/* ******************************************************************************* * * Copyright (C) 1998-2010, International Business Machines * Corporation and others. All Rights Reserved. * ******************************************************************************* * * Private implementation header for C collation * file name: ucol_imp.h * encoding: US-ASCII * tab size: 8 (not used) * indentation:4 * * created on: 2000dec11 * created by: Vladimir Weinstein * * Modification history * Date Name Comments * 02/16/2001 synwee Added UCOL_GETPREVCE for the use in ucoleitr * 02/27/2001 synwee Added getMaxExpansion data structure in UCollator * 03/02/2001 synwee Added UCOL_IMPLICIT_CE * 03/12/2001 synwee Added pointer start to collIterate. */ #ifndef UCOL_IMP_H #define UCOL_IMP_H #include "unicode/utypes.h" #define UCA_DATA_TYPE "icu" #define UCA_DATA_NAME "ucadata" #define INVC_DATA_TYPE "icu" #define INVC_DATA_NAME "invuca" /** * Convenience string denoting the Collation data tree * @internal ICU 3.0 */ #define U_ICUDATA_COLL U_ICUDATA_NAME U_TREE_SEPARATOR_STRING "coll" #if !UCONFIG_NO_COLLATION #ifdef XP_CPLUSPLUS #include "unicode/normalizer2.h" #include "unicode/unistr.h" #endif #include "unicode/ucol.h" #include "utrie.h" #include "cmemory.h" /* This is the internal header file which contains important declarations for * the collation framework. * Ready to use collators are stored as binary images. Both UCA and tailorings * share the same binary format. Individual files (currently only UCA) have a * udata header in front of the image and should be opened using udata_open. * Tailoring images are currently stored inside resource bundles and are intialized * through ucol_open API. * * The following describes the formats for collation binaries * (UCA & tailorings) and for the inverse UCA table. * Substructures are described in the collation design document at * http://source.icu-project.org/repos/icu/icuhtml/trunk/design/collation/ICU_collation_design.htm * * ------------------------------------------------------------- * * Here is the format of binary collation image. * * Physical order of structures: * - header (UCATableHeader) * - options (UColOptionSet) * - expansions (CE[]) * - contractions (UChar[contractionSize] + CE[contractionSize]) * - serialized UTrie with mappings of code points to CEs * - max expansion tables (CE[endExpansionCECount] + uint8_t[endExpansionCECount]) * - two bit sets for backward processing in strcoll (identical prefixes) * and for backward CE iteration (each set is uint8_t[UCOL_UNSAFECP_TABLE_SIZE]) * - UCA constants (UCAConstants) * - UCA contractions (UChar[contractionUCACombosSize][contractionUCACombosWidth]) * * UCATableHeader fields: * * int32_t size; - image size in bytes * * Offsets to interesting data. All offsets are in bytes. * to get the address add to the header address and cast properly. * Some offsets are zero if the corresponding structures are empty. * * Tailoring binaries that only set options and contain no mappings etc. * will have all offsets 0 except for the options and expansion offsets, * which give the position and length of the options array. * * uint32_t options; - offset to default collator options (UColOptionSet *), * a set of 32-bit values. See declaration of UColOptionSet for more details * * uint32_t UCAConsts; - only used (!=0) in UCA image - structure which holds values for indirect positioning and implicit ranges * See declaration of UCAConstants structure. This is a set of unsigned 32-bit values used to store * important constant values that are defined in the UCA and used for building and runtime. * * uint32_t contractionUCACombos; - only used (!=0) in UCA image - list of UCA contractions. This is a zero terminated array of UChar[contractionUCACombosWidth], * containing contractions from the UCA. These are needed in the build process to copy UCA contractions * in case the base contraction symbol is tailored. * * uint32_t magic; - must contain UCOL_HEADER_MAGIC (formatVersion 2.3) * * uint32_t mappingPosition; - offset to UTrie (const uint8_t *mappingPosition). This is a serialized UTrie and should be treated as such. * Used as a primary lookup table for collation elements. * * uint32_t expansion; - offset to expansion table (uint32_t *expansion). This is an array of expansion CEs. Never 0. * * uint32_t contractionIndex; - offset to contraction table (UChar *contractionIndex). Used to look up contraction sequences. Contents * are aligned with the contents of contractionCEs table. 