1 files changed, 329 insertions, 320 deletions

diff --git a/docs/report/vpp_performance_tests/overview.rst b/docs/report/vpp_performance_tests/overview.rst
index 0a5525a6d8..dbc1612f84 100644
--- a/docs/report/vpp_performance_tests/overview.rst
+++ b/docs/report/vpp_performance_tests/overview.rst
@@ -1,320 +1,329 @@
-Overview

-========

-

-Tested Physical Topologies

---------------------------

-

-CSIT VPP performance tests are executed on physical baremetal servers hosted by LF

-FD.io project. Testbed physical topology is shown in the figure below.

-

-::

-

-    +------------------------+           +------------------------+

-    |                        |           |                        |

-    |  +------------------+  |           |  +------------------+  |

-    |  |                  |  |           |  |                  |  |

-    |  |                  <----------------->                  |  |

-    |  |       DUT1       |  |           |  |       DUT2       |  |

-    |  +--^---------------+  |           |  +---------------^--+  |

-    |     |                  |           |                  |     |

-    |     |            SUT1  |           |  SUT2            |     |

-    +------------------------+           +------------------^-----+

-          |                                                 |

-          |                                                 |

-          |                  +-----------+                  |

-          |                  |           |                  |

-          +------------------>    TG     <------------------+

-                             |           |

-                             +-----------+

-

-SUT1 and SUT2 are two System Under Test servers (Cisco UCS C240, each with two

-Intel XEON CPUs), TG is a Traffic Generator (TG, another Cisco UCS C240, with

-two Intel XEON CPUs). SUTs run VPP SW application in Linux user-mode as a

-Device Under Test (DUT). TG runs TRex SW application as a packet Traffic

-Generator. Physical connectivity between SUTs and to TG is provided using

-different NIC models that need to be tested for performance. Currently

-installed and tested NIC models include:

-

-#. 2port10GE X520-DA2 Intel.

-#. 2port10GE X710 Intel.

-#. 2port10GE VIC1227 Cisco.

-#. 2port40GE VIC1385 Cisco.

-#. 2port40GE XL710 Intel.

-

-From SUT and DUT perspective, all performance tests involve forwarding packets

-between two physical Ethernet ports (10GE or 40GE). Due to the number of

-listed NIC models tested and available PCI slot capacity in SUT servers, in

-all of the above cases both physical ports are located on the same NIC. In

-some test cases this results in measured packet throughput being limited not

-by VPP DUT but by either the physical interface or the NIC capacity.

-

-Going forward CSIT project will be looking to add more hardware into FD.io

-performance labs to address larger scale multi-interface and multi-NIC

-performance testing scenarios.

-

-For test cases that require DUT (VPP) to communicate with VM(s) over vhost-user

-interfaces, N of VM instances are created on SUT1 and SUT2. For N=1 DUT (VPP) forwards packets between vhostuser and physical interfaces. For N>1 DUT (VPP) a logical service chain forwarding topology is created on DUT (VPP) by applying L2 or IPv4/IPv6 configuration depending on the test suite.

-DUT (VPP) test topology with N VM instances

-is shown in the figure below including applicable packet flow thru the DUTs and VMs

-(marked in the figure with ``***``).

-

-::

-

-    +-------------------------+           +-------------------------+

-    | +---------+ +---------+ |           | +---------+ +---------+ |

-    | |  VM[1]  | |  VM[N]  | |           | |  VM[1]  | |  VM[N]  | |

-    | |  *****  | |  *****  | |           | |  *****  | |  *****  | |

-    | +--^---^--+ +--^---^--+ |           | +--^---^--+ +--^---^--+ |

-    |   *|   |*     *|   |*   |           |   *|   |*     *|   |*   |

-    | +--v---v-------v---v--+ |           | +--v---v-------v---v--+ |

-    | |  *   *       *   *  |*|***********|*|  *   *       *   *  | |

-    | |  *   *********   ***<-|-----------|->***   *********   *  | |

-    | |  *    DUT1          | |           | |       DUT2       *  | |

-    | +--^------------------+ |           | +------------------^--+ |

-    |   *|                    |           |                    |*   |

-    |   *|            SUT1    |           |  SUT2              |*   |

-    +-------------------------+           +-------------------------+

-        *|                                                     |*

-        *|                                                     |*

-        *|                    +-----------+                    |*

-        *|                    |           |                    |*

-        *+-------------------->    TG     <--------------------+*

-        **********************|           |**********************

-                              +-----------+

-

-For VM tests, packets are switched by DUT (VPP) multiple times: twice for a single VM, three times for two VMs, N+1 times for N VMs.

