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authorVolodymyr Mytnyk <volodymyrx.mytnyk@intel.com>2019-01-11 10:04:20 +0000
committerGerrit Code Review <gerrit@opnfv.org>2019-01-11 10:04:20 +0000
commit07c506d3fff732019651d89de14bf42fa8d9a365 (patch)
tree5d05fff95180e015fafbf48eb894cd8fe95da383 /docs/testing/user/userguide/12-nsb-overview.rst
parente2f2e6b380fb63c4dcabe611aee180d4a0baa034 (diff)
parent3ceadb40c622a58c4b330fb3e6cdf391955b44a8 (diff)
Merge "[docs][userguide] Update formatting on userguide chapters 12-14"
Diffstat (limited to 'docs/testing/user/userguide/12-nsb-overview.rst')
-rw-r--r--docs/testing/user/userguide/12-nsb-overview.rst218
1 files changed, 100 insertions, 118 deletions
diff --git a/docs/testing/user/userguide/12-nsb-overview.rst b/docs/testing/user/userguide/12-nsb-overview.rst
index 7b0d46804..c5e395ee6 100644
--- a/docs/testing/user/userguide/12-nsb-overview.rst
+++ b/docs/testing/user/userguide/12-nsb-overview.rst
@@ -7,16 +7,17 @@
Network Services Benchmarking (NSB)
===================================
-Abstract
-========
-
.. _Yardstick: https://wiki.opnfv.org/display/yardstick
+.. _`ETSI GS NFV-TST001`: http://www.etsi.org/deliver/etsi_gs/NFV-TST/001_099/001/01.01.01_60/gs_nfv-tst001v010101p.pdf
+
+Abstract
+--------
This chapter provides an overview of the NSB, a contribution to OPNFV
Yardstick_ from Intel.
Overview
-========
+--------
The goal of NSB is to Extend Yardstick to perform real world VNFs and NFVi
Characterization and benchmarking with repeatable and deterministic methods.
@@ -31,44 +32,34 @@ according to user defined profiles.
NSB extension includes:
- - Generic data models of Network Services, based on ETSI spec `ETSI GS NFV-TST 001 <http://www.etsi.org/deliver/etsi_gs/NFV-TST/001_099/001/01.01.01_60/gs_nfv-tst001v010101p.pdf>`_
-
- - New Standalone context for VNF testing like SRIOV, OVS, OVS-DPDK etc
-
- - Generic VNF configuration models and metrics implemented with Python
- classes
-
- - Traffic generator features and traffic profiles
-
- - L1-L3 state-less traffic profiles
-
- - L4-L7 state-full traffic profiles
-
- - Tunneling protocol / network overlay support
-
- - Test case samples
-
- - Ping
-
- - Trex
+* Generic data models of Network Services, based on ETSI spec
+ `ETSI GS NFV-TST 001`_
+* Standalone :term:`context` for VNF testing like SRIOV, OVS, OVS-DPDK, etc
+* Generic VNF configuration models and metrics implemented with Python
+ classes
+* Traffic generator features and traffic profiles
- - vPE,vCGNAT, vFirewall etc - ipv4 throughput, latency etc
+ * L1-L3 stateless traffic profiles
+ * L4-L7 state-full traffic profiles
+ * Tunneling protocol/network overlay support
- - Traffic generators like Trex, ab/nginx, ixia, iperf etc
+* Test case samples
- - KPIs for a given use case:
+ * Ping
+ * Trex
+ * vPE, vCGNAT, vFirewall etc - ipv4 throughput, latency etc
- - System agent support for collecting NFVi KPI. This includes:
+* Traffic generators i.e. Trex, ab/nginx, ixia, iperf, etc
+* KPIs for a given use case:
- - CPU statistic
+ * System agent support for collecting NFVi KPI. This includes:
- - Memory BW
+ * CPU statistic
+ * Memory BW
+ * OVS-DPDK Stats
- - OVS-DPDK Stats
-
- - Network KPIs, e.g., inpackets, outpackets, thoughput, latency etc
-
- - VNF KPIs, e.g., packet_in, packet_drop, packet_fwd etc
+ * Network KPIs e.g. inpackets, outpackets, thoughput, latency
+ * VNF KPIs e.g. packet_in, packet_drop, packet_fwd
Architecture
============
@@ -83,111 +74,102 @@ performed network functionality. The part of the data model is a set of the
configuration parameters, number of connection points used and flavor including
core and memory amount.
