[apple/icu.git] / icuSources / i18n / collation.h

/*
*******************************************************************************
* Copyright (C) 2010-2015, International Business Machines
* Corporation and others.  All Rights Reserved.
*******************************************************************************
* collation.h
*
* created on: 2010oct27
* created by: Markus W. Scherer
*/

#ifndef __COLLATION_H__
#define __COLLATION_H__

#include "unicode/utypes.h"

#if !UCONFIG_NO_COLLATION

U_NAMESPACE_BEGIN

/**
 * Collation v2 basic definitions and static helper functions.
 *
 * Data structures except for expansion tables store 32-bit CEs which are
 * either specials (see tags below) or are compact forms of 64-bit CEs.
 */
class U_I18N_API Collation {
public:
    // Special sort key bytes for all levels.
    static const uint8_t TERMINATOR_BYTE = 0;
    static const uint8_t LEVEL_SEPARATOR_BYTE = 1;

    /** The secondary/tertiary lower limit for tailoring before any root elements. */
    static const uint32_t BEFORE_WEIGHT16 = 0x0100;

    /**
     * Merge-sort-key separator.
     * Same as the unique primary and identical-level weights of U+FFFE.
     * Must not be used as primary compression low terminator.
     * Otherwise usable.
     */
    static const uint8_t MERGE_SEPARATOR_BYTE = 2;
    static const uint32_t MERGE_SEPARATOR_PRIMARY = 0x02000000;  // U+FFFE
    static const uint32_t MERGE_SEPARATOR_CE32 = 0x02000505;  // U+FFFE

    /**
     * Primary compression low terminator, must be greater than MERGE_SEPARATOR_BYTE.
     * Reserved value in primary second byte if the lead byte is compressible.
     * Otherwise usable in all CE weight bytes.
     */
    static const uint8_t PRIMARY_COMPRESSION_LOW_BYTE = 3;
    /**
     * Primary compression high terminator.
     * Reserved value in primary second byte if the lead byte is compressible.
     * Otherwise usable in all CE weight bytes.
     */
    static const uint8_t PRIMARY_COMPRESSION_HIGH_BYTE = 0xff;

    /** Default secondary/tertiary weight lead byte. */
    static const uint8_t COMMON_BYTE = 5;
    static const uint32_t COMMON_WEIGHT16 = 0x0500;
    /** Middle 16 bits of a CE with a common secondary weight. */
    static const uint32_t COMMON_SECONDARY_CE = 0x05000000;
    /** Lower 16 bits of a CE with a common tertiary weight. */
    static const uint32_t COMMON_TERTIARY_CE = 0x0500;
    /** Lower 32 bits of a CE with common secondary and tertiary weights. */
    static const uint32_t COMMON_SEC_AND_TER_CE = 0x05000500;

    static const uint32_t SECONDARY_MASK = 0xffff0000;
    static const uint32_t CASE_MASK = 0xc000;
    static const uint32_t SECONDARY_AND_CASE_MASK = SECONDARY_MASK | CASE_MASK;
    /** Only the 2*6 bits for the pure tertiary weight. */
    static const uint32_t ONLY_TERTIARY_MASK = 0x3f3f;
    /** Only the secondary & tertiary bits; no case, no quaternary. */
    static const uint32_t ONLY_SEC_TER_MASK = SECONDARY_MASK | ONLY_TERTIARY_MASK;
    /** Case bits and tertiary bits. */
    static const uint32_t CASE_AND_TERTIARY_MASK = CASE_MASK | ONLY_TERTIARY_MASK;
    static const uint32_t QUATERNARY_MASK = 0xc0;
    /** Case bits and quaternary bits. */
    static const uint32_t CASE_AND_QUATERNARY_MASK = CASE_MASK | QUATERNARY_MASK;

    static const uint8_t UNASSIGNED_IMPLICIT_BYTE = 0xfe;  // compressible
    /**
     * First unassigned: AlphabeticIndex overflow boundary.
     * We want a 3-byte primary so that it fits into the root elements table.
     *
     * This 3-byte primary will not collide with
     * any unassigned-implicit 4-byte primaries because
     * the first few hundred Unicode code points all have real mappings.
     */
    static const uint32_t FIRST_UNASSIGNED_PRIMARY = 0xfe040200;

    static const uint8_t TRAIL_WEIGHT_BYTE = 0xff;  // not compressible
    static const uint32_t FIRST_TRAILING_PRIMARY = 0xff020200;  // [first trailing]
    static const uint32_t MAX_PRIMARY = 0xffff0000;  // U+FFFF
    static const uint32_t MAX_REGULAR_CE32 = 0xffff0505;  // U+FFFF

    // CE32 value for U+FFFD as well as illegal UTF-8 byte sequences (which behave like U+FFFD).
    // We use the third-highest primary weight for U+FFFD (as in UCA 6.3+).
    static const uint32_t FFFD_PRIMARY = MAX_PRIMARY - 0x20000;
    static const uint32_t FFFD_CE32 = MAX_REGULAR_CE32 - 0x20000;

    /**
     * A CE32 is special if its low byte is this or greater.
     * Impossible case bits 11 mark special CE32s.
     * This value itself is used to indicate a fallback to the base collator.
     */
    static const uint8_t SPECIAL_CE32_LOW_BYTE = 0xc0;
    static const uint32_t FALLBACK_CE32 = SPECIAL_CE32_LOW_BYTE;
    /**
     * Low byte of a long-primary special CE32.
     */
    static const uint8_t LONG_PRIMARY_CE32_LOW_BYTE = 0xc1;  // SPECIAL_CE32_LOW_BYTE | LONG_PRIMARY_TAG

    static const uint32_t UNASSIGNED_CE32 = 0xffffffff;  // Compute an unassigned-implicit CE.

