mirrors/tor
1
0
Fork 0
mirror of https://gitlab.torproject.org/tpo/core/tor.git synced 2025-02-27 16:45:53 +01:00
Code Issues Projects Releases Wiki Activity
tor/src/core/mainloop/mainloop.c
Nick Mathewson a49f506e05 Split all controller events code into a new control_events.c 
Also, split the formatting code shared by control.c and
control_events.c into controller_fmt.c.
2019-03-25 12:11:59 -04:00

3051 lines
98 KiB
C
Raw Blame History

/* Copyright (c) 2001 Matej Pfajfar.
* Copyright (c) 2001-2004, Roger Dingledine.
* Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
* Copyright (c) 2007-2019, The Tor Project, Inc. */
/* See LICENSE for licensing information */
/**
* \file mainloop.c
* \brief Toplevel module. Handles signals, multiplexes between
* connections, implements main loop, and drives scheduled events.
*
* For the main loop itself; see run_main_loop_once(). It invokes the rest of
* Tor mostly through Libevent callbacks. Libevent callbacks can happen when
* a timer elapses, a signal is received, a socket is ready to read or write,
* or an event is manually activated.
*
* Most events in Tor are driven from these callbacks:
* <ul>
* <li>conn_read_callback() and conn_write_callback() here, which are
* invoked when a socket is ready to read or write respectively.
* <li>signal_callback(), which handles incoming signals.
* </ul>
* Other events are used for specific purposes, or for building more complex
* control structures. If you search for usage of tor_libevent_new(), you
* will find all the events that we construct in Tor.
*
* Tor has numerous housekeeping operations that need to happen
* regularly. They are handled in different ways:
* <ul>
* <li>The most frequent operations are handled after every read or write
* event, at the end of connection_handle_read() and
* connection_handle_write().
*
* <li>The next most frequent operations happen after each invocation of the
* main loop, in run_main_loop_once().
*
* <li>Once per second, we run all of the operations listed in
* second_elapsed_callback(), and in its child, run_scheduled_events().
*
* <li>Once-a-second operations are handled in second_elapsed_callback().
*
* <li>More infrequent operations take place based on the periodic event
* driver in periodic.c . These are stored in the periodic_events[]
* table.
* </ul>
*
**/
#define MAINLOOP_PRIVATE
#include "core/or/or.h"
#include "app/config/config.h"
#include "app/config/statefile.h"
#include "app/main/ntmain.h"
#include "core/mainloop/connection.h"
#include "core/mainloop/cpuworker.h"
#include "core/mainloop/mainloop.h"
#include "core/mainloop/netstatus.h"
#include "core/mainloop/periodic.h"
#include "core/or/channel.h"
#include "core/or/channelpadding.h"
#include "core/or/channeltls.h"
#include "core/or/circuitbuild.h"
#include "core/or/circuitlist.h"
#include "core/or/circuituse.h"
#include "core/or/connection_edge.h"
#include "core/or/connection_or.h"
#include "core/or/dos.h"
#include "core/or/status.h"
#include "feature/client/addressmap.h"
#include "feature/client/bridges.h"
#include "feature/client/dnsserv.h"
#include "feature/client/entrynodes.h"
#include "feature/client/transports.h"
#include "feature/control/control.h"
#include "feature/control/control_events.h"
#include "feature/dirauth/authmode.h"
#include "feature/dirauth/reachability.h"
#include "feature/dircache/consdiffmgr.h"
#include "feature/dircache/dirserv.h"
#include "feature/dircommon/directory.h"
#include "feature/hibernate/hibernate.h"
#include "feature/hs/hs_cache.h"
#include "feature/hs/hs_client.h"
#include "feature/hs/hs_service.h"
#include "feature/nodelist/microdesc.h"
#include "feature/nodelist/networkstatus.h"
#include "feature/nodelist/nodelist.h"
#include "feature/nodelist/routerlist.h"
#include "feature/relay/dns.h"
#include "feature/relay/routerkeys.h"
#include "feature/relay/routermode.h"
#include "feature/relay/selftest.h"
#include "feature/rend/rendcache.h"
#include "feature/rend/rendservice.h"
#include "feature/stats/geoip_stats.h"
#include "feature/stats/predict_ports.h"
#include "feature/stats/rephist.h"
#include "lib/buf/buffers.h"
#include "lib/crypt_ops/crypto_rand.h"
#include "lib/err/backtrace.h"
#include "lib/tls/buffers_tls.h"
#include "lib/net/buffers_net.h"
#include "lib/evloop/compat_libevent.h"
#include <event2/event.h>
#include "feature/dirauth/dirvote.h"
#include "feature/dirauth/authmode.h"
#include "core/or/cell_st.h"
#include "core/or/entry_connection_st.h"
#include "feature/nodelist/networkstatus_st.h"
#include "core/or/or_connection_st.h"
#include "app/config/or_state_st.h"
#include "feature/nodelist/routerinfo_st.h"
#include "core/or/socks_request_st.h"
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#ifdef HAVE_SYSTEMD
# if defined(__COVERITY__) && !defined(__INCLUDE_LEVEL__)
/* Systemd's use of gcc's __INCLUDE_LEVEL__ extension macro appears to confuse
* Coverity. Here's a kludge to unconfuse it.
*/
# define __INCLUDE_LEVEL__ 2
#endif /* defined(__COVERITY__) && !defined(__INCLUDE_LEVEL__) */
#include <systemd/sd-daemon.h>
#endif /* defined(HAVE_SYSTEMD) */
/* Token bucket for all traffic. */
token_bucket_rw_t global_bucket;
/* Token bucket for relayed traffic. */
token_bucket_rw_t global_relayed_bucket;
/* XXX we might want to keep stats about global_relayed_*_bucket too. Or not.*/
/** How many bytes have we read since we started the process? */
static uint64_t stats_n_bytes_read = 0;
/** How many bytes have we written since we started the process? */
static uint64_t stats_n_bytes_written = 0;
/** What time did this process start up? */
time_t time_of_process_start = 0;
/** How many seconds have we been running? */
static long stats_n_seconds_working = 0;
/** How many times have we returned from the main loop successfully? */
static uint64_t stats_n_main_loop_successes = 0;
/** How many times have we received an error from the main loop? */
static uint64_t stats_n_main_loop_errors = 0;
/** How many times have we returned from the main loop with no events. */
static uint64_t stats_n_main_loop_idle = 0;
/** How often will we honor SIGNEWNYM requests? */
#define MAX_SIGNEWNYM_RATE 10
/** When did we last process a SIGNEWNYM request? */
static time_t time_of_last_signewnym = 0;
/** Is there a signewnym request we're currently waiting to handle? */
static int signewnym_is_pending = 0;
/** Mainloop event for the deferred signewnym call. */
static mainloop_event_t *handle_deferred_signewnym_ev = NULL;
/** How many times have we called newnym? */
static unsigned newnym_epoch = 0;
/** Smartlist of all open connections. */
STATIC smartlist_t *connection_array = NULL;
/** List of connections that have been marked for close and need to be freed
* and removed from connection_array. */
static smartlist_t *closeable_connection_lst = NULL;
/** List of linked connections that are currently reading data into their
* inbuf from their partner's outbuf. */
static smartlist_t *active_linked_connection_lst = NULL;
/** Flag: Set to true iff we entered the current libevent main loop via
* <b>loop_once</b>. If so, there's no need to trigger a loopexit in order
* to handle linked connections. */
static int called_loop_once = 0;
/** Flag: if true, it's time to shut down, so the main loop should exit as
* soon as possible.
*/
static int main_loop_should_exit = 0;
/** The return value that the main loop should yield when it exits, if
* main_loop_should_exit is true.
*/
static int main_loop_exit_value = 0;
/** We set this to 1 when we've opened a circuit, so we can print a log
* entry to inform the user that Tor is working. We set it to 0 when
* we think the fact that we once opened a circuit doesn't mean we can do so
* any longer (a big time jump happened, when we notice our directory is
* heinously out-of-date, etc.
*/
static int can_complete_circuits = 0;
/** How often do we check for router descriptors that we should download
* when we have too little directory info? */
#define GREEDY_DESCRIPTOR_RETRY_INTERVAL (10)
/** How often do we check for router descriptors that we should download
* when we have enough directory info? */
#define LAZY_DESCRIPTOR_RETRY_INTERVAL (60)
static int conn_close_if_marked(int i);
static void connection_start_reading_from_linked_conn(connection_t *conn);
static int connection_should_read_from_linked_conn(connection_t *conn);
static void conn_read_callback(evutil_socket_t fd, short event, void *_conn);
static void conn_write_callback(evutil_socket_t fd, short event, void *_conn);
static void shutdown_did_not_work_callback(evutil_socket_t fd, short event,
void *arg) ATTR_NORETURN;
/****************************************************************************
*
* This section contains accessors and other methods on the connection_array
* variables (which are global within this file and unavailable outside it).
*
****************************************************************************/
/** Return 1 if we have successfully built a circuit, and nothing has changed
* to make us think that maybe we can't.
*/
int
have_completed_a_circuit(void)
{
return can_complete_circuits;
}
/** Note that we have successfully built a circuit, so that reachability
* testing and introduction points and so on may be attempted. */
void
note_that_we_completed_a_circuit(void)
{
can_complete_circuits = 1;
}
/** Note that something has happened (like a clock jump, or DisableNetwork) to
* make us think that maybe we can't complete circuits. */
void
note_that_we_maybe_cant_complete_circuits(void)
{
can_complete_circuits = 0;
}
/** Add <b>conn</b> to the array of connections that we can poll on. The
* connection's socket must be set; the connection starts out
* non-reading and non-writing.
*/
int
connection_add_impl(connection_t *conn, int is_connecting)
{
tor_assert(conn);
tor_assert(SOCKET_OK(conn->s) ||
conn->linked ||
(conn->type == CONN_TYPE_AP &&
TO_EDGE_CONN(conn)->is_dns_request));
tor_assert(conn->conn_array_index == -1); /* can only connection_add once */
conn->conn_array_index = smartlist_len(connection_array);
smartlist_add(connection_array, conn);
(void) is_connecting;
if (SOCKET_OK(conn->s) || conn->linked) {
conn->read_event = tor_event_new(tor_libevent_get_base(),
conn->s, EV_READ|EV_PERSIST, conn_read_callback, conn);
conn->write_event = tor_event_new(tor_libevent_get_base(),
conn->s, EV_WRITE|EV_PERSIST, conn_write_callback, conn);
/* XXXX CHECK FOR NULL RETURN! */
}
log_debug(LD_NET,"new conn type %s, socket %d, address %s, n_conns %d.",
conn_type_to_string(conn->type), (int)conn->s, conn->address,
smartlist_len(connection_array));
return 0;
}
/** Tell libevent that we don't care about <b>conn</b> any more. */
void
connection_unregister_events(connection_t *conn)
{
if (conn->read_event) {
if (event_del(conn->read_event))
log_warn(LD_BUG, "Error removing read event for %d", (int)conn->s);
tor_free(conn->read_event);
}
if (conn->write_event) {
if (event_del(conn->write_event))
log_warn(LD_BUG, "Error removing write event for %d", (int)conn->s);
tor_free(conn->write_event);
}
if (conn->type == CONN_TYPE_AP_DNS_LISTENER) {
dnsserv_close_listener(conn);
}
}
/** Remove the connection from the global list, and remove the
* corresponding poll entry. Calling this function will shift the last
* connection (if any) into the position occupied by conn.
*/
int
connection_remove(connection_t *conn)
{
int current_index;
connection_t *tmp;
tor_assert(conn);
log_debug(LD_NET,"removing socket %d (type %s), n_conns now %d",
(int)conn->s, conn_type_to_string(conn->type),
smartlist_len(connection_array));
if (conn->type == CONN_TYPE_AP && conn->socket_family == AF_UNIX) {
log_info(LD_NET, "Closing SOCKS Unix socket connection");
}
control_event_conn_bandwidth(conn);
tor_assert(conn->conn_array_index >= 0);
current_index = conn->conn_array_index;
connection_unregister_events(conn); /* This is redundant, but cheap. */
if (current_index == smartlist_len(connection_array)-1) { /* at the end */
smartlist_del(connection_array, current_index);
return 0;
}
/* replace this one with the one at the end */
smartlist_del(connection_array, current_index);
tmp = smartlist_get(connection_array, current_index);
tmp->conn_array_index = current_index;
return 0;
}
/** If <b>conn</b> is an edge conn, remove it from the list
* of conn's on this circuit. If it's not on an edge,
* flush and send destroys for all circuits on this conn.
*
* Remove it from connection_array (if applicable) and
* from closeable_connection_list.
