Merge branch 'master' of github.com:krahets/hello-algo

This commit is contained in:
Yudong Jin 2023-01-16 14:31:08 +08:00
commit 416af2d799
4 changed files with 121 additions and 24 deletions

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@ -1,5 +1,5 @@
/**
* File: my_heap.java
* File: heap.java
* Created Time: 2023-01-07
* Author: Krahets (krahets@163.com)
*/

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@ -188,6 +188,20 @@ pub fn build(b: *std.build.Builder) void {
const run_step_binary_tree= b.step("run_binary_tree", "Run binary_tree");
run_step_binary_tree.dependOn(&run_cmd_binary_tree.step);
// Section: "Heap"
// Source File: "chapter_heap/heap.zig"
// Run Command: zig build run_heap
const exe_heap = b.addExecutable("heap", "chapter_heap/heap.zig");
exe_heap.addPackagePath("include", "include/include.zig");
exe_heap.setTarget(target);
exe_heap.setBuildMode(mode);
exe_heap.install();
const run_cmd_heap = exe_heap.run();
run_cmd_heap.step.dependOn(b.getInstallStep());
if (b.args) |args| run_cmd_heap.addArgs(args);
const run_step_heap = b.step("run_heap", "Run heap");
run_step_heap.dependOn(&run_cmd_heap.step);
// Section: "Linear Search"
// Source File: "chapter_searching/linear_search.zig"
// Run Command: zig build run_linear_search

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@ -0,0 +1,81 @@
// File: heap.zig
// Created Time: 2023-01-14
// Author: sjinzh (sjinzh@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); //
std.debug.print("\n元素 {} 入堆后\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(); //
std.debug.print("\n堆顶元素 {} 出堆后\n", .{val});
try inc.PrintUtil.printHeap(T, mem_allocator, heap);
}
// Driver Code
pub fn main() !void {
//
var mem_arena = std.heap.ArenaAllocator.init(std.heap.page_allocator);
defer mem_arena.deinit();
const mem_allocator = mem_arena.allocator();
//
//
const PQlt = std.PriorityQueue(i32, void, lessThan);
var minHeap = PQlt.init(std.heap.page_allocator, {});
defer minHeap.deinit();
//
const PQgt = std.PriorityQueue(i32, void, greaterThan);
var maxHeap = PQgt.init(std.heap.page_allocator, {});
defer maxHeap.deinit();
std.debug.print("\n以下测试样例为大顶堆", .{});
//
try testPush(i32, mem_allocator, &maxHeap, 1);
try testPush(i32, mem_allocator, &maxHeap, 3);
try testPush(i32, mem_allocator, &maxHeap, 2);
try testPush(i32, mem_allocator, &maxHeap, 5);
try testPush(i32, mem_allocator, &maxHeap, 4);
//
var peek = maxHeap.peek().?;
std.debug.print("\n堆顶元素为 {}\n", .{peek});
//
try testPop(i32, mem_allocator, &maxHeap);
try testPop(i32, mem_allocator, &maxHeap);
try testPop(i32, mem_allocator, &maxHeap);
try testPop(i32, mem_allocator, &maxHeap);
try testPop(i32, mem_allocator, &maxHeap);
//
var size = maxHeap.len;
std.debug.print("\n堆元素数量为 {}\n", .{size});
//
var isEmpty = if (maxHeap.len == 0) true else false;
std.debug.print("\n堆是否为空 {}\n", .{isEmpty});
//
try minHeap.addSlice(&[_]i32{ 1, 3, 2, 5, 4 });
std.debug.print("\n输入列表并建立小顶堆后\n", .{});
try inc.PrintUtil.printHeap(i32, mem_allocator, minHeap);
const getchar = try std.io.getStdIn().reader().readByte();
_ = getchar;
}

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@ -24,36 +24,38 @@ pub fn TreeNode(comptime T: type) type {
}
// Generate a binary tree with an array
pub fn arrToTree(comptime T: type, mem_allocator: std.mem.Allocator, list: []T) !?*TreeNode(T) {
if (list.len == 0) return null;
pub fn arrToTree(comptime T: type, mem_allocator: std.mem.Allocator, arr: []T) !?*TreeNode(T) {
if (arr.len == 0) return null;
var root = try mem_allocator.create(TreeNode(T));
root.init(list[0]);
const TailQueue = std.TailQueue(?*TreeNode(T));
const TailQueueNode = std.TailQueue(?*TreeNode(T)).Node;
var que = TailQueue{};
var node_root = TailQueueNode{ .data = root };
que.append(&node_root);
root.init(arr[0]);
const L = std.TailQueue(*TreeNode(T));
var que = L{};
var root_node = try mem_allocator.create(L.Node);
root_node.data = root;
que.append(root_node);
var index: usize = 0;
while (que.len > 0) {
var node = que.popFirst();
var que_node = que.popFirst().?;
var node = que_node.data;
index += 1;
if (index >= list.len) break;
if (index < list.len) {
if (index >= arr.len) break;
if (index < arr.len) {
var tmp = try mem_allocator.create(TreeNode(T));
tmp.init(list[index]);
node.?.data.?.left = tmp;
var a = TailQueueNode{ .data = node.?.data.?.left };
que.append(&a);
tmp.init(arr[index]);
node.left = tmp;
var tmp_node = try mem_allocator.create(L.Node);
tmp_node.data = node.left.?;
que.append(tmp_node);
}
index += 1;
if (index >= list.len) break;
if (index < list.len) {
if (index >= arr.len) break;
if (index < arr.len) {
var tmp = try mem_allocator.create(TreeNode(T));
tmp.init(list[index]);
node.?.data.?.right = tmp;
var a = TailQueueNode{ .data = node.?.data.?.right };
que.append(&a);
tmp.init(arr[index]);
node.right = tmp;
var tmp_node = try mem_allocator.create(L.Node);
tmp_node.data = node.right.?;
que.append(tmp_node);
}
}
return root;