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author | Trevor Cooper <trevor.cooper@intel.com> | 2017-03-21 13:25:49 -0700 |
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committer | Trevor Cooper <trevor.cooper@intel.com> | 2017-03-21 13:25:49 -0700 |
commit | 32a5263216d79ad34041dca55357278f092bb931 (patch) | |
tree | e3bf10ba8190ad93d2b114c1903cc43e2dfbf6b6 /docs/design/vswitchperf_design.rst | |
parent | 59668b1aa68da507335ef351619d9f50019df762 (diff) |
Moved doc files to testing document structure testing/user ... testing/developer and modified doc index to match dir structure
Change-Id: I4b1a535808a48773505fa7874c61707cd349fced
Signed-off-by: Trevor Cooper <trevor.cooper@intel.com>
Diffstat (limited to 'docs/design/vswitchperf_design.rst')
-rw-r--r-- | docs/design/vswitchperf_design.rst | 870 |
1 files changed, 0 insertions, 870 deletions
diff --git a/docs/design/vswitchperf_design.rst b/docs/design/vswitchperf_design.rst deleted file mode 100644 index da7ec6fd..00000000 --- a/docs/design/vswitchperf_design.rst +++ /dev/null @@ -1,870 +0,0 @@ -.. This work is licensed under a Creative Commons Attribution 4.0 International License. -.. http://creativecommons.org/licenses/by/4.0 -.. (c) OPNFV, Intel Corporation, AT&T and others. - -.. _vsperf-design: - -====================== -VSPERF Design Document -====================== - -Intended Audience -================= - -This document is intended to aid those who want to modify the vsperf code. Or -to extend it - for example to add support for new traffic generators, -deployment scenarios and so on. - -Usage -===== - -Example Connectivity to DUT ---------------------------- - -Establish connectivity to the VSPERF DUT Linux host, such as the DUT in Pod 3, -by following the steps in `Testbed POD3 -<https://wiki.opnfv.org/get_started/pod_3_-_characterize_vswitch_performance>`__ - -The steps cover booking the DUT and establishing the VSPERF environment. - -Example Command Lines ---------------------- - -List all the cli options: - -.. code-block:: console - - $ ./vsperf -h - -Run all tests that have ``tput`` in their name - ``phy2phy_tput``, ``pvp_tput`` etc.: - -.. code-block:: console - - $ ./vsperf --tests 'tput' - -As above but override default configuration with settings in '10_custom.conf'. -This is useful as modifying configuration directly in the configuration files -in ``conf/NN_*.py`` shows up as changes under git source control: - -.. code-block:: console - - $ ./vsperf --conf-file=<path_to_custom_conf>/10_custom.conf --tests 'tput' - -Override specific test parameters. Useful for shortening the duration of tests -for development purposes: - -.. code-block:: console - - $ ./vsperf --test-params 'TRAFFICGEN_DURATION=10;TRAFFICGEN_RFC2544_TESTS=1;' \ - 'TRAFFICGEN_PKT_SIZES=(64,)' pvp_tput - -Typical Test Sequence -===================== - -This is a typical flow of control for a test. - -.. image:: vsperf.png - -.. _design-configuration: - -Configuration -============= - -The conf package contains the configuration files (``*.conf``) for all system -components, it also provides a ``settings`` object that exposes all of these -settings. - -Settings are not passed from component to component. Rather they are available -globally to all components once they import the conf package. - -.. code-block:: python - - from conf import settings - ... - log_file = settings.getValue('LOG_FILE_DEFAULT') - -Settings files (``*.conf``) are valid python code so can be set to complex -types such as lists and dictionaries as well as scalar types: - -.. code-block:: python - - first_packet_size = settings.getValue('PACKET_SIZE_LIST')[0] - -Configuration Procedure and Precedence --------------------------------------- - -Configuration files follow a strict naming convention that allows them to be -processed in a specific order. All the .conf files are named ``NN_name.conf``, -where NN is a decimal number. The files are processed in order from 00_name.conf -to 99_name.conf so that if the name setting is given in both a lower and higher -numbered conf file then the higher numbered file is the effective setting as it -is processed after the setting in the lower numbered file. - -The values in the file specified by ``--conf-file`` takes precedence over all -the other configuration files and does not have to follow the naming -convention. - -.. _paths-documentation: - -Configuration of PATHS dictionary ---------------------------------- - -VSPERF uses external tools like Open vSwitch and Qemu for