Fixes for the programmer's manual.

This commit is contained in:
Martin Mares 2000-06-08 12:37:21 +00:00
parent 8d56febe64
commit 725270cb1d
14 changed files with 114 additions and 102 deletions

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@ -456,7 +456,7 @@ cf_symbol_class_name(struct symbol *sym)
* Grammar snippets are files (usually with extension |.Y|) contributed
* by various BIRD modules in order to provide information about syntax of their
* configuration and their CLI commands. Each snipped consists of several
* section, each of them starting with a special keyword: |CF_HDR| for
* sections, each of them starting with a special keyword: |CF_HDR| for
* a list of |#include| directives needed by the C code, |CF_DEFINES|
* for a list of C declarations, |CF_DECLS| for |bison| declarations
* including keyword definitions specified as |CF_KEYWORDS|, |CF_GRAMMAR|
@ -473,5 +473,5 @@ cf_symbol_class_name(struct symbol *sym)
*
* Values of |enum| filter types can be defined using |CF_ENUM| with
* the following parameters: name of filter type, prefix common for all
* literals of this type, names of all the possible values.
* literals of this type and names of all the possible values.
*/

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@ -9,7 +9,7 @@
/**
* DOC: Configuration manager
*
* Configuration of BIRD is complex, yet straightforward. There exist three
* Configuration of BIRD is complex, yet straightforward. There are three
* modules taking care of the configuration: config manager (which takes care
* of storage of the config information and controls switching between configs),
* lexical analyzer and parser.
@ -18,7 +18,7 @@
* accompanied by a linear pool from which all information associated
* with the config and pointed to by the &config structure is allocated.
*
* There can exist up four different configurations at one time: an active
* There can exist up to four different configurations at one time: an active
* one (pointed to by @config), configuration we are just switching from
* (@old_config), one queued for the next reconfiguration (@future_config;
* if it's non-%NULL and the user wants to reconfigure once again, we just

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@ -6,7 +6,7 @@
design decisions and rationale behind them. It also contains documentation on
all the essential components of the system and their interfaces.
<p>Routing daemons are very complicated things which need to act in real time
<p>Routing daemons are complicated things which need to act in real time
to complex sequences of external events, respond correctly even to the most erroneous behavior
of their environment and still handle enormous amount of data with reasonable
speed. Due to all of this, their design is very tricky as one needs to carefully
@ -47,7 +47,7 @@ Easily solvable by abstracting out routing tables and the corresponding operatio
<item><it>Offer powerful route filtering.</it>
There already were several attempts to incorporate route filters to a dynamic router,
but most of them have used simple sequences of filtering rules which were very inflexible
and hard to use for any non-trivial filters. We've decided to employ a simple loop-free
and hard to use for non-trivial filters. We've decided to employ a simple loop-free
programming language having access to all the route attributes and being able to
modify the most of them.
@ -65,8 +65,7 @@ the routing process which are not affected by the change.
In addition to the online reconfiguration, a routing daemon should be able to communicate
with the user and with many other programs (primarily scripts used for network maintenance)
in order to make it possible to inspect contents of routing tables, status of all
routing protocols and also to control their behavior (i.e., it should be possible
to disable, enable or reset a protocol without restarting all the others). To achieve
routing protocols and also to control their behavior (disable, enable or reset a protocol without restarting all the others). To achieve
this, we implement a simple command-line protocol based on those used by FTP and SMTP
(that is textual commands and textual replies accompanied by a numeric code which makes
them both readable to a human and easy to recognize in software).
@ -77,7 +76,9 @@ of all the routing protocols and also of the user interface parts and to hope th
the scheduler will assign time to them in a fair enough manner. This is surely a good
solution, but we have resisted the temptation and preferred to avoid the overhead of threading
and the large number of locks involved and preferred a event driven architecture with
our own scheduling of events.
our own scheduling of events. An unpleasant consequence of such an approach
is that long lasting tasks must be split to more parts linked by special
events or timers to make the CPU available for other tasks as well.
</itemize>
@ -106,7 +107,7 @@ grammar rules and the corresponding snippets of C code. For each group
of code modules (core, each protocol, filters) there exist a configuration
module taking care of all the related configuration stuff.
<tagp>Filters</tagp> implement the route filtering language.
<tagp>The filter</tagp> implements the route filtering language.
<tagp>Protocol modules</tagp> implement the individual routing protocols.
@ -125,25 +126,33 @@ preferred the simplicity and straightforward nature of C which gives us fine
control over all implementation details and on the other hand enough
instruments to build the abstractions we need.
<p>The modules are statically linked to produce a single executable file
(except for the client which stands on its own).
<p>The building process is controlled by a set of Makefiles for GNU Make,
intermixed with several Perl and shell scripts.
<p>The initial configuration of the daemon, detection of system features
and selection of the right modules to include for the particular OS
and the set of protocols the user has chosen is performed by a configure
script created using GNU Autoconf.
script generated by GNU Autoconf.
<p>The parser of the configuration is generated by the GNU Bison.
<p>The documentation is generated using <file/SGMLtools/ with our own DTD
and mapping rules. The printed form of the documentation is first converted
and mapping rules which produce both an online version in HTML and
a neatly formatted one for printing (first converted
from SGML to &latex; and then processed by &tex; and <file/dvips/ to
produce a PostScript file.
get a PostScript file).
<p>The comments from C sources which form a part of the programmer's
documentation are extracted using a modified version of the <file/kernel-doc/
tool.
<p>If you want to work on BIRD, it's highly recommended to configure it
with a <tt/--enable-debug/ switch which enables some internal consistency
checks and it also links BIRD with a memory allocation checking library
if you have one (either <tt/efence/ or <tt/dmalloc/).
<!--
LocalWords: IPv IP CLI snippets Perl Autoconf SGMLtools DTD SGML dvips

