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package com.lowagie.text.pdf;

/*
 * Copyright 2003 Paulo Soares
 *
 * The contents of this file are subject to the Mozilla Public License Version 1.1
 * (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.mozilla.org/MPL/
 *
 * Software distributed under the License is distributed on an "AS IS" basis,
 * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
 * for the specific language governing rights and limitations under the License.
 *
 * The Original Code is 'iText, a free JAVA-PDF library'.
 *
 * The Initial Developer of the Original Code is Bruno Lowagie. Portions created by
 * the Initial Developer are Copyright (C) 1999, 2000, 2001, 2002 by Bruno Lowagie.
 * All Rights Reserved.
 * Co-Developer of the code is Paulo Soares. Portions created by the Co-Developer
 * are Copyright (C) 2000, 2001, 2002 by Paulo Soares. All Rights Reserved.
 *
 * Contributor(s): all the names of the contributors are added in the source code
 * where applicable.
 *
 * Alternatively, the contents of this file may be used under the terms of the
 * LGPL license (the "GNU LIBRARY GENERAL PUBLIC LICENSE"), in which case the
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 * of this file under either the MPL or the GNU LIBRARY GENERAL PUBLIC LICENSE.
 *
 * This library is free software; you can redistribute it and/or modify it
 * under the terms of the MPL as stated above or under the terms of the GNU
 * Library General Public License as published by the Free Software Foundation;
 * either version 2 of the License, or any later version.
 *
 * This library is distributed in the hope that it will be useful, but WITHOUT
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 * FOR A PARTICULAR PURPOSE. See the GNU Library general Public License for more
 * details.
 *
 * If you didn't download this code from the following link, you should check if
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 * http://www.lowagie.com/iText/
 */

/*
 * (C) Copyright IBM Corp. 1999, All Rights Reserved
 *
 * version 1.1
 */

/*
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/**
 * Reference implementation of the Unicode 3.0 Bidi algorithm.
 *
 * 

* This implementation is not optimized for performance. It is intended * as a reference implementation that closely follows the specification * of the Bidirectional Algorithm in The Unicode Standard version 3.0. *

* Input:
* There are two levels of input to the algorithm, since clients may prefer * to supply some information from out-of-band sources rather than relying on * the default behavior. *

    *
  1. unicode type array *
  2. unicode type array, with externally supplied base line direction *
*

Output:
* Output is separated into several stages as well, to better enable clients * to evaluate various aspects of implementation conformance. *

    *
  1. levels array over entire paragraph *
  2. reordering array over entire paragraph *
  3. levels array over line *
  4. reordering array over line *
* Note that for conformance, algorithms are only required to generate correct * reordering and character directionality (odd or even levels) over a line. * Generating identical level arrays over a line is not required. Bidi * explicit format codes (LRE, RLE, LRO, RLO, PDF) and BN can be assigned * arbitrary levels and positions as long as the other text matches. *

* As the algorithm is defined to operate on a single paragraph at a time, * this implementation is written to handle single paragraphs. Thus * rule P1 is presumed by this implementation-- the data provided to the * implementation is assumed to be a single paragraph, and either contains no * 'B' codes, or a single 'B' code at the end of the input. 'B' is allowed * as input to illustrate how the algorithm assigns it a level. *

* Also note that rules L3 and L4 depend on the rendering engine that uses * the result of the bidi algorithm. This implementation assumes that the * rendering engine expects combining marks in visual order (e.g. to the * left of their base character in RTL runs) and that it adjust the glyphs * used to render mirrored characters that are in RTL runs so that they * render appropriately. * * @author Doug Felt */ import com.lowagie.text.error_messages.MessageLocalization; public final class BidiOrder { private byte[] initialTypes; private byte[] embeddings; // generated from processing format codes private byte paragraphEmbeddingLevel = -1; // undefined private int textLength; // for convenience private byte[] resultTypes; // for paragraph, not lines private byte[] resultLevels; // for paragraph, not lines // The bidi types /** Left-to-right*/ public static final byte L = 0; /** Left-to-Right Embedding */ public static final byte LRE = 1; /** Left-to-Right Override */ public static final byte LRO = 2; /** Right-to-Left */ public static final byte R = 3; /** Right-to-Left Arabic */ public static final byte AL = 4; /** Right-to-Left Embedding */ public static final byte RLE = 5; /** Right-to-Left Override */ public static final byte RLO = 6; /** Pop Directional Format */ public static final byte PDF = 7; /** European Number */ public static final byte EN = 8; /** European Number Separator */ public static final byte ES = 9; /** European Number Terminator */ public static final byte ET = 10; /** Arabic Number */ public static final byte AN = 11; /** Common Number Separator */ public static final byte CS = 12; /** Non-Spacing Mark */ public static final byte NSM = 13; /** Boundary Neutral */ public static final byte BN = 14; /** Paragraph Separator */ public static final byte B = 15; /** Segment Separator */ public static final byte S = 16; /** Whitespace */ public static final byte WS = 17; /** Other Neutrals */ public static final byte ON = 18; /** Minimum bidi type value. */ public static final byte TYPE_MIN = 0; /** Maximum bidi type value. */ public static final byte TYPE_MAX = 18; // // Input // /** * Initialize using an array of direction types. Types range from TYPE_MIN to TYPE_MAX inclusive * and represent the direction codes of the characters in the text. * * @param types the types array */ public BidiOrder(byte[] types) { validateTypes(types); this.initialTypes = (byte[])types.clone(); // client type array remains unchanged runAlgorithm(); } /** * Initialize using an array of direction types and an externally supplied paragraph embedding level. * The embedding level may be -1, 0, or 1. -1 means to apply the default algorithm (rules P2 and P3), * 0 is for LTR paragraphs, and 1 is for RTL paragraphs. * * @param types the types array * @param paragraphEmbeddingLevel the externally supplied paragraph embedding level. */ public BidiOrder(byte[] types, byte paragraphEmbeddingLevel) { validateTypes(types); validateParagraphEmbeddingLevel(paragraphEmbeddingLevel); this.initialTypes = (byte[])types.clone(); // client type array remains unchanged this.paragraphEmbeddingLevel = paragraphEmbeddingLevel; runAlgorithm(); } public BidiOrder(char text[], int offset, int length, byte paragraphEmbeddingLevel) { initialTypes = new byte[length]; for (int k = 0; k < length; ++k) { initialTypes[k] = rtypes[text[offset + k]]; } validateParagraphEmbeddingLevel(paragraphEmbeddingLevel); this.paragraphEmbeddingLevel = paragraphEmbeddingLevel; runAlgorithm(); } public final static byte getDirection(char c) { return rtypes[c]; } /** * The algorithm. * Does not include line-based processing (Rules L1, L2). * These are applied later in the line-based phase of the algorithm. */ private void runAlgorithm() { textLength = initialTypes.length; // Initialize output types. // Result types initialized to input types. resultTypes = (byte[])initialTypes.clone(); // 1) determining the paragraph level // Rule P1 is the requirement for entering this algorithm. // Rules P2, P3. // If no externally supplied paragraph embedding level, use default. if (paragraphEmbeddingLevel == -1) { determineParagraphEmbeddingLevel(); } // Initialize result levels to paragraph embedding level. resultLevels = new byte[textLength]; setLevels(0, textLength, paragraphEmbeddingLevel); // 2) Explicit levels and directions // Rules X1-X8. determineExplicitEmbeddingLevels(); // Rule X9. textLength = removeExplicitCodes(); // Rule X10. // Run remainder of algorithm one level run at a time byte prevLevel = paragraphEmbeddingLevel; int start = 0; while (start < textLength) { byte level = resultLevels[start]; byte prevType = typeForLevel(Math.max(prevLevel, level)); int limit = start + 1; while (limit < textLength && resultLevels[limit] == level) { ++limit; } byte succLevel = limit < textLength ? resultLevels[limit] : paragraphEmbeddingLevel; byte succType = typeForLevel(Math.max(succLevel, level)); // 3) resolving weak types // Rules W1-W7. resolveWeakTypes(start, limit, level, prevType, succType); // 4) resolving neutral types // Rules N1-N3. resolveNeutralTypes(start, limit, level, prevType, succType); // 5) resolving implicit embedding levels // Rules I1, I2. resolveImplicitLevels(start, limit, level, prevType, succType); prevLevel = level; start = limit; } // Reinsert explicit codes and assign appropriate levels to 'hide' them. // This is for convenience, so the resulting level array maps 1-1 // with the initial array. // See the implementation suggestions section of TR#9 for guidelines on // how to implement the algorithm without removing and reinserting the codes. textLength = reinsertExplicitCodes(textLength); } /** * 1) determining the paragraph level. *