-Hence the external

-throughput rates measured by TG and listed in this report must be multiplied

-by (N+1) to represent the actual DUT aggregate packet forwarding rate.

-

-CSIT |release|

-

-Note that reported VPP performance results are specific to the SUTs tested.

-Current LF FD.io SUTs are based on Intel XEON E5-2699v3 2.3GHz CPUs. SUTs with

-other CPUs are likely to yield different results. A good rule of thumb, that

-can be applied to estimate VPP packet thoughput for Phy-to-Phy (NIC-to-NIC,

-PCI-to-PCI) topology, is to expect the forwarding performance to be

-proportional to CPU core frequency, assuming CPU is the only limiting factor

-and all other SUT parameters equivalent to FD.io CSIT environment. The same rule of

-thumb can be also applied for Phy-to-VM-to-Phy (NIC-to-VM-to-NIC) topology,

-but due to much higher dependency on intensive memory operations and

-sensitivity to Linux kernel scheduler settings and behaviour, this estimation

-may not always yield good enough accuracy.

-

-For detailed LF FD.io test bed specification and physical topology please refer to `LF FDio CSIT testbed wiki page <https://wiki.fd.io/view/CSIT/CSIT_LF_testbed>`_.

-

-Performance Tests Coverage

---------------------------

-

-Performance tests are split into the two main categories:

-

-- Throughput discovery - discovery of packet forwarding rate using binary search

-  in accordance to RFC2544.

-

-  - NDR - discovery of Non Drop Rate packet throughput, at zero packet loss;

-    followed by one-way packet latency measurements at 10%, 50% and 100% of

-    discovered NDR throughput.

-  - PDR - discovery of Partial Drop Rate, with specified non-zero packet loss

-    currently set to 0.5%; followed by one-way packet latency measurements at

-    100% of discovered PDR throughput.

-

-- Throughput verification - verification of packet forwarding rate against

-  previously discovered throughput rate. These tests are currently done against

-  0.9 of reference NDR, with reference rates updated periodically.

-

-CSIT |release| includes following performance test suites, listed per NIC type:

-

-- 2port10GE X520-DA2 Intel

-

-  - **L2XC** - L2 Cross-Connect switched-forwarding of untagged, dot1q, dot1ad

-    VLAN tagged Ethernet frames.

-  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames

-    with MAC learning; disabled MAC learning i.e. static MAC tests to be added.

-  - **IPv4** - IPv4 routed-forwarding.

-  - **IPv6** - IPv6 routed-forwarding.

-  - **IPv4 Scale** - IPv4 routed-forwarding with 20k, 200k and 2M FIB entries.

-  - **IPv6 Scale** - IPv6 routed-forwarding with 20k, 200k and 2M FIB entries.

-  - **VM with vhost-user** - switching between NIC ports and VM over vhost-user

-    interfaces in different switching modes incl. L2 Cross-Connect, L2

-    Bridge-Domain, VXLAN with L2BD, IPv4 routed-forwarding.

-  - **COP** - IPv4 and IPv6 routed-forwarding with COP address security.

-  - **iACL** - IPv4 and IPv6 routed-forwarding with iACL address security.

-  - **LISP** - LISP overlay tunneling for IPv4-over-IPV4, IPv6-over-IPv4,

-    IPv6-over-IPv6, IPv4-over-IPv6 in IPv4 and IPv6 routed-forwarding modes.

-  - **VXLAN** - VXLAN overlay tunnelling integration with L2XC and L2BD.

-  - **QoS Policer** - ingress packet rate measuring, marking and limiting

-    (IPv4).

-

-- 2port40GE XL710 Intel

-

-  - **L2XC** - L2 Cross-Connect switched-forwarding of untagged Ethernet frames.

-  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames

-    with MAC learning.

-  - **IPv4** - IPv4 routed-forwarding.

-  - **IPv6** - IPv6 routed-forwarding.

