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Adds 'some' error handling.

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This commit is contained in:
Lukas Prause
2023-03-09 14:45:13 +01:00
parent d74c87a4d2
commit e2625998c6
1 changed files with 101 additions and 97 deletions
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198
plot_single_transmission_timeline.py
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@@ -44,125 +44,129 @@ if __name__ == "__main__":
for csv in pcap_csv_list: for csv in pcap_csv_list:
print("\rProcessing {} out of {} CSVs.\t({}%)\t".format(counter, len(pcap_csv_list), math.floor(counter/len(pcap_csv_list)))) print("\rProcessing {} out of {} CSVs.\t({}%)\t".format(counter, len(pcap_csv_list), math.floor(counter/len(pcap_csv_list))))
transmission_df = pd.read_csv(
"{}{}".format(args.pcap_csv_folder, csv),
dtype=dict(is_retranmission=bool, is_dup_ack=bool),
)
transmission_df["datetime"] = pd.to_datetime(transmission_df["datetime"]) - pd.Timedelta(hours=1)
transmission_df = transmission_df.set_index("datetime")
transmission_df.index = pd.to_datetime(transmission_df.index)
transmission_df = transmission_df.sort_index()
# srtt to [s] try:
transmission_df["srtt"] = transmission_df["srtt"].apply(lambda x: x / 10**6) transmission_df = pd.read_csv(
"{}{}".format(args.pcap_csv_folder, csv),
dtype=dict(is_retranmission=bool, is_dup_ack=bool),
)
transmission_df["datetime"] = pd.to_datetime(transmission_df["datetime"]) - pd.Timedelta(hours=1)
transmission_df = transmission_df.set_index("datetime")
transmission_df.index = pd.to_datetime(transmission_df.index)
transmission_df = transmission_df.sort_index()
# key for columns and level for index # srtt to [s]
transmission_df["goodput"] = transmission_df["payload_size"].groupby(pd.Grouper(level="datetime", freq="{}s".format(args.interval))).transform("sum") transmission_df["srtt"] = transmission_df["srtt"].apply(lambda x: x / 10**6)
transmission_df["goodput"] = transmission_df["goodput"].apply(
lambda x: ((x * 8) / args.interval) / 10**6
)
transmission_df["goodput_rolling"] = transmission_df["payload_size"].rolling("{}s".format(args.interval)).sum() # key for columns and level for index
transmission_df["goodput_rolling"] = transmission_df["goodput_rolling"].apply( transmission_df["goodput"] = transmission_df["payload_size"].groupby(pd.Grouper(level="datetime", freq="{}s".format(args.interval))).transform("sum")
lambda x: ((x * 8) / args.interval) / 10 ** 6 transmission_df["goodput"] = transmission_df["goodput"].apply(
) lambda x: ((x * 8) / args.interval) / 10**6
)
# set meta values and remove all not needed columns transmission_df["goodput_rolling"] = transmission_df["payload_size"].rolling("{}s".format(args.interval)).sum()
cc_algo = transmission_df["congestion_control"].iloc[0] transmission_df["goodput_rolling"] = transmission_df["goodput_rolling"].apply(
cc_algo = cc_algo.upper() lambda x: ((x * 8) / args.interval) / 10 ** 6
transmission_direction = transmission_df["direction"].iloc[0] )
#transmission_df = transmission_df.filter(["goodput", "datetime", "ack_rtt", "goodput_rolling", "snd_cwnd"]) # set meta values and remove all not needed columns
cc_algo = transmission_df["congestion_control"].iloc[0]
cc_algo = cc_algo.upper()
transmission_direction = transmission_df["direction"].iloc[0]
# read serial csv #transmission_df = transmission_df.filter(["goodput", "datetime", "ack_rtt", "goodput_rolling", "snd_cwnd"])
serial_df = pd.read_csv(args.serial_file)
serial_df["datetime"] = pd.to_datetime(serial_df["datetime"]) - pd.Timedelta(hours=1)
serial_df = serial_df.set_index("datetime")
serial_df.index = pd.to_datetime(serial_df.index)
serial_df.sort_index()
transmission_df = pd.merge_asof( # read serial csv
transmission_df, serial_df = pd.read_csv(args.serial_file)
serial_df, serial_df["datetime"] = pd.to_datetime(serial_df["datetime"]) - pd.Timedelta(hours=1)
tolerance=pd.Timedelta("1s"), serial_df = serial_df.set_index("datetime")
right_index=True, serial_df.index = pd.to_datetime(serial_df.index)
left_index=True, serial_df.sort_index()
)
# transmission timeline transmission_df = pd.merge_asof(
transmission_df,
serial_df,
tolerance=pd.Timedelta("1s"),
right_index=True,
left_index=True,
)
scaley = 1.5 # transmission timeline
scalex = 1.0
fig, ax = plt.subplots(figsize=[6.4 * scaley, 4.8 * scalex])
plt.title("{} with {}".format(transmission_direction, cc_algo))
fig.subplots_adjust(right=0.75)
twin1 = ax.twinx() scaley = 1.5
twin2 = ax.twinx() scalex = 1.0
twin3 = ax.twinx() fig, ax = plt.subplots(figsize=[6.4 * scaley, 4.8 * scalex])
# Offset the right spine of twin2. The ticks and label have already been plt.title("{} with {}".format(transmission_direction, cc_algo))
# placed on the right by twinx above. fig.subplots_adjust(right=0.75)
twin2.spines.right.set_position(("axes", 1.1))
twin3.spines.right.set_position(("axes", 1.2)) twin1 = ax.twinx()
twin2 = ax.twinx()
twin3 = ax.twinx()
