src/main/java/org/yaml/snakeyaml/constructor/BaseConstructor.java - platform/external/snakeyaml - Git at Google

 /**
  * Copyright (c) 2008-2014, http://www.snakeyaml.org
  *
  * Licensed 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.yaml.snakeyaml.constructor;

 import java.lang.reflect.Array;
 import java.util.ArrayList;
 import java.util.Collection;
 import java.util.EnumMap;
 import java.util.HashMap;
 import java.util.HashSet;
 import java.util.LinkedHashMap;
 import java.util.LinkedHashSet;
 import java.util.List;
 import java.util.Map;
 import java.util.Set;

 import org.yaml.snakeyaml.composer.Composer;
 import org.yaml.snakeyaml.composer.ComposerException;
 import org.yaml.snakeyaml.error.YAMLException;
 import org.yaml.snakeyaml.introspector.PropertyUtils;
 import org.yaml.snakeyaml.nodes.MappingNode;
 import org.yaml.snakeyaml.nodes.Node;
 import org.yaml.snakeyaml.nodes.NodeId;
 import org.yaml.snakeyaml.nodes.NodeTuple;
 import org.yaml.snakeyaml.nodes.ScalarNode;
 import org.yaml.snakeyaml.nodes.SequenceNode;
 import org.yaml.snakeyaml.nodes.Tag;

 public abstract class BaseConstructor {
     /**
      * It maps the node kind to the the Construct implementation. When the
      * runtime class is known then the implicit tag is ignored.
      */
     protected final Map<NodeId, Construct> yamlClassConstructors = new EnumMap<NodeId, Construct>(
             NodeId.class);
     /**
      * It maps the (explicit or implicit) tag to the Construct implementation.
      * It is used: <br/>
      * 1) explicit tag - if present. <br/>
      * 2) implicit tag - when the runtime class of the instance is unknown (the
      * node has the Object.class)
      */
     protected final Map<Tag, Construct> yamlConstructors = new HashMap<Tag, Construct>();
     /**
      * It maps the (explicit or implicit) tag to the Construct implementation.
      * It is used when no exact match found.
      */
     protected final Map<String, Construct> yamlMultiConstructors = new HashMap<String, Construct>();

     private Composer composer;
     private final Map<Node, Object> constructedObjects;
     private final Set<Node> recursiveObjects;
     private final ArrayList<RecursiveTuple<Map<Object, Object>, RecursiveTuple<Object, Object>>> maps2fill;
     private final ArrayList<RecursiveTuple<Set<Object>, Object>> sets2fill;

     protected Tag rootTag;
     private PropertyUtils propertyUtils;
     private boolean explicitPropertyUtils;

     public BaseConstructor() {
         constructedObjects = new HashMap<Node, Object>();
         recursiveObjects = new HashSet<Node>();
         maps2fill = new ArrayList<RecursiveTuple<Map<Object, Object>, RecursiveTuple<Object, Object>>>();
         sets2fill = new ArrayList<RecursiveTuple<Set<Object>, Object>>();
         rootTag = null;
         explicitPropertyUtils = false;
     }

     public void setComposer(Composer composer) {
         this.composer = composer;
     }

     /**
      * Check if more documents available
      *
      * @return true when there are more YAML documents in the stream
      */
     public boolean checkData() {
         // If there are more documents available?
         return composer.checkNode();
     }

     /**
      * Construct and return the next document
      *
      * @return constructed instance
      */
     public Object getData() {
         // Construct and return the next document.
         composer.checkNode();
         Node node = composer.getNode();
         if (rootTag != null) {
             node.setTag(rootTag);
         }
         return constructDocument(node);
     }

     /**
      * Ensure that the stream contains a single document and construct it
      *
      * @return constructed instance
      * @throws ComposerException
      *             in case there are more documents in the stream
      */
     public Object getSingleData(Class<?> type) {
         // Ensure that the stream contains a single document and construct it
         Node node = composer.getSingleNode();
         if (node != null) {
             if (Object.class != type) {
                 node.setTag(new Tag(type));
             } else if (rootTag != null) {
                 node.setTag(rootTag);
             }
             return constructDocument(node);
         }
         return null;
     }

