XJCO1921代做、代写c/c++编程语言
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Module title Programming Project
Module code XJCO1921
Assignment title Assignment 2 – Project Code
Assignment type and
description
You will now implement the maze game, using test-driven development
to create a defensively designed program following a given
specification.
Rationale Using modern and professional development techniques, you will work
on a simple project demonstrating your understanding of different
techniques, such as dynamic memory allocation and structure usage.
You will focus on creating good quality code which is well documented,
modular, and maintainable; these are all important considerations when
writing code in the industry.
Word limit and
guidance
You should spend 16-20 hours working on this assessment.
Weighting 60%
Submission deadline Thursday 30 May 2024 16:00 UK BST (23:00 Beijing Time)
Submission method Gradescope
Feedback provision Marked rubric
Learning outcomes
assessed
- apply professional programming practices to programming projects.
- design, implement, debug and test a modular programming solution to
a real-world problem.
Module lead Zheng Wang, Xiuying Yu
1. Assignment Guidance
You will produce, in C, a program which fits the following specifications:
Maze Game
Usage: ./maze
You are creating a basic game, where players navigate through a maze. Note that we no longer
require passing the maze size as the input arguments.
The maze will be loaded from a file, the filename for which is passed as a command line
argument. Mazes are made up of four characters:
Mazes are made up of four characters:
Character Purpose
‘#’ A wall which the player cannot move across
‘ ‘ (a space) A path which the player can move across
‘S’ The place where the player starts the maze
‘E’ The place where the player exits the maze
A maze has a height and a width, with a maximum of 100 and a minimum of 5. Your program will
dynamically allocate an appropriate data structure to store the maze.
The height and width do not have to be equal – as long as both are within the accepted range.
Within a maze, each ‘row’ and ‘column’ should be the same length – the maze should
be a rectangle.
When the game loads, the player will start at the starting point ‘S’ and can move through the maze
using WASD movement:
Note: For this assignment, each input will be separated with a newline character – this is not
keypress triggered. This is for the purpose of autograding.
The player can move freely through path spaces (‘ ‘) but cannot move through walls or off
the edge of the map. Some helpful prompts (messages) should be provided if this is
attempted.
The map should NOT be shown to the player every time they make a move (again for the
purpose of autograding), but they can enter ‘M’/’m’ to view an image of the map, with their
current location shown by an ‘X’.
When the user reaches the exit point ‘E’, the game is over and will close. The player
should be given some message stating that they have won. There is no ‘lose’ condition.
Key Direction
W/w Up
A/a Left
S/s Down
D/d Right
Q/q Quit the game Maze file specification
A valid maze:
− Has a single starting point ‘S’
− Has a single exit point ‘E’
− Contains only the start and exit characters, spaces (‘ ‘), walls (‘#’), and newline (‘\n’)
characters
− Has every row the same length
− Has every column the same height
− Has a maximum width and height of 100
− Has a minimum width and height of 5
− Does not require every row and column to start or end with a ‘#’
− May have a trailing newline at the end of the file (one empty row containing only ‘\n’)
A selection of valid mazes is provided in your starting repository – you should ensure that
your code accepts all these mazes.
Note that file extension is not important – there is no requirement for a maze file to be stored
as a .txt file provided that the contents of the file are valid.
Standard Outputs
To allow some automatic testing of your functionality, we require some of your outputs to
have a specific format. To prevent you from being overly restricted, this will only be the
final returned value of your code rather than any print statements.
Return Codes
Scenario Value to be returned by your executable
Successful running 0
Argument error 1
File error 2
Invalid maze 3
Any other non-successful exit
Note: it is unlikely that you will need to use
this code
Maze Printing Function
The maze printing function (‘M’/’m’) must output the maze in the following way:
− No additional spaces added
− Newline before the first row is printed
− Newline after the final row
− If the player’s current position overlaps with the starting point, this should display ‘X’
rather than ‘S’
The code required to do this is provided in the template as print_maze() and may be used without
referencing me.
