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Diffstat (limited to 'docs/testing')
-rwxr-xr-x | docs/testing/developer/devguide/devguide_nsb_prox.rst | 333 |
1 files changed, 201 insertions, 132 deletions
diff --git a/docs/testing/developer/devguide/devguide_nsb_prox.rst b/docs/testing/developer/devguide/devguide_nsb_prox.rst index 79990055a..a6e5be946 100755 --- a/docs/testing/developer/devguide/devguide_nsb_prox.rst +++ b/docs/testing/developer/devguide/devguide_nsb_prox.rst @@ -13,7 +13,8 @@ optimal system architectures and configurations. Prerequisites ============= -In order to integrate PROX tests into NSB, the following prerequisites are required. +In order to integrate PROX tests into NSB, the following prerequisites are +required. .. _`dpdk wiki page`: http://dpdk.org/ .. _`yardstick wiki page`: https://wiki.opnfv.org/display/yardstick/ @@ -159,11 +160,13 @@ A NSB Prox test is composed of the following components :- ``tc_prox_heat_context_vpe-4.yaml``. This file describes the components of the test, in the case of openstack the network description and server descriptions, in the case of baremetal the hardware - description location. It also contains the name of the Traffic Generator, the SUT config file - and the traffic profile description, all described below. See nsb-test-description-label_ + description location. It also contains the name of the Traffic Generator, + the SUT config file and the traffic profile description, all described below. + See nsb-test-description-label_ -* Traffic Profile file. Example ``prox_binsearch.yaml``. This describes the packet size, tolerated - loss, initial line rate to start traffic at, test interval etc See nsb-traffic-profile-label_ +* Traffic Profile file. Example ``prox_binsearch.yaml``. This describes the + packet size, tolerated loss, initial line rate to start traffic at, test + interval etc See nsb-traffic-profile-label_ * Traffic Generator Config file. Usually called ``gen_<test>-<ports>.cfg``. @@ -235,7 +238,8 @@ show you how to understand the test description file. Now let's examine the components of the file in detail 1. ``traffic_profile`` - This specifies the traffic profile for the - test. In this case ``prox_binsearch.yaml`` is used. See nsb-traffic-profile-label_ + test. In this case ``prox_binsearch.yaml`` is used. See + nsb-traffic-profile-label_ 2. ``topology`` - This is either ``prox-tg-topology-1.yaml`` or ``prox-tg-topology-2.yaml`` or ``prox-tg-topology-4.yaml`` @@ -330,11 +334,11 @@ This describes the details of the traffic flow. In this case :alt: NSB PROX Traffic Profile -1. ``name`` - The name of the traffic profile. This name should match the name specified in the - ``traffic_profile`` field in the Test Description File. +1. ``name`` - The name of the traffic profile. This name should match the name + specified in the ``traffic_profile`` field in the Test Description File. -2. ``traffic_type`` - This specifies the type of traffic pattern generated, This name matches - class name of the traffic generator See:: +2. ``traffic_type`` - This specifies the type of traffic pattern generated, + This name matches class name of the traffic generator. See:: network_services/traffic_profile/prox_binsearch.py class ProxBinSearchProfile(ProxProfile) @@ -704,15 +708,22 @@ Now let's examine the components of the file in detail physical core improves performance, however sometimes it is optimal to move task to a separate core. This is best decided by checking performance. - c. ``mode=lat`` - Specifies the action carried out by this task on this core. Supported modes are: acl, - classify, drop, gredecap, greencap, ipv6_decap, ipv6_encap, l2fwd, lbnetwork, lbpos, lbqinq, nop, - police, qinqdecapv4, qinqencapv4, qos, routing, impair, lb5tuple, mirror, unmpls, tagmpls, - nat, decapnsh, encapnsh, gen, genl4 and lat. This task(0) per core(3) receives packets on port. - d. ``rx port=p0`` - The port to receive packets on ``Port 0``. Core 4 will receive packets on ``Port 1``. - e. ``lat pos=42`` - Describes where to put a 4-byte timestamp in the packet. Note that the packet length should - be longer than ``lat pos`` + 4 bytes to avoid truncation of the timestamp. It defines where the timestamp is - to be read from. Note that the SUT