); Objects.requireNonNull(before2); return (a, b) -> applyAsFloatThrows(before1.applyAsFloatThrows(a), before2.applyAsFloatThrows(b)); } /** * Returns a composed {@link ThrowableBiBooleanToFloatFunction} that first applies the {@code before} functions to * its input, and then applies this operator to the result. This method is just convenience, to provide the ability * to execute an operation which accepts {@code boolean} input, before this primitive operator is executed. * * @param before1 The first function to apply before this operator is applied * @param before2 The second function to apply before this operator is applied * @return A composed {@code ThrowableBiBooleanToFloatFunction} that first applies the {@code before} functions to * its input, and then applies this operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to handle primitive values. In this case this is {@code * boolean}. */ @Nonnull default ThrowableBiBooleanToFloatFunction<X> composeFromBoolean( @Nonnull final ThrowableBooleanToFloatFunction<? extends X> before1, @Nonnull final ThrowableBooleanToFloatFunction<? extends X> before2) { Objects.requireNonNull(before1); Objects.requireNonNull(before2); return (value1, value2) -> applyAsFloatThrows(before1.applyAsFloatThrows(value1), before2.applyAsFloatThrows(value2)); } /** * Returns a composed {@link ThrowableBiByteToFloatFunction} that first applies the {@code before} functions to * its input, and then applies this operator to the result. * This method is just convenience, to provide the ability to execute an operation which accepts {@code byte} input, * before this primitive operator is executed. * * @param before1 The first function to apply before this operator is applied * @param before2 The second function to apply before this operator is applied * @return A composed {@code ThrowableBiByteToFloatFunction} that first applies the {@code before} functions to its * input, and then applies this operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to handle primitive values. In this case this is {@code * byte}. */ @Nonnull default ThrowableBiByteToFloatFunction<X> composeFromByte( @Nonnull final ThrowableByteToFloatFunction<? extends X> before1, @Nonnull final ThrowableByteToFloatFunction<? extends X> before2) { Objects.requireNonNull(before1); Objects.requireNonNull(before2); return (value1, value2) -> applyAsFloatThrows(before1.applyAsFloatThrows(value1), before2.applyAsFloatThrows(value2)); } /** * Returns a composed {@link ThrowableBiCharToFloatFunction} that first applies the {@code before} functions to * its input, and then applies this operator to the result. * This method is just convenience, to provide the ability to execute an operation which accepts {@code char} input, * before this primitive operator is executed. * * @param before1 The first function to apply before this operator is applied * @param before2 The second function to apply before this operator is applied * @return A composed {@code ThrowableBiCharToFloatFunction} that first applies the {@code before} functions to its * input, and then applies this operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to handle primitive values. In this case this is {@code * char}. */ @Nonnull default ThrowableBiCharToFloatFunction<X> composeFromChar( @Nonnull final ThrowableCharToFloatFunction<? extends X> before1, @Nonnull final ThrowableCharToFloatFunction<? extends X> before2) { Objects.requireNonNull(before1); Objects.requireNonNull(before2); return (value1, value2) -> applyAsFloatThrows(before1.applyAsFloatThrows(value1), before2.applyAsFloatThrows(value2)); } /** * Returns a composed {@link ThrowableBiDoubleToFloatFunction} that first applies the {@code before} functions to * its input, and then applies this operator to the result. This method is just convenience, to provide the ability * to execute an operation which accepts {@code double} input, before this primitive operator is executed. * * @param before1 The first function to apply before this operator is applied * @param before2 The second function to apply before this operator is applied * @return A composed {@code ThrowableBiDoubleToFloatFunction} that first applies the {@code before} functions to * its input, and then applies this operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to handle primitive values. In this case this is {@code * double}. */ @Nonnull default ThrowableBiDoubleToFloatFunction<X> composeFromDouble( @Nonnull final ThrowableDoubleToFloatFunction<? extends X> before1, @Nonnull final ThrowableDoubleToFloatFunction<? extends