feat(chapter_backtracking): Add js and ts codes for chapter 13.3 (#667)

* feat(chapter_dynamic_programming): Add js and ts codes for chapter 14.1 * style(chapter_dynamic_programming): format code * refactor(chapter_dynamic_programming): remove main definition and add type * feat(chapter_backtracking): Add js and ts codes for chapter 13.3 * feat(chapter_divide_and_conquer): Add js and ts codes for chapter 12.2 * feat(chapter_divide_and_conquer): Add js and ts codes for chapter 12.3 * feat(chapter_divide_and_conquer): Add js and ts codes for chapter 12.4 * style(chapter_divide_and_conquer): fix typo * refactor: Use === instead of == in js and ts
1 year ago · 70784a1ec3
parent c7c33f19ac
commit 70784a1ec3
31 changed files with 610 additions and 25 deletions
--- a/codes/javascript/chapter_array_and_linkedlist/array.js
+++ b/codes/javascript/chapter_array_and_linkedlist/array.js
@ -61,7 +61,7 @@ function traverse(nums) {
 /* 在数组中查找指定元素 */
 function find(nums, target) {
    for (let i = 0; i < nums.length; i++) {
-        if (nums[i] == target) return i;
+        if (nums[i] === target) return i;
    }
    return -1;
 }
--- a/codes/javascript/chapter_backtracking/subset_sum_i.js
+++ b/codes/javascript/chapter_backtracking/subset_sum_i.js
@ -0,0 +1,46 @@
 /**
 * File: subset_sum_i.js
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 回溯算法：子集和 I */
 function backtrack(state, target, choices, start, res) {
    // 子集和等于 target 时，记录解
    if (target === 0) {
        res.push([...state]);
        return;
    }
    // 遍历所有选择
    // 剪枝二：从 start 开始遍历，避免生成重复子集
    for (let i = start; i < choices.length; i++) {
        // 剪枝一：若子集和超过 target ，则直接结束循环
        // 这是因为数组已排序，后边元素更大，子集和一定超过 target
        if (target - choices[i] < 0) {
            break;
        }
        // 尝试：做出选择，更新 target, start
        state.push(choices[i]);
        // 进行下一轮选择
        backtrack(state, target - choices[i], choices, i, res);
        // 回退：撤销选择，恢复到之前的状态
        state.pop();
    }
 }
 /* 求解子集和 I */
 function subsetSumI(nums, target) {
    const state = []; // 状态（子集）
    nums.sort(); // 对 nums 进行排序
    const start = 0; // 遍历起始点
    const res = []; // 结果列表（子集列表）
    backtrack(state, target, nums, start, res);
    return res;
 }
 /* Driver Code */
 const nums = [3, 4, 5];
 const target = 9;
 const res = subsetSumI(nums, target);
 console.log(`输入数组 nums = ${JSON.stringify(nums)}, target = ${target}`);
 console.log(`所有和等于 ${target} 的子集 res = ${JSON.stringify(res)}`);
--- a/codes/javascript/chapter_backtracking/subset_sum_i_naive.js
+++ b/codes/javascript/chapter_backtracking/subset_sum_i_naive.js
@ -0,0 +1,44 @@
 /**
 * File: subset_sum_i_naive.js
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 回溯算法：子集和 I */
 function backtrack(state, target, total, choices, res) {
    // 子集和等于 target 时，记录解
    if (total === target) {
        res.push([...state]);
        return;
    }
    // 遍历所有选择
    for (let i = 0; i < choices.length; i++) {
        // 剪枝：若子集和超过 target ，则跳过该选择
        if (total + choices[i] > target) {
            continue;
        }
