diff options
author | Vratko Polak <vrpolak@cisco.com> | 2020-11-19 15:14:34 +0100 |
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committer | Vratko Polak <vrpolak@cisco.com> | 2020-11-19 15:23:17 +0000 |
commit | 39af295749ad197f17ee35ba071e4fbc5c4eaaf8 (patch) | |
tree | 780e339588ada7a8d7d6a4de7a27b0070c13229a /docs/report/introduction | |
parent | 9408b1ff148e8480b6e3308d7b8e0e5b2938b70f (diff) |
Methodology: Edit nat44 test spec doc
- Missing profile specifics and transaction counters.
Change-Id: I6f7378e5fe9d639599c38545b0503354a8a65198
Signed-off-by: Vratko Polak <vrpolak@cisco.com>
Diffstat (limited to 'docs/report/introduction')
-rw-r--r-- | docs/report/introduction/methodology_nat44.rst | 130 |
1 files changed, 97 insertions, 33 deletions
diff --git a/docs/report/introduction/methodology_nat44.rst b/docs/report/introduction/methodology_nat44.rst index 5dc558f029..198837d17d 100644 --- a/docs/report/introduction/methodology_nat44.rst +++ b/docs/report/introduction/methodology_nat44.rst @@ -12,14 +12,17 @@ public range. Following quantities are used to describe inside to outside IP address and port bindings scenarios: -- inside-addresses, ports-per-inside-address, number of inside source - addresses (representing inside hosts) and number of TCP/UDP source +- Inside-addresses, number of inside source addresses + (representing inside hosts). +- Ports-per-inside-address, number of TCP/UDP source ports per inside source address. -- outside-addresses, number of outside (public) source addresses - allocated to NAT44. The maximal number of ports-per-outside-address - usable for NAT is 64 512 (in non-reserved port range 1024-65535, - :rfc:`4787`). -- sharing-ratio, equal to inside-addresses / outside-addresses. +- Outside-addresses, number of outside (public) source addresses + allocated to NAT44. +- Ports-per-outside-address, number of TCP/UDP source + ports per outside source address. The maximal number of + ports-per-outside-address usable for NAT is 64 512 + (in non-reserved port range 1024-65535, :rfc:`4787`). +- Sharing-ratio, equal to inside-addresses / outside-addresses. CSIT NAT44 tests are designed to take into account the maximum number of ports (sessions) required per inside host (inside-address) and at the @@ -43,15 +46,7 @@ Initial CSIT NAT44 tests, including associated TG/TRex traffic profiles, are based on ports-per-inside-address set to 63 and the sharing ratio of 1024. This approach is currently used for all NAT44 tests including NAT44det (NAT44 deterministic used for Carrier Grade NAT applications) -and NAT44ed. - -.. - .. TODO:: - - Note that in the latter case, due to overloading of (ouside-address, - outside-port) tuple for different endpoint destinations the actual - sharing ratio is likely to different, as it will depend on the - destination addresses used by NAT'ed flows. +and NAT44ed (Endpoint Dependent). Private address ranges to be used in tests: @@ -70,13 +65,14 @@ NAT44 Session Scale NAT44 session scale tested is govern by the following logic: -- Number of inside addresses/hosts H[i] = (H[i-1] x 2^2) with H(0)=1 024, i = 1,2,3, ... +- Number of inside-addresses(hosts) H[i] = (H[i-1] x 2^2) with H(0)=1 024, + i = 1,2,3, ... - - H[i] = 1 024, 4 096, 16 384, 65 536, 262 144, 1 048 576, ... + - H[i] = 1 024, 4 096, 16 384, 65 536, 262 144, ... -- Number of sessions S[i](ports-per-host) = H[i] * ports-per-inside-address +- Number of sessions S[i] = H[i] * ports-per-inside-address - - ports-per-host = 63 + - ports-per-inside-address = 63 +---+---------+------------+ | i | hosts | sessions | @@ -101,6 +97,11 @@ ip4, ip6 and l2, sending UDP packets in both directions inside-to-outside and outside-to-inside. See :ref:`data_plane_throughput` for more detail. +The inside-to-outside traffic uses single destination address (20.0.0.0) +and port (1024). +The inside-to-outside traffic covers whole inside address and port range, +the outside-to-inside traffic covers whole outside address and port range. + NAT44det translation entries are created during the ramp-up phase preceding the throughput test, followed by verification that all entries are present, before proceeding to the throughput test. This ensures @@ -117,30 +118,55 @@ NAT44det scenario tested: 16515072. - [mrr|ndrpdr|soak], MRR, NDRPDR or SOAK test. +.. + TODO: The -s{S} part is redundant, + we can save space by removing it. + TODO: Make traffic profile names resemble suite