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Add C++ code for the chapter binary tree.

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This commit is contained in:
Yudong Jin 2022-11-29 02:21:49 +08:00
parent 980eaf65e0
commit d2db8b8d60
14 changed files with 613 additions and 17 deletions
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2
codes/cpp/chapter_searching/hashing_search.cpp
View File

@ -40,7 +40,7 @@ int main() {
cout << "目标元素 3 的索引 = " << index << endl;
/* 哈希查找(链表) */
ListNode* head = vectorToLinkedList(nums);
ListNode* head = vecToLinkedList(nums);
// 初始化哈希表
unordered_map<int, ListNode*> map1;
while (head != nullptr) {

2
codes/cpp/chapter_searching/linear_search.cpp
View File

@ -42,7 +42,7 @@ int main() {
cout << "目标元素 3 的索引 = " << index << endl;
/* 在链表中执行线性查找 */
ListNode* head = vectorToLinkedList(nums);
ListNode* head = vecToLinkedList(nums);
ListNode* node = linearSearch(head, target);
cout << "目标结点值 3 的对应结点对象为 " << node << endl;

2
codes/cpp/chapter_stack_and_queue/queue.cpp
View File

@ -6,6 +6,8 @@
#include "../include/include.hpp"
/* Driver Code */
int main(){
/* 初始化队列 */
queue<int> queue;

2
codes/cpp/chapter_stack_and_queue/stack.cpp
View File

@ -6,6 +6,8 @@
#include "../include/include.hpp"
/* Driver Code */
int main() {
/* 初始化栈 */
stack<int> stack;

146
codes/cpp/chapter_tree/binary_search_tree.cpp
View File

@ -6,3 +6,149 @@
#include "../include/include.hpp"
/* 二叉搜索树 */
class BinarySearchTree {
private:
TreeNode* root;
public:
BinarySearchTree(vector<int> nums) {
sort(nums.begin(), nums.end()); // 排序数组
root = buildTree(nums, 0, nums.size() - 1); // 构建二叉搜索树
}
/* 获取二叉树根结点 */
TreeNode* getRoot() {
return root;
}
/* 构建二叉搜索树 */
TreeNode* buildTree(vector<int> nums, int i, int j) {
if (i > j) return nullptr;
// 将数组中间结点作为根结点
int mid = (i + j) / 2;
TreeNode* root = new TreeNode(nums[mid]);
// 递归建立左子树和右子树
root->left = buildTree(nums, i, mid - 1);
root->right = buildTree(nums, mid + 1, j);
return root;
}
/* 查找结点 */
TreeNode* search(int num) {
TreeNode* cur = root;
// 循环查找,越过叶结点后跳出
while (cur != nullptr) {
// 目标结点在 root 的右子树中
if (cur->val < num) cur = cur->right;
// 目标结点在 root 的左子树中
else if (cur->val > num) cur = cur->left;
// 找到目标结点,跳出循环
else break;
}
// 返回目标结点
return cur;
}
/* 插入结点 */
TreeNode* insert(int num) {
// 若树为空,直接提前返回
if (root == nullptr) return nullptr;
TreeNode *cur = root, *pre = nullptr;
// 循环查找,越过叶结点后跳出
while (cur != nullptr) {
// 找到重复结点,直接返回
if (cur->val == num) return nullptr;
pre = cur;
// 插入位置在 root 的右子树中
if (cur->val < num) cur = cur->right;
// 插入位置在 root 的左子树中
else cur = cur->left;
}
// 插入结点 val
TreeNode* node = new TreeNode(num);
if (pre->val < num) pre->right = node;
else pre->left = node;
return node;
}
/* 删除结点 */
TreeNode* remove(int num) {
// 若树为空,直接提前返回
if (root == nullptr) return nullptr;
TreeNode *cur = root, *pre = nullptr;
// 循环查找,越过叶结点后跳出
while (cur != nullptr) {
// 找到待删除结点,跳出循环
if (cur->val == num) break;
pre = cur;
// 待删除结点在 root 的右子树中
if (cur->val < num) cur = cur->right;
// 待删除结点在 root 的左子树中
else cur = cur->left;
}
// 若无待删除结点,则直接返回
if (cur == nullptr) return nullptr;
// 子结点数量 = 0 or 1
if (cur->left == nullptr || cur->right == nullptr) {
// 当子结点数量 = 0 / 1 时, child = nullptr / 该子结点
TreeNode* child = cur->left != nullptr ? cur->left : cur->right;
// 删除结点 cur
if (pre->left == cur) pre->left = child;
else pre->right = child;
}
// 子结点数量 = 2
else {
// 获取中序遍历中 cur 的下一个结点
TreeNode* nex = min(cur->right);
int tmp = nex->val;
// 递归删除结点 nex
remove(nex->val);
// 将 nex 的值复制给 cur
cur->val = tmp;
}
return cur;
}
/* 获取最小结点 */
TreeNode* min(TreeNode* root) {
if (root == nullptr) return root;
// 循环访问左子结点,直到叶结点时为最小结点,跳出
while (root->left != nullptr) {
root = root->left;
}
return root;
}
};
/* Driver Code */
int main() {
/* 初始化二叉搜索树 */
vector<int> nums = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 };
BinarySearchTree* bst = new BinarySearchTree(nums);
cout << endl << "初始化的二叉树为\n" << endl;
PrintUtil::printTree(bst->getRoot());
/* 查找结点 */
TreeNode* node = bst->search(5);
cout << endl << "查找到的结点对象为 " << node << ",结点值 = " << node->val << endl;
/* 插入结点 */
node = bst->insert(16);
cout << endl << "插入结点 16 后,二叉树为\n" << endl;
PrintUtil::printTree(bst->getRoot());
/* 删除结点 */
bst->remove(1);
cout << endl << "删除结点 1 后,二叉树为\n" << endl;
PrintUtil::printTree(bst->getRoot());
bst->remove(2);
cout << endl << "删除结点 2 后,二叉树为\n" << endl;
PrintUtil::printTree(bst->getRoot());
bst->remove(4);
cout << endl << "删除结点 4 后,二叉树为\n" << endl;
PrintUtil::printTree(bst->getRoot());
return 0;
}