Additional Challenge Task – Maze Generator
This is an optional additional task that will involve researching and developing a more
complex piece of code – you do not need to complete this section to achieve a 2:1/2:2
grade. This task may take longer than the recommended time given above – I recommend
only attempting any part of it if you found the original task trivial to complete.
The task
In addition to allowing users to solve mazes, you will create an additional program `mazegen`
which allows users to generate a valid and solvable maze with the specified width and
height, to be saved in ‘filename’.
For example:
./mazeGen maze4.txt 20 45#
will save a maze that is 20 x 45 into ‘maze4.txt’, creating that file if it does not already exist.
A valid maze means that it fits the rules given in the “maze file specification section”, as well as
being solvable (there is at least one solution to the maze- it is possible to start at S and exit at
E).
There are some existing algorithms that can create mazes, and you should experiment with
using these to produce ‘quality’ mazes that are not trivial to solve and present some challenges
to the player. You should document your process of developing the maze creation algorithm,
as this will form a part of the assessment.
It is recommended that you keep a log including some maze files generated by each iteration,
what you intend to change for the next iteration based on these maze files, and just some
general comments about what you think was good or bad about this particular solution.
Some things to consider for each iteration are:
− Did the program produce a variety of designs of maze?
− Did the program produce only valid mazes?
− How did the program perform with larger dimensions (100 x 100 for example)
− What did the program do particularly well?
o Can you identify what part of the code caused this?
− What did the program do particularly poorly?
o Can you identify what part of the code caused this?
− What will you try next time?
For this task, you will present your maze generation program to a member of the module
team during a lab session and discuss:
− How your program works
− How you iteratively developed it
− The limitations of your solution
− Any improvements you would like to make to it in the future
2. Assessment tasks
Produce the C code for a program that solves the tasks detailed above.
You should ensure that your code is:
- Structured sensibly
- Modular
- Well-documented
- Defensive
- Working as intended
You can use the code skeleton you produced in Assignment 1, or a basic skeleton is provided via
Minerva.
You can use any number of additional header and C files and should produce or adapt a makefile
that allows the program to compile successfully on a GitHub Codespace instance. You may not use
any non-standard C libraries. You should make sure your code runs in Linux.
You should also use your test script and data from assignment 1 to help you produce defensive and
working code. You can adapt and add to these throughout your development process. If you did not
create a test script, or your test script does not work, then you can manually test your code.
Good programming practices
You should follow good software development practices. For this exercise, you are asked to:
• Follow modular development by making sure the code is modular and well structured; code
with proper comments
• Use Makefile for code compilation;
• Use a git repository for version control
Notes:
1. Makefile: You should also submit a Makefile with at least two targets: all and clean. "make
all" compiles your code to generate an executable binary, while "make clean" removes all
object files (.o), all executables, and any temporary files created during your run.
2. Version control: We will check the commit logs of your git repository. We expect to see
steady progress towards completion, as revealed in the pattern of git commits. One of the
implications of this is that we will be penalising any student who develops their code without
git and then dumps it all into git at the last minute.
3. General guidance and study support
You should refer to the lab exercises and lecture notes to support you. Use the lab sessions to ask
for help.
4. Assessment criteria and marking process
A full breakdown of the assessment criteria can be found in section 8.
Your code will be tested with different maze files and user inputs containing errors - the exact nature
of these errors will not be told to you before marking, so ensure that you validate a wide range of
potential user errors. Note that we will be running our own test cases to mark the assignments and
doing our best to devise creative ways to break your code! You should therefore develop your test
cases to beat us to it.
Your code will be manually checked for code quality.
If you complete the additional challenge task, you will submit your code for plagiarism checking but
will present your code to a member of the SWJTU module staff for assessment.
5. Presentation and referencing
If you need to reference any resources, use a simple comment, for example:
// This test is adapted from an example provided on https://byby.dev/bash-exit-codes
You should not be directly copying any code from external resources, even with a reference.
