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Tools to assist in the reading of configuration/preferences files in
various formats
/*
* 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.commons.configuration2;
import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.HashMap;
import java.util.Iterator;
import java.util.LinkedList;
import java.util.List;
import java.util.Map;
import org.apache.commons.configuration2.event.ConfigurationEvent;
import org.apache.commons.configuration2.event.EventListener;
import org.apache.commons.configuration2.ex.ConfigurationRuntimeException;
import org.apache.commons.configuration2.interpol.ConfigurationInterpolator;
import org.apache.commons.configuration2.tree.ConfigurationNodeVisitorAdapter;
import org.apache.commons.configuration2.tree.ImmutableNode;
import org.apache.commons.configuration2.tree.InMemoryNodeModel;
import org.apache.commons.configuration2.tree.InMemoryNodeModelSupport;
import org.apache.commons.configuration2.tree.NodeHandler;
import org.apache.commons.configuration2.tree.NodeModel;
import org.apache.commons.configuration2.tree.NodeSelector;
import org.apache.commons.configuration2.tree.NodeTreeWalker;
import org.apache.commons.configuration2.tree.QueryResult;
import org.apache.commons.configuration2.tree.ReferenceNodeHandler;
import org.apache.commons.configuration2.tree.TrackedNodeModel;
import org.apache.commons.lang3.ObjectUtils;
/**
*
* A specialized hierarchical configuration implementation that is based on a
* structure of {@link ImmutableNode} objects.
*
*
*/
public class BaseHierarchicalConfiguration extends AbstractHierarchicalConfiguration
implements InMemoryNodeModelSupport
{
/** A listener for reacting on changes caused by sub configurations. */
private final EventListener changeListener;
/**
* Creates a new instance of {@code BaseHierarchicalConfiguration}.
*/
public BaseHierarchicalConfiguration()
{
this((HierarchicalConfiguration) null);
}
/**
* Creates a new instance of {@code BaseHierarchicalConfiguration} and
* copies all data contained in the specified configuration into the new
* one.
*
* @param c the configuration that is to be copied (if null, this
* constructor will behave like the standard constructor)
* @since 1.4
*/
public BaseHierarchicalConfiguration(final HierarchicalConfiguration c)
{
this(createNodeModel(c));
}
/**
* Creates a new instance of {@code BaseHierarchicalConfiguration} and
* initializes it with the given {@code NodeModel}.
*
* @param model the {@code NodeModel}
*/
protected BaseHierarchicalConfiguration(final NodeModel model)
{
super(model);
changeListener = createChangeListener();
}
/**
* {@inheritDoc} This implementation returns the {@code InMemoryNodeModel}
* used by this configuration.
*/
@Override
public InMemoryNodeModel getNodeModel()
{
return (InMemoryNodeModel) super.getNodeModel();
}
/**
* Creates a new {@code Configuration} object containing all keys
* that start with the specified prefix. This implementation will return a
* {@code BaseHierarchicalConfiguration} object so that the structure of
* the keys will be saved. The nodes selected by the prefix (it is possible
* that multiple nodes are selected) are mapped to the root node of the
* returned configuration, i.e. their children and attributes will become
* children and attributes of the new root node. However, a value of the root
* node is only set if exactly one of the selected nodes contain a value (if
* multiple nodes have a value, there is simply no way to decide how these
* values are merged together). Note that the returned
* {@code Configuration} object is not connected to its source
* configuration: updates on the source configuration are not reflected in
* the subset and vice versa. The returned configuration uses the same
* {@code Synchronizer} as this configuration.
