#!/usr/bin/env python3 ''' NAME: test_l3_longevity.py PURPOSE: Supports creating user-specified amount stations on multiple radios Supports configuring upload and download requested rates and PDU sizes. Supports generating KPI data for storing in influxdb (used by Graphana) Supports generating connections with different ToS values. Supports generating tcp and/or UDP traffic types. Supports iterating over different PDU sizes Supports iterating over different requested tx rates (configurable as total or per-connection value) Supports iterating over attenuation values. Supports testing connection between two ethernet connection - L3 dataplane EXAMPLE: 10 stations on wiphy0, 1 station on wiphy2. open-auth to ASUS_70 SSID Configured to submit KPI info to influxdb-version2. ./test_l3_longevity.py --mgr localhost --endp_type 'lf_udp lf_tcp' --upstream_port 1.1.eth1 \ --radio "radio==1.1.wiphy0 stations==10 ssid==ASUS_70 ssid_pw==[BLANK] security==open" \ --radio "radio==1.1.wiphy2 stations==1 ssid==ASUS_70 ssid_pw==[BLANK] security==open" \ --test_duration 5s --influx_host c7-graphana --influx_port 8086 --influx_org Candela \ --influx_token=-u_Wd-L8o992701QF0c5UmqEp7w7Z7YOMaWLxOMgmHfATJGnQbbmYyNxHBR9PgD6taM_tcxqJl6U8DjU1xINFQ== \ --influx_bucket ben --rates_are_totals --side_a_min_bps=20000 --side_b_min_bps=300000000 \ --influx_tag testbed ath11k --influx_tag DUT ROG -o longevity.csv Example command using attenuator ./test_l3_longevity.py --test_duration 5m --polling_interval 1s --upstream_port eth2 \ --radio 'radio==wiphy1,stations==1,ssid==TCH-XB7,ssid_pw==comcast123,security==wpa2' \ --radio 'radio==wiphy2,stations==1,ssid==TCH-XB7,ssid_pw==comcast123,security==wpa2' \ --radio 'radio==wiphy3,stations==1,ssid==TCH-XB7,ssid_pw==comcast123,security==wpa2' \ --radio 'radio==wiphy4,stations==1,ssid==TCH-XB7,ssid_pw==comcast123,security==wpa2' \ --endp_type lf_udp --ap_read --ap_scheduler_stats --ap_ofdma_stats --side_a_min_bps=20000 --side_b_min_bps=400000000 \ --attenuators 1.1..1 \ --atten_vals 20,21,40,41 Example using upsteam eth1 downstream eth2 ./test_l3_longevity.py --test_duration 20s --polling_interval 1s --upstream_port eth1 --downstream_port eth2 --endp_type lf --rates_are_totals --side_a_min_bps=10000000,0 --side_a_min_pdu=1000 --side_b_min_bps=0,300000000 --side_b_min_pdu=1000 COPYRIGHT: Copyright 2021 Candela Technologies Inc INCLUDE_IN_README ''' import sys import os if sys.version_info[0] != 3: print("This script requires Python 3") exit(1) if 'py-json' not in sys.path: sys.path.append(os.path.join(os.path.abspath('..'), 'py-json')) if 'py-dashboard' not in sys.path: sys.path.append(os.path.join(os.path.abspath('..'), 'py-dashboard')) from pprint import pprint from InfluxRequest import * import serial import pexpect from pexpect_serial import SerialSpawn from lf_report import lf_report import argparse from LANforge import LFUtils from realm import Realm import time import datetime import csv # This class handles running the test and generating reports. class L3VariableTime(Realm): def __init__(self, endp_types, args, tos, side_b, side_a, radio_name_list, number_of_stations_per_radio_list, ssid_list, ssid_password_list, ssid_security_list, station_lists, name_prefix, outfile, reset_port_enable_list, reset_port_time_min_list, reset_port_time_max_list, side_a_min_rate=[56000], side_a_max_rate=[0], side_b_min_rate=[56000], side_b_max_rate=[0], side_a_min_pdu=["MTU"], side_a_max_pdu=[0], side_b_min_pdu=["MTU"], side_b_max_pdu=[0], user_tags=[], rates_are_totals=False, mconn=1, attenuators=[], atten_vals=[], number_template="00", test_duration="256s", polling_interval="60s", lfclient_host="localhost", lfclient_port=8080, debug=False, influxdb=None, ap_scheduler_stats=False, ap_ofdma_stats=False, ap_read=False, ap_port='/dev/ttyUSB0', ap_baud='115200', ap_cmd_5g='wl -i wl1 bs_data', ap_cmd_2g='wl -i wl0 bs_data', ap_chanim_cmd_5g='wl -i wl1 chanim_stats', ap_chanim_cmd_2g='wl -i wl0 chanim_stats', ap_test_mode=False, _exit_on_error=False, _exit_on_fail=False, _proxy_str=None, _capture_signal_list=[]): super().__init__(lfclient_host=lfclient_host, lfclient_port=lfclient_port, debug_=debug, _exit_on_error=_exit_on_error, _exit_on_fail=_exit_on_fail, _proxy_str=_proxy_str, _capture_signal_list=_capture_signal_list) self.influxdb = influxdb self.tos = tos.split(",") self.endp_types = endp_types.split(",") self.side_b = side_b self.side_a = side_a # if it is a dataplane test the side_a is not none and an ethernet port if self.side_a != None: self.dataplane = True else: self.dataplane = False self.ssid_list = ssid_list self.ssid_password_list = ssid_password_list self.station_lists = station_lists self.ssid_security_list = ssid_security_list self.reset_port_enable_list = reset_port_enable_list self.reset_port_time_min_list = reset_port_time_min_list self.reset_port_time_max_list = reset_port_time_max_list self.number_template = number_template self.name_prefix = name_prefix self.test_duration = test_duration self.radio_name_list = radio_name_list self.number_of_stations_per_radio_list = number_of_stations_per_radio_list #self.local_realm = realm.Realm(lfclient_host=self.host, lfclient_port=self.port, debug_=debug_on) self.polling_interval_seconds = self.duration_time_to_seconds(polling_interval) self.cx_profile = self.new_l3_cx_profile() self.multicast_profile = self.new_multicast_profile() self.multicast_profile.name_prefix = "MLT-"; self.station_profiles = [] self.args = args self.outfile = outfile self.csv_started = False self.epoch_time = int(time.time()) self.debug = debug self.mconn = mconn self.user_tags = user_tags self.side_a_min_rate = side_a_min_rate self.side_a_max_rate = side_a_max_rate self.side_b_min_rate = side_b_min_rate self.side_b_max_rate = side_b_max_rate self.side_a_min_pdu = side_a_min_pdu self.side_a_max_pdu = side_a_max_pdu self.side_b_min_pdu = side_b_min_pdu self.side_b_max_pdu = side_b_max_pdu self.rates_are_totals = rates_are_totals self.cx_count = 0 self.station_count = 0 self.attenuators = attenuators self.atten_vals = atten_vals if ((len(self.atten_vals) > 0) and (self.atten_vals[0] != -1) and (len(self.attenuators) == 0)): print("ERROR: Attenuation values configured, but no Attenuator EIDs specified.