workload might cause the position of the timestamp to change - (i.e. due to encapsulation). + c. ``mode=lat`` - Specifies the action carried out by this task on this + core. + Supported modes are: ``acl``, ``classify``, ``drop``, ``gredecap``, + ``greencap``, ``ipv6_decap``, ``ipv6_encap``, ``l2fwd``, ``lbnetwork``, + ``lbpos``, ``lbqinq``, ``nop``, ``police``, ``qinqdecapv4``, + ``qinqencapv4``, ``qos``, ``routing``, ``impair``, ``lb5tuple``, + ``mirror``, ``unmpls``, ``tagmpls``, ``nat``, ``decapnsh``, ``encapnsh``, + ``gen``, ``genl4`` and ``lat``. This task(0) per core(3) receives packets + on port. + d. ``rx port=p0`` - The port to receive packets on ``Port 0``. Core 4 will + receive packets on ``Port 1``. + e. ``lat pos=42`` - Describes where to put a 4-byte timestamp in the packet. + Note that the packet length should be longer than ``lat pos`` + 4 bytes + to avoid truncation of the timestamp. It defines where the timestamp is + to be read from. Note that the SUT workload might cause the position of + the timestamp to change (i.e. due to encapsulation). .. _nsb-sut-generator-label: @@ -720,7 +731,8 @@ Now let's examine the components of the file in detail ------------------------------- This section will describes the SUT(VNF) config file. This is the same for both -baremetal and heat. See this example of ``handle_l2fwd_multiflow-2.cfg`` to explain the options. +baremetal and heat. See this example of ``handle_l2fwd_multiflow-2.cfg`` to +explain the options. .. image:: images/PROX_Handle_2port_cfg.png :width: 1400px @@ -730,13 +742,15 @@ See `prox options`_ for details Now let's examine the components of the file in detail -1. ``[eal options]`` - same as the Generator config file. This specified the EAL (Environmental Abstraction Layer) - options. These are default values and are not changed. - See `dpdk wiki page`_. +1. ``[eal options]`` - same as the Generator config file. This specified the + EAL (Environmental Abstraction Layer) options. These are default values and + are not changed. See `dpdk wiki page`_. -2. ``[port 0]`` - This section describes the DPDK Port. The number following the keyword ``port`` usually refers to the DPDK Port Id. usually starting from ``0``. - Because you can have multiple ports this entry usually repeated. Eg. For a 2 port setup ``[port0]`` and ``[port 1]`` and for a 4 port setup ``[port 0]``, ``[port 1]``, - ``[port 2]`` and ``[port 3]``:: +2. ``[port 0]`` - This section describes the DPDK Port. The number following + the keyword ``port`` usually refers to the DPDK Port Id. usually starting + from ``0``. Because you can have multiple ports this entry usually + repeated. E.g. For a 2 port setup ``[port0]`` and ``[port 1]`` and for a 4 + port setup ``[port 0]``, ``[port 1]``, ``[port 2]`` and ``[port 3]``:: [port 0] name=if0 @@ -745,10 +759,14 @@ Now let's examine the components of the file in detail tx desc=2048 promiscuous=yes - a. In this example ``name =if0`` assigned the name ``if0`` to the port. Any name can be assigned to a port. - b. ``mac=hardware`` sets the MAC address assigned by the hardware to data from this port. - c. ``rx desc=2048`` sets the number of available descriptors to allocate for receive packets. This can be changed and can effect performance. - d. ``tx desc=2048`` sets the number of available descriptors to allocate for transmit packets. This can be changed and can effect performance. + a. In this example ``name =if0`` assigned the name ``if0`` to the port. Any + name can be assigned to a port. + b. ``mac=hardware`` sets the MAC address assigned by the hardware to data + from this port. + c. ``rx desc=2048`` sets the number of available descriptors to allocate + for receive packets. This can be changed and can effect performance. + d. ``tx desc=2048`` sets the number of available descriptors to allocate + for transmit packets. This can be changed and can effect performance. e. ``promiscuous=yes`` this enables promiscuous mode for this port. 3. ``[defaults]`` - Here default operations and settings can be over written.:: @@ -757,35 +775,46 @@ Now let's examine the components of the file in detail mempool size=8K memcache size=512 - a. In this example ``mempool size=8K`` the number of mbufs per task is altered. Altering this value