Documentation/networking/nexthop-group-resilient.rst - linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0

 =========================
 Resilient Next-hop Groups
 =========================

 Resilient groups are a type of next-hop group that is aimed at minimizing
 disruption in flow routing across changes to the group composition and
 weights of constituent next hops.

 The idea behind resilient hashing groups is best explained in contrast to
 the legacy multipath next-hop group, which uses the hash-threshold
 algorithm, described in RFC 2992.

 To select a next hop, hash-threshold algorithm first assigns a range of
 hashes to each next hop in the group, and then selects the next hop by
 comparing the SKB hash with the individual ranges. When a next hop is
 removed from the group, the ranges are recomputed, which leads to
 reassignment of parts of hash space from one next hop to another. RFC 2992
 illustrates it thus::

              +-------+-------+-------+-------+-------+
              |   1   |   2   |   3   |   4   |   5   |
              +-------+-+-----+---+---+-----+-+-------+
              |    1    |    2    |    4    |    5    |
              +---------+---------+---------+---------+

               Before and after deletion of next hop 3
 	      under the hash-threshold algorithm.

 Note how next hop 2 gave up part of the hash space in favor of next hop 1,
 and 4 in favor of 5. While there will usually be some overlap between the
 previous and the new distribution, some traffic flows change the next hop
 that they resolve to.

 If a multipath group is used for load-balancing between multiple servers,
 this hash space reassignment causes an issue that packets from a single
 flow suddenly end up arriving at a server that does not expect them. This
 can result in TCP connections being reset.

 If a multipath group is used for load-balancing among available paths to
 the same server, the issue is that different latencies and reordering along
 the way causes the packets to arrive in the wrong order, resulting in
 degraded application performance.

 To mitigate the above-mentioned flow redirection, resilient next-hop groups
 insert another layer of indirection between the hash space and its
 constituent next hops: a hash table. The selection algorithm uses SKB hash
 to choose a hash table bucket, then reads the next hop that this bucket
 contains, and forwards traffic there.

 This indirection brings an important feature. In the hash-threshold
 algorithm, the range of hashes associated with a next hop must be
 continuous. With a hash table, mapping between the hash table buckets and
 the individual next hops is arbitrary. Therefore when a next hop is deleted
 the buckets that held it are simply reassigned to other next hops::

 	    +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 	    |1|1|1|1|2|2|2|2|3|3|3|3|4|4|4|4|5|5|5|5|
 	    +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 	                     v v v v
 	    +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 	    |1|1|1|1|2|2|2|2|1|2|4|5|4|4|4|4|5|5|5|5|
 	    +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

 	    Before and after deletion of next hop 3
 	    under the resilient hashing algorithm.

 When weights of next hops in a group are altered, it may be possible to
 choose a subset of buckets that are currently not used for forwarding
 traffic, and use those to satisfy the new next-hop distribution demands,
 keeping the "busy" buckets intact. This way, established flows are ideally
 kept being forwarded to the same endpoints through the same paths as before
 the next-hop group change.

 Algorithm
 ---------

 In a nutshell, the algorithm works as follows. Each next hop deserves a
 certain number of buckets, according to its weight and the number of
 buckets in the hash table. In accordance with the source code, we will call
 this number a "wants count" of a next hop. In case of an event that might
 cause bucket allocation change, the wants counts for individual next hops
 are updated.

 Next hops that have fewer buckets than their wants count, are called
 "underweight". Those that have more are "overweight". If there are no
 overweight (and therefore no underweight) next hops in the group, it is
 said to be "balanced".

 Each bucket maintains a last-used timer. Every time a packet is forwarded
 through a bucket, this timer is updated to current jiffies value. One
 attribute of a resilient group is then the "idle timer", which is the
 amount of time that a bucket must not be hit by traffic in order for it to
 be considered "idle". Buckets that are not idle are busy.

