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measurement-scripts/plot_single_transmission.py

166 satır
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  1. #!/usr/bin/env python3

  2. import math

  3. import multiprocessing

  4. import os

  5. from argparse import ArgumentParser

  6. 

  7. import matplotlib

  8. import pandas as pd

  9. import matplotlib.pyplot as plt

  10. 

  11. 

  12. if __name__ == "__main__":

  13.     parser = ArgumentParser()

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

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

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

  17.     parser.add_argument(

  18.         "-i",

  19.         "--interval",

  20.         default=10,

  21.         type=int,

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

  23.     )

  24. 

  25.     args = parser.parse_args()

  26.     manager = multiprocessing.Manager()

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

  28.     frame_list = manager.list()

  29.     jobs = []

  30. 

  31.     # load all pcap csv into one dataframe

  32.     pcap_csv_list = list()

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

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

  35.             pcap_csv_list.append(filename)

  36. 

  37.     counter = 1

  38.     if len(pcap_csv_list) == 0:

  39.         print("No CSV files found.")

  40. 

  41.     pcap_csv_list.sort(key=lambda x: int(x.split("_")[-1].replace(".csv", "")))

  42. 

  43.     for csv in pcap_csv_list:

  44. 

  45.         print("\rProcessing {} out of {} CSVs.\t({}%)\t".format(counter, len(pcap_csv_list), math.floor(counter/len(pcap_csv_list))))

  46. 

  47.         #try:

  48.         transmission_df = pd.read_csv(

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

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

  51.         )

  52. 

  53.         transmission_df["datetime"] = pd.to_datetime(transmission_df["datetime"]) - pd.Timedelta(hours=1)

  54.         transmission_df = transmission_df.set_index("datetime")

  55.         transmission_df.index = pd.to_datetime(transmission_df.index)

  56.         transmission_df = transmission_df.sort_index()

  57. 

  58.         # srtt to [s]

  59.         transmission_df["srtt"] = transmission_df["srtt"].apply(lambda x: x / 10**6)

  60. 

  61.         # key for columns and level for index

  62.         transmission_df["goodput"] = transmission_df["payload_size"].groupby(pd.Grouper(level="datetime", freq="{}s".format(args.interval))).transform("sum")

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

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

  65.         )

  66. 

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

  68.         transmission_df["goodput_rolling"] = transmission_df["goodput_rolling"].apply(

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

  70.         )

  71. 

  72.         # set meta values and remove all not needed columns

  73.         cc_algo = transmission_df["congestion_control"].iloc[0]

  74.         cc_algo = cc_algo.upper()

  75.         transmission_direction = transmission_df["direction"].iloc[0]

  76. 

  77.         #transmission_df = transmission_df.filter(["goodput", "datetime", "ack_rtt", "goodput_rolling", "snd_cwnd"])

  78. 

  79.         # read serial csv

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

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

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

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

  84.         serial_df.sort_index()

  85. 

  86.         transmission_df = pd.merge_asof(

  87.             transmission_df,

  88.             serial_df,

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

  90.             right_index=True,

  91.             left_index=True,

  92.         )

  93. 

  94.         # transmission timeline

  95. 

  96.         scaley = 1.5

  97.         scalex = 1.0

  98.         ax0 = plt.subplot(211)

  99.         ax1 = ax0.twinx()

  100.         ax2 = ax0.twinx()

  101. 

  102.         ax00 = plt.subplot(212)

  103.         ax01 = ax00.twinx()

  104. 

  105.         plt.title("{} with {}".format(transmission_direction, cc_algo))

  106. 

  107.         # create list fo color indices for lte cells

  108.         color_dict = dict()

  109.         color_list = list()

  110.         i = 0

  111.         for cell_id in transmission_df["PCID"]:

  112.             if cell_id not in color_dict:

  113.                 color_dict[cell_id] = i

  114.                 i += 1

  115.             color_list.append(color_dict[cell_id])

  116. 

  117.         transmission_df["lte_cell_color"] = color_list

  118.         color_dict = None

  119.         color_list = None

  120. 

  121.         cmap = matplotlib.cm.get_cmap("Set3")

  122.         unique_cells = transmission_df["lte_cell_color"].unique()

  123.         color_list = cmap.colors * (round(len(unique_cells) / len(cmap.colors)) + 1)

  124. 

  125.         transmission_df["index"] = transmission_df.index

  126.         for c in transmission_df["lte_cell_color"].unique():

  127.             bounds = transmission_df[["index", "lte_cell_color"]].groupby("lte_cell_color").agg(["min", "max"]).loc[

  128.                 c]

  129.             ax0.axvspan(bounds.min(), bounds.max(), alpha=0.1, color=color_list[c])

  130. 

  131.         # create list fo color indices for nr cells

  132.         color_dict = dict()

  133.         color_list = list()

  134.         i = 0

  135.         for cell_id in transmission_df["PCID.1"]:

  136.             if cell_id not in color_dict:

  137.                 color_dict[cell_id] = i

  138.                 i += 1

  139.             color_list.append(color_dict[cell_id])

  140. 

  141.         transmission_df["nr_cell_color"] = color_list

  142.         color_dict = None

  143.         color_list = None

  144. 

  145.         cmap = matplotlib.cm.get_cmap("Set3")

  146.         unique_cells = transmission_df["nr_cell_color"].unique()

  147.         color_list = cmap.colors * (round(len(unique_cells) / len(cmap.colors)) + 1)

  148. 

  149.         for c in transmission_df["nr_cell_color"].unique():

  150.             bounds = transmission_df[["index", "nr_cell_color"]].groupby("nr_cell_color").agg(["min", "max"]).loc[c]

  151.             ax00.axvspan(bounds.min(), bounds.max(), alpha=0.1, color=color_list[c])

  152. 

  153.         ax0.plot(transmission_df["snd_cwnd"].dropna(), color="lime", linestyle="dashed", label="cwnd")

  154.         ax1.plot(transmission_df["srtt"].dropna(), color="red", linestyle="dashdot", label="sRTT")

  155.         ax2.plot(transmission_df["goodput_rolling"], color="blue", linestyle="solid", label="goodput")

  156.         ax00.plot(transmission_df["downlink_cqi"].dropna(), color="magenta", linestyle="dotted", label="CQI")

  157.         ax01.plot(transmission_df["DL_bandwidth"].dropna(), color="peru", linestyle="dotted", label="DL_bandwidth")

  158. 

  159.         if args.save:

  160.             plt.savefig("{}{}_plot.pdf".format(args.save, csv.replace(".csv", "")))

  161.         #except Exception as e:

  162.         #    print("Error processing file: {}".format(csv))

  163.         #    print(str(e))

  164.         counter += 1

  165. 

  166.         plt.clf()