tjh.dev
Linux kernel mirror (for testing)
git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
kernel
os
linux
1#!/bin/bash
2# SPDX-License-Identifier: GPL-2.0
3#
4# author: Andrea Mayer <andrea.mayer@uniroma2.it>
5#
6# This script is designed for testing the SRv6 H.L2Encaps.Red behavior.
7#
8# Below is depicted the IPv6 network of an operator which offers L2 VPN
9# services to hosts, enabling them to communicate with each other.
10# In this example, hosts hs-1 and hs-2 are connected through an L2 VPN service.
11# Currently, the SRv6 subsystem in Linux allows hosts hs-1 and hs-2 to exchange
12# full L2 frames as long as they carry IPv4/IPv6.
13#
14# Routers rt-1,rt-2,rt-3 and rt-4 implement L2 VPN services
15# leveraging the SRv6 architecture. The key components for such VPNs are:
16#
17# i) The SRv6 H.L2Encaps.Red behavior applies SRv6 Policies on traffic
18# received by connected hosts, initiating the VPN tunnel. Such a behavior
19# is an optimization of the SRv6 H.L2Encap aiming to reduce the
20# length of the SID List carried in the pushed SRH. Specifically, the
21# H.L2Encaps.Red removes the first SID contained in the SID List (i.e. SRv6
22# Policy) by storing it into the IPv6 Destination Address. When a SRv6
23# Policy is made of only one SID, the SRv6 H.L2Encaps.Red behavior omits
24# the SRH at all and pushes that SID directly into the IPv6 DA;
25#
26# ii) The SRv6 End behavior advances the active SID in the SID List
27# carried by the SRH;
28#
29# iii) The SRv6 End.DX2 behavior is used for removing the SRv6 Policy
30# and, thus, it terminates the VPN tunnel. The decapsulated L2 frame is
31# sent over the interface connected with the destination host.
32#
33# cafe::1 cafe::2
34# 10.0.0.1 10.0.0.2
35# +--------+ +--------+
36# | | | |
37# | hs-1 | | hs-2 |
38# | | | |
39# +---+----+ +--- +---+
40# cafe::/64 | | cafe::/64
41# 10.0.0.0/24 | | 10.0.0.0/24
42# +---+----+ +----+---+
43# | | fcf0:0:1:2::/64 | |
44# | rt-1 +-------------------+ rt-2 |
45# | | | |
46# +---+----+ +----+---+
47# | . . |
48# | fcf0:0:1:3::/64 . |
49# | . . |
50# | . . |
51# fcf0:0:1:4::/64 | . | fcf0:0:2:3::/64
52# | . . |
53# | . . |
54# | fcf0:0:2:4::/64 . |
55# | . . |
56# +---+----+ +----+---+
57# | | | |
58# | rt-4 +-------------------+ rt-3 |
59# | | fcf0:0:3:4::/64 | |
60# +---+----+ +----+---+
61#
62#
63# Every fcf0:0:x:y::/64 network interconnects the SRv6 routers rt-x with rt-y
64# in the IPv6 operator network.
65#
66# Local SID table
67# ===============
68#
69# Each SRv6 router is configured with a Local SID table in which SIDs are
70# stored. Considering the given SRv6 router rt-x, at least two SIDs are
71# configured in the Local SID table:
72#
73# Local SID table for SRv6 router rt-x
74# +----------------------------------------------------------+
75# |fcff:x::e is associated with the SRv6 End behavior |
76# |fcff:x::d2 is associated with the SRv6 End.DX2 behavior |
77# +----------------------------------------------------------+
78#
79# The fcff::/16 prefix is reserved by the operator for implementing SRv6 VPN
80# services. Reachability of SIDs is ensured by proper configuration of the IPv6
81# operator's network and SRv6 routers.
82#
83# SRv6 Policies
84# =============
85#
86# An SRv6 ingress router applies SRv6 policies to the traffic received from a
87# connected host. SRv6 policy enforcement consists of encapsulating the
88# received traffic into a new IPv6 packet with a given SID List contained in
89# the SRH.
90#
91# L2 VPN between hs-1 and hs-2
92# ----------------------------
93#
94# Hosts hs-1 and hs-2 are connected using a dedicated L2 VPN.