    static const uint32_t NO_CE32 = 1;

    /** No CE: End of input. Only used in runtime code, not stored in data. */
    static const uint32_t NO_CE_PRIMARY = 1;  // not a left-adjusted weight
    static const uint32_t NO_CE_WEIGHT16 = 0x0100;  // weight of LEVEL_SEPARATOR_BYTE
    static const int64_t NO_CE = INT64_C(0x101000100);  // NO_CE_PRIMARY, NO_CE_WEIGHT16, NO_CE_WEIGHT16

    /** Sort key levels. */
    enum Level {
        /** Unspecified level. */
        NO_LEVEL,
        PRIMARY_LEVEL,
        SECONDARY_LEVEL,
        CASE_LEVEL,
        TERTIARY_LEVEL,
        QUATERNARY_LEVEL,
        IDENTICAL_LEVEL,
        /** Beyond sort key bytes. */
        ZERO_LEVEL
    };

    /**
     * Sort key level flags: xx_FLAG = 1 << xx_LEVEL.
     * In Java, use enum Level with flag() getters, or use EnumSet rather than hand-made bit sets.
     */
    static const uint32_t NO_LEVEL_FLAG = 1;
    static const uint32_t PRIMARY_LEVEL_FLAG = 2;
    static const uint32_t SECONDARY_LEVEL_FLAG = 4;
    static const uint32_t CASE_LEVEL_FLAG = 8;
    static const uint32_t TERTIARY_LEVEL_FLAG = 0x10;
    static const uint32_t QUATERNARY_LEVEL_FLAG = 0x20;
    static const uint32_t IDENTICAL_LEVEL_FLAG = 0x40;
    static const uint32_t ZERO_LEVEL_FLAG = 0x80;

    /**
     * Special-CE32 tags, from bits 3..0 of a special 32-bit CE.
     * Bits 31..8 are available for tag-specific data.
     * Bits  5..4: Reserved. May be used in the future to indicate lccc!=0 and tccc!=0.
     */
    enum {
        /**
         * Fall back to the base collator.
         * This is the tag value in SPECIAL_CE32_LOW_BYTE and FALLBACK_CE32.
         * Bits 31..8: Unused, 0.
         */
        FALLBACK_TAG = 0,
        /**
         * Long-primary CE with COMMON_SEC_AND_TER_CE.
         * Bits 31..8: Three-byte primary.
         */
        LONG_PRIMARY_TAG = 1,
        /**
         * Long-secondary CE with zero primary.
         * Bits 31..16: Secondary weight.
         * Bits 15.. 8: Tertiary weight.
         */
        LONG_SECONDARY_TAG = 2,
        /**
         * Unused.
         * May be used in the future for single-byte secondary CEs (SHORT_SECONDARY_TAG),
         * storing the secondary in bits 31..24, the ccc in bits 23..16,
         * and the tertiary in bits 15..8.
         */
        RESERVED_TAG_3 = 3,
        /**
         * Latin mini expansions of two simple CEs [pp, 05, tt] [00, ss, 05].
         * Bits 31..24: Single-byte primary weight pp of the first CE.
         * Bits 23..16: Tertiary weight tt of the first CE.
         * Bits 15.. 8: Secondary weight ss of the second CE.
         */
        LATIN_EXPANSION_TAG = 4,
        /**
         * Points to one or more simple/long-primary/long-secondary 32-bit CE32s.
         * Bits 31..13: Index into uint32_t table.
         * Bits 12.. 8: Length=1..31.
         */
        EXPANSION32_TAG = 5,
        /**
         * Points to one or more 64-bit CEs.
         * Bits 31..13: Index into CE table.
         * Bits 12.. 8: Length=1..31.
         */
        EXPANSION_TAG = 6,
        /**
         * Builder data, used only in the CollationDataBuilder, not in runtime data.
         *
         * If bit 8 is 0: Builder context, points to a list of context-sensitive mappings.
         * Bits 31..13: Index to the builder's list of ConditionalCE32 for this character.
         * Bits 12.. 9: Unused, 0.
         *
         * If bit 8 is 1 (IS_BUILDER_JAMO_CE32): Builder-only jamoCE32 value.
         * The builder fetches the Jamo CE32 from the trie.
         * Bits 31..13: Jamo code point.
         * Bits 12.. 9: Unused, 0.
         */
        BUILDER_DATA_TAG = 7,
        /**
         * Points to prefix trie.
         * Bits 31..13: Index into prefix/contraction data.
         * Bits 12.. 8: Unused, 0.
         */
        PREFIX_TAG = 8,
        /**
         * Points to contraction data.
         * Bits 31..13: Index into prefix/contraction data.
         * Bits 12..11: Unused, 0.
         * Bit      10: CONTRACT_TRAILING_CCC flag.
         * Bit       9: CONTRACT_NEXT_CCC flag.
         * Bit       8: CONTRACT_SINGLE_CP_NO_MATCH flag.
         */
        CONTRACTION_TAG = 9,
        /**
         * Decimal digit.
         * Bits 31..13: Index into uint32_t table for non-numeric-collation CE32.
         * Bit      12: Unused, 0.
         * Bits 11.. 8: Digit value 0..9.
         */
        DIGIT_TAG = 10,
        /**
         * Tag for U+0000, for moving the NUL-termination handling
         * from the regular fastpath into specials-handling code.
         * Bits 31..8: Unused, 0.
         */
        U0000_TAG = 11,
        /**
         * Tag for a Hangul syllable.
         * Bits 31..9: Unused, 0.
         * Bit      8: HANGUL_NO_SPECIAL_JAMO flag.
         */
        HANGUL_TAG = 12,
        /**
         * Tag for a lead surrogate code unit.
         * Optional optimization for UTF-16 string processing.
         * Bits 31..10: Unused, 0.
         *       9.. 8: =0: All associated supplementary code points are unassigned-implict.
         *              =1: All associated supplementary code points fall back to the base data.
         *              else: (Normally 2) Look up the data for the supplementary code point.
         */
        LEAD_SURROGATE_TAG = 13,
        /**
         * Tag for CEs with primary weights in code point order.
         * Bits 31..13: Index into CE table, for one data "CE".
         * Bits 12.. 8: Unused, 0.
         *
         * This data "CE" has the following bit fields:
         * Bits 63..32: Three-byte primary pppppp00.
         *      31.. 8: Start/base code point of the in-order range.
         *           7: Flag isCompressible primary.
         *       6.. 0: Per-code point primary-weight increment.
         */
        OFFSET_TAG = 14,
        /**
         * Implicit CE tag. Compute an unassigned-implicit CE.
         * All bits are set (UNASSIGNED_CE32=0xffffffff).
         */
        IMPLICIT_TAG = 15
    };

