feat: iteration & recursion in Zig (#804)

* iteration & recursion in Zig * missing part in time_complexity.md (zig) * build.zig sync * Update recursion.zig * Update iteration.zig --------- Co-authored-by: Yudong Jin <krahets@163.com>
2025-02-02 22:43:50 +08:00 · 2023-10-24 11:49:13 -04:00 · 2023-10-24 11:49:13 -04:00 · 2035aa0cf1
commit 2035aa0cf1
parent 19023148ba
4 changed files with 215 additions and 3 deletions
--- a/codes/zig/build.zig
+++ b/codes/zig/build.zig
@ -24,6 +24,14 @@ pub fn build(b: *std.Build) void {
        // Run Command: zig build run_space_complexity -Doptimize=ReleaseSafe
        .{ .name = "space_complexity", .path = "chapter_computational_complexity/space_complexity.zig" },
        // Source File: "chapter_computational_complexity/iteration.zig"
        // Run Command: zig build run_iteration -Doptimize=ReleaseFast
        .{ .name = "iteration", .path = "chapter_computational_complexity/iteration.zig" },
        // Source File: "chapter_computational_complexity/recursion.zig"
        // Run Command: zig build run_recursion -Doptimize=ReleaseFast
        .{ .name = "recursion", .path = "chapter_computational_complexity/recursion.zig" },
        // Source File: "chapter_array_and_linkedlist/array.zig"
        // Run Command: zig build run_array -Doptimize=ReleaseSafe
        .{ .name = "array", .path = "chapter_array_and_linkedlist/array.zig" },
--- a/codes/zig/chapter_computational_complexity/iteration.zig
+++ b/codes/zig/chapter_computational_complexity/iteration.zig
@ -0,0 +1,77 @@
 // File: iteration.zig
 // Created Time: 2023-09-27
 // Author: QiLOL (pikaqqpika@gmail.com)
 const std = @import("std");
 const Allocator = std.mem.Allocator;
 // for 循环
 fn forLoop(n: usize) i32 {
    var res: i32 = 0;
    // 循环求和 1, 2, ..., n-1, n
    for (1..n+1) |i| {
        res = res + @as(i32, @intCast(i));
    }
    return res;
 } 
 // while 循环
 fn whileLoop(n: i32) i32 {
    var res: i32 = 0;
    var i: i32 = 1; // 初始化条件变量
    // 循环求和 1, 2, ..., n-1, n
    while (i <= n) {
        res += @intCast(i);
        i += 1;
    }
    return res;
 }
 //  while 循环（两次更新）
 fn whileLoopII(n: i32) i32 {
    var res: i32 = 0;
    var i: i32 = 1; // 初始化条件变量
    // 循环求和 1, 4, ...
    while (i <= n) {
        res += @intCast(i);
        // 更新条件变量
        i += 1;
        i *= 2;
    }
    return res;
 }
 // 双层 for 循环
 fn nestedForLoop(allocator: Allocator, n: usize) ![]const u8 {
    var res = std.ArrayList(u8).init(allocator);
    defer res.deinit();
    var buffer: [20]u8 = undefined;
    // 循环 i = 1, 2, ..., n-1, n
    for (1..n+1) |i| {
        // 循环 j = 1, 2, ..., n-1, n
        for (1..n+1) |j| {
            var _str = try std.fmt.bufPrint(&buffer, "({d}, {d}), ", .{i, j});
            try res.appendSlice(_str);
        }
    }
    return res.toOwnedSlice();
 }
 // Driver Code
 pub fn main() !void {
    const n: i32 = 5;
    var res: i32 = 0;
    res = forLoop(n);
    std.debug.print("\nfor 循环的求和结果 res = {}\n", .{res});
    res = whileLoop(n);
    std.debug.print("\nwhile 循环的求和结果 res = {}\n", .{res});
    res = whileLoopII(n);
    std.debug.print("\nwhile 循环（两次更新）求和结果 res = {}\n", .{res});
    const allocator = std.heap.page_allocator;
    const resStr = try nestedForLoop(allocator, n);
    std.debug.print("\n双层 for 循环的遍历结果 {s}\n", .{resStr});
 }
--- a/codes/zig/chapter_computational_complexity/recursion.zig
+++ b/codes/zig/chapter_computational_complexity/recursion.zig