95# Specifically, packets generated from hs-1 and directed towards hs-2 are
96# handled by rt-1 which applies the following SRv6 Policies:
97#
98# i.a) L2 traffic, SID List=fcff:2::d2
99#
100# Policy (i.a) steers tunneled L2 traffic through SRv6 router rt-2.
101# The H.L2Encaps.Red omits the presence of SRH at all, since the SID List
102# consists of only one SID (fcff:2::d2) that can be stored directly in the IPv6
103# DA.
104#
105# On the reverse path (i.e. from hs-2 to hs-1), rt-2 applies the following
106# policies:
107#
108# i.b) L2 traffic, SID List=fcff:4::e,fcff:3::e,fcff:1::d2
109#
110# Policy (i.b) steers tunneled L2 traffic through the SRv6 routers
111# rt-4,rt-3,rt2. The H.L2Encaps.Red reduces the SID List in the SRH by removing
112# the first SID (fcff:4::e) and pushing it into the IPv6 DA.
113#
114# In summary:
115# hs-1->hs-2 |IPv6 DA=fcff:2::d2|eth|...| (i.a)
116# hs-2->hs-1 |IPv6 DA=fcff:4::e|SRH SIDs=fcff:3::e,fcff:1::d2|eth|...| (i.b)
117#
118
119# Kselftest framework requirement - SKIP code is 4.
120readonly ksft_skip=4
121
122readonly RDMSUFF="$(mktemp -u XXXXXXXX)"
123readonly DUMMY_DEVNAME="dum0"
124readonly RT2HS_DEVNAME="veth-hs"
125readonly HS_VETH_NAME="veth0"
126readonly LOCALSID_TABLE_ID=90
127readonly IPv6_RT_NETWORK=fcf0:0
128readonly IPv6_HS_NETWORK=cafe
129readonly IPv4_HS_NETWORK=10.0.0
130readonly VPN_LOCATOR_SERVICE=fcff
131readonly MAC_PREFIX=00:00:00:c0:01
132readonly END_FUNC=000e
133readonly DX2_FUNC=00d2
134
135PING_TIMEOUT_SEC=4
136PAUSE_ON_FAIL=${PAUSE_ON_FAIL:=no}
137
138# IDs of routers and hosts are initialized during the setup of the testing
139# network
140ROUTERS=''
141HOSTS=''
142
143SETUP_ERR=1
144
145ret=${ksft_skip}
146nsuccess=0
147nfail=0
148
149log_test()
150{
151 local rc="$1"
152 local expected="$2"
153 local msg="$3"
154
155 if [ "${rc}" -eq "${expected}" ]; then
156 nsuccess=$((nsuccess+1))
157 printf "\n TEST: %-60s [ OK ]\n" "${msg}"
158 else
159 ret=1
160 nfail=$((nfail+1))
161 printf "\n TEST: %-60s [FAIL]\n" "${msg}"
162 if [ "${PAUSE_ON_FAIL}" = "yes" ]; then
163 echo
164 echo "hit enter to continue, 'q' to quit"
165 read a
166 [ "$a" = "q" ] && exit 1
167 fi
168 fi
169}
170
171print_log_test_results()
172{
173 printf "\nTests passed: %3d\n" "${nsuccess}"
174 printf "Tests failed: %3d\n" "${nfail}"
175
176 # when a test fails, the value of 'ret' is set to 1 (error code).
177 # Conversely, when all tests are passed successfully, the 'ret' value
178 # is set to 0 (success code).
