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fastutil extends the Java Collections Framework by providing type-specific maps, sets, lists, and queues with a small memory footprint and fast operations; it provides also big (64-bit) arrays, sets, and lists, sorting algorithms, fast, practical I/O classes for binary and text files, and facilities for memory mapping large files. This jar (fastutil-core.jar) contains data structures based on integers, longs, doubles, and objects, only; fastutil.jar contains all classes. If you have both jars in your dependencies, this jar should be excluded.

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/*
 * Copyright (C) 2010-2022 Sebastiano Vigna
 *
 * 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 PACKAGE;

import static it.unimi.dsi.fastutil.BigArrays.ensureOffsetLength;
import static it.unimi.dsi.fastutil.BigArrays.length;

import it.unimi.dsi.fastutil.BigArrays;

#if KEYS_REFERENCE
import it.unimi.dsi.fastutil.Stack;
import java.util.function.Consumer;
#endif

import java.util.Iterator;
import java.util.Collection;
import java.util.NoSuchElementException;

import it.unimi.dsi.fastutil.BigList;
import it.unimi.dsi.fastutil.BigListIterator;

/**  An abstract class providing basic methods for big lists implementing a type-specific big list interface.
 *
 * 

Most of the methods in this class are optimized with the assumption that the List will have * {@link java.util.RandomAccess have constant-time random access}. If this is not the case, you * should probably at least override {@link #listIterator(long)} and the {@code xAll()} methods * (such as {@link #addAll}) with a more appropriate iteration scheme. Note the {@link #subList(long, long)} * method is cognizant of random-access or not, so that need not be reimplemented. */ public abstract class ABSTRACT_BIG_LIST KEY_GENERIC extends ABSTRACT_COLLECTION KEY_GENERIC implements BIG_LIST KEY_GENERIC, STACK KEY_GENERIC { protected ABSTRACT_BIG_LIST() {} /** Ensures that the given index is nonnegative and not greater than this big-list size. * * @param index an index. * @throws IndexOutOfBoundsException if the given index is negative or greater than this big-list size. */ protected void ensureIndex(final long index) { if (index < 0) throw new IndexOutOfBoundsException("Index (" + index + ") is negative"); if (index > size64()) throw new IndexOutOfBoundsException("Index (" + index + ") is greater than list size (" + (size64()) + ")"); } /** Ensures that the given index is nonnegative and smaller than this big-list size. * * @param index an index. * @throws IndexOutOfBoundsException if the given index is negative or not smaller than this big-list size. */ protected void ensureRestrictedIndex(final long index) { if (index < 0) throw new IndexOutOfBoundsException("Index (" + index + ") is negative"); if (index >= size64()) throw new IndexOutOfBoundsException("Index (" + index + ") is greater than or equal to list size (" + (size64()) + ")"); } /** {@inheritDoc} * * @implSpec This implementation always throws an {@link UnsupportedOperationException}. */ @Override public void add(final long index, final KEY_GENERIC_TYPE k) { throw new UnsupportedOperationException(); } /** {@inheritDoc} * * @implSpec This implementation delegates to the type-specific version of {@link BigList#add(long, Object)}. */ @Override public boolean add(final KEY_GENERIC_TYPE k) { add(size64(), k); return true; } /** {@inheritDoc} * * @implSpec This implementation always throws an {@link UnsupportedOperationException}. */ @Override public KEY_GENERIC_TYPE REMOVE_KEY(long i) { throw new UnsupportedOperationException(); } /** {@inheritDoc} * * @implSpec This implementation always throws an {@link UnsupportedOperationException}. */ @Override public KEY_GENERIC_TYPE set(final long index, final KEY_GENERIC_TYPE k) { throw new UnsupportedOperationException(); } /** Adds all of the elements in the specified collection to this list (optional operation). */ @Override public boolean addAll(long index, final Collection c) { ensureIndex(index); final Iterator i = c.iterator(); final boolean retVal = i.hasNext(); while(i.hasNext()) add(index++, i.next()); return