Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

It's not easy to find red-black tree implementations on the net, especially for learning.

Where can I find a simple red-black tree implementation (C# preferred)?

share|improve this question
1  
Is this for a priority queue? If so, you may want to reconsider using a randomized meldable queue (google that). –  Brannon Jul 14 '12 at 21:40
add comment

2 Answers 2

up vote 4 down vote accepted

Generic red-black trees aren't "simple" by default.
But if you put a small restriction on them and make them "left-leaning", then they become simpler. Take a look at this MSDN blog post.

I've copy-pasted (with slight modifications) the code from that post here (in C#):

using System;
using System.Collections.Generic;
using System.Diagnostics;

/// <summary>Implements a left-leaning red-black tree.</summary>
/// <remarks>
/// Based on the research paper "Left-leaning Red-Black Trees"
/// by Robert Sedgewick. More information available at:
/// http://www.cs.princeton.edu/~rs/talks/LLRB/RedBlack.pdf
/// http://www.cs.princeton.edu/~rs/talks/LLRB/08Penn.pdf
/// </remarks>
/// <typeparam name="TKey">Type of keys.</typeparam>
/// <typeparam name="TValue">Type of values.</typeparam>
public class LeftLeaningRedBlackTree<TKey, TValue>
{
    /// <summary>Stores the key comparison function.</summary>
    private Comparison<TKey> _keyComparison;

    /// <summary>Stores the value comparison function.</summary>
    private Comparison<TValue> _valueComparison;

    /// <summary>Stores the root node of the tree.</summary>
    private Node _rootNode;

    /// <summary>Represents a node of the tree.</summary>
    /// <remarks>Using fields instead of properties drops execution time by about 40%.</remarks>
    [DebuggerDisplay("Key={Key}, Value={Value}, Siblings={Siblings}")]
    private class Node
    {
        /// <summary>Gets or sets the node's key.</summary>
        public TKey Key;

        /// <summary>Gets or sets the node's value.</summary>
        public TValue Value;

        /// <summary>Gets or sets the left node.</summary>
        public Node Left;

        /// <summary>Gets or sets the right node.</summary>
        public Node Right;

        /// <summary>Gets or sets the color of the node.</summary>
        public bool IsBlack;

        /// <summary>Gets or sets the number of "siblings" (nodes with the same key/value).</summary>
        public int Siblings;
    }

    /// <summary>Initializes a new instance of the LeftLeaningRedBlackTree class implementing a normal dictionary.</summary>
    /// <param name="keyComparison">The key comparison function.</param>
    public LeftLeaningRedBlackTree(Comparison<TKey> keyComparison)
    {
        if (null == keyComparison)
        {
            throw new ArgumentNullException("keyComparison");
        }
        _keyComparison = keyComparison;
    }

    /// <summary>Initializes a new instance of the LeftLeaningRedBlackTree class implementing an ordered multi-dictionary.</summary>
    /// <param name="keyComparison">The key comparison function.</param>
    /// <param name="valueComparison">The value comparison function.</param>
    public LeftLeaningRedBlackTree(Comparison<TKey> keyComparison, Comparison<TValue> valueComparison)
        : this(keyComparison)
    {
        if (null == valueComparison)
        {
            throw new ArgumentNullException("valueComparison");
        }
        _valueComparison = valueComparison;
    }

    /// <summary>Gets a value indicating whether the tree is acting as an ordered multi-dictionary.</summary>
    private bool IsMultiDictionary
    {
        get { return null != _valueComparison; }
    }

    /// <summary>Adds a key/value pair to the tree.</summary>
    /// <param name="key">Key to add.</param>
    /// <param name="value">Value to add.</param>
    public void Add(TKey key, TValue value)
    {
        _rootNode = Add(_rootNode, key, value);
        _rootNode.IsBlack = true;
        AssertInvariants();
    }

    /// <summary>Removes a key (and its associated value) from a normal (non-multi) dictionary.</summary>
    /// <param name="key">Key to remove.</param>
    /// <returns>True if key present and removed.</returns>
    public bool Remove(TKey key)
    {
        if (IsMultiDictionary)
        {
            throw new InvalidOperationException("Remove is only supported when acting as a normal (non-multi) dictionary.");
        }
        return Remove(key, default(TValue));
    }

