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ovs/lib/rconn.c

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Import from old repository commit 61ef2b42a9c4ba8e1600f15bb0236765edc2ad45.
2009-07-08 13:19:16 -07:00
/*
* Copyright (c) 2008, 2009 Nicira Networks.
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#include <config.h>
#include "rconn.h"
#include <assert.h>
#include <errno.h>
#include <limits.h>
#include <stdlib.h>
#include <string.h>
#include "coverage.h"
#include "ofpbuf.h"
#include "openflow/openflow.h"
#include "poll-loop.h"
#include "sat-math.h"
#include "timeval.h"
#include "util.h"
#include "vconn.h"
#define THIS_MODULE VLM_rconn
#include "vlog.h"
#define STATES \
STATE(VOID, 1 << 0) \
STATE(BACKOFF, 1 << 1) \
STATE(CONNECTING, 1 << 2) \
STATE(ACTIVE, 1 << 3) \
STATE(IDLE, 1 << 4)
enum state {
#define STATE(NAME, VALUE) S_##NAME = VALUE,
STATES
#undef STATE
};
static const char *
state_name(enum state state)
{
switch (state) {
#define STATE(NAME, VALUE) case S_##NAME: return #NAME;
STATES
#undef STATE
}
return "***ERROR***";
}
/* A reliable connection to an OpenFlow switch or controller.
*
* See the large comment in rconn.h for more information. */
struct rconn {
enum state state;
time_t state_entered;
struct vconn *vconn;
char *name;
bool reliable;
struct ovs_queue txq;
int backoff;
int max_backoff;
time_t backoff_deadline;
time_t last_received;
time_t last_connected;
unsigned int packets_sent;
unsigned int seqno;
/* In S_ACTIVE and S_IDLE, probably_admitted reports whether we believe
* that the peer has made a (positive) admission control decision on our
* connection. If we have not yet been (probably) admitted, then the
* connection does not reset the timer used for deciding whether the switch
* should go into fail-open mode.
*
* last_admitted reports the last time we believe such a positive admission
* control decision was made. */
bool probably_admitted;
time_t last_admitted;
/* These values are simply for statistics reporting, not used directly by
* anything internal to the rconn (or the secchan for that matter). */
unsigned int packets_received;
unsigned int n_attempted_connections, n_successful_connections;
time_t creation_time;
unsigned long int total_time_connected;
/* If we can't connect to the peer, it could be for any number of reasons.
* Usually, one would assume it is because the peer is not running or
* because the network is partitioned. But it could also be because the
* network topology has changed, in which case the upper layer will need to
* reassess it (in particular, obtain a new IP address via DHCP and find
* the new location of the controller). We set this flag when we suspect
* that this could be the case. */
bool questionable_connectivity;
time_t last_questioned;
/* Throughout this file, "probe" is shorthand for "inactivity probe".
* When nothing has been received from the peer for a while, we send out
* an echo request as an inactivity probe packet. We should receive back
* a response. */
int probe_interval; /* Secs of inactivity before sending probe. */
/* Messages sent or received are copied to the monitor connections. */
#define MAX_MONITORS 8
struct vconn *monitors[8];
size_t n_monitors;
};
static unsigned int elapsed_in_this_state(const struct rconn *);
static unsigned int timeout(const struct rconn *);
static bool timed_out(const struct rconn *);
static void state_transition(struct rconn *, enum state);
static int try_send(struct rconn *);
static int reconnect(struct rconn *);
static void disconnect(struct rconn *, int error);
static void flush_queue(struct rconn *);
static void question_connectivity(struct rconn *);
static void copy_to_monitor(struct rconn *, const struct ofpbuf *);
static bool is_connected_state(enum state);
static bool is_admitted_msg(const struct ofpbuf *);
/* Creates a new rconn, connects it (reliably) to 'name', and returns it. */
struct rconn *
rconn_new(const char *name, int inactivity_probe_interval, int max_backoff)
{
struct rconn *rc = rconn_create(inactivity_probe_interval, max_backoff);
rconn_connect(rc, name);
return rc;
}
/* Creates a new rconn, connects it (unreliably) to 'vconn', and returns it. */
struct rconn *
rconn_new_from_vconn(const char *name, struct vconn *vconn)
{
struct rconn *rc = rconn_create(60, 0);
rconn_connect_unreliably(rc, name, vconn);
return rc;
}
/* Creates and returns a new rconn.