retVal; } /** {@inheritDoc} * * @implSpec This implementation delegates to the type-specific version of {@link BigList#addAll(long, Collection)}. */ @Override public boolean addAll(final Collection c) { return addAll(size64(), c); } /** {@inheritDoc} * * @implSpec This implementation delegates to {@link #listIterator()}. */ @Override public KEY_BIG_LIST_ITERATOR KEY_GENERIC iterator() { return listIterator(); } /** {@inheritDoc} * * @implSpec This implementation delegates to {@link BigList#listIterator(long) listIterator(0)}. */ @Override public KEY_BIG_LIST_ITERATOR KEY_GENERIC listIterator() { return listIterator(0L); } /** {@inheritDoc} * @implSpec This implementation is based on the random-access methods. */ @Override public KEY_BIG_LIST_ITERATOR KEY_GENERIC listIterator(final long index) { ensureIndex(index); return new BIG_LIST_ITERATORS.AbstractIndexBasedBigListIterator KEY_GENERIC(0, index) { @Override protected final KEY_GENERIC_TYPE get(long i) { return ABSTRACT_BIG_LIST.this.GET_KEY(i); } @Override protected final void add(long i, KEY_GENERIC_TYPE k) { ABSTRACT_BIG_LIST.this.add(i, k); } @Override protected final void set(long i, KEY_GENERIC_TYPE k) { ABSTRACT_BIG_LIST.this.set(i, k); } @Override protected final void remove(long i) { ABSTRACT_BIG_LIST.this.REMOVE_KEY(i); } @Override protected final long getMaxPos() { return ABSTRACT_BIG_LIST.this.size64(); } }; } static final class IndexBasedSpliterator KEY_GENERIC extends BIG_SPLITERATORS.LateBindingSizeIndexBasedSpliterator KEY_GENERIC { final BIG_LIST KEY_GENERIC l; IndexBasedSpliterator(BIG_LIST KEY_GENERIC l, long pos) { super(pos); this.l = l; } IndexBasedSpliterator(BIG_LIST KEY_GENERIC l, long pos, long maxPos) { super(pos, maxPos); this.l = l; } @Override protected final long getMaxPosFromBackingStore() { return l.size64(); } @Override protected final KEY_GENERIC_TYPE get(long i) { return l.GET_KEY(i); } @Override protected final IndexBasedSpliterator KEY_GENERIC makeForSplit(long pos, long maxPos) { return new IndexBasedSpliterator KEY_GENERIC_DIAMOND(l, pos, maxPos); } } #if KEYS_BYTE_CHAR_SHORT_FLOAT @Override public WIDENED_PACKAGE.KEY_WIDENED_SPLITERATOR KEY_GENERIC KEY_WIDENED_SPLITERATOR_METHOD() { if (this instanceof java.util.RandomAccess) { return SPLITERATORS.widen(spliterator()); } else { return super.KEY_WIDENED_SPLITERATOR_METHOD(); } } #endif /** Returns true if this list contains the specified element. * @implSpec This implementation delegates to {@code indexOf()}. * @see BigList#contains(Object) */ @Override public boolean contains(final KEY_TYPE k) { return indexOf(k) >= 0; } @Override public long indexOf(final KEY_TYPE k) { final KEY_BIG_LIST_ITERATOR KEY_GENERIC i = listIterator(); KEY_GENERIC_TYPE e; while(i.hasNext()) { e = i.NEXT_KEY(); if (KEY_EQUALS(k, e)) return i.previousIndex(); } return -1; } @Override public long lastIndexOf(final KEY_TYPE k) { KEY_BIG_LIST_ITERATOR KEY_GENERIC i = listIterator(size64()); KEY_GENERIC_TYPE e; while(i.hasPrevious()) { e = i.PREV_KEY(); if (KEY_EQUALS(k, e)) return i.nextIndex(); } return -1; } @Override public void size(final long size) { long i = size64(); if (size > i) while(i++ < size) add(KEY_NULL); else while(i-- != size) remove(i); } @Override public BIG_LIST KEY_GENERIC subList(final long from, final long to) { ensureIndex(from); ensureIndex(to); if (from > to) throw new IndexOutOfBoundsException("Start index (" + from + ") is greater than end index (" + to + ")"); return this instanceof java.util.RandomAccess ? new SUBLIST_RANDOM_ACCESS KEY_GENERIC_DIAMOND(this, from, to) : new SUBLIST KEY_GENERIC_DIAMOND(this, from, to); } /** {@inheritDoc} * * @implSpec If this list is {@link java.util.RandomAccess}, will iterate using a for * loop and the type-specific {@link java.util.List#get(int)} method. Otherwise it will fallback * to using the iterator based loop implementation from the superinterface. */ @Override public void forEach(final METHOD_ARG_KEY_CONSUMER action) { if (this instanceof java.util.RandomAccess) { for (long i = 0, max = size64(); i < max; ++i) { action.accept(GET_KEY(i)); } } else { super.forEach(action); } } /** {@inheritDoc} * *

