1 // Copyright (C) 2016 and later: Unicode, Inc. and others. 2 // License & terms of use: http://www.unicode.org/copyright.html 3 /* 4 ********************************************************************** 5 * Copyright (c) 2001-2014, International Business Machines 6 * Corporation and others. All Rights Reserved. 7 ********************************************************************** 8 * Date Name Description 9 * 08/10/2001 aliu Creation. 10 ********************************************************************** 11 */ 12 13 #include "unicode/utypes.h" 14 15 #if !UCONFIG_NO_TRANSLITERATION 16 17 #include "unicode/translit.h" 18 #include "unicode/resbund.h" 19 #include "unicode/uniset.h" 20 #include "unicode/uscript.h" 21 #include "rbt.h" 22 #include "cpdtrans.h" 23 #include "nultrans.h" 24 #include "transreg.h" 25 #include "rbt_data.h" 26 #include "rbt_pars.h" 27 #include "tridpars.h" 28 #include "charstr.h" 29 #include "uassert.h" 30 #include "locutil.h" 31 32 // Enable the following symbol to add debugging code that tracks the 33 // allocation, deletion, and use of Entry objects. BoundsChecker has 34 // reported dangling pointer errors with these objects, but I have 35 // been unable to confirm them. I suspect BoundsChecker is getting 36 // confused with pointers going into and coming out of a UHashtable, 37 // despite the hinting code that is designed to help it. 38 // #define DEBUG_MEM 39 #ifdef DEBUG_MEM 40 #include <stdio.h> 41 #endif 42 43 // UChar constants 44 static const UChar LOCALE_SEP = 95; // '_' 45 //static const UChar ID_SEP = 0x002D; /*-*/ 46 //static const UChar VARIANT_SEP = 0x002F; // '/' 47 48 // String constants 49 static const UChar ANY[] = { 65, 110, 121, 0 }; // Any 50 51 // empty string 52 #define NO_VARIANT UnicodeString() 53 54 /** 55 * Resource bundle key for the RuleBasedTransliterator rule. 56 */ 57 //static const char RB_RULE[] = "Rule"; 58 59 U_NAMESPACE_BEGIN 60 61 //------------------------------------------------------------------ 62 // Alias 63 //------------------------------------------------------------------ 64 65 TransliteratorAlias::TransliteratorAlias(const UnicodeString& theAliasID, 66 const UnicodeSet* cpdFilter) : 67 ID(), 68 aliasesOrRules(theAliasID), 69 transes(0), 70 compoundFilter(cpdFilter), 71 direction(UTRANS_FORWARD), 72 type(TransliteratorAlias::SIMPLE) { 73 } 74 75 TransliteratorAlias::TransliteratorAlias(const UnicodeString& theID, 76 const UnicodeString& idBlocks, 77 UVector* adoptedTransliterators, 78 const UnicodeSet* cpdFilter) : 79 ID(theID), 80 aliasesOrRules(idBlocks), 81 transes(adoptedTransliterators), 82 compoundFilter(cpdFilter), 83 direction(UTRANS_FORWARD), 84 type(TransliteratorAlias::COMPOUND) { 85 } 86 87 TransliteratorAlias::TransliteratorAlias(const UnicodeString& theID, 88 const UnicodeString& rules, 89 UTransDirection dir) : 90 ID(theID), 91 aliasesOrRules(rules), 92 transes(0), 93 compoundFilter(0), 94 direction(dir), 95 type(TransliteratorAlias::RULES) { 96 } 97 98 TransliteratorAlias::~TransliteratorAlias() { 99 delete transes; 100 } 101 102 103 Transliterator* TransliteratorAlias::create(UParseError& pe, 104 UErrorCode& ec) { 105 if (U_FAILURE(ec)) { 106 return 0; 107 } 108 Transliterator *t = NULL; 109 switch (type) { 110 case SIMPLE: 111 t = Transliterator::createInstance(aliasesOrRules, UTRANS_FORWARD, pe, ec); 112 if(U_FAILURE(ec)){ 113 return 0; 114 } 115 if (compoundFilter != 0) 116 t->adoptFilter((UnicodeSet*)compoundFilter->clone()); 117 break; 118 case COMPOUND: 119 { 120 // the total number of transliterators in the compound is the total number of anonymous transliterators 121 // plus the total number of ID blocks-- we start by assuming the list begins and ends with an ID 122 // block and that each pair anonymous transliterators has an ID block between them. Then we go back 123 // to see whether there really are ID blocks at the beginning and end (by looking for U+FFFF, which 124 // marks the position where an anonymous transliterator goes) and adjust accordingly 125 int32_t anonymousRBTs = transes->size(); 126 int32_t transCount = anonymousRBTs * 2 + 1; 127 if (!aliasesOrRules.isEmpty() && aliasesOrRules[0] == (UChar)(0xffff)) 128 --transCount; 129 if (aliasesOrRules.length() >= 2 && aliasesOrRules[aliasesOrRules.length() - 1] == (UChar)(0xffff)) 130 --transCount; 131 UnicodeString noIDBlock((UChar)(0xffff)); 132 noIDBlock += ((UChar)(0xffff)); 133 int32_t pos = aliasesOrRules.indexOf(noIDBlock); 134 while (pos >= 0) { 135 --transCount; 136 pos = aliasesOrRules.indexOf(noIDBlock, pos + 1); 137 } 138 139 UVector transliterators(ec); 140 UnicodeString idBlock; 141 int32_t blockSeparatorPos = aliasesOrRules.indexOf((UChar)(0xffff)); 142 while (blockSeparatorPos >= 0) { 143 aliasesOrRules.extract(0, blockSeparatorPos, idBlock); 144 aliasesOrRules.remove(0, blockSeparatorPos + 1); 145 if (!idBlock.isEmpty()) 146 transliterators.addElement(Transliterator::createInstance(idBlock, UTRANS_FORWARD, pe, ec), ec); 147 if (!transes->isEmpty()) 148 transliterators.addElement(transes->orphanElementAt(0), ec); 149 blockSeparatorPos = aliasesOrRules.indexOf((UChar)(0xffff)); 150 } 151 if (!aliasesOrRules.isEmpty()) 152 transliterators.addElement(Transliterator::createInstance(aliasesOrRules, UTRANS_FORWARD, pe, ec), ec); 153 while (!transes->isEmpty()) 154 transliterators.addElement(transes->orphanElementAt(0), ec); 155 156 if (U_SUCCESS(ec)) { 157 t = new CompoundTransliterator(ID, transliterators, 158 (compoundFilter ? (UnicodeSet*)(compoundFilter->clone()) : 0), 159 anonymousRBTs, pe, ec); 160 if (t == 0) { 161 ec = U_MEMORY_ALLOCATION_ERROR; 162 