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/*
 * Copyright (C) 2007-2010 Júlio Vilmar Gesser.
 * Copyright (C) 2011, 2013-2023 The JavaParser Team.
 *
 * This file is part of JavaParser.
 *
 * JavaParser can be used either under the terms of
 * a) the GNU Lesser General Public License as published by
 *     the Free Software Foundation, either version 3 of the License, or
 *     (at your option) any later version.
 * b) the terms of the Apache License
 *
 * You should have received a copy of both licenses in LICENCE.LGPL and
 * LICENCE.APACHE. Please refer to those files for details.
 *
 * JavaParser is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU Lesser General Public License for more details.
 */
package com.github.javaparser.ast;

import static com.github.javaparser.ast.Node.Parsedness.PARSED;
import static com.github.javaparser.ast.Node.TreeTraversal.PREORDER;
import static java.util.Collections.emptySet;
import static java.util.Collections.unmodifiableList;
import static java.util.Spliterator.DISTINCT;
import static java.util.Spliterator.NONNULL;

import java.util.*;
import java.util.function.Consumer;
import java.util.function.Function;
import java.util.function.Predicate;
import java.util.stream.Stream;
import java.util.stream.StreamSupport;

import com.github.javaparser.HasParentNode;
import com.github.javaparser.Position;
import com.github.javaparser.Range;
import com.github.javaparser.TokenRange;
import com.github.javaparser.ast.comments.BlockComment;
import com.github.javaparser.ast.comments.Comment;
import com.github.javaparser.ast.comments.LineComment;
import com.github.javaparser.ast.nodeTypes.NodeWithOptionalScope;
import com.github.javaparser.ast.nodeTypes.NodeWithRange;
import com.github.javaparser.ast.nodeTypes.NodeWithScope;
import com.github.javaparser.ast.nodeTypes.NodeWithTokenRange;
import com.github.javaparser.ast.observer.AstObserver;
import com.github.javaparser.ast.observer.ObservableProperty;
import com.github.javaparser.ast.observer.PropagatingAstObserver;
import com.github.javaparser.ast.visitor.CloneVisitor;
import com.github.javaparser.ast.visitor.EqualsVisitor;
import com.github.javaparser.ast.visitor.HashCodeVisitor;
import com.github.javaparser.ast.visitor.Visitable;
import com.github.javaparser.metamodel.*;
import com.github.javaparser.printer.DefaultPrettyPrinter;
import com.github.javaparser.printer.Printer;
import com.github.javaparser.printer.configuration.DefaultConfigurationOption;
import com.github.javaparser.printer.configuration.DefaultPrinterConfiguration;
import com.github.javaparser.printer.configuration.DefaultPrinterConfiguration.ConfigOption;
import com.github.javaparser.printer.configuration.PrinterConfiguration;
import com.github.javaparser.resolution.SymbolResolver;
import com.github.javaparser.utils.LineSeparator;

/**
 * Base class for all nodes of the abstract syntax tree.
 * 

Construction

*

The tree is built by instantiating the required nodes, then adding them to other nodes. * If it is the parser who is building the tree, it will use the largest constructor, * the one with "range" as the first parameter. * If you want to manually instantiate nodes, we suggest to... *

    *
  • use a convenience method, like "addStatement(...)", or if none are available...
  • *
  • use a convenient constructor, like ClassOrInterfaceType(String name), or if none are available...
  • *
  • use the default constructor.
  • *
  • Alternatively, use one of the JavaParser.parse(snippet) methods.
  • *
* ... and use the various methods on the node to initialize it further, if needed. *

Parent/child

*

The parent node field is managed automatically and can be seen as read only. * Note that there is only one parent, * and trying to use the same node in two places will lead to unexpected behaviour. * It is advised to clone() a node before moving it around. *

Comments

*

Each Node can have one associated comment which describes it and * a number of "orphan comments" which it contains but are not specifically * associated to any child. *

Positions

*

When the parser creates nodes, it sets their source code position in the "range" field. * When you manually instantiate nodes, their range is not set. * The top left character is position 1, 1. * Note that since this is an abstract syntax tree, * it leaves out a lot of text from the original source file, * like where braces or comma's are exactly. * Therefore there is no position information on everything in the original source file. *

Observers

*

It is possible to add observers to the tree. * Any change in the tree is sent as an event to any observers watching. *

