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// © 2016 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
/*
*******************************************************************************
* Copyright (C) 2010-2015, International Business Machines
* Corporation and others.  All Rights Reserved.
*******************************************************************************
* CollationData.java, ported from collationdata.h/.cpp
*
* C++ version created on: 2010oct27
* created by: Markus W. Scherer
*/

package com.ibm.icu.impl.coll;

import com.ibm.icu.impl.Normalizer2Impl;
import com.ibm.icu.impl.Trie2_32;
import com.ibm.icu.lang.UScript;
import com.ibm.icu.text.Collator;
import com.ibm.icu.text.UnicodeSet;
import com.ibm.icu.util.ICUException;

/**
 * Collation data container.
 * Immutable data created by a CollationDataBuilder, or loaded from a file,
 * or deserialized from API-provided binary data.
 *
 * Includes data for the collation base (root/default), aliased if this is not the base.
 */
public final class CollationData {
    // Note: The ucadata.icu loader could discover the reserved ranges by setting an array
    // parallel with the ranges, and resetting ranges that are indexed.
    // The reordering builder code could clone the resulting template array.
    static final int REORDER_RESERVED_BEFORE_LATIN = Collator.ReorderCodes.FIRST + 14;
    static final int REORDER_RESERVED_AFTER_LATIN = Collator.ReorderCodes.FIRST + 15;

    static final int MAX_NUM_SPECIAL_REORDER_CODES = 8;

    CollationData(Normalizer2Impl nfc) {
        nfcImpl = nfc;
    }

    public int getCE32(int c) {
        return trie.get(c);
    }

    int getCE32FromSupplementary(int c) {
        return trie.get(c);  // TODO: port UTRIE2_GET32_FROM_SUPP(trie, c) to Java?
    }

    boolean isDigit(int c) {
        return c < 0x660 ? c <= 0x39 && 0x30 <= c :
                Collation.hasCE32Tag(getCE32(c), Collation.DIGIT_TAG);
    }

    public boolean isUnsafeBackward(int c, boolean numeric) {
        return unsafeBackwardSet.contains(c) || (numeric && isDigit(c));
    }

    public boolean isCompressibleLeadByte(int b) {
        return compressibleBytes[b];
    }

    public boolean isCompressiblePrimary(long p) {
        return isCompressibleLeadByte((int)p >>> 24);
    }

    /**
     * Returns the CE32 from two contexts words.
     * Access to the defaultCE32 for contraction and prefix matching.
     */
    int getCE32FromContexts(int index) {
        return ((int)contexts.charAt(index) << 16) | contexts.charAt(index + 1);
    }

    /**
     * Returns the CE32 for an indirect special CE32 (e.g., with DIGIT_TAG).
     * Requires that ce32 is special.
     */
    int getIndirectCE32(int ce32) {
        assert(Collation.isSpecialCE32(ce32));
        int tag = Collation.tagFromCE32(ce32);
        if(tag == Collation.DIGIT_TAG) {
            // Fetch the non-numeric-collation CE32.
            ce32 = ce32s[Collation.indexFromCE32(ce32)];
        } else if(tag == Collation.LEAD_SURROGATE_TAG) {
            ce32 = Collation.UNASSIGNED_CE32;
        } else if(tag == Collation.U0000_TAG) {
            // Fetch the normal ce32 for U+0000.
            ce32 = ce32s[0];
        }
        return ce32;
    }

    /**
     * Returns the CE32 for an indirect special CE32 (e.g., with DIGIT_TAG),
     * if ce32 is special.
     */
    int getFinalCE32(int ce32) {
        if(Collation.isSpecialCE32(ce32)) {
            ce32 = getIndirectCE32(ce32);
        }
        return ce32;
    }

