linux/tools/testing/selftests/net/srv6_hl2encap_red_l2vpn_test.sh
Andrea Mayer 95baa4e8fe selftests: seg6: add selftest for SRv6 H.L2Encaps.Red behavior
This selftest is designed for testing the H.L2Encaps.Red behavior. It
instantiates a virtual network composed of several nodes: hosts and SRv6
routers. Each node is realized using a network namespace that is
properly interconnected to others through veth pairs.
The test considers SRv6 routers implementing a L2 VPN leveraged by hosts
for communicating with each other. Such routers make use of the SRv6
H.L2Encaps.Red behavior for applying SRv6 policies to L2 traffic coming
from hosts.

The correct execution of the behavior is verified through reachability
tests carried out between hosts belonging to the same VPN.

Signed-off-by: Andrea Mayer <andrea.mayer@uniroma2.it>
Signed-off-by: David S. Miller <davem@davemloft.net>
2022-07-29 12:14:03 +01:00

822 lines
20 KiB
Bash
Executable File

#!/bin/bash
# SPDX-License-Identifier: GPL-2.0
#
# author: Andrea Mayer <andrea.mayer@uniroma2.it>
#
# This script is designed for testing the SRv6 H.L2Encaps.Red behavior.
#
# Below is depicted the IPv6 network of an operator which offers L2 VPN
# services to hosts, enabling them to communicate with each other.
# In this example, hosts hs-1 and hs-2 are connected through an L2 VPN service.
# Currently, the SRv6 subsystem in Linux allows hosts hs-1 and hs-2 to exchange
# full L2 frames as long as they carry IPv4/IPv6.
#
# Routers rt-1,rt-2,rt-3 and rt-4 implement L2 VPN services
# leveraging the SRv6 architecture. The key components for such VPNs are:
#
# i) The SRv6 H.L2Encaps.Red behavior applies SRv6 Policies on traffic
# received by connected hosts, initiating the VPN tunnel. Such a behavior
# is an optimization of the SRv6 H.L2Encap aiming to reduce the
# length of the SID List carried in the pushed SRH. Specifically, the
# H.L2Encaps.Red removes the first SID contained in the SID List (i.e. SRv6
# Policy) by storing it into the IPv6 Destination Address. When a SRv6
# Policy is made of only one SID, the SRv6 H.L2Encaps.Red behavior omits
# the SRH at all and pushes that SID directly into the IPv6 DA;
#
# ii) The SRv6 End behavior advances the active SID in the SID List
# carried by the SRH;
#
# iii) The SRv6 End.DX2 behavior is used for removing the SRv6 Policy
# and, thus, it terminates the VPN tunnel. The decapsulated L2 frame is
# sent over the interface connected with the destination host.
#
# cafe::1 cafe::2
# 10.0.0.1 10.0.0.2
# +--------+ +--------+
# | | | |
# | hs-1 | | hs-2 |
# | | | |
# +---+----+ +--- +---+
# cafe::/64 | | cafe::/64
# 10.0.0.0/24 | | 10.0.0.0/24
# +---+----+ +----+---+
# | | fcf0:0:1:2::/64 | |
# | rt-1 +-------------------+ rt-2 |
# | | | |
# +---+----+ +----+---+
# | . . |
# | fcf0:0:1:3::/64 . |
# | . . |
# | . . |
# fcf0:0:1:4::/64 | . | fcf0:0:2:3::/64
# | . . |
# | . . |
# | fcf0:0:2:4::/64 . |
# | . . |
# +---+----+ +----+---+
# | | | |
# | rt-4 +-------------------+ rt-3 |
# | | fcf0:0:3:4::/64 | |
# +---+----+ +----+---+
#
#
# Every fcf0:0:x:y::/64 network interconnects the SRv6 routers rt-x with rt-y
# in the IPv6 operator network.