*
* Then free it.
*/
static void
connection_unlink(connection_t *conn)
{
connection_about_to_close_connection(conn);
if (conn->conn_array_index >= 0) {
connection_remove(conn);
}
if (conn->linked_conn) {
conn->linked_conn->linked_conn = NULL;
if (! conn->linked_conn->marked_for_close &&
conn->linked_conn->reading_from_linked_conn)
connection_start_reading(conn->linked_conn);
conn->linked_conn = NULL;
}
smartlist_remove(closeable_connection_lst, conn);
smartlist_remove(active_linked_connection_lst, conn);
if (conn->type == CONN_TYPE_EXIT) {
assert_connection_edge_not_dns_pending(TO_EDGE_CONN(conn));
}
if (conn->type == CONN_TYPE_OR) {
if (!tor_digest_is_zero(TO_OR_CONN(conn)->identity_digest))
connection_or_clear_identity(TO_OR_CONN(conn));
/* connection_unlink() can only get called if the connection
* was already on the closeable list, and it got there by
* connection_mark_for_close(), which was called from
* connection_or_close_normally() or
* connection_or_close_for_error(), so the channel should
* already be in CHANNEL_STATE_CLOSING, and then the
* connection_about_to_close_connection() goes to
* connection_or_about_to_close(), which calls channel_closed()
* to notify the channel_t layer, and closed the channel, so
* nothing more to do here to deal with the channel associated
* with an orconn.
*/
}
connection_free(conn);
}
/** Event that invokes schedule_active_linked_connections_cb. */
static mainloop_event_t *schedule_active_linked_connections_event = NULL;
/**
* Callback: used to activate read events for all linked connections, so
* libevent knows to call their read callbacks. This callback run as a
* postloop event, so that the events _it_ activates don't happen until
* Libevent has a chance to check for other events.
*/
static void
schedule_active_linked_connections_cb(mainloop_event_t *event, void *arg)
{
(void)event;
(void)arg;
/* All active linked conns should get their read events activated,
* so that libevent knows to run their callbacks. */
SMARTLIST_FOREACH(active_linked_connection_lst, connection_t *, conn,
event_active(conn->read_event, EV_READ, 1));
/* Reactivate the event if we still have connections in the active list.
*
* A linked connection doesn't get woken up by I/O but rather artificially
* by this event callback. It has directory data spooled in it and it is
* sent incrementally by small chunks unless spool_eagerly is true. For that
* to happen, we need to induce the activation of the read event so it can
* be flushed. */
if (smartlist_len(active_linked_connection_lst)) {
mainloop_event_activate(schedule_active_linked_connections_event);
}
}
/** Initialize the global connection list, closeable connection list,
* and active connection list. */
void
tor_init_connection_lists(void)
{
if (!connection_array)
connection_array = smartlist_new();
if (!closeable_connection_lst)
closeable_connection_lst = smartlist_new();
if (!active_linked_connection_lst)
active_linked_connection_lst = smartlist_new();
}
/** Schedule <b>conn</b> to be closed. **/
void
add_connection_to_closeable_list(connection_t *conn)
{
tor_assert(!smartlist_contains(closeable_connection_lst, conn));
tor_assert(conn->marked_for_close);
assert_connection_ok(conn, time(NULL));
smartlist_add(closeable_connection_lst, conn);
mainloop_schedule_postloop_cleanup();
}
/** Return 1 if conn is on the closeable list, else return 0. */
int
connection_is_on_closeable_list(connection_t *conn)
{
return smartlist_contains(closeable_connection_lst, conn);
}
/** Return true iff conn is in the current poll array. */
int
connection_in_array(connection_t *conn)
{
return smartlist_contains(connection_array, conn);
}
/** Set <b>*array</b> to an array of all connections. <b>*array</b> must not
* be modified.
*/
MOCK_IMPL(smartlist_t *,
get_connection_array, (void))
{
if (!connection_array)
connection_array = smartlist_new();
return connection_array;
}
/**
* Return the amount of network traffic read, in bytes, over the life of this
* process.
*/
MOCK_IMPL(uint64_t,
get_bytes_read,(void))
{
return stats_n_bytes_read;
}
/**
* Return the amount of network traffic read, in bytes, over the life of this
* process.
*/
MOCK_IMPL(uint64_t,
get_bytes_written,(void))
{
return stats_n_bytes_written;
}
/**
* Increment the amount of network traffic read and written, over the life of
* this process.
*/
void
stats_increment_bytes_read_and_written(uint64_t r, uint64_t w)
{
stats_n_bytes_read += r;
stats_n_bytes_written += w;
}
/** Set the event mask on <b>conn</b> to <b>events</b>. (The event
* mask is a bitmask whose bits are READ_EVENT and WRITE_EVENT)
*/
void
connection_watch_events(connection_t *conn, watchable_events_t events)
{
if (events & READ_EVENT)
connection_start_reading(conn);
else
connection_stop_reading(conn);
if (events & WRITE_EVENT)
connection_start_writing(conn);
else
connection_stop_writing(conn);
}
/** Return true iff <b>conn</b> is listening for read events. */
int
connection_is_reading(connection_t *conn)
{
tor_assert(conn);
return conn->reading_from_linked_conn ||
(conn->read_event && event_pending(conn->read_event, EV_READ, NULL));
}
/** Reset our main loop counters. */
void
reset_main_loop_counters(void)
{
stats_n_main_loop_successes = 0;
stats_n_main_loop_errors = 0;
stats_n_main_loop_idle = 0;
}
/** Increment the main loop success counter. */
static void
increment_main_loop_success_count(void)
{
++stats_n_main_loop_successes;
}
/** Get the main loop success counter. */
uint64_t
get_main_loop_success_count(void)
{
return stats_n_main_loop_successes;
}
/** Increment the main loop error counter. */
static void
increment_main_loop_error_count(void)
{
++stats_n_main_loop_errors;
}
/** Get the main loop error counter. */
uint64_t
get_main_loop_error_count(void)
{
return stats_n_main_loop_errors;
}
/** Increment the main loop idle counter. */
static void
increment_main_loop_idle_count(void)
{
++stats_n_main_loop_idle;
}
/** Get the main loop idle counter. */
uint64_t
get_main_loop_idle_count(void)
{
return stats_n_main_loop_idle;
}
/** Check whether <b>conn</b> is correct in having (or not having) a
* read/write event (passed in <b>ev</b>). On success, return 0. On failure,
* log a warning and return -1. */
static int
connection_check_event(connection_t *conn, struct event *ev)
{
int bad;
if (conn->type == CONN_TYPE_AP && TO_EDGE_CONN(conn)->is_dns_request) {
/* DNS requests which we launch through the dnsserv.c module do not have
* any underlying socket or any underlying linked connection, so they
* shouldn't have any attached events either.
*/
bad = ev != NULL;
} else {
/* Everything else should have an underlying socket, or a linked
* connection (which is also tracked with a read_event/write_event pair).
*/
bad = ev == NULL;
}
if (bad) {
log_warn(LD_BUG, "Event missing on connection %p [%s;%s]. "
"socket=%d. linked=%d. "
"is_dns_request=%d. Marked_for_close=%s:%d",
conn,
conn_type_to_string(conn->type),
conn_state_to_string(conn->type, conn->state),
(int)conn->s, (int)conn->linked,
(conn->type == CONN_TYPE_AP &&
TO_EDGE_CONN(conn)->is_dns_request),
conn->marked_for_close_file ? conn->marked_for_close_file : "-",
conn->marked_for_close
);
log_backtrace(LOG_WARN, LD_BUG, "Backtrace attached.");
return -1;
}
return 0;
}
/** Tell the main loop to stop notifying <b>conn</b> of any read events. */
MOCK_IMPL(void,
connection_stop_reading,(connection_t *conn))
{
tor_assert(conn);
if (connection_check_event(conn, conn->read_event) < 0) {
return;
}
if (conn->linked) {
conn->reading_from_linked_conn = 0;
connection_stop_reading_from_linked_conn(conn);
} else {
if (event_del(conn->read_event))
log_warn(LD_NET, "Error from libevent setting read event state for %d "
"to unwatched: %s",
(int)conn->s,
tor_socket_strerror(tor_socket_errno(conn->s)));
}
}
/** Tell the main loop to start notifying <b>conn</b> of any read events. */
MOCK_IMPL(void,
connection_start_reading,(connection_t *conn))
{
tor_assert(conn);
if (connection_check_event(conn, conn->read_event) < 0) {
return;
}
if (conn->linked) {
conn->reading_from_linked_conn = 1;
if (connection_should_read_from_linked_conn(conn))
connection_start_reading_from_linked_conn(conn);
} else {
if (event_add(conn->read_event, NULL))
log_warn(LD_NET, "Error from libevent setting read event state for %d "
"to watched: %s",
(int)conn->s,
tor_socket_strerror(tor_socket_errno(conn->s)));
}
}
/** Return true iff <b>conn</b> is listening for write events. */
int
connection_is_writing(connection_t *conn)
{
tor_assert(conn);
return conn->writing_to_linked_conn ||
(conn->write_event && event_pending(conn->write_event, EV_WRITE, NULL));
}
/** Tell the main loop to stop notifying <b>conn</b> of any write events. */
MOCK_IMPL(void,
connection_stop_writing,(connection_t *conn))
{
tor_assert(conn);
if (connection_check_event(conn, conn->write_event) < 0) {
return;
}
if (conn->linked) {
conn->writing_to_linked_conn = 0;
if (conn->linked_conn)
connection_stop_reading_from_linked_conn(conn->linked_conn);
} else {
if (event_del(conn->write_event))
log_warn(LD_NET, "Error from libevent setting write event state for %d "
"to unwatched: %s",
(int)conn->s,
tor_socket_strerror(tor_socket_errno(conn->s)));
}
}
/** Tell the main loop to start notifying <b>conn</b> of any write events. */
MOCK_IMPL(void,
connection_start_writing,(connection_t *conn))
{
tor_assert(conn);
if (connection_check_event(conn, conn->write_event) < 0) {
return;
}
if (conn->linked) {
conn->writing_to_linked_conn = 1;
if (conn->linked_conn &&
connection_should_read_from_linked_conn(conn->linked_conn))
connection_start_reading_from_linked_conn(conn->linked_conn);
} else {
if (event_add(conn->write_event, NULL))
log_warn(LD_NET, "Error from libevent setting write event state for %d "
"to watched: %s",
(int)conn->s,
tor_socket_strerror(tor_socket_errno(conn->s)));
}
}
/** Return true iff <b>conn</b> is linked conn, and reading from the conn
* linked to it would be good and feasible. (Reading is "feasible" if the
* other conn exists and has data in its outbuf, and is "good" if we have our
* reading_from_linked_conn flag set and the other conn has its
* writing_to_linked_conn flag set.)*/
static int
connection_should_read_from_linked_conn(connection_t *conn)
{
if (conn->linked && conn->reading_from_linked_conn) {
if (! conn->linked_conn ||
(conn->linked_conn->writing_to_linked_conn &&
buf_datalen(conn->linked_conn->outbuf)))
return 1;
}
return 0;
}
/** Event to run 'shutdown did not work callback'. */
static struct event *shutdown_did_not_work_event = NULL;
/** Failsafe measure that should never actually be necessary: If
* tor_shutdown_event_loop_and_exit() somehow doesn't successfully exit the
* event loop, then this callback will kill Tor with an assertion failure
* seconds later
*/
static void
shutdown_did_not_work_callback(evutil_socket_t fd, short event, void *arg)
{
// LCOV_EXCL_START
(void) fd;
(void) event;
(void) arg;
tor_assert_unreached();
// LCOV_EXCL_STOP
}
#ifdef ENABLE_RESTART_DEBUGGING
static struct event *tor_shutdown_event_loop_for_restart_event = NULL;
static void
tor_shutdown_event_loop_for_restart_cb(
evutil_socket_t fd, short event, void *arg)
{
(void)fd;
(void)event;
(void)arg;
tor_event_free(tor_shutdown_event_loop_for_restart_event);
tor_shutdown_event_loop_and_exit(0);
}
#endif
/**
* After finishing the current callback (if any), shut down the main loop,
* clean up the process, and exit with <b>exitcode</b>.
