#ifndef RED_BLACK_TREE_H #define RED_BLACK_TREE_H #include "dsexceptions.h" #include // For NULL using namespace std; // Red-black tree class // // CONSTRUCTION: with negative infinity object also // used to signal failed finds // // ******************PUBLIC OPERATIONS********************* // void insert( x ) --> Insert x // void remove( x ) --> Remove x (unimplemented) // bool contains( x ) --> Return true if x is present // Comparable findMin( ) --> Return smallest item // Comparable findMax( ) --> Return largest item // bool isEmpty( ) --> Return true if empty; else false // void makeEmpty( ) --> Remove all items // void printTree( ) --> Print tree in sorted order // ******************ERRORS******************************** // Throws UnderflowException as warranted template class RedBlackTree { public: /** * Construct the tree. * negInf is a value less than or equal to all others. */ explicit RedBlackTree( const Comparable & negInf ) { nullNode = new RedBlackNode; nullNode->left = nullNode->right = nullNode; header = new RedBlackNode( negInf ); header->left = header->right = nullNode; } RedBlackTree( const RedBlackTree & rhs ) { nullNode = new RedBlackNode; nullNode->left = nullNode->right = nullNode; header = new RedBlackNode( rhs.header->element ); header->left = header->right = nullNode; *this = rhs; } ~RedBlackTree( ) { makeEmpty( ); delete nullNode; delete header; } const Comparable & findMin( ) const { if( isEmpty( ) ) throw UnderflowException( ); RedBlackNode *itr = header->right; while( itr->left != nullNode ) itr = itr->left; return itr->element; } const Comparable & findMax( ) const { if( isEmpty( ) ) throw UnderflowException( ); RedBlackNode *itr = header->right; while( itr->right != nullNode ) itr = itr->right; return itr->element; } bool contains( const Comparable & x ) const { nullNode->element = x; RedBlackNode *curr = header->right; for( ; ; ) { if( x < curr->element ) curr = curr->left; else if( curr->element < x ) curr = curr->right; else return curr != nullNode; } } bool isEmpty( ) const { return header->right == nullNode; } void printTree( ) const { if( header->right == nullNode ) cout << "Empty tree" << endl; else printTree( header->right ); } void makeEmpty( ) { reclaimMemory( header->right ); header->right = nullNode; } /** * Insert item x into the tree. Does nothing if x already prsent. */ void insert( const Comparable & x ) { current = parent = grand = header; nullNode->element = x; while( current->element != x ) { great = grand; grand = parent; parent = current; current = x < current->element ? current->left : current->right; // Check if two red children; fix if so if( current->left->color == RED && current->right->color == RED ) handleReorient( x ); } // Insertion fails if already present if( current != nullNode ) return; current = new RedBlackNode( x, nullNode, nullNode ); // Attach to parent if( x < parent->element ) parent->left = current; else parent->right = current; handleReorient( x ); } void remove( const Comparable & x ) { cout << "Sorry, remove unimplemented; " << x << " still present" << endl; } enum { RED, BLACK }; const RedBlackTree & operator=( const RedBlackTree & rhs ) { if( this != &rhs ) { makeEmpty( ); header->right = clone( rhs.header->right ); } return *this; } private: struct RedBlackNode { Comparable element; RedBlackNode *left; RedBlackNode *right; int color; RedBlackNode( const Comparable & theElement = Comparable( ), RedBlackNode *lt = NULL, RedBlackNode *rt = NULL, int c = BLACK ) : element( theElement ), left( lt ), right( rt ), color( c ) { } }; RedBlackNode *header; // The tree header (contains negInf) RedBlackNode *nullNode; // Used in insert routine and its helpers (logically static) RedBlackNode *current; RedBlackNode *parent; RedBlackNode *grand; RedBlackNode *great; // Usual recursive stuff void reclaimMemory( RedBlackNode *t ) { if( t != t->left ) { reclaimMemory( t->left ); reclaimMemory( t->right ); delete t; } } void printTree( RedBlackNode *t ) const { if( t != t->left ) { printTree( t->left ); cout << t->element << endl; printTree( t->right ); } } RedBlackNode * clone( RedBlackNode * t ) const { if( t == t->left ) // Cannot test against nullNode!!! return nullNode; else return new RedBlackNode( t->element, clone( t->left ), clone( t->right ), t->color ); } // Red-black tree manipulations /** * Internal routine that is called during an insertion if a node has two red * children. Performs flip and rotatons. item is the item being inserted. */ void handleReorient( const Comparable & item ) { // Do the color flip current->color = RED; current->left->color = BLACK; current->right->color = BLACK; if( parent->color == RED ) // Have to rotate { grand->color = RED; if( item < grand->element != item < parent->element ) parent = rotate( item, grand ); // Start dbl rotate current = rotate( item, great ); current->color = BLACK; } header->right->color = BLACK; // Make root black } /** * Internal routine that performs a single or double rotation. * Because the result is attached to the parent, there are four cases. * Called by handleReorient. * item is the item in handleReorient. * theParent is the parent of the root of the rotated subtree. * Return the root of the rotated subtree. */ RedBlackNode * rotate( const Comparable & item, RedBlackNode *theParent ) { if( item < theParent->element ) { item < theParent->left->element ? rotateWithLeftChild( theParent->left ) : // LL rotateWithRightChild( theParent->left ) ; // LR return theParent->left; } else { item < theParent->right->element ? rotateWithLeftChild( theParent->right ) : // RL rotateWithRightChild( theParent->right ); // RR return theParent->right; } } void rotateWithLeftChild( RedBlackNode * & k2 ) { RedBlackNode *k1 = k2->left; k2->left = k1->right; k1->right = k2; k2 = k1; } void rotateWithRightChild( RedBlackNode * & k1 ) { RedBlackNode *k2 = k1->right; k1->right = k2->left; k2->left = k1; k1 = k2; } }; #endif