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The mirror_gre_scale test creates as many ERSPAN sessions as the underlying chip supports, and tests that they all work. In order to determine that it issues a stream of ICMP packets and checks if they are mirrored as expected. However, the mausezahn invocation missed the -6 flag to identify the use of IPv6 protocol, and was sending ICMP messages over IPv6, as opposed to ICMP6. It also didn't pass an explicit source IP address, which apparently worked at some point in the past, but does not anymore. To fix these issues, extend the function mirror_test() in mirror_lib by detecting the IPv6 protocol addresses, and using a different ICMP scheme. Fix __mirror_gre_test() in the selftest itself to pass a source IP address. Signed-off-by: Petr Machata <petrm@nvidia.com> Signed-off-by: David S. Miller <davem@davemloft.net> |
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| .. | ||
| .gitignore | ||
| bridge_igmp.sh | ||
| bridge_mld.sh | ||
| bridge_port_isolation.sh | ||
| bridge_sticky_fdb.sh | ||
| bridge_vlan_aware.sh | ||
| bridge_vlan_unaware.sh | ||
| config | ||
| devlink_lib.sh | ||
| dual_vxlan_bridge.sh | ||
| ethtool.sh | ||
| ethtool_extended_state.sh | ||
| ethtool_lib.sh | ||
| fib_offload_lib.sh | ||
| forwarding.config.sample | ||
| gre_inner_v4_multipath.sh | ||
| gre_inner_v6_multipath.sh | ||
| gre_multipath.sh | ||
| gre_multipath_nh.sh | ||
| gre_multipath_nh_res.sh | ||
| ip6gre_inner_v4_multipath.sh | ||
| ip6gre_inner_v6_multipath.sh | ||
| ipip_flat_gre.sh | ||
| ipip_flat_gre_key.sh | ||
| ipip_flat_gre_keys.sh | ||
| ipip_hier_gre.sh | ||
| ipip_hier_gre_key.sh | ||
| ipip_hier_gre_keys.sh | ||
| ipip_lib.sh | ||
| lib.sh | ||
| loopback.sh | ||
| Makefile | ||
| mirror_gre.sh | ||
| mirror_gre_bound.sh | ||
| mirror_gre_bridge_1d.sh | ||
| mirror_gre_bridge_1d_vlan.sh | ||
| mirror_gre_bridge_1q.sh | ||
| mirror_gre_bridge_1q_lag.sh | ||
| mirror_gre_changes.sh | ||
| mirror_gre_flower.sh | ||
| mirror_gre_lag_lacp.sh | ||
| mirror_gre_lib.sh | ||
| mirror_gre_neigh.sh | ||
| mirror_gre_nh.sh | ||
| mirror_gre_topo_lib.sh | ||
| mirror_gre_vlan.sh | ||
| mirror_gre_vlan_bridge_1q.sh | ||
| mirror_lib.sh | ||
| mirror_topo_lib.sh | ||
| mirror_vlan.sh | ||
| pedit_dsfield.sh | ||
| pedit_l4port.sh | ||
| q_in_vni.sh | ||
| README | ||
| router.sh | ||
| router_bridge.sh | ||
| router_bridge_vlan.sh | ||
| router_broadcast.sh | ||
| router_mpath_nh.sh | ||
| router_mpath_nh_res.sh | ||
| router_multicast.sh | ||
| router_multipath.sh | ||
| router_nh.sh | ||
| router_vid_1.sh | ||
| sch_ets.sh | ||
| sch_ets_core.sh | ||
| sch_ets_tests.sh | ||
| sch_red.sh | ||
| sch_tbf_core.sh | ||
| sch_tbf_ets.sh | ||
| sch_tbf_etsprio.sh | ||
| sch_tbf_prio.sh | ||
| sch_tbf_root.sh | ||
| skbedit_priority.sh | ||
| tc_actions.sh | ||
| tc_chains.sh | ||
| tc_common.sh | ||
| tc_flower.sh | ||
| tc_flower_router.sh | ||
| tc_mpls_l2vpn.sh | ||
| tc_police.sh | ||
| tc_shblocks.sh | ||
| tc_vlan_modify.sh | ||
| vxlan_asymmetric.sh | ||
| vxlan_bridge_1d.sh | ||
| vxlan_bridge_1d_port_8472.sh | ||
| vxlan_bridge_1q.sh | ||
| vxlan_bridge_1q_port_8472.sh | ||
| vxlan_symmetric.sh | ||
Motivation
==========
One of the nice things about network namespaces is that they allow one
to easily create and test complex environments.
Unfortunately, these namespaces can not be used with actual switching
ASICs, as their ports can not be migrated to other network namespaces
(NETIF_F_NETNS_LOCAL) and most of them probably do not support the
L1-separation provided by namespaces.
However, a similar kind of flexibility can be achieved by using VRFs and
by looping the switch ports together. For example:
br0
+
vrf-h1 | vrf-h2
+ +---+----+ +
| | | |
192.0.2.1/24 + + + + 192.0.2.2/24
swp1 swp2 swp3 swp4
+ + + +
| | | |
+--------+ +--------+
The VRFs act as lightweight namespaces representing hosts connected to
the switch.
This approach for testing switch ASICs has several advantages over the
traditional method that requires multiple physical machines, to name a
few:
1. Only the device under test (DUT) is being tested without noise from
other system.
2. Ability to easily provision complex topologies. Testing bridging
between 4-ports LAGs or 8-way ECMP requires many physical links that are
not always available. With the VRF-based approach one merely needs to
loopback more ports.
These tests are written with switch ASICs in mind, but they can be run
on any Linux box using veth pairs to emulate physical loopbacks.
Guidelines for Writing Tests
============================
o Where possible, reuse an existing topology for different tests instead
of recreating the same topology.
o Tests that use anything but the most trivial topologies should include
an ASCII art showing the topology.
o Where possible, IPv6 and IPv4 addresses shall conform to RFC 3849 and
RFC 5737, respectively.
o Where possible, tests shall be written so that they can be reused by
multiple topologies and added to lib.sh.
o Checks shall be added to lib.sh for any external dependencies.
o Code shall be checked using ShellCheck [1] prior to submission.
1. https://www.shellcheck.net/