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premiere-libtorrent/src/session_impl.cpp

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/*
Copyright (c) 2006-2016, Arvid Norberg, Magnus Jonsson
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions
are met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in
the documentation and/or other materials provided with the distribution.
* Neither the name of the author nor the names of its
contributors may be used to endorse or promote products derived
from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
*/
#include "libtorrent/config.hpp"
#include "libtorrent/aux_/disable_warnings_push.hpp"
#include <ctime>
#include <algorithm>
#include <cctype>
#include <algorithm>
#if defined TORRENT_DEBUG && !defined TORRENT_DISABLE_INVARIANT_CHECKS
#if TORRENT_HAS_BOOST_UNORDERED
#include <boost/unordered_set.hpp>
#else
#include <set>
#endif
#endif // TORRENT_DEBUG && !TORRENT_DISABLE_INVARIANT_CHECKS
#include <boost/limits.hpp>
#include <boost/bind.hpp>
#include <boost/function_equal.hpp>
#include <boost/make_shared.hpp>
#include <boost/asio/ip/v6_only.hpp>
#ifdef TORRENT_USE_VALGRIND
#include <valgrind/memcheck.h>
#endif
#if TORRENT_USE_RLIMIT
#ifdef __GNUC__
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wlong-long"
#endif // __GNUC__
#include <sys/resource.h>
// capture this here where warnings are disabled (the macro generates warnings)
const rlim_t rlim_infinity = RLIM_INFINITY;
#ifdef __GNUC__
#pragma GCC diagnostic pop
#endif // __GNUC__
#endif // TORRENT_USE_RLIMIT
#include "libtorrent/aux_/disable_warnings_pop.hpp"
#include "libtorrent/aux_/openssl.hpp"
#include "libtorrent/peer_id.hpp"
#include "libtorrent/torrent_info.hpp"
#include "libtorrent/tracker_manager.hpp"
#include "libtorrent/bencode.hpp"
#include "libtorrent/hasher.hpp"
#include "libtorrent/entry.hpp"
#include "libtorrent/session.hpp"
#include "libtorrent/fingerprint.hpp"
#include "libtorrent/entry.hpp"
#include "libtorrent/alert_types.hpp"
#include "libtorrent/invariant_check.hpp"
#include "libtorrent/file.hpp"
#include "libtorrent/bt_peer_connection.hpp"
#include "libtorrent/peer_connection_handle.hpp"
#include "libtorrent/ip_filter.hpp"
#include "libtorrent/socket.hpp"
#include "libtorrent/session_stats.hpp"
#include "libtorrent/aux_/session_impl.hpp"
#ifndef TORRENT_DISABLE_DHT
#include "libtorrent/kademlia/dht_tracker.hpp"
#endif
#include "libtorrent/enum_net.hpp"
#include "libtorrent/config.hpp"
#include "libtorrent/utf8.hpp"
#include "libtorrent/upnp.hpp"
#include "libtorrent/natpmp.hpp"
#include "libtorrent/lsd.hpp"
#include "libtorrent/instantiate_connection.hpp"
#include "libtorrent/peer_info.hpp"
#include "libtorrent/build_config.hpp"
#include "libtorrent/extensions.hpp"
#include "libtorrent/random.hpp"
#include "libtorrent/magnet_uri.hpp"
#include "libtorrent/aux_/session_settings.hpp"
#include "libtorrent/torrent_peer.hpp"
#include "libtorrent/torrent_handle.hpp"
#include "libtorrent/choker.hpp"
#include "libtorrent/error.hpp"
#include "libtorrent/platform_util.hpp"
#ifndef TORRENT_DISABLE_LOGGING
#include "libtorrent/socket_io.hpp"
// for logging stat layout
#include "libtorrent/stat.hpp"
// for logging the size of DHT structures
#ifndef TORRENT_DISABLE_DHT
#include <libtorrent/kademlia/find_data.hpp>
#include <libtorrent/kademlia/refresh.hpp>
#include <libtorrent/kademlia/node.hpp>
#include <libtorrent/kademlia/observer.hpp>
#include <libtorrent/kademlia/item.hpp>
#endif // TORRENT_DISABLE_DHT
#include "libtorrent/http_tracker_connection.hpp"
#include "libtorrent/udp_tracker_connection.hpp"
#endif // TORRENT_DISABLE_LOGGING
#ifdef TORRENT_USE_GCRYPT
extern "C" {
GCRY_THREAD_OPTION_PTHREAD_IMPL;
}
namespace
{
// libgcrypt requires this to initialize the library
struct gcrypt_setup
{
gcrypt_setup()
{
gcry_check_version(0);
gcry_error_t e = gcry_control(GCRYCTL_SET_THREAD_CBS, &gcry_threads_pthread);
if (e != 0) fprintf(stderr, "libcrypt ERROR: %s\n", gcry_strerror(e));
e = gcry_control(GCRYCTL_INITIALIZATION_FINISHED, 0);
if (e != 0) fprintf(stderr, "initialization finished error: %s\n", gcry_strerror(e));
}
} gcrypt_global_constructor;
}
#endif // TORRENT_USE_GCRYPT
#ifdef TORRENT_USE_OPENSSL
#include <openssl/crypto.h>
#include <openssl/rand.h>
namespace
{
// openssl requires this to clean up internal
// structures it allocates
struct openssl_cleanup
{
~openssl_cleanup() { CRYPTO_cleanup_all_ex_data(); }
} openssl_global_destructor;
}
#endif // TORRENT_USE_OPENSSL
#ifdef TORRENT_WINDOWS
// for ERROR_SEM_TIMEOUT
#include <winerror.h>
#endif
using boost::shared_ptr;
using boost::weak_ptr;
using libtorrent::aux::session_impl;
#ifdef BOOST_NO_EXCEPTIONS
namespace boost {
void throw_exception(std::exception const& e) { ::abort(); }
}
#endif
namespace libtorrent {
#if defined TORRENT_ASIO_DEBUGGING
std::map<std::string, async_t> _async_ops;
std::deque<wakeup_t> _wakeups;
int _async_ops_nthreads = 0;
mutex _async_ops_mutex;
#endif
socket_job::~socket_job() {}
void network_thread_pool::process_job(socket_job const& j, bool post)
{
TORRENT_UNUSED(post);
if (j.type == socket_job::write_job)
{
TORRENT_ASSERT(j.peer->m_socket_is_writing);
j.peer->get_socket()->async_write_some(
*j.vec, j.peer->make_write_handler(boost::bind(
&peer_connection::on_send_data, j.peer, _1, _2)));
}
else
{
if (j.recv_buf)
{
j.peer->get_socket()->async_read_some(boost::asio::buffer(j.recv_buf, j.buf_size)
, j.peer->make_read_handler(boost::bind(
&peer_connection::on_receive_data, j.peer, _1, _2)));
}
else
{
j.peer->get_socket()->async_read_some(j.read_vec
, j.peer->make_read_handler(boost::bind(
&peer_connection::on_receive_data, j.peer, _1, _2)));
}
}
}
namespace aux {
void session_impl::init_peer_class_filter(bool unlimited_local)
{
// set the default peer_class_filter to use the local peer class
// for peers on local networks
boost::uint32_t lfilter = 1 << m_local_peer_class;
boost::uint32_t gfilter = 1 << m_global_class;
struct class_mapping
{
char const* first;
char const* last;
boost::uint32_t filter;
};
static const class_mapping v4_classes[] =
{
// everything
{"0.0.0.0", "255.255.255.255", gfilter},
// local networks
{"10.0.0.0", "10.255.255.255", lfilter},
{"172.16.0.0", "172.16.255.255", lfilter},
{"192.168.0.0", "192.168.255.255", lfilter},
// link-local
{"169.254.0.0", "169.254.255.255", lfilter},
// loop-back
{"127.0.0.0", "127.255.255.255", lfilter},
};
#if TORRENT_USE_IPV6
static const class_mapping v6_classes[] =
{
// everything
{"::0", "ffff:ffff:ffff:ffff:ffff:ffff:ffff:ffff", gfilter},
// link-local
{"fe80::", "febf::ffff:ffff:ffff:ffff:ffff:ffff:ffff", lfilter},
// loop-back
{"::1", "::1", lfilter},
};
#endif
class_mapping const* p = v4_classes;
int len = sizeof(v4_classes) / sizeof(v4_classes[0]);
if (!unlimited_local) len = 1;
for (int i = 0; i < len; ++i)
{
error_code ec;
address_v4 begin = address_v4::from_string(p[i].first, ec);
address_v4 end = address_v4::from_string(p[i].last, ec);
if (ec) continue;
m_peer_class_filter.add_rule(begin, end, p[i].filter);
}
#if TORRENT_USE_IPV6
p = v6_classes;
len = sizeof(v6_classes) / sizeof(v6_classes[0]);
if (!unlimited_local) len = 1;
for (int i = 0; i < len; ++i)
{
error_code ec;
address_v6 begin = address_v6::from_string(p[i].first, ec);
address_v6 end = address_v6::from_string(p[i].last, ec);
if (ec) continue;
m_peer_class_filter.add_rule(begin, end, p[i].filter);
}
#endif
}
#if defined TORRENT_USE_OPENSSL && BOOST_VERSION >= 104700 && OPENSSL_VERSION_NUMBER >= 0x90812f
namespace {
// when running bittorrent over SSL, the SNI (server name indication)
// extension is used to know which torrent the incoming connection is
// trying to connect to. The 40 first bytes in the name is expected to
// be the hex encoded info-hash
int servername_callback(SSL* s, int* ad, void* arg)
{
TORRENT_UNUSED(ad);
session_impl* ses = reinterpret_cast<session_impl*>(arg);
const char* servername = SSL_get_servername(s, TLSEXT_NAMETYPE_host_name);
if (!servername || strlen(servername) < 40)
return SSL_TLSEXT_ERR_ALERT_FATAL;
sha1_hash info_hash;
bool valid = from_hex(servername, 40, info_hash.data());
// the server name is not a valid hex-encoded info-hash
if (!valid)
return SSL_TLSEXT_ERR_ALERT_FATAL;
// see if there is a torrent with this info-hash
boost::shared_ptr<torrent> t = ses->find_torrent(info_hash).lock();
// if there isn't, fail
if (!t) return SSL_TLSEXT_ERR_ALERT_FATAL;
// if the torrent we found isn't an SSL torrent, also fail.
if (!t->is_ssl_torrent()) return SSL_TLSEXT_ERR_ALERT_FATAL;
// if the torrent doesn't have an SSL context and should not allow
// incoming SSL connections
if (!t->ssl_ctx()) return SSL_TLSEXT_ERR_ALERT_FATAL;
// use this torrent's certificate
SSL_CTX *torrent_context = t->ssl_ctx()->native_handle();
SSL_set_SSL_CTX(s, torrent_context);
SSL_set_verify(s, SSL_CTX_get_verify_mode(torrent_context), SSL_CTX_get_verify_callback(torrent_context));
return SSL_TLSEXT_ERR_OK;
}
} // anonymous namesoace
#endif
session_impl::session_impl(io_service& ios)
:
#ifndef TORRENT_NO_DEPRECATE
m_next_rss_update(min_time())
,
#endif
#ifndef TORRENT_DISABLE_POOL_ALLOCATOR
m_send_buffers(send_buffer_size())
,
#endif
m_io_service(ios)
#ifdef TORRENT_USE_OPENSSL
, m_ssl_ctx(m_io_service, boost::asio::ssl::context::sslv23)
#endif
, m_alerts(m_settings.get_int(settings_pack::alert_queue_size), alert::all_categories)
#ifndef TORRENT_NO_DEPRECATE
, m_alert_pointer_pos(0)
#endif
, m_disk_thread(m_io_service, m_stats_counters
, static_cast<uncork_interface*>(this))
, m_download_rate(peer_connection::download_channel)
, m_upload_rate(peer_connection::upload_channel)
, m_global_class(0)
, m_tcp_peer_class(0)
, m_local_peer_class(0)
, m_tracker_manager(m_udp_socket, m_stats_counters, m_host_resolver
, m_settings
#if !defined TORRENT_DISABLE_LOGGING || TORRENT_USE_ASSERTS
, *this
#endif
)
, m_num_save_resume(0)
, m_work(io_service::work(m_io_service))
, m_max_queue_pos(-1)
, m_key(0)
#if TORRENT_USE_I2P
, m_i2p_conn(m_io_service)
#endif
, m_socks_listen_port(0)
, m_interface_index(0)
, m_unchoke_time_scaler(0)
, m_auto_manage_time_scaler(0)
, m_optimistic_unchoke_time_scaler(0)
, m_disconnect_time_scaler(90)
, m_auto_scrape_time_scaler(180)
#ifndef TORRENT_NO_DEPRECATE
, m_next_explicit_cache_torrent(0)
, m_cache_rotation_timer(0)
#endif
, m_next_suggest_torrent(0)
, m_suggest_timer(0)
, m_peak_up_rate(0)
, m_peak_down_rate(0)
, m_created(clock_type::now())
, m_last_tick(m_created)
, m_last_second_tick(m_created - milliseconds(900))
, m_last_choke(m_created)
, m_last_auto_manage(m_created)
, m_next_port(0)
#ifndef TORRENT_DISABLE_DHT
, m_dht_storage_constructor(dht::dht_default_storage_constructor)
, m_dht_announce_timer(m_io_service)
, m_dht_interval_update_torrents(0)
, m_outstanding_router_lookups(0)
#endif
, m_external_udp_port(0)
, m_udp_socket(m_io_service)
, m_utp_socket_manager(m_settings, m_udp_socket, m_stats_counters, NULL
, boost::bind(&session_impl::incoming_connection, this, _1))
#ifdef TORRENT_USE_OPENSSL
, m_ssl_udp_socket(m_io_service)
, m_ssl_utp_socket_manager(m_settings, m_ssl_udp_socket, m_stats_counters
, &m_ssl_ctx
, boost::bind(&session_impl::on_incoming_utp_ssl, this, _1))
#endif
, m_boost_connections(0)
, m_timer(m_io_service)
, m_lsd_announce_timer(m_io_service)
, m_host_resolver(m_io_service)
, m_next_downloading_connect_torrent(0)
, m_next_finished_connect_torrent(0)
, m_download_connect_attempts(0)
, m_next_scrape_torrent(0)
, m_tick_residual(0)
#ifndef TORRENT_DISABLE_EXTENSIONS
, m_session_extension_features(0)
#endif
, m_deferred_submit_disk_jobs(false)
, m_pending_auto_manage(false)
, m_need_auto_manage(false)
, m_abort(false)
, m_paused(false)
{
#if TORRENT_USE_ASSERTS
m_posting_torrent_updates = false;
#endif
m_udp_socket.set_rate_limit(m_settings.get_int(settings_pack::dht_upload_rate_limit));
m_udp_socket.subscribe(&m_utp_socket_manager);
m_udp_socket.subscribe(this);
m_udp_socket.subscribe(&m_tracker_manager);
#ifdef TORRENT_USE_OPENSSL
m_ssl_udp_socket.subscribe(&m_ssl_utp_socket_manager);
m_ssl_udp_socket.subscribe(this);
#endif
error_code ec;
m_listen_interface = tcp::endpoint(address_v4::any(), 0);
TORRENT_ASSERT_VAL(!ec, ec);
update_time_now();
}
// This function is called by the creating thread, not in the message loop's
// / io_service thread.
// TODO: 2 is there a reason not to move all of this into init()? and just
// post it to the io_service?
void session_impl::start_session(settings_pack const& pack)
{
if (pack.has_val(settings_pack::alert_mask))
{
m_alerts.set_alert_mask(pack.get_int(settings_pack::alert_mask));
}
#ifndef TORRENT_DISABLE_LOGGING
session_log("start session");
#endif
error_code ec;
#ifdef TORRENT_USE_OPENSSL
m_ssl_ctx.set_verify_mode(boost::asio::ssl::context::verify_none, ec);
#if BOOST_VERSION >= 104700
#if OPENSSL_VERSION_NUMBER >= 0x90812f
aux::openssl_set_tlsext_servername_callback(m_ssl_ctx.native_handle()
, servername_callback);
aux::openssl_set_tlsext_servername_arg(m_ssl_ctx.native_handle(), this);
#endif // OPENSSL_VERSION_NUMBER
#endif // BOOST_VERSION
#endif
#ifndef TORRENT_DISABLE_DHT
m_next_dht_torrent = m_torrents.begin();
#endif
m_next_lsd_torrent = m_torrents.begin();
m_tcp_mapping[0] = -1;
m_tcp_mapping[1] = -1;
m_udp_mapping[0] = -1;
m_udp_mapping[1] = -1;
#ifdef TORRENT_USE_OPENSSL
m_ssl_tcp_mapping[0] = -1;
m_ssl_tcp_mapping[1] = -1;
m_ssl_udp_mapping[0] = -1;
m_ssl_udp_mapping[1] = -1;
#endif
m_global_class = m_classes.new_peer_class("global");
m_tcp_peer_class = m_classes.new_peer_class("tcp");
m_local_peer_class = m_classes.new_peer_class("local");
// local peers are always unchoked
m_classes.at(m_local_peer_class)->ignore_unchoke_slots = true;
// local peers are allowed to exceed the normal connection
// limit by 50%
m_classes.at(m_local_peer_class)->connection_limit_factor = 150;
TORRENT_ASSERT(m_global_class == session::global_peer_class_id);
TORRENT_ASSERT(m_tcp_peer_class == session::tcp_peer_class_id);
TORRENT_ASSERT(m_local_peer_class == session::local_peer_class_id);
init_peer_class_filter(true);
// TCP, SSL/TCP and I2P connections should be assigned the TCP peer class
m_peer_class_type_filter.add(peer_class_type_filter::tcp_socket, m_tcp_peer_class);
m_peer_class_type_filter.add(peer_class_type_filter::ssl_tcp_socket, m_tcp_peer_class);
m_peer_class_type_filter.add(peer_class_type_filter::i2p_socket, m_tcp_peer_class);
// TODO: there's no rule here to make uTP connections not have the global or
// local rate limits apply to it. This used to be the default.
#ifndef TORRENT_DISABLE_LOGGING
session_log("config: %s version: %s revision: %s"
, TORRENT_CFG_STRING
, LIBTORRENT_VERSION
, LIBTORRENT_REVISION);
#endif // TORRENT_DISABLE_LOGGING
// ---- auto-cap max connections ----
int max_files = max_open_files();
// deduct some margin for epoll/kqueue, log files,
// futexes, shared objects etc.