0 if no contractions. * * uint32_t contractionCEs; - offset to resulting contraction CEs (uint32_t *contractionCEs). When a contraction is resolved in the * in the contractionIndex table, the resulting index is used to look up corresponding CE in this table. * 0 if no contractions. * uint32_t contractionSize; - size of contraction table in elements (both Index and CEs). * * Tables described below are used for Boyer-Moore searching algorithm - they define the size of longest expansion * and last CEs in expansions. * uint32_t endExpansionCE; - offset to array of last collation element in expansion (uint32_t *). * Never 0. * uint32_t expansionCESize; - array of maximum expansion sizes (uint8_t *) * int32_t endExpansionCECount; - size of endExpansionCE. See UCOL_GETMAXEXPANSION * for the usage model * * These two offsets point to byte tables that are used in the backup heuristics. * uint32_t unsafeCP; - hash table of unsafe code points (uint8_t *). See ucol_unsafeCP function. * uint32_t contrEndCP; - hash table of final code points in contractions (uint8_t *). See ucol_contractionEndCP. * * int32_t contractionUCACombosSize; - number of UChar[contractionUCACombosWidth] in contractionUCACombos * (formatVersion 2.3) * UBool jamoSpecial; - Jamo special indicator (uint8_t). If TRUE, Jamos are special, so we cannot use simple Hangul decomposition. * UBool isBigEndian; - endianness of this collation binary (formatVersion 2.3) * uint8_t charSetFamily; - charset family of this collation binary (formatVersion 2.3) * uint8_t contractionUCACombosWidth; - number of UChars per UCA contraction in contractionUCACombos (formatVersion 2.3) * * Various version fields * UVersionInfo version; - version 4 uint8_t * UVersionInfo UCAVersion; - version 4 uint8_t * UVersionInfo UCDVersion; - version 4 uint8_t * UVersionInfo formatVersion; - version of the format of the collation binary * same formatVersion as in ucadata.icu's UDataInfo header * (formatVersion 2.3) * * uint32_t offset to the reordering code to lead CE byte remapping table * uint32_t offset to the lead CE byte to reordering code mapping table * * uint8_t reserved[76]; - currently unused * * ------------------------------------------------------------- * * Inverse UCA is used for constructing collators from rules. It is always an individual file * and always has a UDataInfo header. * here is the structure: * * uint32_t byteSize; - size of inverse UCA image in bytes * uint32_t tableSize; - length of inverse table (number of uint32_t[3] rows) * uint32_t contsSize; - size of continuation table (number of UChars in table) * * uint32_t table; - offset to inverse table (uint32_t *) * Inverse table contains of rows of 3 uint32_t values. First two values are CE and a possible continuation * the third value is either a code unit (if there is only one code unit for element) or an index to continuation * (number of code units combined with an index). * table. If more than one codepoint have the same CE, continuation table contains code units separated by FFFF and final * code unit sequence for a CE is terminated by FFFE. * uint32_t conts; - offset to continuation table (uint16_t *). Contains code units that transform to a same CE. * * UVersionInfo UCAVersion; - version of the UCA, read from file 4 uint8_t * uint8_t padding[8]; - padding 8 uint8_t * Header is followed by the table and continuation table. */ /* let us know whether reserved fields are reset to zero or junked */ #define UCOL_HEADER_MAGIC 0x20030618 /* UDataInfo for UCA mapping table */ /* dataFormat="UCol" */ #define UCA_DATA_FORMAT_0 ((uint8_t)0x55) #define UCA_DATA_FORMAT_1 ((uint8_t)0x43) #define UCA_DATA_FORMAT_2 ((uint8_t)0x6f) #define UCA_DATA_FORMAT_3 ((uint8_t)0x6c) #define UCA_FORMAT_VERSION_0 ((uint8_t)3) #define UCA_FORMAT_VERSION_1 ((uint8_t)0) #define UCA_FORMAT_VERSION_2 ((uint8_t)0) #define UCA_FORMAT_VERSION_3 ((uint8_t)0) /* UDataInfo for inverse UCA table */ /* dataFormat="InvC" */ #define INVUCA_DATA_FORMAT_0 ((uint8_t)0x49) #define INVUCA_DATA_FORMAT_1 ((uint8_t)0x6E) #define INVUCA_DATA_FORMAT_2 ((uint8_t)0x76) #define INVUCA_DATA_FORMAT_3 ((uint8_t)0x43) #define INVUCA_FORMAT_VERSION_0 ((uint8_t)2) #define INVUCA_FORMAT_VERSION_1 ((uint8_t)1) #define INVUCA_FORMAT_VERSION_2 ((uint8_t)0) #define INVUCA_FORMAT_VERSION_3 ((uint8_t)0) /* This is the size of the stack allocated buffer for sortkey generation and similar operations */ /* if it is too small, heap allocation will occur.*/ /* you can change this value if you need memory - it will affect the performance, though, since we're going to malloc */ #define UCOL_MAX_BUFFER 128 #define UCOL_PRIMARY_MAX_BUFFER 8*UCOL_MAX_BUFFER #define UCOL_SECONDARY_MAX_BUFFER UCOL_MAX_BUFFER #define UCOL_TERTIARY_MAX_BUFFER UCOL_MAX_BUFFER #define UCOL_CASE_MAX_BUFFER UCOL_MAX_BUFFER/4 #define UCOL_QUAD_MAX_BUFFER 2*UCOL_MAX_BUFFER #define UCOL_NORMALIZATION_GROWTH 2 #define UCOL_NORMALIZATION_MAX_BUFFER UCOL_MAX_BUFFER*UCOL_NORMALIZATION_GROWTH /* This writable buffer is used if we encounter Thai and need to reorder the string on the fly */ /* Sometimes we already have a writable buffer (like in case of normalized strings). */ /* you can change this value to any value >= 4 if you need memory - it will affect the performance, though, since we're going to malloc. Note 3 is the minimum value for Thai collation and 4 is the minimum number for special Jamo */ #define UCOL_WRITABLE_BUFFER_SIZE 256 /* This is the size of the buffer for expansion CE's */ /* In reality we should not have to deal with expm sequences longer then 16 */ /* you can change this value if you need memory */ /* WARNING THIS BUFFER DOES HAVE MALLOC FALLBACK. If you make it too