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Documented sockets, events and timers.

This commit is contained in:
Martin Mares 2000-06-05 12:19:12 +00:00
parent 10304bed43
commit 525fa2c1f0
5 changed files with 196 additions and 14 deletions

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@ -6,5 +6,5 @@ D resource.sgml
S resource.c
S mempool.c
S slab.c
S socket.h
S event.c
S ../sysdep/unix/io.c

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@ -6,6 +6,21 @@
* Can be freely distributed and used under the terms of the GNU GPL.
*/
/**
* DOC: Events
*
* Events are there to keep track of deferred execution.
* Since BIRD is single-threaded, it requires long lasting tasks to be split to smaller
* parts, so that no module can monopolize the CPU. To split such a task, just create
* an &event resource, point it to the function you want to have called and call ev_schedule()
* to ask the core to run the event when nothing more important will require attention.
*
* You can also define your own event lists (the &event_list structure), enqueue your
* events in them and explicitly ask to run them.
*
* The actual implementation is system dependent.
*/
#include "nest/bird.h"
#include "lib/event.h"
@ -39,6 +54,13 @@ static struct resclass ev_class = {
ev_dump
};
/**
* ev_new - create a new event
* @p: resource pool
*
* This function creates a new event resource. To use it,
* you need to fill the structure fields and call ev_schedule().
*/
event *
ev_new(pool *p)
{
@ -50,6 +72,16 @@ ev_new(pool *p)
return e;
}
/**
* ev_run - run an event
* @e: an event
*
* This function explicitly runs the event @e (calls its hook
* function) and removes it from an event list if it's linked to any.
*
* From the hook function, you can call ev_enqueue() or ev_schedule()
* to re-add the event.
*/
inline void
ev_run(event *e)
{
@ -57,6 +89,14 @@ ev_run(event *e)
e->hook(e->data);
}
/**
* ev_enqueue - enqueue an event
* @l: an event list
* @e: an event
*
* ev_enqueue() stores the event @e to the specified event
* list @l which can be run by calling ev_run_list().
*/
inline void
ev_enqueue(event_list *l, event *e)
{
@ -64,12 +104,26 @@ ev_enqueue(event_list *l, event *e)
add_tail(l, &e->n);
}
/**
* ev_schedule - schedule an event
* @e: an event
*
* This function schedules an event by enqueueing it to a system-wide
* event list which is run by the platform dependent code whenever
* appropriate.
*/
void
ev_schedule(event *e)
{
ev_enqueue(&global_event_list, e);
}
/**
* ev_run_list - run an event list
* @l: an event list
*
* This function calls ev_run() for all events enqueued in the list @l.
*/
int
ev_run_list(event_list *l)
{

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@ -36,15 +36,7 @@ type.
<item><it/Memory blocks/
<item><it/Linear memory pools/ (<struct/linpool/)
<item><it/Slabs/ (<struct/slab/)
<item><it/Sockets/ (<struct/socket/)
<item><it/Events/ (<struct/event/)
<!--
are there to keep track of deferred execution.
Since BIRD is single-threaded, it requires long lasting tasks to be split to smaller
parts, so that no module can monopolize the CPU. To split such a task, just create
an <struct/event/ resource, point it to the function you want to have called and call <func/ev_schedule()/
to ask the core to run the event when nothing more important will require attention.
The actual implementation is system dependent.
-->
<item><it/Timers/ (<struct/timer/)
<item><it/Sockets/ (<struct/socket/)
</itemize>

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@ -9,3 +9,4 @@ S iface.c
S neighbor.c
S cli.c
S locks.c
# rt-dev.c documented in Protocols chapter