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@ -24,8 +24,8 @@
\advance\textheight -2 ex
%\renewcommand{\baselinestretch}{1.14}
\setcounter{tocdepth}{1}
\oddsidemargin 0.5 in
\evensidemargin 0 in
\oddsidemargin 0.15 in
\evensidemargin -0.35 in
\textwidth 6.5in
\def\ps@headings{\let\@mkboth\markboth

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@ -10,25 +10,23 @@
/**
* DOC: Filters
*
* You can find sources of filters language in |filter/|
* directory. |filter/config.Y| filter grammar, and basically translates
* source from user into tree of &f_inst structures. These trees are
* later interpreted using code in |filter/filter.c|. Filters internally
* work with values/variables in struct f_val, which contains type of
* value and value.
* You can find sources of the filter language in |filter/|
* directory. File |filter/config.Y| contains filter grammar and basically translates
* the source from user into a tree of &f_inst structures. These trees are
* later interpreted using code in |filter/filter.c|.
*
* Filter consists of tree of &f_inst structures, one structure per
* "instruction". Each &f_inst contains code, aux value which is
* usually type of data this instruction operates on, and two generic
* arguments (a1, a2). Some instructions contain pointer(s) to other
* instructions in their (a1, a2) fields.
* A filter is represented by a tree of &f_inst structures, one structure per
* "instruction". Each &f_inst contains @code, @aux value which is
* usually the data type this instruction operates on and two generic
* arguments (@a1, @a2). Some instructions contain pointer(s) to other
* instructions in their (@a1, @a2) fields.
*
* Filters use structure &f_val for its variables. Each &f_val
* contains type and value. Types are constants prefixed with %T_. Few
* of types are special; %T_RETURN can be or-ed with type to indicate
* that return from function/from whole filter should be
* forced. Important thing about &f_val s is that they may be copied
* with simple =. That's fine for all currently defined types: strings
* Filters use a &f_val structure for their data. Each &f_val
* contains type and value (types are constants prefixed with %T_). Few
* of the types are special; %T_RETURN can be or-ed with a type to indicate
* that return from a function or from the whole filter should be
* forced. Important thing about &f_val's is that they may be copied
* with a simple |=|. That's fine for all currently defined types: strings
* are read-only (and therefore okay), paths are copied for each
* operation (okay too).
*/

