Ryujinx/Ryujinx.Common/Collections/IntrusiveRedBlackTreeImpl.cs

using System;

namespace Ryujinx.Common.Collections
{
    /// <summary>
    /// Tree that provides the ability for O(logN) lookups for keys that exist in the tree, and O(logN) lookups for keys immediately greater than or less than a specified key.
    /// </summary>
    /// <typeparam name="T">Derived node type</typeparam>
    public class IntrusiveRedBlackTreeImpl<T> where T : IntrusiveRedBlackTreeNode<T>
    {
        protected const bool Black = true;
        protected const bool Red = false;
        protected T Root = null;

        internal T RootNode => Root;

        /// <summary>
        /// Number of nodes on the tree.
        /// </summary>
        public int Count { get; protected set; }

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

        /// <summary>
        /// Finds the node whose key is immediately greater than <paramref name="node"/>.
        /// </summary>
        /// <param name="node">Node to find the successor of</param>
        /// <returns>Successor of <paramref name="node"/></returns>
        internal static T SuccessorOf(T node)
        {
            if (node.Right != null)
            {
                return Minimum(node.Right);
            }
            T parent = node.Parent;
            while (parent != null && node == parent.Right)
            {
                node = parent;
                parent = parent.Parent;
            }
            return parent;
        }

        /// <summary>
        /// Finds the node whose key is immediately less than <paramref name="node"/>.
        /// </summary>
        /// <param name="node">Node to find the predecessor of</param>
        /// <returns>Predecessor of <paramref name="node"/></returns>
        internal static T PredecessorOf(T node)
        {
            if (node.Left != null)
            {
                return Maximum(node.Left);
            }
            T parent = node.Parent;
            while (parent != null && node == parent.Left)
            {
                node = parent;
                parent = parent.Parent;
            }
            return parent;
        }

        /// <summary>
        /// Returns the node with the largest key where <paramref name="node"/> is considered the root node.
        /// </summary>
        /// <param name="node">Root node</param>
        /// <returns>Node with the maximum key in the tree of <paramref name="node"/></returns>
        protected static T Maximum(T node)
        {
            T tmp = node;
            while (tmp.Right != null)
            {
                tmp = tmp.Right;
            }

            return tmp;
        }

        /// <summary>
        /// Returns the node with the smallest key where <paramref name="node"/> is considered the root node.
        /// </summary>
        /// <param name="node">Root node</param>
        /// <returns>Node with the minimum key in the tree of <paramref name="node"/></returns>
        /// <exception cref="ArgumentNullException"><paramref name="node"/> is null</exception>
        protected static T Minimum(T node)
        {
            ArgumentNullException.ThrowIfNull(node);

            T tmp = node;
            while (tmp.Left != null)
            {
                tmp = tmp.Left;
            }

            return tmp;
        }

        protected void RestoreBalanceAfterRemoval(T balanceNode)
        {
            T ptr = balanceNode;

            while (ptr != Root && ColorOf(ptr) == Black)
            {
                if (ptr == LeftOf(ParentOf(ptr)))
                {
                    T sibling = RightOf(ParentOf(ptr));

                    if (ColorOf(sibling) == Red)
                    {
                        SetColor(sibling, Black);
                        SetColor(ParentOf(ptr), Red);
                        RotateLeft(ParentOf(ptr));
                        sibling = RightOf(ParentOf(ptr));
                    }
                    if (ColorOf(LeftOf(sibling)) == Black && ColorOf(RightOf(sibling)) == Black)
                    {
                        SetColor(sibling, Red);
                        ptr = ParentOf(ptr);
                    }
                    else
                    {
                        if (ColorOf(RightOf(sibling)) == Black)
                        {
                            SetColor(LeftOf(sibling), Black);
                            SetColor(sibling, Red);
                            RotateRight(sibling);
                            sibling = RightOf(ParentOf(ptr));
                        }
                        SetColor(sibling, ColorOf(ParentOf(ptr)));
                        SetColor(ParentOf(ptr), Black);
                        SetColor(RightOf(sibling), Black);
                        RotateLeft(ParentOf(ptr));
                        ptr = Root;
                    }
                }
                else
                {
                    T sibling = LeftOf(ParentOf(ptr));

