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1 /*
2 ******************************************************************************
3 *
4 *   Copyright (C) 2008-2015, International Business Machines
5 *   Corporation and others.  All Rights Reserved.
6 *
7 ******************************************************************************
8 *   file name:  uspoof_conf.cpp
9 *   encoding:   US-ASCII
10 *   tab size:   8 (not used)
11 *   indentation:4
12 *
13 *   created on: 2009Jan05  (refactoring earlier files)
14 *   created by: Andy Heninger
15 *
16 *   Internal classes for compililing confusable data into its binary (runtime) form.
17 */
18 
19 #include "unicode/utypes.h"
20 #include "unicode/uspoof.h"
21 #if !UCONFIG_NO_REGULAR_EXPRESSIONS
22 #if !UCONFIG_NO_NORMALIZATION
23 
24 #include "unicode/unorm.h"
25 #include "unicode/uregex.h"
26 #include "unicode/ustring.h"
27 #include "cmemory.h"
28 #include "uspoof_impl.h"
29 #include "uhash.h"
30 #include "uvector.h"
31 #include "uassert.h"
32 #include "uarrsort.h"
33 #include "uspoof_conf.h"
34 
35 U_NAMESPACE_USE
36 
37 
38 //---------------------------------------------------------------------
39 //
40 //  buildConfusableData   Compile the source confusable data, as defined by
41 //                        the Unicode data file confusables.txt, into the binary
42 //                        structures used by the confusable detector.
43 //
44 //                        The binary structures are described in uspoof_impl.h
45 //
46 //     1.  parse the data, building 4 hash tables, one each for the SL, SA, ML and MA
47 //         tables.  Each maps from a UChar32 to a String.
48 //
49 //     2.  Sort all of the strings encountered by length, since they will need to
50 //         be stored in that order in the final string table.
51 //
52 //     3.  Build a list of keys (UChar32s) from the four mapping tables.  Sort the
53 //         list because that will be the ordering of our runtime table.
54 //
55 //     4.  Generate the run time string table.  This is generated before the key & value
56 //         tables because we need the string indexes when building those tables.
57 //
58 //     5.  Build the run-time key and value tables.  These are parallel tables, and are built
59 //         at the same time
60 //
61 
SPUString(UnicodeString * s)62 SPUString::SPUString(UnicodeString *s) {
63     fStr = s;
64     fStrTableIndex = 0;
65 }
66 
67 
~SPUString()68 SPUString::~SPUString() {
69     delete fStr;
70 }
71 
72 
SPUStringPool(UErrorCode & status)73 SPUStringPool::SPUStringPool(UErrorCode &status) : fVec(NULL), fHash(NULL) {
74     fVec = new UVector(status);
75     fHash = uhash_open(uhash_hashUnicodeString,           // key hash function
76                        uhash_compareUnicodeString,        // Key Comparator
77                        NULL,                              // Value Comparator
78                        &status);
79 }
80 
81 
~SPUStringPool()82 SPUStringPool::~SPUStringPool() {
83     int i;
84     for (i=fVec->size()-1; i>=0; i--) {
85         SPUString *s = static_cast<SPUString *>(fVec->elementAt(i));
86         delete s;
87     }
88     delete fVec;
89     uhash_close(fHash);
90 }
91 
92 
size()93 int32_t SPUStringPool::size() {
94     return fVec->size();
95 }
96 
getByIndex(int32_t index)97 SPUString *SPUStringPool::getByIndex(int32_t index) {
98     SPUString *retString = (SPUString *)fVec->elementAt(index);
99     return retString;
100 }
101 
102 
103 // Comparison function for ordering strings in the string pool.
104 // Compare by length first, then, within a group of the same length,
105 // by code point order.