        // 尝试：做出选择，更新元素和 total
        state.push(choices[i]);
        // 进行下一轮选择
        backtrack(state, target, total + choices[i], choices, res);
        // 回退：撤销选择，恢复到之前的状态
        state.pop();
    }
 }
 /* 求解子集和 I（包含重复子集） */
 function subsetSumINaive(nums, target) {
    const state = []; // 状态（子集）
    const total = 0; // 子集和
    const res = []; // 结果列表（子集列表）
    backtrack(state, target, total, nums, res);
    return res;
 }
 /* Driver Code */
 const nums = [3, 4, 5];
 const target = 9;
 const res = subsetSumINaive(nums, target);
 console.log(`输入数组 nums = ${JSON.stringify(nums)}, target = ${target}`);
 console.log(`所有和等于 ${target} 的子集 res = ${JSON.stringify(res)}`);
 console.log('请注意，该方法输出的结果包含重复集合');
--- a/codes/javascript/chapter_backtracking/subset_sum_ii.js
+++ b/codes/javascript/chapter_backtracking/subset_sum_ii.js
@ -0,0 +1,51 @@
 /**
 * File: subset_sum_ii.js
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 回溯算法：子集和 II */
 function backtrack(state, target, choices, start, res) {
    // 子集和等于 target 时，记录解
    if (target === 0) {
        res.push([...state]);
        return;
    }
    // 遍历所有选择
    // 剪枝二：从 start 开始遍历，避免生成重复子集
    // 剪枝三：从 start 开始遍历，避免重复选择同一元素
    for (let i = start; i < choices.length; i++) {
        // 剪枝一：若子集和超过 target ，则直接结束循环
        // 这是因为数组已排序，后边元素更大，子集和一定超过 target
        if (target - choices[i] < 0) {
            break;
        }
        // 剪枝四：如果该元素与左边元素相等，说明该搜索分支重复，直接跳过
        if (i > start && choices[i] === choices[i - 1]) {
            continue;
        }
        // 尝试：做出选择，更新 target, start
        state.push(choices[i]);
        // 进行下一轮选择
        backtrack(state, target - choices[i], choices, i + 1, res);
        // 回退：撤销选择，恢复到之前的状态
        state.pop();
    }
 }
 /* 求解子集和 II */
 function subsetSumII(nums, target) {
    const state = []; // 状态（子集）
    nums.sort(); // 对 nums 进行排序
    const start = 0; // 遍历起始点
    const res = []; // 结果列表（子集列表）
    backtrack(state, target, nums, start, res);
    return res;
 }
 /* Driver Code */
 const nums = [4, 4, 5];
 const target = 9;
 const res = subsetSumII(nums, target);
 console.log(`输入数组 nums = ${JSON.stringify(nums)}, target = ${target}`);
 console.log(`所有和等于 ${target} 的子集 res = ${JSON.stringify(res)}`);
--- a/codes/javascript/chapter_computational_complexity/time_complexity.js
+++ b/codes/javascript/chapter_computational_complexity/time_complexity.js
@ -77,7 +77,7 @@ function exponential(n) {
 /* 指数阶（递归实现） */
 function expRecur(n) {
-    if (n == 1) return 1;
+    if (n === 1) return 1;
    return expRecur(n - 1) + expRecur(n - 1) + 1;
 }
@ -109,7 +109,7 @@ function linearLogRecur(n) {
 /* 阶乘阶（递归实现） */
 function factorialRecur(n) {
-    if (n == 0) return 1;
+    if (n === 0) return 1;
    let count = 0;
    // 从 1 个分裂出 n 个
    for (let i = 0; i < n; i++) {
--- a/codes/javascript/chapter_divide_and_conquer/binary_search_recur.js
+++ b/codes/javascript/chapter_divide_and_conquer/binary_search_recur.js
@ -0,0 +1,39 @@
 /**
 * File: binary_search_recur.js
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 二分查找：问题 f(i, j) */