*
* 'probe_interval' is a number of seconds. If the interval passes once
* without an OpenFlow message being received from the peer, the rconn sends
* out an "echo request" message. If the interval passes again without a
* message being received, the rconn disconnects and re-connects to the peer.
* Setting 'probe_interval' to 0 disables this behavior.
*
* 'max_backoff' is the maximum number of seconds between attempts to connect
* to the peer. The actual interval starts at 1 second and doubles on each
* failure until it reaches 'max_backoff'. If 0 is specified, the default of
* 60 seconds is used. */
struct rconn *
rconn_create(int probe_interval, int max_backoff)
{
struct rconn *rc = xcalloc(1, sizeof *rc);
rc->state = S_VOID;
rc->state_entered = time_now();
rc->vconn = NULL;
rc->name = xstrdup("void");
rc->reliable = false;
queue_init(&rc->txq);
rc->backoff = 0;
rc->max_backoff = max_backoff ? max_backoff : 60;
rc->backoff_deadline = TIME_MIN;
rc->last_received = time_now();
rc->last_connected = time_now();
rc->seqno = 0;
rc->packets_sent = 0;
rc->probably_admitted = false;
rc->last_admitted = time_now();
rc->packets_received = 0;
rc->n_attempted_connections = 0;
rc->n_successful_connections = 0;
rc->creation_time = time_now();
rc->total_time_connected = 0;
rc->questionable_connectivity = false;
rc->last_questioned = time_now();
rconn_set_probe_interval(rc, probe_interval);
rc->n_monitors = 0;
return rc;
}
void
rconn_set_max_backoff(struct rconn *rc, int max_backoff)
{
rc->max_backoff = MAX(1, max_backoff);
if (rc->state == S_BACKOFF && rc->backoff > max_backoff) {
rc->backoff = max_backoff;
if (rc->backoff_deadline > time_now() + max_backoff) {
rc->backoff_deadline = time_now() + max_backoff;
}
}
}
int
rconn_get_max_backoff(const struct rconn *rc)
{
return rc->max_backoff;
}
void
rconn_set_probe_interval(struct rconn *rc, int probe_interval)
{
rc->probe_interval = probe_interval ? MAX(5, probe_interval) : 0;
}
int
rconn_get_probe_interval(const struct rconn *rc)
{
return rc->probe_interval;
}
int
rconn_connect(struct rconn *rc, const char *name)
{
rconn_disconnect(rc);
free(rc->name);
rc->name = xstrdup(name);
rc->reliable = true;
return reconnect(rc);
}
void
rconn_connect_unreliably(struct rconn *rc,
const char *name, struct vconn *vconn)
{
assert(vconn != NULL);
rconn_disconnect(rc);
free(rc->name);
rc->name = xstrdup(name);
rc->reliable = false;
rc->vconn = vconn;
rc->last_connected = time_now();
state_transition(rc, S_ACTIVE);
}
/* If 'rc' is connected, forces it to drop the connection and reconnect. */
void
rconn_reconnect(struct rconn *rc)
{
if (rc->state & (S_ACTIVE | S_IDLE)) {
disconnect(rc, 0);
}
}
void
rconn_disconnect(struct rconn *rc)
{
if (rc->state != S_VOID) {
if (rc->vconn) {
vconn_close(rc->vconn);
rc->vconn = NULL;
}
free(rc->name);
rc->name = xstrdup("void");
rc->reliable = false;
rc->backoff = 0;
rc->backoff_deadline = TIME_MIN;
state_transition(rc, S_VOID);
}
}
/* Disconnects 'rc' and frees the underlying storage. */
void
rconn_destroy(struct rconn *rc)
{
if (rc) {
size_t i;
free(rc->name);
vconn_close(rc->vconn);
flush_queue(rc);
queue_destroy(&rc->txq);
for (i = 0; i < rc->n_monitors; i++) {