* Rules P2, P3. *

* At the end of this function, the member variable paragraphEmbeddingLevel is set to either 0 or 1. */ private void determineParagraphEmbeddingLevel() { byte strongType = -1; // unknown // Rule P2. for (int i = 0; i < textLength; ++i) { byte t = resultTypes[i]; if (t == L || t == AL || t == R) { strongType = t; break; } } // Rule P3. if (strongType == -1) { // none found // default embedding level when no strong types found is 0. paragraphEmbeddingLevel = 0; } else if (strongType == L) { paragraphEmbeddingLevel = 0; } else { // AL, R paragraphEmbeddingLevel = 1; } } /** * Process embedding format codes. *

* Calls processEmbeddings to generate an embedding array from the explicit format codes. The * embedding overrides in the array are then applied to the result types, and the result levels are * initialized. * @see #processEmbeddings */ private void determineExplicitEmbeddingLevels() { embeddings = processEmbeddings(resultTypes, paragraphEmbeddingLevel); for (int i = 0; i < textLength; ++i) { byte level = embeddings[i]; if ((level & 0x80) != 0) { level &= 0x7f; resultTypes[i] = typeForLevel(level); } resultLevels[i] = level; } } /** * Rules X9. * Remove explicit codes so that they may be ignored during the remainder * of the main portion of the algorithm. The length of the resulting text * is returned. * @return the length of the data excluding explicit codes and BN. */ private int removeExplicitCodes() { int w = 0; for (int i = 0; i < textLength; ++i) { byte t = initialTypes[i]; if (!(t == LRE || t == RLE || t == LRO || t == RLO || t == PDF || t == BN)) { embeddings[w] = embeddings[i]; resultTypes[w] = resultTypes[i]; resultLevels[w] = resultLevels[i]; w++; } } return w; // new textLength while explicit levels are removed } /** * Reinsert levels information for explicit codes. * This is for ease of relating the level information * to the original input data. Note that the levels * assigned to these codes are arbitrary, they're * chosen so as to avoid breaking level runs. * @param textLength the length of the data after compression * @return the length of the data (original length of * types array supplied to constructor) */ private int reinsertExplicitCodes(int textLength) { for (int i = initialTypes.length; --i >= 0;) { byte t = initialTypes[i]; if (t == LRE || t == RLE || t == LRO || t == RLO || t == PDF || t == BN) { embeddings[i] = 0; resultTypes[i] = t; resultLevels[i] = -1; } else { --textLength; embeddings[i] = embeddings[textLength]; resultTypes[i] = resultTypes[textLength]; resultLevels[i] = resultLevels[textLength]; } } // now propagate forward the levels information (could have // propagated backward, the main thing is not to introduce a level // break where one doesn't already exist). if (resultLevels[0] == -1) { resultLevels[0] = paragraphEmbeddingLevel; } for (int i = 1; i < initialTypes.length; ++i) { if (resultLevels[i] == -1) { resultLevels[i] = resultLevels[i-1]; } } // Embedding information is for informational purposes only // so need not be adjusted. return initialTypes.length; } /** * 2) determining explicit levels * Rules X1 - X8 * * The interaction of these rules makes handling them a bit complex. * This examines resultTypes but does not modify it. It returns embedding and * override information in the result array. The low 7 bits are the level, the high * bit is set if the level is an override, and clear if it is an embedding. */ private static byte[] processEmbeddings(byte[] resultTypes, byte paragraphEmbeddingLevel) { final int EXPLICIT_LEVEL_LIMIT = 62; int textLength = resultTypes.length; byte[] embeddings = new byte[textLength]; // This stack will store the embedding levels and override status in a single byte // as described above. byte[] embeddingValueStack = new byte[EXPLICIT_LEVEL_LIMIT]; int stackCounter = 0; // An LRE or LRO at level 60 is invalid, since the new level 62 is invalid. But // an RLE at level 60 is valid, since the new level 61 is valid. The current wording // of the rules requires that the RLE remain valid even if a previous LRE is invalid. // This keeps track of ignored LRE or LRO codes at level 60, so that the matching PDFs // will not try to pop the stack. int overflowAlmostCounter = 0; // This keeps track of ignored pushes at level 61 or higher, so that matching PDFs will // not try to pop the stack. int overflowCounter = 0; // Rule X1. // Keep the level separate from the value (level | override status flag) for ease of access. byte currentEmbeddingLevel = paragraphEmbeddingLevel; byte currentEmbeddingValue = paragraphEmbeddingLevel; // Loop through types, handling all remaining rules for (int i = 0; i < textLength; ++i) { embeddings[i] = currentEmbeddingValue; byte t = resultTypes[i]; // Rules X2, X3, X4, X5 switch (t) { case RLE: case LRE: case RLO: case LRO: // Only need to compute new level if current level is valid if (overflowCounter == 0) { byte newLevel; if (t == RLE || t == RLO) { newLevel = (byte)((currentEmbeddingLevel + 1) | 1); // least greater odd } else { // t == LRE || t == LRO newLevel = (byte)((currentEmbeddingLevel + 2) & ~1); // least greater even } // If the new level is valid, push old embedding level and override status // No check for valid stack counter, since the level check suffices. if (newLevel < EXPLICIT_LEVEL_LIMIT) { embeddingValueStack[stackCounter] = currentEmbeddingValue; stackCounter++; currentEmbeddingLevel = newLevel; if (t == LRO || t == RLO) { // override currentEmbeddingValue = (byte)(newLevel | 0x80); } else { currentEmbeddingValue = newLevel; } // Adjust level of format mark (for expositional purposes only, this gets // removed later). embeddings[i] = currentEmbeddingValue; break; } // Otherwise new level is invalid, but a valid level can still be achieved if this // level is 60 and we encounter an RLE or RLO further on. So record that we // 'almost' overflowed. if (currentEmbeddingLevel == 60) { overflowAlmostCounter++; break; } } // Otherwise old or new level is