32
codes/cpp/chapter_tree/binary_tree.cpp
View File

@ -6,3 +6,35 @@
#include "../include/include.hpp"
/* Driver Code */
int main() {
/* 初始化二叉树 */
// 初始化结点
TreeNode* n1 = new TreeNode(1);
TreeNode* n2 = new TreeNode(2);
TreeNode* n3 = new TreeNode(3);
TreeNode* n4 = new TreeNode(4);
TreeNode* n5 = new TreeNode(5);
// 构建引用指向(即指针)
n1->left = n2;
n1->right = n3;
n2->left = n4;
n2->right = n5;
cout << endl << "初始化二叉树\n" << endl;
PrintUtil::printTree(n1);
/* 插入与删除结点 */
TreeNode* P = new TreeNode(0);
// 在 n1 -> n2 中间插入结点 P
n1->left = P;
P->left = n2;
cout << endl << "插入结点 P 后\n" << endl;
PrintUtil::printTree(n1);
// 删除结点 P
n1->left = n2;
cout << endl << "删除结点 P 后\n" << endl;
PrintUtil::printTree(n1);
return 0;
}

36
codes/cpp/chapter_tree/binary_tree_bfs.cpp
View File

@ -6,3 +6,39 @@
#include "../include/include.hpp"
/* 层序遍历 */
vector<int> hierOrder(TreeNode* root) {
// 初始化队列,加入根结点
queue<TreeNode*> queue;
queue.push(root);
// 初始化一个列表,用于保存遍历序列
vector<int> vec;
while (!queue.empty()) {
TreeNode* node = queue.front();
queue.pop(); // 队列出队
vec.push_back(node->val); // 保存结点
if (node->left != NULL)
queue.push(node->left); // 左子结点入队
if (node->right != NULL)
queue.push(node->right); // 右子结点入队
}
return vec;
}
/* Driver Code */
int main() {
/* 初始化二叉树 */
// 这里借助了一个从数组直接生成二叉树的函数
TreeNode* root = vecToTree(vector<int>
{ 1, 2, 3, 4, 5, 6, 7, INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX });
cout << endl << "初始化二叉树\n" << endl;
PrintUtil::printTree(root);
/* 层序遍历 */
vector<int> vec = hierOrder(root);
cout << endl << "层序遍历的结点打印序列 = ";
PrintUtil::printVector(vec);
return 0;
}

