Files
wlan-lanforge-scripts/lf_tos_plus_test.py
2020-04-22 06:43:55 -07:00

837 lines
33 KiB
Python
Executable File

#!/usr/bin/python3
'''
Create connections using stations with different a/b/g/n/AC/AX modes,
traffic with different QoS, packet size, requested rate, and tcp or udp protocol.
Report the latency and other throughput values.
Optionally start packet-capture on secondary radio(s) and upstream port.
When specifying ports, if the port starts with [Number]., like 1.eth1, then the 1 specifies
the resource ID.
The --cx argument is defined as: station-radio, station-port, mode, upstream-port, protocol, pkt-size, speed_ul, speed_dl, QoS.
Pass this argument multiple times to create multiple connections.
The --radio argument is defined as: radio, spatial-streams, channel
Use NA if you do not want to change from current values. Use 0 for any channel.
Supported modes are: a, b, g, abg, abgn, bgn, bg, abgnAC, anAC, an, bgnAC, abgnAX, bgnAX, anAX
If sniffer_radios is specified, then the lf_sniff.py script will be started in the background once
the stations have become admin-up, and the sniff will run for the entire duration time specified
(there is not a good way to stop the capture early based on packets-sent since on-the-air frames
are very likely more than the PDU count)
# Run connections on wlan0 and sta0 for 1 minute, set radio wiphy0 to use any frequency
# and 2 spatial streams. Use wiphy2 as a sniffer, stop traffic after 10,000 PDUs
# have been sent. Sniffer radio will automatically change to the correct settings
# to sniff the first station. --wait_sniffer 1 tells the script to pause until the
# sniffer process has completed.
./lf_tos_plus_test.py --dur 1 --lfmgr 192.168.100.156 --ssid NETGEAR68-5G --passwd aquaticbug712 \
--radio "1.wiphy0 2 0" --txpkts 9999 --wait_sniffer 1 \
--cx "1.wiphy0 1.wlan0 an 1.eth1 udp 1024 10000 500000000 BK" \
--cx "1.wiphy0 1.wlan0 an 1.eth1 udp MTU 10000 500000000 VI" \
--cx "1.wiphy0 1.sta0 anAC 1.eth1 tcp 1472 56000 2000000 BK" \
--sniffer_radios "1.wiphy2"
# You can also create connections between non-station endpoints.
./lf_tos_plus_test.py --dur 1 --lfmgr 192.168.100.156 --txpkts 99 \
--cx "NA 1.rddVR0 NA 1.rddVR1 tcp MTU 1000000 2000000 0" --wait_sniffer 1
make sure pexpect, pandas is installed:
$ sudo yum install python3-pandas
$ sudo yum install python3-pexpect
$ sudo yum install python3-xlsxwriter
You might need to install pexpect-serial using pip:
$ pip3 install pexpect-serial
$ pip3 install XlsxWriter
'''
# TODO: Maybe HTML output too?
# TODO: Allow selecting tabs or commas for output files
import sys
import os
if sys.version_info[0] != 3:
print("This script requires Python 3")
exit()
import re
import logging
import time
from time import sleep
import pprint
import argparse
import subprocess
import xlsxwriter
import datetime
import pandas as pd
from subprocess import PIPE
NL = "\n"
CR = "\r\n"
Q = '"'
A = "'"
FORMAT = '%(asctime)s %(name)s %(levelname)s: %(message)s'
lfmgr = "127.0.0.1"
cx_strs = [] # station-radio, station-port, mode, upstream-port, protocol, pkt-size, speed_ul, speed_dl, QoS.
outfile = "tos+_results.xlsx"
dur = 5 * 60
passwd = ""
ssid = "Test-SSID"
security = "open"
radio_strs = [] # Radios to modify: radio nss channel
txpkts = "0" # 0 == Run forever
sniffer_radios = ""
wait_sniffer = False
# rssi_adjust = (current_nf - nf_at_calibration)
def usage():
print("$0 ")
print("--outfile: Write results here.")
