# Copyright 2016 Cisco Systems, Inc. All rights reserved. # # 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. """Interface to the traffic generator clients including NDR/PDR binary search.""" import socket import struct import time import sys from attrdict import AttrDict import bitmath from hdrh.histogram import HdrHistogram from netaddr import IPNetwork # pylint: disable=import-error from trex.stl.api import Ether from trex.stl.api import STLError from trex.stl.api import UDP # pylint: disable=wrong-import-order from scapy.contrib.mpls import MPLS # flake8: noqa # pylint: enable=wrong-import-order # pylint: enable=import-error from .log import LOG from .packet_stats import InterfaceStats from .packet_stats import PacketPathStats from .stats_collector import IntervalCollector from .stats_collector import IterationCollector from .traffic_gen import traffic_utils as utils from .utils import cast_integer, find_max_size, find_tuples_equal_to_lcm_value, get_divisors, lcm class TrafficClientException(Exception): """Generic traffic client exception.""" class TrafficRunner(object): """Serialize various steps required to run traffic.""" def __init__(self, client, duration_sec, interval_sec=0, service_mode=False): """Create a traffic runner.""" self.client = client self.start_time = None self.duration_sec = duration_sec self.interval_sec = interval_sec self.service_mode = service_mode def run(self): """Clear stats and instruct the traffic generator to start generating traffic.""" if self.is_running(): return None LOG.info('Running traffic generator') self.client.gen.clear_stats() # Debug use only: the service_mode flag may have been set in # the configuration, in order to enable the 'service' mode # in the trex generator, before starting the traffic (run). # From this point, a T-rex console (launched in readonly mode) would # then be able to capture the transmitted and/or received traffic. self.client.gen.set_service_mode(enabled=self.service_mode) LOG.info('Service mode is %sabled', 'en' if self.service_mode else 'dis') self.client.gen.start_traffic() self.start_time = time.time() return self.poll_stats() def stop(self): """Stop the current run and instruct the traffic generator to stop traffic.""" if self.is_running(): self.start_time = None self.client.gen.stop_traffic() def is_running(self): """Check if a run is still pending.""" return self.start_time is not None def time_elapsed(self): """Return time elapsed since start of run.""" if self.is_running(): return time.time() - self.start_time return self.duration_sec def poll_stats(self): """Poll latest stats from the traffic generator at fixed interval - sleeps if necessary. return: latest stats or None if traffic is stopped """ if not self.is_running(): return None if self.client.skip_sleep(): self.stop() return self.client.get_stats() time_elapsed = self.time_elapsed() if time_elapsed > self.duration_sec: self.stop() return None time_left = self.duration_sec - time_elapsed if self.interval_sec > 0.0: if time_left <= self.interval_sec: time.sleep(time_left) self.stop() else: time.sleep(self.interval_sec) else: time.sleep(self.duration_sec) self.stop() return self.client.get_stats() class IpBlock(object): """Manage a block of IP addresses.""" def __init__(self, base_ip, step_ip, count_ip): """Create an IP block.""" self.base_ip_int = Device.ip_to_int(base_ip) if step_ip == 'random': step_ip = '0.0.0.1' self.step = Device.ip_to_int(step_ip) self.max_available = count_ip self.next_free = 0 def get_ip(self, index=0): """Return the IP address at given index.""" if index < 0 or index >= self.max_available: raise IndexError('Index out of bounds: %d (max=%d)' % (index, self.max_available)) return Device.int_to_ip(self.base_ip_int + index * self.step) def get_ip_from_chain_first_ip(self, first_ip, index=0): """Return the IP address at given index starting from chain first ip.""" if index < 0 or index >= self.max_available: raise IndexError('Index out of bounds: %d (max=%d)' % (index, self.max_available)) return Device.int_to_ip(first_ip + index * self.step) def reserve_ip_range(self, count): """Reserve a range of count consecutive IP addresses spaced by step. """ if self.next_free + count > self.max_available: raise IndexError('No more IP addresses next free=%d max_available=%d requested=%d' % (self.next_free, self.max_available, count)) first_ip = self.get_ip(self.next_free) last_ip = self.get_ip(self.next_free + count - 1) self.next_free += count return (first_ip, last_ip) def reset_reservation(self): """Reset all reservations and restart with a completely unused IP block.""" self.next_free = 0 class UdpPorts(object): def __init__(self, src_min, src_max, dst_min, dst_max, udp_src_size, udp_dst_size, step): self.src_min = int(src_min) self.src_max = int(src_max) self.dst_min = int(dst_min) self.dst_max = int(dst_max) self.udp_src_size = udp_src_size self.udp_dst_size = udp_dst_size self.step = step def get_src_max(self, index=0): """Return the UDP src port at given index.""" return int(self.src_min) + index * int(self.step) def get_dst_max(self, index=0): """Return the UDP dst port at given index.""" return int(self.dst_min) + index * int(self.step) class Device(object): """Represent a port device and all information associated to it. In the curent version we only support 2 port devices for the traffic generator identified as port 0 or port 1. """ def __init__(self, port, generator_config): """Create a new device for a given port.""" self.generator_config = generator_config self.chain_count = generator_config.service_chain_count if generator_config.bidirectional: self.flow_count = generator_config.flow_count / 2 else: self.flow_count = generator_config.flow_count self.port = port self.switch_port = generator_config.interfaces[port].get('switch_port', None) self.vtep_vlan = None self.vtep_src_mac = None self.vxlan = False self.mpls = False self.inner_labels = None self.outer_labels = None self.pci = generator_config.interfaces[port].pci self.mac = None self.dest_macs = None self.vtep_dst_mac = None self.vtep_dst_ip = None if generator_config.vteps is None: self.vtep_src_ip = None else: self.vtep_src_ip = generator_config.vteps[port] self.vnis = None self.vlans = None self.ip_addrs = generator_config.ip_addrs[port] self.ip_src_static = generator_config.ip_src_static self.ip_addrs_step = generator_config.ip_addrs_step if self.ip_addrs_step == 'random': # Set step to 1 to calculate the IP range size (see check_range_size below) step = '0.0.0.1' else: step = self.ip_addrs_step self.ip_size = self.check_range_size(IPNetwork(self.ip_addrs).size, Device.ip_to_int(step)) self.ip = str(IPNetwork(self.ip_addrs).network) ip_addrs_left = generator_config.ip_addrs[0] ip_addrs_right = generator_config.ip_addrs[1] self.ip_addrs_size = { 'left': self.check_range_size(IPNetwork(ip_addrs_left).size, Device.ip_to_int(step)), 'right': self.check_range_size(IPNetwork(ip_addrs_right).size, Device.ip_to_int(step))} udp_src_port = generator_config.gen_config.udp_src_port if udp_src_port is None: udp_src_port = 53 udp_dst_port = generator_config.gen_config.udp_dst_port if udp_dst_port is None: udp_dst_port = 53 src_max, src_min = self.define_udp_range(udp_src_port, 'udp_src_port') dst_max, dst_min = self.define_udp_range(udp_dst_port, 'udp_dst_port') if generator_config.gen_config.udp_port_step == 'random': # Set step to 1 to calculate the UDP range size udp_step = 1 else: udp_step = int(generator_config.gen_config.udp_port_step) udp_src_size = self.check_range_size(int(src_max) - int(src_min) + 1, udp_step) udp_dst_size = self.check_range_size(int(dst_max) - int(dst_min) + 1, udp_step) lcm_port = lcm(udp_src_size, udp_dst_size) if self.ip_src_static is True: lcm_ip = lcm(1, min(self.ip_addrs_size['left'], self.ip_addrs_size['right'])) else: lcm_ip = lcm(self.ip_addrs_size['left'], self.ip_addrs_size['right']) flow_max = lcm(lcm_port, lcm_ip) if self.flow_count > flow_max: raise TrafficClientException('Trying to set unachievable traffic (%d > %d)' % (self.flow_count, flow_max)) self.udp_ports = UdpPorts(src_min, src_max, dst_min, dst_max, udp_src_size, udp_dst_size, generator_config.gen_config.udp_port_step) self.ip_block = IpBlock(self.ip, step, self.ip_size) self.gw_ip_block = IpBlock(generator_config.gateway_ips[port], generator_config.gateway_ip_addrs_step, self.chain_count) self.tg_gateway_ip_addrs = generator_config.tg_gateway_ip_addrs[port] self.tg_gw_ip_block = IpBlock(self.tg_gateway_ip_addrs, generator_config.tg_gateway_ip_addrs_step, self.chain_count) def limit_ip_udp_ranges(self, peer_ip_size, cur_chain_flow_count): # init to min value in case of no matching values found with lcm calculation new_src_ip_size = 1 new_peer_ip_size = 1 new_src_udp_size = 1 new_dst_udp_size = 1 if self.ip_src_static is True: src_ip_size = 1 else: src_ip_size = self.ip_size ip_src_divisors = list(get_divisors(src_ip_size)) ip_dst_divisors = list(get_divisors(peer_ip_size)) udp_src_divisors = list(get_divisors(self.udp_ports.udp_src_size)) udp_dst_divisors = list(get_divisors(self.udp_ports.udp_dst_size)) fc = int(cur_chain_flow_count) tuples_ip = list(find_tuples_equal_to_lcm_value(ip_src_divisors, ip_dst_divisors, fc)) tuples_udp = list(find_tuples_equal_to_lcm_value(udp_src_divisors, udp_dst_divisors, fc)) if tuples_ip: new_src_ip_size = tuples_ip[-1][0] new_peer_ip_size = tuples_ip[-1][1] if tuples_udp: new_src_udp_size = tuples_udp[-1][0] new_dst_udp_size = tuples_udp[-1][1] tuples_src = [] tuples_dst = [] if not tuples_ip and not tuples_udp: # in case of not divisors in common matching LCM value (i.e. requested flow count) # try to find an accurate UDP range to fit requested flow count udp_src_int = range(self.udp_ports.src_min, self.udp_ports.src_max) udp_dst_int = range(self.udp_ports.dst_min, self.udp_ports.dst_max) tuples_src = list(find_tuples_equal_to_lcm_value(ip_src_divisors, udp_src_int, fc)) tuples_dst = list(find_tuples_equal_to_lcm_value(ip_dst_divisors, udp_dst_int, fc)) if not tuples_src and not tuples_dst: # iterate IP and UDP ranges to find a tuple that match flow count values src_ip_range = range(1,src_ip_size) dst_ip_range = range(1, peer_ip_size) tuples_src = list(find_tuples_equal_to_lcm_value(src_ip_range, udp_src_int, fc)) tuples_dst = list(find_tuples_equal_to_lcm_value(dst_ip_range, udp_dst_int, fc)) if tuples_src or tuples_dst: if tuples_src: new_src_ip_size = tuples_src[-1][0] new_src_udp_size = tuples_src[-1][1] if tuples_dst: new_peer_ip_size = tuples_dst[-1][0] new_dst_udp_size = tuples_dst[-1][1] else: if not tuples_ip: if src_ip_size != 1: if src_ip_size > fc: new_src_ip_size = fc else: new_src_ip_size = find_max_size(src_ip_size, tuples_udp, fc) if peer_ip_size != 1: if peer_ip_size > fc: new_peer_ip_size = fc else: new_peer_ip_size = find_max_size(peer_ip_size, tuples_udp, fc) if not tuples_udp: if self.udp_ports.udp_src_size != 1: if self.udp_ports.udp_src_size > fc: new_src_udp_size = fc else: new_src_udp_size = find_max_size(self.udp_ports.udp_src_size, tuples_ip, fc) if self.udp_ports.udp_dst_size != 1: if self.udp_ports.udp_dst_size > fc: new_dst_udp_size = fc else: new_dst_udp_size = find_max_size(self.udp_ports.udp_dst_size, tuples_ip, fc) max_possible_flows = lcm(lcm(new_src_ip_size, new_peer_ip_size), lcm(new_src_udp_size, new_dst_udp_size)) LOG.debug("IP dst size: %d", new_peer_ip_size) LOG.debug("LCM IP: %d", lcm(new_src_ip_size, new_peer_ip_size)) LOG.debug("LCM UDP: %d", lcm(new_src_udp_size, new_dst_udp_size)) LOG.debug("Global LCM: %d", max_possible_flows) LOG.debug("IP src size: %d, IP dst size: %d, UDP src size: %d, UDP dst size: %d", new_src_ip_size, new_peer_ip_size, self.udp_ports.udp_src_size, self.udp_ports.udp_dst_size) if not max_possible_flows == cur_chain_flow_count: if (self.ip_addrs_step != '0.0.0.1' or self.udp_ports.step != '1') and not ( self.ip_addrs_step == 'random' and self.udp_ports.step == 'random'): LOG.warning("Current values of ip_addrs_step and/or udp_port_step properties " "do not allow to control an accurate flow count. " "Values will be overridden as follows:") if self.ip_addrs_step != '0.0.0.1': LOG.info("ip_addrs_step='0.0.0.1' (previous value: ip_addrs_step='%s')", self.ip_addrs_step) self.ip_addrs_step = '0.0.0.1' if self.udp_ports.step != '1': LOG.info("udp_port_step='1' (previous value: udp_port_step='%s')", self.udp_ports.step) self.udp_ports.step = '1' # override config for not logging random step warning message in trex_gen.py self.generator_config.gen_config.udp_port_step = self.udp_ports.step else: LOG.error("Current values of ip_addrs_step and udp_port_step properties " "do not allow to control an accurate flow count.") else: src_ip_size = new_src_ip_size peer_ip_size = new_peer_ip_size self.udp_ports.udp_src_size = new_src_udp_size self.udp_ports.udp_dst_size = new_dst_udp_size return src_ip_size, peer_ip_size @staticmethod def define_udp_range(udp_port, property_name): if isinstance(udp_port, int): min = udp_port max = min elif isinstance(udp_port, tuple): min = udp_port[0] max = udp_port[1] else: raise TrafficClientException('Invalid %s property value (53 or [\'53\',\'1024\'])' % property_name) return max, min @staticmethod def check_range_size(range_size, step): """Check and set the available IPs or UDP ports, considering the step.""" try: if range_size % step == 0: value = range_size // step else: value = range_size // step + 1 return value except ZeroDivisionError: raise