Visitors

*

The most comfortable way of working with an abstract syntax tree is using visitors. * You can use one of the visitors in the visitor package, or extend one of them. * A visitor can be "run" by calling accept on a node: *

node.accept(visitor, argument);
* where argument is an object of your choice (often simply null.) * * @author Julio Vilmar Gesser */ public abstract class Node implements Cloneable, HasParentNode, Visitable, NodeWithRange, NodeWithTokenRange { /** * Different registration mode for observers on nodes. */ public enum ObserverRegistrationMode { /** * Notify exclusively for changes happening on this node alone. */ JUST_THIS_NODE, /** * Notify for changes happening on this node and all its descendants existing at the moment in * which the observer was registered. Nodes attached later will not be observed. */ THIS_NODE_AND_EXISTING_DESCENDANTS, /** * Notify for changes happening on this node and all its descendants. The descendants existing at the moment in * which the observer was registered will be observed immediately. As new nodes are attached later they are * automatically registered to be observed. */ SELF_PROPAGATING } public enum Parsedness { PARSED, UNPARSABLE } /** * This can be used to sort nodes on position. */ public static Comparator> NODE_BY_BEGIN_POSITION = (a, b) -> { if (a.hasRange() && b.hasRange()) { return a.getRange().get().begin.compareTo(b.getRange().get().begin); } if (a.hasRange() || b.hasRange()) { if (a.hasRange()) { return 1; } return -1; } return 0; }; // usefull to find if the node is a phantom node private static final int LEVELS_TO_EXPLORE = 3; protected static final PrinterConfiguration prettyPrinterNoCommentsConfiguration = new DefaultPrinterConfiguration().removeOption(new DefaultConfigurationOption(ConfigOption.PRINT_COMMENTS)); @InternalProperty private Range range; @InternalProperty private TokenRange tokenRange; @InternalProperty private Node parentNode; @InternalProperty private ArrayList childNodes = new ArrayList<>(0); @InternalProperty private ArrayList orphanComments = new ArrayList<>(0); @InternalProperty private IdentityHashMap, Object> data = null; @OptionalProperty private Comment comment; @InternalProperty private ArrayList observers = new ArrayList<>(0); @InternalProperty private Parsedness parsed = PARSED; protected Node(TokenRange tokenRange) { setTokenRange(tokenRange); } /** * Called in every constructor for node specific code. * It can't be written in the constructor itself because it will * be overwritten during code generation. */ protected void customInitialization() { } /* * If there is a printer defined in CompilationUnit, returns it * else create a new DefaultPrettyPrinter with default parameters */ protected Printer getPrinter() { return findCompilationUnit().map(c -> c.getPrinter()).orElse(createDefaultPrinter()); } /* * Return the printer initialized with the specified configuration */ protected Printer getPrinter(PrinterConfiguration configuration) { return findCompilationUnit().map(c -> c.getPrinter(configuration)).orElse(createDefaultPrinter(configuration)); } protected Printer createDefaultPrinter() { return createDefaultPrinter(getDefaultPrinterConfiguration()); } protected Printer createDefaultPrinter(PrinterConfiguration configuration) { return new DefaultPrettyPrinter(configuration); } /* * returns a default printer configuration */ protected PrinterConfiguration getDefaultPrinterConfiguration() { return new DefaultPrinterConfiguration(); } /** * This is a comment associated with this node. * * @return comment property */ @Generated("com.github.javaparser.generator.core.node.PropertyGenerator") public Optional getComment() { return Optional.ofNullable(comment); } /** * @return the range of characters in the source code that this node covers. */ @Override public Optional getRange() { return Optional.ofNullable(range); } /** * @return the range of tokens that this node covers. */ @Override public Optional getTokenRange() { return Optional.ofNullable(tokenRange); } @Override public Node setTokenRange(TokenRange tokenRange) { this.tokenRange = tokenRange; if (tokenRange == null || !