*/
void
tor_shutdown_event_loop_and_exit(int exitcode)
{
if (main_loop_should_exit)
return; /* Ignore multiple calls to this function. */
main_loop_should_exit = 1;
main_loop_exit_value = exitcode;
/* Die with an assertion failure in ten seconds, if for some reason we don't
* exit normally. */
/* XXXX We should consider this code if it's never used. */
struct timeval ten_seconds = { 10, 0 };
shutdown_did_not_work_event = tor_evtimer_new(
tor_libevent_get_base(),
shutdown_did_not_work_callback, NULL);
event_add(shutdown_did_not_work_event, &ten_seconds);
/* Unlike exit_loop_after_delay(), exit_loop_after_callback
* prevents other callbacks from running. */
tor_libevent_exit_loop_after_callback(tor_libevent_get_base());
}
/** Return true iff tor_shutdown_event_loop_and_exit() has been called. */
int
tor_event_loop_shutdown_is_pending(void)
{
return main_loop_should_exit;
}
/** Helper: Tell the main loop to begin reading bytes into <b>conn</b> from
* its linked connection, if it is not doing so already. Called by
* connection_start_reading and connection_start_writing as appropriate. */
static void
connection_start_reading_from_linked_conn(connection_t *conn)
{
tor_assert(conn);
tor_assert(conn->linked == 1);
if (!conn->active_on_link) {
conn->active_on_link = 1;
smartlist_add(active_linked_connection_lst, conn);
mainloop_event_activate(schedule_active_linked_connections_event);
} else {
tor_assert(smartlist_contains(active_linked_connection_lst, conn));
}
}
/** Tell the main loop to stop reading bytes into <b>conn</b> from its linked
* connection, if is currently doing so. Called by connection_stop_reading,
* connection_stop_writing, and connection_read. */
void
connection_stop_reading_from_linked_conn(connection_t *conn)
{
tor_assert(conn);
tor_assert(conn->linked == 1);
if (conn->active_on_link) {
conn->active_on_link = 0;
/* FFFF We could keep an index here so we can smartlist_del
* cleanly. On the other hand, this doesn't show up on profiles,
* so let's leave it alone for now. */
smartlist_remove(active_linked_connection_lst, conn);
} else {
tor_assert(!smartlist_contains(active_linked_connection_lst, conn));
}
}
/** Close all connections that have been scheduled to get closed. */
STATIC void
close_closeable_connections(void)
{
int i;
for (i = 0; i < smartlist_len(closeable_connection_lst); ) {
connection_t *conn = smartlist_get(closeable_connection_lst, i);
if (conn->conn_array_index < 0) {
connection_unlink(conn); /* blow it away right now */
} else {
if (!conn_close_if_marked(conn->conn_array_index))
++i;
}
}
}
/** Count moribund connections for the OOS handler */
MOCK_IMPL(int,
connection_count_moribund, (void))
{
int moribund = 0;
/*
* Count things we'll try to kill when close_closeable_connections()
* runs next.
*/
SMARTLIST_FOREACH_BEGIN(closeable_connection_lst, connection_t *, conn) {
if (SOCKET_OK(conn->s) && connection_is_moribund(conn)) ++moribund;
} SMARTLIST_FOREACH_END(conn);
return moribund;
}
/** Libevent callback: this gets invoked when (connection_t*)<b>conn</b> has
* some data to read. */
static void
conn_read_callback(evutil_socket_t fd, short event, void *_conn)
{
connection_t *conn = _conn;
(void)fd;
(void)event;
log_debug(LD_NET,"socket %d wants to read.",(int)conn->s);
/* assert_connection_ok(conn, time(NULL)); */
if (connection_handle_read(conn) < 0) {
if (!conn->marked_for_close) {
#ifndef _WIN32
log_warn(LD_BUG,"Unhandled error on read for %s connection "
"(fd %d); removing",
conn_type_to_string(conn->type), (int)conn->s);
tor_fragile_assert();
#endif /* !defined(_WIN32) */
if (CONN_IS_EDGE(conn))
connection_edge_end_errno(TO_EDGE_CONN(conn));
connection_mark_for_close(conn);
}
}
assert_connection_ok(conn, time(NULL));
if (smartlist_len(closeable_connection_lst))
close_closeable_connections();
}
/** Libevent callback: this gets invoked when (connection_t*)<b>conn</b> has
* some data to write. */
static void
conn_write_callback(evutil_socket_t fd, short events, void *_conn)
{
connection_t *conn = _conn;
(void)fd;
(void)events;
LOG_FN_CONN(conn, (LOG_DEBUG, LD_NET, "socket %d wants to write.",
(int)conn->s));
/* assert_connection_ok(conn, time(NULL)); */
if (connection_handle_write(conn, 0) < 0) {
if (!conn->marked_for_close) {
/* this connection is broken. remove it. */
log_fn(LOG_WARN,LD_BUG,
"unhandled error on write for %s connection (fd %d); removing",
conn_type_to_string(conn->type), (int)conn->s);
tor_fragile_assert();
if (CONN_IS_EDGE(conn)) {
/* otherwise we cry wolf about duplicate close */
edge_connection_t *edge_conn = TO_EDGE_CONN(conn);
if (!edge_conn->end_reason)
edge_conn->end_reason = END_STREAM_REASON_INTERNAL;
edge_conn->edge_has_sent_end = 1;
}
connection_close_immediate(conn); /* So we don't try to flush. */
connection_mark_for_close(conn);
}
}
assert_connection_ok(conn, time(NULL));
if (smartlist_len(closeable_connection_lst))
close_closeable_connections();
}
/** If the connection at connection_array[i] is marked for close, then:
* - If it has data that it wants to flush, try to flush it.
* - If it _still_ has data to flush, and conn->hold_open_until_flushed is
* true, then leave the connection open and return.
* - Otherwise, remove the connection from connection_array and from
* all other lists, close it, and free it.
* Returns 1 if the connection was closed, 0 otherwise.
*/
static int
conn_close_if_marked(int i)
{
connection_t *conn;
int retval;
time_t now;
conn = smartlist_get(connection_array, i);
if (!conn->marked_for_close)
return 0; /* nothing to see here, move along */
now = time(NULL);
assert_connection_ok(conn, now);
/* assert_all_pending_dns_resolves_ok(); */
log_debug(LD_NET,"Cleaning up connection (fd "TOR_SOCKET_T_FORMAT").",
conn->s);
/* If the connection we are about to close was trying to connect to
a proxy server and failed, the client won't be able to use that
proxy. We should warn the user about this. */
if (conn->proxy_state == PROXY_INFANT)
log_failed_proxy_connection(conn);
if ((SOCKET_OK(conn->s) || conn->linked_conn) &&
connection_wants_to_flush(conn)) {
/* s == -1 means it's an incomplete edge connection, or that the socket
* has already been closed as unflushable. */
ssize_t sz = connection_bucket_write_limit(conn, now);
if (!conn->hold_open_until_flushed)
log_info(LD_NET,
"Conn (addr %s, fd %d, type %s, state %d) marked, but wants "
"to flush %d bytes. (Marked at %s:%d)",
escaped_safe_str_client(conn->address),
(int)conn->s, conn_type_to_string(conn->type), conn->state,
(int)conn->outbuf_flushlen,
conn->marked_for_close_file, conn->marked_for_close);
if (conn->linked_conn) {
retval = buf_move_to_buf(conn->linked_conn->inbuf, conn->outbuf,
&conn->outbuf_flushlen);
if (retval >= 0) {
/* The linked conn will notice that it has data when it notices that
* we're gone. */
connection_start_reading_from_linked_conn(conn->linked_conn);
}
log_debug(LD_GENERAL, "Flushed last %d bytes from a linked conn; "
"%d left; flushlen %d; wants-to-flush==%d", retval,
(int)connection_get_outbuf_len(conn),
(int)conn->outbuf_flushlen,
connection_wants_to_flush(conn));
} else if (connection_speaks_cells(conn)) {
if (conn->state == OR_CONN_STATE_OPEN) {
retval = buf_flush_to_tls(conn->outbuf, TO_OR_CONN(conn)->tls, sz,
&conn->outbuf_flushlen);
} else
retval = -1; /* never flush non-open broken tls connections */
} else {
retval = buf_flush_to_socket(conn->outbuf, conn->s, sz,
&conn->outbuf_flushlen);
}
if (retval >= 0 && /* Technically, we could survive things like
TLS_WANT_WRITE here. But don't bother for now. */
conn->hold_open_until_flushed && connection_wants_to_flush(conn)) {
if (retval > 0) {
LOG_FN_CONN(conn, (LOG_INFO,LD_NET,
"Holding conn (fd %d) open for more flushing.",
(int)conn->s));
conn->timestamp_last_write_allowed = now; /* reset so we can flush
* more */
} else if (sz == 0) {
/* Also, retval==0. If we get here, we didn't want to write anything
* (because of rate-limiting) and we didn't. */
/* Connection must flush before closing, but it's being rate-limited.
* Let's remove from Libevent, and mark it as blocked on bandwidth
* so it will be re-added on next token bucket refill. Prevents
* busy Libevent loops where we keep ending up here and returning
* 0 until we are no longer blocked on bandwidth.
*/
connection_consider_empty_write_buckets(conn);
/* Make sure that consider_empty_buckets really disabled the
* connection: */
if (BUG(connection_is_writing(conn))) {
connection_write_bw_exhausted(conn, true);
}
/* The connection is being held due to write rate limit and thus will
* flush its data later. We need to stop reading because this
* connection is about to be closed once flushed. It should not
* process anything more coming in at this stage. */
connection_stop_reading(conn);
}
return 0;
}
if (connection_wants_to_flush(conn)) {
log_fn(LOG_INFO, LD_NET, "We stalled too much while trying to write %d "
"bytes to address %s. If this happens a lot, either "
"something is wrong with your network connection, or "
"something is wrong with theirs. "
"(fd %d, type %s, state %d, marked at %s:%d).",
(int)connection_get_outbuf_len(conn),
escaped_safe_str_client(conn->address),
(int)conn->s, conn_type_to_string(conn->type), conn->state,
conn->marked_for_close_file,
conn->marked_for_close);
}
}
connection_unlink(conn); /* unlink, remove, free */
return 1;
}
/** Implementation for directory_all_unreachable. This is done in a callback,
* since otherwise it would complicate Tor's control-flow graph beyond all
* reason.
*/
static void
directory_all_unreachable_cb(mainloop_event_t *event, void *arg)
{
(void)event;
(void)arg;
connection_t *conn;
while ((conn = connection_get_by_type_state(CONN_TYPE_AP,
AP_CONN_STATE_CIRCUIT_WAIT))) {
entry_connection_t *entry_conn = TO_ENTRY_CONN(conn);
log_notice(LD_NET,
"Is your network connection down? "
"Failing connection to '%s:%d'.",
safe_str_client(entry_conn->socks_request->address),
entry_conn->socks_request->port);
connection_mark_unattached_ap(entry_conn,
END_STREAM_REASON_NET_UNREACHABLE);
}
control_event_general_error("DIR_ALL_UNREACHABLE");
}
static mainloop_event_t *directory_all_unreachable_cb_event = NULL;
/** We've just tried every dirserver we know about, and none of
* them were reachable. Assume the network is down. Change state
* so next time an application connection arrives we'll delay it
* and try another directory fetch. Kill off all the circuit_wait
* streams that are waiting now, since they will all timeout anyway.
*/
void
directory_all_unreachable(time_t now)
{
(void)now;
reset_uptime(); /* reset it */
if (!directory_all_unreachable_cb_event) {
directory_all_unreachable_cb_event =
mainloop_event_new(directory_all_unreachable_cb, NULL);
tor_assert(directory_all_unreachable_cb_event);
}
mainloop_event_activate(directory_all_unreachable_cb_event);
}
/** This function is called whenever we successfully pull down some new
* network statuses or server descriptors. */
void
directory_info_has_arrived(time_t now, int from_cache, int suppress_logs)
{
const or_options_t *options = get_options();
/* if we have enough dir info, then update our guard status with
* whatever we just learned. */
int invalidate_circs = guards_update_all();
if (invalidate_circs) {
circuit_mark_all_unused_circs();
circuit_mark_all_dirty_circs_as_unusable();
}
if (!router_have_minimum_dir_info()) {
int quiet = suppress_logs || from_cache ||
directory_too_idle_to_fetch_descriptors(options, now);
tor_log(quiet ? LOG_INFO : LOG_NOTICE, LD_DIR,
"I learned some more directory information, but not enough to "
"build a circuit: %s", get_dir_info_status_string());
update_all_descriptor_downloads(now);
return;
} else {
if (directory_fetches_from_authorities(options)) {
update_all_descriptor_downloads(now);
}
/* Don't even bother trying to get extrainfo until the rest of our
* directory info is up-to-date */
if (options->DownloadExtraInfo)
update_extrainfo_downloads(now);
}
if (server_mode(options) && !net_is_disabled() && !from_cache &&
(have_completed_a_circuit() || !any_predicted_circuits(now)))
router_do_reachability_checks(1, 1);
}
/** Perform regular maintenance tasks for a single connection. This
* function gets run once per second per connection by run_scheduled_events.