*
* @param prefix the prefix of the keys for the subset
* @return a new configuration object representing the selected subset
*/
@Override
public Configuration subset(final String prefix)
{
beginRead(false);
try
{
final List> results = fetchNodeList(prefix);
if (results.isEmpty())
{
return new BaseHierarchicalConfiguration();
}
final BaseHierarchicalConfiguration parent = this;
final BaseHierarchicalConfiguration result =
new BaseHierarchicalConfiguration()
{
// Override interpolate to always interpolate on the parent
@Override
protected Object interpolate(final Object value)
{
return parent.interpolate(value);
}
@Override
public ConfigurationInterpolator getInterpolator()
{
return parent.getInterpolator();
}
};
result.getModel().setRootNode(createSubsetRootNode(results));
if (result.isEmpty())
{
return new BaseHierarchicalConfiguration();
}
result.setSynchronizer(getSynchronizer());
return result;
}
finally
{
endRead();
}
}
/**
* Creates a root node for a subset configuration based on the passed in
* query results. This method creates a new root node and adds the children
* and attributes of all result nodes to it. If only a single node value is
* defined, it is assigned as value of the new root node.
*
* @param results the collection of query results
* @return the root node for the subset configuration
*/
private ImmutableNode createSubsetRootNode(
final Collection> results)
{
final ImmutableNode.Builder builder = new ImmutableNode.Builder();
Object value = null;
int valueCount = 0;
for (final QueryResult result : results)
{
if (result.isAttributeResult())
{
builder.addAttribute(result.getAttributeName(),
result.getAttributeValue(getModel().getNodeHandler()));
}
else
{
if (result.getNode().getValue() != null)
{
value = result.getNode().getValue();
valueCount++;
}
builder.addChildren(result.getNode().getChildren());
builder.addAttributes(result.getNode().getAttributes());
}
}
if (valueCount == 1)
{
builder.value(value);
}
return builder.create();
}
/**
* {@inheritDoc} The result of this implementation depends on the
* {@code supportUpdates} flag: If it is false, a plain
* {@code BaseHierarchicalConfiguration} is returned using the selected node
* as root node. This is suitable for read-only access to properties.
* Because the configuration returned in this case is not connected to the
* parent configuration, updates on properties made by one configuration are
* not reflected by the other one. A value of true for this parameter
* causes a tracked node to be created, and result is a
* {@link SubnodeConfiguration} based on this tracked node. This
* configuration is really connected to its parent, so that updated
* properties are visible on both.
*
* @see SubnodeConfiguration
* @throws ConfigurationRuntimeException if the key does not select a single
* node
*/
@Override
public HierarchicalConfiguration configurationAt(final String key,
final boolean supportUpdates)
{
beginRead(false);
try
{
return supportUpdates ? createConnectedSubConfiguration(key)
: createIndependentSubConfiguration(key);
}
finally
{
endRead();
}
}
/**
* Returns the {@code InMemoryNodeModel} to be used as parent model for a
* new sub configuration. This method is called whenever a sub configuration
* is to be created. This base implementation returns the model of this
* configuration. Sub classes with different requirements for the parent
* models of sub configurations have to override it.
*
* @return the parent model for a new sub configuration
*/
protected InMemoryNodeModel getSubConfigurationParentModel()
{
return (InMemoryNodeModel) getModel();
}
/**
* Returns the {@code NodeSelector} to be used for a sub configuration based
* on the passed in key. This method is called whenever a sub configuration
* is to be created. This base implementation returns a new
* {@code NodeSelector} initialized with the passed in key. Sub classes may
* override this method if they have a different strategy for creating a
* selector.
*
* @param key the key of the sub configuration
* @return a {@code NodeSelector} for initializing a sub configuration
* @since 2.0
*/
protected NodeSelector getSubConfigurationNodeSelector(final String key)
{
return new NodeSelector(key);
}
/**
* Creates a connected sub configuration based on a selector for a tracked
* node.
*
* @param selector the {@code NodeSelector}
* @param parentModelSupport the {@code InMemoryNodeModelSupport} object for
* the parent node model
* @return the newly created sub configuration
* @since 2.0
*/
protected SubnodeConfiguration createSubConfigurationForTrackedNode(
final NodeSelector selector, final InMemoryNodeModelSupport parentModelSupport)
{
final SubnodeConfiguration subConfig =
new SubnodeConfiguration(this, new TrackedNodeModel(
parentModelSupport, selector, true));
initSubConfigurationForThisParent(subConfig);
return subConfig;
}
/**
* Initializes a {@code SubnodeConfiguration} object. This method should be
* called for each sub configuration created for this configuration. It
* ensures that the sub configuration is correctly connected to its parent
* instance and that update events are correctly propagated.