(tokenRange.getBegin().hasRange() && tokenRange.getEnd().hasRange())) { range = null; } else { range = new Range(tokenRange.getBegin().getRange().get().begin, tokenRange.getEnd().getRange().get().end); } return this; } /** * @param range the range of characters in the source code that this node covers. null can be used to indicate that * no range information is known, or that it is not of interest. */ @Override public Node setRange(Range range) { if (this.range == range) { return this; } notifyPropertyChange(ObservableProperty.RANGE, this.range, range); this.range = range; return this; } /** * Use this to store additional information to this node. * * @param comment to be set */ public Node setComment(final Comment comment) { if (this.comment == comment) { return this; } notifyPropertyChange(ObservableProperty.COMMENT, this.comment, comment); if (this.comment != null) { this.comment.setCommentedNode(null); } this.comment = comment; if (comment != null) { this.comment.setCommentedNode(this); } return this; } /** * Use this to store additional information to this node. * * @param comment to be set */ public final Node setLineComment(String comment) { return setComment(new LineComment(comment)); } /** * Use this to store additional information to this node. * * @param comment to be set */ public final Node setBlockComment(String comment) { return setComment(new BlockComment(comment)); } /** * @return pretty printed source code for this node and its children. */ @Override public final String toString() { if (containsData(LINE_SEPARATOR_KEY)) { Printer printer = getPrinter(); LineSeparator lineSeparator = getLineEndingStyleOrDefault(LineSeparator.SYSTEM); PrinterConfiguration config = printer.getConfiguration(); config.addOption(new DefaultConfigurationOption(ConfigOption.END_OF_LINE_CHARACTER, lineSeparator.asRawString())); printer.setConfiguration(config); return printer.print(this); } return getPrinter().print(this); } /** * @return pretty printed source code for this node and its children. * Formatting can be configured with parameter PrinterConfiguration. */ public final String toString(PrinterConfiguration configuration) { return getPrinter(configuration).print(this); } @Override public final int hashCode() { return HashCodeVisitor.hashCode(this); } @Override public boolean equals(final Object obj) { if (!(obj instanceof Node)) { return false; } return EqualsVisitor.equals(this, (Node) obj); } @Override public Optional getParentNode() { return Optional.ofNullable(parentNode); } /** * Contains all nodes that have this node set as their parent. * You can add and remove nodes from this list by adding or removing nodes from the fields of this node. * * @return all nodes that have this node as their parent. */ public List getChildNodes() { return unmodifiableList(childNodes); } public void addOrphanComment(Comment comment) { orphanComments.add(comment); comment.setParentNode(this); } public boolean removeOrphanComment(Comment comment) { boolean removed = orphanComments.remove(comment); if (removed) { notifyPropertyChange(ObservableProperty.COMMENT, comment, null); comment.setParentNode(null); orphanComments.trimToSize(); } return removed; } /** * This is a list of Comment which are inside the node and are not associated * with any meaningful AST Node. *

