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Backport of Java 9 java.util.stream API for Android Studio 3+ desugar toolchain, forked from http://sourceforge.net/projects/streamsupport

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/*
 * 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 java9.util.stream;

import java.util.ArrayList;
import java.util.Arrays;
import java.util.Iterator;
import java.util.List;

import java9.util.Objects;
import java9.util.PrimitiveIterator;
import java9.util.Spliterator;
import java9.util.Spliterators;
import java9.util.function.Consumer;
import java9.util.function.DoubleConsumer;
import java9.util.function.IntConsumer;
import java9.util.function.IntFunction;
import java9.util.function.LongConsumer;

/**
 * An ordered collection of elements.  Elements can be added, but not removed.
 * Goes through a building phase, during which elements can be added, and a
 * traversal phase, during which elements can be traversed in order but no
 * further modifications are possible.
 *
 * 

One or more arrays are used to store elements. The use of a multiple * arrays has better performance characteristics than a single array used by * {@link ArrayList}, as when the capacity of the list needs to be increased * no copying of elements is required. This is usually beneficial in the case * where the results will be traversed a small number of times. * * @param the type of elements in this list * @since 1.8 */ class SpinedBuffer extends AbstractSpinedBuffer implements Consumer { /* * We optimistically hope that all the data will fit into the first chunk, * so we try to avoid inflating the spine[] and priorElementCount[] arrays * prematurely. So methods must be prepared to deal with these arrays being * null. If spine is non-null, then spineIndex points to the current chunk * within the spine, otherwise it is zero. The spine and priorElementCount * arrays are always the same size, and for any i <= spineIndex, * priorElementCount[i] is the sum of the sizes of all the prior chunks. * * The curChunk pointer is always valid. The elementIndex is the index of * the next element to be written in curChunk; this may be past the end of * curChunk so we have to check before writing. When we inflate the spine * array, curChunk becomes the first element in it. When we clear the * buffer, we discard all chunks except the first one, which we clear, * restoring it to the initial single-chunk state. */ /** * Chunk that we're currently writing into; may or may not be aliased with * the first element of the spine. */ protected E[] curChunk; /** * All chunks, or null if there is only one chunk. */ protected E[][] spine; /** * Constructs an empty list with the specified initial capacity. * * @param initialCapacity the initial capacity of the list * @throws IllegalArgumentException if the specified initial capacity * is negative */ @SuppressWarnings("unchecked") SpinedBuffer(int initialCapacity) { super(initialCapacity); curChunk = (E[]) new Object[1 << initialChunkPower]; } /** * Constructs an empty list with an initial capacity of sixteen. */ @SuppressWarnings("unchecked") SpinedBuffer() { super(); curChunk = (E[]) new Object[1 << initialChunkPower]; } /** * Returns the current capacity of the buffer */ protected long capacity() { return (spineIndex == 0) ? curChunk.length : priorElementCount[spineIndex] + spine[spineIndex].length; } @SuppressWarnings("unchecked") private void inflateSpine() { if (spine == null) { spine = (E[][]) new Object[MIN_SPINE_SIZE][]; priorElementCount = new long[MIN_SPINE_SIZE]; spine[0] = curChunk; } } /** * Ensure that the buffer has at least capacity to hold the target size */ @SuppressWarnings("unchecked") protected final void ensureCapacity(long targetSize) { long capacity = capacity(); if (targetSize > capacity) { inflateSpine(); for (int i = spineIndex + 1; targetSize > capacity; i++) { if (i >= spine.length) { int newSpineSize = spine.length * 2; spine = Arrays.copyOf(spine, newSpineSize); priorElementCount = Arrays.copyOf(priorElementCount, newSpineSize); } int nextChunkSize = chunkSize(i); spine[i] = (E[]) new Object[nextChunkSize]; priorElementCount[i] = priorElementCount[i-1] + spine[i-1].length; capacity += nextChunkSize; } } } /** * Force the buffer to increase its capacity. */ protected void increaseCapacity() { ensureCapacity(capacity() + 1); } /** * Retrieve the element at the specified index. */ public E get(long index) { // @@@ can further optimize by caching last seen spineIndex, // which is going to be right most of the time // Casts to int are safe since the spine array index is the index minus // the prior element count from the current spine if (spineIndex == 0) { if (index < elementIndex) return curChunk[((int) index)]; else throw new IndexOutOfBoundsException(Long.toString(index)); } if (index >= count()) throw new IndexOutOfBoundsException(Long.toString(index)); for (int j=0; j <= spineIndex; j++) if (index < priorElementCount[j] + spine[j].length) return spine[j][((int) (index - priorElementCount[j]))]; throw new IndexOutOfBoundsException(Long.toString(index)); } /** * Copy the elements, starting at the specified offset, into the specified * array. */ public void copyInto(E[] array, int offset) { long finalOffset = offset + count(); if (finalOffset > array.length || finalOffset < offset) { throw new IndexOutOfBoundsException("does not fit"); } if (spineIndex == 0) System.arraycopy(curChunk, 0, array, offset, elementIndex); else { // full chunks for (int i=0; i < spineIndex; i++) { System.arraycopy(spine[i], 0, array, offset, spine[i].length); offset += spine[i].length; } if (elementIndex > 0) System.arraycopy(curChunk, 0, array, offset, elementIndex); } } /** * Create a new array using the specified array factory, and copy the * elements into it. */ public E[] asArray(IntFunction arrayFactory) { long size = count(); if (size >= Nodes.MAX_ARRAY_SIZE) throw new IllegalArgumentException(Nodes.BAD_SIZE); E[] result = arrayFactory.apply((int) size); copyInto(result, 0); return result; } @Override public void clear() { if (spine != null) { curChunk = spine[0]; for (int i=0; i iterator() { return Spliterators.iterator(spliterator()); } public void forEach(Consumer consumer) { // completed chunks, if any for (int j = 0; j < spineIndex; j++) { for (E t : spine[j]) { consumer.accept(t); } } // current chunk for (int i=0; i= spine.length || spine[spineIndex+1] == null) increaseCapacity(); elementIndex = 0; ++spineIndex; curChunk = spine[spineIndex]; } curChunk[elementIndex++] = e; } @Override public String toString() { List list = new ArrayList<>(); forEach(list::add); return "SpinedBuffer:" + list.toString(); } private static final int SPLITERATOR_CHARACTERISTICS = Spliterator.SIZED | Spliterator.ORDERED | Spliterator.SUBSIZED; /** * Return a {@link Spliterator} describing the contents of the buffer. */ Spliterator spliterator() { class Splitr implements Spliterator { // The current spine index int splSpineIndex; // Last spine index final int lastSpineIndex; // The current element index into the current spine int splElementIndex; // Last spine's last element index + 1 final int lastSpineElementFence; // When splSpineIndex >= lastSpineIndex and // splElementIndex >= lastSpineElementFence then // this spliterator is fully traversed // tryAdvance can set splSpineIndex > spineIndex if the last spine is full // The current spine array E[] splChunk; Splitr(int firstSpineIndex, int lastSpineIndex, int firstSpineElementIndex, int lastSpineElementFence) { this.splSpineIndex = firstSpineIndex; this.lastSpineIndex = lastSpineIndex; this.splElementIndex = firstSpineElementIndex; this.lastSpineElementFence = lastSpineElementFence; splChunk = (spine == null) ? curChunk : spine[firstSpineIndex]; } @Override public long estimateSize() { return (splSpineIndex == lastSpineIndex) ? (long) lastSpineElementFence - splElementIndex : // # of elements prior to end - priorElementCount[lastSpineIndex] + lastSpineElementFence - // # of elements prior to current priorElementCount[splSpineIndex] - splElementIndex; } @Override public int characteristics() { return SPLITERATOR_CHARACTERISTICS; } @Override public boolean tryAdvance(Consumer consumer) { Objects.requireNonNull(consumer); if (splSpineIndex < lastSpineIndex || (splSpineIndex == lastSpineIndex && splElementIndex < lastSpineElementFence)) { consumer.accept(splChunk[splElementIndex++]); if (splElementIndex == splChunk.length) { splElementIndex = 0; ++splSpineIndex; if (spine != null && splSpineIndex <= lastSpineIndex) splChunk = spine[splSpineIndex]; } return true; } return false; } @Override public void forEachRemaining(Consumer consumer) { Objects.requireNonNull(consumer); if (splSpineIndex < lastSpineIndex || (splSpineIndex == lastSpineIndex && splElementIndex < lastSpineElementFence)) { int i = splElementIndex; // completed chunks, if any for (int sp = splSpineIndex; sp < lastSpineIndex; sp++) { E[] chunk = spine[sp]; for (; i < chunk.length; i++) { consumer.accept(chunk[i]); } i = 0; } // last (or current uncompleted) chunk E[] chunk = (splSpineIndex == lastSpineIndex) ? splChunk : spine[lastSpineIndex]; int hElementIndex = lastSpineElementFence; for (; i < hElementIndex; i++) { consumer.accept(chunk[i]); } // mark consumed splSpineIndex = lastSpineIndex; splElementIndex = lastSpineElementFence; } } @Override public Spliterator trySplit() { if (splSpineIndex < lastSpineIndex) { // split just before last chunk (if it is full this means 50:50 split) Spliterator ret = new Splitr(splSpineIndex, lastSpineIndex - 1, splElementIndex, spine[lastSpineIndex-1].length); // position to start of last chunk splSpineIndex = lastSpineIndex; splElementIndex = 0; splChunk = spine[splSpineIndex]; return ret; } else if (splSpineIndex == lastSpineIndex) { int t = (lastSpineElementFence - splElementIndex) / 2; if (t == 0) return null; else { Spliterator ret = java9.util.J8Arrays.spliterator(splChunk, splElementIndex, splElementIndex + t); splElementIndex += t; return ret; } } else { return null; } } } return new Splitr(0, spineIndex, 0, elementIndex); } /** * An ordered collection of primitive values. Elements can be added, but * not removed. Goes through a building phase, during which elements can be * added, and a traversal phase, during which elements can be traversed in * order but no further modifications are possible. * *

One or more arrays are used to store elements. The use of a multiple * arrays has better performance characteristics than a single array used by * {@link ArrayList}, as when the capacity of the list needs to be increased * no copying of elements is required. This is usually beneficial in the case * where the results will be traversed a small number of times. * * @param the wrapper type for this primitive type * @param the array type for this primitive type * @param the Consumer type for this primitive type */ abstract static class OfPrimitive extends AbstractSpinedBuffer { /* * We optimistically hope that all the data will fit into the first chunk, * so we try to avoid inflating the spine[] and priorElementCount[] arrays * prematurely. So methods must be prepared to deal with these arrays being * null. If spine is non-null, then spineIndex points to the current chunk * within the spine, otherwise it is zero. The spine and priorElementCount * arrays are always the same size, and for any i <= spineIndex, * priorElementCount[i] is the sum of the sizes of all the prior chunks. * * The