hello-algo/zh-hant/codes/zig/chapter_heap/heap.zig

// File: heap.zig
// Created Time: 2023-01-14
// Author: codingonion (coderonion@gmail.com)

const std = @import("std");
const inc = @import("include");

fn lessThan(context: void, a: i32, b: i32) std.math.Order {
    _ = context;
    return std.math.order(a, b);
}

fn greaterThan(context: void, a: i32, b: i32) std.math.Order {
    return lessThan(context, a, b).invert();
}

fn testPush(comptime T: type, mem_allocator: std.mem.Allocator, heap: anytype, val: T) !void {
    try heap.add(val);  //元素入堆積
    std.debug.print("\n元素 {} 入堆積後\n", .{val});
    try inc.PrintUtil.printHeap(T, mem_allocator, heap);
}

fn testPop(comptime T: type, mem_allocator: std.mem.Allocator, heap: anytype) !void {
    var val = heap.remove();    //堆積頂元素出堆積
    std.debug.print("\n堆積頂元素 {} 出堆積後\n", .{val});
    try inc.PrintUtil.printHeap(T, mem_allocator, heap);
}

// Driver Code
pub fn main() !void {
    // 初始化記憶體分配器
    var mem_arena = std.heap.ArenaAllocator.init(std.heap.page_allocator);
    defer mem_arena.deinit();
    const mem_allocator = mem_arena.allocator();

    // 初始化堆積
    // 初始化小頂堆積
    const PQlt = std.PriorityQueue(i32, void, lessThan);
    var min_heap = PQlt.init(std.heap.page_allocator, {});
    defer min_heap.deinit();
    // 初始化大頂堆積
    const PQgt = std.PriorityQueue(i32, void, greaterThan);
    var max_heap = PQgt.init(std.heap.page_allocator, {});
    defer max_heap.deinit();

    std.debug.print("\n以下測試樣例為大頂堆積", .{});

    // 元素入堆積
    try testPush(i32, mem_allocator, &max_heap, 1);
    try testPush(i32, mem_allocator, &max_heap, 3);
    try testPush(i32, mem_allocator, &max_heap, 2);
    try testPush(i32, mem_allocator, &max_heap, 5);
    try testPush(i32, mem_allocator, &max_heap, 4);

    // 獲取堆積頂元素
    var peek = max_heap.peek().?;
    std.debug.print("\n堆積頂元素為 {}\n", .{peek});

    // 堆積頂元素出堆積
    try testPop(i32, mem_allocator, &max_heap);
    try testPop(i32, mem_allocator, &max_heap);
    try testPop(i32, mem_allocator, &max_heap);
    try testPop(i32, mem_allocator, &max_heap);
    try testPop(i32, mem_allocator, &max_heap);

    // 獲取堆積的大小
    var size = max_heap.len;
    std.debug.print("\n堆積元素數量為 {}\n", .{size});

    // 判斷堆積是否為空
    var is_empty = if (max_heap.len == 0) true else false;
    std.debug.print("\n堆積是否為空 {}\n", .{is_empty});

    // 輸入串列並建堆積
    try min_heap.addSlice(&[_]i32{ 1, 3, 2, 5, 4 });
    std.debug.print("\n輸入串列並建立小頂堆積後\n", .{});
    try inc.PrintUtil.printHeap(i32, mem_allocator, min_heap);

    _ = try std.io.getStdIn().reader().readByte();
}
feat: Traditional Chinese version (#1163) * First commit * Update mkdocs.yml * Translate all the docs to traditional Chinese * Translate the code files. * Translate the docker file * Fix mkdocs.yml * Translate all the figures from SC to TC * 二叉搜尋樹 -> 二元搜尋樹 * Update terminology. * Update terminology * 构造函数/构造方法 -> 建構子异或 -> 互斥或 * 擴充套件 -> 擴展 * constant - 常量 - 常數 * 類 -> 類別 * AVL -> AVL 樹 * 數組 -> 陣列 * 係統 -> 系統斐波那契數列 -> 費波那契數列運算元量 -> 運算量引數 -> 參數 * 聯絡 -> 關聯 * 麵試 -> 面試 * 面向物件 -> 物件導向歸併排序 -> 合併排序范式 -> 範式 * Fix 算法 -> 演算法 * 錶示 -> 表示反碼 -> 一補數補碼 -> 二補數列列尾部 -> 佇列尾部區域性性 -> 區域性一摞 -> 一疊 * Synchronize with main branch * 賬號 -> 帳號推匯 -> 推導 * Sync with main branch * First commit * Update mkdocs.yml * Translate all the docs to traditional Chinese * Translate the code files. * Translate the docker file * Fix mkdocs.yml * Translate all the figures from SC to TC * 二叉搜尋樹 -> 二元搜尋樹 * Update terminology * 构造函数/构造方法 -> 建構子异或 -> 互斥或 * 擴充套件 -> 擴展 * constant - 常量 - 常數 * 類 -> 類別 * AVL -> AVL 樹 * 數組 -> 陣列 * 係統 -> 系統斐波那契數列 -> 費波那契數列運算元量 -> 運算量引數 -> 參數 * 聯絡 -> 關聯 * 麵試 -> 面試 * 面向物件 -> 物件導向歸併排序 -> 合併排序范式 -> 範式 * Fix 算法 -> 演算法 * 錶示 -> 表示反碼 -> 一補數補碼 -> 二補數列列尾部 -> 佇列尾部區域性性 -> 區域性一摞 -> 一疊 * Synchronize with main branch * 賬號 -> 帳號推匯 -> 推導 * Sync with main branch * Update terminology.md * 操作数量（num. of operations）-> 操作數量 * 字首和->前綴和 * Update figures * 歸 -> 迴記憶體洩漏 -> 記憶體流失 * Fix the bug of the file filter * 支援 -> 支持 Add zh-Hant/README.md * Add the zh-Hant chapter covers. Bug fixes. * 外掛 -> 擴充功能 * Add the landing page for zh-Hant version * Unify the font of the chapter covers for the zh, en, and zh-Hant version * Move zh-Hant/ to zh-hant/ * Translate terminology.md to traditional Chinese 8 months ago			`// File: heap.zig`
			`// Created Time: 2023-01-14`
			`// Author: codingonion (coderonion@gmail.com)`