Generative AI:
If you are referencing a Generative AI model, you must provide the full conversation.
In ChatGPT, you can generate a link to the full conversation:
And provide the reference as follows:
// Lines 1 – 7 were adapted from code provided by the following conversation with
chatGPT: https://chat.openai.com/share/c356221d-fb88-4970-b39e-d00c87ae1e0b
In Copilot, you will need to export the conversation as a text file:
Save this with a filename including the date and 2-3 word summary of what the conversation
was about (’11-03 inputs in C.txt’) and ensure this is submitted with your work.
\You can reference this in your code:
// Lines 1 – 7 were adapted from code provided by the CoPilot conversation
recorded in ’11-03 inputs in C.txt’
If you are using a different Generative AI model, these instructions may differ – you
must still provide a link to or copy of the full conversation and reference in the same
manner above.
Use of Generative AI in this Assessment
This assessment is rated ‘amber’ according to the university guidelines around generative AI.
This means that you can use genAI models such as ChatGPT or CoPilot to explain concepts
that may be useful in this assessment, but you must NOT ask it to write your code for you
nor give it any part of my specification.
The following link is an example of what I would consider ‘reasonable use’ of chatGPT for this
assessment:
https://chat.openai.com/share/c356221d-fb88-4970-b39e-d00c87ae1e0b
6. Submission requirements
Submit your source code via Gradescope. There is a separate submission point for the
extension work.
Ensure that:
− Any .c or .h files are not inside a subdirectory
− The makefile is not inside a subdirectory
− Your executables are named: maze and mazegen
− You have followed the return code instructions above
− Your code compiles on Linux
You will receive some instant feedback which should confirm that your upload is in the
correct format and is using the correct return values – please ensure you correct any
failing tests.
Note: Passing these tests is not a guarantee that your code will gain full marks from the
autograder – just that it is the correct format/returns for the grader to run.
7. Academic misconduct and plagiarism
Leeds students are part of an academic community that shares ideas and develops new ones.
You need to learn how to work with others, how to interpret and present other people's ideas, and how to
produce your own independent academic work. It is essential that you can distinguish between other
people's work and your own, and correctly acknowledge other people's work.
All students new to the University are expected to complete an online Academic Integrity tutorial and test,
and all Leeds students should ensure that they are aware of the principles of Academic integrity.
When you submit work for assessment it is expected that it will meet the University’s academic integrity
standards.
If you do not understand what these standards are, or how they apply to your work, then please ask the
module teaching staff for further guidance.
By submitting this assignment, you are confirming that the work is a true expression of your own work and
ideas and that you have given credit to others where their work has contributed to yours.
8. Assessment/ marking criteria grid
Category 1st 2:1 / 2:2 Pass / 3rd Fail
Basic Task (70)
Auto-graded Questions
Functionality
(25)
Fully
functional,
meeting all
specified
requirements.
Mostly
functional but
with minor bugs
or incomplete
features.
Core functionality
has been
implemented with
some major errors.
Significant errors,
or does not meet
specification.
Defensive
design (10)
Robust
error
handling
and
defensive
programmin
g practices
were
implemente
d
Adequate error
handling but
lacks coverage
for certain
edge cases.
Error handling for a
variety of cases has
been implemented.
Code does not
regularly crash.
Lack of defensive
programming;
code is prone to
errors or crashes.
Manually Marked Questions
Code Structure
(10)
Well-organized
structure that
enhances
readability and
comprehensio
n.
Clear structure
but lacks some
cohesion
affecting
readability.
Structure exists but
causes confusion or
detracts from
readability.
Lack of coherent
structure, code is
hard to follow.
Documentation
(Comments /
readme)
(10)
Thorough
documentatio
n, including
explanations
of code logic
and usage.
Adequate
documentation,
but some parts
lack clarity or
completeness.
Limited
documentation,
making it difficult to
understand code
intentions.
