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#!/usr/bin/python3
# Copyright (c) 2020 Cisco and/or its affiliates.
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at:
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""This module gets T-Rex advanced stateful (astf) traffic profile together
with other parameters, reads the profile and sends the traffic. At the end, it
measures the packet loss and latency.
"""
import argparse
import json
import sys
import time
sys.path.insert(
0, u"/opt/trex-core-2.82/scripts/automation/trex_control_plane/interactive/"
)
from trex.astf.api import *
def fmt_latency(lat_min, lat_avg, lat_max, hdrh):
"""Return formatted, rounded latency.
:param lat_min: Min latency
:param lat_avg: Average latency
:param lat_max: Max latency
:param hdrh: Base64 encoded compressed HDRHistogram object.
:type lat_min: str
:type lat_avg: str
:type lat_max: str
:type hdrh: str
:return: Formatted and rounded output (hdrh unchanged) "min/avg/max/hdrh".
:rtype: str
"""
try:
t_min = int(round(float(lat_min)))
except ValueError:
t_min = int(-1)
try:
t_avg = int(round(float(lat_avg)))
except ValueError:
t_avg = int(-1)
try:
t_max = int(round(float(lat_max)))
except ValueError:
t_max = int(-1)
return u"/".join(str(tmp) for tmp in (t_min, t_avg, t_max, hdrh))
def simple_burst(
profile_file, duration, framesize, mult, warmup_time, port_0, port_1,
latency, async_start=False, traffic_directions=2):
"""Send traffic and measure packet loss and latency.
Procedure:
- reads the given traffic profile with streams,
- connects to the T-rex astf client,
- resets the ports,
- removes all existing streams,
- adds streams from the traffic profile to the ports,
- if the warm-up time is more than 0, sends the warm-up traffic, reads the
statistics,
- clears the statistics from the client,
- starts the traffic,
- waits for the defined time (or runs forever if async mode is defined),
- stops the traffic,
- reads and displays the statistics and
- disconnects from the client.
:param profile_file: A python module with T-rex traffic profile.
:param duration: Duration of traffic run in seconds (-1=infinite).
:param framesize: Frame size.
:param mult: Multiplier of profile CPS.
:param warmup_time: Traffic warm-up time in seconds, 0 = disable.
:param port_0: Port 0 on the traffic generator.
:param port_1: Port 1 on the traffic generator.
:param latency: With latency stats.
:param async_start: Start the traffic and exit.
:param traffic_directions: Bidirectional (2) or unidirectional (1) traffic.
:type profile_file: str
:type duration: float
:type framesize: int or str
:type mult: int
:type warmup_time: float
:type port_0: int
:type port_1: int
:type latency: bool
:type async_start: bool
:type traffic_directions: int
"""
client = None
total_rcvd = 0
total_sent = 0
lost_a = 0
lost_b = 0
lat_a = u"-1/-1/-1/"
lat_b = u"-1/-1/-1/"
lat_a_hist = u""
lat_b_hist = u""
l7_data = u""
stats = dict()
stats_sampling = 1.0
approximated_duration = 0
# Read the profile.
try:
# TODO: key-values pairs to the profile file
# - ips ?
print(f"### Profile file:\n{profile_file}")
profile = ASTFProfile.load(profile_file, framesize=framesize)
except TRexError:
print(f"Error while loading profile '{profile_file}'!")
raise
try:
# Create the client.
client = ASTFClient()
# Connect to server
client.connect()
# Acquire ports, stop the traffic, remove loaded traffic and clear
# stats.
client.reset()
# Load the profile.
client.load_profile(profile)
ports = [port_0]
if traffic_directions > 1:
ports.append(port_1)
# Warm-up phase.
if warmup_time > 0:
# Clear the stats before injecting.
client.clear_stats()
# Choose CPS and start traffic.
client.start(mult=mult, duration=warmup_time)
time_start = time.monotonic()