// 80% of the available file descriptors should go to connections
m_settings.set_int(settings_pack::connections_limit, (std::min)(
m_settings.get_int(settings_pack::connections_limit)
, (std::max)(5, (max_files - 20) * 8 / 10)));
// 20% goes towards regular files (see disk_io_thread)
#ifndef TORRENT_DISABLE_LOGGING
session_log(" max connections: %d", m_settings.get_int(settings_pack::connections_limit));
session_log(" max files: %d", max_files);
session_log(" generated peer ID: %s", m_peer_id.to_string().c_str());
#endif
boost::shared_ptr<settings_pack> copy = boost::make_shared<settings_pack>(pack);
m_io_service.post(boost::bind(&session_impl::init, this, copy));
}
void session_impl::init(boost::shared_ptr<settings_pack> pack)
{
// this is a debug facility
// see single_threaded in debug.hpp
thread_started();
TORRENT_ASSERT(is_single_thread());
#ifndef TORRENT_DISABLE_LOGGING
if (m_alerts.should_post<log_alert>())
{
session_log(" *** session thread init");
// this specific output is parsed by tools/parse_session_stats.py
// if this is changed, that parser should also be changed
std::string stats_header = "session stats header: ";
std::vector<stats_metric> stats = session_stats_metrics();
std::sort(stats.begin(), stats.end()
, boost::bind(&stats_metric::value_index, _1)
< boost::bind(&stats_metric::value_index, _2));
for (int i = 0; i < stats.size(); ++i)
{
if (i > 0) stats_header += ", ";
stats_header += stats[i].name;
}
m_alerts.emplace_alert<log_alert>(stats_header.c_str());
}
#endif
// this is where we should set up all async operations. This
// is called from within the network thread as opposed to the
// constructor which is called from the main thread
#if defined TORRENT_ASIO_DEBUGGING
async_inc_threads();
add_outstanding_async("session_impl::on_tick");
#endif
error_code ec;
m_io_service.post(boost::bind(&session_impl::on_tick, this, ec));
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_lsd_announce");
#endif
int delay = (std::max)(m_settings.get_int(settings_pack::local_service_announce_interval)
/ (std::max)(int(m_torrents.size()), 1), 1);
m_lsd_announce_timer.expires_from_now(seconds(delay), ec);
m_lsd_announce_timer.async_wait(
boost::bind(&session_impl::on_lsd_announce, this, _1));
TORRENT_ASSERT(!ec);
#ifndef TORRENT_DISABLE_DHT
update_dht_announce_interval();
#endif
#ifndef TORRENT_DISABLE_LOGGING
session_log(" done starting session");
#endif
apply_settings_pack(pack);
// call update_* after settings set initialized
#ifndef TORRENT_NO_DEPRECATE
update_local_download_rate();
update_local_upload_rate();
#endif
update_download_rate();
update_upload_rate();
update_connections_limit();
update_unchoke_limit();
update_disk_threads();
update_network_threads();
update_upnp();
update_natpmp();
update_lsd();
update_dht();
update_peer_fingerprint();
update_dht_bootstrap_nodes();
if (m_listen_sockets.empty())
{
update_listen_interfaces();
open_listen_port();
}
}
void session_impl::async_resolve(std::string const& host, int flags
, session_interface::callback_t const& h)
{
m_host_resolver.async_resolve(host, flags, h);
}
void session_impl::queue_async_resume_data(boost::shared_ptr<torrent> const& t)
{
INVARIANT_CHECK;
int loaded_limit = m_settings.get_int(settings_pack::active_loaded_limit);
if (m_num_save_resume + m_alerts.num_queued_resume() >= loaded_limit
&& m_user_load_torrent
&& loaded_limit > 0)
{
TORRENT_ASSERT(t);
// do loaded torrents first, otherwise they'll just be
// evicted and have to be loaded again
if (t->is_loaded())
m_save_resume_queue.push_front(t);
else
m_save_resume_queue.push_back(t);
return;
}
if (t->do_async_save_resume_data())
++m_num_save_resume;
}
// this is called whenever a save_resume_data comes back
// from the disk thread
void session_impl::done_async_resume()
{
TORRENT_ASSERT(m_num_save_resume > 0);
--m_num_save_resume;
}
// this is called when one or all save resume alerts are
// popped off the alert queue
void session_impl::async_resume_dispatched()
{
INVARIANT_CHECK;
int num_queued_resume = m_alerts.num_queued_resume();
int loaded_limit = m_settings.get_int(settings_pack::active_loaded_limit);
while (!m_save_resume_queue.empty()
&& (m_num_save_resume + num_queued_resume < loaded_limit
|| loaded_limit == 0))
{
boost::shared_ptr<torrent> t = m_save_resume_queue.front();
m_save_resume_queue.erase(m_save_resume_queue.begin());
if (t->do_async_save_resume_data())
++m_num_save_resume;
}
}
void session_impl::save_state(entry* eptr, boost::uint32_t flags) const
{
TORRENT_ASSERT(is_single_thread());
entry& e = *eptr;
// make it a dict
e.dict();
if (flags & session::save_settings)
{
entry::dictionary_type& sett = e["settings"].dict();
save_settings_to_dict(m_settings, sett);
}
#ifndef TORRENT_DISABLE_DHT
if (flags & session::save_dht_settings)
{
entry::dictionary_type& dht_sett = e["dht"].dict();
dht_sett["max_peers_reply"] = m_dht_settings.max_peers_reply;
dht_sett["search_branching"] = m_dht_settings.search_branching;
dht_sett["max_fail_count"] = m_dht_settings.max_fail_count;
dht_sett["max_torrents"] = m_dht_settings.max_torrents;
dht_sett["max_dht_items"] = m_dht_settings.max_dht_items;
dht_sett["max_peers"] = m_dht_settings.max_peers;
dht_sett["max_torrent_search_reply"] = m_dht_settings.max_torrent_search_reply;
dht_sett["restrict_routing_ips"] = m_dht_settings.restrict_routing_ips;
dht_sett["restrict_search_ips"] = m_dht_settings.restrict_search_ips;
dht_sett["extended_routing_table"] = m_dht_settings.extended_routing_table;
dht_sett["aggressive_lookups"] = m_dht_settings.aggressive_lookups;
dht_sett["privacy_lookups"] = m_dht_settings.privacy_lookups;
dht_sett["enforce_node_id"] = m_dht_settings.enforce_node_id;
dht_sett["ignore_dark_internet"] = m_dht_settings.ignore_dark_internet;
dht_sett["block_timeout"] = m_dht_settings.block_timeout;
dht_sett["block_ratelimit"] = m_dht_settings.block_ratelimit;
dht_sett["read_only"] = m_dht_settings.read_only;
dht_sett["item_lifetime"] = m_dht_settings.item_lifetime;
}
if (m_dht && (flags & session::save_dht_state))
{
e["dht state"] = m_dht->state();
}
#endif
#ifndef TORRENT_NO_DEPRECATE
if (flags & session::save_feeds)
{
entry::list_type& feeds = e["feeds"].list();
for (std::vector<boost::shared_ptr<feed> >::const_iterator i =
m_feeds.begin(), end(m_feeds.end()); i != end; ++i)
{
feeds.push_back(entry());
(*i)->save_state(feeds.back());
}
}
#endif
#ifndef TORRENT_DISABLE_EXTENSIONS
for (ses_extension_list_t::const_iterator i = m_ses_extensions.begin()
, end(m_ses_extensions.end()); i != end; ++i)
{
TORRENT_TRY {
(*i)->save_state(*eptr);
} TORRENT_CATCH(std::exception&) {}
}
#endif
}
proxy_settings session_impl::proxy() const
{
return proxy_settings(m_settings);
}
void session_impl::load_state(bdecode_node const* e
, boost::uint32_t const flags = 0xffffffff)
{
TORRENT_ASSERT(is_single_thread());
bdecode_node settings;
if (e->type() != bdecode_node::dict_t) return;
#ifndef TORRENT_DISABLE_DHT
bool need_update_dht = false;
// load from the old settings names
if (flags & session::save_dht_settings)
{
settings = e->dict_find_dict("dht");
if (settings)
{
bdecode_node val;
val = settings.dict_find_int("max_peers_reply");
if (val) m_dht_settings.max_peers_reply = val.int_value();
val = settings.dict_find_int("search_branching");
if (val) m_dht_settings.search_branching = val.int_value();
val = settings.dict_find_int("max_fail_count");
if (val) m_dht_settings.max_fail_count = val.int_value();
val = settings.dict_find_int("max_torrents");
if (val) m_dht_settings.max_torrents = val.int_value();
val = settings.dict_find_int("max_dht_items");
if (val) m_dht_settings.max_dht_items = val.int_value();
val = settings.dict_find_int("max_peers");
if (val) m_dht_settings.max_peers = val.int_value();
val = settings.dict_find_int("max_torrent_search_reply");
if (val) m_dht_settings.max_torrent_search_reply = val.int_value();
val = settings.dict_find_int("restrict_routing_ips");
if (val) m_dht_settings.restrict_routing_ips = val.int_value();
val = settings.dict_find_int("restrict_search_ips");
if (val) m_dht_settings.restrict_search_ips = val.int_value();
val = settings.dict_find_int("extended_routing_table");
if (val) m_dht_settings.extended_routing_table = val.int_value();
val = settings.dict_find_int("aggressive_lookups");
if (val) m_dht_settings.aggressive_lookups = val.int_value();
val = settings.dict_find_int("privacy_lookups");
if (val) m_dht_settings.privacy_lookups = val.int_value();
val = settings.dict_find_int("enforce_node_id");
if (val) m_dht_settings.enforce_node_id = val.int_value();
val = settings.dict_find_int("ignore_dark_internet");
if (val) m_dht_settings.ignore_dark_internet = val.int_value();
val = settings.dict_find_int("block_timeout");
if (val) m_dht_settings.block_timeout = val.int_value();
val = settings.dict_find_int("block_ratelimit");
if (val) m_dht_settings.block_ratelimit = val.int_value();
val = settings.dict_find_int("read_only");
if (val) m_dht_settings.read_only = val.int_value();
val = settings.dict_find_int("item_lifetime");
if (val) m_dht_settings.item_lifetime = val.int_value();
}
}
if (flags & session::save_dht_state)
{
settings = e->dict_find_dict("dht state");
if (settings)
{
m_dht_state = settings;
need_update_dht = true;
}
}
#endif
#ifndef TORRENT_NO_DEPRECATE
bool need_update_proxy = false;
if (flags & session::save_proxy)
{
settings = e->dict_find_dict("proxy");
if (settings)
{
bdecode_node val;
val = settings.dict_find_int("port");
if (val) m_settings.set_int(settings_pack::proxy_port, val.int_value());
val = settings.dict_find_int("type");
if (val) m_settings.set_int(settings_pack::proxy_type, val.int_value());
val = settings.dict_find_int("proxy_hostnames");
if (val) m_settings.set_bool(settings_pack::proxy_hostnames, val.int_value());
val = settings.dict_find_int("proxy_peer_connections");
if (val) m_settings.set_bool(settings_pack::proxy_peer_connections, val.int_value());
val = settings.dict_find_string("hostname");
if (val) m_settings.set_str(settings_pack::proxy_hostname, val.string_value());
val = settings.dict_find_string("password");
if (val) m_settings.set_str(settings_pack::proxy_password, val.string_value());
val = settings.dict_find_string("username");
if (val) m_settings.set_str(settings_pack::proxy_username, val.string_value());
need_update_proxy = true;
}
}
settings = e->dict_find_dict("encryption");
if (settings)
{
bdecode_node val;
val = settings.dict_find_int("prefer_rc4");
if (val) m_settings.set_bool(settings_pack::prefer_rc4, val.int_value());
val = settings.dict_find_int("out_enc_policy");
if (val) m_settings.set_int(settings_pack::out_enc_policy, val.int_value());
val = settings.dict_find_int("in_enc_policy");
if (val) m_settings.set_int(settings_pack::in_enc_policy, val.int_value());
val = settings.dict_find_int("allowed_enc_level");
if (val) m_settings.set_int(settings_pack::allowed_enc_level, val.int_value());
}
if (flags & session::save_feeds)
{
settings = e->dict_find_list("feeds");
if (settings)
{
m_feeds.reserve(settings.list_size());
for (int i = 0; i < settings.list_size(); ++i)
{
if (settings.list_at(i).type() != bdecode_node::dict_t) continue;
boost::shared_ptr<feed> f(new_feed(*this, feed_settings()));
f->load_state(settings.list_at(i));
f->update_feed();
m_feeds.push_back(f);
}
update_rss_feeds();
}
}
#endif
if (flags & session::save_settings)
{
settings = e->dict_find_dict("settings");
if (settings)
{
// apply_settings_pack will update dht and proxy
boost::shared_ptr<settings_pack> pack = load_pack_from_dict(settings);
apply_settings_pack(pack);
#ifndef TORRENT_DISABLE_DHT
need_update_dht = false;
#endif
#ifndef TORRENT_NO_DEPRECATE
need_update_proxy = false;
#endif
}
}
#ifndef TORRENT_DISABLE_DHT
if (need_update_dht) update_dht();
#endif
#ifndef TORRENT_NO_DEPRECATE
if (need_update_proxy) update_proxy();
#endif
#ifndef TORRENT_DISABLE_EXTENSIONS
for (ses_extension_list_t::iterator i = m_ses_extensions.begin()
, end(m_ses_extensions.end()); i != end; ++i)
{
TORRENT_TRY {
(*i)->load_state(*e);
} TORRENT_CATCH(std::exception&) {}
}
#endif
}
#ifndef TORRENT_DISABLE_EXTENSIONS
typedef boost::function<boost::shared_ptr<torrent_plugin>(torrent_handle const&, void*)> ext_function_t;
struct session_plugin_wrapper : plugin
{
session_plugin_wrapper(ext_function_t const& f) : m_f(f) {}
virtual boost::shared_ptr<torrent_plugin> new_torrent(torrent_handle const& t, void* user)
{ return m_f(t, user); }
ext_function_t m_f;
};
void session_impl::add_extension(ext_function_t ext)
{
TORRENT_ASSERT(is_single_thread());
TORRENT_ASSERT_VAL(ext, ext);
boost::shared_ptr<plugin> p(new session_plugin_wrapper(ext));
m_ses_extensions.push_back(p);
m_session_extension_features |= p->implemented_features();
}
void session_impl::add_ses_extension(boost::shared_ptr<plugin> ext)
{
TORRENT_ASSERT(is_single_thread());
TORRENT_ASSERT_VAL(ext, ext);
m_ses_extensions.push_back(ext);
m_alerts.add_extension(ext);
ext->added(session_handle(this));
m_session_extension_features |= ext->implemented_features();
// get any DHT queries the plugin would like to handle
// and record them in m_extension_dht_queries for lookup
// later
dht_extensions_t dht_ext;
ext->register_dht_extensions(dht_ext);
for (dht_extensions_t::iterator e = dht_ext.begin();
e != dht_ext.end(); ++e)
{
TORRENT_ASSERT(e->first.size() <= max_dht_query_length);
if (e->first.size() > max_dht_query_length) continue;
extension_dht_query registration;
registration.query_len = e->first.size();
std::copy(e->first.begin(), e->first.end(), registration.query.begin());
registration.handler = e->second;
m_extension_dht_queries.push_back(registration);
}
}
#endif // TORRENT_DISABLE_EXTENSIONS
#ifndef TORRENT_NO_DEPRECATE
feed_handle session_impl::add_feed(feed_settings const& sett)
{
TORRENT_ASSERT(is_single_thread());
// look for duplicates. If we already have a feed with this
// URL, return a handle to the existing one
for (std::vector<boost::shared_ptr<feed> >::const_iterator i
= m_feeds.begin(), end(m_feeds.end()); i != end; ++i)
{
if (sett.url != (*i)->m_settings.url) continue;
return feed_handle(*i);
}
boost::shared_ptr<feed> f(new_feed(*this, sett));
m_feeds.push_back(f);
update_rss_feeds();
return feed_handle(f);
}
void session_impl::remove_feed(feed_handle h)
{
TORRENT_ASSERT(is_single_thread());
boost::shared_ptr<feed> f = h.m_feed_ptr.lock();
if (!f) return;
std::vector<boost::shared_ptr<feed> >::iterator i
= std::find(m_feeds.begin(), m_feeds.end(), f);
if (i == m_feeds.end()) return;
m_feeds.erase(i);
}
void session_impl::get_feeds(std::vector<feed_handle>* ret) const
{
TORRENT_ASSERT(is_single_thread());
ret->clear();
ret->reserve(m_feeds.size());
for (std::vector<boost::shared_ptr<feed> >::const_iterator i = m_feeds.begin()
, end(m_feeds.end()); i != end; ++i)
ret->push_back(feed_handle(*i));
}
#endif
void session_impl::pause()
{
TORRENT_ASSERT(is_single_thread());
if (m_paused) return;
#ifndef TORRENT_DISABLE_LOGGING
session_log(" *** session paused ***");
#endif
m_paused = true;
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
torrent& t = *i->second;
t.do_pause();
}
}
void session_impl::resume()
{
TORRENT_ASSERT(is_single_thread());
if (!m_paused) return;
m_paused = false;
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
torrent& t = *i->second;
t.do_resume();
if (t.should_check_files()) t.start_checking();
}
}
void session_impl::abort()
{
TORRENT_ASSERT(is_single_thread());
if (m_abort) return;
#ifndef TORRENT_DISABLE_LOGGING
session_log(" *** ABORT CALLED ***");
#endif
// at this point we cannot call the notify function anymore, since the
// session will become invalid.
m_alerts.set_notify_function(boost::function<void()>());
// this will cancel requests that are not critical for shutting down
// cleanly. i.e. essentially tracker hostname lookups that we're not
// about to send event=stopped to
m_host_resolver.abort();
// abort the main thread
m_abort = true;
error_code ec;
#if TORRENT_USE_I2P
m_i2p_conn.close(ec);
#endif
stop_lsd();
stop_upnp();
stop_natpmp();
#ifndef TORRENT_DISABLE_DHT
stop_dht();
m_dht_announce_timer.cancel(ec);
#endif
m_lsd_announce_timer.cancel(ec);
for (std::set<boost::shared_ptr<socket_type> >::iterator i = m_incoming_sockets.begin()
, end(m_incoming_sockets.end()); i != end; ++i)
{
(*i)->close(ec);
TORRENT_ASSERT(!ec);
}
m_incoming_sockets.clear();
// close the listen sockets
for (std::list<listen_socket_t>::iterator i = m_listen_sockets.begin()
, end(m_listen_sockets.end()); i != end; ++i)
{
i->sock->close(ec);
TORRENT_ASSERT(!ec);
}
m_listen_sockets.clear();
if (m_socks_listen_socket && m_socks_listen_socket->is_open())
{
m_socks_listen_socket->close(ec);
TORRENT_ASSERT(!ec);
}
m_socks_listen_socket.reset();
#if TORRENT_USE_I2P
if (m_i2p_listen_socket && m_i2p_listen_socket->is_open())
{
m_i2p_listen_socket->close(ec);
TORRENT_ASSERT(!ec);
}
m_i2p_listen_socket.reset();
#endif
#ifndef TORRENT_DISABLE_LOGGING
session_log(" aborting all torrents (%d)", int(m_torrents.size()));
#endif
// abort all torrents
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
i->second->abort();
}
m_torrents.clear();
#ifndef TORRENT_DISABLE_LOGGING
session_log(" aborting all tracker requests");
#endif
m_tracker_manager.abort_all_requests();
#ifndef TORRENT_DISABLE_LOGGING
session_log(" aborting all connections (%d)", int(m_connections.size()));
#endif
// abort all connections
while (!m_connections.empty())
{
#if TORRENT_USE_ASSERTS
int conn = m_connections.size();
#endif
(*m_connections.begin())->disconnect(errors::stopping_torrent, op_bittorrent);
TORRENT_ASSERT_VAL(conn == int(m_connections.size()) + 1, conn);
}
// we need to give all the sockets an opportunity to actually have their handlers
// called and cancelled before we continue the shutdown. This is a bit
// complicated, if there are no "undead" peers, it's safe tor resume the
// shutdown, but if there are, we have to wait for them to be cleared out
// first. In session_impl::on_tick() we check them periodically. If we're
// shutting down and we remove the last one, we'll initiate
// shutdown_stage2 from there.
if (m_undead_peers.empty())
{
m_io_service.post(boost::bind(&session_impl::abort_stage2, this));
}
}
void session_impl::abort_stage2()
{
m_download_rate.close();
m_upload_rate.close();
m_udp_socket.close();
m_external_udp_port = 0;
#ifdef TORRENT_USE_OPENSSL
m_ssl_udp_socket.close();
#endif
// it's OK to detach the threads here. The disk_io_thread
// has an internal counter and won't release the network
// thread until they're all dead (via m_work).
m_disk_thread.abort(false);
// now it's OK for the network thread to exit
m_work.reset();
}
bool session_impl::has_connection(peer_connection* p) const
{
return m_connections.find(p->self()) != m_connections.end();
}
void session_impl::insert_peer(boost::shared_ptr<peer_connection> const& c)
{
TORRENT_ASSERT(!c->m_in_constructor);
m_connections.insert(c);
}
void session_impl::set_port_filter(port_filter const& f)
{
m_port_filter = f;
if (m_settings.get_bool(settings_pack::no_connect_privileged_ports))
m_port_filter.add_rule(0, 1024, port_filter::blocked);
// Close connections whose endpoint is filtered
// by the new ip-filter
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
i->second->port_filter_updated();
}
void session_impl::set_ip_filter(boost::shared_ptr<ip_filter> const& f)
{
INVARIANT_CHECK;
m_ip_filter = f;
// Close connections whose endpoint is filtered
// by the new ip-filter
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
i->second->set_ip_filter(m_ip_filter);
}
void session_impl::ban_ip(address addr)
{
TORRENT_ASSERT(is_single_thread());
if (!m_ip_filter) m_ip_filter = boost::make_shared<ip_filter>();
m_ip_filter->add_rule(addr, addr, ip_filter::blocked);
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
i->second->set_ip_filter(m_ip_filter);
}
ip_filter const& session_impl::get_ip_filter()
{
TORRENT_ASSERT(is_single_thread());
if (!m_ip_filter) m_ip_filter = boost::make_shared<ip_filter>();
return *m_ip_filter;
}
port_filter const& session_impl::get_port_filter() const
{
TORRENT_ASSERT(is_single_thread());
return m_port_filter;
}
namespace
{
template <class Socket>
void set_socket_buffer_size(Socket& s, session_settings const& sett, error_code& ec)
{
int snd_size = sett.get_int(settings_pack::send_socket_buffer_size);
if (snd_size)
{
typename Socket::send_buffer_size prev_option;
s.get_option(prev_option, ec);
if (!ec && prev_option.value() != snd_size)
{
typename Socket::send_buffer_size option(snd_size);
s.set_option(option, ec);
if (ec)
{
// restore previous value
s.set_option(prev_option, ec);
return;
}
}
}
int recv_size = sett.get_int(settings_pack::recv_socket_buffer_size);
if (recv_size)
{
typename Socket::receive_buffer_size prev_option;
s.get_option(prev_option, ec);
if (!ec && prev_option.value() != recv_size)
{
typename Socket::receive_buffer_size option(recv_size);
s.set_option(option, ec);
if (ec)
{
// restore previous value
s.set_option(prev_option, ec);
return;
}
}
}
}
} // anonymous namespace
int session_impl::create_peer_class(char const* name)
{
TORRENT_ASSERT(is_single_thread());
return m_classes.new_peer_class(name);
}
void session_impl::delete_peer_class(int cid)
{
TORRENT_ASSERT(is_single_thread());
// if you hit this assert, you're deleting a non-existent peer class
TORRENT_ASSERT(m_classes.at(cid));
if (m_classes.at(cid) == 0) return;
m_classes.decref(cid);
}
peer_class_info session_impl::get_peer_class(int cid)
{
peer_class_info ret;
peer_class* pc = m_classes.at(cid);
// if you hit this assert, you're passing in an invalid cid
TORRENT_ASSERT(pc);
if (pc == 0)
{
#ifdef TORRENT_DEBUG
// make it obvious that the return value is undefined
ret.upload_limit = 0xf0f0f0f;
ret.download_limit = 0xf0f0f0f;
ret.label.resize(20);
url_random(&ret.label[0], &ret.label[0] + 20);
ret.ignore_unchoke_slots = false;
ret.connection_limit_factor = 0xf0f0f0f;
ret.upload_priority = 0xf0f0f0f;
ret.download_priority = 0xf0f0f0f;
#endif
return ret;
}
pc->get_info(&ret);
return ret;
}
void session_impl::queue_tracker_request(tracker_request& req
, boost::weak_ptr<request_callback> c)
{
req.listen_port = listen_port();
if (m_key) req.key = m_key;
#ifdef TORRENT_USE_OPENSSL
// SSL torrents use the SSL listen port
if (req.ssl_ctx) req.listen_port = ssl_listen_port();
req.ssl_ctx = &m_ssl_ctx;
#endif
#if TORRENT_USE_I2P
if (!m_settings.get_str(settings_pack::i2p_hostname).empty())
{
req.i2pconn = &m_i2p_conn;
}
#endif
if (is_any(req.bind_ip)) req.bind_ip = m_listen_interface.address();
m_tracker_manager.queue_request(get_io_service(), req, c);
}
void session_impl::set_peer_class(int cid, peer_class_info const& pci)
{
peer_class* pc = m_classes.at(cid);
// if you hit this assert, you're passing in an invalid cid
TORRENT_ASSERT(pc);
if (pc == 0) return;
pc->set_info(&pci);
}
void session_impl::set_peer_class_filter(ip_filter const& f)
{
INVARIANT_CHECK;
m_peer_class_filter = f;
}
ip_filter const& session_impl::get_peer_class_filter() const
{
return m_peer_class_filter;
}
void session_impl::set_peer_class_type_filter(peer_class_type_filter f)
{
m_peer_class_type_filter = f;
}
peer_class_type_filter session_impl::get_peer_class_type_filter()
{
return m_peer_class_type_filter;
}
void session_impl::set_peer_classes(peer_class_set* s, address const& a, int st)
{
boost::uint32_t peer_class_mask = m_peer_class_filter.access(a);
// assign peer class based on socket type
static const int mapping[] = { 0, 0, 0, 0, 1, 4, 2, 2, 2, 3};
int socket_type = mapping[st];
// filter peer classes based on type
peer_class_mask = m_peer_class_type_filter.apply(socket_type, peer_class_mask);
for (peer_class_t i = 0; peer_class_mask; peer_class_mask >>= 1, ++i)
{
if ((peer_class_mask & 1) == 0) continue;
// if you hit this assert, your peer class filter contains
// a bitmask referencing a non-existent peer class
TORRENT_ASSERT_PRECOND(m_classes.at(i));
if (m_classes.at(i) == 0) continue;
s->add_class(m_classes, i);
}
}
bool session_impl::ignore_unchoke_slots_set(peer_class_set const& set) const
{
int num = set.num_classes();
for (int i = 0; i < num; ++i)
{
peer_class const* pc = m_classes.at(set.class_at(i));
if (pc == 0) continue;
if (pc->ignore_unchoke_slots) return true;
}
return false;
}
bandwidth_manager* session_impl::get_bandwidth_manager(int channel)
{
return (channel == peer_connection::download_channel)
? &m_download_rate : &m_upload_rate;
}
// the back argument determines whether this bump causes the torrent
// to be the most recently used or the least recently used. Putting
// the torrent at the back of the queue makes it the most recently
// used and the least likely to be evicted. This is the default.
// if back is false, the torrent is moved to the front of the queue,
// and made the most likely to be evicted. This is used for torrents
// that are paused, to give up their slot among the loaded torrents
void session_impl::bump_torrent(torrent* t, bool back)
{
if (t->is_aborted()) return;
bool new_torrent = false;
// if t is the only torrent in the LRU list, both
// its prev and next links will be NULL, even though
// it's already in the list. Cover this case by also
// checking to see if it's the first item
if (t->next != NULL || t->prev != NULL || m_torrent_lru.front() == t)
{
#ifdef TORRENT_DEBUG
torrent* i = m_torrent_lru.front();
while (i != NULL && i != t) i = i->next;
TORRENT_ASSERT(i == t);
#endif
// this torrent is in the list already.
// first remove it
m_torrent_lru.erase(t);
}
else
{
new_torrent = true;
}
// pinned torrents should not be part of the LRU, since
// the LRU is only used to evict torrents
if (t->is_pinned()) return;
if (back)
m_torrent_lru.push_back(t);
else
m_torrent_lru.push_front(t);
if (new_torrent) evict_torrents_except(t);
}
void session_impl::evict_torrent(torrent* t)
{
TORRENT_ASSERT(!t->is_pinned());
// if there's no user-load function set, we cannot evict
// torrents. The feature is not enabled
if (!m_user_load_torrent) return;
// if it's already evicted, there's nothing to do
if (!t->is_loaded() || !t->should_be_loaded()) return;
TORRENT_ASSERT(t->next != NULL || t->prev != NULL || m_torrent_lru.front() == t);
#if defined TORRENT_DEBUG && defined TORRENT_EXPENSIVE_INVARIANT_CHECKS
torrent* i = m_torrent_lru.front();
while (i != NULL && i != t) i = i->next;
TORRENT_ASSERT(i == t);
#endif
int loaded_limit = m_settings.get_int(settings_pack::active_loaded_limit);
// 0 means unlimited, never evict anything
if (loaded_limit == 0) return;
if (m_torrent_lru.size() > loaded_limit)
{
// just evict the torrent
m_stats_counters.inc_stats_counter(counters::torrent_evicted_counter);
TORRENT_ASSERT(t->is_pinned() == false);
t->unload();
m_torrent_lru.erase(t);
return;
}
// move this torrent to be the first to be evicted whenever
// another torrent need its slot
bump_torrent(t, false);
}
void session_impl::evict_torrents_except(torrent* ignore)
{
if (!m_user_load_torrent) return;
int loaded_limit = m_settings.get_int(settings_pack::active_loaded_limit);
// 0 means unlimited, never evict anything
if (loaded_limit == 0) return;
// if the torrent we're ignoring (i.e. making room for), allow
// one more torrent in the list.
if (ignore->next != NULL || ignore->prev != NULL || m_torrent_lru.front() == ignore)
{
#ifdef TORRENT_DEBUG
torrent* i = m_torrent_lru.front();
while (i != NULL && i != ignore) i = i->next;
TORRENT_ASSERT(i == ignore);
#endif
++loaded_limit;
}
while (m_torrent_lru.size() >= loaded_limit)
{
// we're at the limit of loaded torrents. Find the least important
// torrent and unload it. This is done with an LRU.
