二叉树存储结构和二叉树中各种基本算法设计
(1) 创建二叉树;
(2) 输出二叉树;
(3) 输出‘H’结点的左右孩子结点值;
(4) 输出二叉树的高度;
(5) 释放二叉树。
#include<stdio.h>
#include<malloc.h>
#define MaxSize 100
typedef char ElemType;
typedef struct node
{
ElemType data;
struct node *lchild;
struct node *rchild;
}BTNode;
void CreateBTree(BTNode *&b,char *str)
{
BTNode * St[MaxSize],*p;
int top=-1,k,j=0;char ch;
b=NULL;
ch=str[j];
while(ch!='\0')
{
switch(ch)
{
case'(':top++;St[top]=p;k=1;break;
case')':top--;break;
case',':k=2;break;
default:p=(BTNode *)malloc(sizeof(BTNode));
p->data=ch;p->lchild=p->rchild=NULL;
if(b==NULL)
b=p;
else
{
switch(k)
{
case 1:St[top]->lchild=p;break;
case 2:St[top]->rchild=p;break;
}
}
}
j++;ch=str[j];
}
}
void DestroyBTree(BTNode *&b)
{
if(b!=NULL)
{
DestroyBTree(b->lchild);
DestroyBTree(b->rchild);
free(b);
}
}
BTNode *FindNode(BTNode *b,ElemType x)
{
BTNode *p;
if(b==NULL)
return NULL;
else if(b->data==x)
return b;
else
{
p=FindNode(b->lchild,x);
if(p!=NULL)
return p;
else
return FindNode(b->rchild,x);
}
}
BTNode *LchildNode(BTNode *p)
{
return p->lchild;
}
BTNode *RchildNode(BTNode *p)
{
return p->rchild;
}
int BTHeight(BTNode *b)
{
int lchildh,rchildh;
if(b==NULL)return(0);
else
{
lchildh=BTHeight(b->lchild);
rchildh=BTHeight(b->rchild);
return(lchildh>rchildh)?(lchildh+1):(rchildh+1);
}
}
void DispBTree(BTNode *b)
{
if(b!=NULL)
{
printf("%c",b->data);
if(b->lchild!=NULL||b->rchild!=NULL)
{
printf("(");
DispBTree(b->lchild);
if(b->rchild!=NULL)printf(",");
DispBTree(b->rchild);
printf(")");
}
}
}
int main()
{
BTNode *b,*p,*lp,*rp;;
printf("二叉树的基本运算如下:\n");
printf(" (1)创建二叉树\n");
CreateBTree(b,"A(B(D,E(H(J,k(L,M(,N))))),C(F,G(,I)))");
printf(" (2)输出二叉树:");DispBTree(b);printf("\n");
printf(" (3)H结点:");
p=FindNode(b,'H');
if(p!=NULL)
{
lp= LchildNode(p);
if(lp!=NULL)printf("左孩子为%c",lp->data);
else printf("无左孩子");
rp=RchildNode(p);
if(rp!=NULL) printf("右孩子为%c",rp->data);
else printf("无右孩子");
}
printf("\n");
printf(" (4)二叉树b的高度:%d\n",BTHeight(b));
printf(" (5)释放二叉树b\n");
DestroyBTree(b);
return 1;
}
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