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641 lines
23 KiB
C++
641 lines
23 KiB
C++
// © 2016 and later: Unicode, Inc. and others.
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// License & terms of use: http://www.unicode.org/copyright.html
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/*
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*******************************************************************************
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*
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* Copyright (C) 2001-2014, International Business Machines
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* Corporation and others. All Rights Reserved.
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*
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*******************************************************************************
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* file name: unormcmp.cpp
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* encoding: UTF-8
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* tab size: 8 (not used)
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* indentation:4
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*
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* created on: 2004sep13
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* created by: Markus W. Scherer
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*
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* unorm_compare() function moved here from unorm.cpp for better modularization.
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* Depends on both normalization and case folding.
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* Allows unorm.cpp to not depend on any character properties code.
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*/
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#include "unicode/utypes.h"
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#if !UCONFIG_NO_NORMALIZATION
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#include "unicode/unorm.h"
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#include "unicode/ustring.h"
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#include "cmemory.h"
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#include "normalizer2impl.h"
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#include "ucase.h"
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#include "uprops.h"
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#include "ustr_imp.h"
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U_NAMESPACE_USE
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/* compare canonically equivalent ------------------------------------------- */
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/*
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* Compare two strings for canonical equivalence.
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* Further options include case-insensitive comparison and
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* code point order (as opposed to code unit order).
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*
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* In this function, canonical equivalence is optional as well.
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* If canonical equivalence is tested, then both strings must fulfill
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* the FCD check.
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*
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* Semantically, this is equivalent to
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* strcmp[CodePointOrder](NFD(foldCase(s1)), NFD(foldCase(s2)))
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* where code point order, NFD and foldCase are all optional.
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*
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* String comparisons almost always yield results before processing both strings
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* completely.
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* They are generally more efficient working incrementally instead of
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* performing the sub-processing (strlen, normalization, case-folding)
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* on the entire strings first.
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*
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* It is also unnecessary to not normalize identical characters.
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*
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* This function works in principle as follows:
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*
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* loop {
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* get one code unit c1 from s1 (-1 if end of source)
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* get one code unit c2 from s2 (-1 if end of source)
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*
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* if(either string finished) {
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* return result;
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* }
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* if(c1==c2) {
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* continue;
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* }
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*
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* // c1!=c2
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* try to decompose/case-fold c1/c2, and continue if one does;
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*
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* // still c1!=c2 and neither decomposes/case-folds, return result
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* return c1-c2;
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* }
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*
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* When a character decomposes, then the pointer for that source changes to
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* the decomposition, pushing the previous pointer onto a stack.
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* When the end of the decomposition is reached, then the code unit reader
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* pops the previous source from the stack.
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* (Same for case-folding.)
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*
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* This is complicated further by operating on variable-width UTF-16.
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* The top part of the loop works on code units, while lookups for decomposition
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* and case-folding need code points.
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* Code points are assembled after the equality/end-of-source part.
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* The source pointer is only advanced beyond all code units when the code point
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* actually decomposes/case-folds.
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*
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* If we were on a trail surrogate unit when assembling a code point,
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* and the code point decomposes/case-folds, then the decomposition/folding
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* result must be compared with the part of the other string that corresponds to
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* this string's lead surrogate.
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* Since we only assemble a code point when hitting a trail unit when the
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* preceding lead units were identical, we back up the other string by one unit
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* in such a case.
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*
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* The optional code point order comparison at the end works with
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* the same fix-up as the other code point order comparison functions.
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* See ustring.c and the comment near the end of this function.
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*
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* Assumption: A decomposition or case-folding result string never contains
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* a single surrogate. This is a safe assumption in the Unicode Standard.
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* Therefore, we do not need to check for surrogate pairs across
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* decomposition/case-folding boundaries.
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*
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* Further assumptions (see verifications tstnorm.cpp):
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* The API function checks for FCD first, while the core function
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* first case-folds and then decomposes. This requires that case-folding does not
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* un-FCD any strings.
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*
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* The API function may also NFD the input and turn off decomposition.
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* This requires that case-folding does not un-NFD strings either.
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*
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* TODO If any of the above two assumptions is violated,
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* then this entire code must be re-thought.
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* If this happens, then a simple solution is to case-fold both strings up front
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* and to turn off UNORM_INPUT_IS_FCD.
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* We already do this when not both strings are in FCD because makeFCD
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* would be a partial NFD before the case folding, which does not work.
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* Note that all of this is only a problem when case-folding _and_
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* canonical equivalence come together.
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* (Comments in unorm_compare() are more up to date than this TODO.)
