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diff --git a/docs/gettingstarted/developers/fib20/fastconvergence.rst b/docs/gettingstarted/developers/fib20/fastconvergence.rst
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+++ b/docs/gettingstarted/developers/fib20/fastconvergence.rst
@@ -3,6 +3,574 @@
Fast Convergence
------------------------------------
-.. note::
+This is an excellent description of the topic:
+
+'FIB <https://tools.ietf.org/html/draft-ietf-rtgwg-bgp-pic-12>'_
+
+but if you're interested in my take keep reading...
+
+First some definitions:
+
+- Convergence; When a FIB is forwarding all packets correctly based
+ on the network topology (i.e. doing what the routing control plane
+ has instructed it to do), then it is said to be 'converged'.
+ Not being in a converged state is [hopefully] a transient state,
+ when either the topology change (e.g. a link failure) has not been
+ observed or processed by the routing control plane, or that the FIB
+ is still processing routing updates. Convergence is the act of
+ getting to the converged state.
+- Fast: In the shortest time possible. There are no absolute limits
+ placed on how short this must be, although there is one number often
+ mentioned. Apparently the human ear can detect loss/delay/jitter in
+ VOIP of 50ms, therefore network failures should last no longer than
+ this, and some technologies (notably link-free alternate fast
+ reroute) are designed to converge in this time. However, it is
+ generally accepted that it is not possible to converge a FIB with
+ tens of millions of routes in this time scale, the industry
+ 'standard' is sub-second.
+
+Converging the FIB quickly is thus a matter of:
+
+- discovering something is down
+- updating as few objects as possible
+- to determine which objects to update as efficiently as possible
+- to update each object as quickly as possible
+
+we'll discuss each in turn.
+All output came from VPP version 21.01rc0. In what follows I use IPv4
+prefixes, addresses and IPv4 host length masks, however, exactly the
+same applies to IPv6.
+
+
+Failure Detection
+^^^^^^^^^^^^^^^^^
+
+The two common forms (we'll see others later on) of failure detection
+are:
+
+- link down
+- BFD
+
+The FIB needs to hook into these notifications to trigger
+convergence.
+
+Whenever an interface goes down, VPP issues a callback to all
+registerd clients. The adjacency code is such a client. The adjacency
+is a leaf node in the FIB control-plane graph (containing fib_path_t,
+fib_entry_t etc). A back-walk from the adjacnecy will trigger a
+re-resolution of the paths.
+
+FIB is a client of BFD in order to receive BFD notifications. BFD
+comes in two flavours; single and multi hop. Single hop is to protect
+a specific peer on an interface, such peers are modelled by an
+adjacency. Multi hop is to protect a peer on an unspecified interface
+(i.e. a remote peer), this peer is represented by a host-prefix
+**fib_entry_t**. In both case FIB will add a delegate to the
+**ip_adjacency_t** or **fib_entry_t** that represents the association
+to the BFD session. If the BFD session signals up/down then a backwalk
+can be triggered from the object to trigger re-resolution and hence
+convergence.
+
+
+Few Updates
+^^^^^^^^^^^
+
+In order to talk about what 'a few' is we have to leave the realm of
+the FIB as an abstract graph based object DB and move into the
+concrete representation of forwarding in a large network. Large
+networks are built in layers, it's how you scale them. We'll take
+here a hypothetical service provider (SP) network, but the concepts
+apply equally to data center leaf-spines. This is a rudimentary
+description, but it should serve our purpose.
+
+An SP manages a BGP autonomous system (AS). The SP's goal is both to
+attract traffic into its network to serve its customers, but also to
+serve transit traffic passing through it, we'll consider the latter here.
+The SP's network is all devices in that AS, these
+devices are split into those at the edge (provider edge (PE) routers)
+which peer with routers in other SP networks,
+and those in the core (termed provider (P) routers). Both the PE and P
+routers run the IGP (usually OSPF or ISIS). Only the reachability of the devices
+in the AS are advertised in the IGP - thus the scale (i.e. the number
+of routes) in the IGP is 'small' - only the number of
+devices that the SP has (typically not more than a few 10k).
+PE routers run BGP; they have external BGP sessions to devices in
+other ASs and internal BGP sessions to devices in the same AS. BGP is
+used to advertise the routes to *all* networks on the internet - at
+the time of writing this number is approaching 900k IPv4 route, hopefully by
+the time you are reading this the number of IPv6 routes has caught up ...