                    if (ColorOf(sibling) == Red)
                    {
                        SetColor(sibling, Black);
                        SetColor(ParentOf(ptr), Red);
                        RotateRight(ParentOf(ptr));
                        sibling = LeftOf(ParentOf(ptr));
                    }
                    if (ColorOf(RightOf(sibling)) == Black && ColorOf(LeftOf(sibling)) == Black)
                    {
                        SetColor(sibling, Red);
                        ptr = ParentOf(ptr);
                    }
                    else
                    {
                        if (ColorOf(LeftOf(sibling)) == Black)
                        {
                            SetColor(RightOf(sibling), Black);
                            SetColor(sibling, Red);
                            RotateLeft(sibling);
                            sibling = LeftOf(ParentOf(ptr));
                        }
                        SetColor(sibling, ColorOf(ParentOf(ptr)));
                        SetColor(ParentOf(ptr), Black);
                        SetColor(LeftOf(sibling), Black);
                        RotateRight(ParentOf(ptr));
                        ptr = Root;
                    }
                }
            }
            SetColor(ptr, Black);
        }

        protected void RestoreBalanceAfterInsertion(T balanceNode)
        {
            SetColor(balanceNode, Red);
            while (balanceNode != null && balanceNode != Root && ColorOf(ParentOf(balanceNode)) == Red)
            {
                if (ParentOf(balanceNode) == LeftOf(ParentOf(ParentOf(balanceNode))))
                {
                    T sibling = RightOf(ParentOf(ParentOf(balanceNode)));

                    if (ColorOf(sibling) == Red)
                    {
                        SetColor(ParentOf(balanceNode), Black);
                        SetColor(sibling, Black);
                        SetColor(ParentOf(ParentOf(balanceNode)), Red);
                        balanceNode = ParentOf(ParentOf(balanceNode));
                    }
                    else
                    {
                        if (balanceNode == RightOf(ParentOf(balanceNode)))
                        {
                            balanceNode = ParentOf(balanceNode);
                            RotateLeft(balanceNode);
                        }
                        SetColor(ParentOf(balanceNode), Black);
                        SetColor(ParentOf(ParentOf(balanceNode)), Red);
                        RotateRight(ParentOf(ParentOf(balanceNode)));
                    }
                }
                else
                {
                    T sibling = LeftOf(ParentOf(ParentOf(balanceNode)));

                    if (ColorOf(sibling) == Red)
                    {
                        SetColor(ParentOf(balanceNode), Black);
                        SetColor(sibling, Black);
                        SetColor(ParentOf(ParentOf(balanceNode)), Red);
                        balanceNode = ParentOf(ParentOf(balanceNode));
                    }
                    else
                    {
                        if (balanceNode == LeftOf(ParentOf(balanceNode)))
                        {
                            balanceNode = ParentOf(balanceNode);
                            RotateRight(balanceNode);
                        }
                        SetColor(ParentOf(balanceNode), Black);
                        SetColor(ParentOf(ParentOf(balanceNode)), Red);
                        RotateLeft(ParentOf(ParentOf(balanceNode)));
                    }
                }
            }
            SetColor(Root, Black);
        }

        protected virtual void RotateLeft(T node)
        {
            if (node != null)
            {
                T right = RightOf(node);
                node.Right = LeftOf(right);
                if (node.Right != null)
                {
                    node.Right.Parent = node;
                }
                T nodeParent = ParentOf(node);
                right.Parent = nodeParent;
                if (nodeParent == null)
                {
                    Root = right;
                }
                else if (node == LeftOf(nodeParent))
                {
                    nodeParent.Left = right;
                }
                else
                {
                    nodeParent.Right = right;
                }
                right.Left = node;
                node.Parent = right;
            }
        }