X> before2) { Objects.requireNonNull(before1); Objects.requireNonNull(before2); return (value1, value2) -> applyAsFloatThrows(before1.applyAsFloatThrows(value1), before2.applyAsFloatThrows(value2)); } /** * Returns a composed {@link ThrowableFloatBinaryOperator} that first applies the {@code before} operators to its * input, and then applies this operator to the result. This method is just convenience, to provide the ability to * execute an operation which accepts {@code float} input, before this primitive operator is executed. * * @param before1 The first operator to apply before this operator is applied * @param before2 The second operator to apply before this operator is applied * @return A composed {@code ThrowableFloatBinaryOperator} that first applies the {@code before} operators to its * input, and then applies this operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to handle primitive values. In this case this is {@code * float}. */ @Nonnull default ThrowableFloatBinaryOperator<X> composeFromFloat( @Nonnull final ThrowableFloatUnaryOperator<? extends X> before1, @Nonnull final ThrowableFloatUnaryOperator<? extends X> before2) { Objects.requireNonNull(before1); Objects.requireNonNull(before2); return (value1, value2) -> applyAsFloatThrows(before1.applyAsFloatThrows(value1), before2.applyAsFloatThrows(value2)); } /** * Returns a composed {@link ThrowableBiIntToFloatFunction} that first applies the {@code before} functions to * its input, and then applies this operator to the result. * This method is just convenience, to provide the ability to execute an operation which accepts {@code int} input, * before this primitive operator is executed. * * @param before1 The first function to apply before this operator is applied * @param before2 The second function to apply before this operator is applied * @return A composed {@code ThrowableBiIntToFloatFunction} that first applies the {@code before} functions to its * input, and then applies this operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to handle primitive values. In this case this is {@code * int}. */ @Nonnull default ThrowableBiIntToFloatFunction<X> composeFromInt( @Nonnull final ThrowableIntToFloatFunction<? extends X> before1, @Nonnull final ThrowableIntToFloatFunction<? extends X> before2) { Objects.requireNonNull(before1); Objects.requireNonNull(before2); return (value1, value2) -> applyAsFloatThrows(before1.applyAsFloatThrows(value1), before2.applyAsFloatThrows(value2)); } /** * Returns a composed {@link ThrowableBiLongToFloatFunction} that first applies the {@code before} functions to * its input, and then applies this operator to the result. * This method is just convenience, to provide the ability to execute an operation which accepts {@code long} input, * before this primitive operator is executed. * * @param before1 The first function to apply before this operator is applied * @param before2 The second function to apply before this operator is applied * @return A composed {@code ThrowableBiLongToFloatFunction} that first applies the {@code before} functions to its * input, and then applies this operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to handle primitive values. In this case this is {@code * long}. */ @Nonnull default ThrowableBiLongToFloatFunction<X> composeFromLong( @Nonnull final ThrowableLongToFloatFunction<? extends X> before1, @Nonnull final ThrowableLongToFloatFunction<? extends X> before2) { Objects.requireNonNull(before1); Objects.requireNonNull(before2); return (value1, value2) -> applyAsFloatThrows(before1.applyAsFloatThrows(value1), before2.applyAsFloatThrows(value2)); } /** * Returns a composed {@link ThrowableBiShortToFloatFunction} that first applies the {@code before} functions to its * input, and then applies this operator to the result. This method is just convenience, to provide the ability to * execute an operation which accepts {@code short} input, before this primitive operator is executed. * * @param before1 The first function to apply before this operator is applied * @param before2 The second function to apply before this operator is applied * @return A composed {@code ThrowableBiShortToFloatFunction} that first applies the {@code before} functions to its * input, and then applies this operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to handle primitive values. In this case this is {@code * short}. */ @Nonnull default ThrowableBiShortToFloatFunction<X> composeFromShort( @Nonnull final ThrowableShortToFloatFunction<? extends X> before1, @Nonnull final ThrowableShortToFloatFunction<? extends