     /**
      * Construct complete YAML document. Call the second step in case of
      * recursive structures. At the end cleans all the state.
      *
      * @param node
      *            root Node
      * @return Java instance
      */
     private Object constructDocument(Node node) {
         Object data = constructObject(node);
         fillRecursive();
         constructedObjects.clear();
         recursiveObjects.clear();
         return data;
     }

     private void fillRecursive() {
         if (!maps2fill.isEmpty()) {
             for (RecursiveTuple<Map<Object, Object>, RecursiveTuple<Object, Object>> entry : maps2fill) {
                 RecursiveTuple<Object, Object> key_value = entry._2();
                 entry._1().put(key_value._1(), key_value._2());
             }
             maps2fill.clear();
         }
         if (!sets2fill.isEmpty()) {
             for (RecursiveTuple<Set<Object>, Object> value : sets2fill) {
                 value._1().add(value._2());
             }
             sets2fill.clear();
         }
     }

     /**
      * Construct object from the specified Node. Return existing instance if the
      * node is already constructed.
      *
      * @param node
      *            Node to be constructed
      * @return Java instance
      */
     protected Object constructObject(Node node) {
         if (constructedObjects.containsKey(node)) {
             return constructedObjects.get(node);
         }
         if (recursiveObjects.contains(node)) {
             throw new ConstructorException(null, null, "found unconstructable recursive node",
                     node.getStartMark());
         }
         recursiveObjects.add(node);
         Construct constructor = getConstructor(node);
         Object data = constructor.construct(node);
         constructedObjects.put(node, data);
         recursiveObjects.remove(node);
         if (node.isTwoStepsConstruction()) {
             constructor.construct2ndStep(node, data);
         }
         return data;
     }

     /**
      * Get the constructor to construct the Node. For implicit tags if the
      * runtime class is known a dedicated Construct implementation is used.
      * Otherwise the constructor is chosen by the tag.
      *
      * @param node
      *            Node to be constructed
      * @return Construct implementation for the specified node
      */
     protected Construct getConstructor(Node node) {
         if (node.useClassConstructor()) {
             return yamlClassConstructors.get(node.getNodeId());
         } else {
             Construct constructor = yamlConstructors.get(node.getTag());
             if (constructor == null) {
                 for (String prefix : yamlMultiConstructors.keySet()) {
                     if (node.getTag().startsWith(prefix)) {
                         return yamlMultiConstructors.get(prefix);
                     }
                 }
                 return yamlConstructors.get(null);
             }
             return constructor;
         }
     }

     protected Object constructScalar(ScalarNode node) {
         return node.getValue();
     }

     protected List<Object> createDefaultList(int initSize) {
         return new ArrayList<Object>(initSize);
     }

     protected Set<Object> createDefaultSet(int initSize) {
         return new LinkedHashSet<Object>(initSize);
     }

     protected Object createArray(Class<?> type, int size) {
         return Array.newInstance(type.getComponentType(), size);
     }

     @SuppressWarnings("unchecked")
     protected List<? extends Object> constructSequence(SequenceNode node) {
         List<Object> result;
         if (List.class.isAssignableFrom(node.getType()) && !node.getType().isInterface()) {
             // the root class may be defined (Vector for instance)
             try {
                 result = (List<Object>) node.getType().newInstance();
             } catch (Exception e) {
                 throw new YAMLException(e);
             }
         } else {
             result = createDefaultList(node.getValue().size());
         }
         constructSequenceStep2(node, result);
         return result;