    /**
     * Computes a CE from c's ce32 which has the OFFSET_TAG.
     */
    long getCEFromOffsetCE32(int c, int ce32) {
        long dataCE = ces[Collation.indexFromCE32(ce32)];
        return Collation.makeCE(Collation.getThreeBytePrimaryForOffsetData(c, dataCE));
    }

    /**
     * Returns the single CE that c maps to.
     * Throws UnsupportedOperationException if c does not map to a single CE.
     */
    long getSingleCE(int c) {
        CollationData d;
        int ce32 = getCE32(c);
        if(ce32 == Collation.FALLBACK_CE32) {
            d = base;
            ce32 = base.getCE32(c);
        } else {
            d = this;
        }
        while(Collation.isSpecialCE32(ce32)) {
            switch(Collation.tagFromCE32(ce32)) {
            case Collation.LATIN_EXPANSION_TAG:
            case Collation.BUILDER_DATA_TAG:
            case Collation.PREFIX_TAG:
            case Collation.CONTRACTION_TAG:
            case Collation.HANGUL_TAG:
            case Collation.LEAD_SURROGATE_TAG:
                throw new UnsupportedOperationException(String.format(
                        "there is not exactly one collation element for U+%04X (CE32 0x%08x)",
                        c, ce32));
            case Collation.FALLBACK_TAG:
            case Collation.RESERVED_TAG_3:
                throw new AssertionError(String.format(
                        "unexpected CE32 tag for U+%04X (CE32 0x%08x)", c, ce32));
            case Collation.LONG_PRIMARY_TAG:
                return Collation.ceFromLongPrimaryCE32(ce32);
            case Collation.LONG_SECONDARY_TAG:
                return Collation.ceFromLongSecondaryCE32(ce32);
            case Collation.EXPANSION32_TAG:
                if(Collation.lengthFromCE32(ce32) == 1) {
                    ce32 = d.ce32s[Collation.indexFromCE32(ce32)];
                    break;
                } else {
                    throw new UnsupportedOperationException(String.format(
                            "there is not exactly one collation element for U+%04X (CE32 0x%08x)",
                            c, ce32));
                }
            case Collation.EXPANSION_TAG: {
                if(Collation.lengthFromCE32(ce32) == 1) {
                    return d.ces[Collation.indexFromCE32(ce32)];
                } else {
                    throw new UnsupportedOperationException(String.format(
                            "there is not exactly one collation element for U+%04X (CE32 0x%08x)",
                            c, ce32));
                }
            }
            case Collation.DIGIT_TAG:
                // Fetch the non-numeric-collation CE32 and continue.
                ce32 = d.ce32s[Collation.indexFromCE32(ce32)];
                break;
            case Collation.U0000_TAG:
                assert(c == 0);
                // Fetch the normal ce32 for U+0000 and continue.
                ce32 = d.ce32s[0];
                break;
            case Collation.OFFSET_TAG:
                return d.getCEFromOffsetCE32(c, ce32);
            case Collation.IMPLICIT_TAG:
                return Collation.unassignedCEFromCodePoint(c);
            }
        }
        return Collation.ceFromSimpleCE32(ce32);
    }

    /**
     * Returns the FCD16 value for code point c. c must be >= 0.
     */
    int getFCD16(int c) {
        return nfcImpl.getFCD16(c);
    }

    /**
     * Returns the first primary for the script's reordering group.
     * @return the primary with only the first primary lead byte of the group
     *         (not necessarily an actual root collator primary weight),
     *         or 0 if the script is unknown
     */
    long getFirstPrimaryForGroup(int script) {
        int index = getScriptIndex(script);
        return index == 0 ? 0 : (long)scriptStarts[index] << 16;
    }

    /**
     * Returns the last primary for the script's reordering group.
     * @return the last primary of the group
     *         (not an actual root collator primary weight),
     *         or 0 if the script is unknown
     */
    public long getLastPrimaryForGroup(int script) {
        int index = getScriptIndex(script);
        if(index == 0) {
            return 0;
        }
        long limit = scriptStarts[index + 1];
        return (limit << 16) - 1;
    }

