import math import time import datetime import os from os import remove from PIL import Image from multiprocessing import Pool import multiprocessing #starting message print("-"*79) print("Starting...") #path definition diskPath = 'D:/OpenTTD_repositories/BRIX/scripts/' #"C:/Users/Pavel/Downloads/scripts/"#"E:/_BRIX/_BRIX-repository/scripts/" inputFolder = diskPath + "input/" outputFolder = diskPath + "output/" #printing path just to check print("inputFolder is " + inputFolder) print("outputFolder is " + outputFolder) #started time tt = time.time() startedTime = datetime.datetime.fromtimestamp(tt).strftime('%H:%M:%S') #open palette image palette = Image.open(inputFolder + "openttd-palette-dos.png") print("Opening and loading palette: " + "openttd-palette-dos.png") p=[] for b in range(0,palette.height): for a in range(0, palette.width): p.append(palette.getpixel((a,b))) print('Palette loaded.') # ---------------------------------------------------------------------------------------------------------------- # ---------------------------------------------------------------------------------------------------------------- # ---------------------------------------------------------------------------------------------------------------- def rgb2palette(args): input_image = args[0] x_start = args[1] x_end = args[2] #open input image i = Image.open(inputFolder + input_image + ".png") print("Opening: " + input_image + ".png") #create new empty image for output imageOutput = Image.new("RGBA", (i.width,i.height), color=(0,0,0,0)) for y in range (0, i.height): #timeStamp ts = time.time() timeStamp = datetime.datetime.fromtimestamp(ts).strftime('%H:%M:%S') #print(timeStamp + " - " + input_image + " row {}".format(y)) for x in range (x_start, x_end): print(timeStamp + " - " + input_image + " row {}".format(x)) #defining winner variables winnerDistance = 100000000 winnerID = 0 #loading pixel from image and separating RGBA pixelNumber = x + (y * i.width) pix = i.getpixel((x,y)) pixRed = pix[0] pixGreen = pix[1] pixBlue = pix[2] pixAlpha = pix[3] #check Alpha in pixel, and output alpha/color offset if pixAlpha < 128: finalAlpha = 0 colorOffset = 0 if pixAlpha >= 128 and pixAlpha < 178: finalAlpha = 255 colorOffset = 1 if pixAlpha >= 178 and pixAlpha < 230: finalAlpha = 255 colorOffset = 2 if pixAlpha >= 230: finalAlpha = 255 colorOffset = 0 #if alpha above 50%, do colour comparing to palette if pixAlpha >= 128: for z, (r1, g1, b1, ca) in enumerate(p): #dr = pixRed - cr #dg = pixGreen - cg #db = pixBlue - cb #distance = dr*dr + dg*dg + db*db l1 = (r1*299 + g1*587 + b1*114) / 255000 l2 = (pixRed*299 + pixGreen*587 + pixBlue*114) / 255000 dL = l1-l2 dR = (r1-pixRed)/255 dG = (g1-pixGreen)/255 dB = (b1-pixBlue)/255 distance = (dR*dR*0.299 + dG*dG*0.587 + dB*dB*0.114)*0.75 + dL*dL if distance < winnerDistance: winnerDistance = distance winnerID = z #compare input RGB channels and output highest value if pixRed >= pixGreen and pixRed >= pixBlue: highestValue = pixRed if pixGreen >= pixRed and pixGreen >= pixBlue: highestValue = pixGreen if pixBlue >= pixRed and pixBlue >= pixGreen: highestValue = pixBlue # set color offset +/- based on colour value if highestValue < 128: negation = -1 colorOffset = colorOffset * negation #print("colorOffset is ... " + str(colorOffset) ) #final color changed by colorOffset finalColor = p[winnerID - colorOffset] finalR = finalColor[0] finalG = finalColor[1] finalB = finalColor[2] #finalAlpha taken from the if output above palette colour comparing #put the final pixel into the output picture imageOutput.putpixel((x,y),(finalR,finalG,finalB,finalAlpha)) #print("Pixel " + str(pixelNumber) + ": R= " + str(finalR) + ", G= " + str(finalG) + ", B= " + str(finalB) + ", A= " + str(finalAlpha) ) os.makedirs(outputFolder, exist_ok = True) print('Saving picture to Output') imageOutput.save(outputFolder + input_image[-5:] + "WTF_TESTING_8bpp.png") #assumes _#### frame number format (removes last 5 characters) def run(): # ---------------------------------------------------------------------------------------------------------------- #VARIABLES # ---------------------------------------------------------------------------------------------------------------- job_list = [ 'test0' #'BRIDGES_0000' #'LAND_OUTPUT_0000' ] # ---------------------------------------------------------------------------------------------------------------- thread_count = 16 # ---------------------------------------------------------------------------------------------------------------- # ---------------------------------------------------------------------------------------------------------------- # ---------------------------------------------------------------------------------------------------------------- for job in job_list: all_jobs = [] job_chunks = [] queue = [] extra = 0 chunk_image = Image.open(inputFolder + job + ".png") chunk_average_size = math.floor(chunk_image.width/thread_count) chunk_modulo_size = chunk_image.width % thread_count for thread in range(0, thread_count): start = chunk_average_size * thread end = (chunk_average_size * (thread+1)) -1 start += extra if thread < chunk_modulo_size: extra += 1 end += extra start_and_end = [job, start, end] job_chunks.append(start_and_end) queue.append( [job, start, end] ) #print(str(queue)) all_jobs.append(job_chunks) for a_job in all_jobs: #print('-'*32) thread_id = 0 for b_thread in a_job: if thread_id == 0: thread_id += 1 print('Job: ' + str(b_thread[0]))# print(' '*10 + 'Start, ' + 'End')# print('Thread ' + str(thread_id) + ': ' + str(b_thread[1]) + ', ' + str(b_thread[2]))# #print(all_jobs) # ---------------------------------------------------------------------------------------------------------------- # PROCESS # ---------------------------------------------------------------------------------------------------------------- pool = multiprocessing.Pool(processes = thread_count) for q in queue: pool.map(rgb2palette, queue) pool.close() pool.join() #imageOutput.save(outputFolder + input_image[-5:] + "_8bpp.png") #assumes _#### frame number format (removes last 5 characters) #print('SAVING IMAGE') #finished time tx = time.time() finishedTime = datetime.datetime.fromtimestamp(tx).strftime('%H:%M:%S') print("Started: " + startedTime) print("Finished: " + finishedTime) #run() if __name__ == '__main__': #freeze_support() run()