torrent* i = m_torrent_lru.front();
if (i == ignore)
{
i = i->next;
if (i == NULL) break;
}
m_stats_counters.inc_stats_counter(counters::torrent_evicted_counter);
TORRENT_ASSERT(i->is_pinned() == false);
i->unload();
m_torrent_lru.erase(i);
}
}
bool session_impl::load_torrent(torrent* t)
{
TORRENT_ASSERT(is_single_thread());
evict_torrents_except(t);
// we wouldn't be loading the torrent if it was already
// in the LRU (and loaded)
TORRENT_ASSERT(t->next == NULL && t->prev == NULL && m_torrent_lru.front() != t);
TORRENT_ASSERT(m_user_load_torrent);
// now, load t into RAM
std::vector<char> buffer;
error_code ec;
m_user_load_torrent(t->info_hash(), buffer, ec);
if (ec)
{
t->set_error(ec, torrent_status::error_file_metadata);
t->pause(false);
return false;
}
bool ret = t->load(buffer);
if (ret) bump_torrent(t);
return ret;
}
void session_impl::deferred_submit_jobs()
{
if (m_deferred_submit_disk_jobs) return;
m_deferred_submit_disk_jobs = true;
m_io_service.post(boost::bind(&session_impl::submit_disk_jobs, this));
}
void session_impl::submit_disk_jobs()
{
TORRENT_ASSERT(m_deferred_submit_disk_jobs);
m_deferred_submit_disk_jobs = false;
m_disk_thread.submit_jobs();
}
// copies pointers to bandwidth channels from the peer classes
// into the array. Only bandwidth channels with a bandwidth limit
// is considered pertinent and copied
// returns the number of pointers copied
// channel is upload_channel or download_channel
int session_impl::copy_pertinent_channels(peer_class_set const& set
, int channel, bandwidth_channel** dst, int max)
{
int num_channels = set.num_classes();
int num_copied = 0;
for (int i = 0; i < num_channels; ++i)
{
peer_class* pc = m_classes.at(set.class_at(i));
TORRENT_ASSERT(pc);
if (pc == 0) continue;
bandwidth_channel* chan = &pc->channel[channel];
// no need to include channels that don't have any bandwidth limits
if (chan->throttle() == 0) continue;
dst[num_copied] = chan;
++num_copied;
if (num_copied == max) break;
}
return num_copied;
}
bool session_impl::use_quota_overhead(bandwidth_channel* ch, int amount)
{
ch->use_quota(amount);
return (ch->throttle() > 0 && ch->throttle() < amount);
}
int session_impl::use_quota_overhead(peer_class_set& set, int amount_down, int amount_up)
{
int ret = 0;
int num = set.num_classes();
for (int i = 0; i < num; ++i)
{
peer_class* p = m_classes.at(set.class_at(i));
if (p == 0) continue;
bandwidth_channel* ch = &p->channel[peer_connection::download_channel];
if (use_quota_overhead(ch, amount_down))
ret |= 1 << peer_connection::download_channel;
ch = &p->channel[peer_connection::upload_channel];
if (use_quota_overhead(ch, amount_up))
ret |= 1 << peer_connection::upload_channel;
}
return ret;
}
// session_impl is responsible for deleting 'pack'
void session_impl::apply_settings_pack(boost::shared_ptr<settings_pack> pack)
{
apply_settings_pack_impl(*pack);
}
settings_pack session_impl::get_settings() const
{
settings_pack ret;
// TODO: it would be nice to reserve() these vectors up front
for (int i = settings_pack::string_type_base;
i < settings_pack::max_string_setting_internal; ++i)
{
ret.set_str(i, m_settings.get_str(i));
}
for (int i = settings_pack::int_type_base;
i < settings_pack::max_int_setting_internal; ++i)
{
ret.set_int(i, m_settings.get_int(i));
}
for (int i = settings_pack::bool_type_base;
i < settings_pack::max_bool_setting_internal; ++i)
{
ret.set_bool(i, m_settings.get_bool(i));
}
return ret;
}
void session_impl::apply_settings_pack_impl(settings_pack const& pack)
{
bool reopen_listen_port =
(pack.has_val(settings_pack::ssl_listen)
&& pack.get_int(settings_pack::ssl_listen)
!= m_settings.get_int(settings_pack::ssl_listen))
|| (pack.has_val(settings_pack::listen_interfaces)
&& pack.get_str(settings_pack::listen_interfaces)
!= m_settings.get_str(settings_pack::listen_interfaces));
apply_pack(&pack, m_settings, this);
m_disk_thread.set_settings(&pack, m_alerts);
if (reopen_listen_port)
{
error_code ec;
open_listen_port();
}
}
#ifndef TORRENT_NO_DEPRECATE
void session_impl::set_settings(libtorrent::session_settings const& s)
{
INVARIANT_CHECK;
TORRENT_ASSERT(is_single_thread());
boost::shared_ptr<settings_pack> p = load_pack_from_struct(m_settings, s);
apply_settings_pack(p);
}
libtorrent::session_settings session_impl::deprecated_settings() const
{
libtorrent::session_settings ret;
load_struct_from_settings(m_settings, ret);
return ret;
}
#endif
tcp::endpoint session_impl::get_ipv6_interface() const
{
return m_ipv6_interface;
}
tcp::endpoint session_impl::get_ipv4_interface() const
{
return m_ipv4_interface;
}
enum { listen_no_system_port = 0x02 };
listen_socket_t session_impl::setup_listener(std::string const& device
, boost::asio::ip::tcp const& protocol, int port, int flags, error_code& ec)
{
int retries = m_settings.get_int(settings_pack::max_retry_port_bind);
listen_socket_t ret;
ret.ssl = flags & open_ssl_socket;
int last_op = 0;
listen_failed_alert::socket_type_t sock_type = (flags & open_ssl_socket)
? listen_failed_alert::tcp_ssl : listen_failed_alert::tcp;
ret.sock.reset(new tcp::acceptor(m_io_service));
ret.sock->open(protocol, ec);
last_op = listen_failed_alert::open;
if (ec)
{
if (m_alerts.should_post<listen_failed_alert>())
m_alerts.emplace_alert<listen_failed_alert>(device, port, last_op
, ec, sock_type);
#ifndef TORRENT_DISABLE_LOGGING
session_log("failed to open socket: %s: %s"
, device.c_str(), ec.message().c_str());
#endif
return ret;
}
{
// this is best-effort. ignore errors
error_code err;
#ifdef TORRENT_WINDOWS
ret.sock->set_option(exclusive_address_use(true), err);
#endif
ret.sock->set_option(tcp::acceptor::reuse_address(true), err);
}
#if TORRENT_USE_IPV6
if (protocol == boost::asio::ip::tcp::v6())
{
error_code err; // ignore errors here
ret.sock->set_option(boost::asio::ip::v6_only(true), err);
#ifdef TORRENT_WINDOWS
// enable Teredo on windows
ret.sock->set_option(v6_protection_level(PROTECTION_LEVEL_UNRESTRICTED), err);
#endif // TORRENT_WINDOWS
}
#endif // TORRENT_USE_IPV6
address bind_ip = bind_to_device(m_io_service, *ret.sock, protocol
, device.c_str(), port, ec);
while (ec == error_code(error::address_in_use) && retries > 0)
{
TORRENT_ASSERT_VAL(ec, ec);
#ifndef TORRENT_DISABLE_LOGGING
error_code ignore;
session_log("failed to bind to interface [%s %d] \"%s\" : %s (%d) : %s "
"(retries: %d)"
, device.c_str(), port, bind_ip.to_string(ignore).c_str()
, ec.category().name(), ec.value(), ec.message().c_str(), retries);
#endif
ec.clear();
TORRENT_ASSERT_VAL(!ec, ec);
--retries;
port += 1;
bind_ip = bind_to_device(m_io_service, *ret.sock, protocol
, device.c_str(), port, ec);
last_op = listen_failed_alert::bind;
}
if (ec == error_code(error::address_in_use)
&& !(flags & listen_no_system_port))
{
// instead of giving up, try let the OS pick a port
port = 0;
ec.clear();
bind_ip = bind_to_device(m_io_service, *ret.sock, protocol
, device.c_str(), port, ec);
last_op = listen_failed_alert::bind;
}
if (ec)
{
TORRENT_ASSERT_VAL(ec.value() != 0, ec);
// not even that worked, give up
if (m_alerts.should_post<listen_failed_alert>())
m_alerts.emplace_alert<listen_failed_alert>(device, port, last_op, ec, sock_type);
#ifndef TORRENT_DISABLE_LOGGING
error_code err;
session_log("cannot to bind to interface [%s %d] \"%s : %s\": %s"
, device.c_str(), port, bind_ip.to_string(err).c_str()
, ec.category().name(), ec.message().c_str());
#endif
return ret;
}
ret.external_port = ret.sock->local_endpoint(ec).port();
TORRENT_ASSERT(ret.external_port == port || port == 0);
last_op = listen_failed_alert::get_peer_name;
if (!ec)
{
ret.sock->listen(m_settings.get_int(settings_pack::listen_queue_size), ec);
last_op = listen_failed_alert::listen;
}
if (ec)
{
if (m_alerts.should_post<listen_failed_alert>())
m_alerts.emplace_alert<listen_failed_alert>(device, port, last_op, ec, sock_type);
#ifndef TORRENT_DISABLE_LOGGING
session_log("cannot listen on interface \"%s\": %s"
, device.c_str(), ec.message().c_str());
#endif
return ret;
}
// if we asked the system to listen on port 0, which
// socket did it end up choosing?
if (port == 0)
{
port = ret.sock->local_endpoint(ec).port();
last_op = listen_failed_alert::get_peer_name;
if (ec)
{
if (m_alerts.should_post<listen_failed_alert>())
m_alerts.emplace_alert<listen_failed_alert>(device, port, last_op, ec, sock_type);
#ifndef TORRENT_DISABLE_LOGGING
session_log("failed to get peer name \"%s\": %s"
, device.c_str(), ec.message().c_str());
#endif
return ret;
}
}
#ifndef TORRENT_DISABLE_LOGGING
session_log(" listening on: %s external port: %d"
, print_endpoint(tcp::endpoint(bind_ip, port)).c_str(), ret.external_port);
#endif
return ret;
}
void session_impl::open_listen_port()
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("open listen port");
#endif
TORRENT_ASSERT(is_single_thread());
TORRENT_ASSERT(!m_abort);
int flags = m_settings.get_bool(settings_pack::listen_system_port_fallback)
? 0 : listen_no_system_port;
error_code ec;
int listen_port_retries = m_settings.get_int(settings_pack::max_retry_port_bind);
retry:
// close the open listen sockets
// close the listen sockets
for (std::list<listen_socket_t>::iterator i = m_listen_sockets.begin()
, end(m_listen_sockets.end()); i != end; ++i)
i->sock->close(ec);
m_listen_sockets.clear();
m_stats_counters.set_value(counters::has_incoming_connections, 0);
ec.clear();
if (m_abort) return;
m_ipv6_interface = tcp::endpoint();
m_ipv4_interface = tcp::endpoint();
// TODO: instead of having a special case for this, just make the
// default listen interfaces be "0.0.0.0:6881,[::]:6881" and use
// the generic path. That would even allow for not listening at all.
if (m_listen_interfaces.empty())
{
// this means we should open two listen sockets
// one for IPv4 and one for IPv6
listen_socket_t s = setup_listener("0.0.0.0", boost::asio::ip::tcp::v4()
, m_listen_interface.port()
, flags, ec);
if (!ec && s.sock)
{
// update the listen_interface member with the
// actual port we ended up listening on, so that the other
// sockets can be bound to the same one
m_listen_interface.port(s.external_port);
TORRENT_ASSERT(!m_abort);
m_listen_sockets.push_back(s);
}
#ifdef TORRENT_USE_OPENSSL
if (m_settings.get_int(settings_pack::ssl_listen))
{
s = setup_listener("0.0.0.0", boost::asio::ip::tcp::v4()
, m_settings.get_int(settings_pack::ssl_listen)
, flags | open_ssl_socket, ec);
if (!ec && s.sock)
{
TORRENT_ASSERT(!m_abort);
m_listen_sockets.push_back(s);
}
}
#endif
#if TORRENT_USE_IPV6
// only try to open the IPv6 port if IPv6 is installed
if (supports_ipv6())
{
s = setup_listener("::", boost::asio::ip::tcp::v6()
, m_listen_interface.port()
, flags, ec);
if (!ec && s.sock)
{
TORRENT_ASSERT(!m_abort);
m_listen_sockets.push_back(s);
}
#ifdef TORRENT_USE_OPENSSL
if (m_settings.get_int(settings_pack::ssl_listen))
{
s.ssl = true;
s = setup_listener("::", boost::asio::ip::tcp::v6()
, m_settings.get_int(settings_pack::ssl_listen)
, flags | open_ssl_socket, ec);
if (!ec && s.sock)
{
TORRENT_ASSERT(!m_abort);
m_listen_sockets.push_back(s);
}
}
#endif // TORRENT_USE_OPENSSL
}
#endif // TORRENT_USE_IPV6
// set our main IPv4 and IPv6 interfaces
// used to send to the tracker
std::vector<ip_interface> ifs = enum_net_interfaces(m_io_service, ec);
for (std::vector<ip_interface>::const_iterator i = ifs.begin()
, end(ifs.end()); i != end; ++i)
{
address const& addr = i->interface_address;
if (addr.is_v6() && !is_local(addr) && !is_loopback(addr))
m_ipv6_interface = tcp::endpoint(addr, m_listen_interface.port());
else if (addr.is_v4() && !is_local(addr) && !is_loopback(addr))
m_ipv4_interface = tcp::endpoint(addr, m_listen_interface.port());
}
}
else
{
// TODO: 2 the udp socket(s) should be using the same generic
// mechanism and not be restricted to a single one
// we should open a one listen socket for each entry in the
// listen_interfaces list
for (int i = 0; i < m_listen_interfaces.size(); ++i)
{
std::string const& device = m_listen_interfaces[i].first;
int port = m_listen_interfaces[i].second;
int num_device_fails = 0;
#if TORRENT_USE_IPV6
const int first_family = 0;
#else
const int first_family = 1;
#endif
boost::asio::ip::tcp protocol[]
= { boost::asio::ip::tcp::v6(), boost::asio::ip::tcp::v4() };
for (int address_family = first_family; address_family < 2; ++address_family)
{
error_code err;
address test_family = address::from_string(device.c_str(), err);
if (!err
&& test_family.is_v4() != address_family
&& !is_any(test_family))
continue;
listen_socket_t s = setup_listener(device, protocol[address_family]
, port, flags, ec);
if (ec == error_code(boost::system::errc::no_such_device, generic_category()))
{
++num_device_fails;
continue;
}
if (!ec && s.sock)
{
// update the listen_interface member with the
// actual port we ended up listening on, so that the other
// sockets can be bound to the same one
m_listen_interface.port(s.external_port);
TORRENT_ASSERT(!m_abort);
m_listen_sockets.push_back(s);
tcp::endpoint bind_ep = s.sock->local_endpoint(ec);
#if TORRENT_USE_IPV6
if (bind_ep.address().is_v6())
m_ipv6_interface = bind_ep;
else
#endif
m_ipv4_interface = bind_ep;
}
#ifdef TORRENT_USE_OPENSSL
if (m_settings.get_int(settings_pack::ssl_listen))
{
listen_socket_t ssl_s = setup_listener(device
, protocol[address_family]
, m_settings.get_int(settings_pack::ssl_listen)
, flags | open_ssl_socket, ec);
if (!ec && ssl_s.sock)
{
TORRENT_ASSERT(!m_abort);
m_listen_sockets.push_back(ssl_s);
}
}
#endif
}
}
}
if (m_listen_sockets.empty() && ec)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("cannot bind TCP listen socket to interface \"%s\": %s"
, print_endpoint(m_listen_interface).c_str(), ec.message().c_str());
#endif
if (m_alerts.should_post<listen_failed_alert>())
m_alerts.emplace_alert<listen_failed_alert>(
m_listen_interface.address().to_string()
, m_listen_interface.port()
, listen_failed_alert::bind
, ec, listen_failed_alert::tcp);
if (listen_port_retries > 0)
{
m_listen_interface.port(m_listen_interface.port() + 1);
// update the actual port m_listen_interface was derived from also
if (!m_listen_interfaces.empty())
m_listen_interfaces[0].second += 1;
--listen_port_retries;
goto retry;
}
return;
}
#ifdef TORRENT_USE_OPENSSL
int const ssl_port = m_settings.get_int(settings_pack::ssl_listen);
udp::endpoint ssl_bind_if(m_listen_interface.address(), ssl_port);
tcp::endpoint ssl_bind_ep(m_listen_interface.address(), ssl_port);
// if ssl port is 0, we don't want to listen on an SSL port
if (ssl_port != 0)
{
// if the socket is already open with the port we want, just leave it
error_code err;
if (!m_ssl_udp_socket.is_open()
|| m_ssl_udp_socket.local_endpoint(err) != ssl_bind_ep
|| err)
{
m_ssl_udp_socket.bind(ssl_bind_if, ec);
if (ec)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("SSL: cannot bind to UDP interface \"%s\": %s"
, print_endpoint(m_listen_interface).c_str(), ec.message().c_str());
#endif
if (m_alerts.should_post<listen_failed_alert>())
{
m_alerts.emplace_alert<listen_failed_alert>(ssl_bind_if.address().to_string()
, ssl_port, listen_failed_alert::bind, ec, listen_failed_alert::utp_ssl);
}
m_ssl_udp_socket.close();
ec.clear();
}
else
{
maybe_update_udp_mapping(0, true, ssl_port, ssl_port);
maybe_update_udp_mapping(1, true, ssl_port, ssl_port);
}
m_ssl_udp_socket.set_proxy_settings(proxy());
}
}
else
{
m_ssl_udp_socket.close();
// if there are mappings for the SSL socket, delete them now
if (m_ssl_udp_mapping[0] != -1 && m_natpmp)
{
m_natpmp->delete_mapping(m_ssl_udp_mapping[0]);
m_ssl_udp_mapping[0] = -1;
}
if (m_ssl_udp_mapping[1] != -1 && m_upnp)
{
m_upnp->delete_mapping(m_ssl_udp_mapping[1]);
m_ssl_udp_mapping[1] = -1;
}
}
#endif // TORRENT_USE_OPENSSL
udp::endpoint const udp_bind_ep(m_listen_interface.address()
, m_listen_interface.port());
// if the socket is already open with the port we want, just leave it
error_code err;
if (!m_udp_socket.is_open()
|| m_udp_socket.local_endpoint(err) != m_listen_interface
|| err)
{
m_udp_socket.bind(udp_bind_ep, ec);
if (ec)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("cannot bind to UDP interface \"%s\": %s"
, print_endpoint(m_listen_interface).c_str(), ec.message().c_str());
#endif
if (m_alerts.should_post<listen_failed_alert>())
{
m_alerts.emplace_alert<listen_failed_alert>(m_listen_interface.address().to_string()
, m_listen_interface.port()
, listen_failed_alert::bind
, ec, listen_failed_alert::udp);
}
m_udp_socket.close();
if (listen_port_retries > 0)
{
m_listen_interface.port(m_listen_interface.port() + 1);
// update the actual port m_listen_interface was derived from also
if (!m_listen_interfaces.empty())
m_listen_interfaces[0].second += 1;
--listen_port_retries;
goto retry;
}
return;
}
else
{
m_external_udp_port = m_udp_socket.local_port();
maybe_update_udp_mapping(0, false, m_listen_interface.port(), m_listen_interface.port());
maybe_update_udp_mapping(1, false, m_listen_interface.port(), m_listen_interface.port());
}
m_udp_socket.set_proxy_settings(proxy());
}
// we made it! now post all the listen_succeeded_alerts
for (std::list<listen_socket_t>::iterator i = m_listen_sockets.begin()
, end(m_listen_sockets.end()); i != end; ++i)
{
listen_succeeded_alert::socket_type_t const socket_type = i->ssl
? listen_succeeded_alert::tcp_ssl
: listen_succeeded_alert::tcp;
if (!m_alerts.should_post<listen_succeeded_alert>()) continue;
error_code error;
tcp::endpoint bind_ep = i->sock->local_endpoint(error);
if (error) continue;
m_alerts.emplace_alert<listen_succeeded_alert>(bind_ep, socket_type);
}
#ifdef TORRENT_USE_OPENSSL
if (m_ssl_udp_socket.is_open())
{
if (m_alerts.should_post<listen_succeeded_alert>())
m_alerts.emplace_alert<listen_succeeded_alert>(
ssl_bind_ep, listen_succeeded_alert::utp_ssl);
}
#endif
if (m_udp_socket.is_open())
{
if (m_alerts.should_post<listen_succeeded_alert>())
m_alerts.emplace_alert<listen_succeeded_alert>(m_listen_interface
, listen_succeeded_alert::udp);
}
if (m_settings.get_int(settings_pack::peer_tos) != 0)
{
update_peer_tos();
}
ec.clear();
set_socket_buffer_size(m_udp_socket, m_settings, ec);
if (ec)
{
if (m_alerts.should_post<udp_error_alert>())
m_alerts.emplace_alert<udp_error_alert>(udp::endpoint(), ec);
}
// initiate accepting on the listen sockets
for (std::list<listen_socket_t>::iterator i = m_listen_sockets.begin()
, end(m_listen_sockets.end()); i != end; ++i)
async_accept(i->sock, i->ssl);
open_new_incoming_socks_connection();
#if TORRENT_USE_I2P
open_new_incoming_i2p_connection();
#endif
if (!m_listen_sockets.empty())
{
tcp::endpoint local = m_listen_sockets.front().sock->local_endpoint(ec);
if (!ec) remap_tcp_ports(3, local.port(), ssl_listen_port());
}
}
void session_impl::remap_tcp_ports(boost::uint32_t mask, int tcp_port, int ssl_port)
{
#ifndef TORRENT_USE_OPENSSL
TORRENT_UNUSED(ssl_port);
#endif
if ((mask & 1) && m_natpmp)
{
if (m_tcp_mapping[0] != -1) m_natpmp->delete_mapping(m_tcp_mapping[0]);
m_tcp_mapping[0] = m_natpmp->add_mapping(natpmp::tcp, tcp_port, tcp_port);
#ifdef TORRENT_USE_OPENSSL
if (m_ssl_tcp_mapping[0] != -1)
{
m_natpmp->delete_mapping(m_ssl_tcp_mapping[0]);
m_ssl_tcp_mapping[0] = -1;
}
if (ssl_port > 0) m_ssl_tcp_mapping[0] = m_natpmp->add_mapping(natpmp::tcp
, ssl_port, ssl_port);
#endif
}
if ((mask & 2) && m_upnp)
{
if (m_tcp_mapping[1] != -1) m_upnp->delete_mapping(m_tcp_mapping[1]);
m_tcp_mapping[1] = m_upnp->add_mapping(upnp::tcp, tcp_port, tcp_port);
#ifdef TORRENT_USE_OPENSSL
if (m_ssl_tcp_mapping[1] != -1)
{
m_upnp->delete_mapping(m_ssl_tcp_mapping[1]);
m_ssl_tcp_mapping[1] = -1;
}
if (ssl_port > 0) m_ssl_tcp_mapping[1] = m_upnp->add_mapping(upnp::tcp
, ssl_port, ssl_port);
#endif
}
}
void session_impl::open_new_incoming_socks_connection()
{
int const proxy_type = m_settings.get_int(settings_pack::proxy_type);
if (proxy_type != settings_pack::socks5
&& proxy_type != settings_pack::socks5_pw
&& proxy_type != settings_pack::socks4)
return;
if (m_socks_listen_socket) return;
m_socks_listen_socket = boost::make_shared<socket_type>(boost::ref(m_io_service));
bool const ret = instantiate_connection(m_io_service, proxy()
, *m_socks_listen_socket, NULL, NULL, false, false);
TORRENT_ASSERT_VAL(ret, ret);
TORRENT_UNUSED(ret);
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_socks_listen");
#endif
socks5_stream& s = *m_socks_listen_socket->get<socks5_stream>();
m_socks_listen_port = m_listen_interface.port();
if (m_socks_listen_port == 0) m_socks_listen_port = 2000 + random() % 60000;
s.async_listen(tcp::endpoint(address_v4::any(), m_socks_listen_port)
, boost::bind(&session_impl::on_socks_listen, this
, m_socks_listen_socket, _1));
}
void session_impl::on_socks_listen(boost::shared_ptr<socket_type> const& sock
, error_code const& e)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::on_socks_listen");
#endif
TORRENT_ASSERT(sock == m_socks_listen_socket || !m_socks_listen_socket);
if (e)
{
m_socks_listen_socket.reset();
if (e == boost::asio::error::operation_aborted) return;
if (m_alerts.should_post<listen_failed_alert>())
m_alerts.emplace_alert<listen_failed_alert>("socks5"
, -1, listen_failed_alert::accept, e
, listen_failed_alert::socks5);
return;
}
error_code ec;
tcp::endpoint ep = sock->local_endpoint(ec);
TORRENT_ASSERT(!ec);
TORRENT_UNUSED(ec);
if (m_alerts.should_post<listen_succeeded_alert>())
m_alerts.emplace_alert<listen_succeeded_alert>(
ep, listen_succeeded_alert::socks5);
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_socks_accept");
#endif
socks5_stream& s = *m_socks_listen_socket->get<socks5_stream>();
s.async_accept(boost::bind(&session_impl::on_socks_accept, this
, m_socks_listen_socket, _1));
}
void session_impl::on_socks_accept(boost::shared_ptr<socket_type> const& s
, error_code const& e)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::on_socks_accept");
#endif
TORRENT_ASSERT(s == m_socks_listen_socket || !m_socks_listen_socket);
m_socks_listen_socket.reset();
if (e == boost::asio::error::operation_aborted) return;
if (e)
{
if (m_alerts.should_post<listen_failed_alert>())
m_alerts.emplace_alert<listen_failed_alert>("socks5"
, -1, listen_failed_alert::accept, e
, listen_failed_alert::socks5);
return;
}
open_new_incoming_socks_connection();
incoming_connection(s);
}
void session_impl::update_i2p_bridge()
{
// we need this socket to be open before we
// can make name lookups for trackers for instance.