#
# Local SID table
# ===============
#
# Each SRv6 router is configured with a Local SID table in which SIDs are
# stored. Considering the given SRv6 router rt-x, at least two SIDs are
# configured in the Local SID table:
#
# Local SID table for SRv6 router rt-x
# +----------------------------------------------------------+
# |fcff:x::e is associated with the SRv6 End behavior |
# |fcff:x::d2 is associated with the SRv6 End.DX2 behavior |
# +----------------------------------------------------------+
#
# The fcff::/16 prefix is reserved by the operator for implementing SRv6 VPN
# services. Reachability of SIDs is ensured by proper configuration of the IPv6
# operator's network and SRv6 routers.
#
# SRv6 Policies
# =============
#
# An SRv6 ingress router applies SRv6 policies to the traffic received from a
# connected host. SRv6 policy enforcement consists of encapsulating the
# received traffic into a new IPv6 packet with a given SID List contained in
# the SRH.
#
# L2 VPN between hs-1 and hs-2
# ----------------------------
#
# Hosts hs-1 and hs-2 are connected using a dedicated L2 VPN.
# Specifically, packets generated from hs-1 and directed towards hs-2 are
# handled by rt-1 which applies the following SRv6 Policies:
#
# i.a) L2 traffic, SID List=fcff:2::d2
#
# Policy (i.a) steers tunneled L2 traffic through SRv6 router rt-2.
# The H.L2Encaps.Red omits the presence of SRH at all, since the SID List
# consists of only one SID (fcff:2::d2) that can be stored directly in the IPv6
# DA.
#
# On the reverse path (i.e. from hs-2 to hs-1), rt-2 applies the following
# policies:
#
# i.b) L2 traffic, SID List=fcff:4::e,fcff:3::e,fcff:1::d2
#
# Policy (i.b) steers tunneled L2 traffic through the SRv6 routers
# rt-4,rt-3,rt2. The H.L2Encaps.Red reduces the SID List in the SRH by removing
# the first SID (fcff:4::e) and pushing it into the IPv6 DA.
#
# In summary:
# hs-1->hs-2 |IPv6 DA=fcff:2::d2|eth|...| (i.a)
# hs-2->hs-1 |IPv6 DA=fcff:4::e|SRH SIDs=fcff:3::e,fcff:1::d2|eth|...| (i.b)
#
# Kselftest framework requirement - SKIP code is 4.
readonly ksft_skip=4
readonly RDMSUFF="$(mktemp -u XXXXXXXX)"
readonly DUMMY_DEVNAME="dum0"
readonly RT2HS_DEVNAME="veth-hs"
readonly HS_VETH_NAME="veth0"
readonly LOCALSID_TABLE_ID=90
readonly IPv6_RT_NETWORK=fcf0:0
readonly IPv6_HS_NETWORK=cafe
readonly IPv4_HS_NETWORK=10.0.0
readonly VPN_LOCATOR_SERVICE=fcff
readonly MAC_PREFIX=00:00:00:c0:01
readonly END_FUNC=000e
readonly DX2_FUNC=00d2
PING_TIMEOUT_SEC=4
PAUSE_ON_FAIL=${PAUSE_ON_FAIL:=no}
# IDs of routers and hosts are initialized during the setup of the testing
# network
ROUTERS=''
HOSTS=''
SETUP_ERR=1
ret=${ksft_skip}
nsuccess=0
nfail=0
log_test()
{
local rc="$1"
local expected="$2"
local msg="$3"
if [ "${rc}" -eq "${expected}" ]; then
nsuccess=$((nsuccess+1))
printf "\n TEST: %-60s [ OK ]\n" "${msg}"
else
ret=1
nfail=$((nfail+1))
printf "\n TEST: %-60s [FAIL]\n" "${msg}"
if [ "${PAUSE_ON_FAIL}" = "yes" ]; then
echo
echo "hit enter to continue, 'q' to quit"
read a
[ "$a" = "q" ] && exit 1
fi
fi
}
print_log_test_results()
{
printf "\nTests passed: %3d\n" "${nsuccess}"
printf "Tests failed: %3d\n" "${nfail}"