print("--cx: Connection tuple: station-radio station-port mode upstream-port protocol pkt-size speed_ul speed_dl QoS")
print("--radio: Radio tuple: radio nss channel");
print("--lfmgr: LANforge manager IP address")
print("--duration: Duration to run traffic, in minutes")
print("--ssid: AP's SSID")
print("--passwd: Optional: password (do not add this option for OPEN)")
print("--security: Default is 'open', or if passwd is configured, default is wpa2. wpa3 is also valid option")
print("--txpkts: Optional: amount of packets to transmit (and then stop the data connections)")
print("--sniffer_radios: Optional: list of radios to sniff wifi traffic \"1.wiphy2 1.wiphy4\")")
print("--wait_sniffer: Optional: 1 means wait on sniffer to finish before existing script")
print("-h|--help")
def main():
global lfmgr
global cx_strs
global outfile
global dur
global passwd
global ssid
global security
global radio_strs
global txpkts
global sniffer_radios
global wait_sniffer
do_sniff = False
parser = argparse.ArgumentParser(description="ToS++ report Script")
parser.add_argument("--cx", type=str, action='append', help="Connection tuple: station-radio station-port mode upstream-port protocol pkt-size speed_ul speed_dl QoS")
parser.add_argument("--radio", type=str, action='append', help="Radio tuple: radio nss channel")
parser.add_argument("--lfmgr", type=str, help="LANforge Manager IP address")
parser.add_argument("--outfile", type=str, help="Output file for csv data")
parser.add_argument("--duration", type=float, help="Duration to run traffic, in minutes. If txpkts is specified, that may stop the test earlier.")
parser.add_argument("--ssid", type=str, help="AP's SSID")
parser.add_argument("--passwd", type=str, help="AP's password if using PSK authentication, skip this argement for OPEN")
parser.add_argument("--security", type=str, help="Default is 'open', or if passwd is configured, default is wpa2. wpa3 is also valid option")
parser.add_argument("--txpkts", type=str, help="Optional: Packets (PDUs) to send before stopping data connections Default (0) means infinite")
parser.add_argument("--sniffer_radios", type=str, help="Optional: list of radios to sniff wifi traffic \"1.wiphy2 1.wiphy4\"")
parser.add_argument("--wait_sniffer", type=str, help="Optional: 1 means wait on sniffer to finish before existing script.\"")
args = None
try:
args = parser.parse_args()
cx_strs = args.cx.copy()
if (args.radio != None):
radio_strs = args.radio.copy()
if (args.lfmgr != None):
lfmgr = args.lfmgr
if (args.duration != None):
dur = args.duration * 60
if (args.ssid != None):
ssid = args.ssid
if (args.passwd != None):
passwd = args.passwd
security = "wpa2"
if (args.security != None):
security = args.security
if (args.outfile != None):
outfile = args.outfile
if (args.txpkts != None):
txpkts = args.txpkts
if (args.sniffer_radios != None):
sniffer_radios = args.sniffer_radios
do_sniff = True
if (args.wait_sniffer != None):
do_sniff = True
wait_sniffer = args.wait_sniffer == "1"
filehandler = None
except Exception as e:
logging.exception(e);
usage()
exit(2);
# XLSX file
workbook = xlsxwriter.Workbook(outfile)
worksheet = workbook.add_worksheet()
bold = workbook.add_format({'bold': True, 'align': 'center'})
dblue_bold = workbook.add_format({'bold': True, 'align': 'center'})
dblue_bold.set_bg_color("#b8cbe4")
dblue_bold.set_border(1)
dtan_bold = workbook.add_format({'bold': True, 'align': 'center'})
dtan_bold.set_bg_color("#dcd8c3")
dtan_bold.set_border(1)
dpeach_bold = workbook.add_format({'bold': True, 'align': 'center'})
dpeach_bold.set_bg_color("#ffd8bb")
dpeach_bold.set_border(1)
dpink_bold = workbook.add_format({'bold': True, 'align': 'center'})