return 0; 163 } 164 } else { 165 for (int32_t i = 0; i < transliterators.size(); i++) 166 delete (Transliterator*)(transliterators.elementAt(i)); 167 } 168 } 169 break; 170 case RULES: 171 U_ASSERT(FALSE); // don't call create() if isRuleBased() returns TRUE! 172 break; 173 } 174 return t; 175 } 176 177 UBool TransliteratorAlias::isRuleBased() const { 178 return type == RULES; 179 } 180 181 void TransliteratorAlias::parse(TransliteratorParser& parser, 182 UParseError& pe, UErrorCode& ec) const { 183 U_ASSERT(type == RULES); 184 if (U_FAILURE(ec)) { 185 return; 186 } 187 188 parser.parse(aliasesOrRules, direction, pe, ec); 189 } 190 191 //---------------------------------------------------------------------- 192 // class TransliteratorSpec 193 //---------------------------------------------------------------------- 194 195 /** 196 * A TransliteratorSpec is a string specifying either a source or a target. In more 197 * general terms, it may also specify a variant, but we only use the 198 * Spec class for sources and targets. 199 * 200 * A Spec may be a locale or a script. If it is a locale, it has a 201 * fallback chain that goes xx_YY_ZZZ -> xx_YY -> xx -> ssss, where 202 * ssss is the script mapping of xx_YY_ZZZ. The Spec API methods 203 * hasFallback(), next(), and reset() iterate over this fallback 204 * sequence. 205 * 206 * The Spec class canonicalizes itself, so the locale is put into 207 * canonical form, or the script is transformed from an abbreviation 208 * to a full name. 209 */ 210 class TransliteratorSpec : public UMemory { 211 public: 212 TransliteratorSpec(const UnicodeString& spec); 213 ~TransliteratorSpec(); 214 215 const UnicodeString& get() const; 216 UBool hasFallback() const; 217 const UnicodeString& next(); 218 void reset(); 219 220 UBool isLocale() const; 221 ResourceBundle& getBundle() const; 222 223 operator const UnicodeString&() const { return get(); } 224 const UnicodeString& getTop() const { return top; } 225 226 private: 227 void setupNext(); 228 229 UnicodeString top; 230 UnicodeString spec; 231 UnicodeString nextSpec; 232 UnicodeString scriptName; 233 UBool isSpecLocale; // TRUE if spec is a locale 234 UBool isNextLocale; // TRUE if nextSpec is a locale 235 ResourceBundle* res; 236 237 TransliteratorSpec(const TransliteratorSpec &other); // forbid copying of this class 238 TransliteratorSpec &operator=(const TransliteratorSpec &other); // forbid copying of this class 239 }; 240 241 TransliteratorSpec::TransliteratorSpec(const UnicodeString& theSpec) 242 : top(theSpec), 243 res(0) 244 { 245 UErrorCode status = U_ZERO_ERROR; 246 Locale topLoc(""); 247 LocaleUtility::initLocaleFromName(theSpec, topLoc); 248 if (!topLoc.isBogus()) { 249 res = new ResourceBundle(U_ICUDATA_TRANSLIT, topLoc, status); 250 /* test for NULL */ 251 if (res == 0) { 252 return; 253 } 254 if (U_FAILURE(status) || status == U_USING_DEFAULT_WARNING) { 255 delete res; 256 res = 0; 257 } 258 } 259 260 // Canonicalize script name -or- do locale->script mapping 261 status = U_ZERO_ERROR; 262 static const int32_t capacity = 10; 263 UScriptCode script[capacity]={USCRIPT_INVALID_CODE}; 264 int32_t num = uscript_getCode(CharString().appendInvariantChars(theSpec, status).data(), 265 script, capacity, &status); 266 if (num > 0 && script[0] != USCRIPT_INVALID_CODE) { 267 scriptName = UnicodeString(uscript_getName(script[0]), -1, US_INV); 268 } 269 270 // Canonicalize top 271 if (res != 0) { 272 // Canonicalize locale name 273 UnicodeString locStr; 274 LocaleUtility::initNameFromLocale(topLoc, locStr); 275 if (!locStr.isBogus()) { 276 top = locStr; 277 } 278 } else if (scriptName.length() != 0) { 279 // We are a script; use canonical name 280 top = scriptName; 281 } 282 283 // assert(spec != top); 284 reset(); 285 } 286 287 TransliteratorSpec::~TransliteratorSpec() { 288 delete res; 289 } 290 291 UBool TransliteratorSpec::hasFallback() const { 292 return nextSpec.length() != 0; 293 } 294 295 void TransliteratorSpec::reset() { 296 if (spec != top) { 297 spec = top; 298 isSpecLocale = (res != 0); 299 setupNext(); 300 } 301 } 302 303 void TransliteratorSpec::setupNext() { 304 isNextLocale = FALSE; 305 if (isSpecLocale) { 306 nextSpec = spec; 307 int32_t i = nextSpec.lastIndexOf(LOCALE_SEP); 308 // If i == 0 then we have _FOO, so we fall through 309 // to the scriptName. 310 if (i > 0) { 311 nextSpec.truncate(i); 312 isNextLocale = TRUE; 313 } else { 314 nextSpec = scriptName; // scriptName may be empty 315 } 316 } else { 317 // spec is a script, so we are at the end 318 nextSpec.truncate(0); 319 } 320 } 321 322 // Protocol: 323 // for(const UnicodeString& s(spec.get()); 324 // spec.hasFallback(); s(spec.next())) { ... 325 326 const UnicodeString& TransliteratorSpec::next() { 327 spec = nextSpec; 328 isSpecLocale = isNextLocale; 329 setupNext(); 330 return spec; 331 } 332 333 const UnicodeString& TransliteratorSpec::get() const { 334 return spec; 335 } 336 337 UBool TransliteratorSpec::isLocale() const { 338 return isSpecLocale; 339 } 340 341 ResourceBundle& TransliteratorSpec::getBundle() const { 342 return *res; 343 } 344 345 //---------------------------------------------------------------------- 346 347 #ifdef DEBUG_MEM 348 349 // Vector of Entry pointers currently in use 350 static UVector* DEBUG_entries = NULL; 351 352 static void DEBUG_setup() { 353 if (DEBUG_entries == NULL) { 354 UErrorCode ec = U_ZERO_ERROR; 355 DEBUG_entries = new UVector(ec); 356 } 357 } 358 359 // Caller must call DEBUG_setup first. Return index of given Entry, 360 // if it is in use (not deleted yet), or -1 if not found. 