179 if [ "${ret}" -ne 1 ]; then
180 ret=0
181 fi
182}
183
184log_section()
185{
186 echo
187 echo "################################################################################"
188 echo "TEST SECTION: $*"
189 echo "################################################################################"
190}
191
192test_command_or_ksft_skip()
193{
194 local cmd="$1"
195
196 if [ ! -x "$(command -v "${cmd}")" ]; then
197 echo "SKIP: Could not run test without \"${cmd}\" tool";
198 exit "${ksft_skip}"
199 fi
200}
201
202get_nodename()
203{
204 local name="$1"
205
206 echo "${name}-${RDMSUFF}"
207}
208
209get_rtname()
210{
211 local rtid="$1"
212
213 get_nodename "rt-${rtid}"
214}
215
216get_hsname()
217{
218 local hsid="$1"
219
220 get_nodename "hs-${hsid}"
221}
222
223__create_namespace()
224{
225 local name="$1"
226
227 ip netns add "${name}"
228}
229
230create_router()
231{
232 local rtid="$1"
233 local nsname
234
235 nsname="$(get_rtname "${rtid}")"
236
237 __create_namespace "${nsname}"
238}
239
240create_host()
241{
242 local hsid="$1"
243 local nsname
244
245 nsname="$(get_hsname "${hsid}")"
246
247 __create_namespace "${nsname}"
248}
249
250cleanup()
251{
252 local nsname
253 local i
254
255 # destroy routers
256 for i in ${ROUTERS}; do
257 nsname="$(get_rtname "${i}")"
258
259 ip netns del "${nsname}" &>/dev/null || true
260 done
261
262 # destroy hosts
263 for i in ${HOSTS}; do
264 nsname="$(get_hsname "${i}")"
265
266 ip netns del "${nsname}" &>/dev/null || true
267 done
268
269 # check whether the setup phase was completed successfully or not. In
270 # case of an error during the setup phase of the testing environment,
271 # the selftest is considered as "skipped".
272 if [ "${SETUP_ERR}" -ne 0 ]; then
273 echo "SKIP: Setting up the testing environment failed"
274 exit "${ksft_skip}"
275 fi
276
277 exit "${ret}"
278}
279
280add_link_rt_pairs()
281{
282 local rt="$1"
283 local rt_neighs="$2"
284 local neigh
285 local nsname
286 local neigh_nsname
287
288 nsname="$(get_rtname "${rt}")"
289
290 for neigh in ${rt_neighs}; do
291 neigh_nsname="$(get_rtname "${neigh}")"
292
293 ip link add "veth-rt-${rt}-${neigh}" netns "${nsname}" \
294 type veth peer name "veth-rt-${neigh}-${rt}" \
295 netns "${neigh_nsname}"
296 done
297}
298
299get_network_prefix()
300{
301 local rt="$1"
302 local neigh="$2"
303 local p="${rt}"
304 local q="${neigh}"
305
306 if [ "${p}" -gt "${q}" ]; then
307 p="${q}"; q="${rt}"
308 fi
309
310 echo "${IPv6_RT_NETWORK}:${p}:${q}"
311}
312
313# Setup the basic networking for the routers
314setup_rt_networking()
315{
316 local rt="$1"
317 local rt_neighs="$2"
318 local nsname
319 local net_prefix
320 local devname
321 local neigh
322
323 nsname="$(get_rtname "${rt}")"
324
325 for neigh in ${rt_neighs}; do
326 devname="veth-rt-${rt}-${neigh}"
327
328 net_prefix="$(get_network_prefix "${rt}" "${neigh}")"
329
330 ip -netns "${nsname}" addr \
331 add "${net_prefix}::${rt}/64" dev "${devname}" nodad
332
333 ip -netns "${nsname}" link set "${devname}" up
334 done
335
336 ip -netns "${nsname}" link add "${DUMMY_DEVNAME}" type dummy
337
338 ip -netns "${nsname}" link set "${DUMMY_DEVNAME}" up
339 ip -netns "${nsname}" link set lo up
340
341 ip netns exec "${nsname}" sysctl -wq net.ipv6.conf.all.accept_dad=0
342 ip netns exec "${nsname}" sysctl -wq net.ipv6.conf.default.accept_dad=0
343 ip netns exec "${nsname}" sysctl -wq net.ipv6.conf.all.forwarding=1
344
345 ip netns exec "${nsname}" sysctl -wq net.ipv4.conf.all.rp_filter=0
346 ip netns exec "${nsname}" sysctl -wq net.ipv4.conf.default.rp_filter=0
347 ip netns exec "${nsname}" sysctl -wq net.ipv4.ip_forward=1
348}
349
350# Setup local SIDs for an SRv6 router
351setup_rt_local_sids()
352{
353 local rt="$1"
354 local rt_neighs="$2"
355 local net_prefix
356 local devname
357 local nsname
358 local neigh
359
360 nsname="$(get_rtname "${rt}")"
361
362 for neigh in ${rt_neighs}; do
363 devname="veth-rt-${rt}-${neigh}"
364
365 net_prefix="$(get_network_prefix "${rt}" "${neigh}")"
366
367 # set underlay network routes for SIDs reachability
368 ip -netns "${nsname}" -6 route \
369 add "${VPN_LOCATOR_SERVICE}:${neigh}::/32" \
370 table "${LOCALSID_TABLE_ID}" \
371 via "${net_prefix}::${neigh}" dev "${devname}"
372 done
373
374 # Local End behavior (note that dev "${DUMMY_DEVNAME}" is a dummy
375 # interface)
376 ip -netns "${nsname}" -6 route \
377 add "${VPN_LOCATOR_SERVICE}:${rt}::${END_FUNC}" \
378 table "${LOCALSID_TABLE_ID}" \
379 encap seg6local action End dev "${DUMMY_DEVNAME}"
380
381 # all SIDs for VPNs start with a common locator. Routes and SRv6
382 # Endpoint behaviors instaces are grouped together in the 'localsid'
383 # table.