 function dfs(nums, target, i, 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
    const m = i + ((j - i) >> 1);
    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 */
 function binarySearch(nums, target) {
    const n = nums.length;
    // 求解问题 f(0, n-1)
    return dfs(nums, target, 0, n - 1);
 }
 /* Driver Code */
 const target = 6;
 const nums = [1, 3, 6, 8, 12, 15, 23, 26, 31, 35];
 // 二分查找（双闭区间）
 const index = binarySearch(nums, target);
 console.log(`目标元素 6 的索引 = ${index}`);
--- a/codes/javascript/chapter_divide_and_conquer/build_tree.js
+++ b/codes/javascript/chapter_divide_and_conquer/build_tree.js
@ -0,0 +1,44 @@
 /**
 * File: build_tree.js
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 const { printTree } = require('../modules/PrintUtil');
 const { TreeNode } = require('../modules/TreeNode');
 /* 构建二叉树：分治 */
 function dfs(preorder, inorder, hmap, i, l, r) {
    // 子树区间为空时终止
    if (r - l < 0) return null;
    // 初始化根节点
    const root = new TreeNode(preorder[i]);
    // 查询 m ，从而划分左右子树
    const m = hmap.get(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 */
 function buildTree(preorder, inorder) {
    // 初始化哈希表，存储 inorder 元素到索引的映射
    let hmap = new Map();
    for (let i = 0; i < inorder.length; i++) {
        hmap.set(inorder[i], i);
    }
    const root = dfs(preorder, inorder, hmap, 0, 0, inorder.length - 1);
    return root;
 }
 /* Driver Code */
 const preorder = [3, 9, 2, 1, 7];
 const inorder = [9, 3, 1, 2, 7];
 console.log('前序遍历 = ' + JSON.stringify(preorder));
 console.log('中序遍历 = ' + JSON.stringify(inorder));
 const root = buildTree(preorder, inorder);
 console.log('构建的二叉树为：');
 printTree(root);
--- a/codes/javascript/chapter_divide_and_conquer/hanota.js
+++ b/codes/javascript/chapter_divide_and_conquer/hanota.js
@ -0,0 +1,52 @@
 /**
 * File: hanota.js
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 移动一个圆盘 */
 function move(src, tar) {
    // 从 src 顶部拿出一个圆盘
    const pan = src.pop();
    // 将圆盘放入 tar 顶部
    tar.push(pan);
 }
 /* 求解汉诺塔：问题 f(i) */
 function dfs(i, src, buf, 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 */
 function solveHanota(A, B, C) {
    const n = A.length;
    // 将 A 顶部 n 个圆盘借助 B 移到 C
    dfs(n, A, B, C);
 }
 /* Driver Code */
 // 列表尾部是柱子顶部
 const A = [5, 4, 3, 2, 1];
 const B = [];
 const C = [];
 console.log('初始状态下：');
 console.log(`A = ${JSON.stringify(A)}`);
 console.log(`B = ${JSON.stringify(B)}`);
 console.log(`C = ${JSON.stringify(C)}`);
 solveHanota(A, B, C);
 console.log('圆盘移动完成后：');
 console.log(`A = ${JSON.stringify(A)}`);
 console.log(`B = ${JSON.stringify(B)}`);
 console.log(`C = ${JSON.stringify(C)}`);
--- a/codes/javascript/chapter_dynamic_programming/climbing_stairs_dfs.js
+++ b/codes/javascript/chapter_dynamic_programming/climbing_stairs_dfs.js
@ -7,7 +7,7 @@
 /* 搜索 */
 function dfs(i) {
    // 已知 dp[1] 和 dp[2] ，返回之
-    if (i == 1 || i == 2) return i;
+    if (i === 1 || i === 2) return i;
    // dp[i] = dp[i-1] + dp[i-2]
    const count = dfs(i - 1) + dfs(i - 2);
    return count;
