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-rw-r--r--docs/release/release-notes.rst3
-rw-r--r--docs/results/fuel-os-nosdn-kvm-ha.rst38
-rw-r--r--docs/results/fuel-os-odl_l3-nofeature-ha.rst38
-rw-r--r--docs/results/joid-os-onos-sfc-ha.rst36
-rw-r--r--docs/results/os-nosdn-kvm-ha.rst (renamed from docs/results/apex-os-nosdn-nofeature-ha.rst)53
-rw-r--r--docs/results/os-nosdn-nofeature-ha.rst492
-rw-r--r--docs/results/os-nosdn-nofeature-noha.rst259
-rw-r--r--docs/results/os-odl_l2-bgpvpn-ha.rst53
-rw-r--r--docs/results/os-odl_l2-nofeature-ha.rst (renamed from docs/results/fuel-os-odl_l2-nofeature-ha.rst)15
-rw-r--r--docs/results/os-onos-nofeature-ha.rst257
-rw-r--r--docs/results/os-onos-sfc-ha.rst274
-rw-r--r--docs/results/overview.rst30
-rw-r--r--docs/results/results.rst54
-rw-r--r--docs/userguide/07-installation.rst143
-rw-r--r--samples/computecapacity.yaml10
-rw-r--r--tests/ci/report_config.yaml20
-rwxr-xr-xtests/ci/yardstick-verify23
-rw-r--r--tests/opnfv/test_cases/opnfv_yardstick_tc055.yaml10
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-fdio-noha_daily.yaml30
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-kvm-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-kvm-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-kvm_ovs-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-lxd-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-lxd-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-ovs-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-nosdn-ovs-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-ocl-nofeature-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-ocl-nofeature-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l2-fdio-noha_daily.yaml30
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l2-moon-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-onos-nofeature-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-onos-nofeature-noha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-onos-sfc-ha_daily.yaml2
-rw-r--r--tests/opnfv/test_suites/opnfv_os-onos-sfc-noha_daily.yaml2
-rw-r--r--tests/unit/benchmark/scenarios/compute/test_computecapacity.py2
-rw-r--r--yardstick/benchmark/scenarios/compute/computecapacity.bash13
46 files changed, 1607 insertions, 324 deletions
diff --git a/docs/release/release-notes.rst b/docs/release/release-notes.rst
index df20e4375..f1b8a8de1 100644
--- a/docs/release/release-notes.rst
+++ b/docs/release/release-notes.rst
@@ -502,7 +502,8 @@ Known Issues/Faults
- IPv6 support
- Boot up VM failed in joid-os-nosdn-lxd-ha and joid-os-nosdn-lxd-noha scenarios
- Yardstick CI job timeout in fuel-os-onos-nofeature-ha scenario
-
+ - SSH timeout in apex-os-onos-sfc-ha, apex-os-onos-nofeature-ha and apex-os-odl_l3-nofeature-ha scenarios
+ - Scp /home/stack/overcloudrc failed in apex-os-nosdn-ovs-noha and apex-os-odl_l2-sfc-noha scenarios
.. note:: The faults not related to *Yardstick* framework, addressing scenarios
which were not fully verified, are listed in the OPNFV installer's release
diff --git a/docs/results/fuel-os-nosdn-kvm-ha.rst b/docs/results/fuel-os-nosdn-kvm-ha.rst
deleted file mode 100644
index 217bab7c0..000000000
--- a/docs/results/fuel-os-nosdn-kvm-ha.rst
+++ /dev/null
@@ -1,38 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International
-.. License.
-.. http://creativecommons.org/licenses/by/4.0
-
-
-=====================================
-Test Results for fuel-os-nosdn-kvm-ha
-=====================================
-
-.. toctree::
- :maxdepth: 2
-
-
-Details
-=======
-
-.. after this doc is filled, remove all comments and include the scenario in
-.. results.rst by removing the comment on the file name.
-
-
-Overview of test results
-------------------------
-
-.. general on metrics collected, number of iterations
-
-Detailed test results
----------------------
-
-.. info on lab, installer, scenario
-
-Rationale for decisions
------------------------
-.. result analysis, pass/fail
-
-Conclusions and recommendations
--------------------------------
-
-.. did the expected behavior occured?
diff --git a/docs/results/fuel-os-odl_l3-nofeature-ha.rst b/docs/results/fuel-os-odl_l3-nofeature-ha.rst
deleted file mode 100644
index 7c9c377cb..000000000
--- a/docs/results/fuel-os-odl_l3-nofeature-ha.rst
+++ /dev/null
@@ -1,38 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International
-.. License.
-.. http://creativecommons.org/licenses/by/4.0
-
-
-============================================
-Test Results for fuel-os-odl_l3-nofeature-ha
-============================================
-
-.. toctree::
- :maxdepth: 2
-
-
-Details
-=======
-
-.. after this doc is filled, remove all comments and include the scenario in
-.. results.rst by removing the comment on the file name.
-
-
-Overview of test results
-------------------------
-
-.. general on metrics collected, number of iterations
-
-Detailed test results
----------------------
-
-.. info on lab, installer, scenario
-
-Rationale for decisions
------------------------
-.. result analysis, pass/fail
-
-Conclusions and recommendations
--------------------------------
-
-.. did the expected behavior occured?
diff --git a/docs/results/joid-os-onos-sfc-ha.rst b/docs/results/joid-os-onos-sfc-ha.rst
deleted file mode 100644
index 3d80d38ef..000000000
--- a/docs/results/joid-os-onos-sfc-ha.rst
+++ /dev/null
@@ -1,36 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International
-.. License.
-.. http://creativecommons.org/licenses/by/4.0
-
-
-=====================================
-Test Results for joid-os-onos-sfc-ha
-=====================================
-
-.. toctree::
- :maxdepth: 2
-
-
-Details
-=======
-
-.. after this doc is filled, remove all comments and include the scenario in
-.. results.rst by removing the comment on the file name.
-
-
-Overview of test results
-------------------------
-
-.. general on metrics collected, number of iterations
-
-Detailed test results
----------------------
-
-.. info on lab, installer, scenario
-
-Rationale for decisions
------------------------
-.. result analysis, pass/fail
-
-Conclusions and recommendations
--------------------------------
diff --git a/docs/results/apex-os-nosdn-nofeature-ha.rst b/docs/results/os-nosdn-kvm-ha.rst
index faf5e62fb..a8a56f80e 100644
--- a/docs/results/apex-os-nosdn-nofeature-ha.rst
+++ b/docs/results/os-nosdn-kvm-ha.rst
@@ -3,20 +3,19 @@
.. http://creativecommons.org/licenses/by/4.0
-===========================================
-Test Results for apex-os-nosdn-nofeature-ha
-===========================================
+================================
+Test Results for os-nosdn-kvm-ha
+================================
.. toctree::
:maxdepth: 2
-Details
-=======
+fuel
+====
.. _Grafana: http://testresults.opnfv.org/grafana/dashboard/db/yardstick-main
-.. _POD1: https://wiki.opnfv.org/pharos?&#community_test_labs
-
+.. _POD2: https://wiki.opnfv.org/pharos?&#community_test_labs
Overview of test results
------------------------
@@ -26,54 +25,54 @@ is possible to chose which specific scenarios to look at, and then to zoom in
on the details of each run test scenario as well.
All of the test case results below are based on 4 scenario test
-runs, each run on the LF POD1_ between August 25 and 28 in
+runs, each run on the Ericsson POD2_ or LF POD2_ between August 24 and 30 in
2016.
TC002
-----
The round-trip-time (RTT) between 2 VMs on different blades is measured using
-ping. Most test run measurements result on average between 0.74 and 1.08 ms.
-A few runs start with a 0.99 - 1.07 ms RTT spike (This could be because of
-normal ARP handling). One test run has a greater RTT spike of 1.35 ms.
+ping. Most test run measurements result on average between 0.44 and 0.75 ms.
+A few runs start with a 0.65 - 0.68 ms RTT spike (This could be because of
+normal ARP handling). One test run has a greater RTT spike of 1.49 ms.
To be able to draw conclusions more runs should be made. SLA set to 10 ms.
The SLA value is used as a reference, it has not been defined by OPNFV.
TC005
-----
The IO read bandwidth looks similar between different dates, with an
-average between approx. 128 and 136 MB/s. Within each test run the results
-vary, with a minimum 5 MB/s and maximum 446 MB/s on the totality. Most runs
-have a minimum BW of 5 MB/s (one run at 6 MB/s). The maximum BW varies more in
-absolute numbers between the dates, between 416 and 446 MB/s.
+average between approx. 92 and 204 MB/s. Within each test run the results
+vary, with a minimum 2 MB/s and maximum 819 MB/s on the totality. Most runs
+have a minimum BW of 3 MB/s (one run at 2 MB/s). The maximum BW varies more in
+absolute numbers between the dates, between 238 and 819 MB/s.
SLA set to 400 MB/s. The SLA value is used as a reference, it has not been
defined by OPNFV.
TC010
-----
The measurements for memory latency are similar between test dates and result
-in approx. 1.09 ns. The variations within each test run are similar, between
-1.0860 and 1.0880 ns.
+in approx. 2.07 ns. The variations within each test run are similar, between
+1.41 and 3.53 ns.
SLA set to 30 ns. The SLA value is used as a reference, it has not been defined
by OPNFV.
TC011
-----
Packet delay variation between 2 VMs on different blades is measured using
-Iperf3. The reported packet delay variation varies between 0.0025 and 0.0148 ms,
-with an average delay variation between 0.0056 ms and 0.0157 ms.
+Iperf3. The reported packet delay variation varies between 0.0051 and 0.0243 ms,
+with an average delay variation between 0.0081 ms and 0.0195 ms.
TC012
-----
Between test dates, the average measurements for memory bandwidth result in
-approx. 19.70 GB/s. Within each test run the results vary more, with a minimal
-BW of 18.16 GB/s and maximum of 20.13 GB/s on the totality.
+approx. 13.6 GB/s. Within each test run the results vary more, with a minimal
+BW of 6.09 GB/s and maximum of 16.47 GB/s on the totality.
SLA set to 15 GB/s. The SLA value is used as a reference, it has not been
defined by OPNFV.
TC014
-----
-The Unixbench processor test run results vary between scores 3224.4 and 3842.8,
-one result each date. The average score on the total is 3659.5.
+The Unixbench processor test run results vary between scores 2316 and 3619,
+one result each date.
No SLA set.
TC037
@@ -116,6 +115,7 @@ utilization ratio vary between 1% to 2%. The peak of CPU utilization ratio
appears around 7%.
TC069
+-----
Between test dates, the average measurements for memory bandwidth vary between
22.6 and 29.1 GB/s. Within each test run the results vary more, with a minimal
BW of 20.0 GB/s and maximum of 29.5 GB/s on the totality.
@@ -124,6 +124,7 @@ defined by OPNFV.
TC070
+-----
The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
on different blades are measured when increasing the amount of UDP flows sent
between the VMs using pktgen as packet generator tool.
@@ -162,6 +163,7 @@ utilization vary between 225MB to 246MB. The peak of memory utilization appears
around 340MB.
TC071
+-----
The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
on different blades are measured when increasing the amount of UDP flows sent
between the VMs using pktgen as packet generator tool.
@@ -199,6 +201,7 @@ VMs using pktgen as packet generator tool. The average measurements for cache
utilization vary between 205MB to 212MB.
TC072
+-----
The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
on different blades are measured when increasing the amount of UDP flows sent
between the VMs using pktgen as packet generator tool.
@@ -238,8 +241,8 @@ second was average on 600 kpps.