        protected virtual void RotateRight(T node)
        {
            if (node != null)
            {
                T left = LeftOf(node);
                node.Left = RightOf(left);
                if (node.Left != null)
                {
                    node.Left.Parent = node;
                }
                T nodeParent = ParentOf(node);
                left.Parent = nodeParent;
                if (nodeParent == null)
                {
                    Root = left;
                }
                else if (node == RightOf(nodeParent))
                {
                    nodeParent.Right = left;
                }
                else
                {
                    nodeParent.Left = left;
                }
                left.Right = node;
                node.Parent = left;
            }
        }

        #region Safety-Methods

        // These methods save memory by allowing us to forego sentinel nil nodes, as well as serve as protection against NullReferenceExceptions.

        /// <summary>
        /// Returns the color of <paramref name="node"/>, or Black if it is null.
        /// </summary>
        /// <param name="node">Node</param>
        /// <returns>The boolean color of <paramref name="node"/>, or black if null</returns>
        protected static bool ColorOf(T node)
        {
            return node == null || node.Color;
        }

        /// <summary>
        /// Sets the color of <paramref name="node"/> node to <paramref name="color"/>.
        /// <br></br>
        /// This method does nothing if <paramref name="node"/> is null.
        /// </summary>
        /// <param name="node">Node to set the color of</param>
        /// <param name="color">Color (Boolean)</param>
        protected static void SetColor(T node, bool color)
        {
            if (node != null)
            {
                node.Color = color;
            }
        }

        /// <summary>
        /// This method returns the left node of <paramref name="node"/>, or null if <paramref name="node"/> is null.
        /// </summary>
        /// <param name="node">Node to retrieve the left child from</param>
        /// <returns>Left child of <paramref name="node"/></returns>
        protected static T LeftOf(T node)
        {
            return node?.Left;
        }

        /// <summary>
        /// This method returns the right node of <paramref name="node"/>, or null if <paramref name="node"/> is null.
        /// </summary>
        /// <param name="node">Node to retrieve the right child from</param>
        /// <returns>Right child of <paramref name="node"/></returns>
        protected static T RightOf(T node)
        {
            return node?.Right;
        }

        /// <summary>
        /// Returns the parent node of <paramref name="node"/>, or null if <paramref name="node"/> is null.
        /// </summary>
        /// <param name="node">Node to retrieve the parent from</param>
        /// <returns>Parent of <paramref name="node"/></returns>
        protected static T ParentOf(T node)
        {
            return node?.Parent;
        }

        #endregion
    }
}
Optimize kernel memory block lookup and consolidate RBTree implementations (#3410) * Implement intrusive red-black tree, use it for HLE kernel block manager * Implement TreeDictionary using IntrusiveRedBlackTree * Implement IntervalTree using IntrusiveRedBlackTree * Implement IntervalTree (on Ryujinx.Memory) using IntrusiveRedBlackTree * Make PredecessorOf and SuccessorOf internal, expose Predecessor and Successor properties on the node itself * Allocation free tree node lookup 2022-08-26 18:21:48 +00:00			`using System;`

			`namespace Ryujinx.Common.Collections`
			`{`
			`/// <summary>`
			`/// Tree that provides the ability for O(logN) lookups for keys that exist in the tree, and O(logN) lookups for keys immediately greater than or less than a specified key.`
			`/// </summary>`
			`/// <typeparam name="T">Derived node type</typeparam>`
			`public class IntrusiveRedBlackTreeImpl<T> where T : IntrusiveRedBlackTreeNode<T>`
			`{`
			`protected const bool Black = true;`
			`protected const bool Red = false;`
			`protected T Root = null;`

			`internal T RootNode => Root;`

			`/// <summary>`
			`/// Number of nodes on the tree.`
			`/// </summary>`
			`public int Count { get; protected set; }`