--- a/codes/javascript/chapter_dynamic_programming/climbing_stairs_dfs_mem.js
+++ b/codes/javascript/chapter_dynamic_programming/climbing_stairs_dfs_mem.js
@ -7,7 +7,7 @@
 /* 记忆化搜索 */
 function dfs(i, mem) {
    // 已知 dp[1] 和 dp[2] ，返回之
-    if (i == 1 || i == 2) return i;
+    if (i === 1 || i === 2) return i;
    // 若存在记录 dp[i] ，则直接返回之
    if (mem[i] != -1) return mem[i];
    // dp[i] = dp[i-1] + dp[i-2]
--- a/codes/javascript/chapter_dynamic_programming/climbing_stairs_dp.js
+++ b/codes/javascript/chapter_dynamic_programming/climbing_stairs_dp.js
@ -6,7 +6,7 @@
 /* 爬楼梯：动态规划 */
 function climbingStairsDP(n) {
-    if (n == 1 || n == 2) return n;
+    if (n === 1 || n === 2) return n;
    // 初始化 dp 表，用于存储子问题的解
    const dp = new Array(n + 1).fill(-1);
    // 初始状态：预设最小子问题的解
@ -21,7 +21,7 @@ function climbingStairsDP(n) {
 /* 爬楼梯：状态压缩后的动态规划 */
 function climbingStairsDPComp(n) {
-    if (n == 1 || n == 2) return n;
+    if (n === 1 || n === 2) return n;
    let a = 1,
        b = 2;
    for (let i = 3; i <= n; i++) {
--- a/codes/javascript/chapter_graph/graph_adjacency_matrix.js
+++ b/codes/javascript/chapter_graph/graph_adjacency_matrix.js
@ -69,7 +69,7 @@ class GraphAdjMat {
        if (i < 0 || j < 0 || i >= this.size() || j >= this.size() || i === j) {
            throw new RangeError('Index Out Of Bounds Exception');
        }
-        // 在无向图中，邻接矩阵沿主对角线对称，即满足 (i, j) == (j, i)
+        // 在无向图中，邻接矩阵沿主对角线对称，即满足 (i, j) === (j, i)
        this.adjMat[i][j] = 1;
        this.adjMat[j][i] = 1;
    }
--- a/codes/javascript/chapter_heap/my_heap.js
+++ b/codes/javascript/chapter_heap/my_heap.js
@ -103,7 +103,7 @@ class MaxHeap {
            if (l < this.size() && this.#maxHeap[l] > this.#maxHeap[ma]) ma = l;
            if (r < this.size() && this.#maxHeap[r] > this.#maxHeap[ma]) ma = r;
            // 若节点 i 最大或索引 l, r 越界，则无需继续堆化，跳出
-            if (ma == i) break;
+            if (ma === i) break;
            // 交换两节点
            this.#swap(i, ma);
            // 循环向下堆化
--- a/codes/javascript/chapter_searching/binary_search_edge.js
+++ b/codes/javascript/chapter_searching/binary_search_edge.js
@ -18,7 +18,7 @@ function binarySearchLeftEdge(nums, target) {
            j = m - 1; // 首个小于 target 的元素在区间 [i, m-1] 中
        }
    }
-    if (i == nums.length || nums[i] != target) {
+    if (i === nums.length || nums[i] != target) {
        return -1; // 未找到目标元素，返回 -1
    }
    return i;
--- a/codes/javascript/chapter_stack_and_queue/array_queue.js
+++ b/codes/javascript/chapter_stack_and_queue/array_queue.js
@ -26,12 +26,12 @@ class ArrayQueue {
    /* 判断队列是否为空 */
    empty() {
-        return this.#queSize == 0;
+        return this.#queSize === 0;
    }
    /* 入队 */
    push(num) {
-        if (this.size == this.capacity) {
+        if (this.size === this.capacity) {
            console.log('队列已满');
            return;
        }
--- a/codes/javascript/chapter_stack_and_queue/linkedlist_stack.js
+++ b/codes/javascript/chapter_stack_and_queue/linkedlist_stack.js
@ -22,7 +22,7 @@ class LinkedListStack {
    /* 判断栈是否为空 */
    isEmpty() {
