bird/nest/proto.c
Martin Mares bf8558bc9c Converted shutdown to a kind of reconfiguration, it's no more handled
as a exception in protocol state machines. Introduced a `shutdown'
CLI command. Killed few reconfiguration bugs.
2000-01-16 17:40:26 +00:00

573 lines
13 KiB
C

/*
* BIRD -- Protocols
*
* (c) 1998--2000 Martin Mares <mj@ucw.cz>
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
#define LOCAL_DEBUG
#include <string.h>
#include "nest/bird.h"
#include "nest/protocol.h"
#include "lib/resource.h"
#include "lib/lists.h"
#include "lib/event.h"
#include "conf/conf.h"
#include "nest/route.h"
#include "nest/iface.h"
#include "nest/cli.h"
#include "filter/filter.h"
static pool *proto_pool;
list protocol_list;
list proto_list;
static list inactive_proto_list;
static list initial_proto_list;
static list flush_proto_list;
static event *proto_flush_event;
static char *p_states[] = { "DOWN", "START", "UP", "STOP" };
static char *c_states[] = { "HUNGRY", "FEEDING", "HAPPY", "FLUSHING" };
static int proto_flush_all(void *);
static void proto_rethink_goal(struct proto *p);
static void
proto_enqueue(list *l, struct proto *p)
{
int pri = p->proto->priority;
if (!pri)
add_tail(l, &p->n);
else
{
struct proto *q = HEAD(*l);
while (q->n.next && q->proto->priority >= pri)
q = (struct proto *) q->n.next;
insert_node(&p->n, q->n.prev);
}
p->last_state_change = now;
}
static void
proto_relink(struct proto *p)
{
list *l;
rem_node(&p->n);
switch (p->core_state)
{
case FS_HAPPY:
l = &proto_list;
break;
case FS_FLUSHING:
l = &flush_proto_list;
break;
default:
l = &inactive_proto_list;
}
proto_enqueue(l, p);
}
void *
proto_new(struct proto_config *c, unsigned size)
{
struct protocol *pr = c->protocol;
struct proto *p = mb_allocz(proto_pool, size);
p->cf = c;
p->debug = c->debug;
p->name = c->name;
p->preference = c->preference;
p->disabled = c->disabled;
p->proto = pr;
p->table = c->table->table;
p->in_filter = c->in_filter;
p->out_filter = c->out_filter;
p->min_scope = SCOPE_SITE;
c->proto = p;
return p;
}
static void
proto_init_instance(struct proto *p)
{
/* Here we cannot use p->cf->name since it won't survive reconfiguration */
p->pool = rp_new(proto_pool, p->proto->name);
p->attn = ev_new(p->pool);
p->attn->data = p;
rt_lock_table(p->table);
}
struct announce_hook *
proto_add_announce_hook(struct proto *p, struct rtable *t)
{
struct announce_hook *h;
if (!p->rt_notify)
return NULL;
DBG("Connecting protocol %s to table %s\n", p->name, t->name);
h = mb_alloc(p->pool, sizeof(struct announce_hook));
h->table = t;
h->proto = p;
h->next = p->ahooks;
p->ahooks = h;
add_tail(&t->hooks, &h->n);
return h;
}
static void
proto_flush_hooks(struct proto *p)
{
struct announce_hook *h;
for(h=p->ahooks; h; h=h->next)
rem_node(&h->n);
p->ahooks = NULL;
}
void *
proto_config_new(struct protocol *pr, unsigned size)
{
struct proto_config *c = cfg_allocz(size);
add_tail(&new_config->protos, &c->n);
c->global = new_config;
c->protocol = pr;
c->debug = pr->debug;
c->name = pr->name;
c->out_filter = FILTER_REJECT;
c->table = c->global->master_rtc;
return c;
}
void
protos_preconfig(struct config *c)
{
struct protocol *p;
init_list(&proto_list);
init_list(&inactive_proto_list);
init_list(&initial_proto_list);
init_list(&flush_proto_list);
init_list(&c->protos);
debug("Protocol preconfig:");
WALK_LIST(p, protocol_list)
{
debug(" %s", p->name);
p->name_counter = 0;
if (p->preconfig)
p->preconfig(p, c);
}
debug("\n");
}
void
protos_postconfig(struct config *c)
{
struct proto_config *x;
struct protocol *p;
debug("Protocol postconfig:");
WALK_LIST(x, c->protos)
{
debug(" %s", x->name);
p = x->protocol;
if (p->postconfig)
p->postconfig(x);
}
debug("\n");
}
static struct proto *
proto_init(struct proto_config *c)
{
struct protocol *p = c->protocol;
struct proto *q = p->init(c);
q->proto_state = PS_DOWN;
q->core_state = FS_HUNGRY;
proto_enqueue(&initial_proto_list, q);
/*
* HACK ALERT! In case of multiple kernel routing tables,
* the kernel syncer acts as multiple protocols which cooperate
* with each other. In order to speed up their initialization,
* we need to know when we're initializing the last one, hence
* the startup counter.
