Examples of com.sun.org.apache.xerces.internal.xs.XSTypeDefinition

• com.sun.org.apache.xerces.internal.xs.XSTypeDefinition
  This interface represents a complex or simple type definition.

            setCharacterData (false);

            if (augs != null) {
                ElementPSVI elementPSVI = (ElementPSVI)augs.getItem (Constants.ELEMENT_PSVI);
                if (elementPSVI != null && fNamespaceAware) {
                    XSTypeDefinition type = elementPSVI.getMemberTypeDefinition ();
                    if (type == null) {
                        type = elementPSVI.getTypeDefinition ();
                    }
                    ((ElementNSImpl)el).setType (type);
                }

                if (elementPSVI != null) {
                    // Updating TypeInfo. If the declared type is a union the
                    // [member type definition] will only be available at the
                    // end of an element.
                    if (fNamespaceAware) {
                        XSTypeDefinition type = elementPSVI.getMemberTypeDefinition();
                        if (type == null) {
                            type = elementPSVI.getTypeDefinition();
                        }
                        ((ElementNSImpl)fCurrentNode).setType(type);
                    }
                    if (fStorePSVI) {
                        ((PSVIElementNSImpl)fCurrentNode).setPSVI (elementPSVI);
                    }
                }
            }

            if (fDOMFilter != null) {
                if (fFilterReject) {
                    if (fRejectedElementDepth-- == 0) {
                        fFilterReject = false;
                    }
                    return;
                }
                if (!fSkippedElemStack.isEmpty()) {
                    if (fSkippedElemStack.pop() == Boolean.TRUE) {
                        return;
                    }
                }
                setCharacterData (false);
                if ((fCurrentNode != fRoot) && !fInEntityRef && (fDOMFilter.getWhatToShow () & NodeFilter.SHOW_ELEMENT)!=0) {
                    short code = fDOMFilter.acceptNode (fCurrentNode);
                    switch (code) {
                        case LSParserFilter.FILTER_INTERRUPT:{
                            throw Abort.INSTANCE;
                        }
                        case LSParserFilter.FILTER_REJECT:{
                            Node parent = fCurrentNode.getParentNode ();
                            parent.removeChild (fCurrentNode);
                            fCurrentNode = parent;
                            return;
                        }
                        case LSParserFilter.FILTER_SKIP: {
                            // make sure that if any char data is available
                            // the fFirstChunk is true, so that if the next event
                            // is characters(), and the last node is text, we will copy
                            // the value already in the text node to fStringBuffer
                            // (not to lose it).
                            fFirstChunk = true;

                            // replace children
                            Node parent = fCurrentNode.getParentNode ();
                            NodeList ls = fCurrentNode.getChildNodes ();
                            int length = ls.getLength ();

                            for (int i=0;i<length;i++) {
                                parent.appendChild (ls.item (0));
                            }
                            parent.removeChild (fCurrentNode);
                            fCurrentNode = parent;

                            return;
                        }

                        default: { }
                    }
                }
                fCurrentNode = fCurrentNode.getParentNode ();

            } // end-if DOMFilter
            else {
                setCharacterData (false);
                fCurrentNode = fCurrentNode.getParentNode ();
            }

        }
        else {
            if (augs != null) {
                ElementPSVI elementPSVI = (ElementPSVI) augs.getItem(Constants.ELEMENT_PSVI);
                if (elementPSVI != null) {
                    // Setting TypeInfo. If the declared type is a union the
                    // [member type definition] will only be available at the
                    // end of an element.
                    XSTypeDefinition type = elementPSVI.getMemberTypeDefinition();
                    if (type == null) {
                        type = elementPSVI.getTypeDefinition();
                    }
                    fDeferredDocumentImpl.setTypeInfo(fCurrentNodeIndex, type);
                }

            /** Add new top-level type definitions. **/
            map = newGrammar.getComponents(XSConstants.TYPE_DEFINITION);
            length = map.getLength();
            for (int i = 0; i < length; ++i) {
                XSTypeDefinition decl = (XSTypeDefinition) map.item(i);
                if (cachedGrammar.getGlobalTypeDecl(decl.getName()) == null) {
                    cachedGrammar.addGlobalTypeDecl(decl);
                }
            }

            /** Add new top-level attribute group definitions. **/
            map = newGrammar.getComponents(XSConstants.ATTRIBUTE_GROUP);
            length = map.getLength();
            for (int i = 0; i < length; ++i) {
                XSAttributeGroupDecl decl = (XSAttributeGroupDecl) map.item(i);
                if (cachedGrammar.getGlobalAttributeGroupDecl(decl.getName()) == null) {
                    cachedGrammar.addGlobalAttributeGroupDecl(decl);
                }
            }