Absence of
documentation
which makes code
unreadable.
Modular
breakdown
(5)
Clearly
defined
modules with
distinct
functionalities,
promoting
easy
maintenance.
Modules
mostly defined
but may lack
clear
separation or
functionality.
Poor division into
modules, leading
to confusion or
inefficiencies.
Lack of modular
design; code is
monolithic and
hard to manage.
Memory
Management
(5)
Optimal memory
handling;
efficient
allocation and
deallocation with
no leaks.
Mostly
efficient
memory
handling but
may have
minor leaks or
inefficiencies.
Inefficient memory
handling causing
noticeable leaks or
performance
issues.
Severe memory
leaks or grossly
inefficient memory
usage. Use of git for
version control
(5)
A good use of git
for version
control with
steady updates
Use of GitHub
but with
occasional
commits
toward the
end of the
deadline
One or two git
commits before
submission
No use of git for
version controls
Maze Generator (30)
Functionality
(10)
Generates highquality,
challenging
mazes meeting all
criteria.
Mostly generates
challenging mazes but
may have some
limitations.
Generates mazes with
significant limitations
or are too simplistic.
Fails to generate
valid or challenging
mazes.
Algorithm
Development
(20)
It is clear how the final
algorithm was
reached, with a clear
progression from
more simple
algorithms to a final
algorithm.
Students are able to
articulate this
development with
reflective language
and clear justifications
for choices made.
Students were able to
articulate the
limitations of the
solution and any
further work which
could improve it.
There is a clear
progression of
algorithm design, from
a simpler algorithm to
a more complex final
algorithm that builds
on the previous
solutions. Students
can articulate this
development but may
be lacking in reflective
thinking or clear
justifications.
The student has
made some
attempts to
articulate
limitations and
further work.
Some evidence of
progression to a final
solution, though
students may struggle
to explain and justify
choices made and
lack reflection.
Students can
explain basic,
surface-level
limitations.
No evidence of any
progression to the
solution, or the
student is unable to
explain how the
algorithm was
developed.
Module title Programming Project
Module code XJCO1921
Assignment title Assignment 2 – Project Code
Assignment type and
description
You will now implement the maze game, using test-driven development
to create a defensively designed program following a given
specification.
Rationale Using modern and professional development techniques, you will work
on a simple project demonstrating your understanding of different
techniques, such as dynamic memory allocation and structure usage.
You will focus on creating good quality code which is well documented,
modular, and maintainable; these are all important considerations when
writing code in the industry.
Word limit and
guidance
You should spend 16-20 hours working on this assessment.
Weighting 60%
Submission deadline Thursday 30 May 2024 16:00 UK BST (23:00 Beijing Time)
Submission method Gradescope
Feedback provision Marked rubric
Learning outcomes
assessed
- apply professional programming practices to programming projects.
- design, implement, debug and test a modular programming solution to
a real-world problem.
Module lead Zheng Wang, Xiuying Yu
1. Assignment Guidance
You will produce, in C, a program which fits the following specifications:
Maze Game
Usage: ./maze
You are creating a basic game, where players navigate through a maze. Note that we no longer
require passing the maze size as the input arguments.
The maze will be loaded from a file, the filename for which is passed as a command line
argument. Mazes are made up of four characters:
Mazes are made up of four characters:
Character Purpose
‘#’ A wall which the player cannot move across
‘ ‘ (a space) A path which the player can move across
‘S’ The place where the player starts the maze
‘E’ The place where the player exits the maze
A maze has a height and a width, with a maximum of 100 and a minimum of 5. Your program will
dynamically allocate an appropriate data structure to store the maze.
The height and width do not have to be equal – as long as both are within the accepted range.
Within a maze, each ‘row’ and ‘column’ should be the same length – the maze should
be a rectangle.
When the game loads, the player will start at the starting point ‘S’ and can move through the maze
using WASD movement:
Note: For this assignment, each input will be separated with a newline character – this is not
keypress triggered. This is for the purpose of autograding.
