Java Code Examples for com.sun.org.apache.xerces.internal.impl.dtd.models.CMNode#type()

private CMNode copyNode(CMNode node) {
    int type = node.type();
    // for choice or sequence, copy the two subtrees, and combine them
    if (type == XSModelGroupImpl.MODELGROUP_CHOICE ||
        type == XSModelGroupImpl.MODELGROUP_SEQUENCE) {
        XSCMBinOp bin = (XSCMBinOp)node;
        node = fNodeFactory.getCMBinOpNode(type, copyNode(bin.getLeft()),
                             copyNode(bin.getRight()));
    }
    // for ?+*, copy the subtree, and put it in a new ?+* node
    else if (type == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        XSCMUniOp uni = (XSCMUniOp)node;
        node = fNodeFactory.getCMUniOpNode(type, copyNode(uni.getChild()));
    }
    // for element/wildcard (leaf), make a new leaf node,
    // with a distinct position
    else if (type == XSParticleDecl.PARTICLE_ELEMENT ||
             type == XSParticleDecl.PARTICLE_WILDCARD) {
        XSCMLeaf leaf = (XSCMLeaf)node;
        node = fNodeFactory.getCMLeafNode(leaf.type(), leaf.getLeaf(), leaf.getParticleId(), fLeafCount++);
    }

    return node;
}
 

private CMNode copyNode(CMNode node) {
    int type = node.type();
    // for choice or sequence, copy the two subtrees, and combine them
    if (type == XSModelGroupImpl.MODELGROUP_CHOICE ||
        type == XSModelGroupImpl.MODELGROUP_SEQUENCE) {
        XSCMBinOp bin = (XSCMBinOp)node;
        node = fNodeFactory.getCMBinOpNode(type, copyNode(bin.getLeft()),
                             copyNode(bin.getRight()));
    }
    // for ?+*, copy the subtree, and put it in a new ?+* node
    else if (type == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        XSCMUniOp uni = (XSCMUniOp)node;
        node = fNodeFactory.getCMUniOpNode(type, copyNode(uni.getChild()));
    }
    // for element/wildcard (leaf), make a new leaf node,
    // with a distinct position
    else if (type == XSParticleDecl.PARTICLE_ELEMENT ||
             type == XSParticleDecl.PARTICLE_WILDCARD) {
        XSCMLeaf leaf = (XSCMLeaf)node;
        node = fNodeFactory.getCMLeafNode(leaf.type(), leaf.getLeaf(), leaf.getParticleId(), fLeafCount++);
    }

    return node;
}
 

private CMNode copyNode(CMNode node) {
    int type = node.type();
    // for choice or sequence, copy the two subtrees, and combine them
    if (type == XSModelGroupImpl.MODELGROUP_CHOICE ||
        type == XSModelGroupImpl.MODELGROUP_SEQUENCE) {
        XSCMBinOp bin = (XSCMBinOp)node;
        node = fNodeFactory.getCMBinOpNode(type, copyNode(bin.getLeft()),
                             copyNode(bin.getRight()));
    }
    // for ?+*, copy the subtree, and put it in a new ?+* node
    else if (type == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        XSCMUniOp uni = (XSCMUniOp)node;
        node = fNodeFactory.getCMUniOpNode(type, copyNode(uni.getChild()));
    }
    // for element/wildcard (leaf), make a new leaf node,
    // with a distinct position
    else if (type == XSParticleDecl.PARTICLE_ELEMENT ||
             type == XSParticleDecl.PARTICLE_WILDCARD) {
        XSCMLeaf leaf = (XSCMLeaf)node;
        node = fNodeFactory.getCMLeafNode(leaf.type(), leaf.getLeaf(), leaf.getParticleId(), fLeafCount++);
    }

