NFVBENCH-172: Add quartiles and 99 percentile latency values

[nfvbench.git] / nfvbench / cfg.default.yaml

#
# NFVbench default configuration file
#
# This configuration file is ALWAYS loaded by NFVbench and should never be modified by users.
# To specify your own property values, always define them in a separate config file
# and pass that file to the script using -c or --config <file>
# Property values in that config file will override the default values in the current file
#
---
# IMPORTANT CUSTOMIZATION NOTES
# There are roughly 2 types of NFVbench config based on the OpenStack encaps used:
# - VLAN (OVS, OVS-DPDK, ML2/VPP)
# Many of the fields to customize are relevant to only 1 of the 2 encaps
# These will be clearly labeled "VxLAN only" or "VLAN only"
# Fields that are not applicable will not be used by NFVbench and can be left empty
#
# All fields are applicable to all encaps/traffic generators unless explicitly marked otherwise.
# Fields that can be over-ridden at the command line are marked with the corresponding
# option, e.g. "--interval"


# The OpenStack openrc file to use - must be a valid full pathname. If running
# in a container, this path must be valid in the container.
#
# The only case where this field can be empty is when measuring a system that does not run
# OpenStack or when OpenStack APIs are not accessible or OpenStack APis use is not
# desirable. In that case the EXT service chain must be used.
#
# If openrc is not admin some parameters are mandatory and must be filled with valid values in config file such as :
# - availability_zone
# - hypervisor_hostname
# - vlans
openrc_file:

# Forwarder to use in nfvbenchvm image. Available options: ['vpp', 'testpmd']
vm_forwarder: testpmd

# By default (empty) NFVbench will try to locate a VM image file
# from the package root directory named "nfvbench-<version>.qcow2" and
# upload that file. The image name will be "nfvbench-<version>"
# This can be overridden by specifying here a pathname of a file
# that follows the same naming convention.
# In most cases, this field should be left empty as the packaging should
# include the proper VM image file
vm_image_file:

# Name of the flavor to use for the loopback VMs
#
# If the provided name is an exact match to a flavor name known by OpenStack
# (as shown from 'nova flavor-list'), that flavor will be reused.
# Otherwise, a new flavor will be created with attributes listed below.
flavor_type: 'nfvbench.medium'

# Custom flavor attributes for the test VM
flavor:
  # Number of vCPUs for the flavor, must be at least 2!
  vcpus: 2
  # Memory for the flavor in MB
  ram: 4096
  # Size of local disk in GB
  disk: 0
  # metadata are supported and can be added if needed, optional
  # note that if your openstack does not have NUMA optimization
  # (cpu pinning and huge pages)
  # you must comment out extra_specs completely otherwise
  # loopback VM creation will fail
  extra_specs:
      "hw:cpu_policy": dedicated
      "hw:mem_page_size": large

# Enable multiqueue for all test VM interfaces (PVP and PVVP only).
# When enabled, the test VM image will get added the property to enable
# multiqueue (hw_vif_multiqueue_enabled='true').
# The number of queues per interace will be set to the number of vCPUs configured for
# the VM.
# By default there is only 1 queue per interface
# The max allowed queue per interface is 8.
# The valid range for this parameter is [1..min(8, vcpu_count)]
# When multiqueue is used the recommended setting is to set it to same value as the
# number of vCPU used - up to a max of 8 queues.
# Setting to a lower value than vCPU should also work. For example if using 4 vCPU and
# vif_multiqueue_size is set to 2, openstack will create 4 queues per interface but the
# test VM will only use the first 2 queues.
vif_multiqueue_size: 1

# Increase number of buffers allocated for VPP VM forwarder. May be needed in scenarios with large
# number of interfaces and worker threads, or a lot of physical interfaces with multiple RSS queues.
# Value is per CPU socket. Default is 16384.
num_mbufs: 16384

# Name of the availability zone to use for the test VMs
# Must be one of the zones listed by 'nova availability-zone-list'
# availability_zone: 'nova'
# If openrc is not admin set a valid value
availability_zone:
# To force placement on a given hypervisor, set the name here
# (if multiple names are provided, the first will be used)
# Leave empty to let openstack pick the hypervisor
compute_nodes:
# If openrc is not admin set a valid value for hypervisor hostname
# Example of value: hypervisor_hostname: "server1"
hypervisor_hostname:

# Type of service chain to run, possible options are PVP, PVVP and EXT
# PVP - port to VM to port
# PVVP - port to VM to VM to port
# EXT - external chain used only for running traffic and checking traffic generator counters,
#       all other parts of chain must be configured manually
# Can be overriden by --service-chain
service_chain: 'PVP'