invalid. overflowCounter++; break; case PDF: // The only case where this did not actually overflow but may have almost overflowed // is when there was an RLE or RLO on level 60, which would result in level 61. So we // only test the almost overflow condition in that case. // // Also note that there may be a PDF without any pushes at all. if (overflowCounter > 0) { --overflowCounter; } else if (overflowAlmostCounter > 0 && currentEmbeddingLevel != 61) { --overflowAlmostCounter; } else if (stackCounter > 0) { --stackCounter; currentEmbeddingValue = embeddingValueStack[stackCounter]; currentEmbeddingLevel = (byte)(currentEmbeddingValue & 0x7f); } break; case B: // Rule X8. // These values are reset for clarity, in this implementation B can only // occur as the last code in the array. stackCounter = 0; overflowCounter = 0; overflowAlmostCounter = 0; currentEmbeddingLevel = paragraphEmbeddingLevel; currentEmbeddingValue = paragraphEmbeddingLevel; embeddings[i] = paragraphEmbeddingLevel; break; default: break; } } return embeddings; } /** * 3) resolving weak types * Rules W1-W7. * * Note that some weak types (EN, AN) remain after this processing is complete. */ private void resolveWeakTypes(int start, int limit, byte level, byte sor, byte eor) { // Rule W1. // Changes all NSMs. byte preceedingCharacterType = sor; for (int i = start; i < limit; ++i) { byte t = resultTypes[i]; if (t == NSM) { resultTypes[i] = preceedingCharacterType; } else { preceedingCharacterType = t; } } // Rule W2. // EN does not change at the start of the run, because sor != AL. for (int i = start; i < limit; ++i) { if (resultTypes[i] == EN) { for (int j = i - 1; j >= start; --j) { byte t = resultTypes[j]; if (t == L || t == R || t == AL) { if (t == AL) { resultTypes[i] = AN; } break; } } } } // Rule W3. for (int i = start; i < limit; ++i) { if (resultTypes[i] == AL) { resultTypes[i] = R; } } // Rule W4. // Since there must be values on both sides for this rule to have an // effect, the scan skips the first and last value. // // Although the scan proceeds left to right, and changes the type values // in a way that would appear to affect the computations later in the scan, // there is actually no problem. A change in the current value can only // affect the value to its immediate right, and only affect it if it is // ES or CS. But the current value can only change if the value to its // right is not ES or CS. Thus either the current value will not change, // or its change will have no effect on the remainder of the analysis. for (int i = start + 1; i < limit - 1; ++i) { if (resultTypes[i] == ES || resultTypes[i] == CS) { byte prevSepType = resultTypes[i-1]; byte succSepType = resultTypes[i+1]; if (prevSepType == EN && succSepType == EN) { resultTypes[i] = EN; } else if (resultTypes[i] == CS && prevSepType == AN && succSepType == AN) { resultTypes[i] = AN; } } } // Rule W5. for (int i = start; i < limit; ++i) { if (resultTypes[i] == ET) { // locate end of sequence int runstart = i; int runlimit = findRunLimit(runstart, limit, new byte[] { ET }); // check values at ends of sequence byte t = runstart == start ? sor : resultTypes[runstart - 1]; if (t != EN) { t = runlimit == limit ? eor : resultTypes[runlimit]; } if (t == EN) { setTypes(runstart, runlimit, EN); } // continue at end of sequence i = runlimit; } } // Rule W6. for (int i = start; i < limit; ++i) { byte t = resultTypes[i]; if (t == ES || t == ET || t == CS) { resultTypes[i] = ON; } } // Rule W7. for (int i = start; i < limit; ++i) { if (resultTypes[i] == EN) { // set default if we reach start of run byte prevStrongType = sor; for (int j = i - 1; j >= start; --j) { byte t = resultTypes[j]; if (t == L || t == R) { // AL's have been removed prevStrongType = t; break; } } if (prevStrongType == L) { resultTypes[i] = L; } } } } /** * 6) resolving neutral types * Rules N1-N2. */ private void resolveNeutralTypes(int start, int limit, byte level, byte sor, byte eor) { for (int i = start; i < limit; ++i) { byte t = resultTypes[i]; if (t == WS || t == ON || t == B || t == S) { // find bounds of run of neutrals int runstart = i; int runlimit = findRunLimit(runstart, limit, new byte[] {B, S, WS, ON}); // determine effective types at ends of run byte leadingType; byte trailingType; if (runstart == start) { leadingType = sor; } else { leadingType = resultTypes[runstart - 1]; if (leadingType == L || leadingType == R) { // found the strong type } else if (leadingType == AN) { leadingType = R; } else if (leadingType == EN) { // Since EN's with previous strong L types have been changed // to L in W7, the leadingType must be R. leadingType = R; } } if (runlimit == limit) { trailingType = eor; } else { trailingType = resultTypes[runlimit]; if (trailingType == L || trailingType == R) { // found the strong type } else if (trailingType == AN) { trailingType = R; } else if (trailingType == EN) { trailingType = R; } } byte resolvedType; if (leadingType == trailingType) { // Rule N1. resolvedType = leadingType; } else { // Rule N2. // Notice the embedding level of the run is used, not // the paragraph embedding level. resolvedType = typeForLevel(level); } setTypes(runstart, runlimit, resolvedType); // skip over run of (former) neutrals i = runlimit; } } } /** * 7) resolving implicit embedding levels * Rules I1, I2. */ private void resolveImplicitLevels(int start, int limit, byte level, byte sor, byte eor) { if ((level & 1) == 0) { // even level for (int i = start; i < limit; ++i) { byte t = resultTypes[i]; // Rule I1. if (t == L ) { // no change } else if (t == R) { resultLevels[i] += 1; } else { // t == AN || t == EN resultLevels[i] += 2; } } } else { // odd level for (int i = start; i < limit; ++i) { byte t = resultTypes[i]; // Rule I2. if (t == R) { // no change } else { // t == L || t == AN || t == EN resultLevels[i] += 1; } } } } // // Output // public byte[] getLevels() { return getLevels(new int[]{textLength}); } /** * Return levels array breaking lines at offsets in linebreaks.
* Rule L1. *