execution of testcases. These -tools may be downloaded and built automatically (see :ref:`vsperf-installation-script`) -or installed manually by user from binary packages. It is also possible to use a combination -of both approaches, but it is essential to correctly set paths to all required tools. -These paths are stored within a PATHS dictionary, which is evaluated before execution -of each testcase, in order to setup testcase specific environment. Values selected for testcase -execution are internally stored inside TOOLS dictionary, which is used by VSPERF to execute -external tools, load kernel modules, etc. - -The default configuration of PATHS dictionary is spread among three different configuration files -to follow logical grouping of configuration options. Basic description of PATHS dictionary -is placed inside ``conf/00_common.conf``. The configuration specific to DPDK and vswitches -is located at ``conf/02_vswitch.conf``. The last part related to the Qemu is defined inside -``conf/04_vnf.conf``. Default configuration values can be used in case, that all required -tools were downloaded and built automatically by vsperf itself. In case, that some of -tools were installed manually from binary packages, then it will be necessary to modify -the content of PATHS dictionary accordingly. - -Dictionary has a specific section of configuration options for every tool type, it means: - - * ``PATHS['vswitch']`` - contains a separete dictionary for each of vswitches supported by VSPEF - - Example: - - .. code-block:: python - - PATHS['vswitch'] = { - 'OvsDpdkVhost': { ... }, - 'OvsVanilla' : { ... }, - ... - } - - * ``PATHS['dpdk']`` - contains paths to the dpdk sources, kernel modules and tools (e.g. testpmd) - - Example: - - .. code-block:: python - - PATHS['dpdk'] = { - 'type' : 'src', - 'src': { - 'path': os.path.join(ROOT_DIR, 'src/dpdk/dpdk/'), - 'modules' : ['uio', os.path.join(RTE_TARGET, 'kmod/igb_uio.ko')], - 'bind-tool': 'tools/dpdk*bind.py', - 'testpmd': os.path.join(RTE_TARGET, 'app', 'testpmd'), - }, - ... - } - - * ``PATHS['qemu']`` - contains paths to the qemu sources and executable file - - Example: - - .. code-block:: python - - PATHS['qemu'] = { - 'type' : 'bin', - 'bin': { - 'qemu-system': 'qemu-system-x86_64' - }, - ... - } - -Every section specific to the particular vswitch, dpdk or qemu may contain following types -of configuration options: - - * option ``type`` - is a string, which defines the type of configured paths ('src' or 'bin') - to be selected for a given section: - - * value ``src`` means, that VSPERF will use vswitch, DPDK or QEMU built from sources - e.g. by execution of ``systems/build_base_machine.sh`` script during VSPERF - installation - - * value ``bin`` means, that VSPERF will use vswitch, DPDK or QEMU binaries installed - directly in the operating system, e.g. via OS specific packaging system - - * option ``path`` - is a string with a valid system path; Its content is checked for - existence, prefixed with section name and stored into TOOLS for later use - e.g. ``TOOLS['dpdk_src']`` or ``TOOLS['vswitch_src']`` - - * option ``modules`` - is list of strings with names of kernel modules; Every module name - from given list is checked for a '.ko' suffix. In case that it matches and if it is not - an absolute path to the module, then module name is prefixed with value of ``path`` - option defined for the same section - - Example: - - .. code-block:: python - - """ - snippet of PATHS definition from the configuration file: - """ - PATHS['vswitch'] = { - 'OvsVanilla' = { - 'type' : 'src', - 'src': { - 'path': '/tmp/vsperf/src_vanilla/ovs/ovs/', - 'modules' : ['datapath/linux/openvswitch.ko'], - ... - }, - ... - } - ... - } - - """ - Final content of TOOLS dictionary used during runtime: - """ - TOOLS['vswitch_modules'] = ['/tmp/vsperf/src_vanilla/ovs/ovs/datapath/linux/openvswitch.ko'] - - * all other options are strings with names and paths to specific tools; If a given string - contains a relative path and option ``path`` is defined for a given section, then string - content will be prefixed with content of the ``path``. Otherwise the name of the tool will be - searched within standard system directories. In case that filename contains OS specific - wildcards, then they will be expanded to the real path. At the end of the processing, every - absolute path will be checked for its existence. In case that temporary path (i.e. path with - a ``_tmp`` suffix) does not exist, then log will be written and vsperf