The player can move freely through path spaces (‘ ‘) but cannot move through walls or off
the edge of the map. Some helpful prompts (messages) should be provided if this is
attempted.
The map should NOT be shown to the player every time they make a move (again for the
purpose of autograding), but they can enter ‘M’/’m’ to view an image of the map, with their
current location shown by an ‘X’.
When the user reaches the exit point ‘E’, the game is over and will close. The player
should be given some message stating that they have won. There is no ‘lose’ condition.
Key Direction
W/w Up
A/a Left
S/s Down
D/d Right
Q/q Quit the game Maze file specification
A valid maze:
− Has a single starting point ‘S’
− Has a single exit point ‘E’
− Contains only the start and exit characters, spaces (‘ ‘), walls (‘#’), and newline (‘\n’)
characters
− Has every row the same length
− Has every column the same height
− Has a maximum width and height of 100
− Has a minimum width and height of 5
− Does not require every row and column to start or end with a ‘#’
− May have a trailing newline at the end of the file (one empty row containing only ‘\n’)
A selection of valid mazes is provided in your starting repository – you should ensure that
your code accepts all these mazes.
Note that file extension is not important – there is no requirement for a maze file to be stored
as a .txt file provided that the contents of the file are valid.
Standard Outputs
To allow some automatic testing of your functionality, we require some of your outputs to
have a specific format. To prevent you from being overly restricted, this will only be the
final returned value of your code rather than any print statements.
Return Codes
Scenario Value to be returned by your executable
Successful running 0
Argument error 1
File error 2
Invalid maze 3
Any other non-successful exit
Note: it is unlikely that you will need to use
this code
Maze Printing Function
The maze printing function (‘M’/’m’) must output the maze in the following way:
− No additional spaces added
− Newline before the first row is printed
− Newline after the final row
− If the player’s current position overlaps with the starting point, this should display ‘X’
rather than ‘S’
The code required to do this is provided in the template as print_maze() and may be used without
referencing me.
Additional Challenge Task – Maze Generator
This is an optional additional task that will involve researching and developing a more
complex piece of code – you do not need to complete this section to achieve a 2:1/2:2
grade. This task may take longer than the recommended time given above – I recommend
only attempting any part of it if you found the original task trivial to complete.
The task
In addition to allowing users to solve mazes, you will create an additional program `mazegen`
which allows users to generate a valid and solvable maze with the specified width and
height, to be saved in ‘filename’.
For example:
./mazeGen maze4.txt 20 45#
will save a maze that is 20 x 45 into ‘maze4.txt’, creating that file if it does not already exist.
A valid maze means that it fits the rules given in the “maze file specification section”, as well as
being solvable (there is at least one solution to the maze- it is possible to start at S and exit at
E).
There are some existing algorithms that can create mazes, and you should experiment with
using these to produce ‘quality’ mazes that are not trivial to solve and present some challenges
to the player. You should document your process of developing the maze creation algorithm,
as this will form a part of the assessment.
It is recommended that you keep a log including some maze files generated by each iteration,
what you intend to change for the next iteration based on these maze files, and just some
general comments about what you think was good or bad about this particular solution.
Some things to consider for each iteration are:
− Did the program produce a variety of designs of maze?
− Did the program produce only valid mazes?
− How did the program perform with larger dimensions (100 x 100 for example)
− What did the program do particularly well?
o Can you identify what part of the code caused this?
− What did the program do particularly poorly?
o Can you identify what part of the code caused this?
− What will you try next time?
For this task, you will present your maze generation program to a member of the module
team during a lab session and discuss:
− How your program works
− How you iteratively developed it
− The limitations of your solution
− Any improvements you would like to make to it in the future
2. Assessment tasks
Produce the C code for a program that solves the tasks detailed above.
You should ensure that your code is:
- Structured sensibly
- Modular
- Well-documented
- Defensive
- Working as intended
You can use the code skeleton you produced in Assignment 1, or a basic skeleton is provided via
Minerva.