 After assigning wants counts to next hops, an "upkeep" algorithm runs. For
 buckets:

 1) that have no assigned next hop, or
 2) whose next hop has been removed, or
 3) that are idle and their next hop is overweight,

 upkeep changes the next hop that the bucket references to one of the
 underweight next hops. If, after considering all buckets in this manner,
 there are still underweight next hops, another upkeep run is scheduled to a
 future time.

 There may not be enough "idle" buckets to satisfy the updated wants counts
 of all next hops. Another attribute of a resilient group is the "unbalanced
 timer". This timer can be set to 0, in which case the table will stay out
 of balance until idle buckets do appear, possibly never. If set to a
 non-zero value, the value represents the period of time that the table is
 permitted to stay out of balance.

 With this in mind, we update the above list of conditions with one more
 item. Thus buckets:

 4) whose next hop is overweight, and the amount of time that the table has
    been out of balance exceeds the unbalanced timer, if that is non-zero,

 \... are migrated as well.

 Offloading & Driver Feedback
 ----------------------------

 When offloading resilient groups, the algorithm that distributes buckets
 among next hops is still the one in SW. Drivers are notified of updates to
 next hop groups in the following three ways:

 - Full group notification with the type
   ``NH_NOTIFIER_INFO_TYPE_RES_TABLE``. This is used just after the group is
   created and buckets populated for the first time.

 - Single-bucket notifications of the type
   ``NH_NOTIFIER_INFO_TYPE_RES_BUCKET``, which is used for notifications of
   individual migrations within an already-established group.

 - Pre-replace notification, ``NEXTHOP_EVENT_RES_TABLE_PRE_REPLACE``. This
   is sent before the group is replaced, and is a way for the driver to veto
   the group before committing anything to the HW.

 Some single-bucket notifications are forced, as indicated by the "force"
 flag in the notification. Those are used for the cases where e.g. the next
 hop associated with the bucket was removed, and the bucket really must be
 migrated.

 Non-forced notifications can be overridden by the driver by returning an
 error code. The use case for this is that the driver notifies the HW that a
 bucket should be migrated, but the HW discovers that the bucket has in fact
 been hit by traffic.

 A second way for the HW to report that a bucket is busy is through the
 ``nexthop_res_grp_activity_update()`` API. The buckets identified this way
 as busy are treated as if traffic hit them.

 Offloaded buckets should be flagged as either "offload" or "trap". This is
 done through the ``nexthop_bucket_set_hw_flags()`` API.

 Netlink UAPI
 ------------

 Resilient Group Replacement
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^

 Resilient groups are configured using the ``RTM_NEWNEXTHOP`` message in the
 same manner as other multipath groups. The following changes apply to the
 attributes passed in the netlink message:

   =================== =========================================================
   ``NHA_GROUP_TYPE``  Should be ``NEXTHOP_GRP_TYPE_RES`` for resilient group.
   ``NHA_RES_GROUP``   A nest that contains attributes specific to resilient
                       groups.
   =================== =========================================================

 ``NHA_RES_GROUP`` payload:

   =================================== =========================================
   ``NHA_RES_GROUP_BUCKETS``           Number of buckets in the hash table.
   ``NHA_RES_GROUP_IDLE_TIMER``        Idle timer in units of clock_t.
   ``NHA_RES_GROUP_UNBALANCED_TIMER``  Unbalanced timer in units of clock_t.
   =================================== =========================================

 Next Hop Get
 ^^^^^^^^^^^^

 Requests to get resilient next-hop groups use the ``RTM_GETNEXTHOP``
 message in exactly the same way as other next hop get requests. The
 response attributes match the replacement attributes cited above, except
 ``NHA_RES_GROUP`` payload will include the following attribute:

   =================================== =========================================
   ``NHA_RES_GROUP_UNBALANCED_TIME``   How long has the resilient group been out
                                       of balance, in units of clock_t.
   =================================== =========================================