    static UBool isAssignedCE32(uint32_t ce32) {
        return ce32 != FALLBACK_CE32 && ce32 != UNASSIGNED_CE32;
    }

    /**
     * We limit the number of CEs in an expansion
     * so that we can use a small number of length bits in the data structure,
     * and so that an implementation can copy CEs at runtime without growing a destination buffer.
     */
    static const int32_t MAX_EXPANSION_LENGTH = 31;
    static const int32_t MAX_INDEX = 0x7ffff;

    /**
     * Set if there is no match for the single (no-suffix) character itself.
     * This is only possible if there is a prefix.
     * In this case, discontiguous contraction matching cannot add combining marks
     * starting from an empty suffix.
     * The default CE32 is used anyway if there is no suffix match.
     */
    static const uint32_t CONTRACT_SINGLE_CP_NO_MATCH = 0x100;
    /** Set if the first character of every contraction suffix has lccc!=0. */
    static const uint32_t CONTRACT_NEXT_CCC = 0x200;
    /** Set if any contraction suffix ends with lccc!=0. */
    static const uint32_t CONTRACT_TRAILING_CCC = 0x400;

    /** For HANGUL_TAG: None of its Jamo CE32s isSpecialCE32(). */
    static const uint32_t HANGUL_NO_SPECIAL_JAMO = 0x100;

    static const uint32_t LEAD_ALL_UNASSIGNED = 0;
    static const uint32_t LEAD_ALL_FALLBACK = 0x100;
    static const uint32_t LEAD_MIXED = 0x200;
    static const uint32_t LEAD_TYPE_MASK = 0x300;

    static uint32_t makeLongPrimaryCE32(uint32_t p) { return p | LONG_PRIMARY_CE32_LOW_BYTE; }

    /** Turns the long-primary CE32 into a primary weight pppppp00. */
    static inline uint32_t primaryFromLongPrimaryCE32(uint32_t ce32) {
        return ce32 & 0xffffff00;
    }
    static inline int64_t ceFromLongPrimaryCE32(uint32_t ce32) {
        return ((int64_t)(ce32 & 0xffffff00) << 32) | COMMON_SEC_AND_TER_CE;
    }

    static uint32_t makeLongSecondaryCE32(uint32_t lower32) {
        return lower32 | SPECIAL_CE32_LOW_BYTE | LONG_SECONDARY_TAG;
    }
    static inline int64_t ceFromLongSecondaryCE32(uint32_t ce32) {
        return ce32 & 0xffffff00;
    }

    /** Makes a special CE32 with tag, index and length. */
    static uint32_t makeCE32FromTagIndexAndLength(int32_t tag, int32_t index, int32_t length) {
        return (index << 13) | (length << 8) | SPECIAL_CE32_LOW_BYTE | tag;
    }
    /** Makes a special CE32 with only tag and index. */
    static uint32_t makeCE32FromTagAndIndex(int32_t tag, int32_t index) {
        return (index << 13) | SPECIAL_CE32_LOW_BYTE | tag;
    }

    static inline UBool isSpecialCE32(uint32_t ce32) {
        return (ce32 & 0xff) >= SPECIAL_CE32_LOW_BYTE;
    }

    static inline int32_t tagFromCE32(uint32_t ce32) {
        return (int32_t)(ce32 & 0xf);
    }

    static inline UBool hasCE32Tag(uint32_t ce32, int32_t tag) {
        return isSpecialCE32(ce32) && tagFromCE32(ce32) == tag;
    }

    static inline UBool isLongPrimaryCE32(uint32_t ce32) {
        return hasCE32Tag(ce32, LONG_PRIMARY_TAG);
    }

    static UBool isSimpleOrLongCE32(uint32_t ce32) {
        return !isSpecialCE32(ce32) ||
                tagFromCE32(ce32) == LONG_PRIMARY_TAG ||
                tagFromCE32(ce32) == LONG_SECONDARY_TAG;
    }

    /**
     * @return TRUE if the ce32 yields one or more CEs without further data lookups
     */
    static UBool isSelfContainedCE32(uint32_t ce32) {
        return !isSpecialCE32(ce32) ||
                tagFromCE32(ce32) == LONG_PRIMARY_TAG ||
                tagFromCE32(ce32) == LONG_SECONDARY_TAG ||
                tagFromCE32(ce32) == LATIN_EXPANSION_TAG;
    }

    static inline UBool isPrefixCE32(uint32_t ce32) {
        return hasCE32Tag(ce32, PREFIX_TAG);
    }

    static inline UBool isContractionCE32(uint32_t ce32) {
        return hasCE32Tag(ce32, CONTRACTION_TAG);
    }

    static inline UBool ce32HasContext(uint32_t ce32) {
        return isSpecialCE32(ce32) &&
                (tagFromCE32(ce32) == PREFIX_TAG ||
                tagFromCE32(ce32) == CONTRACTION_TAG);
    }