could effect performance. See `prox options`_ for details. - b. ``memcache size=512`` - number of mbufs cached per core, default is 256 this is the cache_size. Altering this value could effect performance. + a. In this example ``mempool size=8K`` the number of mbufs per task is + altered. Altering this value could effect performance. See + `prox options`_ for details. + b. ``memcache size=512`` - number of mbufs cached per core, default is 256 + this is the cache_size. Altering this value could affect performance. -4. ``[global]`` - Here application wide setting are supported. Things like application name, start time, duration and memory configurations can be set here. +4. ``[global]`` - Here application wide setting are supported. Things like + application name, start time, duration and memory configurations can be set + here. In this example.:: [global] start time=5 name=Basic Gen - a. ``start time=5`` Time is seconds after which average stats will be started. + a. ``start time=5`` Time is seconds after which average stats will be + started. b. ``name=Handle L2FWD Multiflow (2x)`` Name of the configuration. -5. ``[core 0]`` - This core is designated the master core. Every Prox application must have a master core. The master mode must be assigned to +5. ``[core 0]`` - This core is designated the master core. Every Prox + application must have a master core. The master mode must be assigned to exactly one task, running alone on one core.:: [core 0] mode=master -6. ``[core 1]`` - This describes the activity on core 1. Cores can be configured by means of a set of [core #] sections, where # represents either: +6. ``[core 1]`` - This describes the activity on core 1. Cores can be + configured by means of a set of [core #] sections, where # represents + either: - a. an absolute core number: e.g. on a 10-core, dual socket system with hyper-threading, - cores are numbered from 0 to 39. + a. an absolute core number: e.g. on a 10-core, dual socket system with + hyper-threading, cores are numbered from 0 to 39. - b. PROX allows a core to be identified by a core number, the letter 's', and a socket number. - However NSB PROX is hardware agnostic (physical and virtual configurations are the same) it - is advisable no to use physical core numbering. + b. PROX allows a core to be identified by a core number, the letter 's', + and a socket number. However NSB PROX is hardware agnostic (physical and + virtual configurations are the same) it is advisable no to use physical + core numbering. - Each core can be assigned with a set of tasks, each running one of the implemented packet processing modes.:: + Each core can be assigned with a set of tasks, each running one of the + implemented packet processing modes.:: [core 1] name=none @@ -796,20 +825,33 @@ Now let's examine the components of the file in detail tx port=if1 a. ``name=none`` - No name assigned to the core. - b. ``task=0`` - Each core can run a set of tasks. Starting with ``0``. Task 1 can be defined later in this core or - can be defined in another ``[core 1]`` section with ``task=1`` later in configuration file. Sometimes running - multiple task related to the same packet on the same physical core improves performance, however sometimes it - is optimal to move task to a separate core. This is best decided by checking performance. - c. ``mode=l2fwd`` - Specifies the action carried out by this task on this core. Supported modes are: acl, - classify, drop, gredecap, greencap, ipv6_decap, ipv6_encap, l2fwd, lbnetwork, lbpos, lbqinq, nop, - police, qinqdecapv4, qinqencapv4, qos, routing, impair, lb5tuple, mirror, unmpls, tagmpls, - nat, decapnsh, encapnsh, gen, genl4 and lat. This code does ``l2fwd`` .. ie it does the L2FWD. - - d. ``dst mac=@@tester_mac1`` - The destination mac address of the packet will be set to the MAC address of ``Port 1`` of destination device. (The Traffic Generator/Verifier) - e. ``rx port=if0`` - This specifies that the packets are received from ``Port 0`` called if0 - f. ``tx port=if1`` - This specifies that the packets are transmitted to ``Port 1`` called if1 - - If this example we receive a packet on core on a port, carry out operation on the packet on the core and transmit it on on another port still using the same task on the