-  - **VM with vhost-user** - switching between NIC ports and VM over vhost-user

-    interfaces in different switching modes incl. L2 Bridge-Domain.

-

-- 2port10GE X710 Intel

-

-  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames

-    with MAC learning.

-  - **VM with vhost-user** - switching between NIC ports and VM over vhost-user

-    interfaces in different switching modes incl. L2 Bridge-Domain.

-

-- 2port10GE VIC1227 Cisco

-

-  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames

-    with MAC learning.

-

-- 2port40GE VIC1385 Cisco

-

-  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames

-     with MAC learning.

-

-Execution of performance tests takes time, especially the throughput discovery

-tests. Due to limited HW testbed resources available within FD.io labs hosted

-by Linux Foundation, the number of tests for NICs other than X520 (a.k.a.

-Niantic) has been limited to few baseline tests. Over time we expect the HW

-testbed resources to grow, and will be adding complete set of performance

-tests for all models of hardware to be executed regularly and(or)

-continuously.

-

-Performance Tests Naming

-------------------------

-

-CSIT |release| follows a common structured naming convention for all

-performance and system functional tests, introduced in CSIT rls1701.

-

-The naming should be intuitive for majority of the tests. Complete

-description of CSIT test naming convention is provided on `CSIT test naming wiki

-<https://wiki.fd.io/view/CSIT/csit-test-naming>`_.

-

-Here few illustrative examples of the new naming usage for performance test

-suites:

-

-#. **Physical port to physical port - a.k.a. NIC-to-NIC, Phy-to-Phy, P2P**

-

-    - *PortNICConfig-WireEncapsulation-PacketForwardingFunction-

-      PacketProcessingFunction1-...-PacketProcessingFunctionN-TestType*

-    - *10ge2p1x520-dot1q-l2bdbasemaclrn-ndrdisc.robot* => 2 ports of 10GE on

-      Intel x520 NIC, dot1q tagged Ethernet, L2 bridge-domain baseline switching

-      with MAC learning, NDR throughput discovery.

-    - *10ge2p1x520-ethip4vxlan-l2bdbasemaclrn-ndrchk.robot* => 2 ports of 10GE

-      on Intel x520 NIC, IPv4 VXLAN Ethernet, L2 bridge-domain baseline

-      switching with MAC learning, NDR throughput discovery.

-    - *10ge2p1x520-ethip4-ip4base-ndrdisc.robot* => 2 ports of 10GE on Intel

-      x520 NIC, IPv4 baseline routed forwarding, NDR throughput discovery.

-    - *10ge2p1x520-ethip6-ip6scale200k-ndrdisc.robot* => 2 ports of 10GE on

-      Intel x520 NIC, IPv6 scaled up routed forwarding, NDR throughput

-      discovery.

-

-#. **Physical port to VM (or VM chain) to physical port - a.k.a. NIC2VM2NIC,

-   P2V2P, NIC2VMchain2NIC, P2V2V2P**

-

-    - *PortNICConfig-WireEncapsulation-PacketForwardingFunction-

-      PacketProcessingFunction1-...-PacketProcessingFunctionN-VirtEncapsulation-

-      VirtPortConfig-VMconfig-TestType*

-    - *10ge2p1x520-dot1q-l2bdbasemaclrn-eth-2vhost-1vm-ndrdisc.robot* => 2 ports

-      of 10GE on Intel x520 NIC, dot1q tagged Ethernet, L2 bridge-domain

-      switching to/from two vhost interfaces and one VM, NDR throughput

-      discovery.

-    - *10ge2p1x520-ethip4vxlan-l2bdbasemaclrn-eth-2vhost-1vm-ndrdisc.robot* => 2

-      ports of 10GE on Intel x520 NIC, IPv4 VXLAN Ethernet, L2 bridge-domain

-      switching to/from two vhost interfaces and one VM, NDR throughput

-      discovery.

-    - *10ge2p1x520-ethip4vxlan-l2bdbasemaclrn-eth-4vhost-2vm-ndrdisc.robot* => 2

-      ports of 10GE on Intel x520 NIC, IPv4 VXLAN Ethernet, L2 bridge-domain

-      switching to/from four vhost interfaces and two VMs, NDR throughput

-      discovery.

