XMLCh* RegularExpression::replace(const XMLCh* const matchString, const XMLCh* const replaceString, const int start, const int end) { //check if matches zero length string - throw error if so if (matches(XMLUni::fgZeroLenString, fMemoryManager)){ ThrowXMLwithMemMgr(RuntimeException, XMLExcepts::Regex_RepPatMatchesZeroString, fMemoryManager); } RefVectorOf<Match> *subEx = new (fMemoryManager) RefVectorOf<Match>(10, true, fMemoryManager); Janitor<RefVectorOf<Match> > janSubEx(subEx); //Call to tokenize with Match vector so that we keep track of the locations //of the subExpression within each of the matches RefArrayVectorOf<XMLCh>* tokenStack = tokenize(matchString, start, end, subEx); Janitor<RefArrayVectorOf<XMLCh> > janTokStack(tokenStack); XMLBuffer result(1023, fMemoryManager); int numSubEx = 0; if (subEx && subEx->size() > 0) numSubEx = subEx->elementAt(0)->getNoGroups() - 1; int tokStackSize = tokenStack->size(); const XMLCh* curRepString = XMLString::replicate(replaceString, fMemoryManager); for (int i = 0; i < tokStackSize; i++){ result.append(tokenStack->elementAt(i)); if (i != tokStackSize - 1) { //if there are subExpressions, then determine the string we want to //substitute in. if (numSubEx != 0) { fMemoryManager->deallocate((XMLCh*)curRepString); curRepString = subInExp(replaceString, matchString, subEx->elementAt(i)); } result.append(curRepString); } } fMemoryManager->deallocate((XMLCh*)curRepString); return XMLString::replicate(result.getRawBuffer(), fMemoryManager); }
inline bool SchemaInfo::circularImportExist(const unsigned int namespaceURI) { unsigned int importSize = fImportingInfoList->size(); for (unsigned int i=0; i < importSize; i++) { if (fImportingInfoList->elementAt(i)->getTargetNSURI() == (int) namespaceURI) { return true; } } return false; }
inline SchemaInfo* SchemaInfo::getImportInfo(const unsigned int namespaceURI) const { unsigned int importSize = (fImportedInfoList) ? fImportedInfoList->size() : 0; SchemaInfo* currInfo = 0; for (unsigned int i=0; i < importSize; i++) { currInfo = fImportedInfoList->elementAt(i); if (currInfo->getTargetNSURI() == (int) namespaceURI) break; } return currInfo; }
int UnionDatatypeValidator::compare(const XMLCh* const lValue , const XMLCh* const rValue , MemoryManager* const manager) { RefVectorOf<DatatypeValidator>* memberDTV = getMemberTypeValidators(); unsigned int memberTypeNumber = memberDTV->size(); for ( unsigned int memberIndex = 0; memberIndex < memberTypeNumber; ++memberIndex) { if (memberDTV->elementAt(memberIndex)->compare(lValue, rValue, manager) ==0) return 0; } //REVISIT: what does it mean for UNION1 to be <less than> or <greater than> UNION2 ? // As long as -1 or +1 indicates an unequality, return either of them is ok. return -1; }
void XSDDOMParser::startAnnotationElement( const XMLElementDecl& elemDecl , const RefVectorOf<XMLAttr>& attrList , const unsigned int attrCount) { fAnnotationBuf.append(chOpenAngle); fAnnotationBuf.append(elemDecl.getFullName()); //fAnnotationBuf.append(chSpace); for(unsigned int i=0; i < attrCount; i++) { const XMLAttr* oneAttr = attrList.elementAt(i); fAnnotationBuf.append(chSpace); fAnnotationBuf.append(oneAttr ->getQName()); fAnnotationBuf.append(chEqual); fAnnotationBuf.append(chDoubleQuote); fAnnotationBuf.append(oneAttr->getValue()); fAnnotationBuf.append(chDoubleQuote); } fAnnotationBuf.append(chCloseAngle); }