ZeroDivisionError("step can't be zero !") from ZeroDivisionError def set_mac(self, mac): """Set the local MAC for this port device.""" if mac is None: raise TrafficClientException('Trying to set traffic generator MAC address as None') self.mac = mac def get_peer_device(self): """Get the peer device (device 0 -> device 1, or device 1 -> device 0).""" return self.generator_config.devices[1 - self.port] def set_vtep_dst_mac(self, dest_macs): """Set the list of dest MACs indexed by the chain id. This is only called in 2 cases: - VM macs discovered using openstack API - dest MACs provisioned in config file """ self.vtep_dst_mac = list(map(str, dest_macs)) def set_dest_macs(self, dest_macs): """Set the list of dest MACs indexed by the chain id. This is only called in 2 cases: - VM macs discovered using openstack API - dest MACs provisioned in config file """ self.dest_macs = list(map(str, dest_macs)) def get_dest_macs(self): """Get the list of dest macs for this device. If set_dest_macs was never called, assumes l2-loopback and return a list of peer mac (as many as chains but normally only 1 chain) """ if self.dest_macs: return self.dest_macs # assume this is l2-loopback return [self.get_peer_device().mac] * self.chain_count def set_vlans(self, vlans): """Set the list of vlans to use indexed by the chain id.""" self.vlans = vlans LOG.info("Port %d: VLANs %s", self.port, self.vlans) def set_vtep_vlan(self, vlan): """Set the vtep vlan to use indexed by specific port.""" self.vtep_vlan = vlan self.vxlan = True self.vlan_tagging = None LOG.info("Port %d: VTEP VLANs %s", self.port, self.vtep_vlan) def set_vxlan_endpoints(self, src_ip, dst_ip): self.vtep_dst_ip = dst_ip self.vtep_src_ip = src_ip LOG.info("Port %d: src_vtep %s, dst_vtep %s", self.port, self.vtep_src_ip, self.vtep_dst_ip) def set_mpls_peers(self, src_ip, dst_ip): self.mpls = True self.vtep_dst_ip = dst_ip self.vtep_src_ip = src_ip LOG.info("Port %d: src_mpls_vtep %s, mpls_peer_ip %s", self.port, self.vtep_src_ip, self.vtep_dst_ip) def set_vxlans(self, vnis): self.vnis = vnis LOG.info("Port %d: VNIs %s", self.port, self.vnis) def set_mpls_inner_labels(self, labels): self.inner_labels = labels LOG.info("Port %d: MPLS Inner Labels %s", self.port, self.inner_labels) def set_mpls_outer_labels(self, labels): self.outer_labels = labels LOG.info("Port %d: MPLS Outer Labels %s", self.port, self.outer_labels) def set_gw_ip(self, gateway_ip): self.gw_ip_block = IpBlock(gateway_ip, self.generator_config.gateway_ip_addrs_step, self.chain_count) def get_gw_ip(self, chain_index): """Retrieve the IP address assigned for the gateway of a given chain.""" return self.gw_ip_block.get_ip(chain_index) def get_stream_configs(self): """Get the stream config for a given chain on this device. Called by the traffic generator driver to program the traffic generator properly before generating traffic """ configs = [] # exact flow count for each chain is calculated as follows: # - all chains except the first will have the same flow count # calculated as (total_flows + chain_count - 1) / chain_count # - the first chain will have the remainder # example 11 flows and 3 chains => 3, 4, 4 flows_per_chain = int((self.flow_count + self.chain_count - 1) / self.chain_count) cur_chain_flow_count = int(self.flow_count - flows_per_chain * (self.chain_count - 1)) peer = self.get_peer_device() self.ip_block.reset_reservation() peer.ip_block.reset_reservation() dest_macs = self.get_dest_macs() # limit ranges of UDP ports and IP to avoid overflow of the number of flows peer_size = peer.ip_size // self.chain_count for chain_idx in range(self.chain_count): src_ip_size, peer_ip_size = self.limit_ip_udp_ranges(peer_size, cur_chain_flow_count) src_ip_first, src_ip_last = self.ip_block.reserve_ip_range \ (src_ip_size) dst_ip_first, dst_ip_last = peer.ip_block.reserve_ip_range \ (peer_ip_size) if self.ip_addrs_step != 'random': src_ip_last = self.ip_block.get_ip_from_chain_first_ip( Device.ip_to_int(src_ip_first), src_ip_size - 1) dst_ip_last = peer.ip_block.get_ip_from_chain_first_ip( Device.ip_to_int(dst_ip_first), peer_ip_size - 1) if self.udp_ports.step != 'random': self.udp_ports.src_max = self.udp_ports.get_src_max(self.udp_ports.udp_src_size - 1) self.udp_ports.dst_max = self.udp_ports.get_dst_max(self.udp_ports.udp_dst_size - 1) if self.ip_src_static: src_ip_last = src_ip_first LOG.info("Port %d, chain %d: IP src range [%s,%s]", self.port, chain_idx, src_ip_first, src_ip_last) LOG.info("Port %d, chain %d: IP dst range [%s,%s]", self.port, chain_idx, dst_ip_first, dst_ip_last) LOG.info("Port %d, chain %d: UDP src range [%s,%s]", self.port, chain_idx, self.udp_ports.src_min, self.udp_ports.src_max) LOG.info("Port %d, chain %d: UDP dst range [%s,%s]", self.port, chain_idx, self.udp_ports.dst_min, self.udp_ports.dst_max) configs.append({ 'count': cur_chain_flow_count, 'mac_src': self.mac, 'mac_dst': dest_macs[chain_idx], 'ip_src_addr': src_ip_first, 'ip_src_addr_max': src_ip_last, 'ip_src_count': src_ip_size, 'ip_dst_addr': dst_ip_first, 'ip_dst_addr_max': dst_ip_last, 'ip_dst_count': peer_ip_size, 'ip_addrs_step': self.ip_addrs_step, 'ip_src_static': self.ip_src_static, 'udp_src_port': self.udp_ports.src_min, 'udp_src_port_max': self.udp_ports.src_max, 'udp_src_count': self.udp_ports.udp_src_size, 'udp_dst_port': self.udp_ports.dst_min, 'udp_dst_port_max': self.udp_ports.dst_max, 'udp_dst_count': self.udp_ports.udp_dst_size, 'udp_port_step': self.udp_ports.step, 'mac_discovery_gw': self.get_gw_ip(chain_idx), 'ip_src_tg_gw': self.tg_gw_ip_block.get_ip(chain_idx), 'ip_dst_tg_gw': peer.tg_gw_ip_block.get_ip(chain_idx), 'vlan_tag': self.vlans[chain_idx] if self.vlans else None, 'vxlan': self.vxlan, 'vtep_vlan': self.vtep_vlan if self.vtep_vlan else None, 'vtep_src_mac': self.mac if (self.vxlan or self.mpls) else None, 'vtep_dst_mac': self.vtep_dst_mac if (self.vxlan or self.mpls) else None, 'vtep_dst_ip': self.vtep_dst_ip if self.vxlan is True else None, 'vtep_src_ip': self.vtep_src_ip if self.vxlan is True else None, 'net_vni': self.vnis[chain_idx] if self.vxlan is True else None, 'mpls': self.mpls, 'mpls_outer_label': self.outer_labels[chain_idx] if self.mpls is True else None, 'mpls_inner_label': self.inner_labels[chain_idx] if self.mpls is True else None }) # after first chain, fall back to the flow count for all other chains cur_chain_flow_count = flows_per_chain return configs @staticmethod def ip_to_int(addr): """Convert an IP address from string to numeric.""" return struct.unpack("!I", socket.inet_aton(addr))[0] @staticmethod def int_to_ip(nvalue): """Convert an IP address from numeric to string.""" return socket.inet_ntoa(struct.pack("!I", int(nvalue))) class GeneratorConfig(object): """Represents traffic configuration for currently running traffic profile.""" DEFAULT_IP_STEP = '0.0.0.1' DEFAULT_SRC_DST_IP_STEP = '0.0.0.1' def __init__(self, config): """Create a generator config.""" self.config = config # name of the generator profile (normally trex or dummy) # pick the default one if not specified explicitly from cli options if not config.generator_profile: config.generator_profile = config.traffic_generator.default_profile # pick up the profile dict based on the name gen_config = self.