/* ****************************************************************************** * Copyright (C) 2001-20109, International Business Machines * Corporation and others. All Rights Reserved. ****************************************************************************** * * File ucoleitr.cpp * * Modification History: * * Date Name Description * 02/15/2001 synwee Modified all methods to process its own function * instead of calling the equivalent c++ api (coleitr.h) ******************************************************************************/ #include "unicode/utypes.h" #if !UCONFIG_NO_COLLATION #include "unicode/ucoleitr.h" #include "unicode/ustring.h" #include "unicode/sortkey.h" #include "unicode/uobject.h" #include "ucol_imp.h" #include "cmemory.h" U_NAMESPACE_USE #define BUFFER_LENGTH 100 #define DEFAULT_BUFFER_SIZE 16 #define BUFFER_GROW 8 #define ARRAY_SIZE(array) (sizeof array / sizeof array[0]) #define ARRAY_COPY(dst, src, count) uprv_memcpy((void *) (dst), (void *) (src), (count) * sizeof (src)[0]) #define NEW_ARRAY(type, count) (type *) uprv_malloc((count) * sizeof(type)) #define GROW_ARRAY(array, newSize) uprv_realloc((void *) (array), (newSize) * sizeof (array)[0]) #define DELETE_ARRAY(array) uprv_free((void *) (array)) typedef struct collIterate collIterator; struct RCEI { uint32_t ce; int32_t low; int32_t high; }; U_NAMESPACE_BEGIN struct RCEBuffer { RCEI defaultBuffer[DEFAULT_BUFFER_SIZE]; RCEI *buffer; int32_t bufferIndex; int32_t bufferSize; RCEBuffer(); ~RCEBuffer(); UBool empty() const; void put(uint32_t ce, int32_t ixLow, int32_t ixHigh); const RCEI *get(); }; RCEBuffer::RCEBuffer() { buffer = defaultBuffer; bufferIndex = 0; bufferSize = DEFAULT_BUFFER_SIZE; } RCEBuffer::~RCEBuffer() { if (buffer != defaultBuffer) { DELETE_ARRAY(buffer); } } UBool RCEBuffer::empty() const { return bufferIndex <= 0; } void RCEBuffer::put(uint32_t ce, int32_t ixLow, int32_t ixHigh) { if (bufferIndex >= bufferSize) { RCEI *newBuffer = NEW_ARRAY(RCEI, bufferSize + BUFFER_GROW); ARRAY_COPY(newBuffer, buffer, bufferSize); if (buffer != defaultBuffer) { DELETE_ARRAY(buffer); } buffer = newBuffer; bufferSize += BUFFER_GROW; } buffer[bufferIndex].ce = ce; buffer[bufferIndex].low = ixLow; buffer[bufferIndex].high = ixHigh; bufferIndex += 1; } const RCEI *RCEBuffer::get() { if (bufferIndex > 0) { return &buffer[--bufferIndex]; } return NULL; } struct PCEI { uint64_t ce; int32_t low; int32_t high; }; struct PCEBuffer { PCEI defaultBuffer[DEFAULT_BUFFER_SIZE]; PCEI *buffer; int32_t bufferIndex; int32_t bufferSize; PCEBuffer(); ~PCEBuffer(); void reset(); UBool empty() const; void put(uint64_t ce, int32_t ixLow, int32_t ixHigh); const PCEI *get(); }; PCEBuffer::PCEBuffer() { buffer = defaultBuffer; bufferIndex = 0; bufferSize = DEFAULT_BUFFER_SIZE; } PCEBuffer::~PCEBuffer() { if (buffer != defaultBuffer) { DELETE_ARRAY(buffer); } } void PCEBuffer::reset() { bufferIndex = 0; } UBool PCEBuffer::empty() const { return bufferIndex <= 0; } void PCEBuffer::put(uint64_t ce, int32_t ixLow, int32_t ixHigh) { if (bufferIndex >= bufferSize) { PCEI *newBuffer = NEW_ARRAY(PCEI, bufferSize + BUFFER_GROW); ARRAY_COPY(newBuffer, buffer, bufferSize); if (buffer != defaultBuffer) { DELETE_ARRAY(buffer); } buffer = newBuffer; bufferSize += BUFFER_GROW; } buffer[bufferIndex].ce = ce; buffer[bufferIndex].low = ixLow; buffer[bufferIndex].high = ixHigh; bufferIndex += 1; } const PCEI *PCEBuffer::get() { if (bufferIndex > 0) { return &buffer[--bufferIndex]; } return NULL; } /* * This inherits from UObject so that * it can be allocated by new and the * constructor for PCEBuffer is called. */ struct UCollationPCE : public UObject { PCEBuffer pceBuffer; UCollationStrength strength; UBool toShift; UBool isShifted; uint32_t variableTop; UCollationPCE(UCollationElements *elems); ~UCollationPCE(); void init(const UCollator *coll); virtual UClassID getDynamicClassID() const; static UClassID getStaticClassID(); }; UOBJECT_DEFINE_RTTI_IMPLEMENTATION(UCollationPCE) UCollationPCE::UCollationPCE(UCollationElements *elems) { init(elems->iteratordata_.coll); } void UCollationPCE::init(const UCollator *coll) { UErrorCode status = U_ZERO_ERROR; strength = ucol_getStrength(coll); toShift = ucol_getAttribute(coll, UCOL_ALTERNATE_HANDLING, &status) == UCOL_SHIFTED; isShifted = FALSE; variableTop = coll->variableTopValue << 16; } UCollationPCE::~UCollationPCE() { // nothing to do } U_NAMESPACE_END inline uint64_t processCE(UCollationElements *elems, uint32_t ce) { uint64_t primary = 0, secondary = 0, tertiary = 0, quaternary = 0; // This is clean, but somewhat slow... // We could apply the mask to ce and then // just get all three orders... switch(elems->pce->strength) { default: tertiary = ucol_tertiaryOrder(ce); /* note fall-through */ case UCOL_SECONDARY: secondary = ucol_secondaryOrder(ce); /* note fall-through */ case UCOL_PRIMARY: primary = ucol_primaryOrder(ce); } // **** This should probably handle continuations too. **** // **** That means that we need 24 bits for the primary **** // **** instead of the 16 that we're currently using. **** // **** So we can lay out the 64 bits as: 24.12.12.16. **** // **** Another complication with continuations is that **** // **** the *second* CE is marked as a continuation, so **** // **** we always have to peek ahead to know how long **** // **** the primary is... **** if (elems->pce->toShift && (elems->pce->variableTop > ce && primary != 0) || (elems->pce->isShifted && primary == 0)) { if (primary == 0) { return UCOL_IGNORABLE; } if (elems->pce->strength >= UCOL_QUATERNARY) { quaternary = primary; } primary = secondary = tertiary = 0; elems->pce->isShifted = TRUE; } else { if (elems->pce->strength >= UCOL_QUATERNARY) { quaternary = 0xFFFF; } elems->pce->isShifted = FALSE; } return primary << 48 | secondary << 32 | tertiary << 16 | quaternary; } U_CAPI void U_EXPORT2 uprv_init_pce(const UCollationElements *elems) { if (elems->pce != NULL) { elems->pce->init(elems->iteratordata_.coll); } } /* public methods ---------------------------------------------------- */ U_CAPI UCollationElements* U_EXPORT2 ucol_openElements(const UCollator *coll, const UChar *text, int32_t textLength, UErrorCode *status) { if (U_FAILURE(*status)) { return NULL; } UCollationElements *result = new UCollationElements; if (result == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return NULL; } result->reset_ = TRUE; result->isWritable = FALSE; result->pce = NULL; if (text == NULL) { textLength = 0; } uprv_init_collIterate(coll, text, textLength, &result->iteratordata_, status); return result; } U_CAPI void U_EXPORT2 ucol_closeElements(UCollationElements *elems) { if (elems != NULL) { collIterate *ci = &elems->iteratordata_; if (ci->extendCEs) { uprv_free(ci->extendCEs); } if (ci->offsetBuffer) { uprv_free(ci->offsetBuffer); } if (elems->isWritable && elems->iteratordata_.string != NULL) { uprv_free((UChar *)elems->iteratordata_.string); } if (elems->pce != NULL) { delete elems->pce; } delete elems; } } U_CAPI void U_EXPORT2 ucol_reset(UCollationElements *elems) { collIterate *ci = &(elems->iteratordata_); elems->reset_ = TRUE; ci->pos = ci->string; if ((ci->flags & UCOL_ITER_HASLEN) == 0 || ci->endp == NULL) { ci->endp = ci->string + u_strlen(ci->string); } ci->CEpos = ci->toReturn = ci->CEs; ci->flags = (ci->flags & UCOL_FORCE_HAN_IMPLICIT) | UCOL_ITER_HASLEN; if (ci->coll->normalizationMode == UCOL_ON) { ci->flags |= UCOL_ITER_NORM; } ci->writableBuffer.remove(); ci->fcdPosition = NULL; //ci->offsetReturn = ci->offsetStore = NULL; ci->offsetRepeatCount = ci->offsetRepeatValue = 0; } U_CAPI void U_EXPORT2 ucol_forceHanImplicit(UCollationElements *elems, UErrorCode *status) { if (U_FAILURE(*status)) { return; } if (elems == NULL) { *status = U_ILLEGAL_ARGUMENT_ERROR; return; } elems->iteratordata_.flags |= UCOL_FORCE_HAN_IMPLICIT; } U_CAPI int32_t U_EXPORT2 ucol_next(UCollationElements *elems, UErrorCode *status) { int32_t result; if (U_FAILURE(*status)) { return UCOL_NULLORDER; } elems->reset_ = FALSE; result = (int32_t)ucol_getNextCE(elems->iteratordata_.coll, &elems->iteratordata_, status); if (result == UCOL_NO_MORE_CES) { result = UCOL_NULLORDER; } return result; } U_CAPI int64_t U_EXPORT2 ucol_nextProcessed(UCollationElements *elems, int32_t *ixLow, int32_t *ixHigh, UErrorCode *status) { const UCollator *coll = elems->iteratordata_.coll; int64_t result = UCOL_IGNORABLE; uint32_t low = 0, high = 0; if (U_FAILURE(*status)) { return UCOL_PROCESSED_NULLORDER; } if (elems->pce == NULL) { elems->pce = new UCollationPCE(elems); } else { elems->pce->pceBuffer.reset(); } elems->reset_ = FALSE; do { low = ucol_getOffset(elems); uint32_t ce = (uint32_t) ucol_getNextCE(coll, &elems->iteratordata_, status); high = ucol_getOffset(elems); if (ce == UCOL_NO_MORE_CES) { result = UCOL_PROCESSED_NULLORDER; break; } result = processCE(elems, ce); } while (result == UCOL_IGNORABLE); if (ixLow != NULL) { *ixLow = low; } if (ixHigh != NULL) { *ixHigh = high; } return result; } U_CAPI int32_t U_EXPORT2 ucol_previous(UCollationElements *elems, UErrorCode *status) { if(U_FAILURE(*status)) { return UCOL_NULLORDER; } else { int32_t result; if (elems->reset_ && (elems->iteratordata_.pos == elems->iteratordata_.string)) { if (elems->iteratordata_.endp == NULL) { elems->iteratordata_.endp = elems->iteratordata_.string + u_strlen(elems->iteratordata_.string); elems->iteratordata_.flags |= UCOL_ITER_HASLEN; } elems->iteratordata_.pos = elems->iteratordata_.endp; elems->iteratordata_.fcdPosition = elems->iteratordata_.endp; } elems->reset_ = FALSE; result = (int32_t)ucol_getPrevCE(elems->iteratordata_.coll, &(elems->iteratordata_), status); if (result == UCOL_NO_MORE_CES) { result = UCOL_NULLORDER; } return result; } } U_CAPI int64_t U_EXPORT2 ucol_previousProcessed(UCollationElements *elems, int32_t *ixLow, int32_t *ixHigh, UErrorCode *status) { const UCollator *coll = elems->iteratordata_.coll; int64_t result = UCOL_IGNORABLE; // int64_t primary = 0, secondary = 0, tertiary = 0, quaternary = 0; // UCollationStrength strength = ucol_getStrength(coll); // UBool toShift = ucol_getAttribute(coll, UCOL_ALTERNATE_HANDLING, status) == UCOL_SHIFTED; // uint32_t variableTop = coll->variableTopValue; int32_t low = 0, high = 0; if (U_FAILURE(*status)) { return UCOL_PROCESSED_NULLORDER; } if (elems->reset_ && (elems->iteratordata_.pos == elems->iteratordata_.string)) { if (elems->iteratordata_.endp == NULL) { elems->iteratordata_.endp = elems->iteratordata_.string + u_strlen(elems->iteratordata_.string); elems->iteratordata_.flags |= UCOL_ITER_HASLEN; } elems->iteratordata_.pos = elems->iteratordata_.endp; elems->iteratordata_.fcdPosition = elems->iteratordata_.endp; } if (elems->pce == NULL) { elems->pce = new UCollationPCE(elems); } else { //elems->pce->pceBuffer.reset(); } elems->reset_ = FALSE; while (elems->pce->pceBuffer.empty()) { // buffer raw CEs up to non-ignorable primary RCEBuffer rceb; uint32_t ce; // **** do we need to reset rceb, or will it always be empty at this point **** do { high = ucol_getOffset(elems); ce = ucol_getPrevCE(coll, &elems->iteratordata_, status); low = ucol_getOffset(elems); if (ce == UCOL_NO_MORE_CES) { if (! rceb.empty()) { break; } goto finish; } rceb.put(ce, low, high); } while ((ce & UCOL_PRIMARYMASK) == 0); // process the raw CEs while (! rceb.empty()) { const RCEI *rcei = rceb.get(); result = processCE(elems, rcei->ce); if (result != UCOL_IGNORABLE) { elems->pce->pceBuffer.put(result, rcei->low, rcei->high); } } } finish: if (elems->pce->pceBuffer.empty()) { // **** Is -1 the right value for ixLow, ixHigh? **** if (ixLow != NULL) { *ixLow = -1; } if (ixHigh != NULL) { *ixHigh = -1 ; } return UCOL_PROCESSED_NULLORDER; } const PCEI *pcei = elems->pce->pceBuffer.get(); if (ixLow != NULL) { *ixLow = pcei->low; } if (ixHigh != NULL) { *ixHigh = pcei->high; } return pcei->ce; } U_CAPI int32_t U_EXPORT2 ucol_getMaxExpansion(const UCollationElements *elems, int32_t order) { uint8_t result; #if 0 UCOL_GETMAXEXPANSION(elems->iteratordata_.coll, (uint32_t)order, result); #else const UCollator *coll = elems->iteratordata_.coll; const uint32_t *start; const uint32_t *limit; const uint32_t *mid; uint32_t strengthMask = 0; uint32_t mOrder = (uint32_t) order; switch (coll->strength) { default: strengthMask |= UCOL_TERTIARYORDERMASK; /* fall through */ case UCOL_SECONDARY: strengthMask |= UCOL_SECONDARYORDERMASK; /* fall through */ case UCOL_PRIMARY: strengthMask |= UCOL_PRIMARYORDERMASK; } mOrder &= strengthMask; start = (coll)->endExpansionCE; limit = (coll)->lastEndExpansionCE; while (start < limit - 1) { mid = start + ((limit - start) >> 1); if (mOrder <= (*mid & strengthMask)) { limit = mid; } else { start = mid; } } // FIXME: with a masked search, there might be more than one hit, // so we need to look forward and backward from the match to find all // of the hits... if ((*start & strengthMask) == mOrder) { result = *((coll)->expansionCESize + (start - (coll)->endExpansionCE)); } else if ((*limit & strengthMask) == mOrder) { result = *(coll->expansionCESize + (limit - coll->endExpansionCE)); } else if ((mOrder & 0xFFFF) == 0x00C0) { result = 2; } else { result = 1; } #endif return result; } U_CAPI void U_EXPORT2 ucol_setText( UCollationElements *elems, const UChar *text, int32_t textLength, UErrorCode *status) { if (U_FAILURE(*status)) { return; } if (elems->isWritable && elems->iteratordata_.string != NULL) { uprv_free((UChar *)elems->iteratordata_.string); } if (text == NULL) { textLength = 0; } elems->isWritable = FALSE; /* free offset buffer to avoid memory leak before initializing. */ ucol_freeOffsetBuffer(&(elems->iteratordata_)); uprv_init_collIterate(elems->iteratordata_.coll, text, textLength, &elems->iteratordata_, status); elems->reset_ = TRUE; } U_CAPI int32_t U_EXPORT2 ucol_getOffset(const UCollationElements *elems) { const collIterate *ci = &(elems->iteratordata_); if (ci->offsetRepeatCount > 0 && ci->offsetRepeatValue != 0) { return ci->offsetRepeatValue; } if (ci->offsetReturn != NULL) { return *ci->offsetReturn; } // while processing characters in normalization buffer getOffset will // return the next non-normalized character. // should be inline with the old implementation since the old codes uses // nextDecomp in normalizer which also decomposes the string till the // first base character is found. if (ci->flags & UCOL_ITER_INNORMBUF) { if (ci->fcdPosition == NULL) { return 0; } return (int32_t)(ci->fcdPosition - ci->string); } else { return (int32_t)(ci->pos - ci->string); } } U_CAPI void U_EXPORT2 ucol_setOffset(UCollationElements *elems, int32_t offset, UErrorCode *status) { if (U_FAILURE(*status)) { return; } // this methods will clean up any use of the writable buffer and points to // the original string collIterate *ci = &(elems->iteratordata_); ci->pos = ci->string + offset; ci->CEpos = ci->toReturn = ci->CEs; if (ci->flags & UCOL_ITER_INNORMBUF) { ci->flags = ci->origFlags; } if ((ci->flags & UCOL_ITER_HASLEN) == 0) { ci->endp = ci->string + u_strlen(ci->string); ci->flags |= UCOL_ITER_HASLEN; } ci->fcdPosition = NULL; elems->reset_ = FALSE; ci->offsetReturn = NULL; ci->offsetStore = ci->offsetBuffer; ci->offsetRepeatCount = ci->offsetRepeatValue = 0; } U_CAPI int32_t U_EXPORT2 ucol_primaryOrder (int32_t order) { order &= UCOL_PRIMARYMASK; return (order >> UCOL_PRIMARYORDERSHIFT); } U_CAPI int32_t U_EXPORT2 ucol_secondaryOrder (int32_t order) { order &= UCOL_SECONDARYMASK; return (order >> UCOL_SECONDARYORDERSHIFT); } U_CAPI int32_t U_EXPORT2 ucol_tertiaryOrder (int32_t order) { return (order & UCOL_TERTIARYMASK); } void ucol_freeOffsetBuffer(collIterate *s) { if (s != NULL && s->offsetBuffer != NULL) { uprv_free(s->offsetBuffer); s->offsetBuffer = NULL; s->offsetBufferSize = 0; } } #endif /* #if !UCONFIG_NO_COLLATION */