diff options
author | Volodymyr Mytnyk <volodymyrx.mytnyk@intel.com> | 2019-01-11 10:04:20 +0000 |
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committer | Gerrit Code Review <gerrit@opnfv.org> | 2019-01-11 10:04:20 +0000 |
commit | 07c506d3fff732019651d89de14bf42fa8d9a365 (patch) | |
tree | 5d05fff95180e015fafbf48eb894cd8fe95da383 /docs | |
parent | e2f2e6b380fb63c4dcabe611aee180d4a0baa034 (diff) | |
parent | 3ceadb40c622a58c4b330fb3e6cdf391955b44a8 (diff) |
Merge "[docs][userguide] Update formatting on userguide chapters 12-14"
Diffstat (limited to 'docs')
-rw-r--r-- | docs/testing/user/userguide/12-nsb-overview.rst | 218 | ||||
-rw-r--r-- | docs/testing/user/userguide/13-nsb-installation.rst | 313 | ||||
-rw-r--r-- | docs/testing/user/userguide/14-nsb-operation.rst | 47 |
3 files changed, 273 insertions, 305 deletions
diff --git a/docs/testing/user/userguide/12-nsb-overview.rst b/docs/testing/user/userguide/12-nsb-overview.rst index 7b0d46804..c5e395ee6 100644 --- a/docs/testing/user/userguide/12-nsb-overview.rst +++ b/docs/testing/user/userguide/12-nsb-overview.rst @@ -7,16 +7,17 @@ Network Services Benchmarking (NSB) =================================== -Abstract -======== - .. _Yardstick: https://wiki.opnfv.org/display/yardstick +.. _`ETSI GS NFV-TST001`: http://www.etsi.org/deliver/etsi_gs/NFV-TST/001_099/001/01.01.01_60/gs_nfv-tst001v010101p.pdf + +Abstract +-------- This chapter provides an overview of the NSB, a contribution to OPNFV Yardstick_ from Intel. Overview -======== +-------- The goal of NSB is to Extend Yardstick to perform real world VNFs and NFVi Characterization and benchmarking with repeatable and deterministic methods. @@ -31,44 +32,34 @@ according to user defined profiles. NSB extension includes: - - Generic data models of Network Services, based on ETSI spec `ETSI GS NFV-TST 001 <http://www.etsi.org/deliver/etsi_gs/NFV-TST/001_099/001/01.01.01_60/gs_nfv-tst001v010101p.pdf>`_ - - - New Standalone context for VNF testing like SRIOV, OVS, OVS-DPDK etc - - - Generic VNF configuration models and metrics implemented with Python - classes - - - Traffic generator features and traffic profiles - - - L1-L3 state-less traffic profiles - - - L4-L7 state-full traffic profiles - - - Tunneling protocol / network overlay support - - - Test case samples - - - Ping - - - Trex +* Generic data models of Network Services, based on ETSI spec + `ETSI GS NFV-TST 001`_ +* Standalone :term:`context` for VNF testing like SRIOV, OVS, OVS-DPDK, etc +* Generic VNF configuration models and metrics implemented with Python + classes +* Traffic generator features and traffic profiles - - vPE,vCGNAT, vFirewall etc - ipv4 throughput, latency etc + * L1-L3 stateless traffic profiles + * L4-L7 state-full traffic profiles + * Tunneling protocol/network overlay support - - Traffic generators like Trex, ab/nginx, ixia, iperf etc +* Test case samples - - KPIs for a given use case: + * Ping + * Trex + * vPE, vCGNAT, vFirewall etc - ipv4 throughput, latency etc - - System agent support for collecting NFVi KPI. This includes: +* Traffic generators i.e. Trex, ab/nginx, ixia, iperf, etc +* KPIs for a given use case: - - CPU statistic + * System agent support for collecting NFVi KPI. This includes: - - Memory BW + * CPU statistic + * Memory BW + * OVS-DPDK Stats - - OVS-DPDK Stats - - - Network KPIs, e.g., inpackets, outpackets, thoughput, latency etc - - - VNF KPIs, e.g., packet_in, packet_drop, packet_fwd etc + * Network KPIs e.g. inpackets, outpackets, thoughput, latency + * VNF KPIs e.g. packet_in, packet_drop, packet_fwd Architecture ============ @@ -83,111 +74,102 @@ performed network functionality. The part of the data model is a set of the configuration parameters, number of connection points used and flavor including core and memory amount. -The ETSI defines a Network Service as a set of configurable VNFs working in -some NFV Infrastructure connecting each other using Virtual Links available -through Connection Points. The ETSI MANO specification defines a set of -management entities called Network Service Descriptors (NSD) and -VNF Descriptors (VNFD) that define real Network Service. The picture below -makes an example how the real Network Operator use-case can map into ETSI -Network service definition - -Network Service framework performs the necessary test steps. It may involve - - - Interacting with traffic generator and providing the inputs on traffic - type / packet structure to generate the required traffic as per the - test case. Traffic profiles will be used for this. - - - Executing the commands required for the test procedure and analyses the - command output for confirming whether the command got executed correctly - or not. E.g. As per the test case, run the traffic for