# when a test fails, the value of 'ret' is set to 1 (error code).
# Conversely, when all tests are passed successfully, the 'ret' value
# is set to 0 (success code).
if [ "${ret}" -ne 1 ]; then
ret=0
fi
}
log_section()
{
echo
echo "################################################################################"
echo "TEST SECTION: $*"
echo "################################################################################"
}
test_command_or_ksft_skip()
{
local cmd="$1"
if [ ! -x "$(command -v "${cmd}")" ]; then
echo "SKIP: Could not run test without \"${cmd}\" tool";
exit "${ksft_skip}"
fi
}
get_nodename()
{
local name="$1"
echo "${name}-${RDMSUFF}"
}
get_rtname()
{
local rtid="$1"
get_nodename "rt-${rtid}"
}
get_hsname()
{
local hsid="$1"
get_nodename "hs-${hsid}"
}
__create_namespace()
{
local name="$1"
ip netns add "${name}"
}
create_router()
{
local rtid="$1"
local nsname
nsname="$(get_rtname "${rtid}")"
__create_namespace "${nsname}"
}
create_host()
{
local hsid="$1"
local nsname
nsname="$(get_hsname "${hsid}")"
__create_namespace "${nsname}"
}
cleanup()
{
local nsname
local i
# destroy routers
for i in ${ROUTERS}; do
nsname="$(get_rtname "${i}")"
ip netns del "${nsname}" &>/dev/null || true
done
# destroy hosts
for i in ${HOSTS}; do
nsname="$(get_hsname "${i}")"
ip netns del "${nsname}" &>/dev/null || true
done
# check whether the setup phase was completed successfully or not. In
# case of an error during the setup phase of the testing environment,
# the selftest is considered as "skipped".
if [ "${SETUP_ERR}" -ne 0 ]; then
echo "SKIP: Setting up the testing environment failed"
exit "${ksft_skip}"
fi
exit "${ret}"
}
add_link_rt_pairs()
{
local rt="$1"
local rt_neighs="$2"
local neigh
local nsname
local neigh_nsname
nsname="$(get_rtname "${rt}")"
for neigh in ${rt_neighs}; do
neigh_nsname="$(get_rtname "${neigh}")"
ip link add "veth-rt-${rt}-${neigh}" netns "${nsname}" \
type veth peer name "veth-rt-${neigh}-${rt}" \
netns "${neigh_nsname}"
done
}
get_network_prefix()
{
local rt="$1"
local neigh="$2"
local p="${rt}"
local q="${neigh}"
if [ "${p}" -gt "${q}" ]; then
p="${q}"; q="${rt}"
fi
echo "${IPv6_RT_NETWORK}:${p}:${q}"
}
# Setup the basic networking for the routers
setup_rt_networking()
{
local rt="$1"
local rt_neighs="$2"
local nsname
local net_prefix
local devname
local neigh
nsname="$(get_rtname "${rt}")"
for neigh in ${rt_neighs}; do
devname="veth-rt-${rt}-${neigh}"
net_prefix="$(get_network_prefix "${rt}" "${neigh}")"
ip -netns "${nsname}" addr \
add "${net_prefix}::${rt}/64" dev "${devname}" nodad
ip -netns "${nsname}" link set "${devname}" up
done
ip -netns "${nsname}" link add "${DUMMY_DEVNAME}" type dummy
ip -netns "${nsname}" link set "${DUMMY_DEVNAME}" up
ip -netns "${nsname}" link set lo up
ip netns exec "${nsname}" sysctl -wq net.ipv6.conf.all.accept_dad=0