Detailed test results
---------------------
-The scenario was run on LF POD1_ with:
-Apex
+The scenario was run on Ericsson POD2_ and LF POD2_ with:
+Fuel 9.0
OpenStack Mitaka
OpenVirtualSwitch 2.5.90
OpenDayLight Beryllium
diff --git a/docs/results/os-nosdn-nofeature-ha.rst b/docs/results/os-nosdn-nofeature-ha.rst
new file mode 100644
index 000000000..9e52731d5
--- /dev/null
+++ b/docs/results/os-nosdn-nofeature-ha.rst
@@ -0,0 +1,492 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International
+.. License.
+.. http://creativecommons.org/licenses/by/4.0
+
+
+======================================
+Test Results for os-nosdn-nofeature-ha
+======================================
+
+.. toctree::
+ :maxdepth: 2
+
+
+apex
+====
+
+.. _Grafana: http://testresults.opnfv.org/grafana/dashboard/db/yardstick-main
+.. _POD1: https://wiki.opnfv.org/pharos?&#community_test_labs
+
+
+Overview of test results
+------------------------
+
+See Grafana_ for viewing test result metrics for each respective test case. It
+is possible to chose which specific scenarios to look at, and then to zoom in
+on the details of each run test scenario as well.
+
+All of the test case results below are based on 4 scenario test
+runs, each run on the LF POD1_ between August 25 and 28 in
+2016.
+
+TC002
+-----
+The round-trip-time (RTT) between 2 VMs on different blades is measured using
+ping. Most test run measurements result on average between 0.74 and 1.08 ms.
+A few runs start with a 0.99 - 1.07 ms RTT spike (This could be because of
+normal ARP handling). One test run has a greater RTT spike of 1.35 ms.
+To be able to draw conclusions more runs should be made. SLA set to 10 ms.
+The SLA value is used as a reference, it has not been defined by OPNFV.
+
+TC005
+-----
+The IO read bandwidth looks similar between different dates, with an
+average between approx. 128 and 136 MB/s. Within each test run the results
+vary, with a minimum 5 MB/s and maximum 446 MB/s on the totality. Most runs
+have a minimum BW of 5 MB/s (one run at 6 MB/s). The maximum BW varies more in
+absolute numbers between the dates, between 416 and 446 MB/s.
+SLA set to 400 MB/s. The SLA value is used as a reference, it has not been
+defined by OPNFV.
+
+TC010
+-----
+The measurements for memory latency are similar between test dates and result
+in approx. 1.09 ns. The variations within each test run are similar, between
+1.0860 and 1.0880 ns.
+SLA set to 30 ns. The SLA value is used as a reference, it has not been defined
+by OPNFV.
+
+TC011
+-----
+Packet delay variation between 2 VMs on different blades is measured using
+Iperf3. The reported packet delay variation varies between 0.0025 and 0.0148 ms,
+with an average delay variation between 0.0056 ms and 0.0157 ms.
+
+TC012
+-----
+Between test dates, the average measurements for memory bandwidth result in
+approx. 19.70 GB/s. Within each test run the results vary more, with a minimal
+BW of 18.16 GB/s and maximum of 20.13 GB/s on the totality.
+SLA set to 15 GB/s. The SLA value is used as a reference, it has not been
+defined by OPNFV.
+
+TC014
+-----
+The Unixbench processor test run results vary between scores 3224.4 and 3842.8,
+one result each date. The average score on the total is 3659.5.
+No SLA set.
+
+TC037
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs at
+approx. 15 ms. Some test runs show an increase with many flows, in the range
+towards 16 to 17 ms. One exception standing out is Feb. 15 where the average
+RTT is stable at approx. 13 ms. The PPS results are not as consistent as the
+RTT results.
+In some test runs when running with less than approx. 10000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. Around 20 percent decrease in the worst
+case. For the other test runs there is however no significant change to the PPS
+throughput when the number of flows are increased. In some test runs the PPS
+is also greater with 1000000 flows compared to other test runs where the PPS
+result is less with only 2 flows.
+
+The average PPS throughput in the different runs varies between 414000 and
+452000 PPS. The total amount of packets in each test run is approx. 7500000 to
+8200000 packets. One test run Feb. 15 sticks out with a PPS average of
+558000 and approx. 1100000 packets in total (same as the on mentioned earlier
+for RTT results).
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally range between 100 and 1000 per test run,
+but there are spikes in the range of 10000 lost packets as well, and even
+more in a rare cases.
+
+CPU utilization statistics are collected during UDP flows sent between the VMs
+using pktgen as packet generator tool. The average measurements for CPU
+utilization ratio vary between 1% to 2%. The peak of CPU utilization ratio
+appears around 7%.
+
+TC069
+-----
+Between test dates, the average measurements for memory bandwidth vary between
+22.6 and 29.1 GB/s. Within each test run the results vary more, with a minimal
+BW of 20.0 GB/s and maximum of 29.5 GB/s on the totality.
+SLA set to 6 GB/s. The SLA value is used as a reference, it has not been
+defined by OPNFV.
+
+TC070
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs at
+approx. 15 ms. Some test runs show an increase with many flows, in the range
+towards 16 to 17 ms. One exception standing out is Feb. 15 where the average
+RTT is stable at approx. 13 ms. The PPS results are not as consistent as the
+RTT results.
+In some test runs when running with less than approx. 10000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. Around 20 percent decrease in the worst
+case. For the other test runs there is however no significant change to the PPS
+throughput when the number of flows are increased. In some test runs the PPS
+is also greater with 1000000 flows compared to other test runs where the PPS
+result is less with only 2 flows.
+
+The average PPS throughput in the different runs varies between 414000 and
+452000 PPS. The total amount of packets in each test run is approx. 7500000 to
+8200000 packets. One test run Feb. 15 sticks out with a PPS average of
+558000 and approx. 1100000 packets in total (same as the on mentioned earlier
+for RTT results).
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally range between 100 and 1000 per test run,
+but there are spikes in the range of 10000 lost packets as well, and even
+more in a rare cases.
+
+Memory utilization statistics are collected during UDP flows sent between the
+VMs using pktgen as packet generator tool. The average measurements for memory
+utilization vary between 225MB to 246MB. The peak of memory utilization appears
+around 340MB.
+
+TC071
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs at
+approx. 15 ms. Some test runs show an increase with many flows, in the range
+towards 16 to 17 ms. One exception standing out is Feb. 15 where the average
+RTT is stable at approx. 13 ms. The PPS results are not as consistent as the
+RTT results.
+In some test runs when running with less than approx. 10000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. Around 20 percent decrease in the worst
+case. For the other test runs there is however no significant change to the PPS
+throughput when the number of flows are increased. In some test runs the PPS
+is also greater with 1000000 flows compared to other test runs where the PPS
+result is less with only 2 flows.
+
+The average PPS throughput in the different runs varies between 414000 and
+452000 PPS. The total amount of packets in each test run is approx. 7500000 to
+8200000 packets. One test run Feb. 15 sticks out with a PPS average of
+558000 and approx. 1100000 packets in total (same as the on mentioned earlier
+for RTT results).
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally range between 100 and 1000 per test run,
+but there are spikes in the range of 10000 lost packets as well, and even
+more in a rare cases.
+
+Cache utilization statistics are collected during UDP flows sent between the
+VMs using pktgen as packet generator tool. The average measurements for cache
+utilization vary between 205MB to 212MB.
+
+TC072
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs at
+approx. 15 ms. Some test runs show an increase with many flows, in the range
+towards 16 to 17 ms. One exception standing out is Feb. 15 where the average
+RTT is stable at approx. 13 ms. The PPS results are not as consistent as the
+RTT results.
+In some test runs when running with less than approx. 10000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. Around 20 percent decrease in the worst
+case. For the other test runs there is however no significant change to the PPS
+throughput when the number of flows are increased. In some test runs the PPS
+is also greater with 1000000 flows compared to other test runs where the PPS
+result is less with only 2 flows.
+
+The average PPS throughput in the different runs varies between 414000 and
+452000 PPS. The total amount of packets in each test run is approx. 7500000 to
+8200000 packets. One test run Feb. 15 sticks out with a PPS average of
+558000 and approx. 1100000 packets in total (same as the on mentioned earlier
+for RTT results).
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally range between 100 and 1000 per test run,
+but there are spikes in the range of 10000 lost packets as well, and even
+more in a rare cases.
+
+Network utilization statistics are collected during UDP flows sent between the
+VMs using pktgen as packet generator tool. Total number of packets received per
+second was average on 200 kpps and total number of packets transmitted per
+second was average on 600 kpps.
+
+Detailed test results
+---------------------
+The scenario was run on LF POD1_ with:
+Apex
+OpenStack Mitaka
+OpenVirtualSwitch 2.5.90
+OpenDayLight Beryllium
+
+Rationale for decisions
+-----------------------
+Pass
+
+Tests were successfully executed and metrics collected.
+No SLA was verified. To be decided on in next release of OPNFV.
+
+
+Joid
+====
+
+.. _Grafana: http://testresults.opnfv.org/grafana/dashboard/db/yardstick-main
+.. _POD5: https://wiki.opnfv.org/pharos?&#community_test_labs
+
+
+Overview of test results
+------------------------
+
+See Grafana_ for viewing test result metrics for each respective test case. It
+is possible to chose which specific scenarios to look at, and then to zoom in
+on the details of each run test scenario as well.
+
+All of the test case results below are based on 4 scenario test runs, each run
+on the Intel POD5_ between September 11 and 14 in 2016.
+
+TC002
+-----
+The round-trip-time (RTT) between 2 VMs on different blades is measured using
+ping. Most test run measurements result on average between 1.59 and 1.70 ms.
+Two test runs have reached the same greater RTT spike of 3.06 ms, which are
+1.66 and 1.70 ms average, but only one has the lower RTT of 1.35 ms. The other
+two runs have no similar spike at all. To be able to draw conclusions more runs
+should be made. SLA set to be 10 ms. The SLA value is used as a reference, it
+has not been defined by OPNFV.
+
+TC005
+-----
+The IO read bandwidth actually refers to the storage throughput and the
+greatest IO read bandwidth of the four runs is 173.3 MB/s. The IO read
+bandwidth of the four runs looks similar on different four days, with an
+average between 32.7 and 60.4 MB/s. One of the runs has a minimum BW of 429
+KM/s and other has a maximum BW of 173.3 MB/s. The SLA of read bandwidth sets
+to be 400 MB/s, which is used as a reference, and it has not been defined by
+OPNFV.
+
+TC010
+-----
+The tool we use to measure memory read latency is lmbench, which is a series of
+micro benchmarks intended to measure basic operating system and hardware system
+metrics. The memory read latency of the four runs is 1.1 ns on average. The
+variations within each test run are different, some vary from a large range and
+others have a small change. For example, the largest change is on September 14,
+the memory read latency of which is ranging from 1.12 ns to 1.22 ns. However,
+the results on September 12 change very little, which range from 1.14 ns to
+1.17 ns. The SLA sets to be 30 ns. The SLA value is used as a reference, it has
+not been defined by OPNFV.
+
+TC011
+-----
+Iperf3 is a tool for evaluating the pocket delay variation between 2 VMs on
+different blades. The reported pocket delay variations of the four test runs
+differ from each other. The results on September 13 within the date look
+similar and the values are between 0.0087 and 0.0190 ms, which is 0.0126 ms on
+average. However, on the fourth day, the pocket delay variation has a large
+wide change within the date, which ranges from 0.0032 ms to 0.0121 ms and has
+the minimum average value. The pocket delay variations of other two test runs
+look relatively similar, which are 0.0076 ms and 0.0152 ms on average. The SLA
+value sets to be 10 ms. The SLA value is used as a reference, it has not been
+defined by OPNFV.