361 static int DEBUG_findEntry(TransliteratorEntry* e) { 362 for (int i=0; i<DEBUG_entries->size(); ++i) { 363 if (e == (TransliteratorEntry*) DEBUG_entries->elementAt(i)) { 364 return i; 365 } 366 } 367 return -1; 368 } 369 370 // Track object creation 371 static void DEBUG_newEntry(TransliteratorEntry* e) { 372 DEBUG_setup(); 373 if (DEBUG_findEntry(e) >= 0) { 374 // This should really never happen unless the heap is broken 375 printf("ERROR DEBUG_newEntry duplicate new pointer %08X\n", e); 376 return; 377 } 378 UErrorCode ec = U_ZERO_ERROR; 379 DEBUG_entries->addElement(e, ec); 380 } 381 382 // Track object deletion 383 static void DEBUG_delEntry(TransliteratorEntry* e) { 384 DEBUG_setup(); 385 int i = DEBUG_findEntry(e); 386 if (i < 0) { 387 printf("ERROR DEBUG_delEntry possible double deletion %08X\n", e); 388 return; 389 } 390 DEBUG_entries->removeElementAt(i); 391 } 392 393 // Track object usage 394 static void DEBUG_useEntry(TransliteratorEntry* e) { 395 if (e == NULL) return; 396 DEBUG_setup(); 397 int i = DEBUG_findEntry(e); 398 if (i < 0) { 399 printf("ERROR DEBUG_useEntry possible dangling pointer %08X\n", e); 400 } 401 } 402 403 #else 404 // If we're not debugging then make these macros into NOPs 405 #define DEBUG_newEntry(x) 406 #define DEBUG_delEntry(x) 407 #define DEBUG_useEntry(x) 408 #endif 409 410 //---------------------------------------------------------------------- 411 // class Entry 412 //---------------------------------------------------------------------- 413 414 /** 415 * The Entry object stores objects of different types and 416 * singleton objects as placeholders for rule-based transliterators to 417 * be built as needed. Instances of this struct can be placeholders, 418 * can represent prototype transliterators to be cloned, or can 419 * represent TransliteratorData objects. We don't support storing 420 * classes in the registry because we don't have the rtti infrastructure 421 * for it. We could easily add this if there is a need for it in the 422 * future. 423 */ 424 class TransliteratorEntry : public UMemory { 425 public: 426 enum Type { 427 RULES_FORWARD, 428 RULES_REVERSE, 429 LOCALE_RULES, 430 PROTOTYPE, 431 RBT_DATA, 432 COMPOUND_RBT, 433 ALIAS, 434 FACTORY, 435 NONE // Only used for uninitialized entries 436 } entryType; 437 // NOTE: stringArg cannot go inside the union because 438 // it has a copy constructor 439 UnicodeString stringArg; // For RULES_*, ALIAS, COMPOUND_RBT 440 int32_t intArg; // For COMPOUND_RBT, LOCALE_RULES 441 UnicodeSet* compoundFilter; // For COMPOUND_RBT 442 union { 443 Transliterator* prototype; // For PROTOTYPE 444 TransliterationRuleData* data; // For RBT_DATA 445 UVector* dataVector; // For COMPOUND_RBT 446 struct { 447 Transliterator::Factory function; 448 Transliterator::Token context; 449 } factory; // For FACTORY 450 } u; 451 TransliteratorEntry(); 452 ~TransliteratorEntry(); 453 void adoptPrototype(Transliterator* adopted); 454 void setFactory(Transliterator::Factory factory, 455 Transliterator::Token context); 456 457 private: 458 459 TransliteratorEntry(const TransliteratorEntry &other); // forbid copying of this class 460 TransliteratorEntry &operator=(const TransliteratorEntry &other); // forbid copying of this class 461 }; 462 463 TransliteratorEntry::TransliteratorEntry() { 464 u.prototype = 0; 465 compoundFilter = NULL; 466 entryType = NONE; 467 DEBUG_newEntry(this); 468 } 469 470 TransliteratorEntry::~TransliteratorEntry() { 471 DEBUG_delEntry(this); 472 if (entryType == PROTOTYPE) { 473 delete u.prototype; 474 } else if (entryType == RBT_DATA) { 475 // The data object is shared between instances of RBT. The 476 // entry object owns it. It should only be deleted when the 477 // transliterator component is being cleaned up. Doing so 478 // invalidates any RBTs that the user has instantiated. 479 delete u.data; 480 } else if (entryType == COMPOUND_RBT) { 481 while (u.dataVector != NULL && !u.dataVector->isEmpty()) 482 delete (TransliterationRuleData*)u.dataVector->orphanElementAt(0); 483 delete u.dataVector; 484 } 485 delete compoundFilter; 486 } 487 488 void TransliteratorEntry::adoptPrototype(Transliterator* adopted) { 489 if (entryType == PROTOTYPE) { 490 delete u.prototype; 491 } 492 entryType = PROTOTYPE; 493 u.prototype = adopted; 494 } 495 496 void TransliteratorEntry::setFactory(Transliterator::Factory factory, 497 Transliterator::Token context) { 498 if (entryType == PROTOTYPE) { 499 delete u.prototype; 500 } 501 entryType = FACTORY; 502 u.factory.function = factory; 503 u.factory.context = context; 504 } 505 506 // UObjectDeleter for Hashtable::setValueDeleter 507 U_CDECL_BEGIN 508 static void U_CALLCONV 509 deleteEntry(void* obj) { 510 delete (TransliteratorEntry*) obj; 511 } 512 U_CDECL_END 513 514 //---------------------------------------------------------------------- 515 // class TransliteratorRegistry: Basic public API 516 //---------------------------------------------------------------------- 517 518 TransliteratorRegistry::TransliteratorRegistry(UErrorCode& status) : 519 registry(TRUE, status), 520 specDAG(TRUE, status), 521 availableIDs(status) 522 { 523 registry.setValueDeleter(deleteEntry); 524 availableIDs.setDeleter(uprv_deleteUObject); 525 availableIDs.setComparer(uhash_compareCaselessUnicodeString); 526 specDAG.setValueDeleter(uhash_deleteHashtable); 527 } 528 529 TransliteratorRegistry::~TransliteratorRegistry() { 530 // Through the magic of C++, everything cleans itself up 531 } 532 533 Transliterator* TransliteratorRegistry::get(const UnicodeString& ID, 534 TransliteratorAlias*& aliasReturn, 535 UErrorCode& status) { 536 U_ASSERT(aliasReturn == NULL); 537 TransliteratorEntry *entry = find(ID); 538 return (entry == 0) ? 