* For example, comments at the end of methods (immediately before the parenthesis) * or at the end of CompilationUnit are orphan comments. *

* When more than one comment preceeds a statement, the one immediately preceding it * it is associated with the statements, while the others are orphans. *

* Changes to this list are not persisted. * * @return all comments that cannot be attributed to a concept */ public List getOrphanComments() { return unmodifiableList(orphanComments); } /** * This is the list of Comment which are contained in the Node either because * they are properly associated to one of its children or because they are floating * around inside the Node * * @return all Comments within the node as a list */ public List getAllContainedComments() { List comments = new LinkedList<>(orphanComments); for (Node child : getChildNodes()) { child.getComment().ifPresent(comments::add); comments.addAll(child.getAllContainedComments()); } return comments; } /** * Assign a new parent to this node, removing it * from the list of children of the previous parent, if any. * * @param newParentNode node to be set as parent */ @Override public Node setParentNode(Node newParentNode) { if (newParentNode == parentNode) { return this; } observers.forEach(o -> o.parentChange(this, parentNode, newParentNode)); // remove from old parent, if any if (parentNode != null) { final ArrayList parentChildNodes = parentNode.childNodes; for (int i = 0; i < parentChildNodes.size(); i++) { if (parentChildNodes.get(i) == this) { parentChildNodes.remove(i); } } parentChildNodes.trimToSize(); } parentNode = newParentNode; // add to new parent, if any if (parentNode != null) { parentNode.childNodes.add(this); } return this; } protected void setAsParentNodeOf(Node childNode) { if (childNode != null) { childNode.setParentNode(getParentNodeForChildren()); } } /** * @deprecated Use {@link Position#ABSOLUTE_BEGIN_LINE} */ @Deprecated public static final int ABSOLUTE_BEGIN_LINE = Position.ABSOLUTE_BEGIN_LINE; /** * @deprecated Use {@link Position#ABSOLUTE_END_LINE} */ @Deprecated public static final int ABSOLUTE_END_LINE = Position.ABSOLUTE_END_LINE; public void tryAddImportToParentCompilationUnit(Class clazz) { findAncestor(CompilationUnit.class).ifPresent(p -> p.addImport(clazz)); } /** * Recursively finds all nodes of a certain type. * * @param clazz the type of node to find. * @deprecated use {@link Node#findAll(Class)} but be aware that findAll also considers the initial node. */ @Deprecated public List getChildNodesByType(Class clazz) { List nodes = new ArrayList<>(); for (Node child : getChildNodes()) { if (clazz.isInstance(child)) { nodes.add(clazz.cast(child)); } nodes.addAll(child.getChildNodesByType(clazz)); } return nodes; } /** * @deprecated use {@link Node#findAll(Class)} but be aware that findAll also considers the initial node. */ @Deprecated public List getNodesByType(Class clazz) { return getChildNodesByType(clazz); } /** * Gets data for this node using the given key. * * @param The type of the data. * @param key The key for the data * @return The data. * @throws IllegalStateException if the key was not set in this node. * @see Node#containsData(DataKey) * @see DataKey */ @SuppressWarnings("unchecked") public M getData(final DataKey key) { if (data == null) { throw new IllegalStateException("No data of this type found. Use containsData to check for this first."); } M value = (M) data.get(key); if (value == null) { throw new IllegalStateException("No data of this type found. Use containsData to check for this first."); } return value; } /** * This method was added to support the clone method. * * @return all known data keys. */ public Set> getDataKeys() { if (data == null) { return emptySet(); } return data.keySet(); } /** * Sets data for this node using the given key. * For information on creating DataKey, see {@link DataKey}. * * @param The type of data * @param key The singleton key for the data * @param object The data object * @see DataKey */ public void setData(DataKey key, M object) { if (data == null) { data = new IdentityHashMap<>(); } data.put(key, object); } /** * @return does this node have data for this key? * @see DataKey */ public boolean containsData(DataKey key) { if (data == null) { return false; } return data.containsKey(key); } /** * Remove data by key. * * @see DataKey */ public void removeData(DataKey key) { if (data != null) { data.remove(key); } } /** * Try to remove this node from the parent * * @return true if removed, false if it is a required property of the parent, or if the parent isn't set. * @throws RuntimeException if it fails in an unexpected way */ public boolean remove() { if (parentNode == null) { return false; } return parentNode.remove(this); } /** * Try to replace this node in the parent with the supplied node. * * @return true if removed, or if the parent isn't set. * @throws RuntimeException if it fails in an unexpected way */ public boolean replace(Node node) { if (parentNode == null) { return false; } return parentNode.replace(this, node); } /** * Forcibly removes this node from the AST. * If it cannot be removed from the parent with remove(), * it will try to remove its parent instead, * until it finds a node that can be removed, * or no parent can be found. *

* Since everything at CompilationUnit level is removable, * this method will only (silently) fail when the node is in a detached AST fragment. */ public void removeForced() { if (!remove()) { getParentNode().ifPresent(Node::remove); } } @Override public Node getParentNodeForChildren() { return this; } protected void setAsParentNodeOf(NodeList list) { if (list != null) { list.setParentNode(getParentNodeForChildren()); } } public

