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/*
 * COPIED FROM APACHE LUCENE 4.7.2
 *
 * Git URL: [email protected]:apache/lucene.git, tag: releases/lucene-solr/4.7.2, path: lucene/core/src/java
 *
 * (see https://issues.apache.org/jira/browse/OAK-10786 for details)
 */

package org.apache.lucene.util;

/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You 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.
 */

import java.util.Arrays;

/**
 * {@link Sorter} implementation based on the
 * TimSort
 * algorithm.
 * 

This implementation is especially good at sorting partially-sorted * arrays and sorts small arrays with binary sort. *

NOTE:There are a few differences with the original implementation:

* @lucene.internal */ public abstract class TimSorter extends Sorter { static final int MINRUN = 32; static final int THRESHOLD = 64; static final int STACKSIZE = 40; // depends on MINRUN static final int MIN_GALLOP = 7; final int maxTempSlots; int minRun; int to; int stackSize; int[] runEnds; /** * Create a new {@link TimSorter}. * @param maxTempSlots the maximum amount of extra memory to run merges */ protected TimSorter(int maxTempSlots) { super(); runEnds = new int[1 + STACKSIZE]; this.maxTempSlots = maxTempSlots; } /** Minimum run length for an array of length length. */ static int minRun(int length) { assert length >= MINRUN; int n = length; int r = 0; while (n >= 64) { r |= n & 1; n >>>= 1; } final int minRun = n + r; assert minRun >= MINRUN && minRun <= THRESHOLD; return minRun; } int runLen(int i) { final int off = stackSize - i; return runEnds[off] - runEnds[off - 1]; } int runBase(int i) { return runEnds[stackSize - i - 1]; } int runEnd(int i) { return runEnds[stackSize - i]; } void setRunEnd(int i, int runEnd) { runEnds[stackSize - i] = runEnd; } void pushRunLen(int len) { runEnds[stackSize + 1] = runEnds[stackSize] + len; ++stackSize; } /** Compute the length of the next run, make the run sorted and return its * length. */ int nextRun() { final int runBase = runEnd(0); assert runBase < to; if (runBase == to - 1) { return 1; } int o = runBase + 2; if (compare(runBase, runBase+1) > 0) { // run must be strictly descending while (o < to && compare(o - 1, o) > 0) { ++o; } reverse(runBase, o); } else { // run must be non-descending while (o < to && compare(o - 1, o) <= 0) { ++o; } } final int runHi = Math.max(o, Math.min(to, runBase + minRun)); binarySort(runBase, runHi, o); return runHi - runBase; } void ensureInvariants() { while (stackSize > 1) { final int runLen0 = runLen(0); final int runLen1 = runLen(1); if (stackSize > 2) { final int runLen2 = runLen(2); if (runLen2 <= runLen1 + runLen0) { // merge the smaller of 0 and 2 with 1 if (runLen2 < runLen0) { mergeAt(1); } else { mergeAt(0); } continue; } } if (runLen1 <= runLen0) { mergeAt(0); continue; } break; } } void exhaustStack() { while (stackSize > 1) { mergeAt(0); } } void reset(int from, int to) { stackSize = 0; Arrays.fill(runEnds, 0); runEnds[0] = from; this.to = to; final int length = to - from; this.minRun = length <= THRESHOLD ? length : minRun(length); } void mergeAt(int n) { assert stackSize >= 2; merge(runBase(n + 1), runBase(n), runEnd(n)); for (int j = n + 1; j > 0; --j) { setRunEnd(j, runEnd(j-1)); } --stackSize; } void merge(int lo, int mid, int hi) { if (compare(mid - 1, mid) <= 0) { return; } lo = upper2(lo, mid, mid); hi = lower2(mid, hi, mid - 1); if (hi - mid <= mid - lo && hi - mid <= maxTempSlots) { mergeHi(lo, mid, hi); } else if (mid - lo <= maxTempSlots) { mergeLo(lo, mid, hi); } else { mergeInPlace(lo, mid, hi); } } @Override public void sort(int from, int