106 // Conforms to the type signature for a USortComparator in uvector.h
107 
SPUStringCompare(UHashTok left,UHashTok right)108 static int8_t U_CALLCONV SPUStringCompare(UHashTok left, UHashTok right) {
109 	const SPUString *sL = const_cast<const SPUString *>(
110         static_cast<SPUString *>(left.pointer));
111  	const SPUString *sR = const_cast<const SPUString *>(
112  	    static_cast<SPUString *>(right.pointer));
113     int32_t lenL = sL->fStr->length();
114     int32_t lenR = sR->fStr->length();
115     if (lenL < lenR) {
116         return -1;
117     } else if (lenL > lenR) {
118         return 1;
119     } else {
120         return sL->fStr->compare(*(sR->fStr));
121     }
122 }
123 
sort(UErrorCode & status)124 void SPUStringPool::sort(UErrorCode &status) {
125     fVec->sort(SPUStringCompare, status);
126 }
127 
128 
addString(UnicodeString * src,UErrorCode & status)129 SPUString *SPUStringPool::addString(UnicodeString *src, UErrorCode &status) {
130     SPUString *hashedString = static_cast<SPUString *>(uhash_get(fHash, src));
131     if (hashedString != NULL) {
132         delete src;
133     } else {
134         hashedString = new SPUString(src);
135         uhash_put(fHash, src, hashedString, &status);
136         fVec->addElement(hashedString, status);
137     }
138     return hashedString;
139 }
140 
141 
142 
ConfusabledataBuilder(SpoofImpl * spImpl,UErrorCode & status)143 ConfusabledataBuilder::ConfusabledataBuilder(SpoofImpl *spImpl, UErrorCode &status) :
144     fSpoofImpl(spImpl),
145     fInput(NULL),
146     fSLTable(NULL),
147     fSATable(NULL),
148     fMLTable(NULL),
149     fMATable(NULL),
150     fKeySet(NULL),
151     fKeyVec(NULL),
152     fValueVec(NULL),
153     fStringTable(NULL),
154     fStringLengthsTable(NULL),
155     stringPool(NULL),
156     fParseLine(NULL),
157     fParseHexNum(NULL),
158     fLineNum(0)
159 {
160     if (U_FAILURE(status)) {
161         return;
162     }
163     fSLTable    = uhash_open(uhash_hashLong, uhash_compareLong, NULL, &status);
164     fSATable    = uhash_open(uhash_hashLong, uhash_compareLong, NULL, &status);
165     fMLTable    = uhash_open(uhash_hashLong, uhash_compareLong, NULL, &status);
166     fMATable    = uhash_open(uhash_hashLong, uhash_compareLong, NULL, &status);
167     fKeySet     = new UnicodeSet();
168     fKeyVec     = new UVector(status);
169     fValueVec   = new UVector(status);
170     stringPool = new SPUStringPool(status);
171 }
172 
173 
~ConfusabledataBuilder()174 ConfusabledataBuilder::~ConfusabledataBuilder() {
175     uprv_free(fInput);
176     uregex_close(fParseLine);
177     uregex_close(fParseHexNum);
178     uhash_close(fSLTable);
179     uhash_close(fSATable);
180     uhash_close(fMLTable);
181     uhash_close(fMATable);
182     delete fKeySet;
183     delete fKeyVec;
184     delete fStringTable;
185     delete fStringLengthsTable;
186     delete fValueVec;
187     delete stringPool;
188 }
189 
190 
buildConfusableData(SpoofImpl * spImpl,const char * confusables,int32_t confusablesLen,int32_t * errorType,UParseError * pe,UErrorCode & status)191 void ConfusabledataBuilder::buildConfusableData(SpoofImpl * spImpl, const char * confusables,
192     int32_t confusablesLen, int32_t *errorType, UParseError *pe, UErrorCode &status) {
193 
194     if (U_FAILURE(status)) {
195         return;
196     }
197     ConfusabledataBuilder builder(spImpl, status);
198     builder.build(confusables, confusablesLen, status);
199     if (U_FAILURE(status) && errorType != NULL) {
200         *errorType = USPOOF_SINGLE_SCRIPT_CONFUSABLE;
201         pe->line = builder.fLineNum;
202     }
203 }
204 
205 
build(const char * confusables,int32_t confusablesLen,UErrorCode & status)206 void ConfusabledataBuilder::build(const char * confusables, int32_t confusablesLen,
207                UErrorCode &status) {
208 
209     // Convert the user input data from UTF-8 to UChar (UTF-16)
210     int32_t inputLen = 0;
211     if (U_FAILURE(status)) {
212         return;
213     }
214     u_strFromUTF8(NULL, 0, &inputLen, confusables, confusablesLen, &status);
215     if (status != U_BUFFER_OVERFLOW_ERROR) {
216         return;
217     }
218     status = U_ZERO_ERROR;
219     fInput = static_cast<UChar *>(uprv_malloc((inputLen+1) * sizeof(UChar)));
220     if (fInput == NULL) {
221         status = U_MEMORY_ALLOCATION_ERROR;
222         return;
223     }
224     u_strFromUTF8(fInput, inputLen+1, NULL, confusables, confusablesLen, &status);
225 
226 
227     // Regular Expression to parse a line from Confusables.txt.  The expression will match
228     // any line.  What was matched is determined by examining which capture groups have a match.