+If we include the additional routes the SP carries to offering VPN service to its
+customers the number of BGP routes can grow to the tens of millions.
+
+BGP scale thus exceeds IGP scale by two orders of magnitude... pause for
+a moment and let that sink in...
+
+A comparison of BGP and an IGP is way way beyond the scope of this
+documentation (and frankly beyond me) so we'll note only the
+difference in the form of the routes they present to FIB. A routing
+protocol will produce routes that specify the prefixes that are
+reachable through its peers. A good IGP
+is link state based, it forms peerings to other devices over these
+links, hence its routes specify links/interfaces. In
+FIB nomenclature this means an IGP produces routes that are
+attached-nexthop, e.g.:
+
+.. code-block:: console
+
+ ip route add 1.1.1.1/32 via 10.0.0.1 GigEthernet0/0/0
+
+BGP on the other hand forms peerings only to neighbours, it does not
+know, nor care, what interface is used to reach the peer. In FIB
+nomenclature therefore BGP produces recursive routes, e.g.:
+
+.. code-block:: console
+
+ ip route 8.0.0.0/16 via 1.1.1.1
+
+where 1.1.1.1 is the BGP peer. It's no accident in this example that
+1.1.1.1/32 happens to be the route the IGP advertised... BGP installs
+routes for prefixes reachable via other BGP peers, and the IGP install
+the routes to those BGP peers.
+
+This has been a very long winded way of describing why the scale of
+recursive routes is therefore 2 orders of magnitude greater than
+non-recursive/attached-nexthop routes.
+
+If we step back for a moment and recall why we've crawled down this
+rabbit hole, we're trying to determine what 'a few' updates means,
+does it include all those recursive routes, probably not ... let's
+keep crawling.
+
+We started this chapter with an abstract description of convergence,
+let's now make that more real. In the event of a network failure an SP
+is interested in moving to an alternate forwarding path as quickly as
+possible. If there is no alternate path, and a converged FIB will drop
+the packet, then who cares how fast it converges. In other words the
+interesting convergence scenarios are the scenarios where the network has
+alternate paths.
+
+PIC Core
+^^^^^^^^
+
+First let's consider alternate paths in the IGP, e.g.;
+
+.. code-block:: console
+
+ ip route add 1.1.1.1/32 via 10.0.0.2 GigEthernet0/0/0
+ ip route add 1.1.1.1/32 via 10.0.1.2 GigEthernet0/0/1
+
+this gives us in the FIB:
+
+.. code-block:: console
+
+ DBGvpp# sh ip fib 1.1.1.1/32
+ ipv4-VRF:0, fib_index:0, flow hash:[src dst sport dport proto ] epoch:0 flags:none locks:[adjacency:1, default-route:1, ]
+ 1.1.1.1/32 fib:0 index:15 locks:2
+ API refs:1 src-flags:added,contributing,active,
+ path-list:[23] locks:2 flags:shared, uPRF-list:22 len:2 itfs:[1, 2, ]
+ path:[27] pl-index:23 ip4 weight=1 pref=0 attached-nexthop: oper-flags:resolved,
+ 10.0.0.2 GigEthernet0/0/0
+ [@0]: ipv4 via 10.0.0.2 GigEthernet0/0/0: mtu:9000 next:3 001111111111dead000000000800
+ path:[28] pl-index:23 ip4 weight=1 pref=0 attached-nexthop: oper-flags:resolved,
+ 10.0.1.2 GigEthernet0/0/1
+ [@0]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+
+ forwarding: unicast-ip4-chain
+ [@0]: dpo-load-balance: [proto:ip4 index:17 buckets:2 uRPF:22 to:[0:0]]
+ [0] [@5]: ipv4 via 10.0.0.2 GigEthernet0/0/0: mtu:9000 next:3 001111111111dead000000000800
+ [1] [@5]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+
+There is ECMP across the two paths. Note that the instance/index of the
+load-balance present in the forwarding graph is 17.