    return node;
}
 

private CMNode copyNode(CMNode node) {
    int type = node.type();
    // for choice or sequence, copy the two subtrees, and combine them
    if (type == XSModelGroupImpl.MODELGROUP_CHOICE ||
        type == XSModelGroupImpl.MODELGROUP_SEQUENCE) {
        XSCMBinOp bin = (XSCMBinOp)node;
        node = fNodeFactory.getCMBinOpNode(type, copyNode(bin.getLeft()),
                             copyNode(bin.getRight()));
    }
    // for ?+*, copy the subtree, and put it in a new ?+* node
    else if (type == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        XSCMUniOp uni = (XSCMUniOp)node;
        node = fNodeFactory.getCMUniOpNode(type, copyNode(uni.getChild()));
    }
    // for element/wildcard (leaf), make a new leaf node,
    // with a distinct position
    else if (type == XSParticleDecl.PARTICLE_ELEMENT ||
             type == XSParticleDecl.PARTICLE_WILDCARD) {
        XSCMLeaf leaf = (XSCMLeaf)node;
        node = fNodeFactory.getCMLeafNode(leaf.type(), leaf.getLeaf(), leaf.getParticleId(), fLeafCount++);
    }

    return node;
}
 

private CMNode copyNode(CMNode node) {
    int type = node.type();
    // for choice or sequence, copy the two subtrees, and combine them
    if (type == XSModelGroupImpl.MODELGROUP_CHOICE ||
        type == XSModelGroupImpl.MODELGROUP_SEQUENCE) {
        XSCMBinOp bin = (XSCMBinOp)node;
        node = fNodeFactory.getCMBinOpNode(type, copyNode(bin.getLeft()),
                             copyNode(bin.getRight()));
    }
    // for ?+*, copy the subtree, and put it in a new ?+* node
    else if (type == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        XSCMUniOp uni = (XSCMUniOp)node;
        node = fNodeFactory.getCMUniOpNode(type, copyNode(uni.getChild()));
    }
    // for element/wildcard (leaf), make a new leaf node,
    // with a distinct position
    else if (type == XSParticleDecl.PARTICLE_ELEMENT ||
             type == XSParticleDecl.PARTICLE_WILDCARD) {
        XSCMLeaf leaf = (XSCMLeaf)node;
        node = fNodeFactory.getCMLeafNode(leaf.type(), leaf.getLeaf(), leaf.getParticleId(), fLeafCount++);
    }

    return node;
}
 

private CMNode copyNode(CMNode node) {
    int type = node.type();
    // for choice or sequence, copy the two subtrees, and combine them
    if (type == XSModelGroupImpl.MODELGROUP_CHOICE ||
        type == XSModelGroupImpl.MODELGROUP_SEQUENCE) {
        XSCMBinOp bin = (XSCMBinOp)node;
        node = fNodeFactory.getCMBinOpNode(type, copyNode(bin.getLeft()),
                             copyNode(bin.getRight()));
    }
    // for ?+*, copy the subtree, and put it in a new ?+* node
    else if (type == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             type == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        XSCMUniOp uni = (XSCMUniOp)node;
        node = fNodeFactory.getCMUniOpNode(type, copyNode(uni.getChild()));
    }
    // for element/wildcard (leaf), make a new leaf node,
    // with a distinct position
    else if (type == XSParticleDecl.PARTICLE_ELEMENT ||
             type == XSParticleDecl.PARTICLE_WILDCARD) {
        XSCMLeaf leaf = (XSCMLeaf)node;
        node = fNodeFactory.getCMLeafNode(leaf.type(), leaf.getLeaf(), leaf.getParticleId(), fLeafCount++);
    }

    return node;
}
 

/** Post tree build initialization. */
private void postTreeBuildInit(CMNode nodeCur) throws RuntimeException {
    // Set the maximum states on this node
    nodeCur.setMaxStates(fLeafCount);