-        return this.size == 0;
+        return this.size === 0;
    }
    /* 入栈 */
--- a/codes/typescript/chapter_backtracking/subset_sum_i.ts
+++ b/codes/typescript/chapter_backtracking/subset_sum_i.ts
@ -0,0 +1,54 @@
 /**
 * File: subset_sum_i.ts
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 回溯算法：子集和 I */
 function backtrack(
    state: number[],
    target: number,
    choices: number[],
    start: number,
    res: number[][]
 ): void {
    // 子集和等于 target 时，记录解
    if (target === 0) {
        res.push([...state]);
        return;
    }
    // 遍历所有选择
    // 剪枝二：从 start 开始遍历，避免生成重复子集
    for (let i = start; i < choices.length; i++) {
        // 剪枝一：若子集和超过 target ，则直接结束循环
        // 这是因为数组已排序，后边元素更大，子集和一定超过 target
        if (target - choices[i] < 0) {
            break;
        }
        // 尝试：做出选择，更新 target, start
        state.push(choices[i]);
        // 进行下一轮选择
        backtrack(state, target - choices[i], choices, i, res);
        // 回退：撤销选择，恢复到之前的状态
        state.pop();
    }
 }
 /* 求解子集和 I */
 function subsetSumI(nums: number[], target: number): number[][] {
    const state = []; // 状态（子集）
    nums.sort(); // 对 nums 进行排序
    const start = 0; // 遍历起始点
    const res = []; // 结果列表（子集列表）
    backtrack(state, target, nums, start, res);
    return res;
 }
 /* Driver Code */
 const nums = [3, 4, 5];
 const target = 9;
 const res = subsetSumI(nums, target);
 console.log(`输入数组 nums = ${JSON.stringify(nums)}, target = ${target}`);
 console.log(`所有和等于 ${target} 的子集 res = ${JSON.stringify(res)}`);
 export {};
--- a/codes/typescript/chapter_backtracking/subset_sum_i_naive.ts
+++ b/codes/typescript/chapter_backtracking/subset_sum_i_naive.ts
@ -0,0 +1,52 @@
 /**
 * File: subset_sum_i_naive.ts
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 回溯算法：子集和 I */
 function backtrack(
    state: number[],
    target: number,
    total: number,
    choices: number[],
    res: number[][]
 ): void {
    // 子集和等于 target 时，记录解
    if (total === target) {
        res.push([...state]);
        return;
    }
    // 遍历所有选择
    for (let i = 0; i < choices.length; i++) {
        // 剪枝：若子集和超过 target ，则跳过该选择
        if (total + choices[i] > target) {
            continue;
        }
        // 尝试：做出选择，更新元素和 total
        state.push(choices[i]);
        // 进行下一轮选择
        backtrack(state, target, total + choices[i], choices, res);
        // 回退：撤销选择，恢复到之前的状态
        state.pop();
    }
 }
 /* 求解子集和 I（包含重复子集） */
 function subsetSumINaive(nums: number[], target: number): number[][] {
    const state = []; // 状态（子集）
    const total = 0; // 子集和
    const res = []; // 结果列表（子集列表）
    backtrack(state, target, total, nums, res);
    return res;
 }
 /* Driver Code */
 const nums = [3, 4, 5];
 const target = 9;
 const res = subsetSumINaive(nums, target);
 console.log(`输入数组 nums = ${JSON.stringify(nums)}, target = ${target}`);
 console.log(`所有和等于 ${target} 的子集 res = ${JSON.stringify(res)}`);
 console.log('请注意，该方法输出的结果包含重复集合');
 export {};
--- a/codes/typescript/chapter_backtracking/subset_sum_ii.ts
+++ b/codes/typescript/chapter_backtracking/subset_sum_ii.ts
