Python/other/game_of_life.py

'''Conway's Game Of Life, Author Anurag Kumar(mailto:anuragkumarak95@gmail.com) 

Requirements:
  - numpy
  - random
  - time
  - matplotlib

Python:
  - 3.5

Usage:
  - $python3 game_o_life <canvas_size:int>

Game-Of-Life Rules:
 
 1.
 Any live cell with fewer than two live neighbours
 dies, as if caused by under-population.
 2.
 Any live cell with two or three live neighbours lives
 on to the next generation.
 3.
 Any live cell with more than three live neighbours
 dies, as if by over-population.
 4.
 Any dead cell with exactly three live neighbours be-
 comes a live cell, as if by reproduction.
 '''
import numpy as np
import random, sys
from matplotlib import pyplot as plt
from matplotlib.colors import ListedColormap

usage_doc='Usage of script: script_nama <size_of_canvas:int>'

choice = [0]*100 + [1]*10
random.shuffle(choice)

def create_canvas(size):
    canvas = [ [False for i in range(size)] for j in range(size)]
    return canvas

def seed(canvas):
    for i,row in enumerate(canvas):
        for j,_ in enumerate(row):
            canvas[i][j]=bool(random.getrandbits(1))

def run(canvas):
    ''' This  function runs the rules of game through all points, and changes their status accordingly.(in the same canvas)
    @Args:
    --
    canvas : canvas of population to run the rules on.

    @returns:
    --
    None
    '''
    canvas = np.array(canvas)
    next_gen_canvas = np.array(create_canvas(canvas.shape[0]))
    for r, row in enumerate(canvas):
        for c, pt in enumerate(row):
            # print(r-1,r+2,c-1,c+2)
            next_gen_canvas[r][c] = __judge_point(pt,canvas[r-1:r+2,c-1:c+2])
    
    canvas = next_gen_canvas
    del next_gen_canvas # cleaning memory as we move on.
    return canvas.tolist()   

def __judge_point(pt,neighbours):
    dead  = 0
    alive = 0
    # finding dead or alive neighbours count.
    for i in neighbours:
        for status in i:
            if status: alive+=1
            else: dead+=1

    # handling duplicate entry for focus pt.
    if pt : alive-=1
    else : dead-=1
    
    # running the rules of game here.
    state = pt
    if pt:
        if alive<2:
            state=False
        elif alive==2 or alive==3:
            state=True
        elif alive>3:
            state=False
    else:
        if alive==3:
            state=True

    return state


if __name__=='__main__':
    if len(sys.argv) != 2: raise Exception(usage_doc)
   
    canvas_size = int(sys.argv[1])
    # main working structure of this module.
    c=create_canvas(canvas_size)
    seed(c)
    fig, ax = plt.subplots()
    fig.show() 
    cmap = ListedColormap(['w','k'])
    try:
        while True:
            c = run(c)            
            ax.matshow(c,cmap=cmap)
            fig.canvas.draw()
            ax.cla() 
    except KeyboardInterrupt:
        # do nothing.
        pass
[other] Added Conway's Game of Life Experiment. 2017-10-26 06:41:32 +00:00			`'''Conway's Game Of Life, Author Anurag Kumar(mailto:anuragkumarak95@gmail.com)`

			`Requirements:`
			`- numpy`
			`- random`
			`- time`
			`- matplotlib`

			`Python:`
			`- 3.5`

			`Usage:`
			`- $python3 game_o_life <canvas_size:int>`

			`Game-Of-Life Rules:`

			`1.`
			`Any live cell with fewer than two live neighbours`
			`dies, as if caused by under-population.`
			`2.`
			`Any live cell with two or three live neighbours lives`
			`on to the next generation.`
			`3.`
			`Any live cell with more than three live neighbours`
			`dies, as if by over-population.`
			`4.`
			`Any dead cell with exactly three live neighbours be-`
			`comes a live cell, as if by reproduction.`
			`'''`
			`import numpy as np`
Remove Multiple Unused Imports and Variable 2018-10-17 21:28:57 +00:00			`import random, sys`
[other] Added Conway's Game of Life Experiment. 2017-10-26 06:41:32 +00:00			`from matplotlib import pyplot as plt`
			`from matplotlib.colors import ListedColormap`

			`usage_doc='Usage of script: script_nama <size_of_canvas:int>'`

			`choice = [0]100 + [1]10`
			`random.shuffle(choice)`

			`def create_canvas(size):`
			`canvas = [ [False for i in range(size)] for j in range(size)]`
			`return canvas`

			`def seed(canvas):`
			`for i,row in enumerate(canvas):`
			`for j,_ in enumerate(row):`
			`canvas[i][j]=bool(random.getrandbits(1))`

			`def run(canvas):`
			`''' This function runs the rules of game through all points, and changes their status accordingly.(in the same canvas)`
			`@Args:`
			`--`
			`canvas : canvas of population to run the rules on.`

			`@returns:`
			`--`
			`None`
			`'''`
			`canvas = np.array(canvas)`
			`next_gen_canvas = np.array(create_canvas(canvas.shape[0]))`
			`for r, row in enumerate(canvas):`
			`for c, pt in enumerate(row):`
			`# print(r-1,r+2,c-1,c+2)`
			`next_gen_canvas[r][c] = __judge_point(pt,canvas[r-1:r+2,c-1:c+2])`

			`canvas = next_gen_canvas`
			`del next_gen_canvas # cleaning memory as we move on.`
			`return canvas.tolist()`

			`def __judge_point(pt,neighbours):`
			`dead = 0`
			`alive = 0`
			`# finding dead or alive neighbours count.`
			`for i in neighbours:`
			`for status in i:`
			`if status: alive+=1`
			`else: dead+=1`

			`# handling duplicate entry for focus pt.`
			`if pt : alive-=1`
			`else : dead-=1`

			`# running the rules of game here.`
			`state = pt`
			`if pt:`
			`if alive<2:`
			`state=False`
			`elif alive==2 or alive==3:`
			`state=True`
			`elif alive>3:`
			`state=False`
			`else:`
			`if alive==3:`
			`state=True`

			`return state`


			`if __name__=='__main__':`
			`if len(sys.argv) != 2: raise Exception(usage_doc)`

			`canvas_size = int(sys.argv[1])`
			`# main working structure of this module.`
			`c=create_canvas(canvas_size)`
			`seed(c)`
			`fig, ax = plt.subplots()`
			`fig.show()`
			`cmap = ListedColormap(['w','k'])`
			`try:`
			`while True:`
			`c = run(c)`
			`ax.matshow(c,cmap=cmap)`
			`fig.canvas.draw()`
			`ax.cla()`
			`except KeyboardInterrupt:`
			`# do nothing.`
			`pass`