+
+Let's add a BGP route via this peer;
+
+.. code-block:: console
+
+ ip route add 8.0.0.0/16 via 1.1.1.1
+
+in the FIB we see:
+
+
+.. code-block:: console
+
+ DBGvpp# sh ip fib 8.0.0.0/16
+ ipv4-VRF:0, fib_index:0, flow hash:[src dst sport dport proto ] epoch:0 flags:none locks:[adjacency:1, recursive-resolution:1, default-route:1, ]
+ 8.0.0.0/16 fib:0 index:18 locks:2
+ API refs:1 src-flags:added,contributing,active,
+ path-list:[24] locks:2 flags:shared, uPRF-list:21 len:2 itfs:[1, 2, ]
+ path:[29] pl-index:24 ip4 weight=1 pref=0 recursive: oper-flags:resolved,
+ via 1.1.1.1 in fib:0 via-fib:15 via-dpo:[dpo-load-balance:17]
+
+ forwarding: unicast-ip4-chain
+ [@0]: dpo-load-balance: [proto:ip4 index:20 buckets:1 uRPF:21 to:[0:0]]
+ [0] [@12]: dpo-load-balance: [proto:ip4 index:17 buckets:2 uRPF:22 to:[0:0]]
+ [0] [@5]: ipv4 via 10.0.0.2 GigEthernet0/0/0: mtu:9000 next:3 001111111111dead000000000800
+ [1] [@5]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+
+the load-balance object used by this route is index 20, but note that
+the next load-balance in the chain is index 17, i.e. it is exactly
+the same instance that appears in the forwarding chain for the IGP
+route. So in the forwarding plane the packet first encounters
+load-balance object 20 (which it will use in ip4-lookup) and then
+number 17 (in ip4-load-balance).
+
+What's the significance? Let's shut down one of those IGP paths:
+
+.. code-block:: console
+
+ DBGvpp# set in state GigEthernet0/0/0 down
+
+the resulting update to the IGP route is:
+
+.. code-block:: console
+
+ DBGvpp# sh ip fib 1.1.1.1/32
+ ipv4-VRF:0, fib_index:0, flow hash:[src dst sport dport proto ] epoch:0 flags:none locks:[adjacency:1, recursive-resolution:1, default-route:1, ]
+ 1.1.1.1/32 fib:0 index:15 locks:4
+ API refs:1 src-flags:added,contributing,active,
+ path-list:[23] locks:2 flags:shared, uPRF-list:25 len:2 itfs:[1, 2, ]
+ path:[27] pl-index:23 ip4 weight=1 pref=0 attached-nexthop:
+ 10.0.0.2 GigEthernet0/0/0
+ [@0]: arp-ipv4: via 10.0.0.2 GigEthernet0/0/0
+ path:[28] pl-index:23 ip4 weight=1 pref=0 attached-nexthop: oper-flags:resolved,
+ 10.0.1.2 GigEthernet0/0/1
+ [@0]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+
+ recursive-resolution refs:1 src-flags:added, cover:-1
+
+ forwarding: unicast-ip4-chain
+ [@0]: dpo-load-balance: [proto:ip4 index:17 buckets:1 uRPF:25 to:[0:0]]
+ [0] [@5]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+
+
+notice that the path via 10.0.0.2 is no longer flagged as resolved,
+and the forwarding chain does not contain this path as a
+choice. However, the key thing to note is the load-balance
+instance is still index 17, i.e. it has been modified not
+exchanged. In the FIB vernacular we say it has been 'in-place
+modified', a somewhat linguistically redundant expression, but one that serves
+to emphasise that it was changed whilst still be part of the graph, it
+was never at any point removed from the graph and re-added, and it was
+modified without worker barrier lock held.
+
+Still don't see the significance? In order to converge around the
+failure of the IGP link it was not necessary to update load-balance
+object number 20! It was not necessary to update the recursive
+route. i.e. convergence is achieved without updating any recursive
+routes, it is only necessary to update the affected IGP routes, this is
+the definition of 'a few'. We call this 'prefix independent
+convergence' (PIC) which should really be called 'recursive prefix
+independent convergence' but it isn't...
+
+How was the trick done? As with all problems in computer science, it
+was solved by a layer of misdirection, I mean indirection. The
+indirection is the load-balance that belongs to the IGP route. By
+keeping this object in the forwarding graph and updating it in place,
+we get PIC. The alternative design would be to collapse the two layers of
+load-balancing into one, which would improve forwarding performance
+but would come at the cost of prefix dependent convergence. No doubt
+there are situations where the VPP deployment would favour forwarding
+performance over convergence, you know the drill, contributions welcome.