-

-Methodology: Multi-Thread and Multi-Core

-----------------------------------------

-

-**HyperThreading** - CSIT |release| performance tests are executed with SUT

-servers' Intel XEON CPUs configured in HyperThreading Disabled mode (BIOS

-settings). This is the simplest configuration used to establish baseline

-single-thread single-core SW packet processing and forwarding performance.

-Subsequent releases of CSIT will add performance tests with Intel

-HyperThreading Enabled (requires BIOS settings change and hard reboot).

-

-**Multi-core Test** - CSIT |release| multi-core tests are executed in the

-following VPP thread and core configurations:

-

-#. 1t1c - 1 VPP worker thread on 1 CPU physical core.

-#. 2t2c - 2 VPP worker threads on 2 CPU physical cores.

-

-Note that in quite a few test cases running VPP on 2 physical cores hits

-the tested NIC I/O bandwidth or packets-per-second limit.

-

-Methodology: Packet Throughput

-------------------------------

-

-Following values are measured and reported for packet throughput tests:

-

-- NDR binary search per RFC2544:

-

-  - Packet rate: "RATE: <aggregate packet rate in packets-per-second> pps

-    (2x <per direction packets-per-second>)"

-  - Aggregate bandwidth: "BANDWIDTH: <aggregate bandwidth in Gigabits per

-    second> Gbps (untagged)"

-

-- PDR binary search per RFC2544:

-

-  - Packet rate: "RATE: <aggregate packet rate in packets-per-second> pps (2x

-    <per direction packets-per-second>)"

-  - Aggregate bandwidth: "BANDWIDTH: <aggregate bandwidth in Gigabits per

-    second> Gbps (untagged)"

-  - Packet loss tolerance: "LOSS_ACCEPTANCE <accepted percentage of packets

-    lost at PDR rate>""

-

-- NDR and PDR are measured for the following L2 frame sizes:

-

-  - IPv4: 64B, IMIX_v4_1 (28x64B,16x570B,4x1518B), 1518B, 9000B.

-  - IPv6: 78B, 1518B, 9000B.

-

-

-Methodology: Packet Latency

----------------------------

-

-TRex Traffic Generator (TG) is used for measuring latency of VPP DUTs. Reported

-latency values are measured using following methodology:

-

-- Latency tests are performed at 10%, 50% of discovered NDR rate (non drop rate)

-  for each NDR throughput test and packet size (except IMIX).

-- TG sends dedicated latency streams, one per direction, each at the rate of

-  10kpps at the prescribed packet size; these are sent in addition to the main

-  load streams.

-- TG reports min/avg/max latency values per stream direction, hence two sets

-  of latency values are reported per test case; future release of TRex is

-  expected to report latency percentiles.

-- Reported latency values are aggregate across two SUTs due to three node

-  topology used for all performance tests; for per SUT latency, reported value

-  should be divided by two.

-- 1usec is the measurement accuracy advertised by TRex TG for the setup used in

-  FD.io labs used by CSIT project.

-- TRex setup introduces an always-on error of about 2*2usec per latency flow -

-  additonal Tx/Rx interface latency induced by TRex SW writing and reading

-  packet timestamps on CPU cores without HW acceleration on NICs closer to the

-  interface line.

-

-

-Methodology: KVM VM vhost

--------------------------

-

-CSIT |release| introduced environment configuration changes to KVM Qemu vhost-

-user tests in order to more representatively measure VPP-17.01 performance in

-configurations with vhost-user interfaces and VMs.

-

-Current setup of CSIT FD.io performance lab is using tuned settings for more

-optimal performance of KVM Qemu:

-

-- Default Qemu virtio queue size of 256 descriptors.

-- Adjusted Linux kernel CFS scheduler settings, as detailed on this CSIT wiki

-  page: https://wiki.fd.io/view/CSIT/csit-perf-env-tuning-ubuntu1604.

-

-Adjusted Linux kernel CFS settings make the NDR and PDR throughput performance

-of VPP+VM system less sensitive to other Linux OS system tasks by reducing

-their interference on CPU cores that are designated for critical software

-tasks under test, namely VPP worker threads in host and Testpmd threads in

-guest dealing with data plan.

