523cbcd1dc
X-SVN-Rev: 41386
479 lines
17 KiB
C++
479 lines
17 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) 2008-2015, 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: uspoof_conf.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: 2009Jan05 (refactoring earlier files)
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* created by: Andy Heninger
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*
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* Internal classes for compililing confusable data into its binary (runtime) form.
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*/
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#include "unicode/utypes.h"
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#include "unicode/uspoof.h"
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#if !UCONFIG_NO_REGULAR_EXPRESSIONS
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#if !UCONFIG_NO_NORMALIZATION
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#include "unicode/unorm.h"
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#include "unicode/uregex.h"
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#include "unicode/ustring.h"
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#include "cmemory.h"
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#include "uspoof_impl.h"
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#include "uhash.h"
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#include "uvector.h"
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#include "uassert.h"
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#include "uarrsort.h"
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#include "uspoof_conf.h"
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U_NAMESPACE_USE
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//---------------------------------------------------------------------
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//
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// buildConfusableData Compile the source confusable data, as defined by
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// the Unicode data file confusables.txt, into the binary
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// structures used by the confusable detector.
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//
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// The binary structures are described in uspoof_impl.h
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//
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// 1. Parse the data, making a hash table mapping from a UChar32 to a String.
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//
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// 2. Sort all of the strings encountered by length, since they will need to
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// be stored in that order in the final string table.
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// TODO: Sorting these strings by length is no longer needed since the removal of
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// the string lengths table. This logic can be removed to save processing time
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// when building confusables data.
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//
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// 3. Build a list of keys (UChar32s) from the four mapping tables. Sort the
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// list because that will be the ordering of our runtime table.
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//
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// 4. Generate the run time string table. This is generated before the key & value
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// tables because we need the string indexes when building those tables.
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//
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// 5. Build the run-time key and value tables. These are parallel tables, and are built
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// at the same time
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//
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SPUString::SPUString(UnicodeString *s) {
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fStr = s;
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fCharOrStrTableIndex = 0;
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}
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SPUString::~SPUString() {
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delete fStr;
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}
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SPUStringPool::SPUStringPool(UErrorCode &status) : fVec(NULL), fHash(NULL) {
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fVec = new UVector(status);
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if (fVec == NULL) {
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status = U_MEMORY_ALLOCATION_ERROR;
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return;
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}
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fHash = uhash_open(uhash_hashUnicodeString, // key hash function
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uhash_compareUnicodeString, // Key Comparator
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NULL, // Value Comparator
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&status);
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}
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SPUStringPool::~SPUStringPool() {
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int i;
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for (i=fVec->size()-1; i>=0; i--) {
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SPUString *s = static_cast<SPUString *>(fVec->elementAt(i));
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delete s;
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}
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delete fVec;
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uhash_close(fHash);
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}
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int32_t SPUStringPool::size() {
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return fVec->size();
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}
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SPUString *SPUStringPool::getByIndex(int32_t index) {
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SPUString *retString = (SPUString *)fVec->elementAt(index);
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return retString;
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}
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// Comparison function for ordering strings in the string pool.
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// Compare by length first, then, within a group of the same length,
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// by code point order.