# Total number of service chains, every chain has own traffic stream
# Can be overriden by --service-chain-count
service_chain_count: 1

# Specifies if all chains share the same right/left/middle networks
service_chain_shared_net: false

# Total number of traffic flows for all chains and directions generated by the traffic generator.
# Minimum is '2 * service_chain_count', it is automatically adjusted if too small
# value was configured. Must be even.
# Every flow has packets with different IPs in headers
# Can be overriden by --flow-count
flow_count: 10000

# set to true if service chains should use SRIOV
# This requires SRIOV to be available on compute nodes
sriov: false

# Perform port to port loopback (direct or through switch)
# Should be used with EXT service chain and no ARP (no_arp: true)
# When enabled, the vlans property must contain the same VLAN id for all chains.
# Can be overriden by --l2-loopback
l2_loopback: false

# Resources created by NFVbench will not be removed
# Can be overriden by --no-cleanup
no_cleanup: false

# Configuration for traffic generator
traffic_generator:
    # Name of the traffic generator, only for informational purposes
    host_name: 'nfvbench_tg'
    # this is the default traffic generator profile to use
    # the name must be defined under generator_profile
    # you can override the traffic generator to use using the
    # -g or --traffic-gen option at the command line
    default_profile: trex-local

    # IP addresses for L3 traffic.
    # This section describes the addresses to use to fill in the UDP packets sent by the
    # traffic generator. If you VNFs are L2 forwarders, these fields below do not need to change.
    # If your VNFs are L3 routers, the fields below must match the static routes in your VNFs
    # so that UDP packets can be routed back to the peer port of the traffic generator.

    # All of the IPs are used as base for IP sequence computed based on chain or flow count.
    # (sim-devices-left)---(tg-gateway-left)---(vnf-left)- ...
    #                                      -(vnf-right)---(tg-gateway-right)---(sim-devices-right)
    #
    # `ip_addrs` base IPs used as src and dst in packet header, quantity depends on flow count
    #            these are used for addressing virtual devices simulated by the traffic generator
    #            and be a different subnet than tg_gateway_ip_addrs and gateway_ip_addrs
    # `ip_addrs_step`: step for generating IP sequence. Use "random" for random patterns, default is 0.0.0.1.
    ip_addrs: ['10.0.0.0/8', '20.0.0.0/8']
    ip_addrs_step: 0.0.0.1

    #'ip_src_static': an attribute to precise the state of source IP during the generation of traffic, It indicates whether
    #                the IP source variate or remain constant. Use True for constant IP and  False for varying IPs.
    #                default value is  True
    ip_src_static: True

    # `tg_gateway_ip_addrs` base IP for traffic generator ports in the left and right networks to the VNFs
    #                       chain count consecutive IP addresses spaced by tg_gateway_ip_addrs_step will be used
    # `tg_gateway_ip_addrs__step`: step for generating traffic generator gateway sequences. default is 0.0.0.1
    tg_gateway_ip_addrs: ['192.168.1.100', '192.168.2.100']
    tg_gateway_ip_cidrs: ['192.168.1.0/24','192.168.2.0/24']
    tg_gateway_ip_addrs_step: 0.0.0.1
    # `gateway_ip_addrs`: base IPs of VNF router gateways (left and right), quantity used depends on chain count
    #                     must correspond to the public IP on the left and right networks
    #                     for each left-most and right-most VNF of every chain.
    #                     must be the same subnet but not same IP as tg_gateway_ip_addrs.
    #                     chain count consecutive IP addresses spaced by gateway_ip_addrs_step will be used
    # `gateway_ip_addrs_step`: step for generating router gateway sequences. default is 0.0.0.1
    gateway_ip_addrs: ['192.168.1.1', '192.168.2.1']
    gateway_ip_addrs_step: 0.0.0.1

    # UDP DEFINED VARIABLES
    # TRex pick default UDP port (53) but the range of UDP source and destination ports are also
    # defined from configuration file by using the following attributes:
    #
    # `udp_src_port`: the source port for sending UDP traffic, default is picked by TRex (53)
    # `udp_dst_port`: the destination port for sending UDP traffic, default is picked by TRex (53)
    # `udp_src_port` and `udp_dst_port` can be defined by a single port or a range. Example:
    #   udp_src_port: 80
    #   udp_dst_port: ['1024','65000']
    # `udp_port_step`: the step between two generated ports, default is equal to '1'
    #
    # NOTICE:
    # Following TRex functionalities, incrementation and decrementation of source port and destination
    # port values occur simultaneously.
    # So, in order to reach the highest possible number of packets, it's recommended that the range of source ports
    # minus the range of destination ports should be different of 1
    # i.e:  |range[source_port] - range[destination_port]| = 1
    udp_src_port:
    udp_dst_port:
    udp_port_step: '1'