This is a trivial iterator-based implementation. It is expected that * implementations will override this method with a more optimized version. */ @Override public void removeElements(final long from, final long to) { ensureIndex(to); KEY_BIG_LIST_ITERATOR KEY_GENERIC i = listIterator(from); long n = to - from; if (n < 0) throw new IllegalArgumentException("Start index (" + from + ") is greater than end index (" + to + ")"); while(n-- != 0) { i.NEXT_KEY(); i.remove(); } } /** {@inheritDoc} * *

This is a trivial iterator-based implementation. It is expected that * implementations will override this method with a more optimized version. */ @Override public void addElements(long index, final KEY_GENERIC_TYPE a[][], long offset, long length) { ensureIndex(index); ensureOffsetLength(a, offset, length); if (this instanceof java.util.RandomAccess) { while(length-- != 0) add(index++, BigArrays.get(a, offset++)); } else { KEY_BIG_LIST_ITERATOR KEY_GENERIC iter = listIterator(index); while(length-- != 0) iter.add(BigArrays.get(a, offset++)); } } /** {@inheritDoc} * * @implSpec This implementation delegates to the analogous method for big-array fragments. */ @Override public void addElements(final long index, final KEY_GENERIC_TYPE a[][]) { addElements(index, a, 0, length(a)); } /** {@inheritDoc} * *

