Mercurial > jhg
view src/org/tmatesoft/hg/internal/ArrayHelper.java @ 709:497e697636fc
Report merged lines as changed block if possible, not as a sequence of added/deleted blocks. To facilitate access to merge parent lines AddBlock got mergeLineAt() method that reports index of the line in the second parent (if any), while insertedAt() has been changed to report index in the first parent always
author | Artem Tikhomirov <tikhomirov.artem@gmail.com> |
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date | Wed, 21 Aug 2013 16:23:27 +0200 |
parents | f568330dd9c0 |
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/* * Copyright (c) 2011-2013 TMate Software Ltd * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; version 2 of the License. * * This program 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 for more details. * * For information on how to redistribute this software under * the terms of a license other than GNU General Public License * contact TMate Software at support@hg4j.com */ package org.tmatesoft.hg.internal; import java.util.Arrays; /** * Internal alternative to Arrays.sort to build reversed index along with sorting * and to perform lookup (binary search) without sorted array, using reversed index. * * @author Artem Tikhomirov * @author TMate Software Ltd. */ public final class ArrayHelper<T extends Comparable<T>> { private int[] reverse; // aka sorted2natural private final T[] data; private T[] sorted; public ArrayHelper(T[] _data) { assert _data != null; data = _data; } /** * Sort data this helper wraps, possibly using supplied array (optional) * to keep sorted elements * @param sortDest array to keep sorted values at, or <code>null</code> * @param sortDestIsEmpty <code>false</code> when sortDest already contains copy of data to be sorted * @param keepSorted <code>true</code> to save sorted array for future use (e.g. in */ public void sort(T[] sortDest, boolean sortDestIsEmpty, boolean keepSorted) { if (sortDest != null) { assert sortDest.length >= data.length; if (sortDestIsEmpty) { System.arraycopy(data, 0, sortDest, 0, data.length); } sorted = sortDest; } else { sorted = data.clone(); } reverse = new int[data.length]; for (int i = 0; i < reverse.length; i++) { // initial reverse indexes, so that elements that do // not move during sort got correct indexes reverse[i] = i; } sort1(0, data.length); if (!keepSorted) { sorted = null; } } /** * @return all reverse indexes */ public int[] getReverseIndexes() { return reverse; } public int getReverseIndex(int sortedIndex) { return reverse[sortedIndex]; } public T get(int index) { return data[index]; } public T[] getData() { return data; } /** * Look up sorted index of the value, using sort information * @return same value as {@link Arrays#binarySearch(Object[], Object)} does */ public int binarySearchSorted(T value) { if (sorted != null) { int x = Arrays.binarySearch(sorted, value); // fulfill the Arrays#binarySearch contract in case sorted array is greater than data return x >= data.length ? -(data.length - 1) : x; } return binarySearchWithReverse(0, data.length, value); } /** * Look up index of the value in the original array. * @return index in original data, or <code>defaultValue</code> if value not found */ public int binarySearch(T value, int defaultValue) { int x = binarySearchSorted(value); if (x < 0) { return defaultValue; } return reverse[x]; } /** * Slightly modified version of Arrays.sort1(int[], int, int) quicksort alg (just to deal with Object[]) */ private void sort1(int off, int len) { Comparable<Object>[] x = comparableSorted(); // Insertion sort on smallest arrays if (len < 7) { for (int i=off; i<len+off; i++) for (int j=i; j>off && x[j-1].compareTo(x[j]) > 0; j--) swap(j, j-1); return; } // Choose a partition element, v int m = off + (len >> 1); // Small arrays, middle element if (len > 7) { int l = off; int n = off + len - 1; if (len > 40) { // Big arrays, pseudomedian of 9 int s = len/8; l = med3(l, l+s, l+2*s); m = med3(m-s, m, m+s); n = med3(n-2*s, n-s, n); } m = med3(l, m, n); // Mid-size, med of 3 } Comparable<Object> v = x[m]; // Establish Invariant: v* (<v)* (>v)* v* int a = off, b = a, c = off + len - 1, d = c; while(true) { while (b <= c && x[b].compareTo(v) <= 0) { if (x[b] == v) swap(a++, b); b++; } while (c >= b && x[c].compareTo(v) >= 0) { if (x[c] == v) swap(c, d--); c--; } if (b > c) break; swap(b++, c--); } // Swap partition elements back to middle int s, n = off + len; s = Math.min(a-off, b-a ); vecswap(off, b-s, s); s = Math.min(d-c, n-d-1); vecswap(b, n-s, s); // Recursively sort non-partition-elements if ((s = b-a) > 1) sort1(off, s); if ((s = d-c) > 1) sort1(n-s, s); } /** * Swaps x[a .. (a+n-1)] with x[b .. (b+n-1)]. */ private void vecswap(int a, int b, int n) { for (int i=0; i<n; i++, a++, b++) { swap(a, b); } } /** * Returns the index of the median of the three indexed integers. */ private int med3(int a, int b, int c) { Comparable<Object>[] x = comparableSorted(); return (x[a].compareTo(x[b]) < 0 ? (x[b].compareTo(x[c]) < 0 ? b : x[a].compareTo(x[c]) < 0 ? c : a) : (x[b].compareTo(x[c]) > 0 ? b : x[a].compareTo(x[c]) > 0 ? c : a)); } private Comparable<Object>[] comparableSorted() { // Comparable<Object>[] x = (Comparable<Object>[]) sorted // eclipse compiler is ok with the line above, while javac doesn't understand it: // inconvertible types found : T[] required: java.lang.Comparable<java.lang.Object>[] // so need to add another step Comparable<?>[] oo = sorted; @SuppressWarnings("unchecked") Comparable<Object>[] x = (Comparable<Object>[]) oo; return x; } /** * Swaps x[a] with x[b]. */ private void swap(int a, int b) { Object[] x = sorted; Object t = x[a]; x[a] = x[b]; x[b] = t; int z1 = reverse[a]; int z2 = reverse[b]; reverse[b] = z1; reverse[a] = z2; } // copied from Arrays.binarySearch0, update to be instance method and to use reverse indexes private int binarySearchWithReverse(int fromIndex, int toIndex, T key) { int low = fromIndex; int high = toIndex - 1; while (low <= high) { int mid = (low + high) >>> 1; // data[reverse[x]] gives sorted value at index x T midVal = data[reverse[mid]]; int cmp = midVal.compareTo(key); if (cmp < 0) low = mid + 1; else if (cmp > 0) high = mid - 1; else return mid; // key found } return -(low + 1); // key not found. } }