From fd54fcc22170aa880fc49730730ad80896e2e608 Mon Sep 17 00:00:00 2001 From: rexlee8776 Date: Wed, 8 Mar 2017 07:12:55 +0000 Subject: Yardstick Preliminary Documentation JIRA: YARDSTICK-554 align with opnfvdocs path structure about testing projects Change-Id: I6c2f2d37e41447dccd76b9f4426d00fd85cb1e3b Signed-off-by: rexlee8776 --- docs/testing/user/userguide/01-introduction.rst | 79 ++++ docs/testing/user/userguide/02-methodology.rst | 195 ++++++++++ docs/testing/user/userguide/03-architecture.rst | 266 ++++++++++++++ docs/testing/user/userguide/04-vtc-overview.rst | 122 +++++++ .../user/userguide/05-apexlake_installation.rst | 300 +++++++++++++++ docs/testing/user/userguide/06-apexlake_api.rst | 89 +++++ docs/testing/user/userguide/07-nsb-overview.rst | 177 +++++++++ .../testing/user/userguide/08-nsb_installation.rst | 253 +++++++++++++ docs/testing/user/userguide/09-installation.rst | 401 +++++++++++++++++++++ .../testing/user/userguide/10-yardstick_plugin.rst | 144 ++++++++ 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This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +============ +Introduction +============ + +**Welcome to Yardstick's documentation !** + +.. _Pharos: https://wiki.opnfv.org/pharos +.. _Yardstick: https://wiki.opnfv.org/yardstick +.. _Presentation: https://wiki.opnfv.org/download/attachments/2925202/opnfv_summit_-_yardstick_project.pdf?version=1&modificationDate=1458848320000&api=v2 +Yardstick_ is an OPNFV Project. + +The project's goal is to verify infrastructure compliance, from the perspective +of a Virtual Network Function (:term:`VNF`). + +The Project's scope is the development of a test framework, *Yardstick*, test +cases and test stimuli to enable Network Function Virtualization Infrastructure +(:term:`NFVI`) verification. +The Project also includes a sample :term:`VNF`, the Virtual Traffic Classifier +(:term:`VTC`) and its experimental framework, *ApexLake* ! + +*Yardstick* is used in OPNFV for verifying the OPNFV infrastructure and some of +the OPNFV features. The *Yardstick* framework is deployed in several OPNFV +community labs. It is *installer*, *infrastructure* and *application* +independent. + +.. seealso:: Pharos_ for information on OPNFV community labs and this + Presentation_ for an overview of *Yardstick* + + +About This Document +=================== + +This document consists of the following chapters: + +* Chapter :doc:`02-methodology` describes the methodology implemented by the + Yardstick Project for :term:`NFVI` verification. + +* Chapter :doc:`03-architecture` provides information on the software architecture + of yardstick. + +* Chapter :doc:`04-vtc-overview` provides information on the :term:`VTC`. + +* Chapter :doc:`05-apexlake_installation` provides instructions to install the + experimental framework *ApexLake* + +* Chapter :doc:`06-apexlake_api` explains how this framework is integrated in + *Yardstick*. + +* Chapter :doc:`07-nsb-overview` describes the methodology implemented by the + yardstick - Network service benchmarking to test real world usecase for a + given VNF + +* Chapter :doc:`08-nsb_installation` provides instructions to install + *Yardstick - Network service benchmarking testing*. + +* Chapter :doc:`09-installation` provides instructions to install *Yardstick*. + +* Chapter :doc:`10-yardstick_plugin` provides information on how to integrate + other OPNFV testing projects into *Yardstick*. + +* Chapter :doc:`11-result-store-InfluxDB` provides inforamtion on how to run + plug-in test cases and store test results into community's InfluxDB. + +* Chapter :doc:`12-list-of-tcs` includes a list of available Yardstick test + cases. + + +Contact Yardstick +================= + +Feedback? `Contact us`_ + +.. _Contact us: opnfv-users@lists.opnfv.org + diff --git a/docs/testing/user/userguide/02-methodology.rst b/docs/testing/user/userguide/02-methodology.rst new file mode 100644 index 000000000..34d271095 --- /dev/null +++ b/docs/testing/user/userguide/02-methodology.rst @@ -0,0 +1,195 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +=========== +Methodology +=========== + +Abstract +======== + +This chapter describes the methodology implemented by the Yardstick project for +verifying the :term:`NFVI` from the perspective of a :term:`VNF`. + +ETSI-NFV +======== + +.. _NFV-TST001: http://www.etsi.org/deliver/etsi_gs/NFV-TST/001_099/001/01.01.01_60/gs_NFV-TST001v010101p.pdf +.. _Yardsticktst: https://wiki.opnfv.org/download/attachments/2925202/opnfv_summit_-_bridging_opnfv_and_etsi.pdf?version=1&modificationDate=1458848320000&api=v2 + + +The document ETSI GS NFV-TST001_, "Pre-deployment Testing; Report on Validation +of NFV Environments and Services", recommends methods for pre-deployment +testing of the functional components of an NFV environment. + +The Yardstick project implements the methodology described in chapter 6, "Pre- +deployment validation of NFV infrastructure". + +The methodology consists in decomposing the typical :term:`VNF` work-load +performance metrics into a number of characteristics/performance vectors, which +each can be represented by distinct test-cases. + +The methodology includes five steps: + +* *Step1:* Define Infrastruture - the Hardware, Software and corresponding + configuration target for validation; the OPNFV infrastructure, in OPNFV + community labs. + +* *Step2:* Identify :term:`VNF` type - the application for which the + infrastructure is to be validated, and its requirements on the underlying + infrastructure. + +* *Step3:* Select test cases - depending on the workload that represents the + application for which the infrastruture is to be validated, the relevant + test cases amongst the list of available Yardstick test cases. + +* *Step4:* Execute tests - define the duration and number of iterations for the + selected test cases, tests runs are automated via OPNFV Jenkins Jobs. + +* *Step5:* Collect results - using the common API for result collection. + +.. seealso:: Yardsticktst_ for material on alignment ETSI TST001 and Yardstick. + +Metrics +======= + +The metrics, as defined by ETSI GS NFV-TST001, are shown in +:ref:`Table1 `, :ref:`Table2 ` and +:ref:`Table3 `. + +In OPNFV Colorado release, generic test cases covering aspects of the listed +metrics are available; further OPNFV releases will provide extended testing of +these metrics. +The view of available Yardstick test cases cross ETSI definitions in +:ref:`Table1 `, :ref:`Table2 ` and :ref:`Table3 ` +is shown in :ref:`Table4 `. +It shall be noticed that the Yardstick test cases are examples, the test +duration and number of iterations are configurable, as are the System Under +Test (SUT) and the attributes (or, in Yardstick nomemclature, the scenario +options). + +.. _table2_1: + +**Table 1 - Performance/Speed Metrics** + ++---------+-------------------------------------------------------------------+ +| Category| Performance/Speed | +| | | ++---------+-------------------------------------------------------------------+ +| Compute | * Latency for random memory access | +| | * Latency for cache read/write operations | +| | * Processing speed (instructions per second) | +| | * Throughput for random memory access (bytes per second) | +| | | ++---------+-------------------------------------------------------------------+ +| Network | * Throughput per NFVI node (frames/byte per second) | +| | * Throughput provided to a VM (frames/byte per second) | +| | * Latency per traffic flow | +| | * Latency between VMs | +| | * Latency between NFVI nodes | +| | * Packet delay variation (jitter) between VMs | +| | * Packet delay variation (jitter) between NFVI nodes | +| | | ++---------+-------------------------------------------------------------------+ +| Storage | * Sequential read/write IOPS | +| | * Random read/write IOPS | +| | * Latency for storage read/write operations | +| | * Throughput for storage read/write operations | +| | | ++---------+-------------------------------------------------------------------+ + +.. _table2_2: + +**Table 2 - Capacity/Scale Metrics** + ++---------+-------------------------------------------------------------------+ +| Category| Capacity/Scale | +| | | ++---------+-------------------------------------------------------------------+ +| Compute | * Number of cores and threads- Available memory size | +| | * Cache size | +| | * Processor utilization (max, average, standard deviation) | +| | * Memory utilization (max, average, standard deviation) | +| | * Cache utilization (max, average, standard deviation) | +| | | ++---------+-------------------------------------------------------------------+ +| Network | * Number of connections | +| | * Number of frames sent/received | +| | * Maximum throughput between VMs (frames/byte per second) | +| | * Maximum throughput between NFVI nodes (frames/byte per second) | +| | * Network utilization (max, average, standard deviation) | +| | * Number of traffic flows | +| | | ++---------+-------------------------------------------------------------------+ +| Storage | * Storage/Disk size | +| | * Capacity allocation (block-based, object-based) | +| | * Block size | +| | * Maximum sequential read/write IOPS | +| | * Maximum random read/write IOPS | +| | * Disk utilization (max, average, standard deviation) | +| | | ++---------+-------------------------------------------------------------------+ + +.. _table2_3: + +**Table 3 - Availability/Reliability Metrics** + ++---------+-------------------------------------------------------------------+ +| Category| Availability/Reliability | +| | | ++---------+-------------------------------------------------------------------+ +| Compute | * Processor availability (Error free processing time) | +| | * Memory availability (Error free memory time) | +| | * Processor mean-time-to-failure | +| | * Memory mean-time-to-failure | +| | * Number of processing faults per second | +| | | ++---------+-------------------------------------------------------------------+ +| Network | * NIC availability (Error free connection time) | +| | * Link availability (Error free transmission time) | +| | * NIC mean-time-to-failure | +| | * Network timeout duration due to link failure | +| | * Frame loss rate | +| | | ++---------+-------------------------------------------------------------------+ +| Storage | * Disk availability (Error free disk access time) | +| | * Disk mean-time-to-failure | +| | * Number of failed storage read/write operations per second | +| | | ++---------+-------------------------------------------------------------------+ + +.. _table2_4: + +**Table 4 - Yardstick Generic Test Cases** + ++---------+-------------------+----------------+------------------------------+ +| Category| Performance/Speed | Capacity/Scale | Availability/Reliability | +| | | | | ++---------+-------------------+----------------+------------------------------+ +| Compute | TC003 [1]_ | TC003 [1]_ | TC013 [1]_ | +| | TC004 | TC004 | TC015 [1]_ | +| | TC010 | TC024 | | +| | TC012 | TC055 | | +| | TC014 | | | +| | TC069 | | | ++---------+-------------------+----------------+------------------------------+ +| Network | TC001 | TC044 | TC016 [1]_ | +| | TC002 | TC073 | TC018 [1]_ | +| | TC009 | TC075 | | +| | TC011 | | | +| | TC042 | | | +| | TC043 | | | ++---------+-------------------+----------------+------------------------------+ +| Storage | TC005 | TC063 | TC017 [1]_ | ++---------+-------------------+----------------+------------------------------+ + +.. note:: The description in this OPNFV document is intended as a reference for + users to understand the scope of the Yardstick Project and the + deliverables of the Yardstick framework. For complete description of + the methodology, please refer to the ETSI document. + +.. rubric:: Footnotes +.. [1] To be included in future deliveries. + diff --git a/docs/testing/user/userguide/03-architecture.rst b/docs/testing/user/userguide/03-architecture.rst new file mode 100755 index 000000000..03bf00f58 --- /dev/null +++ b/docs/testing/user/userguide/03-architecture.rst @@ -0,0 +1,266 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) 2016 Huawei Technologies Co.,Ltd and others + +============ +Architecture +============ + +Abstract +======== +This chapter describes the yardstick framework software architecture. we will introduce it from Use-Case View, +Logical View, Process View and Deployment View. More technical details will be introduced in this chapter. + +Overview +======== + +Architecture overview +--------------------- +Yardstick is mainly written in Python, and test configurations are made +in YAML. Documentation is written in reStructuredText format, i.e. .rst +files. Yardstick is inspired by Rally. Yardstick is intended to run on a +computer with access and credentials to a cloud. The test case is described +in a configuration file given as an argument. + +How it works: the benchmark task configuration file is parsed and converted into +an internal model. The context part of the model is converted into a Heat +template and deployed into a stack. Each scenario is run using a runner, either +serially or in parallel. Each runner runs in its own subprocess executing +commands in a VM using SSH. The output of each scenario is written as json +records to a file or influxdb or http server, we use influxdb as the backend, +the test result will be shown with grafana. + + +Concept +------- +**Benchmark** - assess the relative performance of something + +**Benchmark** configuration file - describes a single test case in yaml format + +**Context** - The set of Cloud resources used by a scenario, such as user +names, image names, affinity rules and network configurations. A context is +converted into a simplified Heat template, which is used to deploy onto the +Openstack environment. + +**Data** - Output produced by running a benchmark, written to a file in json format + +**Runner** - Logic that determines how a test scenario is run and reported, for +example the number of test iterations, input value stepping and test duration. +Predefined runner types exist for re-usage, see `Runner types`_. + +**Scenario** - Type/class of measurement for example Ping, Pktgen, (Iperf, LmBench, ...) + +**SLA** - Relates to what result boundary a test case must meet to pass. For +example a latency limit, amount or ratio of lost packets and so on. Action +based on :term:`SLA` can be configured, either just to log (monitor) or to stop +further testing (assert). The :term:`SLA` criteria is set in the benchmark +configuration file and evaluated by the runner. + + +Runner types +------------ + +There exists several predefined runner types to choose between when designing +a test scenario: + +**Arithmetic:** +Every test run arithmetically steps the specified input value(s) in the +test scenario, adding a value to the previous input value. It is also possible +to combine several input values for the same test case in different +combinations. + +Snippet of an Arithmetic runner configuration: +:: + + + runner: + type: Arithmetic + iterators: + - + name: stride + start: 64 + stop: 128 + step: 64 + +**Duration:** +The test runs for a specific period of time before completed. + +Snippet of a Duration runner configuration: +:: + + + runner: + type: Duration + duration: 30 + +**Sequence:** +The test changes a specified input value to the scenario. The input values +to the sequence are specified in a list in the benchmark configuration file. + +Snippet of a Sequence runner configuration: +:: + + + runner: + type: Sequence + scenario_option_name: packetsize + sequence: + - 100 + - 200 + - 250 + + +**Iteration:** +Tests are run a specified number of times before completed. + +Snippet of an Iteration runner configuration: +:: + + + runner: + type: Iteration + iterations: 2 + + + + +Use-Case View +============= +Yardstick Use-Case View shows two kinds of users. One is the Tester who will +do testing in cloud, the other is the User who is more concerned with test result +and result analyses. + +For testers, they will run a single test case or test case suite to verify +infrastructure compliance or bencnmark their own infrastructure performance. +Test result will be stored by dispatcher module, three kinds of store method +(file, influxdb and http) can be configured. The detail information of +scenarios and runners can be queried with CLI by testers. + +For users, they would check test result with four ways. + +If dispatcher module is configured as file(default), there are two ways to +check test result. One is to get result from yardstick.out ( default path: +/tmp/yardstick.out), the other is to get plot of test result, it will be shown +if users execute command "yardstick-plot". + +If dispatcher module is configured as influxdb, users will check test +result on Grafana which is most commonly used for visualizing time series data. + +If dispatcher module is configured as http, users will check test result +on OPNFV testing dashboard which use MongoDB as backend. + +.. image:: images/Use_case.png + :width: 800px + :alt: Yardstick Use-Case View + +Logical View +============ +Yardstick Logical View describes the most important classes, their +organization, and the most important use-case realizations. + +Main classes: + +**TaskCommands** - "yardstick task" subcommand handler. + +**HeatContext** - Do test yaml file context section model convert to HOT, +deploy and undeploy Openstack heat stack. + +**Runner** - Logic that determines how a test scenario is run and reported. + +**TestScenario** - Type/class of measurement for example Ping, Pktgen, (Iperf, +LmBench, ...) + +**Dispatcher** - Choose user defined way to store test results. + +TaskCommands is the "yardstick task" subcommand's main entry. It takes yaml +file (e.g. test.yaml) as input, and uses HeatContext to convert the yaml +file's context section to HOT. After Openstack heat stack is deployed by +HeatContext with the converted HOT, TaskCommands use Runner to run specified +TestScenario. During first runner initialization, it will create output +process. The output process use Dispatcher to push test results. The Runner +will also create a process to execute TestScenario. And there is a +multiprocessing queue between each runner process and output process, so the +runner process can push the real-time test results to the storage media. +TestScenario is commonly connected with VMs by using ssh. It sets up VMs and +run test measurement scripts through the ssh tunnel. After all TestScenaio +is finished, TaskCommands will undeploy the heat stack. Then the whole test is +finished. + +.. image:: images/Logical_view.png + :width: 800px + :alt: Yardstick Logical View + +Process View (Test execution flow) +================================== +Yardstick process view shows how yardstick runs a test case. Below is the +sequence graph about the test execution flow using heat context, and each +object represents one module in yardstick: + +.. image:: images/test_execution_flow.png + :width: 800px + :alt: Yardstick Process View + +A user wants to do a test with yardstick. He can use the CLI to input the +command to start a task. "TaskCommands" will receive the command and ask +"HeatContext" to parse the context. "HeatContext" will then ask "Model" to +convert the model. After the model is generated, "HeatContext" will inform +"Openstack" to deploy the heat stack by heat template. After "Openstack" +deploys the stack, "HeatContext" will inform "Runner" to run the specific test +case. + +Firstly, "Runner" would ask "TestScenario" to process the specific scenario. +Then "TestScenario" will start to log on the openstack by ssh protocal and +execute the test case on the specified VMs. After the script execution +finishes, "TestScenario" will send a message to inform "Runner". When the +testing job is done, "Runner" will inform "Dispatcher" to output the test +result via file, influxdb or http. After the result is output, "HeatContext" +will call "Openstack" to undeploy the heat stack. Once the stack is +undepoyed, the whole test ends. + +Deployment View +=============== +Yardstick deployment view shows how the yardstick tool can be deployed into the +underlying platform. Generally, yardstick tool is installed on JumpServer(see +`07-installation` for detail installation steps), and JumpServer is +connected with other control/compute servers by networking. Based on this +deployment, yardstick can run the test cases on these hosts, and get the test +result for better showing. + +.. image:: images/Deployment.png + :width: 800px + :alt: Yardstick Deployment View + +Yardstick Directory structure +============================= + +**yardstick/** - Yardstick main directory. + +*ci/* - Used for continuous integration of Yardstick at different PODs and + with support for different installers. + +*docs/* - All documentation is stored here, such as configuration guides, + user guides and Yardstick descriptions. + +*etc/* - Used for test cases requiring specific POD configurations. + +*samples/* - test case samples are stored here, most of all scenario and + feature's samples are shown in this directory. + +*tests/* - Here both Yardstick internal tests (*functional/* and *unit/*) as + well as the test cases run to verify the NFVI (*opnfv/*) are stored. + Also configurations of what to run daily and weekly at the different + PODs is located here. + +*tools/* - Currently contains tools to build image for VMs which are deployed + by Heat. Currently contains how to build the yardstick-trusty-server + image with the different tools that are needed from within the image. + +*plugin/* - Plug-in configuration files are stored here. + +*vTC/* - Contains the files for running the virtual Traffic Classifier tests. + +*yardstick/* - Contains the internals of Yardstick: Runners, Scenario, Contexts, + CLI parsing, keys, plotting tools, dispatcher, plugin + install/remove scripts and so on. + diff --git a/docs/testing/user/userguide/04-vtc-overview.rst b/docs/testing/user/userguide/04-vtc-overview.rst new file mode 100644 index 000000000..82b20cad5 --- /dev/null +++ b/docs/testing/user/userguide/04-vtc-overview.rst @@ -0,0 +1,122 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, National Center of Scientific Research "Demokritos" and others. + +========================== +Virtual Traffic Classifier +========================== + +Abstract +======== + +.. _TNOVA: http://www.t-nova.eu/ +.. _TNOVAresults: http://www.t-nova.eu/results/ +.. _Yardstick: https://wiki.opnfv.org/yardstick + +This chapter provides an overview of the virtual Traffic Classifier, a +contribution to OPNFV Yardstick_ from the EU Project TNOVA_. +Additional documentation is available in TNOVAresults_. + +Overview +======== + +The virtual Traffic Classifier (:term:`VTC`) :term:`VNF`, comprises of a +Virtual Network Function Component (:term:`VNFC`). The :term:`VNFC` contains +both the Traffic Inspection module, and the Traffic forwarding module, needed +to run the :term:`VNF`. The exploitation of Deep Packet Inspection +(:term:`DPI`) methods for traffic classification is built around two basic +assumptions: + +* third parties unaffiliated with either source or recipient are able to +inspect each IP packet’s payload + +* the classifier knows the relevant syntax of each application’s packet +payloads (protocol signatures, data patterns, etc.). + +The proposed :term:`DPI` based approach will only use an indicative, small +number of the initial packets from each flow in order to identify the content +and not inspect each packet. + +In this respect it follows the Packet Based per Flow State (term:`PBFS`). This +method uses a table to track each session based on the 5-tuples (src address, +dest address, src port,dest port, transport protocol) that is maintained for +each flow. + +Concepts +======== + +* *Traffic Inspection*: The process of packet analysis and application +identification of network traffic that passes through the :term:`VTC`. + +* *Traffic Forwarding*: The process of packet forwarding from an incoming +network interface to a pre-defined outgoing network interface. + +* *Traffic Rule Application*: The process of packet tagging, based on a +predefined set of rules. Packet tagging may include e.g. Type of Service +(:term:`ToS`) field modification. + +Architecture +============ + +The Traffic Inspection module is the most computationally intensive component +of the :term:`VNF`. It implements filtering and packet matching algorithms in +order to support the enhanced traffic forwarding capability of the :term:`VNF`. +The component supports a flow table (exploiting hashing algorithms for fast +indexing of flows) and an inspection engine for traffic classification. + +The implementation used for these experiments exploits the nDPI library. +The packet capturing mechanism is implemented using libpcap. When the +:term:`DPI` engine identifies a new flow, the flow register is updated with the +appropriate information and transmitted across the Traffic Forwarding module, +which then applies any required policy updates. + +The Traffic Forwarding moudle is responsible for routing and packet forwarding. +It accepts incoming network traffic, consults the flow table for classification +information for each incoming flow and then applies pre-defined policies +marking e.g. :term:`ToS`/Differentiated Services Code Point (:term:`DSCP`) +multimedia traffic for Quality of Service (:term:`QoS`) enablement on the +forwarded traffic. +It is assumed that the traffic is forwarded using the default policy until it +is identified and new policies are enforced. + +The expected response delay is considered to be negligible, as only a small +number of packets are required to identify each flow. + +Graphical Overview +================== + +.. code-block:: console + + +----------------------------+ + | | + | Virtual Traffic Classifier | + | | + | Analysing/Forwarding | + | ------------> | + | ethA ethB | + | | + +----------------------------+ + | ^ + | | + v | + +----------------------------+ + | | + | Virtual Switch | + | | + +----------------------------+ + +Install +======= + +run the build.sh with root privileges + +Run +=== + +sudo ./pfbridge -a eth1 -b eth2 + +Development Environment +======================= + +Ubuntu 14.04 diff --git a/docs/testing/user/userguide/05-apexlake_installation.rst b/docs/testing/user/userguide/05-apexlake_installation.rst new file mode 100644 index 000000000..d4493e0f8 --- /dev/null +++ b/docs/testing/user/userguide/05-apexlake_installation.rst @@ -0,0 +1,300 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Intel Corporation and others. + + +.. _DPDK: http://dpdk.org/doc/nics +.. _DPDK-pktgen: https://github.com/Pktgen/Pktgen-DPDK/ +.. _SRIOV: https://wiki.openstack.org/wiki/SR-IOV-Passthrough-For-Networking +.. _PORTSEC: https://wiki.openstack.org/wiki/Neutron/ML2PortSecurityExtensionDriver +.. _here: https://wiki.opnfv.org/vtc + + +============================ +Apexlake Installation Guide +============================ + +Abstract +-------- + +ApexLake is a framework that provides automatic execution of experiments and +related data collection to enable a user validate infrastructure from the +perspective of a Virtual Network Function (:term:`VNF`). + +In the context of Yardstick, a virtual Traffic Classifier (:term:`VTC`) network +function is utilized. + + +Framework Hardware Dependencies +=============================== + +In order to run the framework there are some hardware related dependencies for +ApexLake. + +The framework needs to be installed on the same physical node where DPDK-pktgen_ +is installed. + +The installation requires the physical node hosting the packet generator must +have 2 NICs which are DPDK_ compatible. + +The 2 NICs will be connected to the switch where the OpenStack VM +network is managed. + +The switch used must support multicast traffic and :term:`IGMP` snooping. +Further details about the configuration are provided at the following here_. + +The corresponding ports to which the cables are connected need to be configured +as VLAN trunks using two of the VLAN IDs available for Neutron. +Note the VLAN IDs used as they will be required in later configuration steps. + + +Framework Software Dependencies +=============================== +Before starting the framework, a number of dependencies must first be installed. +The following describes the set of instructions to be executed via the Linux +shell in order to install and configure the required dependencies. + +1. Install Dependencies. + +To support the framework dependencies the following packages must be installed. +The example provided is based on Ubuntu and needs to be executed in root mode. + +:: + + apt-get install python-dev + apt-get install python-pip + apt-get install python-mock + apt-get install tcpreplay + apt-get install libpcap-dev + +2. Source OpenStack openrc file. + +:: + + source openrc + +3. Configure Openstack Neutron + +In order to support traffic generation and management by the virtual +Traffic Classifier, the configuration of the port security driver +extension is required for Neutron. + +For further details please follow the following link: PORTSEC_ +This step can be skipped in case the target OpenStack is Juno or Kilo release, +but it is required to support Liberty. +It is therefore required to indicate the release version in the configuration +file located in ./yardstick/vTC/apexlake/apexlake.conf + + +4. Create Two Networks based on VLANs in Neutron. + +To enable network communications between the packet generator and the compute +node, two networks must be created via Neutron and mapped to the VLAN IDs +that were previously used in the configuration of the physical switch. +The following shows the typical set of commands required to configure Neutron +correctly. +The physical switches need to be configured accordingly. + +:: + + VLAN_1=2032 + VLAN_2=2033 + PHYSNET=physnet2 + neutron net-create apexlake_inbound_network \ + --provider:network_type vlan \ + --provider:segmentation_id $VLAN_1 \ + --provider:physical_network $PHYSNET + + neutron subnet-create apexlake_inbound_network \ + 192.168.0.0/24 --name apexlake_inbound_subnet + + neutron net-create apexlake_outbound_network \ + --provider:network_type vlan \ + --provider:segmentation_id $VLAN_2 \ + --provider:physical_network $PHYSNET + + neutron subnet-create apexlake_outbound_network 192.168.1.0/24 \ + --name apexlake_outbound_subnet + + +5. Download Ubuntu Cloud Image and load it on Glance + +The virtual Traffic Classifier is supported on top of Ubuntu 14.04 cloud image. +The image can be downloaded on the local machine and loaded on Glance +using the following commands: + +:: + + wget cloud-images.ubuntu.com/trusty/current/trusty-server-cloudimg-amd64-disk1.img + glance image-create \ + --name ubuntu1404 \ + --is-public true \ + --disk-format qcow \ + --container-format bare \ + --file trusty-server-cloudimg-amd64-disk1.img + + + +6. Configure the Test Cases + +The VLAN tags must also be included in the test case Yardstick yaml file +as parameters for the following test cases: + + * :doc:`opnfv_yardstick_tc006` + + * :doc:`opnfv_yardstick_tc007` + + * :doc:`opnfv_yardstick_tc020` + + * :doc:`opnfv_yardstick_tc021` + + +Install and Configure DPDK Pktgen ++++++++++++++++++++++++++++++++++ + +Execution of the framework is based on DPDK Pktgen. +If DPDK Pktgen has not installed, it is necessary to download, install, compile +and configure it. +The user can create a directory and download the dpdk packet generator source +code: + +:: + + cd experimental_framework/libraries + mkdir dpdk_pktgen + git clone https://github.com/pktgen/Pktgen-DPDK.git + +For instructions on the installation and configuration of DPDK and DPDK Pktgen +please follow the official DPDK Pktgen README file. +Once the installation is completed, it is necessary to load the DPDK kernel +driver, as follow: + +:: + + insmod uio + insmod DPDK_DIR/x86_64-native-linuxapp-gcc/kmod/igb_uio.ko + +It is necessary to set the configuration file to support the desired Pktgen +configuration. +A description of the required configuration parameters and supporting examples +is provided in the following: + +:: + + [PacketGen] + packet_generator = dpdk_pktgen + + # This is the directory where the packet generator is installed + # (if the user previously installed dpdk-pktgen, + # it is required to provide the director where it is installed). + pktgen_directory = /home/user/software/dpdk_pktgen/dpdk/examples/pktgen/ + + # This is the directory where DPDK is installed + dpdk_directory = /home/user/apexlake/experimental_framework/libraries/Pktgen-DPDK/dpdk/ + + # Name of the dpdk-pktgen program that starts the packet generator + program_name = app/app/x86_64-native-linuxapp-gcc/pktgen + + # DPDK coremask (see DPDK-Pktgen readme) + coremask = 1f + + # DPDK memory channels (see DPDK-Pktgen readme) + memory_channels = 3 + + # Name of the interface of the pktgen to be used to send traffic (vlan_sender) + name_if_1 = p1p1 + + # Name of the interface of the pktgen to be used to receive traffic (vlan_receiver) + name_if_2 = p1p2 + + # PCI bus address correspondent to if_1 + bus_slot_nic_1 = 01:00.0 + + # PCI bus address correspondent to if_2 + bus_slot_nic_2 = 01:00.1 + + +To find the parameters related to names of the NICs and the addresses of the PCI buses +the user may find it useful to run the :term:`DPDK` tool nic_bind as follows: + +:: + + DPDK_DIR/tools/dpdk_nic_bind.py --status + +Lists the NICs available on the system, and shows the available drivers and bus addresses for each interface. +Please make sure to select NICs which are :term:`DPDK` compatible. + +Installation and Configuration of smcroute +++++++++++++++++++++++++++++++++++++++++++ + +The user is required to install smcroute which is used by the framework to +support multicast communications. + +The following is the list of commands required to download and install smroute. + +:: + + cd ~ + git clone https://github.com/troglobit/smcroute.git + cd smcroute + git reset --hard c3f5c56 + sed -i 's/aclocal-1.11/aclocal/g' ./autogen.sh + sed -i 's/automake-1.11/automake/g' ./autogen.sh + ./autogen.sh + ./configure + make + sudo make install + cd .. + +It is required to do the reset to the specified commit ID. +It is also requires the creation a configuration file using the following +command: + + SMCROUTE_NIC=(name of the nic) + +where name of the nic is the name used previously for the variable "name_if_2". +For example: + +:: + + SMCROUTE_NIC=p1p2 + +Then create the smcroute configuration file /etc/smcroute.conf + +:: + + echo mgroup from $SMCROUTE_NIC group 224.192.16.1 > /etc/smcroute.conf + + +At the end of this procedure it will be necessary to perform the following +actions to add the user to the sudoers: + +:: + + adduser USERNAME sudo + echo "user ALL=(ALL) NOPASSWD: ALL" >> /etc/sudoers + + +Experiment using SR-IOV Configuration on the Compute Node ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ + +To enable :term:`SR-IOV` interfaces on the physical NIC of the compute node, a +compatible NIC is required. +NIC configuration depends on model and vendor. After proper configuration to +support :term:`SR-IOV`, a proper configuration of OpenStack is required. +For further information, please refer to the SRIOV_ configuration guide + +Finalize installation the framework on the system +================================================= + +The installation of the framework on the system requires the setup of the project. +After entering into the apexlake directory, it is sufficient to run the following +command. + +:: + + python setup.py install + +Since some elements are copied into the /tmp directory (see configuration file) +it could be necessary to repeat this step after a reboot of the host. diff --git a/docs/testing/user/userguide/06-apexlake_api.rst b/docs/testing/user/userguide/06-apexlake_api.rst new file mode 100644 index 000000000..35a1dbe3e --- /dev/null +++ b/docs/testing/user/userguide/06-apexlake_api.rst @@ -0,0 +1,89 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Intel Corporation and others. + + +================================= +Apexlake API Interface Definition +================================= + +Abstract +-------- + +The API interface provided by the framework to enable the execution of test +cases is defined as follows. + + +init +---- + +**static init()** + + Initializes the Framework + + **Returns** None + + +execute_framework +----------------- + +**static execute_framework** (test_cases, + + iterations, + + heat_template, + + heat_template_parameters, + + deployment_configuration, + + openstack_credentials) + + Executes the framework according the specified inputs + + **Parameters** + + - **test_cases** + + Test cases to be run with the workload (dict() of dict()) + + Example: + test_case = dict() + + test_case[’name’] = ‘module.Class’ + + test_case[’params’] = dict() + + test_case[’params’][’throughput’] = ‘1’ + + test_case[’params’][’vlan_sender’] = ‘1000’ + + test_case[’params’][’vlan_receiver’] = ‘1001’ + + test_cases = [test_case] + + - **iterations** + Number of test cycles to be executed (int) + + - **heat_template** + (string) File name of the heat template corresponding to the workload to be deployed. + It contains the parameters to be evaluated in the form of #parameter_name. + (See heat_templates/vTC.yaml as example). + + - **heat_template_parameters** + (dict) Parameters to be provided as input to the + heat template. See http://docs.openstack.org/developer/heat/ template_guide/hot_guide.html + section “Template input parameters” for further info. + + - **deployment_configuration** + ( dict[string] = list(strings) ) ) Dictionary of parameters + representing the deployment configuration of the workload. + + The key is a string corresponding to the name of the parameter, + the value is a list of strings representing the value to be + assumed by a specific param. The parameters are user defined: + they have to correspond to the place holders (#parameter_name) + specified in the heat template. + + **Returns** dict() containing results diff --git a/docs/testing/user/userguide/07-nsb-overview.rst b/docs/testing/user/userguide/07-nsb-overview.rst new file mode 100644 index 000000000..19719f1a7 --- /dev/null +++ b/docs/testing/user/userguide/07-nsb-overview.rst @@ -0,0 +1,177 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, 2016-2017 Intel Corporation. + +===================================== +Network Services Benchmarking (NSB) +===================================== + +Abstract +======== + +.. _Yardstick: https://wiki.opnfv.org/yardstick + +This chapter provides an overview of the NSB, a contribution to OPNFV +Yardstick_ from Intel. + +Overview +======== + +GOAL: Extend Yardstick to perform real world VNFs and NFVi Characterization and +benchmarking with repeatable and deterministic methods. + +The Network Service Benchmarking (NSB) extends the yardstick framework to do +VNF characterization and benchmarking in three different execution +environments viz., bare metal i.e. native Linux environment, standalone virtual +environment and managed virtualized environment (e.g. Open stack etc.). +It also brings in the capability to interact with external traffic generators +both hardware & software based for triggering and validating the traffic +according to user defined profiles. + +NSB extension includes: + • Generic data models of Network Services, based on ETSI specs + • 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 + • vPE,vCGNAT, vFirewall etc - ipv4 throughput, latency etc + • Traffic generators like Trex, ab/nginx, ixia, iperf etc + • KPIs for a given use case: + • System agent support for collecting NFvi KPI. This includes: + o CPU statistic + o Memory BW + o OVS-DPDK Stats + • Network KPIs – eg, inpackets, outpackets, thoughput, latency etc + • VNF KPIs – packet_in, packet_drop, packet_fwd etc + +Architecture +============ +The Network Service (NS) defines a set of Virtual Network Functions (VNF) +connected together using NFV infrastructure. + +The Yardstick NSB extension can support multiple VNFs created by different +vendors including traffic generators. Every VNF being tested has its +own data model. The Network service defines a VNF modelling on base of 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 + o 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. + o 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 + o Verify the test result. + o Validate the traffic flow from SUT + o Fetch the table / data from SUT and verify the value as per the test case + o Upload the logs from SUT onto the Test Harness server + o Read 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. + +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. + +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. + +* *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. + +.. code-block:: console + + +--------+ +-------+ +--------+ + | | | | | | + | Trex | ---> | VNF | ---> | Trex | + | | | | | | + +--------+ +-------+ +--------+ + +Supported testcases scenarios: +• Correlated UDP traffic using TREX traffic generator and replay VNF. + o using different IMIX configuration like pure voice, pure video traffic etc + o using different number IP flows like 1 flow, 1K, 16K, 64K, 256K, 1M flows + o Using different number of rules configured like 1 rule, 1K, 10K rules + +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) + +Graphical Overview +================== + +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 | +-----------+ + +-----------+ + Figure 1: Network Service - 2 server configuration + + +Install +======= + +run the nsb_install.sh with root privileges + +Run +=== + +source ~/.bash_profile +cd /yardstick/cmd +sudo -E ./NSBperf.py --vnf vpe --test tc_baremetal_rfc2544_ipv4_1flow_64B.yaml + +Development Environment +======================= + +Ubuntu 14.04, Ubuntu 16.04 diff --git a/docs/testing/user/userguide/08-nsb_installation.rst b/docs/testing/user/userguide/08-nsb_installation.rst new file mode 100644 index 000000000..a390bb7d7 --- /dev/null +++ b/docs/testing/user/userguide/08-nsb_installation.rst @@ -0,0 +1,253 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, 2016-2017 Intel Corporation. + +Yardstick - NSB Testing -Installation +===================================== + +Abstract +-------- + +Yardstick supports installation on Ubuntu 14.04 or via a Docker image. The +installation procedure on Ubuntu 14.04 or via the docker image are detailed in +the section below. + +The Network Service Benchmarking (NSB) extends the yardstick framework to do +VNF characterization and benchmarking in three different execution +environments viz., bare metal i.e. native Linux environment, standalone virtual +environment and managed virtualized environment (e.g. Open stack etc.). +It also brings in the capability to interact with external traffic generators +both hardware & software based for triggering and validating the traffic +according to user defined profiles. + +The steps needed to run Yardstick with NSB testing are: + +* Install Yardstick (NSB Testing). +* Setup pod.yaml describing Test topology +* Create the test configuration yaml file. +* Run the test case. + + +Prerequisites +------------- + +Refer chapter 08-instalaltion.rst for more information on yardstick +prerequisites + +Several prerequisites are needed for Yardstick(VNF testing): +* Python Modules: pyzmq, pika. +* flex +* bison +* build-essential +* automake +* libtool +* librabbitmq-dev +* rabbitmq-server +* collectd +* intel-cmt-cat + +Installing Yardstick on Ubuntu 14.04 +------------------------------------ + +.. _install-framework: + +You can install Yardstick framework directly on Ubuntu 14.04 or in an Ubuntu +14.04 Docker image. No matter which way you choose to install Yardstick +framework, the following installation steps are identical. + +If you choose to use the Ubuntu 14.04 Docker image, You can pull the Ubuntu +14.04 Docker image from Docker hub: + +:: + + docker pull ubuntu:14.04 + +Installing Yardstick framework +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +Download source code and install python dependencies: + +:: + + git clone https://gerrit.opnfv.org/gerrit/yardstick + cd yardstick + ./nsb_setup.sh + +It will automatically download all the packages needed for NSB Testing setup. + +System Topology: +----------------- + +.. code-block:: console + + +----------+ +----------+ + | | | | + | | (0)----->(0) | Ping/ | + | TG1 | | vPE/ | + | | | 2Trex | + | | (1)<-----(1) | | + +----------+ +----------+ + trafficgen_1 vnf + + +OpenStack parameters and credentials +------------------------------------ + +Environment variables +^^^^^^^^^^^^^^^^^^^^^ +Before running Yardstick (NSB Testing) it is necessary to export traffic +generator libraries. + +:: + source ~/.bash_profile + +Config yardstick conf +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +cp ./etc/yardstick/yardstick.conf.sample /etc/yardstick/yardstick.conf + +vi /etc/yardstick/yardstick.conf + +Config yardstick.conf +:: + + [DEFAULT] + debug = True + dispatcher = influxdb + + [dispatcher_influxdb] + timeout = 5 + target = http://{YOUR_IP_HERE}:8086 + db_name = yardstick + username = root + password = root + + [nsb] + trex_path=/opt/nsb_bin/trex/scripts + bin_path=/opt/nsb_bin + + +Config pod.yaml describing Topology +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +Before executing Yardstick test cases, make sure that pod.yaml reflects the +topology and update all the required fields. + +copy /etc/yardstick/nodes/pod.yaml.nsb.example to /etc/yardstick/nodes/pod.yaml + +Config pod.yaml +:: + nodes: + - + name: trafficgen_1 + role: TrafficGen + ip: 1.1.1.1 + user: root + password: r00t + interfaces: + xe0: # logical name from topology.yaml and vnfd.yaml + vpci: "0000:07:00.0" + driver: i40e # default kernel driver + dpdk_port_num: 0 + local_ip: "152.16.100.20" + netmask: "255.255.255.0" + local_mac: "00:00:00:00:00:01" + xe1: # logical name from topology.yaml and vnfd.yaml + vpci: "0000:07:00.1" + driver: i40e # default kernel driver + dpdk_port_num: 1 + local_ip: "152.16.40.20" + netmask: "255.255.255.0" + local_mac: "00:00.00:00:00:02" + + - + name: vnf + role: vnf + ip: 1.1.1.2 + user: root + password: r00t + host: 1.1.1.2 #BM - host == ip, virtualized env - Host - compute node + interfaces: + xe0: # logical name from topology.yaml and vnfd.yaml + vpci: "0000:07:00.0" + driver: i40e # default kernel driver + dpdk_port_num: 0 + local_ip: "152.16.100.19" + netmask: "255.255.255.0" + local_mac: "00:00:00:00:00:03" + + xe1: # logical name from topology.yaml and vnfd.yaml + vpci: "0000:07:00.1" + driver: i40e # default kernel driver + dpdk_port_num: 1 + local_ip: "152.16.40.19" + netmask: "255.255.255.0" + local_mac: "00:00:00:00:00:04" + routing_table: + - network: "152.16.100.20" + netmask: "255.255.255.0" + gateway: "152.16.100.20" + if: "xe0" + - network: "152.16.40.20" + netmask: "255.255.255.0" + gateway: "152.16.40.20" + if: "xe1" + nd_route_tbl: + - network: "0064:ff9b:0:0:0:0:9810:6414" + netmask: "112" + gateway: "0064:ff9b:0:0:0:0:9810:6414" + if: "xe0" + - network: "0064:ff9b:0:0:0:0:9810:2814" + netmask: "112" + gateway: "0064:ff9b:0:0:0:0:9810:2814" + if: "xe1" + +Enable yardstick virtual environment +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +Before executing yardstick test cases, make sure to activate yardstick +python virtual environment + +:: + source /opt/nsb_bin/yardstick_venv/bin/activate + + +Examples and verifying the install +---------------------------------- + +It is recommended to verify that Yardstick was installed successfully +by executing some simple commands and test samples. Before executing yardstick +test cases make sure yardstick flavor and building yardstick-trusty-server +image can be found in glance and openrc file is sourced. Below is an example +invocation of yardstick help command and ping.py test sample: +:: + + yardstick –h + yardstick task start samples/ping.yaml + +Each testing tool supported by Yardstick has a sample configuration file. +These configuration files can be found in the **samples** directory. + +Default location for the output is ``/tmp/yardstick.out``. + + +Run Yardstick - Network Service Testcases +----------------------------------------- + +NS testing - using NSBperf CLI +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +:: + + source /opt/nsb_setup/yardstick_venv/bin/activate + PYTHONPATH: ". ~/.bash_profile" + cd /yardstick/cmd + Execute command: ./NSPerf.py -h + ./NSBperf.py --vnf --test + eg: ./NSBperf.py --vnf vpe --test tc_baremetal_rfc2544_ipv4_1flow_64B.yaml + +NS testing - using yardstick CLI +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +:: + + source /opt/nsb_setup/yardstick_venv/bin/activate + PYTHONPATH: ". ~/.bash_profile" + Go to test case forlder type we want to execute. + e.g. /samples/vnf_samples/nsut// + run: yardstick --debug task start diff --git a/docs/testing/user/userguide/09-installation.rst b/docs/testing/user/userguide/09-installation.rst new file mode 100644 index 000000000..9c2082a27 --- /dev/null +++ b/docs/testing/user/userguide/09-installation.rst @@ -0,0 +1,401 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB, Huawei Technologies Co.,Ltd and others. + +Yardstick Installation +====================== + +Abstract +-------- + +Yardstick supports installation on Ubuntu 14.04 or via a Docker image. The +installation procedure on Ubuntu 14.04 or via the docker image are detailed in +the section below. + +To use Yardstick you should have access to an OpenStack environment, with at +least Nova, Neutron, Glance, Keystone and Heat installed. + +The steps needed to run Yardstick are: + +1. Install Yardstick. +2. Load OpenStack environment variables. +3. Create a Neutron external network. +4. Build Yardstick flavor and a guest image. +5. Load the guest image into the OpenStack environment. +6. Create the test configuration .yaml file. +7. Run the test case. + + +Prerequisites +------------- + +The OPNFV deployment is out of the scope of this document but it can be +found in http://artifacts.opnfv.org/opnfvdocs/colorado/docs/configguide/index.html. +The OPNFV platform is considered as the System Under Test (SUT) in this +document. + +Several prerequisites are needed for Yardstick: + + #. A Jumphost to run Yardstick on + #. A Docker daemon shall be installed on the Jumphost + #. A public/external network created on the SUT + #. Connectivity from the Jumphost to the SUT public/external network + +WARNING: Connectivity from Jumphost is essential and it is of paramount +importance to make sure it is working before even considering to install +and run Yardstick. Make also sure you understand how your networking is +designed to work. + +NOTE: **Jumphost** refers to any server which meets the previous +requirements. Normally it is the same server from where the OPNFV +deployment has been triggered previously. + +NOTE: If your Jumphost is operating behind a company http proxy and/or +Firewall, please consult first the section `Proxy Support`_, towards +the end of this document. The section details some tips/tricks which +*may* be of help in a proxified environment. + + +Installing Yardstick on Ubuntu 14.04 +------------------------------------ + +.. _install-framework: + +You can install Yardstick framework directly on Ubuntu 14.04 or in an Ubuntu +14.04 Docker image. No matter which way you choose to install Yardstick +framework, the following installation steps are identical. + +If you choose to use the Ubuntu 14.04 Docker image, You can pull the Ubuntu +14.04 Docker image from Docker hub: + +:: + + docker pull ubuntu:14.04 + +Installing Yardstick framework +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +Download source code and install python dependencies: + +:: + + git clone https://gerrit.opnfv.org/gerrit/yardstick + cd yardstick + ./install.sh + + +Installing Yardstick using Docker +--------------------------------- + +Yardstick has a Docker image, this Docker image (**Yardstick-stable**) +serves as a replacement for installing the Yardstick framework in a virtual +environment (for example as done in :ref:`install-framework`). +It is recommended to use this Docker image to run Yardstick test. + +Pulling the Yardstick Docker image +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +.. _dockerhub: https://hub.docker.com/r/opnfv/yardstick/ + +Pull the Yardstick Docker image ('opnfv/yardstick') from the public dockerhub +registry under the OPNFV account: [dockerhub_], with the following docker +command:: + + docker pull opnfv/yardstick:stable + +After pulling the Docker image, check that it is available with the +following docker command:: + + [yardsticker@jumphost ~]$ docker images + REPOSITORY TAG IMAGE ID CREATED SIZE + opnfv/yardstick stable a4501714757a 1 day ago 915.4 MB + +Run the Docker image: + +:: + + docker run --privileged=true -it opnfv/yardstick:stable /bin/bash + +In the container the Yardstick repository is located in the /home/opnfv/repos +directory. + + +OpenStack parameters and credentials +------------------------------------ + +Environment variables +^^^^^^^^^^^^^^^^^^^^^ +Before running Yardstick it is necessary to export OpenStack environment variables +from the OpenStack *openrc* file (using the ``source`` command) and export the +external network name ``export EXTERNAL_NETWORK="external-network-name"``, +the default name for the external network is ``net04_ext``. + +Credential environment variables in the *openrc* file have to include at least: + +* OS_AUTH_URL +* OS_USERNAME +* OS_PASSWORD +* OS_TENANT_NAME + +A sample openrc file may look like this: + +* export OS_PASSWORD=console +* export OS_TENANT_NAME=admin +* export OS_AUTH_URL=http://172.16.1.222:35357/v2.0 +* export OS_USERNAME=admin +* export OS_VOLUME_API_VERSION=2 +* export EXTERNAL_NETWORK=net04_ext + + +Yardstick falvor and guest images +--------------------------------- + +Before executing Yardstick test cases, make sure that yardstick guest image and +yardstick flavor are available in OpenStack. +Detailed steps about creating yardstick flavor and building yardstick-trusty-server +image can be found below. + +Yardstick-flavor +^^^^^^^^^^^^^^^^ +Most of the sample test cases in Yardstick are using an OpenStack flavor called +*yardstick-flavor* which deviates from the OpenStack standard m1.tiny flavor by the +disk size - instead of 1GB it has 3GB. Other parameters are the same as in m1.tiny. + +Create yardstick-flavor: + +:: + + nova flavor-create yardstick-flavor 100 512 3 1 + + +.. _guest-image: + +Building a guest image +^^^^^^^^^^^^^^^^^^^^^^ +Most of the sample test cases in Yardstick are using a guest image called +*yardstick-trusty-server* which deviates from an Ubuntu Cloud Server image +containing all the required tools to run test cases supported by Yardstick. +Yardstick has a tool for building this custom image. It is necessary to have +sudo rights to use this tool. + +Also you may need install several additional packages to use this tool, by +follwing the commands below: + +:: + + apt-get update && apt-get install -y \ + qemu-utils \ + kpartx + +This image can be built using the following command while in the directory where +Yardstick is installed (``~/yardstick`` if the framework is installed +by following the commands above): + +:: + + export YARD_IMG_ARCH="amd64" + sudo echo "Defaults env_keep += \"YARD_IMG_ARCH\"" >> /etc/sudoers + sudo ./tools/yardstick-img-modify tools/ubuntu-server-cloudimg-modify.sh + +**Warning:** the script will create files by default in: +``/tmp/workspace/yardstick`` and the files will be owned by root! + +If you are building this guest image in inside a docker container make sure the +container is granted with privilege. + +The created image can be added to OpenStack using the ``glance image-create`` or +via the OpenStack Dashboard. + +Example command: + +:: + + glance --os-image-api-version 1 image-create \ + --name yardstick-image --is-public true \ + --disk-format qcow2 --container-format bare \ + --file /tmp/workspace/yardstick/yardstick-image.img + +Some Yardstick test cases use a Cirros image, you can find one at +http://download.cirros-cloud.net/0.3.3/cirros-0.3.3-x86_64-disk.img + + +Automatic flavor and image creation +----------------------------------- +Yardstick has a script for automatic creating yardstick flavor and building +guest images. This script is mainly used in CI, but you can still use it in +your local environment. + +Example command: + +:: + + export YARD_IMG_ARCH="amd64" + sudo echo "Defaults env_keep += \"YARD_IMG_ARCH\"" >> /etc/sudoers + source $YARDSTICK_REPO_DIR/tests/ci/load_images.sh + + +Yardstick default key pair +^^^^^^^^^^^^^^^^^^^^^^^^^^ +Yardstick uses a SSH key pair to connect to the guest image. This key pair can +be found in the ``resources/files`` directory. To run the ``ping-hot.yaml`` test +sample, this key pair needs to be imported to the OpenStack environment. + + +Examples and verifying the install +---------------------------------- + +It is recommended to verify that Yardstick was installed successfully +by executing some simple commands and test samples. Before executing yardstick +test cases make sure yardstick flavor and building yardstick-trusty-server +image can be found in glance and openrc file is sourced. Below is an example +invocation of yardstick help command and ping.py test sample: +:: + + yardstick –h + yardstick task start samples/ping.yaml + +Each testing tool supported by Yardstick has a sample configuration file. +These configuration files can be found in the **samples** directory. + +Default location for the output is ``/tmp/yardstick.out``. + + +Deploy InfluxDB and Grafana locally +------------------------------------ + +.. pull docker images + +Pull docker images + +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +:: + + docker pull tutum/influxdb + docker pull grafana/grafana + +Run influxdb and config +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +Run influxdb +:: + + docker run -d --name influxdb \ + -p 8083:8083 -p 8086:8086 --expose 8090 --expose 8099 \ + tutum/influxdb + docker exec -it influxdb bash + +Config influxdb +:: + + influx + >CREATE USER root WITH PASSWORD 'root' WITH ALL PRIVILEGES + >CREATE DATABASE yardstick; + >use yardstick; + >show MEASUREMENTS; + +Run grafana and config +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +Run grafana +:: + + docker run -d --name grafana -p 3000:3000 grafana/grafana + +Config grafana +:: + + http://{YOUR_IP_HERE}:3000 + log on using admin/admin and config database resource to be {YOUR_IP_HERE}:8086 + +.. image:: images/Grafana_config.png + :width: 800px + :alt: Grafana data source configration + +Config yardstick conf +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +cp ./etc/yardstick/yardstick.conf.sample /etc/yardstick/yardstick.conf + +vi /etc/yardstick/yardstick.conf +Config yardstick.conf +:: + + [DEFAULT] + debug = True + dispatcher = influxdb + + [dispatcher_influxdb] + timeout = 5 + target = http://{YOUR_IP_HERE}:8086 + db_name = yardstick + username = root + password = root + +Now you can run yardstick test cases and store the results in influxdb +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + + +Create a test suite for yardstick +------------------------------------ + +A test suite in yardstick is a yaml file which include one or more test cases. +Yardstick is able to support running test suite task, so you can customize you +own test suite and run it in one task. + +"tests/opnfv/test_suites" is where yardstick put ci test-suite. A typical test +suite is like below: + +fuel_test_suite.yaml + +:: + + --- + # Fuel integration test task suite + + schema: "yardstick:suite:0.1" + + name: "fuel_test_suite" + test_cases_dir: "samples/" + test_cases: + - + file_name: ping.yaml + - + file_name: iperf3.yaml + +As you can see, there are two test cases in fuel_test_suite, the syntax is simple +here, you must specify the schema and the name, then you just need to list the +test cases in the tag "test_cases" and also mark their relative directory in the +tag "test_cases_dir". + +Yardstick test suite also support constraints and task args for each test case. +Here is another sample to show this, which is digested from one big test suite. + +os-nosdn-nofeature-ha.yaml + +:: + + --- + + schema: "yardstick:suite:0.1" + + name: "os-nosdn-nofeature-ha" + test_cases_dir: "tests/opnfv/test_cases/" + test_cases: + - + file_name: opnfv_yardstick_tc002.yaml + - + file_name: opnfv_yardstick_tc005.yaml + - + file_name: opnfv_yardstick_tc043.yaml + constraint: + installer: compass + pod: huawei-pod1 + task_args: + huawei-pod1: '{"pod_info": "etc/yardstick/.../pod.yaml", + "host": "node4.LF","target": "node5.LF"}' + +As you can see in test case "opnfv_yardstick_tc043.yaml", there are two tags, "constraint" and +"task_args". "constraint" is where you can specify which installer or pod it can be run in +the ci environment. "task_args" is where you can specify the task arguments for each pod. + +All in all, to create a test suite in yardstick, you just need to create a suite yaml file +and add test cases and constraint or task arguments if necessary. + diff --git a/docs/testing/user/userguide/10-yardstick_plugin.rst b/docs/testing/user/userguide/10-yardstick_plugin.rst new file mode 100644 index 000000000..f16dedd02 --- /dev/null +++ b/docs/testing/user/userguide/10-yardstick_plugin.rst @@ -0,0 +1,144 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB, Huawei Technologies Co.,Ltd and others. + +=================================== +Installing a plug-in into yardstick +=================================== + +Abstract +======== + +Yardstick currently provides a ``plugin`` CLI command to support integration +with other OPNFV testing projects. Below is an example invocation of yardstick +plugin command and Storperf plug-in sample. + + +Installing Storperf into yardstick +================================== + +Storperf is delivered as a Docker container from +https://hub.docker.com/r/opnfv/storperf/tags/. + +There are two possible methods for installation in your environment: + +* Run container on Jump Host +* Run container in a VM + +In this introduction we will install Storperf on Jump Host. + + +Step 0: Environment preparation +>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> + +Running Storperf on Jump Host +Requirements: + +* Docker must be installed +* Jump Host must have access to the OpenStack Controller API +* Jump Host must have internet connectivity for downloading docker image +* Enough floating IPs must be available to match your agent count + +Before installing Storperf into yardstick you need to check your openstack +environment and other dependencies: + +1. Make sure docker is installed. +2. Make sure Keystone, Nova, Neutron, Glance, Heat are installed correctly. +3. Make sure Jump Host have access to the OpenStack Controller API. +4. Make sure Jump Host must have internet connectivity for downloading docker image. +5. You need to know where to get basic openstack Keystone authorization info, such as + OS_PASSWORD, OS_TENANT_NAME, OS_AUTH_URL, OS_USERNAME. +6. To run a Storperf container, you need to have OpenStack Controller environment + variables defined and passed to Storperf container. The best way to do this is to + put environment variables in a "storperf_admin-rc" file. The storperf_admin-rc + should include credential environment variables at least: + +* OS_AUTH_URL +* OS_TENANT_ID +* OS_TENANT_NAME +* OS_PROJECT_NAME +* OS_USERNAME +* OS_PASSWORD +* OS_REGION_NAME + +For this storperf_admin-rc file, during environment preparation a "prepare_storperf_admin-rc.sh" +script can be used to generate it. +:: + + #!