*/
if (!q->disabled)
p->startup_counter++;
return q;
}
void
protos_commit(struct config *new, struct config *old, int force_reconfig)
{
struct proto_config *oc, *nc;
struct proto *p, *n;
DBG("protos_commit:\n");
if (old)
{
WALK_LIST(oc, old->protos)
{
struct proto *p = oc->proto;
struct symbol *sym = cf_find_symbol(oc->name);
if (sym && sym->class == SYM_PROTO && !new->shutdown)
{
/* Found match, let's check if we can smoothly switch to new configuration */
nc = sym->def;
if (!force_reconfig
&& nc->protocol == oc->protocol
&& nc->preference == oc->preference
&& nc->disabled == oc->disabled
&& nc->table->table == oc->table->table
&& nc->in_filter == oc->in_filter
&& nc->out_filter == oc->out_filter
&& p->proto_state != PS_DOWN)
{
/* Generic attributes match, try converting them and then ask the protocol */
p->debug = nc->debug;
if (p->proto->reconfigure && p->proto->reconfigure(p, nc))
{
DBG("\t%s: same\n", oc->name);
p->cf = nc;
nc->proto = p;
continue;
}
}
/* Unsuccessful, force reconfig */
DBG("\t%s: power cycling\n", oc->name);
p->cf_new = nc;
nc->proto = p;
}
else
{
DBG("\t%s: deleting\n", oc->name);
p->cf_new = NULL;
}
p->reconfiguring = 1;
config_add_obstacle(old);
proto_rethink_goal(p);
}
}
WALK_LIST(nc, new->protos)
if (!nc->proto)
{
DBG("\t%s: adding\n", nc->name);
proto_init(nc);
}
DBG("\tdone\n");
DBG("Protocol start\n");
WALK_LIST_DELSAFE(p, n, initial_proto_list)
proto_rethink_goal(p);
}
static void
proto_rethink_goal(struct proto *p)
{
struct protocol *q;
if (p->reconfiguring && p->core_state == FS_HUNGRY && p->proto_state == PS_DOWN)
{
struct proto_config *nc = p->cf_new;
DBG("%s has shut down for reconfiguration\n", p->name);
config_del_obstacle(p->cf->global);
rem_node(&p->n);
mb_free(p);
if (!nc)
return;
p = proto_init(nc); /* FIXME: What about protocol priorities??? */
}
/* Determine what state we want to reach */
if (p->disabled || p->reconfiguring)
p->core_goal = FS_HUNGRY;
else
p->core_goal = FS_HAPPY;
if (p->core_state == p->core_goal)
return;
q = p->proto;
if (p->core_goal == FS_HAPPY) /* Going up */
{
if (p->core_state == FS_HUNGRY && p->proto_state == PS_DOWN)
{
DBG("Kicking %s up\n", p->name);
ASSERT(q->startup_counter > 0);
q->startup_counter--;
proto_init_instance(p);
proto_notify_state(p, (q->start ? q->start(p) : PS_UP));
}
}
else /* Going down */
{
if (p->proto_state == PS_START || p->proto_state == PS_UP)
{
DBG("Kicking %s down\n", p->name);
proto_notify_state(p, (q->shutdown ? q->shutdown(p) : PS_DOWN));
}
}
}
void
protos_dump_all(void)
{
struct proto *p;
debug("Protocols:\n");
WALK_LIST(p, proto_list)
{
debug(" protocol %s (pri=%d): state %s/%s\n", p->name, p->proto->priority,
p_states[p->proto_state], c_states[p->core_state]);
if (p->in_filter)
debug("\tInput filter: %s\n", filter_name(p->in_filter));
if (p->out_filter != FILTER_REJECT)
debug("\tOutput filter: %s\n", filter_name(p->out_filter));
if (p->disabled)
debug("\tDISABLED\n");
else if (p->proto->dump)
p->proto->dump(p);
}
WALK_LIST(p, inactive_proto_list)
debug(" inactive %s: state %s/%s\n", p->name, p_states[p->proto_state], c_states[p->core_state]);
WALK_LIST(p, initial_proto_list)
debug(" initial %s\n", p->name);
}
void
protos_build(void)
{
init_list(&protocol_list);
add_tail(&protocol_list, &proto_device.n);
#ifdef CONFIG_RIP
add_tail(&protocol_list, &proto_rip.n);
#endif
#ifdef CONFIG_STATIC
add_tail(&protocol_list, &proto_static.n);
#endif
#ifdef CONFIG_OSPF
add_tail(&protocol_list, &proto_ospf.n);
#endif
proto_pool = rp_new(&root_pool, "Protocols");
proto_flush_event = ev_new(proto_pool);
proto_flush_event->hook = proto_flush_all;
}
static void
proto_fell_down(struct proto *p)
{
DBG("Protocol %s down\n", p->name);
rt_unlock_table(p->table);
proto_rethink_goal(p);
}
static int
proto_feed(void *P)
{
struct proto *p = P;
DBG("Feeding protocol %s\n", p->name);
proto_add_announce_hook(p, p->table);
