src/third_party/icu/source/i18n/utf16collationiterator.cpp - cobalt - Git at Google

 /*
 *******************************************************************************
 * Copyright (C) 2010-2014, International Business Machines
 * Corporation and others.  All Rights Reserved.
 *******************************************************************************
 * utf16collationiterator.cpp
 *
 * created on: 2010oct27
 * created by: Markus W. Scherer
 */

 #include "unicode/utypes.h"

 #if !UCONFIG_NO_COLLATION

 #include "starboard/client_porting/poem/assert_poem.h"
 #include "starboard/client_porting/poem/string_poem.h"
 #include "charstr.h"
 #include "cmemory.h"
 #include "collation.h"
 #include "collationdata.h"
 #include "collationfcd.h"
 #include "collationiterator.h"
 #include "normalizer2impl.h"
 #include "uassert.h"
 #include "utf16collationiterator.h"

 U_NAMESPACE_BEGIN

 UTF16CollationIterator::UTF16CollationIterator(const UTF16CollationIterator &other,
                                                const UChar *newText)
         : CollationIterator(other),
           start(newText),
           pos(newText + (other.pos - other.start)),
           limit(other.limit == NULL ? NULL : newText + (other.limit - other.start)) {
 }

 UTF16CollationIterator::~UTF16CollationIterator() {}

 UBool
 UTF16CollationIterator::operator==(const CollationIterator &other) const {
     if(!CollationIterator::operator==(other)) { return FALSE; }
     const UTF16CollationIterator &o = static_cast<const UTF16CollationIterator &>(other);
     // Compare the iterator state but not the text: Assume that the caller does that.
     return (pos - start) == (o.pos - o.start);
 }

 void
 UTF16CollationIterator::resetToOffset(int32_t newOffset) {
     reset();
     pos = start + newOffset;
 }

 int32_t
 UTF16CollationIterator::getOffset() const {
     return (int32_t)(pos - start);
 }

 uint32_t
 UTF16CollationIterator::handleNextCE32(UChar32 &c, UErrorCode & /*errorCode*/) {
     if(pos == limit) {
         c = U_SENTINEL;
         return Collation::FALLBACK_CE32;
     }
     c = *pos++;
     return UTRIE2_GET32_FROM_U16_SINGLE_LEAD(trie, c);
 }

 UChar
 UTF16CollationIterator::handleGetTrailSurrogate() {
     if(pos == limit) { return 0; }
     UChar trail;
     if(U16_IS_TRAIL(trail = *pos)) { ++pos; }
     return trail;
 }

 UBool
 UTF16CollationIterator::foundNULTerminator() {
     if(limit == NULL) {
         limit = --pos;
         return TRUE;
     } else {
         return FALSE;
     }
 }

 UChar32
 UTF16CollationIterator::nextCodePoint(UErrorCode & /*errorCode*/) {
     if(pos == limit) {
         return U_SENTINEL;
     }
     UChar32 c = *pos;
     if(c == 0 && limit == NULL) {
         limit = pos;
         return U_SENTINEL;
     }
     ++pos;
     UChar trail;
     if(U16_IS_LEAD(c) && pos != limit && U16_IS_TRAIL(trail = *pos)) {
         ++pos;
         return U16_GET_SUPPLEMENTARY(c, trail);
     } else {
         return c;
     }
 }

 UChar32
 UTF16CollationIterator::previousCodePoint(UErrorCode & /*errorCode*/) {
     if(pos == start) {
         return U_SENTINEL;
     }
     UChar32 c = *--pos;
     UChar lead;
     if(U16_IS_TRAIL(c) && pos != start && U16_IS_LEAD(lead = *(pos - 1))) {
         --pos;
         return U16_GET_SUPPLEMENTARY(lead, c);
     } else {
         return c;
     }
 }

 void
 UTF16CollationIterator::forwardNumCodePoints(int32_t num, UErrorCode & /*errorCode*/) {
     while(num > 0 && pos != limit) {
         UChar32 c = *pos;
         if(c == 0 && limit == NULL) {
             limit = pos;
             break;
         }
         ++pos;
         --num;
         if(U16_IS_LEAD(c) && pos != limit && U16_IS_TRAIL(*pos)) {
             ++pos;
         }
     }
 }

 void
 UTF16CollationIterator::backwardNumCodePoints(int32_t num, UErrorCode & /*errorCode*/) {
     while(num > 0 && pos != start) {
         UChar32 c = *--pos;
         --num;
         if(U16_IS_TRAIL(c) && pos != start && U16_IS_LEAD(*(pos-1))) {
             --pos;
         }
     }
 }