\n") exit(1) self.cx_profile.mconn = mconn self.cx_profile.side_a_min_bps = side_a_min_rate[0] self.cx_profile.side_a_max_bps = side_a_max_rate[0] self.cx_profile.side_b_min_bps = side_b_min_rate[0] self.cx_profile.side_b_max_bps = side_b_max_rate[0] self.ap_scheduler_stats = ap_scheduler_stats self.ap_ofdma_stats = ap_ofdma_stats self.ap_read = ap_read self.ap_port = ap_port self.ap_baud = ap_baud self.ap_cmd_5g = ap_cmd_5g self.ap_cmd_2g = ap_cmd_2g self.ap_chanim_cmd_5g = ap_chanim_cmd_5g self.ap_chanim_cmd_2g = ap_chanim_cmd_2g self.ap_test_mode = ap_test_mode self.ap_5g_umsched = "" self.ap_5g_msched = "" self.ap_24g_umsched = "" self.ap_24g_msched = "" self.ap_ofdma_5g = "" self.ap_ofdma_24g = "" # Lookup key is port-eid name self.port_csv_files = {} self.port_csv_writers = {} # TODO: cmd-line arg to enable/disable these stats. self.ap_stats_col_titles = ["Station Address", "PHY Mbps", "Data Mbps", "Air Use", "Data Use", "Retries", "bw", "mcs", "Nss", "ofdma", "mu-mimo", "channel utilization"] dur = self.duration_time_to_seconds(self.test_duration) if (self.polling_interval_seconds > dur + 1): self.polling_interval_seconds = dur - 1 # Full spread-sheet data if self.outfile is not None: kpi = self.outfile[:-4] kpi = kpi + "-kpi.csv" self.csv_kpi_file = open(kpi, "w") self.csv_kpi_writer = csv.writer(self.csv_kpi_file, delimiter=",") # if side_a is None then side_a is radios if self.dataplane == False: for (radio_, ssid_, ssid_password_, ssid_security_,\ reset_port_enable_, reset_port_time_min_, reset_port_time_max_) \ in zip(radio_name_list, ssid_list, ssid_password_list, ssid_security_list,\ reset_port_enable_list, reset_port_time_min_list, reset_port_time_max_list): self.station_profile = self.new_station_profile() self.station_profile.lfclient_url = self.lfclient_url self.station_profile.ssid = ssid_ self.station_profile.ssid_pass = ssid_password_ self.station_profile.security = ssid_security_ self.station_profile.number_template = self.number_template self.station_profile.mode = 0 self.station_profile.set_reset_extra(reset_port_enable=reset_port_enable_,\ test_duration=self.duration_time_to_seconds(self.test_duration),\ reset_port_min_time=self.duration_time_to_seconds(reset_port_time_min_),\ reset_port_max_time=self.duration_time_to_seconds(reset_port_time_max_)) self.station_profiles.append(self.station_profile) else: pass self.multicast_profile.host = self.lfclient_host self.cx_profile.host = self.lfclient_host self.cx_profile.port = self.lfclient_port self.cx_profile.name_prefix = self.name_prefix def get_ap_5g_umsched(self): return self.ap_5g_umsched def get_ap_5g_msched(self): return self.ap_5g_msched def get_ap_24g_umsched(self): return self.ap_5g_umsched def get_ap_24g_msched(self): return self.ap_5g_msched def get_ap_ofdma_5g(self): return self.ap_ofdma_5g def get_ap_ofdma_24g(self): return self.ap_ofdma_24g def get_kpi_csv(self): #print("self.csv_kpi_file {}".format(self.csv_kpi_file.name)) return self.csv_kpi_file.name # Find avg latency, jitter for connections using specified port. def get_endp_stats_for_port(self, eid_name, endps): lat = 0 jit = 0 total_dl_rate = 0 total_dl_rate_ll = 0 total_dl_pkts_ll = 0 total_ul_rate = 0 total_ul_rate_ll = 0 total_ul_pkts_ll = 0 count = 0 sta_name = 'no_station' #print("endp-stats-for-port, port-eid: {}".format(eid_name)) eid = self.name_to_eid(eid_name) print("eid_name: {eid_name} eid: {eid}".format(eid_name=eid_name,eid=eid)) # Convert all eid elements to strings eid[0] = str(eid[0]) eid[1] = str(eid[1]) eid[2] = str(eid[2]) for endp in endps: pprint(endp) eid_endp = endp["eid"].split(".") print("Comparing eid:{eid} to endp-id {eid_endp}".format(eid=eid,eid_endp=eid_endp)) # Look through all the endpoints (endps), to find the port the eid_name is using. # The eid_name that has the same Shelf, Resource, and Port as the eid_endp (looking at all the endps) # Then read the eid_endp to get the delay, jitter and rx rate # Note: the endp eid is shelf.resource.port.endp-id, the eid can be treated somewhat as # child class of port-eid , and look up the port the eid is using. if eid[0] == eid_endp[0] and eid[1] == eid_endp[1] and eid[2] == eid_endp[2]: lat += int(endp["delay"]) jit += int(endp["jitter"]) name = endp["name"] print("endp name {name}".format(name=name)) sta_name = name.replace('-A','') #only the -A endpoint will be found so need to look count += 1 print("Matched: name: {name} eid:{eid} to endp-id {eid_endp}".format(name=name,eid=eid,eid_endp=eid_endp)) else: name = endp["name"] print("No Match: name: {name} eid:{eid} to endp-id {eid_endp}".format(name=name,eid=eid,eid_endp=eid_endp)) if count > 1: lat = int(lat / count) jit = int(jit / count) # need to loop though again to find the upload and download per station if the name matched for endp in endps: if sta_name in endp["name"]: name = endp["name"] if name.endswith("-A"): print("name has -A") total_dl_rate += int(endp["rx rate"]) total_dl_rate_ll += int(endp["rx rate ll"]) total_dl_pkts_ll += int(endp["rx pkts ll"]) # -B upload side else: total_ul_rate += int(endp["rx rate"]) total_ul_rate_ll += int(endp["rx rate ll"]) total_ul_pkts_ll += int(endp["rx pkts ll"]) return lat, jit, total_dl_rate, total_dl_rate_ll, total_dl_pkts_ll, total_ul_rate, total_ul_rate_ll, total_ul_pkts_ll # Query all endpoints to generate rx and other stats, returned # as an array of objects. def __get_rx_values(self): endp_list = self.json_get("endp?fields=name,eid,delay,jitter,rx+rate,rx+rate+ll,rx+bytes,rx+drop+%25,rx+pkts+ll", debug_=False) endp_rx_drop_map = {} endp_rx_map = {} our_endps = {} endps = [] total_ul = 0 total_ul_ll = 0 total_dl = 0 total_dl_ll = 0 for e in self.multicast_profile.get_mc_names(): our_endps[e] = e; for e in self.cx_profile.created_endp.keys(): our_endps[e] = e; for endp_name in endp_list['endpoint']: if endp_name != 'uri' and endp_name != 'handler': for item, value in endp_name.items(): if item in our_endps: endps.append(value) print("endpoint: ", item, " value:\n") pprint(value) for value_name, value in value.items(): if value_name == 'rx bytes': endp_rx_map[item] = value if value_name == 'rx rate': endp_rx_map[item] = value if value_name == 'rx rate ll': endp_rx_map[item] = value if value_name == 'rx pkts ll': endp_rx_map[item] = value if value_name == 'rx drop %': endp_rx_drop_map[item] = value if value_name == 'rx rate': # This hack breaks for mcast or if someone names endpoints weirdly. #print("item: ", item, " rx-bps: ", value_rx_bps) if item.endswith("-A"): total_dl += int(value) else: total_ul += int(value) if value_name == 'rx rate ll': # This hack breaks for mcast or if someone names endpoints weirdly. if item.endswith("-A"): total_dl_ll += int(value) else: total_ul_ll += int(value) #print("total-dl: ", total_dl, " total-ul: ", total_ul, "\n") return endp_rx_map, endp_rx_drop_map, endps, total_dl, total_ul, total_dl_ll, total_ul_ll # Common code to generate timestamp for CSV files. def time_stamp(self): return time.strftime('%m_%d_%Y_%H_%M_%S', time.localtime(self.epoch_time)) # Cleanup any older config that a previous run of this test may have created. def pre_cleanup(self): self.cx_profile.cleanup_prefix() self.multicast_profile.cleanup_prefix() self.total_stas = 0 for station_list in self.station_lists: for sta in station_list: self.rm_port(sta, check_exists=True) self.total_stas += 1 # Make sure they are gone count = 0 while (count < 10): more = False for station_list in self.station_lists: for sta in station_list: rv = self.rm_port(sta, check_exists=True) if (rv): more = True if not more: break count += 1 time.sleep(5) def gather_port_eids(self): rv = [self.side_b] for station_profile in self.station_profiles: rv = rv + station_profile.station_names return rv; # Create stations and connections/endpoints. If rebuild is true, then # only update connections/endpoints. def build(self, rebuild=False): index = 0 self.station_count = 0 self.udp_endps = [] self.tcp_endps = [] self.eth_endps = [] if rebuild: # if we are just re-applying new cx values, then no need to rebuild # stations, so allow skipping it. # Do clean cx lists so that when we re-apply them we get same endp name # as we had previously #print("rebuild: Clearing cx profile lists.