if_feed_baby(p);
rt_feed_baby(p);
p->core_state = FS_HAPPY;
proto_relink(p);
DBG("Protocol %s up and running\n", p->name);
return 0;
}
void
proto_notify_state(struct proto *p, unsigned ps)
{
unsigned ops = p->proto_state;
unsigned cs = p->core_state;
DBG("%s reporting state transition %s/%s -> */%s\n", p->name, c_states[cs], p_states[ops], p_states[ps]);
if (ops == ps)
return;
switch (ps)
{
case PS_DOWN:
if (cs == FS_HUNGRY) /* Shutdown finished */
{
proto_fell_down(p);
return; /* The protocol might have ceased to exist */
}
else if (cs == FS_FLUSHING) /* Still flushing... */
;
else /* Need to start flushing */
goto schedule_flush;
break;
case PS_START:
ASSERT(ops == PS_DOWN);
ASSERT(cs == FS_HUNGRY);
break;
case PS_UP:
ASSERT(ops == PS_DOWN || ops == PS_START);
ASSERT(cs == FS_HUNGRY);
DBG("%s: Scheduling meal\n", p->name);
if (p->proto->priority) /* FIXME: Terrible hack to get synchronous device/kernel startup! */
{
p->proto_state = ps;
p->core_state = FS_FEEDING;
proto_feed(p);
return;
}
cs = FS_FEEDING;
p->attn->hook = proto_feed;
ev_schedule(p->attn);
break;
case PS_STOP:
if (cs == FS_FEEDING || cs == FS_HAPPY)
{
schedule_flush:
DBG("%s: Scheduling flush\n", p->name);
proto_flush_hooks(p);
cs = FS_FLUSHING;
ev_schedule(proto_flush_event);
}
break;
default:
error:
bug("Invalid state transition for %s from %s/%s to */%s", p->name, c_states[cs], p_states[ops], p_states[ps]);
}
p->proto_state = ps;
p->core_state = cs;
proto_relink(p);
}
static int
proto_flush_all(void *unused)
{
struct proto *p;
rt_prune_all();
neigh_prune();
while ((p = HEAD(flush_proto_list))->n.next)
{
DBG("Flushing protocol %s\n", p->name);
rfree(p->pool);
p->pool = NULL;
p->core_state = FS_HUNGRY;
proto_relink(p);
proto_fell_down(p);
}
return 0;
}
/*
* CLI Commands
*/
static char *
proto_state_name(struct proto *p)
{
#define P(x,y) ((x << 4) | y)
switch (P(p->proto_state, p->core_state))
{
case P(PS_DOWN, FS_HUNGRY): return "down";
case P(PS_START, FS_HUNGRY): return "start";
case P(PS_UP, FS_HUNGRY):
case P(PS_UP, FS_FEEDING): return "feed";
case P(PS_STOP, FS_HUNGRY): return "stop";
case P(PS_UP, FS_HAPPY): return "up";
case P(PS_STOP, FS_FLUSHING):
case P(PS_DOWN, FS_FLUSHING): return "flush";
default: return "???";
}
#undef P
}
static void
proto_do_show(struct proto *p, int verbose)
{
byte buf[256], reltime[TM_RELTIME_BUFFER_SIZE];
buf[0] = 0;
if (p->proto->get_status)
p->proto->get_status(p, buf);
tm_format_reltime(reltime, p->last_state_change);
cli_msg(-1002, "%-8s %-8s %-8s %-5s %-5s %s",
p->name,
p->proto->name,
p->table->name,
proto_state_name(p),
reltime,
buf);
if (verbose)
{
cli_msg(-1006, "\tPreference: %d", p->preference);
cli_msg(-1006, "\tInput filter: %s", filter_name(p->in_filter));
cli_msg(-1006, "\tOutput filter: %s", filter_name(p->out_filter));
}
}
static void
proto_do_show_list(list *l, int verbose)
{
struct proto *p;
WALK_LIST(p, *l)
proto_do_show(p, verbose);
}
void
proto_show(struct symbol *s, int verbose)
{
if (s && s->class != SYM_PROTO)
{
cli_msg(9002, "%s is not a protocol", s->name);
return;
}
cli_msg(-2002, "name proto table state since info");
if (s)
proto_do_show(((struct proto_config *)s->def)->proto, verbose);
else
{
proto_do_show_list(&proto_list, verbose);
proto_do_show_list(&flush_proto_list, verbose);
proto_do_show_list(&inactive_proto_list, verbose);
}
cli_msg(0, "");
}
struct proto *
proto_get_named(struct symbol *sym, struct protocol *pr)
{
struct proto *p, *q;
if (sym)
{
if (sym->class != SYM_PROTO)
cf_error("%s: Not a protocol", sym->name);
p = ((struct proto_config *)sym->def)->proto;
if (!p || p->proto != pr)
cf_error("%s: Not a %s protocol", sym->name, pr->name);
}
else
{
p = NULL;
WALK_LIST(q, proto_list)
if (q->proto == pr)
{
if (p)
cf_error("There are multiple %s protocols running", pr->name);
p = q;
}
if (!p)
cf_error("There is no %s protocol running", pr->name);
}
return p;
}