summaryrefslogtreecommitdiffstats
path: root/kernel/tools/power/cpupower/utils/idle_monitor/cpupower-monitor.h
blob: 9e43f3371fbc625eaabaaeb941ae3a14a732ff7f (plain) 
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85

/*
 *  (C) 2010,2011       Thomas Renninger <trenn@suse.de>, Novell Inc.
 *
 *  Licensed under the terms of the GNU GPL License version 2.
 *
 */

#ifndef __CPUIDLE_INFO_HW__
#define __CPUIDLE_INFO_HW__

#include <stdarg.h>
#include <time.h>

#include "idle_monitor/idle_monitors.h"

#define MONITORS_MAX 20
#define MONITOR_NAME_LEN 20
#define CSTATE_NAME_LEN 5
#define CSTATE_DESC_LEN 60

int cpu_count;

/* Hard to define the right names ...: */
enum power_range_e {
	RANGE_THREAD,	/* Lowest in topology hierarcy, AMD: core, Intel: thread
			   kernel sysfs: cpu */
	RANGE_CORE,	/* AMD: unit, Intel: core, kernel_sysfs: core_id */
	RANGE_PACKAGE,	/* Package, processor socket */
	RANGE_MACHINE,	/* Machine, platform wide */
	RANGE_MAX };

typedef struct cstate {
	int  id;
	enum power_range_e range;
	char name[CSTATE_NAME_LEN];
	char desc[CSTATE_DESC_LEN];

	/* either provide a percentage or a general count */
	int (*get_count_percent)(unsigned int self_id, double *percent,
				 unsigned int cpu);
	int (*get_count)(unsigned int self_id, unsigned long long *count,
			 unsigned int cpu);
} cstate_t;

struct cpuidle_monitor {
	/* Name must not contain whitespaces */
	char name[MONITOR_NAME_LEN];
	int name_len;
	int hw_states_num;
	cstate_t *hw_states;
	int (*start) (void);
	int (*stop) (void);
	struct cpuidle_monitor* (*do_register) (void);
	void (*unregister)(void);
	unsigned int overflow_s;
	int needs_root;
};

extern long long timespec_diff_us(struct timespec start, struct timespec end);

#define print_overflow_err(mes, ov)						\
{										\
	fprintf(stderr, gettext("Measure took %u seconds, but registers could "	\
				"overflow at %u seconds, results "		\
				"could be inaccurate\n"), mes, ov);		\
}


/* Taken over from x86info project sources  -> return 0 on success */
#include <sched.h>
#include <sys/types.h>
#include <unistd.h>
static inline int bind_cpu(int cpu)
{
	cpu_set_t set;

	if (sched_getaffinity(getpid(), sizeof(set), &set) == 0) {
		CPU_ZERO(&set);
		CPU_SET(cpu, &set);
		return sched_setaffinity(getpid(), sizeof(set), &set);
	}
	return 1;
}