384 ip -netns "${nsname}" -6 rule add \
385 to "${VPN_LOCATOR_SERVICE}::/16" \
386 lookup "${LOCALSID_TABLE_ID}" prio 999
387}
388
389# build and install the SRv6 policy into the ingress SRv6 router.
390# args:
391# $1 - destination host (i.e. cafe::x host)
392# $2 - SRv6 router configured for enforcing the SRv6 Policy
393# $3 - SRv6 routers configured for steering traffic (End behaviors)
394# $4 - SRv6 router configured for removing the SRv6 Policy (router connected
395# to the destination host)
396# $5 - encap mode (full or red)
397# $6 - traffic type (IPv6 or IPv4)
398__setup_rt_policy()
399{
400 local dst="$1"
401 local encap_rt="$2"
402 local end_rts="$3"
403 local dec_rt="$4"
404 local mode="$5"
405 local traffic="$6"
406 local nsname
407 local policy=''
408 local n
409
410 nsname="$(get_rtname "${encap_rt}")"
411
412 for n in ${end_rts}; do
413 policy="${policy}${VPN_LOCATOR_SERVICE}:${n}::${END_FUNC},"
414 done
415
416 policy="${policy}${VPN_LOCATOR_SERVICE}:${dec_rt}::${DX2_FUNC}"
417
418 # add SRv6 policy to incoming traffic sent by connected hosts
419 if [ "${traffic}" -eq 6 ]; then
420 ip -netns "${nsname}" -6 route \
421 add "${IPv6_HS_NETWORK}::${dst}" \
422 encap seg6 mode "${mode}" segs "${policy}" \
423 dev dum0
424 else
425 ip -netns "${nsname}" -4 route \
426 add "${IPv4_HS_NETWORK}.${dst}" \
427 encap seg6 mode "${mode}" segs "${policy}" \
428 dev dum0
429 fi
430}
431
432# see __setup_rt_policy
433setup_rt_policy_ipv6()
434{
435 __setup_rt_policy "$1" "$2" "$3" "$4" "$5" 6
436}
437
438#see __setup_rt_policy
439setup_rt_policy_ipv4()
440{
441 __setup_rt_policy "$1" "$2" "$3" "$4" "$5" 4
442}
443
444setup_decap()
445{
446 local rt="$1"
447 local nsname
448
449 nsname="$(get_rtname "${rt}")"
450
451 # Local End.DX2 behavior
452 ip -netns "${nsname}" -6 route \
453 add "${VPN_LOCATOR_SERVICE}:${rt}::${DX2_FUNC}" \
454 table "${LOCALSID_TABLE_ID}" \
455 encap seg6local action End.DX2 oif "${RT2HS_DEVNAME}" \
456 dev "${RT2HS_DEVNAME}"
457}
458
459setup_hs()
460{
461 local hs="$1"
462 local rt="$2"
463 local hsname
464 local rtname
465
466 hsname="$(get_hsname "${hs}")"
467 rtname="$(get_rtname "${rt}")"
468
469 ip netns exec "${hsname}" sysctl -wq net.ipv6.conf.all.accept_dad=0
470 ip netns exec "${hsname}" sysctl -wq net.ipv6.conf.default.accept_dad=0
471
472 ip -netns "${hsname}" link add "${HS_VETH_NAME}" type veth \
473 peer name "${RT2HS_DEVNAME}" netns "${rtname}"
474
475 ip -netns "${hsname}" addr add "${IPv6_HS_NETWORK}::${hs}/64" \
476 dev "${HS_VETH_NAME}" nodad
477 ip -netns "${hsname}" addr add "${IPv4_HS_NETWORK}.${hs}/24" \
478 dev "${HS_VETH_NAME}"
479
480 ip -netns "${hsname}" link set "${HS_VETH_NAME}" up
481 ip -netns "${hsname}" link set lo up
482
483 ip -netns "${rtname}" addr add "${IPv6_HS_NETWORK}::254/64" \
484 dev "${RT2HS_DEVNAME}" nodad
485 ip -netns "${rtname}" addr \
486 add "${IPv4_HS_NETWORK}.254/24" dev "${RT2HS_DEVNAME}"
487
488 ip -netns "${rtname}" link set "${RT2HS_DEVNAME}" up
489
490 # disable the rp_filter otherwise the kernel gets confused about how
491 # to route decap ipv4 packets.