small, you'll get into performance trouble */ /* Reasonable small value is around 10, if you don't do Arabic or other funky collations that have long expansion sequence */ /* This is the longest expansion sequence we can handle without bombing out */ #define UCOL_EXPAND_CE_BUFFER_SIZE 64 /* This is the size to increase the buffer for expansion CE's */ #define UCOL_EXPAND_CE_BUFFER_EXTEND_SIZE 64 /* Unsafe UChar hash table table size. */ /* size is 32 bytes for 1 bit for each latin 1 char + some power of two for */ /* hashing the rest of the chars. Size in bytes */ #define UCOL_UNSAFECP_TABLE_SIZE 1056 /* mask value down to "some power of two"-1 */ /* number of bits, not num of bytes. */ #define UCOL_UNSAFECP_TABLE_MASK 0x1fff /* flags bits for collIterate.flags */ /* */ /* NORM - set for incremental normalize of source string */ #define UCOL_ITER_NORM 1 #define UCOL_ITER_HASLEN 2 /* UCOL_ITER_INNORMBUF - set if the "pos" is in */ /* the writable side buffer, handling */ /* incrementally normalized characters. */ #define UCOL_ITER_INNORMBUF 4 /* UCOL_ITER_ALLOCATED - set if this iterator has */ /* malloced storage to expand a buffer. */ #define UCOL_ITER_ALLOCATED 8 /* UCOL_HIRAGANA_Q - note if the codepoint was hiragana */ #define UCOL_HIRAGANA_Q 16 /* UCOL_WAS_HIRAGANA - set to TRUE if there was a Hiragana */ /* otherwise set to false */ #define UCOL_WAS_HIRAGANA 32 /* UCOL_USE_ITERATOR - set this if collIterate uses a */ /* character iterator instead of simply accessing string */ /* by index */ #define UCOL_USE_ITERATOR 64 #define UCOL_FORCE_HAN_IMPLICIT 128 #define NFC_ZERO_CC_BLOCK_LIMIT_ 0x300 #ifdef XP_CPLUSPLUS U_NAMESPACE_BEGIN typedef struct collIterate : public UMemory { const UChar *string; /* Original string */ /* UChar *start; Pointer to the start of the source string. Either points to string or to writableBuffer */ const UChar *endp; /* string end ptr. Is undefined for null terminated strings */ const UChar *pos; /* This is position in the string. Can be to original or writable buf */ uint32_t *toReturn; /* This is the CE from CEs buffer that should be returned */ uint32_t *CEpos; /* This is the position to which we have stored processed CEs */ int32_t *offsetReturn; /* This is the offset to return, if non-NULL */ int32_t *offsetStore; /* This is the pointer for storing offsets */ int32_t offsetRepeatCount; /* Repeat stored offset if non-zero */ int32_t offsetRepeatValue; /* offset value to repeat */ UnicodeString writableBuffer; const UChar *fcdPosition; /* Position in the original string to continue FCD check from. */ const UCollator *coll; const Normalizer2 *nfd; uint8_t flags; uint8_t origFlags; uint32_t *extendCEs; /* This is use if CEs is not big enough */ int32_t extendCEsSize; /* Holds the size of the dynamic CEs buffer */ uint32_t CEs[UCOL_EXPAND_CE_BUFFER_SIZE]; /* This is where we store CEs */ int32_t *offsetBuffer; /* A dynamic buffer to hold offsets */ int32_t offsetBufferSize; /* The size of the offset buffer */ UCharIterator *iterator; /*int32_t iteratorIndex;*/ // The offsetBuffer should probably be a UVector32, but helper functions // are an improvement over duplicated code. void appendOffset(int32_t offset, UErrorCode &errorCode); } collIterate; U_NAMESPACE_END #else typedef struct collIterate collIterate; #endif #define paddedsize(something) ((something)+((((something)%4)!=0)?(4-(something)%4):0)) #define headersize (paddedsize(sizeof(UCATableHeader))+paddedsize(sizeof(UColOptionSet))) /* struct used internally in getSpecial*CE. data similar to collIterate. */ struct collIterateState { const UChar *pos; /* This is position in the string. Can be to original or writable buf */ const UChar *returnPos; const UChar *fcdPosition; /* Position in the original string to continue FCD check from. */ const UChar *bufferaddress; /* address of the normalization buffer */ int32_t buffersize; uint8_t flags; uint8_t origFlags; uint32_t iteratorIndex; int32_t iteratorMove; }; U_CAPI void U_EXPORT2 uprv_init_collIterate(const UCollator *collator, const UChar *sourceString, int32_t sourceLen, U_NAMESPACE_QUALIFIER collIterate *s, UErrorCode *status); /* Internal functions for C test code. */ U_CAPI U_NAMESPACE_QUALIFIER collIterate * U_EXPORT2 uprv_new_collIterate(UErrorCode *status); U_CAPI void U_EXPORT2 uprv_delete_collIterate(U_NAMESPACE_QUALIFIER collIterate *s); /* @return s->pos == s->endp */ U_CAPI UBool U_EXPORT2 uprv_collIterateAtEnd(U_NAMESPACE_QUALIFIER collIterate *s); #ifdef XP_CPLUSPLUS U_NAMESPACE_BEGIN struct UCollationPCE; typedef struct UCollationPCE UCollationPCE; U_NAMESPACE_END struct UCollationElements : public U_NAMESPACE_QUALIFIER UMemory { /** * Struct wrapper for source data */ U_NAMESPACE_QUALIFIER collIterate iteratordata_; /** * Indicates if this data has been reset. */ UBool reset_; /** * Indicates if the data should be deleted. */ UBool isWritable; /** * Data for getNextProcessed, getPreviousProcessed. */ U_NAMESPACE_QUALIFIER UCollationPCE *pce; }; #else /*opaque type*/ struct UCollationElements; #endif U_CAPI void U_EXPORT2 uprv_init_pce(const struct UCollationElements *elems); #define UCOL_LEVELTERMINATOR 1 /* mask off anything but primary order */ #define UCOL_PRIMARYORDERMASK 0xffff0000 /* mask off anything but secondary order */ #define UCOL_SECONDARYORDERMASK 0x0000ff00 /* mask off anything but tertiary order */ #define UCOL_TERTIARYORDERMASK 0x000000ff /* primary order shift */ #define UCOL_PRIMARYORDERSHIFT 16 /* secondary order shift */ #define UCOL_SECONDARYORDERSHIFT 8 #define UCOL_BYTE_SIZE_MASK 0xFF #define UCOL_CASE_BYTE_START 0x80 #define UCOL_CASE_SHIFT_START 7 #define UCOL_IGNORABLE 0 /* get weights from a CE */ #define UCOL_PRIMARYORDER(order) (((order) & UCOL_PRIMARYORDERMASK)>> UCOL_PRIMARYORDERSHIFT) #define UCOL_SECONDARYORDER(order) (((order) & UCOL_SECONDARYORDERMASK)>> UCOL_SECONDARYORDERSHIFT) #define UCOL_TERTIARYORDER(order) ((order) & UCOL_TERTIARYORDERMASK) /** * Determine if a character is a Thai vowel (which sorts after * its base consonant). */ #define UCOL_ISTHAIPREVOWEL(ch) ((((uint32_t)(ch) - 0xe40) <= (0xe44 - 0xe40)) || \ (((uint32_t)(ch) - 0xec0) <= (0xec4 - 0xec0))) /** * Determine if a character is a Thai base consonant */ #define UCOL_ISTHAIBASECONSONANT(ch) ((uint32_t)(ch) - 0xe01) <= (0xe2e - 0xe01) #define UCOL_ISJAMO(ch) ((((uint32_t)(ch) - 0x1100) <= (0x1112 - 0x1100)) || \ (((uint32_t)(ch) - 0x1161) <= (0x1175 - 0x1161)) || \ (((uint32_t)(ch) - 0x11A8) <= (0x11C2 - 0x11A8))) /* Han character ranges */ #define UCOL_FIRST_HAN 0x4E00 #define UCOL_LAST_HAN 0x9FFF #define UCOL_FIRST_HAN_A 0x3400 #define UCOL_LAST_HAN_A 0x4DBF #define UCOL_FIRST_HAN_COMPAT 0xFAE0 #define UCOL_LAST_HAN_COMPAT 0xFA2F /* Han extension B is in plane 2 */ #define UCOL_FIRST_HAN_B 0x20000 #define UCOL_LAST_HAN_B 0x2A6DF /* Hangul range */ #define UCOL_FIRST_HANGUL 0xAC00 #define UCOL_LAST_HANGUL 0xD7AF /* Jamo ranges */ #define UCOL_FIRST_L_JAMO 0x1100 #define UCOL_FIRST_V_JAMO 0x1161 #define UCOL_FIRST_T_JAMO 0x11A8 #define UCOL_LAST_T_JAMO 0x11F9 #if 0 /* initializes collIterate structure */ /* made as macro to speed up things */ #define init_collIterate(collator, sourceString, sourceLen, s) { \ (s)->start = (s)->string = (s)->pos = (UChar *)(sourceString); \ (s)->endp = (sourceLen) == -1 ? NULL :(UChar *)(sourceString)+(sourceLen); \ (s)->CEpos = (s)->toReturn = (s)->CEs; \ (s)->isThai = TRUE; \ (s)->writableBuffer = (s)->stackWritableBuffer; \ (s)->writableBufSize = UCOL_WRITABLE_BUFFER_SIZE; \ (s)->coll = (collator); \ (s)->fcdPosition = 0; \ (s)->flags = 0; \ if(((collator)->normalizationMode == UCOL_ON)) (s)->flags |= UCOL_ITER_NORM; \ } #endif /* * Macro to get the maximum size of an expansion ending with the argument ce. * Used in the Boyer Moore algorithm. * Note for tailoring, the UCA maxexpansion table has been merged. * Hence we only have to search the tailored collator only. * @param coll const UCollator pointer * @param order last collation element of the expansion sequence * @param result size of the longest expansion with argument collation element * as the last element */ #define UCOL_GETMAXEXPANSION(coll, order, result) { \ const uint32_t *start; \ const uint32_t *limit; \ const uint32_t *mid; \ start = (coll)->endExpansionCE; \ limit = (coll)->lastEndExpansionCE; \ while (start < limit - 1) { \ mid = start + ((limit - start) >> 1); \ if ((order) <= *mid) { \ limit = mid; \ } \ else { \ start = mid; \ } \ } \ if (*start == order) { \ result = *((coll)->expansionCESize + (start - (coll)->endExpansionCE)); \ } \ else if (*limit == order) { \ result = *(coll->expansionCESize + (limit - coll->endExpansionCE)); \ } \ else if ((order & 0xFFFF) == 0x00C0) { \ result = 2; \ } \ else { \ result = 1; \ } \ } U_CFUNC uint32_t ucol_prv_getSpecialCE(const UCollator *coll, UChar ch, uint32_t CE, U_NAMESPACE_QUALIFIER collIterate *source, UErrorCode *status); U_CFUNC uint32_t ucol_prv_getSpecialPrevCE(const UCollator *coll, UChar ch, uint32_t CE, U_NAMESPACE_QUALIFIER collIterate *source, UErrorCode *status); U_CAPI uint32_t U_EXPORT2 ucol_getNextCE(const UCollator *coll, U_NAMESPACE_QUALIFIER collIterate *collationSource, UErrorCode *status); U_CFUNC uint32_t U_EXPORT2 ucol_getPrevCE(const UCollator *coll, U_NAMESPACE_QUALIFIER collIterate *collationSource, UErrorCode *status); /* function used by C++ getCollationKey to prevent restarting the calculation */ U_CFUNC int32_t ucol_getSortKeyWithAllocation(const UCollator *coll, const UChar *source, int32_t sourceLength, uint8_t **pResult, UErrorCode *pErrorCode); /* get some memory */ void *ucol_getABuffer(const UCollator *coll, uint32_t size); /* worker function for generating sortkeys */ U_CFUNC int32_t U_CALLCONV ucol_calcSortKey(const UCollator *coll, const UChar *source, int32_t sourceLength, uint8_t **result, uint32_t resultLength, UBool allocatePrimary, UErrorCode *status); U_CFUNC int32_t U_CALLCONV ucol_calcSortKeySimpleTertiary(const UCollator *coll, const UChar *source, int32_t sourceLength, uint8_t **result, uint32_t resultLength, UBool allocatePrimary, UErrorCode *status); U_CFUNC int32_t ucol_getSortKeySize(const UCollator *coll, U_NAMESPACE_QUALIFIER collIterate *s, int32_t currentSize, UColAttributeValue