*
* @param subConfig the sub configuration to be initialized
* @since 2.0
*/
protected void initSubConfigurationForThisParent(final SubnodeConfiguration subConfig)
{
initSubConfiguration(subConfig);
subConfig.addEventListener(ConfigurationEvent.ANY, changeListener);
}
/**
* Creates a sub configuration from the specified key which is connected to
* this configuration. This implementation creates a
* {@link SubnodeConfiguration} with a tracked node identified by the passed
* in key.
*
* @param key the key of the sub configuration
* @return the new sub configuration
*/
private BaseHierarchicalConfiguration createConnectedSubConfiguration(
final String key)
{
final NodeSelector selector = getSubConfigurationNodeSelector(key);
getSubConfigurationParentModel().trackNode(selector, this);
return createSubConfigurationForTrackedNode(selector, this);
}
/**
* Creates a list of connected sub configurations based on a passed in list
* of node selectors.
*
* @param parentModelSupport the parent node model support object
* @param selectors the list of {@code NodeSelector} objects
* @return the list with sub configurations
*/
private List> createConnectedSubConfigurations(
final InMemoryNodeModelSupport parentModelSupport,
final Collection selectors)
{
final List> configs =
new ArrayList<>(
selectors.size());
for (final NodeSelector selector : selectors)
{
configs.add(createSubConfigurationForTrackedNode(selector,
parentModelSupport));
}
return configs;
}
/**
* Creates a sub configuration from the specified key which is independent
* on this configuration. This means that the sub configuration operates on
* a separate node model (although the nodes are initially shared).
*
* @param key the key of the sub configuration
* @return the new sub configuration
*/
private BaseHierarchicalConfiguration createIndependentSubConfiguration(
final String key)
{
final List targetNodes = fetchFilteredNodeResults(key);
final int size = targetNodes.size();
if (size != 1)
{
throw new ConfigurationRuntimeException(
"Passed in key must select exactly one node (found %,d): %s", size, key);
}
final BaseHierarchicalConfiguration sub =
new BaseHierarchicalConfiguration(new InMemoryNodeModel(
targetNodes.get(0)));
initSubConfiguration(sub);
return sub;
}
/**
* Returns an initialized sub configuration for this configuration that is
* based on another {@code BaseHierarchicalConfiguration}. Thus, it is
* independent from this configuration.
*
* @param node the root node for the sub configuration
* @return the initialized sub configuration
*/
private BaseHierarchicalConfiguration createIndependentSubConfigurationForNode(
final ImmutableNode node)
{
final BaseHierarchicalConfiguration sub =
new BaseHierarchicalConfiguration(new InMemoryNodeModel(node));
initSubConfiguration(sub);
return sub;
}
/**
* Executes a query on the specified key and filters it for node results.
*
* @param key the key
* @return the filtered list with result nodes
*/
private List fetchFilteredNodeResults(final String key)
{
final NodeHandler handler = getModel().getNodeHandler();
return resolveNodeKey(handler.getRootNode(), key, handler);
}
/**
* {@inheritDoc} This implementation creates a {@code SubnodeConfiguration}
* by delegating to {@code configurationAt()}. Then an immutable wrapper
* is created and returned.
*/
@Override
public ImmutableHierarchicalConfiguration immutableConfigurationAt(
final String key, final boolean supportUpdates)
{
return ConfigurationUtils.unmodifiableConfiguration(configurationAt(
key, supportUpdates));
}
/**
* {@inheritDoc} This is a short form for {@code configurationAt(key,
* false)}.
* @throws ConfigurationRuntimeException if the key does not select a single node
*/
@Override
public HierarchicalConfiguration configurationAt(final String key)
{
return configurationAt(key, false);
}
/**
* {@inheritDoc} This implementation creates a {@code SubnodeConfiguration}
* by delegating to {@code configurationAt()}. Then an immutable wrapper
* is created and returned.