* The returned levels array contains the resolved level for each * bidi code passed to the constructor. *

* The linebreaks array must include at least one value. * The values must be in strictly increasing order (no duplicates) * between 1 and the length of the text, inclusive. The last value * must be the length of the text. * * @param linebreaks the offsets at which to break the paragraph * @return the resolved levels of the text */ public byte[] getLevels(int[] linebreaks) { // Note that since the previous processing has removed all // P, S, and WS values from resultTypes, the values referred to // in these rules are the initial types, before any processing // has been applied (including processing of overrides). // // This example implementation has reinserted explicit format codes // and BN, in order that the levels array correspond to the // initial text. Their final placement is not normative. // These codes are treated like WS in this implementation, // so they don't interrupt sequences of WS. validateLineBreaks(linebreaks, textLength); byte[] result = (byte[])resultLevels.clone(); // will be returned to caller // don't worry about linebreaks since if there is a break within // a series of WS values preceding S, the linebreak itself // causes the reset. for (int i = 0; i < result.length; ++i) { byte t = initialTypes[i]; if (t == B || t == S) { // Rule L1, clauses one and two. result[i] = paragraphEmbeddingLevel; // Rule L1, clause three. for (int j = i - 1; j >= 0; --j) { if (isWhitespace(initialTypes[j])) { // including format codes result[j] = paragraphEmbeddingLevel; } else { break; } } } } // Rule L1, clause four. int start = 0; for (int i = 0; i < linebreaks.length; ++i) { int limit = linebreaks[i]; for (int j = limit - 1; j >= start; --j) { if (isWhitespace(initialTypes[j])) { // including format codes result[j] = paragraphEmbeddingLevel; } else { break; } } start = limit; } return result; } /** * Return reordering array breaking lines at offsets in linebreaks. *

* The reordering array maps from a visual index to a logical index. * Lines are concatenated from left to right. So for example, the * fifth character from the left on the third line is *

 getReordering(linebreaks)[linebreaks[1] + 4]
* (linebreaks[1] is the position after the last character of the * second line, which is also the index of the first character on the * third line, and adding four gets the fifth character from the left). *