229     //   Capture Group 1:  the source char
230     //   Capture Group 2:  the replacement chars
231     //   Capture Group 3-6  the table type, SL, SA, ML, or MA
232     //   Capture Group 7:  A blank or comment only line.
233     //   Capture Group 8:  A syntactically invalid line.  Anything that didn't match before.
234     // Example Line from the confusables.txt source file:
235     //   "1D702 ;	006E 0329 ;	SL	# MATHEMATICAL ITALIC SMALL ETA ... "
236     UnicodeString pattern(
237         "(?m)^[ \\t]*([0-9A-Fa-f]+)[ \\t]+;"      // Match the source char
238         "[ \\t]*([0-9A-Fa-f]+"                    // Match the replacement char(s)
239            "(?:[ \\t]+[0-9A-Fa-f]+)*)[ \\t]*;"    //     (continued)
240         "\\s*(?:(SL)|(SA)|(ML)|(MA))"             // Match the table type
241         "[ \\t]*(?:#.*?)?$"                       // Match any trailing #comment
242         "|^([ \\t]*(?:#.*?)?)$"       // OR match empty lines or lines with only a #comment
243         "|^(.*?)$", -1, US_INV);      // OR match any line, which catches illegal lines.
244     // TODO: Why are we using the regex C API here? C++ would just take UnicodeString...
245     fParseLine = uregex_open(pattern.getBuffer(), pattern.length(), 0, NULL, &status);
246 
247     // Regular expression for parsing a hex number out of a space-separated list of them.
248     //   Capture group 1 gets the number, with spaces removed.
249     pattern = UNICODE_STRING_SIMPLE("\\s*([0-9A-F]+)");
250     fParseHexNum = uregex_open(pattern.getBuffer(), pattern.length(), 0, NULL, &status);
251 
252     // Zap any Byte Order Mark at the start of input.  Changing it to a space is benign
253     //   given the syntax of the input.
254     if (*fInput == 0xfeff) {
255         *fInput = 0x20;
256     }
257 
258     // Parse the input, one line per iteration of this loop.
259     uregex_setText(fParseLine, fInput, inputLen, &status);
260     while (uregex_findNext(fParseLine, &status)) {
261         fLineNum++;
262         if (uregex_start(fParseLine, 7, &status) >= 0) {
263             // this was a blank or comment line.
264             continue;
265         }
266         if (uregex_start(fParseLine, 8, &status) >= 0) {
267             // input file syntax error.
268             status = U_PARSE_ERROR;
269             return;
270         }
271 
272         // We have a good input line.  Extract the key character and mapping string, and
273         //    put them into the appropriate mapping table.