            /** Add new top-level model group definitions. **/
            map = newGrammar.getComponents(XSConstants.MODEL_GROUP);
            length = map.getLength();
            for (int i = 0; i < length; ++i) {
                XSGroupDecl decl = (XSGroupDecl) map.item(i);
                if (cachedGrammar.getGlobalGroupDecl(decl.getName()) == null) {
                    cachedGrammar.addGlobalGroupDecl(decl);
                }
            }

            /** Add new top-level notation declarations. **/
            map = newGrammar.getComponents(XSConstants.NOTATION_DECLARATION);
            length = map.getLength();
            for (int i = 0; i < length; ++i) {
                XSNotationDecl decl = (XSNotationDecl) map.item(i);
                if (cachedGrammar.getGlobalNotationDecl(decl.getName()) == null) {
                    cachedGrammar.addGlobalNotationDecl(decl);
                }
            }

            /**

            }
        }
        element.fAnnotation = annotation;

        // get 'type definition'
        XSTypeDefinition elementType = null;
        boolean haveAnonType = false;

        // Handle Anonymous type if there is one
        if (child != null) {
            String childName = DOMUtil.getLocalName(child);

            if (childName.equals(SchemaSymbols.ELT_COMPLEXTYPE)) {
                elementType = fSchemaHandler.fComplexTypeTraverser.traverseLocal(child, schemaDoc, grammar);
                haveAnonType = true;
                child = DOMUtil.getNextSiblingElement(child);
            }
            else if (childName.equals(SchemaSymbols.ELT_SIMPLETYPE)) {
                elementType = fSchemaHandler.fSimpleTypeTraverser.traverseLocal(child, schemaDoc, grammar);
                haveAnonType = true;
                child = DOMUtil.getNextSiblingElement(child);
            }
        }

        // Handler type attribute
        if (elementType == null && typeAtt != null) {
            elementType = (XSTypeDefinition)fSchemaHandler.getGlobalDecl(schemaDoc, XSDHandler.TYPEDECL_TYPE, typeAtt, elmDecl);
        }

        // Get it from the substitutionGroup declaration
        if (elementType == null && element.fSubGroup != null) {
            elementType = element.fSubGroup.fType;
        }

        if (elementType == null) {
            elementType = SchemaGrammar.fAnyType;
        }

        element.fType = elementType;

        // get 'identity constraint'

        // see if there's something here; it had better be key, keyref or unique.
        if (child != null) {
            String childName = DOMUtil.getLocalName(child);
            while (child != null &&
                    (childName.equals(SchemaSymbols.ELT_KEY) ||
                            childName.equals(SchemaSymbols.ELT_KEYREF) ||
                            childName.equals(SchemaSymbols.ELT_UNIQUE))) {

                if (childName.equals(SchemaSymbols.ELT_KEY) ||
                        childName.equals(SchemaSymbols.ELT_UNIQUE)) {
                    // need to set <key>/<unique> to hidden before traversing it,
                    // because it has global scope
                    DOMUtil.setHidden(child);
                    fSchemaHandler.fUniqueOrKeyTraverser.traverse(child, element, schemaDoc, grammar);
                    if(DOMUtil.getAttrValue(child, SchemaSymbols.ATT_NAME).length() != 0 ) {
                        fSchemaHandler.checkForDuplicateNames(
                                (schemaDoc.fTargetNamespace == null) ? ","+DOMUtil.getAttrValue(child, SchemaSymbols.ATT_NAME)
                                        : schemaDoc.fTargetNamespace+","+ DOMUtil.getAttrValue(child, SchemaSymbols.ATT_NAME),
                                        fSchemaHandler.getIDRegistry(), fSchemaHandler.getIDRegistry_sub(),
                                        child, schemaDoc);
                    }
                } else if (childName.equals(SchemaSymbols.ELT_KEYREF)) {
                    fSchemaHandler.storeKeyRef(child, schemaDoc, element);
                }
                child = DOMUtil.getNextSiblingElement(child);
                if (child != null) {
                    childName = DOMUtil.getLocalName(child);
                }
            }
        }

        // Step 2: register the element decl to the grammar
        if (isGlobal && nameAtt != null)
            grammar.addGlobalElementDecl(element);