vconn_close(rc->monitors[i]);
}
free(rc);
}
}
static unsigned int
timeout_VOID(const struct rconn *rc UNUSED)
{
return UINT_MAX;
}
static void
run_VOID(struct rconn *rc UNUSED)
{
/* Nothing to do. */
}
static int
reconnect(struct rconn *rc)
{
int retval;
VLOG_INFO("%s: connecting...", rc->name);
rc->n_attempted_connections++;
retval = vconn_open(rc->name, OFP_VERSION, &rc->vconn);
if (!retval) {
rc->backoff_deadline = time_now() + rc->backoff;
state_transition(rc, S_CONNECTING);
} else {
VLOG_WARN("%s: connection failed (%s)", rc->name, strerror(retval));
rc->backoff_deadline = TIME_MAX; /* Prevent resetting backoff. */
disconnect(rc, 0);
}
return retval;
}
static unsigned int
timeout_BACKOFF(const struct rconn *rc)
{
return rc->backoff;
}
static void
run_BACKOFF(struct rconn *rc)
{
if (timed_out(rc)) {
reconnect(rc);
}
}
static unsigned int
timeout_CONNECTING(const struct rconn *rc)
{
return MAX(1, rc->backoff);
}
static void
run_CONNECTING(struct rconn *rc)
{
int retval = vconn_connect(rc->vconn);
if (!retval) {
VLOG_INFO("%s: connected", rc->name);
rc->n_successful_connections++;
state_transition(rc, S_ACTIVE);
rc->last_connected = rc->state_entered;
} else if (retval != EAGAIN) {
VLOG_INFO("%s: connection failed (%s)", rc->name, strerror(retval));
disconnect(rc, retval);
} else if (timed_out(rc)) {
VLOG_INFO("%s: connection timed out", rc->name);
rc->backoff_deadline = TIME_MAX; /* Prevent resetting backoff. */
disconnect(rc, 0);
}
}
static void
do_tx_work(struct rconn *rc)
{
if (!rc->txq.n) {
return;
}
while (rc->txq.n > 0) {
int error = try_send(rc);
if (error) {
break;
}
}
if (!rc->txq.n) {
poll_immediate_wake();
}
}
static unsigned int
timeout_ACTIVE(const struct rconn *rc)
{
if (rc->probe_interval) {
unsigned int base = MAX(rc->last_received, rc->state_entered);
unsigned int arg = base + rc->probe_interval - rc->state_entered;
return arg;
}
return UINT_MAX;
}
static void
run_ACTIVE(struct rconn *rc)
{
if (timed_out(rc)) {
unsigned int base = MAX(rc->last_received, rc->state_entered);
VLOG_DBG("%s: idle %u seconds, sending inactivity probe",
rc->name, (unsigned int) (time_now() - base));
/* Ordering is important here: rconn_send() can transition to BACKOFF,
* and we don't want to transition back to IDLE if so, because then we
* can end up queuing a packet with vconn == NULL and then *boom*. */
state_transition(rc, S_IDLE);
rconn_send(rc, make_echo_request(), NULL);
return;
}
do_tx_work(rc);
}
static unsigned int
timeout_IDLE(const struct rconn *rc)
{
return rc->probe_interval;
}
static void
run_IDLE(struct rconn *rc)
{
if (timed_out(rc)) {
question_connectivity(rc);
VLOG_ERR("%s: no response to inactivity probe after %u "
"seconds, disconnecting",
rc->name, elapsed_in_this_state(rc));
disconnect(rc, 0);
} else {
do_tx_work(rc);
}
}
/* Performs whatever activities are necessary to maintain 'rc': if 'rc' is
* disconnected, attempts to (re)connect, backing off as necessary; if 'rc' is
* connected, attempts to send packets in the send queue, if any. */
void
rconn_run(struct rconn *rc)
{
int old_state;
do {
old_state = rc->state;
switch (rc->state) {