the given - time period / wait for the necessary time delay - - - Verify the test result. - - - Validate the traffic flow from SUT - - - Fetch the table / data from SUT and verify the value as per the test case - - - Upload the logs from SUT onto the Test Harness server - - - Read the KPI's provided by particular VNF +ETSI defines a Network Service as a set of configurable VNFs working in some +NFV Infrastructure connecting each other using Virtual Links available through +Connection Points. The ETSI MANO specification defines a set of management +entities called Network Service Descriptors (NSD) and VNF Descriptors (VNFD) +that define real Network Service. The picture below makes an example how the +real Network Operator use-case can map into ETSI Network service definition. + +Network Service framework performs the necessary test steps. It may involve: + +* Interacting with traffic generator and providing the inputs on traffic + type / packet structure to generate the required traffic as per the + test case. Traffic profiles will be used for this. +* Executing the commands required for the test procedure and analyses the + command output for confirming whether the command got executed correctly + or not e.g. as per the test case, run the traffic for the given + time period and wait for the necessary time delay. +* Verify the test result. +* Validate the traffic flow from SUT. +* Fetch the data from SUT and verify the value as per the test case. +* Upload the logs from SUT onto the Test Harness server +* Retrieve the KPI's provided by particular VNF Components of Network Service ----------------------------- - * *Models for Network Service benchmarking*: The Network Service benchmarking - requires the proper modelling approach. The NSB provides models using Python - files and defining of NSDs and VNFDs. +* *Models for Network Service benchmarking*: The Network Service benchmarking + requires the proper modelling approach. The NSB provides models using Python + files and defining of NSDs and VNFDs. - The benchmark control application being a part of OPNFV yardstick can call - that python models to instantiate and configure the VNFs. Depending on - infrastructure type (bare-metal or fully virtualized) that calls could be - made directly or using MANO system. +The benchmark control application being a part of OPNFV yardstick can call +that python models to instantiate and configure the VNFs. Depending on +infrastructure type (bare-metal or fully virtualized) that calls could be +made directly or using MANO system. - * *Traffic generators in NSB*: Any benchmark application requires a set of - traffic generator and traffic profiles defining the method in which traffic - is generated. +* *Traffic generators in NSB*: Any benchmark application requires a set of + traffic generator and traffic profiles defining the method in which traffic + is generated. - The Network Service benchmarking model extends the Network Service - definition with a set of Traffic Generators (TG) that are treated - same way as other VNFs being a part of benchmarked network service. - Same as other VNFs the traffic generator are instantiated and terminated. +The Network Service benchmarking model extends the Network Service +definition with a set of Traffic Generators (TG) that are treated +same way as other VNFs being a part of benchmarked network service. +Same as other VNFs the traffic generator are instantiated and terminated. - Every traffic generator has own configuration defined as a traffic profile - and a set of KPIs supported. The python models for TG is extended by - specific calls to listen and generate traffic. +Every traffic generator has own configuration defined as a traffic profile +and a set of KPIs supported. The python models for TG is extended by +specific calls to listen and generate traffic. - * *The stateless TREX traffic generator*: The main traffic generator used as - Network Service stimulus is open source TREX tool. +* *The stateless TREX traffic generator*: The main traffic generator used as + Network Service stimulus is open source TREX tool. - The TREX tool can generate any kind of stateless traffic. +The TREX tool can generate any kind of stateless traffic. - .. code-block:: console - - +--------+ +-------+ +--------+ - | | | | | | - | Trex | ---> | VNF | ---> | Trex | - | | | | | | - +--------+ +-------+ +--------+ - - Supported testcases scenarios: +.. code-block:: console - - Correlated UDP traffic using TREX traffic generator and replay VNF. + +--------+ +-------+ +--------+ + | | | | | | + | Trex | ---> | VNF | ---> | Trex | + | | | | | | + +--------+ +-------+ +--------+ - - using different IMIX configuration like pure voice, pure video traffic etc +Supported testcases