1、序
具体实现了二叉查找树的各种操作:插入结点、构造二叉树、删除结点、查找、 查找最大值、查找最小值、查找指定结点的前驱和后继
2、二叉查找树简单介绍
它或者是一棵空树;或者是具有下列性质的二叉树: (1)若左子树不空,则左子树上全部结点的值均小于它的根结点的值。 (2)若右子树不空。则右子树上全部结点的值均大于它的根结点的值; (3)左、右子树也分别为二叉排序树
3、二叉查找树的各种操作
此处给出代码。凝视很具体。具体操作请參考代码:
#include <iostream>
using namespace std;
typedef struct Binary_Search_Tree //结点结构体
{
int data;
Binary_Search_Tree * lchild;
Binary_Search_Tree * rchild;
Binary_Search_Tree * parent;
}Binary_Search_Tree ;
void insert(Binary_Search_Tree * & root,int data) //插入
{
Binary_Search_Tree * p=new Binary_Search_Tree;
p->data=data;
p->lchild=p->rchild=p->parent=NULL;
if(root==NULL) //假设为空树。即插入结点为根结点
{
root=p;
return ;
}
//插入到当前父节点的右节点
if(root->rchild==NULL&&root->data<data)
{
root->rchild=p;
p->parent=root;
return ;
}
//插入到当前父结点的左节点
if(root->lchild==NULL&&root->data>data)
{
p->parent=root;
root->lchild=p;
return ;
}
if(root->data>data)
insert(root->lchild,data);
else if(root->data < data)
insert(root->rchild,data);
else
return;
}
void create(Binary_Search_Tree * & root,int a[],int size)
{
root=NULL;
for(int i=0;i<size;i++)
insert(root,a[i]);
}
//查找元素,找到返回keyword的结点指针,没找到则返回NULL
Binary_Search_Tree * search(Binary_Search_Tree * &root,int data)
{
if(root==NULL)
return NULL;
if(data<root->data)
return search(root->lchild,data);
else if(data>root->data)
return search(root->rchild,data);
else
return root;
}
//递归方式找到最小的元素
Binary_Search_Tree * searchmin(Binary_Search_Tree * &root)
{
if(root==NULL)
return NULL;
if(root->lchild==NULL)
return root;
else
return searchmin(root->lchild);
}
//递归方式寻找最大的元素
Binary_Search_Tree * searchmax(Binary_Search_Tree * &root)
{
if(root==NULL)
return NULL;
if(root->rchild==NULL)
return root;
else
return searchmax(root->rchild);
}
//查找某个节点的前驱
Binary_Search_Tree * seachpredecessor(Binary_Search_Tree * & p)
{
//空树
if(p=NULL)
return p;
if(p->lchild)
return searchmax(p->lchild);
//无左子树,查找某个结点的右字树遍历完了
else
{
if(p->lchild==NULL)
return NULL;
//向上寻找前驱
while(p)
{
if(p->parent->rchild==p)
break;
}
return p->parent;
}
}
//查找某个元素的后继
Binary_Search_Tree * searchsuccessor(Binary_Search_Tree * & p)
{
if(p==NULL)
return p;
if(p->rchild)
return searchmin(p->rchild);
else
{
if(p->rchild==NULL)
return NULL;
//向上寻找后继
while(p)
{
if(p->parent->lchild==p)
break;
}
return p->parent;
}
}
//依据keyword删除某个结点
//假设把根结点删掉。那么要改变根结点的地址,所以传二级指针
void deletetree(Binary_Search_Tree * & root,int data)
{
Binary_Search_Tree *q;
Binary_Search_Tree *p=search(root,data);
if(!p)
return ;
//假设没有左,右子结点,则直接删除
if(p->lchild==NULL&&p->rchild==NULL)
{
if(p->parent==NULL)
{
delete p;
root=NULL;
}
else
{
if(p==p->parent->lchild)
p->parent->lchild=NULL;
else
p->parent->rchild=NULL;
delete p;
}
}
//假设有左结点,没有右结点
if(p->lchild&&!(p->rchild))
{
p->lchild->parent=p->parent;
if(p->parent==NULL)
root=p->lchild;
else if(p==p->parent->lchild)
p->parent->lchild=p->lchild;
else
p->parent->rchild=p->lchild;
delete p;
}
//假设有右结点。没有左结点
else if(p->rchild&&!(p->lchild))
{
p->rchild->parent=p->parent;
if(p->parent==NULL)
root=p->rchild;
else if(p->parent->lchild==p)
p->parent->lchild=p->rchild;
else
p->parent->rchild=p->rchild;
delete p;
}
//假设既有左结点,又有右结点
else if(p->rchild&&p->lchild)
{
if(p->parent==NULL)
root=p->rchild;
if(p->parent->lchild==p)
p->parent->lchild=p->rchild;
else if(p->parent->rchild==p)
p->parent->rchild=p->lchild;
delete p;
}
else
{
//找到要删除点的后继
q=searchsuccessor(p);
int temp=q->data;
//删除后继节点
deletetree(root,q->data);
p->data=temp;
}
}
int main()
{
Binary_Search_Tree * root=NULL;
int a[12]={15,1,21,3,7,17,20,2,4,13,9};
create(root,a,11);
Binary_Search_Tree * x=new Binary_Search_Tree;
deletetree(root,21); //删除结点21
x=searchmin(root);
cout<<x->data;
cout<<endl;
x=searchmax(root);
cout<<x->data;
cout<<endl;
return 0;
}