+Overview
+========
+
+Tested Physical Topologies
+--------------------------
+
+CSIT VPP performance tests are executed on physical baremetal servers hosted by
+LF FD.io project. Testbed physical topology is shown in the figure below.
+
+::
+
+    +------------------------+           +------------------------+
+    |                        |           |                        |
+    |  +------------------+  |           |  +------------------+  |
+    |  |                  |  |           |  |                  |  |
+    |  |                  <----------------->                  |  |
+    |  |       DUT1       |  |           |  |       DUT2       |  |
+    |  +--^---------------+  |           |  +---------------^--+  |
+    |     |                  |           |                  |     |
+    |     |            SUT1  |           |  SUT2            |     |
+    +------------------------+           +------------------^-----+
+          |                                                 |
+          |                                                 |
+          |                  +-----------+                  |
+          |                  |           |                  |
+          +------------------>    TG     <------------------+
+                             |           |
+                             +-----------+
+
+SUT1 and SUT2 are two System Under Test servers (Cisco UCS C240, each with two
+Intel XEON CPUs), TG is a Traffic Generator (TG, another Cisco UCS C240, with
+two Intel XEON CPUs). SUTs run VPP SW application in Linux user-mode as a
+Device Under Test (DUT). TG runs TRex SW application as a packet Traffic
+Generator. Physical connectivity between SUTs and to TG is provided using
+different NIC models that need to be tested for performance. Currently
+installed and tested NIC models include:
+
+#. 2port10GE X520-DA2 Intel.
+#. 2port10GE X710 Intel.
+#. 2port10GE VIC1227 Cisco.
+#. 2port40GE VIC1385 Cisco.
+#. 2port40GE XL710 Intel.
+
+From SUT and DUT perspective, all performance tests involve forwarding packets
+between two physical Ethernet ports (10GE or 40GE). Due to the number of
+listed NIC models tested and available PCI slot capacity in SUT servers, in
+all of the above cases both physical ports are located on the same NIC. In
+some test cases this results in measured packet throughput being limited not
+by VPP DUT but by either the physical interface or the NIC capacity.
+
+Going forward CSIT project will be looking to add more hardware into FD.io
+performance labs to address larger scale multi-interface and multi-NIC
+performance testing scenarios.
+
+For test cases that require DUT (VPP) to communicate with VM(s) over vhost-user
+interfaces, N of VM instances are created on SUT1 and SUT2. For N=1 DUT (VPP)
+forwards packets between vhostuser and physical interfaces. For N>1 DUT (VPP) a
+logical service chain forwarding topology is created on DUT (VPP) by applying L2
+or IPv4/IPv6 configuration depending on the test suite.
+DUT (VPP) test topology with N VM instances
+is shown in the figure below including applicable packet flow thru the DUTs and
+VMs (marked in the figure with ``***``).
+
+::
+
+    +-------------------------+           +-------------------------+
+    | +---------+ +---------+ |           | +---------+ +---------+ |
+    | |  VM[1]  | |  VM[N]  | |           | |  VM[1]  | |  VM[N]  | |
+    | |  *****  | |  *****  | |           | |  *****  | |  *****  | |
+    | +--^---^--+ +--^---^--+ |           | +--^---^--+ +--^---^--+ |
+    |   *|   |*     *|   |*   |           |   *|   |*     *|   |*   |
+    | +--v---v-------v---v--+ |           | +--v---v-------v---v--+ |
+    | |  *   *       *   *  |*|***********|*|  *   *       *   *  | |
+    | |  *   *********   ***<-|-----------|->***   *********   *  | |
+    | |  *    DUT1          | |           | |       DUT2       *  | |
+    | +--^------------------+ |           | +------------------^--+ |
+    |   *|                    |           |                    |*   |
+    |   *|            SUT1    |           |  SUT2              |*   |