scenarios: - - using different number IP flows like 1 flow, 1K, 16K, 64K, 256K, 1M flows +* Correlated UDP traffic using TREX traffic generator and replay VNF. - - Using different number of rules configured like 1 rule, 1K, 10K rules + * using different IMIX configuration like pure voice, pure video traffic etc + * using different number IP flows e.g. 1, 1K, 16K, 64K, 256K, 1M flows + * Using different number of rules configured e.g. 1, 1K, 10K rules - For UDP correlated traffic following Key Performance Indicators are collected - for every combination of test case parameters: +For UDP correlated traffic following Key Performance Indicators are collected +for every combination of test case parameters: - - RFC2544 throughput for various loss rate defined (1% is a default) +* RFC2544 throughput for various loss rate defined (1% is a default) Graphical Overview ================== -NSB Testing with yardstick framework facilitate performance testing of various +NSB Testing with Yardstick framework facilitate performance testing of various VNFs provided. .. code-block:: console +-----------+ - | | +-----------+ - | vPE | ->|TGen Port 0| - | TestCase | | +-----------+ - | | | - +-----------+ +------------------+ +-------+ | - | | -- API --> | VNF | <---> - +-----------+ | Yardstick | +-------+ | - | Test Case | --> | NSB Testing | | - +-----------+ | | | - | | | | - | +------------------+ | - +-----------+ | +-----------+ - | Traffic | ->|TGen Port 1| - | patterns | +-----------+ + | | +-------------+ + | vPE | -->| TGen Port 0 | + | TestCase | | +-------------+ + | | | + +-----------+ +---------------+ +-------+ | + | | ---> | VNF | <---> + +-----------+ | Yardstick | +-------+ | + | Test Case | --> | NSB Testing | | + +-----------+ | | | + | | | | + | +---------------+ | + +-----------+ | +-------------+ + | Traffic | -->| TGen Port 1 | + | patterns | +-------------+ +-----------+ Figure 1: Network Service - 2 server configuration @@ -199,8 +181,8 @@ VNFs supported for chracterization: 2. vFW - Virtual Firewall 3. vACL - Access Control List 4. Prox - Packet pROcessing eXecution engine: - - VNF can act as Drop, Basic Forwarding (no touch), - L2 Forwarding (change MAC), GRE encap/decap, Load balance based on - packet fields, Symmetric load balancing - - QinQ encap/decap IPv4/IPv6, ARP, QoS, Routing, Unmpls, Policing, ACL + * VNF can act as Drop, Basic Forwarding (no touch), + L2 Forwarding (change MAC), GRE encap/decap, Load balance based on + packet fields, Symmetric load balancing + * QinQ encap/decap IPv4/IPv6, ARP, QoS, Routing, Unmpls, Policing, ACL 5. UDP_Replay diff --git a/docs/testing/user/userguide/13-nsb-installation.rst b/docs/testing/user/userguide/13-nsb-installation.rst index 973d56628..69f6a5a40 100644 --- a/docs/testing/user/userguide/13-nsb-installation.rst +++ b/docs/testing/user/userguide/13-nsb-installation.rst @@ -14,12 +14,12 @@ Avoid deeper levels because they do not render well. -===================================== -Yardstick - NSB Testing -Installation -===================================== +================ +NSB Installation +================ -Abstract --------- +.. _OVS-DPDK: http://docs.openvswitch.org/en/latest/intro/install/dpdk/ +.. _devstack: https://docs.openstack.org/devstack/pike/> The Network Service Benchmarking (NSB) extends the yardstick framework to do VNF characterization and benchmarking in three different execution @@ -32,16 +32,16 @@ according to user defined profiles. The steps needed to run Yardstick with NSB testing are: * Install Yardstick (NSB Testing). -* Setup/Reference pod.yaml describing Test topology -* Create/Reference the test configuration yaml file. +* Setup/reference ``pod.yaml`` describing Test topology +* Create/reference the test configuration yaml file. * Run the test case. Prerequisites ------------- -Refer chapter Yardstick Installation for more information on yardstick -prerequisites +Refer to :doc:`04-installation` for more information on Yardstick +prerequisites. Several prerequisites are needed for Yardstick (VNF testing): @@ -61,7 +61,6 @@ Hardware & Software Ingredients SUT requirements: - ======= =================== Item Description ======= =================== @@ -93,29 +92,25 @@ Boot and BIOS settings: Turbo Boost Disabled ============= ================================================= - - Install Yardstick (NSB Testing) ------------------------------- -Download the source code and install Yardstick from it +Download the source code and check out the latest stable branch:: .. code-block:: console git clone https://gerrit.opnfv.org/gerrit/yardstick - cd yardstick - # Switch to latest stable branch - # git checkout <tag or stable branch> - git checkout stable/euphrates + git checkout stable/gambia Configure the