ip netns exec "${nsname}" sysctl -wq net.ipv6.conf.default.accept_dad=0
ip netns exec "${nsname}" sysctl -wq net.ipv6.conf.all.forwarding=1
ip netns exec "${nsname}" sysctl -wq net.ipv4.conf.all.rp_filter=0
ip netns exec "${nsname}" sysctl -wq net.ipv4.conf.default.rp_filter=0
ip netns exec "${nsname}" sysctl -wq net.ipv4.ip_forward=1
}
# Setup local SIDs for an SRv6 router
setup_rt_local_sids()
{
local rt="$1"
local rt_neighs="$2"
local net_prefix
local devname
local nsname
local neigh
nsname="$(get_rtname "${rt}")"
for neigh in ${rt_neighs}; do
devname="veth-rt-${rt}-${neigh}"
net_prefix="$(get_network_prefix "${rt}" "${neigh}")"
# set underlay network routes for SIDs reachability
ip -netns "${nsname}" -6 route \
add "${VPN_LOCATOR_SERVICE}:${neigh}::/32" \
table "${LOCALSID_TABLE_ID}" \
via "${net_prefix}::${neigh}" dev "${devname}"
done
# Local End behavior (note that dev "${DUMMY_DEVNAME}" is a dummy
# interface)
ip -netns "${nsname}" -6 route \
add "${VPN_LOCATOR_SERVICE}:${rt}::${END_FUNC}" \
table "${LOCALSID_TABLE_ID}" \
encap seg6local action End dev "${DUMMY_DEVNAME}"
# all SIDs for VPNs start with a common locator. Routes and SRv6
# Endpoint behaviors instaces are grouped together in the 'localsid'
# table.
ip -netns "${nsname}" -6 rule add \
to "${VPN_LOCATOR_SERVICE}::/16" \
lookup "${LOCALSID_TABLE_ID}" prio 999
}
# build and install the SRv6 policy into the ingress SRv6 router.
# args:
# $1 - destination host (i.e. cafe::x host)
# $2 - SRv6 router configured for enforcing the SRv6 Policy
# $3 - SRv6 routers configured for steering traffic (End behaviors)
# $4 - SRv6 router configured for removing the SRv6 Policy (router connected
# to the destination host)
# $5 - encap mode (full or red)
# $6 - traffic type (IPv6 or IPv4)
__setup_rt_policy()
{
local dst="$1"
local encap_rt="$2"
local end_rts="$3"
local dec_rt="$4"
local mode="$5"
local traffic="$6"
local nsname
local policy=''
local n
nsname="$(get_rtname "${encap_rt}")"
for n in ${end_rts}; do
policy="${policy}${VPN_LOCATOR_SERVICE}:${n}::${END_FUNC},"
done
policy="${policy}${VPN_LOCATOR_SERVICE}:${dec_rt}::${DX2_FUNC}"
# add SRv6 policy to incoming traffic sent by connected hosts
if [ "${traffic}" -eq 6 ]; then
ip -netns "${nsname}" -6 route \
add "${IPv6_HS_NETWORK}::${dst}" \
encap seg6 mode "${mode}" segs "${policy}" \
dev dum0
else
ip -netns "${nsname}" -4 route \
add "${IPv4_HS_NETWORK}.${dst}" \
encap seg6 mode "${mode}" segs "${policy}" \
dev dum0
fi
}
# see __setup_rt_policy
setup_rt_policy_ipv6()
{
__setup_rt_policy "$1" "$2" "$3" "$4" "$5" 6
}
#see __setup_rt_policy
setup_rt_policy_ipv4()
{
__setup_rt_policy "$1" "$2" "$3" "$4" "$5" 4
}
setup_decap()
{
local rt="$1"
local nsname
nsname="$(get_rtname "${rt}")"
# Local End.DX2 behavior
ip -netns "${nsname}" -6 route \
add "${VPN_LOCATOR_SERVICE}:${rt}::${DX2_FUNC}" \
table "${LOCALSID_TABLE_ID}" \
