// 面试题34:二叉树中和为某一值的路径
// 题目:输入一棵二叉树和一个整数,打印出二叉树中结点值的和为输入整数的所
// 有路径。从树的根结点开始往下一直到叶结点所经过的结点形成一条路径。
#include <cstdio>
#include "BinaryTree.h"
#include <vector>
void FindPath(BinaryTreeNode* pRoot, int expectedSum, std::vector<int>& path, int& currentSum);
void FindPath(BinaryTreeNode* pRoot, int expectedSum)
{
if (pRoot == nullptr || expectedSum <= 0)
return;
std::vector<int> path;
int currentSum = 0;
FindPath(pRoot, expectedSum, path, currentSum);
}
void FindPath
(
BinaryTreeNode* pRoot,
int expectedSum,
std::vector<int>& path,
int& currentSum
)
{
//当前节点加入路径
path.push_back(pRoot->m_nValue);
currentSum += pRoot->m_nValue;
//如果当前节点为叶节点, 且当前和和预期一致, 打印路径
if (pRoot->m_pLeft == nullptr && pRoot->m_pRight == nullptr
&& currentSum == expectedSum)
{
printf("A path is found: ");
std::vector<int>::iterator iter = path.begin();
for (; iter != path.end(); ++iter)
printf("%d\t", *iter);
printf("\n");
}
//存在左右节点
if (pRoot->m_pLeft)
FindPath(pRoot->m_pLeft, expectedSum, path, currentSum);
if (pRoot->m_pRight)
FindPath(pRoot->m_pRight, expectedSum, path, currentSum);
//返回时删除掉此节点
currentSum -= pRoot->m_nValue;
path.pop_back();
}
// ====================测试代码====================
void Test(const char* testName, BinaryTreeNode* pRoot, int expectedSum)
{
if (testName != nullptr)
printf("%s begins:\n", testName);
FindPath(pRoot, expectedSum);
printf("\n");
}
// 10
// / \
// 5 12
// /\
// 4 7
// 有两条路径上的结点和为22
void Test1()
{
BinaryTreeNode* pNode10 = CreateBinaryTreeNode(10);
BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5);
BinaryTreeNode* pNode12 = CreateBinaryTreeNode(12);
BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4);
BinaryTreeNode* pNode7 = CreateBinaryTreeNode(7);
ConnectTreeNodes(pNode10, pNode5, pNode12);
ConnectTreeNodes(pNode5, pNode4, pNode7);
printf("Two paths should be found in Test1.\n");
Test("Test1", pNode10, 22);
DestroyTree(pNode10);
}
// 10
// / \
// 5 12
// /\
// 4 7
// 没有路径上的结点和为15
void Test2()
{
BinaryTreeNode* pNode10 = CreateBinaryTreeNode(10);
BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5);
BinaryTreeNode* pNode12 = CreateBinaryTreeNode(12);
BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4);
BinaryTreeNode* pNode7 = CreateBinaryTreeNode(7);
ConnectTreeNodes(pNode10, pNode5, pNode12);
ConnectTreeNodes(pNode5, pNode4, pNode7);
printf("No paths should be found in Test2.\n");
Test("Test2", pNode10, 15);
DestroyTree(pNode10);
}
// 5
// /
// 4
// /
// 3
// /
// 2
// /
// 1
// 有一条路径上面的结点和为15
void Test3()
{
BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5);
BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4);
BinaryTreeNode* pNode3 = CreateBinaryTreeNode(3);
BinaryTreeNode* pNode2 = CreateBinaryTreeNode(2);
BinaryTreeNode* pNode1 = CreateBinaryTreeNode(1);
ConnectTreeNodes(pNode5, pNode4, nullptr);
ConnectTreeNodes(pNode4, pNode3, nullptr);
ConnectTreeNodes(pNode3, pNode2, nullptr);
ConnectTreeNodes(pNode2, pNode1, nullptr);
printf("One path should be found in Test3.\n");
Test("Test3", pNode5, 15);
DestroyTree(pNode5);
}
// 1
// \
// 2
// \
// 3
// \
// 4
// \
// 5
// 没有路径上面的结点和为16
void Test4()
{
BinaryTreeNode* pNode1 = CreateBinaryTreeNode(1);
BinaryTreeNode* pNode2 = CreateBinaryTreeNode(2);
BinaryTreeNode* pNode3 = CreateBinaryTreeNode(3);
BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4);
BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5);
ConnectTreeNodes(pNode1, nullptr, pNode2);
ConnectTreeNodes(pNode2, nullptr, pNode3);
ConnectTreeNodes(pNode3, nullptr, pNode4);
ConnectTreeNodes(pNode4, nullptr, pNode5);
printf("No paths should be found in Test4.\n");
Test("Test4", pNode1, 16);
DestroyTree(pNode1);
}
// 树中只有1个结点
void Test5()
{
BinaryTreeNode* pNode1 = CreateBinaryTreeNode(1);
printf("One path should be found in Test5.\n");
Test("Test5", pNode1, 1);
DestroyTree(pNode1);
}
// 树中没有结点
void Test6()
{
printf("No paths should be found in Test6.\n");
Test("Test6", nullptr, 0);
}
int main(int argc, char* argv[])
{
Test1();
Test2();
Test3();
Test4();
Test5();
Test6();
return 0;
}
测试代码
分析:递归思想。