    XSCMLeaf leaf = null;
    int pos = 0;
    // Recurse as required
    if (nodeCur.type() == XSParticleDecl.PARTICLE_WILDCARD) {
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_WILDCARD;
    }
    else if ((nodeCur.type() == XSModelGroupImpl.MODELGROUP_CHOICE) ||
             (nodeCur.type() == XSModelGroupImpl.MODELGROUP_SEQUENCE)) {
        postTreeBuildInit(((XSCMBinOp)nodeCur).getLeft());
        postTreeBuildInit(((XSCMBinOp)nodeCur).getRight());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        postTreeBuildInit(((XSCMUniOp)nodeCur).getChild());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ELEMENT) {
        //  Put this node in the leaf list at the current index if its
        //  a non-epsilon leaf.
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_ELEMENT;
    }
    else {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
}
 

/** Post tree build initialization. */
private void postTreeBuildInit(CMNode nodeCur) throws RuntimeException {
    // Set the maximum states on this node
    nodeCur.setMaxStates(fLeafCount);

    XSCMLeaf leaf = null;
    int pos = 0;
    // Recurse as required
    if (nodeCur.type() == XSParticleDecl.PARTICLE_WILDCARD) {
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_WILDCARD;
    }
    else if ((nodeCur.type() == XSModelGroupImpl.MODELGROUP_CHOICE) ||
             (nodeCur.type() == XSModelGroupImpl.MODELGROUP_SEQUENCE)) {
        postTreeBuildInit(((XSCMBinOp)nodeCur).getLeft());
        postTreeBuildInit(((XSCMBinOp)nodeCur).getRight());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        postTreeBuildInit(((XSCMUniOp)nodeCur).getChild());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ELEMENT) {
        //  Put this node in the leaf list at the current index if its
        //  a non-epsilon leaf.
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_ELEMENT;
    }
    else {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
}
 

/** Post tree build initialization. */
private void postTreeBuildInit(CMNode nodeCur) throws RuntimeException {
    // Set the maximum states on this node
    nodeCur.setMaxStates(fLeafCount);

    XSCMLeaf leaf = null;
    int pos = 0;
    // Recurse as required
    if (nodeCur.type() == XSParticleDecl.PARTICLE_WILDCARD) {
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_WILDCARD;
    }
    else if ((nodeCur.type() == XSModelGroupImpl.MODELGROUP_CHOICE) ||
             (nodeCur.type() == XSModelGroupImpl.MODELGROUP_SEQUENCE)) {
        postTreeBuildInit(((XSCMBinOp)nodeCur).getLeft());
        postTreeBuildInit(((XSCMBinOp)nodeCur).getRight());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        postTreeBuildInit(((XSCMUniOp)nodeCur).getChild());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ELEMENT) {
        //  Put this node in the leaf list at the current index if its
        //  a non-epsilon leaf.
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_ELEMENT;
    }
    else {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
}
 

/** Post tree build initialization. */
private void postTreeBuildInit(CMNode nodeCur) throws RuntimeException {
    // Set the maximum states on this node
    nodeCur.setMaxStates(fLeafCount);

    XSCMLeaf leaf = null;
    int pos = 0;
    // Recurse as required
    if (nodeCur.type() == XSParticleDecl.PARTICLE_WILDCARD) {
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_WILDCARD;
    }
    else if ((nodeCur.type() == XSModelGroupImpl.MODELGROUP_CHOICE) ||
             (nodeCur.type() == XSModelGroupImpl.MODELGROUP_SEQUENCE)) {
        postTreeBuildInit(((XSCMBinOp)nodeCur).getLeft());
        postTreeBuildInit(((XSCMBinOp)nodeCur).getRight());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        postTreeBuildInit(((XSCMUniOp)nodeCur).getChild());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ELEMENT) {
        //  Put this node in the leaf list at the current index if its
        //  a non-epsilon leaf.
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_ELEMENT;
    }
    else {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
}
 

/** Post tree build initialization. */
private void postTreeBuildInit(CMNode nodeCur) throws RuntimeException {
    // Set the maximum states on this node
    nodeCur.setMaxStates(fLeafCount);