*/
static void
run_connection_housekeeping(int i, time_t now)
{
cell_t cell;
connection_t *conn = smartlist_get(connection_array, i);
const or_options_t *options = get_options();
or_connection_t *or_conn;
channel_t *chan = NULL;
int have_any_circuits;
int past_keepalive =
now >= conn->timestamp_last_write_allowed + options->KeepalivePeriod;
if (conn->outbuf && !connection_get_outbuf_len(conn) &&
conn->type == CONN_TYPE_OR)
TO_OR_CONN(conn)->timestamp_lastempty = now;
if (conn->marked_for_close) {
/* nothing to do here */
return;
}
/* Expire any directory connections that haven't been active (sent
* if a server or received if a client) for 5 min */
if (conn->type == CONN_TYPE_DIR &&
((DIR_CONN_IS_SERVER(conn) &&
conn->timestamp_last_write_allowed
+ options->TestingDirConnectionMaxStall < now) ||
(!DIR_CONN_IS_SERVER(conn) &&
conn->timestamp_last_read_allowed
+ options->TestingDirConnectionMaxStall < now))) {
log_info(LD_DIR,"Expiring wedged directory conn (fd %d, purpose %d)",
(int)conn->s, conn->purpose);
/* This check is temporary; it's to let us know whether we should consider
* parsing partial serverdesc responses. */
if (conn->purpose == DIR_PURPOSE_FETCH_SERVERDESC &&
connection_get_inbuf_len(conn) >= 1024) {
log_info(LD_DIR,"Trying to extract information from wedged server desc "
"download.");
connection_dir_reached_eof(TO_DIR_CONN(conn));
} else {
connection_mark_for_close(conn);
}
return;
}
if (!connection_speaks_cells(conn))
return; /* we're all done here, the rest is just for OR conns */
/* If we haven't flushed to an OR connection for a while, then either nuke
the connection or send a keepalive, depending. */
or_conn = TO_OR_CONN(conn);
tor_assert(conn->outbuf);
chan = TLS_CHAN_TO_BASE(or_conn->chan);
tor_assert(chan);
if (channel_num_circuits(chan) != 0) {
have_any_circuits = 1;
chan->timestamp_last_had_circuits = now;
} else {
have_any_circuits = 0;
}
if (channel_is_bad_for_new_circs(TLS_CHAN_TO_BASE(or_conn->chan)) &&
! have_any_circuits) {
/* It's bad for new circuits, and has no unmarked circuits on it:
* mark it now. */
log_info(LD_OR,
"Expiring non-used OR connection to fd %d (%s:%d) [Too old].",
(int)conn->s, conn->address, conn->port);
if (conn->state == OR_CONN_STATE_CONNECTING)
connection_or_connect_failed(TO_OR_CONN(conn),
END_OR_CONN_REASON_TIMEOUT,
"Tor gave up on the connection");
connection_or_close_normally(TO_OR_CONN(conn), 1);
} else if (!connection_state_is_open(conn)) {
if (past_keepalive) {
/* We never managed to actually get this connection open and happy. */
log_info(LD_OR,"Expiring non-open OR connection to fd %d (%s:%d).",
(int)conn->s,conn->address, conn->port);
connection_or_close_normally(TO_OR_CONN(conn), 0);
}
} else if (we_are_hibernating() &&
! have_any_circuits &&
!connection_get_outbuf_len(conn)) {
/* We're hibernating or shutting down, there's no circuits, and nothing to
* flush.*/
log_info(LD_OR,"Expiring non-used OR connection to fd %d (%s:%d) "
"[Hibernating or exiting].",
(int)conn->s,conn->address, conn->port);
connection_or_close_normally(TO_OR_CONN(conn), 1);
} else if (!have_any_circuits &&
now - or_conn->idle_timeout >=
chan->timestamp_last_had_circuits) {
log_info(LD_OR,"Expiring non-used OR connection %"PRIu64" to fd %d "
"(%s:%d) [no circuits for %d; timeout %d; %scanonical].",
(chan->global_identifier),
(int)conn->s, conn->address, conn->port,
(int)(now - chan->timestamp_last_had_circuits),
or_conn->idle_timeout,
or_conn->is_canonical ? "" : "non");
connection_or_close_normally(TO_OR_CONN(conn), 0);
} else if (
now >= or_conn->timestamp_lastempty + options->KeepalivePeriod*10 &&
now >=
conn->timestamp_last_write_allowed + options->KeepalivePeriod*10) {
log_fn(LOG_PROTOCOL_WARN,LD_PROTOCOL,
"Expiring stuck OR connection to fd %d (%s:%d). (%d bytes to "
"flush; %d seconds since last write)",
(int)conn->s, conn->address, conn->port,
(int)connection_get_outbuf_len(conn),
(int)(now-conn->timestamp_last_write_allowed));
connection_or_close_normally(TO_OR_CONN(conn), 0);
} else if (past_keepalive && !connection_get_outbuf_len(conn)) {
/* send a padding cell */
log_fn(LOG_DEBUG,LD_OR,"Sending keepalive to (%s:%d)",
conn->address, conn->port);
memset(&cell,0,sizeof(cell_t));
cell.command = CELL_PADDING;
connection_or_write_cell_to_buf(&cell, or_conn);
} else {
channelpadding_decide_to_pad_channel(chan);
}
}
/** Honor a NEWNYM request: make future requests unlinkable to past
* requests. */
static void
signewnym_impl(time_t now)
{
const or_options_t *options = get_options();
if (!proxy_mode(options)) {
log_info(LD_CONTROL, "Ignoring SIGNAL NEWNYM because client functionality "
"is disabled.");
return;
}
circuit_mark_all_dirty_circs_as_unusable();
addressmap_clear_transient();
hs_client_purge_state();
time_of_last_signewnym = now;
signewnym_is_pending = 0;
++newnym_epoch;
control_event_signal(SIGNEWNYM);
}
/** Callback: run a deferred signewnym. */
static void
handle_deferred_signewnym_cb(mainloop_event_t *event, void *arg)
{
(void)event;
(void)arg;
log_info(LD_CONTROL, "Honoring delayed NEWNYM request");
do_signewnym(time(NULL));
}
/** Either perform a signewnym or schedule one, depending on rate limiting. */
void
do_signewnym(time_t now)
{
if (time_of_last_signewnym + MAX_SIGNEWNYM_RATE > now) {
const time_t delay_sec =
time_of_last_signewnym + MAX_SIGNEWNYM_RATE - now;
if (! signewnym_is_pending) {
signewnym_is_pending = 1;
if (!handle_deferred_signewnym_ev) {
handle_deferred_signewnym_ev =
mainloop_event_postloop_new(handle_deferred_signewnym_cb, NULL);
}
const struct timeval delay_tv = { delay_sec, 0 };
mainloop_event_schedule(handle_deferred_signewnym_ev, &delay_tv);
}
log_notice(LD_CONTROL,
"Rate limiting NEWNYM request: delaying by %d second(s)",
(int)(delay_sec));
} else {
signewnym_impl(now);
}
}
/** Return the number of times that signewnym has been called. */
unsigned
get_signewnym_epoch(void)
{
return newnym_epoch;
}
/** True iff we have initialized all the members of <b>periodic_events</b>.
* Used to prevent double-initialization. */
static int periodic_events_initialized = 0;
/* Declare all the timer callback functions... */
#undef CALLBACK
#define CALLBACK(name) \
static int name ## _callback(time_t, const or_options_t *)
CALLBACK(add_entropy);
CALLBACK(check_authority_cert);
CALLBACK(check_canonical_channels);
CALLBACK(check_descriptor);
CALLBACK(check_dns_honesty);
CALLBACK(check_ed_keys);
CALLBACK(check_expired_networkstatus);
CALLBACK(check_for_reachability_bw);
CALLBACK(check_onion_keys_expiry_time);
CALLBACK(clean_caches);
CALLBACK(clean_consdiffmgr);
CALLBACK(dirvote);
CALLBACK(downrate_stability);
CALLBACK(expire_old_ciruits_serverside);
CALLBACK(fetch_networkstatus);
CALLBACK(heartbeat);
CALLBACK(hs_service);
CALLBACK(launch_descriptor_fetches);
CALLBACK(launch_reachability_tests);
CALLBACK(prune_old_routers);
CALLBACK(reachability_warnings);
CALLBACK(record_bridge_stats);
CALLBACK(rend_cache_failure_clean);
CALLBACK(reset_padding_counts);
CALLBACK(retry_dns);
CALLBACK(retry_listeners);
CALLBACK(rotate_onion_key);
CALLBACK(rotate_x509_certificate);
CALLBACK(save_stability);
CALLBACK(save_state);
CALLBACK(write_bridge_ns);
CALLBACK(write_stats_file);
CALLBACK(control_per_second_events);
CALLBACK(second_elapsed);
#undef CALLBACK
/* Now we declare an array of periodic_event_item_t for each periodic event */
#define CALLBACK(name, r, f) \
PERIODIC_EVENT(name, PERIODIC_EVENT_ROLE_ ## r, f)
#define FL(name) (PERIODIC_EVENT_FLAG_ ## name)
STATIC periodic_event_item_t periodic_events[] = {
/* Everyone needs to run these. They need to have very long timeouts for
* that to be safe. */
CALLBACK(add_entropy, ALL, 0),
CALLBACK(heartbeat, ALL, 0),
CALLBACK(reset_padding_counts, ALL, 0),
/* This is a legacy catch-all callback that runs once per second if
* we are online and active. */
CALLBACK(second_elapsed, NET_PARTICIPANT,
FL(NEED_NET)|FL(RUN_ON_DISABLE)),
/* XXXX Do we have a reason to do this on a callback? Does it do any good at
* all? For now, if we're dormant, we can let our listeners decay. */
CALLBACK(retry_listeners, NET_PARTICIPANT, FL(NEED_NET)),
/* We need to do these if we're participating in the Tor network. */
CALLBACK(check_expired_networkstatus, NET_PARTICIPANT, 0),
CALLBACK(fetch_networkstatus, NET_PARTICIPANT, 0),
CALLBACK(launch_descriptor_fetches, NET_PARTICIPANT, FL(NEED_NET)),
CALLBACK(rotate_x509_certificate, NET_PARTICIPANT, 0),
CALLBACK(check_network_participation, NET_PARTICIPANT, 0),
/* We need to do these if we're participating in the Tor network, and
* immediately before we stop. */
CALLBACK(clean_caches, NET_PARTICIPANT, FL(RUN_ON_DISABLE)),
CALLBACK(save_state, NET_PARTICIPANT, FL(RUN_ON_DISABLE)),
CALLBACK(write_stats_file, NET_PARTICIPANT, FL(RUN_ON_DISABLE)),
CALLBACK(prune_old_routers, NET_PARTICIPANT, FL(RUN_ON_DISABLE)),
/* Routers (bridge and relay) only. */
CALLBACK(check_descriptor, ROUTER, FL(NEED_NET)),
CALLBACK(check_ed_keys, ROUTER, 0),
CALLBACK(check_for_reachability_bw, ROUTER, FL(NEED_NET)),
CALLBACK(check_onion_keys_expiry_time, ROUTER, 0),
CALLBACK(expire_old_ciruits_serverside, ROUTER, FL(NEED_NET)),
CALLBACK(reachability_warnings, ROUTER, FL(NEED_NET)),
CALLBACK(retry_dns, ROUTER, 0),
CALLBACK(rotate_onion_key, ROUTER, 0),
/* Authorities (bridge and directory) only. */
CALLBACK(downrate_stability, AUTHORITIES, 0),
CALLBACK(launch_reachability_tests, AUTHORITIES, FL(NEED_NET)),
CALLBACK(save_stability, AUTHORITIES, 0),
/* Directory authority only. */
CALLBACK(check_authority_cert, DIRAUTH, 0),
CALLBACK(dirvote, DIRAUTH, FL(NEED_NET)),
/* Relay only. */
CALLBACK(check_canonical_channels, RELAY, FL(NEED_NET)),
CALLBACK(check_dns_honesty, RELAY, FL(NEED_NET)),
/* Hidden Service service only. */
CALLBACK(hs_service, HS_SERVICE, FL(NEED_NET)), // XXXX break this down more
/* Bridge only. */
CALLBACK(record_bridge_stats, BRIDGE, 0),
/* Client only. */
/* XXXX this could be restricted to CLIENT+NET_PARTICIPANT */
CALLBACK(rend_cache_failure_clean, NET_PARTICIPANT, FL(RUN_ON_DISABLE)),
/* Bridge Authority only. */
CALLBACK(write_bridge_ns, BRIDGEAUTH, 0),
/* Directory server only. */
CALLBACK(clean_consdiffmgr, DIRSERVER, 0),
/* Controller with per-second events only. */
CALLBACK(control_per_second_events, CONTROLEV, 0),
END_OF_PERIODIC_EVENTS
};
#undef CALLBACK
#undef FL
/* These are pointers to members of periodic_events[] that are used to
* implement particular callbacks. We keep them separate here so that we
* can access them by name. We also keep them inside periodic_events[]
* so that we can implement "reset all timers" in a reasonable way. */
static periodic_event_item_t *check_descriptor_event=NULL;
static periodic_event_item_t *dirvote_event=NULL;
static periodic_event_item_t *fetch_networkstatus_event=NULL;
static periodic_event_item_t *launch_descriptor_fetches_event=NULL;
static periodic_event_item_t *check_dns_honesty_event=NULL;
static periodic_event_item_t *save_state_event=NULL;
static periodic_event_item_t *prune_old_routers_event=NULL;
/** Reset all the periodic events so we'll do all our actions again as if we
* just started up.