will continue. If any - other path will not exist, then vsperf execution will be terminated with a runtime error. - - Example: - - .. code-block:: python - - """ - snippet of PATHS definition from the configuration file: - """ - PATHS['vswitch'] = { - 'OvsDpdkVhost': { - 'type' : 'src', - 'src': { - 'path': '/tmp/vsperf/src_vanilla/ovs/ovs/', - 'ovs-vswitchd': 'vswitchd/ovs-vswitchd', - 'ovsdb-server': 'ovsdb/ovsdb-server', - ... - } - ... - } - ... - } - - """ - Final content of TOOLS dictionary used during runtime: - """ - TOOLS['ovs-vswitchd'] = '/tmp/vsperf/src_vanilla/ovs/ovs/vswitchd/ovs-vswitchd' - TOOLS['ovsdb-server'] = '/tmp/vsperf/src_vanilla/ovs/ovs/ovsdb/ovsdb-server' - -Note: In case that ``bin`` type is set for DPDK, then ``TOOLS['dpdk_src']`` will be set to -the value of ``PATHS['dpdk']['src']['path']``. The reason is, that VSPERF uses downloaded -DPDK sources to copy DPDK and testpmd into the GUEST, where testpmd is built. In case, -that DPDK sources are not available, then vsperf will continue with test execution, -but testpmd can't be used as a guest loopback. This is useful in case, that other guest -loopback applications (e.g. buildin or l2fwd) are used. - -Note: In case of RHEL 7.3 OS usage, binary package configuration is required -for Vanilla OVS tests. With the installation of a supported rpm for OVS there is -a section in the ``conf\10_custom.conf`` file that can be used. - -.. _configuration-of-traffic-dictionary: - -Configuration of TRAFFIC dictionary ------------------------------------ - -TRAFFIC dictionary is used for configuration of traffic generator. Default values -can be found in configuration file ``conf/03_traffic.conf``. These default values -can be modified by (first option has the highest priorty): - - 1. ``Parameters`` section of testcase defintion - 2. command line options specified by ``--test-params`` argument - 3. custom configuration file - -It is to note, that in case of option 1 and 2, it is possible to specify only -values, which should be changed. In case of custom configuration file, it is -required to specify whole ``TRAFFIC`` dictionary with its all values or explicitly -call and update() method of ``TRAFFIC`` dictionary. - -Detailed description of ``TRAFFIC`` dictionary items follows: - -.. code-block:: console - - 'traffic_type' - One of the supported traffic types. - E.g. rfc2544_throughput, rfc2544_back2back - or rfc2544_continuous - Data type: str - Default value: "rfc2544_throughput". - 'bidir' - Specifies if generated traffic will be full-duplex (True) - or half-duplex (False) - Data type: str - Supported values: "True", "False" - Default value: "False". - 'frame_rate' - Defines desired percentage of frame rate used during - continuous stream tests. - Data type: int - Default value: 100. - 'multistream' - Defines number of flows simulated by traffic generator. - Value 0 disables multistream feature - Data type: int - Supported values: 0-65535 - Default value: 0. - 'stream_type' - Stream type is an extension of the "multistream" feature. - If multistream is disabled, then stream type will be - ignored. Stream type defines ISO OSI network layer used - for simulation of multiple streams. - Data type: str - Supported values: - "L2" - iteration of destination MAC address - "L3" - iteration of destination IP address - "L4" - iteration of destination port - of selected transport protocol - Default value: "L4". - 'pre_installed_flows' - - Pre-installed flows is an extension of the "multistream" - feature. If enabled, it will implicitly insert a flow - for each stream. If multistream is disabled, then - pre-installed flows will be ignored. - Note: It is supported only for p2p deployment scenario. - Data type: str - Supported values: - "Yes" - flows will be inserted into OVS - "No" - flows won't be inserted into OVS - Default value: "No". - 'flow_type' - Defines flows complexity. - Data type: str - Supported values: - "port" - flow is defined by ingress ports - "IP" - flow is defined by ingress ports - and src and dst IP addresses - Default value: "port" - 'l2' - A dictionary with l2 network layer details. Supported - values are: - 'srcmac' - Specifies source MAC address filled by traffic generator. - NOTE: It can be modified by vsperf in some scenarios. - Data type: str - Default value: "00:00:00:00:00:00". - 'dstmac' - Specifies destination MAC address filled by traffic generator. - NOTE: It can be modified by vsperf in some scenarios. - Data type: str - Default value: "00:00:00:00:00:00". - 