    XSCMLeaf leaf = null;
    int pos = 0;
    // Recurse as required
    if (nodeCur.type() == XSParticleDecl.PARTICLE_WILDCARD) {
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_WILDCARD;
    }
    else if ((nodeCur.type() == XSModelGroupImpl.MODELGROUP_CHOICE) ||
             (nodeCur.type() == XSModelGroupImpl.MODELGROUP_SEQUENCE)) {
        postTreeBuildInit(((XSCMBinOp)nodeCur).getLeft());
        postTreeBuildInit(((XSCMBinOp)nodeCur).getRight());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ONE_OR_MORE ||
             nodeCur.type() == XSParticleDecl.PARTICLE_ZERO_OR_ONE) {
        postTreeBuildInit(((XSCMUniOp)nodeCur).getChild());
    }
    else if (nodeCur.type() == XSParticleDecl.PARTICLE_ELEMENT) {
        //  Put this node in the leaf list at the current index if its
        //  a non-epsilon leaf.
        leaf = (XSCMLeaf)nodeCur;
        pos = leaf.getPosition();
        fLeafList[pos] = leaf;
        fLeafListType[pos] = XSParticleDecl.PARTICLE_ELEMENT;
    }
    else {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
}
 

private CMNode expandContentModel(CMNode node,
                                  int minOccurs, int maxOccurs, boolean optimize) {

    CMNode nodeRet = null;

    if (minOccurs==1 && maxOccurs==1) {
        nodeRet = node;
    }
    else if (minOccurs==0 && maxOccurs==1) {
        //zero or one
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_ONE, node);
    }
    else if (minOccurs == 0 && maxOccurs==SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        //zero or more
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_MORE, node);
    }
    else if (minOccurs == 1 && maxOccurs==SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        //one or more
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
    }
    else if (optimize && node.type() == XSParticleDecl.PARTICLE_ELEMENT ||
             node.type() == XSParticleDecl.PARTICLE_WILDCARD) {
        // Only for elements and wildcards, subsume e{n,m} and e{n,unbounded} to e*
        // or e+ and, once the DFA reaches a final state, check if the actual number
        // of elements is between minOccurs and maxOccurs. This new algorithm runs
        // in constant space.

        // TODO: What is the impact of this optimization on the PSVI?
        nodeRet = fNodeFactory.getCMUniOpNode(
                minOccurs == 0 ? XSParticleDecl.PARTICLE_ZERO_OR_MORE
                    : XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
        nodeRet.setUserData(new int[] { minOccurs, maxOccurs });
    }
    else if (maxOccurs == SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        // => a,a,..,a+
        // create a+ node first, then put minOccurs-1 a's in front of it
        // for the first time "node" is used, we don't need to make a copy
        // and for other references to node, we make copies
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
        // (task 4) we need to call copyNode here, so that we append
        // an entire new copy of the node (a subtree). this is to ensure
        // all leaf nodes have distinct position
        // we know that minOccurs > 1
        nodeRet = fNodeFactory.getCMBinOpNode(XSModelGroupImpl.MODELGROUP_SEQUENCE,
                                              multiNodes(node, minOccurs-1, true), nodeRet);
    }
    else {
        // {n,m} => a,a,a,...(a),(a),...
        // first n a's, then m-n a?'s.
        // copyNode is called, for the same reason as above
        if (minOccurs > 0) {
            nodeRet = multiNodes(node, minOccurs, false);
        }
        if (maxOccurs > minOccurs) {
            node = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_ONE, node);
            if (nodeRet == null) {
                nodeRet = multiNodes(node, maxOccurs-minOccurs, false);
            }
            else {
                nodeRet = fNodeFactory.getCMBinOpNode(XSModelGroupImpl.MODELGROUP_SEQUENCE,
                                                      nodeRet, multiNodes(node, maxOccurs-minOccurs, true));
            }
        }
    }

    return nodeRet;
}
 

private CMNode expandContentModel(CMNode node,
                                  int minOccurs, int maxOccurs, boolean optimize) {