X> before2) { Objects.requireNonNull(before1); Objects.requireNonNull(before2); return (value1, value2) -> applyAsFloatThrows(before1.applyAsFloatThrows(value1), before2.applyAsFloatThrows(value2)); } /** * Returns a composed {@link ThrowableBiFloatFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. * * @param <S> The type of return value from the {@code after} function, and of the composed function * @param after The function to apply after this operator is applied * @return A composed {@code ThrowableBiFloatFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is able to return every type. */ @Nonnull default <S> ThrowableBiFloatFunction<S, X> andThen( @Nonnull final ThrowableFloatFunction<? extends S, ? extends X> after) { Objects.requireNonNull(after); return (value1, value2) -> after.applyThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a composed {@link ThrowableBiFloatPredicate} that first applies this operator to its input, and then * applies the {@code after} predicate to the result. This method is just convenience, to provide the ability to * transform this primitive operator to an operation returning {@code boolean}. * * @param after The predicate to apply after this operator is applied * @return A composed {@code ThrowableBiFloatPredicate} that first applies this operator to its input, and then * applies the {@code after} predicate to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to return primitive values. In this case this is {@code * boolean}. */ @Nonnull default ThrowableBiFloatPredicate<X> andThenToBoolean( @Nonnull final ThrowableFloatPredicate<? extends X> after) { Objects.requireNonNull(after); return (value1, value2) -> after.testThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a composed {@link ThrowableBiFloatToByteFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. This method is just convenience, to provide the ability to * transform this primitive operator to an operation returning {@code byte}. * * @param after The function to apply after this operator is applied * @return A composed {@code ThrowableBiFloatToByteFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to return primitive values. In this case this is {@code * byte}. */ @Nonnull default ThrowableBiFloatToByteFunction<X> andThenToByte( @Nonnull final ThrowableFloatToByteFunction<? extends X> after) { Objects.requireNonNull(after); return (value1, value2) -> after.applyAsByteThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a composed {@link ThrowableBiFloatToCharFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. This method is just convenience, to provide the ability to * transform this primitive operator to an operation returning {@code char}. * * @param after The function to apply after this operator is applied * @return A composed {@code ThrowableBiFloatToCharFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to return primitive values. In this case this is {@code * char}. */ @Nonnull default ThrowableBiFloatToCharFunction<X> andThenToChar( @Nonnull final ThrowableFloatToCharFunction<? extends X> after) { Objects.requireNonNull(after); return (value1, value2) -> after.applyAsCharThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a composed {@link ThrowableBiFloatToDoubleFunction} that first applies this operator to its input, and * then applies the {@code after} function to the result. This method is just convenience, to provide the ability to * transform this primitive operator to an operation returning {@code double}. * * @param after The function to apply after this operator is applied * @return A composed {@code ThrowableBiFloatToDoubleFunction} that first applies this operator to its input, and * then applies the {@code after} function to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to return primitive values. In this case this is {@code * double}. */ @Nonnull default ThrowableBiFloatToDoubleFunction<X> andThenToDouble( @Nonnull final ThrowableFloatToDoubleFunction<? extends X> after) { Objects.requireNonNull(after); return (value1, value2) -> after.applyAsDoubleThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a composed {@link ThrowableFloatBinaryOperator} that first applies this operator to its input, and then * applies the {@code after} operator to the result. This method is just convenience, to provide the ability to * transform this primitive operator to an operation returning {@code float}. * * @param after The operator to apply after this operator is applied * @return A composed {@code ThrowableFloatBinaryOperator} that first