names more closely. + NAT44 Endpoint-Dependent ^^^^^^^^^^^^^^^^^^^^^^^^ -NAT44ed is benchmarked using following methodologies: - -- Uni-directional throughput using *stateless* traffic profile. +.. + TODO: Is it possible to test a NAT44ed scenario where the outside source + address and port is limited to just one value? + In theory, as long as every inside source address&port traffic + uses a different destination address&port, there will be no conflicts, + and we could use bidirectional stateless profiles. + Possibly, VPP requires some amount of outside source address&port + to remain unused for security reasons. But we can try to see what happens. + +In order to excercise NAT44ed ability to translate based on both +source and destination address and port, the inside-to-outside traffic +varies also destination address and port. Destination port is the same +as source port, destination address has the same offset as the source address, +but applied to different subnet (starting with 20.0.0.0). + +As the mapping is not deterministic (for security reasons), +we cannot easily use stateless bidirectional traffic profiles. +Outside address and port range is fully covered, +but we do not know which outside-to-inside source address and port to use +to hit an open session of a particular outside address and port. + +Therefore, NAT44ed is benchmarked using following methodologies: + +- Unidirectional throughput using *stateless* traffic profile. - Connections-per-second using *stateful* traffic profile. -- Bi-directional throughput using *stateful* traffic profile. +- Bidirectional PPS (see below) using *stateful* traffic profile. -Uni-directional NAT44ed throughput tests are using TRex STL (Stateless) +Unidirectional NAT44ed throughput tests are using TRex STL (Stateless) APIs and traffic profiles, but with packets sent only in -inside-to-outside direction. Due to indeterministic bindings of outside -to inside (src_addr,src_port) that are created dynamically at flow start -bidirectional testing is not possible with stateless traffic profiles. -See :ref:`data_plane_throughput` for more detail. - -Similarly to NAT44det, NAT44ed uni-directional throughput tests include +inside-to-outside direction. +Similarly to NAT44det, NAT44ed unidirectional throughput tests include a ramp-up phase to establish and verify the presence of required NAT44ed -binding entries. NAT44ed CPS (connections-per-second) and throughput / -PPS stateful tests do not have a ramp-up phase. +binding entries. Stateful NAT44ed tests are using TRex ASTF (Advanced Stateful) APIs and traffic profiles, with packets sent in both directions. Tests are run with both UDP and TCP/IP sessions. +As both NAT44ed CPS (connections-per-second) and PPS (packets-per-second) +stateful tests measure (also) session opening performance, +they use state reset instead of ramp-up trial. +That is also the reason why PPS tests are not called throughput tests. Associated CSIT test cases use the following naming scheme to indicate NAT44DET case tested: @@ -164,3 +190,41 @@ NAT44DET case tested: - [cps|pps], connections-per-second session establishment rate or packets-per-second throughput rate. - [mrr|ndrpdr], bidirectional stateful tests MRR, NDRPDR. + +Stateful traffic profiles +^^^^^^^^^^^^^^^^^^^^^^^^^ + +WiP. + +UDP CPS +~~~~~~~ + +TCP CPS +~~~~~~~ + +UDP PPS +~~~~~~~ + +TCP PPS +~~~~~~~ + +Ip4base tests +^^^^^^^^^^^^^ + +Contrary to stateless traffic profiles, we do not have a simple limit +that would guarantee TRex is able to send traffic at specified load. +For that reason, we have added tests where "nat44ed" is replaced by "ip4base". +Instead of NAT44ed processing, the tests set minimalistic IPv4 routes, +so that packets are forwarded in both inside-to-outside and outside-to-inside +directions. + +The packets arrive to server end of TRex with different source address&port +than in NAT44ed tests (no translation to outside values is done with ip4base), +but those are not specified in the stateful traffic profiles. +The server end uses the received address&port as destination +for outside-to-inside traffic. Therefore the same stateful traffic profile +works for both NAT44ed and ip4base test (of the same scale). + +The NAT44ed results are displayed together with corresponding ip4base results. +If they are similar, TRex is probably the bottleneck. +If NAT44ed result is visibly smaller, it describes the real VPP performance. |