0 539 : instantiateEntry(ID, entry, aliasReturn, status); 540 } 541 542 Transliterator* TransliteratorRegistry::reget(const UnicodeString& ID, 543 TransliteratorParser& parser, 544 TransliteratorAlias*& aliasReturn, 545 UErrorCode& status) { 546 U_ASSERT(aliasReturn == NULL); 547 TransliteratorEntry *entry = find(ID); 548 549 if (entry == 0) { 550 // We get to this point if there are two threads, one of which 551 // is instantiating an ID, and another of which is removing 552 // the same ID from the registry, and the timing is just right. 553 return 0; 554 } 555 556 // The usage model for the caller is that they will first call 557 // reg->get() inside the mutex, they'll get back an alias, they call 558 // alias->isRuleBased(), and if they get TRUE, they call alias->parse() 559 // outside the mutex, then reg->reget() inside the mutex again. A real 560 // mess, but it gets things working for ICU 3.0. [alan]. 561 562 // Note: It's possible that in between the caller calling 563 // alias->parse() and reg->reget(), that another thread will have 564 // called reg->reget(), and the entry will already have been fixed up. 565 // We have to detect this so we don't stomp over existing entry 566 // data members and potentially leak memory (u.data and compoundFilter). 567 568 if (entry->entryType == TransliteratorEntry::RULES_FORWARD || 569 entry->entryType == TransliteratorEntry::RULES_REVERSE || 570 entry->entryType == TransliteratorEntry::LOCALE_RULES) { 571 572 if (parser.idBlockVector.isEmpty() && parser.dataVector.isEmpty()) { 573 entry->u.data = 0; 574 entry->entryType = TransliteratorEntry::ALIAS; 575 entry->stringArg = UNICODE_STRING_SIMPLE("Any-NULL"); 576 } 577 else if (parser.idBlockVector.isEmpty() && parser.dataVector.size() == 1) { 578 entry->u.data = (TransliterationRuleData*)parser.dataVector.orphanElementAt(0); 579 entry->entryType = TransliteratorEntry::RBT_DATA; 580 } 581 else if (parser.idBlockVector.size() == 1 && parser.dataVector.isEmpty()) { 582 entry->stringArg = *(UnicodeString*)(parser.idBlockVector.elementAt(0)); 583 entry->compoundFilter = parser.orphanCompoundFilter(); 584 entry->entryType = TransliteratorEntry::ALIAS; 585 } 586 else { 587 entry->entryType = TransliteratorEntry::COMPOUND_RBT; 588 entry->compoundFilter = parser.orphanCompoundFilter(); 589 entry->u.dataVector = new UVector(status); 590 entry->stringArg.remove(); 591 592 int32_t limit = parser.idBlockVector.size(); 593 if (parser.dataVector.size() > limit) 594 limit = parser.dataVector.size(); 595 596 for (int32_t i = 0; i < limit; i++) { 597 if (i < parser.idBlockVector.size()) { 598 UnicodeString* idBlock = (UnicodeString*)parser.idBlockVector.elementAt(i); 599 if (!idBlock->isEmpty()) 600 entry->stringArg += *idBlock; 601 } 602 if (!parser.dataVector.isEmpty()) { 603 TransliterationRuleData* data = (TransliterationRuleData*)parser.dataVector.orphanElementAt(0); 604 entry->u.dataVector->addElement(data, status); 605 entry->stringArg += (UChar)0xffff; // use U+FFFF to mark position of RBTs in ID block 606 } 607 } 608 } 609 } 610 611 Transliterator *t = 612 instantiateEntry(ID, entry, aliasReturn, status); 613 return t; 614 } 615 616 void TransliteratorRegistry::put(Transliterator* adoptedProto, 617 UBool visible, 618 UErrorCode& ec) 619 { 620 TransliteratorEntry *entry = new TransliteratorEntry(); 621 if (entry == NULL) { 622 ec = U_MEMORY_ALLOCATION_ERROR; 623 return; 624 } 625 entry->adoptPrototype(adoptedProto); 626 registerEntry(adoptedProto->getID(), entry, visible); 627 } 628 629 void TransliteratorRegistry::put(const UnicodeString& ID, 630 Transliterator::Factory factory, 631 Transliterator::Token context, 632 UBool visible, 633 UErrorCode& ec) { 634 TransliteratorEntry *entry = new TransliteratorEntry(); 635 if (entry == NULL) { 636 ec = U_MEMORY_ALLOCATION_ERROR; 637 return; 638 } 639 entry->setFactory(factory, context); 640 registerEntry(ID, entry, visible); 641 } 642 643 void TransliteratorRegistry::put(const UnicodeString& ID, 644 const UnicodeString& resourceName, 645 UTransDirection dir, 646 UBool readonlyResourceAlias, 647 UBool visible, 648 UErrorCode& ec) { 649 TransliteratorEntry *entry = new TransliteratorEntry(); 650 if (entry == NULL) { 651 ec = U_MEMORY_ALLOCATION_ERROR; 652 return; 653 } 654 entry->entryType = (dir == UTRANS_FORWARD) ? TransliteratorEntry::RULES_FORWARD 655 : TransliteratorEntry::RULES_REVERSE; 656 if (readonlyResourceAlias) { 657 entry->stringArg.setTo(TRUE, resourceName.getBuffer(), -1); 658 } 659 else { 660 entry->stringArg = resourceName; 661 } 662 registerEntry(ID, entry, visible); 663 } 664 665 void TransliteratorRegistry::put(const UnicodeString& ID, 666 const UnicodeString& alias, 667 UBool readonlyAliasAlias, 668 UBool visible, 669 UErrorCode& /*ec*/) { 670 TransliteratorEntry *entry = new TransliteratorEntry(); 671 // Null pointer check 672 if (entry != NULL) { 673 entry->entryType = TransliteratorEntry::ALIAS; 674 if (readonlyAliasAlias) { 675 entry->stringArg.setTo(TRUE, alias.getBuffer(), -1); 676 } 677 else { 678 entry->stringArg = alias; 679 } 680 registerEntry(ID, entry, visible); 681 } 682 } 683 684 void TransliteratorRegistry::remove(const UnicodeString& ID) { 685 UnicodeString source, target, variant; 686 UBool sawSource; 687 TransliteratorIDParser::IDtoSTV(ID, source, target, variant, sawSource); 688 // Only need to do this if ID.indexOf('-') < 0 689 UnicodeString id; 690 TransliteratorIDParser::STVtoID(source, target, variant, id); 691 registry.remove(id); 692 removeSTV(source, target, variant); 693 availableIDs.removeElement((void*) &id); 694 } 695 696 //---------------------------------------------------------------------- 697 // class TransliteratorRegistry: Public ID and spec management 698 //---------------------------------------------------------------------- 699 700 /** 701 * == OBSOLETE - remove in ICU 3.4 == 702 * Return the number of IDs currently registered with the system. 