network proxy, either using the environment variables or setting -the global environment file: +the global environment file. + +* Set environment -.. code-block:: ini +.. code-block:: - cat /etc/environment http_proxy='http://proxy.company.com:port' https_proxy='http://proxy.company.com:port' @@ -124,14 +119,11 @@ the global environment file: export http_proxy='http://proxy.company.com:port' export https_proxy='http://proxy.company.com:port' -The last step is to modify the Yardstick installation inventory, used by -Ansible: - -.. code-block:: ini +Modify the Yardstick installation inventory, used by Ansible:: cat ./ansible/install-inventory.ini [jumphost] - localhost ansible_connection=local + localhost ansible_connection=local [yardstick-standalone] yardstick-standalone-node ansible_host=192.168.1.2 @@ -148,35 +140,29 @@ Ansible: .. note:: - SSH access without password needs to be configured for all your nodes defined in - ``install-inventory.ini`` file. - If you want to use password authentication you need to install sshpass - - .. code-block:: console + SSH access without password needs to be configured for all your nodes + defined in ``yardstick-install-inventory.ini`` file. + If you want to use password authentication you need to install ``sshpass``:: sudo -EH apt-get install sshpass -To execute an installation for a Bare-Metal or a Standalone context: - -.. code-block:: console +To execute an installation for a BareMetal or a Standalone context:: ./nsb_setup.sh -To execute an installation for an OpenStack context: - -.. code-block:: console +To execute an installation for an OpenStack context:: ./nsb_setup.sh <path to admin-openrc.sh> -Above command setup docker with latest yardstick code. To execute - -.. code-block:: console +The above commands will set up Docker with the latest Yardstick code. To +execute:: docker exec -it yardstick bash It will also automatically download all the packages needed for NSB Testing -setup. Refer chapter :doc:`04-installation` for more on docker +setup. Refer chapter :doc:`04-installation` for more on Docker + **Install Yardstick using Docker (recommended)** Another way to execute an installation for a Bare-Metal or a Standalone context @@ -201,24 +187,22 @@ System Topology Environment parameters and credentials -------------------------------------- -Config yardstick conf -~~~~~~~~~~~~~~~~~~~~~ +Configure yardstick.conf +^^^^^^^^^^^^^^^^^^^^^^^^ -If user did not run 'yardstick env influxdb' inside the container, which will -generate correct ``yardstick.conf``, then create the config file manually (run -inside the container): -:: +If you did not run ``yardstick env influxdb`` inside the container to generate + ``yardstick.conf``, then create the config file manually (run inside the +container):: cp ./etc/yardstick/yardstick.conf.sample /etc/yardstick/yardstick.conf vi /etc/yardstick/yardstick.conf -Add trex_path, trex_client_lib and bin_path in 'nsb' section. - -:: +Add ``trex_path``, ``trex_client_lib`` and ``bin_path`` to the ``nsb`` +section:: [DEFAULT] debug = True - dispatcher = file, influxdb + dispatcher = influxdb [dispatcher_influxdb] timeout = 5 @@ -235,18 +219,26 @@ Add trex_path, trex_client_lib and bin_path in 'nsb' section. Run Yardstick - Network Service Testcases ----------------------------------------- - NS testing - using yardstick CLI ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ See :doc:`04-installation` -.. code-block:: console +Connect to the Yardstick container:: docker exec -it yardstick /bin/bash - source /etc/yardstick/openstack.creds (only for heat TC if nsb_setup.sh was NOT used) - export EXTERNAL_NETWORK="<openstack public network>" (only for heat TC) + +If you're running ``heat`` testcases and ``nsb_setup.sh`` was not used:: + source /etc/yardstick/openstack.creds + +In addition to the above, you need to se the ``EXTERNAL_NETWORK`` for +OpenStack:: + + export EXTERNAL_NETWORK="<openstack public network>" + +Finally, you should be able to run the testcase:: + yardstick --debug task start yardstick/samples/vnf_samples/nsut/<vnf>/<test case> Network Service Benchmarking - Bare-Metal @@ -284,8 +276,8 @@ Bare-Metal 3-Node setup - Correlated Traffic Bare-Metal Config pod.yaml -~~~~~~~~~~~~~~~~~~~~~~~~~~ -Before executing Yardstick test cases, make sure that pod.yaml reflects the +^^^^^^^^^^^^^^^^^^^^^^^^^^ +Before executing Yardstick test cases, make sure that ``pod.yaml`` reflects the topology and update all the required fields.:: cp /etc/yardstick/nodes/pod.yaml.nsb.sample /etc/yardstick/nodes/pod.yaml @@ -368,12 +360,10 @@ SR-IOV Pre-requisites +++++++++++++++++++++ On Host, where VM is created: - a) Create and configure a bridge named ``br-int`` for VM to connect to external network. - Currently this can