+
+TC012
+-----
+Lmbench is also used to measure the memory read and write bandwidth, in which
+we use bw_mem to obtain the results. Among the four test runs, the memory
+bandwidth within the second day almost keep stable, which is 11.58 GB/s on
+average. And the memory bandwidth of the fourth day look similar as that of the
+second day, both of which remain stable. The other two test runs relatively
+change from a large wide range, in which the minimum memory bandwidth is 11.22
+GB/s and the maximum bandwidth is 16.65 GB/s with an average bandwidth of about
+12.20 GB/s. Here SLA set to be 15 GB/s. The SLA value is used as a reference,
+it has not been defined by OPNFV.
+
+TC014
+-----
+The Unixbench is used to measure processing speed, that is instructions per
+second. It can be seen from the dashboard that the processing test results
+vary from scores 3272 to 3444, and there is only one result one date. The
+overall average score is 3371. No SLA set.
+
+TC037
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The mean packet throughput of the four test runs is 119.85, 128.02, 121.40 and
+126.08 kpps, of which the result of the second is the highest. The RTT results
+of all the test runs keep flat at approx. 37 ms. It is obvious that the PPS
+results are not as consistent as the RTT results.
+
+The No. flows of the four test runs are 240 k on average and the PPS results
+look a little waved since the largest packet throughput is 184 kpps and the
+minimum throughput is 49 K respectively.
+
+There are no errors of packets received in the four runs, but there are still
+lost packets in all the test runs. The RTT values obtained by ping of the four
+runs have the similar average vaue, that is 38 ms, of which the worest RTT is
+93 ms on Sep. 14th.
+
+CPU load of the four test runs have a large change, since the minimum value and
+the peak of CPU load is 0 percent and 51 percent respectively. And the best
+result is obtained on Sep. 14th.
+
+TC069
+-----
+With the block size changing from 1 kb to 512 kb, the memory write bandwidth
+tends to become larger first and then smaller within every run test, which
+rangs from 22.3 GB/s to 26.8 GB/s and then to 18.5 GB/s on average. Since the
+test id is one, it is that only the INT memory write bandwidth is tested. On
+the whole, when the block size is 8 kb and 16 kb, the memory write bandwidth
+look similar with a minimal BW of 22.5 GB/s and peak value of 28.7 GB/s. SLA
+sets to be 7 GB/s. The SLA value is used as a a reference, it has not been
+defined by OPNFV.
+
+TC070
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The network latency is measured by ping, and the results of the four test runs
+look similar with each other. Within each test run, the maximum RTT can reach
+more than 80 ms and the average RTT is usually approx. 38 ms. On the whole, the
+average RTTs of the four runs keep flat.
+
+Memory utilization is measured by free, which can display amount of free and
+used memory in the system. The largest amount of used memory is 268 MiB on Sep
+14, which also has the largest minimum memory. Besides, the rest three test
+runs have the similar used memory. On the other hand, the free memory of the
+four runs have the same smallest minimum value, that is about 223 MiB, and the
+maximum free memory of three runs have the similar result, that is 337 MiB,
+except that on Sep. 14th, whose maximum free memory is 254 MiB. On the whole,
+all the test runs have similar average free memory.
+
+Network throughput and packet loss can be measured by pktgen, which is a tool
+in the network for generating traffic loads for network experiments. The mean
+network throughput of the four test runs seem quite different, ranging from
+119.85 kpps to 128.02 kpps. The average number of flows in these tests is
+24000, and each run has a minimum number of flows of 2 and a maximum number
+of flows of 1.001 Mil. At the same time, the corresponding packet throughput
+differ between 49.4k and 193.3k with an average packet throughput of approx.
+125k. On the whole, the PPS results seem consistent. Within each test run of
+the four runs, when number of flows becomes larger, the packet throughput seems
+not larger in the meantime.
+
+TC071
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The network latency is measured by ping, and the results of the four test runs
+look similar with each other. Within each test run, the maximum RTT can reach
+more than 94 ms and the average RTT is usually approx. 35 ms. On the whole, the
+average RTTs of the four runs keep flat.
+
+Cache utilization is measured by cachestat, which can display size of cache and
+buffer in the system. Cache utilization statistics are collected during UDP
+flows sent between the VMs using pktgen as packet generator tool.The largest
+cache size is 212 MiB in the four runs, and the smallest cache size is 75 MiB.
+On the whole, the average cache size of the four runs is approx. 208 MiB.
+Meanwhile, the tread of the buffer size looks similar with each other.
+
+Packet throughput can be measured by pktgen, which is a tool in the network for
+generating traffic loads for network experiments. The mean packet throughput of
+the four test runs seem quite different, ranging from 119.85 kpps to 128.02
+kpps. The average number of flows in these tests is 239.7k, and each run has a
+minimum number of flows of 2 and a maximum number of flows of 1.001 Mil. At the
+same time, the corresponding packet throughput differ between 49.4k and 193.3k
+with an average packet throughput of approx. 125k. On the whole, the PPS results
+seem consistent. Within each test run of the four runs, when number of flows
+becomes larger, the packet throughput seems not larger in the meantime.
+
+TC072
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs at
+approx. 32 ms. The PPS results are not as consistent as the RTT results.
+
+Network utilization is measured by sar, that is system activity reporter, which
+can display the average statistics for the time since the system was started.
+Network utilization statistics are collected during UDP flows sent between the
+VMs using pktgen as packet generator tool. The largest total number of packets
+transmitted per second differs from each other, in which the smallest number of
+packets transmitted per second is 6 pps on Sep. 12ed and the largest of that is
+210.8 kpps. Meanwhile, the largest total number of packets received per second
+differs from each other, in which the smallest number of packets received per
+second is 2 pps on Sep. 13rd and the largest of that is 250.2 kpps.
+
+In some test runs when running with less than approx. 90000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. For the other test runs there is however no
+significant change to the PPS throughput when the number of flows are
+increased. In some test runs the PPS is also greater with 1000000 flows
+compared to other test runs where the PPS result is less with only 2 flows.
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally differs a lot per test run.
+
+Detailed test results
+---------------------
+The scenario was run on Intel POD5_ with:
+Joid
+OpenStack Mitaka
+OpenVirtualSwitch 2.5.90
+OpenDayLight Beryllium
+
+Rationale for decisions
+-----------------------
+Pass
+
+Conclusions and recommendations
+-------------------------------
+Tests were successfully executed and metrics collected.
+No SLA was verified. To be decided on in next release of OPNFV.
+
+
diff --git a/docs/results/os-nosdn-nofeature-noha.rst b/docs/results/os-nosdn-nofeature-noha.rst
new file mode 100644
index 000000000..8b7c184bb
--- /dev/null
+++ b/docs/results/os-nosdn-nofeature-noha.rst
@@ -0,0 +1,259 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International
+.. License.
+.. http://creativecommons.org/licenses/by/4.0
+
+
+========================================
+Test Results for os-nosdn-nofeature-noha
+========================================
+
+.. toctree::
+ :maxdepth: 2
+
+
+Joid
+=====
+
+.. _Grafana: http://testresults.opnfv.org/grafana/dashboard/db/yardstick-main
+.. _POD5: https://wiki.opnfv.org/pharos?&#community_test_labs
+
+Overview of test results
+------------------------
+
+See Grafana_ for viewing test result metrics for each respective test case. It
+is possible to chose which specific scenarios to look at, and then to zoom in
+on the details of each run test scenario as well.
+
+All of the test case results below are based on 4 scenario test runs, each run
+on the Intel POD5_ between September 12 and 15 in 2016.
+
+TC002
+-----
+The round-trip-time (RTT) between 2 VMs on different blades is measured using
+ping. Most test run measurements result on average between 1.50 and 1.68 ms.
+Only one test run has reached greatest RTT spike of 2.92 ms, which has
+the smallest RTT of 1.06 ms. The other three runs have no similar spike at all,
+the minimum and average RTTs of which are approx. 1.50 ms and 1.68 ms. SLA set to
+be 10 ms. The SLA value is used as a reference, it has not been defined by
+OPNFV.
+
+TC005
+-----
+The IO read bandwidth actually refers to the storage throughput, which is
+measured by fio and the greatest IO read bandwidth of the four runs is 177.5
+MB/s. The IO read bandwidth of the four runs looks similar on different four
+days, with an average between 46.7 and 62.5 MB/s. One of the runs has a minimum
+BW of 680 KM/s and other has a maximum BW of 177.5 MB/s. The SLA of read
+bandwidth sets to be 400 MB/s, which is used as a reference, and it has not
+been defined by OPNFV.
+
+The results of storage IOPS for the four runs look similar with each other. The
+test runs all have an approx. 1.55 K/s for IO reading with an minimum value of
+less than 60 times per second.
+
+TC010
+-----
+The tool we use to measure memory read latency is lmbench, which is a series of
+micro benchmarks intended to measure basic operating system and hardware system
+metrics. The memory read latency of the four runs is between 1.134 ns and 1.227
+ns on average. The variations within each test run are quite different, some
+vary from a large range and others have a small change. For example, the
+largest change is on September 15, the memory read latency of which is ranging
+from 1.116 ns to 1.393 ns. However, the results on September 12 change very
+little, which mainly keep flat and range from 1.124 ns to 1.55 ns. The SLA sets
+to be 30 ns. The SLA value is used as a reference, it has not been defined by
+OPNFV.
+
+TC011
+-----
+Iperf3 is a tool for evaluating the pocket delay variation between 2 VMs on
+different blades. The reported pocket delay variations of the four test runs
+differ from each other. The results on September 13 within the date look
+similar and the values are between 0.0213 and 0.0225 ms, which is 0.0217 ms on
+average. However, on the third day, the packet delay variation has a large
+wide change within the date, which ranges from 0.008 ms to 0.0225 ms and has
+the minimum value. On Sep. 12, the packet delay is quite long, for the value is
+between 0.0236 and 0.0287 ms and it also has the maximum packet delay of 0.0287
+ms. The packet delay of the last test run is 0.0151 ms on average. The SLA
+value sets to be 10 ms. The SLA value is used as a reference, it has not been
+defined by OPNFV.
+
+TC012
+-----
+Lmbench is also used to measure the memory read and write bandwidth, in which
+we use bw_mem to obtain the results. Among the four test runs, the memory
+bandwidth of three test runs almost keep stable within each run, which is
+11.65, 11.57 and 11.64 GB/s on average. However, the memory read and write
+bandwidth on Sep. 14 has a large range, for it ranges from 11.36 GB/s to 16.68
+GB/s. Here SLA set to be 15 GB/s. The SLA value is used as a reference, it has
+not been defined by OPNFV.
+
+TC014
+-----
+The Unixbench is used to evaluate the IaaS processing speed with regards to
+score of single cpu running and parallel running. It can be seen from the
+dashboard that the processing test results vary from scores 3222 to 3585, and
+there is only one result one date. No SLA set.
+
+TC037
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The mean packet throughput of the four test runs is 124.8, 160.1, 113.8 and
+137.3 kpps, of which the result of the second is the highest. The RTT results
+of all the test runs keep flat at approx. 37 ms. It is obvious that the PPS
+results are not as consistent as the RTT results.
+
+The No. flows of the four test runs are 240 k on average and the PPS results
+look a little waved since the largest packet throughput is 243.1 kpps and the
+minimum throughput is 37.6 kpps respectively.
+
+There are no errors of packets received in the four runs, but there are still
+lost packets in all the test runs. The RTT values obtained by ping of the four
+runs have the similar average vaue, that is between 32 ms and 41 ms, of which
+the worest RTT is 155 ms on Sep. 14th.