__match_generator_profile(config.traffic_generator, config.generator_profile) self.gen_config = gen_config # copy over fields from the dict self.tool = gen_config.tool self.ip = gen_config.ip # overrides on config.cores and config.mbuf_factor if config.cores: self.cores = config.cores else: self.cores = gen_config.get('cores', 1) # let's report the value actually used in the end config.cores_used = self.cores self.mbuf_factor = config.mbuf_factor self.mbuf_64 = config.mbuf_64 self.hdrh = not config.disable_hdrh if config.intf_speed: # interface speed is overriden from the command line self.intf_speed = config.intf_speed elif gen_config.intf_speed: # interface speed is overriden from the generator config self.intf_speed = gen_config.intf_speed else: self.intf_speed = "auto" if self.intf_speed == "auto" or self.intf_speed == "0": # interface speed is discovered/provided by the traffic generator self.intf_speed = 0 else: self.intf_speed = bitmath.parse_string(self.intf_speed.replace('ps', '')).bits self.name = gen_config.name self.zmq_pub_port = gen_config.get('zmq_pub_port', 4500) self.zmq_rpc_port = gen_config.get('zmq_rpc_port', 4501) self.limit_memory = gen_config.get('limit_memory', 1024) self.software_mode = gen_config.get('software_mode', False) self.interfaces = gen_config.interfaces if self.interfaces[0].port != 0 or self.interfaces[1].port != 1: raise TrafficClientException('Invalid port order/id in generator_profile.interfaces') self.service_chain = config.service_chain self.service_chain_count = config.service_chain_count self.flow_count = config.flow_count self.host_name = gen_config.host_name self.bidirectional = config.traffic.bidirectional self.tg_gateway_ip_addrs = gen_config.tg_gateway_ip_addrs self.ip_addrs = gen_config.ip_addrs self.ip_addrs_step = gen_config.ip_addrs_step or self.DEFAULT_SRC_DST_IP_STEP self.tg_gateway_ip_addrs_step = \ gen_config.tg_gateway_ip_addrs_step or self.DEFAULT_IP_STEP self.gateway_ip_addrs_step = gen_config.gateway_ip_addrs_step or self.DEFAULT_IP_STEP self.gateway_ips = gen_config.gateway_ip_addrs self.ip_src_static = gen_config.ip_src_static self.vteps = gen_config.get('vteps') self.devices = [Device(port, self) for port in [0, 1]] # This should normally always be [0, 1] self.ports = [device.port for device in self.devices] # check that pci is not empty if not gen_config.interfaces[0].get('pci', None) or \ not gen_config.interfaces[1].get('pci', None): raise TrafficClientException("configuration interfaces pci fields cannot be empty") self.pcis = [tgif['pci'] for tgif in gen_config.interfaces] self.vlan_tagging = config.vlan_tagging # needed for result/summarizer config['tg-name'] = gen_config.name config['tg-tool'] = self.tool def to_json(self): """Get json form to display the content into the overall result dict.""" return dict(self.gen_config) def set_dest_macs(self, port_index, dest_macs): """Set the list of dest MACs indexed by the chain id on given port. port_index: the port for which dest macs must be set dest_macs: a list of dest MACs indexed by chain id """ if len(dest_macs) < self.config.service_chain_count: raise TrafficClientException('Dest MAC list %s must have %d entries' % (dest_macs, self.config.service_chain_count)) # only pass the first scc dest MACs self.devices[port_index].set_dest_macs(dest_macs[:self.config.service_chain_count]) LOG.info('Port %d: dst MAC %s', port_index, [str(mac) for mac in dest_macs]) def set_vtep_dest_macs(self, port_index, dest_macs): """Set the list of dest MACs indexed by the chain id on given port. port_index: the port for which dest macs must be set dest_macs: a list of dest MACs indexed by chain id """ if len(dest_macs) != self.config.service_chain_count: raise TrafficClientException('Dest MAC list %s must have %d entries' % (dest_macs, self.config.service_chain_count)) self.devices[port_index].set_vtep_dst_mac(dest_macs) LOG.info('Port %d: vtep dst MAC %s', port_index, {str(mac) for mac in dest_macs}) def get_dest_macs(self): """Return the list of dest macs indexed by port.""" return [dev.get_dest_macs() for dev in self.devices] def set_vlans(self, port_index, vlans): """Set the list of vlans to use indexed by the chain id on given port. port_index: the port for which VLANs must be set vlans: a list of vlan lists indexed by chain id """ if len(vlans) != self.config.service_chain_count: raise TrafficClientException('VLAN list %s must have %d entries' % (vlans, self.config.service_chain_count)) self.devices[port_index].set_vlans(vlans) def set_vxlans(self, port_index, vxlans): """Set the list of vxlans (VNIs) to use indexed by the chain id on given port. port_index: the port for which VXLANs must be set VXLANs: a list of VNIs lists indexed by chain id """ if len(vxlans) != self.config.service_chain_count: raise TrafficClientException('VXLAN list %s must have %d entries' % (vxlans, self.config.service_chain_count)) self.devices[port_index].set_vxlans(vxlans) def set_mpls_inner_labels(self, port_index, labels): """Set the list of MPLS Labels to use indexed by the chain id on given port. port_index: the port for which Labels must be set Labels: a list of Labels lists indexed by chain id """ if len(labels) != self.config.service_chain_count: raise TrafficClientException('Inner MPLS list %s must have %d entries' % (labels, self.config.service_chain_count)) self.devices[port_index].set_mpls_inner_labels(labels) def set_mpls_outer_labels(self, port_index, labels): """Set the list of MPLS Labels to use indexed by the chain id on given port. port_index: the port for which Labels must be set Labels: a list of Labels lists indexed by chain id """ if len(labels) != self.config.service_chain_count: raise TrafficClientException('Outer MPLS list %s must have %d entries' % (labels, self.config.service_chain_count)) self.devices[port_index].set_mpls_outer_labels(labels) def set_vtep_vlan(self, port_index, vlan): """Set the vtep vlan to use indexed by the chain id on given port. port_index: the port for which VLAN must be set """ self.devices[port_index].set_vtep_vlan(vlan) def set_vxlan_endpoints(self, port_index, src_ip, dst_ip): self.devices[port_index].set_vxlan_endpoints(src_ip, dst_ip) def