 // FCDUTF16CollationIterator ----------------------------------------------- ***

 FCDUTF16CollationIterator::FCDUTF16CollationIterator(const FCDUTF16CollationIterator &other,
                                                      const UChar *newText)
         : UTF16CollationIterator(other),
           rawStart(newText),
           segmentStart(newText + (other.segmentStart - other.rawStart)),
           segmentLimit(other.segmentLimit == NULL ? NULL : newText + (other.segmentLimit - other.rawStart)),
           rawLimit(other.rawLimit == NULL ? NULL : newText + (other.rawLimit - other.rawStart)),
           nfcImpl(other.nfcImpl),
           normalized(other.normalized),
           checkDir(other.checkDir) {
     if(checkDir != 0 || other.start == other.segmentStart) {
         start = newText + (other.start - other.rawStart);
         pos = newText + (other.pos - other.rawStart);
         limit = other.limit == NULL ? NULL : newText + (other.limit - other.rawStart);
     } else {
         start = normalized.getBuffer();
         pos = start + (other.pos - other.start);
         limit = start + normalized.length();
     }
 }

 FCDUTF16CollationIterator::~FCDUTF16CollationIterator() {}

 UBool
 FCDUTF16CollationIterator::operator==(const CollationIterator &other) const {
     // Skip the UTF16CollationIterator and call its parent.
     if(!CollationIterator::operator==(other)) { return FALSE; }
     const FCDUTF16CollationIterator &o = static_cast<const FCDUTF16CollationIterator &>(other);
     // Compare the iterator state but not the text: Assume that the caller does that.
     if(checkDir != o.checkDir) { return FALSE; }
     if(checkDir == 0 && (start == segmentStart) != (o.start == o.segmentStart)) { return FALSE; }
     if(checkDir != 0 || start == segmentStart) {
         return (pos - rawStart) == (o.pos - o.rawStart);
     } else {
         return (segmentStart - rawStart) == (o.segmentStart - o.rawStart) &&
                 (pos - start) == (o.pos - o.start);
     }
 }

 void
 FCDUTF16CollationIterator::resetToOffset(int32_t newOffset) {
     reset();
     start = segmentStart = pos = rawStart + newOffset;
     limit = rawLimit;
     checkDir = 1;
 }

 int32_t
 FCDUTF16CollationIterator::getOffset() const {
     if(checkDir != 0 || start == segmentStart) {
         return (int32_t)(pos - rawStart);
     } else if(pos == start) {
         return (int32_t)(segmentStart - rawStart);
     } else {
         return (int32_t)(segmentLimit - rawStart);
     }
 }

 uint32_t
 FCDUTF16CollationIterator::handleNextCE32(UChar32 &c, UErrorCode &errorCode) {
     for(;;) {
         if(checkDir > 0) {
             if(pos == limit) {
                 c = U_SENTINEL;
                 return Collation::FALLBACK_CE32;
             }
             c = *pos++;
             if(CollationFCD::hasTccc(c)) {
                 if(CollationFCD::maybeTibetanCompositeVowel(c) ||
                         (pos != limit && CollationFCD::hasLccc(*pos))) {
                     --pos;
                     if(!nextSegment(errorCode)) {
                         c = U_SENTINEL;
                         return Collation::FALLBACK_CE32;
                     }
                     c = *pos++;
                 }
             }
             break;
         } else if(checkDir == 0 && pos != limit) {
             c = *pos++;
             break;
         } else {
             switchToForward();
         }
     }
     return UTRIE2_GET32_FROM_U16_SINGLE_LEAD(trie, c);
 }

 UBool
 FCDUTF16CollationIterator::foundNULTerminator() {
     if(limit == NULL) {
         limit = rawLimit = --pos;
         return TRUE;
     } else {
         return FALSE;
     }
 }