strength, int32_t len); /** * Makes a copy of the Collator's rule data. The format is * that of .col files. * * @param length returns the length of the data, in bytes. * @param status the error status * @return memory, owned by the caller, of size 'length' bytes. * @internal INTERNAL USE ONLY */ U_CFUNC uint8_t* U_EXPORT2 ucol_cloneRuleData(const UCollator *coll, int32_t *length, UErrorCode *status); /** * Used to set requested and valid locales on a collator returned by the collator * service. */ U_CFUNC void U_EXPORT2 ucol_setReqValidLocales(UCollator *coll, char *requestedLocaleToAdopt, char *validLocaleToAdopt, char *actualLocaleToAdopt); #define UCOL_SPECIAL_FLAG 0xF0000000 #define UCOL_TAG_SHIFT 24 #define UCOL_TAG_MASK 0x0F000000 #define INIT_EXP_TABLE_SIZE 1024 #define UCOL_NOT_FOUND 0xF0000000 #define UCOL_EXPANSION 0xF1000000 #define UCOL_CONTRACTION 0xF2000000 #define UCOL_THAI 0xF3000000 #define UCOL_UNMARKED 0x03 #define UCOL_NEW_TERTIARYORDERMASK 0x0000003f /* Bit mask for primary collation strength. */ #define UCOL_PRIMARYMASK 0xFFFF0000 /* Bit mask for secondary collation strength. */ #define UCOL_SECONDARYMASK 0x0000FF00 /* Bit mask for tertiary collation strength. */ #define UCOL_TERTIARYMASK 0x000000FF /** * Internal. * This indicates the last element in a UCollationElements has been consumed. * Compare with the UCOL_NULLORDER, UCOL_NULLORDER is returned if error occurs. */ #define UCOL_NO_MORE_CES 0x00010101 #define UCOL_NO_MORE_CES_PRIMARY 0x00010000 #define UCOL_NO_MORE_CES_SECONDARY 0x00000100 #define UCOL_NO_MORE_CES_TERTIARY 0x00000001 #define isSpecial(CE) ((((CE)&UCOL_SPECIAL_FLAG)>>28)==0xF) #define UCOL_UPPER_CASE 0x80 #define UCOL_MIXED_CASE 0x40 #define UCOL_LOWER_CASE 0x00 #define UCOL_CONTINUATION_MARKER 0xC0 #define UCOL_REMOVE_CONTINUATION 0xFFFFFF3F #define isContinuation(CE) (((CE) & UCOL_CONTINUATION_MARKER) == UCOL_CONTINUATION_MARKER) #define isFlagged(CE) (((CE) & 0x80) == 0x80) #define isLongPrimary(CE) (((CE) & 0xC0) == 0xC0) #define getCETag(CE) (((CE)&UCOL_TAG_MASK)>>UCOL_TAG_SHIFT) #define isContraction(CE) (isSpecial((CE)) && (getCETag((CE)) == CONTRACTION_TAG)) #define isPrefix(CE) (isSpecial((CE)) && (getCETag((CE)) == SPEC_PROC_TAG)) #define constructContractCE(tag, CE) (UCOL_SPECIAL_FLAG | ((tag)<>4) #define getExpansionCount(CE) ((CE)&0xF) #define isCEIgnorable(CE) (((CE) & 0xFFFFFFBF) == 0) /* StringSearch internal use */ #define inNormBuf(coleiter) ((coleiter)->iteratordata_.flags & UCOL_ITER_INNORMBUF) #define isFCDPointerNull(coleiter) ((coleiter)->iteratordata_.fcdPosition == NULL) #define hasExpansion(coleiter) ((coleiter)->iteratordata_.CEpos != (coleiter)->iteratordata_.CEs) #define getExpansionPrefix(coleiter) ((coleiter)->iteratordata_.toReturn - (coleiter)->iteratordata_.CEs) #define setExpansionPrefix(coleiter, offset) ((coleiter)->iteratordata_.CEs + offset) #define getExpansionSuffix(coleiter) ((coleiter)->iteratordata_.CEpos - (coleiter)->iteratordata_.toReturn) #define setExpansionSuffix(coleiter, offset) ((coleiter)->iteratordata_.toReturn = (coleiter)->iteratordata_.CEpos - leftoverces) /* This is an enum that lists magic special byte values from the fractional UCA. * See also http://site.icu-project.org/design/collation/bytes */ /* TODO: all the #defines that refer to special byte values from the UCA should be changed to point here */ enum { UCOL_BYTE_ZERO = 0x00, UCOL_BYTE_LEVEL_SEPARATOR = 0x01, UCOL_BYTE_SORTKEY_GLUE = 0x02, UCOL_BYTE_SHIFT_PREFIX = 0x03, UCOL_BYTE_UNSHIFTED_MIN = UCOL_BYTE_SHIFT_PREFIX, UCOL_BYTE_FIRST_TAILORED = 0x04, UCOL_BYTE_COMMON = 0x05, UCOL_BYTE_FIRST_UCA = UCOL_BYTE_COMMON, /* TODO: Make the following values dynamic since they change with almost every UCA version. */ UCOL_CODAN_PLACEHOLDER = 0x12, UCOL_BYTE_FIRST_NON_LATIN_PRIMARY = 0x5B, UCOL_BYTE_UNSHIFTED_MAX = 0xFF }; #if 0 #define UCOL_RESET_TOP_VALUE 0x9F000303 #define UCOL_FIRST_PRIMARY_IGNORABLE 0x00008705 #define UCOL_LAST_PRIMARY_IGNORABLE 0x0000DD05 #define UCOL_LAST_PRIMARY_IGNORABLE_CONT 0x000051C0 #define UCOL_FIRST_SECONDARY_IGNORABLE 0x00000000 #define UCOL_LAST_SECONDARY_IGNORABLE 0x00000500 #define UCOL_FIRST_TERTIARY_IGNORABLE 0x00000000 #define UCOL_LAST_TERTIARY_IGNORABLE 0x00000000 #define UCOL_FIRST_VARIABLE 0x05070505 #define UCOL_LAST_VARIABLE 0x179B0505 #define UCOL_FIRST_NON_VARIABLE 0x1A200505 #define UCOL_LAST_NON_VARIABLE 0x7B41058F #define UCOL_NEXT_TOP_VALUE 0xE8960303 #define UCOL_NEXT_FIRST_PRIMARY_IGNORABLE 0x00008905 #define UCOL_NEXT_LAST_PRIMARY_IGNORABLE 0x03000303 #define UCOL_NEXT_FIRST_SECONDARY_IGNORABLE 0x00008705 #define UCOL_NEXT_LAST_SECONDARY_IGNORABLE 0x00000500 #define UCOL_NEXT_FIRST_TERTIARY_IGNORABLE 0x00000000 #define UCOL_NEXT_LAST_TERTIARY_IGNORABLE 0x00000000 #define UCOL_NEXT_FIRST_VARIABLE 0x05090505 #define UCOL_NEXT_LAST_VARIABLE 0x1A200505 #define PRIMARY_IMPLICIT_MIN 0xE8000000 #define PRIMARY_IMPLICIT_MAX 0xF0000000 #endif /* These constants can be changed - sortkey size is affected by them */ #define UCOL_PROPORTION2 0.5 #define UCOL_PROPORTION3 0.667 /* These values come from the UCA */ #define UCOL_COMMON_BOT2 UCOL_BYTE_COMMON #define UCOL_COMMON_TOP2 0x86u #define UCOL_TOTAL2 (UCOL_COMMON_TOP2-UCOL_COMMON_BOT2-1) #define UCOL_FLAG_BIT_MASK_CASE_SW_OFF 0x80 #define UCOL_FLAG_BIT_MASK_CASE_SW_ON 0x40 #define UCOL_COMMON_TOP3_CASE_SW_OFF 0x85 #define UCOL_COMMON_TOP3_CASE_SW_LOWER 0x45 #define UCOL_COMMON_TOP3_CASE_SW_UPPER 0xC5 /* These values come from the UCA */ #define UCOL_COMMON_BOT3 0x05 #define UCOL_COMMON_BOTTOM3_CASE_SW_UPPER 0x86; #define UCOL_COMMON_BOTTOM3_CASE_SW_LOWER UCOL_COMMON_BOT3; #define UCOL_TOP_COUNT2 (UCOL_PROPORTION2*UCOL_TOTAL2) #define UCOL_BOT_COUNT2 (UCOL_TOTAL2-UCOL_TOP_COUNT2) #define UCOL_COMMON2 UCOL_COMMON_BOT2 #define UCOL_COMMON3_UPPERFIRST 0xC5 #define UCOL_COMMON3_NORMAL UCOL_COMMON_BOT3 #define UCOL_COMMON4 0xFF /* constants for case level/case first handling */ /* used to instantiate UCollators fields in ucol_updateInternalState */ #define UCOL_CASE_SWITCH 0xC0 #define UCOL_NO_CASE_SWITCH 0x00 #define UCOL_REMOVE_CASE 0x3F #define UCOL_KEEP_CASE 0xFF #define UCOL_CASE_BIT_MASK 0xC0 #define UCOL_TERT_CASE_MASK 0xFF #define UCOL_ENDOFLATINONERANGE 0xFF #define UCOL_LATINONETABLELEN (UCOL_ENDOFLATINONERANGE+50) #define UCOL_BAIL_OUT_CE 0xFF000000 typedef enum { NOT_FOUND_TAG = 0, EXPANSION_TAG = 1, /* This code point results in an expansion */ CONTRACTION_TAG = 2, /* Start of a contraction */ THAI_TAG = 3, /* Thai character - do the reordering */ CHARSET_TAG = 4, /* Charset processing, not yet implemented */ SURROGATE_TAG = 5, /* Lead surrogate that is tailored and doesn't start a contraction */ HANGUL_SYLLABLE_TAG = 6, /* AC00-D7AF*/ LEAD_SURROGATE_TAG = 7, /* D800-DBFF*/ TRAIL_SURROGATE_TAG = 8, /* DC00-DFFF*/ CJK_IMPLICIT_TAG = 9, /* 0x3400-0x4DB5, 0x4E00-0x9FA5, 0xF900-0xFA2D*/ IMPLICIT_TAG = 10, SPEC_PROC_TAG = 11, /* ICU 2.1 */ LONG_PRIMARY_TAG = 12, /* This is a three byte primary with starting secondaries and tertiaries */ /* It fits in a single 32 bit CE and is used instead of expansion to save */ /* space without affecting the performance (hopefully) */ DIGIT_TAG = 13, /* COllate Digits As Numbers (CODAN) implementation */ CE_TAGS_COUNT } UColCETags; /* ***************************************************************************************** * set to zero * NON_CHARACTER FDD0 - FDEF, FFFE, FFFF, 1FFFE, 1FFFF, 2FFFE, 2FFFF,...e.g. **FFFE, **FFFF ****************************************************************************************** */ typedef struct { uint32_t variableTopValue; /*UColAttributeValue*/ int32_t frenchCollation; /*UColAttributeValue*/ int32_t alternateHandling; /* attribute for handling variable elements*/ /*UColAttributeValue*/ int32_t caseFirst; /* who goes first, lower case or uppercase */ /*UColAttributeValue*/ int32_t caseLevel; /* do we have an extra case level */ /*UColAttributeValue*/ int32_t normalizationMode; /* attribute for normalization */ /*UColAttributeValue*/ int32_t strength; /* attribute for strength */ /*UColAttributeValue*/ int32_t hiraganaQ; /* attribute for special Hiragana */ /*UColAttributeValue*/ int32_t numericCollation; /* attribute for numeric collation */ uint32_t reserved[15]; /* for future use */ } UColOptionSet; typedef struct { uint32_t UCA_FIRST_TERTIARY_IGNORABLE[2]; /*0x00000000*/ uint32_t UCA_LAST_TERTIARY_IGNORABLE[2]; /*0x00000000*/ uint32_t UCA_FIRST_PRIMARY_IGNORABLE[2]; /*0x00008705*/ uint32_t UCA_FIRST_SECONDARY_IGNORABLE[2]; /*0x00000000*/ uint32_t UCA_LAST_SECONDARY_IGNORABLE[2]; /*0x00000500*/ uint32_t UCA_LAST_PRIMARY_IGNORABLE[2]; /*0x0000DD05*/ uint32_t UCA_FIRST_VARIABLE[2]; /*0x05070505*/ uint32_t UCA_LAST_VARIABLE[2]; /*0x13CF0505*/ uint32_t UCA_FIRST_NON_VARIABLE[2]; /*0x16200505*/ uint32_t UCA_LAST_NON_VARIABLE[2]; /*0x767C0505*/ uint32_t UCA_RESET_TOP_VALUE[2]; /*0x9F000303*/ uint32_t UCA_FIRST_IMPLICIT[2]; uint32_t UCA_LAST_IMPLICIT[2]; uint32_t UCA_FIRST_TRAILING[2]; uint32_t UCA_LAST_TRAILING[2]; #if 0 uint32_t UCA_NEXT_TOP_VALUE[2]; /*0xE8960303*/ uint32_t UCA_NEXT_FIRST_PRIMARY_IGNORABLE; /*0x00008905*/ uint32_t UCA_NEXT_LAST_PRIMARY_IGNORABLE; /*0x03000303*/ uint32_t UCA_NEXT_FIRST_SECONDARY_IGNORABLE; /*0x00008705*/ uint32_t UCA_NEXT_LAST_SECONDARY_IGNORABLE; /*0x00000500*/ uint32_t UCA_NEXT_FIRST_TERTIARY_IGNORABLE; /*0x00000000*/ uint32_t UCA_NEXT_LAST_TERTIARY_IGNORABLE; /*0x00000000*/ uint32_t UCA_NEXT_FIRST_VARIABLE; /*0x05090505*/ uint32_t UCA_NEXT_LAST_VARIABLE; /*0x16200505*/ #endif uint32_t UCA_PRIMARY_TOP_MIN; uint32_t UCA_PRIMARY_IMPLICIT_MIN; /*0xE8000000*/ uint32_t UCA_PRIMARY_IMPLICIT_MAX; /*0xF0000000*/ uint32_t UCA_PRIMARY_TRAILING_MIN; /*0xE8000000*/ uint32_t UCA_PRIMARY_TRAILING_MAX; /*0xF0000000*/ uint32_t UCA_PRIMARY_SPECIAL_MIN; /*0xE8000000*/ uint32_t UCA_PRIMARY_SPECIAL_MAX; /*0xF0000000*/ } UCAConstants; typedef struct { int32_t size; /* all the offsets are in bytes */ /* to get the address add to the header address and cast properly */ uint32_t options; /* these are the default options for the collator */ uint32_t UCAConsts; /* structure which holds values for indirect positioning and implicit ranges */ uint32_t contractionUCACombos; /* this one is needed