General Notes ============= All CSIT test results listed in this report are sourced and auto-generated from :file:`output.xml` :abbr:`RF (Robot Framework)` files resulting from :abbr:`LF (Linux Foundation)` FD.io Jenkins jobs execution against |vpp-release| release artifacts. References are provided to the original :abbr:`LF (Linux Foundation)` FD.io Jenkins job results. However, as :abbr:`LF (Linux Foundation)` FD.io Jenkins infrastructure does not automatically archive all jobs (history record is provided for the last 30 days or 40 jobs only), additional references are provided to the :abbr:`RF (Robot Framework)` result files that got archived in FD.io nexus online storage system. FD.io CSIT project currently covers multiple FD.io system and sub-system testing areas and this is reflected in this report, where each testing area is listed separately, as follows: #. **VPP Performance Tests** - VPP performance tests are executed in physical FD.io testbeds, focusing on VPP network data plane performance at this stage, both for Phy-to-Phy (NIC-to-NIC) and Phy-to-VM-to-Phy (NIC-to-VM-to-NIC) forwarding topologies. Tested across a range of NICs, 10GE and 40GE interfaces, range of multi-thread and multi-core configurations. VPP application runs in host user-mode. TRex is used as a traffic generator. #. **Container memif connections** - VPP memif virtual interface (shared memory interface) tests to interconnect VPP instances. VPP vswitch instance runs in bare-metal user-mode handling Intel x520 NIC 10GbE interfaces and connecting over memif (Master side) virtual interfaces to more instances of VPP running in LXC or in Docker Containers, both with memif virtual interfaces (Slave side). Tested across a range of NICs, 10GE and 40GE interfaces, range of multi-thread and multi-core configurations. VPP application runs in host user-mode. TRex is used as a traffic generator. #. **Container Orchestrated Performance Tests** - CSIT |release| introduced new tests of Container topologies connected over the memif virtual interface (shared memory interface). For these tests VPP vswitch instance runs in a Docker Container handling Intel x520 NIC 10GbE interfaces and connecting over memif (Master side) virtual interfaces to more instances of VPP running in Docker Containers with memif virtual interfaces (Slave side). Tested across a range of multi-thread and multi-core configurations. VPP application runs in host user-mode. TRex is used as a traffic generator. #. **DPDK Performance Tests** - VPP is using DPDK code to control and drive the NICs and physical interfaces. Testpmd tests are used as a baseline to profile the DPDK sub-system of VPP. DPDK performance tests executed in physical FD.io testbeds, focusing on Testpmd/L3FWD data plane performance for Phy-to-Phy (NIC-to-NIC). Tests cover a range of NICs, 10GE and 40GE interfaces, range of multi-thread and multi-core configurations. Testpmd/L3FWD application runs in host user-mode. TRex is used as a traffic generator. #. **VPP Functional Tests** - VPP functional tests are executed in virtual FD.io testbeds focusing on VPP packet processing functionality, including network data plane and in -line control plane. Tests cover vNIC-to-vNIC vNIC-to-VM-to-vNIC forwarding topologies. Scapy is used as a traffic generator. #. **Honeycomb Functional Tests** - Honeycomb functional tests are executed in virtual FD.io testbeds, focusing on Honeycomb management and programming functionality of VPP. Tests cover a range of CRUD operations executed against VPP. #. **Honeycomb Performance Tests** - Honeycomb performance tests are executed in physical FD.io testbeds, focusing on the performance of Honeycomb management and programming functionality of VPP. Tests cover a range of CRUD operations executed against VPP. #. **NSH_SFC Functional Tests** - NSH_SFC functional tests are executed in virtual FD.io testbeds focusing on NSH_SFC of VPP. Tests cover a range of CRUD operations executed against VPP. In addition to above, CSIT |release| report does also include VPP unit test results. VPP unit tests are developed within the FD.io VPP project and as they complement CSIT system functional tests, they are provided mainly as a reference and to provide a more complete view of automated testing executed against |vpp-release|. FD.io CSIT system is developed using two main coding platforms :abbr:`RF (Robot Framework)` and Python. CSIT |release| source code for the executed test suites is available in CSIT branch |release| in the directory :file:`./tests/`. A local copy of CSIT source code can be obtained by cloning CSIT git repository - :command:`git clone https://gerrit.fd.io/r/csit`. The CSIT testing virtual environment can be run on a local computer workstation (laptop, server) using Vagrant by following the instructions in `CSIT tutorials `_.