    CMNode nodeRet = null;

    if (minOccurs==1 && maxOccurs==1) {
        nodeRet = node;
    }
    else if (minOccurs==0 && maxOccurs==1) {
        //zero or one
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_ONE, node);
    }
    else if (minOccurs == 0 && maxOccurs==SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        //zero or more
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_MORE, node);
    }
    else if (minOccurs == 1 && maxOccurs==SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        //one or more
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
    }
    else if (optimize && node.type() == XSParticleDecl.PARTICLE_ELEMENT ||
             node.type() == XSParticleDecl.PARTICLE_WILDCARD) {
        // Only for elements and wildcards, subsume e{n,m} and e{n,unbounded} to e*
        // or e+ and, once the DFA reaches a final state, check if the actual number
        // of elements is between minOccurs and maxOccurs. This new algorithm runs
        // in constant space.

        // TODO: What is the impact of this optimization on the PSVI?
        nodeRet = fNodeFactory.getCMUniOpNode(
                minOccurs == 0 ? XSParticleDecl.PARTICLE_ZERO_OR_MORE
                    : XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
        nodeRet.setUserData(new int[] { minOccurs, maxOccurs });
    }
    else if (maxOccurs == SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        // => a,a,..,a+
        // create a+ node first, then put minOccurs-1 a's in front of it
        // for the first time "node" is used, we don't need to make a copy
        // and for other references to node, we make copies
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
        // (task 4) we need to call copyNode here, so that we append
        // an entire new copy of the node (a subtree). this is to ensure
        // all leaf nodes have distinct position
        // we know that minOccurs > 1
        nodeRet = fNodeFactory.getCMBinOpNode(XSModelGroupImpl.MODELGROUP_SEQUENCE,
                                              multiNodes(node, minOccurs-1, true), nodeRet);
    }
    else {
        // {n,m} => a,a,a,...(a),(a),...
        // first n a's, then m-n a?'s.
        // copyNode is called, for the same reason as above
        if (minOccurs > 0) {
            nodeRet = multiNodes(node, minOccurs, false);
        }
        if (maxOccurs > minOccurs) {
            node = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_ONE, node);
            if (nodeRet == null) {
                nodeRet = multiNodes(node, maxOccurs-minOccurs, false);
            }
            else {
                nodeRet = fNodeFactory.getCMBinOpNode(XSModelGroupImpl.MODELGROUP_SEQUENCE,
                                                      nodeRet, multiNodes(node, maxOccurs-minOccurs, true));
            }
        }
    }

    return nodeRet;
}
 

/**
 * Dumps the tree of the current node to standard output.
 *
 * @param nodeCur The current node.
 * @param level   The maximum levels to output.
 *
 * @exception RuntimeException Thrown on error.
 */
private void dumpTree(CMNode nodeCur, int level) {
    for (int index = 0; index < level; index++)
        System.out.print("   ");

    int type = nodeCur.type();

    switch(type ) {

    case XSModelGroupImpl.MODELGROUP_CHOICE:
    case XSModelGroupImpl.MODELGROUP_SEQUENCE: {
        if (type == XSModelGroupImpl.MODELGROUP_CHOICE)
            System.out.print("Choice Node ");
        else
            System.out.print("Seq Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMBinOp)nodeCur).getLeft(), level+1);
        dumpTree(((XSCMBinOp)nodeCur).getRight(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ZERO_OR_MORE:
    case XSParticleDecl.PARTICLE_ONE_OR_MORE:
    case XSParticleDecl.PARTICLE_ZERO_OR_ONE: {
        System.out.print("Rep Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMUniOp)nodeCur).getChild(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ELEMENT: {
        System.out.print
        (
            "Leaf: (pos="
            + ((XSCMLeaf)nodeCur).getPosition()
            + "), "
            + "(elemIndex="
            + ((XSCMLeaf)nodeCur).getLeaf()
            + ") "
        );

        if (nodeCur.isNullable())
            System.out.print(" Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    }
    case XSParticleDecl.PARTICLE_WILDCARD:
          System.out.print("Any Node: ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    default: {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
    }