void XSDDOMParser::startAnnotation( const XMLElementDecl& elemDecl , const RefVectorOf<XMLAttr>& attrList , const unsigned int attrCount) { fAnnotationBuf.append(chOpenAngle); fAnnotationBuf.append(elemDecl.getFullName()); fAnnotationBuf.append(chSpace); // attributes are a bit of a pain. To get this right, we have to keep track // of the namespaces we've seen declared, then examine the namespace context // for other namespaces so that we can also include them. // optimized for simplicity and the case that not many // namespaces are declared on this annotation... fURIs->removeAllElements(); for (unsigned int i=0; i < attrCount; i++) { const XMLAttr* oneAttrib = attrList.elementAt(i); const XMLCh* attrValue = oneAttrib->getValue(); if (XMLString::equals(oneAttrib->getName(), XMLUni::fgXMLNSString)) fURIs->addElement(fScanner->getPrefixId(XMLUni::fgZeroLenString)); else if (!XMLString::compareNString(oneAttrib->getQName(), XMLUni::fgXMLNSColonString, 6)) fURIs->addElement(fScanner->getPrefixId(oneAttrib->getName())); fAnnotationBuf.append(oneAttrib->getQName()); fAnnotationBuf.append(chEqual); fAnnotationBuf.append(chDoubleQuote); fAnnotationBuf.append(attrValue); fAnnotationBuf.append(chDoubleQuote); fAnnotationBuf.append(chSpace); } // now we have to look through currently in-scope namespaces to see what // wasn't declared here ValueVectorOf<PrefMapElem*>* namespaceContext = fScanner->getNamespaceContext(); for (unsigned int j=0; j < namespaceContext->size(); j++) { unsigned int prefId = namespaceContext->elementAt(j)->fPrefId; if (!fURIs->containsElement(prefId)) { const XMLCh* prefix = fScanner->getPrefixForId(prefId); if (XMLString::equals(prefix, XMLUni::fgZeroLenString)) { fAnnotationBuf.append(XMLUni::fgXMLNSString); } else { fAnnotationBuf.append(XMLUni::fgXMLNSColonString); fAnnotationBuf.append(prefix); } fAnnotationBuf.append(chEqual); fAnnotationBuf.append(chDoubleQuote); fAnnotationBuf.append(fScanner->getURIText(namespaceContext->elementAt(j)->fURIId)); fAnnotationBuf.append(chDoubleQuote); fAnnotationBuf.append(chSpace); } } fAnnotationBuf.append(chCloseAngle); fAnnotationBuf.append(chLF); }
// --------------------------------------------------------------------------- // XSDDOMParser: Implementation of the XMLDocumentHandler interface // --------------------------------------------------------------------------- void XSDDOMParser::startElement( const XMLElementDecl& elemDecl , const unsigned int urlId , const XMLCh* const elemPrefix , const RefVectorOf<XMLAttr>& attrList , const unsigned int attrCount , const bool isEmpty , const bool isRoot) { fDepth++; // while it is true that non-whitespace character data // may only occur in appInfo or documentation // elements, it's certainly legal for comments and PI's to // occur as children of annotation; we need // to account for these here. if (fAnnotationDepth == -1) { if (XMLString::equals(elemDecl.getBaseName(), SchemaSymbols::fgELT_ANNOTATION) && XMLString::equals(getURIText(urlId), SchemaSymbols::fgURI_SCHEMAFORSCHEMA)) { fAnnotationDepth = fDepth; startAnnotation(elemDecl, attrList, attrCount); } } else if (fDepth == fAnnotationDepth+1) { fInnerAnnotationDepth = fDepth; startAnnotationElement(elemDecl, attrList, attrCount); } else { startAnnotationElement(elemDecl, attrList, attrCount); // avoid falling through; don't call startElement in this case return; } DOMElement *elem; if (urlId != fScanner->getEmptyNamespaceId()) //TagName has a prefix { if (elemPrefix && *elemPrefix) { XMLBufBid elemQName(&fBufMgr); elemQName.set(elemPrefix); elemQName.append(chColon); elemQName.append(elemDecl.getBaseName()); elem = createElementNSNode( fScanner->getURIText(urlId), elemQName.getRawBuffer()); } else { elem = createElementNSNode( fScanner->getURIText(urlId), elemDecl.getBaseName()); } } else { elem = createElementNSNode(0, elemDecl.getBaseName()); } DOMElementImpl *elemImpl = (DOMElementImpl *) elem; for (unsigned