dpink_bold.set_bg_color("#fcc8ca")
dpink_bold.set_border(1)
dyel_bold = workbook.add_format({'bold': True, 'align': 'center'})
dyel_bold.set_bg_color("#ffe699")
dyel_bold.set_border(1)
dgreen_bold = workbook.add_format({'bold': True, 'align': 'center'})
dgreen_bold.set_bg_color("#c6e0b4")
dgreen_bold.set_border(1)
dgreen_bold_left = workbook.add_format({'bold': True, 'align': 'left'})
dgreen_bold_left.set_bg_color("#c6e0b4")
dgreen_bold_left.set_border(1)
center = workbook.add_format({'align': 'center'})
center_blue = workbook.add_format({'align': 'center'})
center_blue.set_bg_color("#dbe5f1")
center_blue.set_border(1)
center_tan = workbook.add_format({'align': 'center'})
center_tan.set_bg_color("#edede1")
center_tan.set_border(1)
center_peach = workbook.add_format({'align': 'center'})
center_peach.set_bg_color("#fce4d6")
center_peach.set_border(1)
center_yel = workbook.add_format({'align': 'center'})
center_yel.set_bg_color("#fdf2cc")
center_yel.set_border(1)
center_yel_red = workbook.add_format({'align': 'center', 'color': 'red'})
center_yel_red.set_bg_color("#fdf2cc")
center_yel_red.set_border(1)
center_pink = workbook.add_format({'align': 'center'})
center_pink.set_bg_color("ffd2d3")
center_pink.set_border(1)
red = workbook.add_format({'color': 'red', 'align': 'center'})
red.set_bg_color("#e0efda")
red.set_border(1)
red_left = workbook.add_format({'color': 'red', 'align': 'left'})
red_left.set_bg_color("#e0efda")
red_left.set_border(1)
green = workbook.add_format({'color': 'green', 'align': 'center'})
green.set_bg_color("#e0efda")
green.set_border(1)
green_left = workbook.add_format({'color': 'green', 'align': 'left'})
green_left.set_bg_color("#e0efda")
green_left.set_border(1)
worksheet.set_row(0, 45) # Set height
bucket_hdrs = "0 1 2-3 4-7 8-15 16-31 32-63 64-127 128-255 256-511 512-1023 1024-2047 2048-4095 4096-8191 8192-16383 16384-32767 32768-65535".split()
col = 0
row = 0
dwidth = 13 # Set width to 13 for all columns by default
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'CX-Name', dblue_bold); col += 1
worksheet.set_column(col, col, 15)
worksheet.write(row, col, 'Endp-Name', dblue_bold); col += 1
worksheet.set_column(col, col, 12)
worksheet.write(row, col, 'Port', dblue_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Protocol', dblue_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'ToS', dblue_bold); col += 1
worksheet.set_column(col, col, 20)
worksheet.write(row, col, 'AP BSSID', dblue_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Band\nwidth', dblue_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Mode', dblue_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Last MCS\nRx', dblue_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Combined\nRSSI', dblue_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Endpoint\nTX Pkt\nSize', dtan_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Endpoint\nOffered\nLoad', dtan_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Endpoint\nRx\nThroughput', dtan_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Cx\nOffered\nLoad', dtan_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Cx\nRx\nThroughput', dtan_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Avg\nLatency', dyel_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Min\nLatency', dyel_bold); col += 1
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, 'Max\nLatency', dyel_bold); col += 1
for i in range(17):
btitle = "Latency\nRange\n%s"%(bucket_hdrs[i])
worksheet.set_column(col, col, dwidth)
worksheet.write(row, col, btitle, dpeach_bold); col += 1
worksheet.set_column(col, col, 50)