 Bucket Get
 ^^^^^^^^^^

 The message ``RTM_GETNEXTHOPBUCKET`` without the ``NLM_F_DUMP`` flag is
 used to request a single bucket. The attributes recognized at get requests
 are:

   =================== =========================================================
   ``NHA_ID``          ID of the next-hop group that the bucket belongs to.
   ``NHA_RES_BUCKET``  A nest that contains attributes specific to bucket.
   =================== =========================================================

 ``NHA_RES_BUCKET`` payload:

   ======================== ====================================================
   ``NHA_RES_BUCKET_INDEX`` Index of bucket in the resilient table.
   ======================== ====================================================

 Bucket Dumps
 ^^^^^^^^^^^^

 The message ``RTM_GETNEXTHOPBUCKET`` with the ``NLM_F_DUMP`` flag is used
 to request a dump of matching buckets. The attributes recognized at dump
 requests are:

   =================== =========================================================
   ``NHA_ID``          If specified, limits the dump to just the next-hop group
                       with this ID.
   ``NHA_OIF``         If specified, limits the dump to buckets that contain
                       next hops that use the device with this ifindex.
   ``NHA_MASTER``      If specified, limits the dump to buckets that contain
                       next hops that use a device in the VRF with this ifindex.
   ``NHA_RES_BUCKET``  A nest that contains attributes specific to bucket.
   =================== =========================================================

 ``NHA_RES_BUCKET`` payload:

   ======================== ====================================================
   ``NHA_RES_BUCKET_NH_ID`` If specified, limits the dump to just the buckets
                            that contain the next hop with this ID.
   ======================== ====================================================

 Usage
 -----

 To illustrate the usage, consider the following commands::

 	# ip nexthop add id 1 via 192.0.2.2 dev eth0
 	# ip nexthop add id 2 via 192.0.2.3 dev eth0
 	# ip nexthop add id 10 group 1/2 type resilient \
 		buckets 8 idle_timer 60 unbalanced_timer 300

 The last command creates a resilient next-hop group. It will have 8 buckets
 (which is unusually low number, and used here for demonstration purposes
 only), each bucket will be considered idle when no traffic hits it for at
 least 60 seconds, and if the table remains out of balance for 300 seconds,
 it will be forcefully brought into balance.

 Changing next-hop weights leads to change in bucket allocation::

 	# ip nexthop replace id 10 group 1,3/2 type resilient

 This can be confirmed by looking at individual buckets::

 	# ip nexthop bucket show id 10
 	id 10 index 0 idle_time 5.59 nhid 1
 	id 10 index 1 idle_time 5.59 nhid 1
 	id 10 index 2 idle_time 8.74 nhid 2
 	id 10 index 3 idle_time 8.74 nhid 2
 	id 10 index 4 idle_time 8.74 nhid 1
 	id 10 index 5 idle_time 8.74 nhid 1
 	id 10 index 6 idle_time 8.74 nhid 1
 	id 10 index 7 idle_time 8.74 nhid 1

 Note the two buckets that have a shorter idle time. Those are the ones that
 were migrated after the next-hop replace command to satisfy the new demand
 that next hop 1 be given 6 buckets instead of 4.

 Netdevsim
 ---------

 The netdevsim driver implements a mock offload of resilient groups, and
 exposes debugfs interface that allows marking individual buckets as busy.
 For example, the following will mark bucket 23 in next-hop group 10 as
 active::

 	# echo 10 23 > /sys/kernel/debug/netdevsim/netdevsim10/fib/nexthop_bucket_activity

 In addition, another debugfs interface can be used to configure that the
 next attempt to migrate a bucket should fail::

 	# echo 1 > /sys/kernel/debug/netdevsim/netdevsim10/fib/fail_nexthop_bucket_replace

 Besides serving as an example, the interfaces that netdevsim exposes are
 useful in automated testing, and
 ``tools/testing/selftests/drivers/net/netdevsim/nexthop.sh`` makes use of
 them to test the algorithm.
	.. SPDX-License-Identifier: GPL-2.0

	=========================
	Resilient Next-hop Groups
	=========================

	Resilient groups are a type of next-hop group that is aimed at minimizing
	disruption in flow routing across changes to the group composition and
	weights of constituent next hops.