# Read the stats after the warmup duration (no sampling needed).
time.sleep(warmup_time)
stats[time.monotonic()-time_start] = client.get_stats()
if client.get_warnings():
for warning in client.get_warnings():
print(warning)
client.reset()
print(u"##### Warmup Statistics #####")
print(json.dumps(stats, indent=4, separators=(u",", u": ")))
# TODO: check stats format
stats = stats[sorted(stats.keys())[-1]]
lost_a = stats[port_0][u"opackets"] - stats[port_1][u"ipackets"]
if traffic_directions > 1:
lost_b = stats[port_1][u"opackets"] - stats[port_0][u"ipackets"]
print(f"packets lost from {port_0} --> {port_1}: {lost_a} pkts")
if traffic_directions > 1:
print(f"packets lost from {port_1} --> {port_0}: {lost_b} pkts")
# Clear the stats before injecting.
lost_a = 0
lost_b = 0
stats = dict()
# Choose CPS and start traffic.
client.start(
mult=mult, duration=duration, nc=True,
latency_pps=mult if latency else 0, client_mask=2**len(ports)-1
)
time_start = time.monotonic()
# t-rex starts the packet flow with the delay
stats[time.monotonic()-time_start] = client.get_stats(ports=[port_0])
while stats[sorted(stats.keys())[-1]][port_0][u"opackets"] == 0:
stats.clear()
time.sleep(0.001)
stats[time.monotonic() - time_start] = \
client.get_stats(ports=[port_0])
else:
trex_start_time = list(sorted(stats.keys()))[-1]
time_start += trex_start_time
stats.clear()
if async_start:
# For async stop, we need to export the current snapshot.
xsnap0 = client.ports[port_0].get_xstats().reference_stats
print(f"Xstats snapshot 0: {xsnap0!r}")
if traffic_directions > 1:
xsnap1 = client.ports[port_1].get_xstats().reference_stats
print(f"Xstats snapshot 1: {xsnap1!r}")
else:
time.sleep(
stats_sampling if stats_sampling < duration else duration
)
# Do not block until done.
while client.is_traffic_active(ports=ports):
# Sample the stats.
stats[time.monotonic()-time_start] = \
client.get_stats(ports=ports)
time.sleep(
stats_sampling if stats_sampling < duration else duration
)
else:
# Read the stats after the test
stats[time.monotonic()-time_start] = \
client.get_stats(ports=ports)
if client.get_warnings():
for warning in client.get_warnings():
print(warning)
client.reset()
print(u"##### Statistics #####")
print(json.dumps(stats, indent=4, separators=(u",", u": ")))
approximated_duration = list(sorted(stats.keys()))[-1]
stats = stats[sorted(stats.keys())[-1]]
lost_a = stats[port_0][u"opackets"] - stats[port_1][u"ipackets"]
if traffic_directions > 1:
lost_b = stats[port_1][u"opackets"] - stats[port_0][u"ipackets"]
# TODO: Latency measurement not used at this phase. This part will
# be aligned in another commit.
# Stats index is not a port number, but "pgid".
if latency:
lat_obj = stats[u"latency"][0][u"hist"]
# TODO: Latency histogram is dictionary in astf mode,
# needs additional processing
lat_a = fmt_latency(
str(lat_obj[u"min_usec"]), str(lat_obj[u"s_avg"]),
str(lat_obj[u"max_usec"]), u"-")
lat_a_hist = str(lat_obj[u"histogram"])
if traffic_directions > 1:
lat_obj = stats[u"latency"][1][u"hist"]
lat_b = fmt_latency(
str(lat_obj[u"min_usec"]), str(lat_obj[u"s_avg"]),
str(lat_obj[u"max_usec"]), u"-")
lat_b_hist = str(lat_obj[u"histogram"])
if traffic_directions > 1:
total_sent = \
stats[port_0][u"opackets"] + stats[port_1][u"opackets"]
total_rcvd = \
stats[port_0][u"ipackets"] + stats[port_1][u"ipackets"]
client_stats = stats[u"traffic"][u"client"]
server_stats = stats[u"traffic"][u"server"]