 UChar32
 FCDUTF16CollationIterator::nextCodePoint(UErrorCode &errorCode) {
     UChar32 c;
     for(;;) {
         if(checkDir > 0) {
             if(pos == limit) {
                 return U_SENTINEL;
             }
             c = *pos++;
             if(CollationFCD::hasTccc(c)) {
                 if(CollationFCD::maybeTibetanCompositeVowel(c) ||
                         (pos != limit && CollationFCD::hasLccc(*pos))) {
                     --pos;
                     if(!nextSegment(errorCode)) {
                         return U_SENTINEL;
                     }
                     c = *pos++;
                 }
             } else if(c == 0 && limit == NULL) {
                 limit = rawLimit = --pos;
                 return U_SENTINEL;
             }
             break;
         } else if(checkDir == 0 && pos != limit) {
             c = *pos++;
             break;
         } else {
             switchToForward();
         }
     }
     UChar trail;
     if(U16_IS_LEAD(c) && pos != limit && U16_IS_TRAIL(trail = *pos)) {
         ++pos;
         return U16_GET_SUPPLEMENTARY(c, trail);
     } else {
         return c;
     }
 }

 UChar32
 FCDUTF16CollationIterator::previousCodePoint(UErrorCode &errorCode) {
     UChar32 c;
     for(;;) {
         if(checkDir < 0) {
             if(pos == start) {
                 return U_SENTINEL;
             }
             c = *--pos;
             if(CollationFCD::hasLccc(c)) {
                 if(CollationFCD::maybeTibetanCompositeVowel(c) ||
                         (pos != start && CollationFCD::hasTccc(*(pos - 1)))) {
                     ++pos;
                     if(!previousSegment(errorCode)) {
                         return U_SENTINEL;
                     }
                     c = *--pos;
                 }
             }
             break;
         } else if(checkDir == 0 && pos != start) {
             c = *--pos;
             break;
         } else {
             switchToBackward();
         }
     }
     UChar lead;
     if(U16_IS_TRAIL(c) && pos != start && U16_IS_LEAD(lead = *(pos - 1))) {
         --pos;
         return U16_GET_SUPPLEMENTARY(lead, c);
     } else {
         return c;
     }
 }

 void
 FCDUTF16CollationIterator::forwardNumCodePoints(int32_t num, UErrorCode &errorCode) {
     // Specify the class to avoid a virtual-function indirection.
     // In Java, we would declare this class final.
     while(num > 0 && FCDUTF16CollationIterator::nextCodePoint(errorCode) >= 0) {
         --num;
     }
 }

 void
 FCDUTF16CollationIterator::backwardNumCodePoints(int32_t num, UErrorCode &errorCode) {
     // Specify the class to avoid a virtual-function indirection.
     // In Java, we would declare this class final.
     while(num > 0 && FCDUTF16CollationIterator::previousCodePoint(errorCode) >= 0) {
         --num;
     }
 }

 void
 FCDUTF16CollationIterator::switchToForward() {
     U_ASSERT(checkDir < 0 || (checkDir == 0 && pos == limit));
     if(checkDir < 0) {
         // Turn around from backward checking.
         start = segmentStart = pos;
         if(pos == segmentLimit) {
             limit = rawLimit;
             checkDir = 1;  // Check forward.
         } else {  // pos < segmentLimit
             checkDir = 0;  // Stay in FCD segment.
         }
     } else {
         // Reached the end of the FCD segment.
         if(start == segmentStart) {
             // The input text segment is FCD, extend it forward.
         } else {
             // The input text segment needed to be normalized.
             // Switch to checking forward from it.
             pos = start = segmentStart = segmentLimit;
             // Note: If this segment is at the end of the input text,
             // then it might help to return FALSE to indicate that, so that
             // we do not have to re-check and normalize when we turn around and go backwards.
             // However, that would complicate the call sites for an optimization of an unusual case.
         }
         limit = rawLimit;
         checkDir = 1;
     }
 }