curChunk pointer is always valid. The elementIndex is the index of * the next element to be written in curChunk; this may be past the end of * curChunk so we have to check before writing. When we inflate the spine * array, curChunk becomes the first element in it. When we clear the * buffer, we discard all chunks except the first one, which we clear, * restoring it to the initial single-chunk state. */ // The chunk we're currently writing into T_ARR curChunk; // All chunks, or null if there is only one chunk T_ARR[] spine; /** * Constructs an empty list with the specified initial capacity. * * @param initialCapacity the initial capacity of the list * @throws IllegalArgumentException if the specified initial capacity * is negative */ OfPrimitive(int initialCapacity) { super(initialCapacity); curChunk = newArray(1 << initialChunkPower); } /** * Constructs an empty list with an initial capacity of sixteen. */ OfPrimitive() { super(); curChunk = newArray(1 << initialChunkPower); } public abstract Iterator iterator(); public abstract void forEach(Consumer consumer); /** Create a new array-of-array of the proper type and size */ protected abstract T_ARR[] newArrayArray(int size); /** Create a new array of the proper type and size */ public abstract T_ARR newArray(int size); /** Get the length of an array */ protected abstract int arrayLength(T_ARR array); /** Iterate an array with the provided consumer */ protected abstract void arrayForEach(T_ARR array, int from, int to, T_CONS consumer); protected long capacity() { return (spineIndex == 0) ? arrayLength(curChunk) : priorElementCount[spineIndex] + arrayLength(spine[spineIndex]); } private void inflateSpine() { if (spine == null) { spine = newArrayArray(MIN_SPINE_SIZE); priorElementCount = new long[MIN_SPINE_SIZE]; spine[0] = curChunk; } } protected final void ensureCapacity(long targetSize) { long capacity = capacity(); if (targetSize > capacity) { inflateSpine(); for (int i=spineIndex+1; targetSize > capacity; i++) { if (i >= spine.length) { int newSpineSize = spine.length * 2; spine = Arrays.copyOf(spine, newSpineSize); priorElementCount = Arrays.copyOf(priorElementCount, newSpineSize); } int nextChunkSize = chunkSize(i); spine[i] = newArray(nextChunkSize); priorElementCount[i] = priorElementCount[i-1] + arrayLength(spine[i - 1]); capacity += nextChunkSize; } } } protected void increaseCapacity() { ensureCapacity(capacity() + 1); } protected int chunkFor(long index) { if (spineIndex == 0) { if (index < elementIndex) return 0; else throw new IndexOutOfBoundsException(Long.toString(index)); } if (index >= count()) throw new IndexOutOfBoundsException(Long.toString(index)); for (int j=0; j <= spineIndex; j++) if (index < priorElementCount[j] + arrayLength(spine[j])) return j; throw new IndexOutOfBoundsException(Long.toString(index)); } public void copyInto(T_ARR array, int offset) { long finalOffset = offset + count(); if (finalOffset > arrayLength(array) || finalOffset < offset) { throw new IndexOutOfBoundsException("does not fit"); } if (spineIndex == 0) System.arraycopy(curChunk, 0, array, offset, elementIndex); else { // full chunks for (int i=0; i < spineIndex; i++) { System.arraycopy(spine[i], 0, array, offset, arrayLength(spine[i])); offset += arrayLength(spine[i]); } if (elementIndex > 0) System.arraycopy(curChunk, 0, array, offset, elementIndex); } } public T_ARR asPrimitiveArray() { long size = count(); if (size >= Nodes.MAX_ARRAY_SIZE) throw new IllegalArgumentException(Nodes.BAD_SIZE); T_ARR result = newArray((int) size); copyInto(result, 0); return result; } protected void preAccept() { if (elementIndex == arrayLength(curChunk)) { inflateSpine(); if (spineIndex+1 >= spine.length || spine[spineIndex+1] == null) increaseCapacity(); elementIndex = 0; ++spineIndex; curChunk = spine[spineIndex]; } } public