\n") self.cx_profile.clean_cx_lists() self.multicast_profile.clean_mc_lists() if self.dataplane: for etype in self.endp_types: for _tos in self.tos: print("Creating connections for endpoint type: %s TOS: %s cx-count: %s"%(etype, _tos, self.cx_profile.get_cx_count())) # use brackes on [self.side_a] to make it a list these_cx, these_endp = self.cx_profile.create(endp_type=etype, side_a=[self.side_a], side_b=self.side_b, sleep_time=0, tos=_tos) if (etype == "lf_udp" or etype == "lf_udp6"): self.udp_endps = self.udp_endps + these_endp elif(etype=="lf"): self.lf_endps = self.eth_endps + these_endp else: self.tcp_endps = self.tcp_endps + these_endp else: for station_profile in self.station_profiles: if not rebuild: station_profile.use_security(station_profile.security, station_profile.ssid, station_profile.ssid_pass) station_profile.set_number_template(station_profile.number_template) print("Creating stations on radio %s"%(self.radio_name_list[index])) station_profile.create(radio=self.radio_name_list[index], sta_names_=self.station_lists[index], debug=self.debug, sleep_time=0) index += 1 self.station_count += len(station_profile.station_names) # Build/update connection types for etype in self.endp_types: if etype == "mc_udp" or etype == "mc_udp6": print("Creating Multicast connections for endpoint type: %s"%(etype)) self.multicast_profile.create_mc_tx(etype, self.side_b, etype) self.multicast_profile.create_mc_rx(etype, side_rx=station_profile.station_names) else: for _tos in self.tos: print("Creating connections for endpoint type: %s TOS: %s cx-count: %s"%(etype, _tos, self.cx_profile.get_cx_count())) these_cx, these_endp = self.cx_profile.create(endp_type=etype, side_a=station_profile.station_names, side_b=self.side_b, sleep_time=0, tos=_tos) if (etype == "lf_udp" or etype == "lf_udp6"): self.udp_endps = self.udp_endps + these_endp; else: self.tcp_endps = self.tcp_endps + these_endp; self.cx_count = self.cx_profile.get_cx_count() if self.dataplane == True: self._pass("PASS: CX build finished: created/updated: %s connections."%(self.cx_count)) else: self._pass("PASS: Stations & CX build finished: created/updated: %s stations and %s connections."%(self.station_count, self.cx_count)) def ap_custom_cmd(self,ap_custom_cmd): ap_results = "" try: # configure the serial interface ser = serial.Serial(self.ap_port, int(self.ap_baud), timeout=5) ss = SerialSpawn(ser) ss.sendline(str(ap_custom_cmd)) ss.expect([pexpect.TIMEOUT], timeout=1) # do not detete line, waits for output ap_results = ss.before.decode('utf-8','ignore') print("ap_custom_cmd: {} ap_results {}".format(ap_custom_cmd, ap_results)) except: print("ap_custom_cmd: {} WARNING unable to read AP ".format(ap_custom_cmd)) return ap_results def read_ap_stats_5g(self): # 5ghz: wl -i wl1 bs_data ap_stats_5g = "" try: # configure the serial interface ser = serial.Serial(self.ap_port, int(self.ap_baud), timeout=5) ss = SerialSpawn(ser) ss.sendline(str(self.ap_cmd_5g)) ss.expect([pexpect.TIMEOUT], timeout=1) # do not detete line, waits for output ap_stats_5g = ss.before.decode('utf-8','ignore') print("ap_stats_5g from AP: {}".format(ap_stats_5g)) except: print("WARNING unable to read AP") return ap_stats_5g def read_ap_stats_2g(self): # 2.4ghz# wl -i wl0 bs_data ap_stats_2g = "" try: # configure the serial interface ser = serial.Serial(self.ap_port, int(self.ap_baud), timeout=5) ss = SerialSpawn(ser) ss.sendline(str(self.ap_cmd_2g)) ss.expect([pexpect.TIMEOUT], timeout=1) # do not detete line, waits for output ap_stats_2g = ss.before.decode('utf-8','ignore') print("ap_stats_2g from AP: {}".format(ap_stats_2g)) except: print("WARNING unable to read AP") return ap_stats_2g def read_ap_chanim_stats_5g(self): # 5ghz: wl -i wl1 chanim_stats ap_chanim_stats_5g = "" try: # configure the serial interface ser = serial.Serial(self.ap_port, int(self.ap_baud), timeout=5) ss = SerialSpawn(ser) ss.sendline(str(self.ap_chanim_cmd_5g)) ss.expect([pexpect.TIMEOUT], timeout=1) # do not detete line, waits for output ap_chanim_stats_5g = ss.before.decode('utf-8','ignore') print("ap_stats {}".format(ap_chanim_stats_5g)) except: print("WARNING unable to read AP") return ap_chanim_stats_5g def read_ap_chanim_stats_2g(self): # 2.4ghz# wl -i wl0 chanim_stats ap_chanim_stats_2g = "" try: # configure the serial interface ser = serial.Serial(self.ap_port, int(self.ap_baud), timeout=5) ss = SerialSpawn(ser) ss.sendline(str(self.ap_chanim_cmd_2g)) ss.expect([pexpect.TIMEOUT], timeout=1) # do not detete line, waits for output ap_chanim_stats_2g = ss.before.decode('utf-8','ignore') print("ap_stats {}".format(ap_chanim_stats_2g)) except: print("WARNING unable to read AP") return ap_chanim_stats_2g # Run the main body of the test logic. def start(self, print_pass=False, print_fail=False): print("Bringing up stations") self.admin_up(self.side_b) for station_profile in self.station_profiles: for sta in station_profile.station_names: print("Bringing up station %s"%(sta)) self.admin_up(sta) temp_stations_list = [] temp_stations_list.append(self.side_b) for station_profile in self.station_profiles: temp_stations_list.extend(station_profile.station_names.copy()) if self.wait_for_ip(temp_stations_list, timeout_sec=120): print("ip's acquired") else: # TODO: Allow fail and abort at this point. print("print failed to get IP's") csv_header = self.csv_generate_column_headers() #print(csv_header) self.csv_add_column_headers(csv_header) port_eids = self.gather_port_eids() for eid_name in port_eids: self.csv_add_port_column_headers(eid_name, self.csv_generate_port_column_headers()) # For each rate rate_idx = 0 for ul in self.side_a_min_rate: dl = self.side_b_min_rate[rate_idx] rate_idx += 1 # For each pdu size pdu_idx = 0 for ul_pdu in self.side_a_min_pdu: dl_pdu = self.side_b_min_pdu[pdu_idx] pdu_idx += 1 # Adjust rate to take into account the number of connections we have. if self.cx_count > 1 and self.rates_are_totals: # Convert from string to int to do math, then back to string # as that is what the cx_profile wants. ul = str(int(int(ul) / self.cx_count)) dl = str(int(int(dl) / self.cx_count)) dl_pdu_str = dl_pdu ul_pdu_str = ul_pdu if (ul_pdu == "AUTO" or ul_pdu == "MTU"): ul_pdu = "-1" if (dl_pdu == "AUTO" or dl_pdu == "MTU"): dl_pdu = "-1" print("ul: %s dl: %s cx-count: %s rates-are-totals: %s\n"%(ul, dl, self.cx_count, self.rates_are_totals)) # Set rate and pdu size config self.cx_profile.side_a_min_bps = ul self.cx_profile.side_a_max_bps = ul self.cx_profile.side_b_min_bps = dl self.cx_profile.side_b_max_bps = dl self.cx_profile.side_a_min_pdu = ul_pdu self.cx_profile.side_a_max_pdu = ul_pdu self.cx_profile.side_b_min_pdu = dl_pdu self.cx_profile.side_b_max_pdu = dl_pdu # Update connections with the new rate and pdu size config. self.build(rebuild=True) if self.ap_scheduler_stats or self.ap_ofdma_stats: self.ap_custom_cmd('wl -i wl1 dump_clear') self.ap_custom_cmd('wl -i wl0 dump_clear') for atten_val in self.atten_vals: if atten_val != -1: for atten_idx in self.attenuators: self.set_atten(atten_idx, atten_val) print("Starting multicast traffic (if any configured)") self.multicast_profile.start_mc(debug_=self.debug) self.multicast_profile.refresh_mc(debug_=self.debug) print("Starting layer-3 traffic (if any configured)") self.cx_profile.start_cx() self.cx_profile.refresh_cx() cur_time = datetime.datetime.now() print("Getting initial values.") old_rx_values, rx_drop_percent, endps, total_dl_bps, total_ul_bps, total_dl_ll_bps, total_ul_ll_bps = self.