encap seg6local action End.DX2 oif "${RT2HS_DEVNAME}" \
dev "${RT2HS_DEVNAME}"
}
setup_hs()
{
local hs="$1"
local rt="$2"
local hsname
local rtname
hsname="$(get_hsname "${hs}")"
rtname="$(get_rtname "${rt}")"
ip netns exec "${hsname}" sysctl -wq net.ipv6.conf.all.accept_dad=0
ip netns exec "${hsname}" sysctl -wq net.ipv6.conf.default.accept_dad=0
ip -netns "${hsname}" link add "${HS_VETH_NAME}" type veth \
peer name "${RT2HS_DEVNAME}" netns "${rtname}"
ip -netns "${hsname}" addr add "${IPv6_HS_NETWORK}::${hs}/64" \
dev "${HS_VETH_NAME}" nodad
ip -netns "${hsname}" addr add "${IPv4_HS_NETWORK}.${hs}/24" \
dev "${HS_VETH_NAME}"
ip -netns "${hsname}" link set "${HS_VETH_NAME}" up
ip -netns "${hsname}" link set lo up
ip -netns "${rtname}" addr add "${IPv6_HS_NETWORK}::254/64" \
dev "${RT2HS_DEVNAME}" nodad
ip -netns "${rtname}" addr \
add "${IPv4_HS_NETWORK}.254/24" dev "${RT2HS_DEVNAME}"
ip -netns "${rtname}" link set "${RT2HS_DEVNAME}" up
# disable the rp_filter otherwise the kernel gets confused about how
# to route decap ipv4 packets.
ip netns exec "${rtname}" \
sysctl -wq net.ipv4.conf."${RT2HS_DEVNAME}".rp_filter=0
}
# set an auto-generated mac address
# args:
# $1 - name of the node (e.g.: hs-1, rt-3, etc)
# $2 - id of the node (e.g.: 1 for hs-1, 3 for rt-3, etc)
# $3 - host part of the IPv6 network address
# $4 - name of the network interface to which the generated mac address must
# be set.
set_mac_address()
{
local nodename="$1"
local nodeid="$2"
local host="$3"
local ifname="$4"
local nsname
nsname=$(get_nodename "${nodename}")
ip -netns "${nsname}" link set dev "${ifname}" down
ip -netns "${nsname}" link set address "${MAC_PREFIX}:${nodeid}" \
dev "${ifname}"
# the IPv6 address must be set once again after the MAC address has
# been changed.
ip -netns "${nsname}" addr add "${IPv6_HS_NETWORK}::${host}/64" \
dev "${ifname}" nodad
ip -netns "${nsname}" link set dev "${ifname}" up
}
set_host_l2peer()
{
local hssrc="$1"
local hsdst="$2"
local ipprefix="$3"
local proto="$4"
local hssrc_name
local ipaddr
hssrc_name="$(get_hsname "${hssrc}")"
if [ "${proto}" -eq 6 ]; then
ipaddr="${ipprefix}::${hsdst}"
else
ipaddr="${ipprefix}.${hsdst}"
fi
ip -netns "${hssrc_name}" route add "${ipaddr}" dev "${HS_VETH_NAME}"
ip -netns "${hssrc_name}" neigh \
add "${ipaddr}" lladdr "${MAC_PREFIX}:${hsdst}" \
dev "${HS_VETH_NAME}"
}
# setup an SRv6 L2 VPN between host hs-x and hs-y (currently, the SRv6
# subsystem only supports L2 frames whose layer-3 is IPv4/IPv6).
# args:
# $1 - source host
# $2 - SRv6 routers configured for steering tunneled traffic
# $3 - destination host
setup_l2vpn()
{
local hssrc="$1"
local end_rts="$2"
local hsdst="$3"
local rtsrc="${hssrc}"
local rtdst="${hsdst}"
# set fixed mac for source node and the neigh MAC address
set_mac_address "hs-${hssrc}" "${hssrc}" "${hssrc}" "${HS_VETH_NAME}"
