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#!/usr/bin/env python
## @file test_l2bd.py
# Module to provide L2 bridge domain test case.
#
# The module provides a set of tools for L2 bridge domain tests.
import logging
logging.getLogger("scapy.runtime").setLevel(logging.ERROR)
import unittest
import random
from framework import *
from scapy.all import *
## Subclass of the VppTestCase class.
#
# This subclass is a class for L2 bridge domain test cases. It provides methods
# to create interfaces, configure L2 bridge domain, create and verify packet
# streams.
class TestL2bd(VppTestCase):
""" L2BD Test Case """
## Test variables
interf_nr = 3 # Number of interfaces
bd_id = 1 # Bridge domain ID
mac_entries = 100 # Number of MAC entries for bridge-domain to learn
dot1q_sub_id = 100 # SubID of dot1q sub-interface
dot1q_tag = 100 # VLAN tag for dot1q sub-interface
dot1ad_sub_id = 200 # SubID of dot1ad sub-interface
dot1ad_outer_tag = 200 # VLAN S-tag for dot1ad sub-interface
dot1ad_inner_tag = 300 # VLAN C-tag for dot1ad sub-interface
pkts_per_burst = 257 # Number of packets per burst
## Class method to start the test case.
# Overrides setUpClass method in VppTestCase class.
# Python try..except statement is used to ensure that the tear down of
# the class will be executed even if exception is raised.
# @param cls The class pointer.
@classmethod
def setUpClass(cls):
super(TestL2bd, cls).setUpClass()
try:
## Create interfaces and sub-interfaces
cls.create_interfaces_and_subinterfaces(TestL2bd.interf_nr)
## Create BD with MAC learning enabled and put interfaces and
# sub-interfaces to this BD
cls.api("bridge_domain_add_del bd_id %u learn 1" % TestL2bd.bd_id)
for i in cls.interfaces:
if isinstance(cls.INT_DETAILS[i], cls.Subint):
interface = "pg%u.%u" % (i, cls.INT_DETAILS[i].sub_id)
else:
interface = "pg%u" % i
cls.api("sw_interface_set_l2_bridge %s bd_id %u"
% (interface, TestL2bd.bd_id))
## Make the BD learn a number of MAC entries specified by the test
# variable <mac_entries>.
cls.create_mac_entries(TestL2bd.mac_entries)
cls.cli(0, "show l2fib")
except Exception as e:
super(TestL2bd, cls).tearDownClass()
raise e
## Method to define tear down VPP actions of the test case.
# Overrides tearDown method in VppTestCase class.
# @param self The object pointer.
def tearDown(self):
self.cli(2, "show int")
self.cli(2, "show trace")
self.cli(2, "show hardware")
self.cli(2, "show l2fib verbose")
self.cli(2, "show error")
self.cli(2, "show run")
self.cli(2, "show bridge-domain 1 detail")
## Class method to create VLAN sub-interface.
# Uses VPP API command to create VLAN sub-interface.
# @param cls The class pointer.
# @param pg_index Integer variable to store the index of the packet
# generator interface to create VLAN sub-interface on.
# @param vlan_id Integer variable to store required VLAN tag value.
@classmethod
def create_vlan_subif(cls, pg_index, vlan_id):
cls.api("create_vlan_subif pg%u vlan %u" % (pg_index, vlan_id))
## Class method to create dot1ad sub-interface.
# Use VPP API command to create dot1ad sub-interface.
# @param cls The class pointer.
# @param pg_index Integer variable to store the index of the packet
# generator interface to create dot1ad sub-interface on.
# @param outer_vlan_id Integer variable to store required outer VLAN tag
# value (S-TAG).
# @param inner_vlan_id Integer variable to store required inner VLAN tag
# value (C-TAG).
@classmethod
def create_dot1ad_subif(cls, pg_index, sub_id, outer_vlan_id,
inner_vlan_id):
cls.api("create_subif pg%u sub_id %u outer_vlan_id %u inner_vlan_id"
" %u dot1ad" % (pg_index, sub_id, outer_vlan_id, inner_vlan_id))
## Base class for interface.
# To define object representation of the interface.
class Interface(object):
pass
## Sub-class of the interface class.
# To define object representation of the HW interface.
class HardInt(Interface):
pass
## Sub-class of the interface class.
# To define object representation of the SW interface.
class SoftInt(Interface):
pass
## Sub-class of the SW interface class.
# To represent the general sub-interface.
class Subint(SoftInt):
## The constructor.
# @param sub_id Integer variable to store sub-interface ID.
def __init__(self, sub_id):
self.sub_id = sub_id
## Sub-class of the SW interface class.
# To represent dot1q sub-interface.
class Dot1QSubint(Subint):