* Useful if our clock just moved back a long time from the future,
* so we don't wait until that future arrives again before acting.
*/
void
reset_all_main_loop_timers(void)
{
int i;
for (i = 0; periodic_events[i].name; ++i) {
periodic_event_reschedule(&periodic_events[i]);
}
}
/** Return the member of periodic_events[] whose name is <b>name</b>.
* Return NULL if no such event is found.
*/
static periodic_event_item_t *
find_periodic_event(const char *name)
{
int i;
for (i = 0; periodic_events[i].name; ++i) {
if (strcmp(name, periodic_events[i].name) == 0)
return &periodic_events[i];
}
return NULL;
}
/** Return a bitmask of the roles this tor instance is configured for using
* the given options. */
STATIC int
get_my_roles(const or_options_t *options)
{
tor_assert(options);
int roles = PERIODIC_EVENT_ROLE_ALL;
int is_bridge = options->BridgeRelay;
int is_relay = server_mode(options);
int is_dirauth = authdir_mode_v3(options);
int is_bridgeauth = authdir_mode_bridge(options);
int is_hidden_service = !!hs_service_get_num_services() ||
!!rend_num_services();
int is_dirserver = dir_server_mode(options);
int sending_control_events = control_any_per_second_event_enabled();
/* We also consider tor to have the role of a client if the ControlPort is
* set because a lot of things can be done over the control port which
* requires tor to have basic functionnalities. */
int is_client = options_any_client_port_set(options) ||
options->ControlPort_set ||
options->OwningControllerFD != UINT64_MAX;
int is_net_participant = is_participating_on_network() ||
is_relay || is_hidden_service;
if (is_bridge) roles |= PERIODIC_EVENT_ROLE_BRIDGE;
if (is_client) roles |= PERIODIC_EVENT_ROLE_CLIENT;
if (is_relay) roles |= PERIODIC_EVENT_ROLE_RELAY;
if (is_dirauth) roles |= PERIODIC_EVENT_ROLE_DIRAUTH;
if (is_bridgeauth) roles |= PERIODIC_EVENT_ROLE_BRIDGEAUTH;
if (is_hidden_service) roles |= PERIODIC_EVENT_ROLE_HS_SERVICE;
if (is_dirserver) roles |= PERIODIC_EVENT_ROLE_DIRSERVER;
if (is_net_participant) roles |= PERIODIC_EVENT_ROLE_NET_PARTICIPANT;
if (sending_control_events) roles |= PERIODIC_EVENT_ROLE_CONTROLEV;
return roles;
}
/** Event to run initialize_periodic_events_cb */
static struct event *initialize_periodic_events_event = NULL;
/** Helper, run one second after setup:
* Initializes all members of periodic_events and starts them running.
*
* (We do this one second after setup for backward-compatibility reasons;
* it might not actually be necessary.) */
static void
initialize_periodic_events_cb(evutil_socket_t fd, short events, void *data)
{
(void) fd;
(void) events;
(void) data;
tor_event_free(initialize_periodic_events_event);
rescan_periodic_events(get_options());
}
/** Set up all the members of periodic_events[], and configure them all to be
* launched from a callback. */
STATIC void
initialize_periodic_events(void)
{
if (periodic_events_initialized)
return;
periodic_events_initialized = 1;
/* Set up all periodic events. We'll launch them by roles. */
int i;
for (i = 0; periodic_events[i].name; ++i) {
periodic_event_setup(&periodic_events[i]);
}
#define NAMED_CALLBACK(name) \
STMT_BEGIN name ## _event = find_periodic_event( #name ); STMT_END
NAMED_CALLBACK(check_descriptor);
NAMED_CALLBACK(prune_old_routers);
NAMED_CALLBACK(dirvote);
NAMED_CALLBACK(fetch_networkstatus);
NAMED_CALLBACK(launch_descriptor_fetches);
NAMED_CALLBACK(check_dns_honesty);
NAMED_CALLBACK(save_state);
struct timeval one_second = { 1, 0 };
initialize_periodic_events_event = tor_evtimer_new(
tor_libevent_get_base(),
initialize_periodic_events_cb, NULL);
event_add(initialize_periodic_events_event, &one_second);
}
STATIC void
teardown_periodic_events(void)
{
int i;
for (i = 0; periodic_events[i].name; ++i) {
periodic_event_destroy(&periodic_events[i]);
}
periodic_events_initialized = 0;
}
static mainloop_event_t *rescan_periodic_events_ev = NULL;
/** Callback: rescan the periodic event list. */
static void
rescan_periodic_events_cb(mainloop_event_t *event, void *arg)
{
(void)event;
(void)arg;
rescan_periodic_events(get_options());
}
/**
* Schedule an event that will rescan which periodic events should run.
**/
MOCK_IMPL(void,
schedule_rescan_periodic_events,(void))
{
if (!rescan_periodic_events_ev) {
rescan_periodic_events_ev =
mainloop_event_new(rescan_periodic_events_cb, NULL);
}
mainloop_event_activate(rescan_periodic_events_ev);
}
/** Do a pass at all our periodic events, disable those we don't need anymore
* and enable those we need now using the given options. */
void
rescan_periodic_events(const or_options_t *options)
{
tor_assert(options);
/* Avoid scanning the event list if we haven't initialized it yet. This is
* particularly useful for unit tests in order to avoid initializing main
* loop events everytime. */
if (!periodic_events_initialized) {
return;
}
int roles = get_my_roles(options);
for (int i = 0; periodic_events[i].name; ++i) {
periodic_event_item_t *item = &periodic_events[i];
int enable = !!(item->roles & roles);
/* Handle the event flags. */
if (net_is_disabled() &&
(item->flags & PERIODIC_EVENT_FLAG_NEED_NET)) {
enable = 0;
}
/* Enable the event if needed. It is safe to enable an event that was
* already enabled. Same goes for disabling it. */
if (enable) {
log_debug(LD_GENERAL, "Launching periodic event %s", item->name);
periodic_event_enable(item);
} else {
log_debug(LD_GENERAL, "Disabling periodic event %s", item->name);
if (item->flags & PERIODIC_EVENT_FLAG_RUN_ON_DISABLE) {
periodic_event_schedule_and_disable(item);
} else {
periodic_event_disable(item);
}
}
}
}
/* We just got new options globally set, see if we need to enabled or disable
* periodic events. */
void
periodic_events_on_new_options(const or_options_t *options)
{
/* Only if we've already initialized the events, rescan the list which will
* enable or disable events depending on our roles. This will be called at
* bootup and we don't want this function to initialize the events because
* they aren't set up at this stage. */
if (periodic_events_initialized) {
rescan_periodic_events(options);
}
}
/**
* Update our schedule so that we'll check whether we need to update our
* descriptor immediately, rather than after up to CHECK_DESCRIPTOR_INTERVAL
* seconds.
*/
void
reschedule_descriptor_update_check(void)
{
if (check_descriptor_event) {
periodic_event_reschedule(check_descriptor_event);
}
}
/**
* Update our schedule so that we'll check whether we need to fetch directory
* info immediately.
*/
void
reschedule_directory_downloads(void)
{
tor_assert(fetch_networkstatus_event);
tor_assert(launch_descriptor_fetches_event);
periodic_event_reschedule(fetch_networkstatus_event);
periodic_event_reschedule(launch_descriptor_fetches_event);
}
/** Mainloop callback: clean up circuits, channels, and connections
* that are pending close. */
static void
postloop_cleanup_cb(mainloop_event_t *ev, void *arg)
{
(void)ev;
(void)arg;
circuit_close_all_marked();
close_closeable_connections();
channel_run_cleanup();
channel_listener_run_cleanup();
}
/** Event to run postloop_cleanup_cb */
static mainloop_event_t *postloop_cleanup_ev=NULL;
/** Schedule a post-loop event to clean up marked channels, connections, and
* circuits. */
void
mainloop_schedule_postloop_cleanup(void)
{
if (PREDICT_UNLIKELY(postloop_cleanup_ev == NULL)) {
// (It's possible that we can get here if we decide to close a connection
// in the earliest stages of our configuration, before we create events.)
return;
}
mainloop_event_activate(postloop_cleanup_ev);
}
/** Event to run 'scheduled_shutdown_cb' */
static mainloop_event_t *scheduled_shutdown_ev=NULL;
/** Callback: run a scheduled shutdown */
static void
scheduled_shutdown_cb(mainloop_event_t *ev, void *arg)
{
(void)ev;
(void)arg;
log_notice(LD_GENERAL, "Clean shutdown finished. Exiting.");
tor_shutdown_event_loop_and_exit(0);
}
/** Schedule the mainloop to exit after <b>delay_sec</b> seconds. */
void
mainloop_schedule_shutdown(int delay_sec)
{
const struct timeval delay_tv = { delay_sec, 0 };
if (! scheduled_shutdown_ev) {
scheduled_shutdown_ev = mainloop_event_new(scheduled_shutdown_cb, NULL);
}
mainloop_event_schedule(scheduled_shutdown_ev, &delay_tv);
}
#define LONGEST_TIMER_PERIOD (30 * 86400)
/** Helper: Return the number of seconds between <b>now</b> and <b>next</b>,
* clipped to the range [1 second, LONGEST_TIMER_PERIOD]. */
static inline int
safe_timer_diff(time_t now, time_t next)
{
if (next > now) {
/* There were no computers at signed TIME_MIN (1902 on 32-bit systems),
* and nothing that could run Tor. It's a bug if 'next' is around then.
* On 64-bit systems with signed TIME_MIN, TIME_MIN is before the Big
* Bang. We cannot extrapolate past a singularity, but there was probably
* nothing that could run Tor then, either.
**/
tor_assert(next > TIME_MIN + LONGEST_TIMER_PERIOD);
if (next - LONGEST_TIMER_PERIOD > now)
return LONGEST_TIMER_PERIOD;
return (int)(next - now);
} else {
return 1;
}
}
/** Perform regular maintenance tasks. This function gets run once per
* second.
*/
static int
second_elapsed_callback(time_t now, const or_options_t *options)
{
/* 0. See if our bandwidth limits are exhausted and we should hibernate
*
* Note: we have redundant mechanisms to handle the case where it's
* time to wake up from hibernation; or where we have a scheduled
* shutdown and it's time to run it, but this will also handle those.
*/
consider_hibernation(now);
/* Maybe enough time elapsed for us to reconsider a circuit. */
circuit_upgrade_circuits_from_guard_wait();
if (options->UseBridges && !net_is_disabled()) {
/* Note: this check uses net_is_disabled(), not should_delay_dir_fetches()
* -- the latter is only for fetching consensus-derived directory info. */
// TODO: client
// Also, schedule this rather than probing 1x / sec
fetch_bridge_descriptors(options, now);
}
if (accounting_is_enabled(options)) {
// TODO: refactor or rewrite?
accounting_run_housekeeping(now);
}
/* 3a. Every second, we examine pending circuits and prune the
* ones which have been pending for more than a few seconds.
* We do this before step 4, so it can try building more if
* it's not comfortable with the number of available circuits.
*/
/* (If our circuit build timeout can ever become lower than a second (which
* it can't, currently), we should do this more often.) */
// TODO: All expire stuff can become NET_PARTICIPANT, RUN_ON_DISABLE
circuit_expire_building();
circuit_expire_waiting_for_better_guard();
/* 3b. Also look at pending streams and prune the ones that 'began'
* a long time ago but haven't gotten a 'connected' yet.