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// Conforms to the type signature for a USortComparator in uvector.h
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static int8_t U_CALLCONV SPUStringCompare(UHashTok left, UHashTok right) {
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const SPUString *sL = const_cast<const SPUString *>(
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static_cast<SPUString *>(left.pointer));
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const SPUString *sR = const_cast<const SPUString *>(
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static_cast<SPUString *>(right.pointer));
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int32_t lenL = sL->fStr->length();
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int32_t lenR = sR->fStr->length();
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if (lenL < lenR) {
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return -1;
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} else if (lenL > lenR) {
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return 1;
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} else {
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return sL->fStr->compare(*(sR->fStr));
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}
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}
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void SPUStringPool::sort(UErrorCode &status) {
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fVec->sort(SPUStringCompare, status);
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}
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SPUString *SPUStringPool::addString(UnicodeString *src, UErrorCode &status) {
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SPUString *hashedString = static_cast<SPUString *>(uhash_get(fHash, src));
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if (hashedString != NULL) {
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delete src;
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} else {
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hashedString = new SPUString(src);
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if (hashedString == NULL) {
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status = U_MEMORY_ALLOCATION_ERROR;
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return NULL;
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}
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uhash_put(fHash, src, hashedString, &status);
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fVec->addElement(hashedString, status);
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}
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return hashedString;
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}
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ConfusabledataBuilder::ConfusabledataBuilder(SpoofImpl *spImpl, UErrorCode &status) :
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fSpoofImpl(spImpl),
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fInput(NULL),
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fTable(NULL),
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fKeySet(NULL),
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fKeyVec(NULL),
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fValueVec(NULL),
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fStringTable(NULL),
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stringPool(NULL),
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fParseLine(NULL),
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fParseHexNum(NULL),
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fLineNum(0)
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{
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if (U_FAILURE(status)) {
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return;
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}
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fTable = uhash_open(uhash_hashLong, uhash_compareLong, NULL, &status);
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fKeySet = new UnicodeSet();
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if (fKeySet == NULL) {
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status = U_MEMORY_ALLOCATION_ERROR;
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return;
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}
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fKeyVec = new UVector(status);
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if (fKeyVec == NULL) {
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status = U_MEMORY_ALLOCATION_ERROR;
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return;
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}
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fValueVec = new UVector(status);
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if (fValueVec == NULL) {
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status = U_MEMORY_ALLOCATION_ERROR;
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return;
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}
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stringPool = new SPUStringPool(status);
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if (stringPool == NULL) {
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status = U_MEMORY_ALLOCATION_ERROR;
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return;
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}
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}
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ConfusabledataBuilder::~ConfusabledataBuilder() {
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uprv_free(fInput);
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uregex_close(fParseLine);
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uregex_close(fParseHexNum);
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uhash_close(fTable);
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delete fKeySet;
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delete fKeyVec;
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delete fStringTable;
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delete fValueVec;
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delete stringPool;
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}
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void ConfusabledataBuilder::buildConfusableData(SpoofImpl * spImpl, const char * confusables,
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int32_t confusablesLen, int32_t *errorType, UParseError *pe, UErrorCode &status) {
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if (U_FAILURE(status)) {
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return;
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}
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ConfusabledataBuilder builder(spImpl, status);
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builder.build(confusables, confusablesLen, status);
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if (U_FAILURE(status) && errorType != NULL) {
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*errorType = USPOOF_SINGLE_SCRIPT_CONFUSABLE;
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pe->line = builder.fLineNum;
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}
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}
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void ConfusabledataBuilder::build(const char * confusables, int32_t confusablesLen,
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UErrorCode &status) {
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// Convert the user input data from UTF-8 to UChar (UTF-16)
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int32_t inputLen = 0;
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if (U_FAILURE(status)) {
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return;
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}
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u_strFromUTF8(NULL, 0, &inputLen, confusables, confusablesLen, &status);
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if (status != U_BUFFER_OVERFLOW_ERROR) {
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return;
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}
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status = U_ZERO_ERROR;
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fInput = static_cast<UChar *>(uprv_malloc((inputLen+1) * sizeof(UChar)));
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if (fInput == NULL) {
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status = U_MEMORY_ALLOCATION_ERROR;
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return;
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}
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u_strFromUTF8(fInput, inputLen+1, NULL, confusables, confusablesLen, &status);
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// Regular Expression to parse a line from Confusables.txt. The expression will match
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// any line. What was matched is determined by examining which capture groups have a match.
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// Capture Group 1: the source char
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// Capture Group 2: the replacement chars
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// Capture Group 3-6 the table type, SL, SA, ML, or MA (deprecated)
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// Capture Group 7: A blank or comment only line.
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// Capture Group 8: A syntactically invalid line. Anything that didn't match before.
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// Example Line from the confusables.txt source file:
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// "1D702 ; 006E 0329 ; SL # MATHEMATICAL ITALIC SMALL ETA ... "
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UnicodeString pattern(
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"(?m)^[ \\t]*([0-9A-Fa-f]+)[ \\t]+;" // Match the source char
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"[ \\t]*([0-9A-Fa-f]+" // Match the replacement char(s)
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"(?:[ \\t]+[0-9A-Fa-f]+)*)[ \\t]*;" // (continued)
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"\\s*(?:(SL)|(SA)|(ML)|(MA))" // Match the table type
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"[ \\t]*(?:#.*?)?$" // Match any trailing #comment
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"|^([ \\t]*(?:#.*?)?)$" // OR match empty lines or lines with only a #comment
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"|^(.*?)$", -1, US_INV); // OR match any line, which catches illegal lines.
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// TODO: Why are we using the regex C API here? C++ would just take UnicodeString...