}
 

/**
 * Dumps the tree of the current node to standard output.
 *
 * @param nodeCur The current node.
 * @param level   The maximum levels to output.
 *
 * @exception RuntimeException Thrown on error.
 */
private void dumpTree(CMNode nodeCur, int level) {
    for (int index = 0; index < level; index++)
        System.out.print("   ");

    int type = nodeCur.type();

    switch(type ) {

    case XSModelGroupImpl.MODELGROUP_CHOICE:
    case XSModelGroupImpl.MODELGROUP_SEQUENCE: {
        if (type == XSModelGroupImpl.MODELGROUP_CHOICE)
            System.out.print("Choice Node ");
        else
            System.out.print("Seq Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMBinOp)nodeCur).getLeft(), level+1);
        dumpTree(((XSCMBinOp)nodeCur).getRight(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ZERO_OR_MORE:
    case XSParticleDecl.PARTICLE_ONE_OR_MORE:
    case XSParticleDecl.PARTICLE_ZERO_OR_ONE: {
        System.out.print("Rep Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMUniOp)nodeCur).getChild(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ELEMENT: {
        System.out.print
        (
            "Leaf: (pos="
            + ((XSCMLeaf)nodeCur).getPosition()
            + "), "
            + "(elemIndex="
            + ((XSCMLeaf)nodeCur).getLeaf()
            + ") "
        );

        if (nodeCur.isNullable())
            System.out.print(" Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    }
    case XSParticleDecl.PARTICLE_WILDCARD:
          System.out.print("Any Node: ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    default: {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
    }

}
 

/**
 * Dumps the tree of the current node to standard output.
 *
 * @param nodeCur The current node.
 * @param level   The maximum levels to output.
 *
 * @exception RuntimeException Thrown on error.
 */
private void dumpTree(CMNode nodeCur, int level) {
    for (int index = 0; index < level; index++)
        System.out.print("   ");

    int type = nodeCur.type();

    switch(type ) {

    case XSModelGroupImpl.MODELGROUP_CHOICE:
    case XSModelGroupImpl.MODELGROUP_SEQUENCE: {
        if (type == XSModelGroupImpl.MODELGROUP_CHOICE)
            System.out.print("Choice Node ");
        else
            System.out.print("Seq Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMBinOp)nodeCur).getLeft(), level+1);
        dumpTree(((XSCMBinOp)nodeCur).getRight(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ZERO_OR_MORE:
    case XSParticleDecl.PARTICLE_ONE_OR_MORE:
    case XSParticleDecl.PARTICLE_ZERO_OR_ONE: {
        System.out.print("Rep Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMUniOp)nodeCur).getChild(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ELEMENT: {
        System.out.print
        (
            "Leaf: (pos="
            + ((XSCMLeaf)nodeCur).getPosition()
            + "), "
            + "(elemIndex="
            + ((XSCMLeaf)nodeCur).getLeaf()
            + ") "
        );

        if (nodeCur.isNullable())
            System.out.print(" Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    }
    case XSParticleDecl.PARTICLE_WILDCARD:
          System.out.print("Any Node: ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    default: {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
    }

}
 

private CMNode expandContentModel(CMNode node,
                                  int minOccurs, int maxOccurs, boolean optimize) {

    CMNode nodeRet = null;

    if (minOccurs==1 && maxOccurs==1) {
        nodeRet = node;
    }
    else if (minOccurs==0 && maxOccurs==1) {
        //zero or one
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_ONE, node);
    }
    else if (minOccurs == 0 && maxOccurs==SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        //zero or more
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_MORE, node);
    }
    else if (minOccurs == 1 && maxOccurs==SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        //one or more
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
    }
    else if (optimize && node.type() == XSParticleDecl.PARTICLE_ELEMENT ||
             node.type() == XSParticleDecl.PARTICLE_WILDCARD) {
        // Only for elements and wildcards, subsume e{n,m} and e{n,unbounded} to e*
        // or e+ and, once the DFA reaches a final state, check if the actual number
        // of elements is between minOccurs and maxOccurs. This new algorithm runs
        // in constant space.