// pause the session now and resume it once we've
// established the i2p SAM connection
#if TORRENT_USE_I2P
if (m_settings.get_str(settings_pack::i2p_hostname).empty())
{
error_code ec;
m_i2p_conn.close(ec);
return;
}
m_i2p_conn.open(m_settings.get_str(settings_pack::i2p_hostname)
, m_settings.get_int(settings_pack::i2p_port)
, boost::bind(&session_impl::on_i2p_open, this, _1));
#endif
}
#if TORRENT_USE_I2P
proxy_settings session_impl::i2p_proxy() const
{
proxy_settings ret;
ret.hostname = m_settings.get_str(settings_pack::i2p_hostname);
ret.type = settings_pack::i2p_proxy;
ret.port = m_settings.get_int(settings_pack::i2p_port);
return ret;
}
void session_impl::on_i2p_open(error_code const& ec)
{
if (ec)
{
if (m_alerts.should_post<i2p_alert>())
m_alerts.emplace_alert<i2p_alert>(ec);
#ifndef TORRENT_DISABLE_LOGGING
session_log("i2p open failed (%d) %s", ec.value(), ec.message().c_str());
#endif
}
// now that we have our i2p connection established
// it's OK to start torrents and use this socket to
// do i2p name lookups
open_new_incoming_i2p_connection();
}
void session_impl::open_new_incoming_i2p_connection()
{
if (!m_i2p_conn.is_open()) return;
if (m_i2p_listen_socket) return;
m_i2p_listen_socket = boost::shared_ptr<socket_type>(new socket_type(m_io_service));
bool ret = instantiate_connection(m_io_service, m_i2p_conn.proxy()
, *m_i2p_listen_socket, NULL, NULL, true, false);
TORRENT_ASSERT_VAL(ret, ret);
TORRENT_UNUSED(ret);
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_i2p_accept");
#endif
i2p_stream& s = *m_i2p_listen_socket->get<i2p_stream>();
s.set_command(i2p_stream::cmd_accept);
s.set_session_id(m_i2p_conn.session_id());
s.async_connect(tcp::endpoint(address_v4::any(), m_listen_interface.port())
, boost::bind(&session_impl::on_i2p_accept, this, m_i2p_listen_socket, _1));
}
void session_impl::on_i2p_accept(boost::shared_ptr<socket_type> const& s
, error_code const& e)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::on_i2p_accept");
#endif
m_i2p_listen_socket.reset();
if (e == boost::asio::error::operation_aborted) return;
if (e)
{
if (m_alerts.should_post<listen_failed_alert>())
m_alerts.emplace_alert<listen_failed_alert>("i2p"
, m_listen_interface.port()
, listen_failed_alert::accept
, e, listen_failed_alert::i2p);
#ifndef TORRENT_DISABLE_LOGGING
session_log("cannot bind to port %d: %s"
, m_listen_interface.port(), e.message().c_str());
#endif
return;
}
open_new_incoming_i2p_connection();
incoming_connection(s);
}
#endif
bool session_impl::incoming_packet(error_code const& ec
, udp::endpoint const& ep, char const*, int)
{
m_stats_counters.inc_stats_counter(counters::on_udp_counter);
if (ec)
{
// don't bubble up operation aborted errors to the user
if (ec != boost::asio::error::operation_aborted
&& m_alerts.should_post<udp_error_alert>())
m_alerts.emplace_alert<udp_error_alert>(ep, ec);
#ifndef TORRENT_DISABLE_LOGGING
session_log("UDP socket error: (%d) %s", ec.value(), ec.message().c_str());
#endif
}
return false;
}
void session_impl::async_accept(boost::shared_ptr<tcp::acceptor> const& listener, bool ssl)
{
TORRENT_ASSERT(!m_abort);
shared_ptr<socket_type> c(new socket_type(m_io_service));
tcp::socket* str = 0;
#ifdef TORRENT_USE_OPENSSL
if (ssl)
{
// accept connections initializing the SSL connection to
// use the generic m_ssl_ctx context. However, since it has
// the servername callback set on it, we will switch away from
// this context into a specific torrent once we start handshaking
c->instantiate<ssl_stream<tcp::socket> >(m_io_service, &m_ssl_ctx);
str = &c->get<ssl_stream<tcp::socket> >()->next_layer();
}
else
#endif
{
c->instantiate<tcp::socket>(m_io_service);
str = c->get<tcp::socket>();
}
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_accept_connection");
#endif
#ifdef TORRENT_USE_OPENSSL
TORRENT_ASSERT(ssl == is_ssl(*c));
#endif
listener->async_accept(*str
, boost::bind(&session_impl::on_accept_connection, this, c
, boost::weak_ptr<tcp::acceptor>(listener), _1, ssl));
}
void session_impl::on_accept_connection(shared_ptr<socket_type> const& s
, weak_ptr<tcp::acceptor> listen_socket, error_code const& e, bool ssl)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::on_accept_connection");
#endif
m_stats_counters.inc_stats_counter(counters::on_accept_counter);
TORRENT_ASSERT(is_single_thread());
boost::shared_ptr<tcp::acceptor> listener = listen_socket.lock();
if (!listener) return;
if (e == boost::asio::error::operation_aborted) return;
if (m_abort) return;
error_code ec;
if (e)
{
tcp::endpoint ep = listener->local_endpoint(ec);
#ifndef TORRENT_DISABLE_LOGGING
session_log("error accepting connection on '%s': %s"
, print_endpoint(ep).c_str(), e.message().c_str());
#endif
#ifdef TORRENT_WINDOWS
// Windows sometimes generates this error. It seems to be
// non-fatal and we have to do another async_accept.
if (e.value() == ERROR_SEM_TIMEOUT)
{
async_accept(listener, ssl);
return;
}
#endif
#ifdef TORRENT_BSD
// Leopard sometimes generates an "invalid argument" error. It seems to be
// non-fatal and we have to do another async_accept.
if (e.value() == EINVAL)
{
async_accept(listener, ssl);
return;
}
#endif
if (e == boost::system::errc::too_many_files_open)
{
// if we failed to accept an incoming connection
// because we have too many files open, try again
// and lower the number of file descriptors used
// elsewere.
if (m_settings.get_int(settings_pack::connections_limit) > 10)
{
// now, disconnect a random peer
torrent_map::iterator i = std::max_element(m_torrents.begin()
, m_torrents.end()
, boost::bind(&torrent::num_peers
, boost::bind(&torrent_map::value_type::second, _1))
< boost::bind(&torrent::num_peers
, boost::bind(&torrent_map::value_type::second, _2))
);
if (m_alerts.should_post<performance_alert>())
m_alerts.emplace_alert<performance_alert>(
torrent_handle(), performance_alert::too_few_file_descriptors);
if (i != m_torrents.end())
{
i->second->disconnect_peers(1, e);
}
m_settings.set_int(settings_pack::connections_limit, m_connections.size());
}
// try again, but still alert the user of the problem
async_accept(listener, ssl);
}
if (m_alerts.should_post<listen_failed_alert>())
{
error_code err;
m_alerts.emplace_alert<listen_failed_alert>(ep.address().to_string()
, ep.port(), listen_failed_alert::accept, e
, ssl ? listen_failed_alert::tcp_ssl : listen_failed_alert::tcp);
}
return;
}
async_accept(listener, ssl);
#ifdef TORRENT_USE_OPENSSL
if (ssl)
{
TORRENT_ASSERT(is_ssl(*s));
// for SSL connections, incoming_connection() is called
// after the handshake is done
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::ssl_handshake");
#endif
s->get<ssl_stream<tcp::socket> >()->async_accept_handshake(
boost::bind(&session_impl::ssl_handshake, this, _1, s));
m_incoming_sockets.insert(s);
}
else
#endif
{
incoming_connection(s);
}
}
#ifdef TORRENT_USE_OPENSSL
void session_impl::on_incoming_utp_ssl(boost::shared_ptr<socket_type> const& s)
{
TORRENT_ASSERT(is_ssl(*s));
// for SSL connections, incoming_connection() is called
// after the handshake is done
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::ssl_handshake");
#endif
s->get<ssl_stream<utp_stream> >()->async_accept_handshake(
boost::bind(&session_impl::ssl_handshake, this, _1, s));
m_incoming_sockets.insert(s);
}
// to test SSL connections, one can use this openssl command template:
//
// openssl s_client -cert <client-cert>.pem -key <client-private-key>.pem
// -CAfile <torrent-cert>.pem -debug -connect 127.0.0.1:4433 -tls1
// -servername <hex-encoded-info-hash>
void session_impl::ssl_handshake(error_code const& ec, boost::shared_ptr<socket_type> s)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::ssl_handshake");
#endif
TORRENT_ASSERT(is_ssl(*s));
m_incoming_sockets.erase(s);
error_code e;
tcp::endpoint endp = s->remote_endpoint(e);
if (e) return;
#ifndef TORRENT_DISABLE_LOGGING
session_log(" *** peer SSL handshake done [ ip: %s ec: %s socket: %s ]"
, print_endpoint(endp).c_str(), ec.message().c_str(), s->type_name());
#endif
if (ec)
{
if (m_alerts.should_post<peer_error_alert>())
{
m_alerts.emplace_alert<peer_error_alert>(torrent_handle(), endp
, peer_id(), op_ssl_handshake, ec);
}
return;
}
incoming_connection(s);
}
#endif // TORRENT_USE_OPENSSL
void session_impl::incoming_connection(boost::shared_ptr<socket_type> const& s)
{
TORRENT_ASSERT(is_single_thread());
#ifdef TORRENT_USE_OPENSSL
// add the current time to the PRNG, to add more unpredictability
boost::uint64_t now = clock_type::now().time_since_epoch().count();
// assume 12 bits of entropy (i.e. about 8 milliseconds)
RAND_add(&now, 8, 1.5);
#endif
if (m_paused)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log(" <== INCOMING CONNECTION [ ignored, paused ]");
#endif
return;
}
error_code ec;
// we got a connection request!
tcp::endpoint endp = s->remote_endpoint(ec);
if (ec)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log(" <== INCOMING CONNECTION FAILED, could "
"not retrieve remote endpoint: %s"
, ec.message().c_str());
#endif
return;
}
#ifndef TORRENT_DISABLE_LOGGING
session_log(" <== INCOMING CONNECTION %s type: %s"
, print_endpoint(endp).c_str(), s->type_name());
#endif
if (!m_settings.get_bool(settings_pack::enable_incoming_utp)
&& is_utp(*s))
{
#ifndef TORRENT_DISABLE_LOGGING
session_log(" rejected uTP connection");
#endif
if (m_alerts.should_post<peer_blocked_alert>())
m_alerts.emplace_alert<peer_blocked_alert>(torrent_handle()
, endp.address(), peer_blocked_alert::utp_disabled);
return;
}
if (!m_settings.get_bool(settings_pack::enable_incoming_tcp)
&& s->get<tcp::socket>())
{
#ifndef TORRENT_DISABLE_LOGGING
session_log(" rejected TCP connection");
#endif
if (m_alerts.should_post<peer_blocked_alert>())
m_alerts.emplace_alert<peer_blocked_alert>(torrent_handle()
, endp.address(), peer_blocked_alert::tcp_disabled);
return;
}
// if there are outgoing interfaces specified, verify this
// peer is correctly bound to on of them
if (!m_settings.get_str(settings_pack::outgoing_interfaces).empty())
{
tcp::endpoint local = s->local_endpoint(ec);
if (ec)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log(" rejected connection: (%d) %s", ec.value()
, ec.message().c_str());
#endif
return;
}
if (!verify_bound_address(local.address()
, is_utp(*s), ec))
{
if (ec)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log(" rejected connection, not allowed local interface: (%d) %s"
, ec.value(), ec.message().c_str());
#endif
return;
}
#ifndef TORRENT_DISABLE_LOGGING
error_code err;
session_log(" rejected connection, not allowed local interface: %s"
, local.address().to_string(err).c_str());
#endif
if (m_alerts.should_post<peer_blocked_alert>())
m_alerts.emplace_alert<peer_blocked_alert>(torrent_handle()
, endp.address(), peer_blocked_alert::invalid_local_interface);
return;
}
}
// local addresses do not count, since it's likely
// coming from our own client through local service discovery
// and it does not reflect whether or not a router is open
// for incoming connections or not.
if (!is_local(endp.address()))
m_stats_counters.set_value(counters::has_incoming_connections, 1);
// this filter is ignored if a single torrent
// is set to ignore the filter, since this peer might be
// for that torrent
if (m_stats_counters[counters::non_filter_torrents] == 0
&& m_ip_filter
&& (m_ip_filter->access(endp.address()) & ip_filter::blocked))
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("filtered blocked ip");
#endif
if (m_alerts.should_post<peer_blocked_alert>())
m_alerts.emplace_alert<peer_blocked_alert>(torrent_handle()
, endp.address(), peer_blocked_alert::ip_filter);
return;
}
// check if we have any active torrents
// if we don't reject the connection
if (m_torrents.empty())
{
#ifndef TORRENT_DISABLE_LOGGING
session_log(" There are no torrents, disconnect");
#endif
return;
}
// figure out which peer classes this is connections has,
// to get connection_limit_factor
peer_class_set pcs;
set_peer_classes(&pcs, endp.address(), s->type());
int connection_limit_factor = 0;
for (int i = 0; i < pcs.num_classes(); ++i)
{
int pc = pcs.class_at(i);
if (m_classes.at(pc) == NULL) continue;
int f = m_classes.at(pc)->connection_limit_factor;
if (connection_limit_factor < f) connection_limit_factor = f;
}
if (connection_limit_factor == 0) connection_limit_factor = 100;
boost::uint64_t limit = m_settings.get_int(settings_pack::connections_limit);
limit = limit * 100 / connection_limit_factor;
// don't allow more connections than the max setting
// weighed by the peer class' setting
bool reject = num_connections() >= limit + m_settings.get_int(settings_pack::connections_slack);
if (reject)
{
if (m_alerts.should_post<peer_disconnected_alert>())
{
m_alerts.emplace_alert<peer_disconnected_alert>(torrent_handle(), endp, peer_id()
, op_bittorrent, s->type()
, error_code(errors::too_many_connections)
, close_no_reason);
}
#ifndef TORRENT_DISABLE_LOGGING
session_log("number of connections limit exceeded (conns: %d, limit: %d, slack: %d), connection rejected"
, num_connections(), m_settings.get_int(settings_pack::connections_limit)
, m_settings.get_int(settings_pack::connections_slack));
#endif
return;
}
// if we don't have any active torrents, there's no
// point in accepting this connection. If, however,
// the setting to start up queued torrents when they
// get an incoming connection is enabled, we cannot
// perform this check.
if (!m_settings.get_bool(settings_pack::incoming_starts_queued_torrents))
{
bool has_active_torrent = false;
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
if (i->second->allows_peers())
{
has_active_torrent = true;
break;
}
}
if (!has_active_torrent)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log(" There are no _active_ torrents, disconnect");
#endif
return;
}
}
m_stats_counters.inc_stats_counter(counters::incoming_connections);
if (m_alerts.should_post<incoming_connection_alert>())
m_alerts.emplace_alert<incoming_connection_alert>(s->type(), endp);
setup_socket_buffers(*s);
peer_connection_args pack;
pack.ses = this;
pack.sett = &m_settings;
pack.stats_counters = &m_stats_counters;
pack.allocator = this;
pack.disk_thread = &m_disk_thread;
pack.ios = &m_io_service;
pack.tor = boost::weak_ptr<torrent>();
pack.s = s;
pack.endp = endp;
pack.peerinfo = 0;
boost::shared_ptr<peer_connection> c
= boost::make_shared<bt_peer_connection>(boost::cref(pack)
, get_peer_id());
#if TORRENT_USE_ASSERTS
c->m_in_constructor = false;
#endif
if (!c->is_disconnecting())
{
// in case we've exceeded the limit, let this peer know that
// as soon as it's received the handshake, it needs to either
// disconnect or pick another peer to disconnect
if (num_connections() >= limit)
c->peer_exceeds_limit();
TORRENT_ASSERT(!c->m_in_constructor);
m_connections.insert(c);
c->start();
}
}
void session_impl::setup_socket_buffers(socket_type& s)
{
error_code ec;
set_socket_buffer_size(s, m_settings, ec);
}
// if cancel_with_cq is set, the peer connection is
// currently expected to be scheduled for a connection
// with the connection queue, and should be cancelled
// TODO: should this function take a shared_ptr instead?
void session_impl::close_connection(peer_connection* p
, error_code const& ec)
{
TORRENT_ASSERT(is_single_thread());
boost::shared_ptr<peer_connection> sp(p->self());
// someone else is holding a reference, it's important that
// it's destructed from the network thread. Make sure the
// last reference is held by the network thread.
if (!sp.unique())
m_undead_peers.push_back(sp);
// too expensive
// INVARIANT_CHECK;
#ifdef TORRENT_DEBUG
// for (aux::session_impl::torrent_map::const_iterator i = m_torrents.begin()
// , end(m_torrents.end()); i != end; ++i)
// TORRENT_ASSERT(!i->second->has_peer((peer_connection*)p));
#endif
#ifndef TORRENT_DISABLE_LOGGING
session_log(" CLOSING CONNECTION %s : %s"
, print_endpoint(p->remote()).c_str(), ec.message().c_str());
#else
TORRENT_UNUSED(ec);
#endif
TORRENT_ASSERT(p->is_disconnecting());
TORRENT_ASSERT(sp.use_count() > 0);
connection_map::iterator i = m_connections.find(sp);
// make sure the next disk peer round-robin cursor stays valid
if (i != m_connections.end()) m_connections.erase(i);
}
void session_impl::set_peer_id(peer_id const& id)
{
m_peer_id = id;
}
void session_impl::set_key(int key)
{
m_key = key;
}
int session_impl::next_port() const
{
int start = m_settings.get_int(settings_pack::outgoing_port);
int num = m_settings.get_int(settings_pack::num_outgoing_ports);
std::pair<int, int> out_ports(start, start + num);
if (m_next_port < out_ports.first || m_next_port > out_ports.second)
m_next_port = out_ports.first;
int port = m_next_port;
++m_next_port;
if (m_next_port > out_ports.second) m_next_port = out_ports.first;
#ifndef TORRENT_DISABLE_LOGGING
session_log(" *** BINDING OUTGOING CONNECTION [ port: %d ]", port);
#endif
return port;
}
int session_impl::rate_limit(peer_class_t c, int channel) const
{
TORRENT_ASSERT(channel >= 0 && channel <= 1);
if (channel < 0 || channel > 1) return 0;
peer_class const* pc = m_classes.at(c);
if (pc == 0) return 0;
return pc->channel[channel].throttle();
}
int session_impl::upload_rate_limit(peer_class_t c) const
{
return rate_limit(c, peer_connection::upload_channel);
}
int session_impl::download_rate_limit(peer_class_t c) const
{
return rate_limit(c, peer_connection::download_channel);
}
void session_impl::set_rate_limit(peer_class_t c, int channel, int limit)
{
TORRENT_ASSERT(is_single_thread());
TORRENT_ASSERT(limit >= -1);
TORRENT_ASSERT(channel >= 0 && channel <= 1);
if (channel < 0 || channel > 1) return;
peer_class* pc = m_classes.at(c);
if (pc == 0) return;
if (limit <= 0) limit = 0;
pc->channel[channel].throttle(limit);
}
void session_impl::set_upload_rate_limit(peer_class_t c, int limit)
{
set_rate_limit(c, peer_connection::upload_channel, limit);
}
void session_impl::set_download_rate_limit(peer_class_t c, int limit)
{
set_rate_limit(c, peer_connection::download_channel, limit);
}
#if TORRENT_USE_ASSERTS
bool session_impl::has_peer(peer_connection const* p) const
{
TORRENT_ASSERT(is_single_thread());
return std::find_if(m_connections.begin(), m_connections.end()
, boost::bind(&boost::shared_ptr<peer_connection>::get, _1) == p)
!= m_connections.end();
}
bool session_impl::any_torrent_has_peer(peer_connection const* p) const
{
for (aux::session_impl::torrent_map::const_iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
if (i->second->has_peer(p)) return true;
return false;
}
#endif
void session_impl::sent_bytes(int bytes_payload, int bytes_protocol)
{
m_stats_counters.inc_stats_counter(counters::sent_bytes
, bytes_payload + bytes_protocol);
m_stats_counters.inc_stats_counter(counters::sent_payload_bytes
, bytes_payload);
m_stat.sent_bytes(bytes_payload, bytes_protocol);
}
void session_impl::received_bytes(int bytes_payload, int bytes_protocol)
{
m_stats_counters.inc_stats_counter(counters::recv_bytes
, bytes_payload + bytes_protocol);
m_stats_counters.inc_stats_counter(counters::recv_payload_bytes
, bytes_payload);
m_stat.received_bytes(bytes_payload, bytes_protocol);
}
void session_impl::trancieve_ip_packet(int bytes, bool ipv6)
{
m_stat.trancieve_ip_packet(bytes, ipv6);
}
void session_impl::sent_syn(bool ipv6)
{
m_stat.sent_syn(ipv6);
}
void session_impl::received_synack(bool ipv6)
{
m_stat.received_synack(ipv6);
}
void session_impl::on_tick(error_code const& e)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::on_tick");
#endif
m_stats_counters.inc_stats_counter(counters::on_tick_counter);
TORRENT_ASSERT(is_single_thread());
// submit all disk jobs when we leave this function
deferred_submit_jobs();
aux::update_time_now();
time_point now = aux::time_now();
// remove undead peers that only have this list as their reference keeping them alive
if (!m_undead_peers.empty())
{
std::vector<boost::shared_ptr<peer_connection> >::iterator remove_it
= std::remove_if(m_undead_peers.begin(), m_undead_peers.end()
, boost::bind(&boost::shared_ptr<peer_connection>::unique, _1));
m_undead_peers.erase(remove_it, m_undead_peers.end());
if (m_undead_peers.empty())
{
// we just removed our last "undead" peer (i.e. a peer connection
// that had some external reference to it). It's now safe to
// shut-down
if (m_abort)
{
m_io_service.post(boost::bind(&session_impl::abort_stage2, this));
}
}
}
// too expensive
// INVARIANT_CHECK;
// we have to keep ticking the utp socket manager
// until they're all closed
if (m_abort)
{
if (m_utp_socket_manager.num_sockets() == 0
&& m_undead_peers.empty())
return;
#if defined TORRENT_ASIO_DEBUGGING
fprintf(stderr, "uTP sockets left: %d undead-peers left: %d\n"
, m_utp_socket_manager.num_sockets()
, int(m_undead_peers.size()));
#endif
}
if (e == boost::asio::error::operation_aborted) return;
if (e)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("*** TICK TIMER FAILED %s", e.message().c_str());
#endif
std::abort();
}
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_tick");
#endif
error_code ec;
m_timer.expires_at(now + milliseconds(m_settings.get_int(settings_pack::tick_interval)), ec);
m_timer.async_wait(make_tick_handler(boost::bind(&session_impl::on_tick, this, _1)));
m_download_rate.update_quotas(now - m_last_tick);
m_upload_rate.update_quotas(now - m_last_tick);
m_last_tick = now;
m_utp_socket_manager.tick(now);
#ifdef TORRENT_USE_OPENSSL
m_ssl_utp_socket_manager.tick(now);
#endif
// only tick the following once per second
if (now - m_last_second_tick < seconds(1)) return;
#ifndef TORRENT_DISABLE_DHT
if (m_dht
&& m_dht_interval_update_torrents < 40
&& m_dht_interval_update_torrents != int(m_torrents.size()))
update_dht_announce_interval();
#endif
int tick_interval_ms = int(total_milliseconds(now - m_last_second_tick));
m_last_second_tick = now;
m_tick_residual += tick_interval_ms - 1000;
boost::int64_t const stime = session_time();
if (stime > 65000)
{
// we're getting close to the point where our timestamps
// in torrent_peer are wrapping. We need to step all counters back
// four hours. This means that any timestamp that refers to a time
// more than 18.2 - 4 = 14.2 hours ago, will be incremented to refer to
// 14.2 hours ago.
m_created += hours(4);
const int four_hours = 60 * 60 * 4;
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
i->second->step_session_time(four_hours);
}
}
#ifndef TORRENT_DISABLE_EXTENSIONS
if (m_session_extension_features & plugin::tick_feature)
{
for (ses_extension_list_t::const_iterator i = m_ses_extensions.begin()
, end(m_ses_extensions.end()); i != end; ++i)
{
TORRENT_TRY {
(*i)->on_tick();
} TORRENT_CATCH(std::exception&) {}
}
}
#endif
// don't do any of the following while we're shutting down
if (m_abort) return;
#ifndef TORRENT_NO_DEPRECATE
// --------------------------------------------------------------
// RSS feeds
// --------------------------------------------------------------
if (now > m_next_rss_update)
update_rss_feeds();
#endif
switch (m_settings.get_int(settings_pack::mixed_mode_algorithm))
{
case settings_pack::prefer_tcp:
set_upload_rate_limit(m_tcp_peer_class, 0);
set_download_rate_limit(m_tcp_peer_class, 0);
break;
case settings_pack::peer_proportional:
{
int num_peers[2][2] = {{0, 0}, {0, 0}};
for (connection_map::iterator i = m_connections.begin()
, end(m_connections.end());i != end; ++i)
{
peer_connection& p = *(*i);
if (p.in_handshake()) continue;
int protocol = 0;
if (is_utp(*p.get_socket())) protocol = 1;
if (p.download_queue().size() + p.request_queue().size() > 0)
++num_peers[protocol][peer_connection::download_channel];
if (p.upload_queue().size() > 0)
++num_peers[protocol][peer_connection::upload_channel];
}
peer_class* pc = m_classes.at(m_tcp_peer_class);
bandwidth_channel* tcp_channel = pc->channel;
int stat_rate[] = {m_stat.upload_rate(), m_stat.download_rate() };
// never throttle below this
int lower_limit[] = {5000, 30000};
for (int i = 0; i < 2; ++i)
{
// if there are no uploading uTP peers, don't throttle TCP up
if (num_peers[1][i] == 0)
{
tcp_channel[i].throttle(0);
}
else
{
if (num_peers[0][i] == 0) num_peers[0][i] = 1;
int total_peers = num_peers[0][i] + num_peers[1][i];
// this are 64 bits since it's multiplied by the number
// of peers, which otherwise might overflow an int
boost::uint64_t rate = stat_rate[i];
tcp_channel[i].throttle((std::max)(int(rate * num_peers[0][i] / total_peers), lower_limit[i]));
}
}
}
break;
}
// --------------------------------------------------------------
// auto managed torrent
// --------------------------------------------------------------
if (!m_paused) m_auto_manage_time_scaler--;
if (m_auto_manage_time_scaler < 0)
{
INVARIANT_CHECK;
m_auto_manage_time_scaler = settings().get_int(settings_pack::auto_manage_interval);
recalculate_auto_managed_torrents();
}
// --------------------------------------------------------------
// check for incoming connections that might have timed out
// --------------------------------------------------------------
for (connection_map::iterator i = m_connections.begin();
i != m_connections.end();)
{
peer_connection* p = (*i).get();
++i;
// ignore connections that already have a torrent, since they
// are ticked through the torrents' second_tick
if (!p->associated_torrent().expired()) continue;
// TODO: have a separate list for these connections, instead of having to loop through all of them
int timeout = m_settings.get_int(settings_pack::handshake_timeout);
#if TORRENT_USE_I2P
timeout *= is_i2p(*p->get_socket()) ? 4 : 1;
#endif
if (m_last_tick - p->connected_time () > seconds(timeout))
p->disconnect(errors::timed_out, op_bittorrent);
}
// --------------------------------------------------------------
// second_tick every torrent (that wants it)
// --------------------------------------------------------------
#if TORRENT_DEBUG_STREAMING > 0
printf("\033[2J\033[0;0H");
#endif
std::vector<torrent*>& want_tick = m_torrent_lists[torrent_want_tick];
for (int i = 0; i < int(want_tick.size()); ++i)
{
torrent& t = *want_tick[i];
TORRENT_ASSERT(t.want_tick());
TORRENT_ASSERT(!t.is_aborted());
t.second_tick(tick_interval_ms);
// if the call to second_tick caused the torrent
// to no longer want to be ticked (i.e. it was
// removed from the list) we need to back up the counter
// to not miss the torrent after it
if (!t.want_tick()) --i;
}
// TODO: this should apply to all bandwidth channels
if (m_settings.get_bool(settings_pack::rate_limit_ip_overhead))
{
int up_limit = upload_rate_limit(m_global_class);
int down_limit = download_rate_limit(m_global_class);
if (down_limit > 0
&& m_stat.download_ip_overhead() >= down_limit
&& m_alerts.should_post<performance_alert>())
{
m_alerts.emplace_alert<performance_alert>(torrent_handle()
, performance_alert::download_limit_too_low);
}
if (up_limit > 0
&& m_stat.upload_ip_overhead() >= up_limit
&& m_alerts.should_post<performance_alert>())
{
m_alerts.emplace_alert<performance_alert>(torrent_handle()
, performance_alert::upload_limit_too_low);
}
}
m_peak_up_rate = (std::max)(m_stat.upload_rate(), m_peak_up_rate);
m_peak_down_rate = (std::max)(m_stat.download_rate(), m_peak_down_rate);
m_stat.second_tick(tick_interval_ms);
// --------------------------------------------------------------
// scrape paused torrents that are auto managed
// (unless the session is paused)
// --------------------------------------------------------------
if (!is_paused())
{
INVARIANT_CHECK;
--m_auto_scrape_time_scaler;
if (m_auto_scrape_time_scaler <= 0)
{
std::vector<torrent*>& want_scrape = m_torrent_lists[torrent_want_scrape];
m_auto_scrape_time_scaler = m_settings.get_int(settings_pack::auto_scrape_interval)
/ (std::max)(1, int(want_scrape.size()));
if (m_auto_scrape_time_scaler < m_settings.get_int(settings_pack::auto_scrape_min_interval))
m_auto_scrape_time_scaler = m_settings.get_int(settings_pack::auto_scrape_min_interval);
if (!want_scrape.empty() && !m_abort)
{
if (m_next_scrape_torrent >= int(want_scrape.size()))
m_next_scrape_torrent = 0;
torrent& t = *want_scrape[m_next_scrape_torrent];
TORRENT_ASSERT(t.is_paused() && t.is_auto_managed());
// false means it's not triggered by the user, but automatically
// by libtorrent
t.scrape_tracker(-1, false);
++m_next_scrape_torrent;
if (m_next_scrape_torrent >= int(want_scrape.size()))
m_next_scrape_torrent = 0;
}
}
}
// --------------------------------------------------------------
// refresh torrent suggestions
// --------------------------------------------------------------
--m_suggest_timer;
if (m_settings.get_int(settings_pack::suggest_mode) != settings_pack::no_piece_suggestions
&& m_suggest_timer <= 0)
{
INVARIANT_CHECK;
m_suggest_timer = 10;
torrent_map::iterator least_recently_refreshed = m_torrents.begin();
if (m_next_suggest_torrent >= int(m_torrents.size()))
m_next_suggest_torrent = 0;
std::advance(least_recently_refreshed, m_next_suggest_torrent);
if (least_recently_refreshed != m_torrents.end())
least_recently_refreshed->second->refresh_suggest_pieces();
++m_next_suggest_torrent;
}
#ifndef TORRENT_NO_DEPRECATE
// --------------------------------------------------------------
// refresh explicit disk read cache
// --------------------------------------------------------------
--m_cache_rotation_timer;
if (m_settings.get_bool(settings_pack::explicit_read_cache)
&& m_cache_rotation_timer <= 0)
{
INVARIANT_CHECK;
m_cache_rotation_timer = m_settings.get_int(settings_pack::explicit_cache_interval);
torrent_map::iterator least_recently_refreshed = m_torrents.begin();
if (m_next_explicit_cache_torrent >= int(m_torrents.size()))
m_next_explicit_cache_torrent = 0;
std::advance(least_recently_refreshed, m_next_explicit_cache_torrent);
// how many blocks does this torrent get?