* The linebreaks array must include at least one value. * The values must be in strictly increasing order (no duplicates) * between 1 and the length of the text, inclusive. The last value * must be the length of the text. * * @param linebreaks the offsets at which to break the paragraph. */ public int[] getReordering(int[] linebreaks) { validateLineBreaks(linebreaks, textLength); byte[] levels = getLevels(linebreaks); return computeMultilineReordering(levels, linebreaks); } /** * Return multiline reordering array for a given level array. * Reordering does not occur across a line break. */ private static int[] computeMultilineReordering(byte[] levels, int[] linebreaks) { int[] result = new int[levels.length]; int start = 0; for (int i = 0; i < linebreaks.length; ++i) { int limit = linebreaks[i]; byte[] templevels = new byte[limit - start]; System.arraycopy(levels, start, templevels, 0, templevels.length); int[] temporder = computeReordering(templevels); for (int j = 0; j < temporder.length; ++j) { result[start + j] = temporder[j] + start; } start = limit; } return result; } /** * Return reordering array for a given level array. This reorders a single line. * The reordering is a visual to logical map. For example, * the leftmost char is string.charAt(order[0]). * Rule L2. */ private static int[] computeReordering(byte[] levels) { int lineLength = levels.length; int[] result = new int[lineLength]; // initialize order for (int i = 0; i < lineLength; ++i) { result[i] = i; } // locate highest level found on line. // Note the rules say text, but no reordering across line bounds is performed, // so this is sufficient. byte highestLevel = 0; byte lowestOddLevel = 63; for (int i = 0; i < lineLength; ++i) { byte level = levels[i]; if (level > highestLevel) { highestLevel = level; } if (((level & 1) != 0) && level < lowestOddLevel) { lowestOddLevel = level; } } for (int level = highestLevel; level >= lowestOddLevel; --level) { for (int i = 0; i < lineLength; ++i) { if (levels[i] >= level) { // find range of text at or above this level int start = i; int limit = i + 1; while (limit < lineLength && levels[limit] >= level) { ++limit; } // reverse run for (int j = start, k = limit - 1; j < k; ++j, --k) { int temp = result[j]; result[j] = result[k]; result[k] = temp; } // skip to end of level run i = limit; } } } return result; } /** * Return the base level of the paragraph. */ public byte getBaseLevel() { return paragraphEmbeddingLevel; } // --- internal utilities ------------------------------------------------- /** * Return true if the type is considered a whitespace type for the line break rules. */ private static boolean isWhitespace(byte biditype) { switch (biditype) { case LRE: case RLE: case LRO: case RLO: case PDF: case BN: case WS: return true; default: return false; } } /** * Return the strong type (L or R) corresponding to the level. */ private static byte typeForLevel(int level) { return ((level & 0x1) == 0) ? L : R; } /** * Return the limit of the run starting at index that includes only resultTypes in validSet. * This checks the value at index, and will return index if that value is not in validSet. */ private int findRunLimit(int index, int limit, byte[] validSet) { --index; loop: while (++index < limit) { byte t = resultTypes[index]; for (int i = 0; i < validSet.length; ++i) { if (t == validSet[i]) { continue loop; } } // didn't find a match in validSet return index; } return limit; } /** * Return the start of the run including index that includes only resultTypes in validSet. * This assumes the value at index is valid, and does not check it. */ private int findRunStart(int index, byte[] validSet) { loop: while (--index >= 0) { byte t = resultTypes[index]; for (int i = 0; i < validSet.length; ++i) { if (t == validSet[i]) { continue loop; } } return index + 1; } return 0; } /** * Set resultTypes from start up to (but not including) limit to newType. */ private void setTypes(int start, int limit, byte newType) { for (int i = start; i < limit; ++i) { resultTypes[i] = newType; } } /** * Set resultLevels from start up to (but not including) limit to newLevel. */ private void setLevels(int start, int limit, byte newLevel) { for (int i = start; i < limit; ++i) { resultLevels[i] = newLevel; } } // --- input validation --------------------------------------------------- /** * Throw exception if type array is invalid. */ private static void validateTypes(byte[] types) { if (types == null) { throw new IllegalArgumentException(MessageLocalization.getComposedMessage("types.is.null")); } for (int i = 0; i < types.length; ++i) { if (types[i] < TYPE_MIN || types[i] > TYPE_MAX) { throw new IllegalArgumentException(MessageLocalization.getComposedMessage("illegal.type.value.at.1.2", String.valueOf(i), String.valueOf(types[i]))); } } for (int i = 0; i < types.length - 1; ++i) { if (types[i] == B) { throw new IllegalArgumentException(MessageLocalization.getComposedMessage("b.type.before.end.of.paragraph.at.index.1", i)); } } } /** * Throw exception if paragraph embedding level is invalid. Special allowance for -1 so that * default processing can still be performed when using this API. */ private static void validateParagraphEmbeddingLevel(byte paragraphEmbeddingLevel) { if (paragraphEmbeddingLevel != -1 && paragraphEmbeddingLevel != 0 && paragraphEmbeddingLevel != 1) { throw new IllegalArgumentException(MessageLocalization.getComposedMessage("illegal.paragraph.embedding.level.1", paragraphEmbeddingLevel)); } } /** * Throw exception if line breaks array is invalid. */ private static void validateLineBreaks(int[] linebreaks, int textLength) { int prev = 0; for (int i = 0; i < linebreaks.length; ++i) { int next = linebreaks[i]; if (next <= prev) { throw new IllegalArgumentException(MessageLocalization.getComposedMessage("bad.linebreak.1.at.index.2", String.valueOf(next), String.valueOf(i))); } prev = next; } if (prev != textLength) { throw new IllegalArgumentException(MessageLocalization.getComposedMessage("last.linebreak.must.be.at.1", textLength)); } } private static final byte rtypes[] = new byte[0x10000]; private static char baseTypes[] = { 0, 8, (char)BN, 9, 9, (char)S, 10, 10, (char)B, 11, 11, (char)S, 12, 12, (char)WS, 13, 13, (char)B, 14, 27, (char)BN, 28, 30, (char)B, 31, 31, (char)S, 32, 32, (char)WS, 33, 34, (char)ON, 35, 37, (char)ET, 38, 42, (char)ON, 43, 43, (char)ET, 44, 44, (char)CS, 45, 45, (char)ET, 46, 46, (char)CS, 47, 47, (char)ES, 48, 57, (char)EN, 58, 58, (char)CS, 59, 64, (char)ON, 65, 90, (char)L, 91, 96, (char)ON, 97, 122, (char)L, 123, 126, (char)ON, 127, 132, (char)BN, 133, 133, (char)B, 134, 159, (char)BN, 160, 160, (char)CS, 161, 161, (char)ON, 162, 165, (char)ET, 166, 169, (char)ON, 170, 170, (char)L, 171, 175, (char)ON, 176, 177, (char)ET, 178, 179, (char)EN, 180, 180, (char)ON, 181, 181, (char)L, 182, 184, (char)ON, 185, 185, (char)EN, 186, 186, (char)L, 187, 191, (char)ON, 192, 214, (char)L, 215, 215, (char)ON, 216, 246, (char)L, 247, 247, (char)ON, 248, 696, (char)L, 697, 698, (char)ON, 699, 705, (char)L, 706, 719, (char)ON, 720, 721, (char)L, 722, 735, (char)ON, 736, 740, (char)L, 741, 749, (char)ON, 750, 750, (char)L, 751, 767, (char)ON, 768, 855, (char)NSM, 856, 860, (char)L, 861, 879, (char)NSM, 880, 883, (char)L, 884, 885, (char)ON, 886, 893, (char)L, 894, 894, (char)ON, 895, 899, (char)L, 900, 901, (char)ON, 902, 902, (char)L, 903, 903, (char)ON, 904, 1013, (char)L, 1014, 1014, (char)ON, 1015, 1154, (char)L, 1155, 1158, (char)NSM, 1159, 1159, (char)L, 1160, 1161, (char)NSM, 1162, 1417, (char)L, 1418, 1418, (char)ON, 1419, 1424, (char)L, 1425, 1441, (char)NSM, 1442, 1442, (char)L, 1443, 1465, (char)NSM, 1466, 1466, (char)L, 1467, 1469, (char)NSM, 1470, 1470, (char)R, 1471, 1471, (char)NSM, 1472, 1472, (char)R, 1473, 1474, (char)NSM, 1475, 1475, (char)R, 1476, 1476, (char)NSM, 1477, 1487, (char)L, 1488, 1514, (char)R, 1515, 1519, (char)L, 1520, 1524, (char)R, 1525, 1535, (char)L, 1536, 1539, (char)AL, 1540, 1547, (char)L, 1548, 1548, (char)CS, 1549, 1549, (char)AL, 1550, 1551, (char)ON, 1552, 1557, (char)NSM, 1558, 1562, (char)L, 1563, 1563, (char)AL, 1564, 1566, (char)L, 1567, 1567, (char)AL, 1568, 1568, (char)L, 1569, 1594, (char)AL, 1595, 1599, (char)L, 1600, 1610, (char)AL, 1611, 1624, (char)NSM, 1625, 1631, (char)L, 1632, 1641, (char)AN, 1642, 1642, (char)ET, 1643, 1644, (char)AN, 1645, 1647, (char)AL, 1648, 1648, (char)NSM, 1649, 1749, (char)AL, 1750, 1756, (char)NSM, 1757, 1757, (char)AL, 1758, 1764, (char)NSM, 1765, 1766, (char)AL, 1767, 1768, (char)NSM, 1769, 1769, (char)ON, 1770, 1773, (char)NSM, 1774, 1775, (char)AL, 1776, 1785, (char)EN, 1786, 1805, (char)AL, 1806, 1806, (char)L, 1807, 1807, (char)BN, 1808, 1808, (char)AL, 1809, 1809, (char)NSM, 1810, 1839, (char)AL, 1840, 1866, (char)NSM, 1867, 1868, (char)L, 1869, 1871, (char)AL, 1872, 1919, (char)L, 1920, 1957, (char)AL, 1958, 1968, (char)NSM, 1969, 1969, (char)AL, 1970, 2304, (char)L, 2305, 2306, (char)NSM, 2307, 2363, (char)L, 2364, 2364, (char)NSM, 2365, 2368, (char)L, 2369, 2376, (char)NSM, 2377, 2380, (char)L, 2381, 2381, (char)NSM, 2382, 2384, (char)L, 2385, 2388, (char)NSM, 2389, 2401, (char)L, 2402, 2403, (char)NSM, 2404, 2432, (char)L, 2433, 2433, (char)NSM, 2434, 2491, (char)L, 2492, 2492, (char)NSM, 2493, 2496, (char)L, 2497, 2500, (char)NSM, 2501, 2508, (char)L, 2509, 2509, (char)NSM, 2510, 2529, (char)L, 2530, 2531, (char)NSM, 2532, 2545, (char)L, 2546, 2547, (char)ET, 2548, 2560, (char)L, 2561, 2562, (char)NSM, 2563, 2619, (char)L, 