    /**
     * Get the first of the two Latin-expansion CEs encoded in ce32.
     * @see LATIN_EXPANSION_TAG
     */
    static inline int64_t latinCE0FromCE32(uint32_t ce32) {
        return ((int64_t)(ce32 & 0xff000000) << 32) | COMMON_SECONDARY_CE | ((ce32 & 0xff0000) >> 8);
    }

    /**
     * Get the second of the two Latin-expansion CEs encoded in ce32.
     * @see LATIN_EXPANSION_TAG
     */
    static inline int64_t latinCE1FromCE32(uint32_t ce32) {
        return ((ce32 & 0xff00) << 16) | COMMON_TERTIARY_CE;
    }

    /**
     * Returns the data index from a special CE32.
     */
    static inline int32_t indexFromCE32(uint32_t ce32) {
        return (int32_t)(ce32 >> 13);
    }

    /**
     * Returns the data length from a ce32.
     */
    static inline int32_t lengthFromCE32(uint32_t ce32) {
        return (ce32 >> 8) & 31;
    }

    /**
     * Returns the digit value from a DIGIT_TAG ce32.
     */
    static inline char digitFromCE32(uint32_t ce32) {
        return (char)((ce32 >> 8) & 0xf);
    }

    /** Returns a 64-bit CE from a simple CE32 (not special). */
    static inline int64_t ceFromSimpleCE32(uint32_t ce32) {
        // normal form ppppsstt -> pppp0000ss00tt00
        // assert (ce32 & 0xff) < SPECIAL_CE32_LOW_BYTE
        return ((int64_t)(ce32 & 0xffff0000) << 32) | ((ce32 & 0xff00) << 16) | ((ce32 & 0xff) << 8);
    }

    /** Returns a 64-bit CE from a simple/long-primary/long-secondary CE32. */
    static inline int64_t ceFromCE32(uint32_t ce32) {
        uint32_t tertiary = ce32 & 0xff;
        if(tertiary < SPECIAL_CE32_LOW_BYTE) {
            // normal form ppppsstt -> pppp0000ss00tt00
            return ((int64_t)(ce32 & 0xffff0000) << 32) | ((ce32 & 0xff00) << 16) | (tertiary << 8);
        } else {
            ce32 -= tertiary;
            if((tertiary & 0xf) == LONG_PRIMARY_TAG) {
                // long-primary form ppppppC1 -> pppppp00050000500
                return ((int64_t)ce32 << 32) | COMMON_SEC_AND_TER_CE;
            } else {
                // long-secondary form ssssttC2 -> 00000000sssstt00
                // assert (tertiary & 0xf) == LONG_SECONDARY_TAG
                return ce32;
            }
        }
    }

    /** Creates a CE from a primary weight. */
    static inline int64_t makeCE(uint32_t p) {
        return ((int64_t)p << 32) | COMMON_SEC_AND_TER_CE;
    }
    /**
     * Creates a CE from a primary weight,
     * 16-bit secondary/tertiary weights, and a 2-bit quaternary.
     */
    static inline int64_t makeCE(uint32_t p, uint32_t s, uint32_t t, uint32_t q) {
        return ((int64_t)p << 32) | (s << 16) | t | (q << 6);
    }

    /**
     * Increments a 2-byte primary by a code point offset.
     */
    static uint32_t incTwoBytePrimaryByOffset(uint32_t basePrimary, UBool isCompressible,
                                              int32_t offset);

    /**
     * Increments a 3-byte primary by a code point offset.
     */
    static uint32_t incThreeBytePrimaryByOffset(uint32_t basePrimary, UBool isCompressible,
                                                int32_t offset);

    /**
     * Decrements a 2-byte primary by one range step (1..0x7f).
     */
    static uint32_t decTwoBytePrimaryByOneStep(uint32_t basePrimary, UBool isCompressible, int32_t step);

    /**
     * Decrements a 3-byte primary by one range step (1..0x7f).
     */
    static uint32_t decThreeBytePrimaryByOneStep(uint32_t basePrimary, UBool isCompressible, int32_t step);

    /**
     * Computes a 3-byte primary for c's OFFSET_TAG data "CE".
     */
    static uint32_t getThreeBytePrimaryForOffsetData(UChar32 c, int64_t dataCE);

    /**
     * Returns the unassigned-character implicit primary weight for any valid code point c.
     */
    static uint32_t unassignedPrimaryFromCodePoint(UChar32 c);

    static inline int64_t unassignedCEFromCodePoint(UChar32 c) {
        return makeCE(unassignedPrimaryFromCodePoint(c));
    }

private:
    Collation();  // No instantiation.
};