    /// <summary>Removes a key/value pair from the tree.</summary>
    /// <param name="key">Key to remove.</param>
    /// <param name="value">Value to remove.</param>
    /// <returns>True if key/value present and removed.</returns>
    public bool Remove(TKey key, TValue value)
    {
        int initialCount = Count;
        if (null != _rootNode)
        {
            _rootNode = Remove(_rootNode, key, value);
            if (null != _rootNode)
            {
                _rootNode.IsBlack = true;
            }
        }
        AssertInvariants();
        return initialCount != Count;
    }

    /// <summary>Removes all nodes in the tree.</summary>
    public void Clear()
    {
        _rootNode = null;
        Count = 0;
        AssertInvariants();
    }

    /// <summary>Gets a sorted list of keys in the tree.</summary>
    /// <returns>Sorted list of keys.</returns>
    public IEnumerable<TKey> GetKeys()
    {
        TKey lastKey = default(TKey);
        bool lastKeyValid = false;
        return Traverse(
            _rootNode,
            n => !lastKeyValid || !object.Equals(lastKey, n.Key),
            n =>
            {
                lastKey = n.Key;
                lastKeyValid = true;
                return lastKey;
            });
    }

    /// <summary>Gets the value associated with the specified key in a normal (non-multi) dictionary.</summary>
    /// <param name="key">Specified key.</param>
    /// <returns>Value associated with the specified key.</returns>
    public TValue GetValueForKey(TKey key)
    {
        if (IsMultiDictionary)
        {
            throw new InvalidOperationException("GetValueForKey is only supported when acting as a normal (non-multi) dictionary.");
        }
        Node node = GetNodeForKey(key);
        if (null != node)
        {
            return node.Value;
        }
        else
        {
            throw new KeyNotFoundException();
        }
    }

    /// <summary>Gets a sequence of the values associated with the specified key.</summary>
    /// <param name="key">Specified key.</param>
    /// <returns>Sequence of values.</returns>
    public IEnumerable<TValue> GetValuesForKey(TKey key)
    {
        return Traverse(GetNodeForKey(key), n => 0 == _keyComparison(n.Key, key), n => n.Value);
    }

    /// <summary>Gets a sequence of all the values in the tree.</summary>
    /// <returns>Sequence of all values.</returns>
    public IEnumerable<TValue> GetValuesForAllKeys()
    {
        return Traverse(_rootNode, n => true, n => n.Value);
    }

    /// <summary>Gets the count of key/value pairs in the tree.</summary>
    public int Count { get; private set; }

    /// <summary>Gets the minimum key in the tree.</summary>
    public TKey MinimumKey
    {
        get { return GetExtreme(_rootNode, n => n.Left, n => n.Key); }
    }

    /// <summary>Gets the maximum key in the tree.</summary>
    public TKey MaximumKey
    {
        get { return GetExtreme(_rootNode, n => n.Right, n => n.Key); }
    }

    /// <summary>Returns true if the specified node is red.</summary>
    /// <param name="node">Specified node.</param>
    /// <returns>True if specified node is red.</returns>
    private static bool IsRed(Node node)
    {
        if (null == node)
        {
            // "Virtual" leaf nodes are always black
            return false;
        }
        return !node.IsBlack;
    }

    /// <summary>Adds the specified key/value pair below the specified root node.</summary>
    /// <param name="node">Specified node.</param>
    /// <param name="key">Key to add.</param>
    /// <param name="value">Value to add.</param>
    /// <returns>New root node.</returns>
    private Node Add(Node node, TKey key, TValue value)
    {
        if (null == node)
        {
            // Insert new node
            Count++;
            return new Node { Key = key, Value = value };
        }

        if (IsRed(node.Left) && IsRed(node.Right))
        {
            // Split node with two red children
            FlipColor(node);
        }

        // Find right place for new node
        int comparisonResult = KeyAndValueComparison(key, value, node.Key, node.Value);
        if (comparisonResult < 0)
        {
            node.Left = Add(node.Left, key, value);
        }
        else if (0 < comparisonResult)
        {
            node.Right = Add(node.Right, key, value);
        }
        else
        {
            if (IsMultiDictionary)
            {
                // Store the presence of a "duplicate" node
                node.Siblings++;
                Count++;
            }
            else
            {
                // Replace the value of the existing node
                node.Value = value;
            }
        }

        if (IsRed(node.Right))
        {
            // Rotate to prevent red node on right
            node = RotateLeft(node);
        }