492 ip netns exec "${rtname}" \
493 sysctl -wq net.ipv4.conf."${RT2HS_DEVNAME}".rp_filter=0
494}
495
496# set an auto-generated mac address
497# args:
498# $1 - name of the node (e.g.: hs-1, rt-3, etc)
499# $2 - id of the node (e.g.: 1 for hs-1, 3 for rt-3, etc)
500# $3 - host part of the IPv6 network address
501# $4 - name of the network interface to which the generated mac address must
502# be set.
503set_mac_address()
504{
505 local nodename="$1"
506 local nodeid="$2"
507 local host="$3"
508 local ifname="$4"
509 local nsname
510
511 nsname=$(get_nodename "${nodename}")
512
513 ip -netns "${nsname}" link set dev "${ifname}" down
514
515 ip -netns "${nsname}" link set address "${MAC_PREFIX}:${nodeid}" \
516 dev "${ifname}"
517
518 # the IPv6 address must be set once again after the MAC address has
519 # been changed.
520 ip -netns "${nsname}" addr add "${IPv6_HS_NETWORK}::${host}/64" \
521 dev "${ifname}" nodad
522
523 ip -netns "${nsname}" link set dev "${ifname}" up
524}
525
526set_host_l2peer()
527{
528 local hssrc="$1"
529 local hsdst="$2"
530 local ipprefix="$3"
531 local proto="$4"
532 local hssrc_name
533 local ipaddr
534
535 hssrc_name="$(get_hsname "${hssrc}")"
536
537 if [ "${proto}" -eq 6 ]; then
538 ipaddr="${ipprefix}::${hsdst}"
539 else
540 ipaddr="${ipprefix}.${hsdst}"
541 fi
542
543 ip -netns "${hssrc_name}" route add "${ipaddr}" dev "${HS_VETH_NAME}"
544
545 ip -netns "${hssrc_name}" neigh \
546 add "${ipaddr}" lladdr "${MAC_PREFIX}:${hsdst}" \
547 dev "${HS_VETH_NAME}"
548}
549
550# setup an SRv6 L2 VPN between host hs-x and hs-y (currently, the SRv6
551# subsystem only supports L2 frames whose layer-3 is IPv4/IPv6).
552# args:
553# $1 - source host
554# $2 - SRv6 routers configured for steering tunneled traffic
555# $3 - destination host
556setup_l2vpn()
557{
558 local hssrc="$1"
559 local end_rts="$2"
560 local hsdst="$3"
561 local rtsrc="${hssrc}"
562 local rtdst="${hsdst}"
563
564 # set fixed mac for source node and the neigh MAC address
565 set_mac_address "hs-${hssrc}" "${hssrc}" "${hssrc}" "${HS_VETH_NAME}"
566 set_host_l2peer "${hssrc}" "${hsdst}" "${IPv6_HS_NETWORK}" 6
567 set_host_l2peer "${hssrc}" "${hsdst}" "${IPv4_HS_NETWORK}" 4
568
569 # we have to set the mac address of the veth-host (on ingress router)
570 # to the mac address of the remote peer (L2 VPN destination host).
571 # Otherwise, traffic coming from the source host is dropped at the
572 # ingress router.
