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DSC 20 Project: Classes, Inheritance and Exceptions.
Total Points: 100 (10% of the Course Grade) Submission due (SD time):
● Checkpoint: Thursday, May 30th, 11:59pm
● Final submission: Thursday, June 6th, 11:59pm Starter Files
Download project.zip
Contents:
● project.py
● image_viewer.py A file for viewing your images
● img/ A folder of images
● knn_data/ A folder of sample images for the KNN
Checkpoint Submission
Earn 5 points extra credit by completing Part 1 and Part 2 by the deadline above.
Final Submission
Submit the project.py file to gradescope.
● Only this file will be checked
● You do not need to submit any other files
● Slip Day: If in a group, both of you need slip days in order for it to count.
Partners
You can work with one other person on this project. If working with a partner, make sure to add them after you submit. If you resubmit, please re-add your partner - Gradescope will not automatically relink your latest submission to your partner. You should submit only one copy per team.
Important: The lateness policy for the project is the same as all homeworks. However, both partners must have an available slip day before you submit late.
Requirements
1. You cannot use any libraries in project.py
2. The project will not be graded on style
a. You do not need to submit your doctests but it is highly recommended to test your code with custom doctests (we will have our own tests, not just provided ones).
b. You can add docstrings, but they will not be graded.
3. Raise exceptions when required by the question
a. Exception requirements will be in bold blue
b. If there are no exception requirements, you can assume valid inputs
c. Do not use asserts
Project Overview:
In this project, we will make a basic image processing app.
● Part 1 covers how images are stored in code.
● Part 2 introduces some image processing methods in a Processor Template.
● Part 3 uses inheritance to simulate a monetized app.
● Part 4 uses inheritance to simulate a premium app with new methods.
● Part 5 implements a KNN classifier to predict the labels of images.
In the digital world, images are defined as 3-dimensional matrices: height (row), width (column), and channel (color). Each (row, col) entry is called a pixel. Height and width dimensions are intuitive : they define the size of the image. The channel dimension defines the color of an image.
The most commonly used color model is RGB. In this model, every color can be defined as a mixture of three primary color channels: Red, Green and Blue. Thus, the color of a pixel is digitally defined as a triplet (R, G, B). Each element in this triplet is an integer (called intensity) with value between 0 and 255 (both inclusive), where 0 represents no R/G/B is present and 255 means R/G/B is fully present. Thus, (0, 0, 0) represents black since no R/G/B are present, and (255, 255, 255) represents white. To better understand how the RGB color model works, you can play around the RGB value with this online color wheel.
In our project, we will use a 3-dimensional list of integers to structure the pixels. This picture s hows how a pixels list is structured.
The first dimension is the row, starting from the top. The second dimension is the column, starting from the left. The third dimension is the color channel. In other words, len(pixels[row][col]) = 3, and each of the items in the pixels[row][col] list represents an intensity (0 - 255, both inclusive) of each color. Therefore, to index a specific intensity value at row i, column j, and channel c of the pixels list, you use pixels[i][j][c].
Note that the width of an image is the length of the column dimension (number of columns), and the height of an image is the length of the row dimension (number of rows). Since in Python we conventionally consider (row, column) as the order of dimensions for 2-dimensional lists, make sure to distinguish these notions clearly.
Install Pillow and NumPy
The project uses two packages: NumPy (np) and Pillow (PIL). These are two of the most common packages to use for image processing. Although we prevent you from using these packages in your own implementation, you can still use them for testing. If you have not installed these packages before, run the following command in your terminal :
Mac/Linux: python3 -m pip install numpy Pillow
Windows: py -m pip install numpy Pillow
If you have trouble installing the packages, try updating pip first: Mac/Linux: python3 -m pip install --upgrade pip
Windows: py -m pip install --upgrade pip
Please note : You are not allowed to use numpy or PIL/Pillow methods in your code.
Testing
We have provided basic doctests that cover simple cases to check if your code works. Note that you will want to create more tests to check edge cases.
The doctests use small square images between 6px and 16px in size. They also use the included expected output images in the img/exp/ directory to compare your results against.
The doctests include some exceptions, deep copy, and cost value checks. Recall the difference between deep and shallow copies.
Since this project is about processing images, it makes more sense for you to visually check the output. Therefore, your main way of debugging will be to look at the images generated.
Mac/Linux: python3 -m doctest project.py Windows: py -m doctest project.py
Using image_viewer.py
We have included a python file that allows you to view your images to check for errors.
To run the file, use the following commands
Make sure to change the path in the "img/out/the_file_to_view.png" to connect to the image that you want to view.
Mac/Linux: python3 image_viewer.py "img/out/the_file_to_view.png" Windows: py image_viewer.py "img/out/the_file_to_view.png"
If you get an error like "ModuleNotFound Error: No module named 'tkinter'", then
run the command python3 -m pip install tk. If this doesn’t work, you can come to office hours and we can help install it for you (involves reinstalling python).
The script takes in a file path that points to an image, and displays it for you to view
You can zoom with your scroll wheel and pan around with your mouse. When you hover over a pixel, it will display the current color value at the bottom.
You can use this to check where your code is creating the wrong output values. You can also use it to manually compare your output against the expected output.
Video Guide:
This is a setup video from a previous quarter with a similar project: Link
We recommend that you watch this video while working on the project to better understand all of its components.
Efficiency and Runtime for Autograder
Because we are dealing with massive lists of lists, your code will need to be efficient.
Your code must run for less than 10 minutes to pass the autograder. Each test in the autograder is limited to 30 seconds. The solution takes around 70 seconds to run the runner file (this time is beatable).