/* * Copyright (c) 2012, 2013, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle in the LICENSE file that accompanied this code. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ package java.util.stream; import java.util.Objects; import java.util.Optional; import java.util.OptionalDouble; import java.util.OptionalInt; import java.util.OptionalLong; import java.util.Spliterator; import java.util.concurrent.CountedCompleter; import java.util.function.BiConsumer; import java.util.function.BiFunction; import java.util.function.BinaryOperator; import java.util.function.DoubleBinaryOperator; import java.util.function.IntBinaryOperator; import java.util.function.LongBinaryOperator; import java.util.function.ObjDoubleConsumer; import java.util.function.ObjIntConsumer; import java.util.function.ObjLongConsumer; import java.util.function.Supplier; /** * Factory for creating instances of {@code TerminalOp} that implement * reductions. * * @since 1.8 */ final class ReduceOps { private ReduceOps() { } /** * Constructs a {@code TerminalOp} that implements a functional reduce on * reference values. * * @param the type of the input elements * @param the type of the result * @param seed the identity element for the reduction * @param reducer the accumulating function that incorporates an additional * input element into the result * @param combiner the combining function that combines two intermediate * results * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeRef(U seed, BiFunction reducer, BinaryOperator combiner) { Objects.requireNonNull(reducer); Objects.requireNonNull(combiner); class ReducingSink extends Box implements AccumulatingSink { @Override public void begin(long size) { state = seed; } @Override public void accept(T t) { state = reducer.apply(state, t); } @Override public void combine(ReducingSink other) { state = combiner.apply(state, other.state); } } return new ReduceOp(StreamShape.REFERENCE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a functional reduce on * reference values producing an optional reference result. * * @param The type of the input elements, and the type of the result * @param operator The reducing function * @return A {@code TerminalOp} implementing the reduction */ public static TerminalOp> makeRef(BinaryOperator operator) { Objects.requireNonNull(operator); class ReducingSink implements AccumulatingSink, ReducingSink> { private boolean empty; private T state; public void begin(long size) { empty = true; state = null; } @Override public void accept(T t) { if (empty) { empty = false; state = t; } else { state = operator.apply(state, t); } } @Override public Optional get() { return empty ? Optional.empty() : Optional.of(state); } @Override public void combine(ReducingSink other) { if (!other.empty) accept(other.state); } } return new ReduceOp, ReducingSink>(StreamShape.REFERENCE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a mutable reduce on * reference values. * * @param the type of the input elements * @param the type of the intermediate reduction result * @param collector a {@code Collector} defining the reduction * @return a {@code ReduceOp} implementing the reduction */ public static TerminalOp makeRef(Collector collector) { Supplier supplier = Objects.requireNonNull(collector).supplier(); BiConsumer accumulator = collector.accumulator(); BinaryOperator combiner = collector.combiner(); class ReducingSink extends Box implements AccumulatingSink { @Override public void begin(long size) { state = supplier.get(); } @Override public void accept(T t) { accumulator.accept(state, t); } @Override public void combine(ReducingSink other) { state = combiner.apply(state, other.state); } } return new ReduceOp(StreamShape.REFERENCE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } @Override public int getOpFlags() { return collector.characteristics().contains(Collector.Characteristics.UNORDERED) ? StreamOpFlag.NOT_ORDERED : 0; } }; } /** * Constructs a {@code TerminalOp} that implements a mutable reduce on * reference values. * * @param the type of the input elements * @param the type of the result * @param seedFactory a factory to produce a new base accumulator * @param accumulator a function to incorporate an element into an * accumulator * @param reducer a function to combine an accumulator into another * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeRef(Supplier seedFactory, BiConsumer accumulator, BiConsumer reducer) { Objects.requireNonNull(seedFactory); Objects.requireNonNull(accumulator); Objects.requireNonNull(reducer); class ReducingSink extends Box implements AccumulatingSink { @Override public void begin(long size) { state = seedFactory.get(); } @Override public void accept(T t) { accumulator.accept(state, t); } @Override public void combine(ReducingSink other) { reducer.accept(state, other.state); } } return new ReduceOp(StreamShape.REFERENCE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a functional reduce on * {@code int} values. * * @param identity the identity for the combining function * @param operator the combining function * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeInt(int identity, IntBinaryOperator operator) { Objects.requireNonNull(operator); class ReducingSink implements AccumulatingSink, Sink.OfInt { private int state; @Override public void begin(long size) { state = identity; } @Override public void accept(int t) { state = operator.applyAsInt(state, t); } @Override public Integer get() { return state; } @Override public void combine(ReducingSink other) { accept(other.state); } } return new ReduceOp(StreamShape.INT_VALUE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a functional reduce on * {@code int} values, producing an optional integer result. * * @param operator the combining function * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeInt(IntBinaryOperator operator) { Objects.requireNonNull(operator); class ReducingSink implements AccumulatingSink, Sink.OfInt { private boolean empty; private int state; public void begin(long size) { empty = true; state = 0; } @Override public void accept(int t) { if (empty) { empty = false; state = t; } else { state = operator.applyAsInt(state, t); } } @Override public OptionalInt get() { return empty ? OptionalInt.empty() : OptionalInt.of(state); } @Override public void combine(ReducingSink other) { if (!other.empty) accept(other.state); } } return new ReduceOp(StreamShape.INT_VALUE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a mutable reduce on * {@code int} values. * * @param The type of the result * @param supplier a factory to produce a new accumulator of the result type * @param accumulator a function to incorporate an int into an * accumulator * @param combiner a function to combine an accumulator into another * @return A {@code ReduceOp} implementing the reduction */ public static TerminalOp makeInt(Supplier supplier, ObjIntConsumer accumulator, BinaryOperator combiner) { Objects.requireNonNull(supplier); Objects.requireNonNull(accumulator); Objects.requireNonNull(combiner); class ReducingSink extends Box implements AccumulatingSink, Sink.OfInt { @Override public void begin(long size) { state = supplier.get(); } @Override public void accept(int t) { accumulator.accept(state, t); } @Override public void combine(ReducingSink other) { state = combiner.apply(state, other.state); } } return new ReduceOp(StreamShape.INT_VALUE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a functional reduce on * {@code long} values. * * @param identity the identity for the combining function * @param operator the combining function * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeLong(long identity, LongBinaryOperator operator) { Objects.requireNonNull(operator); class ReducingSink implements AccumulatingSink, Sink.OfLong { private long state; @Override public void begin(long size) { state = identity; } @Override public void accept(long t) { state = operator.applyAsLong(state, t); } @Override public Long get() { return state; } @Override public void combine(ReducingSink other) { accept(other.state); } } return new ReduceOp(StreamShape.LONG_VALUE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a functional reduce on * {@code long} values, producing an optional long result. * * @param operator the combining function * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeLong(LongBinaryOperator operator) { Objects.requireNonNull(operator); class ReducingSink implements AccumulatingSink, Sink.OfLong { private boolean empty; private long state; public void begin(long size) { empty = true; state = 0; } @Override public void accept(long t) { if (empty) { empty = false; state = t; } else { state = operator.applyAsLong(state, t); } } @Override public OptionalLong get() { return empty ? OptionalLong.empty() : OptionalLong.of(state); } @Override public void combine(ReducingSink other) { if (!other.empty) accept(other.state); } } return new ReduceOp(StreamShape.LONG_VALUE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a mutable reduce on * {@code long} values. * * @param the type of the result * @param supplier a factory to produce a new accumulator of the result type * @param accumulator a function to incorporate an int into an * accumulator * @param combiner a function to combine an accumulator into another * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeLong(Supplier supplier, ObjLongConsumer accumulator, BinaryOperator combiner) { Objects.requireNonNull(supplier); Objects.requireNonNull(accumulator); Objects.requireNonNull(combiner); class ReducingSink extends Box implements AccumulatingSink, Sink.OfLong { @Override public void begin(long size) { state = supplier.get(); } @Override public void accept(long t) { accumulator.accept(state, t); } @Override public void combine(ReducingSink other) { state = combiner.apply(state, other.state); } } return new ReduceOp(StreamShape.LONG_VALUE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a functional reduce on * {@code double} values. * * @param identity the identity for the combining function * @param operator the combining function * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeDouble(double identity, DoubleBinaryOperator