+
+CPU load is measured by mpstat, and CPU load of the four test runs seem a
+little similar, since the minimum value and the peak of CPU load is between 0
+percent and 9 percent respectively. And the best result is obtained on Sep.
+15th, with an CPU load of nine percent.
+
+TC069
+-----
+With the block size changing from 1 kb to 512 kb, the memory write bandwidth
+tends to become larger first and then smaller within every run test, which
+rangs from 22.4 GB/s to 26.5 GB/s and then to 18.6 GB/s on average. Since the
+test id is one, it is that only the INT memory write bandwidth is tested. On
+the whole, when the block size is 8 kb and 16 kb, the memory write bandwidth
+look similar with a minimal BW of 22.5 GB/s and peak value of 28.7 GB/s. And
+then with the block size becoming larger, the memory write bandwidth tends to
+decrease. SLA sets to be 7 GB/s. The SLA value is used as a a reference, it has
+not been defined by OPNFV.
+
+TC070
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The network latency is measured by ping, and the results of three test runs look
+similar with each other, and Within these test runs, the maximum RTT can reach
+95 ms and the average RTT is usually approx. 36 ms. The network latency tested
+on Sep. 14 shows that it has a peak latency of 155 ms. But on the whole, the
+average RTTs of the four runs keep flat.
+
+Memory utilization is measured by free, which can display amount of free and
+used memory in the system. The largest amount of used memory is 270 MiB on Sep
+13, which also has the smallest minimum memory utilization. Besides, the rest
+three test runs have the similar used memory with an average memory usage of
+264 MiB. On the other hand, the free memory of the four runs have the same
+smallest minimum value, that is about 223 MiB, and the maximum free memory of
+three runs have the similar result, that is 226 MiB, except that on Sep. 13th,
+whose maximum free memory is 273 MiB. On the whole, all the test runs have
+similar average free memory.
+
+Network throughput and packet loss can be measured by pktgen, which is a tool
+in the network for generating traffic loads for network experiments. The mean
+network throughput of the four test runs seem quite different, ranging from
+119.85 kpps to 128.02 kpps. The average number of flows in these tests is
+240000, and each run has a minimum number of flows of 2 and a maximum number
+of flows of 1.001 Mil. At the same time, the corresponding packet throughput
+differ between 38k and 243k with an average packet throughput of approx. 134k.
+On the whole, the PPS results seem consistent. Within each test run of the four
+runs, when number of flows becomes larger, the packet throughput seems not
+larger in the meantime.
+
+TC071
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The network latency is measured by ping, and the results of the four test runs
+look similar with each other. Within each test run, the maximum RTT can reach
+79 ms and the average RTT is usually approx. 35 ms. On the whole, the average
+RTTs of the four runs keep flat.
+
+Cache utilization is measured by cachestat, which can display size of cache and
+buffer in the system. Cache utilization statistics are collected during UDP
+flows sent between the VMs using pktgen as packet generator tool.The largest
+cache size is 214 MiB in the four runs, and the smallest cache size is 100 MiB.
+On the whole, the average cache size of the four runs is approx. 210 MiB.
+Meanwhile, the tread of the buffer size looks similar with each other. On the
+other hand, the mean buffer size of the four runs keep flat, since they have a
+minimum value of approx. 7 MiB and a maximum value of 8 MiB, with an average
+value of about 8 MiB.
+
+Packet throughput can be measured by pktgen, which is a tool in the network for
+generating traffic loads for network experiments. The mean packet throughput of
+the four test runs seem quite different, ranging from 113.8 kpps to 124.8 kpps.
+The average number of flows in these tests is 240k, and each run has a minimum
+number of flows of 2 and a maximum number of flows of 1.001 Mil. At the same
+time, the corresponding packet throughput differ between 47.6k and 243.1k with
+an average packet throughput between 113.8k and 160.1k. Within each test run of
+the four runs, when number of flows becomes larger, the packet throughput seems
+not larger in the meantime.
+
+TC072
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs
+between 0 ms and 79 ms with an average leatency of approx. 35 ms. The PPS
+results are not as consistent as the RTT results, for the mean packet
+throughput of the four runs differ from 113.8 kpps to 124.8 kpps.
+
+Network utilization is measured by sar, that is system activity reporter, which
+can display the average statistics for the time since the system was started.
+Network utilization statistics are collected during UDP flows sent between the
+VMs using pktgen as packet generator tool. The largest total number of packets
+transmitted per second look similar on the first three runs with a minimum
+number of 10 pps and a maximum number of 97 kpps, except the one on Sep. 15th,
+in which the number of packets transmitted per second is 10 pps. Meanwhile, the
+largest total number of packets received per second differs from each other,
+in which the smallest number of packets received per second is 1 pps and the
+largest of that is 276 kpps.
+
+In some test runs when running with less than approx. 90000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. For the other test runs there is however no
+significant change to the PPS throughput when the number of flows are
+increased. In some test runs the PPS is also greater with 1000000 flows
+compared to other test runs where the PPS result is less with only 2 flows.
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally differs a lot per test run.
+
+Detailed test results
+---------------------
+The scenario was run on Intel POD5_ with:
+Joid
+OpenStack Mitaka
+OpenVirtualSwitch 2.5.90
+OpenDayLight Beryllium
+
+Rationale for decisions
+-----------------------
+Pass
+
+Conclusions and recommendations
+-------------------------------
+Tests were successfully executed and metrics collected.
+No SLA was verified. To be decided on in next release of OPNFV.
diff --git a/docs/results/os-odl_l2-bgpvpn-ha.rst b/docs/results/os-odl_l2-bgpvpn-ha.rst
new file mode 100644
index 000000000..2bd6dc35d
--- /dev/null
+++ b/docs/results/os-odl_l2-bgpvpn-ha.rst
@@ -0,0 +1,53 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International
+.. License.
+.. http://creativecommons.org/licenses/by/4.0
+
+
+====================================
+Test Results for os-odl_l2-bgpvpn-ha
+====================================
+
+.. toctree::
+ :maxdepth: 2
+
+
+fuel
+====
+
+.. _Grafana: http://testresults.opnfv.org/grafana/dashboard/db/yardstick-main
+.. _POD2: https://wiki.opnfv.org/pharos?&#community_test_labs
+
+Overview of test results
+------------------------
+
+See Grafana_ for viewing test result metrics for each respective test case. It
+is possible to chose which specific scenarios to look at, and then to zoom in
+on the details of each run test scenario as well.
+
+All of the test case results below are based on 4 scenario test runs, each run
+on the Ericsson POD2_ between September 7 and 11 in 2016.
+
+TC043
+-----
+The round-trip-time (RTT) between 2 nodes is measured using
+ping. Most test run measurements result on average between 0.21 and 0.28 ms.
+A few runs start with a 0.32 - 0.35 ms RTT spike (This could be because of
+normal ARP handling). To be able to draw conclusions more runs should be made.
+SLA set to 10 ms. The SLA value is used as a reference, it has not been defined
+by OPNFV.
+
+Detailed test results
+---------------------
+The scenario was run on Ericsson POD2_ with:
+Fuel 9.0
+OpenStack Mitaka
+OpenVirtualSwitch 2.5.90
+OpenDayLight Beryllium
+
+Rationale for decisions
+-----------------------
+Pass
+
+Tests were successfully executed and metrics collected.
+No SLA was verified. To be decided on in next release of OPNFV.
+
diff --git a/docs/results/fuel-os-odl_l2-nofeature-ha.rst b/docs/results/os-odl_l2-nofeature-ha.rst
index e9ef8fe65..6eb6252af 100644
--- a/docs/results/fuel-os-odl_l2-nofeature-ha.rst
+++ b/docs/results/os-odl_l2-nofeature-ha.rst
@@ -3,16 +3,16 @@
.. http://creativecommons.org/licenses/by/4.0
-============================================
-Test Results for fuel-os-odl_l2-nofeature-ha
-============================================
+=======================================
+Test Results for os-odl_l2-nofeature-ha
+=======================================
.. toctree::
:maxdepth: 2
-Details
-=======
+fuel
+====
.. _Grafana: http://testresults.opnfv.org/grafana/dashboard/db/yardstick-main
.. _POD2: https://wiki.opnfv.org/pharos?&#community_test_labs
@@ -120,14 +120,15 @@ utilization ratio vary between 1% to 2%. The peak of CPU utilization ratio
appears around 7%.
TC069
+-----
Between test dates, the average measurements for memory bandwidth vary between
15.5 and 25.4 GB/s. Within each test run the results vary more, with a minimal
BW of 9.7 GB/s and maximum of 29.5 GB/s on the totality.
SLA set to 6 GB/s. The SLA value is used as a reference, it has not been
defined by OPNFV.
-
TC070
+-----
The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
on different blades are measured when increasing the amount of UDP flows sent
between the VMs using pktgen as packet generator tool.
@@ -166,6 +167,7 @@ utilization vary between 225MB to 246MB. The peak of memory utilization appears
around 340MB.
TC071
+-----
The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
on different blades are measured when increasing the amount of UDP flows sent
between the VMs using pktgen as packet generator tool.
@@ -203,6 +205,7 @@ VMs using pktgen as packet generator tool. The average measurements for cache
utilization vary between 205MB to 212MB.
TC072
+-----
The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
on different blades are measured when increasing the amount of UDP flows sent
between the VMs using pktgen as packet generator tool.
diff --git a/docs/results/os-onos-nofeature-ha.rst b/docs/results/os-onos-nofeature-ha.rst
new file mode 100644
index 000000000..e5587505f
--- /dev/null
+++ b/docs/results/os-onos-nofeature-ha.rst
@@ -0,0 +1,257 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International
+.. License.
+.. http://creativecommons.org/licenses/by/4.0
+
+
+======================================
+Test Results for os-onos-nofeature-ha
+======================================
+
+.. toctree::
+ :maxdepth: 2
+
+
+Joid
+=====
+
+.. _Grafana: http://testresults.opnfv.org/grafana/dashboard/db/yardstick-main
+.. _POD6: https://wiki.opnfv.org/pharos?&#community_test_labs
+
+Overview of test results
+------------------------
+
+See Grafana_ for viewing test result metrics for each respective test case. It
+is possible to chose which specific scenarios to look at, and then to zoom in
+on the details of each run test scenario as well.
+
+All of the test case results below are based on 5 scenario test runs, each run
+on the Intel POD6_ between September 13 and 16 in 2016.
+
+TC002
+-----
+The round-trip-time (RTT) between 2 VMs on different blades is measured using
+ping. Most test run measurements result on average between 1.50 and 1.68 ms.
+Only one test run has reached greatest RTT spike of 2.62 ms, which has
+the smallest RTT of 1.00 ms. The other four runs have no similar spike at all,
+the minimum and average RTTs of which are approx. 1.06 ms and 1.32 ms. SLA set
+to be 10 ms. The SLA value is used as a reference, it has not been defined by
+OPNFV.
+
+TC005
+-----
+The IO read bandwidth actually refers to the storage throughput, which is
+measured by fio and the greatest IO read bandwidth of the four runs is 175.4
+MB/s. The IO read bandwidth of the four runs looks similar on different four
+days, with an average between 58.1 and 62.0 MB/s, except one on Sep. 14, for
+its maximum storage throughput is only 133.0 MB/s. One of the runs has a
+minimum BW of 497 KM/s and other has a maximum BW of 177.4 MB/s. The SLA of read
+bandwidth sets to be 400 MB/s, which is used as a reference, and it has not
+been defined by OPNFV.
+
+The results of storage IOPS for the five runs look similar with each other. The
+IO read times per second of the five test runs have an average value between
+1.20 K/s and 1.61 K/s, and meanwhile, the minimum result is only 41 times per
+second.