#endif /* __CPUIDLE_INFO_HW__ */
ble.Global */ .highlight .vi { color: #f8f8f2 } /* Name.Variable.Instance */ .highlight .vm { color: #f8f8f2 } /* Name.Variable.Magic */ .highlight .il { color: #ae81ff } /* Literal.Number.Integer.Long */ } @media (prefers-color-scheme: light) { .highlight .hll { background-color: #ffffcc } .highlight .c { color: #888888 } /* Comment */ .highlight .err { color: #a61717; background-color: #e3d2d2 } /* Error */ .highlight .k { color: #008800; font-weight: bold } /* Keyword */ .highlight .ch { color: #888888 } /* Comment.Hashbang */ .highlight .cm { color: #888888 } /* Comment.Multiline */ .highlight .cp { color: #cc0000; font-weight: bold } /* Comment.Preproc */ .highlight .cpf { color: #888888 } /* Comment.PreprocFile */ .highlight .c1 { color: #888888 } /* Comment.Single */ .highlight .cs { color: #cc0000; font-weight: bold; background-color: #fff0f0 } /* Comment.Special */ .highlight .gd { color: #000000; background-color: #ffdddd } /* Generic.Deleted */ .highlight .ge { font-style: italic } /* Generic.Emph */ .highlight .gr { color: #aa0000 } /* Generic.Error */ .highlight .gh { color: #333333 } /* Generic.Heading */ .highlight .gi { color: #000000; background-color: #ddffdd } /* Generic.Inserted */ .highlight .go { color: #888888 } /* Generic.Output */ .highlight .gp { color: #555555 } /* Generic.Prompt */ .highlight .gs { font-weight: bold } /* Generic.Strong */ .highlight .gu { color: #666666 } /* Generic.Subheading */ .highlight .gt { color: #aa0000 } /* Generic.Traceback */ .highlight .kc { color: #008800; font-weight: bold } /* Keyword.Constant */ .highlight .kd { color: #008800; font-weight: bold } /* Keyword.Declaration */ .highlight .kn { color: #008800; font-weight: bold } /* Keyword.Namespace */ .highlight .kp { color: #008800 } /* Keyword.Pseudo */ .highlight .kr { color: #008800; font-weight: bold } /* Keyword.Reserved */ .highlight .kt { color: #888888; font-weight: bold } /* Keyword.Type */ .highlight .m { color: #0000DD; font-weight: bold } /* Literal.Number */ .highlight .s { color: #dd2200; background-color: #fff0f0 } /* Literal.String */ .highlight .na { color: #336699 } /* Name.Attribute */ .highlight .nb { color: #003388 } /* Name.Builtin */ .highlight .nc { color: #bb0066; font-weight: bold } /* Name.Class */ .highlight .no { color: #003366; font-weight: bold } /* Name.Constant */ .highlight .nd { color: #555555 } /* Name.Decorator */ .highlight .ne { color: #bb0066; font-weight: bold } /* Name.Exception */ .highlight .nf { color: #0066bb; font-weight: bold } /* Name.Function */ .highlight .nl { color: #336699; font-style: italic } /* Name.Label */ .highlight .nn { color: #bb0066; font-weight: bold } /* Name.Namespace */ .highlight .py { color: #336699; font-weight: bold } /* Name.Property */ .highlight .nt { color: #bb0066; font-weight: bold } /* Name.Tag */ .highlight .nv { color: #336699 } /* Name.Variable */ .highlight .ow { color: #008800 } /* Operator.Word */ .highlight .w { color: #bbbbbb } /* Text.Whitespace */ .highlight .mb { color: #0000DD; font-weight: bold } /* Literal.Number.Bin */ .highlight .mf { color: #0000DD; font-weight: bold } /* Literal.Number.Float */ .highlight .mh { color: #0000DD; font-weight: bold } /* Literal.Number.Hex */ .highlight .mi { color: #0000DD; font-weight: bold } /* Literal.Number.Integer */ .highlight .mo { color: #0000DD; font-weight: bold } /* Literal.Number.Oct */ .highlight .sa { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Affix */ .highlight .sb { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Backtick */ .highlight .sc { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Char */ .highlight .dl { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Delimiter */ .highlight .sd { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Doc */ .highlight .s2 { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Double */ .highlight .se { color: #0044dd; background-color: #fff0f0 } /* Literal.String.Escape */ .highlight .sh { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Heredoc */ .highlight .si { color: #3333bb; background-color: #fff0f0 } /* Literal.String.Interpol */ .highlight .sx { color: #22bb22; background-color: #f0fff0 } /* Literal.String.Other */ .highlight .sr { color: #008800; background-color: #fff0ff } /* Literal.String.Regex */ .highlight .s1 { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Single */ .highlight .ss { color: #aa6600; background-color: #fff0f0 } /* Literal.String.Symbol */ .highlight .bp { color: #003388 } /* Name.Builtin.Pseudo */ .highlight .fm { color: #0066bb; font-weight: bold } /* Name.Function.Magic */ .highlight .vc { color: #336699 } /* Name.Variable.Class */ .highlight .vg { color: #dd7700 } /* Name.Variable.Global */ .highlight .vi { color: #3333bb } /* Name.Variable.Instance */ .highlight .vm { color: #336699 } /* Name.Variable.Magic */ .highlight .il { color: #0000DD; font-weight: bold } /* Literal.Number.Integer.Long */ } 
.. This work is licensed under a Creative Commons Attribution 4.0 International License.
.. http://creativecommons.org/licenses/by/4.0
.. (c) OPNFV, Intel Corporation, AT&T and others.

