// 面试题8:二叉树的下一个结点 // 题目:给定一棵二叉树和其中的一个结点,如何找出中序遍历顺序的下一个结点? // 树中的结点除了有两个分别指向左右子结点的指针以外,还有一个指向父结点的指针。 #include <stdio.h> struct BinaryTreeNode { int m_nValue; BinaryTreeNode* m_pLeft; BinaryTreeNode* m_pRight; BinaryTreeNode* m_pParent; }; BinaryTreeNode* GetNext(BinaryTreeNode* pNode) { //鲁棒性测试 1.空指针 if (pNode == nullptr) return nullptr; BinaryTreeNode* pNext = nullptr; //如果该父节点有右子树,返回右子树的左子节点 if (pNode->m_pRight != nullptr) { BinaryTreeNode* pRight = pNode->m_pRight; while (pRight->m_pLeft != nullptr) { pRight = pRight->m_pLeft; } pNext = pRight; } //如果无右节点, 分两种情况 else if (pNode->m_pParent != nullptr) //检查父节点 { BinaryTreeNode* pCurrent = pNode; BinaryTreeNode* pParent = pNode->m_pParent; //如果节点为父节点的右子节点, 则向上遍历寻找是其父节点左子节点的节点 while (pParent != nullptr && pParent->m_pRight == pCurrent) //注意判断顺序,读取访问权限冲突 //while (pParent->m_pRight == pCurrent && pParent != nullptr) { pCurrent = pParent; pParent = pParent->m_pParent; } //如果为父节点的左子节点, 返回父节点 pNext = pParent; } return pNext; }
// ==================== 辅助代码用来构建二叉树 ==================== BinaryTreeNode* CreateBinaryTreeNode(int value) { BinaryTreeNode* pNode = new BinaryTreeNode(); pNode->m_nValue = value; pNode->m_pLeft = nullptr; pNode->m_pRight = nullptr; pNode->m_pParent = nullptr; return pNode; } void ConnectTreeNodes(BinaryTreeNode* pParent, BinaryTreeNode* pLeft, BinaryTreeNode* pRight) { if (pParent != nullptr) { pParent->m_pLeft = pLeft; pParent->m_pRight = pRight; if (pLeft != nullptr) pLeft->m_pParent = pParent; if (pRight != nullptr) pRight->m_pParent = pParent; } } void PrintTreeNode(BinaryTreeNode* pNode) { if (pNode != nullptr) { printf("value of this node is: %d ", pNode->m_nValue); if (pNode->m_pLeft != nullptr) printf("value of its left child is: %d. ", pNode->m_pLeft->m_nValue); else printf("left child is null. "); if (pNode->m_pRight != nullptr) printf("value of its right child is: %d. ", pNode->m_pRight->m_nValue); else printf("right child is null. "); } else { printf("this node is null. "); } printf(" "); } void PrintTree(BinaryTreeNode* pRoot) { PrintTreeNode(pRoot); if (pRoot != nullptr) { if (pRoot->m_pLeft != nullptr) PrintTree(pRoot->m_pLeft); if (pRoot->m_pRight != nullptr) PrintTree(pRoot->m_pRight); } } void DestroyTree(BinaryTreeNode* pRoot) { if (pRoot != nullptr) { BinaryTreeNode* pLeft = pRoot->m_pLeft; BinaryTreeNode* pRight = pRoot->m_pRight; delete pRoot; pRoot = nullptr; DestroyTree(pLeft); DestroyTree(pRight); } }
// ====================测试代码==================== void Test(const char* testName, BinaryTreeNode* pNode, BinaryTreeNode* expected) { if (testName != nullptr) printf("%s begins: ", testName); BinaryTreeNode* pNext = GetNext(pNode); if (pNext == expected) printf("Passed. "); else printf("FAILED. "); } // 8 // 6 10 // 5 7 9 11 void Test1_7() { 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); Test("Test1", pNode8, pNode9); Test("Test2", pNode6, pNode7); Test("Test3", pNode10, pNode11); Test("Test4", pNode5, pNode6); Test("Test5", pNode7, pNode8); Test("Test6", pNode9, pNode10); Test("Test7", pNode11, nullptr); DestroyTree(pNode8); } // 5 // 4 // 3 // 2 void Test8_11() { BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5); BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4); BinaryTreeNode* pNode3 = CreateBinaryTreeNode(3); BinaryTreeNode* pNode2 = CreateBinaryTreeNode(2); ConnectTreeNodes(pNode5, pNode4, nullptr); ConnectTreeNodes(pNode4, pNode3, nullptr); ConnectTreeNodes(pNode3, pNode2, nullptr); Test("Test8", pNode5, nullptr); Test("Test9", pNode4, pNode5); Test("Test10", pNode3, pNode4); Test("Test11", pNode2, pNode3); DestroyTree(pNode5); } // 2 // 3 // 4 // 5 void Test12_15() { BinaryTreeNode* pNode2 = CreateBinaryTreeNode(2); BinaryTreeNode* pNode3 = CreateBinaryTreeNode(3); BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4); BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5); ConnectTreeNodes(pNode2, nullptr, pNode3); ConnectTreeNodes(pNode3, nullptr, pNode4); ConnectTreeNodes(pNode4, nullptr, pNode5); Test("Test12", pNode5, nullptr); Test("Test13", pNode4, pNode5); Test("Test14", pNode3, pNode4); Test("Test15", pNode2, pNode3); DestroyTree(pNode2); } void Test16() { BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5); Test("Test16", pNode5, nullptr); DestroyTree(pNode5); } int main(int argc, char* argv[]) { Test1_7(); Test8_11(); Test12_15(); Test16(); }
分析:根据实例分析规律。注意不要出现读取访问冲突。
/* struct TreeLinkNode { int val; struct TreeLinkNode *left; struct TreeLinkNode *right; struct TreeLinkNode *next; TreeLinkNode(int x) :val(x), left(NULL), right(NULL), next(NULL) { } }; */ class Solution { public: TreeLinkNode* GetNext(TreeLinkNode* pNode) { if (pNode == nullptr) return nullptr; TreeLinkNode* pNext = nullptr; if (pNode->right != nullptr) { TreeLinkNode* pRight = pNode->right; while (pRight->left != nullptr) pRight = pRight->left; pNext = pRight; } else if (pNode->next != nullptr) { TreeLinkNode* pCurrent = pNode; TreeLinkNode* pParent = pNode->next; while (pParent != nullptr && pCurrent == pParent->right) { pCurrent = pParent; pParent = pParent->next; } pNext = pParent; } return pNext; } };