    /**
     * Finds the reordering group which contains the primary weight.
     * @return the first script of the group, or -1 if the weight is beyond the last group
     */
    public int getGroupForPrimary(long p) {
        p >>= 16;
        if(p < scriptStarts[1] || scriptStarts[scriptStarts.length - 1] <= p) {
            return -1;
        }
        int index = 1;
        while(p >= scriptStarts[index + 1]) { ++index; }
        for(int i = 0; i < numScripts; ++i) {
            if(scriptsIndex[i] == index) {
                return i;
            }
        }
        for(int i = 0; i < MAX_NUM_SPECIAL_REORDER_CODES; ++i) {
            if(scriptsIndex[numScripts + i] == index) {
                return Collator.ReorderCodes.FIRST + i;
            }
        }
        return -1;
    }

    private int getScriptIndex(int script) {
        if(script < 0) {
            return 0;
        } else if(script < numScripts) {
            return scriptsIndex[script];
        } else if(script < Collator.ReorderCodes.FIRST) {
            return 0;
        } else {
            script -= Collator.ReorderCodes.FIRST;
            if(script < MAX_NUM_SPECIAL_REORDER_CODES) {
                return scriptsIndex[numScripts + script];
            } else {
                return 0;
            }
        }
    }

    public int[] getEquivalentScripts(int script) {
        int index = getScriptIndex(script);
        if(index == 0) { return EMPTY_INT_ARRAY; }
        if(script >= Collator.ReorderCodes.FIRST) {
            // Special groups have no aliases.
            return new int[] { script };
        }

        int length = 0;
        for(int i = 0; i < numScripts; ++i) {
            if(scriptsIndex[i] == index) {
                ++length;
            }
        }
        int[] dest = new int[length];
        if(length == 1) {
            dest[0] = script;
            return dest;
        }
        length = 0;
        for(int i = 0; i < numScripts; ++i) {
            if(scriptsIndex[i] == index) {
                dest[length++] = i;
            }
        }
        return dest;
    }

    /**
     * Writes the permutation of primary-weight ranges
     * for the given reordering of scripts and groups.
     * The caller checks for illegal arguments and
     * takes care of [DEFAULT] and memory allocation.
     *
     * 