* @throws ConfigurationRuntimeException if the key does not select a single node
*/
@Override
public ImmutableHierarchicalConfiguration immutableConfigurationAt(
final String key)
{
return ConfigurationUtils.unmodifiableConfiguration(configurationAt(
key));
}
/**
* {@inheritDoc} This implementation creates sub configurations in the same
* way as described for {@link #configurationAt(String)}.
*/
@Override
public List> configurationsAt(
final String key)
{
List nodes;
beginRead(false);
try
{
nodes = fetchFilteredNodeResults(key);
}
finally
{
endRead();
}
final List> results =
new ArrayList<>(
nodes.size());
for (final ImmutableNode node : nodes)
{
final BaseHierarchicalConfiguration sub =
createIndependentSubConfigurationForNode(node);
results.add(sub);
}
return results;
}
/**
* {@inheritDoc} This implementation creates tracked nodes for the specified
* key. Then sub configurations for these nodes are created and returned.
*/
@Override
public List> configurationsAt(
final String key, final boolean supportUpdates)
{
if (!supportUpdates)
{
return configurationsAt(key);
}
InMemoryNodeModel parentModel;
beginRead(false);
try
{
parentModel = getSubConfigurationParentModel();
}
finally
{
endRead();
}
final Collection selectors =
parentModel.selectAndTrackNodes(key, this);
return createConnectedSubConfigurations(this, selectors);
}
/**
* {@inheritDoc} This implementation first delegates to
* {@code configurationsAt()} to create a list of
* {@code SubnodeConfiguration} objects. Then for each element of this list
* an unmodifiable wrapper is created.
*/
@Override
public List immutableConfigurationsAt(
final String key)
{
return toImmutable(configurationsAt(key));
}
/**
* {@inheritDoc} This implementation resolves the node(s) selected by the
* given key. If not a single node is selected, an empty list is returned.
* Otherwise, sub configurations for each child of the node are created.
*/
@Override
public List> childConfigurationsAt(
final String key)
{
List nodes;
beginRead(false);
try
{
nodes = fetchFilteredNodeResults(key);
}
finally
{
endRead();
}
if (nodes.size() != 1)
{
return Collections.emptyList();
}
final ImmutableNode parent = nodes.get(0);
final List> subs =
new ArrayList<>(parent
.getChildren().size());
for (final ImmutableNode node : parent.getChildren())
{
subs.add(createIndependentSubConfigurationForNode(node));
}
return subs;
}
/**
* {@inheritDoc} This method works like
* {@link #childConfigurationsAt(String)}; however, depending on the value
* of the {@code supportUpdates} flag, connected sub configurations may be
* created.
*/
@Override
public List> childConfigurationsAt(
final String key, final boolean supportUpdates)
{
if (!supportUpdates)
{
return childConfigurationsAt(key);
}
final InMemoryNodeModel parentModel = getSubConfigurationParentModel();
return createConnectedSubConfigurations(this,
parentModel.trackChildNodes(key, this));
}
/**
* {@inheritDoc} This implementation first delegates to
* {@code childConfigurationsAt()} to create a list of mutable child
* configurations. Then a list with immutable wrapper configurations is
* created.
*/
@Override
public List immutableChildConfigurationsAt(
final String key)
{
return toImmutable(childConfigurationsAt(key));
}
/**
* This method is always called when a subnode configuration created from
* this configuration has been modified. This implementation transforms the
* received event into an event of type {@code SUBNODE_CHANGED}
* and notifies the registered listeners.
*
* @param event the event describing the change
* @since 1.5
*/
protected void subnodeConfigurationChanged(final ConfigurationEvent event)
{
fireEvent(ConfigurationEvent.SUBNODE_CHANGED, null, event, event.isBeforeUpdate());
}
/**
* Initializes properties of a sub configuration. A sub configuration
* inherits some settings from its parent, e.g. the expression engine or the
* synchronizer. The corresponding values are copied by this method.