        if (IsRed(node.Left) && IsRed(node.Left.Left))
        {
            // Rotate to prevent consecutive red nodes
            node = RotateRight(node);
        }

        return node;
    }

    /// <summary>Removes the specified key/value pair from below the specified node.</summary>
    /// <param name="node">Specified node.</param>
    /// <param name="key">Key to remove.</param>
    /// <param name="value">Value to remove.</param>
    /// <returns>True if key/value present and removed.</returns>
    private Node Remove(Node node, TKey key, TValue value)
    {
        int comparisonResult = KeyAndValueComparison(key, value, node.Key, node.Value);
        if (comparisonResult < 0)
        {
            // * Continue search if left is present
            if (null != node.Left)
            {
                if (!IsRed(node.Left) && !IsRed(node.Left.Left))
                {
                    // Move a red node over
                    node = MoveRedLeft(node);
                }

                // Remove from left
                node.Left = Remove(node.Left, key, value);
            }
        }
        else
        {
            if (IsRed(node.Left))
            {
                // Flip a 3 node or unbalance a 4 node
                node = RotateRight(node);
            }
            if ((0 == KeyAndValueComparison(key, value, node.Key, node.Value)) && (null == node.Right))
            {
                // Remove leaf node
                Debug.Assert(null == node.Left, "About to remove an extra node.");
                Count--;
                if (0 < node.Siblings)
                {
                    // Record the removal of the "duplicate" node
                    Debug.Assert(IsMultiDictionary, "Should not have siblings if tree is not a multi-dictionary.");
                    node.Siblings--;
                    return node;
                }
                else
                {
                    // Leaf node is gone
                    return null;
                }
            }
            // * Continue search if right is present
            if (null != node.Right)
            {
                if (!IsRed(node.Right) && !IsRed(node.Right.Left))
                {
                    // Move a red node over
                    node = MoveRedRight(node);
                }
                if (0 == KeyAndValueComparison(key, value, node.Key, node.Value))
                {
                    // Remove leaf node
                    Count--;
                    if (0 < node.Siblings)
                    {
                        // Record the removal of the "duplicate" node
                        Debug.Assert(IsMultiDictionary, "Should not have siblings if tree is not a multi-dictionary.");
                        node.Siblings--;
                    }
                    else
                    {
                        // Find the smallest node on the right, swap, and remove it
                        Node m = GetExtreme(node.Right, n => n.Left, n => n);
                        node.Key = m.Key;
                        node.Value = m.Value;
                        node.Siblings = m.Siblings;
                        node.Right = DeleteMinimum(node.Right);
                    }
                }
                else
                {
                    // Remove from right
                    node.Right = Remove(node.Right, key, value);
                }
            }
        }

        // Maintain invariants
        return FixUp(node);
    }

    /// <summary>Flip the colors of the specified node and its direct children.</summary>
    /// <param name="node">Specified node.</param>
    private static void FlipColor(Node node)
    {
        node.IsBlack = !node.IsBlack;
        node.Left.IsBlack = !node.Left.IsBlack;
        node.Right.IsBlack = !node.Right.IsBlack;
    }

    /// <summary>Rotate the specified node "left".</summary>
    /// <param name="node">Specified node.</param>
    /// <returns>New root node.</returns>
    private static Node RotateLeft(Node node)
    {
        Node x = node.Right;
        node.Right = x.Left;
        x.Left = node;
        x.IsBlack = node.IsBlack;
        node.IsBlack = false;
        return x;
    }

    /// <summary>Rotate the specified node "right".</summary>
    /// <param name="node">Specified node.</param>
    /// <returns>New root node.</returns>
    private static Node RotateRight(Node node)
    {
        Node x = node.Left;
        node.Left = x.Right;
        x.Right = node;
        x.IsBlack = node.IsBlack;
        node.IsBlack = false;
        return x;
    }

    /// <summary>Moves a red node from the right child to the left child.</summary>
    /// <param name="node">Parent node.</param>
    /// <returns>New root node.</returns>
    private static Node MoveRedLeft(Node node)
    {
        FlipColor(node);
        if (IsRed(node.Right.Left))
        {
            node.Right = RotateRight(node.Right);
            node = RotateLeft(node);
            FlipColor(node);

            // * Avoid creating right-leaning nodes
            if (IsRed(node.Right.Right))
            {
                node.Right = RotateLeft(node.Right);
            }
        }
        return node;
    }