/bin/bash + AUTH_URL=${OS_AUTH_URL} + USERNAME=${OS_USERNAME:-admin} + PASSWORD=${OS_PASSWORD:-console} + TENANT_NAME=${OS_TENANT_NAME:-admin} + VOLUME_API_VERSION=${OS_VOLUME_API_VERSION:-2} + PROJECT_NAME=${OS_PROJECT_NAME:-$TENANT_NAME} + TENANT_ID=`keystone tenant-get admin|grep 'id'|awk -F '|' '{print $3}'|sed -e 's/^[[:space:]]*//'` + rm -f ~/storperf_admin-rc + touch ~/storperf_admin-rc + echo "OS_AUTH_URL="$AUTH_URL >> ~/storperf_admin-rc + echo "OS_USERNAME="$USERNAME >> ~/storperf_admin-rc + echo "OS_PASSWORD="$PASSWORD >> ~/storperf_admin-rc + echo "OS_TENANT_NAME="$TENANT_NAME >> ~/storperf_admin-rc + echo "OS_VOLUME_API_VERSION="$VOLUME_API_VERSION >> ~/storperf_admin-rc + echo "OS_PROJECT_NAME="$PROJECT_NAME >> ~/storperf_admin-rc + echo "OS_TENANT_ID="$TENANT_ID >> ~/storperf_admin-rc + + +Step 1: Plug-in configuration file preparation +++++++++++++++++++++++++++++++++++++++++++++++ + +To install a plug-in, first you need to prepare a plug-in configuration file in +YAML format and store it in the "plugin" directory. The plugin configration file +work as the input of yardstick "plugin" command. Below is the Storperf plug-in +configuration file sample: +:: + + --- + # StorPerf plugin configuration file + # Used for integration StorPerf into Yardstick as a plugin + schema: "yardstick:plugin:0.1" + plugins: + name: storperf + deployment: + ip: 192.168.23.2 + user: root + password: root + +In the plug-in configuration file, you need to specify the plug-in name and the +plug-in deployment info, including node ip, node login username and password. +Here the Storperf will be installed on IP 192.168.23.2 which is the Jump Host +in my local environment. + +Step 2: Plug-in install/remove scripts preparation +++++++++++++++++++++++++++++++++++++++++++++++++++ + +Under "yardstick/resource/scripts directory", there are two folders: a "install" +folder and a "remove" folder. You need to store the plug-in install/remove script +in these two folders respectively. + +The detailed installation or remove operation should de defined in these two scripts. +The name of both install and remove scripts should match the plugin-in name that you +specified in the plug-in configuration file. +For example, the install and remove scripts for Storperf are both named to "storperf.bash". + + +Step 3: Install and remove Storperf ++++++++++++++++++++++++++++++++++++ + +To install Storperf, simply execute the following command +:: + + # Install Storperf + yardstick plugin install plugin/storperf.yaml + +removing Storperf from yardstick +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +To remove Storperf, simply execute the following command +:: + + # Remove Storperf + yardstick plugin remove plugin/storperf.yaml + +What yardstick plugin command does is using the username and password to log into the deployment target and then execute the corresponding install or remove script. diff --git a/docs/testing/user/userguide/11-result-store-InfluxDB.rst b/docs/testing/user/userguide/11-result-store-InfluxDB.rst new file mode 100644 index 000000000..a0bb48a80 --- /dev/null +++ b/docs/testing/user/userguide/11-result-store-InfluxDB.rst @@ -0,0 +1,86 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, 2016 Huawei Technologies Co.,Ltd and others. + +============================================== +Store Other Project's Test Results in InfluxDB +============================================== + +Abstract +======== + +.. _Framework: https://wiki.opnfv.org/download/attachments/6827660/wiki.png?version=1&modificationDate=1470298075000&api=v2 + +This chapter illustrates how to run plug-in test cases and store test results +into community's InfluxDB. The framework is shown in Framework_. + + +.. image:: images/InfluxDB_store.png + :width: 800px + :alt: Store Other Project's Test Results in InfluxDB + +Store Storperf Test Results into Community's InfluxDB +===================================================== + +.. _Influxdb: https://git.opnfv.org/cgit/yardstick/tree/yardstick/dispatcher/influxdb.py +.. _Mingjiang: limingjiang@huawei.com +.. _Visual: https://wiki.opnfv.org/download/attachments/6827660/tc074.PNG?version=1&modificationDate=1470298075000&api=v2 +.. _Login: http://testresults.opnfv.org/grafana/login + +As shown in Framework_, there are two ways to store Storperf test results +into community's InfluxDB: + +1. Yardstick asks Storperf to run the test case. After the test case is + completed, Yardstick reads test results via ReST API from Storperf and + posts test data to the influxDB. + +2. Additionally, Storperf can run tests by itself and post the test result + directly to the InfluxDB. The method for posting data directly to influxDB + will be supported in the future. + +Our plan is to support rest-api in D release so that other testing projects can +call the rest-api to use yardstick dispatcher service to push data to yardstick's +influxdb database. + +For now, influxdb only support line protocol, and the json protocol is deprecated. + +Take ping test case for example, the raw_result is json format like this: +:: + + "benchmark": { + "timestamp": 1470315409.868095, + "errors": "", + "data": { + "rtt": { + "ares": 1.125 + } + }, + "sequence": 1 + }, + "runner_id": 2625 + } + +With the help of "influxdb_line_protocol", the json is transform to like below as a line string: +:: + + 'ping,deploy_scenario=unknown,host=athena.demo,installer=unknown,pod_name=unknown, + runner_id=2625,scenarios=Ping,target=ares.demo,task_id=77755f38-1f6a-4667-a7f3- + 301c99963656,version=unknown rtt.ares=1.125 1470315409868094976' + +So, for data output of json format, you just need to transform json into line format and call +influxdb api to post the data into the database. All this function has been implemented in Influxdb_. +If you need support on this, please contact Mingjiang_. +:: + + curl -i -XPOST 'http://104.197.68.199:8086/write?db=yardstick' -- + data-binary 'ping,deploy_scenario=unknown,host=athena.demo,installer=unknown, ...' + +Grafana will be used for visualizing the collected test data, which is shown in Visual_. Grafana +can be accessed by Login_. + + +.. image:: images/results_visualization.png + :width: 800px + :alt: results visualization + diff --git a/docs/testing/user/userguide/12-grafana.rst b/docs/testing/user/userguide/12-grafana.rst new file mode 100644 index 000000000..416857b71 --- /dev/null +++ b/docs/testing/user/userguide/12-grafana.rst @@ -0,0 +1,119 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) 2016 Huawei Technologies Co.,Ltd and others + +================= +Grafana dashboard +================= + + +Abstract +======== + +This chapter describes the Yardstick grafana dashboard. The Yardstick grafana +dashboard can be found here: http://testresults.opnfv.org/grafana/ + + +.. image:: images/login.png + :width: 800px + :alt: Yardstick grafana dashboard + + +Public access +============= + +Yardstick provids a public account for accessing to the dashboard. The username +and password are both set to ‘opnfv’. + + +Testcase dashboard +================== + +For each test case, there is a dedicated dashboard. Shown here is the dashboard +of TC002. + + +.. image:: images/TC002.png + :width: 800px + :alt:TC002 dashboard + +For each test case dashboard. On the top left, we have a dashboard selection, +you can switch to different test cases using this pull-down menu. + +Underneath, we have a pod and scenario selection. +All the pods and scenarios that have ever published test data to the InfluxDB +will be shown here. + +You can check multiple pods or scenarios. + +For each test case, we have a short description and a link to detailed test +case information in Yardstick user guide. + +Underneath, it is the result presentation section. +You can use the time period selection on the top right corner to zoom in or +zoom out the chart. + + +Administration access +===================== + +For a user with administration rights it is easy to update and save any +dashboard configuration. Saved updates immediately take effect and become live. +This may cause issues like: + +- Changes and updates made to the live configuration in Grafana can compromise + existing Grafana content in an unwanted, unpredicted or incompatible way. + Grafana as such is not version controlled, there exists one single Grafana + configuration per dashboard. +- There is a risk several people can disturb each other when doing updates to + the same Grafana dashboard at the same time. + +Any change made by administrator should be careful. + + +Add a dashboard into yardstick grafana +====================================== + +Due to security concern, users that using the public opnfv account are not able +to edit the yardstick grafana directly.It takes a few more steps for a +non-yardstick user to add a custom dashboard into yardstick grafana. + +There are 6 steps to go. + + +.. image:: images/add.png + :width: 800px + :alt: Add a dashboard into yardstick grafana + + +1. You need to build a local influxdb and grafana, so you can do the work + locally. You can refer to How to deploy InfluxDB and Grafana locally wiki + page about how to do this. + +2. Once step one is done, you can fetch the existing grafana dashboard + configuration file from the yardstick repository and import it to your local + grafana. After import is done, you grafana dashboard will be ready to use + just like the community’s dashboard. + +3. The third step is running some test cases to generate test results and + publishing it to your local influxdb. + +4. Now you have some data to visualize in your dashboard. In the fourth step, + it is time to create your own dashboard. You can either modify an existing + dashboard or try to create a new one from scratch. If you choose to modify + an existing dashboard then in the curtain menu of the existing dashboard do + a "Save As..." into a new dashboard copy instance, and then continue doing + all updates and saves within the dashboard copy. + +5. When finished with all Grafana configuration changes in this temporary + dashboard then chose "export" of the updated dashboard copy into a JSON file + and put it up for review in Gerrit, in file /yardstick/dashboard/Yardstick-TCxxx-yyyyyyyyyyyyy. + For instance a typical default name of the file would be "Yardstick-TC001 Copy-1234567891234". + +6. Once you finish your dashboard, the next step is exporting the configuration + file and propose a patch into Yardstick. Yardstick team will review and + merge it into Yardstick repository. After approved review Yardstick team + will do an "import" of the JSON file and also a "save dashboard" as soon as + possible to replace the old live dashboard configuration. + diff --git a/docs/testing/user/userguide/13-list-of-tcs.rst b/docs/testing/user/userguide/13-list-of-tcs.rst new file mode 100644 index 000000000..1b5806cd9 --- /dev/null +++ b/docs/testing/user/userguide/13-list-of-tcs.rst @@ -0,0 +1,129 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +==================== +Yardstick Test Cases +==================== + +Abstract +======== + +This chapter lists available Yardstick test cases. +Yardstick test cases are divided in two main categories: + +* *Generic NFVI Test Cases* - Test Cases developed to realize the methodology +described in :doc:`02-methodology` + +* *OPNFV Feature Test Cases* - Test Cases developed to verify one or more +aspect of a feature delivered by an OPNFV Project, including the test cases +developed for the :term:`VTC`. + +Generic NFVI Test Case Descriptions +=================================== + +.. toctree:: + :maxdepth: 1 + + opnfv_yardstick_tc001.rst + opnfv_yardstick_tc002.rst + opnfv_yardstick_tc004.rst + opnfv_yardstick_tc005.rst + opnfv_yardstick_tc008.rst + opnfv_yardstick_tc009.rst + opnfv_yardstick_tc010.rst + opnfv_yardstick_tc011.rst + opnfv_yardstick_tc012.rst + opnfv_yardstick_tc014.rst + opnfv_yardstick_tc024.rst + opnfv_yardstick_tc037.rst + opnfv_yardstick_tc038.rst + opnfv_yardstick_tc042.rst + opnfv_yardstick_tc043.rst + opnfv_yardstick_tc044.rst + opnfv_yardstick_tc055.rst + opnfv_yardstick_tc061.rst + opnfv_yardstick_tc063.rst + opnfv_yardstick_tc069.rst + opnfv_yardstick_tc070.rst + opnfv_yardstick_tc071.rst + opnfv_yardstick_tc072.rst + opnfv_yardstick_tc073.rst + opnfv_yardstick_tc075.rst + opnfv_yardstick_tc076.rst + +OPNFV Feature Test Cases +======================== + +H A +--- + +.. toctree:: + :maxdepth: 1 + + opnfv_yardstick_tc019.rst + opnfv_yardstick_tc025.rst + opnfv_yardstick_tc045.rst + opnfv_yardstick_tc046.rst + opnfv_yardstick_tc047.rst + opnfv_yardstick_tc048.rst + opnfv_yardstick_tc049.rst + opnfv_yardstick_tc050.rst + opnfv_yardstick_tc051.rst + opnfv_yardstick_tc052.rst + opnfv_yardstick_tc053.rst + opnfv_yardstick_tc054.rst + +IPv6 +---- + +.. toctree:: + :maxdepth: 1 + + opnfv_yardstick_tc027.rst + +KVM +--- + +.. toctree:: + :maxdepth: 1 + + opnfv_yardstick_tc028.rst + +Parser +------ + +.. toctree:: + :maxdepth: 1 + + opnfv_yardstick_tc040.rst + + StorPerf +----------- + +.. toctree:: + :maxdepth: 1 + + opnfv_yardstick_tc074.rst + +virtual Traffic Classifier +-------------------------- + +.. toctree:: + :maxdepth: 1 + + opnfv_yardstick_tc006.rst + opnfv_yardstick_tc007.rst + opnfv_yardstick_tc020.rst + opnfv_yardstick_tc021.rst + +Templates +========= + +.. toctree:: + :maxdepth: 1 + + testcase_description_v2_template + Yardstick_task_templates + diff --git a/docs/testing/user/userguide/Yardstick_task_templates.rst b/docs/testing/user/userguide/Yardstick_task_templates.rst new file mode 100755 index 000000000..e8130dd2a --- /dev/null +++ b/docs/testing/user/userguide/Yardstick_task_templates.rst @@ -0,0 +1,160 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +Task Template Syntax +==================== + +Basic template syntax +--------------------- +A nice feature of the input task format used in Yardstick is that it supports +the template syntax based on Jinja2. +This turns out to be extremely useful when, say, you have a fixed structure of +your task but you want to parameterize this task in some way. +For example, imagine your input task file (task.yaml) runs a set of Ping +scenarios: + +:: + + # Sample benchmark task config file + # measure network latency using ping + schema: "yardstick:task:0.1" + + scenarios: + - + type: Ping + options: + packetsize: 200 + host: athena.demo + target: ares.demo + + runner: + type: Duration + duration: 60 + interval: 1 + + sla: + max_rtt: 10 + action: monitor + + context: + ... + +Let's say you want to run the same set of scenarios with the same runner/ +context/sla, but you want to try another packetsize to compare the performance. +The most elegant solution is then to turn the packetsize name into a template +variable: + +:: + + # Sample benchmark task config file + # measure network latency using ping + + schema: "yardstick:task:0.1" + scenarios: + - + type: Ping + options: + packetsize: {{packetsize}} + host: athena.demo + target: ares.demo + + runner: + type: Duration + duration: 60 + interval: 1 + + sla: + max_rtt: 10 + action: monitor + + context: + ... + +and then pass the argument value for {{packetsize}} when starting a task with +this configuration file. +Yardstick provides you with different ways to do that: + +1.Pass the argument values directly in the command-line interface (with either +a JSON or YAML dictionary): + +:: + + yardstick task start samples/ping-template.yaml + --task-args'{"packetsize":"200"}' + +2.Refer to a file that specifies the argument values (JSON/YAML): + +:: + + yardstick task start samples/ping-template.yaml --task-args-file args.yaml + +Using the default values +------------------------ +Note that the Jinja2 template syntax allows you to set the default values for +your parameters. +With default values set, your task file will work even if you don't +parameterize it explicitly while starting a task. +The default values should be set using the {% set ... %} clause (task.yaml). +For example: + +:: + + # Sample benchmark task config file + # measure network latency using ping + schema: "yardstick:task:0.1" + {% set packetsize = packetsize or "100" %} + scenarios: + - + type: Ping + options: + packetsize: {{packetsize}} + host: athena.demo + target: ares.demo + + runner: + type: Duration + duration: 60 + interval: 1 + ... + +If you don't pass the value for {{packetsize}} while starting a task, the +default one will be used. + +Advanced templates +------------------ + +Yardstick makes it possible to use all the power of Jinja2 template syntax, +including the mechanism of built-in functions. +As an example, let us make up a task file that will do a block storage +performance test. +The input task file (fio-template.yaml) below uses the Jinja2 for-endfor +construct to accomplish that: + +:: + + #Test block sizes of 4KB, 8KB, 64KB, 1MB + #Test 5 workloads: read, write, randwrite, randread, rw + schema: "yardstick:task:0.1" + + scenarios: + {% for bs in ['4k', '8k', '64k', '1024k' ] %} + {% for rw in ['read', 'write', 'randwrite', 'randread', 'rw' ] %} + - + type: Fio + options: + filename: /home/ubuntu/data.raw + bs: {{bs}} + rw: {{rw}} + ramp_time: 10 + host: fio.demo + runner: + type: Duration + duration: 60 + interval: 60 + + {% endfor %} + {% endfor %} + context + ... diff --git a/docs/testing/user/userguide/comp-intro.rst b/docs/testing/user/userguide/comp-intro.rst new file mode 100644 index 000000000..ee68226ad --- /dev/null +++ b/docs/testing/user/userguide/comp-intro.rst @@ -0,0 +1,37 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +========= +Yardstick +========= + +.. _Yardstick: https://wiki.opnfv.org/yardstick +.. _Presentation: https://wiki.opnfv.org/_media/opnfv_summit_-_yardstick_project.pdf +.. _NFV-TST001: https://docbox.etsi.org/ISG/NFV/Open/Drafts/TST001_-_Pre-deployment_Validation/ +.. _Yardsticktst: https://wiki.opnfv.org/_media/opnfv_summit_-_bridging_opnfv_and_etsi.pdf + +The project's goal is to verify infrastructure compliance, from the perspective +of a Virtual Network Function (VNF). + +The Project's scope is the development of a test framework, *Yardstick*, test +cases and test stimuli to enable Network Function Virtualization Infrastructure +(NFVI) verification. + +In OPNFV Brahmaputra release, generic test cases covering aspects of the +metrics in the document ETSI GS NFV-TST001_, "Pre-deployment Testing; Report on +Validation of NFV Environments and Services" are available; further OPNFV +releases will provide extended testing of these metrics. + +The Project also includes a sample VNF, the Virtual Traffic Classifier (VTC) +and its experimental framework, *ApexLake*. + +*Yardstick* is used in OPNFV for verifying the OPNFV infrastructure and some of +the OPNFV features. The *Yardstick* framework is deployed in several OPNFV +community labs. It is *installer*, *infrastructure* and *application* +independent. + + +.. seealso:: This Presentation_ for an overview of *Yardstick* and + Yardsticktst_ for material on alignment ETSI TST001 and Yardstick. diff --git a/docs/testing/user/userguide/glossary.rst b/docs/testing/user/userguide/glossary.rst new file mode 100644 index 000000000..f8ff41887 --- /dev/null +++ b/docs/testing/user/userguide/glossary.rst @@ -0,0 +1,65 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +======== +Glossary +======== + +.. glossary:: + :sorted: + + API + Application Programming Interface + + DPI + Deep Packet Inspection + + DPDK + Data Plane Development Kit + + DSCP + Differentiated Services Code Point + + IGMP + Internet Group Management Protocol + + IOPS + Input/Output Operations Per Second + + NIC + Network Interface Controller + + PBFS + Packet Based per Flow State + + QoS + Quality of Service + + VLAN + Virtual LAN + + VM + Virtual Machine + + VNF + Virtual Network Function + + VNFC + Virtual Network Function Component + + NFVI + Network Function Virtualization Infrastructure + + SR-IOV + Single Root IO Virtualization + + SUT + System Under Test + + ToS + Type of Service + + VTC + Virtual Traffic Classifier diff --git a/docs/testing/user/userguide/images/Deployment.png b/docs/testing/user/userguide/images/Deployment.png new file mode 100755 index 000000000..aca5670cd Binary files /dev/null and b/docs/testing/user/userguide/images/Deployment.png differ diff --git a/docs/testing/user/userguide/images/Grafana_config.png b/docs/testing/user/userguide/images/Grafana_config.png new file mode 100644 index 000000000..cb63098dc Binary files /dev/null and b/docs/testing/user/userguide/images/Grafana_config.png differ diff --git a/docs/testing/user/userguide/images/InfluxDB_store.png b/docs/testing/user/userguide/images/InfluxDB_store.png new file mode 100644 index 000000000..1770fd255 Binary files /dev/null and b/docs/testing/user/userguide/images/InfluxDB_store.png differ diff --git a/docs/testing/user/userguide/images/Logical_view.png b/docs/testing/user/userguide/images/Logical_view.png new file mode 100644 index 000000000..cdb805448 Binary files /dev/null and b/docs/testing/user/userguide/images/Logical_view.png differ diff --git a/docs/testing/user/userguide/images/TC002.png b/docs/testing/user/userguide/images/TC002.png new file mode 100644 index 000000000..89154efcc Binary files /dev/null and b/docs/testing/user/userguide/images/TC002.png differ diff --git a/docs/testing/user/userguide/images/Use_case.png b/docs/testing/user/userguide/images/Use_case.png new file mode 100644 index 000000000..acd52f526 Binary files /dev/null and b/docs/testing/user/userguide/images/Use_case.png differ diff --git a/docs/testing/user/userguide/images/add.png b/docs/testing/user/userguide/images/add.png new file mode 100644 index 000000000..a88a1b146 Binary files /dev/null and b/docs/testing/user/userguide/images/add.png differ diff --git a/docs/testing/user/userguide/images/login.png b/docs/testing/user/userguide/images/login.png new file mode 100644 index 000000000..045e010e4 Binary files /dev/null and b/docs/testing/user/userguide/images/login.png differ diff --git a/docs/testing/user/userguide/images/results_visualization.png b/docs/testing/user/userguide/images/results_visualization.png new file mode 100644 index 000000000..cd092808b Binary files /dev/null and b/docs/testing/user/userguide/images/results_visualization.png differ diff --git a/docs/testing/user/userguide/images/test_execution_flow.png b/docs/testing/user/userguide/images/test_execution_flow.png new file mode 100644 index 000000000..c20a931a4 Binary files /dev/null and b/docs/testing/user/userguide/images/test_execution_flow.png differ diff --git a/docs/testing/user/userguide/index.rst b/docs/testing/user/userguide/index.rst new file mode 100644 index 000000000..1b963af61 --- /dev/null +++ b/docs/testing/user/userguide/index.rst @@ -0,0 +1,27 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +================== +Performance Testing User Guide (Yardstick) +================== + +.. toctree:: + :maxdepth: 2 + + 01-introduction + 02-methodology + 03-architecture + 04-vtc-overview + 05-apexlake_installation + 06-apexlake_api + 07-nsb-overview + 08-nsb_installation + 09-installation + 10-yardstick_plugin + 11-result-store-InfluxDB + 12-grafana + 13-list-of-tcs + glossary + references diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc001.rst b/docs/testing/user/userguide/opnfv_yardstick_tc001.rst new file mode 100644 index 000000000..b53c508a6 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc001.rst @@ -0,0 +1,133 @@ +s work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TC001 +************************************* + +.. _pktgen: https://www.kernel.org/doc/Documentation/networking/pktgen.txt + ++-----------------------------------------------------------------------------+ +|Network Performance | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC001_NETWORK PERFORMANCE | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of flows and throughput | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC001 is to evaluate the IaaS network | +| | performance with regards to flows and throughput, such as if | +| | and how different amounts of flows matter for the throughput | +| | between hosts on different compute blades. Typically e.g. | +| | the performance of a vSwitch depends on the number of flows | +| | running through it. Also performance of other equipment or | +| | entities can depend on the number of flows or the packet | +| | sizes used. | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | pktgen | +| | | +| | Linux packet generator is a tool to generate packets at very | +| | high speed in the kernel. pktgen is mainly used to drive and | +| | LAN equipment test network. pktgen supports multi threading. | +| | To generate random MAC address, IP address, port number UDP | +| | packets, pktgen uses multiple CPU processors in the | +| | different PCI bus (PCI, PCIe bus) with Gigabit Ethernet | +| | tested (pktgen performance depends on the CPU processing | +| | speed, memory delay, PCI bus speed hardware parameters), | +| | Transmit data rate can be even larger than 10GBit/s. Visible | +| | can satisfy most card test requirements. | +| | | +| | (Pktgen is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Docker | +| | image. | +| | As an example see the /yardstick/tools/ directory for how | +| | to generate a Linux image with pktgen included.) | +| | | ++--------------+--------------------------------------------------------------+ +|test | This test case uses Pktgen to generate packet flow between | +|description | two hosts for simulating network workloads on the SUT. | +| | | ++--------------+--------------------------------------------------------------+ +|traffic | An IP table is setup on server to monitor for received | +|profile | packets. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc001.yaml | +| | | +| | Packet size is set to 60 bytes. | +| | Number of ports: 10, 50, 100, 500 and 1000, where each | +| | runs for 20 seconds. The whole sequence is run twice | +| | The client and server are distributed on different hardware. | +| | | +| | For SLA max_ppm is set to 1000. The amount of configured | +| | ports map to between 110 up to 1001000 flows, respectively. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * packet sizes; | +| | * amount of flows; | +| | * test duration. | +| | | +| | Default values exist. | +| | | +| | SLA (optional): max_ppm: The number of packets per million | +| | packets sent that are acceptable to loose, not received. | +| | | ++--------------+--------------------------------------------------------------+ +|usability | This test case is used for generating high network | +| | throughput to simulate certain workloads on the SUT. Hence | +| | it should work with other test cases. | +| | | ++--------------+--------------------------------------------------------------+ +|references | pktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with pktgen included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | Two host VMs are booted, as server and client. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Yardstick is connected with the server VM by using ssh. | +| | 'pktgen_benchmark' bash script is copyied from Jump Host to | +| | the server VM via the ssh tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | An IP table is setup on server to monitor for received | +| | packets. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | pktgen is invoked to generate packet flow between two server | +| | and client for simulating network workloads on the SUT. | +| | Results are processed and checked against the SLA. Logs are | +| | produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 5 | Two host VMs are deleted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc002.rst b/docs/testing/user/userguide/opnfv_yardstick_tc002.rst new file mode 100644 index 000000000..c98780fd5 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc002.rst @@ -0,0 +1,126 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TC002 +************************************* + +.. _cirros-image: https://download.cirros-cloud.net +.. _Ping: https://linux.die.net/man/8/ping + ++-----------------------------------------------------------------------------+ +|Network Latency | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC002_NETWORK LATENCY | +| | | ++--------------+--------------------------------------------------------------+ +|metric | RTT (Round Trip Time) | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC002 is to do a basic verification that | +| | network latency is within acceptable boundaries when packets | +| | travel between hosts located on same or different compute | +| | blades. | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | ping | +| | | +| | Ping is a computer network administration software utility | +| | used to test the reachability of a host on an Internet | +| | Protocol (IP) network. It measures the round-trip time for | +| | packet sent from the originating host to a destination | +| | computer that are echoed back to the source. | +| | | +| | Ping is normally part of any Linux distribution, hence it | +| | doesn't need to be installed. It is also part of the | +| | Yardstick Docker image. | +| | (For example also a Cirros image can be downloaded from | +| | cirros-image_, it includes ping) | +| | | ++--------------+--------------------------------------------------------------+ +|test topology | Ping packets (ICMP protocol's mandatory ECHO_REQUEST | +| | datagram) are sent from host VM to target VM(s) to elicit | +| | ICMP ECHO_RESPONSE. | +| | | +| | For one host VM there can be multiple target VMs. | +| | Host VM and target VM(s) can be on same or different compute | +| | blades. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc002.yaml | +| | | +| | Packet size 100 bytes. Test duration 60 seconds. | +| | One ping each 10 seconds. Test is iterated two times. | +| | SLA RTT is set to maximum 10 ms. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | This test case can be configured with different: | +| | | +| | * packet sizes; | +| | * burst sizes; | +| | * ping intervals; | +| | * test durations; | +| | * test iterations. | +| | | +| | Default values exist. | +| | | +| | SLA is optional. The SLA in this test case serves as an | +| | example. Considerably lower RTT is expected, and also normal | +| | to achieve in balanced L2 environments. However, to cover | +| | most configurations, both bare metal and fully virtualized | +| | ones, this value should be possible to achieve and | +| | acceptable for black box testing. Many real time | +| | applications start to suffer badly if the RTT time is higher | +| | than this. Some may suffer bad also close to this RTT, while | +| | others may not suffer at all. It is a compromise that may | +| | have to be tuned for different configuration purposes. | +| | | ++--------------+--------------------------------------------------------------+ +|usability | This test case is one of Yardstick's generic test. Thus it | +| | is runnable on most of the scenarios. | +| | | ++--------------+--------------------------------------------------------------+ +|references | Ping_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image (cirros-image) needs to be installed | +|conditions | into Glance with ping included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | Two host VMs are booted, as server and client. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Yardstick is connected with the server VM by using ssh. | +| | 'ping_benchmark' bash script is copyied from Jump Host to | +| | the server VM via the ssh tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | Ping is invoked. Ping packets are sent from server VM to | +| | client VM. RTT results are calculated and checked against | +| | the SLA. Logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | Two host VMs are deleted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Test should not PASS if any RTT is above the optional SLA | +| | value, or if there is a test case execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc004.rst b/docs/testing/user/userguide/opnfv_yardstick_tc004.rst new file mode 100644 index 000000000..3554b3826 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc004.rst @@ -0,0 +1,110 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC004 +************************************* + +.. _cachestat: https://github.com/brendangregg/perf-tools/tree/master/fs + ++-----------------------------------------------------------------------------+ +|Cache Utilization | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC004_CACHE Utilization | +| | | ++--------------+--------------------------------------------------------------+ +|metric | cache hit, cache miss, hit/miss ratio, buffer size and page | +| | cache size | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC004 is to evaluate the IaaS compute | +| | capability with regards to cache utilization.This test case | +| | should be run in parallel with other Yardstick test cases | +| | and not run as a stand-alone test case. | +| | | +| | This test case measures cache usage statistics, including | +| | cache hit, cache miss, hit ratio, buffer cache size and page | +| | cache size, with some wokloads runing on the infrastructure. | +| | Both average and maximun values are collected. | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | cachestat | +| | | +| | cachestat is a tool using Linux ftrace capabilities for | +| | showing Linux page cache hit/miss statistics. | +| | | +| | (cachestat is not always part of a Linux distribution, hence | +| | it needs to be installed. As an example see the | +| | /yardstick/tools/ directory for how to generate a Linux | +| | image with cachestat included.) | +| | | ++--------------+--------------------------------------------------------------+ +|test | cachestat test is invoked in a host VM on a compute blade, | +|description | cachestat test requires some other test cases running in the | +| | host to stimulate workload. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | File: cachestat.yaml (in the 'samples' directory) | +| | | +| | Interval is set 1. Test repeat, pausing every 1 seconds | +| | in-between. | +| | Test durarion is set to 60 seconds. | +| | | +| | SLA is not available in this test case. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * interval; | +| | * runner Duration. | +| | | +| | Default values exist. | +| | | ++--------------+--------------------------------------------------------------+ +|usability | This test case is one of Yardstick's generic test. Thus it | +| | is runnable on most of the scenarios. | +| | | ++--------------+--------------------------------------------------------------+ +|references | cachestat_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with cachestat included in the image. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | A host VM with cachestat installed is booted. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Yardstick is connected with the host VM by using ssh. | +| | 'cache_stat' bash script is copyied from Jump Host to | +| | the server VM via the ssh tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | 'cache_stat' script is invoked. Raw cache usage statistics | +| | are collected and filtrated. Average and maximum values are | +| | calculated and recorded. Logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | The host VM is deleted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | None. Cache utilization results are collected and stored. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc005.rst b/docs/testing/user/userguide/opnfv_yardstick_tc005.rst new file mode 100644 index 000000000..1c2d71d81 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc005.rst @@ -0,0 +1,125 @@ +. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC005 +************************************* + +.. _fio: http://bluestop.org/files/fio/HOWTO.txt + ++-----------------------------------------------------------------------------+ +|Storage Performance | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC005_STORAGE PERFORMANCE | +| | | ++--------------+--------------------------------------------------------------+ +|metric | IOPS (Average IOs performed per second), | +| | Throughput (Average disk read/write bandwidth rate), | +| | Latency (Average disk read/write latency) | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC005 is to evaluate the IaaS storage | +| | performance with regards to IOPS, throughput and latency. | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | fio | +| | | +| | fio is an I/O tool meant to be used both for benchmark and | +| | stress/hardware verification. It has support for 19 | +| | different types of I/O engines (sync, mmap, libaio, | +| | posixaio, SG v3, splice, null, network, syslet, guasi, | +| | solarisaio, and more), I/O priorities (for newer Linux | +| | kernels), rate I/O, forked or threaded jobs, and much more. | +| | | +| | (fio is not always part of a Linux distribution, hence it | +| | needs to be installed. As an example see the | +| | /yardstick/tools/ directory for how to generate a Linux | +| | image with fio included.) | +| | | ++--------------+--------------------------------------------------------------+ +|test | fio test is invoked in a host VM on a compute blade, a job | +|description | file as well as parameters are passed to fio and fio will | +| | start doing what the job file tells it to do. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc005.yaml | +| | | +| | IO types is set to read, write, randwrite, randread, rw. | +| | IO block size is set to 4KB, 64KB, 1024KB. | +| | fio is run for each IO type and IO block size scheme, | +| | each iteration runs for 30 seconds (10 for ramp time, 20 for | +| | runtime). | +| | | +| | For SLA, minimum read/write iops is set to 100, | +| | minimum read/write throughput is set to 400 KB/s, | +| | and maximum read/write latency is set to 20000 usec. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | This test case can be configured with different: | +| | | +| | * IO types; | +| | * IO block size; | +| | * IO depth; | +| | * ramp time; | +| | * test duration. | +| | | +| | Default values exist. | +| | | +| | SLA is optional. The SLA in this test case serves as an | +| | example. Considerably higher throughput and lower latency | +| | are expected. However, to cover most configurations, both | +| | baremetal and fully virtualized ones, this value should be | +| | possible to achieve and acceptable for black box testing. | +| | Many heavy IO applications start to suffer badly if the | +| | read/write bandwidths are lower than this. | +| | | ++--------------+--------------------------------------------------------------+ +|usability | This test case is one of Yardstick's generic test. Thus it | +| | is runnable on most of the scenarios. | +| | | ++--------------+--------------------------------------------------------------+ +|references | fio_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with fio included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | A host VM with fio installed is booted. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Yardstick is connected with the host VM by using ssh. | +| | 'fio_benchmark' bash script is copyied from Jump Host to | +| | the host VM via the ssh tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | 'fio_benchmark' script is invoked. Simulated IO operations | +| | are started. IOPS, disk read/write bandwidth and latency are | +| | recorded and checked against the SLA. Logs are produced and | +| | stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | The host VM is deleted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc006.rst b/docs/testing/user/userguide/opnfv_yardstick_tc006.rst new file mode 100644 index 000000000..2ccb417c1 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc006.rst @@ -0,0 +1,144 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Intel Corporation and others. + +************************************* +Yardstick Test Case Description TC006 +************************************* + +.. _DPDKpktgen: https://github.com/Pktgen/Pktgen-DPDK/ +.. _rfc2544: https://www.ietf.org/rfc/rfc2544.txt + ++-----------------------------------------------------------------------------+ +|Network Performance | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC006_Virtual Traffic Classifier Data Plane | +| | Throughput Benchmarking Test. | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Throughput | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To measure the throughput supported by the virtual Traffic | +| | Classifier according to the RFC2544 methodology for a | +| | user-defined set of vTC deployment configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: file: opnfv_yardstick_tc006.yaml | +| | | +| | packet_size: size of the packets to be used during the | +| | throughput calculation. | +| | Allowe values: [64, 128, 256, 512, 1024, 1280, 1518] | +| | | +| | vnic_type: type of VNIC to be used. | +| | Allowed values are: | +| | - normal: for default OvS port configuration | +| | - direct: for SR-IOV port configuration | +| | Default value: None | +| | | +| | vtc_flavor: OpenStack flavor to be used for the vTC | +| | Default available values are: m1.small, m1.medium, | +| | and m1.large, but the user can create his/her own | +| | flavor and give it as input | +| | Default value: None | +| | | +| | vlan_sender: vlan tag of the network on which the vTC will | +| | receive traffic (VLAN Network 1). | +| | Allowed values: range (1, 4096) | +| | | +| | vlan_receiver: vlan tag of the network on which the vTC | +| | will send traffic back to the packet generator | +| | (VLAN Network 2). | +| | Allowed values: range (1, 4096) | +| | | +| | default_net_name: neutron name of the defaul network that | +| | is used for access to the internet from the vTC | +| | (vNIC 1). | +| | | +| | default_subnet_name: subnet name for vNIC1 | +| | (information available through Neutron). | +| | | +| | vlan_net_1_name: Neutron Name for VLAN Network 1 | +| | (information available through Neutron). | +| | | +| | vlan_subnet_1_name: Subnet Neutron name for VLAN Network 1 | +| | (information available through Neutron). | +| | | +| | vlan_net_2_name: Neutron Name for VLAN Network 2 | +| | (information available through Neutron). | +| | | +| | vlan_subnet_2_name: Subnet Neutron name for VLAN Network 2 | +| | (information available through Neutron). | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | DPDK pktgen | +| | | +| | DPDK Pktgen is not part of a Linux distribution, | +| | hence it needs to be installed by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|references | DPDK Pktgen: DPDKpktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | +| | RFC 2544: rfc2544_ | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different flavors, vNIC type | +| | and packet sizes. Default values exist as specified above. | +| | The vNIC type and flavor MUST be specified by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The vTC has been successfully instantiated and configured. | +| | The user has correctly assigned the values to the deployment | +| | configuration parameters. | +| | | +| | - Multicast traffic MUST be enabled on the network. | +| | The Data network switches need to be configured in | +| | order to manage multicast traffic. | +| | - In the case of SR-IOV vNICs use, SR-IOV compatible NICs | +| | must be used on the compute node. | +| | - Yarsdtick needs to be installed on a host connected to the | +| | data network and the host must have 2 DPDK-compatible | +| | NICs. Proper configuration of DPDK and DPDK pktgen is | +| | required before to run the test case. | +| | (For further instructions please refer to the ApexLake | +| | documentation). | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | Description and expected results | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The vTC is deployed, according to the user-defined | +| | configuration | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | The vTC is correctly deployed and configured as necessary | +| | The initialization script has been correctly executed and | +| | vTC is ready to receive and process the traffic. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | Test case is executed with the selected parameters: | +| | - vTC flavor | +| | - vNIC type | +| | - packet size | +| | The traffic is sent to the vTC using the maximum available | +| | traffic rate for 60 seconds. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | The vTC instance forwards all the packets back to the packet | +| | generator for 60 seconds, as specified by RFC 2544. | +| | | +| | Steps 3 and 4 are executed different times, with different | +| | rates in order to find the maximum supported traffic rate | +| | according to the current definition of throughput in RFC | +| | 2544. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | The result of the test is a number between 0 and 100 which | +| | represents the throughput in terms of percentage of the | +| | available pktgen NIC bandwidth. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc007.rst b/docs/testing/user/userguide/opnfv_yardstick_tc007.rst new file mode 100644 index 000000000..87663f816 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc007.rst @@ -0,0 +1,162 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Intel Corporation and others. + +************************************* +Yardstick Test Case Description TC007 +************************************* + +.. _DPDKpktgen: https://github.com/Pktgen/Pktgen-DPDK/ +.. _rfc2544: https://www.ietf.org/rfc/rfc2544.txt + ++-----------------------------------------------------------------------------+ +|Network Performance | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC007_Virtual Traffic Classifier Data Plane | +| | Throughput Benchmarking Test in Presence of Noisy | +| | neighbours | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Throughput | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To measure the throughput supported by the virtual Traffic | +| | Classifier according to the RFC2544 methodology for a | +| | user-defined set of vTC deployment configurations in the | +| | presence of noisy neighbours. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc007.yaml | +| | | +| | packet_size: size of the packets to be used during the | +| | throughput calculation. | +| | Allowe values: [64, 128, 256, 512, 1024, 1280, 1518] | +| | | +| | vnic_type: type of VNIC to be used. | +| | Allowed values are: | +| | - normal: for default OvS port configuration | +| | - direct: for SR-IOV port configuration | +| | | +| | vtc_flavor: OpenStack flavor to be used for the vTC | +| | Default available values are: m1.small, m1.medium, | +| | and m1.large, but the user can create his/her own | +| | flavor and give it as input | +| | | +| | num_of_neighbours: Number of noisy neighbours (VMs) to be | +| | instantiated during the experiment. | +| | Allowed values: range (1, 10) | +| | | +| | amount_of_ram: RAM to be used by each neighbor. | +| | Allowed values: ['250M', '1G', '2G', '3G', '4G', '5G', | +| | '6G', '7G', '8G', '9G', '10G'] | +| | Deault value: 256M | +| | | +| | number_of_cores: Number of noisy neighbours (VMs) to be | +| | instantiated during the experiment. | +| | Allowed values: range (1, 10) | +| | Default value: 1 | +| | | +| | vlan_sender: vlan tag of the network on which the vTC will | +| | receive traffic (VLAN Network 1). | +| | Allowed values: range (1, 4096) | +| | | +| | vlan_receiver: vlan tag of the network on which the vTC | +| | will send traffic back to the packet generator | +| | (VLAN Network 2). | +| | Allowed values: range (1, 4096) | +| | | +| | default_net_name: neutron name of the defaul network that | +| | is used for access to the internet from the vTC | +| | (vNIC 1). | +| | | +| | default_subnet_name: subnet name for vNIC1 | +| | (information available through Neutron). | +| | | +| | vlan_net_1_name: Neutron Name for VLAN Network 1 | +| | (information available through Neutron). | +| | | +| | vlan_subnet_1_name: Subnet Neutron name for VLAN Network 1 | +| | (information available through Neutron). | +| | | +| | vlan_net_2_name: Neutron Name for VLAN Network 2 | +| | (information available through Neutron). | +| | | +| | vlan_subnet_2_name: Subnet Neutron name for VLAN Network 2 | +| | (information available through Neutron). | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | DPDK pktgen | +| | | +| | DPDK Pktgen is not part of a Linux distribution, | +| | hence it needs to be installed by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|references | DPDKpktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | +| | rfc2544_ | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different flavors, vNIC type | +| | and packet sizes. Default values exist as specified above. | +| | The vNIC type and flavor MUST be specified by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The vTC has been successfully instantiated and configured. | +| | The user has correctly assigned the values to the deployment | +| | configuration parameters. | +| | | +| | - Multicast traffic MUST be enabled on the network. | +| | The Data network switches need to be configured in | +| | order to manage multicast traffic. | +| | - In the case of SR-IOV vNICs use, SR-IOV compatible NICs | +| | must be used on the compute node. | +| | - Yarsdtick needs to be installed on a host connected to the | +| | data network and the host must have 2 DPDK-compatible | +| | NICs. Proper configuration of DPDK and DPDK pktgen is | +| | required before to run the test case. | +| | (For further instructions please refer to the ApexLake | +| | documentation). | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | Description and expected results | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The noisy neighbours are deployed as required by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | The vTC is deployed, according to the configuration required | +| | by the user | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | The vTC is correctly deployed and configured as necessary. | +| | The initialization script has been correctly executed and | +| | the vTC is ready to receive and process the traffic. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | Test case is executed with the parameters specified by the | +| | user: | +| | - vTC flavor | +| | - vNIC type | +| | - packet size | +| | The traffic is sent to the vTC using the maximum available | +| | traffic rate | +| | | ++--------------+--------------------------------------------------------------+ +|step 5 | The vTC instance forwards all the packets back to the | +| | packet generator for 60 seconds, as specified by RFC 2544. | +| | | +| | Steps 4 and 5 are executed different times with different | +| | with different traffic rates, in order to find the maximum | +| | supported traffic rate, accoring to the current definition | +| | of throughput in RFC 2544. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | The result of the test is a number between 0 and 100 which | +| | represents the throughput in terms of percentage of the | +| | available pktgen NIC bandwidth. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc008.rst b/docs/testing/user/userguide/opnfv_yardstick_tc008.rst new file mode 100644 index 000000000..a4ecaf6ae --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc008.rst @@ -0,0 +1,90 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TC008 +************************************* + +.. _pktgen: https://www.kernel.org/doc/Documentation/networking/pktgen.txt + ++-----------------------------------------------------------------------------+ +|Packet Loss Extended Test | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC008_NW PERF, Packet loss Extended Test | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of flows, packet size and throughput | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS network performance with regards to | +| | flows and throughput, such as if and how different amounts | +| | of packet sizes and flows matter for the throughput between | +| | VMs on different compute blades. Typically e.g. the | +| | performance of a vSwitch | +| | depends on the number of flows running through it. Also | +| | performance of other equipment or entities can depend | +| | on the number of flows or the packet sizes used. | +| | The purpose is also to be able to spot trends. Test results, | +| | graphs ans similar shall be stored for comparison reasons and| +| | product evolution understanding between different OPNFV | +| | versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc008.yaml | +| | | +| | Packet size: 64, 128, 256, 512, 1024, 1280 and 1518 bytes. | +| | | +| | Number of ports: 1, 10, 50, 100, 500 and 1000. The amount of | +| | configured ports map from 2 up to 1001000 flows, | +| | respectively. Each packet_size/port_amount combination is run| +| | ten times, for 20 seconds each. Then the next | +| | packet_size/port_amount combination is run, and so on. | +| | | +| | The client and server are distributed on different HW. | +| | | +| | For SLA max_ppm is set to 1000. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | pktgen | +| | | +| | (Pktgen is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Docker | +| | image. | +| | As an example see the /yardstick/tools/ directory for how | +| | to generate a Linux image with pktgen included.) | +| | | ++--------------+--------------------------------------------------------------+ +|references | pktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different packet sizes, amount | +| | of flows and test duration. Default values exist. | +| | | +| | SLA (optional): max_ppm: The number of packets per million | +| | packets sent that are acceptable to loose, not received. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with pktgen included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The hosts are installed, as server and client. pktgen is | +| | invoked and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc009.rst b/docs/testing/user/userguide/opnfv_yardstick_tc009.rst new file mode 100644 index 000000000..d6f445361 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc009.rst @@ -0,0 +1,89 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TC009 +************************************* + +.. _pktgen: https://www.kernel.org/doc/Documentation/networking/pktgen.txt + ++-----------------------------------------------------------------------------+ +|Packet Loss | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC009_NW PERF, Packet loss | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of flows, packets lost and throughput | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS network performance with regards to | +| | flows and throughput, such as if and how different amounts | +| | of flows matter for the throughput between VMs on different | +| | compute blades. | +| | Typically e.g. the performance of a vSwitch | +| | depends on the number of flows running through it. Also | +| | performance of other equipment or entities can depend | +| | on the number of flows or the packet sizes used. | +| | The purpose is also to be able to spot trends. Test results, | +| | graphs ans similar shall be stored for comparison reasons and| +| | product evolution understanding between different OPNFV | +| | versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc009.yaml | +| | | +| | Packet size: 64 bytes | +| | | +| | Number of ports: 1, 10, 50, 100, 500 and 1000. The amount of | +| | configured ports map from 2 up to 1001000 flows, | +| | respectively. Each port amount is run ten times, for 20 | +| | seconds each. Then the next port_amount is run, and so on. | +| | | +| | The client and server are distributed on different HW. | +| | | +| | For SLA max_ppm is set to 1000. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | pktgen | +| | | +| | (Pktgen is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Docker | +| | image. | +| | As an example see the /yardstick/tools/ directory for how | +| | to generate a Linux image with pktgen included.) | +| | | ++--------------+--------------------------------------------------------------+ +|references | pktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different packet sizes, amount | +| | of flows and test duration. Default values exist. | +| | | +| | SLA (optional): max_ppm: The number of packets per million | +| | packets sent that are acceptable to loose, not received. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with pktgen included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The hosts are installed, as server and client. pktgen is | +| | invoked and logs are produced and stored. | +| | | +| | Result: logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc010.rst b/docs/testing/user/userguide/opnfv_yardstick_tc010.rst new file mode 100644 index 000000000..202307de6 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc010.rst @@ -0,0 +1,154 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TC010 +************************************* + +.. _lat_mem_rd: http://manpages.ubuntu.com/manpages/trusty/lat_mem_rd.8.html + ++-----------------------------------------------------------------------------+ +|Memory Latency | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC010_MEMORY LATENCY | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Memory read latency (nanoseconds) | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC010 is to evaluate the IaaS compute | +| | performance with regards to memory read latency. | +| | It measures the memory read latency for varying memory sizes | +| | and strides. Whole memory hierarchy is measured. | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Lmbench | +| | | +| | Lmbench is a suite of operating system microbenchmarks. This | +| | test uses lat_mem_rd tool from that suite including: | +| | * Context switching | +| | * Networking: connection establishment, pipe, TCP, UDP, and | +| | RPC hot potato | +| | * File system creates and deletes | +| | * Process creation | +| | * Signal handling | +| | * System call overhead | +| | * Memory read latency | +| | | +| | (LMbench is not always part of a Linux distribution, hence | +| | it needs to be installed. As an example see the | +| | /yardstick/tools/ directory for how to generate a Linux | +| | image with LMbench included.) | +| | | ++--------------+--------------------------------------------------------------+ +|test | LMbench lat_mem_rd benchmark measures memory read latency | +|description | for varying memory sizes and strides. | +| | | +| | The benchmark runs as two nested loops. The outer loop is | +| | the stride size. The inner loop is the array size. For each | +| | array size, the benchmark creates a ring of pointers that | +| | point backward one stride.Traversing the array is done by: | +| | | +| | p = (char **)*p; | +| | | +| | in a for loop (the over head of the for loop is not | +| | significant; the loop is an unrolled loop 100 loads long). | +| | The size of the array varies from 512 bytes to (typically) | +| | eight megabytes. For the small sizes, the cache will have an | +| | effect, and the loads will be much faster. This becomes much | +| | more apparent when the data is plotted. | +| | | +| | Only data accesses are measured; the instruction cache is | +| | not measured. | +| | | +| | The results are reported in nanoseconds per load and have | +| | been verified accurate to within a few nanoseconds on an SGI | +| | Indy. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | File: opnfv_yardstick_tc010.yaml | +| | | +| | * SLA (max_latency): 30 nanoseconds | +| | * Stride - 128 bytes | +| | * Stop size - 64 megabytes | +| | * Iterations: 10 - test is run 10 times iteratively. | +| | * Interval: 1 - there is 1 second delay between each | +| | iteration. | +| | | +| | SLA is optional. The SLA in this test case serves as an | +| | example. Considerably lower read latency is expected. | +| | However, to cover most configurations, both baremetal and | +| | fully virtualized ones, this value should be possible to | +| | achieve and acceptable for black box testing. | +| | Many heavy IO applications start to suffer badly if the | +| | read latency is higher than this. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * strides; | +| | * stop_size; | +| | * iterations and intervals. | +| | | +| | Default values exist. | +| | | +| | SLA (optional) : max_latency: The maximum memory latency | +| | that is accepted. | +| | | ++--------------+--------------------------------------------------------------+ +|usability | This test case is one of Yardstick's generic test. Thus it | +| | is runnable on most of the scenarios. | +| | | ++--------------+--------------------------------------------------------------+ +|references | LMbench lat_mem_rd_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with Lmbench included in the image. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The host is installed as client. LMbench's lat_mem_rd tool | +| | is invoked and logs are produced and stored. | +| | | +| | Result: logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | A host VM with LMbench installed is booted. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Yardstick is connected with the host VM by using ssh. | +| | 'lmbench_latency_benchmark' bash script is copyied from Jump | +| | Host to the host VM via the ssh tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | 'lmbench_latency_benchmark' script is invoked. LMbench's | +| | lat_mem_rd benchmark starts to measures memory read latency | +| | for varying memory sizes and strides. Memory read latency | +| | are recorded and checked against the SLA. Logs are produced | +| | and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | The host VM is deleted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Test fails if the measured memory latency is above the SLA | +| | value or if there is a test case execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc011.rst b/docs/testing/user/userguide/opnfv_yardstick_tc011.rst new file mode 100644 index 000000000..48bdef497 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc011.rst @@ -0,0 +1,123 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC011 +************************************* + +.. _iperf3: https://iperf.fr/ + ++-----------------------------------------------------------------------------+ +|Packet delay variation between VMs | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC011_PACKET DELAY VARIATION BETWEEN VMs | +| | | ++--------------+--------------------------------------------------------------+ +|metric | jitter: packet delay variation (ms) | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC011 is to evaluate the IaaS network | +| | performance with regards to network jitter (packet delay | +| | variation). | +| | It measures the packet delay variation sending the packets | +| | from one VM to the other. | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | iperf3 | +| | | +| | iPerf3 is a tool for active measurements of the maximum | +| | achievable bandwidth on IP networks. It supports tuning of | +| | various parameters related to timing, buffers and protocols. | +| | The UDP protocols can be used to measure jitter delay. | +| | | +| | (iperf3 is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Docker | +| | image. As an example see the /yardstick/tools/ directory for | +| | how to generate a Linux image with pktgen included.) | +| | | ++--------------+--------------------------------------------------------------+ +|test | iperf3 test is invoked between a host VM and a target VM. | +|description | | +| | Jitter calculations are continuously computed by the server, | +| | as specified by RTP in RFC 1889. The client records a 64 bit | +| | second/microsecond timestamp in the packet. The server | +| | computes the relative transit time as (server's receive time | +| | - client's send time). The client's and server's clocks do | +| | not need to be synchronized; any difference is subtracted | +| | outin the jitter calculation. Jitter is the smoothed mean of | +| | differences between consecutive transit times. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | File: opnfv_yardstick_tc011.yaml | +| | | +| | * options: | +| | protocol: udp # The protocol used by iperf3 tools | +| | bandwidth: 20m # It will send the given number of packets | +| | without pausing | +| | * runner: | +| | duration: 30 # Total test duration 30 seconds. | +| | | +| | * SLA (optional): | +| | jitter: 10 (ms) # The maximum amount of jitter that is | +| | accepted. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * bandwidth: Test case can be configured with different | +| | bandwidth. | +| | | +| | * duration: The test duration can be configured. | +| | | +| | * jitter: SLA is optional. The SLA in this test case | +| | serves as an example. | +| | | ++--------------+--------------------------------------------------------------+ +|usability | This test case is one of Yardstick's generic test. Thus it | +| | is runnable on most of the scenarios. | +| | | ++--------------+--------------------------------------------------------------+ +|references | iperf3_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with iperf3 included in the image. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | Two host VMs with iperf3 installed are booted, as server and | +| | client. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Yardstick is connected with the host VM by using ssh. | +| | A iperf3 server is started on the server VM via the ssh | +| | tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | iperf3 benchmark is invoked. Jitter is calculated and check | +| | against the SLA. Logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | The host VMs are deleted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Test should not PASS if any jitter is above the optional SLA | +| | value, or if there is a test case execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc012.rst b/docs/testing/user/userguide/opnfv_yardstick_tc012.rst new file mode 100644 index 000000000..b56e829f5 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc012.rst @@ -0,0 +1,135 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TC012 +************************************* + +.. _bw_mem: http://manpages.ubuntu.com/manpages/trusty/bw_mem.8.html + ++-----------------------------------------------------------------------------+ +|Memory Bandwidth | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC012_MEMORY BANDWIDTH | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Memory read/write bandwidth (MBps) | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC012 is to evaluate the IaaS compute | +| | performance with regards to memory throughput. | +| | It measures the rate at which data can be read from and | +| | written to the memory (this includes all levels of memory). | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | LMbench | +| | | +| | LMbench is a suite of operating system microbenchmarks. | +| | This test uses bw_mem tool from that suite including: | +| | * Cached file read | +| | * Memory copy (bcopy) | +| | * Memory read | +| | * Memory write | +| | * Pipe | +| | * TCP | +| | | +| | (LMbench is not always part of a Linux distribution, hence | +| | it needs to be installed. As an example see the | +| | /yardstick/tools/ directory for how to generate a Linux | +| | image with LMbench included.) | +| | | ++--------------+--------------------------------------------------------------+ +|test | LMbench bw_mem benchmark allocates twice the specified | +|description | amount of memory, zeros it, and then times the copying of | +| | the first half to the second half. The benchmark is invoked | +| | in a host VM on a compute blade. Results are reported in | +| | megabytes moved per second. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | File: opnfv_yardstick_tc012.yaml | +| | | +| | * SLA (optional): 15000 (MBps) min_bw: The minimum amount of | +| | memory bandwidth that is accepted. | +| | * Size: 10 240 kB - test allocates twice that size | +| | (20 480kB) zeros it and then measures the time it takes to | +| | copy from one side to another. | +| | * Benchmark: rdwr - measures the time to read data into | +| | memory and then write data to the same location. | +| | * Warmup: 0 - the number of iterations to perform before | +| | taking actual measurements. | +| | * Iterations: 10 - test is run 10 times iteratively. | +| | * Interval: 1 - there is 1 second delay between each | +| | iteration. | +| | | +| | SLA is optional. The SLA in this test case serves as an | +| | example. Considerably higher bandwidth is expected. | +| | However, to cover most configurations, both baremetal and | +| | fully virtualized ones, this value should be possible to | +| | achieve and acceptable for black box testing. | +| | Many heavy IO applications start to suffer badly if the | +| | read/write bandwidths are lower than this. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * memory sizes; | +| | * memory operations (such as rd, wr, rdwr, cp, frd, fwr, | +| | fcp, bzero, bcopy); | +| | * number of warmup iterations; | +| | * iterations and intervals. | +| | | +| | Default values exist. | +| | | +| | SLA (optional) : min_bandwidth: The minimun memory bandwidth | +| | that is accepted. | +| | | ++--------------+--------------------------------------------------------------+ +|usability | This test case is one of Yardstick's generic test. Thus it | +| | is runnable on most of the scenarios. | +| | | ++--------------+--------------------------------------------------------------+ +|references | LMbench bw_mem_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with Lmbench included in the image. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | A host VM with LMbench installed is booted. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Yardstick is connected with the host VM by using ssh. | +| | "lmbench_bandwidth_benchmark" bash script is copied from | +| | Jump Host to the host VM via ssh tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | 'lmbench_bandwidth_benchmark' script is invoked. LMbench's | +| | bw_mem benchmark starts to measures memory read/write | +| | bandwidth. Memory read/write bandwidth results are recorded | +| | and checked against the SLA. Logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | The host VM is deleted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Test fails if the measured memory bandwidth is below the SLA | +| | value or if there is a test case execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc014.rst b/docs/testing/user/userguide/opnfv_yardstick_tc014.rst new file mode 100644 index 000000000..1b0d7831a --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc014.rst @@ -0,0 +1,126 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC014 +************************************* + +.. _unixbench: https://github.com/kdlucas/byte-unixbench/blob/master/UnixBench + ++-----------------------------------------------------------------------------+ +|Processing speed | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC014_PROCESSING SPEED | +| | | ++--------------+--------------------------------------------------------------+ +|metric | score of single cpu running, | +| | score of parallel running | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC014 is to evaluate the IaaS compute | +| | performance with regards to CPU processing speed. | +| | It measures score of single cpu running and parallel | +| | running. | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | UnixBench | +| | | +| | Unixbench is the most used CPU benchmarking software tool. | +| | It can measure the performance of bash scripts, CPUs in | +| | multithreading and single threading. It can also measure the | +| | performance for parallel taks. Also, specific disk IO for | +| | small and large files are performed. You can use it to | +| | measure either linux dedicated servers and linux vps | +| | servers, running CentOS, Debian, Ubuntu, Fedora and other | +| | distros. | +| | | +| | (UnixBench is not always part of a Linux distribution, hence | +| | it needs to be installed. As an example see the | +| | /yardstick/tools/ directory for how to generate a Linux | +| | image with UnixBench included.) | +| | | ++--------------+--------------------------------------------------------------+ +|test | The UnixBench runs system benchmarks in a host VM on a | +|description | compute blade, getting information on the CPUs in the | +| | system. If the system has more than one CPU, the tests will | +| | be run twice -- once with a single copy of each test running | +| | at once, and once with N copies, where N is the number of | +| | CPUs. | +| | | +| | UnixBench will processs a set of results from a single test | +| | by averaging the individal pass results into a single final | +| | value. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc014.yaml | +| | | +| | run_mode: Run unixbench in quiet mode or verbose mode | +| | test_type: dhry2reg, whetstone and so on | +| | | +| | For SLA with single_score and parallel_score, both can be | +| | set by user, default is NA. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * test types; | +| | * dhry2reg; | +| | * whetstone. | +| | | +| | Default values exist. | +| | | +| | SLA (optional) : min_score: The minimun UnixBench score that | +| | is accepted. | +| | | ++--------------+--------------------------------------------------------------+ +|usability | This test case is one of Yardstick's generic test. Thus it | +| | is runnable on most of the scenarios. | +| | | ++--------------+--------------------------------------------------------------+ +|references | unixbench_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with unixbench included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | A host VM with UnixBench installed is booted. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Yardstick is connected with the host VM by using ssh. | +| | "unixbench_benchmark" bash script is copied from Jump Host | +| | to the host VM via ssh tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | UnixBench is invoked. All the tests are executed using the | +| | "Run" script in the top-level of UnixBench directory. | +| | The "Run" script will run a standard "index" test, and save | +| | the report in the "results" directory. Then the report is | +| | processed by "unixbench_benchmark" and checked againsted the | +| | SLA. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | The host VM is deleted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc019.rst b/docs/testing/user/userguide/opnfv_yardstick_tc019.rst new file mode 100644 index 000000000..1af502253 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc019.rst @@ -0,0 +1,134 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC019 +************************************* + ++-----------------------------------------------------------------------------+ +|Control Node Openstack Service High Availability | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC019_HA: Control node Openstack service down| +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of the | +| | service provided by OpenStack (like nova-api, neutro-server) | +| | on control node. | +| | | ++--------------+--------------------------------------------------------------+ +|test method | This test case kills the processes of a specific Openstack | +| | service on a selected control node, then checks whether the | +| | request of the related Openstack command is OK and the killed| +| | processes are recovered. | +| | | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "kill-process" is | +| | needed. This attacker includes three parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "kill-process" in this | +| | test case. | +| | 2) process_name: which is the process name of the specified | +| | OpenStack service. If there are multiple processes use the | +| | same name on the host, all of them are killed by this | +| | attacker. | +| | 3) host: which is the name of a control node being attacked. | +| | | +| | e.g. | +| | -fault_type: "kill-process" | +| | -process_name: "nova-api" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, two kinds of monitor are needed: | +| | 1. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request | +| | | +| | 2. the "process" monitor check whether a process is running | +| | on a specific node, which needs three parameters: | +| | 1) monitor_type: which used for finding the monitor class and| +| | related scritps. It should be always set to "process" | +| | for this monitor. | +| | 2) process_name: which is the process name for monitor | +| | 3) host: which is the name of the node runing the process | +| | | +| | e.g. | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "nova image-list" | +| | monitor2: | +| | -monitor_type: "process" | +| | -process_name: "nova-api" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there are two metrics: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | +| | 2)process_recover_time: which indicates the maximun time | +| | (seconds) from the process being killed to recovered | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc019.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the kill process script with param value specified by | +| | "process_name" | +| | | +| | Result: Process will be killed. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It will check the| +| | status of the specified process on the host, and restart the | +| | process if it is not running for next test cases | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc020.rst b/docs/testing/user/userguide/opnfv_yardstick_tc020.rst new file mode 100644 index 000000000..f2f1d408b --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc020.rst @@ -0,0 +1,141 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Intel Corporation and others. + +************************************* +Yardstick Test Case Description TC020 +************************************* + +.. _DPDKpktgen: https://github.com/Pktgen/Pktgen-DPDK/ +.. _rfc2544: https://www.ietf.org/rfc/rfc2544.txt + ++-----------------------------------------------------------------------------+ +|Network Performance | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC0020_Virtual Traffic Classifier | +| | Instantiation Test | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Failure | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To verify that a newly instantiated vTC is 'alive' and | +| | functional and its instantiation is correctly supported by | +| | the infrastructure. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc020.yaml | +| | | +| | vnic_type: type of VNIC to be used. | +| | Allowed values are: | +| | - normal: for default OvS port configuration | +| | - direct: for SR-IOV port configuration | +| | Default value: None | +| | | +| | vtc_flavor: OpenStack flavor to be used for the vTC | +| | Default available values are: m1.small, m1.medium, | +| | and m1.large, but the user can create his/her own | +| | flavor and give it as input | +| | Default value: None | +| | | +| | vlan_sender: vlan tag of the network on which the vTC will | +| | receive traffic (VLAN Network 1). | +| | Allowed values: range (1, 4096) | +| | | +| | vlan_receiver: vlan tag of the network on which the vTC | +| | will send traffic back to the packet generator | +| | (VLAN Network 2). | +| | Allowed values: range (1, 4096) | +| | | +| | default_net_name: neutron name of the defaul network that | +| | is used for access to the internet from the vTC | +| | (vNIC 1). | +| | | +| | default_subnet_name: subnet name for vNIC1 | +| | (information available through Neutron). | +| | | +| | vlan_net_1_name: Neutron Name for VLAN Network 1 | +| | (information available through Neutron). | +| | | +| | vlan_subnet_1_name: Subnet Neutron name for VLAN Network 1 | +| | (information available through Neutron). | +| | | +| | vlan_net_2_name: Neutron Name for VLAN Network 2 | +| | (information available through Neutron). | +| | | +| | vlan_subnet_2_name: Subnet Neutron name for VLAN Network 2 | +| | (information available through Neutron). | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | DPDK pktgen | +| | | +| | DPDK Pktgen is not part of a Linux distribution, | +| | hence it needs to be installed by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|references | DPDKpktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | +| | rfc2544_ | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different flavors, vNIC type | +| | and packet sizes. Default values exist as specified above. | +| | The vNIC type and flavor MUST be specified by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The vTC has been successfully instantiated and configured. | +| | The user has correctly assigned the values to the deployment | +| | configuration parameters. | +| | | +| | - Multicast traffic MUST be enabled on the network. | +| | The Data network switches need to be configured in | +| | order to manage multicast traffic. | +| | Installation and configuration of smcroute is required | +| | before to run the test case. | +| | (For further instructions please refer to the ApexLake | +| | documentation). | +| | - In the case of SR-IOV vNICs use, SR-IOV compatible NICs | +| | must be used on the compute node. | +| | - Yarsdtick needs to be installed on a host connected to the | +| | data network and the host must have 2 DPDK-compatible | +| | NICs. Proper configuration of DPDK and DPDK pktgen is | +| | required before to run the test case. | +| | (For further instructions please refer to the ApexLake | +| | documentation). | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | Description and expected results | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The vTC is deployed, according to the configuration provided | +| | by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | The vTC is correctly deployed and configured as necessary. | +| | The initialization script has been correctly executed and | +| | the vTC is ready to receive and process the traffic. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | Test case is executed with the parameters specified by the | +| | the user: | +| | - vTC flavor | +| | - vNIC type | +| | A constant rate traffic is sent to the vTC for 10 seconds. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | The vTC instance tags all the packets and sends them back to | +| | the packet generator for 10 seconds. | +| | | +| | The framework checks that the packet generator receives | +| | back all the packets with the correct tag from the vTC. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | The vTC is deemed to be successfully instantiated if all | +| | packets are sent back with the right tag as requested, | +| | else it is deemed DoA (Dead on arrival) | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc021.rst b/docs/testing/user/userguide/opnfv_yardstick_tc021.rst new file mode 100644 index 000000000..c7adc870a --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc021.rst @@ -0,0 +1,157 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Intel Corporation and others. + +************************************* +Yardstick Test Case Description TC021 +************************************* + +.. _DPDKpktgen: https://github.com/Pktgen/Pktgen-DPDK/ +.. _rfc2544: https://www.ietf.org/rfc/rfc2544.txt + ++-----------------------------------------------------------------------------+ +|Network Performance | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC0021_Virtual Traffic Classifier | +| | Instantiation Test in Presence of Noisy Neighbours | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Failure | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To verify that a newly instantiated vTC is 'alive' and | +| | functional and its instantiation is correctly supported by | +| | the infrastructure in the presence of noisy neighbours. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc021.yaml | +| | | +| | vnic_type: type of VNIC to be used. | +| | Allowed values are: | +| | - normal: for default OvS port configuration | +| | - direct: for SR-IOV port configuration | +| | Default value: None | +| | | +| | vtc_flavor: OpenStack flavor to be used for the vTC | +| | Default available values are: m1.small, m1.medium, | +| | and m1.large, but the user can create his/her own | +| | flavor and give it as input | +| | Default value: None | +| | | +| | num_of_neighbours: Number of noisy neighbours (VMs) to be | +| | instantiated during the experiment. | +| | Allowed values: range (1, 10) | +| | | +| | amount_of_ram: RAM to be used by each neighbor. | +| | Allowed values: ['250M', '1G', '2G', '3G', '4G', '5G', | +| | '6G', '7G', '8G', '9G', '10G'] | +| | Deault value: 256M | +| | | +| | number_of_cores: Number of noisy neighbours (VMs) to be | +| | instantiated during the experiment. | +| | Allowed values: range (1, 10) | +| | Default value: 1 | +| | | +| | vlan_sender: vlan tag of the network on which the vTC will | +| | receive traffic (VLAN Network 1). | +| | Allowed values: range (1, 4096) | +| | | +| | vlan_receiver: vlan tag of the network on which the vTC | +| | will send traffic back to the packet generator | +| | (VLAN Network 2). | +| | Allowed values: range (1, 4096) | +| | | +| | default_net_name: neutron name of the defaul network that | +| | is used for access to the internet from the vTC | +| | (vNIC 1). | +| | | +| | default_subnet_name: subnet name for vNIC1 | +| | (information available through Neutron). | +| | | +| | vlan_net_1_name: Neutron Name for VLAN Network 1 | +| | (information available through Neutron). | +| | | +| | vlan_subnet_1_name: Subnet Neutron name for VLAN Network 1 | +| | (information available through Neutron). | +| | | +| | vlan_net_2_name: Neutron Name for VLAN Network 2 | +| | (information available through Neutron). | +| | | +| | vlan_subnet_2_name: Subnet Neutron name for VLAN Network 2 | +| | (information available through Neutron). | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | DPDK pktgen | +| | | +| | DPDK Pktgen is not part of a Linux distribution, | +| | hence it needs to be installed by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|references | DPDK Pktgen: DPDK Pktgen: DPDKpktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | +| | RFC 2544: rfc2544_ | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different flavors, vNIC type | +| | and packet sizes. Default values exist as specified above. | +| | The vNIC type and flavor MUST be specified by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The vTC has been successfully instantiated and configured. | +| | The user has correctly assigned the values to the deployment | +| | configuration parameters. | +| | | +| | - Multicast traffic MUST be enabled on the network. | +| | The Data network switches need to be configured in | +| | order to manage multicast traffic. | +| | Installation and configuration of smcroute is required | +| | before to run the test case. | +| | (For further instructions please refer to the ApexLake | +| | documentation). | +| | - In the case of SR-IOV vNICs use, SR-IOV compatible NICs | +| | must be used on the compute node. | +| | - Yarsdtick needs to be installed on a host connected to the | +| | data network and the host must have 2 DPDK-compatible | +| | NICs. Proper configuration of DPDK and DPDK pktgen is | +| | required before to run the test case. | +| | (For further instructions please refer to the ApexLake | +| | documentation). | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | Description and expected results | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The noisy neighbours are deployed as required by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | The vTC is deployed, according to the configuration provided | +| | by the user. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | The vTC is correctly deployed and configured as necessary. | +| | The initialization script has been correctly executed and | +| | the vTC is ready to receive and process the traffic. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | Test case is executed with the selected parameters: | +| | - vTC flavor | +| | - vNIC type | +| | A constant rate traffic is sent to the vTC for 10 seconds. | +| | | ++--------------+--------------------------------------------------------------+ +|step 5 | The vTC instance tags all the packets and sends them back to | +| | the packet generator for 10 seconds. | +| | | +| | The framework checks if the packet generator receives back | +| | all the packets with the correct tag from the vTC. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | The vTC is deemed to be successfully instantiated if all | +| | packets are sent back with the right tag as requested, | +| | else it is deemed DoA (Dead on arrival) | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc024.rst b/docs/testing/user/userguide/opnfv_yardstick_tc024.rst new file mode 100644 index 000000000..8d15e8d2f --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc024.rst @@ -0,0 +1,76 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TC024 +************************************* + +.. _man-pages: http://manpages.ubuntu.com/manpages/trusty/man1/mpstat.1.html + ++-----------------------------------------------------------------------------+ +| CPU Load | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC024_CPU Load | +| | | ++--------------+--------------------------------------------------------------+ +|metric | CPU load | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the CPU load performance of the IaaS. This test | +| | case should be run in parallel to other Yardstick test cases | +| | and not run as a stand-alone test case. | +| | Average, minimum and maximun values are obtained. | +| | The purpose is also to be able to spot trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: cpuload.yaml (in the 'samples' directory) | +| | | +| | * interval: 1 - repeat, pausing every 1 seconds in-between. | +| | * count: 10 - display statistics 10 times, then exit. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | mpstat | +| | | +| | (mpstat is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Glance | +| | image. However, if mpstat is not present the TC instead uses | +| | /proc/stats as source to produce "mpstat" output. | +| | | ++--------------+--------------------------------------------------------------+ +|references | man-pages_ | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * interval; | +| | * count; | +| | * runner Iteration and intervals. | +| | | +| | There are default values for each above-mentioned option. | +| | Run in background with other test cases. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with mpstat included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The host is installed. The related TC, or TCs, is | +| | invoked and mpstat logs are produced and stored. | +| | | +| | Result: Stored logs | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | None. CPU load results are fetched and stored. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc025.rst b/docs/testing/user/userguide/opnfv_yardstick_tc025.rst new file mode 100644 index 000000000..0e2e9a5f8 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc025.rst @@ -0,0 +1,123 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC025 +************************************* + ++-----------------------------------------------------------------------------+ +|OpenStack Controller Node abnormally shutdown High Availability | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC025_HA: OpenStack Controller Node | +| | abnormally shutdown | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of | +| | controller node. When one of the controller node abnormally | +| | shutdown, the service provided by it should be OK. | +| | | ++--------------+--------------------------------------------------------------+ +|test method | This test case shutdowns a specified controller node with | +| | some fault injection tools, then checks whether all services | +| | provided by the controller node are OK with some monitor | +| | tools. | +| | | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "host-shutdown" is | +| | needed. This attacker includes two parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "host-shutdown" in | +| | this test case. | +| | 2) host: the name of a controller node being attacked. | +| | | +| | e.g. | +| | -fault_type: "host-shutdown" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, one kind of monitor are needed: | +| | 1. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request | +| | | +| | There are four instance of the "openstack-cmd" monitor: | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -api_name: "nova image-list" | +| | monitor2: | +| | -monitor_type: "openstack-cmd" | +| | -api_name: "neutron router-list" | +| | monitor3: | +| | -monitor_type: "openstack-cmd" | +| | -api_name: "heat stack-list" | +| | monitor4: | +| | -monitor_type: "openstack-cmd" | +| | -api_name: "cinder list" | +| | | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there is one metric: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc019.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | shutdown script on the host | +| | | +| | Result: The host will be shutdown. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: All monitor result will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It restarts the | +| | specified controller node if it is not restarted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc027.rst b/docs/testing/user/userguide/opnfv_yardstick_tc027.rst new file mode 100644 index 000000000..125fd59fa --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc027.rst @@ -0,0 +1,95 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC027 +************************************* + +.. _ipv6: https://wiki.opnfv.org/ipv6_opnfv_project + ++-----------------------------------------------------------------------------+ +|IPv6 connectivity between nodes on the tenant network | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC027_IPv6 connectivity | +| | | ++--------------+--------------------------------------------------------------+ +|metric | RTT, Round Trip Time | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To do a basic verification that IPv6 connectivity is within | +| | acceptable boundaries when ipv6 packets travel between hosts | +| | located on same or different compute blades. | +| | The purpose is also to be able to spot trends. Test results, | +| | graphs and similar shall be stored for comparison reasons and| +| | product evolution understanding between different OPNFV | +| | versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc027.yaml | +| | | +| | Packet size 56 bytes. | +| | SLA RTT is set to maximum 30 ms. | +| | ipv6 test case can be configured as three independent modules| +| | (setup, run, teardown). if you only want to setup ipv6 | +| | testing environment, do some tests as you want, "run_step" | +| | of task yaml file should be configured as "setup". if you | +| | want to setup and run ping6 testing automatically, "run_step"| +| | should be configured as "setup, run". and if you have had a | +| | environment which has been setup, you only wan to verify the | +| | connectivity of ipv6 network, "run_step" should be "run". Of | +| | course, default is that three modules run sequentially. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | ping6 | +| | | +| | Ping6 is normally part of Linux distribution, hence it | +| | doesn't need to be installed. | +| | | ++--------------+--------------------------------------------------------------+ +|references | ipv6_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test case can be configured with different run step | +| | you can run setup, run benchmark, teardown independently | +| | SLA is optional. The SLA in this test case serves as an | +| | example. Considerably lower RTT is expected. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with ping6 included in it. | +| | | +| | For Brahmaputra, a compass_os_nosdn_ha deploy scenario is | +| | need. more installer and more sdn deploy scenario will be | +| | supported soon | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | To setup IPV6 testing environment: | +| | 1. disable security group | +| | 2. create (ipv6, ipv4) router, network and subnet | +| | 3. create VRouter, VM1, VM2 | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | To run ping6 to verify IPV6 connectivity : | +| | 1. ssh to VM1 | +| | 2. Ping6 to ipv6 router from VM1 | +| | 3. Get the result(RTT) and logs are stored | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | To teardown IPV6 testing environment | +| | 1. delete VRouter, VM1, VM2 | +| | 2. delete (ipv6, ipv4) router, network and subnet | +| | 3. enable security group | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Test should not PASS if any RTT is above the optional SLA | +| | value, or if there is a test case execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc028.rst b/docs/testing/user/userguide/opnfv_yardstick_tc028.rst new file mode 100644 index 000000000..24206f33f --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc028.rst @@ -0,0 +1,70 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co., Ltd and others. + +************************************* +Yardstick Test Case Description TC028 +************************************* + +.. _Cyclictest: https://rt.wiki.kernel.org/index.php/Cyclictest + ++-----------------------------------------------------------------------------+ +|KVM Latency measurements | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC028_KVM Latency measurements | +| | | ++--------------+--------------------------------------------------------------+ +|metric | min, avg and max latency | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS KVM virtualization capability with | +| | regards to min, avg and max latency. | +| | The purpose is also to be able to spot trends. Test results, | +| | graphs and similar shall be stored for comparison reasons | +| | and product evolution understanding between different OPNFV | +| | versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: samples/cyclictest-node-context.yaml | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Cyclictest | +| | | +| | (Cyclictest is not always part of a Linux distribution, | +| | hence it needs to be installed. As an example see the | +| | /yardstick/tools/ directory for how to generate a Linux | +| | image with cyclictest included.) | +| | | ++--------------+--------------------------------------------------------------+ +|references | Cyclictest_ | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | This test case is mainly for kvm4nfv project CI verify. | +| | Upgrade host linux kernel, boot a gust vm update it's linux | +| | kernel, and then run the cyclictest to test the new kernel | +| | is work well. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test kernel rpm, test sequence scripts and test guest | +|conditions | image need put the right folders as specified in the test | +| | case yaml file. | +| | The test guest image needs with cyclictest included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The host and guest os kernel is upgraded. Cyclictest is | +| | invoked and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc037.rst b/docs/testing/user/userguide/opnfv_yardstick_tc037.rst new file mode 100644 index 000000000..5a6e1eaae --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc037.rst @@ -0,0 +1,167 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TC037 +************************************* + +.. _cirros-image: https://download.cirros-cloud.net +.. _Ping: https://linux.die.net/man/8/ping +.. _pktgen: https://www.kernel.org/doc/Documentation/networking/pktgen.txt +.. _mpstat: http://www.linuxcommand.org/man_pages/mpstat1.html + ++-----------------------------------------------------------------------------+ +|Latency, CPU Load, Throughput, Packet Loss | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC037_LATENCY,CPU LOAD,THROUGHPUT, | +| | PACKET LOSS | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of flows, latency, throughput, packet loss | +| | CPU utilization percentage, CPU interrupt per second | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC037 is to evaluate the IaaS compute | +| | capacity and network performance with regards to CPU | +| | utilization, packet flows and network throughput, such as if | +| | and how different amounts of flows matter for the throughput | +| | between hosts on different compute blades, and the CPU load | +| | variation. | +| | | +| | Typically e.g. the performance of a vSwitch depends on the | +| | number of flows running through it. Also performance of | +| | other equipment or entities can depend on the number of | +| | flows or the packet sizes used | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Ping, Pktgen, mpstat | +| | | +| | Ping is a computer network administration software utility | +| | used to test the reachability of a host on an Internet | +| | Protocol (IP) network. It measures the round-trip time for | +| | packet sent from the originating host to a destination | +| | computer that are echoed back to the source. | +| | | +| | Linux packet generator is a tool to generate packets at very | +| | high speed in the kernel. pktgen is mainly used to drive and | +| | LAN equipment test network. pktgen supports multi threading. | +| | To generate random MAC address, IP address, port number UDP | +| | packets, pktgen uses multiple CPU processors in the | +| | different PCI bus (PCI, PCIe bus) with Gigabit Ethernet | +| | tested (pktgen performance depends on the CPU processing | +| | speed, memory delay, PCI bus speed hardware parameters), | +| | Transmit data rate can be even larger than 10GBit/s. Visible | +| | can satisfy most card test requirements. | +| | | +| | The mpstat command writes to standard output activities for | +| | each available processor, processor 0 being the first one. | +| | Global average activities among all processors are also | +| | reported. The mpstat command can be used both on SMP and UP | +| | machines, but in the latter, only global average activities | +| | will be printed. | +| | | +| | (Ping is normally part of any Linux distribution, hence it | +| | doesn't need to be installed. It is also part of the | +| | Yardstick Docker image. | +| | For example also a Cirros image can be downloaded from | +| | cirros-image_, it includes ping. | +| | | +| | Pktgen and mpstat are not always part of a Linux | +| | distribution, hence it needs to be installed. It is part of | +| | the Yardstick Docker image. | +| | As an example see the /yardstick/tools/ directory for how | +| | to generate a Linux image with pktgen and mpstat included.) | +| | | ++--------------+--------------------------------------------------------------+ +|test | This test case uses Pktgen to generate packet flow between | +|description | two hosts for simulating network workloads on the SUT. | +| | Ping packets (ICMP protocol's mandatory ECHO_REQUEST | +| | datagram) are sent from a host VM to the target VM(s) to | +| | elicit ICMP ECHO_RESPONSE, meanwhile CPU activities are | +| | monitored by mpstat. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc037.yaml | +| | | +| | Packet size is set to 64 bytes. | +| | Number of ports: 1, 10, 50, 100, 300, 500, 750 and 1000. | +| | The amount configured ports map from 2 up to 1001000 flows, | +| | respectively. Each port amount is run two times, for 20 | +| | seconds each. Then the next port_amount is run, and so on. | +| | During the test CPU load on both client and server, and the | +| | network latency between the client and server are measured. | +| | The client and server are distributed on different hardware. | +| | mpstat monitoring interval is set to 1 second. | +| | ping packet size is set to 100 bytes. | +| | For SLA max_ppm is set to 1000. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * pktgen packet sizes; | +| | * amount of flows; | +| | * test duration; | +| | * ping packet size; | +| | * mpstat monitor interval. | +| | | +| | Default values exist. | +| | | +| | SLA (optional): max_ppm: The number of packets per million | +| | packets sent that are acceptable to loose, not received. | +| | | ++--------------+--------------------------------------------------------------+ +|references | Ping_ | +| | | +| | mpstat_ | +| | | +| | pktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with pktgen, mpstat included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | Two host VMs are booted, as server and client. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Yardstick is connected with the server VM by using ssh. | +| | 'pktgen_benchmark', "ping_benchmark" bash script are copyied | +| | from Jump Host to the server VM via the ssh tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | An IP table is setup on server to monitor for received | +| | packets. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | pktgen is invoked to generate packet flow between two server | +| | and client for simulating network workloads on the SUT. Ping | +| | is invoked. Ping packets are sent from server VM to client | +| | VM. mpstat is invoked, recording activities for each | +| | available processor. Results are processed and checked | +| | against the SLA. Logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|step 5 | Two host VMs are deleted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc038.rst b/docs/testing/user/userguide/opnfv_yardstick_tc038.rst new file mode 100644 index 000000000..692c76819 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc038.rst @@ -0,0 +1,104 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TC038 +************************************* + +.. _cirros: https://download.cirros-cloud.net +.. _pktgen: https://www.kernel.org/doc/Documentation/networking/pktgen.txt + ++-----------------------------------------------------------------------------+ +|Latency, CPU Load, Throughput, Packet Loss (Extended measurements) | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC038_Latency,CPU Load,Throughput,Packet Loss| +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of flows, latency, throughput, CPU load, packet loss | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS network performance with regards to | +| | flows and throughput, such as if and how different amounts | +| | of flows matter for the throughput between hosts on different| +| | compute blades. Typically e.g. the performance of a vSwitch | +| | depends on the number of flows running through it. Also | +| | performance of other equipment or entities can depend | +| | on the number of flows or the packet sizes used. | +| | The purpose is also to be able to spot trends. Test results, | +| | graphs ans similar shall be stored for comparison reasons and| +| | product evolution understanding between different OPNFV | +| | versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc038.yaml | +| | | +| | Packet size: 64 bytes | +| | Number of ports: 1, 10, 50, 100, 300, 500, 750 and 1000. | +| | The amount configured ports map from 2 up to 1001000 flows, | +| | respectively. Each port amount is run ten times, for 20 | +| | seconds each. Then the next port_amount is run, and so on. | +| | During the test CPU load on both client and server, and the | +| | network latency between the client and server are measured. | +| | The client and server are distributed on different HW. | +| | For SLA max_ppm is set to 1000. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | pktgen | +| | | +| | (Pktgen is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Glance | +| | image. | +| | As an example see the /yardstick/tools/ directory for how | +| | to generate a Linux image with pktgen included.) | +| | | +| | ping | +| | | +| | Ping is normally part of any Linux distribution, hence it | +| | doesn't need to be installed. It is also part of the | +| | Yardstick Glance image. | +| | (For example also a cirros_ image can be downloaded, it | +| | includes ping) | +| | | +| | mpstat | +| | | +| | (Mpstat is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Glance | +| | image. | +| | | ++--------------+--------------------------------------------------------------+ +|references | Ping and Mpstat man pages | +| | | +| | pktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different packet sizes, amount | +| | of flows and test duration. Default values exist. | +| | | +| | SLA (optional): max_ppm: The number of packets per million | +| | packets sent that are acceptable to loose, not received. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with pktgen included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The hosts are installed, as server and client. pktgen is | +| | invoked and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc040.rst b/docs/testing/user/userguide/opnfv_yardstick_tc040.rst new file mode 100644 index 000000000..d62fbf787 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc040.rst @@ -0,0 +1,65 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC040 +************************************* + +.. _Parser: https://wiki.opnfv.org/parser + ++-----------------------------------------------------------------------------+ +|Verify Parser Yang-to-Tosca | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC040 Verify Parser Yang-to-Tosca | +| | | ++--------------+--------------------------------------------------------------+ +|metric | 1. tosca file which is converted from yang file by Parser | +| | 2. result whether the output is same with expected outcome | ++--------------+--------------------------------------------------------------+ +|test purpose | To verify the function of Yang-to-Tosca in Parser. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc040.yaml | +| | | +| | yangfile: the path of the yangfile which you want to convert | +| | toscafile: the path of the toscafile which is your expected | +| | outcome. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Parser | +| | | +| | (Parser is not part of a Linux distribution, hence it | +| | needs to be installed. As an example see the | +| | /yardstick/benchmark/scenarios/parser/parser_setup.sh for | +| | how to install it manual. Of course, it will be installed | +| | and uninstalled automatically when you run this test case | +| | by yardstick) | ++--------------+--------------------------------------------------------------+ +|references | Parser_ | +| | | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different path of yangfile and | +| | toscafile to fit your real environment to verify Parser | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | No POD specific requirements have been identified. | +|conditions | it can be run without VM | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | parser is installed without VM, running Yang-to-Tosca module | +| | to convert yang file to tosca file, validating output against| +| | expected outcome. | +| | | +| | Result: Logs are stored. | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if output is different with expected outcome | +| | or if there is a test case execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc042.rst b/docs/testing/user/userguide/opnfv_yardstick_tc042.rst new file mode 100644 index 000000000..8660d9297 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc042.rst @@ -0,0 +1,87 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, ZTE and others. + +*************************************** +Yardstick Test Case Description TC0042 +*************************************** + +.. _DPDK: http://dpdk.org/doc/guides/index.html +.. _Testpmd: http://dpdk.org/doc/guides/testpmd_app_ug/index.html +.. _Pktgen-dpdk: http://pktgen.readthedocs.io/en/latest/index.html + ++-----------------------------------------------------------------------------+ +|Network Performance | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC042_DPDK pktgen latency measurements | +| | | ++--------------+--------------------------------------------------------------+ +|metric | L2 Network Latency | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | Measure L2 network latency when DPDK is enabled between hosts| +| | on different compute blades. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc042.yaml | +| | | +| | * Packet size: 64 bytes | +| | * SLA(max_latency): 100usec | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | DPDK_ | +| | Pktgen-dpdk_ | +| | | +| | (DPDK and Pktgen-dpdk are not part of a Linux distribution, | +| | hence they needs to be installed. | +| | As an example see the /yardstick/tools/ directory for how to | +| | generate a Linux image with DPDK and pktgen-dpdk included.) | +| | | ++--------------+--------------------------------------------------------------+ +|references | DPDK_ | +| | | +| | Pktgen-dpdk_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different packet sizes. Default | +| | values exist. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with DPDK and pktgen-dpdk included in it. | +| | | +| | The NICs of compute nodes must support DPDK on POD. | +| | | +| | And at least compute nodes setup hugepage. | +| | | +| | If you want to achievement a hight performance result, it is | +| | recommend to use NUAM, CPU pin, OVS and so on. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The hosts are installed on different blades, as server and | +| | client. Both server and client have three interfaces. The | +| | first one is management such as ssh. The other two are used | +| | by DPDK. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Testpmd_ is invoked with configurations to forward packets | +| | from one DPDK port to the other on server. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | Pktgen-dpdk is invoked with configurations as a traffic | +| | generator and logs are produced and stored on client. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc043.rst b/docs/testing/user/userguide/opnfv_yardstick_tc043.rst new file mode 100644 index 000000000..a873696dc --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc043.rst @@ -0,0 +1,102 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC043 +************************************* + +.. _cirros-image: https://download.cirros-cloud.net +.. _Ping: https://linux.die.net/man/8/ping + ++-----------------------------------------------------------------------------+ +|Network Latency Between NFVI Nodes | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC043_LATENCY_BETWEEN_NFVI_NODES | +| | | ++--------------+--------------------------------------------------------------+ +|metric | RTT (Round Trip Time) | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | The purpose of TC043 is to do a basic verification that | +| | network latency is within acceptable boundaries when packets | +| | travel between different NFVI nodes. | +| | | +| | The purpose is also to be able to spot the trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | ping | +| | | +| | Ping is a computer network administration software utility | +| | used to test the reachability of a host on an Internet | +| | Protocol (IP) network. It measures the round-trip time for | +| | packet sent from the originating host to a destination | +| | computer that are echoed back to the source. | +| | | ++--------------+--------------------------------------------------------------+ +|test topology | Ping packets (ICMP protocol's mandatory ECHO_REQUEST | +| | datagram) are sent from host node to target node to elicit | +| | ICMP ECHO_RESPONSE. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc043.yaml | +| | | +| | Packet size 100 bytes. Total test duration 600 seconds. | +| | One ping each 10 seconds. SLA RTT is set to maximum 10 ms. | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | This test case can be configured with different: | +| | | +| | * packet sizes; | +| | * burst sizes; | +| | * ping intervals; | +| | * test durations; | +| | * test iterations. | +| | | +| | Default values exist. | +| | | +| | SLA is optional. The SLA in this test case serves as an | +| | example. Considerably lower RTT is expected, and also normal | +| | to achieve in balanced L2 environments. However, to cover | +| | most configurations, both bare metal and fully virtualized | +| | ones, this value should be possible to achieve and | +| | acceptable for black box testing. Many real time | +| | applications start to suffer badly if the RTT time is higher | +| | than this. Some may suffer bad also close to this RTT, while | +| | others may not suffer at all. It is a compromise that may | +| | have to be tuned for different configuration purposes. | +| | | ++--------------+--------------------------------------------------------------+ +|references | Ping_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|pre_test | Each pod node must have ping included in it. | +|conditions | | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | Yardstick is connected with the NFVI node by using ssh. | +| | 'ping_benchmark' bash script is copyied from Jump Host to | +| | the NFVI node via the ssh tunnel. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Ping is invoked. Ping packets are sent from server node to | +| | client node. RTT results are calculated and checked against | +| | the SLA. Logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Test should not PASS if any RTT is above the optional SLA | +| | value, or if there is a test case execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc044.rst b/docs/testing/user/userguide/opnfv_yardstick_tc044.rst new file mode 100644 index 000000000..2be8517a1 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc044.rst @@ -0,0 +1,82 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC044 +************************************* + +.. _man-pages: http://manpages.ubuntu.com/manpages/trusty/en/man1/free.1.html + ++-----------------------------------------------------------------------------+ +|Memory Utilization | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC044_Memory Utilization | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Memory utilization | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS compute capability with regards to | +| | memory utilization.This test case should be run in parallel | +| | to other Yardstick test cases and not run as a stand-alone | +| | test case. | +| | Measure the memory usage statistics including used memory, | +| | free memory, buffer, cache and shared memory. | +| | Both average and maximun values are obtained. | +| | The purpose is also to be able to spot trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | File: memload.yaml (in the 'samples' directory) | +| | | +| | * interval: 1 - repeat, pausing every 1 seconds in-between. | +| | * count: 10 - display statistics 10 times, then exit. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | free | +| | | +| | free provides information about unused and used memory and | +| | swap space on any computer running Linux or another Unix-like| +| | operating system. | +| | free is normally part of a Linux distribution, hence it | +| | doesn't needs to be installed. | +| | | ++--------------+--------------------------------------------------------------+ +|references | man-pages_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * interval; | +| | * count; | +| | * runner Iteration and intervals. | +| | | +| | There are default values for each above-mentioned option. | +| | Run in background with other test cases. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with free included in the image. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The host is installed as client. The related TC, or TCs, is | +| | invoked and free logs are produced and stored. | +| | | +| | Result: logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | None. Memory utilization results are fetched and stored. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc045.rst b/docs/testing/user/userguide/opnfv_yardstick_tc045.rst new file mode 100644 index 000000000..0b0993c34 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc045.rst @@ -0,0 +1,139 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC045 +************************************* + ++-----------------------------------------------------------------------------+ +|Control Node Openstack Service High Availability - Neutron Server | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC045: Control node Openstack service down - | +| | neutron server | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of the | +| | network service provided by OpenStack (neutro-server) on | +| | control node. | +| | | ++--------------+--------------------------------------------------------------+ +|test method | This test case kills the processes of neutron-server service | +| | on a selected control node, then checks whether the request | +| | of the related Openstack command is OK and the killed | +| | processes are recovered. | +| | | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "kill-process" is | +| | needed. This attacker includes three parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "kill-process" in this | +| | test case. | +| | 2) process_name: which is the process name of the specified | +| | OpenStack service. If there are multiple processes use the | +| | same name on the host, all of them are killed by this | +| | attacker. | +| | In this case. This parameter should always set to "neutron- | +| | server". | +| | 3) host: which is the name of a control node being attacked. | +| | | +| | e.g. | +| | -fault_type: "kill-process" | +| | -process_name: "neutron-server" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, two kinds of monitor are needed: | +| | 1. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request. | +| | In this case, the command name should be neutron related | +| | commands. | +| | | +| | 2. the "process" monitor check whether a process is running | +| | on a specific node, which needs three parameters: | +| | 1) monitor_type: which used for finding the monitor class and| +| | related scritps. It should be always set to "process" | +| | for this monitor. | +| | 2) process_name: which is the process name for monitor | +| | 3) host: which is the name of the node runing the process | +| | | +| | e.g. | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "neutron agent-list" | +| | monitor2: | +| | -monitor_type: "process" | +| | -process_name: "neutron-server" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there are two metrics: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | +| | 2)process_recover_time: which indicates the maximun time | +| | (seconds) from the process being killed to recovered | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc045.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the kill process script with param value specified by | +| | "process_name" | +| | | +| | Result: Process will be killed. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It will check the| +| | status of the specified process on the host, and restart the | +| | process if it is not running for next test cases | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc046.rst b/docs/testing/user/userguide/opnfv_yardstick_tc046.rst new file mode 100644 index 000000000..cce6c6884 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc046.rst @@ -0,0 +1,138 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC046 +************************************* + ++-----------------------------------------------------------------------------+ +|Control Node Openstack Service High Availability - Keystone | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC046: Control node Openstack service down - | +| | keystone | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of the | +| | user service provided by OpenStack (keystone) on control | +| | node. | +| | | ++--------------+--------------------------------------------------------------+ +|test method | This test case kills the processes of keystone service on a | +| | selected control node, then checks whether the request of | +| | the related Openstack command is OK and the killed processes | +| | are recovered. | +| | | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "kill-process" is | +| | needed. This attacker includes three parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "kill-process" in this | +| | test case. | +| | 2) process_name: which is the process name of the specified | +| | OpenStack service. If there are multiple processes use the | +| | same name on the host, all of them are killed by this | +| | attacker. | +| | In this case. This parameter should always set to "keystone" | +| | 3) host: which is the name of a control node being attacked. | +| | | +| | e.g. | +| | -fault_type: "kill-process" | +| | -process_name: "keystone" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, two kinds of monitor are needed: | +| | 1. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request. | +| | In this case, the command name should be keystone related | +| | commands. | +| | | +| | 2. the "process" monitor check whether a process is running | +| | on a specific node, which needs three parameters: | +| | 1) monitor_type: which used for finding the monitor class and| +| | related scritps. It should be always set to "process" | +| | for this monitor. | +| | 2) process_name: which is the process name for monitor | +| | 3) host: which is the name of the node runing the process | +| | | +| | e.g. | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "keystone user-list" | +| | monitor2: | +| | -monitor_type: "process" | +| | -process_name: "keystone" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there are two metrics: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | +| | 2)process_recover_time: which indicates the maximun time | +| | (seconds) from the process being killed to recovered | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc046.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the kill process script with param value specified by | +| | "process_name" | +| | | +| | Result: Process will be killed. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It will check the| +| | status of the specified process on the host, and restart the | +| | process if it is not running for next test cases | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc047.rst b/docs/testing/user/userguide/opnfv_yardstick_tc047.rst new file mode 100644 index 000000000..95158cfd6 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc047.rst @@ -0,0 +1,139 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC047 +************************************* + ++-----------------------------------------------------------------------------+ +|Control Node Openstack Service High Availability - Glance Api | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC047: Control node Openstack service down - | +| | glance api | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of the | +| | image service provided by OpenStack (glance-api) on control | +| | node. | +| | | ++--------------+--------------------------------------------------------------+ +|test method | This test case kills the processes of glance-api service on | +| | a selected control node, then checks whether the request of | +| | the related Openstack command is OK and the killed processes | +| | are recovered. | +| | | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "kill-process" is | +| | needed. This attacker includes three parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "kill-process" in this | +| | test case. | +| | 2) process_name: which is the process name of the specified | +| | OpenStack service. If there are multiple processes use the | +| | same name on the host, all of them are killed by this | +| | attacker. | +| | In this case. This parameter should always set to "glance- | +| | api". | +| | 3) host: which is the name of a control node being attacked. | +| | | +| | e.g. | +| | -fault_type: "kill-process" | +| | -process_name: "glance-api" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, two kinds of monitor are needed: | +| | 1. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request. | +| | In this case, the command name should be glance related | +| | commands. | +| | | +| | 2. the "process" monitor check whether a process is running | +| | on a specific node, which needs three parameters: | +| | 1) monitor_type: which used for finding the monitor class and| +| | related scritps. It should be always set to "process" | +| | for this monitor. | +| | 2) process_name: which is the process name for monitor | +| | 3) host: which is the name of the node runing the process | +| | | +| | e.g. | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "glance image-list" | +| | monitor2: | +| | -monitor_type: "process" | +| | -process_name: "glance-api" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there are two metrics: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | +| | 2)process_recover_time: which indicates the maximun time | +| | (seconds) from the process being killed to recovered | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc047.