void clear() { if (spine != null) { curChunk = spine[0]; spine = null; priorElementCount = null; } elementIndex = 0; spineIndex = 0; } public void forEach(T_CONS consumer) { // completed chunks, if any for (int j = 0; j < spineIndex; j++) { arrayForEach(spine[j], 0, arrayLength(spine[j]), consumer); } // current chunk arrayForEach(curChunk, 0, elementIndex, consumer); } abstract class BaseSpliterator> implements Spliterator.OfPrimitive { // The current spine index int splSpineIndex; // Last spine index final int lastSpineIndex; // The current element index into the current spine int splElementIndex; // Last spine's last element index + 1 final int lastSpineElementFence; // When splSpineIndex >= lastSpineIndex and // splElementIndex >= lastSpineElementFence then // this spliterator is fully traversed // tryAdvance can set splSpineIndex > spineIndex if the last spine is full // The current spine array T_ARR splChunk; BaseSpliterator(int firstSpineIndex, int lastSpineIndex, int firstSpineElementIndex, int lastSpineElementFence) { this.splSpineIndex = firstSpineIndex; this.lastSpineIndex = lastSpineIndex; this.splElementIndex = firstSpineElementIndex; this.lastSpineElementFence = lastSpineElementFence; splChunk = (spine == null) ? curChunk : spine[firstSpineIndex]; } abstract T_SPLITR newSpliterator(int firstSpineIndex, int lastSpineIndex, int firstSpineElementIndex, int lastSpineElementFence); abstract void arrayForOne(T_ARR array, int index, T_CONS consumer); abstract T_SPLITR arraySpliterator(T_ARR array, int offset, int len); @Override public long estimateSize() { return (splSpineIndex == lastSpineIndex) ? (long) lastSpineElementFence - splElementIndex : // # of elements prior to end - priorElementCount[lastSpineIndex] + lastSpineElementFence - // # of elements prior to current priorElementCount[splSpineIndex] - splElementIndex; } @Override public int characteristics() { return SPLITERATOR_CHARACTERISTICS; } @Override public boolean tryAdvance(T_CONS consumer) { Objects.requireNonNull(consumer); if (splSpineIndex < lastSpineIndex || (splSpineIndex == lastSpineIndex && splElementIndex < lastSpineElementFence)) { arrayForOne(splChunk, splElementIndex++, consumer); if (splElementIndex == arrayLength(splChunk)) { splElementIndex = 0; ++splSpineIndex; if (spine != null && splSpineIndex <= lastSpineIndex) splChunk = spine[splSpineIndex]; } return true; } return false; } @Override public void forEachRemaining(T_CONS consumer) { Objects.requireNonNull(consumer); if (splSpineIndex < lastSpineIndex || (splSpineIndex == lastSpineIndex && splElementIndex < lastSpineElementFence)) { int i = splElementIndex; // completed chunks, if any for (int sp = splSpineIndex; sp < lastSpineIndex; sp++) { T_ARR chunk = spine[sp]; arrayForEach(chunk, i, arrayLength(chunk), consumer); i = 0; } // last (or current uncompleted) chunk T_ARR chunk = (splSpineIndex == lastSpineIndex) ? splChunk : spine[lastSpineIndex]; arrayForEach(chunk, i, lastSpineElementFence, consumer); // mark consumed splSpineIndex = lastSpineIndex; splElementIndex = lastSpineElementFence; } } @Override public T_SPLITR trySplit() { if (splSpineIndex < lastSpineIndex) { // split just before last chunk (if it is full this means 50:50 split) T_SPLITR ret = newSpliterator(splSpineIndex, lastSpineIndex - 1, splElementIndex, arrayLength(spine[lastSpineIndex - 1])); // position us to start of last chunk splSpineIndex = lastSpineIndex; splElementIndex = 0; splChunk = spine[splSpineIndex]; return ret; } else if (splSpineIndex == lastSpineIndex) { int t = (lastSpineElementFence - splElementIndex) / 2; if (t == 0) return null; else { T_SPLITR ret = arraySpliterator(splChunk, splElementIndex, t); splElementIndex += t; return ret; } } else { return null; } } } } /** * An ordered collection of {@code int} values. */ static class