This is a trivial iterator-based implementation. It is expected that * implementations will override this method with a more optimized version. */ @Override public void getElements(final long from, final KEY_TYPE a[][], long offset, long length) { ensureIndex(from); ensureOffsetLength(a, offset, length); if (from + length > size64()) throw new IndexOutOfBoundsException("End index (" + (from + length) + ") is greater than list size (" + size64() + ")"); if (this instanceof java.util.RandomAccess) { long current = from; while(length-- != 0) BigArrays.set(a, offset++, GET_KEY(current++)); } else { KEY_BIG_LIST_ITERATOR KEY_GENERIC i = listIterator(from); while(length-- != 0) BigArrays.set(a, offset++, i.NEXT_KEY()); } } @Override public void setElements(long index, KEY_GENERIC_TYPE a[][], long offset, long length) { ensureIndex(index); ensureOffsetLength(a, offset, length); if (index + length > size64()) throw new IndexOutOfBoundsException("End index (" + (index + length) + ") is greater than list size (" + size64() + ")"); if (this instanceof java.util.RandomAccess) { for (long i = 0; i < length; ++i) { set(i + index, BigArrays.get(a, i + offset)); } } else { KEY_BIG_LIST_ITERATOR KEY_GENERIC iter = listIterator(index); long i = 0; while (i < length) { iter.NEXT_KEY(); iter.set(BigArrays.get(a, offset + i++)); } } } /** {@inheritDoc} * @implSpec This implementation delegates to {@link #removeElements(long, long)}.*/ @Override public void clear() { removeElements(0, size64()); } /** {@inheritDoc} * * @implSpec This implementation delegates to {@link #size64()}. * @deprecated Please use {@link #size64()} instead. */ @Override @Deprecated public int size() { return (int)Math.min(Integer.MAX_VALUE, size64()); } /** Returns the hash code for this big list, which is identical to {@link java.util.List#hashCode()}. * * @return the hash code for this big list. */ @Override public int hashCode() { KEY_ITERATOR KEY_GENERIC i = iterator(); int h = 1; long s = size64(); while (s-- != 0) { KEY_GENERIC_TYPE k = i.NEXT_KEY(); h = 31 * h + KEY2JAVAHASH(k); } return h; } @Override public boolean equals(final Object o) { if (o == this) return true; if (! (o instanceof BigList)) return false; final BigList l = (BigList)o; long s = size64(); if (s != l.size64()) return false; #if KEYS_PRIMITIVE if (l instanceof BIG_LIST) { final KEY_BIG_LIST_ITERATOR KEY_GENERIC i1 = listIterator(), i2 = ((BIG_LIST KEY_GENERIC)l).listIterator(); while(s-- != 0) if (i1.NEXT_KEY() != i2.NEXT_KEY()) return false; return true; } #endif final BigListIterator i1 = listIterator(), i2 = l.listIterator(); #if KEYS_USE_REFERENCE_EQUALITY while(s-- != 0) if (i1.next() != i2.next()) return false; #else while(s-- != 0) if (! java.util.Objects.equals(i1.next(), i2.next())) return false; #endif return true; } #if ! KEYS_USE_REFERENCE_EQUALITY /** Compares this big list to another object. If the * argument is a {@link BigList}, this method performs a lexicographical comparison; otherwise, * it throws a {@code ClassCastException}. * * @param l a big list. * @return if the argument is a {@link BigList}, a negative integer, * zero, or a positive integer as this list is lexicographically less than, equal * to, or greater than the argument. * @throws ClassCastException if the argument is not a big list. */ SUPPRESS_WARNINGS_KEY_UNCHECKED @Override public int compareTo(final BigList l) { if (l == this) return 0; if (l instanceof BIG_LIST) { final KEY_BIG_LIST_ITERATOR KEY_GENERIC i1 = listIterator(), i2 = ((BIG_LIST KEY_GENERIC)l).listIterator(); int r; KEY_GENERIC_TYPE e1, e2; while(i1.hasNext() && i2.hasNext()) { e1 = i1.NEXT_KEY(); e2 = i2.NEXT_KEY(); if ((r = KEY_CMP(e1, e2)) != 0) return r; } return i2.hasNext() ? -1 : (i1.hasNext() ? 1 : 0); } BigListIterator i1 = listIterator(), i2 = l.listIterator(); int r; while(i1.hasNext() && i2.hasNext()) { if ((r = ((Comparable)i1.next()).compareTo(i2.next())) != 0) return r; } return i2.hasNext() ? -1 : (i1.hasNext() ? 1 : 0); } #endif @Override public void push(KEY_GENERIC_TYPE o) { add(o); } @Override public KEY_GENERIC_TYPE POP() { if (isEmpty()) throw new NoSuchElementException(); return REMOVE_KEY(size64() - 1); } @Override public KEY_GENERIC_TYPE TOP() { if (isEmpty()) throw new NoSuchElementException(); return GET_KEY(size64() - 1); } @Override public KEY_GENERIC_TYPE PEEK(int i) { return GET_KEY(size64() - 1 - i); } #if KEYS_PRIMITIVE /** Removes a single instance of the specified element from this collection, if it is present (optional operation). * @implSpec This implementation delegates to {@code indexOf()}. * @see BigList#remove(Object) */ @Override public boolean rem(KEY_TYPE k) { long index = indexOf(k); if (index == -1) return false; REMOVE_KEY(index); return true; } /** {@inheritDoc} * * @implSpec This implementation delegates to the type-specific version of {@link #addAll(long, Collection)}. */ @Override public boolean addAll(final long index, final COLLECTION c) { return addAll(index, (Collection)c); } /** {@inheritDoc} * * @implSpec