     }

     @SuppressWarnings("unchecked")
     protected Set<? extends Object> constructSet(SequenceNode node) {
         Set<Object> result;
         if (!node.getType().isInterface()) {
             // the root class may be defined
             try {
                 result = (Set<Object>) node.getType().newInstance();
             } catch (Exception e) {
                 throw new YAMLException(e);
             }
         } else {
             result = createDefaultSet(node.getValue().size());
         }
         constructSequenceStep2(node, result);
         return result;

     }

     protected Object constructArray(SequenceNode node) {
         return constructArrayStep2(node, createArray(node.getType(), node.getValue().size()));
     }

     protected void constructSequenceStep2(SequenceNode node, Collection<Object> collection) {
         for (Node child : node.getValue()) {
             collection.add(constructObject(child));
         }
     }

     protected Object constructArrayStep2(SequenceNode node, Object array) {
         final Class<?> componentType = node.getType().getComponentType();

         int index = 0;
         for (Node child : node.getValue()) {
             // Handle multi-dimensional arrays...
             if (child.getType() == Object.class) {
                 child.setType(componentType);
             }

             final Object value = constructObject(child);

             if (componentType.isPrimitive()) {
                 // Null values are disallowed for primitives
                 if (value == null) {
                     throw new NullPointerException("Unable to construct element value for " + child);
                 }

                 // Primitive arrays require quite a lot of work.
                 if (byte.class.equals(componentType)) {
                     Array.setByte(array, index, ((Number) value).byteValue());

                 } else if (short.class.equals(componentType)) {
                     Array.setShort(array, index, ((Number) value).shortValue());

                 } else if (int.class.equals(componentType)) {
                     Array.setInt(array, index, ((Number) value).intValue());

                 } else if (long.class.equals(componentType)) {
                     Array.setLong(array, index, ((Number) value).longValue());

                 } else if (float.class.equals(componentType)) {
                     Array.setFloat(array, index, ((Number) value).floatValue());

                 } else if (double.class.equals(componentType)) {
                     Array.setDouble(array, index, ((Number) value).doubleValue());

                 } else if (char.class.equals(componentType)) {
                     Array.setChar(array, index, ((Character) value).charValue());

                 } else if (boolean.class.equals(componentType)) {
                     Array.setBoolean(array, index, ((Boolean) value).booleanValue());

                 } else {
                     throw new YAMLException("unexpected primitive type");
                 }

             } else {
                 // Non-primitive arrays can simply be assigned:
                 Array.set(array, index, value);
             }

             ++index;
         }
         return array;
     }

     protected Map<Object, Object> createDefaultMap() {
         // respect order from YAML document
         return new LinkedHashMap<Object, Object>();
     }

     protected Set<Object> createDefaultSet() {
         // respect order from YAML document
         return new LinkedHashSet<Object>();
     }

     protected Set<Object> constructSet(MappingNode node) {
         Set<Object> set = createDefaultSet();
         constructSet2ndStep(node, set);
         return set;
     }

     protected Map<Object, Object> constructMapping(MappingNode node) {
         Map<Object, Object> mapping = createDefaultMap();
         constructMapping2ndStep(node, mapping);
         return mapping;
     }

     protected void constructMapping2ndStep(MappingNode node, Map<Object, Object> mapping) {
         List<NodeTuple> nodeValue = (List<NodeTuple>) node.getValue();
         for (NodeTuple tuple : nodeValue) {
             Node keyNode = tuple.getKeyNode();
             Node valueNode = tuple.getValueNode();
             Object key = constructObject(keyNode);
             if (key != null) {
                 try {
                     key.hashCode();// check circular dependencies
                 } catch (Exception e) {
                     throw new ConstructorException("while constructing a mapping",
                             node.getStartMark(), "found unacceptable key " + key, tuple
                                     .getKeyNode().getStartMark(), e);
                 }
             }
             Object value = constructObject(valueNode);
             if (keyNode.isTwoStepsConstruction()) {
                 /*
                  * if keyObject is created it 2 steps we should postpone putting
                  * it in map because it may have different hash after
                  * initialization compared to clean just created one. And map of
                  * course does not observe key hashCode changes.
                  */
                 maps2fill.add(0,
                         new RecursiveTuple<Map<Object, Object>, RecursiveTuple<Object, Object>>(
                                 mapping, new RecursiveTuple<Object, Object>(key, value)));
             } else {
                 mapping.put(key, value);
             }
         }
     }