int cache_size = (std::max)(0, m_settings.get_int(settings_pack::cache_size) * 9 / 10);
if (m_connections.empty())
{
// if we don't have any connections at all, split the
// cache evenly across all torrents
cache_size = cache_size / (std::max)(int(m_torrents.size()), 1);
}
else
{
cache_size = cache_size * least_recently_refreshed->second->num_peers()
/ m_connections.size();
}
if (least_recently_refreshed != m_torrents.end())
least_recently_refreshed->second->refresh_explicit_cache(cache_size);
++m_next_explicit_cache_torrent;
}
#endif
// --------------------------------------------------------------
// connect new peers
// --------------------------------------------------------------
try_connect_more_peers();
// --------------------------------------------------------------
// unchoke set calculations
// --------------------------------------------------------------
m_unchoke_time_scaler--;
if (m_unchoke_time_scaler <= 0 && !m_connections.empty())
{
m_unchoke_time_scaler = settings().get_int(settings_pack::unchoke_interval);
recalculate_unchoke_slots();
}
// --------------------------------------------------------------
// optimistic unchoke calculation
// --------------------------------------------------------------
m_optimistic_unchoke_time_scaler--;
if (m_optimistic_unchoke_time_scaler <= 0)
{
m_optimistic_unchoke_time_scaler
= settings().get_int(settings_pack::optimistic_unchoke_interval);
recalculate_optimistic_unchoke_slots();
}
// --------------------------------------------------------------
// disconnect peers when we have too many
// --------------------------------------------------------------
--m_disconnect_time_scaler;
if (m_disconnect_time_scaler <= 0)
{
m_disconnect_time_scaler = m_settings.get_int(settings_pack::peer_turnover_interval);
// if the connections_limit is too low, the disconnect
// logic is disabled, since it is too disruptive
if (m_settings.get_int(settings_pack::connections_limit) > 5)
{
if (num_connections() >= m_settings.get_int(settings_pack::connections_limit)
* m_settings.get_int(settings_pack::peer_turnover_cutoff) / 100
&& !m_torrents.empty())
{
// every 90 seconds, disconnect the worst peers
// if we have reached the connection limit
torrent_map::iterator i = std::max_element(m_torrents.begin(), m_torrents.end()
, boost::bind(&torrent::num_peers, boost::bind(&torrent_map::value_type::second, _1))
< boost::bind(&torrent::num_peers, boost::bind(&torrent_map::value_type::second, _2)));
TORRENT_ASSERT(i != m_torrents.end());
int peers_to_disconnect = (std::min)((std::max)(
int(i->second->num_peers() * m_settings.get_int(settings_pack::peer_turnover) / 100), 1)
, i->second->num_connect_candidates());
i->second->disconnect_peers(peers_to_disconnect
, error_code(errors::optimistic_disconnect));
}
else
{
// if we haven't reached the global max. see if any torrent
// has reached its local limit
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
boost::shared_ptr<torrent> t = i->second;
// ths disconnect logic is disabled for torrents with
// too low connection limit
if (t->num_peers() < t->max_connections()
* m_settings.get_int(settings_pack::peer_turnover_cutoff) / 100
|| t->max_connections() < 6)
continue;
int peers_to_disconnect = (std::min)((std::max)(int(t->num_peers()
* m_settings.get_int(settings_pack::peer_turnover) / 100), 1)
, t->num_connect_candidates());
t->disconnect_peers(peers_to_disconnect
, error_code(errors::optimistic_disconnect));
}
}
}
}
m_tick_residual = m_tick_residual % 1000;
// m_peer_pool.release_memory();
}
namespace {
// returns the index of the first set bit.
int log2(boost::uint32_t v)
{
// http://graphics.stanford.edu/~seander/bithacks.html#IntegerLogDeBruijn
static const int MultiplyDeBruijnBitPosition[32] =
{
0, 9, 1, 10, 13, 21, 2, 29, 11, 14, 16, 18, 22, 25, 3, 30,
8, 12, 20, 28, 15, 17, 24, 7, 19, 27, 23, 6, 26, 5, 4, 31
};
v |= v >> 1; // first round down to one less than a power of 2
v |= v >> 2;
v |= v >> 4;
v |= v >> 8;
v |= v >> 16;
return MultiplyDeBruijnBitPosition[boost::uint32_t(v * 0x07C4ACDDU) >> 27];
}
} // anonymous namespace
void session_impl::received_buffer(int s)
{
int index = (std::min)(log2(s >> 3), 17);
m_stats_counters.inc_stats_counter(counters::socket_recv_size3 + index);
}
void session_impl::sent_buffer(int s)
{
int index = (std::min)(log2(s >> 3), 17);
m_stats_counters.inc_stats_counter(counters::socket_send_size3 + index);
}
#ifndef TORRENT_NO_DEPRECATE
void session_impl::update_rss_feeds()
{
time_t now_posix = time(0);
time_point min_update = max_time();
time_point now = aux::time_now();
for (std::vector<boost::shared_ptr<feed> >::iterator i
= m_feeds.begin(), end(m_feeds.end()); i != end; ++i)
{
feed& f = **i;
int delta = f.next_update(now_posix);
if (delta <= 0)
delta = f.update_feed();
TORRENT_ASSERT(delta >= 0);
time_point next_update = now + seconds(delta);
if (next_update < min_update) min_update = next_update;
}
m_next_rss_update = min_update;
}
#endif
void session_impl::prioritize_connections(boost::weak_ptr<torrent> t)
{
m_prio_torrents.push_back(std::make_pair(t, 10));
}
#ifndef TORRENT_DISABLE_DHT
void session_impl::add_dht_node(udp::endpoint n)
{
TORRENT_ASSERT(is_single_thread());
if (m_dht) m_dht->add_node(n);
else m_dht_nodes.push_back(n);
}
bool session_impl::has_dht() const
{
return m_dht.get();
}
void session_impl::prioritize_dht(boost::weak_ptr<torrent> t)
{
TORRENT_ASSERT(!m_abort);
if (m_abort) return;
TORRENT_ASSERT(m_dht);
m_dht_torrents.push_back(t);
#ifndef TORRENT_DISABLE_LOGGING
boost::shared_ptr<torrent> tor = t.lock();
if (tor)
session_log("prioritizing DHT announce: \"%s\"", tor->name().c_str());
#endif
// trigger a DHT announce right away if we just added a new torrent and
// there's no back-log. in the timer handler, as long as there are more
// high priority torrents to be announced to the DHT, it will keep the
// timer interval short until all torrents have been announced.
if (m_dht_torrents.size() == 1)
{
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_dht_announce");
#endif
error_code ec;
m_dht_announce_timer.expires_from_now(seconds(0), ec);
m_dht_announce_timer.async_wait(
bind(&session_impl::on_dht_announce, this, _1));
}
}
void session_impl::on_dht_announce(error_code const& e)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::on_dht_announce");
#endif
TORRENT_ASSERT(is_single_thread());
if (e)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("aborting DHT announce timer (%d): %s"
, e.value(), e.message().c_str());
#endif
return;
}
if (m_abort)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("aborting DHT announce timer: m_abort set");
#endif
return;
}
if (!m_dht)
{
m_dht_torrents.clear();
return;
}
TORRENT_ASSERT(m_dht);
// announce to DHT every 15 minutes
int delay = (std::max)(m_settings.get_int(settings_pack::dht_announce_interval)
/ (std::max)(int(m_torrents.size()), 1), 1);
if (!m_dht_torrents.empty())
{
// we have prioritized torrents that need
// an initial DHT announce. Don't wait too long
// until we announce those.
delay = (std::min)(4, delay);
}
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_dht_announce");
#endif
error_code ec;
m_dht_announce_timer.expires_from_now(seconds(delay), ec);
m_dht_announce_timer.async_wait(
bind(&session_impl::on_dht_announce, this, _1));
if (!m_dht_torrents.empty())
{
boost::shared_ptr<torrent> t;
do
{
t = m_dht_torrents.front().lock();
m_dht_torrents.pop_front();
} while (!t && !m_dht_torrents.empty());
if (t)
{
t->dht_announce();
return;
}
}
if (m_torrents.empty()) return;
if (m_next_dht_torrent == m_torrents.end())
m_next_dht_torrent = m_torrents.begin();
m_next_dht_torrent->second->dht_announce();
// TODO: 2 make a list for torrents that want to be announced on the DHT so we
// don't have to loop over all torrents, just to find the ones that want to announce
++m_next_dht_torrent;
if (m_next_dht_torrent == m_torrents.end())
m_next_dht_torrent = m_torrents.begin();
}
#endif
void session_impl::on_lsd_announce(error_code const& e)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::on_lsd_announce");
#endif
m_stats_counters.inc_stats_counter(counters::on_lsd_counter);
TORRENT_ASSERT(is_single_thread());
if (e) return;
if (m_abort) return;
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_lsd_announce");
#endif
// announce on local network every 5 minutes
int delay = (std::max)(m_settings.get_int(settings_pack::local_service_announce_interval)
/ (std::max)(int(m_torrents.size()), 1), 1);
error_code ec;
m_lsd_announce_timer.expires_from_now(seconds(delay), ec);
m_lsd_announce_timer.async_wait(
bind(&session_impl::on_lsd_announce, this, _1));
if (m_torrents.empty()) return;
if (m_next_lsd_torrent == m_torrents.end())
m_next_lsd_torrent = m_torrents.begin();
m_next_lsd_torrent->second->lsd_announce();
++m_next_lsd_torrent;
if (m_next_lsd_torrent == m_torrents.end())
m_next_lsd_torrent = m_torrents.begin();
}
void session_impl::auto_manage_checking_torrents(std::vector<torrent*>& list
, int& limit)
{
for (std::vector<torrent*>::iterator i = list.begin()
, end(list.end()); i != end; ++i)
{
torrent* t = *i;
TORRENT_ASSERT(t->state() == torrent_status::checking_files);
TORRENT_ASSERT(t->is_auto_managed());
if (limit <= 0)
{
t->pause();
}
else
{
t->resume();
t->start_checking();
--limit;
}
}
}
void session_impl::auto_manage_torrents(std::vector<torrent*>& list
, int& dht_limit, int& tracker_limit
, int& lsd_limit, int& hard_limit, int type_limit)
{
for (std::vector<torrent*>::iterator i = list.begin()
, end(list.end()); i != end; ++i)
{
torrent* t = *i;
TORRENT_ASSERT(t->state() != torrent_status::checking_files);
// inactive torrents don't count (and if you configured them to do so,
// the torrent won't say it's inactive)
if (hard_limit > 0 && t->is_inactive())
{
t->set_announce_to_dht(--dht_limit >= 0);
t->set_announce_to_trackers(--tracker_limit >= 0);
t->set_announce_to_lsd(--lsd_limit >= 0);
--hard_limit;
#ifndef TORRENT_DISABLE_LOGGING
if (!t->allows_peers())
t->log_to_all_peers("auto manager starting (inactive) torrent");
#endif
t->set_allow_peers(true);
t->update_gauge();
t->update_want_peers();
continue;
}
if (type_limit > 0 && hard_limit > 0)
{
t->set_announce_to_dht(--dht_limit >= 0);
t->set_announce_to_trackers(--tracker_limit >= 0);
t->set_announce_to_lsd(--lsd_limit >= 0);
--hard_limit;
--type_limit;
#ifndef TORRENT_DISABLE_LOGGING
if (!t->allows_peers())
t->log_to_all_peers("auto manager starting torrent");
#endif
t->set_allow_peers(true);
t->update_gauge();
t->update_want_peers();
continue;
}
#ifndef TORRENT_DISABLE_LOGGING
if (t->allows_peers())
t->log_to_all_peers("auto manager pausing torrent");
#endif
// use graceful pause for auto-managed torrents
t->set_allow_peers(false, torrent::flag_graceful_pause
| torrent::flag_clear_disk_cache);
t->set_announce_to_dht(false);
t->set_announce_to_trackers(false);
t->set_announce_to_lsd(false);
t->update_gauge();
t->update_want_peers();
}
}
int session_impl::get_int_setting(int n) const
{
int const v = settings().get_int(n);
if (v < 0) return (std::numeric_limits<int>::max)();
return v;
}
void session_impl::recalculate_auto_managed_torrents()
{
INVARIANT_CHECK;
m_last_auto_manage = time_now();
m_need_auto_manage = false;
if (is_paused()) return;
// make copies of the lists of torrents that we want to consider for auto
// management. We need copies because they will be sorted.
std::vector<torrent*> checking
= torrent_list(session_interface::torrent_checking_auto_managed);
std::vector<torrent*> downloaders
= torrent_list(session_interface::torrent_downloading_auto_managed);
std::vector<torrent*> seeds
= torrent_list(session_interface::torrent_seeding_auto_managed);
// these counters are set to the number of torrents
// of each kind we're allowed to have active
int downloading_limit = get_int_setting(settings_pack::active_downloads);
int seeding_limit = get_int_setting(settings_pack::active_seeds);
int checking_limit = get_int_setting(settings_pack::active_checking);
int dht_limit = get_int_setting(settings_pack::active_dht_limit);
int tracker_limit = get_int_setting(settings_pack::active_tracker_limit);
int lsd_limit = get_int_setting(settings_pack::active_lsd_limit);
int hard_limit = get_int_setting(settings_pack::active_limit);
// if hard_limit is <= 0, all torrents in these lists should be paused.
// The order is not relevant
if (hard_limit > 0)
{
// we only need to sort the first n torrents here, where n is the number
// of checking torrents we allow. The rest of the list is still used to
// make sure the remaining torrents are paused, but their order is not
// relevant
std::partial_sort(checking.begin(), checking.begin() +
(std::min)(checking_limit, int(checking.size())), checking.end()
, boost::bind(&torrent::sequence_number, _1) < boost::bind(&torrent::sequence_number, _2));
std::partial_sort(downloaders.begin(), downloaders.begin() +
(std::min)(hard_limit, int(downloaders.size())), downloaders.end()
, boost::bind(&torrent::sequence_number, _1) < boost::bind(&torrent::sequence_number, _2));
std::partial_sort(seeds.begin(), seeds.begin() +
(std::min)(hard_limit, int(seeds.size())), seeds.end()
, boost::bind(&torrent::seed_rank, _1, boost::ref(m_settings))
> boost::bind(&torrent::seed_rank, _2, boost::ref(m_settings)));
}
auto_manage_checking_torrents(checking, checking_limit);
if (settings().get_bool(settings_pack::auto_manage_prefer_seeds))
{
auto_manage_torrents(seeds, dht_limit, tracker_limit, lsd_limit
, hard_limit, seeding_limit);
auto_manage_torrents(downloaders, dht_limit, tracker_limit, lsd_limit
, hard_limit, downloading_limit);
}
else
{
auto_manage_torrents(downloaders, dht_limit, tracker_limit, lsd_limit
, hard_limit, downloading_limit);
auto_manage_torrents(seeds, dht_limit, tracker_limit, lsd_limit
, hard_limit, seeding_limit);
}
}
namespace {
bool last_optimistic_unchoke_cmp(torrent_peer const* const l
, torrent_peer const* const r)
{
return l->last_optimistically_unchoked
< r->last_optimistically_unchoked;
}
}
void session_impl::recalculate_optimistic_unchoke_slots()
{
INVARIANT_CHECK;
TORRENT_ASSERT(is_single_thread());
if (m_stats_counters[counters::num_unchoke_slots] == 0) return;
std::vector<torrent_peer*> opt_unchoke;
// collect the currently optimistically unchoked peers here, so we can
// choke them when we've found new optimistic unchoke candidates.
std::vector<torrent_peer*> prev_opt_unchoke;
// TODO: 3 it would probably make sense to have a separate list of peers
// that are eligible for optimistic unchoke, similar to the torrents
// perhaps this could even iterate over the pool allocators of
// torrent_peer objects. It could probably be done in a single pass and
// collect the n best candidates. maybe just a queue of peers would make
// even more sense, just pick the next peer in the queue for unchoking. It
// would be O(1).
for (connection_map::iterator i = m_connections.begin()
, end(m_connections.end()); i != end; ++i)
{
peer_connection* p = i->get();
TORRENT_ASSERT(p);
torrent_peer* pi = p->peer_info_struct();
if (!pi) continue;
if (pi->web_seed) continue;
if (pi->optimistically_unchoked)
{
prev_opt_unchoke.push_back(pi);
}
torrent* t = p->associated_torrent().lock().get();
if (!t) continue;
// TODO: 3 peers should know whether their torrent is paused or not,
// instead of having to ask it over and over again
if (t->is_paused()) continue;
if (!p->is_connecting()
&& !p->is_disconnecting()
&& p->is_peer_interested()
&& t->free_upload_slots()
&& (p->is_choked() || pi->optimistically_unchoked)
&& !p->ignore_unchoke_slots()
&& t->valid_metadata())
{
opt_unchoke.push_back(pi);
}
}
// find the peers that has been waiting the longest to be optimistically
// unchoked
int num_opt_unchoke = m_settings.get_int(settings_pack::num_optimistic_unchoke_slots);
int const allowed_unchoke_slots = m_stats_counters[counters::num_unchoke_slots];
if (num_opt_unchoke == 0) num_opt_unchoke = (std::max)(1, allowed_unchoke_slots / 5);
if (num_opt_unchoke > int(opt_unchoke.size())) num_opt_unchoke =
int(opt_unchoke.size());
// find the n best optimistic unchoke candidates
std::partial_sort(opt_unchoke.begin()
, opt_unchoke.begin() + num_opt_unchoke
, opt_unchoke.end(), &last_optimistic_unchoke_cmp);
#ifndef TORRENT_DISABLE_EXTENSIONS
if (m_session_extension_features & plugin::optimistic_unchoke_feature)
{
// if there is an extension that wants to reorder the optimistic
// unchoke peers, first convert the vector into one containing
// peer_connection_handles, since that's the exported API
std::vector<peer_connection_handle> peers;
peers.reserve(opt_unchoke.size());
for (std::vector<torrent_peer*>::iterator i = opt_unchoke.begin()
, end(opt_unchoke.end()); i != end; ++i)
{
peers.push_back(peer_connection_handle(static_cast<peer_connection*>((*i)->connection)->self()));
}
for (ses_extension_list_t::iterator i = m_ses_extensions.begin()
, end(m_ses_extensions.end()); i != end; ++i)
{
if ((*i)->on_optimistic_unchoke(peers))
break;
}
// then convert back to the internal torrent_peer pointers
opt_unchoke.clear();
for (std::vector<peer_connection_handle>::iterator i = peers.begin()
, end(peers.end()); i != end; ++i)
{
opt_unchoke.push_back(i->native_handle()->peer_info_struct());
}
}
#endif
// unchoke the first num_opt_unchoke peers in the candidate set
// and make sure that the others are choked
std::vector<torrent_peer*>::iterator opt_unchoke_end = opt_unchoke.begin()
+ num_opt_unchoke;
for (std::vector<torrent_peer*>::iterator i = opt_unchoke.begin();
i != opt_unchoke_end; ++i)
{
torrent_peer* pi = *i;
peer_connection* p = static_cast<peer_connection*>(pi->connection);
if (pi->optimistically_unchoked)
{
#ifndef TORRENT_DISABLE_LOGGING
p->peer_log(peer_log_alert::info, "OPTIMISTIC UNCHOKE"
, "already unchoked | session-time: %d"
, pi->last_optimistically_unchoked);
#endif
TORRENT_ASSERT(!pi->connection->is_choked());
// remove this peer from prev_opt_unchoke, to prevent us from
// choking it later. This peer gets another round of optimistic
// unchoke
std::vector<torrent_peer*>::iterator existing =
std::find(prev_opt_unchoke.begin(), prev_opt_unchoke.end(), pi);
TORRENT_ASSERT(existing != prev_opt_unchoke.end());
prev_opt_unchoke.erase(existing);
}
else
{
TORRENT_ASSERT(p->is_choked());
boost::shared_ptr<torrent> t = p->associated_torrent().lock();
bool ret = t->unchoke_peer(*p, true);
TORRENT_ASSERT(ret);
if (ret)
{
pi->optimistically_unchoked = true;
m_stats_counters.inc_stats_counter(counters::num_peers_up_unchoked_optimistic);
pi->last_optimistically_unchoked = boost::uint16_t(session_time());
#ifndef TORRENT_DISABLE_LOGGING
p->peer_log(peer_log_alert::info, "OPTIMISTIC UNCHOKE"
, "session-time: %d", pi->last_optimistically_unchoked);
#endif
}
}
}
// now, choke all the previous optimistically unchoked peers
for (std::vector<torrent_peer*>::iterator i = prev_opt_unchoke.begin()
, end(prev_opt_unchoke.end()); i != end; ++i)
{
torrent_peer* pi = *i;
TORRENT_ASSERT(pi->optimistically_unchoked);
peer_connection* p = static_cast<peer_connection*>(pi->connection);
boost::shared_ptr<torrent> t = p->associated_torrent().lock();
pi->optimistically_unchoked = false;
m_stats_counters.inc_stats_counter(counters::num_peers_up_unchoked_optimistic, -1);
t->choke_peer(*p);
}
// if we have too many unchoked peers now, we need to trigger the regular
// choking logic to choke some
if (m_stats_counters[counters::num_unchoke_slots]
< m_stats_counters[counters::num_peers_up_unchoked_all])
{
m_unchoke_time_scaler = 0;
}
}
void session_impl::try_connect_more_peers()
{
if (m_abort) return;
if (num_connections() >= m_settings.get_int(settings_pack::connections_limit))
return;
// this is the maximum number of connections we will
// attempt this tick
int max_connections = m_settings.get_int(settings_pack::connection_speed);
// zero connections speeds are allowed, we just won't make any connections
if (max_connections <= 0) return;
// this loop will "hand out" connection_speed to the torrents, in a round
// robin fashion, so that every torrent is equally likely to connect to a
// peer
// boost connections are connections made by torrent connection
// boost, which are done immediately on a tracker response. These
// connections needs to be deducted from this second
if (m_boost_connections > 0)
{
if (m_boost_connections > max_connections)
{
m_boost_connections -= max_connections;
max_connections = 0;
}
else
{
max_connections -= m_boost_connections;
m_boost_connections = 0;
}
}
// TODO: use a lower limit than m_settings.connections_limit
// to allocate the to 10% or so of connection slots for incoming
// connections
int limit = m_settings.get_int(settings_pack::connections_limit)
- num_connections();
// this logic is here to smooth out the number of new connection
// attempts over time, to prevent connecting a large number of
// sockets, wait 10 seconds, and then try again
if (m_settings.get_bool(settings_pack::smooth_connects) && max_connections > (limit+1) / 2)
max_connections = (limit+1) / 2;
std::vector<torrent*>& want_peers_download = m_torrent_lists[torrent_want_peers_download];
std::vector<torrent*>& want_peers_finished = m_torrent_lists[torrent_want_peers_finished];
// if no torrent want any peers, just return
if (want_peers_download.empty() && want_peers_finished.empty()) return;
// if we don't have any connection attempt quota, return
if (max_connections <= 0) return;
INVARIANT_CHECK;
int steps_since_last_connect = 0;
int num_torrents = int(want_peers_finished.size() + want_peers_download.size());
for (;;)
{
if (m_next_downloading_connect_torrent >= int(want_peers_download.size()))
m_next_downloading_connect_torrent = 0;
if (m_next_finished_connect_torrent >= int(want_peers_finished.size()))
m_next_finished_connect_torrent = 0;
torrent* t = NULL;
// there are prioritized torrents. Pick one of those
while (!m_prio_torrents.empty())
{
t = m_prio_torrents.front().first.lock().get();
--m_prio_torrents.front().second;
if (m_prio_torrents.front().second > 0
&& t != NULL
&& t->want_peers()) break;
m_prio_torrents.pop_front();
t = NULL;
}
if (t == NULL)
{
if ((m_download_connect_attempts >= m_settings.get_int(
settings_pack::connect_seed_every_n_download)
&& want_peers_finished.size())
|| want_peers_download.empty())
{
// pick a finished torrent to give a peer to
t = want_peers_finished[m_next_finished_connect_torrent];
TORRENT_ASSERT(t->want_peers_finished());
m_download_connect_attempts = 0;
++m_next_finished_connect_torrent;
}
else
{
// pick a downloading torrent to give a peer to
t = want_peers_download[m_next_downloading_connect_torrent];
TORRENT_ASSERT(t->want_peers_download());
++m_download_connect_attempts;
++m_next_downloading_connect_torrent;
}
}
TORRENT_ASSERT(t->want_peers());
TORRENT_ASSERT(t->allows_peers());
TORRENT_TRY
{
if (t->try_connect_peer())
{
--max_connections;
steps_since_last_connect = 0;
m_stats_counters.inc_stats_counter(counters::connection_attempts);
}
}
TORRENT_CATCH(std::bad_alloc&)
{
// we ran out of memory trying to connect to a peer
// lower the global limit to the number of peers
// we already have
m_settings.set_int(settings_pack::connections_limit, num_connections());
if (m_settings.get_int(settings_pack::connections_limit) < 2)
m_settings.set_int(settings_pack::connections_limit, 2);
}
++steps_since_last_connect;
// if there are no more free connection slots, abort
if (max_connections == 0) return;
// there are no more torrents that want peers
if (want_peers_download.empty() && want_peers_finished.empty()) break;
// if we have gone a whole loop without
// handing out a single connection, break
if (steps_since_last_connect > num_torrents + 1) break;
// maintain the global limit on number of connections
if (num_connections() >= m_settings.get_int(settings_pack::connections_limit)) break;
}
}
void session_impl::recalculate_unchoke_slots()
{
TORRENT_ASSERT(is_single_thread());
INVARIANT_CHECK;
time_point const now = aux::time_now();
time_duration const unchoke_interval = now - m_last_choke;
m_last_choke = now;
// build list of all peers that are
// unchokable.
