Unit 4.3A Parallel Computing
Observe an algorithm using parallel computing in Python Code. Monitor processes on host.
- Analyzing Parallel Computing
- Sequential Processing
- Parallel Computing
- Observing Parallel Computing and Threads
- Hacks
Analyzing Parallel Computing
Once again we will use image lab, this time to review Parallel Computing.
- Change baseWidth in this line in code to increase computation requirements:
def process_image(image, baseWidth=512):
For instance 320, 512, 1024, 2048, 4096.- Compare Sequential and Parallel computing code and time to achieve outputs
from IPython.display import HTML, display
from pathlib import Path # https://medium.com/@ageitgey/python-3-quick-tip-the-easy-way-to-deal-with-file-paths-on-windows-mac-and-linux-11a072b58d5f
from PIL import Image as pilImage # as PIL Image is used to avoid conflicts
from io import BytesIO
import base64
import numpy as np
# prepares a series of images
def image_data(path=Path("images/"), images=None): # path of static images is defaulted
if images is None: # default image
images = [
{'source': "Internet", 'label': "Green Square", 'file': "green-square-16.png"},
{'source': "Peter Carolin", 'label': "Clouds Impression", 'file': "clouds-impression.png"},
{'source': "Peter Carolin", 'label': "Lassen Volcano", 'file': "lassen-volcano.jpg"}
]
for image in images:
# File to open
image['filename'] = path / image['file'] # file with path
return images
# Scale to baseWidth
def scale_image(img, baseWidth):
scalePercent = (baseWidth/float(img.size[0]))
scaleHeight = int((float(img.size[1])*float(scalePercent)))
scale = (baseWidth, scaleHeight)
return img.resize(scale)
# PIL image converted to base64
def image_to_base64(img, format):
with BytesIO() as buffer:
img.save(buffer, format)
return base64.b64encode(buffer.getvalue()).decode()
# Convert pixels to Grey Scale
def grey_pixel(pixel):
average = (pixel[0] + pixel[1] + pixel[2]) // 3 # average pixel values and use // for integer division
if len(pixel) > 3:
return( (average, average, average, pixel[3]) ) # PNG format
else:
return( (average, average, average) )
# Convert pixels to Red Scale
def red_pixel(pixel):
if len(pixel) > 3:
return( (pixel[0], 0, 0, pixel[3]) ) # PNG format
else:
return( (pixel[0], 0, 0) )
# Convert pixels to Red Scale
def green_pixel(pixel):
if len(pixel) > 3:
return( (0, pixel[1], 0, pixel[3]) ) # PNG format
else:
return( (0, pixel[1], 0) )
# Convert pixels to Red Scale
def blue_pixel(pixel):
if len(pixel) > 3:
return( (0, 0, pixel[2], pixel[3]) ) # PNG format
else:
return( (0, 0, pixel[2]) )
# Set Properties of Image, Scale, and convert to Base64
def image_management(image, baseWidth): # path of static images is defaulted
# Image open return PIL image object
img = pilImage.open(image['filename'])
# Python Image Library operations
image['format'] = img.format
image['mode'] = img.mode
image['size'] = img.size
# Scale the Image
img = scale_image(img, baseWidth)
image['pil'] = img
image['scaled_size'] = img.size
image['numpy'] = np.array(img.getdata())
# Scaled HTML
image['html'] = '<img src="data:image/png;base64,%s">' % image_to_base64(image['pil'], image['format'])
# Grey HTML
# each pixel in numpy array is turned to grey
# then resulting list, using List Comprehension, is put back into img
img.putdata([grey_pixel(pixel) for pixel in image['numpy']])
image['html_grey'] = '<img src="data:image/png;base64,%s">' % image_to_base64(img, image['format'])
# Red HTML
img.putdata([red_pixel(pixel) for pixel in image['numpy']])
image['html_red'] = '<img src="data:image/png;base64,%s">' % image_to_base64(img, image['format'])
# Green HTML
img.putdata([green_pixel(pixel) for pixel in image['numpy']])
image['html_green'] = '<img src="data:image/png;base64,%s">' % image_to_base64(img, image['format'])
# Blue HTML
img.putdata([blue_pixel(pixel) for pixel in image['numpy']])
image['html_blue'] = '<img src="data:image/png;base64,%s">' % image_to_base64(img, image['format'])
def process_image(image, baseWidth=320):
image_management(image, baseWidth)
print("---- meta data -----")
print(image['label'])
print(image['source'])
print(image['format'])
print(image['mode'])
print("Original size: ", image['size'])
print("Scaled size: ", image['scaled_size'])
print("-- images --")
display(HTML(image['html']))
display(HTML(image['html_grey']))
display(HTML(image['html_red']))
display(HTML(image['html_green']))
display(HTML(image['html_blue']))
if __name__ == "__main__":
# setup default images
images = image_data()
# Sequential Processing
for image in images:
process_image(image)
print()
Parallel Computing
In parallel or concurrent mode, the ThreadPoolExecutor is used to submit each image to a separate worker thread, allowing multiple images to be processed simultaneously. Multithreading allows multiple concurrent tasks of a process at the same time. The executor.map() method is used to apply the process_image function to each image in the images list.