    /// <summary>Moves a red node from the left child to the right child.</summary>
    /// <param name="node">Parent node.</param>
    /// <returns>New root node.</returns>
    private static Node MoveRedRight(Node node)
    {
        FlipColor(node);
        if (IsRed(node.Left.Left))
        {
            node = RotateRight(node);
            FlipColor(node);
        }
        return node;
    }

    /// <summary>Deletes the minimum node under the specified node.</summary>
    /// <param name="node">Specified node.</param>
    /// <returns>New root node.</returns>
    private Node DeleteMinimum(Node node)
    {
        if (null == node.Left)
        {
            // Nothing to do
            return null;
        }

        if (!IsRed(node.Left) && !IsRed(node.Left.Left))
        {
            // Move red node left
            node = MoveRedLeft(node);
        }

        // Recursively delete
        node.Left = DeleteMinimum(node.Left);

        // Maintain invariants
        return FixUp(node);
    }

    /// <summary>Maintains invariants by adjusting the specified nodes children.</summary>
    /// <param name="node">Specified node.</param>
    /// <returns>New root node.</returns>
    private static Node FixUp(Node node)
    {
        if (IsRed(node.Right))
        {
            // Avoid right-leaning node
            node = RotateLeft(node);
        }

        if (IsRed(node.Left) && IsRed(node.Left.Left))
        {
            // Balance 4-node
            node = RotateRight(node);
        }

        if (IsRed(node.Left) && IsRed(node.Right))
        {
            // Push red up
            FlipColor(node);
        }

        // * Avoid leaving behind right-leaning nodes
        if ((null != node.Left) && IsRed(node.Left.Right) && !IsRed(node.Left.Left))
        {
            node.Left = RotateLeft(node.Left);
            if (IsRed(node.Left))
            {
                // Balance 4-node
                node = RotateRight(node);
            }
        }

        return node;
    }

    /// <summary>Gets the (first) node corresponding to the specified key.</summary>
    /// <param name="key">Key to search for.</param>
    /// <returns>Corresponding node or null if none found.</returns>
    private Node GetNodeForKey(TKey key)
    {
        // Initialize
        Node node = _rootNode;
        while (null != node)
        {
            // Compare keys and go left/right
            int comparisonResult = _keyComparison(key, node.Key);
            if (comparisonResult < 0)
            {
                node = node.Left;
            }
            else if (0 < comparisonResult)
            {
                node = node.Right;
            }
            else
            {
                // Match; return node
                return node;
            }
        }

        // No match found
        return null;
    }

    /// <summary>Gets an extreme (ex: minimum/maximum) value.</summary>
    /// <typeparam name="T">Type of value.</typeparam>
    /// <param name="node">Node to start from.</param>
    /// <param name="successor">Successor function.</param>
    /// <param name="selector">Selector function.</param>
    /// <returns>Extreme value.</returns>
    private static T GetExtreme<T>(Node node, Func<Node, Node> successor, Func<Node, T> selector)
    {
        // Initialize
        T extreme = default(T);
        Node current = node;
        while (null != current)
        {
            // Go to extreme
            extreme = selector(current);
            current = successor(current);
        }
        return extreme;
    }

    /// <summary>Traverses a subset of the sequence of nodes in order and selects the specified nodes.</summary>
    /// <typeparam name="T">Type of elements.</typeparam>
    /// <param name="node">Starting node.</param>
    /// <param name="condition">Condition method.</param>
    /// <param name="selector">Selector method.</param>
    /// <returns>Sequence of selected nodes.</returns>
    private IEnumerable<T> Traverse<T>(Node node, Func<Node, bool> condition, Func<Node, T> selector)
    {
        // Create a stack to avoid recursion
        Stack<Node> stack = new Stack<Node>();
        Node current = node;
        while (null != current)
        {
            if (null != current.Left)
            {
                // Save current state and go left
                stack.Push(current);
                current = current.Left;
            }
            else
            {
                do
                {
                    for (int i = 0; i <= current.Siblings; i++)
                    {
                        // Select current node if relevant
                        if (condition(current))
                        {
                            yield return selector(current);
                        }
                    }
                    // Go right - or up if nothing to the right
                    current = current.Right;
                }
                while ((null == current) &&
                       (0 < stack.Count) &&
                       (null != (current = stack.Pop())));
            }
        }
    }