+
+This failure scenario is known as PIC core, since it's one of the IGP's
+core links that has failed.
+
+iBGP PIC Edge
+^^^^^^^^^^^^^
+
+Next, let's consider alternate paths in BGP, e.g:
+
+.. code-block:: console
+
+ ip route add 8.0.0.0/16 via 1.1.1.1
+ ip route add 8.0.0.0/16 via 1.1.1.2
+
+the 8.0.0.0/16 prefix is reachable via two BGP next-hops (two PEs).
+
+Our FIB now also contains:
+
+.. code-block:: console
+
+ DBGvpp# sh ip fib 8.0.0.0/16
+ ipv4-VRF:0, fib_index:0, flow hash:[src dst sport dport proto ] epoch:0 flags:none locks:[adjacency:1, recursive-resolution:2, default-route:1, ]
+ 8.0.0.0/16 fib:0 index:18 locks:2
+ API refs:1 src-flags:added,contributing,active,
+ path-list:[15] locks:2 flags:shared, uPRF-list:11 len:2 itfs:[1, 2, ]
+ path:[17] pl-index:15 ip4 weight=1 pref=0 recursive: oper-flags:resolved,
+ via 1.1.1.1 in fib:0 via-fib:15 via-dpo:[dpo-load-balance:17]
+ path:[15] pl-index:15 ip4 weight=1 pref=0 recursive: oper-flags:resolved,
+ via 1.1.1.2 in fib:0 via-fib:10 via-dpo:[dpo-load-balance:12]
+
+ forwarding: unicast-ip4-chain
+ [@0]: dpo-load-balance: [proto:ip4 index:20 buckets:2 uRPF:11 to:[0:0]]
+ [0] [@12]: dpo-load-balance: [proto:ip4 index:17 buckets:1 uRPF:25 to:[0:0]]
+ [0] [@5]: ipv4 via 10.0.0.2 GigEthernet0/0/0: mtu:9000 next:3 001122334455dead000000000800
+ [1] [@5]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+ [1] [@12]: dpo-load-balance: [proto:ip4 index:12 buckets:1 uRPF:13 to:[0:0]]
+ [0] [@5]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+
+The first load-balance (LB) in the forwarding graph is index 20 (the astute
+reader will note this is the same index as in the previous
+section, I am adding paths to the same route, the load-balance is
+in-place modified again). Each choice in LB 20 is another LB
+contributed by the IGP route through which the route's paths recurse.
+
+So what's the equivalent in BGP to a link down in the IGP? An IGP link
+down means it loses its peering out of that link, so the equivalent in
+BGP is the loss of the peering and thus the loss of reachability to
+the peer. This is signaled by the IGP withdrawing the route to the
+peer. But "Wait wait wait", i hear you say ... "just because the IGP
+withdraws 1.1.1.1/32 doesn't mean I can't reach 1.1.1.1, perhaps there
+is a less specific route that gives reachability to 1.1.1.1". Indeed
+there may be. So a little more on BGP network design. I know it's like
+a bad detective novel where the author drip feeds you the plot... When
+describing iBGP peerings one 'always' describes the peer using one of
+its GigEthernet0/0/back addresses. Why? A GigEthernet0/0/back interface
+never goes down (unless you admin down it yourself), some muppet can't
+accidentally cut through the GigEthernet0/0/back cable whilst digging up the
+street. And what subnet mask length does a prefix have on a GigEthernet0/0/back
+interface? it's 'always' a /32. Why? because there's no cable to connect
+any other devices. This choice justifies there 'always' being a /32
+route for the BGP peer. But what prevents there not being a less
+specific - nothing.
+Now clearly if the BGP peer crashes then the /32 for its GigEthernet0/0/back is
+going to be removed from the IGP, but what will withdraw the less
+specific - nothing.
+
+So in order to make use of this trick of relying on the withdrawal of
+the /32 for the peer to signal that the peer is down and thus the
+signal to converge the FIB, we need to force FIB to recurse only via
+the /32 and not via a less specific. This is called a 'recursion
+constraint'. In this case the constraint is 'recurse via host'
+i.e. for ipv4 use a /32.