        // Step 3: check against schema for schemas

        // required attributes
        if (nameAtt == null) {
            if (isGlobal)
                reportSchemaError("s4s-att-must-appear", new Object[]{SchemaSymbols.ELT_ELEMENT, SchemaSymbols.ATT_NAME}, elmDecl);
            else
                reportSchemaError("src-element.2.1", null, elmDecl);
            nameAtt = NO_NAME;
        }

        // element
        if (child != null) {
            reportSchemaError("s4s-elt-must-match.1", new Object[]{nameAtt, "(annotation?, (simpleType | complexType)?, (unique | key | keyref)*))", DOMUtil.getLocalName(child)}, child);
        }

        // Step 4: check 3.3.3 constraints

        // src-element

        // 1 default and fixed must not both be present.
        if (defaultAtt != null && fixedAtt != null) {
            reportSchemaError("src-element.1", new Object[]{nameAtt}, elmDecl);
        }

        // 2 If the item's parent is not <schema>, then all of the following must be true:
        // 2.1 One of ref or name must be present, but not both.
        // This is checked in XSAttributeChecker

        // 2.2 If ref is present, then all of <complexType>, <simpleType>, <key>, <keyref>, <unique>, nillable, default, fixed, form, block and type must be absent, i.e. only minOccurs, maxOccurs, id are allowed in addition to ref, along with <annotation>.
        // Attributes are checked in XSAttributeChecker, elements are checked in "traverse" method

        // 3 type and either <simpleType> or <complexType> are mutually exclusive.
        if (haveAnonType && (typeAtt != null)) {
            reportSchemaError("src-element.3", new Object[]{nameAtt}, elmDecl);
        }

        // Step 5: check 3.3.6 constraints
        // check for NOTATION type
        checkNotationType(nameAtt, elementType, elmDecl);

        // e-props-correct

        // 2 If there is a {value constraint}, the canonical lexical representation of its value must be valid with respect to the {type definition} as defined in Element Default Valid (Immediate) (3.3.6).
        if (element.fDefault != null) {
            fValidationState.setNamespaceSupport(schemaDoc.fNamespaceSupport);
            if (XSConstraints.ElementDefaultValidImmediate(element.fType, element.fDefault.normalizedValue, fValidationState, element.fDefault) == null) {
                reportSchemaError ("e-props-correct.2", new Object[]{nameAtt, element.fDefault.normalizedValue}, elmDecl);
                element.setConstraintType(XSConstants.VC_NONE);
            }
        }

        // 4 If there is an {substitution group affiliation}, the {type definition} of the element declaration must be validly derived from the {type definition} of the {substitution group affiliation}, given the value of the {substitution group exclusions} of the {substitution group affiliation}, as defined in Type Derivation OK (Complex) (3.4.6) (if the {type definition} is complex) or as defined in Type Derivation OK (Simple) (3.14.6) (if the {type definition} is simple).
        if (element.fSubGroup != null) {
            if (!XSConstraints.checkTypeDerivationOk(element.fType, element.fSubGroup.fType, element.fSubGroup.fFinal)) {
                reportSchemaError ("e-props-correct.4", new Object[]{nameAtt, subGroupAtt.prefix+":"+subGroupAtt.localpart}, elmDecl);
            }
        }

        // 5 If the {type definition} or {type definition}'s {content type} is or is derived from ID then there must not be a {value constraint}.
        if (element.fDefault != null) {
            if ((elementType.getTypeCategory() == XSTypeDefinition.SIMPLE_TYPE &&
                    ((XSSimpleType)elementType).isIDType()) ||
                    (elementType.getTypeCategory() == XSTypeDefinition.COMPLEX_TYPE &&
                            ((XSComplexTypeDecl)elementType).containsTypeID())) {
                reportSchemaError ("e-props-correct.5", new Object[]{element.fName}, elmDecl);
            }
        }

        short devMethod = 0, blockConstraint = blockingConstraint;

        // element.fType should be derived from exemplar.fType
        // add derivation methods of derived types to devMethod;
        // add block of base types to blockConstraint.
        XSTypeDefinition type = element.fType;
        while (type != exemplar.fType && type != SchemaGrammar.fAnyType) {
            if (type.getTypeCategory() == XSTypeDefinition.COMPLEX_TYPE)
                devMethod |= ((XSComplexTypeDecl)type).fDerivedBy;
            else
                devMethod |= XSConstants.DERIVATION_RESTRICTION;
            type = type.getBaseType();
            // type == null means the current type is anySimpleType,
            // whose base type should be anyType
            if (type == null)
                type = SchemaGrammar.fAnyType;
            if (type.getTypeCategory() == XSTypeDefinition.COMPLEX_TYPE)
                blockConstraint |= ((XSComplexTypeDecl)type).fBlock;
        }
        if (type != exemplar.fType)
            return false;