274         UChar32 keyChar = SpoofImpl::ScanHex(fInput, uregex_start(fParseLine, 1, &status),
275                           uregex_end(fParseLine, 1, &status), status);
276 
277         int32_t mapStringStart = uregex_start(fParseLine, 2, &status);
278         int32_t mapStringLength = uregex_end(fParseLine, 2, &status) - mapStringStart;
279         uregex_setText(fParseHexNum, &fInput[mapStringStart], mapStringLength, &status);
280 
281         UnicodeString  *mapString = new UnicodeString();
282         if (mapString == NULL) {
283             status = U_MEMORY_ALLOCATION_ERROR;
284             return;
285         }
286         while (uregex_findNext(fParseHexNum, &status)) {
287             UChar32 c = SpoofImpl::ScanHex(&fInput[mapStringStart], uregex_start(fParseHexNum, 1, &status),
288                                  uregex_end(fParseHexNum, 1, &status), status);
289             mapString->append(c);
290         }
291         U_ASSERT(mapString->length() >= 1);
292 
293         // Put the map (value) string into the string pool
294         // This a little like a Java intern() - any duplicates will be eliminated.
295         SPUString *smapString = stringPool->addString(mapString, status);
296 
297         // Add the UChar32 -> string mapping to the appropriate table.
298         UHashtable *table = uregex_start(fParseLine, 3, &status) >= 0 ? fSLTable :
299                             uregex_start(fParseLine, 4, &status) >= 0 ? fSATable :
300                             uregex_start(fParseLine, 5, &status) >= 0 ? fMLTable :
301                             uregex_start(fParseLine, 6, &status) >= 0 ? fMATable :
302                             NULL;
303         if (U_SUCCESS(status) && table == NULL) {
304             status = U_PARSE_ERROR;
305         }
306         if (U_FAILURE(status)) {
307             return;
308         }
309 
310         // For Unicode 8, the SL, SA and ML tables have been discontinued.
311         //                All input data from confusables.txt is tagged MA.
312         //                ICU spoof check functions should ignore the specified table and always
313         //                use this MA Data.
314         //                For now, implement by populating the MA data into all four tables, and
315         //                keep the multiple table implementation in place, in case it comes back
316         //                at some time in the future.
317         //                There is no run time size penalty to keeping the four table implementation -
318         //                the data is shared when it's the same betweeen tables.
319         if (table != fMATable) {
320             status = U_PARSE_ERROR;
321             return;
322         };
323         //  uhash_iput(table, keyChar, smapString, &status);
324         uhash_iput(fSLTable, keyChar, smapString, &status);
325         uhash_iput(fSATable, keyChar, smapString, &status);
326         uhash_iput(fMLTable, keyChar, smapString, &status);
327         uhash_iput(fMATable, keyChar, smapString, &status);
328         fKeySet->add(keyChar);
329         if (U_FAILURE(status)) {
330             return;
331         }
332     }
333 
334     // Input data is now all parsed and collected.
335     // Now create the run-time binary form of the data.
336     //
337     // This is done in two steps.  First the data is assembled into vectors and strings,
338     //   for ease of construction, then the contents of these collections are dumped
339     //   into the actual raw-bytes data storage.
340 
341     // Build up the string array, and record the index of each string therein
342     //  in the (build time only) string pool.
343     // Strings of length one are not entered into the strings array.
344     // At the same time, build up the string lengths table, which records the
345     // position in the string table of the first string of each length >= 4.
346     // (Strings in the table are sorted by length)
347     stringPool->sort(status);
348     fStringTable = new UnicodeString();
349     fStringLengthsTable = new UVector(status);
350     int32_t previousStringLength = 0;
351     int32_t previousStringIndex  = 0;
352     int32_t poolSize = stringPool->size();
353     int32_t i;
354     for (i=0; i<poolSize; i++) {
355         SPUString *s = stringPool->getByIndex(i);
356         int32_t strLen = s->fStr->length();
357         int32_t strIndex = fStringTable->length();
358         U_ASSERT(strLen >= previousStringLength);
359         if (strLen == 1) {
360             // strings of length one do not get an entry in the string table.
361             // Keep the single string character itself here, which is the same
362             //  convention that is used in the final run-time string table index.