+So we need to update our route additions from before:
+
+.. code-block:: console
+
+ ip route add 8.0.0.0/16 via 1.1.1.1 resolve-via-host
+ ip route add 8.0.0.0/16 via 1.1.1.2 resolve-via-host
+
+checking the FIB output is left as an exercise to the reader. I hope
+you're doing these configs as you read. There's little change in the
+output, you'll see some extra flags on the paths.
+
+Now let's add the less specific, just for fun:
+
+
+.. code-block:: console
+
+ ip route add 1.1.1.0/28 via 10.0.0.2 GigEthernet0/0/0
+
+nothing changes in resolution of 8.0.0.0/16.
+
+Now withdraw the route to 1.1.1.2/32:
+
+.. code-block:: console
+
+ ip route del 1.1.1.2/32 via 10.0.0.2 GigEthernet0/0/0
+
+In the FIB we see:
+
+.. code-block:: console
+
+ DBGvpp# sh ip fib 8.0.0.0/32
+ ipv4-VRF:0, fib_index:0, flow hash:[src dst sport dport proto ] epoch:0 flags:none locks:[adjacency:1, recursive-resolution:2, default-route:1, ]
+ 8.0.0.0/16 fib:0 index:18 locks:2
+ API refs:1 src-flags:added,contributing,active,
+ path-list:[15] locks:2 flags:shared, uPRF-list:13 len:2 itfs:[1, 2, ]
+ path:[15] pl-index:15 ip4 weight=1 pref=0 recursive: oper-flags:resolved, cfg-flags:resolve-host,
+ via 1.1.1.1 in fib:0 via-fib:15 via-dpo:[dpo-load-balance:17]
+ path:[17] pl-index:15 ip4 weight=1 pref=0 recursive: cfg-flags:resolve-host,
+ via 1.1.1.2 in fib:0 via-fib:10 via-dpo:[dpo-drop:0]
+
+ forwarding: unicast-ip4-chain
+ [@0]: dpo-load-balance: [proto:ip4 index:20 buckets:1 uRPF:13 to:[0:0]]
+ [0] [@12]: dpo-load-balance: [proto:ip4 index:17 buckets:2 uRPF:27 to:[0:0]]
+ [0] [@5]: ipv4 via 10.0.0.2 GigEthernet0/0/0: mtu:9000 next:3 001122334455dead000000000800
+ [1] [@5]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+
+the path via 1.1.1.2 is unresolved, because the recursion constraints
+are preventing the the path resolving via 1.1.1.0/28. the LB index 20
+has been updated to remove the unresolved path.
+
+Job done? Not quite! Why not?
+
+Let's re-examine the goals of this chapter. We wanted to update 'a
+few' objects, which we have defined as not all the millions of
+recursive routes. Did we do that here? We sure did, when we
+modified LB index 20. So WTF?? Where's the indirection object that can
+be modified so that the LBs for the recursive routes are not
+modified - it's not there.... WTF?
+
+OK so the great detective has assembled all the suspects in the
+drawing room and only now does he drop the bomb; the FIB knows the
+scale, we talked above about what the scale **can** be, worst case
+scenario, but that's not necessarily what it is in this hypothetical
+(your) deployment. It knows how many recursive routes there are that
+depend on a /32, it can thus make its own determination of the
+definition of 'a few'. In other words, if there are only 'a few'
+recursive prefixes that depend on a /32 then it will update them
+synchronously (and we'll discuss what synchronously means a bit more later).
+
+So what does FIB consider to be 'a few'. Let's add more routes and
+find out.
+
+.. code-block:: console
+
+ DBGvpp# ip route add 8.1.0.0/16 via 1.1.1.2 resolve-via-host via 1.1.1.1 resolve-via-host
+ ...