be done using VXLAN tunnel. + a) Create and configure a bridge named ``br-int`` for VM to connect to + external network. Currently this can be done using VXLAN tunnel. - Execute the following on host, where VM is created: - - .. code-block:: console + Execute the following on host, where VM is created:: ip link add type vxlan remote <Jumphost IP> local <DUT IP> id <ID: 10> dstport 4789 brctl addbr br-int @@ -382,7 +372,7 @@ On Host, where VM is created: ip addr add <IP#1, like: 172.20.2.1/24> dev br-int ip link set dev br-int up - .. note:: May be needed to add extra rules to iptable to forward traffic. + .. note:: You may need to add extra rules to iptable to forward traffic. .. code-block:: console @@ -416,23 +406,24 @@ On Host, where VM is created: Yardstick has a tool for building this custom image with SampleVNF. It is necessary to have ``sudo`` rights to use this tool. - Also you may need to install several additional packages to use this tool, by - following the commands below:: - - sudo apt-get update && sudo apt-get install -y qemu-utils kpartx + Also you may need to install several additional packages to use this tool, by + following the commands below:: - This image can be built using the following command in the directory where Yardstick is installed + sudo apt-get update && sudo apt-get install -y qemu-utils kpartx - .. code-block:: console + This image can be built using the following command in the directory where + Yardstick is installed:: - export YARD_IMG_ARCH='amd64' - sudo echo "Defaults env_keep += \'YARD_IMG_ARCH\'" >> /etc/sudoers + export YARD_IMG_ARCH='amd64' + sudo echo "Defaults env_keep += \'YARD_IMG_ARCH\'" >> /etc/sudoers - Please use ansible script to generate a cloud image refer to :doc:`04-installation` + For instructions on generating a cloud image using Ansible, refer to + :doc:`04-installation`. - for more details refer to chapter :doc:`04-installation` + for more details refer to chapter :doc:`04-installation` - .. note:: VM should be build with static IP and should be accessible from yardstick host. + .. note:: VM should be build with static IP and be accessible from the + Yardstick host. SR-IOV Config pod.yaml describing Topology @@ -457,10 +448,10 @@ SR-IOV 2-Node setup +----------+ +-------------------------+ | | | ^ ^ | | | | | | | - | | (0)<----->(0) | ------ | | - | TG1 | | SUT | | - | | | | | - | | (n)<----->(n) |------------------ | + | | (0)<----->(0) | ------ SUT | | + | TG1 | | | | + | | (n)<----->(n) | ----------------- | + | | | | +----------+ +-------------------------+ trafficgen_1 host @@ -470,29 +461,29 @@ SR-IOV 3-Node setup - Correlated Traffic ++++++++++++++++++++++++++++++++++++++++ .. code-block:: console - +--------------------+ - | | - | | - | DUT | - | (VNF) | - | | - +--------------------+ - | VF NIC | | VF NIC | - +--------+ +--------+ - ^ ^ - | | - | | - +----------+ +-------------------------+ +--------------+ - | | | ^ ^ | | | - | | | | | | | | - | | (0)<----->(0) | ------ | | | TG2 | - | TG1 | | SUT | | | (UDP Replay) | - | | | | | | | - | | (n)<----->(n) | ------ | (n)<-->(n) | | - +----------+ +-------------------------+ +--------------+ - trafficgen_1 host trafficgen_2 - -Before executing Yardstick test cases, make sure that pod.yaml reflects the + +--------------------+ + | | + | | + | DUT | + | (VNF) | + | | + +--------------------+ + | VF NIC | | VF NIC | + +--------+ +--------+ + ^ ^ + | | + | | + +----------+ +---------------------+ +--------------+ + | | | ^ ^ | | | + | | | | | | | | + | | (0)<----->(0) |----- | | | TG2 | + | TG1 | | SUT | | | (UDP Replay) | + | | | | | | | + | | (n)<----->(n) | -----| (n)<-->(n) | | + +----------+ +---------------------+ +--------------+ + trafficgen_1 host trafficgen_2 + +Before executing Yardstick test cases, make sure that ``pod.yaml`` reflects the topology and update all the required fields. .. code-block:: console @@ -599,8 +590,8 @@ OVS-DPDK Pre-requisites ~~~~~~~~~~~~~~~~~~~~~~~ On Host, where VM is created: - a) Create and configure a bridge named ``br-int`` for VM to connect to external network. - Currently this can be done using VXLAN tunnel. + a) Create and configure a bridge named ``br-int`` for VM to connect to + external network. Currently this can be done using VXLAN tunnel. Execute the following on host, where VM is created: @@ -647,26 +638,27 @@ On Host, where VM is created: Yardstick has a tool for building this custom image with SampleVNF. It is necessary to have ``sudo`` rights to use this tool. - Also you may need to install several additional packages to use this tool, by - following the commands below:: + You may need to install several additional packages to use this tool, by + following the commands below:: - sudo apt-get update && sudo apt-get