__get_rx_values() end_time = self.parse_time(self.test_duration) + cur_time print("Monitoring throughput for duration: %s"%(self.test_duration)) # Monitor test for the interval duration. passes = 0 expected_passes = 0 total_dl_bps = 0 total_ul_bps = 0 total_dl_ll_bps = 0 total_ul_ll_bps = 0 endps = [] ap_row = [] ap_stats_col_titles = [] mac_found_5g = False mac_found_2g = False while cur_time < end_time: #interval_time = cur_time + datetime.timedelta(seconds=5) interval_time = cur_time + datetime.timedelta(seconds=self.polling_interval_seconds) #print("polling_interval_seconds {}".format(self.polling_interval_seconds)) while cur_time < interval_time: cur_time = datetime.datetime.now() time.sleep(.2) self.epoch_time = int(time.time()) new_rx_values, rx_drop_percent, endps, total_dl_bps, total_ul_bps, total_dl_ll_bps, total_ul_ll_bps = self.__get_rx_values() print("main loop, total-dl: ", total_dl_bps, " total-ul: ", total_ul_bps, " total-dl-ll: ", total_dl_ll_bps," total-ul-ll: ", total_ul_ll_bps) # AP OUTPUT if self.ap_read: if self.ap_test_mode: # Create the test data as a continuous string ap_stats_5g="{}{}{}{}{}{}".format("root@Docsis-Gateway:~# wl -i wl1 bs_data\n", "Station Address PHY Mbps Data Mbps Air Use Data Use Retries bw mcs Nss ofdma mu-mimo\n", "04:f0:21:82:2f:d6 1016.6 48.9 6.5% 24.4% 16.6% 80 9.7 2 0.0% 0.0%\n", "50:E0:85:84:7A:E7 880.9 52.2 7.7% 26.1% 20.0% 80 8.5 2 0.0% 0.0%\n", "50:E0:85:89:5D:00 840.0 47.6 6.4% 23.8% 2.3% 80 8.0 2 0.0% 0.0%\n", "50:E0:85:87:5B:F4 960.7 51.5 5.9% 25.7% 0.0% 80 9 2 0.0% 0.0%\n", "- note the MAC will match ap_stats.append((overall) - 200.2 26.5% - - \n") print("ap_stats {}".format(ap_stats_5g)) # Create the test data as a continuous string ap_chanim_stats_5g = "{}{}{}{}".format("root@Docsis-Gateway:~# wl -i wl1 chanim_stats\n", "version: 3\n", "chanspec tx inbss obss nocat nopkt doze txop goodtx badtx glitch badplcp knoise idle timestamp\n", #`"0xe06a 61 15 0 17 0 0 6 53 2 0 0 -91 65 343370578\n") "0xe06a 1.67 15.00 0.00 17.00 0.00 0.00 97.33 53.00 2.00 0 0 -91 65 343370578\n") else: # read from the AP ap_stats_5g = self.read_ap_stats_5g() ap_chanim_stats_5g = self.read_ap_chanim_stats_5g() ap_stats_5g_rows = ap_stats_5g.splitlines() print("From AP stats: ap_stats_5g_rows {}".format(ap_stats_5g_rows)) ap_chanim_stats_rows_5g = ap_chanim_stats_5g.splitlines() print("From AP chanim: ap_chanim_stats_rows {}".format(ap_chanim_stats_rows_5g)) channel_utilization = 0 # Query all of our ports # Note: the endp eid is the shelf.resource.port.endp-id port_eids = self.gather_port_eids() for eid_name in port_eids: eid = self.name_to_eid(eid_name) url = "/port/%s/%s/%s"%(eid[0], eid[1], eid[2]) # read LANforge to get the mac response = self.json_get(url) if (response is None) or ("interface" not in response): print("query-port: %s: incomplete response:"%(url)) pprint(response) else: # print("response".format(response)) pprint(response) p = response['interface'] print("#### From LANforge: p, response['insterface']:{}".format(p)) mac = p['mac'] #print("#### From LANforge: p['mac']: {mac}".format(mac=mac)) # Parse the ap stats to find the matching mac then use that row for reporting for row in ap_stats_5g_rows: split_row = row.split() #print("split_row {}".format(split_row)) #print("split_row[0] {} mac {}".format(split_row[0].lower(),mac.lower())) if self.ap_test_mode: if split_row[0].lower() != mac.lower(): ap_row = split_row mac_found_5g = True else: try: # split_row[0].lower() , mac from AP # mac.lower() , mac from LANforge if split_row[0].lower() == mac.lower(): ap_row = split_row mac_found_5g = True except: print(" 'No stations are currently associated.'? from AP") print(" since possibly no stations: excption on compare split_row[0].lower() ") if mac_found_5g == True: mac_found_5g = False print("selected ap_row (from split_row): {}".format(ap_row)) # Find latency, jitter for connections using this port. latency, jitter, total_ul_rate, total_ul_rate_ll, total_ul_pkts_ll, total_dl_rate, total_dl_rate_ll, total_dl_pkts_ll = self.get_endp_stats_for_port(p["port"], endps) # now report the ap_chanim_stats along side of the ap_stats_5g xtop_reported = False for row in ap_chanim_stats_rows_5g: split_row = row.split() if xtop_reported: try: xtop = split_row[7] print("xtop {xtop}".format(xtop=xtop)) channel_utilization = 100 - float(xtop) print("channel_utilization {utilization}".format(utilization=channel_utilization)) except: print("detected chanspec with reading chanim_stats, failed reading xtop") # should be only one channel utilization break else: try: if split_row[0].lower() == 'chanspec': xtop_reported = True except: print("Error reading xtop") # ap information is passed with ap_row so all information needs to be contained in ap_row ap_row.append(str(channel_utilization)) print("channel_utilization {channel_utilization}".format(channel_utilization=channel_utilization)) print("ap_row {ap_row}".format(ap_row=ap_row)) ap_stats_5g_col_titles = ['Station Address','PHY Mbps','Data Mbps','Air Use','Data Use','Retries','bw','mcs','Nss','ofdma','mu-mimo','channel_utilization'] self.write_port_csv(len(temp_stations_list), ul, dl, ul_pdu_str, dl_pdu_str, atten_val, eid_name, p, latency, jitter, total_ul_rate, total_ul_rate_ll, total_ul_pkts_ll, total_dl_rate, total_dl_rate_ll, total_dl_pkts_ll , ap_row, ap_stats_5g_col_titles) #ap_stats_5g_col_titles used as a length if self.ap_test_mode: # Create the test data as a continuous string ap_stats_2g="{}{}{}{}{}{}".format("root@Docsis-Gateway:~# wl -i wl1 bs_data\n", "Station Address PHY Mbps Data Mbps Air Use Data Use Retries bw mcs Nss ofdma mu-mimo\n", "04:f0:21:82:2f:d6 1016.6 48.9 6.5% 24.4% 16.6% 80 9.7 2 0.0% 0.0%\n", "50:E0:85:84:7A:E7 880.9 52.2 7.7% 26.1% 20.0% 80 8.5 2 0.0% 0.0%\n", "50:E0:85:89:5D:00 840.0 47.6 6.4% 23.8% 2.3% 80 8.0 2 0.0% 0.0%\n", "50:E0:85:87:5B:F4 960.7 51.5 5.9% 25.7% 0.0% 80 9 2 0.0% 0.0%\n", "- note the MAC will match ap_stats_2g.append((overall) - 200.2 26.5% - - \n") print("ap_stats_2g {}".format(ap_stats_2g)) # Create the test data as a continuous string ap_chanim_stats_2g = "{}{}{}{}".format("root@Docsis-Gateway:~# wl -i wl1 chanim_stats\n", "version: 3\n", "chanspec tx inbss obss nocat nopkt doze txop goodtx badtx glitch badplcp knoise idle timestamp\n", #"0xe06a 62 15 0 17 0 0 6 53 2 0 0 -91 65 343370578\n") "0xe06a 1.67 