-The ETSI defines a Network Service as a set of configurable VNFs working in
-some NFV Infrastructure connecting each other using Virtual Links available
-through Connection Points. The ETSI MANO specification defines a set of
-management entities called Network Service Descriptors (NSD) and
-VNF Descriptors (VNFD) that define real Network Service. The picture below
-makes an example how the real Network Operator use-case can map into ETSI
-Network service definition
-
-Network Service framework performs the necessary test steps. It may involve
-
- - Interacting with traffic generator and providing the inputs on traffic
- type / packet structure to generate the required traffic as per the
- test case. Traffic profiles will be used for this.
-
- - Executing the commands required for the test procedure and analyses the
- command output for confirming whether the command got executed correctly
- or not. E.g. As per the test case, run the traffic for the given
- time period / wait for the necessary time delay
-
- - Verify the test result.
-
- - Validate the traffic flow from SUT
-
- - Fetch the table / data from SUT and verify the value as per the test case
-
- - Upload the logs from SUT onto the Test Harness server
-
- - Read the KPI's provided by particular VNF
+ETSI defines a Network Service as a set of configurable VNFs working in some
+NFV Infrastructure connecting each other using Virtual Links available through
+Connection Points. The ETSI MANO specification defines a set of management
+entities called Network Service Descriptors (NSD) and VNF Descriptors (VNFD)
+that define real Network Service. The picture below makes an example how the
+real Network Operator use-case can map into ETSI Network service definition.
+
+Network Service framework performs the necessary test steps. It may involve:
+
+* Interacting with traffic generator and providing the inputs on traffic
+ type / packet structure to generate the required traffic as per the
+ test case. Traffic profiles will be used for this.
+* Executing the commands required for the test procedure and analyses the
+ command output for confirming whether the command got executed correctly
+ or not e.g. as per the test case, run the traffic for the given
+ time period and wait for the necessary time delay.
+* Verify the test result.
+* Validate the traffic flow from SUT.
+* Fetch the data from SUT and verify the value as per the test case.
+* Upload the logs from SUT onto the Test Harness server
+* Retrieve the KPI's provided by particular VNF
Components of Network Service
-----------------------------
- * *Models for Network Service benchmarking*: The Network Service benchmarking
- requires the proper modelling approach. The NSB provides models using Python
- files and defining of NSDs and VNFDs.
+* *Models for Network Service benchmarking*: The Network Service benchmarking
+ requires the proper modelling approach. The NSB provides models using Python
+ files and defining of NSDs and VNFDs.
- The benchmark control application being a part of OPNFV yardstick can call
- that python models to instantiate and configure the VNFs. Depending on
- infrastructure type (bare-metal or fully virtualized) that calls could be
- made directly or using MANO system.
+The benchmark control application being a part of OPNFV yardstick can call
+that python models to instantiate and configure the VNFs. Depending on
+infrastructure type (bare-metal or fully virtualized) that calls could be
+made directly or using MANO system.
- * *Traffic generators in NSB*: Any benchmark application requires a set of
- traffic generator and traffic profiles defining the method in which traffic
- is generated.
+* *Traffic generators in NSB*: Any benchmark application requires a set of
+ traffic generator and traffic profiles defining the method in which traffic
+ is generated.
- The Network Service benchmarking model extends the Network Service
- definition with a set of Traffic Generators (TG) that are treated
- same way as other VNFs being a part of benchmarked network service.
- Same as other VNFs the traffic generator are instantiated and terminated.
+The Network Service benchmarking model extends the Network Service
+definition with a set of Traffic Generators (TG) that are treated
+same way as other VNFs being a part of benchmarked network service.
+Same as other VNFs the traffic generator are instantiated and terminated.
- Every traffic generator has own configuration defined as a traffic profile
- and a set of KPIs supported. The python models for TG is extended by
- specific calls to listen and generate traffic.