 UBool
 FCDUTF16CollationIterator::nextSegment(UErrorCode &errorCode) {
     if(U_FAILURE(errorCode)) { return FALSE; }
     U_ASSERT(checkDir > 0 && pos != limit);
     // The input text [segmentStart..pos[ passes the FCD check.
     const UChar *p = pos;
     uint8_t prevCC = 0;
     for(;;) {
         // Fetch the next character's fcd16 value.
         const UChar *q = p;
         uint16_t fcd16 = nfcImpl.nextFCD16(p, rawLimit);
         uint8_t leadCC = (uint8_t)(fcd16 >> 8);
         if(leadCC == 0 && q != pos) {
             // FCD boundary before the [q, p[ character.
             limit = segmentLimit = q;
             break;
         }
         if(leadCC != 0 && (prevCC > leadCC || CollationFCD::isFCD16OfTibetanCompositeVowel(fcd16))) {
             // Fails FCD check. Find the next FCD boundary and normalize.
             do {
                 q = p;
             } while(p != rawLimit && nfcImpl.nextFCD16(p, rawLimit) > 0xff);
             if(!normalize(pos, q, errorCode)) { return FALSE; }
             pos = start;
             break;
         }
         prevCC = (uint8_t)fcd16;
         if(p == rawLimit || prevCC == 0) {
             // FCD boundary after the last character.
             limit = segmentLimit = p;
             break;
         }
     }
     U_ASSERT(pos != limit);
     checkDir = 0;
     return TRUE;
 }

 void
 FCDUTF16CollationIterator::switchToBackward() {
     U_ASSERT(checkDir > 0 || (checkDir == 0 && pos == start));
     if(checkDir > 0) {
         // Turn around from forward checking.
         limit = segmentLimit = pos;
         if(pos == segmentStart) {
             start = rawStart;
             checkDir = -1;  // Check backward.
         } else {  // pos > segmentStart
             checkDir = 0;  // Stay in FCD segment.
         }
     } else {
         // Reached the start of the FCD segment.
         if(start == segmentStart) {
             // The input text segment is FCD, extend it backward.
         } else {
             // The input text segment needed to be normalized.
             // Switch to checking backward from it.
             pos = limit = segmentLimit = segmentStart;
         }
         start = rawStart;
         checkDir = -1;
     }
 }

 UBool
 FCDUTF16CollationIterator::previousSegment(UErrorCode &errorCode) {
     if(U_FAILURE(errorCode)) { return FALSE; }
     U_ASSERT(checkDir < 0 && pos != start);
     // The input text [pos..segmentLimit[ passes the FCD check.
     const UChar *p = pos;
     uint8_t nextCC = 0;
     for(;;) {
         // Fetch the previous character's fcd16 value.
         const UChar *q = p;
         uint16_t fcd16 = nfcImpl.previousFCD16(rawStart, p);
         uint8_t trailCC = (uint8_t)fcd16;
         if(trailCC == 0 && q != pos) {
             // FCD boundary after the [p, q[ character.
             start = segmentStart = q;
             break;
         }
         if(trailCC != 0 && ((nextCC != 0 && trailCC > nextCC) ||
                             CollationFCD::isFCD16OfTibetanCompositeVowel(fcd16))) {
             // Fails FCD check. Find the previous FCD boundary and normalize.
             do {
                 q = p;
             } while(fcd16 > 0xff && p != rawStart &&
                     (fcd16 = nfcImpl.previousFCD16(rawStart, p)) != 0);
             if(!normalize(q, pos, errorCode)) { return FALSE; }
             pos = limit;
             break;
         }
         nextCC = (uint8_t)(fcd16 >> 8);
         if(p == rawStart || nextCC == 0) {
             // FCD boundary before the following character.
             start = segmentStart = p;
             break;
         }
     }
     U_ASSERT(pos != start);
     checkDir = 0;
     return TRUE;
 }

 UBool
 FCDUTF16CollationIterator::normalize(const UChar *from, const UChar *to, UErrorCode &errorCode) {
     // NFD without argument checking.
     U_ASSERT(U_SUCCESS(errorCode));
     nfcImpl.decompose(from, to, normalized, (int32_t)(to - from), errorCode);
     if(U_FAILURE(errorCode)) { return FALSE; }
     // Switch collation processing into the FCD buffer
     // with the result of normalizing [segmentStart, segmentLimit[.
     segmentStart = from;
     segmentLimit = to;
     start = normalized.getBuffer();
     limit = start + normalized.length();
     return TRUE;
 }