+    +-------------------------+           +-------------------------+
+        *|                                                     |*
+        *|                                                     |*
+        *|                    +-----------+                    |*
+        *|                    |           |                    |*
+        *+-------------------->    TG     <--------------------+*
+        **********************|           |**********************
+                              +-----------+
+
+For VM tests, packets are switched by DUT (VPP) multiple times: twice for a
+single VM, three times for two VMs, N+1 times for N VMs.
+Hence the external
+throughput rates measured by TG and listed in this report must be multiplied
+by (N+1) to represent the actual DUT aggregate packet forwarding rate.
+
+Note that reported VPP performance results are specific to the SUTs tested.
+Current LF FD.io SUTs are based on Intel XEON E5-2699v3 2.3GHz CPUs. SUTs with
+other CPUs are likely to yield different results. A good rule of thumb, that
+can be applied to estimate VPP packet thoughput for Phy-to-Phy (NIC-to-NIC,
+PCI-to-PCI) topology, is to expect the forwarding performance to be
+proportional to CPU core frequency, assuming CPU is the only limiting factor
+and all other SUT parameters equivalent to FD.io CSIT environment. The same rule
+of thumb can be also applied for Phy-to-VM-to-Phy (NIC-to-VM-to-NIC) topology,
+but due to much higher dependency on intensive memory operations and
+sensitivity to Linux kernel scheduler settings and behaviour, this estimation
+may not always yield good enough accuracy.
+
+For detailed LF FD.io test bed specification and physical topology please refer
+to `LF FDio CSIT testbed wiki page <https://wiki.fd.io/view/CSIT/CSIT_LF_testbed>`_.
+
+Performance Tests Coverage
+--------------------------
+
+Performance tests are split into the two main categories:
+
+- Throughput discovery - discovery of packet forwarding rate using binary search
+  in accordance to RFC2544.
+
+  - NDR - discovery of Non Drop Rate packet throughput, at zero packet loss;
+    followed by one-way packet latency measurements at 10%, 50% and 100% of
+    discovered NDR throughput.
+  - PDR - discovery of Partial Drop Rate, with specified non-zero packet loss
+    currently set to 0.5%; followed by one-way packet latency measurements at
+    100% of discovered PDR throughput.
+
+- Throughput verification - verification of packet forwarding rate against
+  previously discovered throughput rate. These tests are currently done against
+  0.9 of reference NDR, with reference rates updated periodically.
+
+CSIT |release| includes following performance test suites, listed per NIC type:
+
+- 2port10GE X520-DA2 Intel
+
+  - **L2XC** - L2 Cross-Connect switched-forwarding of untagged, dot1q, dot1ad
+    VLAN tagged Ethernet frames.
+  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames
+    with MAC learning; disabled MAC learning i.e. static MAC tests to be added.
+  - **IPv4** - IPv4 routed-forwarding.
+  - **IPv6** - IPv6 routed-forwarding.
+  - **IPv4 Scale** - IPv4 routed-forwarding with 20k, 200k and 2M FIB entries.
+  - **IPv6 Scale** - IPv6 routed-forwarding with 20k, 200k and 2M FIB entries.
+  - **VMs with vhost-user** - virtual topologies with 1 VM and service chains
+    of 2 VMs using vhost-user interfaces, with VPP forwarding modes incl. L2
+    Cross-Connect, L2 Bridge-Domain, VXLAN with L2BD, IPv4 routed-forwarding.
+  - **COP** - IPv4 and IPv6 routed-forwarding with COP address security.
+  - **iACL** - IPv4 and IPv6 routed-forwarding with iACL address security.
+  - **LISP** - LISP overlay tunneling for IPv4-over-IPv4, IPv6-over-IPv4,
+    IPv6-over-IPv6, IPv4-over-IPv6 in IPv4 and IPv6 routed-forwarding modes.
+  - **VXLAN** - VXLAN overlay tunnelling integration with L2XC and L2BD.
+  - **QoS Policer** - ingress packet rate measuring, marking and limiting
+    (IPv4).
+
+- 2port40GE XL710 Intel
+
+  - **L2XC** - L2 Cross-Connect switched-forwarding of untagged Ethernet frames.