+
+TC010
+-----
+The tool we use to measure memory read latency is lmbench, which is a series of
+micro benchmarks intended to measure basic operating system and hardware system
+metrics. The memory read latency of the five runs is between 1.146 ns and 1.172
+ns on average. The variations within each test run are quite different, some
+vary from a large range and others have a small change. For example, the
+largest change is on September 13, the memory read latency of which is ranging
+from 1.152 ns to 1.221 ns. However, the results on September 14 change very
+little. The SLA sets to be 30 ns. The SLA value is used as a reference, it has
+not been defined by OPNFV.
+
+TC011
+-----
+Iperf3 is a tool for evaluating the packet delay variation between 2 VMs on
+different blades. The reported packet delay variations of the five test runs
+differ from each other. In general, the packet delay of the first two runs look
+similar, for they both stay stable within each run. And the mean packet delay of
+of them are 0.07714 ms and 0.07982 ms respectively. Of the five runs, the third
+has the worst result, because the packet delay reaches 0.08384 ms. The trend of
+therest two runs look the same, for the average packet delay are 0.07808 ms and
+0.07727 ms respectively. The SLA value sets to be 10 ms. The SLA value is used
+as a reference, it has not been defined by OPNFV.
+
+TC012
+-----
+Lmbench is also used to measure the memory read and write bandwidth, in which
+we use bw_mem to obtain the results. Among the five test runs, the memory
+bandwidth of last three test runs almost keep stable within each run, which is
+11.64, 11.71 and 11.61 GB/s on average. However, the memory read and write
+bandwidth on Sep. 13 has a large range, for it ranges from 6.68 GB/s to 11.73
+GB/s. Here SLA set to be 15 GB/s. The SLA value is used as a reference, it has
+not been defined by OPNFV.
+
+TC014
+-----
+The Unixbench is used to evaluate the IaaS processing speed with regards to
+score of single cpu running and parallel running. It can be seen from the
+dashboard that the processing test results vary from scores 3208 to 3314, and
+there is only one result one date. No SLA set.
+
+TC037
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The mean packet throughput of the five test runs is between 259.6 kpps and
+318.4 kpps, of which the result of the second run is the highest. The RTT
+results of all the test runs keep flat at approx. 20 ms. It is obvious that the
+PPS results are not as consistent as the RTT results.
+
+The No. flows of the five test runs are 240 k on average and the PPS results
+look a little waved since the largest packet throughput is 398.9 kpps and the
+minimum throughput is 250.6 kpps respectively.
+
+There are no errors of packets received in the five runs, but there are still
+lost packets in all the test runs. The RTT values obtained by ping of the five
+runs have the similar average vaue, that is between 17 ms and 22 ms, of which
+the worest RTT is 53 ms on Sep. 14th.
+
+CPU load is measured by mpstat, and CPU load of the four test runs seem a
+little similar, since the minimum value and the peak of CPU load is between 0
+percent and 10 percent respectively. And the best result is obtained on Sep.
+13rd, with an CPU load of 10 percent.
+
+TC069
+-----
+With the block size changing from 1 kb to 512 kb, the memory write bandwidth
+tends to become larger first and then smaller within every run test, which
+rangs from 21.6 GB/s to 26.8 GB/s and then to 18.4 GB/s on average. Since the
+test id is one, it is that only the INT memory write bandwidth is tested. On
+the whole, when the block size is 8 kb and 16 kb, the memory write bandwidth
+look similar with a minimal BW of 23.0 GB/s and peak value of 28.6 GB/s. And
+then with the block size becoming larger, the memory write bandwidth tends to
+decrease. SLA sets to be 7 GB/s. The SLA value is used as a a reference, it has
+not been defined by OPNFV.
+
+TC070
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The network latency is measured by ping, and the results of the five test runs
+look similar with each other, and within these test runs, the maximum RTT can
+reach 53 ms and the average RTT is usually approx. 18 ms. The network latency
+tested on Sep. 14 shows that it has a peak latency of 53 ms. But on the whole,
+the average RTTs of the five runs keep flat and the network latency is
+relatively short.
+
+Memory utilization is measured by free, which can display amount of free and
+used memory in the system. The largest amount of used memory is 272 MiB on Sep
+14. In general, the mean used memory of the five test runs have the similar
+trend and the minimum memory used size is approx. 150 MiB, and the average
+used memory size is about 250 MiB. On the other hand, for the mean free memory,
+the five test runs have the similar trend, whose mean free memory change from
+218 MiB to 342 MiB, with an average value of approx. 38 MiB.
+
+Packet throughput and packet loss can be measured by pktgen, which is a tool
+in the network for generating traffic loads for network experiments. The mean
+packet throughput of the five test runs seem quite different, ranging from
+285.29 kpps to 297.76 kpps. The average number of flows in these tests is
+240000, and each run has a minimum number of flows of 2 and a maximum number
+of flows of 1.001 Mil. At the same time, the corresponding packet throughput
+differ between 250.6k and 398.9k with an average packet throughput between
+277.2 K and 318.4 K. In summary, the PPS results seem consistent. Within each
+test run of the five runs, when number of flows becomes larger, the packet
+throughput seems not larger at the same time.
+
+TC071
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The network latency is measured by ping, and the results of the five test runs
+look similar with each other. Within each test run, the maximum RTT is only 49
+ms and the average RTT is usually approx. 20 ms. On the whole, the average
+RTTs of the five runs keep stable and the network latency is relatively short.
+
+Cache utilization is measured by cachestat, which can display size of cache and
+buffer in the system. Cache utilization statistics are collected during UDP
+flows sent between the VMs using pktgen as packet generator tool.The largest
+cache size is 215 MiB in the four runs, and the smallest cache size is 95 MiB.
+On the whole, the average cache size of the five runs change a little and is
+about 200 MiB, except the one on Sep. 14th, the mean cache size is very small,
+which keeps 102 MiB. Meanwhile, the tread of the buffer size keep flat, since
+they have a minimum value of 7 MiB and a maximum value of 8 MiB, with an
+average value of about 7.8 MiB.
+
+Packet throughput can be measured by pktgen, which is a tool in the network for
+generating traffic loads for network experiments. The mean packet throughput of
+the four test runs seem quite different, ranging from 285.29 kpps to 297.76
+kpps. The average number of flows in these tests is 239.7k, and each run has a
+minimum number of flows of 2 and a maximum number of flows of 1.001 Mil. At the
+same time, the corresponding packet throughput differ between 227.3k and 398.9k
+with an average packet throughput between 277.2k and 318.4k. Within each test
+run of the five runs, when number of flows becomes larger, the packet
+throughput seems not larger in the meantime.
+
+TC072
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs
+ between 0 ms and 49 ms with an average leatency of less than 22 ms. The PPS
+results are not as consistent as the RTT results, for the mean packet
+throughput of the five runs differ from 250.6 kpps to 398.9 kpps.
+
+Network utilization is measured by sar, that is system activity reporter, which
+can display the average statistics for the time since the system was started.
+Network utilization statistics are collected during UDP flows sent between the
+VMs using pktgen as packet generator tool. The largest total number of packets
+transmitted per second look similar for four test runs, whose values change a
+lot from 10 pps to 399 kpps, except the one on Sep. 14th, whose total number
+of transmitted per second keep stable, that is 10 pps. Similarly, the total
+number of packets received per second look the same for four runs, except the
+one on Sep. 14th, whose value is only 10 pps.
+
+In some test runs when running with less than approx. 90000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. For the other test runs there is however no
+significant change to the PPS throughput when the number of flows are
+increased. In some test runs the PPS is also greater with 250000 flows
+compared to other test runs where the PPS result is less with only 2 flows.
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally differs a lot per test run.
+
+Detailed test results
+---------------------
+The scenario was run on Intel POD5_ with:
+Joid
+OpenStack Mitaka
+Onos Goldeneye
+OpenVirtualSwitch 2.5.90
+OpenDayLight Beryllium
+
+Rationale for decisions
+-----------------------
+Pass
+
+Conclusions and recommendations
+-------------------------------
+Tests were successfully executed and metrics collected.
+No SLA was verified. To be decided on in next release of OPNFV.
diff --git a/docs/results/os-onos-sfc-ha.rst b/docs/results/os-onos-sfc-ha.rst
new file mode 100644
index 000000000..1a09f53d7
--- /dev/null
+++ b/docs/results/os-onos-sfc-ha.rst
@@ -0,0 +1,274 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International
+.. License.
+.. http://creativecommons.org/licenses/by/4.0
+
+
+===============================
+Test Results for os-onos-sfc-ha
+===============================
+
+.. toctree::
+ :maxdepth: 2
+
+
+fuel
+====
+
+.. _Grafana: http://testresults.opnfv.org/grafana/dashboard/db/yardstick-main
+.. _POD2: https://wiki.opnfv.org/pharos?&#community_test_labs
+
+Overview of test results
+------------------------
+
+See Grafana_ for viewing test result metrics for each respective test case. It
+is possible to chose which specific scenarios to look at, and then to zoom in
+on the details of each run test scenario as well.
+
+All of the test case results below are based on 4 scenario test runs, each run
+on the Ericsson POD2_ or LF POD2_ between September 5 and 10 in 2016.
+
+TC002
+-----
+The round-trip-time (RTT) between 2 VMs on different blades is measured using
+ping. Most test run measurements result on average between 0.5 and 0.6 ms.
+A few runs start with a 1 - 1.5 ms RTT spike (This could be because of normal ARP
+handling). One test run has a greater RTT spike of 1.9 ms, which is the same
+one with the 0.7 ms average. The other runs have no similar spike at all.
+To be able to draw conclusions more runs should be made.
+SLA set to 10 ms. The SLA value is used as a reference, it has not
+been defined by OPNFV.
+
+TC005
+-----
+The IO read bandwidth looks similar between different dates, with an
+average between approx. 170 and 200 MB/s. Within each test run the results
+vary, with a minimum 2 MB/s and maximum 838 MB/s on the totality. Most runs
+have a minimum BW of 3 MB/s (two runs at 2 MB/s). The maximum BW varies more in
+absolute numbers between the dates, between 617 and 838 MB/s.
+SLA set to 400 MB/s. The SLA value is used as a reference, it has not been
+defined by OPNFV.
+
+TC010
+-----
+The measurements for memory latency are similar between test dates and result
+in approx. 1.2 ns. The variations within each test run are similar, between
+1.215 and 1.219 ns. One exception is February 16, where the average is 1.222
+and varies between 1.22 and 1.28 ns.
+SLA set to 30 ns. The SLA value is used as a reference, it has not been defined
+by OPNFV.
+
+TC011
+-----
+Packet delay variation between 2 VMs on different blades is measured using
+Iperf3. On the first date the reported packet delay variation varies between
+0.0025 and 0.011 ms, with an average delay variation of 0.0067 ms.
+On the second date the delay variation varies between 0.002 and 0.006 ms, with
+an average delay variation of 0.004 ms.
+
+TC012
+-----
+Between test dates, the average measurements for memory bandwidth vary between
+17.4 and 17.9 GB/s. Within each test run the results vary more, with a minimal
+BW of 16.4 GB/s and maximum of 18.2 GB/s on the totality.
+SLA set to 15 GB/s. The SLA value is used as a reference, it has not been
+defined by OPNFV.
+
+TC014
+-----
+The Unixbench processor test run results vary between scores 3080 and 3240,
+one result each date. The average score on the total is 3150.
+No SLA set.