Integration tests
=================

VSPERF includes a set of integration tests defined in conf/integration.
These tests can be run by specifying --integration as a parameter to vsperf.
Current tests in conf/integration include switch functionality and Overlay
tests.

Tests in the conf/integration can be used to test scaling of different switch
configurations by adding steps into the test case.

For the overlay tests VSPERF supports VXLAN, GRE and GENEVE tunneling protocols.
Testing of these protocols is limited to unidirectional traffic and
P2P (Physical to Physical scenarios).

NOTE: The configuration for overlay tests provided in this guide is for
unidirectional traffic only.

Executing Integration Tests
---------------------------

To execute integration tests VSPERF is run with the integration parameter. To
view the current test list simply execute the following command:

.. code-block:: console

    ./vsperf --integration --list

The standard tests included are defined inside the
``conf/integration/01_testcases.conf`` file.

Test Steps
----------

Execution of integration tests are done on a step by step work flow starting
with step 0 as defined inside the test case. Each step of the test increments
the step number by one which is indicated in the log.

.. code-block:: console

    (testcases.integration) - Step 1 - 'vswitch add_switch ['int_br1']' ... OK

Each step in the test case is validated. If a step does not pass validation the
test will fail and terminate. The test will continue until a failure is detected
or all steps pass. A csv report file is generated after a test completes with an
OK or FAIL result.

Test Macros
-----------

Test profiles can include macros as part of the test step. Each step in the
profile may return a value such as a port name. Recall macros use #STEP to
indicate the recalled value inside the return structure. If the method the
test step calls returns a value it can be later recalled, for example:

.. code-block:: python

    {
        "Name": "vswitch_add_del_vport",
        "Deployment": "clean",
        "Description": "vSwitch - add and delete virtual port",
        "TestSteps": [
                ['vswitch', 'add_switch', 'int_br0'],               # STEP 0
                ['vswitch', 'add_vport', 'int_br0'],                # STEP 1
                ['vswitch', 'del_port', 'int_br0', '#STEP[1][0]'],  # STEP 2
                ['vswitch', 'del_switch', 'int_br0'],               # STEP 3
             ]
    }

This test profile uses the the vswitch add_vport method which returns a string
value of the port added. This is later called by the del_port method using the
name from step 1.

Also commonly used steps can be created as a separate profile.

.. code-block:: python

    STEP_VSWITCH_PVP_INIT = [
        ['vswitch', 'add_switch', 'int_br0'],           # STEP 0
        ['vswitch', 'add_phy_port', 'int_br0'],         # STEP 1
        ['vswitch', 'add_phy_port', 'int_br0'],         # STEP 2
        ['vswitch', 'add_vport', 'int_br0'],            # STEP 3
        ['vswitch', 'add_vport', 'int_br0'],            # STEP 4
    ]

This profile can then be used inside other testcases

.. code-block:: python

    {
        "Name": "vswitch_pvp",
        "Deployment": "clean",
        "Description": "vSwitch - configure switch and one vnf",
        "TestSteps": STEP_VSWITCH_PVP_INIT +
                     [
                        ['vnf', 'start'],
                        ['vnf', 'stop'],
                     ] +
                     STEP_VSWITCH_PVP_FINIT
    }

Executing Tunnel encapsulation tests
------------------------------------

The VXLAN OVS DPDK encapsulation tests requires IPs, MAC addresses,
bridge names and WHITELIST_NICS for DPDK.