U_NAMESPACE_END

#endif  // !UCONFIG_NO_COLLATION
#endif  // __COLLATION_H__
Commit	Line	Data
57a6839d A	1	/*
57a6839d A	2	*******************************************************************************
b331163b	3	* Copyright (C) 2010-2015, International Business Machines
57a6839d A	4	* Corporation and others. All Rights Reserved.
	5	*******************************************************************************
	6	* collation.h
	7	*
	8	* created on: 2010oct27
	9	* created by: Markus W. Scherer
	10	*/
	11
	12	#ifndef __COLLATION_H__
	13	#define __COLLATION_H__
	14
	15	#include "unicode/utypes.h"
	16
	17	#if !UCONFIG_NO_COLLATION
	18
	19	U_NAMESPACE_BEGIN
	20
	21	/**
	22	* Collation v2 basic definitions and static helper functions.
	23	*
	24	* Data structures except for expansion tables store 32-bit CEs which are
	25	* either specials (see tags below) or are compact forms of 64-bit CEs.
	26	*/
	27	class U_I18N_API Collation {
	28	public:
	29	// Special sort key bytes for all levels.
	30	static const uint8_t TERMINATOR_BYTE = 0;
	31	static const uint8_t LEVEL_SEPARATOR_BYTE = 1;
b331163b A	32
	33	/** The secondary/tertiary lower limit for tailoring before any root elements. */
	34	static const uint32_t BEFORE_WEIGHT16 = 0x0100;
	35
57a6839d A	36	/**
57a6839d A	37	* Merge-sort-key separator.
b331163b A	38	* Same as the unique primary and identical-level weights of U+FFFE.
b331163b A	39	* Must not be used as primary compression low terminator.
57a6839d A	40	* Otherwise usable.
	41	*/
	42	static const uint8_t MERGE_SEPARATOR_BYTE = 2;
	43	static const uint32_t MERGE_SEPARATOR_PRIMARY = 0x02000000; // U+FFFE
b331163b	44	static const uint32_t MERGE_SEPARATOR_CE32 = 0x02000505; // U+FFFE
57a6839d A	45
	46	/**
	47	* Primary compression low terminator, must be greater than MERGE_SEPARATOR_BYTE.
	48	* Reserved value in primary second byte if the lead byte is compressible.
	49	* Otherwise usable in all CE weight bytes.
	50	*/
	51	static const uint8_t PRIMARY_COMPRESSION_LOW_BYTE = 3;
	52	/**
	53	* Primary compression high terminator.
	54	* Reserved value in primary second byte if the lead byte is compressible.
	55	* Otherwise usable in all CE weight bytes.
	56	*/
	57	static const uint8_t PRIMARY_COMPRESSION_HIGH_BYTE = 0xff;
	58
	59	/** Default secondary/tertiary weight lead byte. */
	60	static const uint8_t COMMON_BYTE = 5;
	61	static const uint32_t COMMON_WEIGHT16 = 0x0500;
	62	/** Middle 16 bits of a CE with a common secondary weight. */
	63	static const uint32_t COMMON_SECONDARY_CE = 0x05000000;
	64	/** Lower 16 bits of a CE with a common tertiary weight. */
	65	static const uint32_t COMMON_TERTIARY_CE = 0x0500;
	66	/** Lower 32 bits of a CE with common secondary and tertiary weights. */
	67	static const uint32_t COMMON_SEC_AND_TER_CE = 0x05000500;
	68
	69	static const uint32_t SECONDARY_MASK = 0xffff0000;
	70	static const uint32_t CASE_MASK = 0xc000;
	71	static const uint32_t SECONDARY_AND_CASE_MASK = SECONDARY_MASK \| CASE_MASK;
	72	/** Only the 26 bits for the pure tertiary weight. /
	73	static const uint32_t ONLY_TERTIARY_MASK = 0x3f3f;
	74	/** Only the secondary & tertiary bits; no case, no quaternary. */
	75	static const uint32_t ONLY_SEC_TER_MASK = SECONDARY_MASK \| ONLY_TERTIARY_MASK;
	76	/** Case bits and tertiary bits. */
	77	static const uint32_t CASE_AND_TERTIARY_MASK = CASE_MASK \| ONLY_TERTIARY_MASK;
	78	static const uint32_t QUATERNARY_MASK = 0xc0;
	79	/** Case bits and quaternary bits. */
	80	static const uint32_t CASE_AND_QUATERNARY_MASK = CASE_MASK \| QUATERNARY_MASK;
	81
	82	static const uint8_t UNASSIGNED_IMPLICIT_BYTE = 0xfe; // compressible
	83	/**
	84	* First unassigned: AlphabeticIndex overflow boundary.
	85	* We want a 3-byte primary so that it fits into the root elements table.
	86	*
	87	* This 3-byte primary will not collide with
	88	* any unassigned-implicit 4-byte primaries because
	89	* the first few hundred Unicode code points all have real mappings.
	90	*/
	91	static const uint32_t FIRST_UNASSIGNED_PRIMARY = 0xfe040200;
	92
	93	static const uint8_t TRAIL_WEIGHT_BYTE = 0xff; // not compressible
	94	static const uint32_t FIRST_TRAILING_PRIMARY = 0xff020200; // [first trailing]
	95	static const uint32_t MAX_PRIMARY = 0xffff0000; // U+FFFF
	96	static const uint32_t MAX_REGULAR_CE32 = 0xffff0505; // U+FFFF
	97
	98	// CE32 value for U+FFFD as well as illegal UTF-8 byte sequences (which behave like U+FFFD).
	99	// We use the third-highest primary weight for U+FFFD (as in UCA 6.3+).
	100	static const uint32_t FFFD_PRIMARY = MAX_PRIMARY - 0x20000;
	101	static const uint32_t FFFD_CE32 = MAX_REGULAR_CE32 - 0x20000;