+ DBGvpp# ip route add 8.63.0.0/16 via 1.1.1.2 resolve-via-host via 1.1.1.1 resolve-via-host
+
+and we see:
+
+.. code-block:: console
+
+ DBGvpp# sh ip fib 8.8.0.0
+ ipv4-VRF:0, fib_index:0, flow hash:[src dst sport dport proto ] epoch:0 flags:none locks:[adjacency:1, recursive-resolution:4, default-route:1, ]
+ 8.8.0.0/16 fib:0 index:77 locks:2
+ API refs:1 src-flags:added,contributing,active,
+ path-list:[15] locks:128 flags:shared,popular, uPRF-list:28 len:2 itfs:[1, 2, ]
+ path:[17] pl-index:15 ip4 weight=1 pref=0 recursive: oper-flags:resolved, cfg-flags:resolve-host,
+ via 1.1.1.1 in fib:0 via-fib:15 via-dpo:[dpo-load-balance:17]
+ path:[15] pl-index:15 ip4 weight=1 pref=0 recursive: oper-flags:resolved, cfg-flags:resolve-host,
+ via 1.1.1.2 in fib:0 via-fib:10 via-dpo:[dpo-load-balance:12]
+
+ forwarding: unicast-ip4-chain
+ [@0]: dpo-load-balance: [proto:ip4 index:79 buckets:2 uRPF:28 flags:[uses-map] to:[0:0]]
+ load-balance-map: index:0 buckets:2
+ index: 0 1
+ map: 0 1
+ [0] [@12]: dpo-load-balance: [proto:ip4 index:17 buckets:2 uRPF:27 to:[0:0]]
+ [0] [@5]: ipv4 via 10.0.0.2 GigEthernet0/0/0: mtu:9000 next:3 001122334455dead000000000800
+ [1] [@5]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+ [1] [@12]: dpo-load-balance: [proto:ip4 index:12 buckets:1 uRPF:18 to:[0:0]]
+ [0] [@3]: arp-ipv4: via 10.0.1.2 GigEthernet0/0/0
+
+
+Two elements to note here; the path-list has the 'popular' flag and
+there is a load-balance map in the forwarding path.
+
+'popular' in this case means that the path-list has passed the limit
+of 'a few' in the number of children it has.
+
+here are the children:
+
+.. code-block:: console
+
+ DBGvpp# sh fib path-list 15
+ path-list:[15] locks:128 flags:shared,popular, uPRF-list:28 len:2 itfs:[1, 2, ]
+ path:[17] pl-index:15 ip4 weight=1 pref=0 recursive: oper-flags:resolved, cfg-flags:resolve-host,
+ via 1.1.1.1 in fib:0 via-fib:15 via-dpo:[dpo-load-balance:17]
+ path:[15] pl-index:15 ip4 weight=1 pref=0 recursive: oper-flags:resolved, cfg-flags:resolve-host,
+ via 1.1.1.2 in fib:0 via-fib:10 via-dpo:[dpo-load-balance:12]
+ children:{entry:18}{entry:21}{entry:22}{entry:23}{entry:25}{entry:26}{entry:27}{entry:28}{entry:29}{entry:30}{entry:31}{entry:32}{entry:33}{entry:34}{entry:35}{entry:36}{entry:37}{entry:38}{entry:39}{entry:40}{entry:41}{entry:42}{entry:43}{entry:44}{entry:45}{entry:46}{entry:47}{entry:48}{entry:49}{entry:50}{entry:51}{entry:52}{entry:53}{entry:54}{entry:55}{entry:56}{entry:57}{entry:58}{entry:59}{entry:60}{entry:61}{entry:62}{entry:63}{entry:64}{entry:65}{entry:66}{entry:67}{entry:68}{entry:69}{entry:70}{entry:71}{entry:72}{entry:73}{entry:74}{entry:75}{entry:76}{entry:77}{entry:78}{entry:79}{entry:80}{entry:81}{entry:82}{entry:83}{entry:84}
+
+64 children makes it popular. The number is fixed (there is no API to
+change it). Its choice is an attempt to balance the performance cost
+of the indirection performance degradation versus the convergence
+gain.
+
+Popular path-lists contribute the load-balance map, this is the
+missing indirection object. Its indirection happens when choosing the
+bucket in the LB. The packet's flow-hash is taken 'mod number of
+buckets' to give the 'candidate bucket' then the map will take this
+'index' and convert it into the 'map'. You can see in the example above
+that no change occurs, i.e. if the flow-hash mod n chooses bucket 1
+then it gets bucket 1.
+
+Why is this useful? The path-list is shared (you can convince
+yourself of this if you look at each of the 8.x.0.0/16 routes we
+added) and all of these routes use the same load-balance map, therefore, to
+converge all the recursive routs, we need only change the map and
+we're good; we again get PIC.
+
+OK who's still awake... if you're thinking there's more to this story,
+you're right. Keep reading.