#define STATE(NAME, VALUE) case S_##NAME: run_##NAME(rc); break;
STATES
#undef STATE
default:
NOT_REACHED();
}
} while (rc->state != old_state);
}
/* Causes the next call to poll_block() to wake up when rconn_run() should be
* called on 'rc'. */
void
rconn_run_wait(struct rconn *rc)
{
unsigned int timeo = timeout(rc);
if (timeo != UINT_MAX) {
unsigned int expires = sat_add(rc->state_entered, timeo);
unsigned int remaining = sat_sub(expires, time_now());
poll_timer_wait(sat_mul(remaining, 1000));
}
if ((rc->state & (S_ACTIVE | S_IDLE)) && rc->txq.n) {
vconn_wait(rc->vconn, WAIT_SEND);
}
}
/* Attempts to receive a packet from 'rc'. If successful, returns the packet;
* otherwise, returns a null pointer. The caller is responsible for freeing
* the packet (with ofpbuf_delete()). */
struct ofpbuf *
rconn_recv(struct rconn *rc)
{
if (rc->state & (S_ACTIVE | S_IDLE)) {
struct ofpbuf *buffer;
int error = vconn_recv(rc->vconn, &buffer);
if (!error) {
copy_to_monitor(rc, buffer);
if (is_admitted_msg(buffer)
|| time_now() - rc->last_connected >= 30) {
rc->probably_admitted = true;
rc->last_admitted = time_now();
}
rc->last_received = time_now();
rc->packets_received++;
if (rc->state == S_IDLE) {
state_transition(rc, S_ACTIVE);
}
return buffer;
} else if (error != EAGAIN) {
disconnect(rc, error);
}
}
return NULL;
}
/* Causes the next call to poll_block() to wake up when a packet may be ready
* to be received by vconn_recv() on 'rc'. */
void
rconn_recv_wait(struct rconn *rc)
{
if (rc->vconn) {
vconn_wait(rc->vconn, WAIT_RECV);
}
}
/* Sends 'b' on 'rc'. Returns 0 if successful (in which case 'b' is
* destroyed), or ENOTCONN if 'rc' is not currently connected (in which case
* the caller retains ownership of 'b').
*
* If 'counter' is non-null, then 'counter' will be incremented while the
* packet is in flight, then decremented when it has been sent (or discarded
* due to disconnection). Because 'b' may be sent (or discarded) before this
* function returns, the caller may not be able to observe any change in
* 'counter'.
*
* There is no rconn_send_wait() function: an rconn has a send queue that it
* takes care of sending if you call rconn_run(), which will have the side
* effect of waking up poll_block(). */
int
rconn_send(struct rconn *rc, struct ofpbuf *b,
struct rconn_packet_counter *counter)
{
if (rconn_is_connected(rc)) {
COVERAGE_INC(rconn_queued);
copy_to_monitor(rc, b);
b->private = counter;
if (counter) {
rconn_packet_counter_inc(counter);
}
queue_push_tail(&rc->txq, b);
/* If the queue was empty before we added 'b', try to send some
* packets. (But if the queue had packets in it, it's because the
* vconn is backlogged and there's no point in stuffing more into it
* now. We'll get back to that in rconn_run().) */
if (rc->txq.n == 1) {
try_send(rc);
}
return 0;
} else {
return ENOTCONN;
}
}
/* Sends 'b' on 'rc'. Increments 'counter' while the packet is in flight; it
* will be decremented when it has been sent (or discarded due to
* disconnection). Returns 0 if successful, EAGAIN if 'counter->n' is already
* at least as large as 'queue_limit', or ENOTCONN if 'rc' is not currently
* connected. Regardless of return value, 'b' is destroyed.