			`/// <summary>`
			`/// Removes all nodes on the tree.`
			`/// </summary>`
			`public void Clear()`
			`{`
			`Root = null;`
			`Count = 0;`
			`}`

			`/// <summary>`
			`/// Finds the node whose key is immediately greater than <paramref name="node"/>.`
			`/// </summary>`
			`/// <param name="node">Node to find the successor of</param>`
			`/// <returns>Successor of <paramref name="node"/></returns>`
			`internal static T SuccessorOf(T node)`
			`{`
			`if (node.Right != null)`
			`{`
			`return Minimum(node.Right);`
			`}`
			`T parent = node.Parent;`
			`while (parent != null && node == parent.Right)`
			`{`
			`node = parent;`
			`parent = parent.Parent;`
			`}`
			`return parent;`
			`}`

			`/// <summary>`
			`/// Finds the node whose key is immediately less than <paramref name="node"/>.`
			`/// </summary>`
			`/// <param name="node">Node to find the predecessor of</param>`
			`/// <returns>Predecessor of <paramref name="node"/></returns>`
			`internal static T PredecessorOf(T node)`
			`{`
			`if (node.Left != null)`
			`{`
			`return Maximum(node.Left);`
			`}`
			`T parent = node.Parent;`
			`while (parent != null && node == parent.Left)`
			`{`
			`node = parent;`
			`parent = parent.Parent;`
			`}`
			`return parent;`
			`}`

			`/// <summary>`
			`/// Returns the node with the largest key where <paramref name="node"/> is considered the root node.`
			`/// </summary>`
			`/// <param name="node">Root node</param>`
			`/// <returns>Node with the maximum key in the tree of <paramref name="node"/></returns>`
			`protected static T Maximum(T node)`
			`{`
			`T tmp = node;`
			`while (tmp.Right != null)`
			`{`
			`tmp = tmp.Right;`
			`}`

			`return tmp;`
			`}`

			`/// <summary>`
			`/// Returns the node with the smallest key where <paramref name="node"/> is considered the root node.`
			`/// </summary>`
			`/// <param name="node">Root node</param>`
			`/// <returns>Node with the minimum key in the tree of <paramref name="node"/></returns>`
			`/// <exception cref="ArgumentNullException"><paramref name="node"/> is null</exception>`
			`protected static T Minimum(T node)`
			`{`
Use new ArgumentNullException and ObjectDisposedException throw-helper API (#4163) 2022-12-27 19:27:11 +00:00			`ArgumentNullException.ThrowIfNull(node);`

Optimize kernel memory block lookup and consolidate RBTree implementations (#3410) * Implement intrusive red-black tree, use it for HLE kernel block manager * Implement TreeDictionary using IntrusiveRedBlackTree * Implement IntervalTree using IntrusiveRedBlackTree * Implement IntervalTree (on Ryujinx.Memory) using IntrusiveRedBlackTree * Make PredecessorOf and SuccessorOf internal, expose Predecessor and Successor properties on the node itself * Allocation free tree node lookup 2022-08-26 18:21:48 +00:00			`T tmp = node;`
			`while (tmp.Left != null)`
			`{`
			`tmp = tmp.Left;`
			`}`

			`return tmp;`
			`}`

			`protected void RestoreBalanceAfterRemoval(T balanceNode)`
			`{`
			`T ptr = balanceNode;`

			`while (ptr != Root && ColorOf(ptr) == Black)`
			`{`
			`if (ptr == LeftOf(ParentOf(ptr)))`
			`{`
			`T sibling = RightOf(ParentOf(ptr));`