15.00 0.00 17.00 0.00 0.00 97.33 53.00 2.00 0 0 -91 65 343370578\n") else: # read from the AP ap_stats_2g = self.read_ap_stats_2g() ap_chanim_stats_2g = self.read_ap_chanim_stats_2g() ap_stats_2g_rows = ap_stats_2g.splitlines() print("From AP stats: ap_stats_2g_rows {}".format(ap_stats_2g_rows)) ap_chanim_stats_rows_2g = ap_chanim_stats_2g.splitlines() print("From AP chanim: ap_chanim_stats_rows_2g {}".format(ap_chanim_stats_rows_2g)) channel_utilization = 0 # Query all of our ports # Note: the endp eid is the shelf.resource.port.endp-id port_eids = self.gather_port_eids() for eid_name in port_eids: eid = self.name_to_eid(eid_name) url = "/port/%s/%s/%s"%(eid[0], eid[1], eid[2]) # read LANforge to get the mac response = self.json_get(url) if (response is None) or ("interface" not in response): print("query-port: %s: incomplete response:"%(url)) pprint(response) else: # print("response".format(response)) pprint(response) p = response['interface'] #print("#### From LANforge: p, response['insterface']:{}".format(p)) mac = p['mac'] #print("#### From LANforge: p['mac']: {mac}".format(mac=mac)) # Parse the ap stats to find the matching mac then use that row for reporting for row in ap_stats_2g_rows: split_row = row.split() #print("split_row {}".format(split_row)) #print("split_row[0] {} mac {}".format(split_row[0].lower(),mac.lower())) if self.ap_test_mode: if split_row[0].lower() != mac.lower(): ap_row = split_row mac_found_2g = True else: try: # split_row[0].lower() , mac from AP # mac.lower() , mac from LANforge if split_row[0].lower() == mac.lower(): ap_row = split_row mac_found_2g = True except: print(" 'No stations are currently associated.'? from AP") print(" since possibly no stations: excption on compare split_row[0].lower() ") if mac_found_2g == True: mac_found_2g = False print("selected ap_row (from split_row): {}".format(ap_row)) # Find latency, jitter for connections using this port. latency, jitter, total_ul_rate, total_ul_rate_ll, total_ul_pkts_ll, total_dl_rate, total_dl_rate_ll, total_dl_pkts_ll = self.get_endp_stats_for_port(p["port"], endps) # now report the ap_chanim_stats along side of the ap_stats_2g xtop_reported = False for row in ap_chanim_stats_rows_2g: split_row = row.split() if xtop_reported: try: xtop = split_row[7] print("xtop {xtop}".format(xtop=xtop)) channel_utilization = 100 - float(xtop) print("channel_utilization {utilization}".format(utilization=channel_utilization)) except: print("detected chanspec with reading chanim_stats, failed reading xtop") # should be only one channel utilization break else: try: if split_row[0].lower() == 'chanspec': xtop_reported = True except: print("Error reading xtop") # ap information is passed with ap_row so all information needs to be contained in ap_row ap_row.append(str(channel_utilization)) print("channel_utilization {channel_utilization}".format(channel_utilization=channel_utilization)) print("ap_row {ap_row}".format(ap_row=ap_row)) ap_stats_2g_col_titles = ['Station Address','PHY Mbps','Data Mbps','Air Use','Data Use','Retries','bw','mcs','Nss','ofdma','mu-mimo','channel_utilization'] self.write_port_csv(len(temp_stations_list), ul, dl, ul_pdu_str, dl_pdu_str, atten_val, eid_name, p, latency, jitter, total_ul_rate, total_ul_rate_ll, total_ul_pkts_ll, total_dl_rate, total_dl_rate_ll, total_dl_pkts_ll, ap_row, ap_stats_2g_col_titles) #ap_stats_2g_col_titles used as a length else: # Query all of our ports # Note: the endp eid is the shelf.resource.port.endp-id port_eids = self.gather_port_eids() for eid_name in port_eids: eid = self.name_to_eid(eid_name) url = "/port/%s/%s/%s"%(eid[0], eid[1], eid[2]) response = self.json_get(url) if (response is None) or ("interface" not in response): print("query-port: %s: incomplete response:"%(url)) pprint(response) else: p = response['interface'] latency, jitter, total_ul_rate, total_ul_rate_ll, total_ul_pkts_ll, total_dl_rate, total_dl_rate_ll, total_dl_pkts_ll= self.get_endp_stats_for_port(p["port"], endps) self.write_port_csv(len(temp_stations_list), ul, dl, ul_pdu_str, dl_pdu_str, atten_val, eid_name, p, latency, jitter, total_ul_rate, total_ul_rate_ll, total_ul_pkts_ll, total_dl_rate, total_dl_rate_ll, total_dl_pkts_ll, ap_row, ap_stats_col_titles) #ap_stats_col_titles used as a length # At end of test step, record KPI information. This is different the kpi.csv self.record_kpi(len(temp_stations_list), ul, dl, ul_pdu_str, dl_pdu_str, atten_val, total_dl_bps, total_ul_bps, total_dl_ll_bps, total_ul_ll_bps) # At end of test if requested store upload and download stats if self.ap_scheduler_stats: # get the (UL) Upload scheduler statistics self.ap_umsched += self.ap_custom_cmd('wl -i wl1 dump umsched') # get the (DL) Download schduler staticstics self.ap_msched += self.ap_custom_cmd('wl -i wl1 dump msched') if self.ap_ofdma_stats: # provide OFDMA stats 5GHz self.ap_ofdma_5g += self.ap_custom_cmd('wl -i wl1 muinfo -v') # provide OFDMA stats 2.4GHz self.ap_ofdma_24g += self.ap_custom_cmd('wl -i wl0 muinfo -v') # Stop connections. self.cx_profile.stop_cx(); self.multicast_profile.stop_mc(); cur_time = datetime.datetime.now() if passes == expected_passes: self._pass("PASS: Requested-Rate: %s <-> %s PDU: %s <-> %s All tests passed" % (ul, dl, ul_pdu, dl_pdu), print_pass) def write_port_csv(self, sta_count, ul, dl, ul_pdu, dl_pdu, atten, eid_name, port_data, latency, jitter, total_ul_rate, total_ul_rate_ll, total_ul_pkts_ll, total_dl_rate, total_dl_rate_ll, total_dl_pkts_ll, ap_row, ap_stats_col_titles): row = [self.epoch_time, self.time_stamp(), sta_count, ul, ul, dl, dl, dl_pdu, dl_pdu, ul_pdu, ul_pdu, atten, eid_name ] row = row + [port_data['bps rx'], port_data['bps tx'], port_data['rx-rate'], port_data['tx-rate'], port_data['signal'], port_data['ap'], port_data['mode'], latency, jitter, total_ul_rate, total_ul_rate_ll, total_ul_pkts_ll, total_dl_rate, total_dl_rate_ll, total_dl_pkts_ll] #Add in info queried from AP. NOTE: do not need to pass in the ap_stats_col_titles #print("ap_row length {} col_titles length {}".format(len(ap_row),len(self.ap_stats_col_titles))) #print("self.ap_stats_col_titles {} ap_stats_col_titles {}".format(self.ap_stats_col_titles,ap_stats_col_titles)) if len(ap_row) == len(self.ap_stats_col_titles): i = 0 #print("ap_row {}".format(ap_row)) for col in ap_row: #print("col {}".format(col)) row.append(col) writer = self.port_csv_writers[eid_name] writer.writerow(row) self.port_csv_files[eid_name].flush() # Submit data to the influx db if configured to do so. def record_kpi(self, sta_count, ul, dl, ul_pdu, dl_pdu, atten, total_dl_bps, total_ul_bps, total_dl_ll_bps, total_ul_ll_bps): tags = dict() tags['requested-ul-bps'] = ul tags['requested-dl-bps'] = dl tags['ul-pdu-size'] = ul_pdu tags['dl-pdu-size'] = dl_pdu tags['station-count'] = sta_count tags['attenuation'] = atten tags["script"] = 'test_l3_longevity' # Add user specified tags for k in self.user_tags: tags[k[0]] = k[1] now = str(datetime.datetime.utcnow().isoformat()) print("NOTE: Adding kpi to influx, total-download-bps: %s upload: %s bi-directional: %s\n"%(total_dl_bps, total_ul_bps, (total_ul_bps + total_dl_bps))) if self.influxdb is not None: self.influxdb.post_to_influx("total-download-bps", total_dl_bps, tags, now) self.influxdb.post_to_influx("total-upload-bps", total_ul_bps, tags, now) self.influxdb.post_to_influx("total-bi-directional-bps", total_ul_bps + total_dl_bps, tags, now) if self.csv_kpi_file: row = [self.epoch_time, self.time_stamp(), sta_count, ul, ul, dl, dl, dl_pdu, dl_pdu, ul_pdu, ul_pdu, atten, total_dl_bps, total_ul_bps, (total_ul_bps + total_dl_bps), total_dl_ll_bps, total_ul_ll_bps, (total_ul_ll_bps + total_dl_ll_bps) ] # Add values for any user specified tags for k in self.user_tags: row.append(k[1]) self.csv_kpi_writer.writerow(row) self.csv_kpi_file.flush() # Stop traffic and admin down stations. def stop(self): self.cx_profile.stop_cx() self.multicast_profile.stop_mc() for station_list in self.station_lists: for station_name in station_list: self.admin_down(station_name) # Remove traffic connections and stations. def cleanup(self): self.cx_profile.cleanup() self.multicast_profile.cleanup() for station_profile in self.station_profiles: station_profile.cleanup() def csv_generate_column_headers(self): csv_rx_headers = ['Time epoch','Time','Monitor', 'UL-Min-Requested','UL-Max-Requested','DL-Min-Requested','DL-Max-Requested', 'UL-Min-PDU','UL-Max-PDU','DL-Min-PDU','DL-Max-PDU', ] csv_rx_headers.append("average_rx_data_bytes") return csv_rx_headers def csv_generate_port_column_headers(self): csv_rx_headers = ['Time epoch', 'Time', 'Station-Count', 'UL-Min-Requested','UL-Max-Requested','DL-Min-Requested','DL-Max-Requested', 'UL-Min-PDU','UL-Max-PDU','DL-Min-PDU','DL-Max-PDU','Attenuation', 'Name', 'Rx-Bps', 'Tx-Bps', 'Rx-Link-Rate', 'Tx-Link-Rate', 'RSSI', 'AP', 'Mode', 'Rx-Latency', 'Rx-Jitter', 'Ul-Rx-Goodput-bps', 'Ul-Rx-Rate-ll', 'Ul-Rx-Pkts-ll', 'Dl-Rx-Goodput-bps', 'Dl-Rx-Rate-ll', 'Dl-Rx-Pkts-ll' ] # Add in columns we are going to query from the AP for col in self.ap_stats_col_titles: csv_rx_headers.append(col) return csv_rx_headers def csv_generate_kpi_column_headers(self): csv_rx_headers = ['Time epoch', 'Time', 'Station-Count', 'UL-Min-Requested','UL-Max-Requested','DL-Min-Requested','DL-Max-Requested', 'UL-Min-PDU','UL-Max-PDU','DL-Min-PDU','DL-Max-PDU','Attenuation', 'Total-Download-Bps', 'Total-Upload-Bps', 'Total-UL/DL-Bps', 'Total-Download-LL-Bps', 'Total-Upload-LL-Bps','Total-UL/DL-LL-Bps' ] for k in self.user_tags: csv_rx_headers.append(k[0]) return csv_rx_headers # Write initial headers to csv file. def csv_add_column_headers(self,headers): if self.csv_kpi_file is not None: self.csv_kpi_writer.writerow(self.csv_generate_kpi_column_headers()) self.csv_kpi_file.flush() # Write initial headers to port csv file. def csv_add_port_column_headers(self, eid_name, headers): #if self.csv_file is not None: fname = self.outfile[:-4] # Strip '.csv' from file name fname = fname + "-" + eid_name + ".csv" pfile = open(fname, "w") port_csv_writer = csv.writer(pfile, delimiter=",") self.port_csv_files[eid_name] = pfile self.port_csv_writers[eid_name] = port_csv_writer port_csv_writer.writerow(headers) pfile.flush() def csv_validate_list(self, csv_list, length): if len(csv_list) < length: csv_list = csv_list + [('no data','no data')] * (length - len(csv_list)) return csv_list def csv_add_row(self,row,writer,csv_file): if csv_file is not None: writer.writerow(row) csv_file.flush() # End of the main class. # Check some input values. def valid_endp_types(_endp_type): etypes = _endp_type.split(',') for endp_type in etypes: valid_endp_type=['lf','lf_udp','lf_udp6','lf_tcp','lf_tcp6','mc_udp','mc_udp6'] if not (str(endp_type) in valid_endp_type): print('invalid endp_type: %s. Valid types lf, lf_udp, lf_udp6, lf_tcp, lf_tcp6, mc_udp, mc_udp6' % endp_type) exit(1) return _endp_type # Starting point for running this from cmd line. def main(): lfjson_host = "localhost" lfjson_port = 8080 endp_types = "lf_udp" debug = False parser = argparse.ArgumentParser( prog='test_l3_longevity.py', #formatter_class=argparse.RawDescriptionHelpFormatter, formatter_class=argparse.RawTextHelpFormatter, epilog='''\ Useful Information: 1. Polling interval for checking traffic is fixed at 1 minute 2. The test will generate csv file 3. The tx/rx rates are fixed at 256000 bits per second 4. Maximum stations per radio based on radio ''', description='''\ test_l3_longevity.py: -------------------- Summary : ---------- create stations, create traffic between upstream port and stations, run traffic. The traffic on the stations will be checked once per minute to verify that traffic is transmitted and received. Generic command layout: ----------------------- python .\\test_l3_longevity.py --test_duration --endp_type --upstream_port --radio "radio== stations== ssid== ssid_pw== security==" --debug Multiple radios may be entered with individual --radio switches # UDP bi-directional test, no use of controller. /test_l3_longevity.py --mgr localhost --endp_type 'lf_udp lf_tcp' --upstream_port 1.1.eth1 \ --radio "radio==1.1.wiphy0 stations==10 ssid==ASUS_70 ssid_pw==[BLANK] security==open" \ --radio "radio==1.1.wiphy2 stations==1 ssid==ASUS_70 ssid_pw==[BLANK] security==open" \ --test_duration 30s : number followed by one of the following d - days h - hours m - minutes s - seconds : lf_udp : IPv4 UDP traffic lf_tcp : IPv4 TCP traffic lf_udp6 : IPv6 UDP traffic lf_tcp6 : IPv6 TCP traffic mc_udp : IPv4 multi cast UDP traffic mc_udp6 : IPv6 multi cast UDP traffic : BK, BE, VI, VO: Optional wifi related Tos Settings. Or, use your preferred numeric values. ################################# #Command switches ################################# --mgr ',default='localhost' -d / --test_duration example --time 5d (5 days) default: 3m options: number followed by d, h, m or s',default='3m' --tos: Support different ToS settings: BK | BE | VI | VO | numeric',default="BE" --debug: Enable debugging',default=False -t / --endp_type example --endp_type \"lf_udp lf_tcp mc_udp\" Default: lf_udp , options: lf_udp, lf_udp6, lf_tcp, lf_tcp6, mc_udp, mc_udp6', default='lf_udp', type=valid_endp_types -u / --upstream_port example: --upstream_port eth1',default='eth1') -o / --outfile ", default='longevity_results' ######################################### # Examples # ####################################### Example #1 running traffic with two radios 1. Test duration 4 minutes 2. Traffic IPv4 TCP 3. Upstream-port eth1 4. Radio #0 wiphy0 has 32 stations, ssid = candelaTech-wpa2-x2048-4-1, ssid password = candelaTech-wpa2-x2048-4-1 5. Radio #1 wiphy1 has 64 stations, ssid = candelaTech-wpa2-x2048-5-3, ssid password = candelaTech-wpa2-x2048-5-3 6. Create connections with TOS of BK and VI Command: (remove carriage returns) python3 .