60
codes/cpp/chapter_tree/binary_tree_dfs.cpp
View File

@ -6,3 +6,63 @@
#include "../include/include.hpp"
// 初始化列表,用于存储遍历序列
vector<int> vec;
/* 前序遍历 */
void preOrder(TreeNode* root) {
if (root == nullptr) return;
// 访问优先级:根结点 -> 左子树 -> 右子树
vec.push_back(root->val);
preOrder(root->left);
preOrder(root->right);
}
/* 中序遍历 */
void inOrder(TreeNode* root) {
if (root == nullptr) return;
// 访问优先级:左子树 -> 根结点 -> 右子树
inOrder(root->left);
vec.push_back(root->val);
inOrder(root->right);
}
/* 后序遍历 */
void postOrder(TreeNode* root) {
if (root == nullptr) return;
// 访问优先级:左子树 -> 右子树 -> 根结点
postOrder(root->left);
postOrder(root->right);
vec.push_back(root->val);
}
/* Driver Code */
int main() {
/* 初始化二叉树 */
// 这里借助了一个从数组直接生成二叉树的函数
TreeNode* root = vecToTree(vector<int>
{ 1, 2, 3, 4, 5, 6, 7, INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX});
cout << endl << "初始化二叉树\n" << endl;
PrintUtil::printTree(root);
/* 前序遍历 */
vec.clear();
preOrder(root);
cout << endl << "前序遍历的结点打印序列 = ";
PrintUtil::printVector(vec);
/* 中序遍历 */
vec.clear();
inOrder(root);
cout << endl << "中序遍历的结点打印序列 = ";
PrintUtil::printVector(vec);
/* 后序遍历 */
vec.clear();
postOrder(root);
cout << endl << "后序遍历的结点打印序列 = ";
PrintUtil::printVector(vec);
return 0;
}

2
codes/cpp/include/ListNode.hpp
View File

@ -25,7 +25,7 @@ struct ListNode {
* @param list
* @return ListNode*
*/
ListNode* vectorToLinkedList(vector<int>& list) {
ListNode* vecToLinkedList(vector<int> list) {
ListNode *dum = new ListNode(0);
ListNode *head = dum;
for (int val : list) {

23
codes/cpp/include/PrintUtil.hpp
View File

@ -238,4 +238,27 @@ class PrintUtil {
}
cout << "[" + s.str() + "]" << '\n';
}
/**
* @brief
*
* @tparam T
* @param queue
*/
template <typename T>
static void printQueue(queue<T> &queue)
{
// Generate the string to print
ostringstream s;
bool flag = true;
while(!queue.empty()) {
if (flag) {
s << queue.front();
flag = false;
}
else s << ", " << queue.front();
queue.pop();
}
cout << "[" + s.str() + "]" << '\n';
}
};

2
codes/cpp/include/TreeNode.hpp
View File

@ -23,7 +23,7 @@ struct TreeNode {
* @param list
* @return TreeNode*
*/
TreeNode* vectorToTree(vector<int>& list) {
TreeNode* vecToTree(vector<int> list) {
TreeNode *root = new TreeNode(list[0]);
queue<TreeNode*> que;
que.emplace(root);

1
codes/java/chapter_tree/binary_search_tree.java
View File

@ -9,6 +9,7 @@ package chapter_tree;
import java.util.*;
import include.*;
/* 二叉搜索树 */
class BinarySearchTree {
private TreeNode root;