    /// <summary>Compares the specified keys (primary) and values (secondary).</summary>
    /// <param name="leftKey">The left key.</param>
    /// <param name="leftValue">The left value.</param>
    /// <param name="rightKey">The right key.</param>
    /// <param name="rightValue">The right value.</param>
    /// <returns>CompareTo-style results: -1 if left is less, 0 if equal, and 1 if greater than right.</returns>
    private int KeyAndValueComparison(TKey leftKey, TValue leftValue, TKey rightKey, TValue rightValue)
    {
        // Compare keys
        int comparisonResult = _keyComparison(leftKey, rightKey);
        if ((0 == comparisonResult) && (null != _valueComparison))
        {
            // Keys match; compare values
            comparisonResult = _valueComparison(leftValue, rightValue);
        }
        return comparisonResult;
    }

    /// <summary>Asserts that tree invariants are not violated.</summary>
    [Conditional("Debug")]
    private void AssertInvariants()
    {
        // Root is black
        Debug.Assert((null == _rootNode) || _rootNode.IsBlack, "Root is not black");
        // Every path contains the same number of black nodes
        Dictionary<Node, Node> parents = new Dictionary<LeftLeaningRedBlackTree<TKey, TValue>.Node, LeftLeaningRedBlackTree<TKey, TValue>.Node>();
        foreach (Node node in Traverse(_rootNode, n => true, n => n))
        {
            if (null != node.Left)
            {
                parents[node.Left] = node;
            }
            if (null != node.Right)
            {
                parents[node.Right] = node;
            }
        }
        if (null != _rootNode)
        {
            parents[_rootNode] = null;
        }
        int treeCount = -1;
        foreach (Node node in Traverse(_rootNode, n => (null == n.Left) || (null == n.Right), n => n))
        {
            int pathCount = 0;
            Node current = node;
            while (null != current)
            {
                if (current.IsBlack)
                {
                    pathCount++;
                }
                current = parents[current];
            }
            Debug.Assert((-1 == treeCount) || (pathCount == treeCount), "Not all paths have the same number of black nodes.");
            treeCount = pathCount;
        }
        // Verify node properties...
        foreach (Node node in Traverse(_rootNode, n => true, n => n))
        {
            // Left node is less
            if (null != node.Left)
            {
                Debug.Assert(0 > KeyAndValueComparison(node.Left.Key, node.Left.Value, node.Key, node.Value), "Left node is greater than its parent.");
            }
            // Right node is greater
            if (null != node.Right)
            {
                Debug.Assert(0 < KeyAndValueComparison(node.Right.Key, node.Right.Value, node.Key, node.Value), "Right node is less than its parent.");
            }
            // Both children of a red node are black
            Debug.Assert(!IsRed(node) || (!IsRed(node.Left) && !IsRed(node.Right)), "Red node has a red child.");
            // Always left-leaning
            Debug.Assert(!IsRed(node.Right) || IsRed(node.Left), "Node is not left-leaning.");
            // No consecutive reds (subset of previous rule)
            //Debug.Assert(!(IsRed(node) && IsRed(node.Left)));
        }
    }
}
share|improve this answer
4  
Yeah. Just 656 lines. Peanuts. :) –  oleksii Jul 14 '12 at 21:14
    
@oleksii: lol. :) If you take out the comments and the debugging stuff it's 430 lines... better than non-left-leaning implementations IMO. :P –  Mehrdad Jul 14 '12 at 21:29
1  
Sedgewick's paper on LLRB's is here (with Java source) and discusses algorithmic performance and complexity: cs.princeton.edu/~rs/talks/LLRB/LLRB.pdf. We didn't observe any significant difference in time or space between RB and LLRB for our application, and LLRB was sure simpler to maintain. –  Monroe Thomas Jul 14 '12 at 21:37
    
@MonroeThomas: The link was already in my post :P thanks for the comment though! –  Mehrdad Jul 14 '12 at 21:39
    
@Mehrdad Doh! ;) I need more contrast on link colors on my display for this site. Your answer is even better, then! –  Monroe Thomas Jul 14 '12 at 21:49
add comment

This?

http://www.codeproject.com/Articles/8287/Red-Black-Trees-in-C

share|improve this answer
    
+1 doesn't quite beat the simplicity of LLRB's but still nice! –  Mehrdad Jul 14 '12 at 21:40
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.