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@ -73,8 +73,23 @@ tracked_fopen(pool *p, char *name, char *mode)
return f;
}
/*
* Timers
/**
* DOC: Timers
*
* Timers are resources which represent a wish of a module to call
* a function at the specified time. The platform dependent code
* doesn't guarantee the exact timing, only that a timer function
* won't be called before the requested time.
*
* In BIRD, real time is represented by values of the &bird_clock_t type
* which are integral numbers corresponding to a number of seconds since
* a fixed (but platform dependent) epoch. The current time can be read
* from a variable @now with reasonable accuracy.
*
* Each timer is described by a &timer structure containing a pointer
* to the handler function (@hook), data private to this function (@data),
* time the function should be called at (@expires, 0 for inactive timers),
* for the other fields see |timer.h|.
*/
#define NEAR_TIMER_LIMIT 4
@ -115,6 +130,14 @@ static struct resclass tm_class = {
tm_dump
};
/**
* tm_new - create a timer
* @p: pool
*
* This function creates a new timer resource and returns
* a pointer to it. To use the timer, you need to fill in
* the structure fields and call tm_start() to start timing.
*/
timer *
tm_new(pool *p)
{
@ -136,6 +159,23 @@ tm_insert_near(timer *t)
insert_node(&t->n, n->prev);
}
/**
* tm_start - start a timer
* @t: timer
* @after: number of seconds the timer should be run after
*
* This function schedules the hook function of the timer to
* be called after @after seconds. If the timer has been already
* started, it's @expire time is replaced by the new value.
*
* You can have set the @randomize field of @t, the timeout
* will be increased by a random number of seconds chosen
* uniformly from range 0 .. @randomize.
*
* You can call tm_start() from the handler function of the timer
* to request another run of the timer. Also, you can set the @recurrent
* field to have the timer re-added automatically with the same timeout.
*/
void
tm_start(timer *t, unsigned after)
{
@ -159,6 +199,13 @@ tm_start(timer *t, unsigned after)
}
}
/**
* tm_stop - stop a timer
* @t: timer
*
* This function stops a timer. If the timer is already stopped,
* nothing happens.
*/
void
tm_stop(timer *t)
{
@ -250,6 +297,13 @@ tm_shot(void)
}
}
/**
* tm_parse_date - parse a date
* @x: date string
*
* tm_parse_date() takes a textual representation of a date (dd-mm-yyyy)
* and converts it to the corresponding value of type &bird_clock_t.
*/
bird_clock_t
tm_parse_date(char *x)
{
@ -268,6 +322,14 @@ tm_parse_date(char *x)
return t;
}
/**
* tm_format_date - convert date to textual representation
* @x: destination buffer of size %TM_DATE_BUFFER_SIZE
* @t: time
*
* This function formats the given time value @t to a textual
* date representation (dd-mm-yyyy).
*/
void
tm_format_date(char *x, bird_clock_t t)
{
@ -277,6 +339,14 @@ tm_format_date(char *x, bird_clock_t t)
bsprintf(x, "%02d-%02d-%04d", tm->tm_mday, tm->tm_mon+1, tm->tm_year+1900);
}
/**
* tm_format_datetime - convert date and time to textual representation
* @x: destination buffer of size %TM_DATETIME_BUFFER_SIZE
* @t: time
*
* This function formats the given time value @t to a textual
* date/time representation (dd-mm-yyyy hh:mm:ss).
*/
void
tm_format_datetime(char *x, bird_clock_t t)
{
@ -287,6 +357,14 @@ tm_format_datetime(char *x, bird_clock_t t)
strcpy(x, "<too-long>");
}
/**
* tm_format_reltime - convert date and time to relative textual representation
* @x: destination buffer of size %TM_RELTIME_BUFFER_SIZE
* @t: time
*
* This function formats the given time value @t to a short
* textual representation relative to the current time.
*/
void
tm_format_reltime(char *x, bird_clock_t t)
{
@ -303,8 +381,17 @@ tm_format_reltime(char *x, bird_clock_t t)
bsprintf(x, "%d", tm->tm_year+1900);
}
/*
* Sockets
/**
* DOC: Sockets
*
* Socket resources represent network connections. Their data structure (&socket)
* contains a lot of fields defining the exact type of the socket, the local and
* remote addresses and ports, pointers to socket buffers and finally pointers to
* hook functions to be called when new data have arrived to the receive buffer
* (@rx_hook), when the contents of the transmit buffer have been transmitted
* (@tx_hook) and when an error or connection close occurs (@err_hook).
*
* You should not use rfree() from inside a socket hook, please use sk_close() instead.
*/
#ifndef SOL_IP
@ -350,6 +437,14 @@ static struct resclass sk_class = {
sk_dump
};
/**
* sk_new - create a socket
* @p: pool
*
* This function creates a new socket resource. If you want to use it,
* you need to fill in all the required fields of the structure and
* call sk_open() to do the actual opening of the socket.
*/
sock *
sk_new(pool *p)
{
@ -502,6 +597,16 @@ sk_passive_connected(sock *s, struct sockaddr *sa, int al, int type)
return 0;
}
/**
* sk_open - open a socket
* @s: socket
*
* This function takes a socket resource created by sk_new() and
* initialized by the user and binds a corresponding network connection
* to it.
*
* Result: 0 for success, -1 for an error.
*/
int
sk_open(sock *s)
{
@ -683,6 +788,14 @@ bad:
return -1;
}
/**
* sk_close - close a socket
* @s: a socket
*
* If sk_close() has been called from outside of any socket hook,
* it translates to a rfree(), else it just marks the socket for
* deletion as soon as the socket hook returns.
*/
void
sk_close(sock *s)
{
@ -746,6 +859,18 @@ sk_maybe_write(sock *s)
}
}
/**
* sk_send - send data to a socket
* @s: socket
* @len: number of bytes to send
*
* This function sends @len bytes of data prepared in the
* transmit buffer of the socket @s to the network connection.
* If the packet can be sent immediately, it does so and returns
* 1, else it queues the packet for later processing, returns 0
* and calls the @tx_hook of the socket when the tranmission
* takes place.
*/
int
sk_send(sock *s, unsigned len)
{
@ -756,6 +881,16 @@ sk_send(sock *s, unsigned len)
return sk_maybe_write(s);
}
/**
* sk_send_to - send data to a specific destination
* @s: socket
* @len: number of bytes to send
* @addr: IP address to send the packet to
* @port: port to send the packet to
*
* This is a sk_send() replacement for connectionless packet sockets
* which allows destination of the packet to be chosen dynamically.
*/
int
sk_send_to(sock *s, unsigned len, ip_addr addr, unsigned port)
{