        // TODO: What is the impact of this optimization on the PSVI?
        nodeRet = fNodeFactory.getCMUniOpNode(
                minOccurs == 0 ? XSParticleDecl.PARTICLE_ZERO_OR_MORE
                    : XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
        nodeRet.setUserData(new int[] { minOccurs, maxOccurs });
    }
    else if (maxOccurs == SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        // => a,a,..,a+
        // create a+ node first, then put minOccurs-1 a's in front of it
        // for the first time "node" is used, we don't need to make a copy
        // and for other references to node, we make copies
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
        // (task 4) we need to call copyNode here, so that we append
        // an entire new copy of the node (a subtree). this is to ensure
        // all leaf nodes have distinct position
        // we know that minOccurs > 1
        nodeRet = fNodeFactory.getCMBinOpNode(XSModelGroupImpl.MODELGROUP_SEQUENCE,
                                              multiNodes(node, minOccurs-1, true), nodeRet);
    }
    else {
        // {n,m} => a,a,a,...(a),(a),...
        // first n a's, then m-n a?'s.
        // copyNode is called, for the same reason as above
        if (minOccurs > 0) {
            nodeRet = multiNodes(node, minOccurs, false);
        }
        if (maxOccurs > minOccurs) {
            node = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_ONE, node);
            if (nodeRet == null) {
                nodeRet = multiNodes(node, maxOccurs-minOccurs, false);
            }
            else {
                nodeRet = fNodeFactory.getCMBinOpNode(XSModelGroupImpl.MODELGROUP_SEQUENCE,
                                                      nodeRet, multiNodes(node, maxOccurs-minOccurs, true));
            }
        }
    }

    return nodeRet;
}
 

private CMNode expandContentModel(CMNode node,
                                  int minOccurs, int maxOccurs, boolean optimize) {

    CMNode nodeRet = null;

    if (minOccurs==1 && maxOccurs==1) {
        nodeRet = node;
    }
    else if (minOccurs==0 && maxOccurs==1) {
        //zero or one
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_ONE, node);
    }
    else if (minOccurs == 0 && maxOccurs==SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        //zero or more
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_MORE, node);
    }
    else if (minOccurs == 1 && maxOccurs==SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        //one or more
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
    }
    else if (optimize && node.type() == XSParticleDecl.PARTICLE_ELEMENT ||
             node.type() == XSParticleDecl.PARTICLE_WILDCARD) {
        // Only for elements and wildcards, subsume e{n,m} and e{n,unbounded} to e*
        // or e+ and, once the DFA reaches a final state, check if the actual number
        // of elements is between minOccurs and maxOccurs. This new algorithm runs
        // in constant space.

        // TODO: What is the impact of this optimization on the PSVI?
        nodeRet = fNodeFactory.getCMUniOpNode(
                minOccurs == 0 ? XSParticleDecl.PARTICLE_ZERO_OR_MORE
                    : XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
        nodeRet.setUserData(new int[] { minOccurs, maxOccurs });
    }
    else if (maxOccurs == SchemaSymbols.OCCURRENCE_UNBOUNDED) {
        // => a,a,..,a+
        // create a+ node first, then put minOccurs-1 a's in front of it
        // for the first time "node" is used, we don't need to make a copy
        // and for other references to node, we make copies
        nodeRet = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ONE_OR_MORE, node);
        // (task 4) we need to call copyNode here, so that we append
        // an entire new copy of the node (a subtree). this is to ensure
        // all leaf nodes have distinct position
        // we know that minOccurs > 1
        nodeRet = fNodeFactory.getCMBinOpNode(XSModelGroupImpl.MODELGROUP_SEQUENCE,
                                              multiNodes(node, minOccurs-1, true), nodeRet);
    }
    else {
        // {n,m} => a,a,a,...(a),(a),...
        // first n a's, then m-n a?'s.
        // copyNode is called, for the same reason as above
        if (minOccurs > 0) {
            nodeRet = multiNodes(node, minOccurs, false);
        }
        if (maxOccurs > minOccurs) {
            node = fNodeFactory.getCMUniOpNode(XSParticleDecl.PARTICLE_ZERO_OR_ONE, node);
            if (nodeRet == null) {
                nodeRet = multiNodes(node, maxOccurs-minOccurs, false);
            }
            else {
                nodeRet = fNodeFactory.getCMBinOpNode(XSModelGroupImpl.MODELGROUP_SEQUENCE,
                                                      nodeRet, multiNodes(node, maxOccurs-minOccurs, true));
            }
        }
    }