     protected void constructSet2ndStep(MappingNode node, Set<Object> set) {
         List<NodeTuple> nodeValue = (List<NodeTuple>) node.getValue();
         for (NodeTuple tuple : nodeValue) {
             Node keyNode = tuple.getKeyNode();
             Object key = constructObject(keyNode);
             if (key != null) {
                 try {
                     key.hashCode();// check circular dependencies
                 } catch (Exception e) {
                     throw new ConstructorException("while constructing a Set", node.getStartMark(),
                             "found unacceptable key " + key, tuple.getKeyNode().getStartMark(), e);
                 }
             }
             if (keyNode.isTwoStepsConstruction()) {
                 /*
                  * if keyObject is created it 2 steps we should postpone putting
                  * it into the set because it may have different hash after
                  * initialization compared to clean just created one. And set of
                  * course does not observe value hashCode changes.
                  */
                 sets2fill.add(0, new RecursiveTuple<Set<Object>, Object>(set, key));
             } else {
                 set.add(key);
             }
         }
     }

     public void setPropertyUtils(PropertyUtils propertyUtils) {
         this.propertyUtils = propertyUtils;
         explicitPropertyUtils = true;
     }

     public final PropertyUtils getPropertyUtils() {
         if (propertyUtils == null) {
             propertyUtils = new PropertyUtils();
         }
         return propertyUtils;
     }

     private static class RecursiveTuple<T, K> {
         private final T _1;
         private final K _2;

         public RecursiveTuple(T _1, K _2) {
             this._1 = _1;
             this._2 = _2;
         }

         public K _2() {
             return _2;
         }

         public T _1() {
             return _1;
         }
     }

     public final boolean isExplicitPropertyUtils() {
         return explicitPropertyUtils;
     }
 }
	/**
	* Copyright (c) 2008-2014, http://www.snakeyaml.org
	*
	* Licensed 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.yaml.snakeyaml.constructor;

	import java.lang.reflect.Array;
	import java.util.ArrayList;
	import java.util.Collection;
	import java.util.EnumMap;
	import java.util.HashMap;
	import java.util.HashSet;
	import java.util.LinkedHashMap;
	import java.util.LinkedHashSet;
	import java.util.List;
	import java.util.Map;
	import java.util.Set;

	import org.yaml.snakeyaml.composer.Composer;
	import org.yaml.snakeyaml.composer.ComposerException;
	import org.yaml.snakeyaml.error.YAMLException;
	import org.yaml.snakeyaml.introspector.PropertyUtils;
	import org.yaml.snakeyaml.nodes.MappingNode;
	import org.yaml.snakeyaml.nodes.Node;
	import org.yaml.snakeyaml.nodes.NodeId;
	import org.yaml.snakeyaml.nodes.NodeTuple;
	import org.yaml.snakeyaml.nodes.ScalarNode;
	import org.yaml.snakeyaml.nodes.SequenceNode;
	import org.yaml.snakeyaml.nodes.Tag;

	public abstract class BaseConstructor {
	/**
	* It maps the node kind to the the Construct implementation. When the
	* runtime class is known then the implicit tag is ignored.
	*/
	protected final Map<NodeId, Construct> yamlClassConstructors = new EnumMap<NodeId, Construct>(
	NodeId.class);
	/**
	* It maps the (explicit or implicit) tag to the Construct implementation.
	* It is used: <br/>
	* 1) explicit tag - if present. <br/>
	* 2) implicit tag - when the runtime class of the instance is unknown (the
	* node has the Object.class)
	*/
	protected final Map<Tag, Construct> yamlConstructors = new HashMap<Tag, Construct>();
	/**
	* It maps the (explicit or implicit) tag to the Construct implementation.
	* It is used when no exact match found.
	*/
	protected final Map<String, Construct> yamlMultiConstructors = new HashMap<String, Construct>();

