</p>
</column>
- <column name="other_config" key="flow-eviction-threshold"
+ <column name="other_config" key="flow-limit"
type='{"type": "integer", "minInteger": 0}'>
<p>
- A number of flows as a nonnegative integer. This sets number of
- flows at which eviction from the datapath flow table will be
- triggered. If there are a large number of flows then increasing this
- value to around the number of flows present can result in reduced CPU
- usage and packet loss.
+ The maximum
+ number of flows allowed in the datapath flow table. Internally OVS
+ will choose a flow limit which will likely be lower than this number,
+ based on real time network conditions.
</p>
<p>
- The default is 2500. Values below 100 will be rounded up to 100.
+ The default is 200000.
</p>
</column>
type='{"type": "integer", "minInteger": 1}'>
<p>
Specifies the number of threads for software datapaths to use for
- handling new flows. The default is two less than the number of
- online CPU cores (but at least 1).
+ handling new flows. The default the number of online CPU cores minus
+ the number of revalidators.
+ </p>
+ <p>
+ This configuration is per datapath. If you have more than one
+ software datapath (e.g. some <code>system</code> bridges and some
+ <code>netdev</code> bridges), then the total number of threads is
+ <code>n-handler-threads</code> times the number of software
+ datapaths.
+ </p>
+ </column>
+
+ <column name="other_config" key="n-revalidator-threads"
+ type='{"type": "integer", "minInteger": 1}'>
+ <p>
+ Specifies the number of threads for software datapaths to use for
+ revalidating flows in the datapath. Typically, there is a direct
+ correlation between the number of revalidator threads, and the number
+ of flows allowed in the datapath. The default is the number of cpu
+ cores divided by four plus one. If <code>n-handler-threads</code> is
+ set, the default changes to the number of cpu cores minus the number
+ of handler threads.
</p>
<p>
This configuration is per datapath. If you have more than one
</p>
<column name="cfm_mpid">
- A Maintenance Point ID (MPID) uniquely identifies each endpoint within
- a Maintenance Association. The MPID is used to identify this endpoint
- to other Maintenance Points in the MA. Each end of a link being
- monitored should have a different MPID. Must be configured to enable
- CFM on this <ref table="Interface"/>.
+ <p>
+ A Maintenance Point ID (MPID) uniquely identifies each endpoint
+ within a Maintenance Association. The MPID is used to identify this
+ endpoint to other Maintenance Points in the MA. Each end of a link
+ being monitored should have a different MPID. Must be configured to
+ enable CFM on this <ref table="Interface"/>.
+ </p>
+ <p>
+ According to the 802.1ag specification, MPIDs can only range between
+ [1, 8191]. However, extended mode (see <ref column="other_config"
+ key="cfm_extended"/>) supports eight byte MPIDs.
+ </p>
</column>
<column name="cfm_flap_count">
with compliant implementations which may be running concurrently on the
network. Furthermore, extended mode increases the accuracy of the
<code>cfm_interval</code> configuration parameter by breaking wire
- compatibility with 802.1ag compliant implementations. Defaults to
- <code>false</code>.
+ compatibility with 802.1ag compliant implementations. And extended
+ mode allows eight byte MPIDs. Defaults to <code>false</code>.
</column>
<column name="other_config" key="cfm_demand" type='{"type": "boolean"}'>