573 set_mac_address "rt-${rtsrc}" "${hsdst}" 254 "${RT2HS_DEVNAME}"
574
575 # set the SRv6 Policies at the ingress router
576 setup_rt_policy_ipv6 "${hsdst}" "${rtsrc}" "${end_rts}" "${rtdst}" \
577 l2encap.red 6
578 setup_rt_policy_ipv4 "${hsdst}" "${rtsrc}" "${end_rts}" "${rtdst}" \
579 l2encap.red 4
580
581 # set the decap behavior
582 setup_decap "${rtsrc}"
583}
584
585setup()
586{
587 local i
588
589 # create routers
590 ROUTERS="1 2 3 4"; readonly ROUTERS
591 for i in ${ROUTERS}; do
592 create_router "${i}"
593 done
594
595 # create hosts
596 HOSTS="1 2"; readonly HOSTS
597 for i in ${HOSTS}; do
598 create_host "${i}"
599 done
600
601 # set up the links for connecting routers
602 add_link_rt_pairs 1 "2 3 4"
603 add_link_rt_pairs 2 "3 4"
604 add_link_rt_pairs 3 "4"
605
606 # set up the basic connectivity of routers and routes required for
607 # reachability of SIDs.
608 setup_rt_networking 1 "2 3 4"
609 setup_rt_networking 2 "1 3 4"
610 setup_rt_networking 3 "1 2 4"
611 setup_rt_networking 4 "1 2 3"
612
613 # set up the hosts connected to routers
614 setup_hs 1 1
615 setup_hs 2 2
616
617 # set up default SRv6 Endpoints (i.e. SRv6 End and SRv6 End.DX2)
618 setup_rt_local_sids 1 "2 3 4"
619 setup_rt_local_sids 2 "1 3 4"
620 setup_rt_local_sids 3 "1 2 4"
621 setup_rt_local_sids 4 "1 2 3"
622
623 # create a L2 VPN between hs-1 and hs-2.
624 # NB: currently, H.L2Encap* enables tunneling of L2 frames whose
625 # layer-3 is IPv4/IPv6.
626 #
627 # the network path between hs-1 and hs-2 traverses several routers
628 # depending on the direction of traffic.
629 #
630 # Direction hs-1 -> hs-2 (H.L2Encaps.Red)
631 # - rt-2 (SRv6 End.DX2 behavior)
632 #
633 # Direction hs-2 -> hs-1 (H.L2Encaps.Red)
634 # - rt-4,rt-3 (SRv6 End behaviors)
635 # - rt-1 (SRv6 End.DX2 behavior)
636 setup_l2vpn 1 "" 2
637 setup_l2vpn 2 "4 3" 1
638
639 # testing environment was set up successfully
640 SETUP_ERR=0
641}
642
643check_rt_connectivity()
644{
645 local rtsrc="$1"
646 local rtdst="$2"
647 local prefix
648 local rtsrc_nsname
649
650 rtsrc_nsname="$(get_rtname "${rtsrc}")"
651
652 prefix="$(get_network_prefix "${rtsrc}" "${rtdst}")"
653
654 ip netns exec "${rtsrc_nsname}" ping -c 1 -W "${PING_TIMEOUT_SEC}" \
655 "${prefix}::${rtdst}" >/dev/null 2>&1
656}
657
658check_and_log_rt_connectivity()
659{
660 local rtsrc="$1"
661 local rtdst="$2"
662
663 check_rt_connectivity "${rtsrc}" "${rtdst}"
664 log_test $? 0 "Routers connectivity: rt-${rtsrc} -> rt-${rtdst}"
665}
666
667check_hs_ipv6_connectivity()
668{
669 local hssrc="$1"
670 local hsdst="$2"
671 local hssrc_nsname
672
673 hssrc_nsname="$(get_hsname "${hssrc}")"
674
675 ip netns exec "${hssrc_nsname}" ping -c 1 -W "${PING_TIMEOUT_SEC}" \
676 "${IPv6_HS_NETWORK}::${hsdst}" >/dev/null 2>&1
677}
678
679check_hs_ipv4_connectivity()
680{
681 local hssrc="$1"
682 local hsdst="$2"
683 local hssrc_nsname
684
685 hssrc_nsname="$(get_hsname "${hssrc}")"
686
687 ip netns exec "${hssrc_nsname}" ping -c 1 -W "${PING_TIMEOUT_SEC}" \