set_mpls_peers(self, port_index, src_ip, dst_ip): self.devices[port_index].set_mpls_peers(src_ip, dst_ip) @staticmethod def __match_generator_profile(traffic_generator, generator_profile): gen_config = AttrDict(traffic_generator) gen_config.pop('default_profile') gen_config.pop('generator_profile') matching_profile = [profile for profile in traffic_generator.generator_profile if profile.name == generator_profile] if len(matching_profile) != 1: raise Exception('Traffic generator profile not found: ' + generator_profile) gen_config.update(matching_profile[0]) return gen_config class TrafficClient(object): """Traffic generator client with NDR/PDR binary seearch.""" PORTS = [0, 1] def __init__(self, config, notifier=None): """Create a new TrafficClient instance. config: nfvbench config notifier: notifier (optional) A new instance is created everytime the nfvbench config may have changed. """ self.config = config self.generator_config = GeneratorConfig(config) self.tool = self.generator_config.tool self.gen = self._get_generator() self.notifier = notifier self.interval_collector = None self.iteration_collector = None self.runner = TrafficRunner(self, self.config.duration_sec, self.config.interval_sec, self.config.service_mode) self.config.frame_sizes = self._get_frame_sizes() self.run_config = { 'l2frame_size': None, 'duration_sec': self.config.duration_sec, 'bidirectional': True, 'rates': [] # to avoid unsbuscriptable-obj warning } self.current_total_rate = {'rate_percent': '10'} if self.config.single_run: self.current_total_rate = utils.parse_rate_str(self.config.rate) self.ifstats = None # Speed is either discovered when connecting to TG or set from config # This variable is 0 if not yet discovered from TG or must be the speed of # each interface in bits per second self.intf_speed = self.generator_config.intf_speed def _get_generator(self): tool = self.tool.lower() if tool == 'trex': from .traffic_gen import trex_gen return trex_gen.TRex(self) if tool == 'dummy': from .traffic_gen import dummy return dummy.DummyTG(self) raise TrafficClientException('Unsupported generator tool name:' + self.tool) def skip_sleep(self): """Skip all sleeps when doing unit testing with dummy TG. Must be overriden using mock.patch """ return False def _get_frame_sizes(self): traffic_profile_name = self.config.traffic.profile matching_profiles = [profile for profile in self.config.traffic_profile if profile.name == traffic_profile_name] if len(matching_profiles) > 1: raise TrafficClientException('Multiple traffic profiles with name: ' + traffic_profile_name) if not matching_profiles: raise TrafficClientException('Cannot find traffic profile: ' + traffic_profile_name) return matching_profiles[0].l2frame_size def start_traffic_generator(self): """Start the traffic generator process (traffic not started yet).""" self.gen.connect() # pick up the interface speed if it is not set from config intf_speeds = self.gen.get_port_speed_gbps() # convert Gbps unit into bps tg_if_speed = bitmath.parse_string(str(intf_speeds[0]) + 'Gb').bits if self.intf_speed: # interface speed is overriden from config if self.intf_speed != tg_if_speed: # Warn the user if the speed in the config is different LOG.warning( 'Interface speed provided (%g Gbps) is different from actual speed (%d Gbps)', self.intf_speed / 1000000000.0, intf_speeds[0]) else: # interface speed not provisioned by config self.intf_speed = tg_if_speed # also update the speed in the tg config self.generator_config.intf_speed = tg_if_speed # let's report detected and actually used interface speed self.config.intf_speed_detected = tg_if_speed self.config.intf_speed_used = self.intf_speed # Save the traffic generator local MAC for mac, device in zip(self.gen.get_macs(), self.generator_config.devices): device.set_mac(mac) def setup(self): """Set up the traffic client.""" self.gen.clear_stats() def get_version(self): """Get the traffic generator version.""" return self.gen.get_version() def ensure_end_to_end(self): """Ensure traffic generator receives packets it has transmitted. This ensures end to end connectivity and also waits until VMs are ready to forward packets. VMs that are started and in active state may not pass traffic yet. It is imperative to make sure that all VMs are passing traffic in both directions before starting any benchmarking. To verify this, we need to send at a low frequency bi-directional packets and make sure that we receive all packets back from all VMs. The number of flows is equal to 2 times the number of chains (1 per direction) and we need to make sure we receive packets coming from exactly 2 x chain count different source MAC addresses. Example: PVP chain (1 VM per chain) N = 10 (number of chains) Flow count = 20 (number of flows) If the number of unique source MAC addresses from received packets is 20 then all 10 VMs 10 VMs are in operational state. """ LOG.info('Starting traffic generator to ensure end-to-end connectivity') # send 2pps on each chain and each direction rate_pps = {'rate_pps': str(self.config.service_chain_count * 2)} self.gen.create_traffic('64', [rate_pps, rate_pps], bidirectional=True, latency=False, e2e=True) # ensures enough traffic is coming back retry_count = int((self.config.check_traffic_time_sec + self.config.generic_poll_sec - 1) / self.config.generic_poll_sec) # we expect to see packets coming from 2 unique MAC per chain # because there can be flooding in the case of shared net # we must verify that packets from the right VMs are received # and not just count unique src MAC # create a dict of (port, chain) tuples indexed by dest mac mac_map = {} for port, dest_macs in enumerate(self.generator_config.get_dest_macs()): for chain, mac in enumerate(dest_macs): mac_map[mac] = (port, chain) unique_src_mac_count = len(mac_map) if self.config.vxlan and self.config.traffic_generator.vtep_vlan: get_mac_id = lambda packet: packet['binary'][60:66] elif self.config.vxlan: get_mac_id = lambda packet: packet['binary'][56:62] elif self.config.mpls: get_mac_id = lambda packet: packet['binary'][24:30] # mpls_transport_label = lambda packet: packet['binary'][14:18] else: get_mac_id = lambda packet: packet['binary'][6:12] for it in range(retry_count): self.gen.clear_stats() self.gen.start_traffic() self.gen.start_capture() LOG.info('Captured unique src mac %d/%d, capturing return packets (retry %d/%d)...', unique_src_mac_count - len(mac_map), unique_src_mac_count, it + 1, retry_count) if not self.skip_sleep(): time.sleep(self.config.generic_poll_sec) self.gen.stop_traffic() self.gen.fetch_capture_packets() self.gen.stop_capture() for packet in self.gen.packet_list: mac_id = get_mac_id(packet).decode('latin-1') src_mac = ':'.join(["%02x" % ord(x) for x in mac_id]) if