 U_NAMESPACE_END

 #endif  // !UCONFIG_NO_COLLATION
	/*
	*******************************************************************************
	* Copyright (C) 2010-2014, International Business Machines
	* Corporation and others. All Rights Reserved.
	*******************************************************************************
	* utf16collationiterator.cpp
	*
	* created on: 2010oct27
	* created by: Markus W. Scherer
	*/

	#include "unicode/utypes.h"

	#if !UCONFIG_NO_COLLATION

	#include "starboard/client_porting/poem/assert_poem.h"
	#include "starboard/client_porting/poem/string_poem.h"
	#include "charstr.h"
	#include "cmemory.h"
	#include "collation.h"
	#include "collationdata.h"
	#include "collationfcd.h"
	#include "collationiterator.h"
	#include "normalizer2impl.h"
	#include "uassert.h"
	#include "utf16collationiterator.h"

	U_NAMESPACE_BEGIN

	UTF16CollationIterator::UTF16CollationIterator(const UTF16CollationIterator &other,
	const UChar *newText)
	: CollationIterator(other),
	start(newText),
	pos(newText + (other.pos - other.start)),
	limit(other.limit == NULL ? NULL : newText + (other.limit - other.start)) {
	}

	UTF16CollationIterator::~UTF16CollationIterator() {}

	UBool
	UTF16CollationIterator::operator==(const CollationIterator &other) const {
	if(!CollationIterator::operator==(other)) { return FALSE; }
	const UTF16CollationIterator &o = static_cast<const UTF16CollationIterator &>(other);
	// Compare the iterator state but not the text: Assume that the caller does that.
	return (pos - start) == (o.pos - o.start);
	}

	void
	UTF16CollationIterator::resetToOffset(int32_t newOffset) {
	reset();
	pos = start + newOffset;
	}

	int32_t
	UTF16CollationIterator::getOffset() const {
	return (int32_t)(pos - start);
	}

	uint32_t
	UTF16CollationIterator::handleNextCE32(UChar32 &c, UErrorCode & /errorCode/) {
	if(pos == limit) {
	c = U_SENTINEL;
	return Collation::FALLBACK_CE32;
	}
	c = *pos++;
	return UTRIE2_GET32_FROM_U16_SINGLE_LEAD(trie, c);
	}

	UChar
	UTF16CollationIterator::handleGetTrailSurrogate() {
	if(pos == limit) { return 0; }
	UChar trail;
	if(U16_IS_TRAIL(trail = *pos)) { ++pos; }
	return trail;
	}

	UBool
	UTF16CollationIterator::foundNULTerminator() {
	if(limit == NULL) {
	limit = --pos;
	return TRUE;
	} else {
	return FALSE;
	}
	}

	UChar32
	UTF16CollationIterator::nextCodePoint(UErrorCode & /errorCode/) {
	if(pos == limit) {
	return U_SENTINEL;
	}
	UChar32 c = *pos;
	if(c == 0 && limit == NULL) {
	limit = pos;
	return U_SENTINEL;
	}
	++pos;
	UChar trail;
	if(U16_IS_LEAD(c) && pos != limit && U16_IS_TRAIL(trail = *pos)) {
	++pos;
	return U16_GET_SUPPLEMENTARY(c, trail);
	} else {
	return c;
	}
	}

	UChar32
	UTF16CollationIterator::previousCodePoint(UErrorCode & /errorCode/) {
	if(pos == start) {
	return U_SENTINEL;
	}
	UChar32 c = *--pos;
	UChar lead;
	if(U16_IS_TRAIL(c) && pos != start && U16_IS_LEAD(lead = *(pos - 1))) {
	--pos;
	return U16_GET_SUPPLEMENTARY(lead, c);
	} else {
	return c;
	}
	}

	void
	UTF16CollationIterator::forwardNumCodePoints(int32_t num, UErrorCode & /errorCode/) {
	while(num > 0 && pos != limit) {
	UChar32 c = *pos;
	if(c == 0 && limit == NULL) {
	limit = pos;
	break;
	}
	++pos;
	--num;
	if(U16_IS_LEAD(c) && pos != limit && U16_IS_TRAIL(*pos)) {
	++pos;
	}
	}
	}

	void
	UTF16CollationIterator::backwardNumCodePoints(int32_t num, UErrorCode & /errorCode/) {
	while(num > 0 && pos != start) {
	UChar32 c = *--pos;
	--num;
	if(U16_IS_TRAIL(c) && pos != start && U16_IS_LEAD(*(pos-1))) {
	--pos;
	}
	}
	}