Each list element will be a (limit, offset) pair as described * for the CollationSettings.reorderRanges. * The list will be empty if no ranges are reordered. */ void makeReorderRanges(int[] reorder, UVector32 ranges) { makeReorderRanges(reorder, false, ranges); } private void makeReorderRanges(int[] reorder, boolean latinMustMove, UVector32 ranges) { ranges.removeAllElements(); int length = reorder.length; if(length == 0 || (length == 1 && reorder[0] == UScript.UNKNOWN)) { return; } // Maps each script-or-group range to a new lead byte. short[] table = new short[scriptStarts.length - 1]; // C++: uint8_t[] { // Set "don't care" values for reserved ranges. int index = scriptsIndex[ numScripts + REORDER_RESERVED_BEFORE_LATIN - Collator.ReorderCodes.FIRST]; if(index != 0) { table[index] = 0xff; } index = scriptsIndex[ numScripts + REORDER_RESERVED_AFTER_LATIN - Collator.ReorderCodes.FIRST]; if(index != 0) { table[index] = 0xff; } } // Never reorder special low and high primary lead bytes. assert(scriptStarts.length >= 2); assert(scriptStarts[0] == 0); int lowStart = scriptStarts[1]; assert(lowStart == ((Collation.MERGE_SEPARATOR_BYTE + 1) << 8)); int highLimit = scriptStarts[scriptStarts.length - 1]; assert(highLimit == (Collation.TRAIL_WEIGHT_BYTE << 8)); // Get the set of special reorder codes in the input list. // This supports a fixed number of special reorder codes; // it works for data with codes beyond Collator.ReorderCodes.LIMIT. int specials = 0; for(int i = 0; i < length; ++i) { int reorderCode = reorder[i] - Collator.ReorderCodes.FIRST; if(0 <= reorderCode && reorderCode < MAX_NUM_SPECIAL_REORDER_CODES) { specials |= 1 << reorderCode; } } // Start the reordering with the special low reorder codes that do not occur in the input. for(int i = 0; i < MAX_NUM_SPECIAL_REORDER_CODES; ++i) { int index = scriptsIndex[numScripts + i]; if(index != 0 && (specials & (1 << i)) == 0) { lowStart = addLowScriptRange(table, index, lowStart); } } // Skip the reserved range before Latin if Latin is the first script, // so that we do not move it unnecessarily. int skippedReserved = 0; if(specials == 0 && reorder[0] == UScript.LATIN && !latinMustMove) { int index = scriptsIndex[UScript.LATIN]; assert(index != 0); int start = scriptStarts[index]; assert(lowStart <= start); skippedReserved = start - lowStart; lowStart = start; } // Reorder according to the input scripts, continuing from the bottom of the primary range. boolean hasReorderToEnd = false; for(int i = 0; i < length;) { int script = reorder[i++]; if(script == UScript.UNKNOWN) { // Put the remaining scripts at the top. hasReorderToEnd = true; while(i < length) { script = reorder[--length]; if(script == UScript.UNKNOWN) { // Must occur at most once. throw new IllegalArgumentException( "setReorderCodes(): duplicate UScript.UNKNOWN"); } if(script == Collator.ReorderCodes.DEFAULT) { throw new IllegalArgumentException( "setReorderCodes(): UScript.DEFAULT together with other scripts"); } int index = getScriptIndex(script); if(index == 0) { continue; } if(table[index] != 0) { // Duplicate or equivalent script. throw new IllegalArgumentException( "setReorderCodes(): duplicate or equivalent script " + scriptCodeString(script)); } highLimit = addHighScriptRange(table, index, highLimit); } break; } if(script == Collator.ReorderCodes.DEFAULT) { // The default code must be the only one in the list, and that is handled by the caller. // Otherwise it must not be used. throw new IllegalArgumentException( "setReorderCodes(): UScript.DEFAULT together with other scripts"); } int index = getScriptIndex(script); if(index == 0) { continue; } if(table[index] != 0) { // Duplicate or equivalent script. throw new IllegalArgumentException( "setReorderCodes(): duplicate or equivalent script " + scriptCodeString(script)); } lowStart = addLowScriptRange(table, index, lowStart); } // Put all remaining scripts into the middle. for(int i = 1; i < scriptStarts.length - 1; ++i) { int leadByte = table[i]; if(leadByte != 0) { continue; } int start = scriptStarts[i]; if(!hasReorderToEnd && start > lowStart) { // No need to move this script. lowStart = start; } lowStart = addLowScriptRange(table, i, lowStart); } if(lowStart > highLimit) { if((lowStart - (skippedReserved & 0xff00)) <= highLimit) { // Try not skipping the before-Latin reserved range. makeReorderRanges(reorder, true, ranges); return; } // We need more primary lead bytes than available, despite the reserved