This implementation delegates to the type-specific version of {@link #addAll(long, Collection)}. */ @Override public boolean addAll(final COLLECTION c) { return addAll(size64(), c); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public void add(final long index, final KEY_CLASS ok) { add(index, ok.KEY_VALUE()); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public KEY_CLASS set(final long index, final KEY_CLASS ok) { return KEY2OBJ(set(index, ok.KEY_VALUE())); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public KEY_CLASS get(final long index) { return KEY2OBJ(GET_KEY(index)); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public long indexOf(final Object ok) { return indexOf(KEY_OBJ2TYPE(ok)); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public long lastIndexOf(final Object ok) { return lastIndexOf(KEY_OBJ2TYPE(ok)); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public KEY_CLASS remove(final long index) { return KEY2OBJ(REMOVE_KEY(index)); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public void push(KEY_CLASS o) { push(o.KEY_VALUE()); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public KEY_CLASS pop() { return KEY_CLASS.valueOf(POP()); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public KEY_CLASS top() { return KEY_CLASS.valueOf(TOP()); } /** {@inheritDoc} * * @implSpec This implementation delegates to the corresponding type-specific method. * @deprecated Please use the corresponding type-specific method instead. */ @Deprecated @Override public KEY_CLASS peek(int i) { return KEY_CLASS.valueOf(PEEK(i)); } #endif @Override public String toString() { final StringBuilder s = new StringBuilder(); final KEY_ITERATOR KEY_GENERIC i = iterator(); long n = size64(); KEY_GENERIC_TYPE k; boolean first = true; s.append("["); while(n-- != 0) { if (first) first = false; else s.append(", "); k = i.NEXT_KEY(); #if KEYS_REFERENCE if (this == k) s.append("(this big list)"); else #endif s.append(String.valueOf(k)); } s.append("]"); return s.toString(); } /** A class implementing a sublist view. */ public static class SUBLIST KEY_GENERIC extends ABSTRACT_BIG_LIST KEY_GENERIC implements java.io.Serializable { private static final long serialVersionUID = -7046029254386353129L; /** The list this sublist restricts. */ protected final BIG_LIST KEY_GENERIC l; /** Initial (inclusive) index of this sublist. */ protected final long from; /** Final (exclusive) index of this sublist. */ protected long to; public SUBLIST(final BIG_LIST KEY_GENERIC l, final long from, final long to) { this.l = l; this.from = from; this.to = to; } private boolean assertRange() { assert from <= l.size64(); assert to <= l.size64(); assert to >= from; return true; } @Override public boolean add(final KEY_GENERIC_TYPE k) { l.add(to, k); to++; assert assertRange(); return true; } @Override public void add(final long index, final KEY_GENERIC_TYPE k) { ensureIndex(index); l.add(from + index, k); to++; assert assertRange(); } @Override public boolean addAll(final long index, final Collection c) { ensureIndex(index); to += c.size(); return l.addAll(from + index, c); } @Override public KEY_GENERIC_TYPE GET_KEY(long index) { ensureRestrictedIndex(index); return l.GET_KEY(from + index); } @Override public KEY_GENERIC_TYPE REMOVE_KEY(long index) { ensureRestrictedIndex(index); to--; return l.REMOVE_KEY(from + index); } @Override public KEY_GENERIC_TYPE set(long index, KEY_GENERIC_TYPE k) { ensureRestrictedIndex(index); return l.set(from + index, k); } @Override public long size64() { return to - from; } @Override public void getElements(final long from, final KEY_TYPE[][] a, final long offset, final long length) { ensureIndex(from); if (from + length > size64()) throw new IndexOutOfBoundsException("End index (" + from + length + ") is greater than list size (" + size64() + ")"); l.getElements(this.from + from, a, offset, length); } @Override public void removeElements(final long from, final long to) { ensureIndex(from); ensureIndex(to); l.removeElements(this.from + from, this.from + to); this.to -= (to - from); assert assertRange(); } @Override public void addElements(final long index, final KEY_GENERIC_TYPE a[][], long offset, long length) { ensureIndex(index); l.addElements(this.from + index, a, offset, length); this.to += length; assert assertRange(); } private final class RandomAccessIter extends BIG_LIST_ITERATORS.AbstractIndexBasedBigListIterator KEY_GENERIC { // We don't set the minPos to be "from" because we need to call our containing class' // add, set, and remove methods with 0 relative to the start of the sublist, not the // start of the original list. // Thus pos is relative to the start of the SubList, not the start of the original list. RandomAccessIter(long pos) { super(0, pos); } @Override protected final KEY_GENERIC_TYPE get(long i) { return l.GET_KEY(from + i); } // Remember, these are calling SUBLIST's methods, meaning 0 is the start of the sublist for these. @Override protected final