\\test_l3_longevity.py --test_duration 4m --endp_type \"lf_tcp lf_udp mc_udp\" --tos \"BK VI\" --upstream_port eth1 --radio "radio==wiphy0 stations==32 ssid==candelaTech-wpa2-x2048-4-1 ssid_pw==candelaTech-wpa2-x2048-4-1 security==wpa2" --radio "radio==wiphy1 stations==64 ssid==candelaTech-wpa2-x2048-5-3 ssid_pw==candelaTech-wpa2-x2048-5-3 security==wpa2" ''') parser.add_argument('--local_lf_report_dir', help='--local_lf_report_dir override the report path, primary use when running test in test suite',default="") parser.add_argument('-o','--csv_outfile', help="--csv_outfile ", default="") parser.add_argument('--tty', help='--tty \"/dev/ttyUSB2\" the serial interface to the AP',default="") parser.add_argument('--baud', help='--baud \"9600\" AP baud rate for the serial interface',default="9600") parser.add_argument('--amount_ports_to_reset', help='--amount_ports_to_reset \" \" ', default=None) parser.add_argument('--port_reset_seconds', help='--ports_reset_seconds \" \" ', default="10 30") parser.add_argument('--lfmgr', help='--lfmgr ',default='localhost') parser.add_argument('--test_duration', help='--test_duration example --time 5d (5 days) default: 3m options: number followed by d, h, m or s',default='3m') parser.add_argument('--tos', help='--tos: Support different ToS settings: BK | BE | VI | VO | numeric',default="BE") parser.add_argument('--debug', help='--debug flag present debug on enable debugging',action='store_true') parser.add_argument('-t', '--endp_type', help='--endp_type example --endp_type \"lf_udp lf_tcp mc_udp\" Default: lf_udp , options: lf_udp, lf_udp6, lf_tcp, lf_tcp6, mc_udp, mc_udp6', default='lf_udp', type=valid_endp_types) parser.add_argument('-u', '--upstream_port', help='--upstream_port example: --upstream_port eth1',default='eth1') parser.add_argument('--downstream_port', help='--downstream_port example: --downstream_port eth2') parser.add_argument('--polling_interval', help="--polling_interval ", default='60s') parser.add_argument('-r','--radio', action='append', nargs=1, help='--radio \ \"radio== ssid== ssid_pw== security==\" ') parser.add_argument('--ap_read', help='--ap_read flag present enable reading ap', action='store_true') parser.add_argument('--ap_port', help='--ap_port \'/dev/ttyUSB0\'',default='/dev/ttyUSB0') parser.add_argument('--ap_baud', help='--ap_baud \'115200\'',default='115200') # note wl1 is the 5G interface , check the MAC ifconfig -a of the interface to the AP BSSID connection (default may be eth7) parser.add_argument('--ap_cmd_5g', help='ap_cmd_5g \'wl -i wl1 bs_data\'', default="wl -i wl1 bs_data") # note wl1 is the 2.4G interface , check the MAC ifconfig -a of the interface to the AP BSSID connection parser.add_argument('--ap_cmd_2g', help='ap_cmd_2g \'wl -i wl0 bs_data\'', default="wl -i wl0 bs_data") parser.add_argument('--ap_chanim_cmd_5g', help='ap_chanim_cmd_5g \'wl -i wl1 chanim_stats\'', default="wl -i wl1 chanim_stats") parser.add_argument('--ap_chanim_cmd_2g', help='ap_chanim_cmd_2g \'w1 -i wl0 chanim_stats\'', default="wl -i wl0 chanim_stats") parser.add_argument('--ap_scheduler_stats', help='--ap_scheduler_stats flag to clear stats run test then dump ul and dl stats to file', action='store_true') parser.add_argument('--ap_ofdma_stats', help='--ap_ofdma_stats flag to clear stats run test then dumps wl -i wl1 muinfo -v and wl 0i wl0 muinof -v to file', action='store_true') parser.add_argument('--ap_test_mode', help='ap_test_mode flag present use ap canned data', action='store_true') parser.add_argument('-amr','--side_a_min_bps', help='--side_a_min_bps, requested downstream min tx rate, comma separated list for multiple iterations. Default 256k', default="256000") parser.add_argument('-amp','--side_a_min_pdu', help='--side_a_min_pdu, downstream pdu size, comma separated list for multiple iterations. Default MTU', default="MTU") parser.add_argument('-bmr','--side_b_min_bps', help='--side_b_min_bps, requested upstream min tx rate, comma separated list for multiple iterations. Default 256000', default="256000") parser.add_argument('-bmp','--side_b_min_pdu', help='--side_b_min_pdu, upstream pdu size, comma separated list for multiple iterations. Default MTU', default="MTU") parser.add_argument("--rates_are_totals", default=False, help="Treat configured rates as totals instead of using the un-modified rate for every connection.", action='store_true') parser.add_argument("--multiconn", default=1, help="Configure multi-conn setting for endpoints. Default is 1 (auto-helper is enabled by default as well).") parser.add_argument('--attenuators', help='--attenuators, comma separated list of attenuator module eids: shelf.resource.atten-serno.atten-idx', default="") parser.add_argument('--atten_vals', help='--atten_vals, comma separated list of attenuator settings in ddb units (1/10 of db)', default="") influx_add_parser_args(parser) parser.add_argument("--cap_ctl_out", help="--cap_ctl_out, switch the controller output will be captured", action='store_true') parser.add_argument("--wait", help="--wait , time to wait at the end of the test", default='0') args = parser.parse_args() #print("args: {}".format(args)) debug = args.debug if args.local_lf_report_dir != "": local_lf_report_dir = args.local_lf_report_dir else: local_lf_report_dir = "" if args.ap_read: ap_read = args.ap_read else: ap_read = False if args.ap_scheduler_stats: ap_scheduler_stats = args.ap_scheduler_stats else: ap_scheduler_stats = False if args.ap_ofdma_stats: ap_ofdma_stats = args.ap_ofdma_stats else: ap_ofdma_stats = False if args.ap_test_mode: ap_test_mode = args.ap_test_mode else: ap_test_mode = False if args.ap_port: ap_port = args.ap_port if args.ap_baud: ap_baud = args.ap_baud if args.ap_cmd_5g: ap_cmd_5g = args.ap_cmd_5g if args.ap_cmd_2g: ap_cmd_2g = args.ap_cmd_2g if args.ap_chanim_cmd_5g: ap_chanim_cmd_5g = args.ap_chanim_cmd_5g if args.ap_chanim_cmd_2g: ap_chanim_cmd_2g = args.ap_chanim_cmd_2g if args.test_duration: test_duration = args.test_duration if args.polling_interval: polling_interval = args.polling_interval if args.endp_type: endp_types = args.endp_type if args.lfmgr: lfjson_host = args.lfmgr if args.upstream_port: side_b = args.upstream_port if args.downstream_port: side_a = args.downstream_port else: side_a = None if args.radio: radios = args.radio else: radios = None # Create report, when running with the test framework (lf_check.py) results need to be in the same directory if local_lf_report_dir != "": report = lf_report(_path=local_lf_report_dir, _results_dir_name = "test_l3_longevity",_output_html="test_l3_longevity.html",_output_pdf="test_l3_longevity.pdf") else: report = lf_report(_results_dir_name = "test_l3_longevity",_output_html="test_l3_longevity.html",_output_pdf="test_l3_longevity.pdf") if args.csv_outfile != None: current_time = time.strftime("%Y-%m-%d-%H-%M-%S", time.localtime()) csv_outfile = "{}_{}-test_l3_longevity.csv".format(args.csv_outfile,current_time) csv_outfile = report.file_add_path(csv_outfile) print("csv output file : {}".format(csv_outfile)) influxdb = None if args.influx_bucket is not None: from InfluxRequest import RecordInflux influxdb = RecordInflux(_influx_host=args.influx_host, _influx_port=args.influx_port, _influx_org=args.influx_org, _influx_token=args.influx_token, _influx_bucket=args.influx_bucket) MAX_NUMBER_OF_STATIONS = 1000 radio_name_list = [] number_of_stations_per_radio_list = [] ssid_list = [] ssid_password_list = [] ssid_security_list = [] station_lists = [] #optional radio configuration reset_port_enable_list = [] reset_port_time_min_list = [] reset_port_time_max_list = [] if radios != None: print("radios {}".format(radios)) for radio_ in radios: radio_keys = ['radio','stations','ssid','ssid_pw','security'] print("radio_dict before format {}".format(radio_)) radio_info_dict = dict(map(lambda x: x.split('=='), str(radio_).replace('"','').replace('[','').replace(']','').replace("'","").replace(","," ").split())) print("radio_dict {}".format(radio_info_dict)) for key in radio_keys: if key not in radio_info_dict: print("missing config, for the {}, all of the following need to be present {} ".format(key,radio_keys)) exit(1) radio_name_list.append(radio_info_dict['radio']) number_of_stations_per_radio_list.append(radio_info_dict['stations']) ssid_list.append(radio_info_dict['ssid']) ssid_password_list.append(radio_info_dict['ssid_pw']) ssid_security_list.append(radio_info_dict['security']) optional_radio_reset_keys = ['reset_port_enable'] radio_reset_found = True for key in optional_radio_reset_keys: if key not in radio_info_dict: #print("port reset test not enabled") radio_reset_found = False break if radio_reset_found: reset_port_enable_list.append(True) reset_port_time_min_list.append(radio_info_dict['reset_port_time_min']) reset_port_time_max_list.append(radio_info_dict['reset_port_time_max']) else: reset_port_enable_list.append(False) reset_port_time_min_list.append('0s') reset_port_time_max_list.append('0s') index = 0 for (radio_name_, number_of_stations_per_radio_) in zip(radio_name_list,number_of_stations_per_radio_list): number_of_stations = int(number_of_stations_per_radio_) if number_of_stations > MAX_NUMBER_OF_STATIONS: print("number of stations per radio exceeded max of : {}".format(MAX_NUMBER_OF_STATIONS)) quit(1) station_list = LFUtils.portNameSeries(prefix_="sta", start_id_= 1 + index*1000, end_id_= number_of_stations + index*1000, padding_number_=10000, radio=radio_name_) station_lists.append(station_list) index += 1 #print("endp-types: %s"%(endp_types)) ul_rates = args.side_a_min_bps.split(",") dl_rates = args.side_b_min_bps.split(",") ul_pdus = args.side_a_min_pdu.split(",") dl_pdus = args.side_b_min_pdu.split(",") if args.attenuators == "": attenuators = [] else: attenuators = args.attenuators.split(",") if (args.atten_vals == ""): atten_vals = [-1] else: atten_vals = args.atten_vals.split(",") if (len(ul_rates) != len(dl_rates)): print("ERROR: ul_rates %s and dl_rates %s arrays must be same length\n" %(len(ul_rates), len(dl_rates))) if (len(ul_pdus) != len(dl_pdus)): print("ERROR: ul_pdus %s and dl_pdus %s arrays must be same length\n" %(len(ul_rates), len(dl_rates))) ip_var_test = L3VariableTime( endp_types=endp_types, args=args, tos=args.tos, side_b=side_b, side_a=side_a, radio_name_list=radio_name_list, number_of_stations_per_radio_list=number_of_stations_per_radio_list, ssid_list=ssid_list, ssid_password_list=ssid_password_list, ssid_security_list=ssid_security_list, station_lists= station_lists, name_prefix="LT-", outfile=csv_outfile, reset_port_enable_list=reset_port_enable_list, reset_port_time_min_list=reset_port_time_min_list, reset_port_time_max_list=reset_port_time_max_list, side_a_min_rate=ul_rates, side_b_min_rate=dl_rates, side_a_min_pdu=ul_pdus, side_b_min_pdu=dl_pdus, user_tags=args.influx_tag, rates_are_totals=args.rates_are_totals, mconn=args.multiconn, attenuators=attenuators, atten_vals=atten_vals, number_template="00", test_duration=test_duration, polling_interval= polling_interval, lfclient_host=lfjson_host, lfclient_port=lfjson_port, debug=debug, influxdb=influxdb, ap_scheduler_stats=ap_scheduler_stats, ap_ofdma_stats=ap_ofdma_stats, ap_read=ap_read, ap_port=ap_port, ap_baud=ap_baud, ap_cmd_5g=ap_cmd_5g, ap_cmd_2g=ap_cmd_2g, ap_chanim_cmd_5g=ap_chanim_cmd_5g, ap_chanim_cmd_2g=ap_chanim_cmd_2g, ap_test_mode=ap_test_mode) ip_var_test.pre_cleanup() ip_var_test.build() if not ip_var_test.passes(): print("build step failed.") print(ip_var_test.get_fail_message()) exit(1) ip_var_test.start(False, False) ip_var_test.stop() if not ip_var_test.passes(): print("Test Ended: There were Failures") print(ip_var_test.get_fail_message()) print("Pausing {} seconds after run for manual inspection before we clean up.".format(args.wait)) time.sleep(int(args.wait)) ip_var_test.cleanup() if ip_var_test.passes(): print("Full test passed, all connections increased rx bytes") # Results csv_kpi_file = ip_var_test.get_kpi_csv() report.set_title("L3 Longevity") report.build_banner() report.set_table_title("L3 Longevity Key Performance Indexes") report.build_table_title() report.set_table_dataframe_from_csv(csv_kpi_file) report.build_table() report.write_html_with_timestamp() #report.write_pdf(_page_size = 'A3', _orientation='Landscape') report.write_pdf_with_timestamp(_page_size = 'A4', _orientation='Portrait') # ap scheduler results and write to a file if ap_scheduler_stats: print("getting umsched and msched ap data and writing to a file") file_date = report.get_date() ap_5g_umsched_data = ip_var_test.get_ap_5g_umsched() ap_5g_umsched = "{}-{}".format(file_date,"ap_5g_umsched.txt") ap_5g_umsched = report.file_add_path(ap_5g_umsched) ap_5g_umsched_file = open(ap_5g_umsched, "w") ap_5g_umsched_file.write(str(ap_5g_umsched_data)) ap_5g_umsched_file.close() ap_5g_msched_data = ip_var_test.get_ap_5g_msched() ap_5g_msched = "{}-{}".format(file_date,"ap_5g_msched.txt") ap_5g_msched = report.file_add_path(ap_5g_msched) ap_5g_msched_file = open(ap_5g_msched, "w") ap_5g_msched_file.write(str(ap_5g_msched_data)) ap_5g_msched_file.close() ap_24g_umsched_data = ip_var_test.get_ap_24g_umsched() ap_24g_umsched = "{}-{}".format(file_date,"ap_24g_umsched.txt") ap_24g_umsched = report.file_add_path(ap_24g_umsched) ap_24g_umsched_file = open(ap_24g_umsched, "w") ap_24g_umsched_file.write(str(ap_24g_umsched_data)) ap_24g_umsched_file.close() ap_24g_msched_data = ip_var_test.get_ap_24g_msched() ap_24g_msched = "{}-{}".format(file_date,"ap_24g_msched.txt") ap_24g_msched = report.file_add_path(ap_24g_msched) ap_24g_msched_file = open(ap_24g_msched, "w") ap_24g_msched_file.write(str(ap_24g_msched_data)) ap_24g_msched_file.close() # ap scheduler results and write to a file if ap_ofdma_stats: print("getting ofdma ap data and writing to a file") file_date = report.get_date() ap_ofdma_5g_data = ip_var_test.get_ap_ofdma_5g() ap_ofdma_5g = "{}-{}".format(file_date,"ap_ofdma_5g_data.txt") ap_ofdma_5g = report.file_add_path(ap_ofdma_5g) ap_ofdma_5g_data = open(ap_ofdma_5g, "w") ap_ofdma_5g_data.write(str(ap_ofdma_5g_data)) ap_ofdma_5g_data.close() ap_ofdma_24g_data = ip_var_test.get_ap_ofdma_24g() ap_ofdma_24g = "{}-{}".format(file_date,"ap_ofdma_24g_data.txt") ap_ofdma_24g = report.file_add_path(ap_ofdma_24g) ap_ofdma_24g_data = open(ap_ofdma_24g, "w") ap_ofdma_24g_data.write(str(ap_ofdma_24g_data)) ap_ofdma_24g_data.close() #for csv_file in csv_list: # print("Ouptput reports CSV list value: {}".format(str(csv_file))) if __name__ == "__main__": main()