void notifyPropertyChange(ObservableProperty property, P oldValue, P newValue) { this.observers.forEach(o -> o.propertyChange(this, property, oldValue, newValue)); } @Override public void unregister(AstObserver observer) { this.observers.remove(observer); this.observers.trimToSize(); } @Override public void register(AstObserver observer) { // Check if the observer is not registered yet. // In this case we use a List instead of Set to save on memory space. if (!this.observers.contains(observer)) { this.observers.add(observer); } } /** * Register a new observer for the given node. Depending on the mode specified also descendants, existing * and new, could be observed. For more details see ObserverRegistrationMode. */ public void register(AstObserver observer, ObserverRegistrationMode mode) { if (mode == null) { throw new IllegalArgumentException("Mode should be not null"); } switch(mode) { case JUST_THIS_NODE: register(observer); break; case THIS_NODE_AND_EXISTING_DESCENDANTS: registerForSubtree(observer); break; case SELF_PROPAGATING: registerForSubtree(PropagatingAstObserver.transformInPropagatingObserver(observer)); break; default: throw new UnsupportedOperationException("This mode is not supported: " + mode); } } /** * Register the observer for the current node and all the contained node and nodelists, recursively. */ public void registerForSubtree(AstObserver observer) { register(observer); this.getChildNodes().forEach(c -> c.registerForSubtree(observer)); for (PropertyMetaModel property : getMetaModel().getAllPropertyMetaModels()) { if (property.isNodeList()) { NodeList nodeList = (NodeList) property.getValue(this); if (nodeList != null) nodeList.register(observer); } } } @Override public boolean isRegistered(AstObserver observer) { return this.observers.contains(observer); } @Generated("com.github.javaparser.generator.core.node.RemoveMethodGenerator") public boolean remove(Node node) { if (node == null) { return false; } if (comment != null) { if (node == comment) { removeComment(); return true; } } return false; } @Generated("com.github.javaparser.generator.core.node.RemoveMethodGenerator") public Node removeComment() { return setComment((Comment) null); } @Override @Generated("com.github.javaparser.generator.core.node.CloneGenerator") public Node clone() { return (Node) accept(new CloneVisitor(), null); } /** * @return get JavaParser specific node introspection information. */ @Generated("com.github.javaparser.generator.core.node.GetMetaModelGenerator") public NodeMetaModel getMetaModel() { return JavaParserMetaModel.nodeMetaModel; } /** * @return whether this node was successfully parsed or not. * If it was not, only the range and tokenRange fields will be valid. */ public Parsedness getParsed() { return parsed; } /** * Used by the parser to flag unparsable nodes. */ public Node setParsed(Parsedness parsed) { this.parsed = parsed; return this; } @Generated("com.github.javaparser.generator.core.node.ReplaceMethodGenerator") public boolean replace(Node node, Node replacementNode) { if (node == null) { return false; } if (comment != null) { if (node == comment) { setComment((Comment) replacementNode); return true; } } return false; } /** * Finds the root node of this AST by finding the topmost parent. */ public Node findRootNode() { Node n = this; while (n.getParentNode().isPresent()) { n = n.getParentNode().get(); } return n; } /** * @return the containing CompilationUnit, or empty if this node is not inside a compilation unit. */ public Optional findCompilationUnit() { Node rootNode = findRootNode(); if (rootNode instanceof CompilationUnit) { return Optional.of((CompilationUnit) rootNode); } return Optional.empty(); } public LineSeparator getLineEndingStyleOrDefault(LineSeparator defaultLineSeparator) { if (getLineEndingStyle().isStandardEol()) { return getLineEndingStyle(); } return defaultLineSeparator; } public LineSeparator getLineEndingStyle() { Node current = this; // First check this node if (current.containsData(Node.LINE_SEPARATOR_KEY)) { LineSeparator lineSeparator = current.getData(Node.LINE_SEPARATOR_KEY); return lineSeparator; } // Then check parent/ancestor nodes while (current.getParentNode().isPresent()) { current = current.getParentNode().get(); if (current.containsData(Node.LINE_SEPARATOR_KEY)) { return current.getData(Node.LINE_SEPARATOR_KEY); } } // Default to the system line separator if it's not already set within the parsed node/code. return LineSeparator.SYSTEM; } public SymbolResolver getSymbolResolver() { return findCompilationUnit().map(cu -> { if (cu.containsData(SYMBOL_RESOLVER_KEY)) { return cu.getData(SYMBOL_RESOLVER_KEY); } throw new IllegalStateException("Symbol resolution not configured: to configure consider setting