void add(long i, KEY_GENERIC_TYPE k) { SUBLIST.this.add(i, k); } @Override protected final void set(long i, KEY_GENERIC_TYPE k) { SUBLIST.this.set(i, k); } @Override protected final void remove(long i) { SUBLIST.this.REMOVE_KEY(i); } @Override protected final long getMaxPos() { return to - from; } @Override public void add(KEY_GENERIC_TYPE k) { super.add(k); assert assertRange(); } @Override public void remove() { super.remove(); assert assertRange(); } } private class ParentWrappingIter implements KEY_BIG_LIST_ITERATOR KEY_GENERIC { private KEY_BIG_LIST_ITERATOR KEY_GENERIC parent; ParentWrappingIter(KEY_BIG_LIST_ITERATOR KEY_GENERIC parent) { this.parent = parent; } @Override public long nextIndex() { return parent.nextIndex() - from; } @Override public long previousIndex() { return parent.previousIndex() - from; } @Override public boolean hasNext() { return parent.nextIndex() < to; } @Override public boolean hasPrevious() { return parent.previousIndex() >= from; } @Override public KEY_GENERIC_TYPE NEXT_KEY() { if (! hasNext()) throw new NoSuchElementException(); return parent.NEXT_KEY(); } @Override public KEY_GENERIC_TYPE PREV_KEY() { if (! hasPrevious()) throw new NoSuchElementException(); return parent.PREV_KEY(); } @Override public void add(KEY_GENERIC_TYPE k) { parent.add(k); } @Override public void set(KEY_GENERIC_TYPE k) { parent.set(k); } @Override public void remove() { parent.remove(); } @Override public long back(long n) { if (n < 0) throw new IllegalArgumentException("Argument must be nonnegative: " + n); long currentPos = parent.previousIndex(); long parentNewPos = currentPos - n; // Remember, the minimum acceptable previousIndex is not from but (from - 1), since (from - 1) // means this subList is at the beginning of our sub range. // Same reason why previousIndex()'s minimum for the full list is not 0 but -1. if (parentNewPos < (from - 1)) parentNewPos = (from - 1); long toSkip = parentNewPos - currentPos; return parent.back(toSkip); } @Override public long skip(long n) { if (n < 0) throw new IllegalArgumentException("Argument must be nonnegative: " + n); long currentPos = parent.nextIndex(); long parentNewPos = currentPos + n; if (parentNewPos > to) parentNewPos = to; long toSkip = parentNewPos - currentPos; return parent.skip(toSkip); } } @Override public KEY_BIG_LIST_ITERATOR KEY_GENERIC listIterator(final long index) { ensureIndex(index); // If this class wasn't public, then RandomAccessIter would live in SUBLISTRandomAccess, // and the switching would be done in sublist(long, long). However, this is a public class // that may have existing implementors, so to get the benefit of RandomAccessIter class for // for existing uses, it has to be done in this class. return l instanceof java.util.RandomAccess ? new RandomAccessIter(index) : new ParentWrappingIter(l.listIterator(index + from)); } @Override public KEY_SPLITERATOR KEY_GENERIC spliterator() { return l instanceof java.util.RandomAccess ? new IndexBasedSpliterator KEY_GENERIC_DIAMOND(l, from, to) : super.spliterator(); } #if KEYS_BYTE_CHAR_SHORT_FLOAT @Override public WIDENED_PACKAGE.KEY_WIDENED_SPLITERATOR KEY_GENERIC KEY_WIDENED_SPLITERATOR_METHOD() { if (l instanceof java.util.RandomAccess) { return SPLITERATORS.widen(spliterator()); } else { return super.KEY_WIDENED_SPLITERATOR_METHOD(); } } #endif @Override public BIG_LIST KEY_GENERIC subList(final long from, final long to) { ensureIndex(from); ensureIndex(to); if (from > to) throw new IllegalArgumentException("Start index (" + from + ") is greater than end index (" + to + ")"); // Sadly we have to rewrap this, because if there is a sublist of a sublist, and the // subsublist adds, both sublists need to update their "to" value. return new SUBLIST KEY_GENERIC_DIAMOND(this, from, to); } #if KEYS_PRIMITIVE @Override public boolean rem(KEY_TYPE k) { long index = indexOf(k); if (index == -1) return false; to--; l.REMOVE_KEY(from + index); assert assertRange(); return true; } @Override public boolean addAll(final long index, final COLLECTION c) { return super.addAll(index, c); } @Override public boolean addAll(final long index, final BIG_LIST l) { return super.addAll(index, l); } #endif } public static class SUBLIST_RANDOM_ACCESS KEY_GENERIC extends SUBLIST KEY_GENERIC implements java.util.RandomAccess { private static final long serialVersionUID = -107070782945191929L; public SUBLIST_RANDOM_ACCESS(final BIG_LIST KEY_GENERIC l, final long from, final long to) { super(l, from, to); } @Override public BIG_LIST KEY_GENERIC subList(final long from, final long to) { ensureIndex(from); ensureIndex(to); if (from > to) throw new IllegalArgumentException("Start index (" + from + ") is greater than end index (" + to + ")"); // Sadly we have to rewrap this, because if there is a sublist of a sublist, and the // subsublist adds, both sublists need to update their "to" value. return new SUBLIST_RANDOM_ACCESS KEY_GENERIC_DIAMOND(this, from, to); } } }





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