703 * To retrieve the actual IDs, call getAvailableID(i) with 704 * i from 0 to countAvailableIDs() - 1. 705 */ 706 int32_t TransliteratorRegistry::countAvailableIDs(void) const { 707 return availableIDs.size(); 708 } 709 710 /** 711 * == OBSOLETE - remove in ICU 3.4 == 712 * Return the index-th available ID. index must be between 0 713 * and countAvailableIDs() - 1, inclusive. If index is out of 714 * range, the result of getAvailableID(0) is returned. 715 */ 716 const UnicodeString& TransliteratorRegistry::getAvailableID(int32_t index) const { 717 if (index < 0 || index >= availableIDs.size()) { 718 index = 0; 719 } 720 return *(const UnicodeString*) availableIDs[index]; 721 } 722 723 StringEnumeration* TransliteratorRegistry::getAvailableIDs() const { 724 return new Enumeration(*this); 725 } 726 727 int32_t TransliteratorRegistry::countAvailableSources(void) const { 728 return specDAG.count(); 729 } 730 731 UnicodeString& TransliteratorRegistry::getAvailableSource(int32_t index, 732 UnicodeString& result) const { 733 int32_t pos = UHASH_FIRST; 734 const UHashElement *e = 0; 735 while (index-- >= 0) { 736 e = specDAG.nextElement(pos); 737 if (e == 0) { 738 break; 739 } 740 } 741 if (e == 0) { 742 result.truncate(0); 743 } else { 744 result = *(UnicodeString*) e->key.pointer; 745 } 746 return result; 747 } 748 749 int32_t TransliteratorRegistry::countAvailableTargets(const UnicodeString& source) const { 750 Hashtable *targets = (Hashtable*) specDAG.get(source); 751 return (targets == 0) ? 0 : targets->count(); 752 } 753 754 UnicodeString& TransliteratorRegistry::getAvailableTarget(int32_t index, 755 const UnicodeString& source, 756 UnicodeString& result) const { 757 Hashtable *targets = (Hashtable*) specDAG.get(source); 758 if (targets == 0) { 759 result.truncate(0); // invalid source 760 return result; 761 } 762 int32_t pos = UHASH_FIRST; 763 const UHashElement *e = 0; 764 while (index-- >= 0) { 765 e = targets->nextElement(pos); 766 if (e == 0) { 767 break; 768 } 769 } 770 if (e == 0) { 771 result.truncate(0); // invalid index 772 } else { 773 result = *(UnicodeString*) e->key.pointer; 774 } 775 return result; 776 } 777 778 int32_t TransliteratorRegistry::countAvailableVariants(const UnicodeString& source, 779 const UnicodeString& target) const { 780 Hashtable *targets = (Hashtable*) specDAG.get(source); 781 if (targets == 0) { 782 return 0; 783 } 784 UVector *variants = (UVector*) targets->get(target); 785 // variants may be 0 if the source/target are invalid 786 return (variants == 0) ? 0 : variants->size(); 787 } 788 789 UnicodeString& TransliteratorRegistry::getAvailableVariant(int32_t index, 790 const UnicodeString& source, 791 const UnicodeString& target, 792 UnicodeString& result) const { 793 Hashtable *targets = (Hashtable*) specDAG.get(source); 794 if (targets == 0) { 795 result.truncate(0); // invalid source 796 return result; 797 } 798 UVector *variants = (UVector*) targets->get(target); 799 if (variants == 0) { 800 result.truncate(0); // invalid target 801 return result; 802 } 803 UnicodeString *v = (UnicodeString*) variants->elementAt(index); 804 if (v == 0) { 805 result.truncate(0); // invalid index 806 } else { 807 result = *v; 808 } 809 return result; 810 } 811 812 //---------------------------------------------------------------------- 813 // class TransliteratorRegistry::Enumeration 814 //---------------------------------------------------------------------- 815 816 TransliteratorRegistry::Enumeration::Enumeration(const TransliteratorRegistry& _reg) : 817 index(0), reg(_reg) { 818 } 819 820 TransliteratorRegistry::Enumeration::~Enumeration() { 821 } 822 823 int32_t TransliteratorRegistry::Enumeration::count(UErrorCode& /*status*/) const { 824 return reg.availableIDs.size(); 825 } 826 827 const UnicodeString* TransliteratorRegistry::Enumeration::snext(UErrorCode& status) { 828 // This is sloppy but safe -- if we get out of sync with the underlying 829 // registry, we will still return legal strings, but they might not 830 // correspond to the snapshot at construction time. So there could be 831 // duplicate IDs or omitted IDs if insertions or deletions occur in one 832 // thread while another is iterating. To be more rigorous, add a timestamp, 833 // which is incremented with any modification, and validate this iterator 834 // against the timestamp at construction time. This probably isn't worth 835 // doing as long as there is some possibility of removing this code in favor 836 // of some new code based on Doug's service framework. 837 if (U_FAILURE(status)) { 838 return NULL; 839 } 840 int32_t n = reg.availableIDs.size(); 841 if (index > n) { 842 status = U_ENUM_OUT_OF_SYNC_ERROR; 843 } 844 // index == n is okay -- this means we've reached the end 845 if (index < n) { 846 // Copy the string! This avoids lifetime problems. 847 unistr = *(const UnicodeString*)reg.availableIDs[index++]; 848 return &unistr; 849 } else { 850 return NULL; 851 } 852 } 853 854 void TransliteratorRegistry::Enumeration::reset(UErrorCode& /*status*/) { 855 index = 0; 856 } 857 858 UOBJECT_DEFINE_RTTI_IMPLEMENTATION(TransliteratorRegistry::Enumeration) 859 860 //---------------------------------------------------------------------- 861 // class TransliteratorRegistry: internal 862 //---------------------------------------------------------------------- 863 864 /** 865 * Convenience method. Calls 6-arg registerEntry(). 