// © 2016 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html /* ******************************************************************************* * Copyright (C) 2009-2014, International Business Machines Corporation and * others. All Rights Reserved. ******************************************************************************* */ #include "unicode/utypes.h" #if !UCONFIG_NO_COLLATION #include "unicode/alphaindex.h" #include "unicode/coll.h" #include "unicode/localpointer.h" #include "unicode/normalizer2.h" #include "unicode/tblcoll.h" #include "unicode/uchar.h" #include "unicode/ulocdata.h" #include "unicode/uniset.h" #include "unicode/uobject.h" #include "unicode/usetiter.h" #include "unicode/utf16.h" #include "cmemory.h" #include "cstring.h" #include "uassert.h" #include "uvector.h" #include "uvectr64.h" //#include //#include U_NAMESPACE_BEGIN namespace { /** * Prefix string for Chinese index buckets. * See http://unicode.org/repos/cldr/trunk/specs/ldml/tr35-collation.html#Collation_Indexes */ const UChar BASE[1] = { 0xFDD0 }; const int32_t BASE_LENGTH = 1; UBool isOneLabelBetterThanOther(const Normalizer2 &nfkdNormalizer, const UnicodeString &one, const UnicodeString &other); } // namespace static int32_t U_CALLCONV collatorComparator(const void *context, const void *left, const void *right); static int32_t U_CALLCONV recordCompareFn(const void *context, const void *left, const void *right); // UVector support function, delete a Record. static void U_CALLCONV alphaIndex_deleteRecord(void *obj) { delete static_cast(obj); } namespace { UnicodeString *ownedString(const UnicodeString &s, LocalPointer &owned, UErrorCode &errorCode) { if (U_FAILURE(errorCode)) { return NULL; } if (owned.isValid()) { return owned.orphan(); } UnicodeString *p = new UnicodeString(s); if (p == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; } return p; } inline UnicodeString *getString(const UVector &list, int32_t i) { return static_cast(list[i]); } inline AlphabeticIndex::Bucket *getBucket(const UVector &list, int32_t i) { return static_cast(list[i]); } inline AlphabeticIndex::Record *getRecord(const UVector &list, int32_t i) { return static_cast(list[i]); } /** * Like Java Collections.binarySearch(List, String, Comparator). * * @return the index>=0 where the item was found, * or the index<0 for inserting the string at ~index in sorted order */ int32_t binarySearch(const UVector &list, const UnicodeString &s, const Collator &coll) { if (list.size() == 0) { return ~0; } int32_t start = 0; int32_t limit = list.size(); for (;;) { int32_t i = (start + limit) / 2; const UnicodeString *si = static_cast(list.elementAt(i)); UErrorCode errorCode = U_ZERO_ERROR; UCollationResult cmp = coll.compare(s, *si, errorCode); if (cmp == UCOL_EQUAL) { return i; } else if (cmp < 0) { if (i == start) { return ~start; // insert s before *si } limit = i; } else { if (i == start) { return ~(start + 1); // insert s after *si } start = i; } } } } // namespace // The BucketList is not in the anonymous namespace because only Clang // seems to support its use in other classes from there. // However, we also don't need U_I18N_API because it is not used from outside the i18n library. class BucketList : public UObject { public: BucketList(UVector *bucketList, UVector *publicBucketList) : bucketList_(bucketList), immutableVisibleList_(publicBucketList) { int32_t displayIndex = 0; for (int32_t i = 0; i < publicBucketList->size(); ++i) { getBucket(*publicBucketList, i)->displayIndex_ = displayIndex++; } } // The virtual destructor must not be inline. // See ticket #8454 for details. virtual ~BucketList(); int32_t getBucketCount() const { return immutableVisibleList_->size(); } int32_t getBucketIndex(const UnicodeString &name, const Collator &collatorPrimaryOnly, UErrorCode &errorCode) { // binary search int32_t start = 0; int32_t limit = bucketList_->size(); while ((start + 1) < limit) { int32_t i = (start + limit) / 2; const AlphabeticIndex::Bucket *bucket = getBucket(*bucketList_, i); UCollationResult nameVsBucket = collatorPrimaryOnly.compare(name, bucket->lowerBoundary_, errorCode); if (nameVsBucket < 0) { limit = i; } else { start = i; } } const AlphabeticIndex::Bucket *bucket = getBucket(*bucketList_, start); if (bucket->displayBucket_ != NULL) { bucket = bucket->displayBucket_; } return bucket->displayIndex_; } /** All of the buckets, visible and invisible. */ UVector *bucketList_; /** Just the visible buckets. */ UVector *immutableVisibleList_; }; BucketList::~BucketList() { delete bucketList_; if (immutableVisibleList_ != bucketList_) { delete immutableVisibleList_; } } AlphabeticIndex::ImmutableIndex::~ImmutableIndex() { delete buckets_; delete collatorPrimaryOnly_; } int32_t AlphabeticIndex::ImmutableIndex::getBucketCount() const { return buckets_->getBucketCount(); } int32_t AlphabeticIndex::ImmutableIndex::getBucketIndex( const UnicodeString &name, UErrorCode &errorCode) const { return buckets_->getBucketIndex(name, *collatorPrimaryOnly_, errorCode); } const AlphabeticIndex::Bucket * AlphabeticIndex::ImmutableIndex::getBucket(int32_t index) const { if (0 <= index && index < buckets_->getBucketCount()) { return icu::getBucket(*buckets_->immutableVisibleList_, index); } else { return NULL; } } AlphabeticIndex::AlphabeticIndex(const Locale &locale, UErrorCode &status) : inputList_(NULL), labelsIterIndex_(-1), itemsIterIndex_(0), currentBucket_(NULL), maxLabelCount_(99), initialLabels_(NULL), firstCharsInScripts_(NULL), collator_(NULL), collatorPrimaryOnly_(NULL), buckets_(NULL) { init(&locale, status); } AlphabeticIndex::AlphabeticIndex(RuleBasedCollator *collator, UErrorCode &status) : inputList_(NULL), labelsIterIndex_(-1), itemsIterIndex_(0), currentBucket_(NULL), maxLabelCount_(99), initialLabels_(NULL), firstCharsInScripts_(NULL), collator_(collator), collatorPrimaryOnly_(NULL), buckets_(NULL) { init(NULL, status); } AlphabeticIndex::~AlphabeticIndex() { delete collator_; delete collatorPrimaryOnly_; delete firstCharsInScripts_; delete buckets_; delete inputList_; delete initialLabels_; } AlphabeticIndex &AlphabeticIndex::addLabels(const UnicodeSet &additions, UErrorCode &status) { if (U_FAILURE(status)) { return *this; } initialLabels_->addAll(additions); clearBuckets(); return *this; } AlphabeticIndex &AlphabeticIndex::addLabels(const Locale &locale, UErrorCode &status) { addIndexExemplars(locale, status); clearBuckets(); return *this; } AlphabeticIndex::ImmutableIndex *AlphabeticIndex::buildImmutableIndex(UErrorCode &errorCode) { if (U_FAILURE(errorCode)) { return NULL; } // In C++, the ImmutableIndex must own its copy of the BucketList, // even if it contains no records, for proper memory management. // We could clone the buckets_ if they are not NULL, // but that would be worth it only if this method is called multiple times, // or called after using the old-style bucket iterator API. LocalPointer immutableBucketList(createBucketList(errorCode)); LocalPointer coll( static_cast(collatorPrimaryOnly_->clone())); if (immutableBucketList.isNull() || coll.isNull()) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } ImmutableIndex *immIndex = new ImmutableIndex(immutableBucketList.getAlias(), coll.getAlias()); if (immIndex == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } // The ImmutableIndex adopted its parameter objects. immutableBucketList.orphan(); coll.orphan(); return immIndex; } int32_t AlphabeticIndex::getBucketCount(UErrorCode &status) { initBuckets(status); if (U_FAILURE(status)) { return 0; } return buckets_->getBucketCount(); } int32_t AlphabeticIndex::getRecordCount(UErrorCode &status) { if (U_FAILURE(status) || inputList_ == NULL) { return 0; } return inputList_->size(); } void AlphabeticIndex::initLabels(UVector &indexCharacters, UErrorCode &errorCode) const { const Normalizer2 *nfkdNormalizer = Normalizer2::getNFKDInstance(errorCode); if (U_FAILURE(errorCode)) { return; } const UnicodeString &firstScriptBoundary = *getString(*firstCharsInScripts_, 0); const UnicodeString &overflowBoundary = *getString(*firstCharsInScripts_, firstCharsInScripts_->size() - 1); // We make a sorted array of elements. // Some of the input may be redundant. // That is, we might have c, ch, d, where "ch" sorts just like "c", "h". // We filter out those cases. UnicodeSetIterator iter(*initialLabels_); while (iter.next()) { const UnicodeString *item = &iter.getString(); LocalPointer ownedItem; UBool checkDistinct; int32_t itemLength = item->length(); if (!item->hasMoreChar32Than(0, itemLength, 1)) { checkDistinct = FALSE; } else if(item->charAt(itemLength - 1) == 0x2a && // '*' item->charAt(itemLength - 2) != 0x2a) { // Use a label if it is marked with one trailing star, // even if the label string sorts the same when all contractions are suppressed. ownedItem.adoptInstead(new UnicodeString(*item, 0, itemLength - 1)); item = ownedItem.getAlias(); if (item == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return; } checkDistinct = FALSE; } else { checkDistinct = TRUE; } if (collatorPrimaryOnly_->compare(*item, firstScriptBoundary, errorCode) < 0) { // Ignore a primary-ignorable or non-alphabetic index character. } else if (collatorPrimaryOnly_->compare(*item, overflowBoundary, errorCode) >= 0) { // Ignore an index character that will land in the overflow bucket. } else if (checkDistinct && collatorPrimaryOnly_->compare(*item, separated(*item), errorCode) == 0) { // Ignore a multi-code point index character that does not sort distinctly // from the sequence of its separate characters. } else { int32_t insertionPoint = binarySearch(indexCharacters, *item, *collatorPrimaryOnly_); if (insertionPoint < 0) { indexCharacters.insertElementAt( ownedString(*item, ownedItem, errorCode), ~insertionPoint, errorCode); } else { const UnicodeString &itemAlreadyIn = *getString(indexCharacters, insertionPoint); if (isOneLabelBetterThanOther(*nfkdNormalizer, *item, itemAlreadyIn)) { indexCharacters.setElementAt( ownedString(*item, ownedItem, errorCode), insertionPoint); } } } } if (U_FAILURE(errorCode)) { return; } // if the result is still too large, cut down to maxLabelCount_ elements, by removing every nth element int32_t size = indexCharacters.size() - 1; if (size > maxLabelCount_) { int32_t count = 0; int32_t old = -1; for (int32_t i = 0; i < indexCharacters.size();) { ++count; int32_t bump = count * maxLabelCount_ / size; if (bump == old) { indexCharacters.removeElementAt(i); } else { old = bump; ++i; } } } } namespace { const UnicodeString &fixLabel(const UnicodeString ¤t, UnicodeString &temp) { if (!current.startsWith(BASE, BASE_LENGTH)) { return current; } UChar rest = current.charAt(BASE_LENGTH); if (0x2800 < rest && rest <= 0x28FF) { // stroke count int32_t count = rest-0x2800; temp.setTo((UChar)(0x30 + count % 10)); if (count >= 10) { count /= 10; temp.insert(0, (UChar)(0x30 + count % 10)); if (count >= 10) { count /= 10; temp.insert(0, (UChar)(0x30 + count)); } } return temp.append((UChar)0x5283); } return temp.setTo(current, BASE_LENGTH); } UBool hasMultiplePrimaryWeights( const RuleBasedCollator &coll, uint32_t variableTop, const UnicodeString &s, UVector64 &ces, UErrorCode &errorCode) { ces.removeAllElements(); coll.internalGetCEs(s, ces, errorCode); if (U_FAILURE(errorCode)) { return FALSE; } UBool seenPrimary = FALSE; for (int32_t i = 0; i < ces.size(); ++i) { int64_t ce = ces.elementAti(i); uint32_t p = (uint32_t)(ce >> 32); if (p > variableTop) { // not primary ignorable if (seenPrimary) { return TRUE; } seenPrimary = TRUE; } } return FALSE; } } // namespace BucketList *AlphabeticIndex::createBucketList(UErrorCode &errorCode) const { // Initialize indexCharacters. UVector indexCharacters(errorCode); indexCharacters.setDeleter(uprv_deleteUObject); initLabels(indexCharacters, errorCode); if (U_FAILURE(errorCode)) { return NULL; } // Variables for hasMultiplePrimaryWeights(). UVector64 ces(errorCode); uint32_t variableTop; if (collatorPrimaryOnly_->getAttribute(UCOL_ALTERNATE_HANDLING, errorCode) == UCOL_SHIFTED) { variableTop = collatorPrimaryOnly_->getVariableTop(errorCode); } else { variableTop = 0; } UBool hasInvisibleBuckets = FALSE; // Helper arrays for Chinese Pinyin collation. Bucket *asciiBuckets[26] = { NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL }; Bucket *pinyinBuckets[26] = { NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL }; UBool hasPinyin = FALSE; LocalPointer bucketList(new UVector(errorCode), errorCode); if (U_FAILURE(errorCode)) { return NULL; } bucketList->setDeleter(uprv_deleteUObject); // underflow bucket Bucket *bucket = new Bucket(getUnderflowLabel(), emptyString_, U_ALPHAINDEX_UNDERFLOW); if (bucket == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } bucketList->addElement(bucket, errorCode); if (U_FAILURE(errorCode)) { return NULL; } UnicodeString temp; // fix up the list, adding underflow, additions, overflow // Insert inflow labels as needed. int32_t scriptIndex = -1; const UnicodeString *scriptUpperBoundary = &emptyString_; for (int32_t i = 0; i < indexCharacters.size(); ++i) { UnicodeString ¤t = *getString(indexCharacters, i); if (collatorPrimaryOnly_->compare(current, *scriptUpperBoundary, errorCode) >= 0) { // We crossed the script boundary into a new script. const UnicodeString &inflowBoundary = *scriptUpperBoundary; UBool skippedScript = FALSE; for (;;) { scriptUpperBoundary = getString(*firstCharsInScripts_, ++scriptIndex); if (collatorPrimaryOnly_->compare(current, *scriptUpperBoundary, errorCode) < 0) { break; } skippedScript = TRUE; } if (skippedScript && bucketList->size() > 1) { // We are skipping one or more scripts, // and we are not just getting out of the underflow label. bucket = new Bucket(getInflowLabel(), inflowBoundary, U_ALPHAINDEX_INFLOW); if (bucket == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } bucketList->addElement(bucket, errorCode); } } // Add a bucket with the current label. bucket = new Bucket(fixLabel(current, temp), current, U_ALPHAINDEX_NORMAL); if (bucket == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } bucketList->addElement(bucket, errorCode); // Remember ASCII and Pinyin buckets for Pinyin redirects. UChar c; if (current.length() == 1 && 0x41 <= (c = current.charAt(0)) && c <= 0x5A) { // A-Z asciiBuckets[c - 0x41] = bucket; } else if (current.length() == BASE_LENGTH + 1 && current.startsWith(BASE, BASE_LENGTH) && 0x41 <= (c = current.charAt(BASE_LENGTH)) && c <= 0x5A) { pinyinBuckets[c - 0x41] = bucket; hasPinyin = TRUE; } // Check for multiple primary weights. if (!current.startsWith(BASE, BASE_LENGTH) && hasMultiplePrimaryWeights(*collatorPrimaryOnly_, variableTop, current, ces, errorCode) && current.charAt(current.length() - 1) != 0xFFFF /* !current.endsWith("\uffff") */) { // "AE-ligature" or "Sch" etc. for (int32_t i = bucketList->size() - 2;; --i) { Bucket *singleBucket = getBucket(*bucketList, i); if (singleBucket->labelType_ != U_ALPHAINDEX_NORMAL) { // There is no single-character bucket since the last // underflow or inflow label. break; } if (singleBucket->displayBucket_ == NULL && !hasMultiplePrimaryWeights(*collatorPrimaryOnly_, variableTop, singleBucket->lowerBoundary_, ces, errorCode)) { // Add an invisible bucket that redirects strings greater than the expansion // to the previous single-character bucket. // For example, after ... Q R S Sch we add Sch\uFFFF->S // and after ... Q R S Sch Sch\uFFFF St we add St\uFFFF->S. bucket = new Bucket(emptyString_, UnicodeString(current).append((UChar)0xFFFF), U_ALPHAINDEX_NORMAL); if (bucket == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } bucket->displayBucket_ = singleBucket; bucketList->addElement(bucket, errorCode); hasInvisibleBuckets = TRUE; break; } } } } if (U_FAILURE(errorCode)) { return NULL; } if (bucketList->size() == 1) { // No real labels, show only the underflow label. BucketList *bl = new BucketList(bucketList.getAlias(), bucketList.getAlias()); if (bl == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } bucketList.orphan(); return bl; } // overflow bucket bucket = new Bucket(getOverflowLabel(), *scriptUpperBoundary, U_ALPHAINDEX_OVERFLOW); if (bucket == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } bucketList->addElement(bucket, errorCode); // final if (hasPinyin) { // Redirect Pinyin buckets. Bucket *asciiBucket = NULL; for (int32_t i = 0; i < 26; ++i) { if (asciiBuckets[i] != NULL) { asciiBucket = asciiBuckets[i]; } if (pinyinBuckets[i] != NULL && asciiBucket != NULL) { pinyinBuckets[i]->displayBucket_ = asciiBucket; hasInvisibleBuckets = TRUE; } } } if (U_FAILURE(errorCode)) { return NULL; } if (!hasInvisibleBuckets) { BucketList *bl = new BucketList(bucketList.getAlias(), bucketList.getAlias()); if (bl == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } bucketList.orphan(); return bl; } // Merge inflow buckets that are visually adjacent. // Iterate backwards: Merge inflow into overflow rather than the other way around. int32_t i = bucketList->size() - 1; Bucket *nextBucket = getBucket(*bucketList, i); while (--i > 0) { bucket = getBucket(*bucketList, i); if (bucket->displayBucket_ != NULL) { continue; // skip invisible buckets } if (bucket->labelType_ == U_ALPHAINDEX_INFLOW) { if (nextBucket->labelType_ != U_ALPHAINDEX_NORMAL) { bucket->displayBucket_ = nextBucket; continue; } } nextBucket = bucket; } LocalPointer publicBucketList(new UVector(errorCode), errorCode); if (U_FAILURE(errorCode)) { return NULL; } // Do not call publicBucketList->setDeleter(): // This vector shares its objects with the bucketList. for (int32_t i = 0; i < bucketList->size(); ++i) { bucket = getBucket(*bucketList, i); if (bucket->displayBucket_ == NULL) { publicBucketList->addElement(bucket, errorCode); } } if (U_FAILURE(errorCode)) { return NULL; } BucketList *bl = new BucketList(bucketList.getAlias(), publicBucketList.getAlias()); if (bl == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return NULL; } bucketList.orphan(); publicBucketList.orphan(); return bl; } /** * Creates an index, and buckets and sorts the list of records into the index. */ void AlphabeticIndex::initBuckets(UErrorCode &errorCode) { if (U_FAILURE(errorCode) || buckets_ != NULL) { return; } buckets_ = createBucketList(errorCode); if (U_FAILURE(errorCode) || inputList_ == NULL || inputList_->isEmpty()) { return; } // Sort the records by name. // Stable sort preserves input order of collation duplicates. inputList_->sortWithUComparator(recordCompareFn, collator_, errorCode); // Now, we traverse all of the input, which is now sorted. // If the item doesn't go in the current bucket, we find the next bucket that contains it. // This makes the process order n*log(n), since we just sort the list and then do a linear process. // However, if the user adds an item at a time and then gets the buckets, this isn't efficient, so // we need to improve it for that case. Bucket *currentBucket = getBucket(*buckets_->bucketList_, 0); int32_t bucketIndex = 1; Bucket *nextBucket; const UnicodeString *upperBoundary; if (bucketIndex < buckets_->bucketList_->size()) { nextBucket = getBucket(*buckets_->bucketList_, bucketIndex++); upperBoundary = &nextBucket->lowerBoundary_; } else { nextBucket = NULL; upperBoundary = NULL; } for (int32_t i = 0; i < inputList_->size(); ++i) { Record *r = getRecord(*inputList_, i); // if the current bucket isn't the right one, find the one that is // We have a special flag for the last bucket so that we don't look any further while (upperBoundary != NULL && collatorPrimaryOnly_->compare(r->name_, *upperBoundary, errorCode) >= 0) { currentBucket = nextBucket; // now reset the boundary that we compare against if (bucketIndex < buckets_->bucketList_->size()) { nextBucket = getBucket(*buckets_->bucketList_, bucketIndex++); upperBoundary = &nextBucket->lowerBoundary_; } else { upperBoundary = NULL; } } // now put the record into the bucket. Bucket *bucket = currentBucket; if (bucket->displayBucket_ != NULL) { bucket = bucket->displayBucket_; } if (bucket->records_ == NULL) { bucket->records_ = new UVector(errorCode); if (bucket->records_ == NULL) { errorCode = U_MEMORY_ALLOCATION_ERROR; return; } } bucket->records_->addElement(r, errorCode); } } void AlphabeticIndex::clearBuckets() { if (buckets_ != NULL) { delete buckets_; buckets_ = NULL; internalResetBucketIterator(); } } void AlphabeticIndex::internalResetBucketIterator() { labelsIterIndex_ = -1; currentBucket_ = NULL; } void AlphabeticIndex::addIndexExemplars(const Locale &locale, UErrorCode &status) { LocalULocaleDataPointer uld(ulocdata_open(locale.getName(), &status)); if (U_FAILURE(status)) { return; } UnicodeSet exemplars; ulocdata_getExemplarSet(uld.getAlias(), exemplars.toUSet(), 0, ULOCDATA_ES_INDEX, &status); if (U_SUCCESS(status)) { initialLabels_->addAll(exemplars); return; } status = U_ZERO_ERROR; // Clear out U_MISSING_RESOURCE_ERROR // The locale data did not include explicit Index characters. // Synthesize a set of them from the locale's standard exemplar characters. ulocdata_getExemplarSet(uld.getAlias(), exemplars.toUSet(), 0, ULOCDATA_ES_STANDARD, &status); if (U_FAILURE(status)) { return; } // question: should we add auxiliary exemplars? if (exemplars.containsSome(0x61, 0x7A) /* a-z */ || exemplars.size() == 0) { exemplars.add(0x61, 0x7A); } if (exemplars.containsSome(0xAC00, 0xD7A3)) { // Hangul syllables // cut down to small list exemplars.remove(0xAC00, 0xD7A3). add(0xAC00).add(0xB098).add(0xB2E4).add(0xB77C). add(0xB9C8).add(0xBC14).add(0xC0AC).add(0xC544). add(0xC790).add(0xCC28).add(0xCE74).add(0xD0C0). add(0xD30C).add(0xD558); } if (exemplars.containsSome(0x1200, 0x137F)) { // Ethiopic block // cut down to small list // make use of the fact that Ethiopic is allocated in 8's, where // the base is 0 mod 8. UnicodeSet ethiopic( UNICODE_STRING_SIMPLE("[[:Block=Ethiopic:]&[:Script=Ethiopic:]]"), status); UnicodeSetIterator it(ethiopic); while (it.next() && !it.isString()) { if ((it.getCodepoint() & 0x7) != 0) { exemplars.remove(it.getCodepoint()); } } } // Upper-case any that aren't already so. // (We only do this for synthesized index characters.) UnicodeSetIterator it(exemplars); UnicodeString upperC; while (it.next()) { const UnicodeString &exemplarC = it.getString(); upperC = exemplarC; upperC.toUpper(locale); initialLabels_->add(upperC); } } UBool AlphabeticIndex::addChineseIndexCharacters(UErrorCode &errorCode) { UnicodeSet contractions; collatorPrimaryOnly_->internalAddContractions(BASE[0], contractions, errorCode); if (U_FAILURE(errorCode) || contractions.isEmpty()) { return FALSE; } initialLabels_->addAll(contractions); UnicodeSetIterator iter(contractions); while (iter.next()) { const UnicodeString &s = iter.getString(); U_ASSERT (s.startsWith(BASE, BASE_LENGTH)); UChar c = s.charAt(s.length() - 1); if (0x41 <= c && c <= 0x5A) { // A-Z // There are Pinyin labels, add ASCII A-Z labels as well. initialLabels_->add(0x41, 0x5A); // A-Z break; } } return TRUE; } /* * Return the string with interspersed CGJs. Input must have more than 2 codepoints. */ static const UChar CGJ = 0x034F; UnicodeString AlphabeticIndex::separated(const UnicodeString &item) { UnicodeString result; if (item.length() == 0) { return result; } int32_t i = 0; for (;;) { UChar32 cp = item.char32At(i); result.append(cp); i = item.moveIndex32(i, 1); if (i >= item.length()) { break; } result.append(CGJ); } return result; } UBool AlphabeticIndex::operator==(const AlphabeticIndex& /* other */) const { return FALSE; } UBool AlphabeticIndex::operator!=(const AlphabeticIndex& /* other */) const { return FALSE; } const RuleBasedCollator &AlphabeticIndex::getCollator() const { return *collator_; } const UnicodeString &AlphabeticIndex::getInflowLabel() const { return inflowLabel_; } const UnicodeString &AlphabeticIndex::getOverflowLabel() const { return overflowLabel_; } const UnicodeString &AlphabeticIndex::getUnderflowLabel() const { return underflowLabel_; } AlphabeticIndex &AlphabeticIndex::setInflowLabel(const UnicodeString &label, UErrorCode &/*status*/) { inflowLabel_ = label; clearBuckets(); return *this; } AlphabeticIndex &AlphabeticIndex::setOverflowLabel(const UnicodeString &label, UErrorCode &/*status*/) { overflowLabel_ = label; clearBuckets(); return *this; } AlphabeticIndex &AlphabeticIndex::setUnderflowLabel(const UnicodeString &label, UErrorCode &/*status*/) { underflowLabel_ = label; clearBuckets(); return *this; } int32_t AlphabeticIndex::getMaxLabelCount() const { return maxLabelCount_; } AlphabeticIndex &AlphabeticIndex::setMaxLabelCount(int32_t maxLabelCount, UErrorCode &status) { if (U_FAILURE(status)) { return *this; } if (maxLabelCount <= 0) { status = U_ILLEGAL_ARGUMENT_ERROR; return *this; } maxLabelCount_ = maxLabelCount; clearBuckets(); return *this; } // // init() - Common code for constructors. // void AlphabeticIndex::init(const Locale *locale, UErrorCode &status) { if (U_FAILURE(status)) { return; } if (locale == NULL && collator_ == NULL) { status = U_ILLEGAL_ARGUMENT_ERROR; return; } initialLabels_ = new UnicodeSet(); if (initialLabels_ == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return; } inflowLabel_.setTo((UChar)0x2026); // Ellipsis overflowLabel_ = inflowLabel_; underflowLabel_ = inflowLabel_; if (collator_ == NULL) { Collator *coll = Collator::createInstance(*locale, status); if (U_FAILURE(status)) { delete coll; return; } if (coll == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return; } collator_ = dynamic_cast(coll); if (collator_ == NULL) { delete coll; status = U_UNSUPPORTED_ERROR; return; } } collatorPrimaryOnly_ = static_cast(collator_->clone()); if (collatorPrimaryOnly_ == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return; } collatorPrimaryOnly_->setAttribute(UCOL_STRENGTH, UCOL_PRIMARY, status); firstCharsInScripts_ = firstStringsInScript(status); if (U_FAILURE(status)) { return; } firstCharsInScripts_->sortWithUComparator(collatorComparator, collatorPrimaryOnly_, status); // Guard