*
* Because 'b' may be sent (or discarded) before this function returns, the
* caller may not be able to observe any change in 'counter'.
*
* There is no rconn_send_wait() function: an rconn has a send queue that it
* takes care of sending if you call rconn_run(), which will have the side
* effect of waking up poll_block(). */
int
rconn_send_with_limit(struct rconn *rc, struct ofpbuf *b,
struct rconn_packet_counter *counter, int queue_limit)
{
int retval;
retval = counter->n >= queue_limit ? EAGAIN : rconn_send(rc, b, counter);
if (retval) {
COVERAGE_INC(rconn_overflow);
ofpbuf_delete(b);
}
return retval;
}
/* Returns the total number of packets successfully sent on the underlying
* vconn. A packet is not counted as sent while it is still queued in the
* rconn, only when it has been successfuly passed to the vconn. */
unsigned int
rconn_packets_sent(const struct rconn *rc)
{
return rc->packets_sent;
}
/* Adds 'vconn' to 'rc' as a monitoring connection, to which all messages sent
* and received on 'rconn' will be copied. 'rc' takes ownership of 'vconn'. */
void
rconn_add_monitor(struct rconn *rc, struct vconn *vconn)
{
if (rc->n_monitors < ARRAY_SIZE(rc->monitors)) {
VLOG_INFO("new monitor connection from %s", vconn_get_name(vconn));
rc->monitors[rc->n_monitors++] = vconn;
} else {
VLOG_DBG("too many monitor connections, discarding %s",
vconn_get_name(vconn));
vconn_close(vconn);
}
}
/* Returns 'rc''s name (the 'name' argument passed to rconn_new()). */
const char *
rconn_get_name(const struct rconn *rc)
{
return rc->name;
}
/* Returns true if 'rconn' is connected or in the process of reconnecting,
* false if 'rconn' is disconnected and will not reconnect on its own. */
bool
rconn_is_alive(const struct rconn *rconn)
{
return rconn->state != S_VOID;
}
/* Returns true if 'rconn' is connected, false otherwise. */
bool
rconn_is_connected(const struct rconn *rconn)
{
return is_connected_state(rconn->state);
}
/* Returns 0 if 'rconn' is connected. Otherwise, if 'rconn' is in a "failure
* mode" (that is, it is not connected), returns the number of seconds that it
* has been in failure mode, ignoring any times that it connected but the
* controller's admission control policy caused it to be quickly
* disconnected. */
int
rconn_failure_duration(const struct rconn *rconn)
{
return rconn_is_connected(rconn) ? 0 : time_now() - rconn->last_admitted;
}
/* Returns the IP address of the peer, or 0 if the peer is not connected over
* an IP-based protocol or if its IP address is not known. */
uint32_t
rconn_get_ip(const struct rconn *rconn)
{
return rconn->vconn ? vconn_get_ip(rconn->vconn) : 0;
}
/* If 'rconn' can't connect to the peer, it could be for any number of reasons.