866 */ 867 void TransliteratorRegistry::registerEntry(const UnicodeString& source, 868 const UnicodeString& target, 869 const UnicodeString& variant, 870 TransliteratorEntry* adopted, 871 UBool visible) { 872 UnicodeString ID; 873 UnicodeString s(source); 874 if (s.length() == 0) { 875 s.setTo(TRUE, ANY, 3); 876 } 877 TransliteratorIDParser::STVtoID(source, target, variant, ID); 878 registerEntry(ID, s, target, variant, adopted, visible); 879 } 880 881 /** 882 * Convenience method. Calls 6-arg registerEntry(). 883 */ 884 void TransliteratorRegistry::registerEntry(const UnicodeString& ID, 885 TransliteratorEntry* adopted, 886 UBool visible) { 887 UnicodeString source, target, variant; 888 UBool sawSource; 889 TransliteratorIDParser::IDtoSTV(ID, source, target, variant, sawSource); 890 // Only need to do this if ID.indexOf('-') < 0 891 UnicodeString id; 892 TransliteratorIDParser::STVtoID(source, target, variant, id); 893 registerEntry(id, source, target, variant, adopted, visible); 894 } 895 896 /** 897 * Register an entry object (adopted) with the given ID, source, 898 * target, and variant strings. 899 */ 900 void TransliteratorRegistry::registerEntry(const UnicodeString& ID, 901 const UnicodeString& source, 902 const UnicodeString& target, 903 const UnicodeString& variant, 904 TransliteratorEntry* adopted, 905 UBool visible) { 906 UErrorCode status = U_ZERO_ERROR; 907 registry.put(ID, adopted, status); 908 if (visible) { 909 registerSTV(source, target, variant); 910 if (!availableIDs.contains((void*) &ID)) { 911 UnicodeString *newID = (UnicodeString *)ID.clone(); 912 // Check to make sure newID was created. 913 if (newID != NULL) { 914 // NUL-terminate the ID string 915 newID->getTerminatedBuffer(); 916 availableIDs.addElement(newID, status); 917 } 918 } 919 } else { 920 removeSTV(source, target, variant); 921 availableIDs.removeElement((void*) &ID); 922 } 923 } 924 925 /** 926 * Register a source-target/variant in the specDAG. Variant may be 927 * empty, but source and target must not be. If variant is empty then 928 * the special variant NO_VARIANT is stored in slot zero of the 929 * UVector of variants. 930 */ 931 void TransliteratorRegistry::registerSTV(const UnicodeString& source, 932 const UnicodeString& target, 933 const UnicodeString& variant) { 934 // assert(source.length() > 0); 935 // assert(target.length() > 0); 936 UErrorCode status = U_ZERO_ERROR; 937 Hashtable *targets = (Hashtable*) specDAG.get(source); 938 if (targets == 0) { 939 targets = new Hashtable(TRUE, status); 940 if (U_FAILURE(status) || targets == 0) { 941 return; 942 } 943 targets->setValueDeleter(uprv_deleteUObject); 944 specDAG.put(source, targets, status); 945 } 946 UVector *variants = (UVector*) targets->get(target); 947 if (variants == 0) { 948 variants = new UVector(uprv_deleteUObject, 949 uhash_compareCaselessUnicodeString, status); 950 if (variants == 0) { 951 return; 952 } 953 targets->put(target, variants, status); 954 } 955 // assert(NO_VARIANT == ""); 956 // We add the variant string. If it is the special "no variant" 957 // string, that is, the empty string, we add it at position zero. 958 if (!variants->contains((void*) &variant)) { 959 UnicodeString *tempus; // Used for null pointer check. 960 if (variant.length() > 0) { 961 tempus = new UnicodeString(variant); 962 if (tempus != NULL) { 963 variants->addElement(tempus, status); 964 } 965 } else { 966 tempus = new UnicodeString(); // = NO_VARIANT 967 if (tempus != NULL) { 968 variants->insertElementAt(tempus, 0, status); 969 } 970 } 971 } 972 } 973 974 /** 975 * Remove a source-target/variant from the specDAG. 976 */ 977 void TransliteratorRegistry::removeSTV(const UnicodeString& source, 978 const UnicodeString& target, 979 const UnicodeString& variant) { 980 // assert(source.length() > 0); 981 // assert(target.length() > 0); 982 // UErrorCode status = U_ZERO_ERROR; 983 Hashtable *targets = (Hashtable*) specDAG.get(source); 984 if (targets == 0) { 985 return; // should never happen for valid s-t/v 986 } 987 UVector *variants = (UVector*) targets->get(target); 988 if (variants == 0) { 989 return; // should never happen for valid s-t/v 990 } 991 variants->removeElement((void*) &variant); 992 if (variants->size() == 0) { 993 targets->remove(target); // should delete variants 994 if (targets->count() == 0) { 995 specDAG.remove(source); // should delete targets 996 } 997 } 998 } 999 1000 /** 1001 * Attempt to find a source-target/variant in the dynamic registry 1002 * store. Return 0 on failure. 1003 * 1004 * Caller does NOT own returned object. 1005 */ 1006 TransliteratorEntry* TransliteratorRegistry::findInDynamicStore(const TransliteratorSpec& src, 1007 const TransliteratorSpec& trg, 1008 const UnicodeString& variant) const { 1009 UnicodeString ID; 1010 TransliteratorIDParser::STVtoID(src, trg, variant, ID); 1011 TransliteratorEntry *e = (TransliteratorEntry*) registry.get(ID); 1012 DEBUG_useEntry(e); 1013 return e; 1014 } 1015 1016 /** 1017 * Attempt to find a source-target/variant in the static locale 1018 * resource store. Do not perform fallback. Return 0 on failure. 1019 * 1020 * On success, create a new entry object, register it in the dynamic 1021 * store, and return a pointer to it, but do not make it public -- 1022 * just because someone requested something, we do not expand the 1023 * available ID list (or spec DAG). 1024 * 1025 * Caller does NOT own returned object. 