    # VxLAN only: optionally specify what VLAN tag to use for the VxLAN overlay
    # This is used if the vxlan tunnels are running on a specific VLAN.
    # Leave empty if there is no VLAN tagging required, or specify the VLAN id to use
    # for all VxLAN tunneled traffic
    vtep_vlan:
    # VxLAN and MPLS only: local/source vteps IP addresses for port 0 and 1 ['10.1.1.230', '10.1.1.231']
    src_vteps:
    # VxLAN only: remote IP address of the remote VTEPs that terminate all tunnels originating from local VTEPs
    dst_vtep:
    # The encapsulated L3/MPLS packet needs to traverse L3 or MPLS fabric to reach to its final dst_vtep.
    # This parameter is required to resolve first next-hop MAC address if it next-hop is not its final dst_vtep.
    # This parameter is mandatory for MPLS only
    vtep_gateway_ips:
    # L2 ADDRESSING OF UDP PACKETS
    # Lists of dest MAC addresses to use on each traffic generator port (one dest MAC per chain)
    # Leave empty for PVP, PVVP, EXT with ARP
    # Only used when `service_chain` is EXT and `no_arp` is true.
    #   - If both lists are empty the far end MAC of the traffic generator will be used for left and right
    #     (this is typicaly used to loop back on the first hop switch or using a loopback cable)
    #   - The length of each list must match the number of chains being used!
    #   - The index of each list must correspond to the chain index to ensure proper pairing.
    #   - Below is an example of using two chains:
    #     - mac_addrs_left: ['00:00:00:00:01:00', '00:00:00:00:02:00']
    #     - mac_addrs_right: ['00:00:00:00:01:01', '00:00:00:00:02:01']
    #     UDP packets sent on port 0 will use dest MAC '00:00:00:00:01:00' for chain #0 and
    #                                         dest MAC '00:00:00:00:02:00' for chain #1
    #     UDP packets sent on port 1 will use dest MAC '00:00:00:00:01:01' for chain #0 and
    #                                         dest MAC '00:00:00:00:02:01' for chain #1
    #     It is expected that the looping device (L2 forwarder) will rewrite the src and dst MAC
    #     of the looping UDP packet so that it can reach back to the peer port of the traffic
    #     generator.
    #
    mac_addrs_left:
    mac_addrs_right:

    # Traffic Generator Profiles
    # In case you have multiple testbeds or traffic generators,
    # you can define one traffic generator profile per testbed/traffic generator.
    # In most cases you only need to fill in the pci address for the 2 ports used by the
    # traffic generator and leave all other fields unchanged
    #
    # Generator profiles are listed in the following format:
    # `name`: Traffic generator profile name (use a unique name, no space or special character)
    #         Do not change this field
    # `tool`: Traffic generator tool to be used (currently supported is `TRex`).
    #         Do not change this field
    # `ip`: IP address of the traffic generator.
    #       The default loopback address is used when the traffic generator runs on the same host
    #       as NFVbench.
    # `cores`: Specify the number of cores for running the TRex traffic generator.
    #          ONLY applies to trex-local.
    # `software_mode`: Advice TRex to use software mode which provides the best compability. But
    #                  note that TRex will not use any hardware acceleration technology under
    #                  software mode, therefore the performance of TRex will be significantly
    #                  lower. ONLY applies to trex-local.
    #                  Recommended to leave the default value (false)
    # `limit_memory`: Specify the memory reserved for running the TRex traffic generator (in MB). Limit the amount
    #                 of packet memory used. (Passed to dpdk as -m arg)
    #          ONLY applies to trex-local.
    # `zmq_pub_port`: Specify the ZMQ pub port number for the TRex traffic generator instance (default value is 4500).
    #          ONLY applies to trex-local.
    # `zmq_rpc_port`: Specify the ZMQ rpc port for the TRex traffic generator instance (default value is 4501).
    #          ONLY applies to trex-local.
    # `interfaces`: Configuration of traffic generator interfaces.
    # `interfaces.port`: The port of the traffic generator to be used (leave as 0 and 1 resp.)
    # `interfaces.switch_port`: Leave empty (deprecated)
    # `interfaces.pci`: The PCI address of the intel NIC interface associated to this port
    #                   This field is required and cannot be empty
    #                   Use lspci to list the PCI address of all devices
    #                   Example of value: "0000:5e:00.0"
    # `intf_speed`: The speed of the interfaces used by the traffic generator (per direction).
    #               Empty value (default) to use the speed discovered by the traffic generator.
    #               Recommended to leave this field empty.
    #               Do not use unless you want to override the speed discovered by the
    #               traffic generator. Expected format: 10Gbps
    #
    # `platform`: Optional. Used to tune the performance and allocate the cores to the right NUMA.
    #             See https://trex-tgn.cisco.com/trex/doc/trex_manual.html (6.2.3. Platform section configuration)
    #             for more details
    # `platform.master_thread_id`: Hardware thread_id for control thread. (Valid value is mandatory if platform property is set)
    # `platform.latency_thread_id`: Hardware thread_id for RX thread. (Valid value is mandatory if platform property is set)
    # `platform.dual_if`: Section defines info for interface pairs (according to the order in “interfaces” list). (Valid value is mandatory if platform property is set)
    #                     Each section, starting with “- socket” defines info for different interface pair. (Valid value is mandatory if platform property is set)
    # `platform.dual_if.socket`: The NUMA node from which memory will be allocated for use by the interface pair. (Valid value is mandatory if platform property is set)
    # `platform.dual_if.threads`: Hardware threads to be used for sending packets for the interface pair. (Valid value is mandatory if platform property is set)
    #                     Threads are pinned to cores, so specifying threads actually determines the hardware cores.
    # Example of values:
    # platform:
    #   master_thread_id: 0
    #   latency_thread_id: 2
    #   dual_if:
    #     - socket: 0
    #       threads: [1]
    #
    generator_profile:
        - name: trex-local
          tool: TRex
          ip: 127.0.0.1
          cores: 4
          software_mode: false
          limit_memory: 1024
          zmq_pub_port: 4500
          zmq_rpc_port: 4501
          interfaces:
            - port: 0
              pci:
              switch_port:
            - port: 1
              pci:
              switch_port:
          intf_speed:
          platform:
            master_thread_id:
            latency_thread_id:
            dual_if:
              - socket:
                threads:

# Use 'true' to force restart of local TRex server before next run
# TRex local server will be restarted even if restart property is false in case of generator config changes between runs
restart: false

# Simpler override for trex core count and mbuf multilier factor
# if empty defaults to the one specified in generator_profile.cores
cores:

# Add cache size in packet generation for TRex field engine (FE).
# More information for TRex performance:
# https://trex-tgn.cisco.com/trex/doc/trex_stateless.html#_tutorial_field_engine_significantly_improve_performance
# If cache_size = 0 (or empty): no cache will be used by TRex (default)
# If cache_size < 0: cache_size will be set to flow count value
cache_size: 0
# The cache size is actually limited by the number of 64B mbufs configured in the trex platform configuration (see Trex manual 6.2.2. Memory section configuration)
# Trex will use 1 x 64B mbuf per pre-built cached packet, assuming 1 pre-built cached packet per flow, it means for very large number of flows, the number of configured mbuf_64 will need to be set accordingly.
mbuf_64:

# mbuffer ratio to use for TRex (see TRex documentation for more details)
mbuf_factor: 0.2

# A switch to disable hdrh
# hdrh is enabled by default and requires TRex v2.58 or higher
disable_hdrh: false

# List of latency percentiles values returned using hdrh
# elements should be int or float between 0.0 and 100.0
lat_percentiles: [25, 75, 99]

# -----------------------------------------------------------------------------
# These variables are not likely to be changed

