概述
AVL树的介绍
AVL树是一种自平衡的二叉搜索树,它通过单旋转(single rotate)和双旋转(double rotate)的方式实现了根节点的左子树与右子树的高度差不超过1,。这有效的降低了二叉搜索树的时间复杂度,为O(log n)。那么,下面小编将详细介绍C++实现AVL树的代码。最后一步提供可靠的代码实现
这里先粘贴代码
给大家的忠告,一定要及时去实现,不然之后再实现要花更多的时间
/* *平衡二叉树应该有些功能 *插入 删除 查找 *前序遍历 中序遍历 后序遍历 层次遍历 *统计结点数目 */ //代码已经调好,写了很久才写出来 #ifndef _AVLTREE_ #define _AVLTREE_ #include<iostream> #include<vector> #include<queue> #include<map> using namespace std; #define MAXFACTOR = 2; template<class Key , class E> class AVLNode { private: Key key; E value; AVLNode<Key,E>* left; AVLNode<Key,E>* right; AVLNode<Key,E>* parent; public: AVLNode():left(nullptr),right(nullptr),parent(nullptr){} AVLNode(Key _key,E _value , AVLNode<Key,E>* _parent = nullptr,AVLNode<Key,E>*_left = nullptr, AVLNode<Key,E>*_right = nullptr): key(_key),value(_value),left(_left),right(_right),parent(_parent){} bool isLeaf(){return left==nullptr && right == nullptr ;} //元素设置 Key getKey() const { return key;} void setKey(Key set) {key = set;} E getValue() const { return value;} void setValue(E set) {value = set;} AVLNode<Key,E>* getLeft() { return left; } void setLeft (AVLNode< Key,E >* set){ left = set;} AVLNode<Key,E>* getRight() { return right;} void setRight (AVLNode<Key,E>* set) {right = set ;} AVLNode<Key,E>* getParent() {return parent;} void setParent(AVLNode<Key,E>* set) { parent = set;} }; template<class Key , class E> class AVLTree { private: AVLNode<Key,E>* root; void clear(AVLNode<Key,E>* &r) { if(r==nullptr)return; if(r->getLeft())clear(r->getLeft()); if(r->getRight())clear(r->getRight); delete r; } void Init() { root = new AVLNode<Key,E>(); root=nullptr; } void preOrder(AVLNode<Key,E>* r,void(*visit) (AVLNode<Key,E> * node)) { if(r==nullptr)return; (*visit) (r); preOrder(r->getLeft() , visit); preOrder(r->getRight(), visit); } void inOrder(AVLNode<Key,E>* r , void(*visit)(AVLNode<Key,E>* node) ) { if(r==nullptr)return; inOrder(r->getLeft() , visit); (*visit)(r); inOrder(r->getRight(),visit); } void postOrder(AVLNode<Key,E>*r , void (*visit) (AVLNode<Key,E>* node)) { if(r==nullptr)return; postOrder(r->getLeft(),visit); postOrder(r->getRight(),visit); (*visit)(r); } void levelOrder(AVLNode<Key,E>*r , void (*visit) (AVLNode<Key,E>* node)) { queue< AVLNode<Key,E>* > q; if(r==nullptr)return; q.push(r); while( ! q.empty() ) { AVLNode<Key,E>* tmp = q.front(); q.pop(); (*visit)(tmp); if(tmp->getLeft() ) q.push(tmp->getLeft() ); if(tmp->getRight()) q.push(tmp->getRight()); } } AVLNode<Key,E>* find(AVLNode<Key,E>* r,Key k) { if(r==nullptr)return nullptr; if(k == r->getKey() ) return r; else if( k < r->getKey()) { find(r->getLeft(),k); } else { find(r->getRight(),k); } } //Find the smallest element in the avl tree AVLNode<Key,E>* getMin(AVLNode<Key,E>* r) { if(r->getLeft() == nullptr) return r; else{ getMin(r->getLeft()); } } //Remove the smallest element AVLNode<Key,E>* deleteMin(AVLNode<Key,E>* rt) { if(rt->getLeft() == nullptr) return rt->getRight(); else{ rt->setLeft(deleteMin(rt->getLeft())); return rt; } } AVLNode<Key,E>* leftRotate(AVLNode<Key,E>* node) { if( node == nullptr) return nullptr; AVLNode<Key,E>* newHead = node->getRight(); node->setRight( newHead -> getLeft() ); newHead -> setLeft( node ); return newHead; } AVLNode<Key,E>* rightRotate(AVLNode<Key,E>* node) { if(node == nullptr)return nullptr; AVLNode<Key,E>* newHead = node->getLeft(); node->setLeft( newHead->getRight() ); newHead ->setRight(node); return newHead; } int getHeight(AVLNode<Key,E>*node) { if(node == nullptr)return 0; if(node->isLeaf())return 1; else return ( getHeight( node->getLeft() ) > getHeight( node->getRight() ) ? getHeight( node->getLeft() ) : getHeight( node->getRight() ) ) + 1; } int getBalanceFactor(AVLNode<Key,E>* node) { return getHeight(node->getLeft()) - getHeight(node->getRight() ); } AVLNode<Key,E>* balance(AVLNode<Key,E>* node) { if(!node) return nullptr; else if ( getBalanceFactor( node ) == 2) { if(getBalanceFactor( node ->getLeft() ) == 1) { node = rightRotate(node); } else { node->setLeft(leftRotate( node->getLeft() ) ); node = rightRotate(node); } } else if(getBalanceFactor( node ) == -2) { if(getBalanceFactor( node->getRight()) == -1) { node = leftRotate(node); } else { node->setRight( rightRotate( node->getRight() ) ); node = leftRotate(node); } } return node; } AVLNode<Key,E>* insert( AVLNode<Key,E>* root ,const pair<Key,E>& it) { if(root == nullptr) { return new AVLNode<Key,E>(it.first , it.second,NULL,NULL,NULL); } else if (it.first < root->getKey() ) { root ->setLeft( insert(root->getLeft() , it) ) ; } else{ root ->setRight( insert(root->getRight() , it) ); } root = balance(root); return root; } AVLNode<Key,E>* remove(AVLNode<Key,E>* node , const Key k) { if(node == nullptr) return nullptr; if(node->getKey() > k) { node->setLeft( remove(node->getLeft() , k) ); node = balance(node); } else if(node->getKey() < k) { node->setRight( remove(node->getRight(), k) ); node = balance(node); } else if(node->getKey() == k) { if(! node->isLeaf() ) { AVLNode<Key,E>* tmp = getMin(node->getRight() ); node->setKey( tmp->getKey() ); node->setValue( tmp->getValue() ); node->setRight( deleteMin(node->getRight() ) ); delete tmp; } else { AVLNode<Key,E>* tmp = node; node = (node->getLeft() != nullptr) ? node->getLeft() : node->getRight() ; delete tmp; } } return node; } public: ~AVLTree(){clear(root);} AVLTree(){/*Init();*/ root = nullptr; } //四种遍历方式 void preOrder( void (*visit)(AVLNode<Key,E>* r)) { preOrder(root,visit); } void inOrder(void (*visit)(AVLNode<Key,E>* r)) { inOrder(root,visit); } void postOrder(void (*visit)(AVLNode<Key,E>* r)) { postOrder(root,visit); } void levelOrder( void(*visit)(AVLNode<Key,E>*r) ) { levelOrder(root,visit); } //插入 void insert(const pair<Key,E> &it) { root = insert(root,it); } //删除 void remove(const Key& k) { remove(root,k); } bool find(const Key&k) { return find(root,k); } }; #endif
//AVLtest.cpp #include"NewAvl.h" #include<iostream> using namespace std; template<typename Key,typename E> void traverse(AVLNode<Key,E>* root) { cout<<root->getKey()<<" "<<root->getValue()<<" "; cout<<endl; } int main() { AVLTree<int,int>* tree = new AVLTree<int ,int>; for(int i = 0 ; i < 5 ; i ++) { tree->insert(make_pair(i,i)); } tree->remove(1); cout<<"PreOrder: "<<endl; tree->preOrder(traverse); cout<<endl; cout<<"LevelOrder: "<<endl; tree->levelOrder(traverse); cout<<endl; cout<<"InOrder: "<<endl; tree->inOrder(traverse); cout<<endl; cout<<"PostOrder: "<<endl; tree->postOrder(traverse); cout<<endl; cout<<tree->find(2)<<endl; tree->insert(make_pair(9,9)); tree->levelOrder(traverse); }
运行结果
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