# Some zero counters are not sent
# Active and established flows UDP/TCP
# Client
c_act_flows = client_stats[u"m_active_flows"]
c_est_flows = client_stats[u"m_est_flows"]
c_traffic_duration = client_stats.get(u"m_traffic_duration", 0)
l7_data = f"client_active_flows={c_act_flows}, "
l7_data += f"client_established_flows={c_est_flows}, "
l7_data += f"client_traffic_duration={c_traffic_duration}, "
# Possible errors
# Too many packets in NIC rx queue
c_err_rx_throttled = client_stats.get(u"err_rx_throttled", 0)
l7_data += f"client_err_rx_throttled={c_err_rx_throttled}, "
# Number of client side flows that were not opened
# due to flow-table overflow
c_err_nf_throttled = client_stats.get(u"err_c_nf_throttled", 0)
l7_data += f"client_err_nf_throttled={c_err_nf_throttled}, "
# Too many flows
c_err_flow_overflow = client_stats.get(u"err_flow_overflow", 0)
l7_data += f"client_err_flow_overflow={c_err_flow_overflow}, "
# Server
s_act_flows = server_stats[u"m_active_flows"]
s_est_flows = server_stats[u"m_est_flows"]
s_traffic_duration = server_stats.get(u"m_traffic_duration", 0)
l7_data += f"server_active_flows={s_act_flows}, "
l7_data += f"server_established_flows={s_est_flows}, "
l7_data += f"server_traffic_duration={s_traffic_duration}, "
# Possible errors
# Too many packets in NIC rx queue
s_err_rx_throttled = server_stats.get(u"err_rx_throttled", 0)
l7_data += f"client_err_rx_throttled={s_err_rx_throttled}, "
if u"udp" in profile_file:
# Client
# Established connections
c_udp_connects = client_stats.get(u"udps_connects", 0)
l7_data += f"client_udp_connects={c_udp_connects}, "
# Closed connections
c_udp_closed = client_stats.get(u"udps_closed", 0)
l7_data += f"client_udp_closed={c_udp_closed}, "
# Sent bytes
c_udp_sndbyte = client_stats.get(u"udps_sndbyte", 0)
l7_data += f"client_udp_tx_bytes={c_udp_sndbyte}, "
# Sent packets
c_udp_sndpkt = client_stats.get(u"udps_sndpkt", 0)
l7_data += f"client_udp_tx_packets={c_udp_sndpkt}, "
# Received bytes
c_udp_rcvbyte = client_stats.get(u"udps_rcvbyte", 0)
l7_data += f"client_udp_rx_bytes={c_udp_rcvbyte}, "
# Received packets
c_udp_rcvpkt = client_stats.get(u"udps_rcvpkt", 0)
l7_data += f"client_udp_rx_packets={c_udp_rcvpkt}, "
# Keep alive drops
c_udp_keepdrops = client_stats.get(u"udps_keepdrops", 0)
l7_data += f"client_udp_keep_drops={c_udp_keepdrops}, "
# Server
# Accepted connections
s_udp_accepts = server_stats.get(u"udps_accepts", 0)
l7_data += f"server_udp_accepts={s_udp_accepts}, "
# Closed connections
s_udp_closed = server_stats.get(u"udps_closed", 0)
l7_data += f"server_udp_closed={s_udp_closed}, "
# Sent bytes
s_udp_sndbyte = server_stats.get(u"udps_sndbyte", 0)
l7_data += f"server_udp_tx_bytes={s_udp_sndbyte}, "
# Sent packets
s_udp_sndpkt = server_stats.get(u"udps_sndpkt", 0)
l7_data += f"server_udp_tx_packets={s_udp_sndpkt}, "
# Received bytes
s_udp_rcvbyte = server_stats.get(u"udps_rcvbyte", 0)
l7_data += f"server_udp_rx_bytes={s_udp_rcvbyte}, "
# Received packets
s_udp_rcvpkt = server_stats.get(u"udps_rcvpkt", 0)
l7_data += f"server_udp_rx_packets={s_udp_rcvpkt}, "
elif u"tcp" in profile_file:
# Client
# Initiated connections
c_tcp_connatt = client_stats.get(u"tcps_connattempt", 0)
l7_data += f"client_tcp_connect_inits={c_tcp_connatt}, "
# Established connections
c_tcp_connects = client_stats.get(u"tcps_connects", 0)
l7_data += f"client_tcp_connects={c_tcp_connects}, "
# Closed connections
c_tcp_closed = client_stats.get(u"tcps_closed", 0)
l7_data += f"client_tcp_closed={c_tcp_closed}, "