363             s->fStrTableIndex = s->fStr->charAt(0);
364         } else {
365             if ((strLen > previousStringLength) && (previousStringLength >= 4)) {
366                 fStringLengthsTable->addElement(previousStringIndex, status);
367                 fStringLengthsTable->addElement(previousStringLength, status);
368             }
369             s->fStrTableIndex = strIndex;
370             fStringTable->append(*(s->fStr));
371         }
372         previousStringLength = strLen;
373         previousStringIndex  = strIndex;
374     }
375     // Make the final entry to the string lengths table.
376     //   (it holds an entry for the _last_ string of each length, so adding the
377     //    final one doesn't happen in the main loop because no longer string was encountered.)
378     if (previousStringLength >= 4) {
379         fStringLengthsTable->addElement(previousStringIndex, status);
380         fStringLengthsTable->addElement(previousStringLength, status);
381     }
382 
383     // Construct the compile-time Key and Value tables
384     //
385     // For each key code point, check which mapping tables it applies to,
386     //   and create the final data for the key & value structures.
387     //
388     //   The four logical mapping tables are conflated into one combined table.
389     //   If multiple logical tables have the same mapping for some key, they
390     //     share a single entry in the combined table.
391     //   If more than one mapping exists for the same key code point, multiple
392     //     entries will be created in the table
393 
394     for (int32_t range=0; range<fKeySet->getRangeCount(); range++) {
395         // It is an oddity of the UnicodeSet API that simply enumerating the contained
396         //   code points requires a nested loop.
397         for (UChar32 keyChar=fKeySet->getRangeStart(range);
398                 keyChar <= fKeySet->getRangeEnd(range); keyChar++) {
399             addKeyEntry(keyChar, fSLTable, USPOOF_SL_TABLE_FLAG, status);
400             addKeyEntry(keyChar, fSATable, USPOOF_SA_TABLE_FLAG, status);
401             addKeyEntry(keyChar, fMLTable, USPOOF_ML_TABLE_FLAG, status);
402             addKeyEntry(keyChar, fMATable, USPOOF_MA_TABLE_FLAG, status);
403         }
404     }
405 
406     // Put the assembled data into the flat runtime array
407     outputData(status);
408 
409     // All of the intermediate allocated data belongs to the ConfusabledataBuilder
410     //  object  (this), and is deleted in the destructor.
411     return;
412 }
413 
414 //
415 // outputData     The confusable data has been compiled and stored in intermediate
416 //                collections and strings.  Copy it from there to the final flat
417 //                binary array.
418 //
419 //                Note that as each section is added to the output data, the
420 //                expand (reserveSpace() function will likely relocate it in memory.
421 //                Be careful with pointers.
422 //
outputData(UErrorCode & status)423 void ConfusabledataBuilder::outputData(UErrorCode &status) {
424 
425     U_ASSERT(fSpoofImpl->fSpoofData->fDataOwned == TRUE);
426 
427     //  The Key Table
428     //     While copying the keys to the runtime array,
429     //       also sanity check that they are sorted.
430 
431     int32_t numKeys = fKeyVec->size();
432     int32_t *keys =
433         static_cast<int32_t *>(fSpoofImpl->fSpoofData->reserveSpace(numKeys*sizeof(int32_t), status));
434     if (U_FAILURE(status)) {
435         return;
436     }
437     int i;
438     int32_t previousKey = 0;
439     for (i=0; i<numKeys; i++) {
440         int32_t key =  fKeyVec->elementAti(i);
441         (void)previousKey;         // Suppress unused variable warning on gcc.