			`if (ColorOf(sibling) == Red)`
			`{`
			`SetColor(sibling, Black);`
			`SetColor(ParentOf(ptr), Red);`
			`RotateLeft(ParentOf(ptr));`
			`sibling = RightOf(ParentOf(ptr));`
			`}`
			`if (ColorOf(LeftOf(sibling)) == Black && ColorOf(RightOf(sibling)) == Black)`
			`{`
			`SetColor(sibling, Red);`
			`ptr = ParentOf(ptr);`
			`}`
			`else`
			`{`
			`if (ColorOf(RightOf(sibling)) == Black)`
			`{`
			`SetColor(LeftOf(sibling), Black);`
			`SetColor(sibling, Red);`
			`RotateRight(sibling);`
			`sibling = RightOf(ParentOf(ptr));`
			`}`
			`SetColor(sibling, ColorOf(ParentOf(ptr)));`
			`SetColor(ParentOf(ptr), Black);`
			`SetColor(RightOf(sibling), Black);`
			`RotateLeft(ParentOf(ptr));`
			`ptr = Root;`
			`}`
			`}`
			`else`
			`{`
			`T sibling = LeftOf(ParentOf(ptr));`

			`if (ColorOf(sibling) == Red)`
			`{`
			`SetColor(sibling, Black);`
			`SetColor(ParentOf(ptr), Red);`
			`RotateRight(ParentOf(ptr));`
			`sibling = LeftOf(ParentOf(ptr));`
			`}`
			`if (ColorOf(RightOf(sibling)) == Black && ColorOf(LeftOf(sibling)) == Black)`
			`{`
			`SetColor(sibling, Red);`
			`ptr = ParentOf(ptr);`
			`}`
			`else`
			`{`
			`if (ColorOf(LeftOf(sibling)) == Black)`
			`{`
			`SetColor(RightOf(sibling), Black);`
			`SetColor(sibling, Red);`
			`RotateLeft(sibling);`
			`sibling = LeftOf(ParentOf(ptr));`
			`}`
			`SetColor(sibling, ColorOf(ParentOf(ptr)));`
			`SetColor(ParentOf(ptr), Black);`
			`SetColor(LeftOf(sibling), Black);`
			`RotateRight(ParentOf(ptr));`
			`ptr = Root;`
			`}`
			`}`
			`}`
			`SetColor(ptr, Black);`
			`}`

			`protected void RestoreBalanceAfterInsertion(T balanceNode)`
			`{`
			`SetColor(balanceNode, Red);`
			`while (balanceNode != null && balanceNode != Root && ColorOf(ParentOf(balanceNode)) == Red)`
			`{`
			`if (ParentOf(balanceNode) == LeftOf(ParentOf(ParentOf(balanceNode))))`
			`{`
			`T sibling = RightOf(ParentOf(ParentOf(balanceNode)));`

			`if (ColorOf(sibling) == Red)`
			`{`
			`SetColor(ParentOf(balanceNode), Black);`
			`SetColor(sibling, Black);`
			`SetColor(ParentOf(ParentOf(balanceNode)), Red);`
			`balanceNode = ParentOf(ParentOf(balanceNode));`
			`}`
			`else`
			`{`
			`if (balanceNode == RightOf(ParentOf(balanceNode)))`
			`{`
			`balanceNode = ParentOf(balanceNode);`
			`RotateLeft(balanceNode);`
			`}`
			`SetColor(ParentOf(balanceNode), Black);`
			`SetColor(ParentOf(ParentOf(balanceNode)), Red);`
			`RotateRight(ParentOf(ParentOf(balanceNode)));`
			`}`
			`}`
			`else`
			`{`
			`T sibling = LeftOf(ParentOf(ParentOf(balanceNode)));`

			`if (ColorOf(sibling) == Red)`
			`{`
			`SetColor(ParentOf(balanceNode), Black);`
			`SetColor(sibling, Black);`
			`SetColor(ParentOf(ParentOf(balanceNode)), Red);`
			`balanceNode = ParentOf(ParentOf(balanceNode));`
			`}`
			`else`
			`{`
			`if (balanceNode == LeftOf(ParentOf(balanceNode)))`
			`{`
			`balanceNode = ParentOf(balanceNode);`
			`RotateRight(balanceNode);`
			`}`
			`SetColor(ParentOf(balanceNode), Black);`
			`SetColor(ParentOf(ParentOf(balanceNode)), Red);`
			`RotateLeft(ParentOf(ParentOf(balanceNode)));`
			`}`
			`}`
			`}`
			`SetColor(Root, Black);`
			`}`