same core. + b. ``task=0`` - Each core can run a set of tasks. Starting with ``0``. + Task 1 can be defined later in this core or can be defined in another + ``[core 1]`` section with ``task=1`` later in configuration file. + Sometimes running multiple task related to the same packet on the same + physical core improves performance, however sometimes it is optimal to + move task to a separate core. This is best decided by checking + performance. + c. ``mode=l2fwd`` - Specifies the action carried out by this task on this + core. Supported modes are: ``acl``, ``classify``, ``drop``, + ``gredecap``, ``greencap``, ``ipv6_decap``, ``ipv6_encap``, ``l2fwd``, + ``lbnetwork``, ``lbpos``, ``lbqinq``, ``nop``, ``police``, + ``qinqdecapv4``, ``qinqencapv4``, ``qos``, ``routing``, ``impair``, + ``lb5tuple``, ``mirror``, ``unmpls``, ``tagmpls``, ``nat``, + ``decapnsh``, ``encapnsh``, ``gen``, ``genl4`` and ``lat``. This code + does ``l2fwd``. i.e. it does the L2FWD. + + d. ``dst mac=@@tester_mac1`` - The destination mac address of the packet + will be set to the MAC address of ``Port 1`` of destination device. + (The Traffic Generator/Verifier) + e. ``rx port=if0`` - This specifies that the packets are received from + ``Port 0`` called if0 + f. ``tx port=if1`` - This specifies that the packets are transmitted to + ``Port 1`` called if1 + + In this example we receive a packet on core on a port, carry out operation + on the packet on the core and transmit it on on another port still using + the same task on the same core. On some implementation you may wish to use multiple tasks, like this.:: @@ -829,15 +871,22 @@ Now let's examine the components of the file in detail tx port=if0 drop=no - In this example you can see Core 1/Task 0 called ``rx_task`` receives the packet from if0 and perform the l2fwd. However instead of sending the packet to a - port it sends it to a core see ``tx cores=1t1``. In this case it sends it to Core 1/Task 1. + In this example you can see Core 1/Task 0 called ``rx_task`` receives the + packet from if0 and perform the l2fwd. However instead of sending the + packet to a port it sends it to a core see ``tx cores=1t1``. In this case it + sends it to Core 1/Task 1. - Core 1/Task 1 called ``l2fwd_if0``, receives the packet, not from a port but from the ring. See ``rx ring=yes``. It does not perform any operation on the packet See ``mode=none`` - and sends the packets to ``if0`` see ``tx port=if0``. + Core 1/Task 1 called ``l2fwd_if0``, receives the packet, not from a port but + from the ring. See ``rx ring=yes``. It does not perform any operation on the + packet See ``mode=none`` and sends the packets to ``if0`` see + ``tx port=if0``. - It is also possible to implement more complex operations be chaining multiple operations in sequence and using rings to pass packets from one core to another. + It is also possible to implement more complex operations by chaining + multiple operations in sequence and using rings to pass packets from one + core to another. - In thus example we show a Broadband Network Gateway (BNG) with Quality of Service (QoS). Communication from task to task is via rings. + In this example, we show a Broadband Network Gateway (BNG) with Quality of + Service (QoS). Communication from task to task is via rings. .. image:: images/PROX_BNG_QOS.png :width: 1000px @@ -848,26 +897,36 @@ Now let's examine the components of the file in detail .. _baremetal-config-label: -This is required for baremetal testing. It describes the IP address of the various ports, the Network devices drivers and MAC addresses and the network +This is required for baremetal testing. It describes the IP address of the +various ports, the Network devices drivers and MAC addresses and the network configuration. -In this example we will describe a 2 port configuration. This file is the same for all 2 port NSB Prox tests on the same platforms/configuration. +In this example we will describe a 2 port configuration. This file is the same +for all 2 port NSB Prox tests on the same platforms/configuration. .. image:: images/PROX_Baremetal_config.png :width: 1000px :alt: NSB PROX Yardstick Config -Now lets describe the sections of the file. - - 1. ``TrafficGen`` - This section describes the Traffic Generator