			`const std = @import("std");`
			`const inc = @import("include");`

			`fn lessThan(context: void, a: i32, b: i32) std.math.Order {`
			`_ = context;`
			`return std.math.order(a, b);`
			`}`

			`fn greaterThan(context: void, a: i32, b: i32) std.math.Order {`
			`return lessThan(context, a, b).invert();`
			`}`

			`fn testPush(comptime T: type, mem_allocator: std.mem.Allocator, heap: anytype, val: T) !void {`
			`try heap.add(val); //元素入堆積`
			`std.debug.print("\n元素 {} 入堆積後\n", .{val});`
			`try inc.PrintUtil.printHeap(T, mem_allocator, heap);`
			`}`

			`fn testPop(comptime T: type, mem_allocator: std.mem.Allocator, heap: anytype) !void {`
			`var val = heap.remove(); //堆積頂元素出堆積`
			`std.debug.print("\n堆積頂元素 {} 出堆積後\n", .{val});`
			`try inc.PrintUtil.printHeap(T, mem_allocator, heap);`
			`}`

			`// Driver Code`
			`pub fn main() !void {`
			`// 初始化記憶體分配器`
			`var mem_arena = std.heap.ArenaAllocator.init(std.heap.page_allocator);`
			`defer mem_arena.deinit();`
			`const mem_allocator = mem_arena.allocator();`

			`// 初始化堆積`
			`// 初始化小頂堆積`
			`const PQlt = std.PriorityQueue(i32, void, lessThan);`
			`var min_heap = PQlt.init(std.heap.page_allocator, {});`
			`defer min_heap.deinit();`
			`// 初始化大頂堆積`
			`const PQgt = std.PriorityQueue(i32, void, greaterThan);`
			`var max_heap = PQgt.init(std.heap.page_allocator, {});`
			`defer max_heap.deinit();`

			`std.debug.print("\n以下測試樣例為大頂堆積", .{});`

			`// 元素入堆積`
			`try testPush(i32, mem_allocator, &max_heap, 1);`
			`try testPush(i32, mem_allocator, &max_heap, 3);`
			`try testPush(i32, mem_allocator, &max_heap, 2);`
			`try testPush(i32, mem_allocator, &max_heap, 5);`
			`try testPush(i32, mem_allocator, &max_heap, 4);`

			`// 獲取堆積頂元素`
			`var peek = max_heap.peek().?;`
			`std.debug.print("\n堆積頂元素為 {}\n", .{peek});`

			`// 堆積頂元素出堆積`
			`try testPop(i32, mem_allocator, &max_heap);`
			`try testPop(i32, mem_allocator, &max_heap);`
			`try testPop(i32, mem_allocator, &max_heap);`
			`try testPop(i32, mem_allocator, &max_heap);`
			`try testPop(i32, mem_allocator, &max_heap);`

			`// 獲取堆積的大小`
			`var size = max_heap.len;`
			`std.debug.print("\n堆積元素數量為 {}\n", .{size});`

			`// 判斷堆積是否為空`
			`var is_empty = if (max_heap.len == 0) true else false;`
			`std.debug.print("\n堆積是否為空 {}\n", .{is_empty});`

			`// 輸入串列並建堆積`
			`try min_heap.addSlice(&[_]i32{ 1, 3, 2, 5, 4 });`
			`std.debug.print("\n輸入串列並建立小頂堆積後\n", .{});`
			`try inc.PrintUtil.printHeap(i32, mem_allocator, min_heap);`

			`_ = try std.io.getStdIn().reader().readByte();`
			`}`