	// FCDUTF16CollationIterator ----------------------------------------------- ***

	FCDUTF16CollationIterator::FCDUTF16CollationIterator(const FCDUTF16CollationIterator &other,
	const UChar *newText)
	: UTF16CollationIterator(other),
	rawStart(newText),
	segmentStart(newText + (other.segmentStart - other.rawStart)),
	segmentLimit(other.segmentLimit == NULL ? NULL : newText + (other.segmentLimit - other.rawStart)),
	rawLimit(other.rawLimit == NULL ? NULL : newText + (other.rawLimit - other.rawStart)),
	nfcImpl(other.nfcImpl),
	normalized(other.normalized),
	checkDir(other.checkDir) {
	if(checkDir != 0 \|\| other.start == other.segmentStart) {
	start = newText + (other.start - other.rawStart);
	pos = newText + (other.pos - other.rawStart);
	limit = other.limit == NULL ? NULL : newText + (other.limit - other.rawStart);
	} else {
	start = normalized.getBuffer();
	pos = start + (other.pos - other.start);
	limit = start + normalized.length();
	}
	}

	FCDUTF16CollationIterator::~FCDUTF16CollationIterator() {}

	UBool
	FCDUTF16CollationIterator::operator==(const CollationIterator &other) const {
	// Skip the UTF16CollationIterator and call its parent.
	if(!CollationIterator::operator==(other)) { return FALSE; }
	const FCDUTF16CollationIterator &o = static_cast<const FCDUTF16CollationIterator &>(other);
	// Compare the iterator state but not the text: Assume that the caller does that.
	if(checkDir != o.checkDir) { return FALSE; }
	if(checkDir == 0 && (start == segmentStart) != (o.start == o.segmentStart)) { return FALSE; }
	if(checkDir != 0 \|\| start == segmentStart) {
	return (pos - rawStart) == (o.pos - o.rawStart);
	} else {
	return (segmentStart - rawStart) == (o.segmentStart - o.rawStart) &&
	(pos - start) == (o.pos - o.start);
	}
	}

	void
	FCDUTF16CollationIterator::resetToOffset(int32_t newOffset) {
	reset();
	start = segmentStart = pos = rawStart + newOffset;
	limit = rawLimit;
	checkDir = 1;
	}

	int32_t
	FCDUTF16CollationIterator::getOffset() const {
	if(checkDir != 0 \|\| start == segmentStart) {
	return (int32_t)(pos - rawStart);
	} else if(pos == start) {
	return (int32_t)(segmentStart - rawStart);
	} else {
	return (int32_t)(segmentLimit - rawStart);
	}
	}

	uint32_t
	FCDUTF16CollationIterator::handleNextCE32(UChar32 &c, UErrorCode &errorCode) {
	for(;;) {
	if(checkDir > 0) {
	if(pos == limit) {
	c = U_SENTINEL;
	return Collation::FALLBACK_CE32;
	}
	c = *pos++;
	if(CollationFCD::hasTccc(c)) {
	if(CollationFCD::maybeTibetanCompositeVowel(c) \|\|
	(pos != limit && CollationFCD::hasLccc(*pos))) {
	--pos;
	if(!nextSegment(errorCode)) {
	c = U_SENTINEL;
	return Collation::FALLBACK_CE32;
	}
	c = *pos++;
	}
	}
	break;
	} else if(checkDir == 0 && pos != limit) {
	c = *pos++;
	break;
	} else {
	switchToForward();
	}
	}
	return UTRIE2_GET32_FROM_U16_SINGLE_LEAD(trie, c);
	}

	UBool
	FCDUTF16CollationIterator::foundNULTerminator() {
	if(limit == NULL) {
	limit = rawLimit = --pos;
	return TRUE;
	} else {
	return FALSE;
	}
	}