int index = 0; index < attrCount; ++index) { const XMLAttr* oneAttrib = attrList.elementAt(index); unsigned int attrURIId = oneAttrib->getURIId(); const XMLCh* namespaceURI = 0; //for xmlns=... if (XMLString::equals(oneAttrib->getName(), XMLUni::fgXMLNSString)) attrURIId = fScanner->getXMLNSNamespaceId(); //TagName has a prefix if (attrURIId != fScanner->getEmptyNamespaceId()) namespaceURI = fScanner->getURIText(attrURIId); //get namespaceURI // revisit. Optimize to init the named node map to the // right size up front. DOMAttrImpl *attr = (DOMAttrImpl *) fDocument->createAttributeNS(namespaceURI, oneAttrib->getQName()); attr->setValue(oneAttrib -> getValue()); DOMNode* remAttr = elemImpl->setAttributeNodeNS(attr); if (remAttr) remAttr->release(); // Attributes of type ID. If this is one, add it to the hashtable of IDs // that is constructed for use by GetElementByID(). if (oneAttrib->getType()==XMLAttDef::ID) { if (fDocument->fNodeIDMap == 0) fDocument->fNodeIDMap = new (fDocument) DOMNodeIDMap(500, fDocument); fDocument->fNodeIDMap->add(attr); attr->fNode.isIdAttr(true); } attr->setSpecified(oneAttrib->getSpecified()); } // set up the default attributes if (elemDecl.hasAttDefs()) { XMLAttDefList* defAttrs = &elemDecl.getAttDefList(); XMLAttDef* attr = 0; DOMAttrImpl * insertAttr = 0; while (defAttrs->hasMoreElements()) { attr = &defAttrs->nextElement(); const XMLAttDef::DefAttTypes defType = attr->getDefaultType(); if ((defType == XMLAttDef::Default) || (defType == XMLAttDef::Fixed)) { // DOM Level 2 wants all namespace declaration attributes // to be bound to "http://www.w3.org/2000/xmlns/" // So as long as the XML parser doesn't do it, it needs to // done here. const XMLCh* qualifiedName = attr->getFullName(); XMLBufBid bbPrefixQName(&fBufMgr); XMLBuffer& prefixBuf = bbPrefixQName.getBuffer(); int colonPos = -1; unsigned int uriId = fScanner->resolveQName(qualifiedName, prefixBuf, ElemStack::Mode_Attribute, colonPos); const XMLCh* namespaceURI = 0; if (XMLString::equals(qualifiedName, XMLUni::fgXMLNSString)) uriId = fScanner->getXMLNSNamespaceId(); //TagName has a prefix if (uriId != fScanner->getEmptyNamespaceId()) namespaceURI = fScanner->getURIText(uriId); insertAttr = (DOMAttrImpl *) fDocument->createAttributeNS( namespaceURI, qualifiedName); DOMAttr* remAttr = elemImpl->setDefaultAttributeNodeNS(insertAttr); if (remAttr) remAttr->release(); if (attr->getValue() != 0) { insertAttr->setValue(attr->getValue()); insertAttr->setSpecified(false); } } insertAttr = 0; attr->reset(); } } fCurrentParent->appendChild(elem); fNodeStack->push(fCurrentParent); fCurrentParent = elem; fCurrentNode = elem; fWithinElement = true; // If an empty element, do end right now (no endElement() will be called) if (isEmpty) endElement(elemDecl, urlId, isRoot, elemPrefix); }
void processDatatypeValidator( const DatatypeValidator* dtValidator, bool margin ) { if( !dtValidator ) { return; } if( margin ) { XERCES_STD_QUALIFIER cout << "\t"; } XERCES_STD_QUALIFIER cout << "Base Datatype:\t\t"; switch( dtValidator->getType() ) { case DatatypeValidator::String: XERCES_STD_QUALIFIER cout << "string"; break; case DatatypeValidator::AnyURI: XERCES_STD_QUALIFIER cout << "AnyURI"; break; case DatatypeValidator::QName: XERCES_STD_QUALIFIER cout << "QName"; break; case DatatypeValidator::Name: XERCES_STD_QUALIFIER cout << "Name"; break; case DatatypeValidator::NCName: XERCES_STD_QUALIFIER cout << "NCName"; break; case DatatypeValidator::Boolean: XERCES_STD_QUALIFIER cout << "Boolean"; break; case DatatypeValidator::Float: XERCES_STD_QUALIFIER cout << "Float"; break; case DatatypeValidator::Double: XERCES_STD_QUALIFIER cout << "Double"; break; case DatatypeValidator::Decimal: XERCES_STD_QUALIFIER cout << "Decimal"; break; case DatatypeValidator::HexBinary: XERCES_STD_QUALIFIER cout << "HexBinary"; break; case DatatypeValidator::Base64Binary: XERCES_STD_QUALIFIER cout << "Base64Binary";break; case DatatypeValidator::Duration: XERCES_STD_QUALIFIER cout << "Duration"; break; case DatatypeValidator::DateTime: XERCES_STD_QUALIFIER cout << "DateTime"; break; case DatatypeValidator::Date: XERCES_STD_QUALIFIER cout << "Date"; break; case DatatypeValidator::Time: XERCES_STD_QUALIFIER cout << "Time"; break; case DatatypeValidator::MonthDay: XERCES_STD_QUALIFIER cout << "MonthDay"; break; case DatatypeValidator::YearMonth: XERCES_STD_QUALIFIER cout << "YearMonth"; break; case DatatypeValidator::Year: XERCES_STD_QUALIFIER cout << "Year"; break; case DatatypeValidator::Month: XERCES_STD_QUALIFIER cout << "Month"; break; case DatatypeValidator::Day: XERCES_STD_QUALIFIER cout << "Day"; break; case DatatypeValidator::ID: XERCES_STD_QUALIFIER cout << "ID"; break; case DatatypeValidator::IDREF: XERCES_STD_QUALIFIER cout << "IDREF"; break; case DatatypeValidator::ENTITY: XERCES_STD_QUALIFIER cout << "ENTITY"; break; case DatatypeValidator::NOTATION: XERCES_STD_QUALIFIER cout << "NOTATION"; break; case DatatypeValidator::List: XERCES_STD_QUALIFIER cout << "List"; break; case DatatypeValidator::Union: XERCES_STD_QUALIFIER cout << "Union"; break; case DatatypeValidator::AnySimpleType: XERCES_STD_QUALIFIER cout << "AnySimpleType"; break; case DatatypeValidator::UnKnown: XERCES_STD_QUALIFIER cout << "UNKNOWN"; break; } XERCES_STD_QUALIFIER cout << "\n"; // Facets RefHashTableOf<KVStringPair>* facets = dtValidator->getFacets(); if( facets && facets->getCount()>0) { XMLSize_t i; // Element's properties XERCES_STD_QUALIFIER cout << "Facets:\t\t\n"; // use a list to print them sorted, or the list could be different on 64-bit machines RefVectorOf<XMLCh> sortedList(facets->getCount(), false); RefHashTableOfEnumerator<KVStringPair> enumFacets(facets); while( enumFacets.hasMoreElements() ) { const KVStringPair& curPair = enumFacets.nextElement(); const XMLCh* key=curPair.getKey(); XMLSize_t len=sortedList.size(); for(i=0;i<len;i++) if(XMLString::compareString(key, sortedList.elementAt(i))<0) { sortedList.insertElementAt((XMLCh*)key,i); break; } if(i==len) sortedList.addElement((XMLCh*)key); } XMLSize_t len=sortedList.size(); for(i=0;i<len;i++) { const XMLCh* key = sortedList.elementAt(i); XERCES_STD_QUALIFIER cout << "\t" << StrX( key ) << "=" << StrX( facets->get(key)->getValue() ) << "\n"; } } // Enumerations RefVectorOf<XMLCh>* enums = (RefVectorOf<XMLCh>*) dtValidator->getEnumString(); if (enums) { XERCES_STD_QUALIFIER cout << "Enumeration:\t\t\n"; XMLSize_t enumLength = enums->size(); for ( XMLSize_t i = 0; i < enumLength; i++) { XERCES_STD_QUALIFIER cout << "\t" << StrX( enums->elementAt(i)) << "\n"; } } }
void TestParser::startElement(const XMLElementDecl& elemDecl , const unsigned int uriId , const XMLCh* const prefixName , const RefVectorOf<XMLAttr>& attrList , const unsigned int attCount , const bool isEmpty , const bool isRoot) { // Set the flag that says we're now inside the root, if its not empty if (isRoot && !isEmpty) fInsideRoot = true; if (fOutputType == OutputType_Debug) { XMLBuffer bufURI; if (fDoNamespaces) { fScanner->getURIText(uriId, bufURI); XERCES_STD_QUALIFIER cout << "Got STARTELEMENT:\n " << " Name: {" << StrX(bufURI.getRawBuffer()) << "}" << StrX(elemDecl.getBaseName()) << ", AttCount: " << attCount << ", Empty?: " << (isEmpty ? "yes" : "no") << "\n"; } else { XERCES_STD_QUALIFIER cout << "Got STARTELEMENT:\n Name: " << StrX(elemDecl.getFullName()) << ", AttCount: " << attCount << ", Empty?: " << (isEmpty ? "yes" : "no") << "\n"; } XERCES_STD_QUALIFIER cout << " SrcOfs: " << fScanner->getSrcOffset() << "\n"; // If any attributes, then show them if (attCount) { XERCES_STD_QUALIFIER cout << " Attrs: "; for (unsigned int attInd = 0; attInd < attCount; attInd++) { const XMLAttr* curAttr = attrList.elementAt(attInd); if (fDoNamespaces) { fScanner->getURIText(curAttr->getURIId(), bufURI); XERCES_STD_QUALIFIER cout << "Name=" << "{" << StrX(bufURI.getRawBuffer()) << "}" << StrX(curAttr->getName()); } else { XERCES_STD_QUALIFIER cout << "Name=" << StrX(curAttr->getQName()); } if (curAttr->getSpecified()) XERCES_STD_QUALIFIER cout << " (Explicit) "; else XERCES_STD_QUALIFIER cout << " (Defaulted) "; XERCES_STD_QUALIFIER cout << "Value=" << StrX(curAttr->getValue()) << "\n" << " "; } } XERCES_STD_QUALIFIER cout << XERCES_STD_QUALIFIER endl; } else if (fOutputType == OutputType_XML) { XERCES_STD_QUALIFIER cout << "<"; showString(elemDecl.getFullName()); if (attCount) { XERCES_STD_QUALIFIER cout << " "; for (unsigned int index = 0; index < attCount; index++) { const XMLAttr* curAttr = attrList.elementAt(index); showString(curAttr->getQName()); XERCES_STD_QUALIFIER cout << "=\""; showString(curAttr->getValue()); XERCES_STD_QUALIFIER cout << "\""; if (index < attCount-1) XERCES_STD_QUALIFIER cout << " "; } } if (isEmpty) XERCES_STD_QUALIFIER cout << "/>"; else XERCES_STD_QUALIFIER cout << ">"; } else if ((fOutputType == OutputType_JCCanon) || (fOutputType == OutputType_SunCanon)) { XERCES_STD_QUALIFIER cout << "<"; showString(elemDecl.getFullName()); if (attCount) { XERCES_STD_QUALIFIER cout << " "; // // Get a list of attribute pointers. The canonical output // format requires sorted attributes. If we aren't doing // canonical output, then we don't sort it, but we still use // the array. // const XMLAttr** attrTmp = new const XMLAttr*[attCount]; unsigned int index; for (index = 0; index < attCount; index++) attrTmp[index] = attrList.elementAt(index); if (attCount > 1) qsort(attrTmp, attCount, sizeof(XMLAttr*), attrComp); for (index = 0; index < attCount; index++) { const XMLAttr* curAttr = attrTmp[index]; showString(curAttr->getQName()); XERCES_STD_QUALIFIER cout << "=\""; showString(curAttr->getValue()); XERCES_STD_QUALIFIER cout << "\""; if (index < attCount-1) XERCES_STD_QUALIFIER cout << " "; } delete [] attrTmp; } if (isEmpty) { XERCES_STD_QUALIFIER cout << "></"; showString(elemDecl.getFullName()); XERCES_STD_QUALIFIER cout << ">"; } else { XERCES_STD_QUALIFIER cout << ">"; } } }
// // 1) the bottom level UnionDTV would check against // pattern and enumeration as well // 2) each UnionDTV(s) above the bottom level UnionDTV and // below the native UnionDTV (the top level DTV) // would check against pattern only. // 3) the natvie Union DTV (the top level DTV) would invoke // memberTypeValidator to validate // void UnionDatatypeValidator::checkContent(const XMLCh* const content , ValidationContext* const context , bool asBase , MemoryManager* const manager) { DatatypeValidator* bv = getBaseValidator(); if (bv) ((UnionDatatypeValidator*)bv)->checkContent(content, context, true, manager); else { // 3) native union type // check content against each member type validator in Union // report an error only in case content is not valid against all member datatypes. // bool memTypeValid = false; for ( unsigned int i = 0; i < fMemberTypeValidators->size(); ++i ) { if ( memTypeValid ) break; try { fMemberTypeValidators->elementAt(i)->validate(content, context, manager); memTypeValid = true; //set the validator of the type actually used