applies this operator to its input, and then * applies the {@code after} operator to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to return primitive values. In this case this is {@code * float}. */ @Nonnull default ThrowableFloatBinaryOperator<X> andThenToFloat( @Nonnull final ThrowableFloatUnaryOperator<? extends X> after) { Objects.requireNonNull(after); return (value1, value2) -> after.applyAsFloatThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a composed {@link ThrowableBiFloatToIntFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. This method is just convenience, to provide the ability to * transform this primitive operator to an operation returning {@code int}. * * @param after The function to apply after this operator is applied * @return A composed {@code ThrowableBiFloatToIntFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to return primitive values. In this case this is {@code * int}. */ @Nonnull default ThrowableBiFloatToIntFunction<X> andThenToInt( @Nonnull final ThrowableFloatToIntFunction<? extends X> after) { Objects.requireNonNull(after); return (value1, value2) -> after.applyAsIntThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a composed {@link ThrowableBiFloatToLongFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. This method is just convenience, to provide the ability to * transform this primitive operator to an operation returning {@code long}. * * @param after The function to apply after this operator is applied * @return A composed {@code ThrowableBiFloatToLongFunction} that first applies this operator to its input, and then * applies the {@code after} function to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to return primitive values. In this case this is {@code * long}. */ @Nonnull default ThrowableBiFloatToLongFunction<X> andThenToLong( @Nonnull final ThrowableFloatToLongFunction<? extends X> after) { Objects.requireNonNull(after); return (value1, value2) -> after.applyAsLongThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a composed {@link ThrowableBiFloatToShortFunction} that first applies this operator to its input, and * then applies the {@code after} function to the result. This method is just convenience, to provide the ability to * transform this primitive operator to an operation returning {@code short}. * * @param after The function to apply after this operator is applied * @return A composed {@code ThrowableBiFloatToShortFunction} that first applies this operator to its input, and * then applies the {@code after} function to the result. * @throws NullPointerException If given argument is {@code null} * @implSpec The input argument of this method is a able to return primitive values. In this case this is {@code * short}. */ @Nonnull default ThrowableBiFloatToShortFunction<X> andThenToShort( @Nonnull final ThrowableFloatToShortFunction<? extends X> after) { Objects.requireNonNull(after); return (value1, value2) -> after.applyAsShortThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a composed {@link ThrowableBiFloatConsumer} that fist applies this operator to its input, and then * consumes the result using the given {@link ThrowableFloatConsumer}. * * @param consumer The operation which consumes the result from this operation * @return A composed {@code ThrowableBiFloatConsumer} that first applies this operator to its input, and then * consumes the result using the given {@code ThrowableFloatConsumer}. * @throws NullPointerException If given argument is {@code null} */ @Nonnull default ThrowableBiFloatConsumer<X> consume(@Nonnull final ThrowableFloatConsumer<? extends X> consumer) { Objects.requireNonNull(consumer); return (value1, value2) -> consumer.acceptThrows(applyAsFloatThrows(value1, value2)); } /** * Returns a memoized (caching) version of this {@link ThrowableFloatBinaryOperator}. Whenever it is called, the * mapping between the input parameters and the return value is preserved in a cache, making subsequent calls * returning the memoized value instead of computing the return value again. * <p> * Unless the operator and therefore the used cache will be garbage-collected, it will keep all memoized values * forever. * * @return A memoized (caching) version of this {@code ThrowableFloatBinaryOperator}. * @implSpec This implementation does not allow the input parameters or return value to be {@code null} for the * resulting memoized operator, as the cache used internally does not permit {@code null} keys or values. * @implNote The returned memoized operator can be safely used concurrently from multiple