- The order in which the images are processed is not guaranteed, as threads are performed simultaneously.
import concurrent.futures
# Jupyter Notebook Visualization of Images
if __name__ == "__main__":
# setup default images
images = image_data()
# Parallel Processsing
# executor allocates threads, it considers core execution capability of machine
with concurrent.futures.ThreadPoolExecutor() as executor:
executor.map(process_image, images) # order is not predictable
print()
Observing Parallel Computing and Threads
You can observe Processes, CPU Percentage, and Threads with Tools on your machine. Common tools to monitor performance are Activity Monitor on MacOS or Task Manager on Windows.
- This example is using
top
launched in VSCode Terminal. (mac) - Try
top -H
for linux.- PID is Process ID.
- COMMAND is task running on machine. Python is activated when running this Jupyter notebook.
- #TH is number of threads. This increases from 15/1 to 18/1 on my machine when running python parallel computing example.
Hacks
AP Classroom. Provide answers and thoughts on theoritical question form college board Video in section 4.3. They start at about the 9 minute mark.
- Example 1:The minimum amount of time to execute all three processes when the two processors are run in parallel is 50 seconds. Process X can be run on Processor 1, so that will take 50 seconds, and while that is running Process Y can run on processor 2, for 10 seconds. When Process Y is done, Process X is still continuing to run, but processor 2 is open so Process Z can be run on processor 2. That will take another 30 seconds. Then, after Process Z is finished, Process X still takes 10 more seconds to complete. That in total takes 50 seconds, the amount of time for Process X to run.- Example 2: If you run them on a single processor one after another, then it will take 25 seconds plus 45 seconds, so it will take 70 seconds. However, if you run them in parallel, then it will only take 45 seconds, the amount of time for Process B to run because Process B takes longer than Process A. Therefore, the difference is 25 seconds.
Data Structures. Build a List Comprehension example
- list = [calc(item) for item in items]
TS_folklore = ["exile", "my tears ricochet", "this is me trying", "illicit affairs", "august", "mirrorball", "betty", "mad woman", "epiphany", "peace", "cardigan"]
# this list is only songs that have less than 10 characters in the title
TS_folklore_updated = [x for x in TS_folklore if len(x) < 7]
print("These are the songs in Taylor Swift's folklore album that have less than 7 characters in their title")
print(TS_folklore_updated)
TS_folklore_ratings = {"exile": 8, "my tears ricochet": 6, "this is me trying": 7, "illicit affairs": 8, "august": 4, "mirrorball": 3, "betty": 6, "mad woman": 6, "epiphany": 2, "peace": 10, "cardigan": 10}
TS_folklore_best = {k:v for (k,v) in TS_folklore_ratings.items() if v>7}
print("These are the songs in Taylor Swift's folklore album that I give a rating greater than 7")
print(TS_folklore_best)