Github Repo:https://github.com/sinkinben/DataStructure.git
图解可以看这篇文章:https://www.cnblogs.com/skywang12345/p/3576969.html
二叉搜索树 BST 在插入序列为升序序列时,退化为单向链表,增删改查的复杂度变为 (O(n)) ,因此对其改进,提出二叉平衡树。
二叉平衡树,简称 AVL (以三位提出者的首字母连接起来作为命名),在二叉搜索树的基础上,加入以下约束条件:每个节点的左右子树高度之差小于 2 。
例如,这些子树都是不平衡的:
1 a
/
2 b
/
3 c
再例如:
x1
/
x2 x3
/
x4 x5
/
x6
因此,在 AVL 的插入/删除过程中,需要对某个局部的子树进行「旋转」,以保持 AVL 本身平衡的性质。因此,AVL 的查询时间复杂度始终为 (O(lgn)) ,不会像 BST 那样退化为 (O(n)) 。
但是,由于 AVL 的插入/删除带来了额外的时间与空间开销(本文均采用递归实现),而 BST 始终为 (O(lgn)),因此,在频繁插入/删除元素的场景下,AVL 是不适宜的。为了克服 AVL 这种弊端,同时保留其查询的优势,后来又有人提出了 红黑树 。
本文实现的 API :
- draw:在终端输出 AVL 的结构。
- insert:插入节点。
- remove:删除节点。
- leftRotate:左旋处理。
- rightRotate:右旋处理。
- leftBalance:左子树超高时,左平衡处理。
- rightBalance:右子树超高时,右平衡处理。
代码实现
RTFSC.
#include "BinaryTree.hpp"
#include <cassert>
#include <iostream>
#ifndef AVLTREE_H
#define AVLTREE_H
template <typename T>
class AVLTree : public BinaryTree<T>
{
private:
void selfCheck()
{
auto v = this->inorder();
int len = v.size();
for (int i = 1; i < len; i++)
assert(v[i] > v[i - 1]);
}
public:
void rightRotate(TreeNode<T> *p)
{
if (p == nullptr)
return;
auto lc = p->left;
assert(lc != nullptr);
p->left = lc->right;
if (p->left)
p->left->parent = p;
if (p->parent == nullptr)
this->root = lc;
else if (p->parent->left == p)
p->parent->left = lc;
else
p->parent->right = lc;
lc->parent = p->parent;
lc->right = p, p->parent = lc;
// p = lc;
}
void leftRotate(TreeNode<T> *p)
{
// std::cout << "00";
if (p == nullptr)
return;
auto rc = p->right;
assert(rc != nullptr);
p->right = rc->left;
if (p->right)
p->right->parent = p;
if (p->parent == nullptr)
this->root = rc;
else if (p->parent->left == p)
p->parent->left = rc;
else
{
// std::cout << "11";
p->parent->right = rc;
}
rc->parent = p->parent;
rc->left = p, p->parent = rc;
// p = rc;
}
bool insert(int val)
{
bool taller;
return insert(this->root, val, taller, nullptr);
// std::cout << "111";
}
bool insert(TreeNode<T> *&subtree, T val, bool &taller, TreeNode<T> *parent)
{
if (subtree == nullptr)
{
subtree = new TreeNode<T>(val, AVLFactor::EH, parent);
taller = true;
}
else if (val == subtree->val)
{
taller = false;
return false;
}
else if (val < subtree->val)
{
if (!insert(subtree->left, val, taller, subtree))
return false;
if (taller)
{
switch (subtree->factor)
{
case AVLFactor::LH:
leftBalance(subtree);
taller = false;
break;
case AVLFactor::EH:
subtree->factor = AVLFactor::LH;
taller = true;
break;
case AVLFactor::RH:
subtree->factor = AVLFactor::EH;
taller = false;
break;
default:
assert(0);
break;
}
}
}
else if (val > subtree->val)
{
if (!insert(subtree->right, val, taller, subtree))
return false;
if (taller)
{
switch (subtree->factor)
{
case AVLFactor::LH:
subtree->factor = AVLFactor::EH;
taller = false;
break;
case AVLFactor::EH:
subtree->factor = AVLFactor::RH;
taller = true;
break;
case AVLFactor::RH:
rightBalance(subtree);
taller = false;
break;
default:
break;
}
}
}
else
{
assert(0);
}
return true;
}
TreeNode<T> *search(T val)
{
auto p = this->root;
while (p != nullptr && p->val != val)
{
if (val < p->val)
p = p->left;
else
p = p->right;
}
return p;
}
bool remove(T val)
{
bool shorter = false;
return remove(this->root, val, shorter);
}
bool remove(TreeNode<T> *&subtree, T val, bool &shorter)
{
// val is not in AVL
if (subtree == nullptr)
{
return false;
}
else if (subtree->val == val)
{
auto p = subtree;
bool hasLeft = p->left != nullptr;
bool hasRight = p->right != nullptr;
if (!hasLeft && hasRight)
{
subtree->right->parent = subtree->parent;
subtree = subtree->right;
delete p;
shorter = true;
return true;
}
if (hasLeft && !hasRight)
{