a SymbolResolver in the ParserConfiguration"); }).orElseThrow(() -> new IllegalStateException("The node is not inserted in a CompilationUnit")); } // We need to expose it because we will need to use it to inject the SymbolSolver public static final DataKey SYMBOL_RESOLVER_KEY = new DataKey() { }; public static final DataKey LINE_SEPARATOR_KEY = new DataKey() { }; protected static final DataKey PRINTER_KEY = new DataKey() { }; protected static final DataKey PHANTOM_KEY = new DataKey() { }; public enum TreeTraversal { PREORDER, BREADTHFIRST, POSTORDER, PARENTS, DIRECT_CHILDREN } private Iterator treeIterator(TreeTraversal traversal) { switch(traversal) { case BREADTHFIRST: return new BreadthFirstIterator(this); case POSTORDER: return new PostOrderIterator(this); case PREORDER: return new PreOrderIterator(this); case DIRECT_CHILDREN: return new DirectChildrenIterator(this); case PARENTS: return new ParentsVisitor(this); default: throw new IllegalArgumentException("Unknown traversal choice."); } } private Iterable treeIterable(TreeTraversal traversal) { return () -> treeIterator(traversal); } /** * Make a stream of nodes using traversal algorithm "traversal". */ public Stream stream(TreeTraversal traversal) { return StreamSupport.stream(Spliterators.spliteratorUnknownSize(treeIterator(traversal), NONNULL | DISTINCT), false); } /** * Make a stream of nodes using pre-order traversal. */ public Stream stream() { return StreamSupport.stream(Spliterators.spliteratorUnknownSize(treeIterator(PREORDER), NONNULL | DISTINCT), false); } /** * Walks the AST, calling the consumer for every node, with traversal algorithm "traversal". *
This is the most general walk method. All other walk and findAll methods are based on this. */ public void walk(TreeTraversal traversal, Consumer consumer) { // Could be implemented as a call to the above walk method, but this is a little more efficient. for (Node node : treeIterable(traversal)) { consumer.accept(node); } } /** * Walks the AST, calling the consumer for every node with pre-order traversal. */ public void walk(Consumer consumer) { walk(PREORDER, consumer); } /** * Walks the AST with pre-order traversal, calling the consumer for every node of type "nodeType". */ public void walk(Class nodeType, Consumer consumer) { walk(TreeTraversal.PREORDER, node -> { if (nodeType.isAssignableFrom(node.getClass())) { consumer.accept(nodeType.cast(node)); } }); } /** * Walks the AST with pre-order traversal, returning all nodes of type "nodeType". */ public List findAll(Class nodeType) { final List found = new ArrayList<>(); walk(nodeType, found::add); return found; } /** * Walks the AST with specified traversal order, returning all nodes of type "nodeType". */ public List findAll(Class nodeType, TreeTraversal traversal) { final List found = new ArrayList<>(); walk(traversal, node -> { if (nodeType.isAssignableFrom(node.getClass())) { found.add(nodeType.cast(node)); } }); return found; } /** * Walks the AST with pre-order traversal, returning all nodes of type "nodeType" that match the predicate. */ public List findAll(Class nodeType, Predicate predicate) { final List found = new ArrayList<>(); walk(nodeType, n -> { if (predicate.test(n)) found.add(n); }); return found; } /** * Walks the AST, applying the function for every node, with traversal algorithm "traversal". If the function * returns something else than null, the traversal is stopped and the function result is returned.
This is the * most general findFirst method. All other findFirst methods are based on this. */ public Optional findFirst(TreeTraversal traversal, Function> consumer) { for (Node node : treeIterable(traversal)) { final Optional result = consumer.apply(node); if (result.isPresent()) { return result; } } return Optional.empty(); } /** * Walks the AST with pre-order traversal, returning the first node of type "nodeType" or empty() if none is found. */ public Optional findFirst(Class nodeType) { return findFirst(TreeTraversal.PREORDER, node -> { if (nodeType.isAssignableFrom(node.getClass())) { return Optional.of(nodeType.cast(node)); } return Optional.empty(); }); } /** * Walks the AST with pre-order traversal, returning the first node of type "nodeType" that matches "predicate" or empty() if none is * found. */ public Optional findFirst(Class nodeType, Predicate predicate) { return findFirst(TreeTraversal.PREORDER, node -> { if (nodeType.isAssignableFrom(node.getClass())) { final N castNode = nodeType.cast(node); if (predicate.test(castNode)) { return Optional.of(castNode); } } return Optional.empty(); }); } /** * Determines whether this node is an ancestor of the given node. A node is not an ancestor of itself. * * @param descendant the node for which to determine whether it