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measurement-scripts/plot_transmission_timeline.py

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  1. #!/usr/bin/env python3

  2. import multiprocessing

  3. import os

  4. from argparse import ArgumentParser

  5. from math import ceil

  6. from time import sleep

  7. 

  8. import pandas as pd

  9. import matplotlib.pyplot as plt

  10. from mpl_toolkits import axisartist

  11. from mpl_toolkits.axes_grid1 import host_subplot

  12. 

  13. 

  14. 

  15. def csv_to_dataframe(csv_list, dummy):

  16. 

  17.     global n

  18.     global frame_list

  19. 

  20.     transmission_df = None

  21. 

  22.     for csv in csv_list:

  23.         tmp_df = pd.read_csv(

  24.             "{}{}".format(args.pcap_csv_folder, csv),

  25.             dtype=dict(is_retranmission=bool, is_dup_ack=bool),

  26.         )

  27.         tmp_df["datetime"] = pd.to_datetime(tmp_df["datetime"]) - pd.Timedelta(hours=1)

  28.         tmp_df = tmp_df.set_index("datetime")

  29.         tmp_df.index = pd.to_datetime(tmp_df.index)

  30.         if transmission_df is None:

  31.             transmission_df = tmp_df

  32.         else:

  33.             transmission_df = pd.concat([transmission_df, tmp_df])

  34. 

  35.         n.value += 1

  36. 

  37.     frame_list.append(transmission_df)

  38. 

  39. 

  40. from itertools import islice

  41. 

  42. def chunk(it, size):

  43.     it = iter(it)

  44.     return iter(lambda: tuple(islice(it, size)), ())

  45. 

  46. 

  47. if __name__ == "__main__":

  48.     parser = ArgumentParser()

  49.     parser.add_argument("-f", "--gps_file", required=True, help="GPS csv file.")

  50.     parser.add_argument("-s", "--serial_file", required=True, help="Serial csv file.")

  51.     parser.add_argument("-p", "--pcap_csv_folder", required=True, help="PCAP csv folder.")

  52.     parser.add_argument("--save", default=None, help="Location to save pdf file.")

  53.     parser.add_argument(

  54.         "--show_providerinfo",

  55.         default=False,

  56.         help="Show providerinfo for map tiles an zoom levels.",

  57.     )

  58.     parser.add_argument(

  59.         "-c",

  60.         "--cores",

  61.         default=1,

  62.         type=int,

  63.         help="Number of cores for multiprocessing.",

  64.     )

  65.     parser.add_argument(

  66.         "-i",

  67.         "--interval",

  68.         default=10,

  69.         type=int,

  70.         help="Time interval for rolling window.",

  71.     )

  72. 

  73.     args = parser.parse_args()

  74.     manager = multiprocessing.Manager()

  75.     n = manager.Value("i", 0)

  76.     frame_list = manager.list()

  77.     jobs = []

  78. 

  79.     # load all pcap csv into one dataframe

  80.     pcap_csv_list = list()

  81.     for filename in os.listdir(args.pcap_csv_folder):

  82.         if filename.endswith(".csv") and "tcp" in filename:

  83.             pcap_csv_list.append(filename)

  84. 

  85.     parts = chunk(pcap_csv_list, ceil(len(pcap_csv_list) / args.cores))

  86.     print("Start processing with {} jobs.".format(args.cores))

  87.     for p in parts:

  88.         process = multiprocessing.Process(target=csv_to_dataframe, args=(p, "dummy"))

  89.         jobs.append(process)

  90. 

  91.     for j in jobs:

  92.         j.start()

  93. 

  94.     print("Started all jobs.")

  95.     # Ensure all of the processes have finished

  96.     finished_job_counter = 0

  97.     working = ["|", "/", "-", "\\", "|", "/", "-", "\\"]

  98.     w = 0

  99.     while len(jobs) != finished_job_counter:

  100.         sleep(1)

  101.         print(

  102.             "\r\t{}{}{}\t Running {} jobs ({} finished). Processed {} out of {} pcap csv files.    ({}%)    ".format(

  103.                 working[w],

  104.                 working[w],

  105.                 working[w],

  106.                 len(jobs),

  107.                 finished_job_counter,

  108.                 n.value,

  109.                 len(pcap_csv_list),

  110.                 round((n.value / len(pcap_csv_list)) * 100, 2),

  111.             ),

  112.             end="",

  113.         )

  114.         finished_job_counter = 0

  115.         for j in jobs:

  116.             if not j.is_alive():

  117.                 finished_job_counter += 1

  118.         if (w + 1) % len(working) == 0:

  119.             w = 0

  120.         else:

  121.             w += 1

  122.     print("\r\nSorting table...")