	102
	103	/**
	104	* A CE32 is special if its low byte is this or greater.
	105	* Impossible case bits 11 mark special CE32s.
	106	* This value itself is used to indicate a fallback to the base collator.
	107	*/
	108	static const uint8_t SPECIAL_CE32_LOW_BYTE = 0xc0;
109	static const uint32_t FALLBACK_CE32 = SPECIAL_CE32_LOW_BYTE;
110	/**
111	* Low byte of a long-primary special CE32.
112	*/
113	static const uint8_t LONG_PRIMARY_CE32_LOW_BYTE = 0xc1; // SPECIAL_CE32_LOW_BYTE \| LONG_PRIMARY_TAG
114
115	static const uint32_t UNASSIGNED_CE32 = 0xffffffff; // Compute an unassigned-implicit CE.
116
117	static const uint32_t NO_CE32 = 1;
118
119	/** No CE: End of input. Only used in runtime code, not stored in data. */
120	static const uint32_t NO_CE_PRIMARY = 1; // not a left-adjusted weight
121	static const uint32_t NO_CE_WEIGHT16 = 0x0100; // weight of LEVEL_SEPARATOR_BYTE
122	static const int64_t NO_CE = INT64_C(0x101000100); // NO_CE_PRIMARY, NO_CE_WEIGHT16, NO_CE_WEIGHT16
123
124	/** Sort key levels. */
125	enum Level {
126	/** Unspecified level. */
127	NO_LEVEL,
128	PRIMARY_LEVEL,
129	SECONDARY_LEVEL,
130	CASE_LEVEL,
131	TERTIARY_LEVEL,
132	QUATERNARY_LEVEL,
133	IDENTICAL_LEVEL,
134	/** Beyond sort key bytes. */
135	ZERO_LEVEL
136	};
137
138	/**
139	* Sort key level flags: xx_FLAG = 1 << xx_LEVEL.
140	* In Java, use enum Level with flag() getters, or use EnumSet rather than hand-made bit sets.
141	*/
142	static const uint32_t NO_LEVEL_FLAG = 1;
143	static const uint32_t PRIMARY_LEVEL_FLAG = 2;
144	static const uint32_t SECONDARY_LEVEL_FLAG = 4;
145	static const uint32_t CASE_LEVEL_FLAG = 8;
146	static const uint32_t TERTIARY_LEVEL_FLAG = 0x10;
147	static const uint32_t QUATERNARY_LEVEL_FLAG = 0x20;
148	static const uint32_t IDENTICAL_LEVEL_FLAG = 0x40;
149	static const uint32_t ZERO_LEVEL_FLAG = 0x80;
150
151	/**
152	* Special-CE32 tags, from bits 3..0 of a special 32-bit CE.
153	* Bits 31..8 are available for tag-specific data.
154	* Bits 5..4: Reserved. May be used in the future to indicate lccc!=0 and tccc!=0.
155	*/
156	enum {
157	/**
158	* Fall back to the base collator.
159	* This is the tag value in SPECIAL_CE32_LOW_BYTE and FALLBACK_CE32.
160	* Bits 31..8: Unused, 0.
161	*/
162	FALLBACK_TAG = 0,
163	/**
164	* Long-primary CE with COMMON_SEC_AND_TER_CE.
165	* Bits 31..8: Three-byte primary.
166	*/
167	LONG_PRIMARY_TAG = 1,
168	/**
169	* Long-secondary CE with zero primary.
170	* Bits 31..16: Secondary weight.
171	* Bits 15.. 8: Tertiary weight.
172	*/
173	LONG_SECONDARY_TAG = 2,
174	/**
175	* Unused.
176	* May be used in the future for single-byte secondary CEs (SHORT_SECONDARY_TAG),
177	* storing the secondary in bits 31..24, the ccc in bits 23..16,
178	* and the tertiary in bits 15..8.
179	*/
180	RESERVED_TAG_3 = 3,
181	/**
182	* Latin mini expansions of two simple CEs [pp, 05, tt] [00, ss, 05].
183	* Bits 31..24: Single-byte primary weight pp of the first CE.
184	* Bits 23..16: Tertiary weight tt of the first CE.
185	* Bits 15.. 8: Secondary weight ss of the second CE.
186	*/
187	LATIN_EXPANSION_TAG = 4,
188	/**
189	* Points to one or more simple/long-primary/long-secondary 32-bit CE32s.
190	* Bits 31..13: Index into uint32_t table.
191	* Bits 12.. 8: Length=1..31.
192	*/
193	EXPANSION32_TAG = 5,
194	/**
195	* Points to one or more 64-bit CEs.
196	* Bits 31..13: Index into CE table.
197	* Bits 12.. 8: Length=1..31.
198	*/
199	EXPANSION_TAG = 6,
200	/**
201	* Builder data, used only in the CollationDataBuilder, not in runtime data.
202	*
203	* If bit 8 is 0: Builder context, points to a list of context-sensitive mappings.
204	* Bits 31..13: Index to the builder's list of ConditionalCE32 for this character.
205	* Bits 12.. 9: Unused, 0.
206	*
207	* If bit 8 is 1 (IS_BUILDER_JAMO_CE32): Builder-only jamoCE32 value.
208	* The builder fetches the Jamo CE32 from the trie.
209	* Bits 31..13: Jamo code point.
210	* Bits 12.. 9: Unused, 0.
211	*/
212	BUILDER_DATA_TAG = 7,
213	/**
214	* Points to prefix trie.
215	* Bits 31..13: Index into prefix/contraction data.
216	* Bits 12.. 8: Unused, 0.
217	*/
218	PREFIX_TAG = 8,
219	/**
220	* Points to contraction data.
221	* Bits 31..13: Index into prefix/contraction data.
222	* Bits 12..11: Unused, 0.
223	* Bit 10: CONTRACT_TRAILING_CCC flag.
224	* Bit 9: CONTRACT_NEXT_CCC flag.
225	* Bit 8: CONTRACT_SINGLE_CP_NO_MATCH flag.
226	*/
227	CONTRACTION_TAG = 9,
228	/**
229	* Decimal digit.
230	* Bits 31..13: Index into uint32_t table for non-numeric-collation CE32.
231	* Bit 12: Unused, 0.
232	* Bits 11.. 8: Digit value 0..9.
233	*/
234	DIGIT_TAG = 10,