You can use any number of additional header and C files and should produce or adapt a makefile
that allows the program to compile successfully on a GitHub Codespace instance. You may not use
any non-standard C libraries. You should make sure your code runs in Linux.
You should also use your test script and data from assignment 1 to help you produce defensive and
working code. You can adapt and add to these throughout your development process. If you did not
create a test script, or your test script does not work, then you can manually test your code.
Good programming practices
You should follow good software development practices. For this exercise, you are asked to:
• Follow modular development by making sure the code is modular and well structured; code
with proper comments
• Use Makefile for code compilation;
• Use a git repository for version control
Notes:
1. Makefile: You should also submit a Makefile with at least two targets: all and clean. "make
all" compiles your code to generate an executable binary, while "make clean" removes all
object files (.o), all executables, and any temporary files created during your run.
2. Version control: We will check the commit logs of your git repository. We expect to see
steady progress towards completion, as revealed in the pattern of git commits. One of the
implications of this is that we will be penalising any student who develops their code without
git and then dumps it all into git at the last minute.
3. General guidance and study support
You should refer to the lab exercises and lecture notes to support you. Use the lab sessions to ask
for help.
4. Assessment criteria and marking process
A full breakdown of the assessment criteria can be found in section 8.
Your code will be tested with different maze files and user inputs containing errors - the exact nature
of these errors will not be told to you before marking, so ensure that you validate a wide range of
potential user errors. Note that we will be running our own test cases to mark the assignments and
doing our best to devise creative ways to break your code! You should therefore develop your test
cases to beat us to it.
Your code will be manually checked for code quality.
If you complete the additional challenge task, you will submit your code for plagiarism checking but
will present your code to a member of the SWJTU module staff for assessment.
5. Presentation and referencing
If you need to reference any resources, use a simple comment, for example:
// This test is adapted from an example provided on https://byby.dev/bash-exit-codes
You should not be directly copying any code from external resources, even with a reference.
Generative AI:
If you are referencing a Generative AI model, you must provide the full conversation.
In ChatGPT, you can generate a link to the full conversation:
And provide the reference as follows:
// Lines 1 – 7 were adapted from code provided by the following conversation with
chatGPT: https://chat.openai.com/share/c356221d-fb88-4970-b39e-d00c87ae1e0b
In Copilot, you will need to export the conversation as a text file:
Save this with a filename including the date and 2-3 word summary of what the conversation
was about (’11-03 inputs in C.txt’) and ensure this is submitted with your work.
\You can reference this in your code:
// Lines 1 – 7 were adapted from code provided by the CoPilot conversation
recorded in ’11-03 inputs in C.txt’
If you are using a different Generative AI model, these instructions may differ – you
must still provide a link to or copy of the full conversation and reference in the same
manner above.
Use of Generative AI in this Assessment
This assessment is rated ‘amber’ according to the university guidelines around generative AI.
This means that you can use genAI models such as ChatGPT or CoPilot to explain concepts
that may be useful in this assessment, but you must NOT ask it to write your code for you
nor give it any part of my specification.
The following link is an example of what I would consider ‘reasonable use’ of chatGPT for this
assessment:
https://chat.openai.com/share/c356221d-fb88-4970-b39e-d00c87ae1e0b
6. Submission requirements
Submit your source code via Gradescope. There is a separate submission point for the
extension work.
Ensure that:
− Any .c or .h files are not inside a subdirectory
− The makefile is not inside a subdirectory
− Your executables are named: maze and mazegen
− You have followed the return code instructions above
− Your code compiles on Linux
You will receive some instant feedback which should confirm that your upload is in the
correct format and is using the correct return values – please ensure you correct any
failing tests.
Note: Passing these tests is not a guarantee that your code will gain full marks from the
autograder – just that it is the correct format/returns for the grader to run.
7. Academic misconduct and plagiarism
Leeds students are part of an academic community that shares ideas and develops new ones.