to validate the content DatatypeValidator *dtv = fMemberTypeValidators->elementAt(i); fValidatedDatatype = dtv; // context will be null during schema construction if(context) context->setValidatingMemberType(dtv); } catch (XMLException&) { //absorbed } } // for if ( !memTypeValid ) { ThrowXMLwithMemMgr1(InvalidDatatypeValueException , XMLExcepts::VALUE_no_match_memberType , content , manager); //( "Content '"+content+"' does not match any union types" ); } } // 1) and 2). we check pattern first if ( (getFacetsDefined() & DatatypeValidator::FACET_PATTERN ) != 0 ) { if (getRegex()->matches(content, manager) == false) { ThrowXMLwithMemMgr2(InvalidDatatypeValueException , XMLExcepts::VALUE_NotMatch_Pattern , content , getPattern() , manager); } } // if this is a base validator, we only need to check pattern facet // all other facet were inherited by the derived type if (asBase) return; if ((getFacetsDefined() & DatatypeValidator::FACET_ENUMERATION) != 0 && (getEnumeration() != 0)) { // If the content match (compare equal) any enumeration with // any of the member types, it is considerd valid. // RefVectorOf<DatatypeValidator>* memberDTV = getMemberTypeValidators(); RefArrayVectorOf<XMLCh>* tmpEnum = getEnumeration(); unsigned int memberTypeNumber = memberDTV->size(); unsigned int enumLength = tmpEnum->size(); for ( unsigned int memberIndex = 0; memberIndex < memberTypeNumber; ++memberIndex) { for ( unsigned int enumIndex = 0; enumIndex < enumLength; ++enumIndex) { try { if (memberDTV->elementAt(memberIndex)->compare(content, tmpEnum->elementAt(enumIndex), manager) == 0) return; } catch (XMLException&) { //absorbed } } // for enumIndex } // for memberIndex ThrowXMLwithMemMgr1(InvalidDatatypeValueException, XMLExcepts::VALUE_NotIn_Enumeration, content, manager); } // enumeration }
XSSimpleTypeDefinition* XSObjectFactory::addOrFind(DatatypeValidator* const validator, XSModel* const xsModel, bool isAnySimpleType) { XSSimpleTypeDefinition* xsObj = (XSSimpleTypeDefinition*) xsModel->getXSObject(validator); if (!xsObj) { XSTypeDefinition* baseType = 0; XSSimpleTypeDefinitionList* memberTypes = 0; XSSimpleTypeDefinition* primitiveOrItemType = 0; XSSimpleTypeDefinition::VARIETY typeVariety = XSSimpleTypeDefinition::VARIETY_ATOMIC; bool primitiveTypeSelf = false; //REVISIT: the getFixed method is protected so added friend XSObjectFactory // to DatatypeValidator class... DatatypeValidator::ValidatorType dvType = validator->getType(); DatatypeValidator* baseDV = validator->getBaseValidator(); if (dvType == DatatypeValidator::Union) { typeVariety = XSSimpleTypeDefinition::VARIETY_UNION; RefVectorOf<DatatypeValidator>* membersDV = ((UnionDatatypeValidator*)validator)->getMemberTypeValidators(); XMLSize_t size = membersDV->size(); if (size) { memberTypes = new (fMemoryManager) RefVectorOf<XSSimpleTypeDefinition>(size, false, fMemoryManager); for (XMLSize_t i=0; i<size; i++) memberTypes->addElement(addOrFind(membersDV->elementAt(i), xsModel)); } if (baseDV) { baseType = addOrFind(baseDV, xsModel); } else { baseType = (XSSimpleTypeDefinition*) xsModel->getTypeDefinition ( SchemaSymbols::fgDT_ANYSIMPLETYPE , SchemaSymbols::fgURI_SCHEMAFORSCHEMA ); } } else if (dvType == DatatypeValidator::List) { typeVariety = XSSimpleTypeDefinition::VARIETY_LIST; if (baseDV->getType() == DatatypeValidator::List) { baseType = addOrFind(baseDV, xsModel); primitiveOrItemType = ((XSSimpleTypeDefinition*) baseType)->getItemType(); } else { baseType = (XSSimpleTypeDefinition*) xsModel->getTypeDefinition ( SchemaSymbols::fgDT_ANYSIMPLETYPE , SchemaSymbols::fgURI_SCHEMAFORSCHEMA ); primitiveOrItemType = addOrFind(baseDV, xsModel); } } else