+  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames
+    with MAC learning.
+  - **IPv4** - IPv4 routed-forwarding.
+  - **IPv6** - IPv6 routed-forwarding.
+  - **VMs with vhost-user** - virtual topologies with 1 VM and service chains
+    of 2 VMs using vhost-user interfaces, with VPP forwarding modes incl. L2
+    Cross-Connect, L2 Bridge-Domain, VXLAN with L2BD, IPv4 routed-forwarding.
+  - **IPSec** - IPSec encryption with AES-GCM, CBC-SHA1 ciphers, in combination
+    with IPv4 routed-forwarding.
+  - **IPSec+LISP** - IPSec encryption with CBC-SHA1 ciphers, in combination
+    with LISP-GPE overlay tunneling for IPv4-over-IPv4.
+
+- 2port10GE X710 Intel
+
+  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames
+    with MAC learning.
+  - **VMs with vhost-user** - virtual topologies with 1 VM using vhost-user
+    interfaces, with VPP forwarding modes incl. L2 Bridge-Domain.
+
+- 2port10GE VIC1227 Cisco
+
+  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames
+    with MAC learning.
+
+- 2port40GE VIC1385 Cisco
+
+  - **L2BD** - L2 Bridge-Domain switched-forwarding of untagged Ethernet frames
+     with MAC learning.
+
+Execution of performance tests takes time, especially the throughput discovery
+tests. Due to limited HW testbed resources available within FD.io labs hosted
+by Linux Foundation, the number of tests for NICs other than X520 (a.k.a.
+Niantic) has been limited to few baseline tests. Over time we expect the HW
+testbed resources to grow, and will be adding complete set of performance
+tests for all models of hardware to be executed regularly and(or)
+continuously.
+
+Performance Tests Naming
+------------------------
+
+CSIT |release| follows a common structured naming convention for all
+performance and system functional tests, introduced in CSIT rls1701.
+
+The naming should be intuitive for majority of the tests. Complete
+description of CSIT test naming convention is provided on `CSIT test naming wiki
+<https://wiki.fd.io/view/CSIT/csit-test-naming>`_.
+
+Here few illustrative examples of the new naming usage for performance test
+suites:
+
+#. **Physical port to physical port - a.k.a. NIC-to-NIC, Phy-to-Phy, P2P**
+
+    - *PortNICConfig-WireEncapsulation-PacketForwardingFunction-
+      PacketProcessingFunction1-...-PacketProcessingFunctionN-TestType*
+    - *10ge2p1x520-dot1q-l2bdbasemaclrn-ndrdisc.robot* => 2 ports of 10GE on
+      Intel x520 NIC, dot1q tagged Ethernet, L2 bridge-domain baseline switching
+      with MAC learning, NDR throughput discovery.
+    - *10ge2p1x520-ethip4vxlan-l2bdbasemaclrn-ndrchk.robot* => 2 ports of 10GE
+      on Intel x520 NIC, IPv4 VXLAN Ethernet, L2 bridge-domain baseline
+      switching with MAC learning, NDR throughput discovery.
+    - *10ge2p1x520-ethip4-ip4base-ndrdisc.robot* => 2 ports of 10GE on Intel
+      x520 NIC, IPv4 baseline routed forwarding, NDR throughput discovery.
+    - *10ge2p1x520-ethip6-ip6scale200k-ndrdisc.robot* => 2 ports of 10GE on
+      Intel x520 NIC, IPv6 scaled up routed forwarding, NDR throughput
+      discovery.
+
+#. **Physical port to VM (or VM chain) to physical port - a.k.a. NIC2VM2NIC,
+   P2V2P, NIC2VMchain2NIC, P2V2V2P**
+
+    - *PortNICConfig-WireEncapsulation-PacketForwardingFunction-
+      PacketProcessingFunction1-...-PacketProcessingFunctionN-VirtEncapsulation-
+      VirtPortConfig-VMconfig-TestType*
+    - *10ge2p1x520-dot1q-l2bdbasemaclrn-eth-2vhost-1vm-ndrdisc.robot* => 2 ports
+      of 10GE on Intel x520 NIC, dot1q tagged Ethernet, L2 bridge-domain
+      switching to/from two vhost interfaces and one VM, NDR throughput
+      discovery.
+    - *10ge2p1x520-ethip4vxlan-l2bdbasemaclrn-eth-2vhost-1vm-ndrdisc.robot* => 2
+      ports of 10GE on Intel x520 NIC, IPv4 VXLAN Ethernet, L2 bridge-domain
+      switching to/from two vhost interfaces and one VM, NDR throughput
+      discovery.
+    - *10ge2p1x520-ethip4vxlan-l2bdbasemaclrn-eth-4vhost-2vm-ndrdisc.robot* => 2
+      ports of 10GE on Intel x520 NIC, IPv4 VXLAN Ethernet, L2 bridge-domain
+      switching to/from four vhost interfaces and two VMs, NDR throughput
