Lab Exercise 5: Lists as Information Collections
The purpose of this lab time is to prepare for project 5, which will use lists of information to produce collages.
Here is the reference guide to the Zelle graphics package.
Download two or more of the following images. Right click on the link and select 'Save As...'.
If you want to make the images smaller while testing, the command to shrink an image by half is below.
convert myImage.ppm -scale 50% mySmallImage.ppm
- On your personal volume, make a folder for project 5 (Project5). Then download the graphics and display packages. You can also just copy them over from project 4.
- Copy your filter.py file from your Project4 directory into your Project5 directory.
Now we're going to add alpha blending to the placeImage function in
your filter.py file. This is a modification of your existing
function. The new algorithm is given below. Each comment is a line of
python code. Note the added function parameter alpha.
def placeImage( dst, src, x, y, alpha ): # for each row i # for each column j # assign to (r1, g1, b1) the rgb values from src location (j, i) # assign to (r2, g2, b2) the rgb values from dst location (j + x, i + y) # assign to rnew the alpha blend of r1 and r2 # assign to gnew the alpha blend of g1 and g2 # assign to bnew the alpha blend of b1 and b2 # set dst pixel (j+x, i+y) to (rnew, gnew, bnew)
If you have two colors, (r1, g1, b1) and (r2, g2, b2), then the alpha blend of the red color band is given by the expression below. You will need to write a similar expression for the green and blue values. Note that the graphics color_rgb function expects integers, hence the cast.
r = int(r1 * alpha + r2 * (1.0 - alpha))
Remember to remove our comments once you have written the code (they contribute to clutter).
When you are finished, download the file testimage.py, read through the test file, and run it. As the usage statement indicates, it wants the names of two ppm images. When the program is finished, look at the image blend.ppm using your show.py file from last week.
If you wish, use the program xv to look at ppm images. Just type
on the command-line and it will display the image. Type 'q' in the image window to make the program quit. If this does not work, it means xv is not yet installed.
Note that in a terminal you can put a process into the background by adding the & symbol after the command. So if you type
xv blend.ppm &
you can still use the terminal and the xv program will run in the background. If you type return or enter in the xv window it will re-read the image from the file, so you don't have to quit xv while you are experimenting with an image.
The goal of the project this week is to enable you to easily blend
together multiple images, with various effects, into a collage.
Rather than hard code all the collage positions, however, we want to
put the essential information defining a collage into a list. Then we
can write a general function that takes in all of that information and
generates the correct collage image. To change the collage, we then
just change the information defining the collage, not the code.
What is the essential information that defines a collage?
First, we should identify the essential information for a single image, since a collage is just a collection of single images.
- Filename of the image
- X offset in the collage
- Y offset in the collage
- Effect for the image
- Alpha blend value
- The Image object (after being read from a file)
To store the information for a single image, we can use a list. To store the information for all of the images, we can use a list of lists. Consider the assignment below, which creates a list that defines a collage with two images.
collageList = [ [ 'maine1.ppm', 0, 0, 'rbswap', 0.8, None ], [ 'maine5.ppm', 200, 150, 'original', 0.8, None ] ]
The one problem with using a list is that when we need to access a parameter for a given image, we have to remember that parameter's index in the list. Consider looping over collageList and printing out the filename.
for pictureParams in collageList: print( pictureParams)
We have to remember that the filename will be pictureParams, since we set up the parameter list with that value in the first position.
Using a design where you have to use actual numbers means it is easy to make mistakes when you have to remember whether a given value is in position 4 or position 5. It also makes it hard to modify your code. For example, if you feel you need to add a new parameter to the list of parameters for a picture, what happens if you put it first in the list? That would mean you would have to go through all of your code and change the indexes everywhere you were accessing a parameter value. That's a lot of code and a lot of opportunities to make mistakes.
Instead, how could we use software engineering principles to avoid having to remember the index? What about using a module-level (top-level) variable whose value remains constant throughout the simulation? We can use it to index into the list. For example, we could create a variable IDXFilename that is set to 0, the index of the filename in the list of parameters for an image. Then, when we need to access the filename, we use code like
for pictureParams in collageList: print(pictureParams[IDXFilename])
instead of the code above. It's a lot easier to remember IDXFilename, and if you decide to change the position of the filename parameter in your list, you have to change only one place in your code: the assignment of a value to IDXFilename.
- Create a new file called collage.py. You will
want to import filter so you can use your filters to modify the
After the import statements, create the module-level variables you will use to access the individual picture lists. Create one variable for each of the picture parameters: filename, X offset, Y offset, filter, alpha, and Image. When naming your variables, please begin each name with IDX to indicate the value is an index, then use a name that indicates the field. Using IDX is not a Python rule, but a convention the differentiates these variables as having a special purpose. Each of the assignments will be something like the following.
IDXFilename = 0
Since we will be using mnemonic variables as indexes, it doesn't really matter what order you put the values into the list. However, if you want to be able to use the provided test code then the ordering needs to be: filename, x-offset, y-offset, filter, alpha, Image.
Copy the following test function into your collage.py and then add more print statements to test each of the parameter entries. Run it and make sure it prints out the right information for each of the pictures.
# project test function def test( argv ): collageList = [ [ 'maine1.ppm', 0, 0, 'rbswap', 0.8, None ], [ 'maine2.ppm', 200, 150, 'original', 0.8, None ] ] # test that the parameters are accessing the right value for picParams in collageList: print( '----------------------') print( 'filename:', picParams[IDXFilename]) print( 'X Offset:', picParams[IDXXoffset]) print( 'Y Offset:', picParams[IDXYoffset]) # add more print statements here, one for each parameter return if __name__ == "__main__": test( sys.argv )
- Next, write a function readImages. Given the collage list structure we designed above, write a function that reads in each of the images in the collage and for each image stores the corresponding Image in the picture list. The template is below.
# reads in the files in the collage and stores the Image objects in the list def readImages( clist ): # for each pictureParams in clist # assign to the variable filename the IDXFilename element of pictureParams # assign to the variable src, the Image returned by reading filename (graphics.Image) # assign to the IDXImage element of pictureParams the value in src
Test the readImages function by creating a test function in collage.py that makes the above collageList variable, calls readImages, and then prints out the names and sizes of each image. Since in the readImages function you stored a Image in the last location of each picture list, you can use the Image to getWidth() and getHeight(). You can use the template below in your test function.
# for each picParams in collageList: # print the IDXFilename element of picParams # print the result of using the IDXImage element of picParams to call the method getWidth() # print the result of using the IDXImage element of picParams to call the method getHeight()
Given the collage list structure we developed, write a function that calculates
how big the program needs to make the background Image to hold the collage.
def getImageSize( clist ): # assign to the variable rows, 0 # assign to the variable cols, 0 # for each item in clist # assign to x0 the x offset information in item # assign to y0 the y offset information in item # assign to src the Image reference (last element in item) # assign to dx the offset x0 plus the width of src # if dx is greater than cols # assign to cols, dx # assign to dy the offset y0 plus the height of src # if dy is greater than rows # assign to rows, dy # return a tuple with cols and rows in it
Test out your getImageSize function using the simple collage list above, after reading in the images using your readImages function. The answer should be 600 wide (cols) and 450 high (rows) if you use maine1.ppm and main2.ppm as test images.
Now that you have practice working with the collage information lists, you should be able to write a generic buildCollage program that creates a collage from the information in the list. And this is precisely what you will do in the project.
When you are done with the lab exercises, you may begin the project.