/* * Copyright (C) 2010, 2011 Apple Inc. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of Apple Inc. ("Apple") nor the names of * its contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY APPLE AND ITS CONTRIBUTORS "AS IS" AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL APPLE OR ITS CONTRIBUTORS BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #pragma once #include #include #include namespace WTF { // This implements a red-black tree with the following properties: // - The allocation of nodes in the tree is entirely up to the user. // - If you are in possession of a pointer to a node, you can delete // it from the tree. The tree will subsequently no longer have a // reference to this node. // - The key type must implement operator< and ==. template class RedBlackTree final { WTF_MAKE_NONCOPYABLE(RedBlackTree); WTF_MAKE_FAST_ALLOCATED; private: static constexpr unsigned s_maximumTreeDepth = 128; enum Color { Red = 1, Black }; public: class Node { friend class RedBlackTree; public: const NodeType* successor() const { const Node* x = this; if (x->right()) return treeMinimum(x->right()); const NodeType* y = x->parent(); unsigned depth = 0; while (y && x == y->right()) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); x = y; y = y->parent(); } return y; } const NodeType* predecessor() const { const Node* x = this; if (x->left()) return treeMaximum(x->left()); const NodeType* y = x->parent(); unsigned depth = 0; while (y && x == y->left()) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); x = y; y = y->parent(); } return y; } NodeType* successor() { return const_cast(const_cast(this)->successor()); } NodeType* predecessor() { return const_cast(const_cast(this)->predecessor()); } private: void reset() { m_left = nullptr; m_right = nullptr; m_parentAndRed = 1; // initialize to red } // NOTE: these methods should pack the parent and red into a single // word. But doing so appears to reveal a bug in the compiler. NodeType* parent() const { return reinterpret_cast(m_parentAndRed & ~static_cast(1)); } void setParent(NodeType* newParent) { m_parentAndRed = reinterpret_cast(newParent) | (m_parentAndRed & 1); } NodeType* left() const { return m_left; } void setLeft(NodeType* node) { m_left = node; } NodeType* right() const { return m_right; } void setRight(NodeType* node) { m_right = node; } Color color() const { if (m_parentAndRed & 1) return Red; return Black; } void setColor(Color value) { if (value == Red) m_parentAndRed |= 1; else m_parentAndRed &= ~static_cast(1); } NodeType* m_left; NodeType* m_right; uintptr_t m_parentAndRed; }; RedBlackTree() : m_root(nullptr) { } void insert(NodeType* x) { x->reset(); treeInsert(x); x->setColor(Red); unsigned depth = 0; while (x != m_root && x->parent()->color() == Red) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); if (x->parent() == x->parent()->parent()->left()) { NodeType* y = x->parent()->parent()->right(); if (y && y->color() == Red) { // Case 1 x->parent()->setColor(Black); y->setColor(Black); x->parent()->parent()->setColor(Red); x = x->parent()->parent(); } else { if (x == x->parent()->right()) { // Case 2 x = x->parent(); leftRotate(x); } // Case 3 x->parent()->setColor(Black); x->parent()->parent()->setColor(Red); rightRotate(x->parent()->parent()); } } else { // Same as "then" clause with "right" and "left" exchanged. NodeType* y = x->parent()->parent()->left(); if (y && y->color() == Red) { // Case 1 x->parent()->setColor(Black); y->setColor(Black); x->parent()->parent()->setColor(Red); x = x->parent()->parent(); } else { if (x == x->parent()->left()) { // Case 2 x = x->parent(); rightRotate(x); } // Case 3 x->parent()->setColor(Black); x->parent()->parent()->setColor(Red); leftRotate(x->parent()->parent()); } } } m_root->setColor(Black); } NodeType* remove(NodeType* z) { ASSERT(z); ASSERT(z->parent() || z == m_root); // Y is the node to be unlinked from the tree. NodeType* y; if (!z->left() || !z->right()) y = z; else y = z->successor(); // Y is guaranteed to be non-null at this point. NodeType* x; if (y->left()) x = y->left(); else x = y->right(); // X is the child of y which might potentially replace y in // the tree. X might be null at this point. NodeType* xParent; if (x) { x->setParent(y->parent()); xParent = x->parent(); } else xParent = y->parent(); if (!y->parent()) m_root = x; else { if (y == y->parent()->left()) y->parent()->setLeft(x); else y->parent()->setRight(x); } if (y != z) { if (y->color() == Black) removeFixup(x, xParent); y->setParent(z->parent()); y->setColor(z->color()); y->setLeft(z->left()); y->setRight(z->right()); if (z->left()) z->left()->setParent(y); if (z->right()) z->right()->setParent(y); if (z->parent()) { if (z->parent()->left() == z) z->parent()->setLeft(y); else z->parent()->setRight(y); } else { ASSERT(m_root == z); m_root = y; } } else if (y->color() == Black) removeFixup(x, xParent); return z; } NodeType* remove(const KeyType& key) { NodeType* result = findExact(key); if (!result) return 0; return remove(result); } NodeType* findExact(const KeyType& key) const { unsigned depth = 0; for (NodeType* current = m_root; current;) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); if (current->key() == key) return current; if (key < current->key()) current = current->left(); else current = current->right(); } return 0; } NodeType* findLeastGreaterThanOrEqual(const KeyType& key) const { NodeType* best = nullptr; unsigned depth = 0; for (NodeType* current = m_root; current;) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); if (current->key() == key) return current; if (current->key() < key) current = current->right(); else { best = current; current = current->left(); } } return best; } NodeType* findGreatestLessThanOrEqual(const KeyType& key) const { NodeType* best = nullptr; unsigned depth = 0; for (NodeType* current = m_root; current;) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); if (current->key() == key) return current; if (current->key() > key) current = current->left(); else { best = current; current = current->right(); } } return best; } template void iterate(Function function) { if (!m_root) return; Vector toIterate; unsigned size = 0; toIterate.append(m_root); while (toIterate.size()) { RELEASE_ASSERT(++size < std::numeric_limits::max()); NodeType& current = *toIterate.takeLast(); bool iterateLeft = false; bool iterateRight = false; function(current, iterateLeft, iterateRight); if (iterateLeft && current.left()) toIterate.append(current.left()); if (iterateRight && current.right()) toIterate.append(current.right()); } } NodeType* first() const { if (!m_root) return nullptr; return treeMinimum(m_root); } NodeType* last() const { if (!m_root) return 0; return treeMaximum(m_root); } // This is an O(n) operation. size_t size() { size_t result = 0; for (NodeType* current = first(); current; current = current->successor()) result++; return result; } // This is an O(1) operation. bool isEmpty() { return !m_root; } private: // Finds the minimum element in the sub-tree rooted at the given // node. static NodeType* treeMinimum(NodeType* x) { unsigned depth = 0; while (x->left()) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); x = x->left(); } return x; } static NodeType* treeMaximum(NodeType* x) { unsigned depth = 0; while (x->right()) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); x = x->right(); } return x; } static const NodeType* treeMinimum(const NodeType* x) { unsigned depth = 0; while (x->left()) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); x = x->left(); } return x; } static const NodeType* treeMaximum(const NodeType* x) { unsigned depth = 0; while (x->right()) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); x = x->right(); } return x; } void treeInsert(NodeType* z) { ASSERT(!z->left()); ASSERT(!z->right()); ASSERT(!z->parent()); ASSERT(z->color() == Red); NodeType* y = nullptr; NodeType* x = m_root; unsigned depth = 0; while (x) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); y = x; if (z->key() < x->key()) x = x->left(); else x = x->right(); } z->setParent(y); if (!y) m_root = z; else { if (z->key() < y->key()) y->setLeft(z); else y->setRight(z); } } //---------------------------------------------------------------------- // Red-Black tree operations // // Left-rotates the subtree rooted at x. // Returns the new root of the subtree (x's right child). NodeType* leftRotate(NodeType* x) { // Set y. NodeType* y = x->right(); // Turn y's left subtree into x's right subtree. x->setRight(y->left()); if (y->left()) y->left()->setParent(x); // Link x's parent to y. y->setParent(x->parent()); if (!x->parent()) m_root = y; else { if (x == x->parent()->left()) x->parent()->setLeft(y); else x->parent()->setRight(y); } // Put x on y's left. y->setLeft(x); x->setParent(y); return y; } // Right-rotates the subtree rooted at y. // Returns the new root of the subtree (y's left child). NodeType* rightRotate(NodeType* y) { // Set x. NodeType* x = y->left(); // Turn x's right subtree into y's left subtree. y->setLeft(x->right()); if (x->right()) x->right()->setParent(y); // Link y's parent to x. x->setParent(y->parent()); if (!y->parent()) m_root = x; else { if (y == y->parent()->left()) y->parent()->setLeft(x); else y->parent()->setRight(x); } // Put y on x's right. x->setRight(y); y->setParent(x); return x; } // Restores the red-black property to the tree after splicing out // a node. Note that x may be null, which is why xParent must be // supplied. void removeFixup(NodeType* x, NodeType* xParent) { unsigned depth = 0; while (x != m_root && (!x || x->color() == Black)) { RELEASE_ASSERT(++depth <= s_maximumTreeDepth); if (x == xParent->left()) { // Note: the text points out that w can not be null. // The reason is not obvious from simply looking at // the code; it comes about from the properties of the // red-black tree. NodeType* w = xParent->right(); ASSERT(w); // x's sibling should not be null. if (w->color() == Red) { // Case 1 w->setColor(Black); xParent->setColor(Red); leftRotate(xParent); w = xParent->right(); } if ((!w->left() || w->left()->color() == Black) && (!w->right() || w->right()->color() == Black)) { // Case 2 w->setColor(Red); x = xParent; xParent = x->parent(); } else { if (!w->right() || w->right()->color() == Black) { // Case 3 w->left()->setColor(Black); w->setColor(Red); rightRotate(w); w = xParent->right(); } // Case 4 w->setColor(xParent->color()); xParent->setColor(Black); if (w->right()) w->right()->setColor(Black); leftRotate(xParent); x = m_root; xParent = x->parent(); } } else { // Same as "then" clause with "right" and "left" // exchanged. // Note: the text points out that w can not be null. // The reason is not obvious from simply looking at // the code; it comes about from the properties of the // red-black tree. NodeType* w = xParent->left(); ASSERT(w); // x's sibling should not be null. if (w->color() == Red) { // Case 1 w->setColor(Black); xParent->setColor(Red); rightRotate(xParent); w = xParent->left(); } if ((!w->right() || w->right()->color() == Black) && (!w->left() || w->left()->color() == Black)) { // Case 2 w->setColor(Red); x = xParent; xParent = x->parent(); } else { if (!w->left() || w->left()->color() == Black) { // Case 3 w->right()->setColor(Black); w->setColor(Red); leftRotate(w); w = xParent->left(); } // Case 4 w->setColor(xParent->color()); xParent->setColor(Black); if (w->left()) w->left()->setColor(Black); rightRotate(xParent); x = m_root; xParent = x->parent(); } } } if (x) x->setColor(Black); } NodeType* m_root; }; }