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fParseLine = uregex_open(pattern.getBuffer(), pattern.length(), 0, NULL, &status);
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// Regular expression for parsing a hex number out of a space-separated list of them.
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// Capture group 1 gets the number, with spaces removed.
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pattern = UNICODE_STRING_SIMPLE("\\s*([0-9A-F]+)");
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fParseHexNum = uregex_open(pattern.getBuffer(), pattern.length(), 0, NULL, &status);
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// Zap any Byte Order Mark at the start of input. Changing it to a space is benign
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// given the syntax of the input.
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if (*fInput == 0xfeff) {
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*fInput = 0x20;
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}
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// Parse the input, one line per iteration of this loop.
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uregex_setText(fParseLine, fInput, inputLen, &status);
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while (uregex_findNext(fParseLine, &status)) {
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fLineNum++;
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if (uregex_start(fParseLine, 7, &status) >= 0) {
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// this was a blank or comment line.
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continue;
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}
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if (uregex_start(fParseLine, 8, &status) >= 0) {
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// input file syntax error.
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status = U_PARSE_ERROR;
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return;
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}
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// We have a good input line. Extract the key character and mapping string, and
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// put them into the appropriate mapping table.
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UChar32 keyChar = SpoofImpl::ScanHex(fInput, uregex_start(fParseLine, 1, &status),
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uregex_end(fParseLine, 1, &status), status);
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int32_t mapStringStart = uregex_start(fParseLine, 2, &status);
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int32_t mapStringLength = uregex_end(fParseLine, 2, &status) - mapStringStart;
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uregex_setText(fParseHexNum, &fInput[mapStringStart], mapStringLength, &status);
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UnicodeString *mapString = new UnicodeString();
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if (mapString == NULL) {
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status = U_MEMORY_ALLOCATION_ERROR;
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return;
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}
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while (uregex_findNext(fParseHexNum, &status)) {
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UChar32 c = SpoofImpl::ScanHex(&fInput[mapStringStart], uregex_start(fParseHexNum, 1, &status),
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uregex_end(fParseHexNum, 1, &status), status);
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mapString->append(c);
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}
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U_ASSERT(mapString->length() >= 1);
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// Put the map (value) string into the string pool
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// This a little like a Java intern() - any duplicates will be eliminated.
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SPUString *smapString = stringPool->addString(mapString, status);
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// Add the UChar32 -> string mapping to the table.
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// For Unicode 8, the SL, SA and ML tables have been discontinued.
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// All input data from confusables.txt is tagged MA.
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uhash_iput(fTable, keyChar, smapString, &status);
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if (U_FAILURE(status)) { return; }
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fKeySet->add(keyChar);
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}
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// Input data is now all parsed and collected.
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// Now create the run-time binary form of the data.
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//
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// This is done in two steps. First the data is assembled into vectors and strings,
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// for ease of construction, then the contents of these collections are dumped
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// into the actual raw-bytes data storage.
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// Build up the string array, and record the index of each string therein
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// in the (build time only) string pool.
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// Strings of length one are not entered into the strings array.
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// (Strings in the table are sorted by length)
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stringPool->sort(status);
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fStringTable = new UnicodeString();
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int32_t poolSize = stringPool->size();
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int32_t i;
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for (i=0; i<poolSize; i++) {
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SPUString *s = stringPool->getByIndex(i);
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int32_t strLen = s->fStr->length();
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int32_t strIndex = fStringTable->length();
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if (strLen == 1) {
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// strings of length one do not get an entry in the string table.
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// Keep the single string character itself here, which is the same
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// convention that is used in the final run-time string table index.
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s->fCharOrStrTableIndex = s->fStr->charAt(0);
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} else {
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s->fCharOrStrTableIndex = strIndex;
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fStringTable->append(*(s->fStr));
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}
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}
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// Construct the compile-time Key and Value tables
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//
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// For each key code point, check which mapping tables it applies to,
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// and create the final data for the key & value structures.
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//
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// The four logical mapping tables are conflated into one combined table.
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// If multiple logical tables have the same mapping for some key, they
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// share a single entry in the combined table.
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// If more than one mapping exists for the same key code point, multiple
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// entries will be created in the table
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for (int32_t range=0; range<fKeySet->getRangeCount(); range++) {
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// It is an oddity of the UnicodeSet API that simply enumerating the contained
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// code points requires a nested loop.