install -y qemu-utils kpartx + sudo apt-get update && sudo apt-get install -y qemu-utils kpartx - This image can be built using the following command in the directory where Yardstick is installed:: + This image can be built using the following command in the directory where + Yardstick is installed:: - export YARD_IMG_ARCH='amd64' - sudo echo "Defaults env_keep += \'YARD_IMG_ARCH\'" >> /etc/sudoers - sudo tools/yardstick-img-dpdk-modify tools/ubuntu-server-cloudimg-samplevnf-modify.sh + export YARD_IMG_ARCH='amd64' + sudo echo "Defaults env_keep += \'YARD_IMG_ARCH\'" >> /etc/sudoers + sudo tools/yardstick-img-dpdk-modify tools/ubuntu-server-cloudimg-samplevnf-modify.sh - for more details refer to chapter :doc:`04-installation` + for more details refer to chapter :doc:`04-installation` - .. note:: VM should be build with static IP and should be accessible from yardstick host. + .. note:: VM should be build with static IP and should be accessible from + yardstick host. - c) OVS & DPDK version. - - OVS 2.7 and DPDK 16.11.1 above version is supported +3. OVS & DPDK version. + * OVS 2.7 and DPDK 16.11.1 above version is supported - d) Setup OVS/DPDK on host. - Please refer to below link on how to setup `OVS-DPDK <http://docs.openvswitch.org/en/latest/intro/install/dpdk/>`_ +4. Setup `OVS-DPDK`_ on host. OVS-DPDK Config pod.yaml describing Topology @@ -732,10 +724,8 @@ OVS-DPDK 3-Node setup - Correlated Traffic trafficgen_1 host trafficgen_2 -Before executing Yardstick test cases, make sure that pod.yaml reflects the -topology and update all the required fields. - -.. code-block:: console +Before executing Yardstick test cases, make sure that the ``pod.yaml`` reflects +the topology and update all the required fields:: cp <yardstick>/etc/yardstick/nodes/standalone/trex_bm.yaml.sample /etc/yardstick/nodes/standalone/pod_trex.yaml cp <yardstick>/etc/yardstick/nodes/standalone/host_ovs.yaml /etc/yardstick/nodes/standalone/host_ovs.yaml @@ -883,26 +873,22 @@ Single node OpenStack setup with external TG Host pre-configuration ++++++++++++++++++++++ -.. warning:: The following configuration requires sudo access to the system. Make - sure that your user have the access. +.. warning:: The following configuration requires sudo access to the system. + Make sure that your user have the access. -Enable the Intel VT-d or AMD-Vi extension in the BIOS. Some system manufacturers -disable this extension by default. +Enable the Intel VT-d or AMD-Vi extension in the BIOS. Some system +manufacturers disable this extension by default. Activate the Intel VT-d or AMD-Vi extension in the kernel by modifying the GRUB config file ``/etc/default/grub``. -For the Intel platform: - -.. code:: bash +For the Intel platform:: ... GRUB_CMDLINE_LINUX_DEFAULT="intel_iommu=on" ... -For the AMD platform: - -.. code:: bash +For the AMD platform:: ... GRUB_CMDLINE_LINUX_DEFAULT="amd_iommu=on" @@ -917,9 +903,7 @@ Update the grub configuration file and restart the system: sudo update-grub sudo reboot -Make sure the extension has been enabled: - -.. code:: bash +Make sure the extension has been enabled:: sudo journalctl -b 0 | grep -e IOMMU -e DMAR @@ -932,6 +916,8 @@ Make sure the extension has been enabled: Feb 06 14:50:14 hostname kernel: DMAR: dmar1: reg_base_addr e0ffc000 ver 1:0 cap 8d2078c106f0466 ecap f020de Feb 06 14:50:14 hostname kernel: DMAR: DRHD base: 0x000000ee7fc000 flags: 0x0 +.. TODO: Refer to the yardstick installation guide for proxy set up + Setup system proxy (if needed). Add the following configuration into the ``/etc/environment`` file: @@ -954,13 +940,11 @@ Upgrade the system: sudo -EH apt-get upgrade sudo -EH apt-get dist-upgrade -Install dependencies needed for the DevStack +Install dependencies needed for DevStack .. code:: bash - sudo -EH apt-get install python - sudo -EH apt-get install python-dev - sudo -EH apt-get install python-pip + sudo -EH apt-get install python python-dev python-pip Setup SR-IOV ports on the host: @@ -983,10 +967,10 @@ Setup SR-IOV ports on the host: DevStack installation +++++++++++++++++++++ -Use official `Devstack <https://docs.openstack.org/devstack/pike/>`_ -documentation to install OpenStack on a host. Please note, that stable -``pike`` branch of devstack repo should be used during the installation. -The required `local.conf`` configuration file are described below. +If you want to try out NSB, but don't have OpenStack set-up, you can use +`Devstack`_ to install OpenStack on a host. Please note, that the +``stable/pike`` branch of devstack repo should be used during the installation. +The required ``local.conf`` configuration file are described below. DevStack configuration file: @@ -1005,11 +989,10 @@ Start the devstack installation on a host. TG host configuration +++++++++++++++++++++ -Yardstick automatically install and configure Trex traffic generator on TG +Yardstick automatically installs and configures Trex traffic generator on TG host based on provided POD file (see below). Anyway, it's recommended to check -the compatibility of the installed NIC on the TG server with software Trex using -the manual at https://trex-tgn.cisco.com/trex/doc/trex_manual.html. - +the compatibility of the installed NIC on the TG server with software Trex +using the `manual <https://trex-tgn.cisco.com/trex/doc/trex_manual.html>`_. Run the Sample VNF test case ++++++++++++++++++++++++++++ @@ -1018,7 +1001,7 @@ There is an example of Sample VNF test case ready to be executed in an OpenStack environment with SR-IOV support: ``samples/vnf_samples/nsut/vfw/ tc_heat_sriov_external_rfc2544_ipv4_1rule_1flow_64B_trex.yaml``. -Install yardstick using `Install Yardstick (NSB Testing)`_ steps for OpenStack +Install Yardstick using `Install Yardstick (NSB Testing)`_ steps for OpenStack context. Create pod file for TG in the yardstick repo folder located in the yardstick @@ -1071,16 +1054,15 @@ Controller/Compute pre-configuration ++++++++++++++++++++++++++++++++++++ Pre-configuration of the controller and compute hosts are the same as -described in `Host pre-configuration`_ section. Follow the steps in the section. +described in `Host pre-configuration`_ section. DevStack configuration ++++++++++++++++++++++ -Use official `Devstack <https://docs.openstack.org/devstack/pike/>`_ -documentation to install OpenStack on a host. Please note, that stable -``pike`` branch of devstack repo should be used during the installation. -The required `local.conf`` configuration file are described below. +A reference ``local.conf`` for deploying OpenStack in a multi-host environment +using `Devstack`_ is shown in this section. The ``stable/pike`` branch of +devstack repo should be used during the installation. .. note:: Update the devstack configuration files by replacing angluar brackets with a short description inside. @@ -1104,13 +1086,14 @@ Start the devstack installation on the controller and compute hosts. Run the sample vFW TC +++++++++++++++++++++ -Install yardstick using `Install Yardstick (NSB Testing)`_ steps for OpenStack +Install Yardstick using `Install Yardstick (NSB Testing)`_ steps for OpenStack context. -Run sample vFW RFC2544 SR-IOV TC (``samples/vnf_samples/nsut/vfw/ -tc_heat_rfc2544_ipv4_1rule_1flow_64B_trex.yaml``) in the heat -context using steps described in `NS testing - using yardstick CLI`_ section -and the following yardtick command line arguments: +Run the sample vFW RFC2544 SR-IOV test case +(``samples/vnf_samples/nsut/vfw/tc_heat_rfc2544_ipv4_1rule_1flow_64B_trex.yaml``) +in the heat context using steps described in +`NS testing - using yardstick CLI`_ section and the following Yardstick command +line arguments: .. code:: bash @@ -1118,8 +1101,8 @@ and the following yardtick command line arguments: samples/vnf_samples/nsut/vfw/tc_heat_rfc2544_ipv4_1rule_1flow_64B_trex.yaml -Enabling other Traffic generator --------------------------------- +Enabling other Traffic generators +--------------------------------- IxLoad ~~~~~~ @@ -1138,14 +1121,16 @@ IxLoad .. code-block:: console - cp <repo>/etc/yardstick/nodes/pod.yaml.nsb.sample.ixia etc/yardstick/nodes/pod_ixia.yaml + cp <repo>/etc/yardstick/nodes/pod.yaml.nsb.sample.ixia \ + etc/yardstick/nodes/pod_ixia.yaml Config ``pod_ixia.yaml`` .. literalinclude:: code/pod_ixia.yaml :language: console - for sriov/ovs_dpdk pod files, please refer to above Standalone Virtualization for ovs-dpdk/sriov configuration + for sriov/ovs_dpdk pod files, please refer to `Standalone Virtualization`_ + for ovs-dpdk/sriov configuration 3. Start IxOS TCL Server (Install 'Ixia IxExplorer IxOS <version>') You will also need to configure the IxLoad machine to start the IXIA @@ -1155,7 +1140,7 @@ IxLoad * Go to: ``Start->Programs->Ixia->IxOS->IxOS 8.01-GA-Patch1->Ixia Tcl Server IxOS 8.01-GA-Patch1`` or - ``"C:\Program Files (x86)\Ixia\IxOS\8.01-GA-Patch1\ixTclServer.exe"`` + ``C:\Program Files (x86)\Ixia\IxOS\8.01-GA-Patch1\ixTclServer.exe`` 4. Create a folder ``Results`` in c:\ and share the folder on the network. @@ -1172,14 +1157,16 @@ installed as part of the requirements of the project. .. code-block:: console - cp <repo>/etc/yardstick/nodes/pod.yaml.nsb.sample.ixia etc/yardstick/nodes/pod_ixia.yaml + cp <repo>/etc/yardstick/nodes/pod.yaml.nsb.sample.ixia \ + etc/yardstick/nodes/pod_ixia.yaml - Config pod_ixia.yaml + Configure ``pod_ixia.yaml`` .. literalinclude:: code/pod_ixia.yaml :language: console - for sriov/ovs_dpdk pod files, please refer to above Standalone Virtualization for ovs-dpdk/sriov configuration + for