node of the test configuration. The name of the node ``trafficgen_1`` must match the node name - in the ``Test Description File for Baremetal`` mentioned earlier. The password attribute of the test needs to be configured. All other parameters - can remain as default settings. - 2. ``interfaces`` - This defines the DPDK interfaces on the Traffic Generator. - 3. ``xe0`` is DPDK Port 0. ``lspci`` and `` ./dpdk-devbind.py -s`` can be used to provide the interface information. ``netmask`` and ``local_ip`` should not be changed - 4. ``xe1`` is DPDK Port 1. If more than 2 ports are required then ``xe1`` section needs to be repeated and modified accordingly. - 5. ``vnf`` - This section describes the SUT of the test configuration. The name of the node ``vnf`` must match the node name in the - ``Test Description File for Baremetal`` mentioned earlier. The password attribute of the test needs to be configured. All other parameters - can remain as default settings +Now let's describe the sections of the file. + + 1. ``TrafficGen`` - This section describes the Traffic Generator node of the + test configuration. The name of the node ``trafficgen_1`` must match the + node name in the ``Test Description File for Baremetal`` mentioned + earlier. The password attribute of the test needs to be configured. All + other parameters can remain as default settings. + 2. ``interfaces`` - This defines the DPDK interfaces on the Traffic + Generator. + 3. ``xe0`` is DPDK Port 0. ``lspci`` and ``./dpdk-devbind.py -s`` can be used + to provide the interface information. ``netmask`` and ``local_ip`` should + not be changed + 4. ``xe1`` is DPDK Port 1. If more than 2 ports are required then ``xe1`` + section needs to be repeated and modified accordingly. + 5. ``vnf`` - This section describes the SUT of the test configuration. The + name of the node ``vnf`` must match the node name in the + ``Test Description File for Baremetal`` mentioned earlier. The password + attribute of the test needs to be configured. All other parameters can + remain as default settings 6. ``interfaces`` - This defines the DPDK interfaces on the SUT 7. ``xe0`` - Same as 3 but for the ``SUT``. 8. ``xe1`` - Same as 4 but for the ``SUT`` also. @@ -877,11 +936,13 @@ Now lets describe the sections of the file. *Grafana Dashboard* ------------------- -The grafana dashboard visually displays the results of the tests. The steps required to produce a grafana dashboard are described here. +The grafana dashboard visually displays the results of the tests. The steps +required to produce a grafana dashboard are described here. .. _yardstick-config-label: - a. Configure ``yardstick`` to use influxDB to store test results. See file ``/etc/yardstick/yardstick.conf``. + a. Configure ``yardstick`` to use influxDB to store test results. See file + ``/etc/yardstick/yardstick.conf``. .. image:: images/PROX_Yardstick_config.png :width: 1000px @@ -890,10 +951,12 @@ The grafana dashboard visually displays the results of the tests. The steps requ 1. Specify the dispatcher to use influxDB to store results. 2. "target = .. " - Specify location of influxDB to store results. "db_name = yardstick" - name of database. Do not change - "username = root" - username to use to store result. (Many tests are run as root) + "username = root" - username to use to store result. (Many tests are + run as root) "password = ... " - Please set to root user password - b. Deploy InfludDB & Grafana. See how to Deploy InfluxDB & Grafana. See `grafana deployment`_. + b. Deploy InfludDB & Grafana. See how to Deploy InfluxDB & Grafana. See + `grafana deployment`_. c. Generate the test data. Run the tests as follows .:: yardstick --debug task start tc_prox_<context>_<test>-ports.yaml @@ -910,7 +973,8 @@ How to run NSB Prox Test on an baremetal environment In order to run the NSB PROX test. - 1. Install NSB on Traffic Generator node and Prox in SUT. See `NSB Installation`_ + 1. Install NSB on Traffic Generator node and Prox in SUT. See + `NSB Installation`_ 2. To enter container:: @@ -922,8 +986,8 @@ In order to run the NSB PROX test. cd /home/opnfv/repos/yardstick/samples/vnf_samples/nsut/prox - b. Install prox-baremetal-2.yam and prox-baremetal-4.yaml for that topology - into this directory as per baremetal-config-label_ + b. Install prox-baremetal-2.yam and prox-baremetal-4.yaml for that + topology into this directory as per baremetal-config-label_ c. Install and configure ``yardstick.conf`` :: @@ -971,7 +1035,8 @@ Here is a list of frequently asked questions. *NSB Prox does not work on Baremetal, How do I resolve this?