only for UCA, to copy the appropriate contractions */ uint32_t magic; /* magic number - lets us know whether reserved data is reset or junked */ uint32_t mappingPosition; /* const uint8_t *mappingPosition; */ uint32_t expansion; /* uint32_t *expansion; */ uint32_t contractionIndex; /* UChar *contractionIndex; */ uint32_t contractionCEs; /* uint32_t *contractionCEs; */ uint32_t contractionSize; /* needed for various closures */ /*int32_t latinOneMapping;*/ /* this is now handled in the trie itself *//* fast track to latin1 chars */ uint32_t endExpansionCE; /* array of last collation element in expansion */ uint32_t expansionCESize; /* array of maximum expansion size corresponding to the expansion collation elements with last element in endExpansionCE*/ int32_t endExpansionCECount; /* size of endExpansionCE */ uint32_t unsafeCP; /* hash table of unsafe code points */ uint32_t contrEndCP; /* hash table of final code points */ /* in contractions. */ int32_t contractionUCACombosSize; /* number of UCA contraction items. */ /*Length is contractionUCACombosSize*contractionUCACombosWidth*sizeof(UChar) */ UBool jamoSpecial; /* is jamoSpecial */ UBool isBigEndian; /* is this data big endian? from the UDataInfo header*/ uint8_t charSetFamily; /* what is the charset family of this data from the UDataInfo header*/ uint8_t contractionUCACombosWidth; /* width of UCA combos field */ UVersionInfo version; UVersionInfo UCAVersion; /* version of the UCA, read from file */ UVersionInfo UCDVersion; /* UCD version, obtained by u_getUnicodeVersion */ UVersionInfo formatVersion; /* format version from the UDataInfo header */ uint32_t scriptToLeadByte; /* offset to script to lead collation byte mapping data */ uint32_t leadByteToScript; /* offset to lead collation byte to script mapping data */ uint8_t reserved[76]; /* for future use */ } UCATableHeader; #define U_UNKNOWN_STATE 0 #define U_COLLATOR_STATE 0x01 #define U_STATE_LIMIT 0x02 /* This is the first structure in a state */ /* it should be machine independent */ typedef struct { /* this structure is supposed to be readable on all the platforms.*/ /* first 2 fields hold the size of the structure in a platform independent way */ uint8_t sizeLo; uint8_t sizeHi; /* identifying the writing platform */ uint8_t isBigEndian; /* see U_CHARSET_FAMILY values in utypes.h */ uint8_t charsetFamily; /* version of ICU this state structure comes from */ uint8_t icuVersion[4]; /* What is the data following this state */ uint8_t type; /* more stuff to come, keep it on 16 byte boundary */ uint8_t reserved[7]; } UStateStruct; /* This structure follows UStatusStruct */ /* and contains data specific for the collators */ /* Endianess needs to be decided before accessing this structure */ /* However, it's size IS endianess independent */ typedef struct { /* size of this structure */ uint8_t sizeLo; uint8_t sizeHi; /* This state is followed by the frozen tailoring */ uint8_t containsTailoring; /* This state is followed by the frozen UCA */ uint8_t containsUCA; /* Version info - the same one */ uint8_t versionInfo[4]; /* for charset CEs */ uint8_t charsetName[32]; /* this is the resolved locale name*/ uint8_t locale[32]; /* Attributes. Open ended */ /* all the following will be moved to uint32_t because of portability */ /* variable top value */ uint32_t variableTopValue; /* attribute for handling variable elements*/ uint32_t /*UColAttributeValue*/ alternateHandling; /* how to handle secondary weights */ uint32_t /*UColAttributeValue*/ frenchCollation; /* who goes first, lower case or uppercase */ uint32_t /*UColAttributeValue*/ caseFirst; /* do we have an extra case level */ uint32_t /*UColAttributeValue*/ caseLevel; /* attribute for normalization */ uint32_t /*UColAttributeValue*/ normalizationMode; /* attribute for strength */ uint32_t /*UColAttributeValue*/ strength; /* to be immediately 16 byte aligned */ uint8_t reserved[12]; } UColStateStruct; #define UCOL_INV_SIZEMASK 0xFFF00000 #define UCOL_INV_OFFSETMASK 0x000FFFFF #define UCOL_INV_SHIFTVALUE 20 U_CDECL_BEGIN typedef struct { uint32_t byteSize; uint32_t tableSize; uint32_t contsSize; uint32_t table; uint32_t conts; UVersionInfo UCAVersion; /* version of the UCA, read from file */ uint8_t padding[8]; } InverseUCATableHeader; typedef int32_t U_CALLCONV SortKeyGenerator(const UCollator *coll, const UChar *source, int32_t sourceLength, uint8_t **result, uint32_t resultLength, UBool allocatePrimary, UErrorCode *status); typedef void U_CALLCONV ResourceCleaner(UCollator *coll); struct UCollator { UColOptionSet *options; SortKeyGenerator *sortKeyGen; uint32_t *latinOneCEs; char* actualLocale; char* validLocale; char* requestedLocale; const UChar *rules; const UChar *ucaRules; const UCollator *UCA; const UCATableHeader *image; UTrie mapping; const uint32_t *latinOneMapping; const uint32_t *expansion; const UChar *contractionIndex; const uint32_t *contractionCEs; const uint32_t *endExpansionCE; /* array of last ces in an expansion ce. corresponds to expansionCESize */ const uint32_t *lastEndExpansionCE;/* pointer to the last element in endExpansionCE */ const