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Xerces2 is the next generation of high performance, fully compliant XML parsers in the Apache Xerces family. This new version of Xerces introduces the Xerces Native Interface (XNI), a complete framework for building parser components and configurations that is extremely modular and easy to program. The Apache Xerces2 parser is the reference implementation of XNI but other parser components, configurations, and parsers can be written using the Xerces Native Interface. For complete design and implementation documents, refer to the XNI Manual. Xerces2 is a fully conforming XML Schema 1.0 processor. A partial experimental implementation of the XML Schema 1.1 Structures and Datatypes Working Drafts (December 2009) and an experimental implementation of the XML Schema Definition Language (XSD): Component Designators (SCD) Candidate Recommendation (January 2010) are provided for evaluation. For more information, refer to the XML Schema page. Xerces2 also provides a complete implementation of the Document Object Model Level 3 Core and Load/Save W3C Recommendations and provides a complete implementation of the XML Inclusions (XInclude) W3C Recommendation. It also provides support for OASIS XML Catalogs v1.1. Xerces2 is able to parse documents written according to the XML 1.1 Recommendation, except that it does not yet provide an option to enable normalization checking as described in section 2.13 of this specification. It also handles namespaces according to the XML Namespaces 1.1 Recommendation, and will correctly serialize XML 1.1 documents if the DOM level 3 load/save APIs are in use.

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/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package org.apache.xerces.impl.xs;

import org.apache.xerces.impl.xs.util.XSObjectListImpl;
import org.apache.xerces.xs.XSAnnotation;
import org.apache.xerces.xs.XSConstants;
import org.apache.xerces.xs.XSModelGroup;
import org.apache.xerces.xs.XSNamespaceItem;
import org.apache.xerces.xs.XSObjectList;

/**
 * Store schema model group declaration.
 *
 * @xerces.internal 
 *
 * @author Sandy Gao, IBM
 *
 * @version $Id: XSModelGroupImpl.java 699892 2008-09-28 21:08:27Z mrglavas $
 */
public class XSModelGroupImpl implements XSModelGroup {

    // types of model groups
    // REVISIT: can't use same constants as those for particles, because
    // there are place where the constants are used together. For example,
    // to check whether the content is an element or a sequence.
    public static final short MODELGROUP_CHOICE       = 101;
    public static final short MODELGROUP_SEQUENCE     = 102;
    public static final short MODELGROUP_ALL          = 103;

    // compositor of the model group
    public short fCompositor;

    // particles
    public XSParticleDecl[] fParticles = null;
    public int fParticleCount = 0;

    // this particle's optional annotations
    public XSObjectList fAnnotations = null;

    // whether this model group contains nothing
    public boolean isEmpty() {
        for (int i = 0; i < fParticleCount; i++) {
            if (!fParticles[i].isEmpty())
                return false;
        }
        return true;
    }

    /**
     * 3.8.6 Effective Total Range (all and sequence) and
     *       Effective Total Range (choice)
     * The following methods are used to return min/max range for a particle.
     * They are not exactly the same as it's described in the spec, but all the
     * values from the spec are retrievable by these methods.
     */
    public int minEffectiveTotalRange() {
        if (fCompositor == MODELGROUP_CHOICE)
            return minEffectiveTotalRangeChoice();
        else
            return minEffectiveTotalRangeAllSeq();
    }

    // return the sum of all min values of the particles
    private int minEffectiveTotalRangeAllSeq() {
        int total = 0;
        for (int i = 0; i < fParticleCount; i++)
            total += fParticles[i].minEffectiveTotalRange();
        return total;
    }

    // return the min of all min values of the particles
    private int minEffectiveTotalRangeChoice() {
        int min = 0, one;
        if (fParticleCount > 0)
            min = fParticles[0].minEffectiveTotalRange();

        for (int i = 1; i < fParticleCount; i++) {
            one = fParticles[i].minEffectiveTotalRange();
            if (one < min)
                min = one;
        }

        return min;
    }

    public int maxEffectiveTotalRange() {
        if (fCompositor == MODELGROUP_CHOICE)
            return maxEffectiveTotalRangeChoice();
        else
            return maxEffectiveTotalRangeAllSeq();
    }