# Number of seconds to wait for VMs to pass traffic in both directions
check_traffic_time_sec: 200

# General retry count
generic_retry_count: 100

# General poll period
generic_poll_sec: 2

# name of the loop VM
loop_vm_name: 'nfvbench-loop-vm'

# Default names, subnets and CIDRs for PVP/PVVP networks (openstack only)
#
# If a network with given name already exists it will be reused.
# - PVP only uses left and right
# - PVVP uses left, middle and right
# - for EXT chains, this structure is not relevant - refer to external_networks
# Otherwise a new internal network will be created with that name, subnet and CIDR.
#
# network_type must be 'vlan' (for VLAN and SRIOV) or 'vxlan' (for VxLAN)
#              all 3 networks must use the same network type in this release
# segmentation_id can be set to enforce a specific segmentation id (vlan ID or VNI if vxlan)
#                 by default (empty) the segmentation id will be assigned by Neutron.
#                 If specified, it must be unique for each network
#                 For multi-chaining, see notes below
# physical_network can be set to pick a specific phsyical network - by default (empty) the
#                   default physical network will be picked
# SR-IOV: both physical_network and VLAN segmentation ID must be provided
# VxLAN: the VNI must generally be provided (except special Neutron VxLAN implementations)
#
# For example to setup 1xPVP using 2 different SR-IOV ports, you must put the appropriate physnet
# names under left.physical_network and right.physical_network.
# For multi-chaining and non shared networks,
# Example of override configuration to force PVP to run on 2 SRIOV ports (phys_sriov0 and phys_sriov1)
# using VLAN ID 2000 and 2001:
# internal_networks:
#    left:
#        segmentation_id: 2000
#        physical_network: phys_sriov0
#    right:
#        segmentation_id: 2001
#        physical_network: phys_sriov1
#
# For multi-chaining and non shared network mode (VLAN, SRIOV, VxLAN, MPLS):
# - the segmentation_id field if provided must be a list of values (as many as chains)
# - segmentation_id auto-indexing:
#   the segmentation_id field can also be a single value that represents the base value from which
#   values for each chain is derived using the chain ID as an offset. For example
#   if 2000 is specified, NFVbench will use 2000 for chain 0, 2001 for chain 1 etc...
#   The ranges of all the networks must not overlap.
# - the physical_network can be a single name (all VFs to be allocated on same physnet)
#   of a list of physnet names to use different PFs
#
#   Example of 2-chain VLAN configuration:
#   internal_networks:
#      left:
#          segmentation_id: [2000, 2001]
#          physical_network: phys_sriov0
#      right:
#          segmentation_id: [2010, 2011]
#          physical_network: phys_sriov1
#   Equivalent to (using auto-indexing):
#   internal_networks:
#      left:
#          segmentation_id: 2000
#          physical_network: phys_sriov0
#      right:
#          segmentation_id: 2010
#          physical_network: phys_sriov1
#
# - mpls_transport_labels is used only when MPLS encapsulation is enabled (mpls: true)
#   this parameter doesn't support auto-indexing because this is not a typical scenario
#   expected the list of values in a range 256-1048575, one value per chain is expected
#
#   In the bellow configuration example 'segmentation_id; contains the inner MPLS label for each chain
#   and 'mpls_transport_labels' contains the outer transport MPLS label for each chain
#   Example of 2-chain MPLS configuration:
#   internal_networks:
#      left:
#          network_type: mpls
#          segmentation_id: [2000, 2001]
#          mpls_transport_labels: [10000, 10000]
#          physical_network: phys_sriov0
#      right:
#          network_type: mpls
#          segmentation_id: [2010, 2011]
#          mpls_transport_labels: [11000, 11000]
#          physical_network: phys_sriov1


internal_networks:
    left:
        name: 'nfvbench-lnet'
        subnet: 'nfvbench-lsubnet'
        cidr: '192.168.1.0/24'
        network_type: 'vlan'
        segmentation_id:
        physical_network:
        mpls_transport_labels:
    right:
        name: 'nfvbench-rnet'
        subnet: 'nfvbench-rsubnet'
        cidr: '192.168.2.0/24'
        network_type: 'vlan'
        segmentation_id:
        physical_network:
        mpls_transport_labels:
    middle:
        name: 'nfvbench-mnet'
        subnet: 'nfvbench-msubnet'
        cidr: '192.168.3.0/24'
        network_type: 'vlan'
        segmentation_id:
        physical_network:
        mpls_transport_labels:

# IDLE INTERFACES: PVP, PVVP and non shared net only.
# By default each test VM will have 2 virtual interfaces for looping traffic.
# If service_chain_shared_net is false, additional virtual interfaces can be
# added at VM creation time, these interfaces will not carry any traffic and
# can be used to test the impact of idle interfaces in the overall performance.
# All these idle interfaces will use normal ports (not direct).
# Number of idle interfaces per VM (none by default)
idle_interfaces_per_vm: 0

# A new network is created for each idle interface.
# If service_chain_shared_net is true, the options below will be ignored
# and no idle interfaces will be added.
idle_networks:
    # Prefix for all idle networks, the final name will append the chain ID and idle index
    # e.g. "nfvbench-idle-net.0.4" chain 0 idle index 4
    name: 'nfvbench-idle-net'
    # Subnet name to use for all idle subnetworks
    subnet: 'nfvbench-idle-subnet'
    # CIDR to use for all idle networks (value should not matter)
    cidr: '192.169.1.0/24'
    # Type of network associated to the idle virtual interfaces (vlan or vxlan)
    network_type: 'vlan'
    # segmentation ID to use for the network attached to the idle virtual interfaces
    # vlan: leave empty to let neutron pick the segmentation ID
    # vxlan: must specify the starting VNI value to be used (cannot be empty)
    # Note that NFVbench will use as many consecutive segmentation IDs as needed.
    # For example, for 4 PVP chains and 8 idle
    # interfaces per VM, NFVbench will use 32 consecutive values of segmentation ID
    # starting from the value provided.
    segmentation_id:
    # physnet name to use for all idle interfaces
    physical_network:

# MANAGEMENT INTERFACE
# By default each test VM will have 2 virtual interfaces for looping traffic.
# If use_management_port is true, additional virtual interface can be
# added at VM creation time, this interface will be used for VM management over SSH.
# This will be helpful for debug (forwarder config, capture traffic...)
# or to emulate VNF with management interface
use_management_port: false

# If a network with given name already exists it will be reused.
# Otherwise a new network is created for management interface.
# If use_management_port is false, the options below will be ignored
# and no management interface will be added.
management_network:
    name: 'nfvbench-management-net'
    # Subnet name to use for management subnetwork
    subnet: 'nfvbench-management-subnet'
    # CIDR to use for management network
    cidr: '192.168.0.0/24'
    gateway: '192.168.0.254'
    # Type of network associated to the management virtual interface (vlan or vxlan)
    network_type: 'vlan'
    # segmentation ID to use for the network attached to the management virtual interface
    # vlan: leave empty to let neutron pick the segmentation ID
    # vxlan: must specify the starting VNI value to be used (cannot be empty)
    segmentation_id:
    # physnet name to use for all idle interfaces
    physical_network:

# Floating IP for management interface
# If use_floating_ip is true, floating IP will be set on management interface port
# One floating IP by loop VM will be used (floating ips are often limited,
# use them on limited context mainly for debug). If there are 10 PVP chains, this will require 10
# floating IPs. If 10 PVVP chains, it will require 20 floating IPs
use_floating_ip: false

# If a network with given name already exists it will be reused.
# Set same name as management_network if you want to use a floating IP from this network
# Otherwise set name, subnet and CIDR information from your floating IP pool network
# Floating network used to set floating IP on management port.
# Only 1 floating network will be used for all VMs and chains (shared network).
# If use_floating_ip is false, the options below will be ignored
# and no floating IP will be added.
floating_network:
    name: 'nfvbench-floating-net'
    # Subnet name to use for floating subnetwork
    subnet: 'nfvbench-floating-subnet'
    # CIDR to use for floating network
    cidr: '192.168.0.0/24'
    # Type of network associated to the management virtual interface (vlan or vxlan)
    network_type: 'vlan'
    # segmentation ID to use for the network attached to the management virtual interface
    # vlan: leave empty to let neutron pick the segmentation ID
    # vxlan: must specify the starting VNI value to be used (cannot be empty)
    segmentation_id:
    # physnet name to use for all idle interfaces
    physical_network:

# In the scenario of PVVP + SRIOV, there is choice of how the traffic will be
# handled in the middle network. The default (false) will use vswitch, while
# SRIOV can be used by toggling below setting.
use_sriov_middle_net: false

# EXT chain only. Prefix names of edge networks or list of edge network names
# used to send traffic via traffic generator.
#
# If service_chain_shared_net is true, the left and right networks must pre-exist and match exactly by name.
#
# If service_chain_shared_net is false, each chain must have its own pre-existing left and right networks.
# left and right can take either a string prefix or a list of arbitrary network names
# If a string prefix is passed, an index will be appended to each network name to form the final name.
# Example:
# external_networks:
#    left:  'ext-lnet'
#    right: 'ext-rnet'
# ext-lnet0 ext-rnet0 for chain #0
# ext-lnet1 ext-rnet1 for chain #1
# etc...
# If a list of strings is passed, each string in the list must be the name of the network used for the
# chain indexed by the entry position in the list.
# The list must have at least as many entries as there are chains
# Example:
# external_networks:
#   left:  ['ext-lnet', 'ext-lnet2']
#   right: ['ext-rnet', 'ext-rnet2']
#
external_networks:
    left:
    right:

# PVP with L3 router in the packet path only.
# Only use when l3_router option is True (see l3_router)
# Prefix names of edge networks which will be used to send traffic via traffic generator.
# If a network with given name already exists it will be reused.
# Otherwise a new edge network will be created with that name, subnet and CIDR.
#
# gateway can be set in case of L3 traffic with edge networks - refer to edge_networks
#
# segmentation_id can be set to enforce a specific VLAN id - by default (empty) the VLAN id
#                 will be assigned by Neutron.
#                 Must be unique for each network
# physical_network can be set to pick a specific phsyical network - by default (empty) the
#                   default physical network will be picked
#
edge_networks:
    left:
        name: 'nfvbench-net2'
        router_name: 'router_left'
        subnet: 'nfvbench-subnet2'
        cidr: '192.168.3.0/24'
        gateway:
        network_type:
        segmentation_id:
        physical_network:
    right:
        name: 'nfvbench-net3'
        router_name: 'router_right'
        subnet: 'nfvbench-subnet3'
        cidr: '192.168.4.0/24'
        gateway:
        network_type:
        segmentation_id:
        physical_network:

# Use 'true' to enable VXLAN encapsulation support and sent by the traffic generator
# When this option enabled internal networks 'network type' parameter value should be 'vxlan'
# VxLAN and MPLS encapsulations are mutual exclusive if 'vxlan' is true then 'mpls' should be false
# and vise versa
vxlan: false
# Use 'true' to enable MPLS encapsulation support and sent by the traffic generator
# When this option enabled internal networks 'network type' parameter value should be 'mpls'
# MPLS and VxLAN encapsulations are mutual exclusive if 'mpls' is 'true' then 'vxlan' should be set to 'false'
# and vise versa. no_flow_stats, no_latency_stats, no_latency_streams should be set to 'true' because these
# features are not supported at the moment. In future when these features will be supported they will require
# special NIC hardware. Only 2 label stack supported at the moment where one label is transport and another
# is VPN for more details please refer to 'mpls_transport_labels' and 'segmentation_id' in networks configuration
mpls: false
# Use 'true' to enable VLAN tagging of packets generated and sent by the traffic generator
# Leave empty or set to false if you do not want the traffic generator to insert the VLAN tag (this is
# needed for example if VLAN tagging is enabled on switch (access mode) or if you want to hook
# directly to a NIC).
# By default is set to true (which is the nominal use case with TOR and trunk mode to Trex ports)
# If VxLAN or MPLS are enabled, this option should be set to false (vlan tagging for encapsulated packets
# is not supported). Use the vtep_vlan option to enable vlan tagging for the VxLAN overlay network.
vlan_tagging: true

# Used only in the case of EXT chain and no openstack or not admin access to specify the VLAN IDs to use.
# This property is ignored when OpenStakc is used or in the case of l2-loopback.
# If OpenStack is used leave the list empty, VLAN IDs are retrieved from OpenStack networks using Neutron API.
# If networks are shared across all chains (service_chain_shared_net=true), the list should have exactly 2 values
# If networks are not shared across chains (service_chain_shared_net=false), the list should have
# 2 list of vlan IDs
# In the special case of l2-loopback the list should have the same VLAN id for all chains
# Examples:
#   [1998, 1999] left network uses vlan 1998 right network uses vlan 1999
#   [[1,2],[3,4]] chain 0 left vlan 1, right vlan 2 - chain 1 left vlan 3 right vlan 4
#   [1010, 1010] same VLAN id with l2-loopback enabled
#
vlans: []

# ARP is used to discover the MAC address of VNFs that run L3 routing.
# Used only with EXT chain.
# False (default): ARP requests are sent to find out dest MAC addresses.
# True: do not send ARP but use provisioned dest macs instead
#       (see mac_addrs_left and mac_addrs_right)
no_arp: false

# Loop VM (VPP forwarder) can use ARP to discover next hop mac address
# False (default): do not send ARP but use static config devices macs instead (TRex gratuitous ARP are not interpreted by VPP)
# True: ARP requests are sent to find out next hop MAC addresses (for instance SDN-GW)
loop_vm_arp: false

# Traffic Profiles
# You can add here more profiles as needed
# `l2frame_size` can be specified in any none zero integer value to represent the size in bytes
# of the L2 frame, or "IMIX" to represent the standard 3-packet size mixed sequence (IMIX1).
traffic_profile:
    - name: traffic_profile_64B
      l2frame_size: ['64']
    - name: traffic_profile_IMIX
      l2frame_size: ['IMIX']
    - name: traffic_profile_1518B
      l2frame_size: ['1518']
    - name: traffic_profile_3sizes
      l2frame_size: ['64', 'IMIX', '1518']

# Traffic Configuration
# bidirectional: to have traffic generated from both direction, set bidirectional to true
# profile: must be one of the profiles defined in traffic_profile
# The traffic profile can be overriden with the options --frame-size and --uni-dir
traffic:
    bidirectional: true
    profile: traffic_profile_64B

# Check config and connectivity only - do not generate traffic
# Can be overriden by --no-traffic
no_traffic: false

# Use an L3 router in the packet path. This option if set will create or reuse an openstack neutron
# router (PVP, PVVP) or reuse an existing L3 router (EXT) to route traffic to the destination VM.
# Can be overriden by --l3-router
l3_router: false