235	/**
236	* Tag for U+0000, for moving the NUL-termination handling
237	* from the regular fastpath into specials-handling code.
238	* Bits 31..8: Unused, 0.
239	*/
240	U0000_TAG = 11,
241	/**
242	* Tag for a Hangul syllable.
243	* Bits 31..9: Unused, 0.
244	* Bit 8: HANGUL_NO_SPECIAL_JAMO flag.
245	*/
246	HANGUL_TAG = 12,
247	/**
248	* Tag for a lead surrogate code unit.
249	* Optional optimization for UTF-16 string processing.
250	* Bits 31..10: Unused, 0.
251	* 9.. 8: =0: All associated supplementary code points are unassigned-implict.
252	* =1: All associated supplementary code points fall back to the base data.
253	* else: (Normally 2) Look up the data for the supplementary code point.
254	*/
255	LEAD_SURROGATE_TAG = 13,
256	/**
257	* Tag for CEs with primary weights in code point order.
258	* Bits 31..13: Index into CE table, for one data "CE".
259	* Bits 12.. 8: Unused, 0.
260	*
261	* This data "CE" has the following bit fields:
262	* Bits 63..32: Three-byte primary pppppp00.
263	* 31.. 8: Start/base code point of the in-order range.
264	* 7: Flag isCompressible primary.
265	* 6.. 0: Per-code point primary-weight increment.
266	*/
267	OFFSET_TAG = 14,
268	/**
269	* Implicit CE tag. Compute an unassigned-implicit CE.
270	* All bits are set (UNASSIGNED_CE32=0xffffffff).
271	*/
272	IMPLICIT_TAG = 15
273	};
274
275	static UBool isAssignedCE32(uint32_t ce32) {
276	return ce32 != FALLBACK_CE32 && ce32 != UNASSIGNED_CE32;
277	}
278
279	/**
280	* We limit the number of CEs in an expansion
281	* so that we can use a small number of length bits in the data structure,
282	* and so that an implementation can copy CEs at runtime without growing a destination buffer.
283	*/
284	static const int32_t MAX_EXPANSION_LENGTH = 31;
285	static const int32_t MAX_INDEX = 0x7ffff;
286
287	/**
288	* Set if there is no match for the single (no-suffix) character itself.
289	* This is only possible if there is a prefix.
290	* In this case, discontiguous contraction matching cannot add combining marks
291	* starting from an empty suffix.
292	* The default CE32 is used anyway if there is no suffix match.
293	*/
294	static const uint32_t CONTRACT_SINGLE_CP_NO_MATCH = 0x100;
295	/** Set if the first character of every contraction suffix has lccc!=0. */
296	static const uint32_t CONTRACT_NEXT_CCC = 0x200;
297	/** Set if any contraction suffix ends with lccc!=0. */
298	static const uint32_t CONTRACT_TRAILING_CCC = 0x400;
299
300	/** For HANGUL_TAG: None of its Jamo CE32s isSpecialCE32(). */
301	static const uint32_t HANGUL_NO_SPECIAL_JAMO = 0x100;
302
303	static const uint32_t LEAD_ALL_UNASSIGNED = 0;
304	static const uint32_t LEAD_ALL_FALLBACK = 0x100;
305	static const uint32_t LEAD_MIXED = 0x200;
306	static const uint32_t LEAD_TYPE_MASK = 0x300;
307
308	static uint32_t makeLongPrimaryCE32(uint32_t p) { return p \| LONG_PRIMARY_CE32_LOW_BYTE; }
309
310	/** Turns the long-primary CE32 into a primary weight pppppp00. */
311	static inline uint32_t primaryFromLongPrimaryCE32(uint32_t ce32) {
312	return ce32 & 0xffffff00;
313	}
314	static inline int64_t ceFromLongPrimaryCE32(uint32_t ce32) {
315	return ((int64_t)(ce32 & 0xffffff00) << 32) \| COMMON_SEC_AND_TER_CE;
316	}
317
318	static uint32_t makeLongSecondaryCE32(uint32_t lower32) {
319	return lower32 \| SPECIAL_CE32_LOW_BYTE \| LONG_SECONDARY_TAG;
320	}
321	static inline int64_t ceFromLongSecondaryCE32(uint32_t ce32) {
322	return ce32 & 0xffffff00;
323	}
324
325	/** Makes a special CE32 with tag, index and length. */
326	static uint32_t makeCE32FromTagIndexAndLength(int32_t tag, int32_t index, int32_t length) {
327	return (index << 13) \| (length << 8) \| SPECIAL_CE32_LOW_BYTE \| tag;
328	}
329	/** Makes a special CE32 with only tag and index. */
330	static uint32_t makeCE32FromTagAndIndex(int32_t tag, int32_t index) {
331	return (index << 13) \| SPECIAL_CE32_LOW_BYTE \| tag;
332	}
333
334	static inline UBool isSpecialCE32(uint32_t ce32) {
335	return (ce32 & 0xff) >= SPECIAL_CE32_LOW_BYTE;
336	}
337
338	static inline int32_t tagFromCE32(uint32_t ce32) {
339	return (int32_t)(ce32 & 0xf);
340	}
341
342	static inline UBool hasCE32Tag(uint32_t ce32, int32_t tag) {
343	return isSpecialCE32(ce32) && tagFromCE32(ce32) == tag;
344	}
345
346	static inline UBool isLongPrimaryCE32(uint32_t ce32) {
347	return hasCE32Tag(ce32, LONG_PRIMARY_TAG);
348	}
349
350	static UBool isSimpleOrLongCE32(uint32_t ce32) {
351	return !isSpecialCE32(ce32) \|\|
352	tagFromCE32(ce32) == LONG_PRIMARY_TAG \|\|
353	tagFromCE32(ce32) == LONG_SECONDARY_TAG;
354	}
355
356	/**