+
+TC037
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs at
+approx. 15 ms. Some test runs show an increase with many flows, in the range
+towards 16 to 17 ms. One exception standing out is Feb. 15 where the average
+RTT is stable at approx. 13 ms. The PPS results are not as consistent as the
+RTT results.
+In some test runs when running with less than approx. 10000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. Around 20 percent decrease in the worst
+case. For the other test runs there is however no significant change to the PPS
+throughput when the number of flows are increased. In some test runs the PPS
+is also greater with 1000000 flows compared to other test runs where the PPS
+result is less with only 2 flows.
+
+The average PPS throughput in the different runs varies between 414000 and
+452000 PPS. The total amount of packets in each test run is approx. 7500000 to
+8200000 packets. One test run Feb. 15 sticks out with a PPS average of
+558000 and approx. 1100000 packets in total (same as the on mentioned earlier
+for RTT results).
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally range between 100 and 1000 per test run,
+but there are spikes in the range of 10000 lost packets as well, and even
+more in a rare cases.
+
+CPU utilization statistics are collected during UDP flows sent between the VMs
+using pktgen as packet generator tool. The average measurements for CPU
+utilization ratio vary between 1% to 2%. The peak of CPU utilization ratio
+appears around 7%.
+
+TC069
+-----
+Between test dates, the average measurements for memory bandwidth vary between
+15.5 and 25.4 GB/s. Within each test run the results vary more, with a minimal
+BW of 9.7 GB/s and maximum of 29.5 GB/s on the totality.
+SLA set to 6 GB/s. The SLA value is used as a reference, it has not been
+defined by OPNFV.
+
+TC070
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs at
+approx. 15 ms. Some test runs show an increase with many flows, in the range
+towards 16 to 17 ms. One exception standing out is Feb. 15 where the average
+RTT is stable at approx. 13 ms. The PPS results are not as consistent as the
+RTT results.
+In some test runs when running with less than approx. 10000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. Around 20 percent decrease in the worst
+case. For the other test runs there is however no significant change to the PPS
+throughput when the number of flows are increased. In some test runs the PPS
+is also greater with 1000000 flows compared to other test runs where the PPS
+result is less with only 2 flows.
+
+The average PPS throughput in the different runs varies between 414000 and
+452000 PPS. The total amount of packets in each test run is approx. 7500000 to
+8200000 packets. One test run Feb. 15 sticks out with a PPS average of
+558000 and approx. 1100000 packets in total (same as the on mentioned earlier
+for RTT results).
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally range between 100 and 1000 per test run,
+but there are spikes in the range of 10000 lost packets as well, and even
+more in a rare cases.
+
+Memory utilization statistics are collected during UDP flows sent between the
+VMs using pktgen as packet generator tool. The average measurements for memory
+utilization vary between 225MB to 246MB. The peak of memory utilization appears
+around 340MB.
+
+TC071
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs at
+approx. 15 ms. Some test runs show an increase with many flows, in the range
+towards 16 to 17 ms. One exception standing out is Feb. 15 where the average
+RTT is stable at approx. 13 ms. The PPS results are not as consistent as the
+RTT results.
+In some test runs when running with less than approx. 10000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. Around 20 percent decrease in the worst
+case. For the other test runs there is however no significant change to the PPS
+throughput when the number of flows are increased. In some test runs the PPS
+is also greater with 1000000 flows compared to other test runs where the PPS
+result is less with only 2 flows.
+
+The average PPS throughput in the different runs varies between 414000 and
+452000 PPS. The total amount of packets in each test run is approx. 7500000 to
+8200000 packets. One test run Feb. 15 sticks out with a PPS average of
+558000 and approx. 1100000 packets in total (same as the on mentioned earlier
+for RTT results).
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally range between 100 and 1000 per test run,
+but there are spikes in the range of 10000 lost packets as well, and even
+more in a rare cases.
+
+Cache utilization statistics are collected during UDP flows sent between the
+VMs using pktgen as packet generator tool. The average measurements for cache
+utilization vary between 205MB to 212MB.
+
+TC072
+-----
+The amount of packets per second (PPS) and round trip times (RTT) between 2 VMs
+on different blades are measured when increasing the amount of UDP flows sent
+between the VMs using pktgen as packet generator tool.
+
+Round trip times and packet throughput between VMs can typically be affected by
+the amount of flows set up and result in higher RTT and less PPS throughput.
+
+The RTT results are similar throughout the different test dates and runs at
+approx. 15 ms. Some test runs show an increase with many flows, in the range
+towards 16 to 17 ms. One exception standing out is Feb. 15 where the average
+RTT is stable at approx. 13 ms. The PPS results are not as consistent as the
+RTT results.
+In some test runs when running with less than approx. 10000 flows the PPS
+throughput is normally flatter compared to when running with more flows, after
+which the PPS throughput decreases. Around 20 percent decrease in the worst
+case. For the other test runs there is however no significant change to the PPS
+throughput when the number of flows are increased. In some test runs the PPS
+is also greater with 1000000 flows compared to other test runs where the PPS
+result is less with only 2 flows.
+
+The average PPS throughput in the different runs varies between 414000 and
+452000 PPS. The total amount of packets in each test run is approx. 7500000 to
+8200000 packets. One test run Feb. 15 sticks out with a PPS average of
+558000 and approx. 1100000 packets in total (same as the on mentioned earlier
+for RTT results).
+
+There are lost packets reported in most of the test runs. There is no observed
+correlation between the amount of flows and the amount of lost packets.
+The lost amount of packets normally range between 100 and 1000 per test run,
+but there are spikes in the range of 10000 lost packets as well, and even
+more in a rare cases.
+
+Network utilization statistics are collected during UDP flows sent between the
+VMs using pktgen as packet generator tool. Total number of packets received per
+second was average on 200 kpps and total number of packets transmitted per
+second was average on 600 kpps.
+
+Detailed test results
+---------------------
+The scenario was run on Ericsson POD2_ and LF POD2_ with:
+Fuel 9.0
+OpenStack Mitaka
+Onos Goldeneye
+OpenVirtualSwitch 2.5.90
+OpenDayLight Beryllium
+
+Rationale for decisions
+-----------------------
+Pass
+
+Tests were successfully executed and metrics collected.
+No SLA was verified. To be decided on in next release of OPNFV.
+
+Conclusions and recommendations
+-------------------------------
+The pktgen test configuration has a relatively large base effect on RTT in
+TC037 compared to TC002, where there is no background load at all. Approx.
+15 ms compared to approx. 0.5 ms, which is more than a 3000 percentage
+difference in RTT results.
+Especially RTT and throughput come out with better results than for instance
+the *fuel-os-nosdn-nofeature-ha* scenario does. The reason for this should
+probably be further analyzed and understood. Also of interest could be
+to make further analyzes to find patterns and reasons for lost traffic.
+Also of interest could be to see if there are continuous variations where
+some test cases stand out with better or worse results than the general test
+case.
+
diff --git a/docs/results/overview.rst b/docs/results/overview.rst
index ee0ebe504..b4a050545 100644
--- a/docs/results/overview.rst
+++ b/docs/results/overview.rst
@@ -45,39 +45,41 @@ The list of scenarios supported by each installer can be described as follows:
+-------------------------+---------+---------+---------+---------+
| Scenario | Apex | Compass | Fuel | Joid |
+=========================+=========+=========+=========+=========+
-| os-nosdn-nofeature-noha | | | | X |
+| os-nosdn-nofeature-noha | | | X | X |
+-------------------------+---------+---------+---------+---------+
-| os-nosdn-nofeature-ha | X | | X | X |
+| os-nosdn-nofeature-ha | X | X | X | X |
+-------------------------+---------+---------+---------+---------+
| os-odl_l2-nofeature-ha | X | X | X | X |
+-------------------------+---------+---------+---------+---------+
-| os-odl_l2-nofeature-noha| | X | | |
+| os-odl_l2-nofeature-noha| | | X | |
+-------------------------+---------+---------+---------+---------+
-| os-odl_l3-nofeature-ha | X | | X | |
+| os-odl_l3-nofeature-ha | X | X | X | |
+-------------------------+---------+---------+---------+---------+
-| os-odl_l3-nofeature-ha | | X | | |
+| os-odl_l3-nofeature-noha| | | X | |
+-------------------------+---------+---------+---------+---------+
-| os-onos-sfc-ha | X | | X | X |
+| os-onos-sfc-ha | X | X | X | X |
+-------------------------+---------+---------+---------+---------+
-| os-onos-nofeature-ha | X | | X | X |
+| os-onos-sfc-noha | | | X | |
+-------------------------+---------+---------+---------+---------+
-| os-onos-nofeature-noha | | X | | |
+| os-onos-nofeature-ha | X | X | X | X |
++-------------------------+---------+---------+---------+---------+
+| os-onos-nofeature-noha | | | X | |
+-------------------------+---------+---------+---------+---------+
| os-odl_l2-sfc-ha | | | X | |
+-------------------------+---------+---------+---------+---------+
-| os-odl_l2-sfc-noha | X | X | | |
+| os-odl_l2-sfc-noha | X | X | X | |
+-------------------------+---------+---------+---------+---------+
| os-odl_l2-bgpvpn-ha | X | | X | |
+-------------------------+---------+---------+---------+---------+
-| os-odl_l2-bgpvpn-noha | | X | | |
+| os-odl_l2-bgpvpn-noha | | X | X | |
+-------------------------+---------+---------+---------+---------+
| os-nosdn-kvm-ha | | | X | |
+-------------------------+---------+---------+---------+---------+
-| os-nosdn-kvm-noha | | X | | |
+| os-nosdn-kvm-noha | | X | X | |
+-------------------------+---------+---------+---------+---------+
-| os-nosdn-ovs-ha | | | | |
+| os-nosdn-ovs-ha | | | X | |
+-------------------------+---------+---------+---------+---------+
-| os-nosdn-ovs-noha | X | X | | |
+| os-nosdn-ovs-noha | X | | X | |
+-------------------------+---------+---------+---------+---------+
| os-ocl-nofeature-ha | | | | |
+-------------------------+---------+---------+---------+---------+
@@ -87,6 +89,8 @@ The list of scenarios supported by each installer can be described as follows:
+-------------------------+---------+---------+---------+---------+
| os-odl_l2-fdio-noha | X | | | |
+-------------------------+---------+---------+---------+---------+
+| os-odl_l2-moon-ha | | X | | |
++-------------------------+---------+---------+---------+---------+
To qualify for release, the scenarios must have deployed and been successfully
tested in four consecutive installations to establish stability of deployment
diff --git a/docs/results/results.rst b/docs/results/results.rst
index bfdba20e9..c5598a069 100644
--- a/docs/results/results.rst
+++ b/docs/results/results.rst
@@ -20,56 +20,16 @@ The following documents contain results of Yardstick test cases executed on
OPNFV labs, triggered by OPNFV CI pipeline, documented per scenario.
