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diff --git a/docs/developer/corefeatures/fib/routes.rst b/docs/developer/corefeatures/fib/routes.rst new file mode 100644 index 00000000000..a43cbd112d5 --- /dev/null +++ b/docs/developer/corefeatures/fib/routes.rst @@ -0,0 +1,353 @@ +.. _routes: + +Routes +^^^^^^ + +Basics +------ + +The anatomy of a route is crucial to understand: + +.. code-block:: console + + 1.1.1.0/24 via 10.0.0.1 eth0 + +A route is composed of two parts; **what** to match against and **how** to forward +the matched packets. In the above example we want to match packets +whose destination IP address is in the 1.1.1.0/24 subnet and then we +want to forward those packet to 10.0.0.1 on interface eth0. We +therefore want to match the **prefix** 1.1.1.0/24 and forward on the +**path** to 10.0.0.1, eth0. + +Matching on a prefix is the particular task of the IP FIB, matching on +other packet attributes is done by other subsystems, e.g. matching on +MPLS labels in the MPLS-FIB, or matching on a tuple in ACL based +forwarding (ABF), 'matching' on all packets that arrive on an L3 +interface (l3XC). Although these subsystems match on different +properties, they share the infrastructure on **how** to forward +matched packets, that is they share the **paths**. The FIB paths (or +really the path-list) thus provide services to clients, this service +is to **contribute** forwarding, this, in terms that will be made +clear in later sections, is to provide the DPO to use. + +The prime function of the FIB is to *resolve* the paths for a +route. To resolve a route is to construct an object graph that fully +describes how to forward matching packets. This means that the graph +must terminate with an object (the leaf node) that describes how +to send a packet on an interface [#f1]_, i.e what encap to add to the +packet and what interface to send it to; this is the purpose of the IP +adjacency object. In Figure 3 the route is resolved as the graph is +complete from *fib_entry_t* to *ip_adjacency_t*. + + +Thread Model +^^^^^^^^^^^^ + +The FIB is not thread safe. All actions on the FIB are expected to +occur exclusively in the main thread. However, the data-structures +that FIB updates to add routes are thread safe, +w.r.t. addition/deletion and read, therefore routes can be added +without holding the worker thread barrier lock. + + +Tables +------ + +An IP FIB is a set of prefixes against which to match; it is +sub-address family (SAFI) specific (i.e. there is one for ipv4 and ipv6, unicast +and multicast). An IP Table is address family (AFI) specific (i.e. the +'table' includes the unicast and multicast FIB). + +Each FIB is identified by the SAFI and instance number (the [pool] +index), each table is identified by the AFI and ID. The table's ID is +assigned by the user when the table is constructed. Table ID 0 is +reserved for the global/default table. + +In most routing models a VRF is composed of an IPv4 and IPv6 table, +however, VPP has no construct to model this association, it deals only +with tables and FIBs. + +A unicast FIB is comprised of two route data-bases; forwarding and non-forwarding. The +forwarding data-base contains routes against which a packet will perform a longest +prefix match (LPM) in the data-plane. The non-forwarding DB contains all the routes +with which VPP has been programmed. Some of these routes may be +unresolved, preventing their insertion into the forwarding DB. +(see section: Adjacency source FIB entries). + +Model +----- + +The route data is decomposed into three parts; entry, path-list and paths; + +* The *fib_entry_t*, which contains the route's prefix, is the representation of that prefix's entry in the FIB table. +* The *fib_path_t* is a description of where to send the packets destined to the route's prefix. There are several types of path, including: + + * Attached next-hop: the path is described with an interface and a next-hop. The next-hop is in the same sub-net as the router's own address on that interface, hence the peer is considered to be *attached* + + * Attached: the path is described only by an interface. An + attached path means that all addresses covered by the route's + prefix are on the same L2 segment to which that router's + interface is attached. This means it is possible to ARP for any + address covered by the route's prefix. If this is not the case + then another device in that L2 segment needs to run proxy + ARP. An attached path is really only appropriate for a point-to-point + (P2P) interface where ARP is not required, i.e. a GRE