134
docs/chapter_tree/binary_search_tree.md
View File

@ -59,12 +59,43 @@ comments: true
}
```
=== "C++"
```cpp title="binary_search_tree.cpp"
/* 查找结点 */
TreeNode* search(int num) {
TreeNode* cur = root;
// 循环查找,越过叶结点后跳出
while (cur != nullptr) {
// 目标结点在 root 的右子树中
if (cur->val < num) cur = cur->right;
// 目标结点在 root 的左子树中
else if (cur->val > num) cur = cur->left;
// 找到目标结点,跳出循环
else break;
}
// 返回目标结点
return cur;
}
```
=== "Python"
```python title="binary_search_tree.py"
```
=== "Go"
```go title="binary_search_tree.go"
```
### 插入结点
给定一个待插入元素 `num` ,为了保持二叉搜索树 “左子树 < 根结点 < 右子树 的性质插入操作分为两步
1. **查找插入位置:** 与查找操作类似,我们从根结点出发,根据当前结点值和 `num` 的大小关系循环向下搜索,直到越过叶结点(遍历到 $\text{null}$ )时跳出循环;
2. **在该位置插入结点:** 初始化结点 `num` ,将该结点放到 $\text{null}$ 的位置
二叉搜索树不允许存在重复结点,否则将会违背其定义。因此若待插入结点在树中已经存在,则不执行插入,直接返回即可。
@ -97,6 +128,44 @@ comments: true
}
```
=== "C++"
```cpp title="binary_search_tree.cpp"
/* 插入结点 */
TreeNode* insert(int num) {
// 若树为空,直接提前返回
if (root == nullptr) return nullptr;
TreeNode *cur = root, *pre = nullptr;
// 循环查找,越过叶结点后跳出
while (cur != nullptr) {
// 找到重复结点,直接返回
if (cur->val == num) return nullptr;
pre = cur;
// 插入位置在 root 的右子树中
if (cur->val < num) cur = cur->right;
// 插入位置在 root 的左子树中
else cur = cur->left;
}
// 插入结点 val
TreeNode* node = new TreeNode(num);
if (pre->val < num) pre->right = node;
else pre->left = node;
return node;
}
```
=== "Python"
```python title="binary_search_tree.py"
```
=== "Go"
```go title="binary_search_tree.go"
```
为了插入结点,需要借助 **辅助结点 `prev`** 保存上一轮循环的结点,这样在遍历到 $\text{null}$ 时,我们也可以获取到其父结点,从而完成结点插入操作。
与查找结点相同,插入结点使用 $O(\log n)$ 时间。
@ -188,6 +257,69 @@ comments: true
}
```
=== "C++"
```cpp title="binary_search_tree.cpp"
/* 删除结点 */
TreeNode* remove(int num) {
// 若树为空,直接提前返回
if (root == nullptr) return nullptr;
TreeNode *cur = root, *pre = nullptr;
// 循环查找,越过叶结点后跳出
while (cur != nullptr) {
// 找到待删除结点,跳出循环
if (cur->val == num) break;
pre = cur;
// 待删除结点在 root 的右子树中
if (cur->val < num) cur = cur->right;
// 待删除结点在 root 的左子树中
else cur = cur->left;
}
// 若无待删除结点,则直接返回
if (cur == nullptr) return nullptr;
// 子结点数量 = 0 or 1
if (cur->left == nullptr || cur->right == nullptr) {
// 当子结点数量 = 0 / 1 时, child = nullptr / 该子结点
TreeNode* child = cur->left != nullptr ? cur->left : cur->right;
// 删除结点 cur
if (pre->left == cur) pre->left = child;
else pre->right = child;
}
// 子结点数量 = 2
else {
// 获取中序遍历中 cur 的下一个结点
TreeNode* nex = min(cur->right);
int tmp = nex->val;
// 递归删除结点 nex
remove(nex->val);
// 将 nex 的值复制给 cur
cur->val = tmp;
}
return cur;
}
/* 获取最小结点 */
TreeNode* min(TreeNode* root) {
if (root == nullptr) return root;
// 循环访问左子结点,直到叶结点时为最小结点,跳出
while (root->left != nullptr) {
root = root->left;
}
return root;
}
```
=== "Python"
```python title="binary_search_tree.py"
```
=== "Go"
```go title="binary_search_tree.go"
```
## 二叉搜索树的优势
假设给定 $n$ 个数字,最常用的存储方式是「数组」,那么对于这串乱序的数字,常见操作的效率为:

162
docs/chapter_tree/binary_tree.md
View File

@ -18,6 +18,35 @@ comments: true
}
```
=== "C++"
```cpp
/* 链表结点结构体 */
struct TreeNode {
int val; // 结点值
TreeNode *left; // 左子结点指针