442         U_ASSERT((key & 0x00ffffff) >= (previousKey & 0x00ffffff));
443         U_ASSERT((key & 0xff000000) != 0);
444         keys[i] = key;
445         previousKey = key;
446     }
447     SpoofDataHeader *rawData = fSpoofImpl->fSpoofData->fRawData;
448     rawData->fCFUKeys = (int32_t)((char *)keys - (char *)rawData);
449     rawData->fCFUKeysSize = numKeys;
450     fSpoofImpl->fSpoofData->fCFUKeys = keys;
451 
452 
453     // The Value Table, parallels the key table
454     int32_t numValues = fValueVec->size();
455     U_ASSERT(numKeys == numValues);
456     uint16_t *values =
457         static_cast<uint16_t *>(fSpoofImpl->fSpoofData->reserveSpace(numKeys*sizeof(uint16_t), status));
458     if (U_FAILURE(status)) {
459         return;
460     }
461     for (i=0; i<numValues; i++) {
462         uint32_t value = static_cast<uint32_t>(fValueVec->elementAti(i));
463         U_ASSERT(value < 0xffff);
464         values[i] = static_cast<uint16_t>(value);
465     }
466     rawData = fSpoofImpl->fSpoofData->fRawData;
467     rawData->fCFUStringIndex = (int32_t)((char *)values - (char *)rawData);
468     rawData->fCFUStringIndexSize = numValues;
469     fSpoofImpl->fSpoofData->fCFUValues = values;
470 
471     // The Strings Table.
472 
473     uint32_t stringsLength = fStringTable->length();
474     // Reserve an extra space so the string will be nul-terminated.  This is
475     // only a convenience, for when debugging; it is not needed otherwise.
476     UChar *strings =
477         static_cast<UChar *>(fSpoofImpl->fSpoofData->reserveSpace(stringsLength*sizeof(UChar)+2, status));
478     if (U_FAILURE(status)) {
479         return;
480     }
481     fStringTable->extract(strings, stringsLength+1, status);
482     rawData = fSpoofImpl->fSpoofData->fRawData;
483     U_ASSERT(rawData->fCFUStringTable == 0);
484     rawData->fCFUStringTable = (int32_t)((char *)strings - (char *)rawData);
485     rawData->fCFUStringTableLen = stringsLength;
486     fSpoofImpl->fSpoofData->fCFUStrings = strings;
487 
488     // The String Lengths Table
489     //    While copying into the runtime array do some sanity checks on the values
490     //    Each complete entry contains two fields, an index and an offset.
491     //    Lengths should increase with each entry.
492     //    Offsets should be less than the size of the string table.
493     int32_t lengthTableLength = fStringLengthsTable->size();
494     uint16_t *stringLengths =
495         static_cast<uint16_t *>(fSpoofImpl->fSpoofData->reserveSpace(lengthTableLength*sizeof(uint16_t), status));
496     if (U_FAILURE(status)) {
497         return;
498     }
499     int32_t destIndex = 0;
500     uint32_t previousLength = 0;
501     for (i=0; i<lengthTableLength; i+=2) {
502         uint32_t offset = static_cast<uint32_t>(fStringLengthsTable->elementAti(i));
503         uint32_t length = static_cast<uint32_t>(fStringLengthsTable->elementAti(i+1));
504         U_ASSERT(offset < stringsLength);
505         U_ASSERT(length < 40);
506         (void)previousLength;  // Suppress unused variable warning on gcc.
507         U_ASSERT(length > previousLength);
508         stringLengths[destIndex++] = static_cast<uint16_t>(offset);
509         stringLengths[destIndex++] = static_cast<uint16_t>(length);
510         previousLength = length;
511     }
512     rawData = fSpoofImpl->fSpoofData->fRawData;
513     rawData->fCFUStringLengths = (int32_t)((char *)stringLengths - (char *)rawData);
514     // Note: StringLengthsSize in the raw data is the number of complete entries,
515     //       each consisting of a pair of 16 bit values, hence the divide by 2.
516     rawData->fCFUStringLengthsSize = lengthTableLength / 2;
517     fSpoofImpl->fSpoofData->fCFUStringLengths =
518         reinterpret_cast<SpoofStringLengthsElement *>(stringLengths);
519 }
520 
521 
522 
523 //  addKeyEntry   Construction of the confusable Key and Mapping Values tables.
524 //                This is an intermediate point in the building process.
525 //                We already have the mappings in the hash tables fSLTable, etc.
526 //                This function builds corresponding run-time style table entries into
527 //                  fKeyVec and fValueVec
528 
addKeyEntry(UChar32 keyChar,UHashtable * table,int32_t tableFlag,UErrorCode & status)529 void ConfusabledataBuilder::addKeyEntry(
530     UChar32     keyChar,     // The key character
531     UHashtable *table,       // The table, one of SATable, MATable, etc.
532     int32_t     tableFlag,   // One of USPOOF_SA_TABLE_FLAG, etc.