uint8_t *expansionCESize; /* array of the maximum size of a expansion ce with the last ce corresponding to endExpansionCE, terminated with a null */ const uint8_t *unsafeCP; /* unsafe code points hashtable */ const uint8_t *contrEndCP; /* Contraction ending chars hash table */ UChar minUnsafeCP; /* Smallest unsafe Code Point. */ UChar minContrEndCP; /* Smallest code point at end of a contraction */ int32_t rulesLength; int32_t latinOneTableLen; uint32_t variableTopValue; UColAttributeValue frenchCollation; UColAttributeValue alternateHandling; /* attribute for handling variable elements*/ UColAttributeValue caseFirst; /* who goes first, lower case or uppercase */ UColAttributeValue caseLevel; /* do we have an extra case level */ UColAttributeValue normalizationMode; /* attribute for normalization */ UColAttributeValue strength; /* attribute for strength */ UColAttributeValue hiraganaQ; /* attribute for Hiragana */ UColAttributeValue numericCollation; UBool variableTopValueisDefault; UBool frenchCollationisDefault; UBool alternateHandlingisDefault; /* attribute for handling variable elements*/ UBool caseFirstisDefault; /* who goes first, lower case or uppercase */ UBool caseLevelisDefault; /* do we have an extra case level */ UBool normalizationModeisDefault; /* attribute for normalization */ UBool strengthisDefault; /* attribute for strength */ UBool hiraganaQisDefault; /* attribute for Hiragana */ UBool numericCollationisDefault; UBool hasRealData; /* some collators have only options, like French, no rules */ /* to speed up things, we use the UCA image, but we don't want it */ /* to run around */ UBool freeOnClose; UBool freeOptionsOnClose; UBool freeRulesOnClose; UBool freeImageOnClose; UBool latinOneUse; UBool latinOneRegenTable; UBool latinOneFailed; int8_t tertiaryAddition; /* when switching case, we need to add or subtract different values */ uint8_t caseSwitch; uint8_t tertiaryCommon; uint8_t tertiaryMask; uint8_t tertiaryTop; /* Upper range when compressing */ uint8_t tertiaryBottom; /* Upper range when compressing */ uint8_t tertiaryTopCount; uint8_t tertiaryBottomCount; UVersionInfo dataVersion; /* Data info of UCA table */ int32_t* reorderCodes; int32_t reorderCodesLength; uint8_t* leadBytePermutationTable; }; U_CDECL_END /* various internal functions */ /* do not close UCA returned by ucol_initUCA! */ U_CFUNC UCollator* ucol_initUCA(UErrorCode *status); U_CFUNC UCollator* ucol_initCollator(const UCATableHeader *image, UCollator *fillIn, const UCollator *UCA, UErrorCode *status); U_CFUNC void ucol_setOptionsFromHeader(UCollator* result, UColOptionSet * opts, UErrorCode *status); U_CFUNC UCollator* ucol_open_internal(const char* loc, UErrorCode* status); #if 0 U_CFUNC void ucol_putOptionsToHeader(UCollator* result, UColOptionSet * opts, UErrorCode *status); #endif U_CFUNC void ucol_updateInternalState(UCollator *coll, UErrorCode *status); U_CFUNC uint32_t U_EXPORT2 ucol_getFirstCE(const UCollator *coll, UChar u, UErrorCode *status); U_CAPI UBool U_EXPORT2 ucol_isTailored(const UCollator *coll, const UChar u, UErrorCode *status); U_CAPI const InverseUCATableHeader* U_EXPORT2 ucol_initInverseUCA(UErrorCode *status); U_CAPI void U_EXPORT2 uprv_uca_initImplicitConstants(UErrorCode *status); U_CAPI uint32_t U_EXPORT2 uprv_uca_getImplicitFromRaw(UChar32 cp); /*U_CFUNC uint32_t U_EXPORT2 uprv_uca_getImplicitPrimary(UChar32 cp);*/ U_CAPI UChar32 U_EXPORT2 uprv_uca_getRawFromImplicit(uint32_t implicit); U_CAPI UChar32 U_EXPORT2 uprv_uca_getRawFromCodePoint(UChar32 i); U_CAPI UChar32 U_EXPORT2 uprv_uca_getCodePointFromRaw(UChar32 i); typedef const UChar* GetCollationRulesFunction(void* context, const char* locale, const char* type, int32_t* pLength, UErrorCode* status); U_CAPI UCollator* U_EXPORT2 ucol_openRulesForImport( const UChar *rules, int32_t rulesLength, UColAttributeValue normalizationMode, UCollationStrength strength, UParseError *parseError, GetCollationRulesFunction importFunc, void* context, UErrorCode *status); U_CAPI void U_EXPORT2 ucol_buildPermutationTable(UCollator *coll, UErrorCode *status); #ifdef XP_CPLUSPLUS /* * Test whether a character is potentially "unsafe" for use as a collation * starting point. Unsafe chars are those with combining class != 0 plus * those that are the 2nd thru nth character in a contraction sequence. * * Function is in header file because it's used in both collation and string search, * and needs to be inline for performance. */ static inline UBool ucol_unsafeCP(UChar c, const UCollator *coll) { int32_t hash; uint8_t htbyte; if (c < coll->minUnsafeCP) { return FALSE; } hash = c; if (hash >= UCOL_UNSAFECP_TABLE_SIZE*8) { if(UTF_IS_SURROGATE(c)) { /* Lead or trail surrogate */ /* These are always considered unsafe. */ return TRUE; } hash = (hash & UCOL_UNSAFECP_TABLE_MASK) + 256; } htbyte = coll->unsafeCP[hash>>3]; return ((htbyte >> (hash & 7)) & 1); } #endif /* XP_CPLUSPLUS */ /* The offsetBuffer in collIterate might need to be freed to avoid memory leaks. */ void ucol_freeOffsetBuffer(U_NAMESPACE_QUALIFIER collIterate *s); #endif /* #if !UCONFIG_NO_COLLATION */ #endif