утилита трассировки логической сети Open Virtual Network (Open Virtual Network logical network tracing utility)
Имя (Name)
ovn-trace - Open Virtual Network logical network tracing utility
Синопсис (Synopsis)
ovn-trace [options] datapath microflow
ovn-trace [options] --detach
Описание (Description)
This utility simulates packet forwarding within an OVN logical
network. It can be used to run through ``what-if'' scenarios: if
a packet originates at a logical port, what will happen to it and
where will it ultimately end up? Users already familiar with the
Open vSwitch ofproto/trace command described in ovs-vswitch(8)
will find ovn-trace to be a similar tool for logical networks.
ovn-trace works by reading the Logical_Flow and other tables from
the OVN southbound database (see ovn-sb(5)). It simulates a
packet's path through logical networks by repeatedly looking it
up in the logical flow table, following the entire tree of
possibilities.
ovn-trace simulates only the OVN logical network. It does not
simulate the physical elements on which the logical network is
layered. This means that, for example, it is unimportant how VMs
are distributed among hypervisors, or whether their hypervisors
are functioning and reachable, so ovn-trace will yield the same
results regardless. There is one important exception: ovn-northd,
the daemon that generates the logical flows that ovn-trace
simulates, treats logical ports differently based on whether they
are up or down. Thus, if you see surprising results, ensure that
the ports involved in a simulation are up.
The simplest way to use ovn-trace is to provide datapath and
microflow arguments on the command line. In this case, it
simulates the behavior of a single packet and exits. For an
alternate usage model, see Daemon Mode below.
The datapath argument specifies the name of a logical datapath.
Acceptable names are the name from the northbound Logical_Switch
or Logical_Router table, the UUID of a record from one of those
tables, or the UUID of a record from the southbound
Datapath_Binding table.
The microflow argument describes the packet whose forwarding is
to be simulated, in the syntax of an OVN logical expression, as
described in ovn-sb(5), to express constraints. The parser
understands prerequisites; for example, if the expression refers
to ip4.src, there is no need to explicitly state ip4 or eth.type
== 0x800.
For reasonable L2 behavior, the microflow should include at least
inport and eth.dst, plus eth.src if port security is enabled. For
example:
inport == "lp11" && eth.src == 00:01:02:03:04:05 && eth.dst == ff:ff:ff:ff:ff:ff
For reasonable L3 behavior, microflow should also include ip4.src
and ip4.dst (or ip6.src and ip6.dst) and ip.ttl. For example:
inport == "lp111" && eth.src == f0:00:00:00:01:11 && eth.dst == 00:00:00:00:ff:11
&& ip4.src == 192.168.11.1 && ip4.dst == 192.168.22.2 && ip.ttl == 64
Here's an ARP microflow example:
inport == "lp123"
&& eth.dst == ff:ff:ff:ff:ff:ff && eth.src == f0:00:00:00:01:11
&& arp.op == 1 && arp.sha == f0:00:00:00:01:11 && arp.spa == 192.168.1.11
&& arp.tha == ff:ff:ff:ff:ff:ff && arp.tpa == 192.168.2.22
ovn-trace will reject erroneous microflow expressions, which
beyond syntax errors fall into two categories. First, they can be
ambiguous. For example, tcp.src == 80 is ambiguous because it
does not state IPv4 or IPv6 as the Ethernet type. ip4 && tcp.src
> 1024 is also ambiguous because it does not constrain bits of
tcp.src to particular values. Second, they can be contradictory,
e.g. ip4 && ip6.