	UChar32
	FCDUTF16CollationIterator::nextCodePoint(UErrorCode &errorCode) {
	UChar32 c;
	for(;;) {
	if(checkDir > 0) {
	if(pos == limit) {
	return U_SENTINEL;
	}
	c = *pos++;
	if(CollationFCD::hasTccc(c)) {
	if(CollationFCD::maybeTibetanCompositeVowel(c) \|\|
	(pos != limit && CollationFCD::hasLccc(*pos))) {
	--pos;
	if(!nextSegment(errorCode)) {
	return U_SENTINEL;
	}
	c = *pos++;
	}
	} else if(c == 0 && limit == NULL) {
	limit = rawLimit = --pos;
	return U_SENTINEL;
	}
	break;
	} else if(checkDir == 0 && pos != limit) {
	c = *pos++;
	break;
	} else {
	switchToForward();
	}
	}
	UChar trail;
	if(U16_IS_LEAD(c) && pos != limit && U16_IS_TRAIL(trail = *pos)) {
	++pos;
	return U16_GET_SUPPLEMENTARY(c, trail);
	} else {
	return c;
	}
	}

	UChar32
	FCDUTF16CollationIterator::previousCodePoint(UErrorCode &errorCode) {
	UChar32 c;
	for(;;) {
	if(checkDir < 0) {
	if(pos == start) {
	return U_SENTINEL;
	}
	c = *--pos;
	if(CollationFCD::hasLccc(c)) {
	if(CollationFCD::maybeTibetanCompositeVowel(c) \|\|
	(pos != start && CollationFCD::hasTccc(*(pos - 1)))) {
	++pos;
	if(!previousSegment(errorCode)) {
	return U_SENTINEL;
	}
	c = *--pos;
	}
	}
	break;
	} else if(checkDir == 0 && pos != start) {
	c = *--pos;
	break;
	} else {
	switchToBackward();
	}
	}
	UChar lead;
	if(U16_IS_TRAIL(c) && pos != start && U16_IS_LEAD(lead = *(pos - 1))) {
	--pos;
	return U16_GET_SUPPLEMENTARY(lead, c);
	} else {
	return c;
	}
	}

	void
	FCDUTF16CollationIterator::forwardNumCodePoints(int32_t num, UErrorCode &errorCode) {
	// Specify the class to avoid a virtual-function indirection.
	// In Java, we would declare this class final.
	while(num > 0 && FCDUTF16CollationIterator::nextCodePoint(errorCode) >= 0) {
	--num;
	}
	}

	void
	FCDUTF16CollationIterator::backwardNumCodePoints(int32_t num, UErrorCode &errorCode) {
	// Specify the class to avoid a virtual-function indirection.
	// In Java, we would declare this class final.
	while(num > 0 && FCDUTF16CollationIterator::previousCodePoint(errorCode) >= 0) {
	--num;
	}
	}

	void
	FCDUTF16CollationIterator::switchToForward() {
	U_ASSERT(checkDir < 0 \|\| (checkDir == 0 && pos == limit));
	if(checkDir < 0) {
	// Turn around from backward checking.
	start = segmentStart = pos;
	if(pos == segmentLimit) {
	limit = rawLimit;
	checkDir = 1; // Check forward.
	} else { // pos < segmentLimit
	checkDir = 0; // Stay in FCD segment.
	}
	} else {
	// Reached the end of the FCD segment.
	if(start == segmentStart) {
	// The input text segment is FCD, extend it forward.
	} else {
	// The input text segment needed to be normalized.
	// Switch to checking forward from it.
	pos = start = segmentStart = segmentLimit;
	// Note: If this segment is at the end of the input text,
	// then it might help to return FALSE to indicate that, so that
	// we do not have to re-check and normalize when we turn around and go backwards.
	// However, that would complicate the call sites for an optimization of an unusual case.
	}
	limit = rawLimit;
	checkDir = 1;
	}
	}