set_host_l2peer "${hssrc}" "${hsdst}" "${IPv6_HS_NETWORK}" 6
set_host_l2peer "${hssrc}" "${hsdst}" "${IPv4_HS_NETWORK}" 4
# we have to set the mac address of the veth-host (on ingress router)
# to the mac address of the remote peer (L2 VPN destination host).
# Otherwise, traffic coming from the source host is dropped at the
# ingress router.
set_mac_address "rt-${rtsrc}" "${hsdst}" 254 "${RT2HS_DEVNAME}"
# set the SRv6 Policies at the ingress router
setup_rt_policy_ipv6 "${hsdst}" "${rtsrc}" "${end_rts}" "${rtdst}" \
l2encap.red 6
setup_rt_policy_ipv4 "${hsdst}" "${rtsrc}" "${end_rts}" "${rtdst}" \
l2encap.red 4
# set the decap behavior
setup_decap "${rtsrc}"
}
setup()
{
local i
# create routers
ROUTERS="1 2 3 4"; readonly ROUTERS
for i in ${ROUTERS}; do
create_router "${i}"
done
# create hosts
HOSTS="1 2"; readonly HOSTS
for i in ${HOSTS}; do
create_host "${i}"
done
# set up the links for connecting routers
add_link_rt_pairs 1 "2 3 4"
add_link_rt_pairs 2 "3 4"
add_link_rt_pairs 3 "4"
# set up the basic connectivity of routers and routes required for
# reachability of SIDs.
setup_rt_networking 1 "2 3 4"
setup_rt_networking 2 "1 3 4"
setup_rt_networking 3 "1 2 4"
setup_rt_networking 4 "1 2 3"
# set up the hosts connected to routers
setup_hs 1 1
setup_hs 2 2
# set up default SRv6 Endpoints (i.e. SRv6 End and SRv6 End.DX2)
setup_rt_local_sids 1 "2 3 4"
setup_rt_local_sids 2 "1 3 4"
setup_rt_local_sids 3 "1 2 4"
setup_rt_local_sids 4 "1 2 3"
# create a L2 VPN between hs-1 and hs-2.
# NB: currently, H.L2Encap* enables tunneling of L2 frames whose
# layer-3 is IPv4/IPv6.
#
# the network path between hs-1 and hs-2 traverses several routers
# depending on the direction of traffic.
#
# Direction hs-1 -> hs-2 (H.L2Encaps.Red)
# - rt-2 (SRv6 End.DX2 behavior)
#
# Direction hs-2 -> hs-1 (H.L2Encaps.Red)
# - rt-4,rt-3 (SRv6 End behaviors)
# - rt-1 (SRv6 End.DX2 behavior)
setup_l2vpn 1 "" 2
setup_l2vpn 2 "4 3" 1
# testing environment was set up successfully
SETUP_ERR=0
}
check_rt_connectivity()
{
local rtsrc="$1"
local rtdst="$2"
local prefix
local rtsrc_nsname
rtsrc_nsname="$(get_rtname "${rtsrc}")"
prefix="$(get_network_prefix "${rtsrc}" "${rtdst}")"
ip netns exec "${rtsrc_nsname}" ping -c 1 -W "${PING_TIMEOUT_SEC}" \
"${prefix}::${rtdst}" >/dev/null 2>&1
}
check_and_log_rt_connectivity()
{
local rtsrc="$1"
local rtdst="$2"
check_rt_connectivity "${rtsrc}" "${rtdst}"
log_test $? 0 "Routers connectivity: rt-${rtsrc} -> rt-${rtdst}"
}
check_hs_ipv6_connectivity()
{
local hssrc="$1"
local hsdst="$2"
local hssrc_nsname
hssrc_nsname="$(get_hsname "${hssrc}")"
ip netns exec "${hssrc_nsname}" ping -c 1 -W "${PING_TIMEOUT_SEC}" \
"${IPv6_HS_NETWORK}::${hsdst}" >/dev/null 2>&1