* Usually, one would assume it is because the peer is not running or because
* the network is partitioned. But it could also be because the network
* topology has changed, in which case the upper layer will need to reassess it
* (in particular, obtain a new IP address via DHCP and find the new location
* of the controller). When this appears that this might be the case, this
* function returns true. It also clears the questionability flag and prevents
* it from being set again for some time. */
bool
rconn_is_connectivity_questionable(struct rconn *rconn)
{
bool questionable = rconn->questionable_connectivity;
rconn->questionable_connectivity = false;
return questionable;
}
/* Returns the total number of packets successfully received by the underlying
* vconn. */
unsigned int
rconn_packets_received(const struct rconn *rc)
{
return rc->packets_received;
}
/* Returns a string representing the internal state of 'rc'. The caller must
* not modify or free the string. */
const char *
rconn_get_state(const struct rconn *rc)
{
return state_name(rc->state);
}
/* Returns the number of connection attempts made by 'rc', including any
* ongoing attempt that has not yet succeeded or failed. */
unsigned int
rconn_get_attempted_connections(const struct rconn *rc)
{
return rc->n_attempted_connections;
}
/* Returns the number of successful connection attempts made by 'rc'. */
unsigned int
rconn_get_successful_connections(const struct rconn *rc)
{
return rc->n_successful_connections;
}
/* Returns the time at which the last successful connection was made by
* 'rc'. */
time_t
rconn_get_last_connection(const struct rconn *rc)
{
return rc->last_connected;
}
/* Returns the time at which 'rc' was created. */
time_t
rconn_get_creation_time(const struct rconn *rc)
{
return rc->creation_time;
}
/* Returns the approximate number of seconds that 'rc' has been connected. */
unsigned long int
rconn_get_total_time_connected(const struct rconn *rc)
{
return (rc->total_time_connected
+ (rconn_is_connected(rc) ? elapsed_in_this_state(rc) : 0));
}
/* Returns the current amount of backoff, in seconds. This is the amount of
* time after which the rconn will transition from BACKOFF to CONNECTING. */
int
rconn_get_backoff(const struct rconn *rc)
{
return rc->backoff;
}
/* Returns the number of seconds spent in this state so far. */
unsigned int
rconn_get_state_elapsed(const struct rconn *rc)
{
return elapsed_in_this_state(rc);
}
/* Returns 'rc''s current connection sequence number, a number that changes
* every time that 'rconn' connects or disconnects. */
unsigned int
rconn_get_connection_seqno(const struct rconn *rc)
{
return rc->seqno;
}
struct rconn_packet_counter *
rconn_packet_counter_create(void)
{
struct rconn_packet_counter *c = xmalloc(sizeof *c);
c->n = 0;
c->ref_cnt = 1;
return c;
}
void
rconn_packet_counter_destroy(struct rconn_packet_counter *c)
{
if (c) {
assert(c->ref_cnt > 0);
if (!--c->ref_cnt && !c->n) {
free(c);
}
}
}
void
rconn_packet_counter_inc(struct rconn_packet_counter *c)
{
c->n++;
}
void
rconn_packet_counter_dec(struct rconn_packet_counter *c)
{
assert(c->n > 0);
if (!--c->n && !c->ref_cnt) {
free(c);
}
}
/* Tries to send a packet from 'rc''s send buffer. Returns 0 if successful,
* otherwise a positive errno value. */
static int
try_send(struct rconn *rc)
{
int retval = 0;
struct ofpbuf *next = rc->txq.head->next;
struct rconn_packet_counter *counter = rc->txq.head->private;
retval = vconn_send(rc->vconn, rc->txq.head);
if (retval) {
if (retval != EAGAIN) {
disconnect(rc, retval);
}
return retval;
}
COVERAGE_INC(rconn_sent);
rc->packets_sent++;
if (counter) {
rconn_packet_counter_dec(counter);
