PS:所有的代码示例使用的都是这个图
2019-10-29
利用p126的算法5.3建立二叉树,并完成三种遍历算法 中序 后序 先序
#include<iostream>
#include<stack>
#define TElemType char
using namespace std;
typedef struct BiTNode
{
TElemType data;
struct BiTNode *lchild,*rchild;
}BiTNode,*BiTree;
//先序遍历的顺序建立二叉链表
void xCreateBiTree(BiTree &T)
{
char ch;
cin>>ch;
if(ch=='#') T=NULL;
else
{
T=new BiTNode;
T->data=ch;
xCreateBiTree(T->lchild);
xCreateBiTree(T->rchild);
}
}
//先序遍历输出
void xPrintTree(BiTree T)
{
if(T)
{
cout<<T->data;
xPrintTree(T->lchild);
xPrintTree(T->rchild);
}
else
{
return;
}
}
//中序遍历的顺序建立二叉链表
void zCreateBiTree(BiTree &T)
{
char ch;
cin>>ch;
if(ch=='#') T=NULL;
else
{
T=new BiTNode;
zCreateBiTree(T->lchild);
T->data=ch;
zCreateBiTree(T->rchild);
}
}
//中序遍历输出
void zPrintTree(BiTree T)
{
if(T)
{
zPrintTree(T->lchild);
cout<<T->data;
zPrintTree(T->rchild);
}
else
{
return;
}
}
//后序遍历的顺序建立二叉链表
void hCreateBiTree(BiTree &T)
{
char ch;
cin>>ch;
if(ch=='#') T=NULL;
else
{
T=new BiTNode;
hCreateBiTree(T->lchild);
hCreateBiTree(T->rchild);
T->data=ch;
}
}
//后序遍历输出
void hPrintTree(BiTree T)
{
if(T)
{
hPrintTree(T->lchild);
hPrintTree(T->rchild);
cout<<T->data;
}
else
{
return;
}
}
int main()
{
BiTree root;
// xCreateBiTree(root);
// xPrintTree(root);
/*
输入:ABC##DE#G##F###
输出:ABCDEGF
*/
// zCreateBiTree(root);
// zPrintTree(root);
/*
输入:ABC##DE#G##F###
输出:CBEGDFA
*/
hCreateBiTree(root);
hPrintTree(root);
/*
输入:ABC##DE#G##F###
输出:CGEFDBA
*/
return 0;
}
2019-11-04
利用p126的算法5.3建立二叉树,并完成四种遍历算法 中序 先序 后序 层次
输入:ABC##DE#G##F###
#include<iostream>
#include<stack>
#include<queue>
#define TElemType char
#define status int
#define OK 1
#define OVERFLOW 0
using namespace std;
typedef struct BiTNode
{
TElemType data;
struct BiTNode *lchild,*rchild;
}BiTNode,*BiTree;
//先序遍历输出
void xPrintTree(BiTree T)
{
if(T)
{
cout<<T->data;
xPrintTree(T->lchild);
xPrintTree(T->rchild);
}
else
{
return;
}
}
//中序遍历输出
void zPrintTree(BiTree T)
{
if(T)
{
zPrintTree(T->lchild);
cout<<T->data;
zPrintTree(T->rchild);
}
else
{
return;
}
}
//后序遍历输出
void hPrintTree(BiTree T)
{
if(T)
{
hPrintTree(T->lchild);
hPrintTree(T->rchild);
cout<<T->data;
}
else
{
return;
}
}
//层次遍历输出
void LPrintTree(BiTree T)
{
queue<BiTree>q;
q.push(T);
while(!q.empty())
{
BiTree head=q.front();
q.pop();
cout<<head->data;
if(head->lchild)
{
q.push(head->lchild);
}
if(head->rchild)
{
q.push(head->rchild);
}
}
}
void CreateBiTree(BiTree &T)
{
TElemType ch;
cin>>ch;
if(ch=='#')
{
T=NULL;
}
else
{
T=new BiTNode;
T->data = ch;
CreateBiTree(T->lchild);
CreateBiTree(T->rchild);
}
}
int main()
{
BiTree root;
CreateBiTree(root);
cout<<"
先序遍历输出"<<endl;
xPrintTree(root);
cout<<"
中序遍历输出"<<endl;
zPrintTree(root);
cout<<"
后序遍历输出"<<endl;
hPrintTree(root);
cout<<"
层次遍历输出"<<endl;
LPrintTree(root);
return 0;
}
设计四个算法,分别实现:
(1)统计二叉树中结点的个数。
(2)统计二叉树中叶子结点的个数
(3)统计二叉树中度为2的结点的个数
(4)统计二叉树中度为1的结点的个数
/**
#图P121(b)
#建立二叉树,并且用三种遍历法遍历他
#2019/11/4
输入:
ABC##DE#G##F###
输出:
这棵树的节点数:7
这棵树的叶子节点数:3
这棵树的度为2的结点的数:2
这棵树的度为1的结点的数:2
*/
#include<iostream>
#include<stack>
#define TElemType char
#define status int
#define OK 1
#define OVERFLOW 0
using namespace std;
typedef struct BiTNode
{
TElemType data;
struct BiTNode *lchild,*rchild;
}BiTNode,*BiTree;
//统计二叉树中结点的个数
int CountTreeNode(BiTree T,int &count)
{
if(T)
{
count++;
CountTreeNode(T->lchild,count);
CountTreeNode(T->rchild,count);
}
else
{
return count;
}
}
//统计二叉树中叶子结点的个数
int CountTreeLeaf(BiTree T,int &count)
{
if(T)
{
if(!T->lchild&&!T->rchild)
count++;
CountTreeLeaf(T->lchild,count);
CountTreeLeaf(T->rchild,count);
}
else
{
return count;
}
}
//统计二叉树中度为2的结点的个数
int CountTreeDegreeTwo(BiTree T,int &count)
{
if(T)
{
if(T->lchild&&T->rchild)
count++;
CountTreeDegreeTwo(T->lchild,count);
CountTreeDegreeTwo(T->rchild,count);
}
else
{
return count;
}
}
//统计二叉树中度为1的结点的个数
int CountTreeDegreeOne(BiTree T,int &count)
{
if(T)
{
if((T->lchild&&!T->rchild)||(!T->lchild&&T->rchild))
count++;
CountTreeDegreeOne(T->lchild,count);
CountTreeDegreeOne(T->rchild,count);
}
else
{
return count;
}
}
void CreateBiTree(BiTree &T)
{
TElemType ch;
cin>>ch;
if(ch=='#')
{
T=NULL;
}
else
{
T=new BiTNode;
T->data = ch;
CreateBiTree(T->lchild);
CreateBiTree(T->rchild);
}
}
int main()
{
BiTree root;
CreateBiTree(root);
int count=0;
cout<<"这棵树的节点数:"<<CountTreeNode(root,count)<<endl;
count=0;
cout<<"这棵树的叶子节点数:"<<CountTreeLeaf(root,count)<<endl;
count=0;
cout<<"这棵树的度为2的结点的数:"<<CountTreeDegreeTwo(root,count)<<endl;
count=0;
cout<<"这棵树的度为1的结点的数:"<<CountTreeDegreeOne(root,count)<<endl;
return 0;
}