has this node as an ancestor. * @return {@code true} if this node is an ancestor of the given node, and {@code false} otherwise. * @see HasParentNode#isDescendantOf(Node) */ public boolean isAncestorOf(Node descendant) { return this != descendant && findFirst(Node.class, n -> n == descendant).isPresent(); } /** * Performs a breadth-first node traversal starting with a given node. * * @see Breadth-first traversal */ public static class BreadthFirstIterator implements Iterator { private final Queue queue = new LinkedList<>(); public BreadthFirstIterator(Node node) { queue.add(node); } @Override public boolean hasNext() { return !queue.isEmpty(); } @Override public Node next() { Node next = queue.remove(); queue.addAll(next.getChildNodes()); return next; } } /** * Performs a simple traversal over all nodes that have the passed node as their parent. */ public static class DirectChildrenIterator implements Iterator { private final Iterator childrenIterator; public DirectChildrenIterator(Node node) { childrenIterator = node.getChildNodes().iterator(); } @Override public boolean hasNext() { return childrenIterator.hasNext(); } @Override public Node next() { return childrenIterator.next(); } } /** * Iterates over the parent of the node, then the parent's parent, then the parent's parent's parent, until running * out of parents. */ public static class ParentsVisitor implements Iterator { private Node node; public ParentsVisitor(Node node) { this.node = node; } @Override public boolean hasNext() { return node.getParentNode().isPresent(); } @Override public Node next() { node = node.getParentNode().orElse(null); return node; } } /** * Performs a pre-order (or depth-first) node traversal starting with a given node. * * @see Pre-order traversal */ public static class PreOrderIterator implements Iterator { private final Stack stack = new Stack<>(); public PreOrderIterator(Node node) { stack.add(node); } @Override public boolean hasNext() { return !stack.isEmpty(); } @Override public Node next() { Node next = stack.pop(); List children = next.getChildNodes(); for (int i = children.size() - 1; i >= 0; i--) { stack.add(children.get(i)); } return next; } } /** * Performs a post-order (or leaves-first) node traversal starting with a given node. * * @see Post-order traversal */ public static class PostOrderIterator implements Iterator { private final Stack> nodesStack = new Stack<>(); private final Stack cursorStack = new Stack<>(); private final Node root; private boolean hasNext = true; public PostOrderIterator(Node root) { this.root = root; fillStackToLeaf(root); } private void fillStackToLeaf(Node node) { while (true) { List childNodes = node.getChildNodes(); if (childNodes.isEmpty()) { break; } nodesStack.push(childNodes); cursorStack.push(0); node = childNodes.get(0); } } @Override public boolean hasNext() { return hasNext; } @Override public Node next() { final List nodes = nodesStack.peek(); final int cursor = cursorStack.peek(); final boolean levelHasNext = cursor < nodes.size(); if (levelHasNext) { Node node = nodes.get(cursor); fillStackToLeaf(node); return nextFromLevel(); } nodesStack.pop(); cursorStack.pop(); hasNext = !nodesStack.empty(); if (hasNext) { return nextFromLevel(); } return root; } private Node nextFromLevel() { final List nodes = nodesStack.peek(); final int cursor = cursorStack.pop(); cursorStack.push(cursor + 1); return nodes.get(cursor); } } /* * Returns true if the node has an (optional) scope expression eg. method calls (object.method()) */ public boolean hasScope() { return (NodeWithOptionalScope.class.isAssignableFrom(this.getClass()) && ((NodeWithOptionalScope) this).getScope().isPresent()) || (NodeWithScope.class.isAssignableFrom(this.getClass()) && ((NodeWithScope) this).getScope() != null); } /* * A "phantom" node, is a node that is not really an AST node (like the fake type of variable in FieldDeclaration or an UnknownType) */ public boolean isPhantom() { return isPhantom(this); } private boolean isPhantom(Node node) { if (!node.containsData(PHANTOM_KEY)) { boolean res = (node.getParentNode().isPresent() && node.getParentNode().get().hasRange() && node.hasRange() && !node.getParentNode().get().getRange().get().contains(node.getRange().get()) || inPhantomNode(node, LEVELS_TO_EXPLORE)); node.setData(PHANTOM_KEY, res); } return node.getData(PHANTOM_KEY); } /** * A node contained in a phantom node is also a phantom node. We limit how many levels up we check just for performance reasons. */ private boolean inPhantomNode(Node node, int levels) { return node.getParentNode().isPresent() && (isPhantom(node.getParentNode().get()) || inPhantomNode(node.getParentNode().get(), levels - 1)); } }





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