threads which makes it * thread-safe. */ @Nonnull default ThrowableFloatBinaryOperator<X> memoized() { if (isMemoized()) { return this; } else { final Map<Pair<Float, Float>, Float> cache = new ConcurrentHashMap<>(); final Object lock = new Object(); return (ThrowableFloatBinaryOperator<X> & Memoized) (value1, value2) -> { final float returnValue; synchronized (lock) { returnValue = cache.computeIfAbsent(Pair.of(value1, value2), ThrowableFunction.of(key -> applyAsFloatThrows(key.getLeft(), key.getRight()))); } return returnValue; }; } } /** * Returns a composed {@link ThrowableBinaryOperator} which represents this {@link ThrowableFloatBinaryOperator}. * Thereby the primitive input argument for this operator is autoboxed. This method provides the possibility to use * this {@code ThrowableFloatBinaryOperator} with methods provided by the {@code JDK}. * * @return A composed {@code ThrowableBinaryOperator} which represents this {@code ThrowableFloatBinaryOperator}. */ @Nonnull default ThrowableBinaryOperator<Float, X> boxed() { return this::applyAsFloatThrows; } /** * Returns a composed {@link FloatBinaryOperator} that applies this operator to its input and nests the thrown * {@link Throwable} from it. The {@code Throwable} is nested (wrapped) in a {@link * ThrownByFunctionalInterfaceException}, which is constructed from the thrown {@code Throwable}s message and the * thrown {@code Throwable} itself. * * @return A composed {@link FloatBinaryOperator} that applies this operator to its input and nests the thrown * {@code Throwable} from it. * @implNote If thrown {@code Throwable} is of type {@link Error} it is thrown as-is and thus not nested. * @see #nestWith(Function) * @see ThrownByFunctionalInterfaceException */ @Nonnull default FloatBinaryOperator nest() { return nestWith(throwable -> new ThrownByFunctionalInterfaceException(throwable.getMessage(), throwable)); } /** * Returns a composed {@link FloatBinaryOperator} that applies this operator to its input and nests the thrown * {@link Throwable} from it using {@code mapper} operation. Thereby {@code mapper} may modify the thrown {@code * Throwable}, regarding its implementation, and returns it nested (wrapped) in a {@link RuntimeException}. * * @param mapper The operation to map the thrown {@code Throwable} to {@code RuntimeException} * @return A composed {@link FloatBinaryOperator} that applies this operator to its input and nests the thrown * {@code Throwable} from it using {@code mapper} operation. * @throws NullPointerException If given argument is {@code null} * @implNote If thrown {@code Throwable} is of type {@link Error} it is thrown as-is and thus not nested. * @see #nest() */ @Nonnull default FloatBinaryOperator nestWith( @Nonnull final Function<? super Throwable, ? extends RuntimeException> mapper) { return recover(throwable -> { throw mapper.apply(throwable); }); } /** * Returns a composed {@link FloatBinaryOperator} that applies this operator to its input and sneakily throws the * thrown {@link Throwable} from it, if it is not of type {@link RuntimeException} or {@link Error}. This means that * each throwable thrown from the returned composed operator behaves exactly the same as an <em>unchecked</em> * throwable does. As a result, there is no need to handle the throwable of this operator in the returned composed * operator by either wrapping it in an <em>unchecked</em> throwable or to declare it in the {@code throws} clause, * as it would be done in a non sneaky throwing operator. * <p> * What sneaky throwing simply does, is to fake out the compiler and thus it bypasses the principle of * <em>checked</em> throwables. On the JVM (class file) level, all throwables, checked or not, can be thrown * regardless of the {@code throws} clause of methods, which is why this works at all. * <p> * However, when using this method to get a sneaky throwing operator variant of this throwable operator, the * following advantages, disadvantages and limitations will apply: * <p> * If the calling-code is to handle the sneakily thrown throwable, it is required to add it to the {@code throws} * clause of the method that applies the returned composed operator. The compiler will not force the declaration in * the {@code throws} clause anymore. * <p> * If the calling-code already handles the sneakily thrown throwable, the compiler requires it to be added to the * {@code throws} clause of the method that applies the returned composed operator. If not added, the compiler will * error that the caught throwable is never thrown in the corresponding {@code try} block. * <p> * If