    return nodeRet;
}
 

/**
 * Dumps the tree of the current node to standard output.
 *
 * @param nodeCur The current node.
 * @param level   The maximum levels to output.
 *
 * @exception RuntimeException Thrown on error.
 */
private void dumpTree(CMNode nodeCur, int level) {
    for (int index = 0; index < level; index++)
        System.out.print("   ");

    int type = nodeCur.type();

    switch(type ) {

    case XSModelGroupImpl.MODELGROUP_CHOICE:
    case XSModelGroupImpl.MODELGROUP_SEQUENCE: {
        if (type == XSModelGroupImpl.MODELGROUP_CHOICE)
            System.out.print("Choice Node ");
        else
            System.out.print("Seq Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMBinOp)nodeCur).getLeft(), level+1);
        dumpTree(((XSCMBinOp)nodeCur).getRight(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ZERO_OR_MORE:
    case XSParticleDecl.PARTICLE_ONE_OR_MORE:
    case XSParticleDecl.PARTICLE_ZERO_OR_ONE: {
        System.out.print("Rep Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMUniOp)nodeCur).getChild(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ELEMENT: {
        System.out.print
        (
            "Leaf: (pos="
            + ((XSCMLeaf)nodeCur).getPosition()
            + "), "
            + "(elemIndex="
            + ((XSCMLeaf)nodeCur).getLeaf()
            + ") "
        );

        if (nodeCur.isNullable())
            System.out.print(" Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    }
    case XSParticleDecl.PARTICLE_WILDCARD:
          System.out.print("Any Node: ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    default: {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
    }

}
 

/**
 * Dumps the tree of the current node to standard output.
 *
 * @param nodeCur The current node.
 * @param level   The maximum levels to output.
 *
 * @exception RuntimeException Thrown on error.
 */
private void dumpTree(CMNode nodeCur, int level) {
    for (int index = 0; index < level; index++)
        System.out.print("   ");

    int type = nodeCur.type();

    switch(type ) {

    case XSModelGroupImpl.MODELGROUP_CHOICE:
    case XSModelGroupImpl.MODELGROUP_SEQUENCE: {
        if (type == XSModelGroupImpl.MODELGROUP_CHOICE)
            System.out.print("Choice Node ");
        else
            System.out.print("Seq Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMBinOp)nodeCur).getLeft(), level+1);
        dumpTree(((XSCMBinOp)nodeCur).getRight(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ZERO_OR_MORE:
    case XSParticleDecl.PARTICLE_ONE_OR_MORE:
    case XSParticleDecl.PARTICLE_ZERO_OR_ONE: {
        System.out.print("Rep Node ");

        if (nodeCur.isNullable())
            System.out.print("Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());

        dumpTree(((XSCMUniOp)nodeCur).getChild(), level+1);
        break;
    }
    case XSParticleDecl.PARTICLE_ELEMENT: {
        System.out.print
        (
            "Leaf: (pos="
            + ((XSCMLeaf)nodeCur).getPosition()
            + "), "
            + "(elemIndex="
            + ((XSCMLeaf)nodeCur).getLeaf()
            + ") "
        );

        if (nodeCur.isNullable())
            System.out.print(" Nullable ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    }
    case XSParticleDecl.PARTICLE_WILDCARD:
          System.out.print("Any Node: ");

        System.out.print("firstPos=");
        System.out.print(nodeCur.firstPos().toString());
        System.out.print(" lastPos=");
        System.out.println(nodeCur.lastPos().toString());
        break;
    default: {
        throw new RuntimeException("ImplementationMessages.VAL_NIICM");
    }
    }

}