@ -0,0 +1,59 @@
 /**
 * File: subset_sum_ii.ts
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 回溯算法：子集和 II */
 function backtrack(
    state: number[],
    target: number,
    choices: number[],
    start: number,
    res: number[][]
 ): void {
    // 子集和等于 target 时，记录解
    if (target === 0) {
        res.push([...state]);
        return;
    }
    // 遍历所有选择
    // 剪枝二：从 start 开始遍历，避免生成重复子集
    // 剪枝三：从 start 开始遍历，避免重复选择同一元素
    for (let i = start; i < choices.length; i++) {
        // 剪枝一：若子集和超过 target ，则直接结束循环
        // 这是因为数组已排序，后边元素更大，子集和一定超过 target
        if (target - choices[i] < 0) {
            break;
        }
        // 剪枝四：如果该元素与左边元素相等，说明该搜索分支重复，直接跳过
        if (i > start && choices[i] === choices[i - 1]) {
            continue;
        }
        // 尝试：做出选择，更新 target, start
        state.push(choices[i]);
        // 进行下一轮选择
        backtrack(state, target - choices[i], choices, i + 1, res);
        // 回退：撤销选择，恢复到之前的状态
        state.pop();
    }
 }
 /* 求解子集和 II */
 function subsetSumII(nums: number[], target: number): number[][] {
    const state = []; // 状态（子集）
    nums.sort(); // 对 nums 进行排序
    const start = 0; // 遍历起始点
    const res = []; // 结果列表（子集列表）
    backtrack(state, target, nums, start, res);
    return res;
 }
 /* Driver Code */
 const nums = [4, 4, 5];
 const target = 9;
 const res = subsetSumII(nums, target);
 console.log(`输入数组 nums = ${JSON.stringify(nums)}, target = ${target}`);
 console.log(`所有和等于 ${target} 的子集 res = ${JSON.stringify(res)}`);
 export {};
--- a/codes/typescript/chapter_computational_complexity/time_complexity.ts
+++ b/codes/typescript/chapter_computational_complexity/time_complexity.ts
@ -77,7 +77,7 @@ function exponential(n: number): number {
 /* 指数阶（递归实现） */
 function expRecur(n: number): number {
-    if (n == 1) return 1;
+    if (n === 1) return 1;
    return expRecur(n - 1) + expRecur(n - 1) + 1;
 }
@ -109,7 +109,7 @@ function linearLogRecur(n: number): number {
 /* 阶乘阶（递归实现） */
 function factorialRecur(n: number): number {
-    if (n == 0) return 1;
+    if (n === 0) return 1;
    let count = 0;
    // 从 1 个分裂出 n 个
    for (let i = 0; i < n; i++) {
--- a/codes/typescript/chapter_divide_and_conquer/binary_search_recur.ts
+++ b/codes/typescript/chapter_divide_and_conquer/binary_search_recur.ts
@ -0,0 +1,41 @@
 /**
 * File: binary_search_recur.ts
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 二分查找：问题 f(i, j) */
 function dfs(nums: number[], target: number, i: number, j: number): number {
    // 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
    const m = i + ((j - i) >> 1);
    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 */
 function binarySearch(nums: number[], target: number): number {
    const n = nums.length;
    // 求解问题 f(0, n-1)
    return dfs(nums, target, 0, n - 1);
 }
 /* Driver Code */
 const target = 6;
 const nums = [1, 3, 6, 8, 12, 15, 23, 26, 31, 35];
 // 二分查找（双闭区间）
 const index = binarySearch(nums, target);
 console.log(`目标元素 6 的索引 = ${index}`);
 export {};