* ------------------------------------------------------------- -If PROX NSB does not work on baremetal, problem is either in network configuration or test file. +If PROX NSB does not work on baremetal, problem is either in network +configuration or test file. *Solution* @@ -1011,8 +1076,8 @@ If PROX NSB does not work on baremetal, problem is either in network configurati See ``Link detected`` if ``yes`` .... Cable is good. If ``no`` you have an issue with your cable/port. -2. If existing baremetal works then issue is with your test. Check the traffic generator gen_<test>-<ports>.cfg to ensure - it is producing a valid packet. +2. If existing baremetal works then issue is with your test. Check the traffic + generator gen_<test>-<ports>.cfg to ensure it is producing a valid packet. *How do I debug NSB Prox on Baremetal?* --------------------------------------- @@ -1033,7 +1098,8 @@ If PROX NSB does not work on baremetal, problem is either in network configurati cd /opt/nsb_bin/prox -f /tmp/handle_<test>-<ports>.cfg -4. Now let's examine the Generator Output. In this case the output of gen_l2fwd-4.cfg. +4. Now let's examine the Generator Output. In this case the output of + ``gen_l2fwd-4.cfg``. .. image:: images/PROX_Gen_GUI.png :width: 1000px @@ -1048,10 +1114,12 @@ If PROX NSB does not work on baremetal, problem is either in network configurati It appears what is transmitted is received. .. Caution:: - The number of packets MAY not exactly match because the ports are read in sequence. + The number of packets MAY not exactly match because the ports are read in + sequence. .. Caution:: - What is transmitted on PORT X may not always be received on same port. Please check the Test scenario. + What is transmitted on PORT X may not always be received on same port. + Please check the Test scenario. 5. Now lets examine the SUT Output @@ -1083,17 +1151,18 @@ If PROX NSB does not work on baremetal, problem is either in network configurati *NSB Prox works on Baremetal but not in Openstack. How do I resolve this?* -------------------------------------------------------------------------- -NSB Prox on Baremetal is a lot more forgiving than NSB Prox on Openstack. A badly -formed packed may still work with PROX on Baremetal. However on +NSB Prox on Baremetal is a lot more forgiving than NSB Prox on Openstack. A +badly formed packed may still work with PROX on Baremetal. However on Openstack the packet must be correct and all fields of the header correct. -Eg A packet with an invalid Protocol ID would still work in Baremetal -but this packet would be rejected by openstack. +E.g. A packet with an invalid Protocol ID would still work in Baremetal but +this packet would be rejected by openstack. *Solution* 1. Check the validity of the packet. 2. Use a known good packet in your test - 3. If using ``Random`` fields in the traffic generator, disable them and retry. + 3. If using ``Random`` fields in the traffic generator, disable them and + retry. *How do I debug NSB Prox on Openstack?* @@ -1111,7 +1180,8 @@ but this packet would be rejected by openstack. 3. Install openstack credentials. - Depending on your openstack deployment, the location of these credentials may vary. + Depending on your openstack deployment, the location of these credentials + may vary. On this platform I do this via:: scp root@10.237.222.55:/etc/kolla/admin-openrc.sh . @@ -1127,8 +1197,8 @@ but this packet would be rejected by openstack. b. Get the Floating IP of the Traffic Generator & SUT - This generates a lot of information. Please not the floating IP of the VNF and - the Traffic Generator. + This generates a lot of information. Please note the floating IP of the + VNF and the Traffic Generator. .. image:: images/PROX_Openstack_stack_show_a.png :width: 1000px @@ -1215,7 +1285,8 @@ If it fails due to :: Missing value auth-url required for auth plugin password -Check your shell environment for Openstack variables. One of