## The constructor.
# @param sub_id Integer variable to store sub-interface ID.
# @param vlan Integer variable (optional) to store VLAN tag value. Set
# to sub_id value when VLAN tag value not provided.
def __init__(self, sub_id, vlan=None):
if vlan is None:
vlan = sub_id
super(TestL2bd.Dot1QSubint, self).__init__(sub_id)
self.vlan = vlan
## Sub-class of the SW interface class.
# To represent dot1ad sub-interface.
class Dot1ADSubint(Subint):
## The constructor.
# @param sub_id Integer variable to store sub-interface ID.
# @param outer_vlan Integer variable to store outer VLAN tag value.
# @param inner_vlan Integer variable to store inner VLAN tag value.
def __init__(self, sub_id, outer_vlan, inner_vlan):
super(TestL2bd.Dot1ADSubint, self).__init__(sub_id)
self.outer_vlan = outer_vlan
self.inner_vlan = inner_vlan
## Class method to create interfaces and sub-interfaces.
# Current implementation: create three interfaces, then create Dot1Q
# sub-interfaces for the second and the third interface with VLAN tags
# equal to their sub-interface IDs. Set sub-interfaces status to admin-up.
# @param cls The class pointer.
# @param int_nr Integer variable to store the number of interfaces to be
# created.
# TODO: Parametrize required numbers of dot1q and dot1ad to be created.
@classmethod
def create_interfaces_and_subinterfaces(cls, int_nr):
## A class list variable to store interface indexes.
cls.interfaces = range(int_nr)
# Create interfaces
cls.create_interfaces(cls.interfaces)
# Make vpp_api_test see interfaces created using debug CLI (in function
# create_interfaces)
cls.api("sw_interface_dump")
## A class dictionary variable to store data about interfaces.
# First create an empty dictionary then store interface data there.
cls.INT_DETAILS = dict()
# 1st interface is untagged - no sub-interface required
cls.INT_DETAILS[0] = cls.HardInt()
# 2nd interface is dot1q tagged
cls.INT_DETAILS[1] = cls.Dot1QSubint(TestL2bd.dot1q_sub_id,
TestL2bd.dot1q_tag)
cls.create_vlan_subif(1, cls.INT_DETAILS[1].vlan)
# 3rd interface is dot1ad tagged
# FIXME: Wrong packet format/wrong layer on output of interface 2
#self.INT_DETAILS[2] = self.Dot1ADSubint(TestL2bd.dot1ad_sub_id, TestL2bd.dot1ad_outer_tag, TestL2bd.dot1ad_inner_tag)
#self.create_dot1ad_subif(2, self.INT_DETAILS[2].sub_id, self.INT_DETAILS[2].outer_vlan, self.INT_DETAILS[2].inner_vlan)
# Use dot1q for now.
cls.INT_DETAILS[2] = cls.Dot1QSubint(TestL2bd.dot1ad_sub_id,
TestL2bd.dot1ad_outer_tag)
cls.create_vlan_subif(2, cls.INT_DETAILS[2].vlan)
for i in cls.interfaces:
if isinstance(cls.INT_DETAILS[i], cls.Subint):
cls.api("sw_interface_set_flags pg%u.%u admin-up"
% (i, cls.INT_DETAILS[i].sub_id))
## @var interfaces
# List variable to store interface indexes.
## @var INT_DETAILS
# Dictionary variable to store data about interfaces.
## Class method for bridge-domain to learn defined number of MAC addresses.
# Create required number of host MAC addresses and distribute them among
# interfaces. Create host IPv4 address for every host MAC address. Create
# L2 MAC packet stream with host MAC addresses per interface to let
# the bridge domain learn these MAC addresses.
# @param cls The class pointer.
# @param count Integer variable to store the number of MAC addresses to be
# created.
@classmethod
def create_mac_entries(cls, count):
n_int = len(cls.interfaces)
macs_per_if = count / n_int
for i in cls.interfaces:
start_nr = macs_per_if*i
end_nr = count if i == (n_int - 1) else macs_per_if*(i+1)
cls.MY_MACS[i] = []
cls.MY_IP4S[i] = []
packets = []
for j in range(start_nr, end_nr):
cls.MY_MACS[i].append("00:00:00:ff:%02x:%02x" % (i, j))
cls.MY_IP4S[i].append("172.17.1%02x.%u" % (i, j))
packet = (Ether(dst="ff:ff:ff:ff:ff:ff", src=cls.MY_MACS[i]))
packets.append(packet)
cls.pg_add_stream(i, packets)
# Based on the verbosity level set in the system print the log.
cls.log("Sending broadcast eth frames for MAC learning", 1)
cls.pg_start()