# Send bytes
c_tcp_sndbyte = client_stats.get(u"tcps_sndbyte", 0)
l7_data += f"client_tcp_tx_bytes={c_tcp_sndbyte}, "
# Received bytes
c_tcp_rcvbyte = client_stats.get(u"tcps_rcvbyte", 0)
l7_data += f"client_tcp_rx_bytes={c_tcp_rcvbyte}, "
# Server
# Accepted connections
s_tcp_accepts = server_stats.get(u"tcps_accepts", 0)
l7_data += f"server_tcp_accepts={s_tcp_accepts}, "
# Established connections
s_tcp_connects = server_stats.get(u"tcps_connects", 0)
l7_data += f"server_tcp_connects={s_tcp_connects}, "
# Closed connections
s_tcp_closed = server_stats.get(u"tcps_closed", 0)
l7_data += f"server_tcp_closed={s_tcp_closed}, "
# Sent bytes
s_tcp_sndbyte = server_stats.get(u"tcps_sndbyte", 0)
l7_data += f"server_tcp_tx_bytes={s_tcp_sndbyte}, "
# Received bytes
s_tcp_rcvbyte = server_stats.get(u"tcps_rcvbyte", 0)
l7_data += f"server_tcp_rx_bytes={s_tcp_rcvbyte}, "
else:
total_sent = stats[port_0][u"opackets"]
total_rcvd = stats[port_1][u"ipackets"]
print(f"packets lost from {port_0} --> {port_1}: {lost_a} pkts")
if traffic_directions > 1:
print(f"packets lost from {port_1} --> {port_0}: {lost_b} pkts")
except TRexError:
print(u"T-Rex ASTF runtime error!", file=sys.stderr)
raise
finally:
if client:
if async_start:
client.disconnect(stop_traffic=False, release_ports=True)
else:
client.clear_profile()
client.disconnect()
print(
f"trex_start_time={trex_start_time}, "
f"cps={mult!r}, total_received={total_rcvd}, "
f"total_sent={total_sent}, frame_loss={lost_a + lost_b}, "
f"approximated_duration={approximated_duration}, "
f"latency_stream_0(usec)={lat_a}, "
f"latency_stream_1(usec)={lat_b}, "
f"latency_hist_stream_0={lat_a_hist}, "
f"latency_hist_stream_1={lat_b_hist}, "
f"{l7_data}"
)
def main():
"""Main function for the traffic generator using T-rex.
It verifies the given command line arguments and runs "simple_burst"
function.
"""
parser = argparse.ArgumentParser()
parser.add_argument(
u"-p", u"--profile", required=True, type=str,
help=u"Python traffic profile."
)
parser.add_argument(
u"-d", u"--duration", required=True, type=float,
help=u"Duration of traffic run."
)
parser.add_argument(
u"-s", u"--frame_size", required=True,
help=u"Size of a Frame without padding and IPG."
)
parser.add_argument(
u"-m", u"--mult", required=True, type=int,
help=u"Multiplier of profile CPS."
)
parser.add_argument(
u"-w", u"--warmup_time", type=float, default=5.0,
help=u"Traffic warm-up time in seconds, 0 = disable."
)
parser.add_argument(
u"--port_0", required=True, type=int,
help=u"Port 0 on the traffic generator."
)
parser.add_argument(
u"--port_1", required=True, type=int,
help=u"Port 1 on the traffic generator."
)
parser.add_argument(
u"--async_start", action=u"store_true", default=False,
help=u"Non-blocking call of the script."
)
parser.add_argument(
u"--latency", action=u"store_true", default=False,
help=u"Add latency stream."
)
parser.add_argument(
u"--traffic_directions", type=int, default=2,
help=u"Send bi- (2) or uni- (1) directional traffic."
)
args = parser.parse_args()
try:
framesize = int(args.frame_size)
except ValueError:
framesize = args.frame_size
simple_burst(
profile_file=args.profile, duration=args.duration, framesize=framesize,
mult=args.mult, warmup_time=args.warmup_time, port_0=args.port_0,
port_1=args.port_1, latency=args.latency, async_start=args.async_start,
traffic_directions=args.traffic_directions
)
if __name__ == u"__main__":
main()
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