	private Composer composer;
	private final Map<Node, Object> constructedObjects;
	private final Set<Node> recursiveObjects;
	private final ArrayList<RecursiveTuple<Map<Object, Object>, RecursiveTuple<Object, Object>>> maps2fill;
	private final ArrayList<RecursiveTuple<Set<Object>, Object>> sets2fill;

	protected Tag rootTag;
	private PropertyUtils propertyUtils;
	private boolean explicitPropertyUtils;

	public BaseConstructor() {
	constructedObjects = new HashMap<Node, Object>();
	recursiveObjects = new HashSet<Node>();
	maps2fill = new ArrayList<RecursiveTuple<Map<Object, Object>, RecursiveTuple<Object, Object>>>();
	sets2fill = new ArrayList<RecursiveTuple<Set<Object>, Object>>();
	rootTag = null;
	explicitPropertyUtils = false;
	}

	public void setComposer(Composer composer) {
	this.composer = composer;
	}

	/**
	* Check if more documents available
	*
	* @return true when there are more YAML documents in the stream
	*/
	public boolean checkData() {
	// If there are more documents available?
	return composer.checkNode();
	}

	/**
	* Construct and return the next document
	*
	* @return constructed instance
	*/
	public Object getData() {
	// Construct and return the next document.
	composer.checkNode();
	Node node = composer.getNode();
	if (rootTag != null) {
	node.setTag(rootTag);
	}
	return constructDocument(node);
	}

	/**
	* Ensure that the stream contains a single document and construct it
	*
	* @return constructed instance
	* @throws ComposerException
	* in case there are more documents in the stream
	*/
	public Object getSingleData(Class<?> type) {
	// Ensure that the stream contains a single document and construct it
	Node node = composer.getSingleNode();
	if (node != null) {
	if (Object.class != type) {
	node.setTag(new Tag(type));
	} else if (rootTag != null) {
	node.setTag(rootTag);
	}
	return constructDocument(node);
	}
	return null;
	}

	/**
	* Construct complete YAML document. Call the second step in case of
	* recursive structures. At the end cleans all the state.
	*
	* @param node
	* root Node
	* @return Java instance
	*/
	private Object constructDocument(Node node) {
	Object data = constructObject(node);
	fillRecursive();
	constructedObjects.clear();
	recursiveObjects.clear();
	return data;
	}

	private void fillRecursive() {
	if (!maps2fill.isEmpty()) {
	for (RecursiveTuple<Map<Object, Object>, RecursiveTuple<Object, Object>> entry : maps2fill) {
	RecursiveTuple<Object, Object> key_value = entry._2();
	entry._1().put(key_value._1(), key_value._2());
	}
	maps2fill.clear();
	}
	if (!sets2fill.isEmpty()) {
	for (RecursiveTuple<Set<Object>, Object> value : sets2fill) {
	value._1().add(value._2());
	}
	sets2fill.clear();
	}
	}

	/**
	* Construct object from the specified Node. Return existing instance if the
	* node is already constructed.
	*
	* @param node
	* Node to be constructed
	* @return Java instance
	*/
	protected Object constructObject(Node node) {
	if (constructedObjects.containsKey(node)) {
	return constructedObjects.get(node);
	}
	if (recursiveObjects.contains(node)) {
	throw new ConstructorException(null, null, "found unconstructable recursive node",
	node.getStartMark());
	}
	recursiveObjects.add(node);
	Construct constructor = getConstructor(node);
	Object data = constructor.construct(node);
	constructedObjects.put(node, data);
	recursiveObjects.remove(node);
	if (node.isTwoStepsConstruction()) {
	constructor.construct2ndStep(node, data);
	}
	return data;
	}