}
check_hs_ipv4_connectivity()
{
local hssrc="$1"
local hsdst="$2"
local hssrc_nsname
hssrc_nsname="$(get_hsname "${hssrc}")"
ip netns exec "${hssrc_nsname}" ping -c 1 -W "${PING_TIMEOUT_SEC}" \
"${IPv4_HS_NETWORK}.${hsdst}" >/dev/null 2>&1
}
check_and_log_hs2gw_connectivity()
{
local hssrc="$1"
check_hs_ipv6_connectivity "${hssrc}" 254
log_test $? 0 "IPv6 Hosts connectivity: hs-${hssrc} -> gw"
check_hs_ipv4_connectivity "${hssrc}" 254
log_test $? 0 "IPv4 Hosts connectivity: hs-${hssrc} -> gw"
}
check_and_log_hs_ipv6_connectivity()
{
local hssrc="$1"
local hsdst="$2"
check_hs_ipv6_connectivity "${hssrc}" "${hsdst}"
log_test $? 0 "IPv6 Hosts connectivity: hs-${hssrc} -> hs-${hsdst}"
}
check_and_log_hs_ipv4_connectivity()
{
local hssrc="$1"
local hsdst="$2"
check_hs_ipv4_connectivity "${hssrc}" "${hsdst}"
log_test $? 0 "IPv4 Hosts connectivity: hs-${hssrc} -> hs-${hsdst}"
}
check_and_log_hs_connectivity()
{
local hssrc="$1"
local hsdst="$2"
check_and_log_hs_ipv4_connectivity "${hssrc}" "${hsdst}"
check_and_log_hs_ipv6_connectivity "${hssrc}" "${hsdst}"
}
router_tests()
{
local i
local j
log_section "IPv6 routers connectivity test"
for i in ${ROUTERS}; do
for j in ${ROUTERS}; do
if [ "${i}" -eq "${j}" ]; then
continue
fi
check_and_log_rt_connectivity "${i}" "${j}"
done
done
}
host2gateway_tests()
{
local hs
log_section "IPv4/IPv6 connectivity test among hosts and gateways"
for hs in ${HOSTS}; do
check_and_log_hs2gw_connectivity "${hs}"
done
}
host_vpn_tests()
{
log_section "SRv6 L2 VPN connectivity test hosts (h1 <-> h2)"
check_and_log_hs_connectivity 1 2
check_and_log_hs_connectivity 2 1
}
test_dummy_dev_or_ksft_skip()
{
local test_netns
test_netns="dummy-$(mktemp -u XXXXXXXX)"
if ! ip netns add "${test_netns}"; then
echo "SKIP: Cannot set up netns for testing dummy dev support"
exit "${ksft_skip}"
fi
modprobe dummy &>/dev/null || true
if ! ip -netns "${test_netns}" link \
add "${DUMMY_DEVNAME}" type dummy; then
echo "SKIP: dummy dev not supported"
ip netns del "${test_netns}"
exit "${ksft_skip}"
fi
ip netns del "${test_netns}"
}
test_iproute2_supp_or_ksft_skip()
{
if ! ip route help 2>&1 | grep -qo "l2encap.red"; then
echo "SKIP: Missing SRv6 l2encap.red support in iproute2"
exit "${ksft_skip}"
fi
}
if [ "$(id -u)" -ne 0 ]; then
echo "SKIP: Need root privileges"
exit "${ksft_skip}"
fi
# required programs to carry out this selftest
test_command_or_ksft_skip ip
test_command_or_ksft_skip ping
test_command_or_ksft_skip sysctl
test_command_or_ksft_skip grep
test_iproute2_supp_or_ksft_skip
test_dummy_dev_or_ksft_skip
set -e
trap cleanup EXIT
setup
set +e
router_tests
host2gateway_tests
host_vpn_tests
print_log_test_results