// TODO: 3 there should be a pre-calculated list of all peers eligible for
// unchoking
std::vector<peer_connection*> peers;
for (connection_map::iterator i = m_connections.begin();
i != m_connections.end();)
{
boost::shared_ptr<peer_connection> p = *i;
TORRENT_ASSERT(p);
++i;
torrent* const t = p->associated_torrent().lock().get();
torrent_peer* const pi = p->peer_info_struct();
if (p->ignore_unchoke_slots() || t == 0 || pi == 0
|| pi->web_seed || t->is_paused())
{
p->reset_choke_counters();
continue;
}
if (!p->is_peer_interested()
|| p->is_disconnecting()
|| p->is_connecting())
{
// this peer is not unchokable. So, if it's unchoked
// already, make sure to choke it.
if (p->is_choked())
{
p->reset_choke_counters();
continue;
}
if (pi && pi->optimistically_unchoked)
{
m_stats_counters.inc_stats_counter(counters::num_peers_up_unchoked_optimistic, -1);
pi->optimistically_unchoked = false;
// force a new optimistic unchoke
m_optimistic_unchoke_time_scaler = 0;
// TODO: post a message to have this happen
// immediately instead of waiting for the next tick
}
t->choke_peer(*p);
p->reset_choke_counters();
continue;
}
peers.push_back(p.get());
}
// the unchoker wants an estimate of our upload rate capacity
// (used by bittyrant)
int max_upload_rate = upload_rate_limit(m_global_class);
if (m_settings.get_int(settings_pack::choking_algorithm)
== settings_pack::bittyrant_choker
&& max_upload_rate == 0)
{
// we don't know at what rate we can upload. If we have a
// measurement of the peak, use that + 10kB/s, otherwise
// assume 20 kB/s
max_upload_rate = (std::max)(20000, m_peak_up_rate + 10000);
if (m_alerts.should_post<performance_alert>())
m_alerts.emplace_alert<performance_alert>(torrent_handle()
, performance_alert::bittyrant_with_no_uplimit);
}
int const allowed_upload_slots = unchoke_sort(peers, max_upload_rate
, unchoke_interval, m_settings);
m_stats_counters.set_value(counters::num_unchoke_slots
, allowed_upload_slots);
#ifndef TORRENT_DISABLE_LOGGING
session_log("RECALCULATE UNCHOKE SLOTS: [ peers: %d "
"eligible-peers: %d"
" max_upload_rate: %d"
" allowed-slots: %d ]"
, int(m_connections.size())
, int(peers.size())
, max_upload_rate
, allowed_upload_slots);
#endif
int const unchoked_counter_optimistic
= m_stats_counters[counters::num_peers_up_unchoked_optimistic];
int const num_opt_unchoke = (unchoked_counter_optimistic == 0)
? (std::max)(1, allowed_upload_slots / 5) : unchoked_counter_optimistic;
int unchoke_set_size = allowed_upload_slots - num_opt_unchoke;
// go through all the peers and unchoke the first ones and choke
// all the other ones.
for (std::vector<peer_connection*>::iterator i = peers.begin()
, end(peers.end()); i != end; ++i)
{
peer_connection* p = *i;
TORRENT_ASSERT(p);
TORRENT_ASSERT(!p->ignore_unchoke_slots());
// this will update the m_uploaded_at_last_unchoke
p->reset_choke_counters();
torrent* t = p->associated_torrent().lock().get();
TORRENT_ASSERT(t);
if (unchoke_set_size > 0)
{
// yes, this peer should be unchoked
if (p->is_choked())
{
if (!t->unchoke_peer(*p))
continue;
}
--unchoke_set_size;
TORRENT_ASSERT(p->peer_info_struct());
if (p->peer_info_struct()->optimistically_unchoked)
{
// force a new optimistic unchoke
// since this one just got promoted into the
// proper unchoke set
m_optimistic_unchoke_time_scaler = 0;
p->peer_info_struct()->optimistically_unchoked = false;
m_stats_counters.inc_stats_counter(counters::num_peers_up_unchoked_optimistic, -1);
}
}
else
{
// no, this peer should be choked
TORRENT_ASSERT(p->peer_info_struct());
if (!p->is_choked() && !p->peer_info_struct()->optimistically_unchoked)
t->choke_peer(*p);
}
}
}
void session_impl::cork_burst(peer_connection* p)
{
TORRENT_ASSERT(is_single_thread());
if (p->is_corked()) return;
p->cork_socket();
m_delayed_uncorks.push_back(p);
}
void session_impl::do_delayed_uncork()
{
m_stats_counters.inc_stats_counter(counters::on_disk_counter);
TORRENT_ASSERT(is_single_thread());
for (std::vector<peer_connection*>::iterator i = m_delayed_uncorks.begin()
, end(m_delayed_uncorks.end()); i != end; ++i)
{
(*i)->uncork_socket();
}
m_delayed_uncorks.clear();
}
boost::shared_ptr<torrent> session_impl::delay_load_torrent(sha1_hash const& info_hash
, peer_connection* pc)
{
#ifndef TORRENT_DISABLE_EXTENSIONS
for (ses_extension_list_t::iterator i = m_ses_extensions.begin()
, end(m_ses_extensions.end()); i != end; ++i)
{
add_torrent_params p;
if ((*i)->on_unknown_torrent(info_hash, peer_connection_handle(pc->self()), p))
{
error_code ec;
torrent_handle handle = add_torrent(p, ec);
return handle.native_handle();
}
}
#else
TORRENT_UNUSED(pc);
TORRENT_UNUSED(info_hash);
#endif
return boost::shared_ptr<torrent>();
}
// the return value from this function is valid only as long as the
// session is locked!
boost::weak_ptr<torrent> session_impl::find_torrent(sha1_hash const& info_hash) const
{
TORRENT_ASSERT(is_single_thread());
torrent_map::const_iterator i = m_torrents.find(info_hash);
#if defined TORRENT_DEBUG && defined TORRENT_EXPENSIVE_INVARIANT_CHECKS
for (torrent_map::const_iterator j
= m_torrents.begin(); j != m_torrents.end(); ++j)
{
torrent* p = boost::get_pointer(j->second);
TORRENT_ASSERT(p);
}
#endif
if (i != m_torrents.end()) return i->second;
return boost::weak_ptr<torrent>();
}
void session_impl::insert_torrent(sha1_hash const& ih, boost::shared_ptr<torrent> const& t
, std::string uuid)
{
m_torrents.insert(std::make_pair(ih, t));
if (!uuid.empty()) m_uuids.insert(std::make_pair(uuid, t));
TORRENT_ASSERT(m_torrents.size() >= m_torrent_lru.size());
}
void session_impl::set_queue_position(torrent* me, int p)
{
if (p >= 0 && me->queue_position() == -1)
{
for (session_impl::torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
torrent* t = i->second.get();
if (t->queue_position() >= p)
{
t->set_queue_position_impl(t->queue_position()+1);
t->state_updated();
}
if (t->queue_position() >= p) t->set_queue_position_impl(t->queue_position()+1);
}
++m_max_queue_pos;
me->set_queue_position_impl((std::min)(m_max_queue_pos, p));
}
else if (p < 0)
{
TORRENT_ASSERT(me->queue_position() >= 0);
TORRENT_ASSERT(p == -1);
for (session_impl::torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
torrent* t = i->second.get();
if (t == me) continue;
if (t->queue_position() == -1) continue;
if (t->queue_position() >= me->queue_position())
{
t->set_queue_position_impl(t->queue_position()-1);
t->state_updated();
}
}
--m_max_queue_pos;
me->set_queue_position_impl(p);
}
else if (p < me->queue_position())
{
for (session_impl::torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
torrent* t = i->second.get();
if (t == me) continue;
if (t->queue_position() == -1) continue;
if (t->queue_position() >= p
&& t->queue_position() < me->queue_position())
{
t->set_queue_position_impl(t->queue_position()+1);
t->state_updated();
}
}
me->set_queue_position_impl(p);
}
else if (p > me->queue_position())
{
for (session_impl::torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
torrent* t = i->second.get();
int pos = t->queue_position();
if (t == me) continue;
if (pos == -1) continue;
if (pos <= p
&& pos > me->queue_position()
&& pos != -1)
{
t->set_queue_position_impl(t->queue_position()-1);
t->state_updated();
}
}
me->set_queue_position_impl((std::min)(m_max_queue_pos, p));
}
trigger_auto_manage();
}
#if !defined(TORRENT_DISABLE_ENCRYPTION) && !defined(TORRENT_DISABLE_EXTENSIONS)
torrent const* session_impl::find_encrypted_torrent(sha1_hash const& info_hash
, sha1_hash const& xor_mask)
{
sha1_hash obfuscated = info_hash;
obfuscated ^= xor_mask;
torrent_map::iterator i = m_obfuscated_torrents.find(obfuscated);
if (i == m_obfuscated_torrents.end()) return NULL;
return i->second.get();
}
#endif
boost::weak_ptr<torrent> session_impl::find_torrent(std::string const& uuid) const
{
TORRENT_ASSERT(is_single_thread());
std::map<std::string, boost::shared_ptr<torrent> >::const_iterator i
= m_uuids.find(uuid);
if (i != m_uuids.end()) return i->second;
return boost::weak_ptr<torrent>();
}
#ifndef TORRENT_DISABLE_MUTABLE_TORRENTS
std::vector<boost::shared_ptr<torrent> > session_impl::find_collection(
std::string const& collection) const
{
std::vector<boost::shared_ptr<torrent> > ret;
for (session_impl::torrent_map::const_iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
boost::shared_ptr<torrent> t = i->second;
if (!t) continue;
std::vector<std::string> const& c = t->torrent_file().collections();
if (std::count(c.begin(), c.end(), collection) == 0) continue;
ret.push_back(t);
}
return ret;
}
#endif //TORRENT_DISABLE_MUTABLE_TORRENTS
namespace {
// returns true if lhs is a better disconnect candidate than rhs
bool compare_disconnect_torrent(session_impl::torrent_map::value_type const& lhs
, session_impl::torrent_map::value_type const& rhs)
{
// a torrent with 0 peers is never a good disconnect candidate
// since there's nothing to disconnect
if ((lhs.second->num_peers() == 0) != (rhs.second->num_peers() == 0))
return lhs.second->num_peers() != 0;
// other than that, always prefer to disconnect peers from seeding torrents
// in order to not harm downloading ones
if (lhs.second->is_seed() != rhs.second->is_seed())
return lhs.second->is_seed();
return lhs.second->num_peers() > rhs.second->num_peers();
}
} // anonymous namespace
boost::weak_ptr<torrent> session_impl::find_disconnect_candidate_torrent() const
{
aux::session_impl::torrent_map::const_iterator i = std::min_element(m_torrents.begin(), m_torrents.end()
, &compare_disconnect_torrent);
TORRENT_ASSERT(i != m_torrents.end());
if (i == m_torrents.end()) return boost::shared_ptr<torrent>();
return i->second;
}
#ifndef TORRENT_DISABLE_LOGGING
TORRENT_FORMAT(2,3)
void session_impl::session_log(char const* fmt, ...) const
{
if (!m_alerts.should_post<log_alert>()) return;
va_list v;
va_start(v, fmt);
session_vlog(fmt, v);
va_end(v);
}
TORRENT_FORMAT(2, 0)
void session_impl::session_vlog(char const* fmt, va_list& v) const
{
if (!m_alerts.should_post<log_alert>()) return;
char buf[1024];
vsnprintf(buf, sizeof(buf), fmt, v);
m_alerts.emplace_alert<log_alert>(buf);
}
#endif
void session_impl::get_torrent_status(std::vector<torrent_status>* ret
, boost::function<bool(torrent_status const&)> const& pred
, boost::uint32_t flags) const
{
for (torrent_map::const_iterator i
= m_torrents.begin(), end(m_torrents.end());
i != end; ++i)
{
if (i->second->is_aborted()) continue;
torrent_status st;
i->second->status(&st, flags);
if (!pred(st)) continue;
ret->push_back(st);
}
}
void session_impl::refresh_torrent_status(std::vector<torrent_status>* ret
, boost::uint32_t flags) const
{
for (std::vector<torrent_status>::iterator i
= ret->begin(), end(ret->end()); i != end; ++i)
{
boost::shared_ptr<torrent> t = i->handle.m_torrent.lock();
if (!t) continue;
t->status(&*i, flags);
}
}
void session_impl::post_torrent_updates(boost::uint32_t flags)
{
INVARIANT_CHECK;
TORRENT_ASSERT(is_single_thread());
std::vector<torrent*>& state_updates
= m_torrent_lists[aux::session_impl::torrent_state_updates];
#if TORRENT_USE_ASSERTS
m_posting_torrent_updates = true;
#endif
std::vector<torrent_status> status;
status.reserve(state_updates.size());
// TODO: it might be a nice feature here to limit the number of torrents
// to send in a single update. By just posting the first n torrents, they
// would nicely be round-robined because the torrent lists are always
// pushed back. Perhaps the status_update_alert could even have a fixed
// array of n entries rather than a vector, to further improve memory
// locality.
for (std::vector<torrent*>::iterator i = state_updates.begin()
, end(state_updates.end()); i != end; ++i)
{
torrent* t = *i;
TORRENT_ASSERT(t->m_links[aux::session_impl::torrent_state_updates].in_list());
status.push_back(torrent_status());
// querying accurate download counters may require
// the torrent to be loaded. Loading a torrent, and evicting another
// one will lead to calling state_updated(), which screws with
// this list while we're working on it, and break things
t->status(&status.back(), flags);
t->clear_in_state_update();
}
state_updates.clear();
#if TORRENT_USE_ASSERTS
m_posting_torrent_updates = false;
#endif
m_alerts.emplace_alert<state_update_alert>(status);
}
void session_impl::post_session_stats()
{
m_disk_thread.update_stats_counters(m_stats_counters);
#ifndef TORRENT_DISABLE_DHT
if (m_dht)
m_dht->update_stats_counters(m_stats_counters);
#endif
m_stats_counters.set_value(counters::sent_ip_overhead_bytes
, m_stat.total_transfer(stat::upload_ip_protocol));
m_stats_counters.set_value(counters::recv_ip_overhead_bytes
, m_stat.total_transfer(stat::download_ip_protocol));
m_stats_counters.set_value(counters::limiter_up_queue
, m_upload_rate.queue_size());
m_stats_counters.set_value(counters::limiter_down_queue
, m_download_rate.queue_size());
m_stats_counters.set_value(counters::limiter_up_bytes
, m_upload_rate.queued_bytes());
m_stats_counters.set_value(counters::limiter_down_bytes
, m_download_rate.queued_bytes());
m_alerts.emplace_alert<session_stats_alert>(m_stats_counters);
}
void session_impl::post_dht_stats()
{
std::vector<dht_lookup> requests;
std::vector<dht_routing_bucket> table;
#ifndef TORRENT_DISABLE_DHT
if (m_dht)
m_dht->dht_status(table, requests);
#endif
m_alerts.emplace_alert<dht_stats_alert>(table, requests);
}
std::vector<torrent_handle> session_impl::get_torrents() const
{
std::vector<torrent_handle> ret;
for (torrent_map::const_iterator i
= m_torrents.begin(), end(m_torrents.end());
i != end; ++i)
{
if (i->second->is_aborted()) continue;
ret.push_back(torrent_handle(i->second));
}
return ret;
}
torrent_handle session_impl::find_torrent_handle(sha1_hash const& info_hash)
{
return torrent_handle(find_torrent(info_hash));
}
void session_impl::async_add_torrent(add_torrent_params* params)
{
if (string_begins_no_case("file://", params->url.c_str()) && !params->ti)
{
m_disk_thread.async_load_torrent(params
, boost::bind(&session_impl::on_async_load_torrent, this, _1));
return;
}
error_code ec;
torrent_handle handle = add_torrent(*params, ec);
delete params;
}
void session_impl::on_async_load_torrent(disk_io_job const* j)
{
add_torrent_params* params = static_cast<add_torrent_params*>(j->requester);
error_code ec;
torrent_handle handle;
if (j->error.ec)
{
ec = j->error.ec;
m_alerts.emplace_alert<add_torrent_alert>(handle, *params, ec);
}
else
{
params->url.clear();
params->ti = boost::shared_ptr<torrent_info>(j->buffer.torrent_file);
handle = add_torrent(*params, ec);
}
delete params;
}
#ifndef TORRENT_DISABLE_EXTENSIONS
void session_impl::add_extensions_to_torrent(
boost::shared_ptr<torrent> const& torrent_ptr, void* userdata)
{
for (ses_extension_list_t::iterator i = m_ses_extensions.begin()
, end(m_ses_extensions.end()); i != end; ++i)
{
boost::shared_ptr<torrent_plugin> tp((*i)->new_torrent(torrent_ptr->get_handle(), userdata));
if (tp) torrent_ptr->add_extension(tp);
}
}
#endif
torrent_handle session_impl::add_torrent(add_torrent_params const& p
, error_code& ec)
{
// params is updated by add_torrent_impl()
add_torrent_params params = p;
boost::shared_ptr<torrent> torrent_ptr;
bool added;
boost::tie(torrent_ptr, added) = add_torrent_impl(params, ec);
torrent_handle const handle(torrent_ptr);
m_alerts.emplace_alert<add_torrent_alert>(handle, params, ec);
if (!torrent_ptr) return handle;
// params.info_hash should have been initialized by add_torrent_impl()
TORRENT_ASSERT(params.info_hash != sha1_hash(0));
// --- PEERS --- (delete when merged to master)
std::vector<tcp::endpoint> peers;
parse_magnet_uri_peers(p.url, peers);
for (std::vector<tcp::endpoint>::const_iterator i = peers.begin()
, end(peers.end()); i != end; ++i)
{
torrent_ptr->add_peer(*i , peer_info::resume_data);
}
if (!peers.empty())
torrent_ptr->update_want_peers();
#ifndef TORRENT_DISABLE_DHT
if (params.ti)
{
torrent_info::nodes_t const& nodes = params.ti->nodes();
for (std::vector<std::pair<std::string, int> >::const_iterator i = nodes.begin()
, end(nodes.end()); i != end; ++i)
{
add_dht_node_name(*i);
}
}
#endif
if (m_alerts.should_post<torrent_added_alert>())
m_alerts.emplace_alert<torrent_added_alert>(handle);
// if this was an existing torrent, we can't start it again, or add
// another set of plugins etc. we're done
if (!added) return handle;
torrent_ptr->set_ip_filter(m_ip_filter);
torrent_ptr->start(params);
#ifndef TORRENT_DISABLE_EXTENSIONS
typedef std::vector<boost::function<
boost::shared_ptr<torrent_plugin>(torrent_handle const&, void*)> >
torrent_plugins_t;
for (torrent_plugins_t::const_iterator i = params.extensions.begin()
, end(params.extensions.end()); i != end; ++i)
{
torrent_ptr->add_extension((*i)(handle, params.userdata));
}
add_extensions_to_torrent(torrent_ptr, params.userdata);
#endif
#if TORRENT_HAS_BOOST_UNORDERED
sha1_hash next_lsd(0);
sha1_hash next_dht(0);
if (m_next_lsd_torrent != m_torrents.end())
next_lsd = m_next_lsd_torrent->first;
#ifndef TORRENT_DISABLE_DHT
if (m_next_dht_torrent != m_torrents.end())
next_dht = m_next_dht_torrent->first;
#endif
float load_factor = m_torrents.load_factor();
#endif // TORRENT_HAS_BOOST_UNORDERED
m_torrents.insert(std::make_pair(params.info_hash, torrent_ptr));
TORRENT_ASSERT(m_torrents.size() >= m_torrent_lru.size());
#if !defined(TORRENT_DISABLE_ENCRYPTION) && !defined(TORRENT_DISABLE_EXTENSIONS)
hasher h;
h.update("req2", 4);
h.update(params.info_hash.data(), 20);
// this is SHA1("req2" + info-hash), used for
// encrypted hand shakes
m_obfuscated_torrents.insert(std::make_pair(h.final(), torrent_ptr));
#endif
if (torrent_ptr->is_pinned() == false)
{
evict_torrents_except(torrent_ptr.get());
bump_torrent(torrent_ptr.get());
}
#if TORRENT_HAS_BOOST_UNORDERED
// if this insert made the hash grow, the iterators became invalid
// we need to reset them
if (m_torrents.load_factor() < load_factor)
{
// this indicates the hash table re-hashed
if (!next_lsd.is_all_zeros())
m_next_lsd_torrent = m_torrents.find(next_lsd);
#ifndef TORRENT_DISABLE_DHT
if (!next_dht.is_all_zeros())
m_next_dht_torrent = m_torrents.find(next_dht);
#endif
}
#endif // TORRENT_HAS_BOOST_UNORDERED
if (!params.uuid.empty() || !params.url.empty())
m_uuids.insert(std::make_pair(params.uuid.empty()
? params.url : params.uuid, torrent_ptr));
// recalculate auto-managed torrents sooner (or put it off)
// if another torrent will be added within one second from now
// we want to put it off again anyway. So that while we're adding
// a boat load of torrents, we postpone the recalculation until
// we're done adding them all (since it's kind of an expensive operation)
if (params.flags & add_torrent_params::flag_auto_managed)
{
const int max_downloading = settings().get_int(settings_pack::active_downloads);
const int max_seeds = settings().get_int(settings_pack::active_seeds);
const int max_active = settings().get_int(settings_pack::active_limit);
const int num_downloading
= int(torrent_list(session_interface::torrent_downloading_auto_managed).size());
const int num_seeds
= int(torrent_list(session_interface::torrent_seeding_auto_managed).size());
const int num_active = num_downloading + num_seeds;
// there's no point in triggering the auto manage logic early if we
// don't have a reason to believe anything will change. It's kind of
// expensive.
if ((num_downloading < max_downloading
|| num_seeds < max_seeds)
&& num_active < max_active)
{
trigger_auto_manage();
}
}
return handle;
}
std::pair<boost::shared_ptr<torrent>, bool>
session_impl::add_torrent_impl(
add_torrent_params& params
, error_code& ec)
{
TORRENT_ASSERT(!params.save_path.empty());
typedef boost::shared_ptr<torrent> ptr_t;
#ifndef TORRENT_NO_DEPRECATE
params.update_flags();
#endif
if (string_begins_no_case("magnet:", params.url.c_str()))
{
parse_magnet_uri(params.url, params, ec);
if (ec) return std::make_pair(ptr_t(), false);
params.url.clear();
}
if (string_begins_no_case("file://", params.url.c_str()) && !params.ti)
{
std::string filename = resolve_file_url(params.url);
boost::shared_ptr<torrent_info> t = boost::make_shared<torrent_info>(filename, boost::ref(ec), 0);
if (ec) return std::make_pair(ptr_t(), false);
params.url.clear();
params.ti = t;
}
if (params.ti && !params.ti->is_valid())
{
ec = errors::no_metadata;
return std::make_pair(ptr_t(), false);
}
if (params.ti && params.ti->is_valid() && params.ti->num_files() == 0)
{
ec = errors::no_files_in_torrent;
return std::make_pair(ptr_t(), false);
}
#ifndef TORRENT_DISABLE_DHT
// add params.dht_nodes to the DHT, if enabled
if (!params.dht_nodes.empty())
{
for (std::vector<std::pair<std::string, int> >::const_iterator i = params.dht_nodes.begin()
, end(params.dht_nodes.end()); i != end; ++i)
{
add_dht_node_name(*i);
}
}
#endif
INVARIANT_CHECK;
if (is_aborted())
{
ec = errors::session_is_closing;
return std::make_pair(ptr_t(), false);
}
// figure out the info hash of the torrent and make sure params.info_hash
// is set correctly
if (params.ti) params.info_hash = params.ti->info_hash();
else if (!params.url.empty())
{
// in order to avoid info-hash collisions, for
// torrents where we don't have an info-hash, but
// just a URL, set the temporary info-hash to the
// hash of the URL. This will be changed once we
// have the actual .torrent file
params.info_hash = hasher(&params.url[0], params.url.size()).final();
}
// we don't have a torrent file. If the user provided
// resume data, there may be some metadata in there
// TODO: this logic could probably be less spaghetti looking by being
// moved to a function with early exits
if ((!params.ti || !params.ti->is_valid())
&& !params.resume_data.empty())
{
int pos;
error_code err;
bdecode_node root;
bdecode_node info;
#ifndef TORRENT_DISABLE_LOGGING
session_log("adding magnet link with resume data");
#endif
if (bdecode(&params.resume_data[0], &params.resume_data[0]
+ params.resume_data.size(), root, err, &pos) == 0
&& root.type() == bdecode_node::dict_t
&& (info = root.dict_find_dict("info")))
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("found metadata in resume data");
#endif
// verify the info-hash of the metadata stored in the resume file matches
// the torrent we're loading
std::pair<char const*, int> const buf = info.data_section();
sha1_hash const resume_ih = hasher(buf.first, buf.second).final();
// if url is set, the info_hash is not actually the info-hash of the
// torrent, but the hash of the URL, until we have the full torrent
// only require the info-hash to match if we actually passed in one
if (resume_ih == params.info_hash
|| !params.url.empty()
|| params.info_hash.is_all_zeros())
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("info-hash matched");
#endif
params.ti = boost::make_shared<torrent_info>(resume_ih);
if (params.ti->parse_info_section(info, err, 0))
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("successfully loaded metadata from resume file");
#endif
// make the info-hash be the one in the resume file
params.info_hash = resume_ih;
}
else
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("failed to load metadata from resume file: %s"
, err.message().c_str());
#endif
}
}
#ifndef TORRENT_DISABLE_LOGGING
else
{
session_log("metadata info-hash failed");
}
#endif
}
#ifndef TORRENT_DISABLE_LOGGING
else
{
session_log("no metadata found (\"%s\")", err.message().c_str());
}
#endif
}
// is the torrent already active?