# Packet stream capturing is not started as we don't need to read
# the output.
## @var n_int
# Integer variable to store the number of interfaces.
## @var macs_per_if
# Integer variable to store the number of MAC addresses per interface.
## @var start_nr
# Integer variable to store the starting number of the range used to
# generate MAC addresses for the interface.
## @var end_nr
# Integer variable to store the ending number of the range used to
# generate MAC addresses for the interface.
## @var MY_MACS
# Dictionary variable to store list of MAC addresses per interface.
## @var MY_IP4S
# Dictionary variable to store list of IPv4 addresses per interface.
## Class method to add dot1q or dot1ad layer to the packet.
# Based on sub-interface data of the defined interface add dot1q or dot1ad
# Ethernet header layer to the packet.
# @param cls The class pointer.
# @param i Integer variable to store the index of the interface.
# @param packet Object variable to store the packet where to add dot1q or
# dot1ad layer.
# TODO: Move this class method to utils.py.
@classmethod
def add_dot1_layers(cls, i, packet):
assert(type(packet) is Ether)
payload = packet.payload
if isinstance(cls.INT_DETAILS[i], cls.Dot1QSubint):
packet.remove_payload()
packet.add_payload(Dot1Q(vlan=cls.INT_DETAILS[i].vlan) / payload)
elif isinstance(cls.INT_DETAILS[i], cls.Dot1ADSubint):
packet.remove_payload()
packet.add_payload(Dot1Q(vlan=cls.INT_DETAILS[i].outer_vlan,
type=0x8100) /
Dot1Q(vlan=cls.INT_DETAILS[i].inner_vlan) /
payload)
packet.type = 0x88A8
## @var payload
# Object variable to store payload of the packet.
## @var INT_DETAILS
# Dictionary variable to store data about interfaces.
## @var Dot1QSubint
# Class variable representing dot1q sub-interfaces.
## @var Dot1ADSubint
# Class variable representing dot1ad sub-interfaces.
## Method to remove dot1q or dot1ad layer from the packet.
# Based on sub-interface data of the defined interface remove dot1q or
# dot1ad layer from the packet.
# @param cls The class pointer.
# @param i Integer variable to store the index of the interface.
# @param packet Object variable to store the packet where to remove dot1q
# or dot1ad layer.
def remove_dot1_layers(self, i, packet):
self.assertEqual(type(packet), Ether)
payload = packet.payload
if isinstance(self.INT_DETAILS[i], self.Dot1QSubint):
self.assertEqual(type(payload), Dot1Q)
self.assertEqual(payload.vlan, self.INT_DETAILS[i].vlan)
payload = payload.payload
elif isinstance(self.INT_DETAILS[i], self.Dot1ADSubint): # TODO: change 88A8 type
self.assertEqual(type(payload), Dot1Q)
self.assertEqual(payload.vlan, self.INT_DETAILS[i].outer_vlan)
payload = payload.payload
self.assertEqual(type(payload), Dot1Q)
self.assertEqual(payload.vlan, self.INT_DETAILS[i].inner_vlan)
payload = payload.payload
packet.remove_payload()
packet.add_payload(payload)
## @var payload
# Object variable to store payload of the packet.
## @var INT_DETAILS
# Dictionary variable to store data about interfaces.
## @var Dot1QSubint
# Class variable representing dot1q sub-interfaces.
## @var Dot1ADSubint
# Class variable representing dot1ad sub-interfaces.
## Method to create packet stream for the packet generator interface.
# Create input packet stream for the given packet generator interface with
# packets of different length targeted for all other created packet
# generator interfaces.
# @param self The object pointer.
# @param pg_id Integer variable to store the index of the interface to
# create the input packet stream.
# @return pkts List variable to store created input stream of packets.
def create_stream(self, pg_id):
# TODO: use variables to create lists based on interface number
pg_targets = [None] * 3
pg_targets[0] = [1, 2]
pg_targets[1] = [0, 2]
pg_targets[2] = [0, 1]
pkts = []
for i in range(0, TestL2bd.pkts_per_burst):
target_pg_id = pg_targets[pg_id][i % 2]
target_host_id = random.randrange(len(self.MY_MACS[target_pg_id]))
source_host_id = random.randrange(len(self.MY_MACS[pg_id]))
pkt_info = self.create_packet_info(pg_id, target_pg_id)
payload = self.info_to_payload(pkt_info)
p = (Ether(dst=self.MY_MACS[target_pg_id][target_host_id],
src=self.MY_MACS[pg_id][source_host_id]) /
IP(src=self.MY_IP4S[pg_id][source_host_id],
dst=self.MY_IP4S[target_pg_id][target_host_id]) /
UDP(sport=1234, dport=1234) /
Raw(payload))
pkt_info.data = p.copy()
self.add_dot1_layers(pg_id, p)
if not isinstance(self.INT_DETAILS[pg_id], self.Subint):
packet_sizes = [64, 512, 1518, 9018]
else:
packet_sizes = [64, 512, 1518+4, 9018+4]
size = packet_sizes[(i / 2) % len(packet_sizes)]
self.extend_packet(p, size)
pkts.append(p)