worksheet.write(row, col, 'Warnings and Errors', dgreen_bold_left); col += 1
row += 1
# Use subprocess.check_output("Cmd") to utilize existing LF scripts.
sta_to_mode = {} # map station name to mode
cxnames = [] # list of all cxnames
endpnames = []
endp_to_port = {}
endp_to_pktsz = {}
endp_to_proto = {}
endp_to_tos = {}
e_tot = ""
opposite_speed = 56000
count = 0
# Configure radios as requested
for rad in radio_strs:
ra = rad.split()
radio = ra[0]
nss = ra[1]
ch = ra[2]
rad_resource = "1"
rad_name = radio;
if radio[0].isdigit():
tmpa = radio.split(".", 1);
rad_resource = tmpa[0];
rad_name = tmpa[1];
print("Setting radio %s.%s NSS %s Channel %s"%(rad_resource, rad_name, nss, ch))
subprocess.run(["./lf_portmod.pl", "--manager", lfmgr, "--card", rad_resource, "--port_name", rad_name,
"--set_nss", nss, "--set_channel", ch]);
upstreams = []
stations = []
for cx in cx_strs:
cxa = cx.split()
#station-radio, station-port, mode, upstream-port, protocol, pkt-size, speed_ul, speed_dl, QoS.
radio = cxa[0]
sta = cxa[1]
mode = cxa[2]
upstream_port = cxa[3]
p = cxa[4]
pkt_sz = cxa[5]
cx_speed_ul = cxa[6]
cx_speed_dl = cxa[7]
t = cxa[8] # qos
u_name = upstream_port
u_resource = 1
if (upstream_port[0].isdigit()):
tmpa = upstream_port.split(".", 1)
u_resource = tmpa[0]
u_name = tmpa[1]
sta_resource = "1"
sta_name = sta;
if sta[0].isdigit():
tmpa = sta.split(".", 1);
sta_resource = tmpa[0];
sta_name = tmpa[1];
sta_key = "%s.%s"%(sta_resource, sta_name)
if sta_key in sta_to_mode:
old_mode = sta_to_mode[sta_key]
if old_mode != mode:
emsg = ("ERROR: Skipping connection: \"%s\", mode conflicts with previous mode: %s"%(cx, old_mode))
e_tot.append(cxa)
print(emsg)
continue
else:
sta_to_mode[sta_key] = mode
stations.append(sta_key)
ukey = "%s.%s"%(u_resource, u_name)
if not ukey in upstreams:
upstreams.append(ukey)
if radio != "NA":
rad_resource = "1"
rad_name = radio;
if radio[0].isdigit():
tmpa = radio.split(".", 1);
rad_resource = tmpa[0];
rad_name = tmpa[1];
# Create or update station with requested mode
subprocess.run(["./lf_associate_ap.pl", "--mgr", lfmgr, "--resource", rad_resource, "--action", "add",
"--radio", rad_name, "--ssid", ssid, "--passphrase", passwd, "--security", security,
"--first_sta", sta_name, "--first_ip", "DHCP", "--wifi_mode", mode, "--num_stations", "1"])
else:
# Assume it should be sniffed.
ukey = "%s.%s"%(sta_resource, sta_name)
if not ukey in upstreams:
upstreams.append(ukey)
# Up station / A-side Port
subprocess.run(["./lf_portmod.pl", "--manager", lfmgr, "--card", sta_resource, "--port_name", sta_name,
"--set_ifstate", "up"]);
i = 0
wait_ip_print = False;
wait_assoc_print = False;
# Wait until LANforge station connects
while True:
port_stats = subprocess.run(["./lf_portmod.pl", "--manager", lfmgr, "--card", sta_resource, "--port_name", sta_name,
"--show_port", "AP,IP,Mode,NSS,Bandwidth,Channel,Signal,Noise,Status,RX-Rate"], stdout=PIPE, stderr=PIPE);
pss = port_stats.stdout.decode('utf-8', 'ignore');
_status = None
_ip = None
for line in pss.splitlines():
m = re.search('Status:\s+(.*)', line)
if (m != None):
_status = m.group(1)
m = re.search('IP:\s+(.*)', line)
if (m != None):
_ip = m.group(1)
#print("IP %s Status %s"%(_ip, _status))
if sta_name.startswith("wlan") or sta_name.startswith("sta"):
if (_status == "Authorized"):
if ((_ip != None) and (_ip != "0.0.0.0")):
print("Station is associated with IP address.")