2620, 2620, (char)NSM, 2621, 2624, (char)L, 2625, 2626, (char)NSM, 2627, 2630, (char)L, 2631, 2632, (char)NSM, 2633, 2634, (char)L, 2635, 2637, (char)NSM, 2638, 2671, (char)L, 2672, 2673, (char)NSM, 2674, 2688, (char)L, 2689, 2690, (char)NSM, 2691, 2747, (char)L, 2748, 2748, (char)NSM, 2749, 2752, (char)L, 2753, 2757, (char)NSM, 2758, 2758, (char)L, 2759, 2760, (char)NSM, 2761, 2764, (char)L, 2765, 2765, (char)NSM, 2766, 2785, (char)L, 2786, 2787, (char)NSM, 2788, 2800, (char)L, 2801, 2801, (char)ET, 2802, 2816, (char)L, 2817, 2817, (char)NSM, 2818, 2875, (char)L, 2876, 2876, (char)NSM, 2877, 2878, (char)L, 2879, 2879, (char)NSM, 2880, 2880, (char)L, 2881, 2883, (char)NSM, 2884, 2892, (char)L, 2893, 2893, (char)NSM, 2894, 2901, (char)L, 2902, 2902, (char)NSM, 2903, 2945, (char)L, 2946, 2946, (char)NSM, 2947, 3007, (char)L, 3008, 3008, (char)NSM, 3009, 3020, (char)L, 3021, 3021, (char)NSM, 3022, 3058, (char)L, 3059, 3064, (char)ON, 3065, 3065, (char)ET, 3066, 3066, (char)ON, 3067, 3133, (char)L, 3134, 3136, (char)NSM, 3137, 3141, (char)L, 3142, 3144, (char)NSM, 3145, 3145, (char)L, 3146, 3149, (char)NSM, 3150, 3156, (char)L, 3157, 3158, (char)NSM, 3159, 3259, (char)L, 3260, 3260, (char)NSM, 3261, 3275, (char)L, 3276, 3277, (char)NSM, 3278, 3392, (char)L, 3393, 3395, (char)NSM, 3396, 3404, (char)L, 3405, 3405, (char)NSM, 3406, 3529, (char)L, 3530, 3530, (char)NSM, 3531, 3537, (char)L, 3538, 3540, (char)NSM, 3541, 3541, (char)L, 3542, 3542, (char)NSM, 3543, 3632, (char)L, 3633, 3633, (char)NSM, 3634, 3635, (char)L, 3636, 3642, (char)NSM, 3643, 3646, (char)L, 3647, 3647, (char)ET, 3648, 3654, (char)L, 3655, 3662, (char)NSM, 3663, 3760, (char)L, 3761, 3761, (char)NSM, 3762, 3763, (char)L, 3764, 3769, (char)NSM, 3770, 3770, (char)L, 3771, 3772, (char)NSM, 3773, 3783, (char)L, 3784, 3789, (char)NSM, 3790, 3863, (char)L, 3864, 3865, (char)NSM, 3866, 3892, (char)L, 3893, 3893, (char)NSM, 3894, 3894, (char)L, 3895, 3895, (char)NSM, 3896, 3896, (char)L, 3897, 3897, (char)NSM, 3898, 3901, (char)ON, 3902, 3952, (char)L, 3953, 3966, (char)NSM, 3967, 3967, (char)L, 3968, 3972, (char)NSM, 3973, 3973, (char)L, 3974, 3975, (char)NSM, 3976, 3983, (char)L, 3984, 3991, (char)NSM, 3992, 3992, (char)L, 3993, 4028, (char)NSM, 4029, 4037, (char)L, 4038, 4038, (char)NSM, 4039, 4140, (char)L, 4141, 4144, (char)NSM, 4145, 4145, (char)L, 4146, 4146, (char)NSM, 4147, 4149, (char)L, 4150, 4151, (char)NSM, 4152, 4152, (char)L, 4153, 4153, (char)NSM, 4154, 4183, (char)L, 4184, 4185, (char)NSM, 4186, 5759, (char)L, 5760, 5760, (char)WS, 5761, 5786, (char)L, 5787, 5788, (char)ON, 5789, 5905, (char)L, 5906, 5908, (char)NSM, 5909, 5937, (char)L, 5938, 5940, (char)NSM, 5941, 5969, (char)L, 5970, 5971, (char)NSM, 5972, 6001, (char)L, 6002, 6003, (char)NSM, 6004, 6070, (char)L, 6071, 6077, (char)NSM, 6078, 6085, (char)L, 6086, 6086, (char)NSM, 6087, 6088, (char)L, 6089, 6099, (char)NSM, 6100, 6106, (char)L, 6107, 6107, (char)ET, 6108, 6108, (char)L, 6109, 6109, (char)NSM, 6110, 6127, (char)L, 6128, 6137, (char)ON, 6138, 6143, (char)L, 6144, 6154, (char)ON, 6155, 6157, (char)NSM, 6158, 6158, (char)WS, 6159, 6312, (char)L, 6313, 6313, (char)NSM, 6314, 6431, (char)L, 6432, 6434, (char)NSM, 6435, 6438, (char)L, 6439, 6443, (char)NSM, 6444, 6449, (char)L, 6450, 6450, (char)NSM, 6451, 6456, (char)L, 6457, 6459, (char)NSM, 6460, 6463, (char)L, 6464, 6464, (char)ON, 6465, 6467, (char)L, 6468, 6469, (char)ON, 6470, 6623, (char)L, 6624, 6655, (char)ON, 6656, 8124, (char)L, 8125, 8125, (char)ON, 8126, 8126, (char)L, 8127, 8129, (char)ON, 8130, 8140, (char)L, 8141, 8143, (char)ON, 8144, 8156, (char)L, 8157, 8159, (char)ON, 8160, 8172, (char)L, 8173, 8175, (char)ON, 8176, 8188, (char)L, 8189, 8190, (char)ON, 8191, 8191, (char)L, 8192, 8202, (char)WS, 8203, 8205, (char)BN, 8206, 8206, (char)L, 8207, 8207, (char)R, 8208, 8231, (char)ON, 8232, 8232, (char)WS, 8233, 8233, (char)B, 8234, 8234, (char)LRE, 8235, 8235, (char)RLE, 8236, 8236, (char)PDF, 8237, 8237, (char)LRO, 8238, 8238, (char)RLO, 8239, 8239, (char)WS, 8240, 8244, (char)ET, 8245, 8276, (char)ON, 8277, 8278, (char)L, 8279, 8279, (char)ON, 8280, 8286, (char)L, 8287, 8287, (char)WS, 8288, 8291, (char)BN, 8292, 8297, (char)L, 8298, 8303, (char)BN, 8304, 8304, (char)EN, 8305, 8307, (char)L, 8308, 8313, (char)EN, 8314, 8315, (char)ET, 8316, 8318, (char)ON, 8319, 8319, (char)L, 8320, 8329, (char)EN, 8330, 8331, (char)ET, 8332, 8334, (char)ON, 8335, 8351, (char)L, 8352, 8369, (char)ET, 8370, 8399, (char)L, 8400, 8426, (char)NSM, 8427, 8447, (char)L, 8448, 8449, (char)ON, 8450, 8450, (char)L, 8451, 8454, (char)ON, 8455, 8455, (char)L, 8456, 8457, (char)ON, 8458, 8467, (char)L, 8468, 8468, (char)ON, 8469, 8469, (char)L, 8470, 8472, (char)ON, 8473, 8477, (char)L, 