--- a/codes/typescript/chapter_divide_and_conquer/build_tree.ts
+++ b/codes/typescript/chapter_divide_and_conquer/build_tree.ts
@ -0,0 +1,51 @@
 /**
 * File: build_tree.ts
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 import { printTree } from '../modules/PrintUtil';
 import { TreeNode } from '../modules/TreeNode';
 /* 构建二叉树：分治 */
 function dfs(
    preorder: number[],
    inorder: number[],
    hmap: Map<number, number>,
    i: number,
    l: number,
    r: number
 ): TreeNode | null {
    // 子树区间为空时终止
    if (r - l < 0) return null;
    // 初始化根节点
    const root: TreeNode = new TreeNode(preorder[i]);
    // 查询 m ，从而划分左右子树
    const m = hmap.get(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 */
 function buildTree(preorder: number[], inorder: number[]): TreeNode | null {
    // 初始化哈希表，存储 inorder 元素到索引的映射
    let hmap = new Map<number, number>();
    for (let i = 0; i < inorder.length; i++) {
        hmap.set(inorder[i], i);
    }
    const root = dfs(preorder, inorder, hmap, 0, 0, inorder.length - 1);
    return root;
 }
 /* Driver Code */
 const preorder = [3, 9, 2, 1, 7];
 const inorder = [9, 3, 1, 2, 7];
 console.log('前序遍历 = ' + JSON.stringify(preorder));
 console.log('中序遍历 = ' + JSON.stringify(inorder));
 const root = buildTree(preorder, inorder);
 console.log('构建的二叉树为：');
 printTree(root);
--- a/codes/typescript/chapter_divide_and_conquer/hanota.ts
+++ b/codes/typescript/chapter_divide_and_conquer/hanota.ts
@ -0,0 +1,52 @@
 /**
 * File: hanota.ts
 * Created Time: 2023-07-30
 * Author: yuan0221 (yl1452491917@gmail.com)
 */
 /* 移动一个圆盘 */
 function move(src: number[], tar: number[]): void {
    // 从 src 顶部拿出一个圆盘
    const pan = src.pop();
    // 将圆盘放入 tar 顶部
    tar.push(pan);
 }
 /* 求解汉诺塔：问题 f(i) */
 function dfs(i: number, src: number[], buf: number[], tar: number[]): void {
    // 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 */
 function solveHanota(A: number[], B: number[], C: number[]): void {
    const n = A.length;
    // 将 A 顶部 n 个圆盘借助 B 移到 C
    dfs(n, A, B, C);
 }
 /* Driver Code */
 // 列表尾部是柱子顶部
 const A = [5, 4, 3, 2, 1];
 const B = [];
 const C = [];
 console.log('初始状态下：');
 console.log(`A = ${JSON.stringify(A)}`);
 console.log(`B = ${JSON.stringify(B)}`);
 console.log(`C = ${JSON.stringify(C)}`);
 solveHanota(A, B, C);
 console.log('圆盘移动完成后：');
 console.log(`A = ${JSON.stringify(A)}`);
 console.log(`B = ${JSON.stringify(B)}`);
 console.log(`C = ${JSON.stringify(C)}`);
--- a/codes/typescript/chapter_dynamic_programming/climbing_stairs_dfs.ts
+++ b/codes/typescript/chapter_dynamic_programming/climbing_stairs_dfs.ts
@ -7,7 +7,7 @@
 /* 搜索 */
 function dfs(i: number): number {
    // 已知 dp[1] 和 dp[2] ，返回之
-    if (i == 1 || i == 2) return i;
+    if (i === 1 || i === 2) return i;
    // dp[i] = dp[i-1] + dp[i-2]
    const count = dfs(i - 1) + dfs(i - 2);
    return count;
--- a/codes/typescript/chapter_dynamic_programming/climbing_stairs_dfs_mem.ts
+++ b/codes/typescript/chapter_dynamic_programming/climbing_stairs_dfs_mem.ts
@ -7,7 +7,7 @@
 /* 记忆化搜索 */
 function dfs(i: number, mem: number[]): number {