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*/
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/* stack element for previous-level source/decomposition pointers */
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struct CmpEquivLevel {
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const UChar *start, *s, *limit;
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};
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typedef struct CmpEquivLevel CmpEquivLevel;
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/**
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* Internal option for unorm_cmpEquivFold() for decomposing.
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* If not set, just do strcasecmp().
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*/
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#define _COMPARE_EQUIV 0x80000
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/* internal function */
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static int32_t
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unorm_cmpEquivFold(const UChar *s1, int32_t length1,
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const UChar *s2, int32_t length2,
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uint32_t options,
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UErrorCode *pErrorCode) {
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const Normalizer2Impl *nfcImpl;
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/* current-level start/limit - s1/s2 as current */
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const UChar *start1, *start2, *limit1, *limit2;
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/* decomposition and case folding variables */
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const UChar *p;
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int32_t length;
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/* stacks of previous-level start/current/limit */
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CmpEquivLevel stack1[2], stack2[2];
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/* buffers for algorithmic decompositions */
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UChar decomp1[4], decomp2[4];
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/* case folding buffers, only use current-level start/limit */
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UChar fold1[UCASE_MAX_STRING_LENGTH+1], fold2[UCASE_MAX_STRING_LENGTH+1];
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/* track which is the current level per string */
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int32_t level1, level2;
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/* current code units, and code points for lookups */
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UChar32 c1, c2, cp1, cp2;
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/* no argument error checking because this itself is not an API */
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/*
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* assume that at least one of the options _COMPARE_EQUIV and U_COMPARE_IGNORE_CASE is set
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* otherwise this function must behave exactly as uprv_strCompare()
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* not checking for that here makes testing this function easier
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*/
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/* normalization/properties data loaded? */
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if((options&_COMPARE_EQUIV)!=0) {
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nfcImpl=Normalizer2Factory::getNFCImpl(*pErrorCode);
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} else {
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nfcImpl=NULL;
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}
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if(U_FAILURE(*pErrorCode)) {
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return 0;
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}
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/* initialize */
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start1=s1;
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if(length1==-1) {
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limit1=NULL;
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} else {
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limit1=s1+length1;
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}
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start2=s2;
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if(length2==-1) {
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limit2=NULL;
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} else {
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limit2=s2+length2;
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}
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level1=level2=0;
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c1=c2=-1;
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/* comparison loop */
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for(;;) {
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/*
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* here a code unit value of -1 means "get another code unit"
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* below it will mean "this source is finished"
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*/
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if(c1<0) {
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/* get next code unit from string 1, post-increment */
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for(;;) {
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if(s1==limit1 || ((c1=*s1)==0 && (limit1==NULL || (options&_STRNCMP_STYLE)))) {
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if(level1==0) {
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c1=-1;
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break;
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}
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} else {
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++s1;
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break;
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}
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/* reached end of level buffer, pop one level */
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do {
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--level1;
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start1=stack1[level1].start; /*Not uninitialized*/
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} while(start1==NULL);
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s1=stack1[level1].s; /*Not uninitialized*/
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limit1=stack1[level1].limit; /*Not uninitialized*/
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}
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}
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if(c2<0) {
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/* get next code unit from string 2, post-increment */
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for(;;) {
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if(s2==limit2 || ((c2=*s2)==0 && (limit2==NULL || (options&_STRNCMP_STYLE)))) {
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if(level2==0) {
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c2=-1;
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break;
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}
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} else {
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++s2;
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break;
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}
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/* reached end of level buffer, pop one level */
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do {
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--level2;
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start2=stack2[level2].start; /*Not uninitialized*/
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} while(start2==NULL);
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s2=stack2[level2].s; /*Not uninitialized*/
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limit2=stack2[level2].limit; /*Not uninitialized*/
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}
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}
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/*
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* compare c1 and c2
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* either variable c1, c2 is -1 only if the corresponding string is finished
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*/
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if(c1==c2) {
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if(c1<0) {
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return 0; /* c1==c2==-1 indicating end of strings */