			`protected virtual void RotateLeft(T node)`
			`{`
			`if (node != null)`
			`{`
			`T right = RightOf(node);`
			`node.Right = LeftOf(right);`
			`if (node.Right != null)`
			`{`
			`node.Right.Parent = node;`
			`}`
			`T nodeParent = ParentOf(node);`
			`right.Parent = nodeParent;`
			`if (nodeParent == null)`
			`{`
			`Root = right;`
			`}`
			`else if (node == LeftOf(nodeParent))`
			`{`
			`nodeParent.Left = right;`
			`}`
			`else`
			`{`
			`nodeParent.Right = right;`
			`}`
			`right.Left = node;`
			`node.Parent = right;`
			`}`
			`}`

			`protected virtual void RotateRight(T node)`
			`{`
			`if (node != null)`
			`{`
			`T left = LeftOf(node);`
			`node.Left = RightOf(left);`
			`if (node.Left != null)`
			`{`
			`node.Left.Parent = node;`
			`}`
			`T nodeParent = ParentOf(node);`
			`left.Parent = nodeParent;`
			`if (nodeParent == null)`
			`{`
			`Root = left;`
			`}`
			`else if (node == RightOf(nodeParent))`
			`{`
			`nodeParent.Right = left;`
			`}`
			`else`
			`{`
			`nodeParent.Left = left;`
			`}`
			`left.Right = node;`
			`node.Parent = left;`
			`}`
			`}`

			`#region Safety-Methods`

			`// These methods save memory by allowing us to forego sentinel nil nodes, as well as serve as protection against NullReferenceExceptions.`

			`/// <summary>`
			`/// Returns the color of <paramref name="node"/>, or Black if it is null.`
			`/// </summary>`
			`/// <param name="node">Node</param>`
			`/// <returns>The boolean color of <paramref name="node"/>, or black if null</returns>`
			`protected static bool ColorOf(T node)`
			`{`
			`return node == null \|\| node.Color;`
			`}`

			`/// <summary>`
			`/// Sets the color of <paramref name="node"/> node to <paramref name="color"/>.`
			`/// <br></br>`
			`/// This method does nothing if <paramref name="node"/> is null.`
			`/// </summary>`
			`/// <param name="node">Node to set the color of</param>`
			`/// <param name="color">Color (Boolean)</param>`
			`protected static void SetColor(T node, bool color)`
			`{`
			`if (node != null)`
			`{`
			`node.Color = color;`
			`}`
			`}`

			`/// <summary>`
			`/// This method returns the left node of <paramref name="node"/>, or null if <paramref name="node"/> is null.`
			`/// </summary>`
			`/// <param name="node">Node to retrieve the left child from</param>`
			`/// <returns>Left child of <paramref name="node"/></returns>`
			`protected static T LeftOf(T node)`
			`{`
			`return node?.Left;`
			`}`

			`/// <summary>`
			`/// This method returns the right node of <paramref name="node"/>, or null if <paramref name="node"/> is null.`
			`/// </summary>`
			`/// <param name="node">Node to retrieve the right child from</param>`
			`/// <returns>Right child of <paramref name="node"/></returns>`
			`protected static T RightOf(T node)`
			`{`
			`return node?.Right;`
			`}`

			`/// <summary>`
			`/// Returns the parent node of <paramref name="node"/>, or null if <paramref name="node"/> is null.`
			`/// </summary>`
			`/// <param name="node">Node to retrieve the parent from</param>`
			`/// <returns>Parent of <paramref name="node"/></returns>`
			`protected static T ParentOf(T node)`
			`{`
			`return node?.Parent;`
			`}`

			`#endregion`
			`}`
			`}`