                                (AttributePSVI) attributes.getAugmentations(i).getItem(Constants.ATTRIBUTE_PSVI);

                        if (attrPSVI != null) {
                //REVISIT: instead we should be using augmentations:
                // to set/retrieve Id attributes
                XSTypeDefinition decl = attrPSVI.getMemberTypeDefinition();
                boolean id = false;
                if (decl != null){
                    id = ((XSSimpleType)decl).isIDType();
                } else{
                    decl = attrPSVI.getTypeDefinition();

        // 1 If B and D are not the same type definition, then the {derivation method} of D must not be in the subset.
        if ((derived.fDerivedBy & block) != 0)
            return false;

        // 2 One of the following must be true:
        XSTypeDefinition directBase = derived.fBaseType;
        // 2.2 B must be D's {base type definition}.
        if (directBase == base)
            return true;

        // 2.3 All of the following must be true:
        // 2.3.1 D's {base type definition} must not be the ur-type definition.
        if (directBase == SchemaGrammar.fAnyType ||
            directBase == SchemaGrammar.fAnySimpleType) {
            return false;
        }

        // 2.3.2 The appropriate case among the following must be true:
        // 2.3.2.1 If D's {base type definition} is complex, then it must be validly derived from B given the subset as defined by this constraint.
        if (directBase.getTypeCategory() == XSTypeDefinition.COMPLEX_TYPE)
            return checkComplexDerivation((XSComplexTypeDecl)directBase, base, block);

        // 2.3.2.2 If D's {base type definition} is simple, then it must be validly derived from B given the subset as defined in Type Derivation OK (Simple) (3.14.6).
        if (directBase.getTypeCategory() == XSTypeDefinition.SIMPLE_TYPE) {
            // if base is complex type
            if (base.getTypeCategory() == XSTypeDefinition.COMPLEX_TYPE) {
                // if base is anyType, change base to anySimpleType,
                // otherwise, not valid
                if (base == SchemaGrammar.fAnyType)

            setCharacterData (false);

            if (augs != null) {
                ElementPSVI elementPSVI = (ElementPSVI)augs.getItem (Constants.ELEMENT_PSVI);
                if (elementPSVI != null && fNamespaceAware) {
                    XSTypeDefinition type = elementPSVI.getMemberTypeDefinition ();
                    if (type == null) {
                        type = elementPSVI.getTypeDefinition ();
                    }
                    ((ElementNSImpl)el).setType (type);
                }

                if (elementPSVI != null) {
                    // Updating TypeInfo. If the declared type is a union the
                    // [member type definition] will only be available at the
                    // end of an element.
                    if (fNamespaceAware) {
                        XSTypeDefinition type = elementPSVI.getMemberTypeDefinition();
                        if (type == null) {
                            type = elementPSVI.getTypeDefinition();
                        }
                        ((ElementNSImpl)fCurrentNode).setType(type);
                    }

            fAttrChecker.returnAttrArray(derivationTypeAttrValues, schemaDoc);
            throw new ComplexTypeRecoverableError("s4s-att-must-appear",
                    new Object[]{simpleContentName, "base"}, simpleContent);
        }

        XSTypeDefinition type = (XSTypeDefinition)fSchemaHandler.getGlobalDecl(schemaDoc,
                XSDHandler.TYPEDECL_TYPE, baseTypeName,
                simpleContent);
        if (type==null) {
            fAttrChecker.returnAttrArray(simpleContentAttrValues, schemaDoc);
            fAttrChecker.returnAttrArray(derivationTypeAttrValues, schemaDoc);
            throw new ComplexTypeRecoverableError();
        }

        fBaseType = type;

        XSSimpleType baseValidator = null;
        XSComplexTypeDecl baseComplexType = null;
        int baseFinalSet = 0;

        // If the base type is complex, it must have simpleContent
        if ((type.getTypeCategory() == XSTypeDefinition.COMPLEX_TYPE)) {

            baseComplexType = (XSComplexTypeDecl)type;
            baseFinalSet = baseComplexType.getFinal();
            // base is a CT with simple content (both restriction and extension are OK)
            if (baseComplexType.getContentType() == XSComplexTypeDecl.CONTENTTYPE_SIMPLE) {