/* ********************************************************************** * Copyright (C) 1999-2011, International Business Machines * Corporation and others. All Rights Reserved. ********************************************************************** * Date Name Description * 11/17/99 aliu Creation. ********************************************************************** */ #include "unicode/utypes.h" #if !UCONFIG_NO_TRANSLITERATION #include "unicode/unistr.h" #include "unicode/uniset.h" #include "unicode/utf16.h" #include "rbt_set.h" #include "rbt_rule.h" #include "cmemory.h" #include "putilimp.h" U_CDECL_BEGIN static void U_CALLCONV _deleteRule(void *rule) { delete (icu::TransliterationRule *)rule; } U_CDECL_END //---------------------------------------------------------------------- // BEGIN Debugging support //---------------------------------------------------------------------- // #define DEBUG_RBT #ifdef DEBUG_RBT #include <stdio.h> #include "charstr.h" /** * @param appendTo result is appended to this param. * @param input the string being transliterated * @param pos the index struct */ static UnicodeString& _formatInput(UnicodeString &appendTo, const UnicodeString& input, const UTransPosition& pos) { // Output a string of the form aaa{bbb|ccc|ddd}eee, where // the {} indicate the context start and limit, and the || // indicate the start and limit. if (0 <= pos.contextStart && pos.contextStart <= pos.start && pos.start <= pos.limit && pos.limit <= pos.contextLimit && pos.contextLimit <= input.length()) { UnicodeString a, b, c, d, e; input.extractBetween(0, pos.contextStart, a); input.extractBetween(pos.contextStart, pos.start, b); input.extractBetween(pos.start, pos.limit, c); input.extractBetween(pos.limit, pos.contextLimit, d); input.extractBetween(pos.contextLimit, input.length(), e); appendTo.append(a).append((UChar)123/*{*/).append(b). append((UChar)124/*|*/).append(c).append((UChar)124/*|*/).append(d). append((UChar)125/*}*/).append(e); } else { appendTo.append("INVALID UTransPosition"); //appendTo.append((UnicodeString)"INVALID UTransPosition {cs=" + // pos.contextStart + ", s=" + pos.start + ", l=" + // pos.limit + ", cl=" + pos.contextLimit + "} on " + // input); } return appendTo; } // Append a hex string to the target UnicodeString& _appendHex(uint32_t number, int32_t digits, UnicodeString& target) { static const UChar digitString[] = { 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, 0 }; while (digits--) { target += digitString[(number >> (digits*4)) & 0xF]; } return target; } // Replace nonprintable characters with unicode escapes UnicodeString& _escape(const UnicodeString &source, UnicodeString &target) { for (int32_t i = 0; i < source.length(); ) { UChar32 ch = source.char32At(i); i += U16_LENGTH(ch); if (ch < 0x09 || (ch > 0x0A && ch < 0x20)|| ch > 0x7E) { if (ch <= 0xFFFF) { target += "\\u"; _appendHex(ch, 4, target); } else { target += "\\U"; _appendHex(ch, 8, target); } } else { target += ch; } } return target; } inline void _debugOut(const char* msg, TransliterationRule* rule, const Replaceable& theText, UTransPosition& pos) { UnicodeString buf(msg, ""); if (rule) { UnicodeString r; rule->toRule(r, TRUE); buf.append((UChar)32).append(r); } buf.append(UnicodeString(" => ", "")); UnicodeString* text = (UnicodeString*)&theText; _formatInput(buf, *text, pos); UnicodeString esc; _escape(buf, esc); CharString cbuf(esc); printf("%s\n", (const char*) cbuf); } #else #define _debugOut(msg, rule, theText, pos) #endif //---------------------------------------------------------------------- // END Debugging support //---------------------------------------------------------------------- // Fill the precontext and postcontext with the patterns of the rules // that are masking one another. static void maskingError(const icu::TransliterationRule& rule1, const icu::TransliterationRule& rule2, UParseError& parseError) { icu::UnicodeString r; int32_t len; parseError.line = parseError.offset = -1; // for pre-context rule1.toRule(r, FALSE); len = uprv_min(r.length(), U_PARSE_CONTEXT_LEN-1); r.extract(0, len, parseError.preContext); parseError.preContext[len] = 0; //for post-context r.truncate(0); rule2.toRule(r, FALSE); len = uprv_min(r.length(), U_PARSE_CONTEXT_LEN-1); r.extract(0, len, parseError.postContext); parseError.postContext[len] = 