ranges. throw new ICUException( "setReorderCodes(): reordering too many partial-primary-lead-byte scripts"); } // Turn lead bytes into a list of (limit, offset) pairs. // Encode each pair in one list element: // Upper 16 bits = limit, lower 16 = signed lead byte offset. int offset = 0; for(int i = 1;; ++i) { int nextOffset = offset; while(i < scriptStarts.length - 1) { int newLeadByte = table[i]; if(newLeadByte == 0xff) { // "Don't care" lead byte for reserved range, continue with current offset. } else { nextOffset = newLeadByte - (scriptStarts[i] >> 8); if(nextOffset != offset) { break; } } ++i; } if(offset != 0 || i < scriptStarts.length - 1) { ranges.addElement(((int)scriptStarts[i] << 16) | (offset & 0xffff)); } if(i == scriptStarts.length - 1) { break; } offset = nextOffset; } } private int addLowScriptRange(short[] table, int index, int lowStart) { int start = scriptStarts[index]; if((start & 0xff) < (lowStart & 0xff)) { lowStart += 0x100; } table[index] = (short)(lowStart >> 8); int limit = scriptStarts[index + 1]; lowStart = ((lowStart & 0xff00) + ((limit & 0xff00) - (start & 0xff00))) | (limit & 0xff); return lowStart; } private int addHighScriptRange(short[] table, int index, int highLimit) { int limit = scriptStarts[index + 1]; if((limit & 0xff) > (highLimit & 0xff)) { highLimit -= 0x100; } int start = scriptStarts[index]; highLimit = ((highLimit & 0xff00) - ((limit & 0xff00) - (start & 0xff00))) | (start & 0xff); table[index] = (short)(highLimit >> 8); return highLimit; } private static String scriptCodeString(int script) { // Do not use the script name here: We do not want to depend on that data. return (script < Collator.ReorderCodes.FIRST) ? Integer.toString(script) : "0x" + Integer.toHexString(script); } private static final int[] EMPTY_INT_ARRAY = new int[0]; /** @see jamoCE32s */ static final int JAMO_CE32S_LENGTH = 19 + 21 + 27; /** Main lookup trie. */ Trie2_32 trie; /** * Array of CE32 values. * At index 0 there must be CE32(U+0000) * to support U+0000's special-tag for NUL-termination handling. */ int[] ce32s; /** Array of CE values for expansions and OFFSET_TAG. */ long[] ces; /** Array of prefix and contraction-suffix matching data. */ String contexts; /** Base collation data, or null if this data itself is a base. */ public CollationData base; /** * Simple array of JAMO_CE32S_LENGTH=19+21+27 CE32s, one per canonical Jamo L/V/T. * They are normally simple CE32s, rarely expansions. * For fast handling of HANGUL_TAG. */ int[] jamoCE32s = new int[JAMO_CE32S_LENGTH]; public Normalizer2Impl nfcImpl; /** The single-byte primary weight (xx000000) for numeric collation. */ long numericPrimary = 0x12000000; /** 256 flags for which primary-weight lead bytes are compressible. */ public boolean[] compressibleBytes; /** * Set of code points that are unsafe for starting string comparison after an identical prefix, * or in backwards CE iteration. */ UnicodeSet unsafeBackwardSet; /** * Fast Latin table for common-Latin-text string comparisons. * Data structure see class CollationFastLatin. */ public char[] fastLatinTable; /** * Header portion of the fastLatinTable. * In C++, these are one array, and the header is skipped for mapping characters. * In Java, two arrays work better. */ char[] fastLatinTableHeader; /** * Data for scripts and reordering groups. * Uses include building a reordering permutation table and * providing script boundaries to AlphabeticIndex. */ int numScripts; /** * The length of scriptsIndex is numScripts+16. * It maps from a UScriptCode or a special reorder code to an entry in scriptStarts. * 16 special reorder codes (not all used) are mapped starting at numScripts. * Up to MAX_NUM_SPECIAL_REORDER_CODES are codes for special groups like space/punct/digit. * There are special codes at the end for reorder-reserved primary ranges. * *

Multiple scripts may share a range and index, for example Hira & Kana. */ char[] scriptsIndex; /** * Start primary weight (top 16 bits only) for a group/script/reserved range * indexed by scriptsIndex. * The first range (separators & terminators) and the last range (trailing weights) * are not reorderable, and no scriptsIndex entry points to them. */ char[] scriptStarts; /** * Collation elements in the root collator. * Used by the CollationRootElements class. The data structure is described there. * null in a tailoring. */ public long[] rootElements; }





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