break
else:
if (not wait_ip_print):
print("Waiting for station %s.%s to get IP Address."%(sta_resource, sta_name))
wait_ip_print = True
else:
if (not wait_assoc_print):
print("Waiting up to 180s for station %s.%s to associate."%(sta_resource, sta_name))
wait_assoc_print = True
else:
if ((_ip != None) and (_ip != "0.0.0.0")):
print("Port is associated with IP address.")
break
else:
if (not wait_ip_print):
print("Waiting for port %s.%s to get IP Address."%(sta_resource, sta_name))
wait_ip_print = True
i = i + 1
# We wait a fairly long time since AP will take a long time to start on a CAC channel.
if (i > 180):
err = "ERROR: Station did not connect within 180 seconds."
print(err)
e_tot += err
e_tot += " "
if (args.wait_forever):
print("Will continue waiting, you may wish to debug the system...")
i = 0
else:
break
time.sleep(1)
# Station is up, create connection
# Create connections.
# First, delete any old ones
cxn = "scr-tos-%i"%count
ena = "scr-tos-%i-A"%count
enb = "scr-tos-%i-B"%count
cxnames.append(cxn)
endpnames.append(ena)
endpnames.append(enb)
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "do_cmd",
"--cmd", "rm_cx ALL %s"%cxn], stderr=PIPE, stdout=PIPE);
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "do_cmd",
"--cmd", "rm_endp %s"%ena], stderr=PIPE, stdout=PIPE);
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "do_cmd",
"--cmd", "rm_endp %s"%enb], stderr=PIPE, stdout=PIPE);
cx_proto = p;
if (cx_proto == "udp"):
cx_proto = "lf_udp"
if (cx_proto == "tcp"):
cx_proto = "lf_tcp"
endp_to_port[ena] = "%s.%s"%(sta_resource, sta_name);
endp_to_pktsz[ena] = pkt_sz
endp_to_proto[ena] = p;
endp_to_tos[ena] = t;
endp_to_port[enb] = "%s.%s"%(u_resource, u_name);
endp_to_pktsz[enb] = pkt_sz
endp_to_proto[enb] = p;
endp_to_tos[enb] = t;
# Now, create the new connection
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--resource", "%s"%sta_resource, "--action", "create_endp", "--port_name", sta_name,
"--endp_type", cx_proto, "--endp_name", ena, "--speed", "%s"%cx_speed_ul, "--report_timer", "1000", "--tos", t,
"--min_pkt_sz", pkt_sz, "--multicon", "1", "--pkts_to_send", txpkts])#, capture_output=True);
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--resource", "%s"%u_resource, "--action", "create_endp", "--port_name", u_name,
"--endp_type", cx_proto, "--endp_name", enb, "--speed", "%s"%cx_speed_dl, "--report_timer", "1000", "--tos", t,
"--min_pkt_sz", pkt_sz, "--multicon", "1", "--pkts_to_send", txpkts])# capture_output=True);
# Enable Multi-Helper
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "do_cmd", "--cmd",
"set_endp_flag %s AutoHelper 1"%(ena)])
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "do_cmd", "--cmd",
"set_endp_flag %s AutoHelper 1"%(enb)])
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "do_cmd", "--cmd",
"add_cx %s default_tm %s %s"%(cxn, ena, enb)])# capture_output=True);
count = count + 1
# Start sniffer?
if do_sniff:
lfstations = ""
lfupstreams = ""
if sniffer_radios != "":
radios = sniffer_radios.split()
ri = 0
for r in radios:
lfstations = lfstations + " " + stations[ri]
ri = ri + 1
for u in upstreams:
lfupstreams = lfupstreams + " " + u
# Add 15 seconds to capture length in case it takes a bit of time to start all
# of the connections.
cmd = ["./lf_sniff.py", "--lfmgr", lfmgr, "--duration", "%f"%((dur + 15) / 60)]
if lfstations != "":
cmd.extend(["--station", lfstations, "--sniffer_radios", sniffer_radios])
if lfupstreams != "":
cmd.extend(["--upstreams", lfupstreams])
subprocess.run(cmd)
sniff_done_at = time.time() + dur + 15;
# All traffic connects are created, now start them all
for cxn in cxnames:
# Start traffic
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "do_cmd",
"--cmd", "set_cx_state all %s RUNNING"%cxn]);
# Traffic is started, wait requested amount of time
stop_at = time.time() + dur;
if txpkts == 0:
print("Waiting %s seconds to let traffic run for a bit"%(dur))
time.sleep(dur)
else:
# Wait until connections are done transmitting and all are stopped
print("Waiting until all connections have finished transmitting %s PDUs and have stopped themselves."%txpkts);
done = False
while not done:
if time.time() > stop_at:
print("Duration expired, stop waiting for Endpoints to quiesce.")
break
foundone = False
for ename in endpnames:
#print("Checking endpoint: %s"%ename)
endp_stats = subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--endp_name", ename,
"--endp_vals", "Endpoint-flags"], stderr=PIPE, stdout=PIPE);
ess = endp_stats.stdout.decode('utf-8', 'ignore');
for line in ess.splitlines():
#print("endp-stats line: %s"%line)
m = re.search('Endpoint-flags:\s+(.*)', line)
if (m != None):
flags = m.group(1)
if not "NOT_RUNNING" in flags:
foundone = True
#print("Flags, was running: %s"%flags)
break
#else:
#print("Flags, was not running: %s"%flags)
if foundone:
break
if not foundone:
print("All endpoints stopped, continuing on.")
done = True
break
sleep(3) # wait 3 seconds, then poll again
# Gather probe results and record data, verify NSS, BW, Channel
sta_stats = {} # Key is resource.station, holds array of values
for sta in sta_to_mode:
sta_resource = "1"
sta_name = sta;
if sta[0].isdigit():
tmpa = sta.split(".", 1);
sta_resource = tmpa[0];
sta_name = tmpa[1];
sta_key = "%s.%s"%(sta_resource, sta_name)
print("Checking station stats, key: %s"%(sta_key))
port_stats = subprocess.run(["./lf_portmod.pl", "--manager", lfmgr, "--card", sta_resource, "--port_name", sta_name,
"--show_port", "AP,Mode,Bandwidth,Signal,Status,RX-Rate"], stderr=PIPE, stdout=PIPE);
pss = port_stats.stdout.decode('utf-8', 'ignore');
_ap = None
_bw = None
_mode = None
_rxrate = None
_signal = None
for line in pss.splitlines():
m = re.search('AP:\s+(.*)', line)
if (m != None):
_ap = m.group(1)
m = re.search('Bandwidth:\s+(.*)Mhz', line)
if (m != None):
_bw = m.group(1)
m = re.search('Mode:\s+(.*)', line)
if (m != None):
_mode = m.group(1)
m = re.search('RX-Rate:\s+(.*)', line)