	/**
	* Get the constructor to construct the Node. For implicit tags if the
	* runtime class is known a dedicated Construct implementation is used.
	* Otherwise the constructor is chosen by the tag.
	*
	* @param node
	* Node to be constructed
	* @return Construct implementation for the specified node
	*/
	protected Construct getConstructor(Node node) {
	if (node.useClassConstructor()) {
	return yamlClassConstructors.get(node.getNodeId());
	} else {
	Construct constructor = yamlConstructors.get(node.getTag());
	if (constructor == null) {
	for (String prefix : yamlMultiConstructors.keySet()) {
	if (node.getTag().startsWith(prefix)) {
	return yamlMultiConstructors.get(prefix);
	}
	}
	return yamlConstructors.get(null);
	}
	return constructor;
	}
	}

	protected Object constructScalar(ScalarNode node) {
	return node.getValue();
	}

	protected List<Object> createDefaultList(int initSize) {
	return new ArrayList<Object>(initSize);
	}

	protected Set<Object> createDefaultSet(int initSize) {
	return new LinkedHashSet<Object>(initSize);
	}

	protected Object createArray(Class<?> type, int size) {
	return Array.newInstance(type.getComponentType(), size);
	}

	@SuppressWarnings("unchecked")
	protected List<? extends Object> constructSequence(SequenceNode node) {
	List<Object> result;
	if (List.class.isAssignableFrom(node.getType()) && !node.getType().isInterface()) {
	// the root class may be defined (Vector for instance)
	try {
	result = (List<Object>) node.getType().newInstance();
	} catch (Exception e) {
	throw new YAMLException(e);
	}
	} else {
	result = createDefaultList(node.getValue().size());
	}
	constructSequenceStep2(node, result);
	return result;

	}

	@SuppressWarnings("unchecked")
	protected Set<? extends Object> constructSet(SequenceNode node) {
	Set<Object> result;
	if (!node.getType().isInterface()) {
	// the root class may be defined
	try {
	result = (Set<Object>) node.getType().newInstance();
	} catch (Exception e) {
	throw new YAMLException(e);
	}
	} else {
	result = createDefaultSet(node.getValue().size());
	}
	constructSequenceStep2(node, result);
	return result;

	}

	protected Object constructArray(SequenceNode node) {
	return constructArrayStep2(node, createArray(node.getType(), node.getValue().size()));
	}

	protected void constructSequenceStep2(SequenceNode node, Collection<Object> collection) {
	for (Node child : node.getValue()) {
	collection.add(constructObject(child));
	}
	}

	protected Object constructArrayStep2(SequenceNode node, Object array) {
	final Class<?> componentType = node.getType().getComponentType();

	int index = 0;
	for (Node child : node.getValue()) {
	// Handle multi-dimensional arrays...
	if (child.getType() == Object.class) {
	child.setType(componentType);
	}

	final Object value = constructObject(child);

	if (componentType.isPrimitive()) {
	// Null values are disallowed for primitives
	if (value == null) {
	throw new NullPointerException("Unable to construct element value for " + child);
	}

	// Primitive arrays require quite a lot of work.
	if (byte.class.equals(componentType)) {
	Array.setByte(array, index, ((Number) value).byteValue());

	} else if (short.class.equals(componentType)) {
	Array.setShort(array, index, ((Number) value).shortValue());

	} else if (int.class.equals(componentType)) {
	Array.setInt(array, index, ((Number) value).intValue());

	} else if (long.class.equals(componentType)) {
	Array.setLong(array, index, ((Number) value).longValue());

	} else if (float.class.equals(componentType)) {
	Array.setFloat(array, index, ((Number) value).floatValue());

	} else if (double.class.equals(componentType)) {
	Array.setDouble(array, index, ((Number) value).doubleValue());

	} else if (char.class.equals(componentType)) {
	Array.setChar(array, index, ((Character) value).charValue());