	The idea behind resilient hashing groups is best explained in contrast to
	the legacy multipath next-hop group, which uses the hash-threshold
	algorithm, described in RFC 2992.

	To select a next hop, hash-threshold algorithm first assigns a range of
	hashes to each next hop in the group, and then selects the next hop by
	comparing the SKB hash with the individual ranges. When a next hop is
	removed from the group, the ranges are recomputed, which leads to
	reassignment of parts of hash space from one next hop to another. RFC 2992
	illustrates it thus::

	+-------+-------+-------+-------+-------+
	\| 1 \| 2 \| 3 \| 4 \| 5 \|
	+-------+-+-----+---+---+-----+-+-------+
	\| 1 \| 2 \| 4 \| 5 \|
	+---------+---------+---------+---------+

	Before and after deletion of next hop 3
	under the hash-threshold algorithm.

	Note how next hop 2 gave up part of the hash space in favor of next hop 1,
	and 4 in favor of 5. While there will usually be some overlap between the
	previous and the new distribution, some traffic flows change the next hop
	that they resolve to.

	If a multipath group is used for load-balancing between multiple servers,
	this hash space reassignment causes an issue that packets from a single
	flow suddenly end up arriving at a server that does not expect them. This
	can result in TCP connections being reset.

	If a multipath group is used for load-balancing among available paths to
	the same server, the issue is that different latencies and reordering along
	the way causes the packets to arrive in the wrong order, resulting in
	degraded application performance.

	To mitigate the above-mentioned flow redirection, resilient next-hop groups
	insert another layer of indirection between the hash space and its
	constituent next hops: a hash table. The selection algorithm uses SKB hash
	to choose a hash table bucket, then reads the next hop that this bucket
	contains, and forwards traffic there.

	This indirection brings an important feature. In the hash-threshold
	algorithm, the range of hashes associated with a next hop must be
	continuous. With a hash table, mapping between the hash table buckets and
	the individual next hops is arbitrary. Therefore when a next hop is deleted
	the buckets that held it are simply reassigned to other next hops::

	+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
	\|1\|1\|1\|1\|2\|2\|2\|2\|3\|3\|3\|3\|4\|4\|4\|4\|5\|5\|5\|5\|
	+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
	v v v v
	+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
	\|1\|1\|1\|1\|2\|2\|2\|2\|1\|2\|4\|5\|4\|4\|4\|4\|5\|5\|5\|5\|
	+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

	Before and after deletion of next hop 3
	under the resilient hashing algorithm.

	When weights of next hops in a group are altered, it may be possible to
	choose a subset of buckets that are currently not used for forwarding
	traffic, and use those to satisfy the new next-hop distribution demands,
	keeping the "busy" buckets intact. This way, established flows are ideally
	kept being forwarded to the same endpoints through the same paths as before
	the next-hop group change.

	Algorithm
	---------

	In a nutshell, the algorithm works as follows. Each next hop deserves a
	certain number of buckets, according to its weight and the number of
	buckets in the hash table. In accordance with the source code, we will call
	this number a "wants count" of a next hop. In case of an event that might
	cause bucket allocation change, the wants counts for individual next hops
	are updated.

	Next hops that have fewer buckets than their wants count, are called
	"underweight". Those that have more are "overweight". If there are no
	overweight (and therefore no underweight) next hops in the group, it is
	said to be "balanced".

	Each bucket maintains a last-used timer. Every time a packet is forwarded
	through a bucket, this timer is updated to current jiffies value. One
	attribute of a resilient group is then the "idle timer", which is the
	amount of time that a bucket must not be hit by traffic in order for it to
	be considered "idle". Buckets that are not idle are busy.