subtree->left->parent = subtree->parent;
subtree = subtree->left;
delete p;
shorter = true;
return true;
}
if (!hasLeft && !hasRight)
{
if (p == this->root)
{
delete this->root;
this->root = nullptr;
return true;
}
if (p == p->parent->left)
p->parent->left = nullptr;
else
p->parent->right = nullptr;
delete p;
shorter = true;
return true;
}
if (hasLeft && hasRight)
{
// 把前驱的值搬上来,然后递归删除这个前驱
auto lmax = maxval(p->left);
subtree->val = lmax->val;
if (remove(subtree->left, lmax->val, shorter))
{
if (shorter)
{
switch (subtree->factor)
{
case AVLFactor::LH:
subtree->factor = AVLFactor::EH;
shorter = true;
break;
case AVLFactor::EH:
subtree->factor = AVLFactor::RH;
shorter = false;
break;
case AVLFactor::RH:
shorter = (subtree->right->factor == AVLFactor::EH) ? false : true;
rightBalance(subtree);
break;
default:
assert(0);
break;
}
}
return true;
}
}
return false;
}
else if (val < subtree->val)
{
if (!remove(subtree->left, val, shorter))
return false;
if (shorter)
{
switch (subtree->factor)
{
case AVLFactor::LH:
subtree->factor = AVLFactor::EH;
shorter = true;
break;
case AVLFactor::EH:
subtree->factor = AVLFactor::RH;
shorter = false;
break;
case AVLFactor::RH:
shorter = (subtree->right->factor == AVLFactor::EH) ? false : true;
rightBalance(subtree);
break;
default:
assert(0);
break;
}
}
return true;
}
else if (val > subtree->val)
{
if (!remove(subtree->right, val, shorter))
return false;
if (shorter)
{
switch (subtree->factor)
{
case AVLFactor::LH:
shorter = (subtree->left->factor == AVLFactor::EH) ? (false) : (true);
leftBalance(subtree);
break;
case AVLFactor::EH:
subtree->factor = AVLFactor::LH;
shorter = false;
break;
case AVLFactor::RH:
subtree->factor = AVLFactor::EH;
shorter = true;
break;
default:
assert(0);
}
}
return true;
}
return false;
}
TreeNode<T> *maxval(TreeNode<T> *subtree)
{
if (subtree == nullptr)
return nullptr;
auto p = subtree;
while (p->right != nullptr)
p = p->right;
return p;
}
TreeNode<T> *maxval() { return maxval(this->root); }
void leftBalance(TreeNode<T> *p)
{
// lc means left child
// lcr means leftChild->right
TreeNode<T> *l = p->left, *lr = nullptr;
switch (l->factor)
{
case AVLFactor::LH:
p->factor = AVLFactor::EH;
l->factor = AVLFactor::EH;
rightRotate(p);
break;
case AVLFactor::RH:
// here lcr must be not nullptr
lr = l->right;
switch (lr->factor)
{
case AVLFactor::LH:
l->factor = AVLFactor::EH;
lr->factor = AVLFactor::EH;
p->factor = AVLFactor::RH;
break;
case AVLFactor::EH:
l->factor = AVLFactor::EH;
lr->factor = AVLFactor::EH;
p->factor = AVLFactor::EH;
break;
case AVLFactor::RH:
l->factor = AVLFactor::LH;
lr->factor = AVLFactor::EH;
p->factor = AVLFactor::EH;
break;
default:
break;
}
leftRotate(p->left);
rightRotate(p);
break;
// only used in remove operation
case AVLFactor::EH:
p->factor = AVLFactor::LH;
p->left->factor = AVLFactor::RH;
rightRotate(p);
break;
default:
break;
}
}
void rightBalance(TreeNode<T> *p)
{
TreeNode<T> *r, *rl;
r = p->right;
switch (r->factor)
{
case AVLFactor::RH:
r->factor = p->factor = AVLFactor::EH;
leftRotate(p);
break;
case AVLFactor::LH:
rl = r->left;
switch (rl->factor)
{
case AVLFactor::LH:
p->factor = AVLFactor::EH;
r->factor = AVLFactor::RH;
break;
case AVLFactor::EH:
p->factor = r->factor = AVLFactor::EH;
break;
case AVLFactor::RH:
p->factor = AVLFactor::EH;
r->factor = AVLFactor::LH;
break;
default:
break;
}
rl->factor = AVLFactor::EH;
rightRotate(p->right);
leftRotate(p);
break;
// only used in remove operation
case AVLFactor::EH:
p->factor = AVLFactor::RH;
p->right->factor = AVLFactor::LH;
leftRotate(p);
break;
default:
break;
}
}
};
#endif