	} else if (boolean.class.equals(componentType)) {
	Array.setBoolean(array, index, ((Boolean) value).booleanValue());

	} else {
	throw new YAMLException("unexpected primitive type");
	}

	} else {
	// Non-primitive arrays can simply be assigned:
	Array.set(array, index, value);
	}

	++index;
	}
	return array;
	}

	protected Map<Object, Object> createDefaultMap() {
	// respect order from YAML document
	return new LinkedHashMap<Object, Object>();
	}

	protected Set<Object> createDefaultSet() {
	// respect order from YAML document
	return new LinkedHashSet<Object>();
	}

	protected Set<Object> constructSet(MappingNode node) {
	Set<Object> set = createDefaultSet();
	constructSet2ndStep(node, set);
	return set;
	}

	protected Map<Object, Object> constructMapping(MappingNode node) {
	Map<Object, Object> mapping = createDefaultMap();
	constructMapping2ndStep(node, mapping);
	return mapping;
	}

	protected void constructMapping2ndStep(MappingNode node, Map<Object, Object> mapping) {
	List<NodeTuple> nodeValue = (List<NodeTuple>) node.getValue();
	for (NodeTuple tuple : nodeValue) {
	Node keyNode = tuple.getKeyNode();
	Node valueNode = tuple.getValueNode();
	Object key = constructObject(keyNode);
	if (key != null) {
	try {
	key.hashCode();// check circular dependencies
	} catch (Exception e) {
	throw new ConstructorException("while constructing a mapping",
	node.getStartMark(), "found unacceptable key " + key, tuple
	.getKeyNode().getStartMark(), e);
	}
	}
	Object value = constructObject(valueNode);
	if (keyNode.isTwoStepsConstruction()) {
	/*
	* if keyObject is created it 2 steps we should postpone putting
	* it in map because it may have different hash after
	* initialization compared to clean just created one. And map of
	* course does not observe key hashCode changes.
	*/
	maps2fill.add(0,
	new RecursiveTuple<Map<Object, Object>, RecursiveTuple<Object, Object>>(
	mapping, new RecursiveTuple<Object, Object>(key, value)));
	} else {
	mapping.put(key, value);
	}
	}
	}

	protected void constructSet2ndStep(MappingNode node, Set<Object> set) {
	List<NodeTuple> nodeValue = (List<NodeTuple>) node.getValue();
	for (NodeTuple tuple : nodeValue) {
	Node keyNode = tuple.getKeyNode();
	Object key = constructObject(keyNode);
	if (key != null) {
	try {
	key.hashCode();// check circular dependencies
	} catch (Exception e) {
	throw new ConstructorException("while constructing a Set", node.getStartMark(),
	"found unacceptable key " + key, tuple.getKeyNode().getStartMark(), e);
	}
	}
	if (keyNode.isTwoStepsConstruction()) {
	/*
	* if keyObject is created it 2 steps we should postpone putting
	* it into the set because it may have different hash after
	* initialization compared to clean just created one. And set of
	* course does not observe value hashCode changes.
	*/
	sets2fill.add(0, new RecursiveTuple<Set<Object>, Object>(set, key));
	} else {
	set.add(key);
	}
	}
	}

	public void setPropertyUtils(PropertyUtils propertyUtils) {
	this.propertyUtils = propertyUtils;
	explicitPropertyUtils = true;
	}

	public final PropertyUtils getPropertyUtils() {
	if (propertyUtils == null) {
	propertyUtils = new PropertyUtils();
	}
	return propertyUtils;
	}

	private static class RecursiveTuple<T, K> {
	private final T _1;
	private final K _2;

	public RecursiveTuple(T _1, K _2) {
	this._1 = _1;
	this._2 = _2;
	}

	public K _2() {
	return _2;
	}

	public T _1() {
	return _1;
	}
	}

	public final boolean isExplicitPropertyUtils() {
	return explicitPropertyUtils;
	}
	}