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for (UChar32 keyChar=fKeySet->getRangeStart(range);
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keyChar <= fKeySet->getRangeEnd(range); keyChar++) {
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SPUString *targetMapping = static_cast<SPUString *>(uhash_iget(fTable, keyChar));
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U_ASSERT(targetMapping != NULL);
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// Set an error code if trying to consume a long string. Otherwise,
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// codePointAndLengthToKey will abort on a U_ASSERT.
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if (targetMapping->fStr->length() > 256) {
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status = U_ILLEGAL_ARGUMENT_ERROR;
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return;
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}
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int32_t key = ConfusableDataUtils::codePointAndLengthToKey(keyChar,
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targetMapping->fStr->length());
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int32_t value = targetMapping->fCharOrStrTableIndex;
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fKeyVec->addElement(key, status);
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fValueVec->addElement(value, status);
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}
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}
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// Put the assembled data into the flat runtime array
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outputData(status);
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// All of the intermediate allocated data belongs to the ConfusabledataBuilder
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// object (this), and is deleted in the destructor.
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return;
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}
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//
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// outputData The confusable data has been compiled and stored in intermediate
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// collections and strings. Copy it from there to the final flat
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// binary array.
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//
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// Note that as each section is added to the output data, the
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// expand (reserveSpace() function will likely relocate it in memory.
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// Be careful with pointers.
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//
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void ConfusabledataBuilder::outputData(UErrorCode &status) {
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U_ASSERT(fSpoofImpl->fSpoofData->fDataOwned == TRUE);
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// The Key Table
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// While copying the keys to the runtime array,
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// also sanity check that they are sorted.
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int32_t numKeys = fKeyVec->size();
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int32_t *keys =
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static_cast<int32_t *>(fSpoofImpl->fSpoofData->reserveSpace(numKeys*sizeof(int32_t), status));
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if (U_FAILURE(status)) {
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return;
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}
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int i;
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UChar32 previousCodePoint = 0;
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for (i=0; i<numKeys; i++) {
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int32_t key = fKeyVec->elementAti(i);
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UChar32 codePoint = ConfusableDataUtils::keyToCodePoint(key);
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(void)previousCodePoint; // Suppress unused variable warning.
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// strictly greater because there can be only one entry per code point
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U_ASSERT(codePoint > previousCodePoint);
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keys[i] = key;
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previousCodePoint = codePoint;
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}
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SpoofDataHeader *rawData = fSpoofImpl->fSpoofData->fRawData;
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rawData->fCFUKeys = (int32_t)((char *)keys - (char *)rawData);
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rawData->fCFUKeysSize = numKeys;
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fSpoofImpl->fSpoofData->fCFUKeys = keys;
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// The Value Table, parallels the key table
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int32_t numValues = fValueVec->size();
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U_ASSERT(numKeys == numValues);
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uint16_t *values =
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static_cast<uint16_t *>(fSpoofImpl->fSpoofData->reserveSpace(numKeys*sizeof(uint16_t), status));
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if (U_FAILURE(status)) {
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return;
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}
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for (i=0; i<numValues; i++) {
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uint32_t value = static_cast<uint32_t>(fValueVec->elementAti(i));
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U_ASSERT(value < 0xffff);
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values[i] = static_cast<uint16_t>(value);
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}
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rawData = fSpoofImpl->fSpoofData->fRawData;
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rawData->fCFUStringIndex = (int32_t)((char *)values - (char *)rawData);
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rawData->fCFUStringIndexSize = numValues;
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fSpoofImpl->fSpoofData->fCFUValues = values;
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// The Strings Table.
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uint32_t stringsLength = fStringTable->length();
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// Reserve an extra space so the string will be nul-terminated. This is
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// only a convenience, for when debugging; it is not needed otherwise.
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UChar *strings =
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static_cast<UChar *>(fSpoofImpl->fSpoofData->reserveSpace(stringsLength*sizeof(UChar)+2, status));
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if (U_FAILURE(status)) {
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return;
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}
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fStringTable->extract(strings, stringsLength+1, status);
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rawData = fSpoofImpl->fSpoofData->fRawData;
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U_ASSERT(rawData->fCFUStringTable == 0);
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rawData->fCFUStringTable = (int32_t)((char *)strings - (char *)rawData);
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rawData->fCFUStringTableLen = stringsLength;
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fSpoofImpl->fSpoofData->fCFUStrings = strings;
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}
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#endif
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#endif // !UCONFIG_NO_REGULAR_EXPRESSIONS
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