* Do this before step 4, so we can put them back into pending
* state to be picked up by the new circuit.
*/
connection_ap_expire_beginning();
/* 3c. And expire connections that we've held open for too long.
*/
connection_expire_held_open();
/* 4. Every second, we try a new circuit if there are no valid
* circuits. Every NewCircuitPeriod seconds, we expire circuits
* that became dirty more than MaxCircuitDirtiness seconds ago,
* and we make a new circ if there are no clean circuits.
*/
const int have_dir_info = router_have_minimum_dir_info();
if (have_dir_info && !net_is_disabled()) {
circuit_build_needed_circs(now);
} else {
circuit_expire_old_circs_as_needed(now);
}
/* 5. We do housekeeping for each connection... */
channel_update_bad_for_new_circs(NULL, 0);
int i;
for (i=0;i<smartlist_len(connection_array);i++) {
run_connection_housekeeping(i, now);
}
/* Run again in a second. */
return 1;
}
/* Periodic callback: rotate the onion keys after the period defined by the
* "onion-key-rotation-days" consensus parameter, shut down and restart all
* cpuworkers, and update our descriptor if necessary.
*/
static int
rotate_onion_key_callback(time_t now, const or_options_t *options)
{
if (server_mode(options)) {
int onion_key_lifetime = get_onion_key_lifetime();
time_t rotation_time = get_onion_key_set_at()+onion_key_lifetime;
if (rotation_time > now) {
return ONION_KEY_CONSENSUS_CHECK_INTERVAL;
}
log_info(LD_GENERAL,"Rotating onion key.");
rotate_onion_key();
cpuworkers_rotate_keyinfo();
if (router_rebuild_descriptor(1)<0) {
log_info(LD_CONFIG, "Couldn't rebuild router descriptor");
}
if (advertised_server_mode() && !net_is_disabled())
router_upload_dir_desc_to_dirservers(0);
return ONION_KEY_CONSENSUS_CHECK_INTERVAL;
}
return PERIODIC_EVENT_NO_UPDATE;
}
/* Period callback: Check if our old onion keys are still valid after the
* period of time defined by the consensus parameter
* "onion-key-grace-period-days", otherwise expire them by setting them to
* NULL.
*/
static int
check_onion_keys_expiry_time_callback(time_t now, const or_options_t *options)
{
if (server_mode(options)) {
int onion_key_grace_period = get_onion_key_grace_period();
time_t expiry_time = get_onion_key_set_at()+onion_key_grace_period;
if (expiry_time > now) {
return ONION_KEY_CONSENSUS_CHECK_INTERVAL;
}
log_info(LD_GENERAL, "Expiring old onion keys.");
expire_old_onion_keys();
cpuworkers_rotate_keyinfo();
return ONION_KEY_CONSENSUS_CHECK_INTERVAL;
}
return PERIODIC_EVENT_NO_UPDATE;
}
/* Periodic callback: Every 30 seconds, check whether it's time to make new
* Ed25519 subkeys.
*/
static int
check_ed_keys_callback(time_t now, const or_options_t *options)
{
if (server_mode(options)) {
if (should_make_new_ed_keys(options, now)) {
int new_signing_key = load_ed_keys(options, now);
if (new_signing_key < 0 ||
generate_ed_link_cert(options, now, new_signing_key > 0)) {
log_err(LD_OR, "Unable to update Ed25519 keys! Exiting.");
tor_shutdown_event_loop_and_exit(1);
}
}
return 30;
}
return PERIODIC_EVENT_NO_UPDATE;
}
/**
* Periodic callback: Every {LAZY,GREEDY}_DESCRIPTOR_RETRY_INTERVAL,
* see about fetching descriptors, microdescriptors, and extrainfo
* documents.
*/
static int
launch_descriptor_fetches_callback(time_t now, const or_options_t *options)
{
if (should_delay_dir_fetches(options, NULL))
return PERIODIC_EVENT_NO_UPDATE;
update_all_descriptor_downloads(now);
update_extrainfo_downloads(now);
if (router_have_minimum_dir_info())
return LAZY_DESCRIPTOR_RETRY_INTERVAL;
else
return GREEDY_DESCRIPTOR_RETRY_INTERVAL;
}
/**
* Periodic event: Rotate our X.509 certificates and TLS keys once every
* MAX_SSL_KEY_LIFETIME_INTERNAL.
*/
static int
rotate_x509_certificate_callback(time_t now, const or_options_t *options)
{
static int first = 1;
(void)now;
(void)options;
if (first) {
first = 0;
return MAX_SSL_KEY_LIFETIME_INTERNAL;
}
/* 1b. Every MAX_SSL_KEY_LIFETIME_INTERNAL seconds, we change our
* TLS context. */
log_info(LD_GENERAL,"Rotating tls context.");
if (router_initialize_tls_context() < 0) {
log_err(LD_BUG, "Error reinitializing TLS context");
tor_assert_unreached();
}
if (generate_ed_link_cert(options, now, 1)) {
log_err(LD_OR, "Unable to update Ed25519->TLS link certificate for "
"new TLS context.");
tor_assert_unreached();
}
/* We also make sure to rotate the TLS connections themselves if they've
* been up for too long -- but that's done via is_bad_for_new_circs in
* run_connection_housekeeping() above. */
return MAX_SSL_KEY_LIFETIME_INTERNAL;
}
/**
* Periodic callback: once an hour, grab some more entropy from the
* kernel and feed it to our CSPRNG.
**/
static int
add_entropy_callback(time_t now, const or_options_t *options)
{
(void)now;
(void)options;
/* We already seeded once, so don't die on failure. */
if (crypto_seed_rng() < 0) {
log_warn(LD_GENERAL, "Tried to re-seed RNG, but failed. We already "
"seeded once, though, so we won't exit here.");
}
/** How often do we add more entropy to OpenSSL's RNG pool? */
#define ENTROPY_INTERVAL (60*60)
return ENTROPY_INTERVAL;
}
/** Periodic callback: if there has been no network usage in a while,
* enter a dormant state. */
STATIC int
check_network_participation_callback(time_t now, const or_options_t *options)
{
/* If we're a server, we can't become dormant. */
if (server_mode(options)) {
goto found_activity;
}
/* If we're running an onion service, we can't become dormant. */
/* XXXX this would be nice to change, so that we can be dormant with a
* service. */
if (hs_service_get_num_services() || rend_num_services()) {
goto found_activity;
}
/* If we have any currently open entry streams other than "linked"
* connections used for directory requests, those count as user activity.
*/
if (options->DormantTimeoutDisabledByIdleStreams) {
if (connection_get_by_type_nonlinked(CONN_TYPE_AP) != NULL) {
goto found_activity;
}
}
/* XXXX Make this configurable? */
/** How often do we check whether we have had network activity? */
#define CHECK_PARTICIPATION_INTERVAL (5*60)
/* Become dormant if there has been no user activity in a long time.
* (The funny checks below are in order to prevent overflow.) */
time_t time_since_last_activity = 0;
if (get_last_user_activity_time() < now)
time_since_last_activity = now - get_last_user_activity_time();
if (time_since_last_activity >= options->DormantClientTimeout) {
log_notice(LD_GENERAL, "No user activity in a long time: becoming"
" dormant.");
set_network_participation(false);
rescan_periodic_events(options);
}
return CHECK_PARTICIPATION_INTERVAL;
found_activity:
note_user_activity(now);
return CHECK_PARTICIPATION_INTERVAL;
}
/**
* Periodic callback: if we're an authority, make sure we test
* the routers on the network for reachability.
*/
static int
launch_reachability_tests_callback(time_t now, const or_options_t *options)
{
if (authdir_mode_tests_reachability(options) &&
!net_is_disabled()) {
/* try to determine reachability of the other Tor relays */
dirserv_test_reachability(now);
}
return REACHABILITY_TEST_INTERVAL;
}
/**
* Periodic callback: if we're an authority, discount the stability
* information (and other rephist information) that's older.
*/
static int
downrate_stability_callback(time_t now, const or_options_t *options)
{
(void)options;
/* 1d. Periodically, we discount older stability information so that new
* stability info counts more, and save the stability information to disk as
* appropriate. */
time_t next = rep_hist_downrate_old_runs(now);
return safe_timer_diff(now, next);
}
/**
* Periodic callback: if we're an authority, record our measured stability
* information from rephist in an mtbf file.
*/
static int
save_stability_callback(time_t now, const or_options_t *options)
{
if (authdir_mode_tests_reachability(options)) {
if (rep_hist_record_mtbf_data(now, 1)<0) {
log_warn(LD_GENERAL, "Couldn't store mtbf data.");
}
}
#define SAVE_STABILITY_INTERVAL (30*60)
return SAVE_STABILITY_INTERVAL;
}
/**
* Periodic callback: if we're an authority, check on our authority
* certificate (the one that authenticates our authority signing key).
*/
static int
check_authority_cert_callback(time_t now, const or_options_t *options)
{
(void)now;
(void)options;
/* 1e. Periodically, if we're a v3 authority, we check whether our cert is
* close to expiring and warn the admin if it is. */
v3_authority_check_key_expiry();
#define CHECK_V3_CERTIFICATE_INTERVAL (5*60)
return CHECK_V3_CERTIFICATE_INTERVAL;
}
/**
* Scheduled callback: Run directory-authority voting functionality.
*
* The schedule is a bit complicated here, so dirvote_act() manages the
* schedule itself.
**/
static int
dirvote_callback(time_t now, const or_options_t *options)
{
if (!authdir_mode_v3(options)) {
tor_assert_nonfatal_unreached();
return 3600;
}
time_t next = dirvote_act(options, now);
if (BUG(next == TIME_MAX)) {
/* This shouldn't be returned unless we called dirvote_act() without
* being an authority. If it happens, maybe our configuration will
* fix itself in an hour or so? */
return 3600;
}
return safe_timer_diff(now, next);
}
/** Reschedule the directory-authority voting event. Run this whenever the
* schedule has changed. */
void
reschedule_dirvote(const or_options_t *options)
{
if (periodic_events_initialized && authdir_mode_v3(options)) {
periodic_event_reschedule(dirvote_event);
}
}
/**
* Periodic callback: If our consensus is too old, recalculate whether
* we can actually use it.
*/
static int
check_expired_networkstatus_callback(time_t now, const or_options_t *options)
{
(void)options;
/* Check whether our networkstatus has expired. */
networkstatus_t *ns = networkstatus_get_latest_consensus();
/* Use reasonably live consensuses until they are no longer reasonably live.
*/
if (ns && !networkstatus_consensus_reasonably_live(ns, now) &&
router_have_minimum_dir_info()) {
router_dir_info_changed();
}
#define CHECK_EXPIRED_NS_INTERVAL (2*60)
return CHECK_EXPIRED_NS_INTERVAL;
}
/**
* Scheduled callback: Save the state file to disk if appropriate.
*/
static int
save_state_callback(time_t now, const or_options_t *options)
{
(void) options;
(void) or_state_save(now); // only saves if appropriate
const time_t next_write = get_or_state()->next_write;
if (next_write == TIME_MAX) {
return 86400;
}
return safe_timer_diff(now, next_write);
}
/** Reschedule the event for saving the state file.
*
* Run this when the state becomes dirty. */
void
reschedule_or_state_save(void)
{
if (save_state_event == NULL) {
/* This can happen early on during startup. */
return;
}
periodic_event_reschedule(save_state_event);
}
/**
* Periodic callback: Write statistics to disk if appropriate.
*/
static int
write_stats_file_callback(time_t now, const or_options_t *options)
{
/* 1g. Check whether we should write statistics to disk.
