合肥生活安徽新闻合肥交通合肥房产生活服务合肥教育合肥招聘合肥旅游文化艺术合肥美食合肥地图合肥社保合肥医院企业服务合肥法律

代写CS1010S: Advanced Recursion

时间:2024-02-24  来源:合肥网hfw.cc  作者:hfw.cc 我要纠错


CS1010S: Programming Methodology

Semester II, 2023/2024

Mission 4

Advanced Recursion

Release date: 16th February 2024

Due: 22nd February 2024, 23:59

Required Files

• mission04-template.py

Background

After demonstrating your abilities to Pharaoh Tyro, you were honored with the presti-gious role of bishop within his esteemed team. The anticipation was palpable as you entered his chambers, where Tyro’s eyes sparkled with expectation. With a grand ges-ture, he handed you three scrolls (Your mission tasks), each bearing the royal seal.

"These," he declared, his voice resonating with authority, "are your inaugural assign-ments as bishop. Execute them diligently and report to me during the upcoming CS1010S class."

This mission consists of three tasks.

Task 1: Number of ways to sum to an Integer (3 marks)

A positive integer n ≥ 2 can be expressed as the sum of a number of positive integers smaller than n. For example:

2 = 1 + 1

3 = 1 + 2

   = 1 + 1 + 1

4 = 1 + 3

   = 2 + 2

   = 1 + 1 + 2

   = 1 + 1 + 1 + 1

5 = 1 + 4

   = 1 + 1 + 3

   = 2 + 3

   = 1 + 2 + 2

   = 1 + 1 + 1 + 2

   = 1 + 1 + 1 + 1 + 1

The function num_sum returns the number of ways that an integer can be expressed as the sum of a number of positive integers. From the above examples, it should be clear that:

>>> num_sum ( 2 )

1

>>> num_sum ( 3 )

2

>>> num_sum ( 4 )

4

>>> num_sum ( 5 )

6

Hint: If you grasp the essence of the count change problem, you’ll recognize that this problem is a variation of it. You may want to consider implementing a helper function that model the count change process of this problem. Solving the problem using closed-form formulas are not allowed.

Task 2: Generalized Pathfinding: Enumerate All Paths (3 marks)

In Lecture Training 5, you faced a problem where you were required to assist Jon in im-plementing a function, num_of_possible_path(board). This function determined the num-ber of possible paths to move from the starting point "S" to the ending point "E" by either walking (covering 1 step) or jumping (covering 2 steps).

Now, you encountered a similar challenge. The game no longer restricts the steps to just 1 or 2; instead, it can be any arbitrary number of steps (i.e. 1, 2, 3, ..., n). Your task is to implement an iterative recursive function, num_of_possible_path(board), which calculates the number of possible paths to move from the starting point "S" to the ending point "E" given that there are n possible ways to move at each step.

You may assume substring(string, start, end, step) function is given.

Hint: Observe that this problem resembles a count change problem. At each step, you have the choice to move 1 step forward, or 2 steps forward, or 3 steps forward, and so on, up to n steps forward.

>>> num_of_possible_path ("S##E", 1 )

1

>>> num_of_possible_path ("S##E", 2 )

3

>>> num_of_possible_path ("S##E", 3 )

4

Task 3: Check valid brackets (5 marks)

Consider a string containing only brackets "(" and ")". A string of brackets is considered valid if:

• Every opening parenthesis has a corresponding closing parenthesis.

• Opening and closing parentheses are in the correct order.

• Each closing parenthesis has a matching opening parenthesis.

Implement a function, check_valid_brackets(s), that returns True if the string s is valid brackets, and False otherwise.

Hint: If a string of brackets is valid, it can repeatedly remove the innermost non-nested "()" until it becomes an empty string.

Subtask 3a: Illustrate Your Problem-Solving Approach

In Lecture 1, you have learnt the Polya’s Problem Solving Process:

1. Understand the Problem

2. Make a Plan (Create a Flowchart, as outlined in Lecture 1 slides)

3. Do the Plan

4. Review & Generalize

Apply the Polya problem-solving methodology, and demonstrate your problem-solving process for Task 3. You are tasked to write out each step, providing insights into your approach and decision-making. This exercise aims to reinforce your understanding and application of the problem-solving methodology.