+
+This failure scenario is called iBGP PIC edge. It's 'edge' because it
+refers to the loss of an edge device, and iBGP because the device was
+a iBGP peer (we learn iBGP peers in the IGP). There is a similar eBGP
+PIC edge scenario, but this is left for an exercise to the reader (hint
+there are other recursion constraints - see the RFC).
+
+Which Objects
+^^^^^^^^^^^^^
+
+The next topic on our list of how to converge quickly was to
+effectively find the objects that need to be updated when a converge
+event happens. If you haven't realised by now that the FIB is an
+object graph, then can I politely suggest you go back and start from
+the beginning ...
+
+Finding the objects affected by a change is simply a matter of walking
+from the parent (the object affected) to its children. These
+dependencies are kept really for this reason.
+
+So is fast convergence just a matter of walking the graph? Yes and
+no. The question to ask yourself is this, "in the case of iBGP PIC edge,
+when the /32 is withdrawn, what is the list of objects that need to be
+updated and particularly what is the order they should be updated in
+order to obtain the best convergence time?" Think breadth v. depth first.
+
+... ponder for a while ...
+
+For iBGP PIC edge we said it's the path-list that provides the
+indirection through the load-balance map. Hence once all path-lists
+are updated we are converged, thereafter, at our leisure, we can
+update the child recursive prefixes. Is the breadth or depth first?
+
+It's breadth first.
+
+Breadth first walks are achieved by spawning an async walk of the
+branch of the graph that we don't want to traverse. Withdrawing the /32
+triggers a synchronous walk of the children of the /32 route, we want
+a synchronous walk because we want to converge ASAP. This synchronous
+walk will encounter path-lists in the /32 route's child dependent list.
+These path-lists (and thier LB maps) will be updated. If a path-list is
+popular, then it will spawn a async walk of the path-list's child
+dependent routes, if not it will walk those routes. So the walk
+effectively proceeds breadth first across the path-lists, then returns
+to the start to do the affected routes.
+
+Now the story is complete. The murderer is revealed.
+
+Let's withdraw one of the IGP routes.
+
+.. code-block:: console
+
+ DBGvpp# ip route del 1.1.1.2/32 via 10.0.1.2 GigEthernet0/0/1
+
+ DBGvpp# sh ip fib 8.8.0.0
+ ipv4-VRF:0, fib_index:0, flow hash:[src dst sport dport proto ] epoch:0 flags:none locks:[adjacency:1, recursive-resolution:4, default-route:1, ]
+ 8.8.0.0/16 fib:0 index:77 locks:2
+ API refs:1 src-flags:added,contributing,active,
+ path-list:[15] locks:128 flags:shared,popular, uPRF-list:18 len:2 itfs:[1, 2, ]
+ path:[17] pl-index:15 ip4 weight=1 pref=0 recursive: oper-flags:resolved, cfg-flags:resolve-host,
+ via 1.1.1.1 in fib:0 via-fib:15 via-dpo:[dpo-load-balance:17]
+ path:[15] pl-index:15 ip4 weight=1 pref=0 recursive: cfg-flags:resolve-host,
+ via 1.1.1.2 in fib:0 via-fib:10 via-dpo:[dpo-drop:0]
+
+ forwarding: unicast-ip4-chain
+ [@0]: dpo-load-balance: [proto:ip4 index:79 buckets:1 uRPF:18 to:[0:0]]
+ [0] [@12]: dpo-load-balance: [proto:ip4 index:17 buckets:2 uRPF:27 to:[0:0]]
+ [0] [@5]: ipv4 via 10.0.0.2 GigEthernet0/0/0: mtu:9000 next:3 001122334455dead000000000800
+ [1] [@5]: ipv4 via 10.0.1.2 GigEthernet0/0/1: mtu:9000 next:4 001111111111dead000000010800
+
+the LB Map has gone, since the prefix now only has one path. You'll
+need to be a CLI ninja if you want to catch the output showing the LB
+map in its transient state of:
+
+.. code-block:: console
+
+ load-balance-map: index:0 buckets:2
+ index: 0 1
+ map: 0 0
+
+but it happens. Trust me. I've got tests and everything.
+
+On the final topic of how to converge quickly; 'make each update fast'
+there are no tricks.
+
+
- To be written