tunnel. On + a p2p interface, attached and attached-nexthop paths will + resolve via a special 'auto-adjacency'. This is an adjacency + whose next-hop is the all zeros address and describes the only + peer on the link. + + * Recursive: The path is described only via the next-hop and table-id. + + * De-aggregate: The path is described only via the special all + zeros address and a table-id. This implies a subsequent lookup + in the table should be performed. + + * There are other path types, please consult the code. + +* The *fib_path_list_t* represents the list of paths from which to choose when forwarding. A path-list is a shared object, i.e. it is the parent to multiple fib_entry_t children. In order to share any object type it is necessary for a child to search for an existing object matching its requirements. For this there must be a database. The key to the path-list database is a combined description of all of the paths it contains [#f2]_. Searching the path-list database is required with each route addition, so it is populated only with path-lists for which sharing will bring convergence benefits (see Section: :ref:`fastconvergence`). + +.. figure:: /_images/fib20fig2.png + +Figure 2: Route data model class diagram + +Figure 2 shows an example of a route with two attached-next-hop paths. Each of these +paths will *resolve* by finding the adjacency that matches the paths attributes, which +are the same as the key for the adjacency database [#f3]_. The *forwarding information (FI)* +is the set of adjacencies that are available for load-balancing the traffic in the +data-plane. A path *contributes* an adjacency to the route's forwarding information, the +path-list contributes the full forwarding information for IP packets. + +.. figure:: /_images/fib20fig3.png + +Figure 3: Route object diagram + +Figure 3 shows the object instances and their relationships created in order to resolve +the routes also shown. The graph nature of these relationships is evident; children +are displayed at the top of the diagram, their parents below them. Forward walks are +thus from top to bottom, back walks bottom to top. The diagram shows the objects +that are shared, the path-list and adjacency. Sharing objects is critical to fast +convergence (see section :ref:`fastconvergence`). + +FIB sources +""""""""""" +There are various entities in the system that can add routes to the FIB tables. +Each of these entities is termed a *source*. When the same prefix is added by different +sources the FIB must arbitrate between them to determine which source will contribute +the forwarding information. Since each source determines the forwarding information +using different best path and loop prevention algorithms, it is not correct for the +forwarding information of multiple sources to be combined. Instead the FIB must choose +to use the forwarding information from only one source. This choice is based on a static +priority assignment [#f4]_. The FIB must maintain the information each source has added +so it can be restored should that source become the best source. VPP has two +*control-plane* sources; the API and the CLI the API has the higher priority. +Each *source* data is represented by a *fib_entry_src_t* object of which a +*fib_entry_t* maintains a sorted vector. + +The following configuration: + +.. code-block:: console + + $ set interface ip address GigabitEthernet0/8/0 192.168.1.1/24 + +results in the addition of two FIB entries; 192.168.1.0/24 which is connected and +attached, and 192.168.1.1/32 which is connected and local (a.k.a. +receive or for-us). A prefix is *connected* when it is applied to a router's interface. +Both prefixes are *interface* sourced. The interface source has a high priority, so +the accidental or nefarious addition of identical prefixes does not prevent the +router from correctly forwarding. Packets matching a connected prefix will +generate an ARP request for the packets destination address, this process is known +as a *glean*. + +An *attached* prefix also results in a glean, but the router does not have its own +address in that sub-net. The following configuration will result in an attached +route, which resolves via an attached path; + +.. code-block:: console + + $ ip route add table X 10.10.10.0/24 via gre0 + +as mentioned before, these are only appropriate for point-to-point +links. + +If table X is not the table to which gre0 is bound, +then this is the case of an attached export (see the section :ref:`attachedexport`). + +Adjacency source FIB entries +"""""""""""""""""""""""""""" + +Whenever