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@ -15,7 +15,7 @@
* BIRD uses its own abstraction of IP address in order to share the same
* code for both IPv4 and IPv6. IP addresses are represented as entities
* of type &ip_addr which are never to be treated as numbers and instead
* they should be manipulated using the following functions and macros.
* they must be manipulated using the following functions and macros.
*/
/**

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@ -18,7 +18,7 @@ references to.
<p>We've tried to solve this problem by employing a resource tracking
system which keeps track of all the resources allocated by all the
modules of BIRD, deallocates everything automatically when a module
shuts down and it's is able to print out the list of resources and
shuts down and it is able to print out the list of resources and
the corresponding modules they are allocated by.
<p>Each allocated resource (from now we'll speak about allocated

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@ -35,12 +35,12 @@
* on the current state of command processing.
*
* The CLI commands are declared as a part of the configuration grammar
* by using the |CF_CLI| macro. When a command is received, it's processed
* by using the |CF_CLI| macro. When a command is received, it is processed
* by the same lexical analyzer and parser as used for the configuration, but
* it's switched to a special mode by prepending a fake token to the text,
* so that it uses only the CLI command rules. Then the parser invokes
* an execution routine corresponding to the command, which either constructs
* the whole reply and returns back or (in case it expects the reply will be long)
* the whole reply and returns it back or (in case it expects the reply will be long)
* it prints a partial reply and asks the CLI module (using the @cont hook)
* to call it again when the output is transferred to the user.
*

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@ -8,14 +8,14 @@
<sect1>Introduction
<p>The routing protocols are the BIRD's heart and a fine amount of code
<p>The routing protocols are the bird's heart and a fine amount of code
is dedicated to their management and for providing support functions to them.
(-: Actually, this is the reason why the directory with sources of the core
code is called <tt/nest/ :-).
<p>When talking about protocols, one need to distinguish between <em/protocols/
and protocol <em/instances/. A protocol exists exactly once, not depending on whether
it's configured on not and it can have an arbitrary number of instances corresponding
it's configured or not and it can have an arbitrary number of instances corresponding
to its "incarnations" requested by the configuration file. Each instance is completely
autonomous, has its own configuration, its own status, its own set of routes and its
own set of interfaces it works on.
@ -49,7 +49,7 @@ we have decided to supervise them by a pair of simple state machines -- the prot
state machine and a core state machine.
<p>The <em/protocol state machine/ corresponds to internal state of the protocol
and the protocol can alter its state whenever it wants to. There exist
and the protocol can alter its state whenever it wants to. There are
the following states:
<descrip>
@ -73,7 +73,7 @@ its state by calling the <func/proto_notify_state/ function.
The states are traversed according to changes of the protocol state machine, but
sometimes the transitions are delayed if the core needs to finish some actions
(for example sending of new routes to the protocol) before proceeding to the
new state. There exist the following core states:
new state. There are the following core states:
<descrip>
<tag/FS_HUNGRY/ The protocol is down, it doesn't have any routes and

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@ -13,12 +13,12 @@
* hold all the information about known networks, the associated routes and
* their attributes.
*
* There exist multiple routing tables (a primary one together with any
* There are multiple routing tables (a primary one together with any
* number of secondary ones if requested by the configuration). Each table
* is basically a FIB containing entries describing the individual
* destination networks. For each network (represented by structure &net),
* there is a one-way linked list of network entries (&rte), the first entry
* on the list being the best possible one (i.e., the one we currently use
* there is a one-way linked list of route entries (&rte), the first entry
* on the list being the best one (i.e., the one we currently use
* for routing), the order of the other ones is undetermined.
*
* The &rte contains information specific to the route (preference, protocol

