How do I efficiently search this hierarchical structure?

Question

I have a data structure that looks like this:

public class Node
{
     public string Code { get; set; }
     public string Description { get; set; }
     ...
     public List<Node> Children { get; set; }
}

I want to write a method that will return a specific node, given the specified Code. Normally I would just do a recursive walk through the hierarchy to find the node, but I'm concerned about performance. There will be several thousand nodes in the hierarchy, and this method will be called many, many times.

How do I structure this to make it faster? Can I use an existing data structure that perhaps performs a binary search on Code while retaining the hierarchical structure, without re-implementing some form of binary search myself?

Answer 1

Add all the nodes to dictionary with the code as key. (you can do it once), the look-up in dictionary is basically O(1).

void FillDictionary(Dictionary<string, Node> dictionary, Node node)
{
  if (dictionary.ContainsKey(node.Code))
    return;

  dictionary.Add(node.Code, node);

  foreach (Node child in node.Children)
    FillDictionary(dictionary, child)
}  

If you know the root, usage will be:

var dictionary = new Dictionary<string, Node>();
FillDictionary(dictionary, rootNode);

If you don't you can call the FillDictionary() method on all your nodes with the same dictionary.

Answer 2

Without any kind of comparison-based organization for Code, there's nothing you can do to prevent an O(n) walkthrough of the tree. However, if you build another data structure (either a Dictionary for O(1) access or List for O(log n) access) at the same time you're reading through your XML file to build the Node tree, you could build the additional structure to access quickly without much more overhead.

Answer 3

Store them in a Dictionary, this affords you O(1) lookup time.

var dict = new Dictionary<string, Node>();
dict.Add(n.Code, n);

Assuming n is a hydrated Node object. Then to get a particular node item you can do

var node = dict["CODEKEY"];

which will return your particular Node according to the provided key. You can even check the node exists using :

if (d.ContainsKey("CODEKEY"))
{
   //Do something
}

In order to know where the node was in the original collection you would need to add some sort of pointer hierarchy to your Node class so that it had knowledge of the previous node

Answer 4

Here's a full implementation of what I and others were talking about. Note that by having the index dictionary, you will use a bit more memory (only references to the nodes) in exchange for faster searches. I'm using events to dynamically update the index.

Edit: Added comments and fixed up a few things.

using System;
using System.Collections.Generic;
using System.Collections.ObjectModel;
using System.Reflection;

namespace ConsoleApplication1
{
    class Program
    {
        static void Main(string[] args)
        {
            // Create the root node for the tree
            MyNode rootNode = new MyNode { Code = "abc", Description = "abc node" };

            // Instantiate a new tree with the given root node.  string is the index key type, "Code" is the index property name
            var tree = new IndexedTree<MyNode, string>("Code", rootNode);

            // Add a child to the root node
            tree.Root.AddChild(new MyNode { Code = "def", Description = "def node" });

            MyNode newNode = new MyNode { Code = "foo", Description = "foo node" };

            // Add a child to the first child of root
            tree.Root.Children[0].AddChild(newNode);

            // Add a child to the previously added node
            newNode.AddChild(new MyNode { Code = "bar", Description = "bar node" });


            // Show the full tree
            Console.WriteLine("Root node tree:");
            PrintNodeTree(tree.Root, 0);

            Console.WriteLine();

            // Find the second level node
            MyNode foundNode = tree.FindNode("def");

            if (foundNode != null)
            {
                // Show the tree starting from the found node
                Console.WriteLine("Found node tree:");
                PrintNodeTree(foundNode, 0);
            }

            // Remove the last child
            foundNode = tree.FindNode("foo");
            TreeNodeBase nodeToRemove = foundNode.Children[0];
            foundNode.RemoveChild(nodeToRemove);

            // Add a child to this removed node.  The tree index is not updated.
            nodeToRemove.AddChild(new MyNode { Code = "blah", Description = "blah node" });

