feat(csharp): add csharp code for charper divide and conquer (#628)

1 year ago · 7a6fd4b3dd
parent 8737fc66dd
commit 7a6fd4b3dd
4 changed files with 155 additions and 1 deletions
--- a/codes/csharp/chapter_divide_and_conquer/binary_search_recur.cs
+++ b/codes/csharp/chapter_divide_and_conquer/binary_search_recur.cs
@ -0,0 +1,46 @@
 /**
 * File: binary_search_recur.cs
 * Created Time: 2023-07-18
 * Author: hpstory (hpstory1024@163.com)
 */
 namespace hello_algo.chapter_divide_and_conquer;
 public class binary_search_recur {
    /* 二分查找：问题 f(i, j) */
    public int dfs(int[] nums, int target, int i, int j) {
        // 若区间为空，代表无目标元素，则返回 -1
        if (i > j) {
            return -1;
        }
        // 计算中点索引 m
        int m = (i + j) / 2;
        if (nums[m] < target) {
            // 递归子问题 f(m+1, j)
            return dfs(nums, target, m + 1, j);
        } else if (nums[m] > target) {
            // 递归子问题 f(i, m-1)
            return dfs(nums, target, i, m - 1);
        } else {
            // 找到目标元素，返回其索引
            return m;
        }
    }
    /* 二分查找 */
    public int binarySearch(int[] nums, int target) {
        int n = nums.Length;
        // 求解问题 f(0, n-1)
        return dfs(nums, target, 0, n - 1);
    }
    [Test]
    public void Test() {
        int target = 6;
        int[] nums = { 1, 3, 6, 8, 12, 15, 23, 26, 31, 35 };
        // 二分查找（双闭区间）
        int index = binarySearch(nums, target);
        Console.WriteLine("目标元素 6 的索引 = " + index);
    }
 }
--- a/codes/csharp/chapter_divide_and_conquer/build_tree.cs
+++ b/codes/csharp/chapter_divide_and_conquer/build_tree.cs
@ -0,0 +1,49 @@
 /**
 * File: build_tree.cs
 * Created Time: 2023-07-18
 * Author: hpstory (hpstory1024@163.com)
 */
 namespace hello_algo.chapter_divide_and_conquer;
 public class build_tree {
    /* 构建二叉树：分治 */
    public TreeNode dfs(int[] preorder, int[] inorder, Dictionary<int, int> hmap, int i, int l, int r) {
        // 子树区间为空时终止
        if (r - l < 0)
            return null;
        // 初始化根节点
        TreeNode root = new TreeNode(preorder[i]);
        // 查询 m ，从而划分左右子树
        int m = hmap[preorder[i]];
        // 子问题：构建左子树
        root.left = dfs(preorder, inorder, hmap, i + 1, l, m - 1);
        // 子问题：构建右子树
        root.right = dfs(preorder, inorder, hmap, i + 1 + m - l, m + 1, r);
        // 返回根节点
        return root;
    }
    /* 构建二叉树 */
    public TreeNode buildTree(int[] preorder, int[] inorder) {
        // 初始化哈希表，存储 inorder 元素到索引的映射
        Dictionary<int, int> hmap = new Dictionary<int, int>();
        for (int i = 0; i < inorder.Length; i++) {
            hmap.TryAdd(inorder[i], i);
        }
        TreeNode root = dfs(preorder, inorder, hmap, 0, 0, inorder.Length - 1);
        return root;
    }
    [Test]
    public void Test() {
        int[] preorder = { 3, 9, 2, 1, 7 };
        int[] inorder = { 9, 3, 1, 2, 7 };
        Console.WriteLine("前序遍历 = " + string.Join(", ", preorder));
        Console.WriteLine("中序遍历 = " + string.Join(", ", inorder));
        TreeNode root = buildTree(preorder, inorder);
        Console.WriteLine("构建的二叉树为：");
        PrintUtil.PrintTree(root);
    }
 }
--- a/codes/csharp/chapter_divide_and_conquer/hanota.cs
+++ b/codes/csharp/chapter_divide_and_conquer/hanota.cs
@ -0,0 +1,59 @@
 /**
 * File: hanota.cs
 * Created Time: 2023-07-18
 * Author: hpstory (hpstory1024@163.com)
 */
 namespace hello_algo.chapter_divide_and_conquer;
 public class hanota {
    /* 移动一个圆盘 */
    public void move(List<int> src, List<int> tar) {
        // 从 src 顶部拿出一个圆盘
        int pan = src[^1];
        src.RemoveAt(src.Count - 1);
        // 将圆盘放入 tar 顶部
        tar.Add(pan);
    }
    /* 求解汉诺塔：问题 f(i) */
    public void dfs(int i, List<int> src, List<int> buf, List<int> tar) {
        // 若 src 只剩下一个圆盘，则直接将其移到 tar
        if (i == 1) {
            move(src, tar);
            return;
        }
        // 子问题 f(i-1) ：将 src 顶部 i-1 个圆盘借助 tar 移到 buf
        dfs(i - 1, src, tar, buf);
        // 子问题 f(1) ：将 src 剩余一个圆盘移到 tar
        move(src, tar);
        // 子问题 f(i-1) ：将 buf 顶部 i-1 个圆盘借助 src 移到 tar
        dfs(i - 1, buf, src, tar);
    }
    /* 求解汉诺塔 */
    public void solveHanota(List<int> A, List<int> B, List<int> C) {
        int n = A.Count;
        // 将 A 顶部 n 个圆盘借助 B 移到 C
        dfs(n, A, B, C);
    }
    [Test]
    public void Test() {
        // 列表尾部是柱子顶部
        List<int> A = new List<int> { 5, 4, 3, 2, 1 };
        List<int> B = new List<int>();
        List<int> C = new List<int>();
        Console.WriteLine("初始状态下：");
        Console.WriteLine("A = " + string.Join(", ", A));
        Console.WriteLine("B = " + string.Join(", ", B));
        Console.WriteLine("C = " + string.Join(", ", C));
        solveHanota(A, B, C);
        Console.WriteLine("圆盘移动完成后：");
        Console.WriteLine("A = " + string.Join(", ", A));
        Console.WriteLine("B = " + string.Join(", ", B));
        Console.WriteLine("C = " + string.Join(", ", C));
    }
 }
--- a/docs/chapter_divide_and_conquer/hanota_problem.md
+++ b/docs/chapter_divide_and_conquer/hanota_problem.md
@ -153,7 +153,7 @@
    [class]{hanota}-[func]{dfs}
-    [class]{hanota}-[func]{hanota}
+    [class]{hanota}-[func]{solveHanota}
    ```
 === "Swift"