*/
#define CHECK_WRITE_STATS_INTERVAL (60*60)
time_t next_time_to_write_stats_files = now + CHECK_WRITE_STATS_INTERVAL;
if (options->CellStatistics) {
time_t next_write =
rep_hist_buffer_stats_write(now);
if (next_write && next_write < next_time_to_write_stats_files)
next_time_to_write_stats_files = next_write;
}
if (options->DirReqStatistics) {
time_t next_write = geoip_dirreq_stats_write(now);
if (next_write && next_write < next_time_to_write_stats_files)
next_time_to_write_stats_files = next_write;
}
if (options->EntryStatistics) {
time_t next_write = geoip_entry_stats_write(now);
if (next_write && next_write < next_time_to_write_stats_files)
next_time_to_write_stats_files = next_write;
}
if (options->HiddenServiceStatistics) {
time_t next_write = rep_hist_hs_stats_write(now);
if (next_write && next_write < next_time_to_write_stats_files)
next_time_to_write_stats_files = next_write;
}
if (options->ExitPortStatistics) {
time_t next_write = rep_hist_exit_stats_write(now);
if (next_write && next_write < next_time_to_write_stats_files)
next_time_to_write_stats_files = next_write;
}
if (options->ConnDirectionStatistics) {
time_t next_write = rep_hist_conn_stats_write(now);
if (next_write && next_write < next_time_to_write_stats_files)
next_time_to_write_stats_files = next_write;
}
if (options->BridgeAuthoritativeDir) {
time_t next_write = rep_hist_desc_stats_write(now);
if (next_write && next_write < next_time_to_write_stats_files)
next_time_to_write_stats_files = next_write;
}
return safe_timer_diff(now, next_time_to_write_stats_files);
}
#define CHANNEL_CHECK_INTERVAL (60*60)
static int
check_canonical_channels_callback(time_t now, const or_options_t *options)
{
(void)now;
if (public_server_mode(options))
channel_check_for_duplicates();
return CHANNEL_CHECK_INTERVAL;
}
static int
reset_padding_counts_callback(time_t now, const or_options_t *options)
{
if (options->PaddingStatistics) {
rep_hist_prep_published_padding_counts(now);
}
rep_hist_reset_padding_counts();
return REPHIST_CELL_PADDING_COUNTS_INTERVAL;
}
static int should_init_bridge_stats = 1;
/**
* Periodic callback: Write bridge statistics to disk if appropriate.
*/
static int
record_bridge_stats_callback(time_t now, const or_options_t *options)
{
/* 1h. Check whether we should write bridge statistics to disk.
*/
if (should_record_bridge_info(options)) {
if (should_init_bridge_stats) {
/* (Re-)initialize bridge statistics. */
geoip_bridge_stats_init(now);
should_init_bridge_stats = 0;
return WRITE_STATS_INTERVAL;
} else {
/* Possibly write bridge statistics to disk and ask when to write
* them next time. */
time_t next = geoip_bridge_stats_write(now);
return safe_timer_diff(now, next);
}
} else if (!should_init_bridge_stats) {
/* Bridge mode was turned off. Ensure that stats are re-initialized
* next time bridge mode is turned on. */
should_init_bridge_stats = 1;
}
return PERIODIC_EVENT_NO_UPDATE;
}
/**
* Periodic callback: Clean in-memory caches every once in a while
*/
static int
clean_caches_callback(time_t now, const or_options_t *options)
{
/* Remove old information from rephist and the rend cache. */
rep_history_clean(now - options->RephistTrackTime);
rend_cache_clean(now, REND_CACHE_TYPE_SERVICE);
hs_cache_clean_as_client(now);
hs_cache_clean_as_dir(now);
microdesc_cache_rebuild(NULL, 0);
#define CLEAN_CACHES_INTERVAL (30*60)
return CLEAN_CACHES_INTERVAL;
}
/**
* Periodic callback: Clean the cache of failed hidden service lookups
* frequently.
*/
static int
rend_cache_failure_clean_callback(time_t now, const or_options_t *options)
{
(void)options;
/* We don't keep entries that are more than five minutes old so we try to
* clean it as soon as we can since we want to make sure the client waits
* as little as possible for reachability reasons. */
rend_cache_failure_clean(now);
hs_cache_client_intro_state_clean(now);
return 30;
}
/**
* Periodic callback: If we're a server and initializing dns failed, retry.
*/
static int
retry_dns_callback(time_t now, const or_options_t *options)
{
(void)now;
#define RETRY_DNS_INTERVAL (10*60)
if (server_mode(options) && has_dns_init_failed())
dns_init();
return RETRY_DNS_INTERVAL;
}
/**
* Periodic callback: prune routerlist of old information about Tor network.
*/
static int
prune_old_routers_callback(time_t now, const or_options_t *options)
{
#define ROUTERLIST_PRUNING_INTERVAL (60*60) // 1 hour.
(void)now;
(void)options;
if (!net_is_disabled()) {
/* If any networkstatus documents are no longer recent, we need to
* update all the descriptors' running status. */
/* Remove dead routers. */
log_debug(LD_GENERAL, "Pruning routerlist...");
routerlist_remove_old_routers();
}
return ROUTERLIST_PRUNING_INTERVAL;
}
/** Periodic callback: consider rebuilding or and re-uploading our descriptor
* (if we've passed our internal checks). */
static int
check_descriptor_callback(time_t now, const or_options_t *options)
{
/** How often do we check whether part of our router info has changed in a
* way that would require an upload? That includes checking whether our IP
* address has changed. */
#define CHECK_DESCRIPTOR_INTERVAL (60)
(void)options;
/* 2b. Once per minute, regenerate and upload the descriptor if the old
* one is inaccurate. */
if (!net_is_disabled()) {
check_descriptor_bandwidth_changed(now);
check_descriptor_ipaddress_changed(now);
mark_my_descriptor_dirty_if_too_old(now);
consider_publishable_server(0);
}
return CHECK_DESCRIPTOR_INTERVAL;
}
/**
* Periodic callback: check whether we're reachable (as a relay), and
* whether our bandwidth has changed enough that we need to
* publish a new descriptor.
*/
static int
check_for_reachability_bw_callback(time_t now, const or_options_t *options)
{
/* XXXX This whole thing was stuck in the middle of what is now
* XXXX check_descriptor_callback. I'm not sure it's right. */
static int dirport_reachability_count = 0;
/* also, check religiously for reachability, if it's within the first
* 20 minutes of our uptime. */
if (server_mode(options) &&
(have_completed_a_circuit() || !any_predicted_circuits(now)) &&
!net_is_disabled()) {
if (get_uptime() < TIMEOUT_UNTIL_UNREACHABILITY_COMPLAINT) {
router_do_reachability_checks(1, dirport_reachability_count==0);
if (++dirport_reachability_count > 5)
dirport_reachability_count = 0;
return 1;
} else {
/* If we haven't checked for 12 hours and our bandwidth estimate is
* low, do another bandwidth test. This is especially important for
* bridges, since they might go long periods without much use. */
const routerinfo_t *me = router_get_my_routerinfo();
static int first_time = 1;
if (!first_time && me &&
me->bandwidthcapacity < me->bandwidthrate &&
me->bandwidthcapacity < 51200) {
reset_bandwidth_test();
}
first_time = 0;
#define BANDWIDTH_RECHECK_INTERVAL (12*60*60)
return BANDWIDTH_RECHECK_INTERVAL;
}
}
return CHECK_DESCRIPTOR_INTERVAL;
}
/**
* Periodic event: once a minute, (or every second if TestingTorNetwork, or
* during client bootstrap), check whether we want to download any
* networkstatus documents. */
static int
fetch_networkstatus_callback(time_t now, const or_options_t *options)
{
/* How often do we check whether we should download network status
* documents? */
const int we_are_bootstrapping = networkstatus_consensus_is_bootstrapping(
now);
const int prefer_mirrors = !directory_fetches_from_authorities(
get_options());
int networkstatus_dl_check_interval = 60;
/* check more often when testing, or when bootstrapping from mirrors
* (connection limits prevent too many connections being made) */
if (options->TestingTorNetwork
|| (we_are_bootstrapping && prefer_mirrors)) {
networkstatus_dl_check_interval = 1;
}
if (should_delay_dir_fetches(options, NULL))
return PERIODIC_EVENT_NO_UPDATE;
update_networkstatus_downloads(now);
return networkstatus_dl_check_interval;
}
/**
* Periodic callback: Every 60 seconds, we relaunch listeners if any died. */
static int
retry_listeners_callback(time_t now, const or_options_t *options)
{
(void)now;
(void)options;
if (!net_is_disabled()) {
retry_all_listeners(NULL, 0);
return 60;
}
return PERIODIC_EVENT_NO_UPDATE;
}
/**
* Periodic callback: as a server, see if we have any old unused circuits
* that should be expired */
static int
expire_old_ciruits_serverside_callback(time_t now, const or_options_t *options)
{
(void)options;
/* every 11 seconds, so not usually the same second as other such events */
circuit_expire_old_circuits_serverside(now);
return 11;
}
/**
* Callback: Send warnings if Tor doesn't find its ports reachable.
*/
static int
reachability_warnings_callback(time_t now, const or_options_t *options)
{
(void) now;
if (get_uptime() < TIMEOUT_UNTIL_UNREACHABILITY_COMPLAINT) {
return (int)(TIMEOUT_UNTIL_UNREACHABILITY_COMPLAINT - get_uptime());
}
if (server_mode(options) &&
!net_is_disabled() &&
have_completed_a_circuit()) {
/* every 20 minutes, check and complain if necessary */
const routerinfo_t *me = router_get_my_routerinfo();
if (me && !check_whether_orport_reachable(options)) {
char *address = tor_dup_ip(me->addr);
log_warn(LD_CONFIG,"Your server (%s:%d) has not managed to confirm that "
"its ORPort is reachable. Relays do not publish descriptors "
"until their ORPort and DirPort are reachable. Please check "
"your firewalls, ports, address, /etc/hosts file, etc.",
address, me->or_port);
control_event_server_status(LOG_WARN,
"REACHABILITY_FAILED ORADDRESS=%s:%d",
address, me->or_port);
tor_free(address);
}
if (me && !check_whether_dirport_reachable(options)) {
char *address = tor_dup_ip(me->addr);
log_warn(LD_CONFIG,
"Your server (%s:%d) has not managed to confirm that its "
"DirPort is reachable. Relays do not publish descriptors "
"until their ORPort and DirPort are reachable. Please check "
"your firewalls, ports, address, /etc/hosts file, etc.",
address, me->dir_port);
control_event_server_status(LOG_WARN,
"REACHABILITY_FAILED DIRADDRESS=%s:%d",
address, me->dir_port);
tor_free(address);
}
}
return TIMEOUT_UNTIL_UNREACHABILITY_COMPLAINT;
}
static int dns_honesty_first_time = 1;
/**
* Periodic event: if we're an exit, see if our DNS server is telling us
* obvious lies.
*/
static int
check_dns_honesty_callback(time_t now, const or_options_t *options)
{
(void)now;
/* 9. and if we're an exit node, check whether our DNS is telling stories
* to us. */
if (net_is_disabled() ||
! public_server_mode(options) ||
router_my_exit_policy_is_reject_star())
return PERIODIC_EVENT_NO_UPDATE;
if (dns_honesty_first_time) {
/* Don't launch right when we start */
dns_honesty_first_time = 0;
return crypto_rand_int_range(60, 180);
}
dns_launch_correctness_checks();
return 12*3600 + crypto_rand_int(12*3600);
}
/**
* Periodic callback: if we're the bridge authority, write a networkstatus
* file to disk.
*/
static int
write_bridge_ns_callback(time_t now, const or_options_t *options)
{
/* 10. write bridge networkstatus file to disk */
if (options->BridgeAuthoritativeDir) {
networkstatus_dump_bridge_status_to_file(now);
#define BRIDGE_STATUSFILE_INTERVAL (30*60)
return BRIDGE_STATUSFILE_INTERVAL;
}
return PERIODIC_EVENT_NO_UPDATE;
}
static int heartbeat_callback_first_time = 1;
/**
* Periodic callback: write the heartbeat message in the logs.
*
* If writing the heartbeat message to the logs fails for some reason, retry
* again after <b>MIN_HEARTBEAT_PERIOD</b> seconds.
*/
static int
heartbeat_callback(time_t now, const or_options_t *options)
{
/* Check if heartbeat is disabled */
if (!options->HeartbeatPeriod) {
return PERIODIC_EVENT_NO_UPDATE;
}
/* Skip the first one. */
if (heartbeat_callback_first_time) {
heartbeat_callback_first_time = 0;
return options->HeartbeatPeriod;
}
/* Write the heartbeat message */
if (log_heartbeat(now) == 0) {
return options->HeartbeatPeriod;
} else {
/* If we couldn't write the heartbeat log message, try again in the minimum
* interval of time. */
return MIN_HEARTBEAT_PERIOD;
}
}
#define CDM_CLEAN_CALLBACK_INTERVAL 600
static int
clean_consdiffmgr_callback(time_t now, const or_options_t *options)
{
(void)now;
if (dir_server_mode(options)) {
consdiffmgr_cleanup();
}
return CDM_CLEAN_CALLBACK_INTERVAL;
}
/*
* Periodic callback: Run scheduled events for HS service. This is called
* every second.
*/
static int
hs_service_callback(time_t now, const or_options_t *options)
{
(void) options;
/* We need to at least be able to build circuits and that we actually have
* a working network. */
if (!have_completed_a_circuit() || net_is_disabled() ||
networkstatus_get_live_consensus(now) == NULL) {
goto end;
}
hs_service_run_scheduled_events(now);
end:
/* Every 1 second. */
return 1;
}
/*
* Periodic callback: Send once-per-second events to the controller(s).