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the kill process script with param value specified by | +| | "process_name" | +| | | +| | Result: Process will be killed. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It will check the| +| | status of the specified process on the host, and restart the | +| | process if it is not running for next test cases | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc048.rst b/docs/testing/user/userguide/opnfv_yardstick_tc048.rst new file mode 100644 index 000000000..21c00d1fe --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc048.rst @@ -0,0 +1,139 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC048 +************************************* + ++-----------------------------------------------------------------------------+ +|Control Node Openstack Service High Availability - Cinder Api | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC048: Control node Openstack service down - | +| | cinder api | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of the | +| | volume service provided by OpenStack (cinder-api) on control | +| | node. | +| | | ++--------------+--------------------------------------------------------------+ +|test method | This test case kills the processes of cinder-api service on | +| | a selected control node, then checks whether the request of | +| | the related Openstack command is OK and the killed processes | +| | are recovered. | +| | | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "kill-process" is | +| | needed. This attacker includes three parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "kill-process" in this | +| | test case. | +| | 2) process_name: which is the process name of the specified | +| | OpenStack service. If there are multiple processes use the | +| | same name on the host, all of them are killed by this | +| | attacker. | +| | In this case. This parameter should always set to "cinder- | +| | api". | +| | 3) host: which is the name of a control node being attacked. | +| | | +| | e.g. | +| | -fault_type: "kill-process" | +| | -process_name: "cinder-api" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, two kinds of monitor are needed: | +| | 1. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request. | +| | In this case, the command name should be cinder related | +| | commands. | +| | | +| | 2. the "process" monitor check whether a process is running | +| | on a specific node, which needs three parameters: | +| | 1) monitor_type: which used for finding the monitor class and| +| | related scritps. It should be always set to "process" | +| | for this monitor. | +| | 2) process_name: which is the process name for monitor | +| | 3) host: which is the name of the node runing the process | +| | | +| | e.g. | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "cinder list" | +| | monitor2: | +| | -monitor_type: "process" | +| | -process_name: "cinder-api" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there are two metrics: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | +| | 2)process_recover_time: which indicates the maximun time | +| | (seconds) from the process being killed to recovered | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc048.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the kill process script with param value specified by | +| | "process_name" | +| | | +| | Result: Process will be killed. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It will check the| +| | status of the specified process on the host, and restart the | +| | process if it is not running for next test cases | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc049.rst b/docs/testing/user/userguide/opnfv_yardstick_tc049.rst new file mode 100644 index 000000000..f58bb9989 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc049.rst @@ -0,0 +1,139 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC049 +************************************* + ++-----------------------------------------------------------------------------+ +|Control Node Openstack Service High Availability - Swift Proxy | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC049: Control node Openstack service down - | +| | swift proxy | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of the | +| | storage service provided by OpenStack (swift-proxy) on | +| | control node. | +| | | ++--------------+--------------------------------------------------------------+ +|test method | This test case kills the processes of swift-proxy service on | +| | a selected control node, then checks whether the request of | +| | the related Openstack command is OK and the killed processes | +| | are recovered. | +| | | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "kill-process" is | +| | needed. This attacker includes three parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "kill-process" in this | +| | test case. | +| | 2) process_name: which is the process name of the specified | +| | OpenStack service. If there are multiple processes use the | +| | same name on the host, all of them are killed by this | +| | attacker. | +| | In this case. This parameter should always set to "swift- | +| | proxy". | +| | 3) host: which is the name of a control node being attacked. | +| | | +| | e.g. | +| | -fault_type: "kill-process" | +| | -process_name: "swift-proxy" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, two kinds of monitor are needed: | +| | 1. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request. | +| | In this case, the command name should be swift related | +| | commands. | +| | | +| | 2. the "process" monitor check whether a process is running | +| | on a specific node, which needs three parameters: | +| | 1) monitor_type: which used for finding the monitor class and| +| | related scritps. It should be always set to "process" | +| | for this monitor. | +| | 2) process_name: which is the process name for monitor | +| | 3) host: which is the name of the node runing the process | +| | | +| | e.g. | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "swift stat" | +| | monitor2: | +| | -monitor_type: "process" | +| | -process_name: "swift-proxy" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there are two metrics: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | +| | 2)process_recover_time: which indicates the maximun time | +| | (seconds) from the process being killed to recovered | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc049.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the kill process script with param value specified by | +| | "process_name" | +| | | +| | Result: Process will be killed. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It will check the| +| | status of the specified process on the host, and restart the | +| | process if it is not running for next test cases | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc050.rst b/docs/testing/user/userguide/opnfv_yardstick_tc050.rst new file mode 100644 index 000000000..8890c9d53 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc050.rst @@ -0,0 +1,135 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC050 +************************************* + ++-----------------------------------------------------------------------------+ +|OpenStack Controller Node Network High Availability | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC050: OpenStack Controller Node Network | +| | High Availability | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of control | +| | node. When one of the controller failed to connect the | +| | network, which breaks down the Openstack services on this | +| | node. These Openstack service should able to be accessed by | +| | other controller nodes, and the services on failed | +| | controller node should be isolated. | ++--------------+--------------------------------------------------------------+ +|test method | This test case turns off the network interfaces of a | +| | specified control node, then checks whether all services | +| | provided by the control node are OK with some monitor tools. | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "close-interface" is | +| | needed. This attacker includes three parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "close-interface" in | +| | this test case. | +| | 2) host: which is the name of a control node being attacked. | +| | 3) interface: the network interface to be turned off. | +| | | +| | There are four instance of the "close-interface" monitor: | +| | attacker1(for public netork): | +| | -fault_type: "close-interface" | +| | -host: node1 | +| | -interface: "br-ex" | +| | attacker2(for management netork): | +| | -fault_type: "close-interface" | +| | -host: node1 | +| | -interface: "br-mgmt" | +| | attacker3(for storage netork): | +| | -fault_type: "close-interface" | +| | -host: node1 | +| | -interface: "br-storage" | +| | attacker4(for private netork): | +| | -fault_type: "close-interface" | +| | -host: node1 | +| | -interface: "br-mesh" | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, the monitor named "openstack-cmd" is | +| | needed. The monitor needs needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request | +| | | +| | There are four instance of the "openstack-cmd" monitor: | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "nova image-list" | +| | monitor2: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "neutron router-list" | +| | monitor3: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "heat stack-list" | +| | monitor4: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "cinder list" | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there is one metric: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc050.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the turnoff network interface script with param value | +| | specified by "interface". | +| | | +| | Result: Network interfaces will be turned down. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It turns up the | +| | network interface of the control node if it is not turned | +| | up. | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc051.rst b/docs/testing/user/userguide/opnfv_yardstick_tc051.rst new file mode 100644 index 000000000..3402ccd92 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc051.rst @@ -0,0 +1,117 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC051 +************************************* + ++-----------------------------------------------------------------------------+ +|OpenStack Controller Node CPU Overload High Availability | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC051: OpenStack Controller Node CPU | +| | Overload High Availability | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of control | +| | node. When the CPU usage of a specified controller node is | +| | stressed to 100%, which breaks down the Openstack services | +| | on this node. These Openstack service should able to be | +| | accessed by other controller nodes, and the services on | +| | failed controller node should be isolated. | ++--------------+--------------------------------------------------------------+ +|test method | This test case stresses the CPU uasge of a specified control | +| | node to 100%, then checks whether all services provided by | +| | the environment are OK with some monitor tools. | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "stress-cpu" is | +| | needed. This attacker includes two parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "stress-cpu" in | +| | this test case. | +| | 2) host: which is the name of a control node being attacked. | +| | e.g. | +| | -fault_type: "stress-cpu" | +| | -host: node1 | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, the monitor named "openstack-cmd" is | +| | needed. The monitor needs needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request | +| | | +| | There are four instance of the "openstack-cmd" monitor: | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "nova image-list" | +| | monitor2: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "neutron router-list" | +| | monitor3: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "heat stack-list" | +| | monitor4: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "cinder list" | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there is one metric: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc051.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the stress cpu script on the host. | +| | | +| | Result: The CPU usage of the host will be stressed to 100%. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It kills the | +| | process that stresses the CPU usage. | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc052.rst b/docs/testing/user/userguide/opnfv_yardstick_tc052.rst new file mode 100644 index 000000000..9514b6819 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc052.rst @@ -0,0 +1,141 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC052 +************************************* + ++-----------------------------------------------------------------------------+ +|OpenStack Controller Node Disk I/O Block High Availability | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC052: OpenStack Controller Node Disk I/O | +| | Block High Availability | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of control | +| | node. When the disk I/O of a specified disk is blocked, | +| | which breaks down the Openstack services on this node. Read | +| | and write services should still be accessed by other | +| | controller nodes, and the services on failed controller node | +| | should be isolated. | ++--------------+--------------------------------------------------------------+ +|test method | This test case blocks the disk I/O of a specified control | +| | node, then checks whether the services that need to read or | +| | wirte the disk of the control node are OK with some monitor | +| | tools. | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "disk-block" is | +| | needed. This attacker includes two parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "disk-block" in this | +| | test case. | +| | 2) host: which is the name of a control node being attacked. | +| | e.g. | +| | -fault_type: "disk-block" | +| | -host: node1 | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, two kinds of monitor are needed: | +| | 1. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scripts. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request. | +| | | +| | e.g. | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "nova flavor-list" | +| | | +| | 2. the second monitor verifies the read and write function | +| | by a "operation" and a "result checker". | +| | the "operation" have two parameters: | +| | 1) operation_type: which is used for finding the operation | +| | class and related scripts. | +| | 2) action_parameter: parameters for the operation. | +| | the "result checker" have three parameters: | +| | 1) checker_type: which is used for finding the reuslt | +| | checker class and realted scripts. | +| | 2) expectedValue: the expected value for the output of the | +| | checker script. | +| | 3) condition: whether the expected value is in the output of | +| | checker script or is totally same with the output. | +| | | +| | In this case, the "operation" adds a flavor and the "result | +| | checker" checks whether ths flavor is created. Their | +| | parameters show as follows: | +| | operation: | +| | -operation_type: "nova-create-flavor" | +| | -action_parameter: | +| | flavorconfig: "test-001 test-001 100 1 1" | +| | result checker: | +| | -checker_type: "check-flavor" | +| | -expectedValue: "test-001" | +| | -condition: "in" | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there is one metric: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc052.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | do attacker: connect the host through SSH, and then execute | +| | the block disk I/O script on the host. | +| | | +| | Result: The disk I/O of the host will be blocked | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | do operation: add a flavor | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | do result checker: check whether the falvor is created | +| | | ++--------------+--------------------------------------------------------------+ +|step 5 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 6 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It excutes the | +| | release disk I/O script to release the blocked I/O. | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails if monnitor SLA is not passed or the result checker is | +| | not passed, or if there is a test case execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc053.rst b/docs/testing/user/userguide/opnfv_yardstick_tc053.rst new file mode 100644 index 000000000..3c6bbc628 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc053.rst @@ -0,0 +1,142 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC053 +************************************* + ++-----------------------------------------------------------------------------+ +|OpenStack Controller Load Balance Service High Availability | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC053: OpenStack Controller Load Balance | +| | Service High Availability | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability of the | +| | load balance service(current is HAProxy) that supports | +| | OpenStack on controller node. When the load balance service | +| | of a specified controller node is killed, whether other load | +| | balancers on other controller nodes will work, and whether | +| | the controller node will restart the load balancer are | +| | checked. | ++--------------+--------------------------------------------------------------+ +|test method | This test case kills the processes of load balance service | +| | on a selected control node, then checks whether the request | +| | of the related Openstack command is OK and the killed | +| | processes are recovered. | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "kill-process" is | +| | needed. This attacker includes three parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "kill-process" in this | +| | test case. | +| | 2) process_name: which is the process name of the specified | +| | OpenStack service. If there are multiple processes use the | +| | same name on the host, all of them are killed by this | +| | attacker. | +| | In this case. This parameter should always set to "swift- | +| | proxy". | +| | 3) host: which is the name of a control node being attacked. | +| | | +| | e.g. | +| | -fault_type: "kill-process" | +| | -process_name: "haproxy" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, two kinds of monitor are needed: | +| | 1. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scritps. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request. | +| | | +| | 2. the "process" monitor check whether a process is running | +| | on a specific node, which needs three parameters: | +| | 1) monitor_type: which used for finding the monitor class | +| | and related scripts. It should be always set to "process" | +| | for this monitor. | +| | 2) process_name: which is the process name for monitor | +| | 3) host: which is the name of the node runing the process | +| | In this case, the command_name of monitor1 should be | +| | services that is supported by load balancer and the process- | +| | name of monitor2 should be "haproxy", for example: | +| | | +| | e.g. | +| | monitor1: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "nova image-list" | +| | monitor2: | +| | -monitor_type: "process" | +| | -process_name: "haproxy" | +| | -host: node1 | +| | | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there are two metrics: | +| | 1)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | +| | 2)process_recover_time: which indicates the maximun time | +| | (seconds) from the process being killed to recovered | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc053.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the kill process script with param value specified by | +| | "process_name" | +| | | +| | Result: Process will be killed. | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It will check | +| | the status of the specified process on the host, and restart | +| | the process if it is not running for next test cases. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc054.rst b/docs/testing/user/userguide/opnfv_yardstick_tc054.rst new file mode 100644 index 000000000..7f92be2bc --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc054.rst @@ -0,0 +1,125 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Yin Kanglin and others. +.. 14_ykl@tongji.edu.cn + +************************************* +Yardstick Test Case Description TC054 +************************************* + ++-----------------------------------------------------------------------------+ +|OpenStack Virtual IP High Availability | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC054: OpenStack Virtual IP High | +| | Availability | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will verify the high availability for virtual | +| | ip in the environment. When master node of virtual ip is | +| | abnormally shutdown, connection to virtual ip and | +| | the services binded to the virtual IP it should be OK. | ++--------------+--------------------------------------------------------------+ +|test method | This test case shutdowns the virtual IP master node with | +| | some fault injection tools, then checks whether virtual ips | +| | can be pinged and services binded to virtual ip are OK with | +| | some monitor tools. | ++--------------+--------------------------------------------------------------+ +|attackers | In this test case, an attacker called "control-shutdown" is | +| | needed. This attacker includes two parameters: | +| | 1) fault_type: which is used for finding the attacker's | +| | scripts. It should be always set to "control-shutdown" in | +| | this test case. | +| | 2) host: which is the name of a control node being attacked. | +| | | +| | In this case the host should be the virtual ip master node, | +| | that means the host ip is the virtual ip, for exapmle: | +| | -fault_type: "control-shutdown" | +| | -host: node1(the VIP Master node) | ++--------------+--------------------------------------------------------------+ +|monitors | In this test case, two kinds of monitor are needed: | +| | 1. the "ip_status" monitor that pings a specific ip to check | +| | the connectivity of this ip, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scripts. It should be always set to "ip_status" | +| | for this monitor. | +| | 2) ip_address: The ip to be pinged. In this case, ip_address | +| | should be the virtual IP. | +| | | +| | 2. the "openstack-cmd" monitor constantly request a specific | +| | Openstack command, which needs two parameters: | +| | 1) monitor_type: which is used for finding the monitor class | +| | and related scripts. It should be always set to | +| | "openstack-cmd" for this monitor. | +| | 2) command_name: which is the command name used for request. | +| | | +| | e.g. | +| | monitor1: | +| | -monitor_type: "ip_status" | +| | -host: 192.168.0.2 | +| | monitor2: | +| | -monitor_type: "openstack-cmd" | +| | -command_name: "nova image-list" | +| | | ++--------------+--------------------------------------------------------------+ +|metrics | In this test case, there are two metrics: | +| | 1) ping_outage_time: which-indicates the maximum outage time | +| | to ping the specified host. | +| | 2)service_outage_time: which indicates the maximum outage | +| | time (seconds) of the specified Openstack command request. | ++--------------+--------------------------------------------------------------+ +|test tool | Developed by the project. Please see folder: | +| | "yardstick/benchmark/scenarios/availability/ha_tools" | +| | | ++--------------+--------------------------------------------------------------+ +|references | ETSI NFV REL001 | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | This test case needs two configuration files: | +| | 1) test case file: opnfv_yardstick_tc054.yaml | +| | -Attackers: see above "attackers" discription | +| | -waiting_time: which is the time (seconds) from the process | +| | being killed to stoping monitors the monitors | +| | -Monitors: see above "monitors" discription | +| | -SLA: see above "metrics" discription | +| | | +| | 2)POD file: pod.yaml | +| | The POD configuration should record on pod.yaml first. | +| | the "host" item in this test case will use the node name in | +| | the pod.yaml. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | start monitors: | +| | each monitor will run with independently process | +| | | +| | Result: The monitor info will be collected. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | do attacker: connect the host through SSH, and then execute | +| | the shutdown script on the VIP master node. | +| | | +| | Result: VIP master node will be shutdown | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | stop monitors after a period of time specified by | +| | "waiting_time" | +| | | +| | Result: The monitor info will be aggregated. | +| | | ++--------------+--------------------------------------------------------------+ +|step 4 | verify the SLA | +| | | +| | Result: The test case is passed or not. | +| | | ++--------------+--------------------------------------------------------------+ +|post-action | It is the action when the test cases exist. It restarts the | +| | original VIP master node if it is not restarted. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc055.rst b/docs/testing/user/userguide/opnfv_yardstick_tc055.rst new file mode 100644 index 000000000..c861ca90c --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc055.rst @@ -0,0 +1,67 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC055 +************************************* + +.. _/proc/cpuinfo: http://www.linfo.org/proc_cpuinfo.html + ++-----------------------------------------------------------------------------+ +|Compute Capacity | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC055_Compute Capacity | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of cpus, number of cores, number of threads, available| +| | memory size and total cache size. | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS compute capacity with regards to | +| | hardware specification, including number of cpus, number of | +| | cores, number of threads, available memory size and total | +| | cache size. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc055.yaml | +| | | +| | There is are no additional configurations to be set for this | +| | TC. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | /proc/cpuinfo | +| | | +| | this TC uses /proc/cpuinfo as source to produce compute | +| | capacity output. | +| | | ++--------------+--------------------------------------------------------------+ +|references | /proc/cpuinfo_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | None. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | No POD specific requirements have been identified. | +|conditions | | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The hosts are installed, TC is invoked and logs are produced | +| | and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | None. Hardware specification are fetched and stored. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc061.rst b/docs/testing/user/userguide/opnfv_yardstick_tc061.rst new file mode 100644 index 000000000..1d424414e --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc061.rst @@ -0,0 +1,88 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC061 +************************************* + +.. _man-pages: http://linux.die.net/man/1/sar + ++-----------------------------------------------------------------------------+ +|Network Utilization | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC061_Network Utilization | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Network utilization | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS network capability with regards to | +| | network utilization, including Total number of packets | +| | received per second, Total number of packets transmitted per | +| | second, Total number of kilobytes received per second, Total | +| | number of kilobytes transmitted per second, Number of | +| | compressed packets received per second (for cslip etc.), | +| | Number of compressed packets transmitted per second, Number | +| | of multicast packets received per second, Utilization | +| | percentage of the network interface. | +| | This test case should be run in parallel to other Yardstick | +| | test cases and not run as a stand-alone test case. | +| | Measure the network usage statistics from the network devices| +| | Average, minimum and maximun values are obtained. | +| | The purpose is also to be able to spot trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | File: netutilization.yaml (in the 'samples' directory) | +| | | +| | * interval: 1 - repeat, pausing every 1 seconds in-between. | +| | * count: 1 - display statistics 1 times, then exit. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | sar | +| | | +| | The sar command writes to standard output the contents of | +| | selected cumulative activity counters in the operating | +| | system. | +| | sar is normally part of a Linux distribution, hence it | +| | doesn't needs to be installed. | +| | | ++--------------+--------------------------------------------------------------+ +|references | man-pages_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * interval; | +| | * count; | +| | * runner Iteration and intervals. | +| | | +| | There are default values for each above-mentioned option. | +| | Run in background with other test cases. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with sar included in the image. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result. | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The host is installed as client. The related TC, or TCs, is | +| | invoked and sar logs are produced and stored. | +| | | +| | Result: logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | None. Network utilization results are fetched and stored. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc063.rst b/docs/testing/user/userguide/opnfv_yardstick_tc063.rst new file mode 100644 index 000000000..a77653aa5 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc063.rst @@ -0,0 +1,81 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC063 +************************************* + +.. _iostat: http://linux.die.net/man/1/iostat +.. _fdisk: http://www.tldp.org/HOWTO/Partition/fdisk_partitioning.html + ++-----------------------------------------------------------------------------+ +|Storage Capacity | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC063_Storage Capacity | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Storage/disk size, block size | +| | Disk Utilization | ++--------------+--------------------------------------------------------------+ +|test purpose | This test case will check the parameters which could decide | +| | several models and each model has its specified task to | +| | measure. The test purposes are to measure disk size, block | +| | size and disk utilization. With the test results, we could | +| | evaluate the storage capacity of the host. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc063.yaml | +| | | +| |* test_type: "disk_size" | +| |* runner: | +| | type: Iteration | +| | iterations: 1 - test is run 1 time iteratively. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | fdisk | +| | A command-line utility that provides disk partitioning | +| | functions | +| | | +| | iostat | +| | This is a computer system monitor tool used to collect and | +| | show operating system storage input and output statistics. | ++--------------+--------------------------------------------------------------+ +|references | iostat_ | +| | fdisk_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * test_type: "disk size", "block size", "disk utilization" | +| | * interval: 1 - how ofter to stat disk utilization | +| | type: int | +| | unit: seconds | +| | * count: 15 - how many times to stat disk utilization | +| | type: int | +| | unit: na | +| | There are default values for each above-mentioned option. | +| | Run in background with other test cases. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | Output the specific storage capacity of disk information as | +| | the sequence into file. | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The pod is available and the hosts are installed. Node5 is | +| | used and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | None. | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc069.rst b/docs/testing/user/userguide/opnfv_yardstick_tc069.rst new file mode 100644 index 000000000..af0e64fbf --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc069.rst @@ -0,0 +1,100 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC069 +************************************* + +.. _RAMspeed: http://alasir.com/software/ramspeed/ + +.. table:: + :class: longtable + ++-----------------------------------------------------------------------------+ +|Memory Bandwidth | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC069_Memory Bandwidth | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Megabyte per second (MBps) | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS compute performance with regards to | +| | memory bandwidth. | +| | Measure the maximum possible cache and memory performance | +| | while reading and writing certain blocks of data (starting | +| | from 1Kb and further in power of 2) continuously through ALU | +| | and FPU respectively. | +| | Measure different aspects of memory performance via | +| | synthetic simulations. Each simulation consists of four | +| | performances (Copy, Scale, Add, Triad). | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | File: opnfv_yardstick_tc069.yaml | +| | | +| | * SLA (optional): 7000 (MBps) min_bandwidth: The minimum | +| | amount of memory bandwidth that is accepted. | +| | * type_id: 1 - runs a specified benchmark | +| | (by an ID number): | +| | 1 -- INTmark [writing] 4 -- FLOATmark [writing] | +| | 2 -- INTmark [reading] 5 -- FLOATmark [reading] | +| | 3 -- INTmem 6 -- FLOATmem | +| | * block_size: 64 Megabytes - the maximum block | +| | size per array. | +| | * load: 32 Gigabytes - the amount of data load per pass. | +| | * iterations: 5 - test is run 5 times iteratively. | +| | * interval: 1 - there is 1 second delay between each | +| | iteration. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | RAMspeed | +| | | +| | RAMspeed is a free open source command line utility to | +| | measure cache and memory performance of computer systems. | +| | RAMspeed is not always part of a Linux distribution, hence | +| | it needs to be installed in the test image. | +| | | ++--------------+--------------------------------------------------------------+ +|references | RAMspeed_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * benchmark operations (such as INTmark [writing], | +| | INTmark [reading], FLOATmark [writing], | +| | FLOATmark [reading], INTmem, FLOATmem); | +| | * block size per array; | +| | * load per pass; | +| | * number of batch run iterations; | +| | * iterations and intervals. | +| | | +| | There are default values for each above-mentioned option. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with RAmspeed included in the image. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The host is installed as client. RAMspeed is invoked and | +| | logs are produced and stored. | +| | | +| | Result: logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Test fails if the measured memory bandwidth is below the SLA | +| | value or if there is a test case execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc070.rst b/docs/testing/user/userguide/opnfv_yardstick_tc070.rst new file mode 100644 index 000000000..64fcc0c91 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc070.rst @@ -0,0 +1,110 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC070 +************************************* + +.. _cirros: https://download.cirros-cloud.net +.. _pktgen: https://www.kernel.org/doc/Documentation/networking/pktgen.txt +.. _free: http://manpages.ubuntu.com/manpages/trusty/en/man1/free.1.html + ++-----------------------------------------------------------------------------+ +|Latency, Memory Utilization, Throughput, Packet Loss | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC070_Latency, Memory Utilization, | +| | Throughput,Packet Loss | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of flows, latency, throughput, Memory Utilization, | +| | packet loss | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS network performance with regards to | +| | flows and throughput, such as if and how different amounts | +| | of flows matter for the throughput between hosts on different| +| | compute blades. Typically e.g. the performance of a vSwitch | +| | depends on the number of flows running through it. Also | +| | performance of other equipment or entities can depend | +| | on the number of flows or the packet sizes used. | +| | The purpose is also to be able to spot trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc070.yaml | +| | | +| | Packet size: 64 bytes | +| | Number of ports: 1, 10, 50, 100, 300, 500, 750 and 1000. | +| | The amount configured ports map from 2 up to 1001000 flows, | +| | respectively. Each port amount is run two times, for 20 | +| | seconds each. Then the next port_amount is run, and so on. | +| | During the test Memory Utilization on both client and server,| +| | and the network latency between the client and server are | +| | measured. | +| | The client and server are distributed on different HW. | +| | For SLA max_ppm is set to 1000. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | pktgen | +| | | +| | Pktgen is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Glance | +| | image. | +| | (As an example see the /yardstick/tools/ directory for how | +| | to generate a Linux image with pktgen included.) | +| | | +| | ping | +| | | +| | Ping is normally part of any Linux distribution, hence it | +| | doesn't need to be installed. It is also part of the | +| | Yardstick Glance image. | +| | (For example also a cirros_ image can be downloaded, it | +| | includes ping) | +| | | +| | free | +| | | +| | free provides information about unused and used memory and | +| | swap space on any computer running Linux or another Unix-like| +| | operating system. | +| | free is normally part of a Linux distribution, hence it | +| | doesn't needs to be installed. | +| | | ++--------------+--------------------------------------------------------------+ +|references | Ping and free man pages | +| | | +| | pktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different packet sizes, amount | +| | of flows and test duration. Default values exist. | +| | | +| | SLA (optional): max_ppm: The number of packets per million | +| | packets sent that are acceptable to lose, not received. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with pktgen included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The hosts are installed, as server and client. pktgen is | +| | invoked and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc071.rst b/docs/testing/user/userguide/opnfv_yardstick_tc071.rst new file mode 100644 index 000000000..673480b55 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc071.rst @@ -0,0 +1,109 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC071 +************************************* + +.. _cirros: https://download.cirros-cloud.net +.. _pktgen: https://www.kernel.org/doc/Documentation/networking/pktgen.txt +.. _cachestat: https://github.com/brendangregg/perf-tools/tree/master/fs + ++-----------------------------------------------------------------------------+ +|Latency, Cache Utilization, Throughput, Packet Loss | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC071_Latency, Cache Utilization, | +| | Throughput,Packet Loss | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of flows, latency, throughput, Cache Utilization, | +| | packet loss | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS network performance with regards to | +| | flows and throughput, such as if and how different amounts | +| | of flows matter for the throughput between hosts on different| +| | compute blades. Typically e.g. the performance of a vSwitch | +| | depends on the number of flows running through it. Also | +| | performance of other equipment or entities can depend | +| | on the number of flows or the packet sizes used. | +| | The purpose is also to be able to spot trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc071.yaml | +| | | +| | Packet size: 64 bytes | +| | Number of ports: 1, 10, 50, 100, 300, 500, 750 and 1000. | +| | The amount configured ports map from 2 up to 1001000 flows, | +| | respectively. Each port amount is run two times, for 20 | +| | seconds each. Then the next port_amount is run, and so on. | +| | During the test Cache Utilization on both client and server, | +| | and the network latency between the client and server are | +| | measured. | +| | The client and server are distributed on different HW. | +| | For SLA max_ppm is set to 1000. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | pktgen | +| | | +| | Pktgen is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Glance | +| | image. | +| | (As an example see the /yardstick/tools/ directory for how | +| | to generate a Linux image with pktgen included.) | +| | | +| | ping | +| | | +| | Ping is normally part of any Linux distribution, hence it | +| | doesn't need to be installed. It is also part of the | +| | Yardstick Glance image. | +| | (For example also a cirros_ image can be downloaded, it | +| | includes ping) | +| | | +| | cachestat | +| | | +| | cachestat is not always part of a Linux distribution, hence | +| | it needs to be installed. | +| | | ++--------------+--------------------------------------------------------------+ +|references | Ping man pages | +| | | +| | pktgen_ | +| | | +| | cachestat_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different packet sizes, amount | +| | of flows and test duration. Default values exist. | +| | | +| | SLA (optional): max_ppm: The number of packets per million | +| | packets sent that are acceptable to lose, not received. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with pktgen included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The hosts are installed, as server and client. pktgen is | +| | invoked and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc072.rst b/docs/testing/user/userguide/opnfv_yardstick_tc072.rst new file mode 100644 index 000000000..2e7ee057c --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc072.rst @@ -0,0 +1,110 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC072 +************************************* + +.. _cirros: https://download.cirros-cloud.net +.. _pktgen: https://www.kernel.org/doc/Documentation/networking/pktgen.txt +.. _sar: http://linux.die.net/man/1/sar + ++-----------------------------------------------------------------------------+ +|Latency, Network Utilization, Throughput, Packet Loss | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC072_Latency, Network Utilization, | +| | Throughput,Packet Loss | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of flows, latency, throughput, Network Utilization, | +| | packet loss | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS network performance with regards to | +| | flows and throughput, such as if and how different amounts | +| | of flows matter for the throughput between hosts on different| +| | compute blades. Typically e.g. the performance of a vSwitch | +| | depends on the number of flows running through it. Also | +| | performance of other equipment or entities can depend | +| | on the number of flows or the packet sizes used. | +| | The purpose is also to be able to spot trends. | +| | Test results, graphs and similar shall be stored for | +| | comparison reasons and product evolution understanding | +| | between different OPNFV versions and/or configurations. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc072.yaml | +| | | +| | Packet size: 64 bytes | +| | Number of ports: 1, 10, 50, 100, 300, 500, 750 and 1000. | +| | The amount configured ports map from 2 up to 1001000 flows, | +| | respectively. Each port amount is run two times, for 20 | +| | seconds each. Then the next port_amount is run, and so on. | +| | During the test Network Utilization on both client and | +| | server, and the network latency between the client and server| +| | are measured. | +| | The client and server are distributed on different HW. | +| | For SLA max_ppm is set to 1000. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | pktgen | +| | | +| | Pktgen is not always part of a Linux distribution, hence it | +| | needs to be installed. It is part of the Yardstick Glance | +| | image. | +| | (As an example see the /yardstick/tools/ directory for how | +| | to generate a Linux image with pktgen included.) | +| | | +| | ping | +| | | +| | Ping is normally part of any Linux distribution, hence it | +| | doesn't need to be installed. It is also part of the | +| | Yardstick Glance image. | +| | (For example also a cirros_ image can be downloaded, it | +| | includes ping) | +| | | +| | sar | +| | | +| | The sar command writes to standard output the contents of | +| | selected cumulative activity counters in the operating | +| | system. | +| | sar is normally part of a Linux distribution, hence it | +| | doesn't needs to be installed. | +| | | ++--------------+--------------------------------------------------------------+ +|references | Ping and sar man pages | +| | | +| | pktgen_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different packet sizes, amount | +| | of flows and test duration. Default values exist. | +| | | +| | SLA (optional): max_ppm: The number of packets per million | +| | packets sent that are acceptable to lose, not received. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The test case image needs to be installed into Glance | +|conditions | with pktgen included in it. | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The hosts are installed, as server and client. pktgen is | +| | invoked and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc073.rst b/docs/testing/user/userguide/opnfv_yardstick_tc073.rst new file mode 100644 index 000000000..ad4526405 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc073.rst @@ -0,0 +1,81 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC073 +************************************* + +.. _netperf: http://www.netperf.org/netperf/training/Netperf.html + ++-----------------------------------------------------------------------------+ +|Throughput per NFVI node test | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC073_Network latency and throughput between | +| | nodes | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Network latency and throughput | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the IaaS network performance with regards to | +| | flows and throughput, such as if and how different amounts | +| | of packet sizes and flows matter for the throughput between | +| | nodes in one pod. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc073.yaml | +| | | +| | Packet size: default 1024 bytes. | +| | | +| | Test length: default 20 seconds. | +| | | +| | The client and server are distributed on different nodes. | +| | | +| | For SLA max_mean_latency is set to 100. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | netperf_ | +| | Netperf is a software application that provides network | +| | bandwidth testing between two hosts on a network. It | +| | supports Unix domain sockets, TCP, SCTP, DLPI and UDP via | +| | BSD Sockets. Netperf provides a number of predefined tests | +| | e.g. to measure bulk (unidirectional) data transfer or | +| | request response performance. | +| | (netperf is not always part of a Linux distribution, hence | +| | it needs to be installed.) | +| | | ++--------------+--------------------------------------------------------------+ +|references | netperf Man pages | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different packet sizes and | +| | test duration. Default values exist. | +| | | +| | SLA (optional): max_mean_latency | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | The POD can be reached by external ip and logged on via ssh | +|conditions | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | Install netperf tool on each specified node, one is as the | +| | server, and the other as the client. | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | Log on to the client node and use the netperf command to | +| | execute the network performance test | +| | | ++--------------+--------------------------------------------------------------+ +|step 3 | The throughput results stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | Fails only if SLA is not passed, or if there is a test case | +| | execution problem. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc074.rst b/docs/testing/user/userguide/opnfv_yardstick_tc074.rst new file mode 100644 index 000000000..92cd51439 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc074.rst @@ -0,0 +1,137 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC074 +************************************* + +.. _Storperf: https://wiki.opnfv.org/display/storperf/Storperf + ++-----------------------------------------------------------------------------+ +|Storperf | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC074_Storperf | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Storage performance | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | Storperf integration with yardstick. The purpose of StorPerf | +| | is to provide a tool to measure block and object storage | +| | performance in an NFVI. When complemented with a | +| | characterization of typical VF storage performance | +| | requirements, it can provide pass/fail thresholds for test, | +| | staging, and production NFVI environments. | +| | | +| | The benchmarks developed for block and object storage will | +| | be sufficiently varied to provide a good preview of expected | +| | storage performance behavior for any type of VNF workload. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc074.yaml | +| | | +| | * agent_count: 1 - the number of VMs to be created | +| | * agent_image: "Ubuntu-14.04" - image used for creating VMs | +| | * public_network: "ext-net" - name of public network | +| | * volume_size: 2 - cinder volume size | +| | * block_sizes: "4096" - data block size | +| | * queue_depths: "4" | +| | * StorPerf_ip: "192.168.200.2" | +| | * query_interval: 10 - state query interval | +| | * timeout: 600 - maximum allowed job time | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | Storperf_ | +| | | +| | StorPerf is a tool to measure block and object storage | +| | performance in an NFVI. | +| | | +| | StorPerf is delivered as a Docker container from | +| | https://hub.docker.com/r/opnfv/storperf/tags/. | +| | | ++--------------+--------------------------------------------------------------+ +|references | Storperf_ | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | Test can be configured with different: | +| | | +| | * agent_count | +| | * volume_size | +| | * block_sizes | +| | * queue_depths | +| | * query_interval | +| | * timeout | +| | * target=[device or path] | +| | The path to either an attached storage device | +| | (/dev/vdb, etc) or a directory path (/opt/storperf) that | +| | will be used to execute the performance test. In the case | +| | of a device, the entire device will be used. If not | +| | specified, the current directory will be used. | +| | * workload=[workload module] | +| | If not specified, the default is to run all workloads. The | +| | workload types are: | +| | - rs: 100% Read, sequential data | +| | - ws: 100% Write, sequential data | +| | - rr: 100% Read, random access | +| | - wr: 100% Write, random access | +| | - rw: 70% Read / 30% write, random access | +| | * nossd: Do not perform SSD style preconditioning. | +| | * nowarm: Do not perform a warmup prior to | +| | measurements. | +| | * report= [job_id] | +| | Query the status of the supplied job_id and report on | +| | metrics. If a workload is supplied, will report on only | +| | that subset. | +| | | +| | There are default values for each above-mentioned option. | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | If you do not have an Ubuntu 14.04 image in Glance, you will | +|conditions | need to add one. A key pair for launching agents is also | +| | required. | +| | | +| | Storperf is required to be installed in the environment. | +| | There are two possible methods for Storperf installation: | +| | Run container on Jump Host | +| | Run container in a VM | +| | | +| | Running StorPerf on Jump Host | +| | Requirements: | +| | - Docker must be installed | +| | - Jump Host must have access to the OpenStack Controller | +| | API | +| | - Jump Host must have internet connectivity for | +| | downloading docker image | +| | - Enough floating IPs must be available to match your | +| | agent count | +| | | +| | Running StorPerf in a VM | +| | Requirements: | +| | - VM has docker installed | +| | - VM has OpenStack Controller credentials and can | +| | communicate with the Controller API | +| | - VM has internet connectivity for downloading the | +| | docker image | +| | - Enough floating IPs must be available to match your | +| | agent count | +| | | +| | No POD specific requirements have been identified. | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The Storperf is installed and Ubuntu 14.04 image is stored | +| | in glance. TC is invoked and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | None. Storage performance results are fetched and stored. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc075.rst b/docs/testing/user/userguide/opnfv_yardstick_tc075.rst new file mode 100644 index 000000000..a6ff34447 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc075.rst @@ -0,0 +1,60 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC075 +************************************* + + ++-----------------------------------------------------------------------------+ +|Network Capacity and Scale Testing | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC075_Network_Capacity_and_Scale_testing | +| | | ++--------------+--------------------------------------------------------------+ +|metric | Number of connections, Number of frames sent/received | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | To evaluate the network capacity and scale with regards to | +| | connections and frmaes. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc075.yaml | +| | | +| | There is no additional configuration to be set for this TC. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | netstar | +| | | +| | Netstat is normally part of any Linux distribution, hence it | +| | doesn't need to be installed. | +| | | ++--------------+--------------------------------------------------------------+ +|references | Netstat man page | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | This test case is mainly for evaluating network performance. | +| | | ++--------------+--------------------------------------------------------------+ +|pre_test | Each pod node must have netstat included in it. | +|conditions | | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The pod is available. | +| | Netstat is invoked and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | None. Number of connections and frames are fetched and | +| | stored. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/opnfv_yardstick_tc076.rst b/docs/testing/user/userguide/opnfv_yardstick_tc076.rst new file mode 100644 index 000000000..ac7bde794 --- /dev/null +++ b/docs/testing/user/userguide/opnfv_yardstick_tc076.rst @@ -0,0 +1,61 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Huawei Technologies Co.,Ltd and others. + +************************************* +Yardstick Test Case Description TC076 +************************************* + + ++-----------------------------------------------------------------------------+ +|Monitor Network Metrics | +| | ++--------------+--------------------------------------------------------------+ +|test case id | OPNFV_YARDSTICK_TC076_Monitor_Network_Metrics | +| | | ++--------------+--------------------------------------------------------------+ +|metric | IP datagram error rate, ICMP message error rate, | +| | TCP segment error rate and UDP datagram error rate | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | Monitor network metrics provided by the kernel in a host and | +| | calculate IP datagram error rate, ICMP message error rate, | +| | TCP segment error rate and UDP datagram error rate. | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | file: opnfv_yardstick_tc076.yaml | +| | | +| | There is no additional configuration to be set for this TC. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | nstat | +| | | +| | nstat is a simple tool to monitor kernel snmp counters and | +| | network interface statistics. | +| | | ++--------------+--------------------------------------------------------------+ +|references | nstat man page | +| | | +| | ETSI-NFV-TST001 | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | This test case is mainly for monitoring network metrics. | +| | | ++--------------+--------------------------------------------------------------+ +|pre_test | | +|conditions | | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | The pod is available. | +| | Nstat is invoked and logs are produced and stored. | +| | | +| | Result: Logs are stored. | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | None. | +| | | ++--------------+--------------------------------------------------------------+ diff --git a/docs/testing/user/userguide/references.rst b/docs/testing/user/userguide/references.rst new file mode 100644 index 000000000..05729ba75 --- /dev/null +++ b/docs/testing/user/userguide/references.rst @@ -0,0 +1,60 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +========== +References +========== + + +OPNFV +===== + +* Parser wiki: https://wiki.opnfv.org/parser +* Pharos wiki: https://wiki.opnfv.org/pharos +* VTC: https://wiki.opnfv.org/vtc +* Yardstick CI: https://build.opnfv.org/ci/view/yardstick/ +* Yardstick and ETSI TST001 presentation: https://wiki.opnfv.org/display/yardstick/Yardstick?preview=%2F2925202%2F2925205%2Fopnfv_summit_-_bridging_opnfv_and_etsi.pdf +* Yardstick Project presentation: https://wiki.opnfv.org/display/yardstick/Yardstick?preview=%2F2925202%2F2925208%2Fopnfv_summit_-_yardstick_project.pdf +* Yardstick wiki: https://wiki.opnfv.org/yardstick + +References used in Test Cases +============================= + +* cachestat: https://github.com/brendangregg/perf-tools/tree/master/fs +* cirros-image: https://download.cirros-cloud.net +* cyclictest: https://rt.wiki.kernel.org/index.php/Cyclictest +* DPDKpktgen: https://github.com/Pktgen/Pktgen-DPDK/ +* DPDK supported NICs: http://dpdk.org/doc/nics +* fdisk: http://www.tldp.org/HOWTO/Partition/fdisk_partitioning.html +* fio: http://www.bluestop.org/fio/HOWTO.txt +* free: http://manpages.ubuntu.com/manpages/trusty/en/man1/free.1.html +* iperf3: https://iperf.fr/ +* iostat: http://linux.die.net/man/1/iostat +* Lmbench man-pages: http://manpages.ubuntu.com/manpages/trusty/lat_mem_rd.8.html +* Memory bandwidth man-pages: http://manpages.ubuntu.com/manpages/trusty/bw_mem.8.html +* mpstat man-pages: http://manpages.ubuntu.com/manpages/trusty/man1/mpstat.1.html +* netperf: http://www.netperf.org/netperf/training/Netperf.html +* pktgen: https://www.kernel.org/doc/Documentation/networking/pktgen.txt +* RAMspeed: http://alasir.com/software/ramspeed/ +* sar: http://linux.die.net/man/1/sar +* SR-IOV: https://wiki.openstack.org/wiki/SR-IOV-Passthrough-For-Networking +* Storperf: https://wiki.opnfv.org/display/storperf/Storperf +* unixbench: https://github.com/kdlucas/byte-unixbench/blob/master/UnixBench + + +Research +======== + +* NCSRD: http://www.demokritos.gr/?lang=en +* T-NOVA: http://www.t-nova.eu/ +* T-NOVA Results: http://www.t-nova.eu/results/ + +Standards +========= + +* ETSI NFV: http://www.etsi.org/technologies-clusters/technologies/nfv +* 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 +* RFC2544: https://www.ietf.org/rfc/rfc2544.txt + diff --git a/docs/testing/user/userguide/testcase_description_v2_template.rst b/docs/testing/user/userguide/testcase_description_v2_template.rst new file mode 100644 index 000000000..91c2a7e33 --- /dev/null +++ b/docs/testing/user/userguide/testcase_description_v2_template.rst @@ -0,0 +1,64 @@ +.. This work is licensed under a Creative Commons Attribution 4.0 International +.. License. +.. http://creativecommons.org/licenses/by/4.0 +.. (c) OPNFV, Ericsson AB and others. + +************************************* +Yardstick Test Case Description TCXXX +************************************* + ++-----------------------------------------------------------------------------+ +|test case slogan e.g. Network Latency | +| | ++--------------+--------------------------------------------------------------+ +|test case id | e.g. OPNFV_YARDSTICK_TC001_NW Latency | +| | | ++--------------+--------------------------------------------------------------+ +|metric | what will be measured, e.g. latency | +| | | ++--------------+--------------------------------------------------------------+ +|test purpose | describe what is the purpose of the test case | +| | | ++--------------+--------------------------------------------------------------+ +|configuration | what .yaml file to use, state SLA if applicable, state | +| | test duration, list and describe the scenario options used in| +| | this TC and also list the options using default values. | +| | | ++--------------+--------------------------------------------------------------+ +|test tool | e.g. ping | +| | | ++--------------+--------------------------------------------------------------+ +|references | e.g. RFCxxx, ETSI-NFVyyy | +| | | ++--------------+--------------------------------------------------------------+ +|applicability | describe variations of the test case which can be | +| | performend, e.g. run the test for different packet sizes | +| | | ++--------------+--------------------------------------------------------------+ +|pre-test | describe configuration in the tool(s) used to perform | +|conditions | the measurements (e.g. fio, pktgen), POD-specific | +| | configuration required to enable running the test | +| | | ++--------------+--------------------------------------------------------------+ +|test sequence | description and expected result | +| | | ++--------------+--------------------------------------------------------------+ +|step 1 | use this to describe tests that require sveveral steps e.g | +| | collect logs. | +| | | +| | Result: what happens in this step e.g. logs collected | +| | | ++--------------+--------------------------------------------------------------+ +|step 2 | remove interface | +| | | +| | Result: interface down. | +| | | ++--------------+--------------------------------------------------------------+ +|step N | what is done in step N | +| | | +| | Result: what happens | +| | | ++--------------+--------------------------------------------------------------+ +|test verdict | expected behavior, or SLA, pass/fail criteria | +| | | ++--------------+--------------------------------------------------------------+ -- cgit 1.2.3-korg