sriov/ovs_dpdk pod files, please refer to above + `Standalone Virtualization`_ for ovs-dpdk/sriov configuration 2. Start IxNetwork TCL Server You will also need to configure the IxNetwork machine to start the IXIA diff --git a/docs/testing/user/userguide/14-nsb-operation.rst b/docs/testing/user/userguide/14-nsb-operation.rst index 72b1c4bbc..910985069 100644 --- a/docs/testing/user/userguide/14-nsb-operation.rst +++ b/docs/testing/user/userguide/14-nsb-operation.rst @@ -89,9 +89,9 @@ Availability zone ^^^^^^^^^^^^^^^^^ The configuration of the availability zone is requred in cases where location -of exact compute host/group of compute hosts needs to be specified for SampleVNF -or traffic generator in the heat test case. If this is the case, please follow -the instructions below. +of exact compute host/group of compute hosts needs to be specified for +:term:`SampleVNF` or traffic generator in the heat test case. If this is the +case, please follow the instructions below. .. _`Create a host aggregate`: @@ -105,7 +105,8 @@ the instructions below. .. code-block:: bash # create host aggregate - openstack aggregate create --zone <AZ_NAME> --property availability_zone=<AZ_NAME> <AGG_NAME> + openstack aggregate create --zone <AZ_NAME> \ + --property availability_zone=<AZ_NAME> <AGG_NAME> # show available hosts openstack compute service list --service nova-compute # add selected host into the host aggregate @@ -136,8 +137,9 @@ the instructions below. networks: ... -There are two example of SampleVNF scale out test case which use the availability zone -feature to specify the exact location of scaled VNFs and traffic generators. +There are two example of SampleVNF scale out test case which use the +``availability zone`` feature to specify the exact location of scaled VNFs and +traffic generators. Those are: @@ -164,21 +166,19 @@ Those are: | 5 | agg1 | AZ_NAME_1 | +----+------+-------------------+ -2. If no host aggregates are configured, please use `steps above`__ to - configure them. +2. If no host aggregates are configured, please follow the instructions to + `Create a host aggregate`_ -__ `Create a host aggregate`_ - -3. Run the SampleVNF PROX scale-out test case, specifying the availability - zone of each VNF and traffic generator as a task arguments. +3. Run the SampleVNF PROX scale-out test case, specifying the + ``availability zone`` of each VNF and traffic generator as task arguments. .. note:: The ``az_0`` and ``az_1`` should be changed according to the host - aggregates created in the OpenStack. + aggregates created in the OpenStack. .. code-block:: console - yardstick -d task start\ + yardstick -d task start \ <repo>/samples/vnf_samples/nsut/prox/tc_prox_heat_context_l2fwd_multiflow-2-scale-out.yaml\ --task-args='{ "num_vnfs": 4, "availability_zone": { @@ -198,7 +198,7 @@ Collectd KPIs ------------- NSB can collect KPIs from collected. We have support for various plugins -enabled by the Barometer project. +enabled by the :term:`Barometer` project. The default yardstick-samplevnf has collectd installed. This allows for collecting KPIs from the VNF. @@ -208,12 +208,11 @@ We assume that collectd is not installed on the compute nodes. To collectd KPIs from the NFVi compute nodes: - * install_collectd on the compute nodes * create pod.yaml for the compute nodes * enable specific plugins depending on the vswitch and DPDK - example pod.yaml section for Compute node running collectd. + example ``pod.yaml`` section for Compute node running collectd. .. code-block:: yaml @@ -356,8 +355,8 @@ Scale-Out VNFs performance data with scale-out helps - * in capacity planning to meet the given network node requirements - * in comparison between different VNF vendor offerings + * capacity planning to meet the given network node requirements + * comparison between different VNF vendor offerings * better the scale-out index, provides the flexibility in meeting future capacity requirements @@ -488,11 +487,11 @@ Default values for OVS-DPDK: Sample test case file ^^^^^^^^^^^^^^^^^^^^^ - 1. Prepare SampleVNF image and copy it to ``flavor/images``. - 2. Prepare context files for TREX and SampleVNF under ``contexts/file``. - 3. Add bridge named ``br-int`` to the baremetal where SampleVNF image is deployed. - 4. Modify ``networks/phy_port`` accordingly to the baremetal setup. - 5. Run test from: +1. Prepare SampleVNF image and copy it to ``flavor/images``. +2. Prepare context files for TREX and SampleVNF under ``contexts/file``. +3. Add bridge named ``br-int`` to the baremetal where SampleVNF image is deployed. +4. Modify ``networks/phy_port`` accordingly to the baremetal setup. +5. Run test from: .. literalinclude:: /../samples/vnf_samples/nsut/acl/tc_ovs_rfc2544_ipv4_1rule_1flow_64B_trex.yaml :language: yaml |