* This is called every second.
*/
static int
control_per_second_events_callback(time_t now, const or_options_t *options)
{
(void) options;
(void) now;
control_per_second_events();
return 1;
}
/** Last time that update_current_time was called. */
static time_t current_second = 0;
/** Last time that update_current_time updated current_second. */
static monotime_coarse_t current_second_last_changed;
/**
* Set the current time to "now", which should be the value returned by
* time(). Check for clock jumps and track the total number of seconds we
* have been running.
*/
void
update_current_time(time_t now)
{
if (PREDICT_LIKELY(now == current_second)) {
/* We call this function a lot. Most frequently, the current second
* will not have changed, so we just return. */
return;
}
const time_t seconds_elapsed = current_second ? (now - current_second) : 0;
/* Check the wall clock against the monotonic clock, so we can
* better tell idleness from clock jumps and/or other shenanigans. */
monotime_coarse_t last_updated;
memcpy(&last_updated, &current_second_last_changed, sizeof(last_updated));
monotime_coarse_get(&current_second_last_changed);
/** How much clock jumping means that we should adjust our idea of when
* to go dormant? */
#define NUM_JUMPED_SECONDS_BEFORE_NETSTATUS_UPDATE 20
/* Don't go dormant early or late just because we jumped in time. */
if (ABS(seconds_elapsed) >= NUM_JUMPED_SECONDS_BEFORE_NETSTATUS_UPDATE) {
if (is_participating_on_network()) {
netstatus_note_clock_jumped(seconds_elapsed);
}
}
/** How much clock jumping do we tolerate? */
#define NUM_JUMPED_SECONDS_BEFORE_WARN 100
/** How much idleness do we tolerate? */
#define NUM_IDLE_SECONDS_BEFORE_WARN 3600
if (seconds_elapsed < -NUM_JUMPED_SECONDS_BEFORE_WARN) {
// moving back in time is always a bad sign.
circuit_note_clock_jumped(seconds_elapsed, false);
} else if (seconds_elapsed >= NUM_JUMPED_SECONDS_BEFORE_WARN) {
/* Compare the monotonic clock to the result of time(). */
const int32_t monotime_msec_passed =
monotime_coarse_diff_msec32(&last_updated,
&current_second_last_changed);
const int monotime_sec_passed = monotime_msec_passed / 1000;
const int discrepancy = monotime_sec_passed - (int)seconds_elapsed;
/* If the monotonic clock deviates from time(NULL), we have a couple of
* possibilities. On some systems, this means we have been suspended or
* sleeping. Everywhere, it can mean that the wall-clock time has
* been changed -- for example, with settimeofday().
*
* On the other hand, if the monotonic time matches with the wall-clock
* time, we've probably just been idle for a while, with no events firing.
* we tolerate much more of that.
*/
const bool clock_jumped = abs(discrepancy) > 2;
if (clock_jumped || seconds_elapsed >= NUM_IDLE_SECONDS_BEFORE_WARN) {
circuit_note_clock_jumped(seconds_elapsed, ! clock_jumped);
}
} else if (seconds_elapsed > 0) {
stats_n_seconds_working += seconds_elapsed;
}
update_approx_time(now);
current_second = now;
}
#ifdef HAVE_SYSTEMD_209
static periodic_timer_t *systemd_watchdog_timer = NULL;
/** Libevent callback: invoked to reset systemd watchdog. */
static void
systemd_watchdog_callback(periodic_timer_t *timer, void *arg)
{
(void)timer;
(void)arg;
sd_notify(0, "WATCHDOG=1");
}
#endif /* defined(HAVE_SYSTEMD_209) */
#define UPTIME_CUTOFF_FOR_NEW_BANDWIDTH_TEST (6*60*60)
/** Called when our IP address seems to have changed. <b>at_interface</b>
* should be true if we detected a change in our interface, and false if we
* detected a change in our published address. */
void
ip_address_changed(int at_interface)
{
const or_options_t *options = get_options();
int server = server_mode(options);
int exit_reject_interfaces = (server && options->ExitRelay
&& options->ExitPolicyRejectLocalInterfaces);
if (at_interface) {
if (! server) {
/* Okay, change our keys. */
if (init_keys_client() < 0)
log_warn(LD_GENERAL, "Unable to rotate keys after IP change!");
}
} else {
if (server) {
if (get_uptime() > UPTIME_CUTOFF_FOR_NEW_BANDWIDTH_TEST)
reset_bandwidth_test();
reset_uptime();
router_reset_reachability();
}
}
/* Exit relays incorporate interface addresses in their exit policies when
* ExitPolicyRejectLocalInterfaces is set */
if (exit_reject_interfaces || (server && !at_interface)) {
mark_my_descriptor_dirty("IP address changed");
}
dns_servers_relaunch_checks();
}
/** Forget what we've learned about the correctness of our DNS servers, and
* start learning again. */
void
dns_servers_relaunch_checks(void)
{
if (server_mode(get_options())) {
dns_reset_correctness_checks();
if (periodic_events_initialized) {
tor_assert(check_dns_honesty_event);
periodic_event_reschedule(check_dns_honesty_event);
}
}
}
/** Initialize some mainloop_event_t objects that we require. */
void
initialize_mainloop_events(void)
{
initialize_periodic_events();
if (!schedule_active_linked_connections_event) {
schedule_active_linked_connections_event =
mainloop_event_postloop_new(schedule_active_linked_connections_cb, NULL);
}
if (!postloop_cleanup_ev) {
postloop_cleanup_ev =
mainloop_event_postloop_new(postloop_cleanup_cb, NULL);
}
}
/** Tor main loop. */
int
do_main_loop(void)
{
/* initialize the periodic events first, so that code that depends on the
* events being present does not assert.
*/
initialize_periodic_events();
initialize_mainloop_events();
#ifdef HAVE_SYSTEMD_209
uint64_t watchdog_delay;
/* set up systemd watchdog notification. */
if (sd_watchdog_enabled(1, &watchdog_delay) > 0) {
if (! systemd_watchdog_timer) {
struct timeval watchdog;
/* The manager will "act on" us if we don't send them a notification
* every 'watchdog_delay' microseconds. So, send notifications twice
* that often. */
watchdog_delay /= 2;
watchdog.tv_sec = watchdog_delay / 1000000;
watchdog.tv_usec = watchdog_delay % 1000000;
systemd_watchdog_timer = periodic_timer_new(tor_libevent_get_base(),
&watchdog,
systemd_watchdog_callback,
NULL);
tor_assert(systemd_watchdog_timer);
}
}
#endif /* defined(HAVE_SYSTEMD_209) */
#ifdef ENABLE_RESTART_DEBUGGING
{
static int first_time = 1;
if (first_time && getenv("TOR_DEBUG_RESTART")) {
first_time = 0;
const char *sec_str = getenv("TOR_DEBUG_RESTART_AFTER_SECONDS");
long sec;
int sec_ok=0;
if (sec_str &&
(sec = tor_parse_long(sec_str, 10, 0, INT_MAX, &sec_ok, NULL)) &&
sec_ok) {
/* Okay, we parsed the seconds. */
} else {
sec = 5;
}
struct timeval restart_after = { (time_t) sec, 0 };
tor_shutdown_event_loop_for_restart_event =
tor_evtimer_new(tor_libevent_get_base(),
tor_shutdown_event_loop_for_restart_cb, NULL);
event_add(tor_shutdown_event_loop_for_restart_event, &restart_after);
}
}
#endif
return run_main_loop_until_done();
}
#ifndef _WIN32
/** Rate-limiter for EINVAL-type libevent warnings. */
static ratelim_t libevent_error_ratelim = RATELIM_INIT(10);
#endif
/**
* Run the main loop a single time. Return 0 for "exit"; -1 for "exit with
* error", and 1 for "run this again."
*/
static int
run_main_loop_once(void)
{
int loop_result;
if (nt_service_is_stopping())
return 0;
if (main_loop_should_exit)
return 0;
#ifndef _WIN32
/* Make it easier to tell whether libevent failure is our fault or not. */
errno = 0;
#endif
if (get_options()->MainloopStats) {
/* We always enforce that EVLOOP_ONCE is passed to event_base_loop() if we
* are collecting main loop statistics. */
called_loop_once = 1;
} else {
called_loop_once = 0;
}
/* Make sure we know (about) what time it is. */
update_approx_time(time(NULL));
/* Here it is: the main loop. Here we tell Libevent to poll until we have
* an event, or the second ends, or until we have some active linked
* connections to trigger events for. Libevent will wait till one
* of these happens, then run all the appropriate callbacks. */
loop_result = tor_libevent_run_event_loop(tor_libevent_get_base(),
called_loop_once);
if (get_options()->MainloopStats) {
/* Update our main loop counters. */
if (loop_result == 0) {
// The call was successful.
increment_main_loop_success_count();
} else if (loop_result == -1) {
// The call was erroneous.
increment_main_loop_error_count();
} else if (loop_result == 1) {
// The call didn't have any active or pending events
// to handle.
increment_main_loop_idle_count();
}
}
/* Oh, the loop failed. That might be an error that we need to
* catch, but more likely, it's just an interrupted poll() call or something,
* and we should try again. */
if (loop_result < 0) {
int e = tor_socket_errno(-1);
/* let the program survive things like ^z */
if (e != EINTR && !ERRNO_IS_EINPROGRESS(e)) {
log_err(LD_NET,"libevent call with %s failed: %s [%d]",
tor_libevent_get_method(), tor_socket_strerror(e), e);
return -1;
#ifndef _WIN32
} else if (e == EINVAL) {
log_fn_ratelim(&libevent_error_ratelim, LOG_WARN, LD_NET,
"EINVAL from libevent: should you upgrade libevent?");
if (libevent_error_ratelim.n_calls_since_last_time > 8) {
log_err(LD_NET, "Too many libevent errors, too fast: dying");
return -1;
}
#endif /* !defined(_WIN32) */
} else {
tor_assert_nonfatal_once(! ERRNO_IS_EINPROGRESS(e));
log_debug(LD_NET,"libevent call interrupted.");
/* You can't trust the results of this poll(). Go back to the
* top of the big for loop. */
return 1;
}
}
if (main_loop_should_exit)
return 0;
return 1;
}
/** Run the run_main_loop_once() function until it declares itself done,
* and return its final return value.
*
* Shadow won't invoke this function, so don't fill it up with things.
*/
STATIC int
run_main_loop_until_done(void)
{
int loop_result = 1;
main_loop_should_exit = 0;
main_loop_exit_value = 0;
do {
loop_result = run_main_loop_once();
} while (loop_result == 1);
if (main_loop_should_exit)
return main_loop_exit_value;
else
return loop_result;
}
/** Returns Tor's uptime. */
MOCK_IMPL(long,
get_uptime,(void))
{
return stats_n_seconds_working;
}
/** Reset Tor's uptime. */
MOCK_IMPL(void,
reset_uptime,(void))
{
stats_n_seconds_working = 0;
}
void
tor_mainloop_free_all(void)
{
smartlist_free(connection_array);
smartlist_free(closeable_connection_lst);
smartlist_free(active_linked_connection_lst);
teardown_periodic_events();
tor_event_free(shutdown_did_not_work_event);
tor_event_free(initialize_periodic_events_event);
mainloop_event_free(directory_all_unreachable_cb_event);
mainloop_event_free(schedule_active_linked_connections_event);
mainloop_event_free(postloop_cleanup_ev);
mainloop_event_free(handle_deferred_signewnym_ev);
mainloop_event_free(scheduled_shutdown_ev);
mainloop_event_free(rescan_periodic_events_ev);
#ifdef HAVE_SYSTEMD_209
periodic_timer_free(systemd_watchdog_timer);
#endif
stats_n_bytes_read = stats_n_bytes_written = 0;
memset(&global_bucket, 0, sizeof(global_bucket));
memset(&global_relayed_bucket, 0, sizeof(global_relayed_bucket));
time_of_process_start = 0;
time_of_last_signewnym = 0;
signewnym_is_pending = 0;
newnym_epoch = 0;
called_loop_once = 0;
main_loop_should_exit = 0;
main_loop_exit_value = 0;
can_complete_circuits = 0;
quiet_level = 0;
should_init_bridge_stats = 1;
dns_honesty_first_time = 1;
heartbeat_callback_first_time = 1;
current_second = 0;
memset(&current_second_last_changed, 0,
sizeof(current_second_last_changed));
}
Reference in a new issue View git blame Copy permalink