an ARP entry is created it will source a *fib_entry_t*. In this case the +route is of the form: + +.. code-block:: console + + $ ip route add table X 10.0.0.1/32 via 10.0.0.1 GigabitEthernet0/8/0 + +This is a host prefix with a path whose next-hop address is the same host. This route +highlights the distinction between the route's prefix - a description of the traffic +to match - and the path - a description of where to send the matched traffic. +Table X is the same table to which the interface is bound. FIB entries that are +sourced by adjacencies are termed *adj-fibs*. The priority of the adjacency source +is lower than the API source, so the following configuration: + +.. code-block:: console + + $ set interface address 192.168.1.1/24 GigabitEthernet0/8/0 + $ ip arp 192.168.1.2 GigabitEthernet0/8/0 dead.dead.dead + $ ip route add 192.168.1.2 via 10.10.10.10 GigabitEthernet1/8/0 + +will forward traffic for 192.168.1.2 via GigabitEthernet1/8/0. That is the route added by the control +plane is favoured over the adjacency discovered by ARP. The control plane, with its +associated authentication, is considered the authoritative source. To counter the +nefarious addition of adj-fibs, through the nefarious injection of adjacencies, the +FIB is also required to ensure that only adj-fibs whose less specific covering prefix +is attached are installed in forwarding. This requires the use of *cover tracking*, +where a route maintains a dependency relationship with the route that is its less +specific cover. When this cover changes (i.e. there is a new covering route) or the +forwarding information of the cover is updated, then the covered route is notified. +Adj-fibs that fail this cover check are not installed in the fib_table_t's forwarding +table, they are only present in the non-forwarding table. + +Overlapping sub-nets are not supported, so no adj-fib has multiple paths. The control +plane is expected to remove a prefix configured for an interface before the interface +changes VRF. + +Recursive Routes +"""""""""""""""" + +Figure 4 shows the data structures used to describe a recursive route. The +representation is almost identical to attached next-hop paths. The difference +being that the *fib_path_t* has a parent that is another *fib_entry_t*, termed the +*via-entry* + +.. figure:: /_images/fib20fig4.png + +Figure 4: Recursive route class diagram. + +In order to forward traffic to 64.10.128.0/20 the FIB must first determine how to forward +traffic to 1.1.1.1/32. This is recursive resolution. Recursive resolution, which is +essentially a cache of the data-plane result, emulates a longest prefix match for the +*via-address" 1.1.1.1 in the *via-table* table 0 [#f5]_. + +Recursive resolution (RR) will source a host-prefix entry in the via-table for the +via-address. The RR source is a low priority source. In the unlikely [#f6]_ event that the +RR source is the best source, then it must derive forwarding information from its +covering prefix. + +There are two cases to consider: + +* The cover is connected [#f7]_. The via-address is then an attached host and the RR source can resolve directly via the adjacency with the key {via-address, interface-of-connected-cover} +* The cover is not connected [#f8]_. The RR source can directly inherit the forwarding information from its cover. + +This dependency on the covering prefix means the RR source will track its cover The +covering prefix will *change* when; + +* A more specific prefix is inserted. For this reason whenever an entry is inserted into a FIB table its cover must be found so that its covered dependents can be informed. +* The existing cover is removed. The covered prefixes must form a new relationship with the next less specific. + +The cover will be *updated* when the route for the covering prefix is modified. The +cover tracking mechanism will provide the RR sourced entry with a notification in the +event of a change or update of the cover, and the source can take the necessary action. + +The RR sourced FIB entry becomes the parent of the *fib_path_t* and will contribute its +forwarding information to that path, so that the child's FIB entry can construct its own +forwarding information. + +Figure 5 shows the object instances created to represent the recursive route and +its resolving route also shown. + +.. figure:: /_images/fib20fig5.png + +Figure 5: Recursive Routes object diagram + +If the source adding recursive routes does not itself perform recursive resolution [#f9]_ +then it is possible that the source may inadvertently programme a recursion