	UBool
	FCDUTF16CollationIterator::nextSegment(UErrorCode &errorCode) {
	if(U_FAILURE(errorCode)) { return FALSE; }
	U_ASSERT(checkDir > 0 && pos != limit);
	// The input text [segmentStart..pos[ passes the FCD check.
	const UChar *p = pos;
	uint8_t prevCC = 0;
	for(;;) {
	// Fetch the next character's fcd16 value.
	const UChar *q = p;
	uint16_t fcd16 = nfcImpl.nextFCD16(p, rawLimit);
	uint8_t leadCC = (uint8_t)(fcd16 >> 8);
	if(leadCC == 0 && q != pos) {
	// FCD boundary before the [q, p[ character.
	limit = segmentLimit = q;
	break;
	}
	if(leadCC != 0 && (prevCC > leadCC \|\| CollationFCD::isFCD16OfTibetanCompositeVowel(fcd16))) {
	// Fails FCD check. Find the next FCD boundary and normalize.
	do {
	q = p;
	} while(p != rawLimit && nfcImpl.nextFCD16(p, rawLimit) > 0xff);
	if(!normalize(pos, q, errorCode)) { return FALSE; }
	pos = start;
	break;
	}
	prevCC = (uint8_t)fcd16;
	if(p == rawLimit \|\| prevCC == 0) {
	// FCD boundary after the last character.
	limit = segmentLimit = p;
	break;
	}
	}
	U_ASSERT(pos != limit);
	checkDir = 0;
	return TRUE;
	}

	void
	FCDUTF16CollationIterator::switchToBackward() {
	U_ASSERT(checkDir > 0 \|\| (checkDir == 0 && pos == start));
	if(checkDir > 0) {
	// Turn around from forward checking.
	limit = segmentLimit = pos;
	if(pos == segmentStart) {
	start = rawStart;
	checkDir = -1; // Check backward.
	} else { // pos > segmentStart
	checkDir = 0; // Stay in FCD segment.
	}
	} else {
	// Reached the start of the FCD segment.
	if(start == segmentStart) {
	// The input text segment is FCD, extend it backward.
	} else {
	// The input text segment needed to be normalized.
	// Switch to checking backward from it.
	pos = limit = segmentLimit = segmentStart;
	}
	start = rawStart;
	checkDir = -1;
	}
	}

	UBool
	FCDUTF16CollationIterator::previousSegment(UErrorCode &errorCode) {
	if(U_FAILURE(errorCode)) { return FALSE; }
	U_ASSERT(checkDir < 0 && pos != start);
	// The input text [pos..segmentLimit[ passes the FCD check.
	const UChar *p = pos;
	uint8_t nextCC = 0;
	for(;;) {
	// Fetch the previous character's fcd16 value.
	const UChar *q = p;
	uint16_t fcd16 = nfcImpl.previousFCD16(rawStart, p);
	uint8_t trailCC = (uint8_t)fcd16;
	if(trailCC == 0 && q != pos) {
	// FCD boundary after the [p, q[ character.
	start = segmentStart = q;
	break;
	}
	if(trailCC != 0 && ((nextCC != 0 && trailCC > nextCC) \|\|
	CollationFCD::isFCD16OfTibetanCompositeVowel(fcd16))) {
	// Fails FCD check. Find the previous FCD boundary and normalize.
	do {
	q = p;
	} while(fcd16 > 0xff && p != rawStart &&
	(fcd16 = nfcImpl.previousFCD16(rawStart, p)) != 0);
	if(!normalize(q, pos, errorCode)) { return FALSE; }
	pos = limit;
	break;
	}
	nextCC = (uint8_t)(fcd16 >> 8);
	if(p == rawStart \|\| nextCC == 0) {
	// FCD boundary before the following character.
	start = segmentStart = p;
	break;
	}
	}
	U_ASSERT(pos != start);
	checkDir = 0;
	return TRUE;
	}

	UBool
	FCDUTF16CollationIterator::normalize(const UChar from, const UChar to, UErrorCode &errorCode) {
	// NFD without argument checking.
	U_ASSERT(U_SUCCESS(errorCode));
	nfcImpl.decompose(from, to, normalized, (int32_t)(to - from), errorCode);
	if(U_FAILURE(errorCode)) { return FALSE; }
	// Switch collation processing into the FCD buffer
	// with the result of normalizing [segmentStart, segmentLimit[.
	segmentStart = from;
	segmentLimit = to;
	start = normalized.getBuffer();
	limit = start + normalized.length();
	return TRUE;
	}

	U_NAMESPACE_END

	#endif // !UCONFIG_NO_COLLATION