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}
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c1=c2=-1; /* make us fetch new code units */
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continue;
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} else if(c1<0) {
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return -1; /* string 1 ends before string 2 */
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} else if(c2<0) {
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return 1; /* string 2 ends before string 1 */
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}
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/* c1!=c2 && c1>=0 && c2>=0 */
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/* get complete code points for c1, c2 for lookups if either is a surrogate */
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cp1=c1;
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if(U_IS_SURROGATE(c1)) {
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UChar c;
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if(U_IS_SURROGATE_LEAD(c1)) {
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if(s1!=limit1 && U16_IS_TRAIL(c=*s1)) {
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/* advance ++s1; only below if cp1 decomposes/case-folds */
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cp1=U16_GET_SUPPLEMENTARY(c1, c);
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}
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} else /* isTrail(c1) */ {
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if(start1<=(s1-2) && U16_IS_LEAD(c=*(s1-2))) {
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cp1=U16_GET_SUPPLEMENTARY(c, c1);
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}
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}
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}
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cp2=c2;
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if(U_IS_SURROGATE(c2)) {
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UChar c;
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if(U_IS_SURROGATE_LEAD(c2)) {
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if(s2!=limit2 && U16_IS_TRAIL(c=*s2)) {
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/* advance ++s2; only below if cp2 decomposes/case-folds */
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cp2=U16_GET_SUPPLEMENTARY(c2, c);
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}
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} else /* isTrail(c2) */ {
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if(start2<=(s2-2) && U16_IS_LEAD(c=*(s2-2))) {
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cp2=U16_GET_SUPPLEMENTARY(c, c2);
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}
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}
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}
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/*
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* go down one level for each string
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* continue with the main loop as soon as there is a real change
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*/
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if( level1==0 && (options&U_COMPARE_IGNORE_CASE) &&
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(length=ucase_toFullFolding((UChar32)cp1, &p, options))>=0
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) {
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/* cp1 case-folds to the code point "length" or to p[length] */
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if(U_IS_SURROGATE(c1)) {
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if(U_IS_SURROGATE_LEAD(c1)) {
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/* advance beyond source surrogate pair if it case-folds */
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++s1;
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} else /* isTrail(c1) */ {
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/*
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* we got a supplementary code point when hitting its trail surrogate,
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* therefore the lead surrogate must have been the same as in the other string;
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* compare this decomposition with the lead surrogate in the other string
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* remember that this simulates bulk text replacement:
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* the decomposition would replace the entire code point
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*/
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--s2;
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c2=*(s2-1);
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}
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}
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/* push current level pointers */
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stack1[0].start=start1;
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stack1[0].s=s1;
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stack1[0].limit=limit1;
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++level1;
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/* copy the folding result to fold1[] */
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if(length<=UCASE_MAX_STRING_LENGTH) {
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u_memcpy(fold1, p, length);
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} else {
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int32_t i=0;
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U16_APPEND_UNSAFE(fold1, i, length);
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length=i;
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}
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/* set next level pointers to case folding */
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start1=s1=fold1;
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limit1=fold1+length;
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/* get ready to read from decomposition, continue with loop */
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c1=-1;
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continue;
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}
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if( level2==0 && (options&U_COMPARE_IGNORE_CASE) &&
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(length=ucase_toFullFolding((UChar32)cp2, &p, options))>=0
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) {
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/* cp2 case-folds to the code point "length" or to p[length] */
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if(U_IS_SURROGATE(c2)) {
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if(U_IS_SURROGATE_LEAD(c2)) {
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/* advance beyond source surrogate pair if it case-folds */
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++s2;
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} else /* isTrail(c2) */ {
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/*
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* we got a supplementary code point when hitting its trail surrogate,
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* therefore the lead surrogate must have been the same as in the other string;
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* compare this decomposition with the lead surrogate in the other string
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* remember that this simulates bulk text replacement:
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* the decomposition would replace the entire code point
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*/
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--s1;
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c1=*(s1-1);
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}
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}
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/* push current level pointers */
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stack2[0].start=start2;
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stack2[0].s=s2;
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stack2[0].limit=limit2;
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++level2;
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/* copy the folding result to fold2[] */
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if(length<=UCASE_MAX_STRING_LENGTH) {
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u_memcpy(fold2, p, length);
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} else {
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int32_t i=0;
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U16_APPEND_UNSAFE(fold2, i, length);
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length=i;
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}
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/* set next level pointers to case folding */