boost::shared_ptr<torrent> torrent_ptr = find_torrent(params.info_hash).lock();
if (!torrent_ptr && !params.uuid.empty()) torrent_ptr = find_torrent(params.uuid).lock();
// if we still can't find the torrent, look for it by url
if (!torrent_ptr && !params.url.empty())
{
torrent_map::iterator i = std::find_if(m_torrents.begin()
, m_torrents.end(), boost::bind(&torrent::url, boost::bind(&std::pair<const sha1_hash
, boost::shared_ptr<torrent> >::second, _1)) == params.url);
if (i != m_torrents.end())
torrent_ptr = i->second;
}
if (torrent_ptr)
{
if ((params.flags & add_torrent_params::flag_duplicate_is_error) == 0)
{
if (!params.uuid.empty() && torrent_ptr->uuid().empty())
torrent_ptr->set_uuid(params.uuid);
if (!params.url.empty() && torrent_ptr->url().empty())
torrent_ptr->set_url(params.url);
if (!params.source_feed_url.empty() && torrent_ptr->source_feed_url().empty())
torrent_ptr->set_source_feed_url(params.source_feed_url);
return std::make_pair(torrent_ptr, false);
}
ec = errors::duplicate_torrent;
return std::make_pair(ptr_t(), false);
}
int queue_pos = ++m_max_queue_pos;
torrent_ptr = boost::make_shared<torrent>(boost::ref(*this)
, 16 * 1024, queue_pos, boost::cref(params), boost::cref(params.info_hash));
return std::make_pair(torrent_ptr, true);
}
void session_impl::update_outgoing_interfaces()
{
INVARIANT_CHECK;
std::string net_interfaces = m_settings.get_str(settings_pack::outgoing_interfaces);
// declared in string_util.hpp
parse_comma_separated_string(net_interfaces, m_net_interfaces);
}
tcp::endpoint session_impl::bind_outgoing_socket(socket_type& s, address
const& remote_address, error_code& ec) const
{
tcp::endpoint bind_ep(address_v4(), 0);
if (m_settings.get_int(settings_pack::outgoing_port) > 0)
{
#ifdef TORRENT_WINDOWS
s.set_option(exclusive_address_use(true), ec);
#endif
s.set_option(tcp::acceptor::reuse_address(true), ec);
// ignore errors because the underlying socket may not
// be opened yet. This happens when we're routing through
// a proxy. In that case, we don't yet know the address of
// the proxy server, and more importantly, we don't know
// the address family of its address. This means we can't
// open the socket yet. The socks abstraction layer defers
// opening it.
ec.clear();
bind_ep.port(next_port());
}
if (!m_net_interfaces.empty())
{
if (m_interface_index >= m_net_interfaces.size()) m_interface_index = 0;
std::string const& ifname = m_net_interfaces[m_interface_index++];
if (ec) return bind_ep;
bind_ep.address(bind_to_device(m_io_service, s
, remote_address.is_v4()
? boost::asio::ip::tcp::v4()
: boost::asio::ip::tcp::v6()
, ifname.c_str(), bind_ep.port(), ec));
return bind_ep;
}
// if we're not binding to a specific interface, bind
// to the same protocol family as the target endpoint
if (is_any(bind_ep.address()))
{
#if TORRENT_USE_IPV6
if (remote_address.is_v6())
bind_ep.address(address_v6::any());
else
#endif
bind_ep.address(address_v4::any());
}
s.bind(bind_ep, ec);
return bind_ep;
}
// verify that the given local address satisfies the requirements of
// the outgoing interfaces. i.e. that one of the allowed outgoing
// interfaces has this address. For uTP sockets, which are all backed
// by an unconnected udp socket, we won't be able to tell what local
// address is used for this peer's packets, in that case, just make
// sure one of the allowed interfaces exists and maybe that it's the
// default route. For systems that have SO_BINDTODEVICE, it should be
// enough to just know that one of the devices exist
bool session_impl::verify_bound_address(address const& addr, bool utp
, error_code& ec)
{
TORRENT_UNUSED(utp);
// we have specific outgoing interfaces specified. Make sure the
// local endpoint for this socket is bound to one of the allowed
// interfaces. the list can be a mixture of interfaces and IP
// addresses. first look for the address
for (int i = 0; i < int(m_net_interfaces.size()); ++i)
{
error_code err;
address ip = address::from_string(m_net_interfaces[i].c_str(), err);
if (err) continue;
if (ip == addr) return true;
}
// we didn't find the address as an IP in the interface list. Now,
// resolve which device (if any) has this IP address.
std::string device = device_for_address(addr, m_io_service, ec);
if (ec) return false;
// if no device was found to have this address, we fail
if (device.empty()) return false;
for (int i = 0; i < int(m_net_interfaces.size()); ++i)
{
if (m_net_interfaces[i] == device) return true;
}
return false;
}
void session_impl::remove_torrent(const torrent_handle& h, int options)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> tptr = h.m_torrent.lock();
if (!tptr) return;
m_alerts.emplace_alert<torrent_removed_alert>(tptr->get_handle()
, tptr->info_hash());
remove_torrent_impl(tptr, options);
tptr->abort();
tptr->set_queue_position(-1);
}
void session_impl::remove_torrent_impl(boost::shared_ptr<torrent> tptr
, int options)
{
// remove from uuid list
if (!tptr->uuid().empty())
{
std::map<std::string, boost::shared_ptr<torrent> >::iterator j
= m_uuids.find(tptr->uuid());
if (j != m_uuids.end()) m_uuids.erase(j);
}
torrent_map::iterator i =
m_torrents.find(tptr->torrent_file().info_hash());
// this torrent might be filed under the URL-hash
if (i == m_torrents.end() && !tptr->url().empty())
{
std::string const& url = tptr->url();
sha1_hash urlhash = hasher(&url[0], url.size()).final();
i = m_torrents.find(urlhash);
}
if (i == m_torrents.end()) return;
torrent& t = *i->second;
if (options)
{
if (!t.delete_files(options))
{
if (m_alerts.should_post<torrent_delete_failed_alert>())
m_alerts.emplace_alert<torrent_delete_failed_alert>(t.get_handle()
, error_code(), t.torrent_file().info_hash());
}
}
if (m_torrent_lru.size() > 0
&& (t.prev != NULL || t.next != NULL || m_torrent_lru.front() == &t))
m_torrent_lru.erase(&t);
TORRENT_ASSERT(t.prev == NULL && t.next == NULL);
tptr->update_gauge();
#if TORRENT_USE_ASSERTS
sha1_hash i_hash = t.torrent_file().info_hash();
#endif
#ifndef TORRENT_DISABLE_DHT
if (i == m_next_dht_torrent)
++m_next_dht_torrent;
#endif
if (i == m_next_lsd_torrent)
++m_next_lsd_torrent;
m_torrents.erase(i);
TORRENT_ASSERT(m_torrents.size() >= m_torrent_lru.size());
#if !defined(TORRENT_DISABLE_ENCRYPTION) && !defined(TORRENT_DISABLE_EXTENSIONS)
hasher h;
h.update("req2", 4);
h.update(tptr->info_hash().data(), 20);
m_obfuscated_torrents.erase(h.final());
#endif
#ifndef TORRENT_DISABLE_DHT
if (m_next_dht_torrent == m_torrents.end())
m_next_dht_torrent = m_torrents.begin();
#endif
if (m_next_lsd_torrent == m_torrents.end())
m_next_lsd_torrent = m_torrents.begin();
// this torrent may open up a slot for a queued torrent
trigger_auto_manage();
TORRENT_ASSERT(m_torrents.find(i_hash) == m_torrents.end());
}
void session_impl::update_listen_interfaces()
{
INVARIANT_CHECK;
std::string net_interfaces = m_settings.get_str(settings_pack::listen_interfaces);
std::vector<std::pair<std::string, int> > new_listen_interfaces;
// declared in string_util.hpp
parse_comma_separated_string_port(net_interfaces, new_listen_interfaces);
#ifndef TORRENT_DISABLE_LOGGING
session_log("update listen interfaces: %s", net_interfaces.c_str());
#endif
// if the interface is the same and the socket is open
// don't do anything
if (new_listen_interfaces == m_listen_interfaces
&& !m_listen_sockets.empty())
return;
m_listen_interfaces = new_listen_interfaces;
// for backwards compatibility. Some components still only supports
// a single listen interface
m_listen_interface.address(address_v4::any());
m_listen_interface.port(0);
if (m_listen_interfaces.size() > 0)
{
error_code ec;
m_listen_interface.port(m_listen_interfaces[0].second);
char const* device_name = m_listen_interfaces[0].first.c_str();
// if the first character is [, skip it since it may be an
// IPv6 address
m_listen_interface.address(address::from_string(
device_name[0] == '[' ? device_name + 1 : device_name, ec));
if (ec)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("failed to treat %s as an IP address [ %s ]"
, device_name, ec.message().c_str());
#endif
// it may have been a device name.
std::vector<ip_interface> ifs = enum_net_interfaces(m_io_service, ec);
#ifndef TORRENT_DISABLE_LOGGING
if (ec)
session_log("failed to enumerate interfaces [ %s ]"
, ec.message().c_str());
#endif
bool found = false;
for (int i = 0; i < int(ifs.size()); ++i)
{
// we're looking for a specific interface, and its address
// (which must be of the same family as the address we're
// connecting to)
if (strcmp(ifs[i].name, device_name) != 0) continue;
m_listen_interface.address(ifs[i].interface_address);
#ifndef TORRENT_DISABLE_LOGGING
error_code err;
session_log("binding to %s"
, m_listen_interface.address().to_string(err).c_str());
#endif
found = true;
break;
}
if (!found)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("failed to find device %s", device_name);
#endif
// effectively disable whatever socket decides to bind to this
m_listen_interface.address(address_v4::loopback());
}
}
}
}
void session_impl::update_privileged_ports()
{
if (m_settings.get_bool(settings_pack::no_connect_privileged_ports))
{
m_port_filter.add_rule(0, 1024, port_filter::blocked);
// Close connections whose endpoint is filtered
// by the new ip-filter
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
i->second->port_filter_updated();
}
else
{
m_port_filter.add_rule(0, 1024, 0);
}
}
void session_impl::update_auto_sequential()
{
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
i->second->update_auto_sequential();
}
void session_impl::update_max_failcount()
{
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
i->second->update_max_failcount();
}
}
void session_impl::update_proxy()
{
// in case we just set a socks proxy, we might have to
// open the socks incoming connection
if (!m_socks_listen_socket) open_new_incoming_socks_connection();
m_udp_socket.set_proxy_settings(proxy());
#ifdef TORRENT_USE_OPENSSL
m_ssl_udp_socket.set_proxy_settings(proxy());
#endif
}
void session_impl::update_upnp()
{
if (m_settings.get_bool(settings_pack::enable_upnp))
start_upnp();
else
stop_upnp();
}
void session_impl::update_natpmp()
{
if (m_settings.get_bool(settings_pack::enable_natpmp))
start_natpmp();
else
stop_natpmp();
}
void session_impl::update_lsd()
{
if (m_settings.get_bool(settings_pack::enable_lsd))
start_lsd();
else
stop_lsd();
}
void session_impl::update_dht()
{
#ifndef TORRENT_DISABLE_DHT
if (m_settings.get_bool(settings_pack::enable_dht))
start_dht();
else
stop_dht();
#endif
}
void session_impl::update_peer_fingerprint()
{
// ---- generate a peer id ----
std::string print = m_settings.get_str(settings_pack::peer_fingerprint);
if (print.size() > 20) print.resize(20);
// the client's fingerprint
std::copy(print.begin(), print.begin() + print.length(), m_peer_id.begin());
if (print.length() < 20)
{
url_random(m_peer_id.data() + print.length(), m_peer_id.data() + 20);
}
}
void session_impl::update_dht_bootstrap_nodes()
{
#ifndef TORRENT_DISABLE_DHT
std::string const& node_list = m_settings.get_str(settings_pack::dht_bootstrap_nodes);
std::vector<std::pair<std::string, int> > nodes;
parse_comma_separated_string_port(node_list, nodes);
for (int i = 0; i < nodes.size(); ++i)
{
add_dht_router(nodes[i]);
}
#endif
}
void session_impl::update_count_slow()
{
error_code ec;
for (torrent_map::const_iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
i->second->on_inactivity_tick(ec);
}
}
address session_impl::listen_address() const
{
for (std::list<listen_socket_t>::const_iterator i = m_listen_sockets.begin()
, end(m_listen_sockets.end()); i != end; ++i)
{
if (i->external_address != address()) return i->external_address;
}
return address();
}
boost::uint16_t session_impl::listen_port() const
{
// if peer connections are set up to be received over a socks
// proxy, and it's the same one as we're using for the tracker
// just tell the tracker the socks5 port we're listening on
if (m_socks_listen_socket && m_socks_listen_socket->is_open())
return m_socks_listen_socket->local_endpoint().port();
// if not, don't tell the tracker anything if we're in force_proxy
// mode. We don't want to leak our listen port since it can
// potentially identify us if it is leaked elsewere
if (m_settings.get_bool(settings_pack::force_proxy)) return 0;
if (m_listen_sockets.empty()) return 0;
return m_listen_sockets.front().external_port;
}
boost::uint16_t session_impl::ssl_listen_port() const
{
#ifdef TORRENT_USE_OPENSSL
// if peer connections are set up to be received over a socks
// proxy, and it's the same one as we're using for the tracker
// just tell the tracker the socks5 port we're listening on
if (m_socks_listen_socket && m_socks_listen_socket->is_open())
return m_socks_listen_port;
// if not, don't tell the tracker anything if we're in force_proxy
// mode. We don't want to leak our listen port since it can
// potentially identify us if it is leaked elsewere
if (m_settings.get_bool(settings_pack::force_proxy)) return 0;
for (std::list<listen_socket_t>::const_iterator i = m_listen_sockets.begin()
, end(m_listen_sockets.end()); i != end; ++i)
{
if (i->ssl) return i->external_port;
}
if (m_ssl_udp_socket.is_open())
return m_ssl_udp_socket.local_port();
#endif
return 0;
}
void session_impl::announce_lsd(sha1_hash const& ih, int port, bool broadcast)
{
// use internal listen port for local peers
if (m_lsd)
m_lsd->announce(ih, port, broadcast);
}
void session_impl::on_lsd_peer(tcp::endpoint peer, sha1_hash const& ih)
{
m_stats_counters.inc_stats_counter(counters::on_lsd_peer_counter);
TORRENT_ASSERT(is_single_thread());
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = find_torrent(ih).lock();
if (!t) return;
// don't add peers from lsd to private torrents
if (t->torrent_file().priv() || (t->torrent_file().is_i2p()
&& !m_settings.get_bool(settings_pack::allow_i2p_mixed))) return;
#ifndef TORRENT_DISABLE_LOGGING
session_log("added peer from local discovery: %s", print_endpoint(peer).c_str());
#endif
t->add_peer(peer, peer_info::lsd);
t->do_connect_boost();
if (m_alerts.should_post<lsd_peer_alert>())
m_alerts.emplace_alert<lsd_peer_alert>(t->get_handle(), peer);
}
// TODO: perhaps this function should not exist when logging is disabled
void session_impl::on_port_map_log(
char const* msg, int map_transport)
{
#ifndef TORRENT_DISABLE_LOGGING
TORRENT_ASSERT(map_transport >= 0 && map_transport <= 1);
// log message
if (m_alerts.should_post<portmap_log_alert>())
m_alerts.emplace_alert<portmap_log_alert>(map_transport, msg);
#else
TORRENT_UNUSED(msg);
TORRENT_UNUSED(map_transport);
#endif
}
void session_impl::on_port_mapping(int mapping, address const& ip, int port
, int protocol, error_code const& ec, int map_transport)
{
TORRENT_ASSERT(is_single_thread());
TORRENT_ASSERT(map_transport >= 0 && map_transport <= 1);
if (mapping == m_udp_mapping[map_transport] && port != 0)
{
m_external_udp_port = port;
if (m_alerts.should_post<portmap_alert>())
m_alerts.emplace_alert<portmap_alert>(mapping, port
, map_transport, protocol == natpmp::udp
? portmap_alert::udp : portmap_alert::tcp);
return;
}
if (mapping == m_tcp_mapping[map_transport] && port != 0)
{
if (ip != address())
{
// TODO: 1 report the proper address of the router as the source IP of
// this understanding of our external address, instead of the empty address
set_external_address(ip, source_router, address());
}
if (!m_listen_sockets.empty()) {
m_listen_sockets.front().external_address = ip;
m_listen_sockets.front().external_port = port;
}
if (m_alerts.should_post<portmap_alert>())
m_alerts.emplace_alert<portmap_alert>(mapping, port
, map_transport, protocol == natpmp::udp
? portmap_alert::udp : portmap_alert::tcp);
return;
}
if (ec)
{
if (m_alerts.should_post<portmap_error_alert>())
m_alerts.emplace_alert<portmap_error_alert>(mapping
, map_transport, ec);
}
else
{
if (m_alerts.should_post<portmap_alert>())
m_alerts.emplace_alert<portmap_alert>(mapping, port
, map_transport, protocol == natpmp::udp
? portmap_alert::udp : portmap_alert::tcp);
}
}
#ifndef TORRENT_NO_DEPRECATE
session_status session_impl::status() const
{
// INVARIANT_CHECK;
TORRENT_ASSERT(is_single_thread());
session_status s;
s.optimistic_unchoke_counter = m_optimistic_unchoke_time_scaler;
s.unchoke_counter = m_unchoke_time_scaler;
s.num_dead_peers = int(m_undead_peers.size());
s.num_peers = m_stats_counters[counters::num_peers_connected];
s.num_unchoked = m_stats_counters[counters::num_peers_up_unchoked_all];
s.allowed_upload_slots = m_stats_counters[counters::num_unchoke_slots];
s.num_torrents
= m_stats_counters[counters::num_checking_torrents]
+ m_stats_counters[counters::num_stopped_torrents]
+ m_stats_counters[counters::num_queued_seeding_torrents]
+ m_stats_counters[counters::num_queued_download_torrents]
+ m_stats_counters[counters::num_upload_only_torrents]
+ m_stats_counters[counters::num_downloading_torrents]
+ m_stats_counters[counters::num_seeding_torrents]
+ m_stats_counters[counters::num_error_torrents];
s.num_paused_torrents
= m_stats_counters[counters::num_stopped_torrents]
+ m_stats_counters[counters::num_error_torrents]
+ m_stats_counters[counters::num_queued_seeding_torrents]
+ m_stats_counters[counters::num_queued_download_torrents];
s.total_redundant_bytes = m_stats_counters[counters::recv_redundant_bytes];
s.total_failed_bytes = m_stats_counters[counters::recv_failed_bytes];
s.up_bandwidth_queue = m_stats_counters[counters::limiter_up_queue];
s.down_bandwidth_queue = m_stats_counters[counters::limiter_down_queue];
s.up_bandwidth_bytes_queue = m_stats_counters[counters::limiter_up_bytes];
s.down_bandwidth_bytes_queue = m_stats_counters[counters::limiter_down_bytes];
s.disk_write_queue = m_stats_counters[counters::num_peers_down_disk];
s.disk_read_queue = m_stats_counters[counters::num_peers_up_disk];
s.has_incoming_connections = m_stats_counters[counters::has_incoming_connections];
// total
s.download_rate = m_stat.download_rate();
s.total_upload = m_stat.total_upload();
s.upload_rate = m_stat.upload_rate();
s.total_download = m_stat.total_download();
// payload
s.payload_download_rate = m_stat.transfer_rate(stat::download_payload);
s.total_payload_download = m_stat.total_transfer(stat::download_payload);
s.payload_upload_rate = m_stat.transfer_rate(stat::upload_payload);
s.total_payload_upload = m_stat.total_transfer(stat::upload_payload);
// IP-overhead
s.ip_overhead_download_rate = m_stat.transfer_rate(stat::download_ip_protocol);
s.total_ip_overhead_download = m_stat.total_transfer(stat::download_ip_protocol);
s.ip_overhead_upload_rate = m_stat.transfer_rate(stat::upload_ip_protocol);
s.total_ip_overhead_upload = m_stat.total_transfer(stat::upload_ip_protocol);
// tracker
s.total_tracker_download = m_stats_counters[counters::recv_tracker_bytes];
s.total_tracker_upload = m_stats_counters[counters::sent_tracker_bytes];
// dht
s.total_dht_download = m_stats_counters[counters::dht_bytes_in];
s.total_dht_upload = m_stats_counters[counters::dht_bytes_out];
// deprecated
s.tracker_download_rate = 0;
s.tracker_upload_rate = 0;
s.dht_download_rate = 0;
s.dht_upload_rate = 0;
#ifndef TORRENT_DISABLE_DHT
if (m_dht)
{
m_dht->dht_status(s);
}
else
#endif
{
s.dht_nodes = 0;
s.dht_node_cache = 0;
s.dht_torrents = 0;
s.dht_global_nodes = 0;
s.dht_total_allocations = 0;
}
s.utp_stats.packet_loss = m_stats_counters[counters::utp_packet_loss];
s.utp_stats.timeout = m_stats_counters[counters::utp_timeout];
s.utp_stats.packets_in = m_stats_counters[counters::utp_packets_in];
s.utp_stats.packets_out = m_stats_counters[counters::utp_packets_out];
s.utp_stats.fast_retransmit = m_stats_counters[counters::utp_fast_retransmit];
s.utp_stats.packet_resend = m_stats_counters[counters::utp_packet_resend];
s.utp_stats.samples_above_target = m_stats_counters[counters::utp_samples_above_target];
s.utp_stats.samples_below_target = m_stats_counters[counters::utp_samples_below_target];
s.utp_stats.payload_pkts_in = m_stats_counters[counters::utp_payload_pkts_in];
s.utp_stats.payload_pkts_out = m_stats_counters[counters::utp_payload_pkts_out];
s.utp_stats.invalid_pkts_in = m_stats_counters[counters::utp_invalid_pkts_in];
s.utp_stats.redundant_pkts_in = m_stats_counters[counters::utp_redundant_pkts_in];
s.utp_stats.num_idle = m_stats_counters[counters::num_utp_idle];
s.utp_stats.num_syn_sent = m_stats_counters[counters::num_utp_syn_sent];
s.utp_stats.num_connected = m_stats_counters[counters::num_utp_connected];
s.utp_stats.num_fin_sent = m_stats_counters[counters::num_utp_fin_sent];
s.utp_stats.num_close_wait = m_stats_counters[counters::num_utp_close_wait];
// this loop is potentially expensive. It could be optimized by
// simply keeping a global counter
int peerlist_size = 0;
for (torrent_map::const_iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
peerlist_size += i->second->num_known_peers();
}
s.peerlist_size = peerlist_size;
return s;
}
#endif // TORRENT_NO_DEPRECATE
#ifndef TORRENT_DISABLE_DHT
void session_impl::start_dht()
{ start_dht(m_dht_state); }
namespace {
void on_bootstrap(alert_manager& alerts)
{
if (alerts.should_post<dht_bootstrap_alert>())
alerts.emplace_alert<dht_bootstrap_alert>();
}
}
void session_impl::start_dht(entry const& startup_state)
{
INVARIANT_CHECK;
stop_dht();
// postpone starting the DHT if we're still resolving the DHT router
if (m_outstanding_router_lookups > 0) return;
if (m_abort) return;
m_dht = boost::make_shared<dht::dht_tracker>(static_cast<dht_observer*>(this)
, boost::ref(m_udp_socket), boost::cref(m_dht_settings)
, boost::ref(m_stats_counters)
, m_dht_storage_constructor
, startup_state);
for (std::vector<udp::endpoint>::iterator i = m_dht_router_nodes.begin()
, end(m_dht_router_nodes.end()); i != end; ++i)
{
m_dht->add_router_node(*i);
}
for (std::vector<udp::endpoint>::iterator i = m_dht_nodes.begin()
, end(m_dht_nodes.end()); i != end; ++i)
{
m_dht->add_node(*i);
}
m_dht_nodes.clear();
m_dht->start(startup_state, boost::bind(&on_bootstrap, boost::ref(m_alerts)));
m_udp_socket.subscribe(m_dht.get());
}
void session_impl::stop_dht()
{
if (!m_dht) return;
m_udp_socket.unsubscribe(m_dht.get());
m_dht->stop();
m_dht.reset();
}
void session_impl::set_dht_settings(dht_settings const& settings)
{
m_dht_settings = settings;
}
void session_impl::set_dht_storage(dht::dht_storage_constructor_type sc)
{
m_dht_storage_constructor = sc;
}
#ifndef TORRENT_NO_DEPRECATE
entry session_impl::dht_state() const
{
if (!m_dht) return entry();
return m_dht->state();
}
void session_impl::start_dht_deprecated(entry const& startup_state)
{
m_settings.set_bool(settings_pack::enable_dht, true);
start_dht(startup_state);
}
#endif
void session_impl::add_dht_node_name(std::pair<std::string, int> const& node)
{
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_dht_name_lookup");
#endif
m_host_resolver.async_resolve(node.first, resolver_interface::abort_on_shutdown
, boost::bind(&session_impl::on_dht_name_lookup
, this, _1, _2, node.second));
}
void session_impl::on_dht_name_lookup(error_code const& e
, std::vector<address> const& addresses, int port)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::on_dht_name_lookup");
#endif
if (e)
{
if (m_alerts.should_post<dht_error_alert>())
m_alerts.emplace_alert<dht_error_alert>(
dht_error_alert::hostname_lookup, e);
return;
}
for (std::vector<address>::const_iterator i = addresses.begin()
, end(addresses.end()); i != end; ++i)
{
udp::endpoint ep(*i, port);
add_dht_node(ep);
}
}
void session_impl::add_dht_router(std::pair<std::string, int> const& node)
{
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_dht_router_name_lookup");
#endif
++m_outstanding_router_lookups;
m_host_resolver.async_resolve(node.first, resolver_interface::abort_on_shutdown
, boost::bind(&session_impl::on_dht_router_name_lookup
, this, _1, _2, node.second));
}
void session_impl::on_dht_router_name_lookup(error_code const& e
, std::vector<address> const& addresses, int port)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("session_impl::on_dht_router_name_lookup");
#endif
--m_outstanding_router_lookups;
if (e)
{
if (m_alerts.should_post<dht_error_alert>())
m_alerts.emplace_alert<dht_error_alert>(
dht_error_alert::hostname_lookup, e);
if (m_outstanding_router_lookups == 0) update_dht();
return;
}
for (std::vector<address>::const_iterator i = addresses.begin()
, end(addresses.end()); i != end; ++i)
{
// router nodes should be added before the DHT is started (and bootstrapped)
udp::endpoint ep(*i, port);
if (m_dht) m_dht->add_router_node(ep);
m_dht_router_nodes.push_back(ep);
}
if (m_outstanding_router_lookups == 0) update_dht();
}
// callback for dht_immutable_get
void session_impl::get_immutable_callback(sha1_hash target
, dht::item const& i)
{
TORRENT_ASSERT(!i.is_mutable());
m_alerts.emplace_alert<dht_immutable_item_alert>(target, i.value());
}
void session_impl::dht_get_immutable_item(sha1_hash const& target)
{
if (!m_dht) return;
m_dht->get_item(target, boost::bind(&session_impl::get_immutable_callback
, this, target, _1));
}
// callback for dht_mutable_get
void session_impl::get_mutable_callback(dht::item const& i, bool authoritative)
{
TORRENT_ASSERT(i.is_mutable());
m_alerts.emplace_alert<dht_mutable_item_alert>(i.pk(), i.sig(), i.seq()
, i.salt(), i.value(), authoritative);
}
// key is a 32-byte binary string, the public key to look up.