# Test configuration

# The rate pps for traffic going in reverse direction in case of unidirectional flow. Default to 1.
unidir_reverse_traffic_pps: 1

# The rate specifies if NFVbench should determine the NDR/PDR
#  or if NFVbench should just generate traffic at a given fixed rate
# for a given duration (called "single run" mode)
# Supported rate format:
# NDR/PDR test: `ndr`, `pdr`, `ndr_pdr` (default)
# Or for single run mode:
# Packet per second: pps (e.g. `50pps`)
# Bits per second: bps, kbps, Mbps, etc (e.g. `1Gbps`, `1000bps`)
# Load percentage: % (e.g. `50%`)
# Can be overridden by --rate
rate: ndr_pdr

# Default run duration (single run at given rate only)
# Can be overridden by --duration
duration_sec: 60

# Interval between intermediate reports when interval reporting is enabled
# Can be overridden by --interval
interval_sec: 10

# Default pause between iterations of a binary search (NDR/PDR)
pause_sec: 2

# NDR / PDR configuration
measurement:
    # Drop rates represent the ratio of dropped packet to the total number of packets sent.
    # Values provided here are percentages. A value of 0.01 means that at most 0.01% of all
    # packets sent are dropped (or 1 packet every 10,000 packets sent)

    # No Drop Rate in percentage; Default to 0.001%
    NDR: 0.001
    # Partial Drop Rate in percentage; NDR should always be less than PDR
    PDR: 0.1
    # The accuracy of NDR and PDR as a percnetage of line rate; The exact NDR
    # or PDR should be within `load_epsilon` line rate % from the one calculated.
    # For example, with a value 0.1, and a line rate of 10Gbps, the accuracy
    # of NDR and PDR will be within 0.1% Of 10Gbps or 10Mbps.
    # The lower the value the more iterations and the longer it will take to find the NDR/PDR.
    # In practice, due to the precision of the traffic generator it is not recommended to
    # set it to lower than 0.1
    load_epsilon: 0.1

# Location where to store results in a JSON format. Must be container specific path.
# Can be overriden by --json
json:

# Location where to store results in the NFVbench standard JSON format:
# <service-chain-type>-<service-chain-count>-<flow-count>-<packet-sizes>.json
# Example: PVP-1-10-64-IMIX.json
# Must be container specific path.
# Can be overriden by --std-json
std_json:

# Prints debug messages (verbose mode)
# Can be overriden by --debug
debug: false

# Set to a valid path name if logging to file is to be enabled
# Defaults to disabled
log_file:

# When enabled, all results and/or logs will be sent to a fluentd servers at the requested IPs and ports
# A list of one or more fluentd servers identified by their IPs and  port numbers should be given.
# For each recipient it is possible to enable both sending logs and performance
# results, or enable either logs or performance results. For enabling logs or results logging_tag or
# result_tag should be set.

fluentd:
      # by default (logging_tag is empty) nfvbench log messages are not sent to fluentd
      # to enable logging to fluents, specify a valid fluentd tag name to be used for the
      # log records
    - logging_tag:

      # by default (result_tag is empty) nfvbench results are not sent to fluentd
      # to enable sending nfvbench results to fluentd, specify a valid fluentd tag name
      # to be used for the results records, which is different than logging_tag
      result_tag:

      # IP address of the server, defaults to loopback
      ip: 127.0.0.1

      # port # to use, by default, use the default fluentd forward port
      port: 24224

      # by default (logging_tag is empty) nfvbench log messages are not sent to fluentd
      # to enable logging to fluents, specify a valid fluentd tag name to be used for the
      # log records

# Module and class name of factory which will be used to provide classes dynamically for other components.
factory_module: 'nfvbench.factory'
factory_class: 'BasicFactory'

# Custom label added for every perf record generated during this run.
# Can be overriden by --user-label
user_label:


# THESE FIELDS SHOULD BE USED VERY RARELY

# Skip vswitch configuration and retrieving of stats
# Can be overriden by --no-vswitch-access
# Should be left to the default value (false)
no_vswitch_access: false


# Enable service mode for trafic capture from TRex console (for debugging purpose)
# Can be overriden by --service-mode
# Should be left to the default value (false)
service_mode: false

# Disable extra flow stats (on high load traffic)
# Can be overriden by --no-flow-stats
# Should be left to the default value (false)
no_flow_stats: false

# Disable flow stats for latency traffic
# Can be overriden by --no-latency-stats
# Should be left to the default value (false)
no_latency_stats: false

# Disable latency measurements (no streams)
# Can be overriden by --no-latency-stream
# Should be left to the default value (false)
no_latency_streams: false