357	* @return TRUE if the ce32 yields one or more CEs without further data lookups
358	*/
359	static UBool isSelfContainedCE32(uint32_t ce32) {
360	return !isSpecialCE32(ce32) \|\|
361	tagFromCE32(ce32) == LONG_PRIMARY_TAG \|\|
362	tagFromCE32(ce32) == LONG_SECONDARY_TAG \|\|
363	tagFromCE32(ce32) == LATIN_EXPANSION_TAG;
364	}
365
366	static inline UBool isPrefixCE32(uint32_t ce32) {
367	return hasCE32Tag(ce32, PREFIX_TAG);
368	}
369
370	static inline UBool isContractionCE32(uint32_t ce32) {
371	return hasCE32Tag(ce32, CONTRACTION_TAG);
372	}
373
374	static inline UBool ce32HasContext(uint32_t ce32) {
375	return isSpecialCE32(ce32) &&
376	(tagFromCE32(ce32) == PREFIX_TAG \|\|
377	tagFromCE32(ce32) == CONTRACTION_TAG);
378	}
379
380	/**
381	* Get the first of the two Latin-expansion CEs encoded in ce32.
382	* @see LATIN_EXPANSION_TAG
383	*/
384	static inline int64_t latinCE0FromCE32(uint32_t ce32) {
385	return ((int64_t)(ce32 & 0xff000000) << 32) \| COMMON_SECONDARY_CE \| ((ce32 & 0xff0000) >> 8);
386	}
387
388	/**
389	* Get the second of the two Latin-expansion CEs encoded in ce32.
390	* @see LATIN_EXPANSION_TAG
391	*/
392	static inline int64_t latinCE1FromCE32(uint32_t ce32) {
393	return ((ce32 & 0xff00) << 16) \| COMMON_TERTIARY_CE;
394	}
395
396	/**
397	* Returns the data index from a special CE32.
398	*/
399	static inline int32_t indexFromCE32(uint32_t ce32) {
400	return (int32_t)(ce32 >> 13);
401	}
402
403	/**
404	* Returns the data length from a ce32.
405	*/
406	static inline int32_t lengthFromCE32(uint32_t ce32) {
407	return (ce32 >> 8) & 31;
408	}
409
410	/**
411	* Returns the digit value from a DIGIT_TAG ce32.
412	*/
413	static inline char digitFromCE32(uint32_t ce32) {
414	return (char)((ce32 >> 8) & 0xf);
415	}
416
417	/** Returns a 64-bit CE from a simple CE32 (not special). */
418	static inline int64_t ceFromSimpleCE32(uint32_t ce32) {
419	// normal form ppppsstt -> pppp0000ss00tt00
420	// assert (ce32 & 0xff) < SPECIAL_CE32_LOW_BYTE
421	return ((int64_t)(ce32 & 0xffff0000) << 32) \| ((ce32 & 0xff00) << 16) \| ((ce32 & 0xff) << 8);
422	}
423
424	/** Returns a 64-bit CE from a simple/long-primary/long-secondary CE32. */
425	static inline int64_t ceFromCE32(uint32_t ce32) {
426	uint32_t tertiary = ce32 & 0xff;
427	if(tertiary < SPECIAL_CE32_LOW_BYTE) {
428	// normal form ppppsstt -> pppp0000ss00tt00
429	return ((int64_t)(ce32 & 0xffff0000) << 32) \| ((ce32 & 0xff00) << 16) \| (tertiary << 8);
430	} else {
431	ce32 -= tertiary;
432	if((tertiary & 0xf) == LONG_PRIMARY_TAG) {
433	// long-primary form ppppppC1 -> pppppp00050000500
434	return ((int64_t)ce32 << 32) \| COMMON_SEC_AND_TER_CE;
435	} else {
436	// long-secondary form ssssttC2 -> 00000000sssstt00
437	// assert (tertiary & 0xf) == LONG_SECONDARY_TAG
438	return ce32;
439	}
440	}
441	}
442
443	/** Creates a CE from a primary weight. */
444	static inline int64_t makeCE(uint32_t p) {
445	return ((int64_t)p << 32) \| COMMON_SEC_AND_TER_CE;
446	}
447	/**
448	* Creates a CE from a primary weight,
449	* 16-bit secondary/tertiary weights, and a 2-bit quaternary.
450	*/
451	static inline int64_t makeCE(uint32_t p, uint32_t s, uint32_t t, uint32_t q) {
452	return ((int64_t)p << 32) \| (s << 16) \| t \| (q << 6);
453	}
454
455	/**
456	* Increments a 2-byte primary by a code point offset.
457	*/
458	static uint32_t incTwoBytePrimaryByOffset(uint32_t basePrimary, UBool isCompressible,
459	int32_t offset);
460
461	/**
462	* Increments a 3-byte primary by a code point offset.
463	*/
464	static uint32_t incThreeBytePrimaryByOffset(uint32_t basePrimary, UBool isCompressible,
465	int32_t offset);
466
467	/**
468	* Decrements a 2-byte primary by one range step (1..0x7f).
469	*/
470	static uint32_t decTwoBytePrimaryByOneStep(uint32_t basePrimary, UBool isCompressible, int32_t step);
471
472	/**
473	* Decrements a 3-byte primary by one range step (1..0x7f).
474	*/
475	static uint32_t decThreeBytePrimaryByOneStep(uint32_t basePrimary, UBool isCompressible, int32_t step);
476
477	/**
478	* Computes a 3-byte primary for c's OFFSET_TAG data "CE".
479	*/
480	static uint32_t getThreeBytePrimaryForOffsetData(UChar32 c, int64_t dataCE);
481
482	/**
483	* Returns the unassigned-character implicit primary weight for any valid code point c.
484	*/
485	static uint32_t unassignedPrimaryFromCodePoint(UChar32 c);
486
487	static inline int64_t unassignedCEFromCodePoint(UChar32 c) {
488	return makeCE(unassignedPrimaryFromCodePoint(c));
489	}
490
57a6839d A	491	private:
	492	Collation(); // No instantiation.
	493	};
	494
	495	U_NAMESPACE_END
	496
	497	#endif // !UCONFIG_NO_COLLATION
	498	#endif // __COLLATION_H__