8478, 8483, (char)ON, 8484, 8484, (char)L, 8485, 8485, (char)ON, 8486, 8486, (char)L, 8487, 8487, (char)ON, 8488, 8488, (char)L, 8489, 8489, (char)ON, 8490, 8493, (char)L, 8494, 8494, (char)ET, 8495, 8497, (char)L, 8498, 8498, (char)ON, 8499, 8505, (char)L, 8506, 8507, (char)ON, 8508, 8511, (char)L, 8512, 8516, (char)ON, 8517, 8521, (char)L, 8522, 8523, (char)ON, 8524, 8530, (char)L, 8531, 8543, (char)ON, 8544, 8591, (char)L, 8592, 8721, (char)ON, 8722, 8723, (char)ET, 8724, 9013, (char)ON, 9014, 9082, (char)L, 9083, 9108, (char)ON, 9109, 9109, (char)L, 9110, 9168, (char)ON, 9169, 9215, (char)L, 9216, 9254, (char)ON, 9255, 9279, (char)L, 9280, 9290, (char)ON, 9291, 9311, (char)L, 9312, 9371, (char)EN, 9372, 9449, (char)L, 9450, 9450, (char)EN, 9451, 9751, (char)ON, 9752, 9752, (char)L, 9753, 9853, (char)ON, 9854, 9855, (char)L, 9856, 9873, (char)ON, 9874, 9887, (char)L, 9888, 9889, (char)ON, 9890, 9984, (char)L, 9985, 9988, (char)ON, 9989, 9989, (char)L, 9990, 9993, (char)ON, 9994, 9995, (char)L, 9996, 10023, (char)ON, 10024, 10024, (char)L, 10025, 10059, (char)ON, 10060, 10060, (char)L, 10061, 10061, (char)ON, 10062, 10062, (char)L, 10063, 10066, (char)ON, 10067, 10069, (char)L, 10070, 10070, (char)ON, 10071, 10071, (char)L, 10072, 10078, (char)ON, 10079, 10080, (char)L, 10081, 10132, (char)ON, 10133, 10135, (char)L, 10136, 10159, (char)ON, 10160, 10160, (char)L, 10161, 10174, (char)ON, 10175, 10191, (char)L, 10192, 10219, (char)ON, 10220, 10223, (char)L, 10224, 11021, (char)ON, 11022, 11903, (char)L, 11904, 11929, (char)ON, 11930, 11930, (char)L, 11931, 12019, (char)ON, 12020, 12031, (char)L, 12032, 12245, (char)ON, 12246, 12271, (char)L, 12272, 12283, (char)ON, 12284, 12287, (char)L, 12288, 12288, (char)WS, 12289, 12292, (char)ON, 12293, 12295, (char)L, 12296, 12320, (char)ON, 12321, 12329, (char)L, 12330, 12335, (char)NSM, 12336, 12336, (char)ON, 12337, 12341, (char)L, 12342, 12343, (char)ON, 12344, 12348, (char)L, 12349, 12351, (char)ON, 12352, 12440, (char)L, 12441, 12442, (char)NSM, 12443, 12444, (char)ON, 12445, 12447, (char)L, 12448, 12448, (char)ON, 12449, 12538, (char)L, 12539, 12539, (char)ON, 12540, 12828, (char)L, 12829, 12830, (char)ON, 12831, 12879, (char)L, 12880, 12895, (char)ON, 12896, 12923, (char)L, 12924, 12925, (char)ON, 12926, 12976, (char)L, 12977, 12991, (char)ON, 12992, 13003, (char)L, 13004, 13007, (char)ON, 13008, 13174, (char)L, 13175, 13178, (char)ON, 13179, 13277, (char)L, 13278, 13279, (char)ON, 13280, 13310, (char)L, 13311, 13311, (char)ON, 13312, 19903, (char)L, 19904, 19967, (char)ON, 19968, 42127, (char)L, 42128, 42182, (char)ON, 42183, 64284, (char)L, 64285, 64285, (char)R, 64286, 64286, (char)NSM, 64287, 64296, (char)R, 64297, 64297, (char)ET, 64298, 64310, (char)R, 64311, 64311, (char)L, 64312, 64316, (char)R, 64317, 64317, (char)L, 64318, 64318, (char)R, 64319, 64319, (char)L, 64320, 64321, (char)R, 64322, 64322, (char)L, 64323, 64324, (char)R, 64325, 64325, (char)L, 64326, 64335, (char)R, 64336, 64433, (char)AL, 64434, 64466, (char)L, 64467, 64829, (char)AL, 64830, 64831, (char)ON, 64832, 64847, (char)L, 64848, 64911, (char)AL, 64912, 64913, (char)L, 64914, 64967, (char)AL, 64968, 65007, (char)L, 65008, 65020, (char)AL, 65021, 65021, (char)ON, 65022, 65023, (char)L, 65024, 65039, (char)NSM, 65040, 65055, (char)L, 65056, 65059, (char)NSM, 65060, 65071, (char)L, 65072, 65103, (char)ON, 65104, 65104, (char)CS, 65105, 65105, (char)ON, 65106, 65106, (char)CS, 65107, 65107, (char)L, 65108, 65108, (char)ON, 65109, 65109, (char)CS, 65110, 65118, (char)ON, 65119, 65119, (char)ET, 65120, 65121, (char)ON, 65122, 65123, (char)ET, 65124, 65126, (char)ON, 65127, 65127, (char)L, 65128, 65128, (char)ON, 65129, 65130, (char)ET, 65131, 65131, (char)ON, 65132, 65135, (char)L, 65136, 65140, (char)AL, 65141, 65141, (char)L, 65142, 65276, (char)AL, 65277, 65278, (char)L, 65279, 65279, (char)BN, 65280, 65280, (char)L, 65281, 65282, (char)ON, 65283, 65285, (char)ET, 65286, 65290, (char)ON, 65291, 65291, (char)ET, 65292, 65292, (char)CS, 65293, 65293, (char)ET, 65294, 65294, (char)CS, 65295, 65295, (char)ES, 65296, 65305, (char)EN, 65306, 65306, (char)CS, 65307, 65312, (char)ON, 65313, 65338, (char)L, 65339, 65344, (char)ON, 65345, 65370, (char)L, 65371, 65381, (char)ON, 65382, 65503, (char)L, 65504, 65505, (char)ET, 65506, 65508, (char)ON, 65509, 65510, (char)ET, 65511, 65511, (char)L, 65512, 65518, (char)ON, 65519, 65528, (char)L, 65529, 65531, (char)BN, 65532, 65533, (char)ON, 65534, 65535, (char)L}; static { for (int k = 0; k < baseTypes.length; ++k) { int start = baseTypes[k]; int end = baseTypes[++k]; byte b = (byte)baseTypes[++k]; while (start <= end) rtypes[start++] = b; } } }





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