TreeNode *right; // 右子结点指针
TreeNode(int x) : val(x), left(nullptr), right(nullptr) {}
};
```
=== "Python"
```python
""" 链表结点类 """
class TreeNode:
def __init__(self, val=0, left=None, right=None):
self.val = val # 结点值
self.left = left # 左子结点指针
self.right = right # 右子结点指针
```
=== "Go"
```go
```
结点的两个指针分别指向「左子结点 Left Child Node」和「右子结点 Right Child Node」并且称该结点为两个子结点的「父结点 Parent Node」。给定二叉树某结点将左子结点以下的树称为该结点的「左子树 Left Subtree」右子树同理。
![binary_tree_definition](binary_tree.assets/binary_tree_definition.png)
@ -84,12 +113,43 @@ comments: true
n2.right = n5;
```
=== "C++"
```cpp title="binary_tree.cpp"
/* 初始化二叉树 */
// 初始化结点
TreeNode* n1 = new TreeNode(1);
TreeNode* n2 = new TreeNode(2);
TreeNode* n3 = new TreeNode(3);
TreeNode* n4 = new TreeNode(4);
TreeNode* n5 = new TreeNode(5);
// 构建引用指向(即指针)
n1->left = n2;
n1->right = n3;
n2->left = n4;
n2->right = n5;
```
=== "Python"
```python title="binary_tree.py"
```
=== "Go"
```go title="binary_tree.go"
```
**插入与删除结点。** 与链表类似,插入与删除结点都可以通过修改指针实现。
![binary_tree_add_remove](binary_tree.assets/binary_tree_add_remove.png)
<p align="center"> Fig. 在二叉树中插入与删除结点 </p>
=== "Java"
```java title="binary_tree.java"
TreeNode P = new TreeNode(0);
// 在 n1 -> n2 中间插入结点 P
@ -99,6 +159,30 @@ P.left = n2;
n1.left = n2;
```
=== "C++"
```cpp title="binary_tree.cpp"
/* 插入与删除结点 */
TreeNode* P = new TreeNode(0);
// 在 n1 -> n2 中间插入结点 P
n1->left = P;
P->left = n2;
// 删除结点 P
n1->left = n2;
```
=== "Python"
```python title="binary_tree.py"
```
=== "Go"
```go title="binary_tree.go"
```
!!! note
插入结点会改变二叉树的原有逻辑结构,删除结点往往意味着删除了该结点的所有子树。因此,二叉树中的插入与删除一般都是由一套操作配合完成的,这样才能实现有意义的操作。
@ -140,6 +224,41 @@ n1.left = n2;
}
```
=== "C++"
```cpp title="binary_tree_bfs.cpp"
/* 层序遍历 */
vector<int> hierOrder(TreeNode* root) {
// 初始化队列,加入根结点
queue<TreeNode*> queue;
queue.push(root);
// 初始化一个列表,用于保存遍历序列
vector<int> vec;
while (!queue.empty()) {
TreeNode* node = queue.front();
queue.pop(); // 队列出队
vec.push_back(node->val); // 保存结点
if (node->left != NULL)
queue.push(node->left); // 左子结点入队
if (node->right != NULL)
queue.push(node->right); // 右子结点入队
}
return vec;
}
```
=== "Python"
```python title="binary_tree_bfs.py"
```
=== "Go"
```go title="binary_tree_bfs.go"
```
### 前序、中序、后序遍历
相对地,前、中、后序遍历皆属于「深度优先遍历 Depth-First Traversal」其体现着一种 “先走到尽头,再回头继续” 的回溯遍历方式。
@ -191,6 +310,49 @@ n1.left = n2;
}
```
=== "C++"
```cpp title="binary_tree_dfs.cpp"
/* 前序遍历 */
void preOrder(TreeNode* root) {
if (root == nullptr) return;
// 访问优先级:根结点 -> 左子树 -> 右子树
vec.push_back(root->val);
preOrder(root->left);
preOrder(root->right);
}
/* 中序遍历 */
void inOrder(TreeNode* root) {
if (root == nullptr) return;
// 访问优先级:左子树 -> 根结点 -> 右子树
inOrder(root->left);
vec.push_back(root->val);
inOrder(root->right);
}
/* 后序遍历 */
void postOrder(TreeNode* root) {
if (root == nullptr) return;
// 访问优先级:左子树 -> 右子树 -> 根结点
postOrder(root->left);
postOrder(root->right);
vec.push_back(root->val);
}
```
=== "Python"
```python title="binary_tree_dfs.py"
```
=== "Go"
```go title="binary_tree_dfs.go"
```
!!! note
使用循环一样可以实现前、中、后序遍历,但代码相对繁琐,有兴趣的同学可以自行实现。