return pkts
## @var pg_targets
# List variable to store list of indexes of target packet generator
# interfaces for every source packet generator interface.
## @var target_pg_id
# Integer variable to store the index of the random target packet
# generator interfaces.
## @var target_host_id
# Integer variable to store the index of the randomly chosen
# destination host MAC/IPv4 address.
## @var source_host_id
# Integer variable to store the index of the randomly chosen source
# host MAC/IPv4 address.
## @var pkt_info
# Object variable to store the information about the generated packet.
## @var payload
# String variable to store the payload of the packet to be generated.
## @var p
# Object variable to store the generated packet.
## @var packet_sizes
# List variable to store required packet sizes.
## @var size
# List variable to store required packet sizes.
## Method to verify packet stream received on the packet generator interface.
# Verify packet-by-packet the output stream captured on a given packet
# generator (pg) interface using following packet payload data - order of
# packet in the stream, index of the source and destination pg interface,
# src and dst host IPv4 addresses and src port and dst port values of UDP
# layer.
# @param self The object pointer.
# @param o Integer variable to store the index of the interface to
# verify the output packet stream.
# @param capture List variable to store the captured output packet stream.
def verify_capture(self, o, capture):
last_info = {}
for i in self.interfaces:
last_info[i] = None
for packet in capture:
try:
ip = packet[IP]
udp = packet[UDP]
payload_info = self.payload_to_info(str(packet[Raw]))
# Check VLAN tags and Ethernet header
# TODO: Rework to check VLAN tag(s) and do not remove them
self.remove_dot1_layers(payload_info.src, packet)
self.assertTrue(Dot1Q not in packet)
self.assertEqual(payload_info.dst, o)
self.log("Got packet on port %u: src=%u (id=%u)"
% (o, payload_info.src, payload_info.index), 2)
next_info = self.get_next_packet_info_for_interface2(
payload_info.src, payload_info.dst,
last_info[payload_info.src])
last_info[payload_info.src] = next_info
self.assertTrue(next_info is not None)
self.assertEqual(payload_info.index, next_info.index)
# Check standard fields
self.assertEqual(ip.src, next_info.data[IP].src)
self.assertEqual(ip.dst, next_info.data[IP].dst)
self.assertEqual(udp.sport, next_info.data[UDP].sport)
self.assertEqual(udp.dport, next_info.data[UDP].dport)
except:
self.log("Unexpected or invalid packet:")
packet.show()
raise
for i in self.interfaces:
remaining_packet = self.get_next_packet_info_for_interface2(
i, o, last_info[i])
self.assertTrue(remaining_packet is None,
"Port %u: Packet expected from source %u didn't"
" arrive" % (o, i))
## @var last_info
# Dictionary variable to store verified packets per packet generator
# interface.
## @var ip
# Object variable to store the IP layer of the packet.
## @var udp
# Object variable to store the UDP layer of the packet.
## @var payload_info
# Object variable to store required information about the packet.
## @var next_info
# Object variable to store information about next packet.
## @var remaining_packet
# Object variable to store information about remaining packet.
## Method defining VPP L2 bridge domain test case.
# Contains execution steps of the test case.
# @param self The object pointer.
def test_l2bd(self):
""" L2BD MAC learning test
1.config
MAC learning enabled
learn 100 MAC enries
3 interfaces: untagged, dot1q, dot1ad (dot1q used instead of dot1ad
in the first version)
2.sending l2 eth pkts between 3 interface
64B, 512B, 1518B, 9200B (ether_size)
burst of 257 pkts per interface
"""
## Create incoming packet streams for packet-generator interfaces
for i in self.interfaces:
pkts = self.create_stream(i)
self.pg_add_stream(i, pkts)
## Enable packet capture and start packet sending
self.pg_enable_capture(self.interfaces)
self.pg_start()
## Verify outgoing packet streams per packet-generator interface
for i in self.interfaces:
out = self.pg_get_capture(i)
self.log("Verifying capture %u" % i)
self.verify_capture(i, out)
## @var pkts
# List variable to store created input stream of packets for the packet
# generator interface.
## @var out
# List variable to store captured output stream of packets for
# the packet generator interface.
if __name__ == '__main__':
unittest.main(testRunner = VppTestRunner)
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