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start2=s2=fold2;
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limit2=fold2+length;
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/* get ready to read from decomposition, continue with loop */
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c2=-1;
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continue;
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}
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if( level1<2 && (options&_COMPARE_EQUIV) &&
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0!=(p=nfcImpl->getDecomposition((UChar32)cp1, decomp1, length))
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) {
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/* cp1 decomposes into p[length] */
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if(U_IS_SURROGATE(c1)) {
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if(U_IS_SURROGATE_LEAD(c1)) {
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/* advance beyond source surrogate pair if it decomposes */
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++s1;
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} else /* isTrail(c1) */ {
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/*
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* we got a supplementary code point when hitting its trail surrogate,
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* therefore the lead surrogate must have been the same as in the other string;
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* compare this decomposition with the lead surrogate in the other string
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* remember that this simulates bulk text replacement:
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* the decomposition would replace the entire code point
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*/
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--s2;
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c2=*(s2-1);
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}
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}
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/* push current level pointers */
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stack1[level1].start=start1;
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stack1[level1].s=s1;
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stack1[level1].limit=limit1;
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++level1;
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/* set empty intermediate level if skipped */
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if(level1<2) {
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stack1[level1++].start=NULL;
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}
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/* set next level pointers to decomposition */
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start1=s1=p;
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limit1=p+length;
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/* get ready to read from decomposition, continue with loop */
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c1=-1;
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continue;
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}
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if( level2<2 && (options&_COMPARE_EQUIV) &&
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0!=(p=nfcImpl->getDecomposition((UChar32)cp2, decomp2, length))
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) {
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/* cp2 decomposes into p[length] */
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if(U_IS_SURROGATE(c2)) {
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if(U_IS_SURROGATE_LEAD(c2)) {
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/* advance beyond source surrogate pair if it decomposes */
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++s2;
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} else /* isTrail(c2) */ {
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/*
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* we got a supplementary code point when hitting its trail surrogate,
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* therefore the lead surrogate must have been the same as in the other string;
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* compare this decomposition with the lead surrogate in the other string
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* remember that this simulates bulk text replacement:
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* the decomposition would replace the entire code point
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*/
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--s1;
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c1=*(s1-1);
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}
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}
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/* push current level pointers */
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stack2[level2].start=start2;
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stack2[level2].s=s2;
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stack2[level2].limit=limit2;
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++level2;
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/* set empty intermediate level if skipped */
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if(level2<2) {
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stack2[level2++].start=NULL;
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}
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/* set next level pointers to decomposition */
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start2=s2=p;
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limit2=p+length;
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/* get ready to read from decomposition, continue with loop */
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c2=-1;
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continue;
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}
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/*
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* no decomposition/case folding, max level for both sides:
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* return difference result
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*
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* code point order comparison must not just return cp1-cp2
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* because when single surrogates are present then the surrogate pairs
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* that formed cp1 and cp2 may be from different string indexes
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*
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* example: { d800 d800 dc01 } vs. { d800 dc00 }, compare at second code units
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* c1=d800 cp1=10001 c2=dc00 cp2=10000
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* cp1-cp2>0 but c1-c2<0 and in fact in UTF-32 it is { d800 10001 } < { 10000 }
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*
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* therefore, use same fix-up as in ustring.c/uprv_strCompare()
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* except: uprv_strCompare() fetches c=*s while this functions fetches c=*s++
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* so we have slightly different pointer/start/limit comparisons here
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*/
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if(c1>=0xd800 && c2>=0xd800 && (options&U_COMPARE_CODE_POINT_ORDER)) {
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/* subtract 0x2800 from BMP code points to make them smaller than supplementary ones */
|
|
if(
|
|
(c1<=0xdbff && s1!=limit1 && U16_IS_TRAIL(*s1)) ||
|
|
(U16_IS_TRAIL(c1) && start1!=(s1-1) && U16_IS_LEAD(*(s1-2)))
|
|
) {
|
|
/* part of a surrogate pair, leave >=d800 */
|
|
} else {
|
|
/* BMP code point - may be surrogate code point - make <d800 */
|
|
c1-=0x2800;
|
|
}
|
|
|
|
if(
|
|
(c2<=0xdbff && s2!=limit2 && U16_IS_TRAIL(*s2)) ||
|
|
(U16_IS_TRAIL(c2) && start2!=(s2-1) && U16_IS_LEAD(*(s2-2)))
|
|
) {
|
|
/* part of a surrogate pair, leave >=d800 */
|
|
} else {
|
|
/* BMP code point - may be surrogate code point - make <d800 */
|
|
c2-=0x2800;
|
|
}
|
|
}
|
|
|
|
return c1-c2;
|
|
}
|
|
}
|
|
|
|
static
|
|
UBool _normalize(const Normalizer2 *n2, const UChar *s, int32_t length,
|
|
UnicodeString &normalized, UErrorCode *pErrorCode) {
|
|
UnicodeString str(length<0, s, length);
|
|
|
|
// check if s fulfill the conditions
|
|
int32_t spanQCYes=n2->spanQuickCheckYes(str, *pErrorCode);
|
|
if (U_FAILURE(*pErrorCode)) {
|
|
return FALSE;
|
|
}
|
|
/*
|
|
* ICU 2.4 had a further optimization:
|
|
* If both strings were not in FCD, then they were both NFD'ed,
|
|
* and the _COMPARE_EQUIV option was turned off.