	After assigning wants counts to next hops, an "upkeep" algorithm runs. For
	buckets:

	1) that have no assigned next hop, or
	2) whose next hop has been removed, or
	3) that are idle and their next hop is overweight,

	upkeep changes the next hop that the bucket references to one of the
	underweight next hops. If, after considering all buckets in this manner,
	there are still underweight next hops, another upkeep run is scheduled to a
	future time.

	There may not be enough "idle" buckets to satisfy the updated wants counts
	of all next hops. Another attribute of a resilient group is the "unbalanced
	timer". This timer can be set to 0, in which case the table will stay out
	of balance until idle buckets do appear, possibly never. If set to a
	non-zero value, the value represents the period of time that the table is
	permitted to stay out of balance.

	With this in mind, we update the above list of conditions with one more
	item. Thus buckets:

	4) whose next hop is overweight, and the amount of time that the table has
	been out of balance exceeds the unbalanced timer, if that is non-zero,

	\... are migrated as well.

	Offloading & Driver Feedback
	----------------------------

	When offloading resilient groups, the algorithm that distributes buckets
	among next hops is still the one in SW. Drivers are notified of updates to
	next hop groups in the following three ways:

	- Full group notification with the type
	``NH_NOTIFIER_INFO_TYPE_RES_TABLE``. This is used just after the group is
	created and buckets populated for the first time.

	- Single-bucket notifications of the type
	``NH_NOTIFIER_INFO_TYPE_RES_BUCKET``, which is used for notifications of
	individual migrations within an already-established group.

	- Pre-replace notification, ``NEXTHOP_EVENT_RES_TABLE_PRE_REPLACE``. This
	is sent before the group is replaced, and is a way for the driver to veto
	the group before committing anything to the HW.

	Some single-bucket notifications are forced, as indicated by the "force"
	flag in the notification. Those are used for the cases where e.g. the next
	hop associated with the bucket was removed, and the bucket really must be
	migrated.

	Non-forced notifications can be overridden by the driver by returning an
	error code. The use case for this is that the driver notifies the HW that a
	bucket should be migrated, but the HW discovers that the bucket has in fact
	been hit by traffic.

	A second way for the HW to report that a bucket is busy is through the
	``nexthop_res_grp_activity_update()`` API. The buckets identified this way
	as busy are treated as if traffic hit them.

	Offloaded buckets should be flagged as either "offload" or "trap". This is
	done through the ``nexthop_bucket_set_hw_flags()`` API.

	Netlink UAPI
	------------

	Resilient Group Replacement
	^^^^^^^^^^^^^^^^^^^^^^^^^^^

	Resilient groups are configured using the ``RTM_NEWNEXTHOP`` message in the
	same manner as other multipath groups. The following changes apply to the
	attributes passed in the netlink message:

	=================== =========================================================
	``NHA_GROUP_TYPE`` Should be ``NEXTHOP_GRP_TYPE_RES`` for resilient group.
	``NHA_RES_GROUP`` A nest that contains attributes specific to resilient
	groups.
	=================== =========================================================

	``NHA_RES_GROUP`` payload:

	=================================== =========================================
	``NHA_RES_GROUP_BUCKETS`` Number of buckets in the hash table.
	``NHA_RES_GROUP_IDLE_TIMER`` Idle timer in units of clock_t.
	``NHA_RES_GROUP_UNBALANCED_TIMER`` Unbalanced timer in units of clock_t.
	=================================== =========================================

	Next Hop Get
	^^^^^^^^^^^^

	Requests to get resilient next-hop groups use the ``RTM_GETNEXTHOP``
	message in exactly the same way as other next hop get requests. The
	response attributes match the replacement attributes cited above, except
	``NHA_RES_GROUP`` payload will include the following attribute:

	=================================== =========================================
	``NHA_RES_GROUP_UNBALANCED_TIME`` How long has the resilient group been out
	of balance, in units of clock_t.
	=================================== =========================================