the returned composed operator is directly surrounded by a {@code try}-{@code catch} block to catch the * sneakily thrown throwable from it, the compiler will error that the caught throwable is never thrown in the * corresponding {@code try} block. * <p> * In any case, if the throwable is not added to the to the {@code throws} clause of the method that applies the * returned composed operator, the calling-code won't be able to catch the throwable by name. It will bubble and * probably be caught in some {@code catch} statement, catching a base type such as {@code try { ... } * catch(RuntimeException e) { ... }} or {@code try { ... } catch(Exception e) { ... }}, but perhaps this is * intended. * <p> * When the called code never throws the specific throwable that it declares, it should obviously be omitted. For * example: {@code new String(byteArr, "UTF-8") throws UnsupportedEncodingException}, but {@code UTF-8} is * guaranteed by the Java specification to be always present. Here, the {@code throws} declaration is a nuisance and * any solution to silence it with minimal boilerplate is welcome. The throwable should therefore be omitted in the * {@code throws} clause of the method that applies the returned composed operator. * <p> * With all that mentioned, the following example will demonstrate this methods correct use: * <pre>{@code * // when called with illegal value ClassNotFoundException is thrown * public Class<?> sneakyThrowingFunctionalInterface(final String className) throws ClassNotFoundException { * return ThrowableFunction.of(Class::forName) // create the correct throwable functional interface * .sneakyThrow() // create a non-throwable variant which is able to sneaky throw (this method) * .apply(className); // apply non-throwable variant -> may sneaky throw a throwable * } * * // call the the method which surround the sneaky throwing functional interface * public void callingMethod() { * try { * final Class<?> clazz = sneakyThrowingFunctionalInterface("some illegal class name"); * // ... do something with clazz ... * } catch(ClassNotFoundException e) { * // ... do something with e ... * } * } * }</pre> * In conclusion, this somewhat contentious ability should be used carefully, of course, with the advantages, * disadvantages and limitations described above kept in mind. * * @return A composed {@link FloatBinaryOperator} that applies this operator to its input and sneakily throws the * thrown {@link Throwable} from it, unless it is of type {@link RuntimeException} or {@link Error}. * @implNote If thrown {@link Throwable} is of type {@link RuntimeException} or {@link Error}, it is thrown as-is * and thus not sneakily thrown. */ @Nonnull default FloatBinaryOperator sneakyThrow() { return (value1, value2) -> { try { return this.applyAsFloatThrows(value1, value2); } catch (RuntimeException | Error e) { throw e; } catch (Throwable throwable) { throw ThrowableUtils.sneakyThrow(throwable); } }; } /** * Returns a composed {@link FloatBinaryOperator} that first applies this operator to its input, and then applies * the {@code recover} operation if a {@link Throwable} is thrown from this one. The {@code recover} operation is * represented by a curried operation which is called with throwable information and same arguments of this * operator. * * @param recover The operation to apply if this operator throws a {@code Throwable} * @return A composed {@link FloatBinaryOperator} that first applies this operator to its input, and then applies * the {@code recover} operation if a {@code Throwable} is thrown from this one. * @throws NullPointerException If given argument or the returned enclosing operator is {@code null} * @implSpec The implementation checks that the returned enclosing operator from {@code recover} operation is not * {@code null}. If it is, then a {@link NullPointerException} with appropriate message is thrown. * @implNote If thrown {@code Throwable} is of type {@link Error}, it is thrown as-is and thus not passed to {@code * recover} operation. */ @Nonnull default FloatBinaryOperator recover( @Nonnull final Function<? super Throwable, ? extends FloatBinaryOperator> recover) { Objects.requireNonNull(recover); return (value1, value2) -> { try { return this.applyAsFloatThrows(value1, value2); } catch (Error e) { throw e; } catch (Throwable throwable) { final FloatBinaryOperator operator = recover.apply(throwable); Objects.requireNonNull(operator, () -> "recover returned null for " + throwable.getClass() + ": " + throwable.getMessage()); return operator.applyAsFloat(value1, value2); } }; } }