if (m != None):
_rxrate = m.group(1)
m = re.search('Signal:\s+(.*)', line)
if (m != None):
_signal = m.group(1)
sta_stats[sta_key] = [_ap, _bw, _mode, _rxrate, _signal];
print("sta-stats found: %s, mode: %s bw: %s"%(sta_key, _mode, _bw));
for cxn in cxnames:
# Results: tx_bytes, rx_bytes, tx_bps, rx_bps, tx_pkts, rx_pkts, Latency
resultsA = ["0"] * 7
resultsB = ["0"] * 7
e_tot2 = ""
ena = "%s-A"%cxn;
enb = "%s-B"%cxn;
enames = [ena, enb]
for ename in enames:
results = [""] * 7
endp_stats = subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--endp_vals", "RealTxRate,RealRxRate,Tx Bytes,Rx Bytes,Tx Pkts,Rx Pkts,Latency",
"--endp_name", ename], stderr=PIPE, stdout=PIPE);
pss = endp_stats.stdout.decode('utf-8', 'ignore');
for line in pss.splitlines():
#print("probe-line, endp: %s: %s"%(ename, line))
m = re.search('Rx Bytes:\s+(\d+)', line)
if (m != None):
results[1] = int(m.group(1))
if (results[1] == 0):
err = "ERROR: No bytes received by data connection %s, test results may not be valid."%(ename)
e_tot2 += err
e_tot2 += " "
m = re.search('Tx Bytes:\s+(\d+)', line)
if (m != None):
results[0] = int(m.group(1))
if (results[0] == 0):
err = "ERROR: No bytes transmitted by data connection %s, test results may not be valid."%(ename)
e_tot2 += err
e_tot2 += " "
m = re.search('RealTxRate:\s+(.*)bps', line)
if (m != None):
results[2] = m.group(1)
m = re.search('RealRxRate:\s+(.*)bps', line)
if (m != None):
results[3] = m.group(1)
m = re.search('Tx Pkts:\s+(.*)', line)
if (m != None):
results[4] = m.group(1)
m = re.search('Rx Pkts:\s+(.*)', line)
if (m != None):
results[5] = m.group(1)
m = re.search('Latency:\s+(.*)', line)
if (m != None):
results[6] = m.group(1)
if (ena == ename):
resultsA = results.copy()
else:
resultsB = results.copy()
# Now that we know both latencies, we can normalize them.
endp_statsA = subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "normalize_latency",
"--lat1", resultsA[6], "--lat2", resultsB[6]], stderr=PIPE, stdout=PIPE);
pssA = endp_statsA.stdout.decode('utf-8', 'ignore');
endp_statsB = subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "normalize_latency",
"--lat1", resultsB[6], "--lat2", resultsA[6]], stderr=PIPE, stdout=PIPE);
pssB = endp_statsB.stdout.decode('utf-8', 'ignore');
#print("%s: latA: %s"%(cxn, resultsA[6]))
#print("%s: latB: %s"%(cxn, resultsB[6]))
#print("%s: pssA: %s"%(cxn, pssA))
#print("%s: pssB: %s"%(cxn, pssB))
for line in pssA.splitlines():
m = re.search('Normalized-Latency:\s+(.*)', line)
if (m != None):
resultsA[6] = m.group(1);
for line in pssB.splitlines():
m = re.search('Normalized-Latency:\s+(.*)', line)
if (m != None):
resultsB[6] = m.group(1);
for ename in enames:
col = 0
if (ena == ename):
results = resultsA.copy()
else:
results = resultsB.copy()
lat_cols = results[6].split() # min, max, avg, columns....