Default values are already provided. To customize for your environment, override
the following variables in you user_settings.py file:

  .. code-block:: python

    # Variables defined in conf/integration/02_vswitch.conf
    # Tunnel endpoint for Overlay P2P deployment scenario
    # used for br0
    VTEP_IP1 = '192.168.0.1/24'

    # Used as remote_ip in adding OVS tunnel port and
    # to set ARP entry in OVS (e.g. tnl/arp/set br-ext 192.168.240.10 02:00:00:00:00:02
    VTEP_IP2 = '192.168.240.10'

    # Network to use when adding a route for inner frame data
    VTEP_IP2_SUBNET = '192.168.240.0/24'

    # Bridge names
    TUNNEL_INTEGRATION_BRIDGE = 'br0'
    TUNNEL_EXTERNAL_BRIDGE = 'br-ext'

    # IP of br-ext
    TUNNEL_EXTERNAL_BRIDGE_IP = '192.168.240.1/24'

    # vxlan|gre|geneve
    TUNNEL_TYPE = 'vxlan'

    # Variables defined conf/integration/03_traffic.conf
    # For OP2P deployment scenario
    TRAFFICGEN_PORT1_MAC = '02:00:00:00:00:01'
    TRAFFICGEN_PORT2_MAC = '02:00:00:00:00:02'
    TRAFFICGEN_PORT1_IP = '1.1.1.1'
    TRAFFICGEN_PORT2_IP = '192.168.240.10'

To run VXLAN encapsulation tests:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --integration
             --test-params 'tunnel_type=vxlan' overlay_p2p_tput

To run GRE encapsulation tests:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --integration
             --test-params 'tunnel_type=gre' overlay_p2p_tput

To run GENEVE encapsulation tests:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --integration
             --test-params 'tunnel_type=geneve' overlay_p2p_tput

To run OVS NATIVE tunnel tests (VXLAN/GRE/GENEVE):

1. Install the OVS kernel modules

  .. code:: console

    cd src/ovs/ovs
    sudo -E make modules_install

2. Set the following variables:

  .. code-block:: python

    VSWITCH = 'OvsVanilla'
    # Specify vport_* kernel module to test.
    VSWITCH_VANILLA_KERNEL_MODULES = ['vport_vxlan',
                                      'vport_gre',
                                      'vport_geneve',
                                      os.path.join(OVS_DIR_VANILLA,
                                      'datapath/linux/openvswitch.ko')]

3. Run tests:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --integration
             --test-params 'tunnel_type=vxlan' overlay_p2p_tput


Executing VXLAN decapsulation tests
------------------------------------

To run VXLAN decapsulation tests:

1. Set the variables used in "Executing Tunnel encapsulation tests"

2. Set dstmac of DUT_NIC2_MAC to the MAC adddress of the 2nd NIC of your DUT

  .. code-block:: python

    DUT_NIC2_MAC = '<DUT NIC2 MAC>'

3. Run test:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --integration overlay_p2p_decap_cont

If you want to use different values for your VXLAN frame, you may set:

  .. code-block:: python

    VXLAN_FRAME_L3 = {'proto': 'udp',
                      'packetsize': 64,
                      'srcip': TRAFFICGEN_PORT1_IP,
                      'dstip': '192.168.240.1',
                     }
    VXLAN_FRAME_L4 = {'srcport': 4789,
                      'dstport': 4789,
                      'vni': VXLAN_VNI,
                      'inner_srcmac': '01:02:03:04:05:06',
                      'inner_dstmac': '06:05:04:03:02:01',
                      'inner_srcip': '192.168.0.10',
                      'inner_dstip': '192.168.240.9',
                      'inner_proto': 'udp',
                      'inner_srcport': 3000,
                      'inner_dstport': 3001,
                     }


Executing GRE decapsulation tests
---------------------------------

To run GRE decapsulation tests:

1. Set the variables used in "Executing Tunnel encapsulation tests"

2. Set dstmac of DUT_NIC2_MAC to the MAC adddress of the 2nd NIC of your DUT

  .. code-block:: python

    DUT_NIC2_MAC = '<DUT NIC2 MAC>'

3. Run test:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --test-params 'tunnel_type=gre'
             --integration overlay_p2p_decap_cont


If you want to use different values for your GRE frame, you may set:

  .. code-block:: python

    GRE_FRAME_L3 = {'proto': 'gre',
                    'packetsize': 64,
                    'srcip': TRAFFICGEN_PORT1_IP,
                    'dstip': '192.168.240.1',
                   }

    GRE_FRAME_L4 = {'srcport': 0,
                    'dstport': 0
                    'inner_srcmac': '01:02:03:04:05:06',
                    'inner_dstmac': '06:05:04:03:02:01',
                    'inner_srcip': '192.168.0.10',
                    'inner_dstip': '192.168.240.9',
                    'inner_proto': 'udp',
                    'inner_srcport': 3000,
                    'inner_dstport': 3001,
                   }


Executing GENEVE decapsulation tests
------------------------------------

IxNet 7.3X does not have native support of GENEVE protocol. The
template, GeneveIxNetTemplate.xml_ClearText.xml, should be imported
into IxNET for this testcase to work.