    // 已知 dp[1] 和 dp[2] ，返回之
-    if (i == 1 || i == 2) return i;
+    if (i === 1 || i === 2) return i;
    // 若存在记录 dp[i] ，则直接返回之
    if (mem[i] != -1) return mem[i];
    // dp[i] = dp[i-1] + dp[i-2]
--- a/codes/typescript/chapter_dynamic_programming/climbing_stairs_dp.ts
+++ b/codes/typescript/chapter_dynamic_programming/climbing_stairs_dp.ts
@ -6,7 +6,7 @@
 /* 爬楼梯：动态规划 */
 function climbingStairsDP(n: number): number {
-    if (n == 1 || n == 2) return n;
+    if (n === 1 || n === 2) return n;
    // 初始化 dp 表，用于存储子问题的解
    const dp = new Array(n + 1).fill(-1);
    // 初始状态：预设最小子问题的解
@ -21,7 +21,7 @@ function climbingStairsDP(n: number): number {
 /* 爬楼梯：状态压缩后的动态规划 */
 function climbingStairsDPComp(n: number): number {
-    if (n == 1 || n == 2) return n;
+    if (n === 1 || n === 2) return n;
    let a = 1,
        b = 2;
    for (let i = 3; i <= n; i++) {
--- a/codes/typescript/chapter_graph/graph_adjacency_matrix.ts
+++ b/codes/typescript/chapter_graph/graph_adjacency_matrix.ts
@ -69,7 +69,7 @@ class GraphAdjMat {
        if (i < 0 || j < 0 || i >= this.size() || j >= this.size() || i === j) {
            throw new RangeError('Index Out Of Bounds Exception');
        }
-        // 在无向图中，邻接矩阵沿主对角线对称，即满足 (i, j) == (j, i)
+        // 在无向图中，邻接矩阵沿主对角线对称，即满足 (i, j) === (j, i)
        this.adjMat[i][j] = 1;
        this.adjMat[j][i] = 1;
    }
--- a/codes/typescript/chapter_heap/my_heap.ts
+++ b/codes/typescript/chapter_heap/my_heap.ts
@ -102,7 +102,7 @@ class MaxHeap {
            if (l < this.size() && this.maxHeap[l] > this.maxHeap[ma]) ma = l;
            if (r < this.size() && this.maxHeap[r] > this.maxHeap[ma]) ma = r;
            // 若节点 i 最大或索引 l, r 越界，则无需继续堆化，跳出
-            if (ma == i) break;
+            if (ma === i) break;
            // 交换两节点
            this.swap(i, ma);
            // 循环向下堆化
--- a/codes/typescript/chapter_searching/binary_search_edge.ts
+++ b/codes/typescript/chapter_searching/binary_search_edge.ts
@ -17,7 +17,7 @@ function binarySearchLeftEdge(nums: number[], target: number): number {
            j = m - 1;  // 首个小于 target 的元素在区间 [i, m-1] 中
        }
    }
-    if (i == nums.length || nums[i] != target) {
+    if (i === nums.length || nums[i] != target) {
        return -1;  // 未找到目标元素，返回 -1
    }
    return i;
--- a/codes/typescript/chapter_stack_and_queue/array_queue.ts
+++ b/codes/typescript/chapter_stack_and_queue/array_queue.ts
@ -27,12 +27,12 @@ class ArrayQueue {
    /* 判断队列是否为空 */
    empty(): boolean {
-        return this.queSize == 0;
+        return this.queSize === 0;
    }
    /* 入队 */
    push(num: number): void {
-        if (this.size == this.capacity) {
+        if (this.size === this.capacity) {
            console.log('队列已满');
            return;
        }
--- a/codes/typescript/chapter_stack_and_queue/linkedlist_stack.ts
+++ b/codes/typescript/chapter_stack_and_queue/linkedlist_stack.ts
@ -22,7 +22,7 @@ class LinkedListStack {
    /* 判断栈是否为空 */
    isEmpty(): boolean {
-        return this.size == 0;
+        return this.size === 0;
    }
    /* 入栈 */