@ -0,0 +1,78 @@
 // File: recursion.zig
 // Created Time: 2023-09-27
 // Author: QiLOL (pikaqqpika@gmail.com)
 const std = @import("std");
 // 递归函数
 fn recur(n: i32) i32 {
    // 终止条件
    if (n == 1) {
        return 1;
    }
    // 递：递归调用
    var res: i32 = recur(n - 1);
    // 归：返回结果
    return n + res;
 }
 // 使用迭代模拟递归
 fn forLoopRecur(comptime n: i32) i32 {
    // 使用一个显式的栈来模拟系统调用栈
    var stack: [n]i32 = undefined;
    var res: i32 = 0;
    // 递：递归调用
    var i: usize = n;
    while (i > 0) {
        stack[i - 1] = @intCast(i);
        i -= 1;
    }
    // 归：返回结果
    var index: usize = n;
    while (index > 0) {
        index -= 1;
        res += stack[index];
    }
    // res = 1+2+3+...+n
    return res;
 }
 // 尾递归函数
 fn tailRecur(n: i32, res: i32) i32 {
    // 终止条件
    if (n == 0) {
        return res;
    }
    // 尾递归调用
    return tailRecur(n - 1, res + n);
 }
 // 斐波那契数列
 fn fib(n: i32) i32 {
    // 终止条件 f(1) = 0, f(2) = 1
    if (n == 1 or n == 2) {
        return n - 1;
    }
    // 递归调用 f(n) = f(n-1) + f(n-2)
    var res: i32 = fib(n - 1) + fib(n - 2);
    // 返回结果 f(n)
    return res;
 }
 // Driver Code
 pub fn main() !void {
    const n: i32 = 5;
    var res: i32 = 0;
    res = recur(n);
    std.debug.print("\n递归函数的求和结果 res = {}\n", .{recur(n)});
    res = forLoopRecur(n);
    std.debug.print("\n使用迭代模拟递归的求和结果 res = {}\n", .{forLoopRecur(n)});
    res = tailRecur(n, 0);
    std.debug.print("\n尾递归函数的求和结果 res = {}\n", .{tailRecur(n, 0)});
    res = fib(n);
    std.debug.print("\n斐波那契数列的第 {} 项为 {}\n", .{n, fib(n)});
 }
--- a/docs/chapter_computational_complexity/time_complexity.md
+++ b/docs/chapter_computational_complexity/time_complexity.md
@ -174,7 +174,16 @@
 === "Zig"
    ```zig title=""
-
+    // 在某运行平台下
    fn algorithm(n: usize) void {
        var a: i32 = 2; // 1 ns
        a += 1; // 1 ns
        a *= 2; // 10 ns
        // 循环 n 次
        for (0..n) |_| { // 1 ns
            std.debug.print("{}\n", .{0}); // 5 ns
        }
    }
    ```
 根据以上方法，可以得到算法运行时间为 $6n + 12$ ns ：
@ -423,7 +432,24 @@ $$
 === "Zig"
    ```zig title=""
-
+    // 算法 A 的时间复杂度：常数阶
    fn algorithm_A(n: usize) void {
        _ = n;
        std.debug.print("{}\n", .{0});
    }
    // 算法 B 的时间复杂度：线性阶
    fn algorithm_B(n: i32) void {
        for (0..n) |_| {
            std.debug.print("{}\n", .{0});
        }
    }
    // 算法 C 的时间复杂度：常数阶
    fn algorithm_C(n: i32) void {
        _ = n;
        for (0..1000000) |_| { 
            std.debug.print("{}\n", .{0});
        }
    }
    ```
 下图展示了以上三个算法函数的时间复杂度。
@ -600,7 +626,15 @@ $$
 === "Zig"
    ```zig title=""
-
+    fn algorithm(n: usize) void {
        var a: i32 = 1; // +1
        a += 1; // +1
        a *= 2; // +1
        // 循环 n 次
        for (0..n) |_| { // +1（每轮都执行 i ++）
            std.debug.print("{}\n", .{0}); // +1
        }
    }
    ```
 设算法的操作数量是一个关于输入数据大小 $n$ 的函数，记为 $T(n)$ ，则以上函数的的操作数量为：
@ -849,7 +883,22 @@ $T(n)$ 是一次函数，说明其运行时间的增长趋势是线性的，因
 === "Zig"
    ```zig title=""
    fn algorithm(n: usize) void {
        var a: i32 = 1;     // +0（技巧 1）
        a = a + @as(i32, @intCast(n));        // +0（技巧 1）
        // +n（技巧 2）
        for(0..(5 * n + 1)) |_| {
            std.debug.print("{}\n", .{0}); 
        }
        // +n*n（技巧 3）
        for(0..(2 * n)) |_| {
            for(0..(n + 1)) |_| {
                std.debug.print("{}\n", .{0}); 
            }
        }
    }
    ```
 以下公式展示了使用上述技巧前后的统计结果，两者推出的时间复杂度都为 $O(n^2)$ 。