*
* @param sub the sub configuration to be initialized
*/
private void initSubConfiguration(final BaseHierarchicalConfiguration sub)
{
sub.setSynchronizer(getSynchronizer());
sub.setExpressionEngine(getExpressionEngine());
sub.setListDelimiterHandler(getListDelimiterHandler());
sub.setThrowExceptionOnMissing(isThrowExceptionOnMissing());
sub.getInterpolator().setParentInterpolator(getInterpolator());
}
/**
* Creates a listener which reacts on all changes on this configuration or
* one of its {@code SubnodeConfiguration} instances. If such a change is
* detected, some updates have to be performed.
*
* @return the newly created change listener
*/
private EventListener createChangeListener()
{
return event -> subnodeConfigurationChanged(event);
}
/**
* Returns a configuration with the same content as this configuration, but
* with all variables replaced by their actual values. This implementation
* is specific for hierarchical configurations. It clones the current
* configuration and runs a specialized visitor on the clone, which performs
* interpolation on the single configuration nodes.
*
* @return a configuration with all variables interpolated
* @since 1.5
*/
@Override
public Configuration interpolatedConfiguration()
{
final InterpolatedVisitor visitor = new InterpolatedVisitor();
final NodeHandler handler = getModel().getNodeHandler();
NodeTreeWalker.INSTANCE
.walkDFS(handler.getRootNode(), visitor, handler);
final BaseHierarchicalConfiguration c =
(BaseHierarchicalConfiguration) clone();
c.getNodeModel().setRootNode(visitor.getInterpolatedRoot());
return c;
}
/**
* {@inheritDoc} This implementation creates a new instance of
* {@link InMemoryNodeModel}, initialized with this configuration's root
* node. This has the effect that although the same nodes are used, the
* original and copied configurations are independent on each other.
*/
@Override
protected NodeModel cloneNodeModel()
{
return new InMemoryNodeModel(getModel().getNodeHandler().getRootNode());
}
/**
* Creates a list with immutable configurations from the given input list.
*
* @param subs a list with mutable configurations
* @return a list with corresponding immutable configurations
*/
private static List toImmutable(
final List extends HierarchicalConfiguration>> subs)
{
final List res =
new ArrayList<>(subs.size());
for (final HierarchicalConfiguration> sub : subs)
{
res.add(ConfigurationUtils.unmodifiableConfiguration(sub));
}
return res;
}
/**
* Creates the {@code NodeModel} for this configuration based on a passed in
* source configuration. This implementation creates an
* {@link InMemoryNodeModel}. If the passed in source configuration is
* defined, its root node also becomes the root node of this configuration.
* Otherwise, a new, empty root node is used.
*
* @param c the configuration that is to be copied
* @return the {@code NodeModel} for the new configuration
*/
private static NodeModel createNodeModel(
final HierarchicalConfiguration c)
{
final ImmutableNode root = c != null ? obtainRootNode(c) : null;
return new InMemoryNodeModel(root);
}
/**
* Obtains the root node from a configuration whose data is to be copied. It
* has to be ensured that the synchronizer is called correctly.
*
* @param c the configuration that is to be copied
* @return the root node of this configuration
*/
private static ImmutableNode obtainRootNode(
final HierarchicalConfiguration c)
{
return c.getNodeModel().getNodeHandler().getRootNode();
}
/**
* A specialized visitor base class that can be used for storing the tree of
* configuration nodes. The basic idea is that each node can be associated
* with a reference object. This reference object has a concrete meaning in
* a derived class, e.g. an entry in a JNDI context or an XML element. When
* the configuration tree is set up, the {@code load()} method is
* responsible for setting the reference objects. When the configuration
* tree is later modified, new nodes do not have a defined reference object.
* This visitor class processes all nodes and finds the ones without a
* defined reference object. For those nodes the {@code insert()}
* method is called, which must be defined in concrete sub classes. This
* method can perform all steps to integrate the new node into the original
* structure.