|
|
* It is not entirely clear that this is valid with the current
|
|
* definition of the canonical caseless match.
|
|
* Therefore, ICU 2.6 removes that optimization.
|
|
*/
|
|
if(spanQCYes<str.length()) {
|
|
UnicodeString unnormalized=str.tempSubString(spanQCYes);
|
|
normalized.setTo(FALSE, str.getBuffer(), spanQCYes);
|
|
n2->normalizeSecondAndAppend(normalized, unnormalized, *pErrorCode);
|
|
if (U_SUCCESS(*pErrorCode)) {
|
|
return TRUE;
|
|
}
|
|
}
|
|
return FALSE;
|
|
}
|
|
|
|
U_CAPI int32_t U_EXPORT2
|
|
unorm_compare(const UChar *s1, int32_t length1,
|
|
const UChar *s2, int32_t length2,
|
|
uint32_t options,
|
|
UErrorCode *pErrorCode) {
|
|
/* argument checking */
|
|
if(U_FAILURE(*pErrorCode)) {
|
|
return 0;
|
|
}
|
|
if(s1==0 || length1<-1 || s2==0 || length2<-1) {
|
|
*pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
|
|
return 0;
|
|
}
|
|
|
|
UnicodeString fcd1, fcd2;
|
|
int32_t normOptions=(int32_t)(options>>UNORM_COMPARE_NORM_OPTIONS_SHIFT);
|
|
options|=_COMPARE_EQUIV;
|
|
|
|
/*
|
|
* UAX #21 Case Mappings, as fixed for Unicode version 4
|
|
* (see Jitterbug 2021), defines a canonical caseless match as
|
|
*
|
|
* A string X is a canonical caseless match
|
|
* for a string Y if and only if
|
|
* NFD(toCasefold(NFD(X))) = NFD(toCasefold(NFD(Y)))
|
|
*
|
|
* For better performance, we check for FCD (or let the caller tell us that
|
|
* both strings are in FCD) for the inner normalization.
|
|
* BasicNormalizerTest::FindFoldFCDExceptions() makes sure that
|
|
* case-folding preserves the FCD-ness of a string.
|
|
* The outer normalization is then only performed by unorm_cmpEquivFold()
|
|
* when there is a difference.
|
|
*
|
|
* Exception: When using the Turkic case-folding option, we do perform
|
|
* full NFD first. This is because in the Turkic case precomposed characters
|
|
* with 0049 capital I or 0069 small i fold differently whether they
|
|
* are first decomposed or not, so an FCD check - a check only for
|
|
* canonical order - is not sufficient.
|
|
*/
|
|
if(!(options&UNORM_INPUT_IS_FCD) || (options&U_FOLD_CASE_EXCLUDE_SPECIAL_I)) {
|
|
const Normalizer2 *n2;
|
|
if(options&U_FOLD_CASE_EXCLUDE_SPECIAL_I) {
|
|
n2=Normalizer2::getNFDInstance(*pErrorCode);
|
|
} else {
|
|
n2=Normalizer2Factory::getFCDInstance(*pErrorCode);
|
|
}
|
|
if (U_FAILURE(*pErrorCode)) {
|
|
return 0;
|
|
}
|
|
|
|
if(normOptions&UNORM_UNICODE_3_2) {
|
|
const UnicodeSet *uni32=uniset_getUnicode32Instance(*pErrorCode);
|
|
FilteredNormalizer2 fn2(*n2, *uni32);
|
|
if(_normalize(&fn2, s1, length1, fcd1, pErrorCode)) {
|
|
s1=fcd1.getBuffer();
|
|
length1=fcd1.length();
|
|
}
|
|
if(_normalize(&fn2, s2, length2, fcd2, pErrorCode)) {
|
|
s2=fcd2.getBuffer();
|
|
length2=fcd2.length();
|
|
}
|
|
} else {
|
|
if(_normalize(n2, s1, length1, fcd1, pErrorCode)) {
|
|
s1=fcd1.getBuffer();
|
|
length1=fcd1.length();
|
|
}
|
|
if(_normalize(n2, s2, length2, fcd2, pErrorCode)) {
|
|
s2=fcd2.getBuffer();
|
|
length2=fcd2.length();
|
|
}
|
|
}
|
|
}
|
|
|
|
if(U_SUCCESS(*pErrorCode)) {
|
|
return unorm_cmpEquivFold(s1, length1, s2, length2, options, pErrorCode);
|
|
} else {
|
|
return 0;
|
|
}
|
|
}
|
|
|
|
#endif /* #if !UCONFIG_NO_NORMALIZATION */
|