You need to learn how to work with others, how to interpret and present other people's ideas, and how to
produce your own independent academic work. It is essential that you can distinguish between other
people's work and your own, and correctly acknowledge other people's work.
All students new to the University are expected to complete an online Academic Integrity tutorial and test,
and all Leeds students should ensure that they are aware of the principles of Academic integrity.
When you submit work for assessment it is expected that it will meet the University’s academic integrity
standards.
If you do not understand what these standards are, or how they apply to your work, then please ask the
module teaching staff for further guidance.
By submitting this assignment, you are confirming that the work is a true expression of your own work and
ideas and that you have given credit to others where their work has contributed to yours.
8. Assessment/ marking criteria grid
Category 1st 2:1 / 2:2 Pass / 3rd Fail
Basic Task (70)
Auto-graded Questions
Functionality
(25)
Fully
functional,
meeting all
specified
requirements.
Mostly
functional but
with minor bugs
or incomplete
features.
Core functionality
has been
implemented with
some major errors.
Significant errors,
or does not meet
specification.
Defensive
design (10)
Robust
error
handling
and
defensive
programmin
g practices
were
implemente
d
Adequate error
handling but
lacks coverage
for certain
edge cases.
Error handling for a
variety of cases has
been implemented.
Code does not
regularly crash.
Lack of defensive
programming;
code is prone to
errors or crashes.
Manually Marked Questions
Code Structure
(10)
Well-organized
structure that
enhances
readability and
comprehensio
n.
Clear structure
but lacks some
cohesion
affecting
readability.
Structure exists but
causes confusion or
detracts from
readability.
Lack of coherent
structure, code is
hard to follow.
Documentation
(Comments /
readme)
(10)
Thorough
documentatio
n, including
explanations
of code logic
and usage.
Adequate
documentation,
but some parts
lack clarity or
completeness.
Limited
documentation,
making it difficult to
understand code
intentions.
Absence of
documentation
which makes code
unreadable.
Modular
breakdown
(5)
Clearly
defined
modules with
distinct
functionalities,
promoting
easy
maintenance.
Modules
mostly defined
but may lack
clear
separation or
functionality.
Poor division into
modules, leading
to confusion or
inefficiencies.
Lack of modular
design; code is
monolithic and
hard to manage.
Memory
Management
(5)
Optimal memory
handling;
efficient
allocation and
deallocation with
no leaks.
Mostly
efficient
memory
handling but
may have
minor leaks or
inefficiencies.
Inefficient memory
handling causing
noticeable leaks or
performance
issues.
Severe memory
leaks or grossly
inefficient memory
usage. Use of git for
version control
(5)
A good use of git
for version
control with
steady updates
Use of GitHub
but with
occasional
commits
toward the
end of the
deadline
One or two git
commits before
submission
No use of git for
version controls
Maze Generator (30)
Functionality
(10)
Generates highquality,
challenging
mazes meeting all
criteria.
Mostly generates
challenging mazes but
may have some
limitations.
Generates mazes with
significant limitations
or are too simplistic.
Fails to generate
valid or challenging
mazes.
Algorithm
Development
(20)
It is clear how the final
algorithm was
reached, with a clear
progression from
more simple
algorithms to a final
algorithm.
Students are able to
articulate this
development with
reflective language
and clear justifications
for choices made.
Students were able to
articulate the
limitations of the
solution and any
further work which
could improve it.
There is a clear
progression of
algorithm design, from
a simpler algorithm to
a more complex final
algorithm that builds
on the previous
solutions. Students
can articulate this
development but may
be lacking in reflective
thinking or clear
justifications.
The student has
made some
attempts to
articulate
limitations and
further work.
Some evidence of
progression to a final
solution, though
students may struggle
to explain and justify
choices made and
lack reflection.
Students can
explain basic,
surface-level
limitations.
No evidence of any
progression to the
solution, or the
student is unable to
explain how the
algorithm was
developed.