self.config.mpls: if src_mac in mac_map and self.is_mpls(packet): port, chain = mac_map[src_mac] LOG.info('Received mpls packet from mac: %s (chain=%d, port=%d)', src_mac, chain, port) mac_map.pop(src_mac, None) else: if src_mac in mac_map and self.is_udp(packet): port, chain = mac_map[src_mac] LOG.info('Received udp packet from mac: %s (chain=%d, port=%d)', src_mac, chain, port) mac_map.pop(src_mac, None) if not mac_map: LOG.info('End-to-end connectivity established') return if self.config.l3_router and not self.config.no_arp: # In case of L3 traffic mode, routers are not able to route traffic # until VM interfaces are up and ARP requests are done LOG.info('Waiting for loopback service completely started...') LOG.info('Sending ARP request to assure end-to-end connectivity established') self.ensure_arp_successful() raise TrafficClientException('End-to-end connectivity cannot be ensured') def is_udp(self, packet): pkt = Ether(packet['binary']) return UDP in pkt def is_mpls(self, packet): pkt = Ether(packet['binary']) return MPLS in pkt def ensure_arp_successful(self): """Resolve all IP using ARP and throw an exception in case of failure.""" dest_macs = self.gen.resolve_arp() if dest_macs: # all dest macs are discovered, saved them into the generator config if self.config.vxlan or self.config.mpls: self.generator_config.set_vtep_dest_macs(0, dest_macs[0]) self.generator_config.set_vtep_dest_macs(1, dest_macs[1]) else: self.generator_config.set_dest_macs(0, dest_macs[0]) self.generator_config.set_dest_macs(1, dest_macs[1]) else: raise TrafficClientException('ARP cannot be resolved') def set_traffic(self, frame_size, bidirectional): """Reconfigure the traffic generator for a new frame size.""" self.run_config['bidirectional'] = bidirectional self.run_config['l2frame_size'] = frame_size self.run_config['rates'] = [self.get_per_direction_rate()] if bidirectional: self.run_config['rates'].append(self.get_per_direction_rate()) else: unidir_reverse_pps = int(self.config.unidir_reverse_traffic_pps) if unidir_reverse_pps > 0: self.run_config['rates'].append({'rate_pps': str(unidir_reverse_pps)}) # Fix for [NFVBENCH-67], convert the rate string to PPS for idx, rate in enumerate(self.run_config['rates']): if 'rate_pps' not in rate: self.run_config['rates'][idx] = {'rate_pps': self.__convert_rates(rate)['rate_pps']} self.gen.clear_streamblock() if self.config.no_latency_streams: LOG.info("Latency streams are disabled") # in service mode, we must disable flow stats (e2e=True) self.gen.create_traffic(frame_size, self.run_config['rates'], bidirectional, latency=not self.config.no_latency_streams, e2e=self.runner.service_mode) def _modify_load(self, load): self.current_total_rate = {'rate_percent': str(load)} rate_per_direction = self.get_per_direction_rate() self.gen.modify_rate(rate_per_direction, False) self.run_config['rates'][0] = rate_per_direction if self.run_config['bidirectional']: self.gen.modify_rate(rate_per_direction, True) self.run_config['rates'][1] = rate_per_direction def get_ndr_and_pdr(self): """Start the NDR/PDR iteration and return the results.""" dst = 'Bidirectional' if self.run_config['bidirectional'] else 'Unidirectional' targets = {} if self.config.ndr_run: LOG.info('*** Searching NDR for %s (%s)...', self.run_config['l2frame_size'], dst) targets['ndr'] = self.config.measurement.NDR if self.config.pdr_run: LOG.info('*** Searching PDR for %s (%s)...', self.run_config['l2frame_size'], dst) targets['pdr'] = self.config.measurement.PDR self.run_config['start_time'] = time.time() self.interval_collector = IntervalCollector(self.run_config['start_time']) self.interval_collector.attach_notifier(self.notifier) self.iteration_collector = IterationCollector(self.run_config['start_time']) results = {} self.__range_search(0.0, 200.0, targets, results) results['iteration_stats'] = { 'ndr_pdr': self.iteration_collector.get() } if self.config.ndr_run: LOG.info('NDR load: %s', results['ndr']['rate_percent']) results['ndr']['time_taken_sec'] = \ results['ndr']['timestamp_sec'] - self.run_config['start_time'] if self.config.pdr_run: LOG.info('PDR load: %s', results['pdr']['rate_percent']) results['pdr']['time_taken_sec'] = \ results['pdr']['timestamp_sec'] - results['ndr']['timestamp_sec'] else: LOG.info('PDR load: %s', results['pdr']['rate_percent']) results['pdr']['time_taken_sec'] = \ results['pdr']['timestamp_sec'] - self.run_config['start_time'] return results def __get_dropped_rate(self, result): dropped_pkts = result['rx']['dropped_pkts'] total_pkts = result['tx']['total_pkts'] if not total_pkts: return float('inf') return float(dropped_pkts) / total_pkts * 100 def get_stats(self): """Collect final stats for previous run.""" stats = self.gen.get_stats(self.ifstats) retDict = {'total_tx_rate': stats['total_tx_rate'], 'offered_tx_rate_bps': stats['offered_tx_rate_bps'], 'theoretical_tx_rate_bps': stats['theoretical_tx_rate_bps'], 'theoretical_tx_rate_pps': stats['theoretical_tx_rate_pps']} tx_keys = ['total_pkts', 'total_pkt_bytes', 'pkt_rate', 'pkt_bit_rate'] rx_keys = tx_keys + ['dropped_pkts'] for port in self.PORTS: port_stats = {'tx': {}, 'rx': {}} for key in tx_keys: port_stats['tx'][key] = int(stats[port]['tx'][key]) for key in rx_keys: try: port_stats['rx'][key] = int(stats[port]['rx'][key]) except ValueError: port_stats['rx'][key] = 0 port_stats['rx']['avg_delay_usec'] = cast_integer( stats[port]['rx']['avg_delay_usec']) port_stats['rx']['min_delay_usec'] = cast_integer( stats[port]['rx']['min_delay_usec']) port_stats['rx']['max_delay_usec'] = cast_integer( stats[port]['rx']['max_delay_usec']) port_stats['drop_rate_percent'] = self.__get_dropped_rate(port_stats) retDict[str(port)] = port_stats ports = sorted(list(retDict.keys()), key=str) if self.run_config['bidirectional']: retDict['overall'] = {'tx': {}, 'rx': {}} for key in tx_keys: retDict['overall']['tx'][key] = \ retDict[ports[0]]['tx'][key] + retDict[ports[1]]['tx'][key] for key in rx_keys: retDict['overall']['rx'][key] = \ retDict[ports[0]]['rx'][key] + retDict[ports[1]]['rx'][key] total_pkts = [retDict[ports[0]]['rx']['total_pkts'], retDict[ports[1]]['rx']['total_pkts']] avg_delays = [retDict[ports[0]]['rx']['avg_delay_usec'], retDict[ports[1]]['rx']['avg_delay_usec']] max_delays = [retDict[ports[0]]['rx']['max_delay_usec'], retDict[ports[1]]['rx']['max_delay_usec']] min_delays = [retDict[ports[0]]['rx']['min_delay_usec'], retDict[ports[1]]['rx']['min_delay_usec']] retDict['overall']['rx']['avg_delay_usec'] = utils.weighted_avg(total_pkts, avg_delays) retDict['overall']['rx']['min_delay_usec'] = min(min_delays) retDict['overall']['rx']['max_delay_usec'] = max(max_delays) for key in ['pkt_bit_rate', 'pkt_rate']: for dirc in ['tx', 'rx']: retDict['overall'][dirc][key] /= 2.0 else: retDict['overall'] = retDict[ports[0]] retDict['overall']['drop_rate_percent'] = self.