  123. 

  124.     transmission_df = pd.concat(frame_list)

  125.     frame_list = None

  126.     transmission_df = transmission_df.sort_index()

  127. 

  128.     print("Calculate goodput...")

  129.     transmission_df["goodput"] = transmission_df["payload_size"].rolling("{}s".format(args.interval)).sum()

  130.     transmission_df["goodput"] = transmission_df["goodput"].apply(

  131.         lambda x: ((x * 8) / args.interval) / 10**6

  132.     )

  133. 

  134.     # remove all not needed columns

  135.     transmission_df = transmission_df.filter(["goodput", "datetime"])

  136. 

  137.     # read serial csv

  138.     serial_df = pd.read_csv(args.serial_file)

  139.     serial_df["datetime"] = pd.to_datetime(serial_df["datetime"]) - pd.Timedelta(hours=1)

  140.     serial_df = serial_df.set_index("datetime")

  141.     serial_df.index = pd.to_datetime(serial_df.index)

  142. 

  143.     transmission_df = pd.merge_asof(

  144.         transmission_df,

  145.         serial_df,

  146.         tolerance=pd.Timedelta("1s"),

  147.         right_index=True,

  148.         left_index=True,

  149.     )

  150. 

  151.     scaley = 1.5

  152.     scalex = 1.0

  153.     plt.figure(figsize=[6.4 * scaley, 4.8 * scalex])

  154. 

  155.     host = host_subplot(111, axes_class=axisartist.Axes)

  156.     plt.subplots_adjust()

  157. 

  158.     # additional y axes

  159.     par11 = host.twinx()

  160.     par12 = host.twinx()

  161.     # par13 = host.twinx()

  162. 

  163.     # axes offset

  164.     par12.axis["right"] = par12.new_fixed_axis(loc="right", offset=(60, 0))

  165.     # par13.axis["right"] = par13.new_fixed_axis(loc="right", offset=(120, 0))

  166. 

  167.     par11.axis["right"].toggle(all=True)

  168.     par12.axis["right"].toggle(all=True)

  169.     # par13.axis["right"].toggle(all=True)

  170. 

  171.     host.plot(transmission_df["goodput"], "-", color="blue", label="goodput" )

  172.     host.set_xlabel("datetime")

  173.     host.set_ylabel("goodput [Mbps]")

  174.     #host.set_ylim([0, 13])

  175.     #host.set_yscale("log")

  176.     #host.set_yscale("log")

  177.     #host.set_yscale("log")

  178.     #host.set_yscale("log")

  179. 

  180.     par11.plot(transmission_df["downlink_cqi"], "--", color="green", label="CQI")

  181.     par11.set_ylabel("CQI")

  182.     par11.set_ylim([0, 15])

  183. 

  184.     par12.plot()

  185. 

  186.     if args.save:

  187.         plt.savefig("{}timeline_plot.pdf".format(args.save))

  188.     else:

  189.         plt.show()

  190. 

  191.     plt.clf()

  192. 

  193.     print("Calculate and polt CDF...")

  194.     # Get the frequency, PDF and CDF for each value in the series

  195.     # copy column

  196.     transmission_df["gp_frequency"] = transmission_df.loc[:, "goodput"]

  197. 

  198.     # Frequency

  199.     transmission_df = transmission_df.groupby("gp_frequency")["gp_frequency"].agg("count").pipe(pd.DataFrame)

  200. 

  201.     # PDF

  202.     transmission_df["pdf"] = transmission_df["gp_frequency"] / sum(transmission_df["gp_frequency"])

  203. 

  204.     # CDF

  205.     transmission_df["cdf"] = transmission_df["pdf"].cumsum()

  206.     #transmission_df = transmission_df.reset_index()

  207. 

  208.     transmission_df.plot(x="goodput", y=["cdf"], grid=True)

  209. 

  210.     if args.save:

  211.         plt.savefig("{}cdf_plot.pdf".format(args.save))

  212.     else:

  213.         plt.show()