*/
protected abstract static class BuilderVisitor extends
ConfigurationNodeVisitorAdapter
{
@Override
public void visitBeforeChildren(final ImmutableNode node, final NodeHandler handler)
{
final ReferenceNodeHandler refHandler = (ReferenceNodeHandler) handler;
updateNode(node, refHandler);
insertNewChildNodes(node, refHandler);
}
/**
* Inserts a new node into the structure constructed by this builder.
* This method is called for each node that has been added to the
* configuration tree after the configuration has been loaded from its
* source. These new nodes have to be inserted into the original
* structure. The passed in nodes define the position of the node to be
* inserted: its parent and the siblings between to insert.
*
* @param newNode the node to be inserted
* @param parent the parent node
* @param sibling1 the sibling after which the node is to be inserted;
* can be null if the new node is going to be the first
* child node
* @param sibling2 the sibling before which the node is to be inserted;
* can be null if the new node is going to be the last
* child node
* @param refHandler the {@code ReferenceNodeHandler}
*/
protected abstract void insert(ImmutableNode newNode,
ImmutableNode parent, ImmutableNode sibling1,
ImmutableNode sibling2, ReferenceNodeHandler refHandler);
/**
* Updates a node that already existed in the original hierarchy. This
* method is called for each node that has an assigned reference object.
* A concrete implementation should update the reference according to
* the node's current value.
*
* @param node the current node to be processed
* @param reference the reference object for this node
* @param refHandler the {@code ReferenceNodeHandler}
*/
protected abstract void update(ImmutableNode node, Object reference,
ReferenceNodeHandler refHandler);
/**
* Updates the value of a node. If this node is associated with a
* reference object, the {@code update()} method is called.
*
* @param node the current node to be processed
* @param refHandler the {@code ReferenceNodeHandler}
*/
private void updateNode(final ImmutableNode node,
final ReferenceNodeHandler refHandler)
{
final Object reference = refHandler.getReference(node);
if (reference != null)
{
update(node, reference, refHandler);
}
}
/**
* Inserts new children that have been added to the specified node.
*
* @param node the current node to be processed
* @param refHandler the {@code ReferenceNodeHandler}
*/
private void insertNewChildNodes(final ImmutableNode node,
final ReferenceNodeHandler refHandler)
{
final Collection subNodes =
new LinkedList<>(refHandler.getChildren(node));
final Iterator children = subNodes.iterator();
ImmutableNode sibling1;
ImmutableNode nd = null;
while (children.hasNext())
{
// find the next new node
do
{
sibling1 = nd;
nd = children.next();
} while (refHandler.getReference(nd) != null
&& children.hasNext());
if (refHandler.getReference(nd) == null)
{
// find all following new nodes
final List newNodes =
new LinkedList<>();
newNodes.add(nd);
while (children.hasNext())
{
nd = children.next();
if (refHandler.getReference(nd) == null)
{
newNodes.add(nd);
}
else
{
break;
}
}
// Insert all new nodes
final ImmutableNode sibling2 =
refHandler.getReference(nd) == null ? null : nd;
for (final ImmutableNode insertNode : newNodes)
{
if (refHandler.getReference(insertNode) == null)
{
insert(insertNode, node, sibling1, sibling2,
refHandler);
sibling1 = insertNode;
}
}
}
}
}
}
/**
* A specialized visitor implementation which constructs the root node of a
* configuration with all variables replaced by their interpolated values.
*/
private class InterpolatedVisitor extends
ConfigurationNodeVisitorAdapter
{
/** A stack for managing node builder instances. */
private final List builderStack;
/** The resulting root node. */
private ImmutableNode interpolatedRoot;
/**
* Creates a new instance of {@code InterpolatedVisitor}.
*/
public InterpolatedVisitor()
{
builderStack = new LinkedList<>();
}
/**
* Returns the result of this builder: the root node of the interpolated
* nodes hierarchy.