	Bucket Get
	^^^^^^^^^^

	The message ``RTM_GETNEXTHOPBUCKET`` without the ``NLM_F_DUMP`` flag is
	used to request a single bucket. The attributes recognized at get requests
	are:

	=================== =========================================================
	``NHA_ID`` ID of the next-hop group that the bucket belongs to.
	``NHA_RES_BUCKET`` A nest that contains attributes specific to bucket.
	=================== =========================================================

	``NHA_RES_BUCKET`` payload:

	======================== ====================================================
	``NHA_RES_BUCKET_INDEX`` Index of bucket in the resilient table.
	======================== ====================================================

	Bucket Dumps
	^^^^^^^^^^^^

	The message ``RTM_GETNEXTHOPBUCKET`` with the ``NLM_F_DUMP`` flag is used
	to request a dump of matching buckets. The attributes recognized at dump
	requests are:

	=================== =========================================================
	``NHA_ID`` If specified, limits the dump to just the next-hop group
	with this ID.
	``NHA_OIF`` If specified, limits the dump to buckets that contain
	next hops that use the device with this ifindex.
	``NHA_MASTER`` If specified, limits the dump to buckets that contain
	next hops that use a device in the VRF with this ifindex.
	``NHA_RES_BUCKET`` A nest that contains attributes specific to bucket.
	=================== =========================================================

	``NHA_RES_BUCKET`` payload:

	======================== ====================================================
	``NHA_RES_BUCKET_NH_ID`` If specified, limits the dump to just the buckets
	that contain the next hop with this ID.
	======================== ====================================================

	Usage
	-----

	To illustrate the usage, consider the following commands::

	# ip nexthop add id 1 via 192.0.2.2 dev eth0
	# ip nexthop add id 2 via 192.0.2.3 dev eth0
	# ip nexthop add id 10 group 1/2 type resilient \
	buckets 8 idle_timer 60 unbalanced_timer 300

	The last command creates a resilient next-hop group. It will have 8 buckets
	(which is unusually low number, and used here for demonstration purposes
	only), each bucket will be considered idle when no traffic hits it for at
	least 60 seconds, and if the table remains out of balance for 300 seconds,
	it will be forcefully brought into balance.

	Changing next-hop weights leads to change in bucket allocation::

	# ip nexthop replace id 10 group 1,3/2 type resilient

	This can be confirmed by looking at individual buckets::

	# ip nexthop bucket show id 10
	id 10 index 0 idle_time 5.59 nhid 1
	id 10 index 1 idle_time 5.59 nhid 1
	id 10 index 2 idle_time 8.74 nhid 2
	id 10 index 3 idle_time 8.74 nhid 2
	id 10 index 4 idle_time 8.74 nhid 1
	id 10 index 5 idle_time 8.74 nhid 1
	id 10 index 6 idle_time 8.74 nhid 1
	id 10 index 7 idle_time 8.74 nhid 1

	Note the two buckets that have a shorter idle time. Those are the ones that
	were migrated after the next-hop replace command to satisfy the new demand
	that next hop 1 be given 6 buckets instead of 4.

	Netdevsim
	---------

	The netdevsim driver implements a mock offload of resilient groups, and
	exposes debugfs interface that allows marking individual buckets as busy.
	For example, the following will mark bucket 23 in next-hop group 10 as
	active::

	# echo 10 23 > /sys/kernel/debug/netdevsim/netdevsim10/fib/nexthop_bucket_activity

	In addition, another debugfs interface can be used to configure that the
	next attempt to migrate a bucket should fail::

	# echo 1 > /sys/kernel/debug/netdevsim/netdevsim10/fib/fail_nexthop_bucket_replace

	Besides serving as an example, the interfaces that netdevsim exposes are
	useful in automated testing, and
	``tools/testing/selftests/drivers/net/netdevsim/nexthop.sh`` makes use of
	them to test the algorithm.