to) { checkRange(from, to); if (to - from <= 1) { return; } reset(from, to); do { ensureInvariants(); pushRunLen(nextRun()); } while (runEnd(0) < to); exhaustStack(); assert runEnd(0) == to; } @Override void doRotate(int lo, int mid, int hi) { final int len1 = mid - lo; final int len2 = hi - mid; if (len1 == len2) { while (mid < hi) { swap(lo++, mid++); } } else if (len2 < len1 && len2 <= maxTempSlots) { save(mid, len2); for (int i = lo + len1 - 1, j = hi - 1; i >= lo; --i, --j) { copy(i, j); } for (int i = 0, j = lo; i < len2; ++i, ++j) { restore(i, j); } } else if (len1 <= maxTempSlots) { save(lo, len1); for (int i = mid, j = lo; i < hi; ++i, ++j) { copy(i, j); } for (int i = 0, j = lo + len2; j < hi; ++i, ++j) { restore(i, j); } } else { reverse(lo, mid); reverse(mid, hi); reverse(lo, hi); } } void mergeLo(int lo, int mid, int hi) { assert compare(lo, mid) > 0; int len1 = mid - lo; save(lo, len1); copy(mid, lo); int i = 0, j = mid + 1, dest = lo + 1; outer: for (;;) { for (int count = 0; count < MIN_GALLOP; ) { if (i >= len1 || j >= hi) { break outer; } else if (compareSaved(i, j) <= 0) { restore(i++, dest++); count = 0; } else { copy(j++, dest++); ++count; } } // galloping... int next = lowerSaved3(j, hi, i); for (; j < next; ++dest) { copy(j++, dest); } restore(i++, dest++); } for (; i < len1; ++dest) { restore(i++, dest); } assert j == dest; } void mergeHi(int lo, int mid, int hi) { assert compare(mid - 1, hi - 1) > 0; int len2 = hi - mid; save(mid, len2); copy(mid - 1, hi - 1); int i = mid - 2, j = len2 - 1, dest = hi - 2; outer: for (;;) { for (int count = 0; count < MIN_GALLOP; ) { if (i < lo || j < 0) { break outer; } else if (compareSaved(j, i) >= 0) { restore(j--, dest--); count = 0; } else { copy(i--, dest--); ++count; } } // galloping int next = upperSaved3(lo, i + 1, j); while (i >= next) { copy(i--, dest--); } restore(j--, dest--); } for (; j >= 0; --dest) { restore(j--, dest); } assert i == dest; } int lowerSaved(int from, int to, int val) { int len = to - from; while (len > 0) { final int half = len >>> 1; final int mid = from + half; if (compareSaved(val, mid) > 0) { from = mid + 1; len = len - half -1; } else { len = half; } } return from; } int upperSaved(int from, int to, int val) { int len = to - from; while (len > 0) { final int half = len >>> 1; final int mid = from + half; if (compareSaved(val, mid) < 0) { len = half; } else { from = mid + 1; len = len - half -1; } } return from; } // faster than lowerSaved when val is at the beginning of [from:to[ int lowerSaved3(int from, int to, int val) { int f = from, t = f + 1; while (t < to) { if (compareSaved(val, t) <= 0) { return lowerSaved(f, t, val); } int delta = t - f; f = t; t += delta << 1; } return lowerSaved(f, to, val); } //faster than upperSaved when val is at the end of [from:to[ int upperSaved3(int from, int to, int val) { int f = to - 1, t = to; while (f > from) { if (compareSaved(val, f) >= 0) { return upperSaved(f, t, val); } final int delta = t - f; t = f; f -= delta << 1; } return upperSaved(from, t, val); } /** Copy data from slot src to slot dest. */ protected abstract void copy(int src, int dest); /** Save all elements between slots i and i+len * into the temporary storage. */ protected abstract void save(int i, int len); /** Restore element j from the temporary storage into slot i. */ protected abstract void restore(int i, int j); /** Compare element i from the temporary storage with element * j from the slice to sort, similarly to * {@link #compare(int, int)}. */ protected abstract int compareSaved(int i, int j); }




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