按行打印二叉树
文章目录
//按行打印二叉树 //一个变量表示当前层还没有打印的节点数,另一个变量表示下一层节点的数目
#include <iostream>
#include<queue>
#include<stdio.h>
#include "../common/ConstructBST.h"
using namespace std;
//按行打印二叉树
void Print(BinaryTreeNode* pRoot){
if(pRoot==NULL)
return;
queue<BinaryTreeNode*> nodes;
nodes.push(pRoot);
int nextLevel=0;//下一层的节点数目
int toBePrinted=1;//当前层剩下的节点数
while(!nodes.empty()){
BinaryTreeNode* pNode=nodes.front();
cout<<pNode->m_nValue<<" ";
if(pNode->m_pLeft!=NULL){
nodes.push(pNode->m_pLeft);
++nextLevel;
}
if(pNode->m_pRight!=NULL){
nodes.push(pNode->m_pRight);
++nextLevel;
}
nodes.pop();//弹出节点
--toBePrinted;//第一个层打印完了
if(toBePrinted==0){
cout<<endl;
toBePrinted=nextLevel;
nextLevel=0;
}
}
}
// ==================== Test Code ====================
// 8
// 6 10
// 5 7 9 11
void Test1()
{
BinaryTreeNode* pNode8 = CreateBinaryTreeNode(8);
BinaryTreeNode* pNode6 = CreateBinaryTreeNode(6);
BinaryTreeNode* pNode10 = CreateBinaryTreeNode(10);
BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5);
BinaryTreeNode* pNode7 = CreateBinaryTreeNode(7);
BinaryTreeNode* pNode9 = CreateBinaryTreeNode(9);
BinaryTreeNode* pNode11 = CreateBinaryTreeNode(11);
ConnectTreeNodes(pNode8, pNode6, pNode10);
ConnectTreeNodes(pNode6, pNode5, pNode7);
ConnectTreeNodes(pNode10, pNode9, pNode11);
printf("====Test1 Begins: ====\n");
printf("Expected Result is:\n");
printf("8 \n");
printf("6 10 \n");
printf("5 7 9 11 \n\n");
printf("Actual Result is: \n");
Print(pNode8);
printf("\n");
DestroyTree(pNode8);
}
// 5
// 4
// 3
// 2
void Test2()
{
BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5);
BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4);
BinaryTreeNode* pNode3 = CreateBinaryTreeNode(3);
BinaryTreeNode* pNode2 = CreateBinaryTreeNode(2);
ConnectTreeNodes(pNode5, pNode4, NULL);
ConnectTreeNodes(pNode4, pNode3, NULL);
ConnectTreeNodes(pNode3, pNode2, NULL);
printf("====Test2 Begins: ====\n");
printf("Expected Result is:\n");
printf("5 \n");
printf("4 \n");
printf("3 \n");
printf("2 \n\n");
printf("Actual Result is: \n");
Print(pNode5);
printf("\n");
DestroyTree(pNode5);
}
// 5
// 4
// 3
// 2
void Test3()
{
BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5);
BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4);
BinaryTreeNode* pNode3 = CreateBinaryTreeNode(3);
BinaryTreeNode* pNode2 = CreateBinaryTreeNode(2);
ConnectTreeNodes(pNode5, NULL, pNode4);
ConnectTreeNodes(pNode4, NULL, pNode3);
ConnectTreeNodes(pNode3, NULL, pNode2);
printf("====Test3 Begins: ====\n");
printf("Expected Result is:\n");
printf("5 \n");
printf("4 \n");
printf("3 \n");
printf("2 \n\n");
printf("Actual Result is: \n");
Print(pNode5);
printf("\n");
DestroyTree(pNode5);
}
void Test4()
{
BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5);
printf("====Test4 Begins: ====\n");
printf("Expected Result is:\n");
printf("5 \n\n");
printf("Actual Result is: \n");
Print(pNode5);
printf("\n");
DestroyTree(pNode5);
}
void Test5()
{
printf("====Test5 Begins: ====\n");
printf("Expected Result is:\n");
printf("Actual Result is: \n");
Print(NULL);
printf("\n");
}
// 100
// /
// 50
// \
// 150
void Test6()
{
BinaryTreeNode* pNode100 = CreateBinaryTreeNode(100);
BinaryTreeNode* pNode50 = CreateBinaryTreeNode(50);
BinaryTreeNode* pNode150 = CreateBinaryTreeNode(150);
ConnectTreeNodes(pNode100, pNode50, NULL);
ConnectTreeNodes(pNode50, NULL, pNode150);
printf("====Test6 Begins: ====\n");
printf("Expected Result is:\n");
printf("100 \n");
printf("50 \n");
printf("150 \n\n");
printf("Actual Result is: \n");
Print(pNode100);
printf("\n");
}
int main()
{
Test1();
Test2();
Test3();
Test4();
Test5();
Test6();
return 0;
}