            Console.ReadLine();
        }

        static void PrintNodeTree(MyNode node, int level)
        {
            Console.WriteLine(new String(' ', level * 2) + "[" + node.Code + "] " + node.Description);

            foreach (MyNode child in node.Children)
            {
                // Recurse through each child
                PrintNodeTree(child, ++level);
            }
        }
    }

    public class NodeEventArgs : EventArgs
    {
        public TreeNodeBase Node { get; private set; }

        public bool Cancel { get; set; }

        public NodeEventArgs(TreeNodeBase node)
        {
            this.Node = node;
        }
    }

    /// <summary>
    /// The base node class that handles the hierarchy
    /// </summary>
    public abstract class TreeNodeBase
    {
        /// <summary>
        /// A read-only list of children so that you are forced to use the proper methods
        /// </summary>
        public ReadOnlyCollection<TreeNodeBase> Children
        {
            get { return new ReadOnlyCollection<TreeNodeBase>(this.children); }
        }

        private IList<TreeNodeBase> children;

        /// <summary>
        /// Default constructor
        /// </summary>
        public TreeNodeBase()
            : this(new List<TreeNodeBase>())
        {
        }

        /// <summary>
        /// Constructor that populates children
        /// </summary>
        /// <param name="children">A list of children</param>
        public TreeNodeBase(IList<TreeNodeBase> children)
        {
            if (children == null)
            {
                throw new ArgumentNullException("children");
            }

            this.children = children;
        }

        public event EventHandler<NodeEventArgs> ChildAdding;

        public event EventHandler<NodeEventArgs> ChildRemoving;

        protected virtual void OnChildAdding(NodeEventArgs e)
        {
            if (this.ChildAdding != null)
            {
                this.ChildAdding(this, e);
            }
        }

        protected virtual void OnChildRemoving(NodeEventArgs e)
        {
            if (this.ChildRemoving != null)
            {
                this.ChildRemoving(this, e);
            }
        }

        /// <summary>
        /// Adds a child node to the current node
        /// </summary>
        /// <param name="child">The child to add.</param>
        /// <returns>The child node, if it was added.  Useful for chaining methods.</returns>
        public TreeNodeBase AddChild(TreeNodeBase child)
        {
            NodeEventArgs eventArgs = new NodeEventArgs(child);
            this.OnChildAdding(eventArgs);

            if (eventArgs.Cancel)
            {
                return null;
            }

            this.children.Add(child);
            return child;
        }

        /// <summary>
        /// Removes the specified child in the current node
        /// </summary>
        /// <param name="child">The child to remove.</param>
        public void RemoveChild(TreeNodeBase child)
        {
            NodeEventArgs eventArgs = new NodeEventArgs(child);
            this.OnChildRemoving(eventArgs);

            if (eventArgs.Cancel)
            {
                return;
            }

            this.children.Remove(child);
        }
    }

    /// <summary>
    /// Your custom node with custom properties.  The base node class handles the tree structure.
    /// </summary>
    public class MyNode : TreeNodeBase
    {
        public string Code { get; set; }
        public string Description { get; set; }
    }

    /// <summary>
    /// The main tree class
    /// </summary>
    /// <typeparam name="TNode">The node type.</typeparam>
    /// <typeparam name="TIndexKey">The type of the index key.</typeparam>
    public class IndexedTree<TNode, TIndexKey> where TNode : TreeNodeBase, new()
    {
        public TNode Root { get; private set; }

        public Dictionary<TIndexKey, TreeNodeBase> Index { get; private set; }

        public string IndexProperty { get; private set; }

        public IndexedTree(string indexProperty, TNode rootNode)
        {
            // Make sure we have a valid indexProperty
            if (String.IsNullOrEmpty(indexProperty))
            {
                throw new ArgumentNullException("indexProperty");
            }

            Type nodeType = rootNode.GetType();
            PropertyInfo property = nodeType.GetProperty(indexProperty);

            if (property == null)
            {
                throw new ArgumentException("The [" + indexProperty + "] property does not exist in [" + nodeType.FullName + "].", "indexProperty");
            }

            // Make sure we have a valid root node
            if (rootNode == null)
            {
                throw new ArgumentNullException("rootNode");
            }

            // Set the index properties
            this.IndexProperty = indexProperty;
            this.Index = new Dictionary<TIndexKey, TreeNodeBase>();