worksheet.write(row, col, cxn, center_blue); col += 1
worksheet.write(row, col, ename, center_blue); col += 1
en_port = endp_to_port[ename]
worksheet.write(row, col, en_port, center_blue); col += 1
worksheet.write(row, col, endp_to_proto[ename], center_blue); col += 1
worksheet.write(row, col, endp_to_tos[ename], center_blue); col += 1
if ename == ena:
key = en_port
#print("endp, key: %s"%(key));
sta_rpt = sta_stats[key]
worksheet.write(row, col, sta_rpt[0], center_blue); col += 1
worksheet.write(row, col, sta_rpt[1], center_blue); col += 1
worksheet.write(row, col, sta_rpt[2], center_blue); col += 1
worksheet.write(row, col, sta_rpt[3], center_blue); col += 1
worksheet.write(row, col, sta_rpt[4], center_blue); col += 1
else:
# Upstream is likely wired, don't print station info
worksheet.write(row, col, "", center_blue); col += 1
worksheet.write(row, col, "", center_blue); col += 1
worksheet.write(row, col, "", center_blue); col += 1
worksheet.write(row, col, "", center_blue); col += 1
worksheet.write(row, col, "", center_blue); col += 1
#print("results[2]:%s 3: %s"%(results[2], results[3]))
worksheet.write(row, col, endp_to_pktsz[ename], center_tan); col += 1
worksheet.write(row, col, "%.2f"%(float(results[2]) / 1000000), center_tan); col += 1
worksheet.write(row, col, "%.2f"%(float(results[3]) / 1000000), center_tan); col += 1
worksheet.write(row, col, "%.2f"%((float(resultsA[2]) + float(resultsB[2])) / 1000000), center_tan); col += 1
worksheet.write(row, col, "%.2f"%((float(resultsA[3]) + float(resultsB[3])) / 1000000), center_tan); col += 1
worksheet.write(row, col, lat_cols[2], center_yel); col += 1
worksheet.write(row, col, lat_cols[0], center_yel); col += 1
worksheet.write(row, col, lat_cols[1], center_yel); col += 1
for x in range(17):
worksheet.write(row, col, lat_cols[x + 3], center_peach); col += 1
if (e_tot2 == ""):
worksheet.write(row, col, e_tot2, green_left); col += 1
else:
worksheet.write(row, col, e_tot2, red_left); col += 1
row += 1
# Stop traffic
for cxn in cxnames:
cmd = "set_cx_state all %s STOPPED"%cxn
#print("Stopping CX: %s with command: %s"%(cxn, cmd));
subprocess.run(["./lf_firemod.pl", "--manager", lfmgr, "--action", "do_cmd",
"--cmd", cmd]);
workbook.close()
# Convert workbook to csv
csvfname = "%s.csv"%(outfile)
csv = open(csvfname, "w")
df = pd.read_excel(outfile)
list_of_columns = df.columns.values
# Print header
for c in range(len(list_of_columns)):
cell = list_of_columns[c]
if cell != cell:
cell = ""
# convert newlines to spaces
if isinstance(cell, str):
cell = cell.replace('\n', ' ')
cell = cell.replace('\r', '')
# Remove commas
cell = cell.replace(',', '')
if c == 0:
csv.write(cell)
else:
csv.write(",%s"%(cell))
csv.write("\n")
for r in range (len(df)):
for c in range(len(list_of_columns)):
#print("list-of-columns[c]: %s"%(list_of_columns[c]))
cell = df[list_of_columns[c]][r]
#print("cell: %s c: %i r: %i"%(cell, c, r))
# NAN check
if cell != cell:
cell = ""
if isinstance(cell, str):
# convert newlines to spaces
cell = cell.replace('\n', ' ')
cell = cell.replace('\r', '')
# Remove commas
cell = cell.replace(',', '')
if c == 0:
csv.write(cell)
else:
csv.write(",%s"%(cell))
csv.write("\n");
csv.close()
print("CSV report data saved to: %s"%(csvfname))
tstr = ""
if sniffer_radios != "":
now = time.time()
if now < sniff_done_at:
waitfor = int(sniff_done_at - now);
if wait_sniffer:
print("Waiting %i seconds until sniffer completes."%(waitfor))
sleep(waitfor)
# move capture files into a new directory
tstr = time.strftime("%Y-%m-%d-%H:%M:%S")
os.mkdir(tstr)
os.system("mv /home/lanforge/*.pcap %s"%(tstr))
print("Captures are found in directory: %s"%tstr)
else:
print("Sniffer will complete in %f seconds."%(waitfor))
# Create a file easily sourced by a shell script to communicate the directory
# name and such.
fname = "TOS_PLUS.sh"
sh = open(fname, "w")
sh.write("CAPTURE_DIR=%s\n"%(tstr))
sh.write("CSV_FILE=%s\n"%(csvfname))
sh.write("XLSX_FILE=%s\n"%(outfile))
sh.close()
# ----- ----- ----- ----- ----- ----- ----- ----- ----- ----- ----- -----
if __name__ == '__main__':
main()
print("Xlsx results stored in %s"%(outfile))
####
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