'framesize' - Specifies default frame size. This value should not be - changed directly. It will be overridden during testcase - execution by values specified by list TRAFFICGEN_PKT_SIZES. - Data type: int - Default value: 64 - 'l3' - A dictionary with l3 network layer details. Supported - values are: - 'srcip' - Specifies source MAC address filled by traffic generator. - NOTE: It can be modified by vsperf in some scenarios. - Data type: str - Default value: "1.1.1.1". - 'dstip' - Specifies destination MAC address filled by traffic generator. - NOTE: It can be modified by vsperf in some scenarios. - Data type: str - Default value: "90.90.90.90". - 'proto' - Specifies deflaut protocol type. - Please check particular traffic generator implementation - for supported protocol types. - Data type: str - Default value: "udp". - 'l4' - A dictionary with l4 network layer details. Supported - values are: - 'srcport' - Specifies source port of selected transport protocol. - NOTE: It can be modified by vsperf in some scenarios. - Data type: int - Default value: 3000 - 'dstport' - Specifies destination port of selected transport protocol. - NOTE: It can be modified by vsperf in some scenarios. - Data type: int - Default value: 3001 - 'vlan' - A dictionary with vlan encapsulation details. Supported - values are: - 'enabled' - Specifies if vlan encapsulation should be enabled or - disabled. - Data type: bool - Default value: False - 'id' - Specifies vlan id. - Data type: int (NOTE: must fit to 12 bits) - Default value: 0 - 'priority' - Specifies a vlan priority (PCP header field). - Data type: int (NOTE: must fit to 3 bits) - Default value: 0 - 'cfi' - Specifies if frames can or cannot be dropped during - congestion (DEI header field). - Data type: int (NOTE: must fit to 1 bit) - Default value: 0 - -.. _configuration-of-guest-options: - -Configuration of GUEST options ------------------------------- - -VSPERF is able to setup scenarios involving a number of VMs in series or in parallel. -All configuration options related to a particular VM instance are defined as -lists and prefixed with ``GUEST_`` label. It is essential, that there is enough -items in all ``GUEST_`` options to cover all VM instances involved in the test. -In case there is not enough items, then VSPERF will use the first item of -particular ``GUEST_`` option to expand the list to required length. - -Example of option expansion for 4 VMs: - - .. code-block:: python - - """ - Original values: - """ - GUEST_SMP = ['2'] - GUEST_MEMORY = ['2048', '4096'] - - """ - Values after automatic expansion: - """ - GUEST_SMP = ['2', '2', '2', '2'] - GUEST_MEMORY = ['2048', '4096', '2048', '2048'] - - -First option can contain macros starting with ``#`` to generate VM specific values. -These macros can be used only for options of ``list`` or ``str`` types with ``GUEST_`` -prefix. - -Example of macros and their expnasion for 2 VMs: - - .. code-block:: python - - """ - Original values: - """ - GUEST_SHARE_DIR = ['/tmp/qemu#VMINDEX_share'] - GUEST_BRIDGE_IP = ['#IP(1.1.1.5)/16'] - - """ - Values after automatic expansion: - """ - GUEST_SHARE_DIR = ['/tmp/qemu0_share', '/tmp/qemu1_share'] - GUEST_BRIDGE_IP = ['1.1.1.5/16', '1.1.1.6/16'] - -Additional examples are available at ``04_vnf.conf``. - -Note: In case, that macro is detected in the first item of the list, then -all other items are ignored and list content is created automatically. - -Multiple macros can be used inside one configuration option definition, but macros -cannot be used inside other macros. The only exception is macro ``#VMINDEX``, which -is expanded first and thus it can be used inside other macros. - -Following macros are supported: - - * ``#VMINDEX`` - it is replaced by index of VM being executed; This macro - is expanded first, so it can be used inside other macros. - - Example: - - .. code-block:: python - - GUEST_SHARE_DIR = ['/tmp/qemu#VMINDEX_share'] - - * ``#MAC(mac_address[, step])`` - it will iterate given ``mac_address`` - with optional ``step``. In case that step is not defined, then it is set to 1. - It means, that first VM will use the value of ``mac_address``, second VM - value of ``mac_address`` increased by ``step``, etc. - - Example: - - .. code-block:: python - - GUEST_NICS = [[{'mac' : '#MAC(00:00:00:00:00:01,2)'}]] - - * ``#IP(ip_address[, step])`` - it will iterate given ``ip_address`` - with optional ``step``. In case that step is not defined, then it is set to 1. - It means, that first VM will use the value