Please submit your illustration to coursemology. Note that you must include Step 1 and Step 2 in your illustration; Step 3 and Step 4 are optional. (For an example, please refer to Coursemology -> Workbin -> PolyasProblemSolvingExample.pdf)

By using the idea of divide and conquer, here are the steps to solve Task 2

1. Implement an iterative function remove_bracket_pair(s) that takes in a string of brackets. This function iterates through the string from left to right, removing the first occurrence of the brackets pair "()" within the string s, and returns the modified string. You may assume substring(string, start, end, step) function is given.

>>> remove_bracket_pair (" ()()() ")

" ()() "

>>> remove_bracket_pair (" (()()) ")

" (()) "

>>> remove_bracket_pair (" ((())) ")

" (()) "

>>> remove_bracket_pair (")()")

")"

>>> remove_bracket_pair ("()")

""

>>> remove_bracket_pair (" (())((())) ")

" ()((())) "

2. Using the above iterative remove_bracket_pair(s) function, implement a recursive check_valid_brackets(s) that takes in a string of brackets and returns True if the string s is valid brackets, and False otherwise.

>>> check_valid_brackets ("()")

True

>>> check_valid_brackets (" (()) ")

True

>>> check_valid_brackets (" ()() ")

True

>>> check_valid_brackets (" (()")

False

>>> check_valid_brackets (" ())")

False

>>> check_valid_brackets (" ())( ")

False

Subtask 3b: Execute Your Plan

1. Implement the iterative function remove_bracket_pair(s).

2. Implement the recursive function check_valid_brackets(s).

You may assume substring(string, start, end, step) function is given.

You are highly encouraged to test your functions with additional test cases.

Optional: Spiral Maze Iterative Recursively

Write an iterative recursive function num_of_steps that takes in 4 arguments, the x and y coordinates of ending point, x and y, width of the maze, W and height of the maze, H. The function returns the number of steps to navigate from the bottom-left corner (origin) of the maze to the specified ending point. Please follow the question requirements any closed form formula or pure iterative solution will not be accepted.

Hint: You will need to iterate until the boundary, then recursively call the function with the new boundary and updated x & y.



Figure 1: A spiral maze with height 3 and width 3. The number of steps from the origin to the ending point (1, 1) is 8.

num_of_steps (1 , 1 , 3 , 3 )

>>> 8

num_of_steps (0 , 0 , 3 , 3 )

>>> 0

num_of_steps (1 , 1 , 3 , 2 )

>>> 4

num_of_steps (1 , 3 , 5 , 7 )

>>>

Optional: Alternative approach of Task 2

There are many ways to solve the problem in Task 2. You are encouraged to explore alternative approaches to solve the problem.

You may assume substring(string, start, end, step) function is given in this task.

Implement a function, check_valid_brackets_alt(s), that returns True if the string s is valid brackets, and False otherwise.

Completely Iterative Approach (Easy)

You can implement the function purely iterative. Please confine your implementation to what you’ve learned from CS1010S thus far.

Completely Recursive Approach (Challenging)

You may also implement the function purely recursively.

Warning: This is a challenging task.

请加QQ:99515681  邮箱:99515681@qq.com   WX:codehelp 

扫一扫在手机打开当前页
  • 上一篇:代写ELEC-4840 编程
  • 下一篇:代写 Financial Derivatives and Financial
  • 无相关信息
    合肥生活资讯

    合肥图文信息
    新能源捕鱼一体电鱼竿好用吗
    新能源捕鱼一体电鱼竿好用吗
    海信罗马假日洗衣机亮相AWE  复古美学与现代科技完美结合
    海信罗马假日洗衣机亮相AWE 复古美学与现代
    合肥机场巴士4号线
    合肥机场巴士4号线
    合肥机场巴士3号线
    合肥机场巴士3号线
    合肥机场巴士2号线
    合肥机场巴士2号线
    合肥机场巴士1号线
    合肥机场巴士1号线
    合肥轨道交通线路图
    合肥轨道交通线路图
    合肥地铁5号线 运营时刻表
    合肥地铁5号线 运营时刻表
  • 币安app官网下载

    关于我们 | 打赏支持 | 广告服务 | 联系我们 | 网站地图 | 免责声明 | 帮助中心 | 友情链接 |

    Copyright © 2024 hfw.cc Inc. All Rights Reserved. 合肥网 版权所有
    ICP备06013414号-3 公安备 42010502001045