against a degenerate collator where // some script boundary strings are primary ignorable. for (;;) { if (U_FAILURE(status)) { return; } if (firstCharsInScripts_->isEmpty()) { // AlphabeticIndex requires some non-ignorable script boundary strings. status = U_ILLEGAL_ARGUMENT_ERROR; return; } if (collatorPrimaryOnly_->compare( *static_cast(firstCharsInScripts_->elementAt(0)), emptyString_, status) == UCOL_EQUAL) { firstCharsInScripts_->removeElementAt(0); } else { break; } } // Chinese index characters, which are specific to each of the several Chinese tailorings, // take precedence over the single locale data exemplar set per language. if (!addChineseIndexCharacters(status) && locale != NULL) { addIndexExemplars(*locale, status); } } // // Comparison function for UVector sorting with a collator. // static int32_t U_CALLCONV collatorComparator(const void *context, const void *left, const void *right) { const UElement *leftElement = static_cast(left); const UElement *rightElement = static_cast(right); const UnicodeString *leftString = static_cast(leftElement->pointer); const UnicodeString *rightString = static_cast(rightElement->pointer); if (leftString == rightString) { // Catches case where both are NULL return 0; } if (leftString == NULL) { return 1; }; if (rightString == NULL) { return -1; } const Collator *col = static_cast(context); UErrorCode errorCode = U_ZERO_ERROR; return col->compare(*leftString, *rightString, errorCode); } // // Comparison function for UVector sorting with a collator. // static int32_t U_CALLCONV recordCompareFn(const void *context, const void *left, const void *right) { const UElement *leftElement = static_cast(left); const UElement *rightElement = static_cast(right); const AlphabeticIndex::Record *leftRec = static_cast(leftElement->pointer); const AlphabeticIndex::Record *rightRec = static_cast(rightElement->pointer); const Collator *col = static_cast(context); UErrorCode errorCode = U_ZERO_ERROR; return col->compare(leftRec->name_, rightRec->name_, errorCode); } UVector *AlphabeticIndex::firstStringsInScript(UErrorCode &status) { if (U_FAILURE(status)) { return NULL; } LocalPointer dest(new UVector(status), status); if (U_FAILURE(status)) { return NULL; } dest->setDeleter(uprv_deleteUObject); // Fetch the script-first-primary contractions which are defined in the root collator. // They all start with U+FDD1. UnicodeSet set; collatorPrimaryOnly_->internalAddContractions(0xFDD1, set, status); if (U_FAILURE(status)) { return NULL; } if (set.isEmpty()) { status = U_UNSUPPORTED_ERROR; return NULL; } UnicodeSetIterator iter(set); while (iter.next()) { const UnicodeString &boundary = iter.getString(); uint32_t gcMask = U_GET_GC_MASK(boundary.char32At(1)); if ((gcMask & (U_GC_L_MASK | U_GC_CN_MASK)) == 0) { // Ignore boundaries for the special reordering groups. // Take only those for "real scripts" (where the sample character is a Letter, // and the one for unassigned implicit weights (Cn). continue; } UnicodeString *s = new UnicodeString(boundary); if (s == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return NULL; } dest->addElement(s, status); } return dest.orphan(); } namespace { /** * Returns true if one index character string is "better" than the other. * Shorter NFKD is better, and otherwise NFKD-binary-less-than is * better, and otherwise binary-less-than is better. */ UBool isOneLabelBetterThanOther(const Normalizer2 &nfkdNormalizer, const UnicodeString &one, const UnicodeString &other) { // This is called with primary-equal strings, but never with one.equals(other). UErrorCode status = U_ZERO_ERROR; UnicodeString n1 = nfkdNormalizer.normalize(one, status); UnicodeString n2 = nfkdNormalizer.normalize(other, status); if (U_FAILURE(status)) { return FALSE; } int32_t result = n1.countChar32() - n2.countChar32(); if (result != 0) { return result < 0; } result = n1.compareCodePointOrder(n2); if (result != 0) { return result < 0; } return one.compareCodePointOrder(other) < 0; } } // namespace // // Constructor & Destructor for AlphabeticIndex::Record // // Records are internal only, instances are not directly surfaced in the public API. // This class is mostly struct-like, with all public fields. AlphabeticIndex::Record::Record(const