}
queue_advance_head(&rc->txq, next);
return 0;
}
/* Disconnects 'rc'. 'error' is used only for logging purposes. If it is
* nonzero, then it should be EOF to indicate the connection was closed by the
* peer in a normal fashion or a positive errno value. */
static void
disconnect(struct rconn *rc, int error)
{
if (rc->reliable) {
time_t now = time_now();
if (rc->state & (S_CONNECTING | S_ACTIVE | S_IDLE)) {
if (error > 0) {
VLOG_WARN("%s: connection dropped (%s)",
rc->name, strerror(error));
} else if (error == EOF) {
if (rc->reliable) {
VLOG_INFO("%s: connection closed by peer", rc->name);
}
} else {
VLOG_INFO("%s: connection dropped", rc->name);
}
vconn_close(rc->vconn);
rc->vconn = NULL;
flush_queue(rc);
}
if (now >= rc->backoff_deadline) {
rc->backoff = 1;
} else {
rc->backoff = MIN(rc->max_backoff, MAX(1, 2 * rc->backoff));
VLOG_INFO("%s: waiting %d seconds before reconnect\n",
rc->name, rc->backoff);
}
rc->backoff_deadline = now + rc->backoff;
state_transition(rc, S_BACKOFF);
if (now - rc->last_connected > 60) {
question_connectivity(rc);
}
} else {
rconn_disconnect(rc);
}
}
/* Drops all the packets from 'rc''s send queue and decrements their queue
* counts. */
static void
flush_queue(struct rconn *rc)
{
if (!rc->txq.n) {
return;
}
while (rc->txq.n > 0) {
struct ofpbuf *b = queue_pop_head(&rc->txq);
struct rconn_packet_counter *counter = b->private;
if (counter) {
rconn_packet_counter_dec(counter);
}
COVERAGE_INC(rconn_discarded);
ofpbuf_delete(b);
}
poll_immediate_wake();
}
static unsigned int
elapsed_in_this_state(const struct rconn *rc)
{
return time_now() - rc->state_entered;
}
static unsigned int
timeout(const struct rconn *rc)
{
switch (rc->state) {
#define STATE(NAME, VALUE) case S_##NAME: return timeout_##NAME(rc);
STATES
#undef STATE
default:
NOT_REACHED();
}
}
static bool
timed_out(const struct rconn *rc)
{
return time_now() >= sat_add(rc->state_entered, timeout(rc));
}
static void
state_transition(struct rconn *rc, enum state state)
{
rc->seqno += (rc->state == S_ACTIVE) != (state == S_ACTIVE);
if (is_connected_state(state) && !is_connected_state(rc->state)) {
rc->probably_admitted = false;
}
if (rconn_is_connected(rc)) {
rc->total_time_connected += elapsed_in_this_state(rc);
}
VLOG_DBG("%s: entering %s", rc->name, state_name(state));
rc->state = state;
rc->state_entered = time_now();
}
static void
question_connectivity(struct rconn *rc)
{
time_t now = time_now();
if (now - rc->last_questioned > 60) {
rc->questionable_connectivity = true;
rc->last_questioned = now;
}
}
static void
copy_to_monitor(struct rconn *rc, const struct ofpbuf *b)
{
struct ofpbuf *clone = NULL;
int retval;
size_t i;
for (i = 0; i < rc->n_monitors; ) {
struct vconn *vconn = rc->monitors[i];
if (!clone) {
clone = ofpbuf_clone(b);
}
retval = vconn_send(vconn, clone);
if (!retval) {
clone = NULL;
} else if (retval != EAGAIN) {
VLOG_DBG("%s: closing monitor connection to %s: %s",
rconn_get_name(rc), vconn_get_name(vconn),
strerror(retval));
rc->monitors[i] = rc->monitors[--rc->n_monitors];
continue;
}
i++;
}
ofpbuf_delete(clone);
}
static bool
is_connected_state(enum state state)
{
return (state & (S_ACTIVE | S_IDLE)) != 0;
}
static bool
is_admitted_msg(const struct ofpbuf *b)
{
struct ofp_header *oh = b->data;
uint8_t type = oh->type;
return !(type < 32
&& (1u << type) & ((1u << OFPT_HELLO) |
(1u << OFPT_ERROR) |
(1u << OFPT_ECHO_REQUEST) |
(1u << OFPT_ECHO_REPLY) |
(1u << OFPT_VENDOR) |
(1u << OFPT_FEATURES_REQUEST) |
(1u << OFPT_FEATURES_REPLY) |
(1u << OFPT_GET_CONFIG_REQUEST) |
(1u << OFPT_GET_CONFIG_REPLY) |
(1u << OFPT_SET_CONFIG)));
}
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