剑指offer——面试题8:二叉树的下一个节点
1 // 面试题8:二叉树的下一个结点 2 // 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? 3 // 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。 4 5 #include <stdio.h> 6 7 struct BinaryTreeNode 8 { 9 int m_nValue; 10 BinaryTreeNode* m_pLeft; 11 BinaryTreeNode* m_pRight; 12 BinaryTreeNode* m_pParent; 13 }; 14 15 BinaryTreeNode* GetNext(BinaryTreeNode* pNode) 16 { 17 if(pNode == nullptr) 18 return nullptr; 19 20 BinaryTreeNode* pNext = nullptr; 21 if(pNode->m_pRight != nullptr) 22 { 23 BinaryTreeNode* pRight = pNode->m_pRight; 24 while(pRight->m_pLeft != nullptr) 25 pRight = pRight->m_pLeft; 26 27 pNext = pRight; 28 } 29 else if(pNode->m_pParent != nullptr) 30 { 31 BinaryTreeNode* pCurrent = pNode; 32 BinaryTreeNode* pParent = pNode->m_pParent; 33 while(pParent != nullptr && pCurrent == pParent->m_pRight) 34 { 35 pCurrent = pParent; 36 pParent = pParent->m_pParent; 37 } 38 39 pNext = pParent; 40 } 41 42 return pNext; 43 } 44 45 // ==================== 辅助代码用来构建二叉树 ==================== 46 BinaryTreeNode* CreateBinaryTreeNode(int value) 47 { 48 BinaryTreeNode* pNode = new BinaryTreeNode(); 49 pNode->m_nValue = value; 50 pNode->m_pLeft = nullptr; 51 pNode->m_pRight = nullptr; 52 pNode->m_pParent = nullptr; 53 54 return pNode; 55 } 56 57 void ConnectTreeNodes(BinaryTreeNode* pParent, BinaryTreeNode* pLeft, BinaryTreeNode* pRight) 58 { 59 if(pParent != nullptr) 60 { 61 pParent->m_pLeft = pLeft; 62 pParent->m_pRight = pRight; 63 64 if(pLeft != nullptr) 65 pLeft->m_pParent = pParent; 66 if(pRight != nullptr) 67 pRight->m_pParent = pParent; 68 } 69 } 70 71 void PrintTreeNode(BinaryTreeNode* pNode) 72 { 73 if(pNode != nullptr) 74 { 75 printf("value of this node is: %d\n", pNode->m_nValue); 76 77 if(pNode->m_pLeft != nullptr) 78 printf("value of its left child is: %d.\n", pNode->m_pLeft->m_nValue); 79 else 80 printf("left child is null.\n"); 81 82 if(pNode->m_pRight != nullptr) 83 printf("value of its right child is: %d.\n", pNode->m_pRight->m_nValue); 84 else 85 printf("right child is null.\n"); 86 } 87 else 88 { 89 printf("this node is null.\n"); 90 } 91 92 printf("\n"); 93 } 94 95 void PrintTree(BinaryTreeNode* pRoot) 96 { 97 PrintTreeNode(pRoot); 98 99 if(pRoot != nullptr) 100 { 101 if(pRoot->m_pLeft != nullptr) 102 PrintTree(pRoot->m_pLeft); 103 104 if(pRoot->m_pRight != nullptr) 105 PrintTree(pRoot->m_pRight); 106 } 107 } 108 109 void DestroyTree(BinaryTreeNode* pRoot) 110 { 111 if(pRoot != nullptr) 112 { 113 BinaryTreeNode* pLeft = pRoot->m_pLeft; 114 BinaryTreeNode* pRight = pRoot->m_pRight; 115 116 delete pRoot; 117 pRoot = nullptr; 118 119 DestroyTree(pLeft); 120 DestroyTree(pRight); 121 } 122 } 123 124 // ====================测试代码==================== 125 void Test(char* testName, BinaryTreeNode* pNode, BinaryTreeNode* expected) 126 { 127 if(testName != nullptr) 128 printf("%s begins: ", testName); 129 130 BinaryTreeNode* pNext = GetNext(pNode); 131 if(pNext == expected) 132 printf("Passed.\n"); 133 else 134 printf("FAILED.\n"); 135 } 136 137 // 8 138 // 6 10 139 // 5 7 9 11 140 void Test1_7() 141 { 142 BinaryTreeNode* pNode8 = CreateBinaryTreeNode(8); 143 BinaryTreeNode* pNode6 = CreateBinaryTreeNode(6); 144 BinaryTreeNode* pNode10 = CreateBinaryTreeNode(10); 145 BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5); 146 BinaryTreeNode* pNode7 = CreateBinaryTreeNode(7); 147 BinaryTreeNode* pNode9 = CreateBinaryTreeNode(9); 148 BinaryTreeNode* pNode11 = CreateBinaryTreeNode(11); 149 150 ConnectTreeNodes(pNode8, pNode6, pNode10); 151 ConnectTreeNodes(pNode6, pNode5, pNode7); 152 ConnectTreeNodes(pNode10, pNode9, pNode11); 153 154 Test("Test1", pNode8, pNode9); 155 Test("Test2", pNode6, pNode7); 156 Test("Test3", pNode10, pNode11); 157 Test("Test4", pNode5, pNode6); 158 Test("Test5", pNode7, pNode8); 159 Test("Test6", pNode9, pNode10); 160 Test("Test7", pNode11, nullptr); 161 162 DestroyTree(pNode8); 163 } 164 165 // 5 166 // 4 167 // 3 168 // 2 169 void Test8_11() 170 { 171 BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5); 172 BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4); 173 BinaryTreeNode* pNode3 = CreateBinaryTreeNode(3); 174 BinaryTreeNode* pNode2 = CreateBinaryTreeNode(2); 175 176 ConnectTreeNodes(pNode5, pNode4, nullptr); 177 ConnectTreeNodes(pNode4, pNode3, nullptr); 178 ConnectTreeNodes(pNode3, pNode2, nullptr); 179 180 Test("Test8", pNode5, nullptr); 181 Test("Test9", pNode4, pNode5); 182 Test("Test10", pNode3, pNode4); 183 Test("Test11", pNode2, pNode3); 184 185 DestroyTree(pNode5); 186 } 187 188 // 2 189 // 3 190 // 4 191 // 5 192 void Test12_15() 193 { 194 BinaryTreeNode* pNode2 = CreateBinaryTreeNode(2); 195 BinaryTreeNode* pNode3 = CreateBinaryTreeNode(3); 196 BinaryTreeNode* pNode4 = CreateBinaryTreeNode(4); 197 BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5); 198 199 ConnectTreeNodes(pNode2, nullptr, pNode3); 200 ConnectTreeNodes(pNode3, nullptr, pNode4); 201 ConnectTreeNodes(pNode4, nullptr, pNode5); 202 203 Test("Test12", pNode5, nullptr); 204 Test("Test13", pNode4, pNode5); 205 Test("Test14", pNode3, pNode4); 206 Test("Test15", pNode2, pNode3); 207 208 DestroyTree(pNode2); 209 } 210 211 void Test16() 212 { 213 BinaryTreeNode* pNode5 = CreateBinaryTreeNode(5); 214 215 Test("Test16", pNode5, nullptr); 216 217 DestroyTree(pNode5); 218 } 219 220 int main(int argc, char* argv[]) 221 { 222 Test1_7(); 223 Test8_11(); 224 Test12_15(); 225 Test16(); 226 }