To import the template do:

1. Run the IxNetwork TCL Server
2. Click on the Traffic menu
3. Click on the Traffic actions and click Edit Packet Templates
4. On the Template editor window, click Import. Select the template
   tools/pkt_gen/ixnet/GeneveIxNetTemplate.xml_ClearText.xml
   and click import.
5. Restart the TCL Server.

To run GENEVE decapsulation tests:

1. Set the variables used in "Executing Tunnel encapsulation tests"

2. Set dstmac of DUT_NIC2_MAC to the MAC adddress of the 2nd NIC of your DUT

  .. code-block:: python

    DUT_NIC2_MAC = '<DUT NIC2 MAC>'

3. Run test:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --test-params 'tunnel_type=geneve'
             --integration overlay_p2p_decap_cont


If you want to use different values for your GENEVE frame, you may set:

  .. code-block:: python

    GENEVE_FRAME_L3 = {'proto': 'udp',
                       'packetsize': 64,
                       'srcip': TRAFFICGEN_PORT1_IP,
                       'dstip': '192.168.240.1',
                      }

    GENEVE_FRAME_L4 = {'srcport': 6081,
                       'dstport': 6081,
                       'geneve_vni': 0,
                       'inner_srcmac': '01:02:03:04:05:06',
                       'inner_dstmac': '06:05:04:03:02:01',
                       'inner_srcip': '192.168.0.10',
                       'inner_dstip': '192.168.240.9',
                       'inner_proto': 'udp',
                       'inner_srcport': 3000,
                       'inner_dstport': 3001,
                      }


Executing Native/Vanilla OVS VXLAN decapsulation tests
------------------------------------------------------

To run VXLAN decapsulation tests:

1. Set the following variables in your user_settings.py file:

  .. code-block:: python

    VSWITCH_VANILLA_KERNEL_MODULES = ['vport_vxlan',
                                      os.path.join(OVS_DIR_VANILLA,
                                      'datapath/linux/openvswitch.ko')]

    DUT_NIC1_MAC = '<DUT NIC1 MAC ADDRESS>'

    TRAFFICGEN_PORT1_IP = '172.16.1.2'
    TRAFFICGEN_PORT2_IP = '192.168.1.11'

    VTEP_IP1 = '172.16.1.2/24'
    VTEP_IP2 = '192.168.1.1'
    VTEP_IP2_SUBNET = '192.168.1.0/24'
    TUNNEL_EXTERNAL_BRIDGE_IP = '172.16.1.1/24'
    TUNNEL_INT_BRIDGE_IP = '192.168.1.1'

    VXLAN_FRAME_L2 = {'srcmac':
                      '01:02:03:04:05:06',
                      'dstmac': DUT_NIC1_MAC
                     }

    VXLAN_FRAME_L3 = {'proto': 'udp',
                      'packetsize': 64,
                      'srcip': TRAFFICGEN_PORT1_IP,
                      'dstip': '172.16.1.1',
                     }

    VXLAN_FRAME_L4 = {
                      'srcport': 4789,
                      'dstport': 4789,
                      'protocolpad': 'true',
                      'vni': 99,
                      'inner_srcmac': '01:02:03:04:05:06',
                      'inner_dstmac': '06:05:04:03:02:01',
                      'inner_srcip': '192.168.1.2',
                      'inner_dstip': TRAFFICGEN_PORT2_IP,
                      'inner_proto': 'udp',
                      'inner_srcport': 3000,
                      'inner_dstport': 3001,
                     }

2. Run test:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --integration
             --test-params 'tunnel_type=vxlan' overlay_p2p_decap_cont