# Offset the right spine of twin2. The ticks and label have already been
# placed on the right by twinx above.
twin2.spines.right.set_position(("axes", 1.1))
twin3.spines.right.set_position(("axes", 1.2))
# create list fo color indices # create list fo color indices
transmission_df["index"] = transmission_df.index transmission_df["index"] = transmission_df.index
color_dict = dict() color_dict = dict()
color_list = list() color_list = list()
i = 0 i = 0
for cell_id in transmission_df["cellID"]: for cell_id in transmission_df["cellID"]:
if cell_id not in color_dict: if cell_id not in color_dict:
color_dict[cell_id] = i color_dict[cell_id] = i
i += 1 i += 1
color_list.append(color_dict[cell_id]) color_list.append(color_dict[cell_id])
transmission_df["cell_color"] = color_list transmission_df["cell_color"] = color_list
color_dict = None color_dict = None
color_list = None color_list = None
cmap = matplotlib.cm.get_cmap("Set3") cmap = matplotlib.cm.get_cmap("Set3")
unique_cells = transmission_df["cell_color"].unique() unique_cells = transmission_df["cell_color"].unique()
color_list = cmap.colors * (round(len(unique_cells) / len(cmap.colors)) + 1) color_list = cmap.colors * (round(len(unique_cells) / len(cmap.colors)) + 1)
for c in transmission_df["cell_color"].unique(): for c in transmission_df["cell_color"].unique():
bounds = transmission_df[["index", "cell_color"]].groupby("cell_color").agg(["min", "max"]).loc[c] bounds = transmission_df[["index", "cell_color"]].groupby("cell_color").agg(["min", "max"]).loc[c]
ax.axvspan(bounds.min(), bounds.max(), alpha=0.3, color=color_list[c]) ax.axvspan(bounds.min(), bounds.max(), alpha=0.3, color=color_list[c])
p4, = twin3.plot(transmission_df["snd_cwnd"].dropna(), color="lime", linestyle="dashed", label="cwnd") p4, = twin3.plot(transmission_df["snd_cwnd"].dropna(), color="lime", linestyle="dashed", label="cwnd")
p3, = twin2.plot(transmission_df["srtt"].dropna(), color="red", linestyle="dashdot", label="sRTT") p3, = twin2.plot(transmission_df["srtt"].dropna(), color="red", linestyle="dashdot", label="sRTT")
p1, = ax.plot(transmission_df["goodput_rolling"], color="blue", linestyle="solid", label="goodput") p1, = ax.plot(transmission_df["goodput_rolling"], color="blue", linestyle="solid", label="goodput")
p2, = twin1.plot(transmission_df["downlink_cqi"].dropna(), color="magenta", linestyle="dotted", label="CQI") p2, = twin1.plot(transmission_df["downlink_cqi"].dropna(), color="magenta", linestyle="dotted", label="CQI")
ax.set_xlim(transmission_df["index"].min(), transmission_df["index"].max()) ax.set_xlim(transmission_df["index"].min(), transmission_df["index"].max())
ax.set_ylim(0, 500) ax.set_ylim(0, 500)
twin1.set_ylim(0, 15) twin1.set_ylim(0, 15)
twin2.set_ylim(0, transmission_df["ack_rtt"].max()) twin2.set_ylim(0, transmission_df["ack_rtt"].max())
twin3.set_ylim(0, transmission_df["snd_cwnd"].max() + 10) twin3.set_ylim(0, transmission_df["snd_cwnd"].max() + 10)
ax.set_xlabel("arrival time") ax.set_xlabel("arrival time")
ax.set_ylabel("Goodput [mbps]") ax.set_ylabel("Goodput [mbps]")
twin1.set_ylabel("CQI") twin1.set_ylabel("CQI")
twin2.set_ylabel("sRTT [s]") twin2.set_ylabel("sRTT [s]")
twin3.set_ylabel("cwnd") twin3.set_ylabel("cwnd")
ax.yaxis.label.set_color(p1.get_color()) ax.yaxis.label.set_color(p1.get_color())
twin1.yaxis.label.set_color(p2.get_color()) twin1.yaxis.label.set_color(p2.get_color())
twin2.yaxis.label.set_color(p3.get_color()) twin2.yaxis.label.set_color(p3.get_color())
twin3.yaxis.label.set_color(p4.get_color()) twin3.yaxis.label.set_color(p4.get_color())
tkw = dict(size=4, width=1.5) tkw = dict(size=4, width=1.5)
ax.tick_params(axis='y', colors=p1.get_color(), **tkw) ax.tick_params(axis='y', colors=p1.get_color(), **tkw)
twin1.tick_params(axis='y', colors=p2.get_color(), **tkw) twin1.tick_params(axis='y', colors=p2.get_color(), **tkw)
twin2.tick_params(axis='y', colors=p3.get_color(), **tkw) twin2.tick_params(axis='y', colors=p3.get_color(), **tkw)
twin3.tick_params(axis='y', colors=p4.get_color(), **tkw) twin3.tick_params(axis='y', colors=p4.get_color(), **tkw)
ax.tick_params(axis='x', **tkw) ax.tick_params(axis='x', **tkw)
#ax.legend(handles=[p1, p2, p3]) #ax.legend(handles=[p1, p2, p3])
if args.save:
plt.savefig("{}{}_plot.pdf".format(args.save, csv.replace(".csv", "")))
if args.save:
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 counter += 1
plt.clf() plt.clf()