-Ready scenarios
----------------
-
-The following scenarios have been successfully tested at least four consecutive
-times:
-
.. toctree::
:maxdepth: 1
- fuel-os-odl_l2-nofeature-ha.rst
- fuel-os-odl_l3-nofeature-noha.rst
- fuel-os-nosdn-kvm-ha.rst
- fuel-os-nosdn-kvm-noha.rst
- fuel-os-odl_l2-bgpvpn-ha.rst
- fuel-os-odl_l2-bgpvpn-noha.rst
- compass-os-nosdn-nofeature-ha.rst
- compass-os-odl_l2-moon-ha.rst
- compass-os-onos-sfc-ha.rst
- compass-onos-nofeature-ha.rst
- joid-os-nosdn-nofeature-ha.rst
- joid-os-nosdn-nofeature-noha.rst
- joid-odl_l2-nofeature-ha.rst
- joid-os-onos-nofeature-ha.rst
- joid-os-onos-sfc-ha.rst
- apex-os-nosdn-nofeature-ha.rst
- apex-os-odl_l2-bgpvpn-ha.rst
-
-Limitations
------------
-
-For the following scenarios, Yardstick generic test cases suite was executed at
-least one time however less than four consecutive times, measurements
-collected:
-
-
- * fuel-os-odl_l3-nofeature-ha
-
-
-For the following scenario, Yardstick generic test cases suite was executed
-four consecutive times, measurements collected; no feature test cases were
-executed, therefore the feature is not verified by Yardstick:
-
-
-
-For the following scenario, Yardstick generic test cases suite was executed
-three consecutive times, measurements collected; no feature test cases
-were executed, therefore the feature is not verified by Yardstick:
-
- * fuel-os-odl_l2-sfc-ha
-
+ os-odl_l2-nofeature-ha.rst
+ os-nosdn-nofeature-ha.rst
+ os-nosdn-kvm-ha.rst
+ os-odl_l2-bgpvpn-ha.rst
+ os-nosdn-nofeature-noha.rst
+ os-onos-nofeature-h.rst
+ os-onos-sfc-ha.rst
Test results of executed tests are avilable in Dashboard_ and logs in Jenkins_.
diff --git a/docs/userguide/07-installation.rst b/docs/userguide/07-installation.rst
index 8d87bc09d..aa45b61af 100644
--- a/docs/userguide/07-installation.rst
+++ b/docs/userguide/07-installation.rst
@@ -11,7 +11,7 @@ Abstract
Yardstick supports installation on Ubuntu 14.04 or by using a Docker image.
The installation procedure on Ubuntu 14.04 or via the docker image are
-detailed in the section below
+detailed in the section below.
To use Yardstick you should have access to an OpenStack environment,
with at least Nova, Neutron, Glance, Keystone and Heat installed.
@@ -21,7 +21,7 @@ The steps needed to run Yardstick are:
1. Install Yardstick.
2. Create the test configuration .yaml file.
3. Build a guest image。
-4 .Load the image into the OpenStack environment.
+4. Load the image into the OpenStack environment.
5. Create a Neutron external network.
6. Load OpenStack environment variables.
6. Run the test case.
@@ -87,48 +87,6 @@ at: http://www.youtube.com/watch?v=4S4izNolmR0
:alt: http://www.youtube.com/watch?v=4S4izNolmR0
:target: http://www.youtube.com/watch?v=4S4izNolmR0
-.. _guest-image:
-
-Building a guest image
-^^^^^^^^^^^^^^^^^^^^^^
-Yardstick has a tool for building an Ubuntu Cloud Server image containing all
-the required tools to run test cases supported by Yardstick. It is necessary to
-have sudo rights to use this tool.
-
-Also you may need install several additional packages to use this tool, by
-follwing the commands below:
-
-::
-
- apt-get update && apt-get install -y \
- qemu-utils \
- kpartx
-
-This image can be built using the following command while in the directory where
-Yardstick is installed (``~/yardstick`` if the framework is installed
-by following the commands above):
-
-::
-
- eport YARD_IMG_ARCH="amd64"
- sudo echo "Defaults env_keep += \"YARD_IMG_ARCH\"" >> /etc/sudoers
- sudo ./tools/yardstick-img-modify tools/ubuntu-server-cloudimg-modify.sh
-
-**Warning:** the script will create files by default in:
-``/tmp/workspace/yardstick`` and the files will be owned by root!
-
-The created image can be added to OpenStack using the ``glance image-create`` or
-via the OpenStack Dashboard.
-
-Example command:
-
-::
-
- glance --os-image-api-version 1 image-create \
- --name yardstick-trusty-server --is-public true \
- --disk-format qcow2 --container-format bare \
- --file /tmp/workspace/yardstick/yardstick-trusty-server.img
-
Installing Yardstick using Docker
---------------------------------
@@ -150,51 +108,13 @@ Run the Docker image:
::
- docker run \
- --privileged=true \
- --rm \
- -t \
- -e "INSTALLER_TYPE=${INSTALLER_TYPE}" \
- -e "INSTALLER_IP=${INSTALLER_IP}" \
- opnfv/yardstick \
- exec_tests.sh ${YARDSTICK_DB_BACKEND} ${YARDSTICK_SUITE_NAME}
-
-Where ``${INSTALLER_TYPE}`` can be apex, compass, fuel or joid, ``${INSTALLER_IP}``
-is the installer master node IP address (i.e. 10.20.0.2 is default for fuel). ``${YARDSTICK_DB_BACKEND}``
-is the IP and port number of DB, ``${YARDSTICK_SUITE_NAME}`` is the test suite you want to run.
-For more details, please refer to the Jenkins job defined in Releng project, labconfig information
-and sshkey are required. See the link
-https://git.opnfv.org/cgit/releng/tree/jjb/yardstick/yardstick-ci-jobs.yml.
-
-Note: exec_tests.sh is used for executing test suite here, furthermore, if someone
-wants to execute the test suite manually, it can be used as long as the parameters
-are configured correct. Another script called run_tests.sh is used for unittest in
-Jenkins verify job, in local manaul environment, it is recommended to run before
-test suite execuation.
-
-Basic steps performed by the **Yardstick-stable** container:
-
-1. clone yardstick and releng repos
-2. setup OS credentials (releng scripts)
-3. install yardstick and dependencies
-4. build yardstick cloud image
-5. Upload yardstick cloud image to glance
-6. upload cirros-0.3.3 cloud image and ubuntu-14.04 cloud image to glance
-7. run yardstick test scenarios
-8. cleanup
-
-If someone only wants to execute a single test case, one can log into the yardstick-stable
-container first using command:
-
-::
-
- docker run -it openfv/yardstick /bin/bash
+ docker run --privileged=true -it openfv/yardstick /bin/bash
-Then in the container run yardstick task command to execute a single test case.
+In the container run yardstick task command to execute a test case.
Before executing Yardstick test case, make sure that yardstick-trusty-server
image and yardstick flavor is available in OpenStack.
-Detailed steps about creating yardstick flavor and executing Yardstick test case
-can be found below.
+Detailed steps about creating yardstick flavor and building yardstick-trusty-server
+image can be found below.
OpenStack parameters and credentials
@@ -226,6 +146,51 @@ Credential environment variables in the *openrc* file have to include at least:
* OS_PASSWORD
* OS_TENANT_NAME
+
+.. _guest-image:
+
+Building a guest image
+^^^^^^^^^^^^^^^^^^^^^^
+Yardstick has a tool for building an Ubuntu Cloud Server image containing all
+the required tools to run test cases supported by Yardstick. It is necessary to
+have sudo rights to use this tool.
+
+Also you may need install several additional packages to use this tool, by
+follwing the commands below:
+
+::
+
+ apt-get update && apt-get install -y \
+ qemu-utils \
+ kpartx
+
+This image can be built using the following command while in the directory where
+Yardstick is installed (``~/yardstick`` if the framework is installed
+by following the commands above):
+
+::
+
+ export YARD_IMG_ARCH="amd64"
+ sudo echo "Defaults env_keep += \"YARD_IMG_ARCH\"" >> /etc/sudoers
+ sudo ./tools/yardstick-img-modify tools/ubuntu-server-cloudimg-modify.sh
+
+**Warning:** the script will create files by default in:
+``/tmp/workspace/yardstick`` and the files will be owned by root!
+If you are building this guest image in inside a docker container make sure the
+container is granted with privilege.
+The created image can be added to OpenStack using the ``glance image-create`` or
+via the OpenStack Dashboard.
+
+Example command:
+
+::
+
+ glance --os-image-api-version 1 image-create \
+ --name yardstick-trusty-server --is-public true \
+ --disk-format qcow2 --container-format bare \
+ --file /tmp/workspace/yardstick/yardstick-trusty-server.img
+
+
Yardstick default key pair
^^^^^^^^^^^^^^^^^^^^^^^^^^
Yardstick uses a SSH key pair to connect to the guest image. This key pair can
@@ -237,8 +202,10 @@ Examples and verifying the install
----------------------------------
It is recommended to verify that Yardstick was installed successfully
-by executing some simple commands and test samples. Below is an example invocation
-of yardstick help command and ping.py test sample:
+by executing some simple commands and test samples. Before executing yardstick
+test cases make sure yardstick flavor and building yardstick-trusty-server
+image can be found in glance and openrc file is sourced. Below is an example
+invocation of yardstick help command and ping.py test sample:
::
yardstick –h
diff --git a/samples/computecapacity.yaml b/samples/computecapacity.yaml
index 006b3ef3d..ae527d2ca 100644
--- a/samples/computecapacity.yaml
+++ b/samples/computecapacity.yaml
@@ -1,8 +1,12 @@
---
# Sample benchmark task config file
-# Measure compute capacity and scale.
-# Including number of cores, number of threads, available memory size and
-# cache size.
+# compute capacity and scale.
+
+# the results have
+# number of CPUs, number of physical cores in a single CPU
+# number of logical cores, total memory size
+# cache size per CPU, total cache size
+# HT (Hyper-Thread) support status, 1 for open, 0 for close
schema: "yardstick:task:0.1"
diff --git a/tests/ci/report_config.yaml b/tests/ci/report_config.yaml
new file mode 100644
index 000000000..ae19894c0
--- /dev/null
+++ b/tests/ci/report_config.yaml
@@ -0,0 +1,20 @@
+reporting:
+ -
+ name: apex
+ scenario:
+ -
+ os-nosdn-ovs-noha
+ -
+ os-onos-sfc-ha
+ -
+ os-onos-nofeature-ha
+
+ -
+ name: fuel
+ scenario:
+ -
+ os-odl_l2-sfc-noha
+ -
+ os-odl_l2-sfc-ha
+ -
+ os-nosdn-ovs-ha
diff --git a/tests/ci/yardstick-verify b/tests/ci/yardstick-verify
index 16df3bb59..77a560c71 100755
--- a/tests/ci/yardstick-verify
+++ b/tests/ci/yardstick-verify
@@ -185,6 +185,10 @@ create_nova_flavor()
if [[ "$DEPLOY_SCENARIO" == *"-ovs-"* ]]; then
nova flavor-key yardstick-flavor set hw:mem_page_size=large
fi
+ # VPP requires guest memory to be backed by large pages
+ if [[ "$DEPLOY_SCENARIO" == *"-fdio-"* ]]; then
+ nova flavor-key yardstick-flavor set hw:mem_page_size=large
+ fi
fi
}
@@ -195,10 +199,17 @@ load_cirros_image()
local image_file=/home/opnfv/images/cirros-0.3.3-x86_64-disk.img
+ EXTRA_PARAMS=""
+ # VPP requires guest memory to be backed by large pages
+ if [[ "$DEPLOY_SCENARIO" == *"-fdio-"* ]]; then
+ EXTRA_PARAMS=$EXTRA_PARAMS" --property hw_mem_page_size=large"
+ fi
+
output=$(glance image-create \
--name cirros-0.3.3 \
--disk-format $DISK_FORMAT \
--container-format bare \
+ $EXTRA_PARAMS \
--file $image_file)
echo "$output"
@@ -218,10 +229,17 @@ load_ubuntu_image()
local ubuntu_image_file=/home/opnfv/images/trusty-server-cloudimg-amd64-disk1.img
+ EXTRA_PARAMS=""
+ # VPP requires guest memory to be backed by large pages
+ if [[ "$DEPLOY_SCENARIO" == *"-fdio-"* ]]; then
+ EXTRA_PARAMS=$EXTRA_PARAMS" --property hw_mem_page_size=large"
+ fi
+
output=$(glance image-create \
--name Ubuntu-14.04 \
--disk-format qcow2 \
--container-format bare \
+ $EXTRA_PARAMS \
--file $ubuntu_image_file)
echo "$output"
@@ -270,6 +288,11 @@ load_yardstick_image()
cd $YARDSTICK_REPO_DIR
fi
+ # VPP requires guest memory to be backed by large pages
+ if [[ "$DEPLOY_SCENARIO" == *"-fdio-"* ]]; then
+ EXTRA_PARAMS=$EXTRA_PARAMS" --property hw_mem_page_size=large"
+ fi
+
output=$(eval glance --os-image-api-version 1 image-create \
--name yardstick-trusty-server \
--is-public true --disk-format $DISK_FORMAT \
diff --git a/tests/opnfv/test_cases/opnfv_yardstick_tc055.yaml b/tests/opnfv/test_cases/opnfv_yardstick_tc055.yaml
index 403bc344e..54fc965c6 100644
--- a/tests/opnfv/test_cases/opnfv_yardstick_tc055.yaml
+++ b/tests/opnfv/test_cases/opnfv_yardstick_tc055.yaml
@@ -1,7 +1,13 @@
---
# Yardstick TC055 config file
-# Collect hardware specification from /proc/cpuinfo
-# Measure number of cores, number of threads, available memory size and cache size
+# Collect hardware specification from /proc/cpuinfo /proc/meminfo
+# compute capacity and scale.