__get_dropped_rate(retDict['overall']) if 'overall_hdrh' in stats: retDict['overall']['hdrh'] = stats.get('overall_hdrh', None) decoded_histogram = HdrHistogram.decode(retDict['overall']['hdrh']) retDict['overall']['rx']['lat_percentile'] = {} # override min max and avg from hdrh (only if histogram is valid) if decoded_histogram.get_total_count() != 0: retDict['overall']['rx']['min_delay_usec'] = decoded_histogram.get_min_value() retDict['overall']['rx']['max_delay_usec'] = decoded_histogram.get_max_value() retDict['overall']['rx']['avg_delay_usec'] = decoded_histogram.get_mean_value() for percentile in self.config.lat_percentiles: retDict['overall']['rx']['lat_percentile'][percentile] = \ decoded_histogram.get_value_at_percentile(percentile) else: for percentile in self.config.lat_percentiles: retDict['overall']['rx']['lat_percentile'][percentile] = 'n/a' return retDict def __convert_rates(self, rate): return utils.convert_rates(self.run_config['l2frame_size'], rate, self.intf_speed) def __ndr_pdr_found(self, tag, load): rates = self.__convert_rates({'rate_percent': load}) self.iteration_collector.add_ndr_pdr(tag, rates['rate_pps']) last_stats = self.iteration_collector.peek() self.interval_collector.add_ndr_pdr(tag, last_stats) def __format_output_stats(self, stats): for key in self.PORTS + ['overall']: key = str(key) interface = stats[key] stats[key] = { 'tx_pkts': interface['tx']['total_pkts'], 'rx_pkts': interface['rx']['total_pkts'], 'drop_percentage': interface['drop_rate_percent'], 'drop_pct': interface['rx']['dropped_pkts'], 'avg_delay_usec': interface['rx']['avg_delay_usec'], 'max_delay_usec': interface['rx']['max_delay_usec'], 'min_delay_usec': interface['rx']['min_delay_usec'], } if key == 'overall': if 'hdrh' in interface: stats[key]['hdrh'] = interface.get('hdrh', None) decoded_histogram = HdrHistogram.decode(stats[key]['hdrh']) stats[key]['lat_percentile'] = {} # override min max and avg from hdrh (only if histogram is valid) if decoded_histogram.get_total_count() != 0: stats[key]['min_delay_usec'] = decoded_histogram.get_min_value() stats[key]['max_delay_usec'] = decoded_histogram.get_max_value() stats[key]['avg_delay_usec'] = decoded_histogram.get_mean_value() for percentile in self.config.lat_percentiles: stats[key]['lat_percentile'][percentile] = decoded_histogram.\ get_value_at_percentile(percentile) else: for percentile in self.config.lat_percentiles: stats[key]['lat_percentile'][percentile] = 'n/a' return stats def __targets_found(self, rate, targets, results): for tag, target in list(targets.items()): LOG.info('Found %s (%s) load: %s', tag, target, rate) self.__ndr_pdr_found(tag, rate) results[tag]['timestamp_sec'] = time.time() def __range_search(self, left, right, targets, results): """Perform a binary search for a list of targets inside a [left..right] range or rate. left the left side of the range to search as a % the line rate (100 = 100% line rate) indicating the rate to send on each interface right the right side of the range to search as a % of line rate indicating the rate to send on each interface targets a dict of drop rates to search (0.1 = 0.1%), indexed by the DR name or "tag" ('ndr', 'pdr') results a dict to store results """ if not targets: return LOG.info('Range search [%s .. %s] targets: %s', left, right, targets) # Terminate search when gap is less than load epsilon if right - left < self.config.measurement.load_epsilon: self.__targets_found(left, targets, results) return # Obtain the average drop rate in for middle load middle = (left + right) / 2.0 try: stats, rates = self.__run_search_iteration(middle) except STLError: LOG.exception("Got exception from traffic generator during binary search") self.__targets_found(left, targets, results) return # Split target dicts based on the avg drop rate left_targets = {} right_targets = {} for tag, target in list(targets.items()): if stats['overall']['drop_rate_percent'] <= target: # record the best possible rate found for this target results[tag] = rates results[tag].update({ 'load_percent_per_direction': middle, 'stats': self.__format_output_stats(dict(stats)), 'timestamp_sec': None }) right_targets[tag] = target else: # initialize to 0 all fields of result for # the worst case scenario of the binary search (if ndr/pdr is not found) if tag not in results: results[tag] = dict.fromkeys(rates, 0) empty_stats = self.__format_output_stats(dict(stats)) for key in empty_stats: if isinstance(empty_stats[key], dict): empty_stats[key] = dict.fromkeys(empty_stats[key], 0) else: empty_stats[key] = 0 results[tag].update({ 'load_percent_per_direction': 0, 'stats': empty_stats, 'timestamp_sec': None }) left_targets[tag] = target # search lower half self.__range_search(left, middle, left_targets, results) # search upper half only if the upper rate does not exceed # 100%, this only happens when the first search at 100% # yields a DR that is < target DR if middle >= 100: self.__targets_found(100, right_targets, results) else: self.__range_search(middle, right, right_targets, results) def __run_search_iteration(self, rate): """Run one iteration at the given rate level. rate: the rate to send on each port in percent (0 to 100) """ self._modify_load(rate) # There used to be a inconsistency in case of interface speed override. # The emulated 'intf_speed' value is unknown to the T-Rex generator which # refers to the detected line rate for converting relative traffic loads. # Therefore, we need to convert actual rates here, in terms of packets/s. for idx, str_rate in enumerate(self.gen.rates): if str_rate.endswith('%'): float_rate = float(str_rate.replace('%', '').strip()) pps_rate = self.__convert_rates({'rate_percent': float_rate})['rate_pps'] self.gen.rates[idx] = str(pps_rate) + 'pps' # poll interval stats and collect them for stats in self.run_traffic(): self.interval_collector.add(stats) time_elapsed_ratio = self.runner.time_elapsed() / self.run_config['duration_sec'] if time_elapsed_ratio >= 1: self.cancel_traffic() if not self.skip_sleep(): time.sleep(self.config.pause_sec) self.interval_collector.reset() # get stats from the run stats = self.runner.client.get_stats() current_traffic_config = self._get_traffic_config() warning = self.compare_tx_rates(current_traffic_config['direction-total']['rate_pps'], stats['total_tx_rate']) if warning is not None: stats['warning'] = warning # save reliable stats from whole iteration self.iteration_collector.add(stats, current_traffic_config['direction-total']['rate_pps']) LOG.info('Average drop rate: %f', stats['overall']['drop_rate_percent']) return stats, current_traffic_config['direction-total'] def log_stats(self, stats): """Log estimated stats during run.""" # Calculate a rolling drop rate based on differential to # the previous reading cur_tx = stats['overall']['tx']['total_pkts'] cur_rx = stats['overall']['rx']['total_pkts'] delta_tx = cur_tx - self.prev_tx delta_rx = cur_rx - self.prev_rx drops = delta_tx - delta_rx if delta_tx == 0: LOG.info("\x1b[1mConfiguration issue!