them should contain the authentication URL :: +Check your shell environment for Openstack variables. One of them should +contain the authentication URL :: OS_AUTH_URL=``https://192.168.72.41:5000/v3`` @@ -1239,16 +1310,16 @@ Result :: and visible. -If the Openstack Cli appears to hang, then verify the proxys and no_proxy are set correctly. -They should be similar to :: +If the Openstack ClI appears to hang, then verify the proxys and ``no_proxy`` +are set correctly. They should be similar to :: - FTP_PROXY="http://proxy.ir.intel.com:911/" - HTTPS_PROXY="http://proxy.ir.intel.com:911/" - HTTP_PROXY="http://proxy.ir.intel.com:911/" + FTP_PROXY="http://<your_proxy>:<port>/" + HTTPS_PROXY="http://<your_proxy>:<port>/" + HTTP_PROXY="http://<your_proxy>:<port>/" NO_PROXY="localhost,127.0.0.1,10.237.222.55,10.237.223.80,10.237.222.134,.ir.intel.com" - ftp_proxy="http://proxy.ir.intel.com:911/" - http_proxy="http://proxy.ir.intel.com:911/" - https_proxy="http://proxy.ir.intel.com:911/" + ftp_proxy="http://<your_proxy>:<port>/" + http_proxy="http://<your_proxy>:<port>/" + https_proxy="http://<your_proxy>:<port>/" no_proxy="localhost,127.0.0.1,10.237.222.55,10.237.223.80,10.237.222.134,.ir.intel.com" Where @@ -1256,8 +1327,6 @@ Where 1) 10.237.222.55 = IP Address of deployment node 2) 10.237.223.80 = IP Address of Controller node 3) 10.237.222.134 = IP Address of Compute Node - 4) ir.intel.com = local no proxy - *How to Understand the Grafana output?* --------------------------------------- @@ -1280,48 +1349,48 @@ Where A. Test Parameters - Test interval, Duartion, Tolerated Loss and Test Precision -B. Overall No of packets send and received during test +B. No. of packets send and received during test C. Generator Stats - packets sent, received and attempted by Generator -D. Packets Size - -E. No of packets received by SUT - -F. No of packets forwarded by SUT - -G. This is the number of packets sent by the generator per port, for each interval. +D. Packet size -H. This is the number of packets received by the generator per port, for each interval. +E. No. of packets received by SUT -I. This is the number of packets send and received by the generator and lost by the SUT - that meet the success criteria +F. No. of packets forwarded by SUT -J. This is the changes the Percentage of Line Rate used over a test, The MAX and the - MIN should converge to within the interval specified as the ``test-precision``. +G. No. of packets sent by the generator per port, for each interval. -K. This is the packets Size supported during test. If "N/A" appears in any field the result has not been decided. +H. No. of packets received by the generator per port, for each interval. -L. This is the calculated throughput in MPPS(Million Packets Per second) for this line rate. +I. No. of packets sent and received by the generator and lost by the SUT that + meet the success criteria -M. This is the actual No, of packets sent by the generator in MPPS +J. The change in the Percentage of Line Rate used over a test, The MAX and the + MIN should converge to within the interval specified as the + ``test-precision``. -N. This is the actual No. of packets received by the generator in MPPS +K. Packet size supported during test. If *N/A* appears in any field the + result has not been decided. -O. This is the total No. of packets sent by SUT. +L. Calculated throughput in MPPS (Million Packets Per second) for this line + rate. -P. This is the total No. of packets received by the SUT +M. No. of packets sent by the generator in MPPS -Q. This is the total No. of packets dropped. (These packets were sent by the generator but not - received back by the generator, these may be dropped by the SUT or the Generator) +N. No. of packets received by the generator in MPPS -R. This is the tolerated no of packets that can be dropped. +O. No. of packets sent by SUT. -S. This is the test Throughput in Gbps +P. No. of packets received by the SUT -T. This is the Latencey per Port +Q. Total no. of dropped packets -- Packets sent but not received back by the + generator, these may be dropped by the SUT or the generator. -U. This is the CPU Utilization +R. The tolerated no. of dropped packets. +S. Test throughput in Gbps +T. Latencey per Port +U. CPU Utilization |