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160 lines
8.0 KiB
Markdown
160 lines
8.0 KiB
Markdown
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# BIRD Journey to Threads. Chapter 1: The Route and its Attributes
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BIRD is a fast, robust and memory-efficient routing daemon designed and
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implemented at the end of 20th century. We're doing a significant amount of
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BIRD's internal structure changes to make it possible to run in multiple
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threads in parallel. This chapter covers necessary changes of data structures
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which store every single routing data.
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*If you want to see the changes in code, look (basically) into the
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`route-storage-updates` branch. Not all of them are already implemented, anyway
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most of them are pretty finished as of end of March, 2021.*
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## How routes are stored
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BIRD routing table is just a hierarchical noSQL database. On top level, the
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routes are keyed by their destination, called *net*. Due to historic reasons,
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the *net* is not only *IPv4 prefix*, *IPv6 prefix*, *IPv4 VPN prefix* etc.,
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but also *MPLS label*, *ROA information* or *BGP Flowspec record*. As there may
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be several routes for each *net*, an obligatory part of the key is *src* aka.
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*route source*. The route source is a tuple of the originating protocol
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instance and a 32-bit unsigned integer. If a protocol wants to withdraw a route,
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it is enough and necessary to have the *net* and *src* to identify what route
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is to be withdrawn.
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The route itself consists of (basically) a list of key-value records, with
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value types ranging from a 16-bit unsigned integer for preference to a complex
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BGP path structure. The keys are pre-defined by protocols (e.g. BGP path or
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OSPF metrics), or by BIRD core itself (preference, route gateway).
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Finally, the user can declare their own attribute keys using the keyword
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`attribute` in config.
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## Attribute list implementation
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Currently, there are three layers of route attributes. We call them *route*
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(*rte*), *attributes* (*rta*) and *extended attributes* (*ea*, *eattr*).
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The first layer, *rte*, contains the *net* pointer, several fixed-size route
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attributes (mostly preference and protocol-specific metrics), flags, lastmod
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time and a pointer to *rta*.
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The second layer, *rta*, contains the *src* (a pointer to a singleton instance),
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a route gateway, several other fixed-size route attributes and a pointer to
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*ea* list.
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The third layer, *ea* list, is a variable-length list of key-value attributes,
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containing all the remaining route attributes.
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Distribution of the route attributes between the attribute layers is somehow
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arbitrary. Mostly, in the first and second layer, there are attributes that
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were thought to be accessed frequently (e.g. in best route selection) and
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filled in in most routes, while the third layer is for infrequently used
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and/or infrequently accessed route attributes.
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## Attribute list deduplication
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When protocols originate routes, there are commonly more routes with the
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same attribute list. BIRD could ignore this fact, anyway if you have several
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tables connected with pipes, it is more memory-efficient to store the same
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attribute lists only once.
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Therefore, the two lower layers (*rta* and *ea*) are hashed and stored in a
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BIRD-global database. Routes (*rte*) contain a pointer to *rta* in this
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database, maintaining a use-count of each *rta*. Attributes (*rta*) contain
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a pointer to normalized (sorted by numerical key ID) *ea*.
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## Attribute list rework
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The first thing to change is the distribution of route attributes between
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attribute list layers. We decided to make the first layer (*rte*) only the key
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and other per-record internal technical information. Therefore we move *src* to
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*rte* and preference to *rta* (beside other things). *This is already done.*
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We also found out that the nexthop (gateway), originally one single IP address
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and an interface, has evolved to a complex attribute with several sub-attributes;
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not only considering multipath routing but also MPLS stacks and other per-route
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attributes. This has led to a too complex data structure holding the nexthop set.
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We decided finally to squash *rta* and *ea* to one type of data structure,
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allowing for completely dynamic route attribute lists. This is also supported
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by adding other *net* types (BGP FlowSpec or ROA) where lots of the fields make
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no sense at all, yet we still want to use the same data structures and implementation
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as we don't like duplicating code. *Multithreading doesn't depend on this change,
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anyway this change is going to happen soon anyway.*
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## Route storage
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The process of route import from protocol into a table can be divided into several phases:
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1. (In protocol code.) Create the route itself (typically from
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protocol-internal data) and choose the right channel to use.
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2. (In protocol code.) Create the *rta* and *ea* and obtain an appropriate
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hashed pointer. Allocate the *rte* structure and fill it in.
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3. (Optionally.) Store the route to the *import table*.
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4. Run filters. If reject, free everything.
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5. Check whether this is a real change (it may be idempotent). If not, free everything and do nothing more.
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6. Run the best route selection algorithm.
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7. Execute exports if needed.
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We found out that the *rte* structure allocation is done too early. BIRD uses
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global optimized allocators for fixed-size blocks (which *rte* is) to reduce
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its memory footprint, therefore the allocation of *rte* structure would be a
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synchronization point in multithreaded environment.
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The common code is also much more complicated when we have to track whether the
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current *rte* has to be freed or not. This is more a problem in export than in
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import as the export filter can also change the route (and therefore allocate
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another *rte*). The changed route must be therefore freed after use. All the
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route changing code must also track whether this route is writable or
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read-only.
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We therefore introduce a variant of *rte* called *rte_storage*. Both of these
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hold the same, the layer-1 route information (destination, author, cached
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attribute pointer, flags etc.), anyway *rte* is always local and *rte_storage*
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is intended to be put in global data structures.
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This change allows us to remove lots of the code which only tracks whether any
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*rte* is to be freed as *rte*'s are almost always allocated on-stack, naturally
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limiting their lifetime. If not on-stack, it's the responsibility of the owner
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to free the *rte* after import is done.
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This change also removes the need for *rte* allocation in protocol code and
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also *rta* can be safely allocated on-stack. As a result, protocols can simply
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allocate all the data on stack, call the update routine and the common code in
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BIRD's *nest* does all the storage for them.
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Allocating *rta* on-stack is however not required. BGP and OSPF use this to
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import several routes with the same attribute list. In BGP, this is due to the
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format of BGP update messages containing first the attributes and then the
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destinations (BGP NLRI's). In OSPF, in addition to *rta* deduplication, it is
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also presumed that no import filter (or at most some trivial changes) is applied
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as OSPF would typically not work well when filtered.
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*This change is already done.*
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## Route cleanup and table maintenance
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In some cases, the route update is not originated by a protocol/channel code.
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When the channel shuts down, all routes originated by that channel are simply
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cleaned up. Also routes with recursive routes may get changed without import,
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simply by changing the IGP route.
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This is currently done by a `rt_event` (see `nest/rt-table.c` for source code)
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which is to be converted to a parallel thread, running when nobody imports any
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route. *This change is freshly done in branch `guernsey`.*
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## Parallel protocol execution
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The long-term goal of these reworks is to allow for completely independent
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execution of all the protocols. Typically, there is no direct interaction
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between protocols; everything is done thought BIRD's *nest*. Protocols should
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therefore run in parallel in future and wait/lock only when something is needed
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to do externally.
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We also aim for a clean and documented protocol API.
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*It's still a long road to the version 2.1. This series of texts should document
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what is needed to be changed, why we do it and how. In the next chapter, we're
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going to describe how the route is exported from table to protocols and how this
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process is changing. Stay tuned!*
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