UnicodeString &name, const void *data) : name_(name), data_(data) {} AlphabeticIndex::Record::~Record() { } AlphabeticIndex & AlphabeticIndex::addRecord(const UnicodeString &name, const void *data, UErrorCode &status) { if (U_FAILURE(status)) { return *this; } if (inputList_ == NULL) { inputList_ = new UVector(status); if (inputList_ == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return *this; } inputList_->setDeleter(alphaIndex_deleteRecord); } Record *r = new Record(name, data); if (r == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return *this; } inputList_->addElement(r, status); clearBuckets(); //std::string ss; //std::string ss2; //std::cout << "added record: name = \"" << r->name_.toUTF8String(ss) << "\"" << // " sortingName = \"" << r->sortingName_.toUTF8String(ss2) << "\"" << std::endl; return *this; } AlphabeticIndex &AlphabeticIndex::clearRecords(UErrorCode &status) { if (U_SUCCESS(status) && inputList_ != NULL && !inputList_->isEmpty()) { inputList_->removeAllElements(); clearBuckets(); } return *this; } int32_t AlphabeticIndex::getBucketIndex(const UnicodeString &name, UErrorCode &status) { initBuckets(status); if (U_FAILURE(status)) { return 0; } return buckets_->getBucketIndex(name, *collatorPrimaryOnly_, status); } int32_t AlphabeticIndex::getBucketIndex() const { return labelsIterIndex_; } UBool AlphabeticIndex::nextBucket(UErrorCode &status) { if (U_FAILURE(status)) { return FALSE; } if (buckets_ == NULL && currentBucket_ != NULL) { status = U_ENUM_OUT_OF_SYNC_ERROR; return FALSE; } initBuckets(status); if (U_FAILURE(status)) { return FALSE; } ++labelsIterIndex_; if (labelsIterIndex_ >= buckets_->getBucketCount()) { labelsIterIndex_ = buckets_->getBucketCount(); return FALSE; } currentBucket_ = getBucket(*buckets_->immutableVisibleList_, labelsIterIndex_); resetRecordIterator(); return TRUE; } const UnicodeString &AlphabeticIndex::getBucketLabel() const { if (currentBucket_ != NULL) { return currentBucket_->label_; } else { return emptyString_; } } UAlphabeticIndexLabelType AlphabeticIndex::getBucketLabelType() const { if (currentBucket_ != NULL) { return currentBucket_->labelType_; } else { return U_ALPHAINDEX_NORMAL; } } int32_t AlphabeticIndex::getBucketRecordCount() const { if (currentBucket_ != NULL && currentBucket_->records_ != NULL) { return currentBucket_->records_->size(); } else { return 0; } } AlphabeticIndex &AlphabeticIndex::resetBucketIterator(UErrorCode &status) { if (U_FAILURE(status)) { return *this; } internalResetBucketIterator(); return *this; } UBool AlphabeticIndex::nextRecord(UErrorCode &status) { if (U_FAILURE(status)) { return FALSE; } if (currentBucket_ == NULL) { // We are trying to iterate over the items in a bucket, but there is no // current bucket from the enumeration of buckets. status = U_INVALID_STATE_ERROR; return FALSE; } if (buckets_ == NULL) { status = U_ENUM_OUT_OF_SYNC_ERROR; return FALSE; } if (currentBucket_->records_ == NULL) { return FALSE; } ++itemsIterIndex_; if (itemsIterIndex_ >= currentBucket_->records_->size()) { itemsIterIndex_ = currentBucket_->records_->size(); return FALSE; } return TRUE; } const UnicodeString &AlphabeticIndex::getRecordName() const { const UnicodeString *retStr = &emptyString_; if (currentBucket_ != NULL && currentBucket_->records_ != NULL && itemsIterIndex_ >= 0 && itemsIterIndex_ < currentBucket_->records_->size()) { Record *item = static_cast(currentBucket_->records_->elementAt(itemsIterIndex_)); retStr = &item->name_; } return *retStr; } const void *AlphabeticIndex::getRecordData() const { const void *retPtr = NULL; if (currentBucket_ != NULL && currentBucket_->records_ != NULL && itemsIterIndex_ >= 0 && itemsIterIndex_ < currentBucket_->records_->size()) { Record *item = static_cast(currentBucket_->records_->elementAt(itemsIterIndex_)); retPtr = item->data_; } return retPtr; } AlphabeticIndex & AlphabeticIndex::resetRecordIterator() { itemsIterIndex_ = -1; return *this; } AlphabeticIndex::Bucket::Bucket(const UnicodeString &label, const UnicodeString &lowerBoundary, UAlphabeticIndexLabelType type) : label_(label), lowerBoundary_(lowerBoundary), labelType_(type), displayBucket_(NULL), displayIndex_(-1), records_(NULL) { } AlphabeticIndex::Bucket::~Bucket() { delete records_; } U_NAMESPACE_END #endif // !UCONFIG_NO_COLLATION