    // if one of the max value of the particles is unbounded, return unbounded;
    // otherwise return the sum of all max values
    private int maxEffectiveTotalRangeAllSeq() {
        int total = 0, one;
        for (int i = 0; i < fParticleCount; i++) {
            one = fParticles[i].maxEffectiveTotalRange();
            if (one == SchemaSymbols.OCCURRENCE_UNBOUNDED)
                return SchemaSymbols.OCCURRENCE_UNBOUNDED;
            total += one;
        }
        return total;
    }

    // if one of the max value of the particles is unbounded, return unbounded;
    // otherwise return the max of all max values
    private int maxEffectiveTotalRangeChoice() {
        int max = 0, one;
        if (fParticleCount > 0) {
            max = fParticles[0].maxEffectiveTotalRange();
            if (max == SchemaSymbols.OCCURRENCE_UNBOUNDED)
                return SchemaSymbols.OCCURRENCE_UNBOUNDED;
        }

        for (int i = 1; i < fParticleCount; i++) {
            one = fParticles[i].maxEffectiveTotalRange();
            if (one == SchemaSymbols.OCCURRENCE_UNBOUNDED)
                return SchemaSymbols.OCCURRENCE_UNBOUNDED;
            if (one > max)
                max = one;
        }
        return max;
    }

    /**
     * get the string description of this particle
     */
    private String fDescription = null;
    public String toString() {
    	// REVISIT: Commented code may help to eliminate redundant parentheses (test first before committing)
        if (fDescription == null) {
            StringBuffer buffer = new StringBuffer();
            if (fCompositor == MODELGROUP_ALL)
                buffer.append("all(");
            else  //if (fMinOccurs != 1 || fMaxOccurs != 1)
                buffer.append('(');
            if (fParticleCount > 0)
                buffer.append(fParticles[0].toString());
            for (int i = 1; i < fParticleCount; i++) {
                if (fCompositor == MODELGROUP_CHOICE)
                    buffer.append('|');
                else
                    buffer.append(',');
                buffer.append(fParticles[i].toString());
            }
            //if (fCompositor == MODELGROUP_ALL || fMinOccurs != 1 || fMaxOccurs != 1)
                  buffer.append(')');
            fDescription = buffer.toString();
        }
        return fDescription;
    }

    public void reset(){
        fCompositor = MODELGROUP_SEQUENCE;
        fParticles = null;
        fParticleCount = 0;
        fDescription = null;
        fAnnotations = null;
    }

    /**
     * Get the type of the object, i.e ELEMENT_DECLARATION.
     */
    public short getType() {
        return XSConstants.MODEL_GROUP;
    }

    /**
     * The name of this XSObject depending on the
     * XSObject type.
     */
    public String getName() {
        return null;
    }

    /**
     * The namespace URI of this node, or null if it is
     * unspecified.  defines how a namespace URI is attached to schema
     * components.
     */
    public String getNamespace() {
        return null;
    }

    /**
     * {compositor} One of all, choice or sequence. The valid constants values
     * are: ALL, CHOICE, SEQUENCE.
     */
    public short getCompositor() {
        if (fCompositor == MODELGROUP_CHOICE)
            return XSModelGroup.COMPOSITOR_CHOICE;
        else if (fCompositor == MODELGROUP_SEQUENCE)
            return XSModelGroup.COMPOSITOR_SEQUENCE;
        else
            return XSModelGroup.COMPOSITOR_ALL;
    }

    /**
     * {particles} A list of particles
     */
    public XSObjectList getParticles() {
        return new XSObjectListImpl(fParticles, fParticleCount);
    }

    /**
     * Optional. Annotation.
     */
    public XSAnnotation getAnnotation() {
        return (fAnnotations != null) ? (XSAnnotation) fAnnotations.item(0) : null;
    }

    /**
     * Optional. Annotations.
     */
    public XSObjectList getAnnotations() {
        return (fAnnotations != null) ? fAnnotations : XSObjectListImpl.EMPTY_LIST;
    }

    /**
     * @see org.apache.xerces.xs.XSObject#getNamespaceItem()
     */
    public XSNamespaceItem getNamespaceItem() {
        return null;
    }

} // class XSModelGroupImpl