*
* @return the resulting root node
*/
public ImmutableNode getInterpolatedRoot()
{
return interpolatedRoot;
}
@Override
public void visitBeforeChildren(final ImmutableNode node,
final NodeHandler handler)
{
if (isLeafNode(node, handler))
{
handleLeafNode(node, handler);
}
else
{
final ImmutableNode.Builder builder =
new ImmutableNode.Builder(handler.getChildrenCount(
node, null))
.name(handler.nodeName(node))
.value(interpolate(handler.getValue(node)))
.addAttributes(
interpolateAttributes(node, handler));
push(builder);
}
}
@Override
public void visitAfterChildren(final ImmutableNode node,
final NodeHandler handler)
{
if (!isLeafNode(node, handler))
{
final ImmutableNode newNode = pop().create();
storeInterpolatedNode(newNode);
}
}
/**
* Pushes a new builder on the stack.
*
* @param builder the builder
*/
private void push(final ImmutableNode.Builder builder)
{
builderStack.add(0, builder);
}
/**
* Pops the top-level element from the stack.
*
* @return the element popped from the stack
*/
private ImmutableNode.Builder pop()
{
return builderStack.remove(0);
}
/**
* Returns the top-level element from the stack without removing it.
*
* @return the top-level element from the stack
*/
private ImmutableNode.Builder peek()
{
return builderStack.get(0);
}
/**
* Returns a flag whether the given node is a leaf. This is the case if
* it does not have children.
*
* @param node the node in question
* @param handler the {@code NodeHandler}
* @return a flag whether this is a leaf node
*/
private boolean isLeafNode(final ImmutableNode node,
final NodeHandler handler)
{
return handler.getChildren(node).isEmpty();
}
/**
* Handles interpolation for a node with no children. If interpolation
* does not change this node, it is copied as is to the resulting
* structure. Otherwise, a new node is created with the interpolated
* values.
*
* @param node the current node to be processed
* @param handler the {@code NodeHandler}
*/
private void handleLeafNode(final ImmutableNode node,
final NodeHandler handler)
{
final Object value = interpolate(node.getValue());
final Map interpolatedAttributes =
new HashMap<>();
final boolean attributeChanged =
interpolateAttributes(node, handler, interpolatedAttributes);
final ImmutableNode newNode =
valueChanged(value, handler.getValue(node)) || attributeChanged ? new ImmutableNode.Builder()
.name(handler.nodeName(node)).value(value)
.addAttributes(interpolatedAttributes).create()
: node;
storeInterpolatedNode(newNode);
}
/**
* Stores a processed node. Per default, the node is added to the
* current builder on the stack. If no such builder exists, this is the
* result node.
*
* @param node the node to be stored
*/
private void storeInterpolatedNode(final ImmutableNode node)
{
if (builderStack.isEmpty())
{
interpolatedRoot = node;
}
else
{
peek().addChild(node);
}
}
/**
* Populates a map with interpolated attributes of the passed in node.
*
* @param node the current node to be processed
* @param handler the {@code NodeHandler}
* @param interpolatedAttributes a map for storing the results
* @return a flag whether an attribute value was changed by
* interpolation
*/
private boolean interpolateAttributes(final ImmutableNode node,
final NodeHandler handler,
final Map interpolatedAttributes)
{
boolean attributeChanged = false;
for (final String attr : handler.getAttributes(node))
{
final Object attrValue =
interpolate(handler.getAttributeValue(node, attr));
if (valueChanged(attrValue,
handler.getAttributeValue(node, attr)))
{
attributeChanged = true;
}
interpolatedAttributes.put(attr, attrValue);
}
return attributeChanged;
}
/**
* Returns a map with interpolated attributes of the passed in node.
*
* @param node the current node to be processed
* @param handler the {@code NodeHandler}
* @return the map with interpolated attributes
*/
private Map interpolateAttributes(final ImmutableNode node,
final NodeHandler handler)
{
final Map attributes = new HashMap<>();
interpolateAttributes(node, handler, attributes);
return attributes;
}
/**
* Tests whether a value is changed because of interpolation.
*
* @param interpolatedValue the interpolated value
* @param value the original value
* @return a flag whether the value was changed
*/
private boolean valueChanged(final Object interpolatedValue, final Object value)
{
return ObjectUtils.notEqual(interpolatedValue, value);
}
}
}