0; } U_NAMESPACE_BEGIN /** * Construct a new empty rule set. */ TransliterationRuleSet::TransliterationRuleSet(UErrorCode& status) : UMemory() { ruleVector = new UVector(&_deleteRule, NULL, status); if (U_FAILURE(status)) { return; } if (ruleVector == NULL) { status = U_MEMORY_ALLOCATION_ERROR; } rules = NULL; maxContextLength = 0; } /** * Copy constructor. */ TransliterationRuleSet::TransliterationRuleSet(const TransliterationRuleSet& other) : UMemory(other), ruleVector(0), rules(0), maxContextLength(other.maxContextLength) { int32_t i, len; uprv_memcpy(index, other.index, sizeof(index)); UErrorCode status = U_ZERO_ERROR; ruleVector = new UVector(&_deleteRule, NULL, status); if (other.ruleVector != 0 && ruleVector != 0 && U_SUCCESS(status)) { len = other.ruleVector->size(); for (i=0; i<len && U_SUCCESS(status); ++i) { TransliterationRule *tempTranslitRule = new TransliterationRule(*(TransliterationRule*)other.ruleVector->elementAt(i)); // Null pointer test if (tempTranslitRule == NULL) { status = U_MEMORY_ALLOCATION_ERROR; break; } ruleVector->addElement(tempTranslitRule, status); if (U_FAILURE(status)) { break; } } } if (other.rules != 0 && U_SUCCESS(status)) { UParseError p; freeze(p, status); } } /** * Destructor. */ TransliterationRuleSet::~TransliterationRuleSet() { delete ruleVector; // This deletes the contained rules uprv_free(rules); } void TransliterationRuleSet::setData(const TransliterationRuleData* d) { /** * We assume that the ruleset has already been frozen. */ int32_t len = index[256]; // see freeze() for (int32_t i=0; i<len; ++i) { rules[i]->setData(d); } } /** * Return the maximum context length. * @return the length of the longest preceding context. */ int32_t TransliterationRuleSet::getMaximumContextLength(void) const { return maxContextLength; } /** * Add a rule to this set. Rules are added in order, and order is * significant. The last call to this method must be followed by * a call to <code>freeze()</code> before the rule set is used. * * <p>If freeze() has already been called, calling addRule() * unfreezes the rules, and freeze() must be called again. * * @param adoptedRule the rule to add */ void TransliterationRuleSet::addRule(TransliterationRule* adoptedRule, UErrorCode& status) { if (U_FAILURE(status)) { delete adoptedRule; return; } ruleVector->addElement(adoptedRule, status); int32_t len; if ((len = adoptedRule->getContextLength()) > maxContextLength) { maxContextLength = len; } uprv_free(rules); rules = 0; } /** * Check this for masked rules and index it to optimize performance. * The sequence of operations is: (1) add rules to a set using * <code>addRule()</code>; (2) freeze the set using * <code>freeze()</code>; (3) use the rule set. If * <code>addRule()</code> is called after calling this method, it * invalidates this object, and this method must be called again. * That is, <code>freeze()</code> may be called multiple times, * although for optimal performance it shouldn't be. */ void TransliterationRuleSet::freeze(UParseError& parseError,UErrorCode& status) { /* Construct the rule array and index table. We reorder the * rules by sorting them into 256 bins. Each bin contains all * rules matching the index value for that bin. A rule * matches an index value if string whose first key character * has a low byte equal to the index value can match the rule. * * Each bin contains zero or more rules, in the same order * they were found originally. However, the total rules in * the bins may exceed the number in the original vector, * since rules that have a variable as their first key * character will generally fall into more than one bin. * * That is, each bin contains all rules that either have that * first index value as their first key character, or have * a set containing the index value as their first character. */ int32_t n = ruleVector->size(); int32_t j; int16_t x; UVector v(2*n, status); // heuristic; adjust as needed if (U_FAILURE(status)) { return; } /* Precompute the index values. This saves a LOT of time. * Be careful not to call malloc(0). */ int16_t* indexValue = (int16_t*) uprv_malloc( sizeof(int16_t) * (n > 0 ? n : 1) ); /* test for NULL */ if (indexValue == 0) { status = U_MEMORY_ALLOCATION_ERROR; return; } for (j=0; j<n; ++j) { TransliterationRule* r = (TransliterationRule*) ruleVector->elementAt(j); indexValue[j] = r->getIndexValue(); } for (x=0; x<256; ++x) { index[x] = v.size(); for (j=0; j<n; ++j) { if (indexValue[j] >= 0) { if (indexValue[j] == x) { v.addElement(ruleVector->elementAt(j), status); } } else { // If the indexValue is < 0, then the first key character is // a set, and we must use the more time-consuming // matchesIndexValue check. In practice this happens // rarely, so we seldom tread this code path. TransliterationRule* r = (TransliterationRule*) ruleVector->elementAt(j); if (r->matchesIndexValue((uint8_t)x)) { v.addElement(r, status); } } } } uprv_free(indexValue); index[256] = v.size(); /* Freeze things into an array. */ uprv_free(rules); // Contains alias pointers /* You can't do malloc(0)! */ if (v.size() == 0) { rules = NULL; return; } rules = (TransliterationRule **)uprv_malloc(v.size() * sizeof(TransliterationRule *)); /* test for NULL */ if (rules == 0) { status = U_MEMORY_ALLOCATION_ERROR; return; } for (j=0; j<v.size(); ++j) { rules[j] = (TransliterationRule*) v.elementAt(j); } // TODO Add error reporting that indicates the rules that // are being masked. //UnicodeString errors; /* Check for masking. This is MUCH faster than our old check, * which was each rule against each following rule, since we * only have to check for masking within each bin now. It's * 256*O(n2^2) instead of O(n1^2), where n1 is the total rule * count, and n2 is the per-bin rule count. But n2<<n1, so * it's a big win. */ for (x=0; x<256; ++x) { for (j=index[x]; j<index[x+1]-1; ++j) { TransliterationRule* r1 = rules[j]; for (int32_t k=j+1; k<index[x+1]; ++k) { TransliterationRule* r2 = rules[k]; if (r1->masks(*r2)) { //| if (errors == null) { //| errors = new StringBuffer(); //| } else { //| errors.append("\n"); //| } //| errors.append("Rule " + r1 + " masks " + r2); status = U_RULE_MASK_ERROR; maskingError(*r1, *r2, parseError); return; } } } } //if (errors != null) { // throw new IllegalArgumentException(errors.toString()); //} } /** * Transliterate the given text with the given UTransPosition * indices. Return TRUE if the transliteration should continue * or FALSE if it should halt (because of a U_PARTIAL_MATCH match). * Note that FALSE is only ever returned if isIncremental is TRUE. * @param text the text to be transliterated * @param pos the position indices, which will be updated * @param incremental if TRUE, assume new text may be inserted * at index.limit, and return FALSE if thre is a partial match. * @return TRUE unless a U_PARTIAL_MATCH has been obtained, * indicating that transliteration should stop until more text * arrives. */ UBool TransliterationRuleSet::transliterate(Replaceable& text, UTransPosition& pos, UBool incremental) { int16_t indexByte = (int16_t) (text.char32At(pos.start) & 0xFF); for (int32_t i=index[indexByte]; i<index[indexByte+1]; ++i) { UMatchDegree m = rules[i]->matchAndReplace(text, pos, incremental); switch (m) { case U_MATCH: _debugOut("match", rules[i], text, pos); return TRUE; case U_PARTIAL_MATCH: _debugOut("partial match", rules[i], text, pos); return FALSE; default: /* Ram: added default to make GCC happy */ break; } } // No match or partial match from any rule pos.start += U16_LENGTH(text.char32At(pos.start)); _debugOut("no match", NULL, text, pos); return TRUE; } /** * Create rule strings that represents this rule set. */ UnicodeString& TransliterationRuleSet::toRules(UnicodeString& ruleSource, UBool escapeUnprintable) const { int32_t i; int32_t count = ruleVector->size(); ruleSource.truncate(0); for (i=0; i<count; ++i) { if (i != 0) { ruleSource.append((UChar) 0x000A /*\n*/); } TransliterationRule *r = (TransliterationRule*) ruleVector->elementAt(i); r->toRule(ruleSource, escapeUnprintable); } return ruleSource; } /** * Return the set of all characters that may be modified * (getTarget=false) or emitted (getTarget=true) by this set. */ UnicodeSet& TransliterationRuleSet::getSourceTargetSet(UnicodeSet& result, UBool getTarget) const { result.clear(); int32_t count = ruleVector->size(); for (int32_t i=0; i<count; ++i) { TransliterationRule* r = (TransliterationRule*) ruleVector->elementAt(i); if (getTarget) { r->addTargetSetTo(result); } else { r->addSourceSetTo(result); } } return result; } U_NAMESPACE_END #endif /* #if !UCONFIG_NO_TRANSLITERATION */