if (!isAnySimpleType) { if (baseDV) { baseType = addOrFind(baseDV, xsModel); primitiveOrItemType = ((XSSimpleTypeDefinition*) baseType)->getPrimitiveType(); } else // built-in { baseType = (XSSimpleTypeDefinition*) xsModel->getTypeDefinition ( SchemaSymbols::fgDT_ANYSIMPLETYPE , SchemaSymbols::fgURI_SCHEMAFORSCHEMA ); primitiveTypeSelf = true; } } else { baseType = xsModel->getTypeDefinition(SchemaSymbols::fgATTVAL_ANYTYPE, SchemaSymbols::fgURI_SCHEMAFORSCHEMA); } xsObj = new (fMemoryManager) XSSimpleTypeDefinition ( validator , typeVariety , baseType , primitiveOrItemType , memberTypes , getAnnotationFromModel(xsModel, validator) , xsModel , fMemoryManager ); putObjectInMap(validator, xsObj); if (primitiveTypeSelf) xsObj->setPrimitiveType(xsObj); // process facets processFacets(validator, xsModel, xsObj); } return xsObj; }
void XPathMatcher::startElement(const XMLElementDecl& elemDecl, const unsigned int urlId, const XMLCh* const elemPrefix, const RefVectorOf<XMLAttr>& attrList, const unsigned int attrCount) { for (int i = 0; i < (int) fLocationPathSize; i++) { // push context int startStep = fCurrentStep[i]; fStepIndexes->elementAt(i)->push(startStep); // try next xpath, if not matching if ((fMatched[i] & XP_MATCHED_D) == XP_MATCHED || fNoMatchDepth[i] > 0) { fNoMatchDepth[i]++; continue; } if((fMatched[i] & XP_MATCHED_D) == XP_MATCHED_D) { fMatched[i] = XP_MATCHED_DP; } // consume self::node() steps XercesLocationPath* locPath = fLocationPaths->elementAt(i); int stepSize = locPath->getStepSize(); while (fCurrentStep[i] < stepSize && locPath->getStep(fCurrentStep[i])->getAxisType() == XercesStep::SELF) { fCurrentStep[i]++; } if (fCurrentStep[i] == stepSize) { fMatched[i] = XP_MATCHED; continue; } // now if the current step is a descendant step, we let the next // step do its thing; if it fails, we reset ourselves // to look at this step for next time we're called. // so first consume all descendants: int descendantStep = fCurrentStep[i]; while (fCurrentStep[i] < stepSize && locPath->getStep(fCurrentStep[i])->getAxisType() == XercesStep::DESCENDANT) { fCurrentStep[i]++; } bool sawDescendant = fCurrentStep[i] > descendantStep; if (fCurrentStep[i] == stepSize) { fNoMatchDepth[i]++; continue; } // match child::... step, if haven't consumed any self::node() if ((fCurrentStep[i] == startStep || fCurrentStep[i] > descendantStep) && locPath->getStep(fCurrentStep[i])->getAxisType() == XercesStep::CHILD) { XercesStep* step = locPath->getStep(fCurrentStep[i]); XercesNodeTest* nodeTest = step->getNodeTest(); if (nodeTest->getType() == XercesNodeTest::QNAME) { QName elemQName(elemPrefix, elemDecl.getElementName()->getLocalPart(), urlId, fMemoryManager); // if (!(*(nodeTest->getName()) == *(elemDecl.getElementName()))) { if (!(*(nodeTest->getName()) == elemQName)) { if(fCurrentStep[i] > descendantStep) { fCurrentStep[i] = descendantStep; continue; } fNoMatchDepth[i]++; continue; } } fCurrentStep[i]++; } if (fCurrentStep[i] == stepSize) { if (sawDescendant) { fCurrentStep[i] = descendantStep; fMatched[i] = XP_MATCHED_D; } else { fMatched[i] = XP_MATCHED; } continue; } // match attribute::... step if (fCurrentStep[i] < stepSize && locPath->getStep(fCurrentStep[i])->getAxisType() == XercesStep::ATTRIBUTE) { if (attrCount) { XercesNodeTest* nodeTest = locPath->getStep(fCurrentStep[i])->getNodeTest(); for (unsigned int attrIndex = 0; attrIndex < attrCount; attrIndex++) { const XMLAttr* curDef = attrList.elementAt(attrIndex); if (nodeTest->getType() != XercesNodeTest::QNAME || (*(nodeTest->getName()) == *(curDef->getAttName()))) { fCurrentStep[i]++; if (fCurrentStep[i] == stepSize) { fMatched[i] = XP_MATCHED_A; int j=0; for(; j<i && ((fMatched[j] & XP_MATCHED) != XP_MATCHED); j++) ; if(j == i) { SchemaAttDef* attDef = ((SchemaElementDecl&) elemDecl).getAttDef(curDef->getName(), curDef->getURIId()); DatatypeValidator* dv = (attDef) ? attDef->getDatatypeValidator() : 0; matched(curDef->getValue(), dv, false); } } break; } } } if ((fMatched[i] & XP_MATCHED) != XP_MATCHED) { if(fCurrentStep[i] > descendantStep) { fCurrentStep[i] = descendantStep; continue; } fNoMatchDepth[i]++; } } } }