1026 */ 1027 TransliteratorEntry* TransliteratorRegistry::findInStaticStore(const TransliteratorSpec& src, 1028 const TransliteratorSpec& trg, 1029 const UnicodeString& variant) { 1030 TransliteratorEntry* entry = 0; 1031 if (src.isLocale()) { 1032 entry = findInBundle(src, trg, variant, UTRANS_FORWARD); 1033 } else if (trg.isLocale()) { 1034 entry = findInBundle(trg, src, variant, UTRANS_REVERSE); 1035 } 1036 1037 // If we found an entry, store it in the Hashtable for next 1038 // time. 1039 if (entry != 0) { 1040 registerEntry(src.getTop(), trg.getTop(), variant, entry, FALSE); 1041 } 1042 1043 return entry; 1044 } 1045 1046 // As of 2.0, resource bundle keys cannot contain '_' 1047 static const UChar TRANSLITERATE_TO[] = {84,114,97,110,115,108,105,116,101,114,97,116,101,84,111,0}; // "TransliterateTo" 1048 1049 static const UChar TRANSLITERATE_FROM[] = {84,114,97,110,115,108,105,116,101,114,97,116,101,70,114,111,109,0}; // "TransliterateFrom" 1050 1051 static const UChar TRANSLITERATE[] = {84,114,97,110,115,108,105,116,101,114,97,116,101,0}; // "Transliterate" 1052 1053 /** 1054 * Attempt to find an entry in a single resource bundle. This is 1055 * a one-sided lookup. findInStaticStore() performs up to two such 1056 * lookups, one for the source, and one for the target. 1057 * 1058 * Do not perform fallback. Return 0 on failure. 1059 * 1060 * On success, create a new Entry object, populate it, and return it. 1061 * The caller owns the returned object. 1062 */ 1063 TransliteratorEntry* TransliteratorRegistry::findInBundle(const TransliteratorSpec& specToOpen, 1064 const TransliteratorSpec& specToFind, 1065 const UnicodeString& variant, 1066 UTransDirection direction) 1067 { 1068 UnicodeString utag; 1069 UnicodeString resStr; 1070 int32_t pass; 1071 1072 for (pass=0; pass<2; ++pass) { 1073 utag.truncate(0); 1074 // First try either TransliteratorTo_xxx or 1075 // TransliterateFrom_xxx, then try the bidirectional 1076 // Transliterate_xxx. This precedence order is arbitrary 1077 // but must be consistent and documented. 1078 if (pass == 0) { 1079 utag.append(direction == UTRANS_FORWARD ? 1080 TRANSLITERATE_TO : TRANSLITERATE_FROM, -1); 1081 } else { 1082 utag.append(TRANSLITERATE, -1); 1083 } 1084 UnicodeString s(specToFind.get()); 1085 utag.append(s.toUpper("")); 1086 UErrorCode status = U_ZERO_ERROR; 1087 ResourceBundle subres(specToOpen.getBundle().get( 1088 CharString().appendInvariantChars(utag, status).data(), status)); 1089 if (U_FAILURE(status) || status == U_USING_DEFAULT_WARNING) { 1090 continue; 1091 } 1092 1093 s.truncate(0); 1094 if (specToOpen.get() != LocaleUtility::initNameFromLocale(subres.getLocale(), s)) { 1095 continue; 1096 } 1097 1098 if (variant.length() != 0) { 1099 status = U_ZERO_ERROR; 1100 resStr = subres.getStringEx( 1101 CharString().appendInvariantChars(variant, status).data(), status); 1102 if (U_SUCCESS(status)) { 1103 // Exit loop successfully 1104 break; 1105 } 1106 } else { 1107 // Variant is empty, which means match the first variant listed. 1108 status = U_ZERO_ERROR; 1109 resStr = subres.getStringEx(1, status); 1110 if (U_SUCCESS(status)) { 1111 // Exit loop successfully 1112 break; 1113 } 1114 } 1115 } 1116 1117 if (pass==2) { 1118 // Failed 1119 return NULL; 1120 } 1121 1122 // We have succeeded in loading a string from the locale 1123 // resources. Create a new registry entry to hold it and return it. 1124 TransliteratorEntry *entry = new TransliteratorEntry(); 1125 if (entry != 0) { 1126 // The direction is always forward for the 1127 // TransliterateTo_xxx and TransliterateFrom_xxx 1128 // items; those are unidirectional forward rules. 1129 // For the bidirectional Transliterate_xxx items, 1130 // the direction is the value passed in to this 1131 // function. 1132 int32_t dir = (pass == 0) ? UTRANS_FORWARD : direction; 1133 entry->entryType = TransliteratorEntry::LOCALE_RULES; 1134 entry->stringArg = resStr; 1135 entry->intArg = dir; 1136 } 1137 1138 return entry; 1139 } 1140 1141 /** 1142 * Convenience method. Calls 3-arg find(). 1143 */ 1144 TransliteratorEntry* TransliteratorRegistry::find(const UnicodeString& ID) { 1145 UnicodeString source, target, variant; 1146 UBool sawSource; 1147 TransliteratorIDParser::IDtoSTV(ID, source, target, variant, sawSource); 1148 return find(source, target, variant); 1149 } 1150 1151 /** 1152 * Top-level find method. Attempt to find a source-target/variant in 1153 * either the dynamic or the static (locale resource) store. Perform 1154 * fallback. 1155 * 1156 * Lookup sequence for ss_SS_SSS-tt_TT_TTT/v: 1157 * 1158 * ss_SS_SSS-tt_TT_TTT/v -- in hashtable 1159 * ss_SS_SSS-tt_TT_TTT/v -- in ss_SS_SSS (no fallback) 1160 * 1161 * repeat with t = tt_TT_TTT, tt_TT, tt, and tscript 1162 * 1163 * ss_SS_SSS-t/ * 1164 * ss_SS-t/ * 1165 * ss-t/ * 1166 * sscript-t/ * 1167 * 1168 * Here * matches the first variant listed. 1169 * 1170 * Caller does NOT own returned object. Return 0 on failure. 1171 */ 1172 TransliteratorEntry* TransliteratorRegistry::find(UnicodeString& source, 1173 UnicodeString& target, 1174 UnicodeString& variant) { 1175 1176 TransliteratorSpec src(source); 1177 TransliteratorSpec trg(target); 1178 TransliteratorEntry* entry; 1179 1180 // Seek exact match in hashtable. Temporary fix for ICU 4.6. 1181 // TODO: The general logic for finding a matching transliterator needs to be reviewed. 