of ``ip_address``, second VM - value of ``ip_address`` increased by ``step``, etc. - - Example: - - .. code-block:: python - - GUEST_BRIDGE_IP = ['#IP(1.1.1.5)/16'] - - * ``#EVAL(expression)`` - it will evaluate given ``expression`` as python code; - Only simple expressions should be used. Call of the functions is not supported. - - Example: - - .. code-block:: python - - GUEST_CORE_BINDING = [('#EVAL(6+2*#VMINDEX)', '#EVAL(7+2*#VMINDEX)')] - -Other Configuration -------------------- - -``conf.settings`` also loads configuration from the command line and from the environment. - -.. _pxp-deployment: - -PXP Deployment -============== - -Every testcase uses one of the supported deployment scenarios to setup test environment. -The controller responsible for a given scenario configures flows in the vswitch to route -traffic among physical interfaces connected to the traffic generator and virtual -machines. VSPERF supports several deployments including PXP deployment, which can -setup various scenarios with multiple VMs. - -These scenarios are realized by VswitchControllerPXP class, which can configure and -execute given number of VMs in serial or parallel configurations. Every VM can be -configured with just one or an even number of interfaces. In case that VM has more than -2 interfaces, then traffic is properly routed among pairs of interfaces. - -Example of traffic routing for VM with 4 NICs in serial configuration: - -.. code-block:: console - - +------------------------------------------+ - | VM with 4 NICs | - | +---------------+ +---------------+ | - | | Application | | Application | | - | +---------------+ +---------------+ | - | ^ | ^ | | - | | v | v | - | +---------------+ +---------------+ | - | | logical ports | | logical ports | | - | | 0 1 | | 2 3 | | - +--+---------------+----+---------------+--+ - ^ : ^ : - | | | | - : v : v - +-----------+---------------+----+---------------+----------+ - | vSwitch | 0 1 | | 2 3 | | - | | logical ports | | logical ports | | - | previous +---------------+ +---------------+ next | - | VM or PHY ^ | ^ | VM or PHY| - | port -----+ +------------+ +---> port | - +-----------------------------------------------------------+ - -It is also possible to define different number of interfaces for each VM to better -simulate real scenarios. - -Example of traffic routing for 2 VMs in serial configuration, where 1st VM has -4 NICs and 2nd VM 2 NICs: - -.. code-block:: console - - +------------------------------------------+ +---------------------+ - | 1st VM with 4 NICs | | 2nd VM with 2 NICs | - | +---------------+ +---------------+ | | +---------------+ | - | | Application | | Application | | | | Application | | - | +---------------+ +---------------+ | | +---------------+ | - | ^ | ^ | | | ^ | | - | | v | v | | | v | - | +---------------+ +---------------+ | | +---------------+ | - | | logical ports | | logical ports | | | | logical ports | | - | | 0 1 | | 2 3 | | | | 0 1 | | - +--+---------------+----+---------------+--+ +--+---------------+--+ - ^ : ^ : ^ : - | | | | | | - : v : v : v - +-----------+---------------+----+---------------+-------+---------------+----------+ - | vSwitch | 0 1 | | 2 3 | | 4 5 | | - | | logical ports | | logical ports | | logical ports | | - | previous +---------------+ +---------------+ +---------------+ next | - | VM or PHY ^ | ^ | ^ | VM or PHY| - | port -----+ +------------+ +---------------+ +----> port | - +-----------------------------------------------------------------------------------+ - -The number of VMs involved in the test and the type of their connection is defined -by deployment name as follows: - - * ``pvvp[number]`` - configures scenario with VMs connected in series with - optional ``number`` of VMs. In case that ``number`` is not specified, then - 2 VMs will be used. - - Example of 2 VMs in a serial configuration: - - .. code-block:: console - - +----------------------+ +----------------------+ - | 1st VM | | 2nd VM | - | +---------------+ | | +---------------+ | - | | Application | | | | Application | | - | +---------------+ | | +---------------+ | - | ^ | | | ^ | | - | | v | | | v | - | +---------------+ | | +---------------+ | - | | logical ports | | | | logical ports | | - | | 0 1 | | | | 0 1 | | - +---+---------------+--+ +---+---------------+--+ - ^ : ^ : - | | | | - : v : v - +---+---------------+---------+---------------+--+ - | | 0 1 | | 3 4 | | - | | logical ports | vSwitch | logical ports | | - | +---------------+ +---------------+ | - | ^ | ^ | | - | | +-----------------+ v | - | +----------------------------------------+ | - | | physical ports | | - | | 0 1 | | - +---+----------------------------------------+---+ - ^ : - | | - : v - +------------------------------------------------+ - | | - | traffic generator | - | | - +------------------------------------------------+ - - * ``pvpv[number]`` - configures scenario with VMs connected in parallel with - optional ``number`` of VMs. In case that ``number`` is not specified, then - 2 VMs will be used. Multistream feature is used to route traffic to particular - VMs (or NIC pairs of every VM). It means, that VSPERF will enable multistream - feaure and sets the number of streams to the number of VMs and their NIC - pairs. Traffic will be dispatched based on Stream Type, i.e. by UDP port, - IP address or MAC address. - - Example of 2 VMs in a parallel configuration, where traffic is dispatched - based on the UDP port. - - .. code-block:: console - - +----------------------+ +----------------------+ - | 1st VM | | 2nd VM | - | +---------------+ | | +---------------+ | - | | Application | | | | Application | | - | +---------------+ | | +---------------+ | - | ^ | | | ^ | | - | | v | | | v | - | +---------------+ | | +---------------+ | - | | logical ports | | | | logical ports | | - | | 0 1 | | | | 0 1 | | - +---+---------------+--+ +---+---------------+--+ - ^ : ^ : - | | | | - : v : v - +---+---------------+---------+---------------+--+ - | | 0 1 | | 3 4 | | - | | logical ports | vSwitch | logical ports | | - | +---------------+ +---------------+ | - | ^ | ^ : | - | | ......................: : | - | UDP | UDP : | : | - | port| port: +--------------------+ : | - | 0 | 1 : | : | - | | : v v | - | +----------------------------------------+ | - | | physical ports | | - | | 0 1 | | - +---+----------------------------------------+---+ - ^ : - | | - : v - +------------------------------------------------+ - | | - | traffic generator | - | | - +------------------------------------------------+ - - -PXP deployment is backward compatible with PVP deployment, where ``pvp`` is -an alias for ``pvvp1`` and it executes just one VM. - -The number of interfaces used by VMs is defined by configuration option -``GUEST_NICS_NR``. In case that more than one pair of interfaces is defined -for VM, then: - - * for ``pvvp`` (serial) scenario every NIC pair is connected in serial - before connection to next VM is created - * for ``pvpv`` (parallel) scenario every NIC pair is directly connected - to the physical ports and unique traffic stream is assigned to it - -Examples: - - * Deployment ``pvvp10`` will start 10 VMs and connects them in series - * Deployment ``pvpv4`` will start 4 VMs and connects them in parallel - * Deployment ``pvpv1`` and GUEST_NICS_NR = [4] will start 1 VM with - 4 interfaces and every NIC pair is directly connected to the - physical ports - * Deployment ``pvvp`` and GUEST_NICS_NR = [2, 4] will start 2 VMs; - 1st VM will have 2 interfaces and 2nd VM 4 interfaces. These interfaces - will be connected in serial, i.e. traffic will flow as follows: - PHY1 -> VM1_1 -> VM1_2 -> VM2_1 -> VM2_2 -> VM2_3 -> VM2_4 -> PHY2 - -Note: In case that only 1 or more than 2 NICs are configured for VM, -then ``testpmd`` should be used as forwarding application inside the VM. -As it is able to forward traffic between multiple VM NIC pairs. - -Note: In case of ``linux_bridge``, all NICs are connected to the same -bridge inside the VM. - -VM, vSwitch, Traffic Generator Independence -=========================================== - -VSPERF supports different vSwithes, Traffic Generators, VNFs -and Forwarding Applications by using standard object-oriented polymorphism: - - * Support for vSwitches is implemented by a class inheriting from IVSwitch. - * Support for Traffic Generators is implemented by a class inheriting from - ITrafficGenerator. - * Support for VNF is implemented by a class inheriting from IVNF. - * Support for Forwarding Applications is implemented by a class inheriting - from IPktFwd. - -By dealing only with the abstract interfaces the core framework can support -many implementations of different vSwitches, Traffic Generators, VNFs -and Forwarding Applications. - -IVSwitch --------- - -.. code-block:: python - - class IVSwitch: - start(self) - stop(self) - add_switch(switch_name) - del_switch(switch_name) - add_phy_port(switch_name) - add_vport(switch_name) - get_ports(switch_name) - del_port(switch_name, port_name) - add_flow(switch_name, flow) - del_flow(switch_name, flow=None) - -ITrafficGenerator ------------------ - -.. code-block:: python - - class ITrafficGenerator: - connect() - disconnect() - - send_burst_traffic(traffic, numpkts, time, framerate) - - send_cont_traffic(traffic, time, framerate) - start_cont_traffic(traffic, time, framerate) - stop_cont_traffic(self): - - send_rfc2544_throughput(traffic, tests, duration, lossrate) - start_rfc2544_throughput(traffic, tests, duration, lossrate) - wait_rfc2544_throughput(self) - - send_rfc2544_back2back(traffic, tests, duration, lossrate) - start_rfc2544_back2back(traffic, , tests, duration, lossrate) - wait_rfc2544_back2back() - -Note ``send_xxx()`` blocks whereas ``start_xxx()`` does not and must be followed by a subsequent call to ``wait_xxx()``. - -IVnf ----- - -.. code-block:: python - - class IVnf: - start(memory, cpus, - monitor_path, shared_path_host, - shared_path_guest, guest_prompt) - stop() - execute(command) - wait(guest_prompt) - execute_and_wait (command) - -IPktFwd --------- - - .. code-block:: python - - class IPktFwd: - start() - stop() - - -Controllers ------------ - -Controllers are used in conjunction with abstract interfaces as way -of decoupling the control of vSwtiches, VNFs, TrafficGenerators -and Forwarding Applications from other components. - -The controlled classes provide basic primitive operations. The Controllers -sequence and co-ordinate these primitive operation in to useful actions. For -instance the vswitch_controller_p2p can be used to bring any vSwitch (that -implements the primitives defined in IVSwitch) into the configuration required -by the Phy-to-Phy Deployment Scenario. - -In order to support a new vSwitch only a new implementation of IVSwitch needs -be created for the new vSwitch to be capable of fulfilling all the Deployment -Scenarios provided for by existing or future vSwitch Controllers. - -Similarly if a new Deployment Scenario is required it only needs to be written -once as a new vSwitch Controller and it will immediately be capable of -controlling all existing and future vSwitches in to that Deployment Scenario. - -Similarly the Traffic Controllers can be used to co-ordinate basic operations -provided by implementers of ITrafficGenerator to provide useful tests. Though -traffic generators generally already implement full test cases i.e. they both -generate suitable traffic and analyse returned traffic in order to implement a -test which has typically been predefined in an RFC document. However the -Traffic Controller class allows for the possibility of further enhancement - -such as iterating over tests for various packet sizes or creating new tests. - -Traffic Controller's Role -------------------------- - -.. image:: traffic_controller.png - - -Loader & Component Factory --------------------------- - -The working of the Loader package (which is responsible for *finding* arbitrary -classes based on configuration data) and the Component Factory which is -responsible for *choosing* the correct class for a particular situation - e.g. -Deployment Scenario can be seen in this diagram. - -.. image:: factory_and_loader.png - -Routing Tables -============== - -Vsperf uses a standard set of routing tables in order to allow tests to easily -mix and match Deployment Scenarios (PVP, P2P topology), Tuple Matching and -Frame Modification requirements. - -.. code-block:: console - - +--------------+ - | | - | Table 0 | table#0 - Match table. Flows designed to force 5 & 10 - | | tuple matches go here. - | | - +--------------+ - | - | - v - +--------------+ table#1 - Routing table. Flow entries to forward - | | packets between ports goes here. - | Table 1 | The chosen port is communicated to subsequent tables by - | | setting the metadata value to the egress port number. - | | Generally this table is set-up by by the - +--------------+ vSwitchController. - | - | - v - +--------------+ table#2 - Frame modification table. Frame modification - | | flow rules are isolated in this table so that they can - | Table 2 | be turned on or off without affecting the routing or - | | tuple-matching flow rules. This allows the frame - | | modification and tuple matching required by the tests - | | in the VSWITCH PERFORMANCE FOR TELCO NFV test - +--------------+ specification to be independent of the Deployment - | Scenario set up by the vSwitchController. - | - v - +--------------+ - | | - | Table 3 | table#3 - Egress table. Egress packets on the ports - | | setup in Table 1. - +--------------+ - - |