+Every traffic generator has own configuration defined as a traffic profile
+and a set of KPIs supported. The python models for TG is extended by
+specific calls to listen and generate traffic.
- * *The stateless TREX traffic generator*: The main traffic generator used as
- Network Service stimulus is open source TREX tool.
+* *The stateless TREX traffic generator*: The main traffic generator used as
+ Network Service stimulus is open source TREX tool.
- The TREX tool can generate any kind of stateless traffic.
+The TREX tool can generate any kind of stateless traffic.
- .. code-block:: console
-
- +--------+ +-------+ +--------+
- | | | | | |
- | Trex | ---> | VNF | ---> | Trex |
- | | | | | |
- +--------+ +-------+ +--------+
-
- Supported testcases scenarios:
+.. code-block:: console
- - Correlated UDP traffic using TREX traffic generator and replay VNF.
+ +--------+ +-------+ +--------+
+ | | | | | |
+ | Trex | ---> | VNF | ---> | Trex |
+ | | | | | |
+ +--------+ +-------+ +--------+
- - using different IMIX configuration like pure voice, pure video traffic etc
+Supported testcases scenarios:
- - using different number IP flows like 1 flow, 1K, 16K, 64K, 256K, 1M flows
+* Correlated UDP traffic using TREX traffic generator and replay VNF.
- - Using different number of rules configured like 1 rule, 1K, 10K rules
+ * using different IMIX configuration like pure voice, pure video traffic etc
+ * using different number IP flows e.g. 1, 1K, 16K, 64K, 256K, 1M flows
+ * Using different number of rules configured e.g. 1, 1K, 10K rules
- For UDP correlated traffic following Key Performance Indicators are collected
- for every combination of test case parameters:
+For UDP correlated traffic following Key Performance Indicators are collected
+for every combination of test case parameters:
- - RFC2544 throughput for various loss rate defined (1% is a default)
+* RFC2544 throughput for various loss rate defined (1% is a default)
Graphical Overview
==================
-NSB Testing with yardstick framework facilitate performance testing of various
+NSB Testing with Yardstick framework facilitate performance testing of various
VNFs provided.
.. code-block:: console
+-----------+
- | | +-----------+
- | vPE | ->|TGen Port 0|
- | TestCase | | +-----------+
- | | |
- +-----------+ +------------------+ +-------+ |
- | | -- API --> | VNF | <--->
- +-----------+ | Yardstick | +-------+ |
- | Test Case | --> | NSB Testing | |
- +-----------+ | | |
- | | | |
- | +------------------+ |
- +-----------+ | +-----------+
- | Traffic | ->|TGen Port 1|
- | patterns | +-----------+
+ | | +-------------+
+ | vPE | -->| TGen Port 0 |
+ | TestCase | | +-------------+
+ | | |
+ +-----------+ +---------------+ +-------+ |
+ | | ---> | VNF | <--->
+ +-----------+ | Yardstick | +-------+ |
+ | Test Case | --> | NSB Testing | |
+ +-----------+ | | |
+ | | | |
+ | +---------------+ |
+ +-----------+ | +-------------+
+ | Traffic | -->| TGen Port 1 |
+ | patterns | +-------------+
+-----------+
Figure 1: Network Service - 2 server configuration
@@ -199,8 +181,8 @@ VNFs supported for chracterization:
2. vFW - Virtual Firewall
3. vACL - Access Control List
4. Prox - Packet pROcessing eXecution engine:
- - VNF can act as Drop, Basic Forwarding (no touch),
- L2 Forwarding (change MAC), GRE encap/decap, Load balance based on
- packet fields, Symmetric load balancing
- - QinQ encap/decap IPv4/IPv6, ARP, QoS, Routing, Unmpls, Policing, ACL
+ * VNF can act as Drop, Basic Forwarding (no touch),
+ L2 Forwarding (change MAC), GRE encap/decap, Load balance based on
+ packet fields, Symmetric load balancing
+ * QinQ encap/decap IPv4/IPv6, ARP, QoS, Routing, Unmpls, Policing, ACL
5. UDP_Replay