            // Add the root node
            this.Root = rootNode;

            // Notify that we have added the root node
            this.ChildAdding(this, new NodeEventArgs(Root));
        }

        /// <summary>
        /// Find a node with the specified key value
        /// </summary>
        /// <param name="key">The node key value</param>
        /// <returns>A TNode if found, otherwise null</returns>
        public TNode FindNode(TIndexKey key)
        {
            if (Index.ContainsKey(key))
            {
                return (TNode)Index[key];
            }

            return null;
        }

        private void ChildAdding(object sender, NodeEventArgs e)
        {
            if (e.Node.Children.Count > 0)
            {
                throw new InvalidOperationException("You can only add nodes that don't have children");
                // Alternatively, you could recursively get the children, set up the added/removed events and add to the index
            }

            // Add to the index.  Add events as soon as possible to be notified when children change.
            e.Node.ChildAdding += new EventHandler<NodeEventArgs>(ChildAdding);
            e.Node.ChildRemoving += new EventHandler<NodeEventArgs>(ChildRemoving);
            Index.Add(this.GetNodeIndex(e.Node), e.Node);
        }

        private void ChildRemoving(object sender, NodeEventArgs e)
        {
            if (e.Node.Children.Count > 0)
            {
                throw new InvalidOperationException("You can only remove leaf nodes that don't have children");
                // Alternatively, you could recursively get the children, remove the events and remove from the index
            }

            // Remove from the index.  Remove events in case user code keeps reference to this node and later adds/removes children
            e.Node.ChildAdding -= new EventHandler<NodeEventArgs>(ChildAdding);
            e.Node.ChildRemoving -= new EventHandler<NodeEventArgs>(ChildRemoving);
            Index.Remove(this.GetNodeIndex(e.Node));
        }

        /// <summary>
        /// Gets the index key value for the given node
        /// </summary>
        /// <param name="node">The node</param>
        /// <returns>The index key value</returns>
        private TIndexKey GetNodeIndex(TreeNodeBase node)
        {
            TIndexKey key = (TIndexKey)node.GetType().GetProperty(this.IndexProperty).GetValue(node, null);
            if (key == null)
            {
                throw new ArgumentNullException("The node index property [" + this.IndexProperty + "] cannot be null", this.IndexProperty);
            }

            return key;
        }
    }
}

Answer 5

If you can change the order of the nodes, you can make a Binary Search Tree.

Answer 6

This SO answer references a library that you should be able to use?

Answer 7

Why not use SortedSet<Node> to build a BST containing all your Node instances? Comparator would be based on Code - container would have to be scoped such that this is unique across all members.

Answer 8

I'll be honest; I'm having great difficulty understanding how Itay's suggestion doesn't make perfect sense.

Here is the requirement that you've stated:

I want to write a method that will return a specific node, given the specified Code.

So the Code is unique, I take it? Then there's nothing stopping you from putting all of your Node objects into a Dictionary<string, Node>.

In your comments to Itay's answer you say this:

I get that the dictionary is a flat index, I just don't understand yet how that index is going to reach into my hierarchical data structure and retrieve the correct node.

If you mean you don't understand how the dictionary is going to know where your Node is in the data structure, that's because it isn't. Does this matter? You haven't stated in your requirements that you want to know where the node is in the data structure; you only specified that you want to get the node. In order to do this, the dictionary only needs to know where the node is in memory, not in some completely separate data structure.

To provide a simplified example (and I apologize if I'm insulting your intelligence here, but bear with me as this may at least clarify the point for someone else), suppose you had a plain LinkedList<int> containing all unique integers. You then enumerate over this list and use it to construct a Dictionary<int, LinkedListNode<int>>, the idea being that you want to be able to quickly find a node based on its value.

Does the dictionary need to know where in the linked list each node is? Certainly not—only where it is in memory. Once you've found your node based on its value in O(1) using the dictionary, you can of course easily traverse the linked list forwards or backwards using the node itself, which happens to be aware (by design) of the linked list containing it.

It's the same with your hierarchical structure, only a bit more complex than a linked list. But the same principle applies.