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@ -9,60 +9,63 @@
/**
* DOC: Open Shortest Path First (OSPF)
*
* As OSPF protocol is quite complicated and complex implemenation is
* split into many files. In |ospf.c| you can find mostly interfaces
* for communication with nest. (E.g. reconfiguration hooks, shutdown
* and inicialisation and so on.) In |packet.c| you can find various
* functions for sending and receiving generic OSPF packet. There are
* also routins for autentications, checksumming. |Iface.c| contains
* interface state machine, allocation and deallocation of OSPF's
* interface data structures. |Neighbor.c| includes neighbor state
* machine and function for election of Designed Router and Backup
* Designed router. In |hello.c| there are routines for sending
* and receiving hello packets as well as functions for maintaining
* wait times and inactivity timer. |Lsreq.c|, |lsack.c|, |dbdes.c|
* contains functions for sending and receiving link-state request,
* link-state acknoledge and database description respectively.
* In |lsupd.c| there are function for sending and receiving
* link-state updates and also flooding algoritmus. |Topology.c| is
* a place where routins for searching LSAs in link-state database,
* adding and deleting them, there are also functions for originating
* various types of LSA. (router lsa, net lsa, external lsa) |Rt.c|
* contains routins for calculating of routing table. |Lsalib.c| is a set
* of various functions for work with LSAs. (Endianity transformations,
* checksum calculation etc.)
* The OSPF protocol is quite complicated and its complex implemenation is
* split to many files. In |ospf.c|, you can find mostly interface
* for communication with the core (e.g., reconfiguration hooks, shutdown
* and initialisation and so on). In |packet.c|, you can find various
* functions for sending and receiving of generic OSPF packets. There are
* also routines for autentication and checksumming. File |iface.c| contains
* the interface state machine, allocation and deallocation of OSPF's
* interface data structures. Source |neighbor.c| includes the neighbor state
* machine and functions for election of Designed Router and Backup
* Designed router. In |hello.c|, there are routines for sending
* and receiving of hello packets as well as functions for maintaining
* wait times and the inactivity timer. Files |lsreq.c|, |lsack.c|, |dbdes.c|
* contain functions for sending and receiving of link-state requests,
* link-state acknoledges and database descriptions respectively.
* In |lsupd.c|, there are functions for sending and receiving
* of link-state updates and also the flooding algorithm. Source |topology.c| is
* a place where routines for searching LSA's in the link-state database,
* adding and deleting them reside, there also are functions for originating
* of various types of LSA's (router LSA, net LSA, external LSA). File |rt.c|
* contains routines for calculating the routing table. |lsalib.c| is a set
* of various functions for working with the LSA's (endianity conversions,
* calculation of checksum etc.).
*
* Just one instance of protocol is able to hold LSA databases for
* multiple OSPF areas and exhange routing information between
* multiple neighbors and calculate routing tables. The core
* structure is &proto_ospf, to which multiple &ospf_area and
* &ospf_iface are connected. To &ospf_area is connected
* &top_hash_graph, which is a dynamic hashing structure that
* describes link-state database. It allows fast search, adding
* and deleting. LSA is kept in two pieces: header and body. Both of them are
* kept in endianity of CPU.
* One instance of the protocol is able to hold LSA databases for
* multiple OSPF areas, to exchange routing information between
* multiple neighbors and to calculate the routing tables. The core
* structure is &proto_ospf to which multiple &ospf_area and
* &ospf_iface structures are connected. To &ospf_area is also connected
* &top_hash_graph which is a dynamic hashing structure that
* describes the link-state database. It allows fast search, addition
* and deletion. Each LSA is kept in two pieces: header and body. Both of them are
* kept in endianity of the CPU.
*
* Every area has it's own area_disp() that is
* responsible for late originating of router LSA, calcutating
* of routing table and it also ages and flushes LSA database. This
* Every area has its own area_disp() which is
* responsible for late originating of router LSA, calculating
* of the routing table and it also ages and flushes the LSA's. This
* function is called in regular intervals.
* To every &ospf_iface is connected one or more
* &ospf_neighbors. This structure contains many timers and queues
* for building adjacency and exchange routing messages.
* To every &ospf_iface, we connect one or more
* &ospf_neighbor's -- a structure containing many timers and queues
* for building adjacency and for exchange of routing messages.
*
* BIRD's OSPF implementation respects RFC2328 in every detail but
* some of inner function differs. RFC recommends to make a snapshot
* of link-state database when new adjacency is building and send
* database description packets based on information of this
* snapshot. The database can be quite large in some networks so
* I rather walk through &slist structure which allows me to
* continue even if actual LSA I worked on is deleted. New
* LSA are added to the tail of this slist.
* BIRD's OSPF implementation respects RFC2328 in every detail, but
* some of internal algorithms do differ. The RFC recommends to make a snapshot
* of the link-state database when a new adjacency is forming and send
* the database description packets based on information of this
* snapshot. The database can be quite large in some networks, so
* we rather walk through a &slist structure which allows us to
* continue even if the actual LSA we were worked with is deleted. New
* LSA's are added at the tail of this &slist.
*
* I also don't build another, new routing table besides the old
* one because nest helps me. I simply flush all calculated and
* deleted routes into nest's routing table. It's simplyfies
* this process and spares memory.
* We also don't keep a separate OSPF routing table, because the core
* helps us by being able to recognize when a route is updated
* to an identical one and it suppresses the update automatically.
* Due to this, we can flush all the routes we've recalculated and
* also those we're deleted to the core's routing table and the
* core will take care of the rest. This simplifies the process
* and conserves memory.
*/
#include "ospf.h"