\x1b[0m (no transmission)") sys.exit(0) drop_rate_pct = 100 * (delta_tx - delta_rx)/delta_tx self.prev_tx = cur_tx self.prev_rx = cur_rx LOG.info('TX: %15s; RX: %15s; (Est.) Dropped: %12s; Drop rate: %8.4f%%', format(cur_tx, ',d'), format(cur_rx, ',d'), format(drops, ',d'), drop_rate_pct) def run_traffic(self): """Start traffic and return intermediate stats for each interval.""" stats = self.runner.run() self.prev_tx = 0 self.prev_rx = 0 while self.runner.is_running: self.log_stats(stats) yield stats stats = self.runner.poll_stats() if stats is None: return self.log_stats(stats) LOG.info('Drop rate: %f', stats['overall']['drop_rate_percent']) yield stats def cancel_traffic(self): """Stop traffic.""" self.runner.stop() def _get_traffic_config(self): config = {} load_total = 0.0 bps_total = 0.0 pps_total = 0.0 for idx, rate in enumerate(self.run_config['rates']): key = 'direction-forward' if idx == 0 else 'direction-reverse' config[key] = { 'l2frame_size': self.run_config['l2frame_size'], 'duration_sec': self.run_config['duration_sec'] } config[key].update(rate) config[key].update(self.__convert_rates(rate)) load_total += float(config[key]['rate_percent']) bps_total += float(config[key]['rate_bps']) pps_total += float(config[key]['rate_pps']) config['direction-total'] = dict(config['direction-forward']) config['direction-total'].update({ 'rate_percent': load_total, 'rate_pps': cast_integer(pps_total), 'rate_bps': bps_total }) return config def get_run_config(self, results): """Return configuration which was used for the last run.""" r = {} # because we want each direction to have the far end RX rates, # use the far end index (1-idx) to retrieve the RX rates for idx, key in enumerate(["direction-forward", "direction-reverse"]): tx_rate = results["stats"][str(idx)]["tx"]["total_pkts"] / self.config.duration_sec rx_rate = results["stats"][str(1 - idx)]["rx"]["total_pkts"] / self.config.duration_sec r[key] = { "orig": self.__convert_rates(self.run_config['rates'][idx]), "tx": self.__convert_rates({'rate_pps': tx_rate}), "rx": self.__convert_rates({'rate_pps': rx_rate}) } total = {} for direction in ['orig', 'tx', 'rx']: total[direction] = {} for unit in ['rate_percent', 'rate_bps', 'rate_pps']: total[direction][unit] = sum([float(x[direction][unit]) for x in list(r.values())]) r['direction-total'] = total return r def insert_interface_stats(self, pps_list): """Insert interface stats to a list of packet path stats. pps_list: a list of packet path stats instances indexed by chain index This function will insert the packet path stats for the traffic gen ports 0 and 1 with itemized per chain tx/rx counters. There will be as many packet path stats as chains. Each packet path stats will have exactly 2 InterfaceStats for port 0 and port 1 self.pps_list: [ PacketPathStats(InterfaceStats(chain 0, port 0), InterfaceStats(chain 0, port 1)), PacketPathStats(InterfaceStats(chain 1, port 0), InterfaceStats(chain 1, port 1)), ... ] """ def get_if_stats(chain_idx): return [InterfaceStats('p' + str(port), self.tool) for port in range(2)] # keep the list of list of interface stats indexed by the chain id self.ifstats = [get_if_stats(chain_idx) for chain_idx in range(self.config.service_chain_count)] # note that we need to make a copy of the ifs list so that any modification in the # list from pps will not change the list saved in self.ifstats self.pps_list = [PacketPathStats(self.config, list(ifs)) for ifs in self.ifstats] # insert the corresponding pps in the passed list pps_list.extend(self.pps_list) def update_interface_stats(self, diff=False): """Update all interface stats. diff: if False, simply refresh the interface stats values with latest values if True, diff the interface stats with the latest values Make sure that the interface stats inserted in insert_interface_stats() are updated with proper values. self.ifstats: [ [InterfaceStats(chain 0, port 0), InterfaceStats(chain 0, port 1)], [InterfaceStats(chain 1, port 0), InterfaceStats(chain 1, port 1)], ... ] """ if diff: stats = self.gen.get_stats(self.ifstats) for chain_idx, ifs in enumerate(self.ifstats): # each ifs has exactly 2 InterfaceStats and 2 Latency instances # corresponding to the # port 0 and port 1 for the given chain_idx # Note that we cannot use self.pps_list[chain_idx].if_stats to pick the # interface stats for the pps because it could have been modified to contain # additional interface stats self.gen.get_stream_stats(stats, ifs, self.pps_list[chain_idx].latencies, chain_idx) # special handling for vxlan # in case of vxlan, flow stats are not available so all rx counters will be # zeros when the total rx port counter is non zero. # in that case, for port in range(2): total_rx = 0 for ifs in self.ifstats: total_rx += ifs[port].rx if total_rx == 0: # check if the total port rx from Trex is also zero port_rx = stats[port]['rx']['total_pkts'] if port_rx: # the total rx for all chains from port level stats is non zero # which means that the per-chain stats are not available if len(self.ifstats) == 1: # only one chain, simply report the port level rx to the chain rx stats self.ifstats[0][port].rx = port_rx else: for ifs in self.ifstats: # mark this data as unavailable ifs[port].rx = None # pitch in the total rx only in the last chain pps self.ifstats[-1][port].rx_total = port_rx @staticmethod def compare_tx_rates(required, actual): """Compare the actual TX rate to the required TX rate.""" threshold = 0.9 are_different = False try: if float(actual) / required < threshold: are_different = True except ZeroDivisionError: are_different = True if are_different: msg = "WARNING: There is a significant difference between requested TX rate ({r}) " \ "and actual TX rate ({a}). The traffic generator may not have sufficient CPU " \ "to achieve the requested TX rate.".format(r=required, a=actual) LOG.info(msg) return msg return None def get_per_direction_rate(self): """Get the rate for each direction.""" divisor = 2 if self.run_config['bidirectional'] else 1 if 'rate_percent' in self.current_total_rate: # don't split rate if it's percentage divisor = 1 return utils.divide_rate(self.current_total_rate, divisor) def close(self): """Close this instance.""" try: self.gen.stop_traffic() except Exception: pass self.gen.clear_stats() self.gen.cleanup()