+
+# the results have
+# number of CPUs, number of physical cores in a single CPU
+# number of logical cores, total memory size
+# cache size per CPU, total cache size
+# HT (Hyper-Thread) support status, 1 for open, 0 for close
schema: "yardstick:task:0.1"
{% set host = host or "node5.yardstick-TC055" %}
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-fdio-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-fdio-noha_daily.yaml
new file mode 100644
index 000000000..187e10988
--- /dev/null
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-fdio-noha_daily.yaml
@@ -0,0 +1,30 @@
+---
+# FDS suite
+
+schema: "yardstick:suite:0.1"
+
+name: "os-nosdn-fdio-noha"
+test_cases_dir: "tests/opnfv/test_cases/"
+test_cases:
+-
+ file_name: opnfv_yardstick_tc001.yaml
+-
+ file_name: opnfv_yardstick_tc002.yaml
+-
+ file_name: opnfv_yardstick_tc006.yaml
+-
+ file_name: opnfv_yardstick_tc007.yaml
+-
+ file_name: opnfv_yardstick_tc008.yaml
+-
+ file_name: opnfv_yardstick_tc009.yaml
+-
+ file_name: opnfv_yardstick_tc011.yaml
+-
+ file_name: opnfv_yardstick_tc020.yaml
+-
+ file_name: opnfv_yardstick_tc021.yaml
+-
+ file_name: opnfv_yardstick_tc037.yaml
+-
+ file_name: opnfv_yardstick_tc038.yaml
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-kvm-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-kvm-ha_daily.yaml
index eb1226f80..29235b6f6 100644
--- a/tests/opnfv/test_suites/opnfv_os-nosdn-kvm-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-kvm-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-nosdn-kvm-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-kvm-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-kvm-noha_daily.yaml
index 02fb31e47..fd48cadb1 100644
--- a/tests/opnfv/test_suites/opnfv_os-nosdn-kvm-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-kvm-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-nosdn-kvm-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-kvm_ovs-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-kvm_ovs-ha_daily.yaml
index 27accf49c..b488505af 100644
--- a/tests/opnfv/test_suites/opnfv_os-nosdn-kvm_ovs-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-kvm_ovs-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-nosdn-kvm_ovs-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-lxd-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-lxd-ha_daily.yaml
index cbb2069f9..93de7b88e 100644
--- a/tests/opnfv/test_suites/opnfv_os-nosdn-lxd-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-lxd-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-nosdn-lxd-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-lxd-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-lxd-noha_daily.yaml
index cbbf8c13e..ac8535e81 100644
--- a/tests/opnfv/test_suites/opnfv_os-nosdn-lxd-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-lxd-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-nosdn-lxd-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-ha_daily.yaml
index ebe7a0513..1ad871e51 100644
--- a/tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-nosdn-nofeature-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-noha_daily.yaml
index 567e8bf73..e85a9788f 100644
--- a/tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-nofeature-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-nosdn-nofeature-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-ovs-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-ovs-ha_daily.yaml
index 6cf5b38d3..a61d8242c 100644
--- a/tests/opnfv/test_suites/opnfv_os-nosdn-ovs-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-ovs-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-nosdn-ovs-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-nosdn-ovs-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-nosdn-ovs-noha_daily.yaml
index 9e5074fc6..6c91a3337 100644
--- a/tests/opnfv/test_suites/opnfv_os-nosdn-ovs-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-nosdn-ovs-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-nosdn-ovs-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-ocl-nofeature-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-ocl-nofeature-ha_daily.yaml
index 7106a1335..9ea030a40 100644
--- a/tests/opnfv/test_suites/opnfv_os-ocl-nofeature-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-ocl-nofeature-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-ocl-nofeature-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-ocl-nofeature-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-ocl-nofeature-noha_daily.yaml
index 42781a841..e2f07650c 100644
--- a/tests/opnfv/test_suites/opnfv_os-ocl-nofeature-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-ocl-nofeature-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-ocl-nofeature-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-ha_daily.yaml
index 84d630cc1..cd9c29268 100644
--- a/tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-odl_l2-bgpvpn-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-noha_daily.yaml
index a9e272aa6..0d4113e59 100644
--- a/tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l2-bgpvpn-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-odl_l2-bgpvpn-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l2-fdio-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l2-fdio-noha_daily.yaml
new file mode 100644
index 000000000..3b7fe80e5
--- /dev/null
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l2-fdio-noha_daily.yaml
@@ -0,0 +1,30 @@
+---
+# FDS suite
+
+schema: "yardstick:suite:0.1"
+
+name: "os-odl_l2-fdio-noha"
+test_cases_dir: "tests/opnfv/test_cases/"
+test_cases:
+-
+ file_name: opnfv_yardstick_tc001.yaml
+-
+ file_name: opnfv_yardstick_tc002.yaml
+-
+ file_name: opnfv_yardstick_tc006.yaml
+-
+ file_name: opnfv_yardstick_tc007.yaml
+-
+ file_name: opnfv_yardstick_tc008.yaml
+-
+ file_name: opnfv_yardstick_tc009.yaml
+-
+ file_name: opnfv_yardstick_tc011.yaml
+-
+ file_name: opnfv_yardstick_tc020.yaml
+-
+ file_name: opnfv_yardstick_tc021.yaml
+-
+ file_name: opnfv_yardstick_tc037.yaml
+-
+ file_name: opnfv_yardstick_tc038.yaml
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l2-moon-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l2-moon-ha_daily.yaml
index dadcb2f22..4a775b5bf 100644
--- a/tests/opnfv/test_suites/opnfv_os-odl_l2-moon-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l2-moon-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-odl_l2-moon-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-ha_daily.yaml
index 1de157a37..35358bcfe 100644
--- a/tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-odl_l2-nofeature-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-noha_daily.yaml
index 1661e08f1..dc8b2efd0 100644
--- a/tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l2-nofeature-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-odl_l2-nofeature-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-ha_daily.yaml
index 9e0e4186e..1899d407a 100644
--- a/tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-odl_l2-sfc-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-noha_daily.yaml
index 1ebd73216..33f24e332 100644
--- a/tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l2-sfc-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-odl_l2-sfc-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-ha_daily.yaml
index 4bcf81b45..97094bf32 100644
--- a/tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-odl_l3-nofeature-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-noha_daily.yaml
index c50569b69..2796dca05 100644
--- a/tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-odl_l3-nofeature-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-odl_l3-nofeature-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-onos-nofeature-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-onos-nofeature-ha_daily.yaml
index 48718abb7..777565ae5 100644
--- a/tests/opnfv/test_suites/opnfv_os-onos-nofeature-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-onos-nofeature-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-onos-nofeature-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-onos-nofeature-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-onos-nofeature-noha_daily.yaml
index 0e9ff81d9..e6745613b 100644
--- a/tests/opnfv/test_suites/opnfv_os-onos-nofeature-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-onos-nofeature-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-onos-nofeature-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-onos-sfc-ha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-onos-sfc-ha_daily.yaml
index bfb02cf48..aada4b450 100644
--- a/tests/opnfv/test_suites/opnfv_os-onos-sfc-ha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-onos-sfc-ha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-onos-sfc-ha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/opnfv/test_suites/opnfv_os-onos-sfc-noha_daily.yaml b/tests/opnfv/test_suites/opnfv_os-onos-sfc-noha_daily.yaml
index 2661e583e..a4e7c823f 100644
--- a/tests/opnfv/test_suites/opnfv_os-onos-sfc-noha_daily.yaml
+++ b/tests/opnfv/test_suites/opnfv_os-onos-sfc-noha_daily.yaml
@@ -1,5 +1,5 @@
---
-# Huawei US bare daily task suite
+# os-onos-sfc-noha daily task suite
schema: "yardstick:suite:0.1"
diff --git a/tests/unit/benchmark/scenarios/compute/test_computecapacity.py b/tests/unit/benchmark/scenarios/compute/test_computecapacity.py
index 660bb3391..da06b5dbb 100644
--- a/tests/unit/benchmark/scenarios/compute/test_computecapacity.py
+++ b/tests/unit/benchmark/scenarios/compute/test_computecapacity.py
@@ -20,7 +20,7 @@ from yardstick.benchmark.scenarios.compute import computecapacity
SAMPLE_OUTPUT = '{"Cpu_number": "2", "Core_number": "24",\
"Memory_size": "263753976 kB", "Thread_number": "48",\
- "Cache_size": "30720 KB"}'
+ "Cache_size": "30720 KB", "HT_Open": "0"}'
@mock.patch('yardstick.benchmark.scenarios.compute.computecapacity.ssh')
diff --git a/yardstick/benchmark/scenarios/compute/computecapacity.bash b/yardstick/benchmark/scenarios/compute/computecapacity.bash
index 98d4b8fb5..68741a94f 100644
--- a/yardstick/benchmark/scenarios/compute/computecapacity.bash
+++ b/yardstick/benchmark/scenarios/compute/computecapacity.bash
@@ -9,13 +9,15 @@
# http://www.apache.org/licenses/LICENSE-2.0
##############################################################################
-# Measure compute capacity and scale of a host
+# compute capacity and scale of a host
set -e
# run capacity test
run_capacity()
{
+ #parameter used for HT(Hyper-Thread) check
+ HT_Para=2
# Number of CPUs
CPU=$(grep 'physical id' /proc/cpuinfo | sort -u | wc -l)
# Number of physical cores in a single CPU
@@ -31,6 +33,12 @@ run_capacity()
CACHE=$(grep 'cache size' /proc/cpuinfo | sort -u)
CA=$(echo $CACHE | awk '/ /{printf "%s", $4}')
CACHES=$[$CA * $CPU]
+ HT_Value=$[$HT_Para * $CORES]
+ if [ $HT_Value -eq $THREAD ]; then
+ HT_OPEN=1
+ else
+ HT_OPEN=0
+ fi
}
# write the result to stdout in json format
@@ -41,7 +49,8 @@ output_json()
\"Core_number\":\"$CORES\", \
\"Thread_number\":\"$THREAD\", \
\"Memory_size\": \"$ME\", \
- \"Cache_size\": \"$CACHES KB\" \
+ \"Cache_size\": \"$CACHES KB\", \
+ \"HT_Open\": \"$HT_OPEN\" \
}"
}