Executing Native/Vanilla OVS GRE decapsulation tests
----------------------------------------------------

To run GRE decapsulation tests:

1. Set the following variables in your user_settings.py file:

  .. code-block:: python

    VSWITCH_VANILLA_KERNEL_MODULES = ['vport_gre',
                                      os.path.join(OVS_DIR_VANILLA,
                                      'datapath/linux/openvswitch.ko')]

    DUT_NIC1_MAC = '<DUT NIC1 MAC ADDRESS>'

    TRAFFICGEN_PORT1_IP = '172.16.1.2'
    TRAFFICGEN_PORT2_IP = '192.168.1.11'

    VTEP_IP1 = '172.16.1.2/24'
    VTEP_IP2 = '192.168.1.1'
    VTEP_IP2_SUBNET = '192.168.1.0/24'
    TUNNEL_EXTERNAL_BRIDGE_IP = '172.16.1.1/24'
    TUNNEL_INT_BRIDGE_IP = '192.168.1.1'

    GRE_FRAME_L2 = {'srcmac':
                    '01:02:03:04:05:06',
                    'dstmac': DUT_NIC1_MAC
                   }

    GRE_FRAME_L3 = {'proto': 'udp',
                    'packetsize': 64,
                    'srcip': TRAFFICGEN_PORT1_IP,
                    'dstip': '172.16.1.1',
                   }

    GRE_FRAME_L4 = {
                    'srcport': 4789,
                    'dstport': 4789,
                    'protocolpad': 'true',
                    'inner_srcmac': '01:02:03:04:05:06',
                    'inner_dstmac': '06:05:04:03:02:01',
                    'inner_srcip': '192.168.1.2',
                    'inner_dstip': TRAFFICGEN_PORT2_IP,
                    'inner_proto': 'udp',
                    'inner_srcport': 3000,
                    'inner_dstport': 3001,
                   }

2. Run test:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --integration
             --test-params 'tunnel_type=gre' overlay_p2p_decap_cont

Executing Native/Vanilla OVS GENEVE decapsulation tests
-------------------------------------------------------

To run GENEVE decapsulation tests:

1. Set the following variables in your user_settings.py file:

  .. code-block:: python

    VSWITCH_VANILLA_KERNEL_MODULES = ['vport_geneve',
                                      os.path.join(OVS_DIR_VANILLA,
                                      'datapath/linux/openvswitch.ko')]

    DUT_NIC1_MAC = '<DUT NIC1 MAC ADDRESS>'

    TRAFFICGEN_PORT1_IP = '172.16.1.2'
    TRAFFICGEN_PORT2_IP = '192.168.1.11'

    VTEP_IP1 = '172.16.1.2/24'
    VTEP_IP2 = '192.168.1.1'
    VTEP_IP2_SUBNET = '192.168.1.0/24'
    TUNNEL_EXTERNAL_BRIDGE_IP = '172.16.1.1/24'
    TUNNEL_INT_BRIDGE_IP = '192.168.1.1'

    GENEVE_FRAME_L2 = {'srcmac':
                       '01:02:03:04:05:06',
                       'dstmac': DUT_NIC1_MAC
                      }

    GENEVE_FRAME_L3 = {'proto': 'udp',
                       'packetsize': 64,
                       'srcip': TRAFFICGEN_PORT1_IP,
                       'dstip': '172.16.1.1',
                      }

    GENEVE_FRAME_L4 = {'srcport': 6081,
                       'dstport': 6081,
                       'protocolpad': 'true',
                       'geneve_vni': 0,
                       'inner_srcmac': '01:02:03:04:05:06',
                       'inner_dstmac': '06:05:04:03:02:01',
                       'inner_srcip': '192.168.1.2',
                       'inner_dstip': TRAFFICGEN_PORT2_IP,
                       'inner_proto': 'udp',
                       'inner_srcport': 3000,
                       'inner_dstport': 3001,
                      }

2. Run test:

  .. code-block:: console

    ./vsperf --conf-file user_settings.py --integration
             --test-params 'tunnel_type=geneve' overlay_p2p_decap_cont