void processDatatypeValidator( const DatatypeValidator* dtValidator, bool margin ) { if( !dtValidator ) { return; } if( margin ) { XERCES_STD_QUALIFIER cout << "\t"; } XERCES_STD_QUALIFIER cout << "Base Datatype:\t\t"; switch( dtValidator->getType() ) { case DatatypeValidator::String: XERCES_STD_QUALIFIER cout << "string"; break; case DatatypeValidator::AnyURI: XERCES_STD_QUALIFIER cout << "AnyURI"; break; case DatatypeValidator::QName: XERCES_STD_QUALIFIER cout << "QName"; break; case DatatypeValidator::Name: XERCES_STD_QUALIFIER cout << "Name"; break; case DatatypeValidator::NCName: XERCES_STD_QUALIFIER cout << "NCName"; break; case DatatypeValidator::Boolean: XERCES_STD_QUALIFIER cout << "Boolean"; break; case DatatypeValidator::Float: XERCES_STD_QUALIFIER cout << "Float"; break; case DatatypeValidator::Double: XERCES_STD_QUALIFIER cout << "Double"; break; case DatatypeValidator::Decimal: XERCES_STD_QUALIFIER cout << "Decimal"; break; case DatatypeValidator::HexBinary: XERCES_STD_QUALIFIER cout << "HexBinary"; break; case DatatypeValidator::Base64Binary: XERCES_STD_QUALIFIER cout << "Base64Binary";break; case DatatypeValidator::Duration: XERCES_STD_QUALIFIER cout << "Duration"; break; case DatatypeValidator::DateTime: XERCES_STD_QUALIFIER cout << "DateTime"; break; case DatatypeValidator::Date: XERCES_STD_QUALIFIER cout << "Date"; break; case DatatypeValidator::Time: XERCES_STD_QUALIFIER cout << "Time"; break; case DatatypeValidator::MonthDay: XERCES_STD_QUALIFIER cout << "MonthDay"; break; case DatatypeValidator::YearMonth: XERCES_STD_QUALIFIER cout << "YearMonth"; break; case DatatypeValidator::Year: XERCES_STD_QUALIFIER cout << "Year"; break; case DatatypeValidator::Month: XERCES_STD_QUALIFIER cout << "Month"; break; case DatatypeValidator::Day: XERCES_STD_QUALIFIER cout << "Day"; break; case DatatypeValidator::ID: XERCES_STD_QUALIFIER cout << "ID"; break; case DatatypeValidator::IDREF: XERCES_STD_QUALIFIER cout << "IDREF"; break; case DatatypeValidator::ENTITY: XERCES_STD_QUALIFIER cout << "ENTITY"; break; case DatatypeValidator::NOTATION: XERCES_STD_QUALIFIER cout << "NOTATION"; break; case DatatypeValidator::List: XERCES_STD_QUALIFIER cout << "List"; break; case DatatypeValidator::Union: XERCES_STD_QUALIFIER cout << "Union"; break; case DatatypeValidator::AnySimpleType: XERCES_STD_QUALIFIER cout << "AnySimpleType"; break; } XERCES_STD_QUALIFIER cout << "\n"; // Facets RefHashTableOf<KVStringPair>* facets = dtValidator->getFacets(); if( facets ) { RefHashTableOfEnumerator<KVStringPair> enumFacets(facets); if( enumFacets.hasMoreElements() ) { XERCES_STD_QUALIFIER cout << "Facets:\t\t\n"; } while(enumFacets.hasMoreElements()) { // Element's properties const KVStringPair& curPair = enumFacets.nextElement(); XERCES_STD_QUALIFIER cout << "\t" << StrX( curPair.getKey() ) << "=" << StrX( curPair.getValue() ) << "\n"; } } // Enumerations RefVectorOf<XMLCh>* enums = (RefVectorOf<XMLCh>*) dtValidator->getEnumString(); if (enums) { XERCES_STD_QUALIFIER cout << "Enumeration:\t\t\n"; int enumLength = enums->size(); for ( int i = 0; i < enumLength; i++) { XERCES_STD_QUALIFIER cout << "\t" << StrX( enums->elementAt(i)) << "\n"; } } }