operator) { Objects.requireNonNull(operator); class ReducingSink implements AccumulatingSink, Sink.OfDouble { private double state; @Override public void begin(long size) { state = identity; } @Override public void accept(double t) { state = operator.applyAsDouble(state, t); } @Override public Double get() { return state; } @Override public void combine(ReducingSink other) { accept(other.state); } } return new ReduceOp(StreamShape.DOUBLE_VALUE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a functional reduce on * {@code double} values, producing an optional double result. * * @param operator the combining function * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeDouble(DoubleBinaryOperator operator) { Objects.requireNonNull(operator); class ReducingSink implements AccumulatingSink, Sink.OfDouble { private boolean empty; private double state; public void begin(long size) { empty = true; state = 0; } @Override public void accept(double t) { if (empty) { empty = false; state = t; } else { state = operator.applyAsDouble(state, t); } } @Override public OptionalDouble get() { return empty ? OptionalDouble.empty() : OptionalDouble.of(state); } @Override public void combine(ReducingSink other) { if (!other.empty) accept(other.state); } } return new ReduceOp(StreamShape.DOUBLE_VALUE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * Constructs a {@code TerminalOp} that implements a mutable reduce on * {@code double} values. * * @param the type of the result * @param supplier a factory to produce a new accumulator of the result type * @param accumulator a function to incorporate an int into an * accumulator * @param combiner a function to combine an accumulator into another * @return a {@code TerminalOp} implementing the reduction */ public static TerminalOp makeDouble(Supplier supplier, ObjDoubleConsumer accumulator, BinaryOperator combiner) { Objects.requireNonNull(supplier); Objects.requireNonNull(accumulator); Objects.requireNonNull(combiner); class ReducingSink extends Box implements AccumulatingSink, Sink.OfDouble { @Override public void begin(long size) { state = supplier.get(); } @Override public void accept(double t) { accumulator.accept(state, t); } @Override public void combine(ReducingSink other) { state = combiner.apply(state, other.state); } } return new ReduceOp(StreamShape.DOUBLE_VALUE) { @Override public ReducingSink makeSink() { return new ReducingSink(); } }; } /** * A type of {@code TerminalSink} that implements an associative reducing * operation on elements of type {@code T} and producing a result of type * {@code R}. * * @param the type of input element to the combining operation * @param the result type * @param the type of the {@code AccumulatingSink}. */ private interface AccumulatingSink> extends TerminalSink { public void combine(K other); } /** * State box for a single state element, used as a base class for * {@code AccumulatingSink} instances * * @param The type of the state element */ private static abstract class Box { U state; Box() {} // Avoid creation of special accessor public U get() { return state; } } /** * A {@code TerminalOp} that evaluates a stream pipeline and sends the * output into an {@code AccumulatingSink}, which performs a reduce * operation. The {@code AccumulatingSink} must represent an associative * reducing operation. * * @param the output type of the stream pipeline * @param the result type of the reducing operation * @param the type of the {@code AccumulatingSink} */ private static abstract class ReduceOp> implements TerminalOp { private final StreamShape inputShape; /** * Create a {@code ReduceOp} of the specified stream shape which uses * the specified {@code Supplier} to create accumulating sinks. * * @param shape The shape of the stream pipeline */ ReduceOp(StreamShape shape) { inputShape = shape; } public abstract S makeSink(); @Override public StreamShape inputShape() { return inputShape; } @Override public R evaluateSequential(PipelineHelper helper, Spliterator spliterator) { return helper.wrapAndCopyInto(makeSink(), spliterator).get(); } @Override public R evaluateParallel(PipelineHelper helper, Spliterator spliterator) { return new ReduceTask<>(this, helper, spliterator).invoke().get(); } } /** * A {@code ForkJoinTask} for performing a parallel reduce operation. */ @SuppressWarnings("serial") private static final class ReduceTask> extends AbstractTask> { private final ReduceOp op; ReduceTask(ReduceOp op, PipelineHelper helper, Spliterator spliterator) { super(helper, spliterator); this.op = op; } ReduceTask(ReduceTask parent, Spliterator spliterator) { super(parent, spliterator); this.op = parent.op; } @Override protected ReduceTask makeChild(Spliterator spliterator) { return new ReduceTask<>(this, spliterator); } @Override protected S doLeaf() { return helper.wrapAndCopyInto(op.makeSink(), spliterator); } @Override public void onCompletion(CountedCompleter caller) { if (!isLeaf()) { S leftResult = leftChild.getLocalResult(); leftResult.combine(rightChild.getLocalResult()); setLocalResult(leftResult); } // GC spliterator, left and right child super.onCompletion(caller); } } }