From c463195a25906d4369003a08d1f5ea748a814419 Mon Sep 17 00:00:00 2001 From: Lukas Prause Date: Thu, 16 Mar 2023 18:14:54 +0100 Subject: [PATCH] Pls fix. --- plot_single_transmission.py | 91 +++++++++++++++---------------------- 1 file changed, 36 insertions(+), 55 deletions(-) diff --git a/plot_single_transmission.py b/plot_single_transmission.py index 27bf807..91cd8ab 100755 --- a/plot_single_transmission.py +++ b/plot_single_transmission.py @@ -13,7 +13,7 @@ if __name__ == "__main__": parser = ArgumentParser() parser.add_argument("-s", "--serial_file", required=True, help="Serial csv file.") parser.add_argument("-p", "--pcap_csv_folder", required=True, help="PCAP csv folder.") - parser.add_argument("--save", default=None, help="Location to save pdf file.") + parser.add_argument("--save", required=True, help="Location to save pdf file.") parser.add_argument( "-i", "--interval", @@ -23,12 +23,7 @@ if __name__ == "__main__": ) args = parser.parse_args() - manager = multiprocessing.Manager() - n = manager.Value("i", 0) - frame_list = manager.list() - jobs = [] - # load all pcap csv into one dataframe pcap_csv_list = list() for filename in os.listdir(args.pcap_csv_folder): if filename.endswith(".csv") and "tcp" in filename: @@ -90,65 +85,37 @@ if __name__ == "__main__": right_index=True, left_index=True, ) + transmission_df = transmission_df.rename(columns={"PCID": "lte_pcid", "PCID.1": "nr_pcid"}) # transmission timeline - scaley = 1.5 scalex = 1.0 - ax0 = plt.subplot(211) + plt.title("{} with {}".format(transmission_direction, cc_algo)) + fig, ax = plt.subplots(2, 1, figsize=[6.4 * scaley, 4.8 * scalex]) + fig.subplots_adjust(right=0.75) + ax0 = ax[0] ax1 = ax0.twinx() ax2 = ax0.twinx() + ax2.spines.right.set_position(("axes", 3)) - ax00 = plt.subplot(212) + ax00 = ax[1] ax01 = ax00.twinx() - plt.title("{} with {}".format(transmission_direction, cc_algo)) + transmission_df["lte_handovers"] = transmission_df["lte_pcid"].diff() - # create list fo color indices for lte cells - color_dict = dict() - color_list = list() - i = 0 - for cell_id in transmission_df["PCID"]: - if cell_id not in color_dict: - color_dict[cell_id] = i - i += 1 - color_list.append(color_dict[cell_id]) - transmission_df["lte_cell_color"] = color_list - color_dict = None - color_list = None + lte_handovers = transmission_df[transmission_df.lte_pcid.diff() != 0].index.values + nr_handovers = transmission_df[transmission_df.nr_pcid.diff() != 0].index.values - cmap = matplotlib.cm.get_cmap("Set3") - unique_cells = transmission_df["lte_cell_color"].unique() - color_list = cmap.colors * (round(len(unique_cells) / len(cmap.colors)) + 1) + print(transmission_df["lte_handovers"]) + print(len(transmission_df["lte_handovers"])) + continue - transmission_df["index"] = transmission_df.index - for c in transmission_df["lte_cell_color"].unique(): - bounds = transmission_df[["index", "lte_cell_color"]].groupby("lte_cell_color").agg(["min", "max"]).loc[ - c] - ax0.axvspan(bounds.min(), bounds.max(), alpha=0.1, color=color_list[c]) - - # create list fo color indices for nr cells - color_dict = dict() - color_list = list() - i = 0 - for cell_id in transmission_df["PCID.1"]: - if cell_id not in color_dict: - color_dict[cell_id] = i - i += 1 - color_list.append(color_dict[cell_id]) - - transmission_df["nr_cell_color"] = color_list - color_dict = None - color_list = None - - cmap = matplotlib.cm.get_cmap("Set3") - unique_cells = transmission_df["nr_cell_color"].unique() - color_list = cmap.colors * (round(len(unique_cells) / len(cmap.colors)) + 1) - - for c in transmission_df["nr_cell_color"].unique(): - bounds = transmission_df[["index", "nr_cell_color"]].groupby("nr_cell_color").agg(["min", "max"]).loc[c] - ax00.axvspan(bounds.min(), bounds.max(), alpha=0.1, color=color_list[c]) + # Plot vertical lines + for item in lte_handovers[1::]: + ax00.axvline(item, ymin=0, ymax=1, color='red') + for item in nr_handovers[1::]: + ax00.axvline(item, ymin=0, ymax=1, color='red') ax0.plot(transmission_df["snd_cwnd"].dropna(), color="lime", linestyle="dashed", label="cwnd") ax1.plot(transmission_df["srtt"].dropna(), color="red", linestyle="dashdot", label="sRTT") @@ -156,11 +123,25 @@ if __name__ == "__main__": ax00.plot(transmission_df["downlink_cqi"].dropna(), color="magenta", linestyle="dotted", label="CQI") ax01.plot(transmission_df["DL_bandwidth"].dropna(), color="peru", linestyle="dotted", label="DL_bandwidth") - if args.save: - plt.savefig("{}{}_plot.pdf".format(args.save, csv.replace(".csv", ""))) + ax2.spines.right.set_position(("axes", 1.1)) + + ax0.set_ylim(0, 5000) + ax1.set_ylim(0, 0.3) + ax2.set_ylim(0, 500) + ax00.set_ylim(0, 16) + ax01.set_ylim(0, 21) + + ax00.set_xlabel("arrival time") + ax2.set_ylabel("Goodput [mbps]") + ax00.set_ylabel("CQI") + ax1.set_ylabel("sRTT [s]") + ax0.set_ylabel("cwnd") + ax01.set_ylabel("Bandwidth [MHz]") + + plt.savefig("{}{}_plot.pdf".format(args.save, csv.replace(".csv", ""))) #except Exception as e: # print("Error processing file: {}".format(csv)) # print(str(e)) counter += 1 - plt.clf() \ No newline at end of file + plt.clf()