loop. + +An example of a recursion loop is the following configuration: + +.. code-block:: console + + $ ip route add 5.5.5.5/32 via 6.6.6.6 + $ ip route add 6.6.6.6/32 via 7.7.7.7 + $ ip route add 7.7.7.7/32 via 5.5.5.5 + +This shows a loop over three levels, but any number is possible. FIB will detect +recursion loops by forward walking the graph when a *fib_entry_t* forms a child-parent +relationship with a *fib_path_list_t*. The walk checks to see if the same object instances +are encountered. When a recursion loop is formed the control plane [#f10]_ graph becomes +cyclic, thus allowing the child-parent dependencies to form. This is necessary so that +when the loop breaks, the affected children and be updated. + +Output labels +""""""""""""" + +A route may have associated output MPLS labels [#f11]_. These are labels that are expected +to be imposed on a packet as it is forwarded. It is important to note that an MPLS +label is per-route and per-path, therefore, even though routes share paths they do not +necessarily have the same label for that path [#f12]_. A label is therefore uniquely associated +to a *fib_entry_t* and associated with one of the *fib_path_t* to which it forwards. +MPLS labels are modelled via the generic concept of a *path-extension*. A *fib_entry_t* +therefore has a vector of zero to many *fib_path_ext_t* objects to represent the labels +with which it is configured. + + +Delegates +^^^^^^^^^ + +A common software development pattern, a delegate is a means to +extend the functionality of one object through composition of +another, these other objects are called delegates. Both +**fib_entry_t** and **ip_adjacency_t** support extension via delegates. + +The FIB uses delegates to add functionality when those functions are +required by only a few objects instances rather than all of them, to +save on memory. For example, building/contributing a load-balance +object used to forward non-EOS MPLS traffic is only required for a +fib_entry_t that corresponds to a BGP peer and that peer is +advertising labeled route - there are only a few of +these. See **fib_entry_delegate.h** for a full list of delegate types. + + +Tracking +^^^^^^^^ + +A prime service FIB provides for other sub-system is the ability to +'track' the forwarding for a given next-hop. For example, a tunnel +will want to know how to forward to its destination address. It can +therefore request of the FIB to track this host-prefix and inform it +when the forwarding for that prefix changes. + +FIB tracking sources a host-prefix entry in the FIB using the 'recusive +resolution (RR)' source, it exactly the same way that a recursive path +does. If the entry did not previously exist, then the RR source will +inherit (and track) forwarding from its covering prefix, therefore all +packets that match this entry are forwarded in the same way as if the +entry did not exist. The tunnel that is tracking this FIB entry will +become a child dependent. The benefit to creating the entry, is that +it now exists in the FIB node graph, so all actions that happen on its +parents, are propagated to the host-prefix entry and consequently to +the tunnel. + +FIB provides a wrapper to the sourcing of the host-prefix using a +delegate attached to the entry, and the entry is RR sourced only once. +. The benefit of this approach is that each time a new client tracks +the entry it doesn't RR source it. When an entry is sourced all its +children are updated. Thus, new clients tracking an entry is +O(n^2). With the tracker as indirection, the entry is sourced only once. + + +.. rubric:: Footnotes: + +.. [#f1] Or terminate in an object that transitions the packet out of + the FIB domain, e.g. a drop. +.. [#f2] Optimisations +.. [#f3] Note it is valid for either interface to be bound to a different table than table 1 +.. [#f4] The engaged reader can see the full priority list in vnet/vnet/fib/fib_entry.h +.. [#f5] Note it is only possible to add routes via an address (i.e. a/32 or /128) not via a shorter mask prefix. There is no use case for the latter +.. [#f6] For iBGP the via-address is the loopback address of the peer PE, for eBGP it is the adj-fib for the CE +.. [#f7] As is the case ofr eBGP +.. [#f8] As is the case for iBGP +.. [#f9] If that source is relying on FIB to perform recursive resolution, then there is no reason it should do so itself. +.. [#f10] The derived data-plane graph MUST never be cyclic +.. [#f11] Advertised, e.g. by LDP, SR or BGP +.. [#f12] The only case where the labels will be the same is BGP VPNv4 label allocation per-VRF |