OfInt extends SpinedBuffer.OfPrimitive implements IntConsumer { OfInt() { } OfInt(int initialCapacity) { super(initialCapacity); } @Override public void forEach(Consumer consumer) { if (consumer instanceof IntConsumer) { forEach((IntConsumer) consumer); } else { ((Spliterator) spliterator()).forEachRemaining(consumer); } } @Override protected int[][] newArrayArray(int size) { return new int[size][]; } @Override public int[] newArray(int size) { return new int[size]; } @Override protected int arrayLength(int[] array) { return array.length; } @Override protected void arrayForEach(int[] array, int from, int to, IntConsumer consumer) { for (int i = from; i < to; i++) consumer.accept(array[i]); } @Override public void accept(int i) { preAccept(); curChunk[elementIndex++] = i; } public int get(long index) { // Casts to int are safe since the spine array index is the index minus // the prior element count from the current spine int ch = chunkFor(index); if (spineIndex == 0 && ch == 0) return curChunk[(int) index]; else return spine[ch][(int) (index - priorElementCount[ch])]; } @Override public PrimitiveIterator.OfInt iterator() { return Spliterators.iterator(spliterator()); } public Spliterator.OfInt spliterator() { class Splitr extends BaseSpliterator implements Spliterator.OfInt { Splitr(int firstSpineIndex, int lastSpineIndex, int firstSpineElementIndex, int lastSpineElementFence) { super(firstSpineIndex, lastSpineIndex, firstSpineElementIndex, lastSpineElementFence); } @Override Splitr newSpliterator(int firstSpineIndex, int lastSpineIndex, int firstSpineElementIndex, int lastSpineElementFence) { return new Splitr(firstSpineIndex, lastSpineIndex, firstSpineElementIndex, lastSpineElementFence); } @Override void arrayForOne(int[] array, int index, IntConsumer consumer) { consumer.accept(array[index]); } @Override Spliterator.OfInt arraySpliterator(int[] array, int offset, int len) { return java9.util.J8Arrays.spliterator(array, offset, offset+len); } } return new Splitr(0, spineIndex, 0, elementIndex); } @Override public String toString() { int[] array = asPrimitiveArray(); if (array.length < 200) { return String.format("%s[length=%d, chunks=%d]%s", getClass().getSimpleName(), array.length, spineIndex, Arrays.toString(array)); } else { int[] array2 = Arrays.copyOf(array, 200); return String.format("%s[length=%d, chunks=%d]%s...", getClass().getSimpleName(), array.length, spineIndex, Arrays.toString(array2)); } } } /** * An ordered collection of {@code long} values. */ static class OfLong extends SpinedBuffer.OfPrimitive implements LongConsumer { OfLong() { } OfLong(int initialCapacity) { super(initialCapacity); } @Override public void forEach(Consumer consumer) { if (consumer instanceof LongConsumer) { forEach((LongConsumer) consumer); } else { ((Spliterator) spliterator()).forEachRemaining(consumer); } } @Override protected long[][] newArrayArray(int size) { return new long[size][]; } @Override public long[] newArray(int size) { return new long[size]; } @Override protected int arrayLength(long[] array) { return array.length; } @Override protected void arrayForEach(long[] array, int from, int to, LongConsumer consumer) { for (int i = from; i < to; i++) consumer.accept(array[i]); } @Override public void accept(long i) { preAccept(); curChunk[elementIndex++] = i; } public long get(long index) { // Casts to int are safe since the spine array index is the index minus // the prior element count from the current spine int ch = chunkFor(index); if (spineIndex == 0 && ch == 0) return curChunk[(int) index]; else return spine[ch][(int) (index - priorElementCount[ch])]; } @Override public PrimitiveIterator.OfLong iterator() { return Spliterators.iterator(spliterator()); } public Spliterator.OfLong spliterator() { class Splitr extends BaseSpliterator implements Spliterator.OfLong { Splitr(int firstSpineIndex, int lastSpineIndex, int firstSpineElementIndex, int lastSpineElementFence) { super(firstSpineIndex, lastSpineIndex, firstSpineElementIndex, lastSpineElementFence); } @Override Splitr newSpliterator(int firstSpineIndex, int lastSpineIndex, int firstSpineElementIndex, int lastSpineElementFence) { return new Splitr(firstSpineIndex, lastSpineIndex, firstSpineElementIndex, lastSpineElementFence); } @Override void arrayForOne(long[] array, int index, LongConsumer consumer) { consumer.accept(array[index]); } @Override Spliterator.OfLong arraySpliterator(long[] array, int offset, int len) { return java9.util.J8Arrays.spliterator(array, offset, offset+len); } } return new Splitr(0, spineIndex, 0, elementIndex); } @Override public String toString() { long[] array = asPrimitiveArray(); if (array.length < 200) { return String.format("%s[length=%d, chunks=%d]%s", getClass().getSimpleName(), array.length, spineIndex, Arrays.toString(array)); } else { long[] array2 = Arrays.copyOf(array, 200); return String.format("%s[length=%d, chunks=%d]%s...", getClass().getSimpleName(), array.length, spineIndex, Arrays.toString(array2)); } } } /** * An ordered collection of {@code double} values. */ static class OfDouble extends SpinedBuffer.OfPrimitive implements DoubleConsumer { OfDouble() { } OfDouble(int initialCapacity) { super(initialCapacity); } @Override public void forEach(Consumer consumer) { if (consumer instanceof DoubleConsumer) { forEach((DoubleConsumer) consumer); } else { ((Spliterator) spliterator()).forEachRemaining(consumer); } } @Override protected double[][] newArrayArray(int size) { return new double[size][]; } @Override public double[] newArray(int size) { return new double[size]; } @Override protected int arrayLength(double[] array) { return array.length; } @Override protected void arrayForEach(double[] array, int from, int to, DoubleConsumer consumer) { for (int i = from; i < to; i++) consumer.accept(array[i]); } @Override public void accept(double i) { preAccept(); curChunk[elementIndex++] = i; } public double get(long index) { // Casts to int are safe since the spine array index is the index minus // the prior element count from the current spine int ch = chunkFor(index); if (spineIndex == 0 && ch == 0) return curChunk[(int) index]; else return spine[ch][(int) (index - priorElementCount[ch])]; } @Override public PrimitiveIterator.OfDouble iterator() { return Spliterators.iterator(spliterator()); } public Spliterator.OfDouble spliterator() { class Splitr extends BaseSpliterator implements Spliterator.OfDouble { Splitr(int firstSpineIndex, int lastSpineIndex, int firstSpineElementIndex, int lastSpineElementFence) { super(firstSpineIndex, lastSpineIndex, firstSpineElementIndex, lastSpineElementFence); } @Override Splitr newSpliterator(int firstSpineIndex, int lastSpineIndex, int firstSpineElementIndex, int lastSpineElementFence) { return new Splitr(firstSpineIndex, lastSpineIndex, firstSpineElementIndex, lastSpineElementFence); } @Override void arrayForOne(double[] array, int index, DoubleConsumer consumer) { consumer.accept(array[index]); } @Override Spliterator.OfDouble arraySpliterator(double[] array, int offset, int len) { return java9.util.J8Arrays.spliterator(array, offset, offset+len); } } return new Splitr(0, spineIndex, 0, elementIndex); } @Override public String toString() { double[] array = asPrimitiveArray(); if (array.length < 200) { return String.format("%s[length=%d, chunks=%d]%s", getClass().getSimpleName(), array.length, spineIndex, Arrays.toString(array)); } else { double[] array2 = Arrays.copyOf(array, 200); return String.format("%s[length=%d, chunks=%d]%s...", getClass().getSimpleName(), array.length, spineIndex, Arrays.toString(array2)); } } } }





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