688 "${IPv4_HS_NETWORK}.${hsdst}" >/dev/null 2>&1
689}
690
691check_and_log_hs2gw_connectivity()
692{
693 local hssrc="$1"
694
695 check_hs_ipv6_connectivity "${hssrc}" 254
696 log_test $? 0 "IPv6 Hosts connectivity: hs-${hssrc} -> gw"
697
698 check_hs_ipv4_connectivity "${hssrc}" 254
699 log_test $? 0 "IPv4 Hosts connectivity: hs-${hssrc} -> gw"
700}
701
702check_and_log_hs_ipv6_connectivity()
703{
704 local hssrc="$1"
705 local hsdst="$2"
706
707 check_hs_ipv6_connectivity "${hssrc}" "${hsdst}"
708 log_test $? 0 "IPv6 Hosts connectivity: hs-${hssrc} -> hs-${hsdst}"
709}
710
711check_and_log_hs_ipv4_connectivity()
712{
713 local hssrc="$1"
714 local hsdst="$2"
715
716 check_hs_ipv4_connectivity "${hssrc}" "${hsdst}"
717 log_test $? 0 "IPv4 Hosts connectivity: hs-${hssrc} -> hs-${hsdst}"
718}
719
720check_and_log_hs_connectivity()
721{
722 local hssrc="$1"
723 local hsdst="$2"
724
725 check_and_log_hs_ipv4_connectivity "${hssrc}" "${hsdst}"
726 check_and_log_hs_ipv6_connectivity "${hssrc}" "${hsdst}"
727}
728
729router_tests()
730{
731 local i
732 local j
733
734 log_section "IPv6 routers connectivity test"
735
736 for i in ${ROUTERS}; do
737 for j in ${ROUTERS}; do
738 if [ "${i}" -eq "${j}" ]; then
739 continue
740 fi
741
742 check_and_log_rt_connectivity "${i}" "${j}"
743 done
744 done
745}
746
747host2gateway_tests()
748{
749 local hs
750
751 log_section "IPv4/IPv6 connectivity test among hosts and gateways"
752
753 for hs in ${HOSTS}; do
754 check_and_log_hs2gw_connectivity "${hs}"
755 done
756}
757
758host_vpn_tests()
759{
760 log_section "SRv6 L2 VPN connectivity test hosts (h1 <-> h2)"
761
762 check_and_log_hs_connectivity 1 2
763 check_and_log_hs_connectivity 2 1
764}
765
766test_dummy_dev_or_ksft_skip()
767{
768 local test_netns
769
770 test_netns="dummy-$(mktemp -u XXXXXXXX)"
771
772 if ! ip netns add "${test_netns}"; then
773 echo "SKIP: Cannot set up netns for testing dummy dev support"
774 exit "${ksft_skip}"
775 fi
776
777 modprobe dummy &>/dev/null || true
778 if ! ip -netns "${test_netns}" link \
779 add "${DUMMY_DEVNAME}" type dummy; then
780 echo "SKIP: dummy dev not supported"
781
782 ip netns del "${test_netns}"
783 exit "${ksft_skip}"
784 fi
785
786 ip netns del "${test_netns}"
787}
788
789test_iproute2_supp_or_ksft_skip()
790{
791 if ! ip route help 2>&1 | grep -qo "l2encap.red"; then
792 echo "SKIP: Missing SRv6 l2encap.red support in iproute2"
793 exit "${ksft_skip}"
794 fi
795}
796
797if [ "$(id -u)" -ne 0 ]; then
798 echo "SKIP: Need root privileges"
799 exit "${ksft_skip}"
800fi
801
802# required programs to carry out this selftest
803test_command_or_ksft_skip ip
804test_command_or_ksft_skip ping
805test_command_or_ksft_skip sysctl
806test_command_or_ksft_skip grep
807
808test_iproute2_supp_or_ksft_skip
809test_dummy_dev_or_ksft_skip
810
811set -e
812trap cleanup EXIT
813
814setup
815set +e
816
817router_tests
818host2gateway_tests
819host_vpn_tests
820
821print_log_test_results