533     UErrorCode &status) {
534 
535     SPUString *targetMapping = static_cast<SPUString *>(uhash_iget(table, keyChar));
536     if (targetMapping == NULL) {
537         // No mapping for this key character.
538         //   (This function is called for all four tables for each key char that
539         //    is seen anywhere, so this no entry cases are very much expected.)
540         return;
541     }
542 
543     // Check whether there is already an entry with the correct mapping.
544     // If so, simply set the flag in the keyTable saying that the existing entry
545     // applies to the table that we're doing now.
546 
547     UBool keyHasMultipleValues = FALSE;
548     int32_t i;
549     for (i=fKeyVec->size()-1; i>=0 ; i--) {
550         int32_t key = fKeyVec->elementAti(i);
551         if ((key & 0x0ffffff) != keyChar) {
552             // We have now checked all existing key entries for this key char (if any)
553             //  without finding one with the same mapping.
554             break;
555         }
556         UnicodeString mapping = getMapping(i);
557         if (mapping == *(targetMapping->fStr)) {
558             // The run time entry we are currently testing has the correct mapping.
559             // Set the flag in it indicating that it applies to the new table also.
560             key |= tableFlag;
561             fKeyVec->setElementAt(key, i);
562             return;
563         }
564         keyHasMultipleValues = TRUE;
565     }
566 
567     // Need to add a new entry to the binary data being built for this mapping.
568     // Includes adding entries to both the key table and the parallel values table.
569 
570     int32_t newKey = keyChar | tableFlag;
571     if (keyHasMultipleValues) {
572         newKey |= USPOOF_KEY_MULTIPLE_VALUES;
573     }
574     int32_t adjustedMappingLength = targetMapping->fStr->length() - 1;
575     if (adjustedMappingLength>3) {
576         adjustedMappingLength = 3;
577     }
578     newKey |= adjustedMappingLength << USPOOF_KEY_LENGTH_SHIFT;
579 
580     int32_t newData = targetMapping->fStrTableIndex;
581 
582     fKeyVec->addElement(newKey, status);
583     fValueVec->addElement(newData, status);
584 
585     // If the preceding key entry is for the same key character (but with a different mapping)
586     //   set the multiple-values flag on it.
587     if (keyHasMultipleValues) {
588         int32_t previousKeyIndex = fKeyVec->size() - 2;
589         int32_t previousKey = fKeyVec->elementAti(previousKeyIndex);
590         previousKey |= USPOOF_KEY_MULTIPLE_VALUES;
591         fKeyVec->setElementAt(previousKey, previousKeyIndex);
592     }
593 }
594 
595 
596 
getMapping(int32_t index)597 UnicodeString ConfusabledataBuilder::getMapping(int32_t index) {
598     int32_t key = fKeyVec->elementAti(index);
599     int32_t value = fValueVec->elementAti(index);
600     int32_t length = USPOOF_KEY_LENGTH_FIELD(key);
601     int32_t lastIndexWithLen;
602     switch (length) {
603       case 0:
604         return UnicodeString(static_cast<UChar>(value));
605       case 1:
606       case 2:
607         return UnicodeString(*fStringTable, value, length+1);
608       case 3:
609         length = 0;
610         int32_t i;
611         for (i=0; i<fStringLengthsTable->size(); i+=2) {
612             lastIndexWithLen = fStringLengthsTable->elementAti(i);
613             if (value <= lastIndexWithLen) {
614                 length = fStringLengthsTable->elementAti(i+1);
615                 break;
616             }
617         }
618         U_ASSERT(length>=3);
619         return UnicodeString(*fStringTable, value, length);
620       default:
621         U_ASSERT(FALSE);
622     }
623     return UnicodeString();
624 }
625 
626 #endif
627 #endif // !UCONFIG_NO_REGULAR_EXPRESSIONS
628 
629