+      discovery.
+
+Methodology: Multi-Thread and Multi-Core
+----------------------------------------
+
+**HyperThreading** - CSIT |release| performance tests are executed with SUT
+servers' Intel XEON CPUs configured in HyperThreading Disabled mode (BIOS
+settings). This is the simplest configuration used to establish baseline
+single-thread single-core SW packet processing and forwarding performance.
+Subsequent releases of CSIT will add performance tests with Intel
+HyperThreading Enabled (requires BIOS settings change and hard reboot).
+
+**Multi-core Test** - CSIT |release| multi-core tests are executed in the
+following VPP thread and core configurations:
+
+#. 1t1c - 1 VPP worker thread on 1 CPU physical core.
+#. 2t2c - 2 VPP worker threads on 2 CPU physical cores.
+
+Note that in quite a few test cases running VPP on 2 physical cores hits
+the tested NIC I/O bandwidth or packets-per-second limit.
+
+Methodology: Packet Throughput
+------------------------------
+
+Following values are measured and reported for packet throughput tests:
+
+- NDR binary search per RFC2544:
+
+  - Packet rate: "RATE: <aggregate packet rate in packets-per-second> pps
+    (2x <per direction packets-per-second>)"
+  - Aggregate bandwidth: "BANDWIDTH: <aggregate bandwidth in Gigabits per
+    second> Gbps (untagged)"
+
+- PDR binary search per RFC2544:
+
+  - Packet rate: "RATE: <aggregate packet rate in packets-per-second> pps (2x
+    <per direction packets-per-second>)"
+  - Aggregate bandwidth: "BANDWIDTH: <aggregate bandwidth in Gigabits per
+    second> Gbps (untagged)"
+  - Packet loss tolerance: "LOSS_ACCEPTANCE <accepted percentage of packets
+    lost at PDR rate>""
+
+- NDR and PDR are measured for the following L2 frame sizes:
+
+  - IPv4: 64B, IMIX_v4_1 (28x64B,16x570B,4x1518B), 1518B, 9000B.
+  - IPv6: 78B, 1518B, 9000B.
+
+
+Methodology: Packet Latency
+---------------------------
+
+TRex Traffic Generator (TG) is used for measuring latency of VPP DUTs. Reported
+latency values are measured using following methodology:
+
+- Latency tests are performed at 10%, 50% of discovered NDR rate (non drop rate)
+  for each NDR throughput test and packet size (except IMIX).
+- TG sends dedicated latency streams, one per direction, each at the rate of
+  10kpps at the prescribed packet size; these are sent in addition to the main
+  load streams.
+- TG reports min/avg/max latency values per stream direction, hence two sets
+  of latency values are reported per test case; future release of TRex is
+  expected to report latency percentiles.
+- Reported latency values are aggregate across two SUTs due to three node
+  topology used for all performance tests; for per SUT latency, reported value
+  should be divided by two.
+- 1usec is the measurement accuracy advertised by TRex TG for the setup used in
+  FD.io labs used by CSIT project.
+- TRex setup introduces an always-on error of about 2*2usec per latency flow -
+  additonal Tx/Rx interface latency induced by TRex SW writing and reading
+  packet timestamps on CPU cores without HW acceleration on NICs closer to the
+  interface line.
+
+
+Methodology: KVM VM vhost
+-------------------------
+
+CSIT |release| introduced environment configuration changes to KVM Qemu vhost-
+user tests in order to more representatively measure VPP-17.04 performance in
+configurations with vhost-user interfaces and VMs.
+
+Current setup of CSIT FD.io performance lab is using tuned settings for more
+optimal performance of KVM Qemu:
+
+- Qemu virtio queue size has been increased from default value of 256 to 1024
+  descriptors.
+- Adjusted Linux kernel CFS scheduler settings, as detailed on this CSIT wiki
+  page: https://wiki.fd.io/view/CSIT/csit-perf-env-tuning-ubuntu1604.
+
+Adjusted Linux kernel CFS settings make the NDR and PDR throughput performance
+of VPP+VM system less sensitive to other Linux OS system tasks by reducing
+their interference on CPU cores that are designated for critical software
+tasks under test, namely VPP worker threads in host and Testpmd threads in
+guest dealing with data plan.