1182 // ICU ticket #8089 1183 UnicodeString ID; 1184 TransliteratorIDParser::STVtoID(source, target, variant, ID); 1185 entry = (TransliteratorEntry*) registry.get(ID); 1186 if (entry != 0) { 1187 // std::string ss; 1188 // std::cout << ID.toUTF8String(ss) << std::endl; 1189 return entry; 1190 } 1191 1192 if (variant.length() != 0) { 1193 1194 // Seek exact match in hashtable 1195 entry = findInDynamicStore(src, trg, variant); 1196 if (entry != 0) { 1197 return entry; 1198 } 1199 1200 // Seek exact match in locale resources 1201 entry = findInStaticStore(src, trg, variant); 1202 if (entry != 0) { 1203 return entry; 1204 } 1205 } 1206 1207 for (;;) { 1208 src.reset(); 1209 for (;;) { 1210 // Seek match in hashtable 1211 entry = findInDynamicStore(src, trg, NO_VARIANT); 1212 if (entry != 0) { 1213 return entry; 1214 } 1215 1216 // Seek match in locale resources 1217 entry = findInStaticStore(src, trg, NO_VARIANT); 1218 if (entry != 0) { 1219 return entry; 1220 } 1221 if (!src.hasFallback()) { 1222 break; 1223 } 1224 src.next(); 1225 } 1226 if (!trg.hasFallback()) { 1227 break; 1228 } 1229 trg.next(); 1230 } 1231 1232 return 0; 1233 } 1234 1235 /** 1236 * Given an Entry object, instantiate it. Caller owns result. Return 1237 * 0 on failure. 1238 * 1239 * Return a non-empty aliasReturn value if the ID points to an alias. 1240 * We cannot instantiate it ourselves because the alias may contain 1241 * filters or compounds, which we do not understand. Caller should 1242 * make aliasReturn empty before calling. 1243 * 1244 * The entry object is assumed to reside in the dynamic store. It may be 1245 * modified. 1246 */ 1247 Transliterator* TransliteratorRegistry::instantiateEntry(const UnicodeString& ID, 1248 TransliteratorEntry *entry, 1249 TransliteratorAlias* &aliasReturn, 1250 UErrorCode& status) { 1251 Transliterator *t = 0; 1252 U_ASSERT(aliasReturn == 0); 1253 1254 switch (entry->entryType) { 1255 case TransliteratorEntry::RBT_DATA: 1256 t = new RuleBasedTransliterator(ID, entry->u.data); 1257 if (t == 0) { 1258 status = U_MEMORY_ALLOCATION_ERROR; 1259 } 1260 return t; 1261 case TransliteratorEntry::PROTOTYPE: 1262 t = entry->u.prototype->clone(); 1263 if (t == 0) { 1264 status = U_MEMORY_ALLOCATION_ERROR; 1265 } 1266 return t; 1267 case TransliteratorEntry::ALIAS: 1268 aliasReturn = new TransliteratorAlias(entry->stringArg, entry->compoundFilter); 1269 if (aliasReturn == 0) { 1270 status = U_MEMORY_ALLOCATION_ERROR; 1271 } 1272 return 0; 1273 case TransliteratorEntry::FACTORY: 1274 t = entry->u.factory.function(ID, entry->u.factory.context); 1275 if (t == 0) { 1276 status = U_MEMORY_ALLOCATION_ERROR; 1277 } 1278 return t; 1279 case TransliteratorEntry::COMPOUND_RBT: 1280 { 1281 UVector* rbts = new UVector(entry->u.dataVector->size(), status); 1282 // Check for null pointer 1283 if (rbts == NULL) { 1284 status = U_MEMORY_ALLOCATION_ERROR; 1285 return NULL; 1286 } 1287 int32_t passNumber = 1; 1288 for (int32_t i = 0; U_SUCCESS(status) && i < entry->u.dataVector->size(); i++) { 1289 // TODO: Should passNumber be turned into a decimal-string representation (1 -> "1")? 1290 Transliterator* t = new RuleBasedTransliterator(UnicodeString(CompoundTransliterator::PASS_STRING) + UnicodeString(passNumber++), 1291 (TransliterationRuleData*)(entry->u.dataVector->elementAt(i)), FALSE); 1292 if (t == 0) 1293 status = U_MEMORY_ALLOCATION_ERROR; 1294 else 1295 rbts->addElement(t, status); 1296 } 1297 if (U_FAILURE(status)) { 1298 delete rbts; 1299 return 0; 1300 } 1301 aliasReturn = new TransliteratorAlias(ID, entry->stringArg, rbts, entry->compoundFilter); 1302 } 1303 if (aliasReturn == 0) { 1304 status = U_MEMORY_ALLOCATION_ERROR; 1305 } 1306 return 0; 1307 case TransliteratorEntry::LOCALE_RULES: 1308 aliasReturn = new TransliteratorAlias(ID, entry->stringArg, 1309 (UTransDirection) entry->intArg); 1310 if (aliasReturn == 0) { 1311 status = U_MEMORY_ALLOCATION_ERROR; 1312 } 1313 return 0; 1314 case TransliteratorEntry::RULES_FORWARD: 1315 case TransliteratorEntry::RULES_REVERSE: 1316 // Process the rule data into a TransliteratorRuleData object, 1317 // and possibly also into an ::id header and/or footer. Then 1318 // we modify the registry with the parsed data and retry. 1319 { 1320 TransliteratorParser parser(status); 1321 1322 // We use the file name, taken from another resource bundle 1323 // 2-d array at static init time, as a locale language. We're 1324 // just using the locale mechanism to map through to a file 1325 // name; this in no way represents an actual locale. 1326 //CharString ch(entry->stringArg); 1327 //UResourceBundle *bundle = ures_openDirect(0, ch, &status); 1328 UnicodeString rules = entry->stringArg; 1329 //ures_close(bundle); 1330 1331 //if (U_FAILURE(status)) { 1332 // We have a failure of some kind. Remove the ID from the 1333 // registry so we don't keep trying. NOTE: This will throw off 1334 // anyone who is, at the moment, trying to iterate over the 1335 // available IDs. That's acceptable since we should never 1336 // really get here except under installation, configuration, 1337 // or unrecoverable run time memory failures. 1338 // remove(ID); 1339 //} else { 1340 1341 // If the status indicates a failure, then we don't have any 1342 // rules -- there is probably an installation error. The list 1343 // in the root locale should correspond to all the installed 1344 // transliterators; if it lists something that's not 1345 // installed, we'll get an error from ResourceBundle. 1346 aliasReturn = new TransliteratorAlias(ID, rules, 1347 ((entry->entryType == TransliteratorEntry::RULES_REVERSE) ? 1348 UTRANS_REVERSE : UTRANS_FORWARD)); 1349 if (aliasReturn == 0) { 1350 status = U_MEMORY_ALLOCATION_ERROR; 1351 } 1352 //} 1353 } 1354 return 0; 1355 default: 1356 U_ASSERT(FALSE); // can't get here 1357 return 0; 1358 } 1359 } 1360 U_NAMESPACE_END 1361 1362 #endif /* #if !UCONFIG_NO_TRANSLITERATION */ 1363 1364 //eof 1365
