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author | Maciek Konstantynowicz <mkonstan@cisco.com> | 2019-02-05 21:22:17 +0000 |
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committer | Maciek Konstantynowicz <mkonstan@cisco.com> | 2019-02-06 14:04:24 +0000 |
commit | 1eb5821ae2975d69d1c655049db02348bb79a5ca (patch) | |
tree | a0d4ad197d6e3a0d65efa801c0a9a81d91d7af6f /docs/report/introduction/methodology_nfv_service_density.rst | |
parent | 124101d22151239b0411a73ae4d2bf8d70970937 (diff) |
Report: methodology section, added nfv service density.
Change-Id: Ia5f3a8befd5a9cc6c4b644ddd785e21f11b1c156
Signed-off-by: Maciek Konstantynowicz <mkonstan@cisco.com>
Diffstat (limited to 'docs/report/introduction/methodology_nfv_service_density.rst')
-rw-r--r-- | docs/report/introduction/methodology_nfv_service_density.rst | 106 |
1 files changed, 106 insertions, 0 deletions
diff --git a/docs/report/introduction/methodology_nfv_service_density.rst b/docs/report/introduction/methodology_nfv_service_density.rst new file mode 100644 index 0000000000..2946ba2777 --- /dev/null +++ b/docs/report/introduction/methodology_nfv_service_density.rst @@ -0,0 +1,106 @@ +NFV Service Density +------------------- + +Network Function Virtualization (NFV) service density tests focus on +measuring total per server throughput at varied NFV service “packing” +densities with vswitch providing host dataplane. The goal is to compare +and contrast performance of a shared vswitch for different network +topologies and virtualization technologies, and their impact on vswitch +performance and efficiency in a range of NFV service configurations. + +Each NFV service instance consists of a set of Network Functions (NFs), +running in VMs (VNFs) or in Containers (CNFs), that are connected into a +virtual network topology using VPP vswitch running in Linux user-mode. +Multiple service instances share the vswitch that in turn provides per +service chain forwarding context(s). In order to provide a most complete +picture, each network topology and service configuration is tested in +different service density setups by varying two parameters: + +- Number of service instances (e.g. 1,2,4..10). +- Number of NFs per service instance (e.g. 1,2,4..10). + +The initial implementation of NFV service density tests in +|csit-release| is using two NF applications: + +- VNF: DPDK L3fwd running in KVM VM, configured with /8 IPv4 prefix + routing. L3fwd got chosen as a lightweight fast IPv4 VNF application, + and follows CSIT approach of using DPDK sample applications in VMs for + performance testing. +- CNF: VPP running in Docker Container, configured with /24 IPv4 prefix + routing. VPP got chosen as a fast IPv4 NF application that supports + required memif interface (L3fwd does not). This is similar to all + other Container tests in CSIT that use VPP. + +Tests are designed such that in all tested cases VPP vswitch is the most +stressed application, as for each flow vswitch is processing each packet +multiple times, whereas VNFs and CNFs process each packets only once. To +that end, all VNFs and CNFs are allocated enough resources to not become +a bottleneck. + +Service Configurations +~~~~~~~~~~~~~~~~~~~~~~ + +Following NFV network topologies and configurations are tested: + +- VNF Service Chains (VSC) with L2 vswitch + + - *Network Topology*: Sets of VNFs dual-homed to VPP vswitch over + virtio-vhost links. Each set belongs to separate service instance. + - *Network Configuration*: VPP L2 bridge-domain contexts form logical + service chains of VNF sets and connect each chain to physical + interfaces. + +- CNF Service Chains (CSC) with L2 vswitch + + - *Network Topology*: Sets of CNFs dual-homed to VPP vswitch over + memif links. Each set belongs to separate service instance. + - *Network Configuration*: VPP L2 bridge-domain contexts form logical + service chains of CNF sets and connect each chain to physical + interfaces. + +- CNF Service Pipelines (CSP) with L2 vswitch + + - *Network Topology*: Sets of CNFs connected into pipelines over a + series of memif links, with edge CNFs single-homed to VPP vswitch + over memif links. Each set belongs to separate service instance. + - *Network Configuration*: VPP L2 bridge-domain contexts connect each + CNF pipeline to physical interfaces. + +Thread-to-Core Mapping +~~~~~~~~~~~~~~~~~~~~~~ + +CSIT defines specific ratios for mapping software threads of vswitch and +VNFs/CNFs to physical cores, with separate ratios defined for main +control threads and data-plane threads. + +In |csit-release| NFV service density tests run on Intel Xeon testbeds +with Intel Hyper-Threading enabled, so each physical core is associated +with a pair of sibling logical cores corresponding to the hyper-threads. + +|csit-release| executes tests with the following software thread to +physical core mapping ratios: + +- vSwitch + + - Data-plane on single core + + - (data:core) = (1:1) => 2dt1c - 2 Data-plane Threads on 1 Core. + - (main:core) = (1:1) => 1mt1c - 1 Main Thread on 1 Core. + + - Data-plane on two cores + + - (data:core) = (1:2) => 4dt2c - 4 Data-plane Threads on 2 Cores. + - (main:core) = (1:1) => 1mt1c - 1 Main Thread on 1 Core. + +- VNF and CNF + + - Data-plane on single core + + - (data:core) = (1:1) => 2dt1c - 2 Data-plane Threads on 1 Core per + NF. + - (main:core) = (2:1) => 2mt1c - 2 Main Threads on 1 Core, 1 Thread + per NF, core shared between two NFs. + +Maximum tested service densities are limited by a number of physical +cores per NUMA. |csit-release| allocates cores within NUMA0. Support for +multi NUMA tests is to be added in future release.
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