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@ -9,19 +9,18 @@
/**
* DOC: Static
*
* The Static protocol is implemented in a very straightforward way. It keeps
* a two lists of static routes: one containing interface routes and one
* The Static protocol is implemented in a straightforward way. It keeps
* two lists of static routes: one containing interface routes and one
* holding the remaining ones. Interface routes are inserted and removed according
* to interface events received from the core via the if_notify() hook, routes
* to interface events received from the core via the if_notify() hook. Routes
* pointing to a neighboring router use a sticky node in the neighbor cache
* to be notified about gaining or losing the neighbor and finally special
* to be notified about gaining or losing the neighbor. Special
* routes like black holes or rejects are inserted all the time.
*
* The only other thing worth mentioning is that when asked for reconfiguration,
* Static not only compares the two configurations, but it also calculates
* difference between the lists of static routes mentioned in the old config
* and the lists in the new one and it just inserts the newly added routes
* and removes the obsolete ones.
* difference between the lists of static routes and it just inserts the
* newly added routes and removes the obsolete ones.
*/
#undef LOCAL_DEBUG

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@ -20,7 +20,7 @@
* a local routing table copy.
*
* The kernel syncer can work in three different modes (according to system config header):
* Either with a single routing table and single KRT protocol [traditional Unix]
* Either with a single routing table and single KRT protocol [traditional UNIX]
* or with many routing tables and separate KRT protocols for all of them
* or with many routing tables, but every scan including all tables, so we start
* separate KRT protocols which cooperate with each other [Linux 2.2].
@ -33,7 +33,8 @@
*
* When starting up, we cheat by looking if there is another
* KRT instance to be initialized later and performing table scan
* only once for all the instances. */
* only once for all the instances.
*/
/*
* If you are brave enough, continue now. You cannot say you haven't been warned.

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@ -10,7 +10,9 @@
* DOC: Logging
*
* The Logging module offers a simple set of functions for writing
* messages to system logs and to the debug output.
* messages to system logs and to the debug output. Message classes
* used by this module are described in |birdlib.h| and also in the
* user's manual.
*/
#include <stdio.h>