// the salt is optional
void session_impl::dht_get_mutable_item(boost::array<char, 32> key
, std::string salt)
{
if (!m_dht) return;
m_dht->get_item(key.data(), boost::bind(&session_impl::get_mutable_callback
, this, _1, _2), salt);
}
namespace {
void on_dht_put_immutable_item(alert_manager& alerts, sha1_hash target, int num)
{
if (alerts.should_post<dht_put_alert>())
alerts.emplace_alert<dht_put_alert>(target, num);
}
void on_dht_put_mutable_item(alert_manager& alerts, dht::item const& i, int num)
{
boost::array<char, 64> sig = i.sig();
boost::array<char, 32> pk = i.pk();
boost::uint64_t seq = i.seq();
std::string salt = i.salt();
if (alerts.should_post<dht_put_alert>())
alerts.emplace_alert<dht_put_alert>(pk, sig, salt, seq, num);
}
void put_mutable_callback(dht::item& i
, boost::function<void(entry&, boost::array<char,64>&
, boost::uint64_t&, std::string const&)> cb)
{
entry value = i.value();
boost::array<char, 64> sig = i.sig();
boost::array<char, 32> pk = i.pk();
boost::uint64_t seq = i.seq();
std::string salt = i.salt();
cb(value, sig, seq, salt);
i.assign(value, salt, seq, pk.data(), sig.data());
}
void on_dht_get_peers(alert_manager& alerts, sha1_hash info_hash, std::vector<tcp::endpoint> const& peers)
{
if (alerts.should_post<dht_get_peers_reply_alert>())
alerts.emplace_alert<dht_get_peers_reply_alert>(info_hash, peers);
}
void on_direct_response(alert_manager& alerts, void* userdata, dht::msg const& msg)
{
if (msg.message.type() == bdecode_node::none_t)
alerts.emplace_alert<dht_direct_response_alert>(userdata, msg.addr);
else
alerts.emplace_alert<dht_direct_response_alert>(userdata, msg.addr, msg.message);
}
} // anonymous namespace
void session_impl::dht_put_immutable_item(entry const& data, sha1_hash target)
{
if (!m_dht) return;
m_dht->put_item(data, boost::bind(&on_dht_put_immutable_item, boost::ref(m_alerts)
, target, _1));
}
void session_impl::dht_put_mutable_item(boost::array<char, 32> key
, boost::function<void(entry&, boost::array<char,64>&
, boost::uint64_t&, std::string const&)> cb
, std::string salt)
{
if (!m_dht) return;
m_dht->put_item(key.data(),
boost::bind(&on_dht_put_mutable_item, boost::ref(m_alerts), _1, _2),
boost::bind(&put_mutable_callback, _1, cb), salt);
}
void session_impl::dht_get_peers(sha1_hash const& info_hash)
{
if (!m_dht) return;
m_dht->get_peers(info_hash, boost::bind(&on_dht_get_peers, boost::ref(m_alerts), info_hash, _1));
}
void session_impl::dht_announce(sha1_hash const& info_hash, int port, int flags)
{
if (!m_dht) return;
m_dht->announce(info_hash, port, flags, boost::bind(&on_dht_get_peers, boost::ref(m_alerts), info_hash, _1));
}
void session_impl::dht_direct_request(udp::endpoint ep, entry& e, void* userdata)
{
if (!m_dht) return;
m_dht->direct_request(ep, e, boost::bind(&on_direct_response, boost::ref(m_alerts), userdata, _1));
}
#endif
void session_impl::maybe_update_udp_mapping(int const nat, bool const ssl
, int const local_port, int const external_port)
{
int local, external, protocol;
#ifdef TORRENT_USE_OPENSSL
int* mapping = ssl ? m_ssl_udp_mapping : m_udp_mapping;
#else
TORRENT_UNUSED(ssl);
int* mapping = m_udp_mapping;
#endif
if (nat == 0 && m_natpmp)
{
if (mapping[nat] != -1)
{
if (m_natpmp->get_mapping(mapping[nat], local, external, protocol))
{
// we already have a mapping. If it's the same, don't do anything
if (local == local_port && external == external_port && protocol == natpmp::udp)
return;
}
m_natpmp->delete_mapping(mapping[nat]);
}
mapping[nat] = m_natpmp->add_mapping(natpmp::udp
, local_port, external_port);
return;
}
else if (nat == 1 && m_upnp)
{
if (mapping[nat] != -1)
{
if (m_upnp->get_mapping(mapping[nat], local, external, protocol))
{
// we already have a mapping. If it's the same, don't do anything
if (local == local_port && external == external_port && protocol == natpmp::udp)
return;
}
m_upnp->delete_mapping(mapping[nat]);
}
mapping[nat] = m_upnp->add_mapping(upnp::udp
, local_port, external_port);
return;
}
}
#if !defined(TORRENT_DISABLE_ENCRYPTION) && !defined(TORRENT_DISABLE_EXTENSIONS)
void session_impl::add_obfuscated_hash(sha1_hash const& obfuscated
, boost::weak_ptr<torrent> const& t)
{
m_obfuscated_torrents.insert(std::make_pair(obfuscated, t.lock()));
}
#endif // !defined(TORRENT_DISABLE_ENCRYPTION) && !defined(TORRENT_DISABLE_EXTENSIONS)
bool session_impl::is_listening() const
{
return !m_listen_sockets.empty();
}
session_impl::~session_impl()
{
// this is not allowed to be the network thread!
// TORRENT_ASSERT(is_not_thread());
m_udp_socket.unsubscribe(this);
m_udp_socket.unsubscribe(&m_utp_socket_manager);
m_udp_socket.unsubscribe(&m_tracker_manager);
#ifdef TORRENT_USE_OPENSSL
m_ssl_udp_socket.unsubscribe(this);
m_ssl_udp_socket.unsubscribe(&m_ssl_utp_socket_manager);
#endif
TORRENT_ASSERT(m_torrents.empty());
TORRENT_ASSERT(m_connections.empty());
#if defined TORRENT_ASIO_DEBUGGING
FILE* f = fopen("wakeups.log", "w+");
if (f != NULL)
{
time_point m = min_time();
if (_wakeups.size() > 0) m = _wakeups[0].timestamp;
time_point prev = m;
boost::uint64_t prev_csw = 0;
if (_wakeups.size() > 0) prev_csw = _wakeups[0].context_switches;
fprintf(f, "abs. time\trel. time\tctx switch\tidle-wakeup\toperation\n");
for (int i = 0; i < _wakeups.size(); ++i)
{
wakeup_t const& w = _wakeups[i];
bool idle_wakeup = w.context_switches > prev_csw;
fprintf(f, "%" PRId64 "\t%" PRId64 "\t%" PRId64 "\t%c\t%s\n"
, total_microseconds(w.timestamp - m)
, total_microseconds(w.timestamp - prev)
, w.context_switches
, idle_wakeup ? '*' : '.'
, w.operation);
prev = w.timestamp;
prev_csw = w.context_switches;
}
fclose(f);
}
#endif
// clear the torrent LRU. We do this to avoid having the torrent
// destructor assert because it's still linked into the lru list
#if TORRENT_USE_ASSERTS
list_node<torrent>* i = m_torrent_lru.get_all();
// clear the prev and next pointers in all torrents
// to avoid the assert when destructing them
while (i)
{
list_node<torrent>* tmp = i;
i = i->next;
tmp->next = NULL;
tmp->prev = NULL;
}
#endif
}
#ifndef TORRENT_NO_DEPRECATE
int session_impl::max_connections() const
{
return m_settings.get_int(settings_pack::connections_limit);
}
int session_impl::max_uploads() const
{
return m_settings.get_int(settings_pack::unchoke_slots_limit);
}
void session_impl::set_local_download_rate_limit(int bytes_per_second)
{
settings_pack p;
p.set_int(settings_pack::local_download_rate_limit, bytes_per_second);
apply_settings_pack_impl(p);
}
void session_impl::set_local_upload_rate_limit(int bytes_per_second)
{
settings_pack p;
p.set_int(settings_pack::local_upload_rate_limit, bytes_per_second);
apply_settings_pack_impl(p);
}
void session_impl::set_download_rate_limit(int bytes_per_second)
{
settings_pack p;
p.set_int(settings_pack::download_rate_limit, bytes_per_second);
apply_settings_pack_impl(p);
}
void session_impl::set_upload_rate_limit(int bytes_per_second)
{
settings_pack p;
p.set_int(settings_pack::upload_rate_limit, bytes_per_second);
apply_settings_pack_impl(p);
}
void session_impl::set_max_connections(int limit)
{
settings_pack p;
p.set_int(settings_pack::connections_limit, limit);
apply_settings_pack_impl(p);
}
void session_impl::set_max_uploads(int limit)
{
settings_pack p;
p.set_int(settings_pack::unchoke_slots_limit, limit);
apply_settings_pack_impl(p);
}
int session_impl::local_upload_rate_limit() const
{
return upload_rate_limit(m_local_peer_class);
}
int session_impl::local_download_rate_limit() const
{
return download_rate_limit(m_local_peer_class);
}
int session_impl::upload_rate_limit() const
{
return upload_rate_limit(m_global_class);
}
int session_impl::download_rate_limit() const
{
return download_rate_limit(m_global_class);
}
#endif
// TODO: 2 this should be factored into the udp socket, so we only have the
// code once
void session_impl::update_peer_tos()
{
error_code ec;
#if TORRENT_USE_IPV6 && defined IPV6_TCLASS
if (m_udp_socket.local_endpoint(ec).address().is_v6())
m_udp_socket.set_option(traffic_class(m_settings.get_int(settings_pack::peer_tos)), ec);
else
#endif
m_udp_socket.set_option(type_of_service(m_settings.get_int(settings_pack::peer_tos)), ec);
#ifdef TORRENT_USE_OPENSSL
#if TORRENT_USE_IPV6 && defined IPV6_TCLASS
if (m_ssl_udp_socket.local_endpoint(ec).address().is_v6())
m_ssl_udp_socket.set_option(traffic_class(m_settings.get_int(settings_pack::peer_tos)), ec);
else
#endif
m_ssl_udp_socket.set_option(type_of_service(m_settings.get_int(settings_pack::peer_tos)), ec);
#endif
#ifndef TORRENT_DISABLE_LOGGING
session_log(">>> SET_TOS [ udp_socket tos: %x e: %s ]"
, m_settings.get_int(settings_pack::peer_tos)
, ec.message().c_str());
#endif
}
void session_impl::update_user_agent()
{
// replace all occurrences of '\n' with ' '.
std::string agent = m_settings.get_str(settings_pack::user_agent);
std::string::iterator i = agent.begin();
while ((i = std::find(i, agent.end(), '\n'))
!= agent.end())
*i = ' ';
m_settings.set_str(settings_pack::user_agent, agent);
}
void session_impl::update_unchoke_limit()
{
int const allowed_upload_slots = get_int_setting(settings_pack::unchoke_slots_limit);
m_stats_counters.set_value(counters::num_unchoke_slots
, allowed_upload_slots);
if (m_settings.get_int(settings_pack::num_optimistic_unchoke_slots)
>= allowed_upload_slots / 2)
{
if (m_alerts.should_post<performance_alert>())
m_alerts.emplace_alert<performance_alert>(torrent_handle()
, performance_alert::too_many_optimistic_unchoke_slots);
}
}
void session_impl::update_connection_speed()
{
if (m_settings.get_int(settings_pack::connection_speed) < 0)
m_settings.set_int(settings_pack::connection_speed, 200);
}
void session_impl::update_queued_disk_bytes()
{
boost::uint64_t cache_size = m_settings.get_int(settings_pack::cache_size);
if (m_settings.get_int(settings_pack::max_queued_disk_bytes) / 16 / 1024
> cache_size / 2
&& cache_size > 5
&& m_alerts.should_post<performance_alert>())
{
m_alerts.emplace_alert<performance_alert>(torrent_handle()
, performance_alert::too_high_disk_queue_limit);
}
}
void session_impl::update_alert_queue_size()
{
m_alerts.set_alert_queue_size_limit(m_settings.get_int(settings_pack::alert_queue_size));
}
bool session_impl::preemptive_unchoke() const
{
return m_stats_counters[counters::num_peers_up_unchoked]
< m_stats_counters[counters::num_unchoke_slots]
|| m_settings.get_int(settings_pack::unchoke_slots_limit) < 0;
}
void session_impl::update_dht_upload_rate_limit()
{
m_udp_socket.set_rate_limit(m_settings.get_int(settings_pack::dht_upload_rate_limit));
}
void session_impl::update_disk_threads()
{
if (m_settings.get_int(settings_pack::aio_threads) < 0)
m_settings.set_int(settings_pack::aio_threads, 0);
#if !TORRENT_USE_PREAD && !TORRENT_USE_PREADV
// if we don't have pread() nor preadv() there's no way
// to perform concurrent file operations on the same file
// handle, so we must limit the disk thread to a single one
if (m_settings.get_int(settings_pack::aio_threads) > 1)
m_settings.set_int(settings_pack::aio_threads, 1);
#endif
m_disk_thread.set_num_threads(m_settings.get_int(settings_pack::aio_threads));
}
void session_impl::update_network_threads()
{
int num_threads = m_settings.get_int(settings_pack::network_threads);
int num_pools = num_threads > 0 ? num_threads : 1;
while (num_pools > m_net_thread_pool.size())
{
m_net_thread_pool.push_back(boost::make_shared<network_thread_pool>());
m_net_thread_pool.back()->set_num_threads(num_threads > 0 ? 1 : 0);
}
while (num_pools < m_net_thread_pool.size())
{
m_net_thread_pool.erase(m_net_thread_pool.end() - 1);
}
if (num_threads == 0 && m_net_thread_pool.size() > 0)
{
m_net_thread_pool[0]->set_num_threads(0);
}
}
void session_impl::post_socket_job(socket_job& j)
{
uintptr_t idx = 0;
if (m_net_thread_pool.size() > 1)
{
// each peer needs to be pinned to a specific thread
// since reading and writing simultaneously on the same
// socket from different threads is not supported by asio.
// as long as a specific socket is consistently used from
// the same thread, it's safe
idx = uintptr_t(j.peer.get());
idx ^= idx >> 8;
idx %= m_net_thread_pool.size();
}
m_net_thread_pool[idx]->post_job(j);
}
void session_impl::update_cache_buffer_chunk_size()
{
if (m_settings.get_int(settings_pack::cache_buffer_chunk_size) <= 0)
m_settings.set_int(settings_pack::cache_buffer_chunk_size, 1);
}
void session_impl::update_report_web_seed_downloads()
{
// if this flag changed, update all web seed connections
bool report = m_settings.get_bool(settings_pack::report_web_seed_downloads);
for (connection_map::iterator i = m_connections.begin()
, end(m_connections.end()); i != end; ++i)
{
int type = (*i)->type();
if (type == peer_connection::url_seed_connection
|| type == peer_connection::http_seed_connection)
(*i)->ignore_stats(!report);
}
}
void session_impl::trigger_auto_manage()
{
if (m_pending_auto_manage || m_abort) return;
// we recalculated auto-managed torrents less than a second ago,
// put it off one second.
if (time_now() - m_last_auto_manage < seconds(1))
{
m_auto_manage_time_scaler = 0;
return;
}
m_pending_auto_manage = true;
m_need_auto_manage = true;
m_io_service.post(boost::bind(&session_impl::on_trigger_auto_manage, this));
}
void session_impl::on_trigger_auto_manage()
{
TORRENT_ASSERT(m_pending_auto_manage);
if (!m_need_auto_manage || m_abort)
{
m_pending_auto_manage = false;
return;
}
// don't clear m_pending_auto_manage until after we've
// recalculated the auto managed torrents. The auto-managed
// logic may trigger another auto-managed event otherwise
recalculate_auto_managed_torrents();
m_pending_auto_manage = false;
}
void session_impl::update_socket_buffer_size()
{
error_code ec;
set_socket_buffer_size(m_udp_socket, m_settings, ec);
if (ec)
{
if (m_alerts.should_post<udp_error_alert>())
m_alerts.emplace_alert<udp_error_alert>(udp::endpoint(), ec);
}
#ifdef TORRENT_USE_OPENSSL
set_socket_buffer_size(m_ssl_udp_socket, m_settings, ec);
if (ec)
{
if (m_alerts.should_post<udp_error_alert>())
m_alerts.emplace_alert<udp_error_alert>(udp::endpoint(), ec);
}
#endif
}
void session_impl::update_dht_announce_interval()
{
#ifndef TORRENT_DISABLE_DHT
if (!m_dht)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("not starting DHT announce timer: m_dht == NULL");
#endif
return;
}
m_dht_interval_update_torrents = m_torrents.size();
if (m_abort)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log("not starting DHT announce timer: m_abort set");
#endif
return;
}
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("session_impl::on_dht_announce");
#endif
error_code ec;
int delay = (std::max)(m_settings.get_int(settings_pack::dht_announce_interval)
/ (std::max)(int(m_torrents.size()), 1), 1);
m_dht_announce_timer.expires_from_now(seconds(delay), ec);
m_dht_announce_timer.async_wait(
boost::bind(&session_impl::on_dht_announce, this, _1));
#endif
}
void session_impl::update_anonymous_mode()
{
if (!m_settings.get_bool(settings_pack::anonymous_mode))
{
if (m_upnp)
m_upnp->set_user_agent(m_settings.get_str(settings_pack::user_agent));
return;
}
if (m_upnp)
m_upnp->set_user_agent("");
m_settings.set_str(settings_pack::user_agent, "");
url_random(m_peer_id.data(), m_peer_id.data() + 20);
}
void session_impl::update_force_proxy()
{
m_udp_socket.set_force_proxy(m_settings.get_bool(settings_pack::force_proxy));
#ifdef TORRENT_USE_OPENSSL
m_ssl_udp_socket.set_force_proxy(m_settings.get_bool(settings_pack::force_proxy));
#endif
if (!m_settings.get_bool(settings_pack::force_proxy)) return;
// enable force_proxy mode. We don't want to accept any incoming
// connections, except through a proxy.
stop_lsd();
stop_upnp();
stop_natpmp();
#ifndef TORRENT_DISABLE_DHT
stop_dht();
#endif
// close the listen sockets
error_code ec;
for (std::list<listen_socket_t>::iterator i = m_listen_sockets.begin()
, end(m_listen_sockets.end()); i != end; ++i)
i->sock->close(ec);
m_listen_sockets.clear();
}
#ifndef TORRENT_NO_DEPRECATE
void session_impl::update_local_download_rate()
{
if (m_settings.get_int(settings_pack::local_download_rate_limit) < 0)
m_settings.set_int(settings_pack::local_download_rate_limit, 0);
set_download_rate_limit(m_local_peer_class
, m_settings.get_int(settings_pack::local_download_rate_limit));
}
void session_impl::update_local_upload_rate()
{
if (m_settings.get_int(settings_pack::local_upload_rate_limit) < 0)
m_settings.set_int(settings_pack::local_upload_rate_limit, 0);
set_upload_rate_limit(m_local_peer_class
, m_settings.get_int(settings_pack::local_upload_rate_limit));
}
#endif
void session_impl::update_download_rate()
{
if (m_settings.get_int(settings_pack::download_rate_limit) < 0)
m_settings.set_int(settings_pack::download_rate_limit, 0);
set_download_rate_limit(m_global_class
, m_settings.get_int(settings_pack::download_rate_limit));
}
void session_impl::update_upload_rate()
{
if (m_settings.get_int(settings_pack::upload_rate_limit) < 0)
m_settings.set_int(settings_pack::upload_rate_limit, 0);
set_upload_rate_limit(m_global_class
, m_settings.get_int(settings_pack::upload_rate_limit));
}
void session_impl::update_connections_limit()
{
int limit = m_settings.get_int(settings_pack::connections_limit);
if (limit <= 0)
limit = (std::numeric_limits<int>::max)();
limit = (std::max)(5, (std::min)(limit
, max_open_files() - 20 - m_settings.get_int(settings_pack::file_pool_size)));
m_settings.set_int(settings_pack::connections_limit, limit);
if (num_connections() > m_settings.get_int(settings_pack::connections_limit)
&& !m_torrents.empty())
{
// if we have more connections that we're allowed, disconnect
// peers from the torrents so that they are all as even as possible
int to_disconnect = num_connections() - m_settings.get_int(settings_pack::connections_limit);
int last_average = 0;
int average = m_settings.get_int(settings_pack::connections_limit) / m_torrents.size();
// the number of slots that are unused by torrents
int extra = m_settings.get_int(settings_pack::connections_limit) % m_torrents.size();
// run 3 iterations of this, then we're probably close enough
for (int iter = 0; iter < 4; ++iter)
{
// the number of torrents that are above average
int num_above = 0;
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
int num = i->second->num_peers();
if (num <= last_average) continue;
if (num > average) ++num_above;
if (num < average) extra += average - num;
}
// distribute extra among the torrents that are above average
if (num_above == 0) num_above = 1;
last_average = average;
average += extra / num_above;
if (extra == 0) break;
// save the remainder for the next iteration
extra = extra % num_above;
}
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
int num = i->second->num_peers();
if (num <= average) continue;
// distribute the remainder
int my_average = average;
if (extra > 0)
{
++my_average;
--extra;
}
int disconnect = (std::min)(to_disconnect, num - my_average);
to_disconnect -= disconnect;
i->second->disconnect_peers(disconnect, errors::too_many_connections);
}
}
}
void session_impl::update_alert_mask()
{
m_alerts.set_alert_mask(m_settings.get_int(settings_pack::alert_mask));
}
void session_impl::pop_alerts(std::vector<alert*>* alerts)
{
int num_resume = 0;
m_alerts.get_all(*alerts, num_resume);
if (num_resume > 0)
{
// we can only issue more resume data jobs from
// the network thread
m_io_service.post(boost::bind(&session_impl::async_resume_dispatched
, this));
}
}
#ifndef TORRENT_NO_DEPRECATE
void session_impl::update_rate_limit_utp()
{
if (m_settings.get_bool(settings_pack::rate_limit_utp))
{
// allow the global or local peer class to limit uTP peers
m_peer_class_type_filter.add(peer_class_type_filter::utp_socket
, m_local_peer_class);
m_peer_class_type_filter.add(peer_class_type_filter::utp_socket
, m_global_class);
m_peer_class_type_filter.add(peer_class_type_filter::ssl_utp_socket
, m_local_peer_class);
m_peer_class_type_filter.add(peer_class_type_filter::ssl_utp_socket
, m_global_class);
}
else
{
// don't add the global or local peer class to limit uTP peers
m_peer_class_type_filter.remove(peer_class_type_filter::utp_socket
, m_local_peer_class);
m_peer_class_type_filter.remove(peer_class_type_filter::utp_socket
, m_global_class);
m_peer_class_type_filter.remove(peer_class_type_filter::ssl_utp_socket
, m_local_peer_class);
m_peer_class_type_filter.remove(peer_class_type_filter::ssl_utp_socket
, m_global_class);
}
}
void session_impl::update_ignore_rate_limits_on_local_network()
{
init_peer_class_filter(
m_settings.get_bool(settings_pack::ignore_limits_on_local_network));
}
// this function is called on the user's thread
// not the network thread
void session_impl::pop_alerts()
{
// if we don't have any alerts in our local cache, we have to ask
// the alert_manager for more. It will swap our vector with its and
// destruct eny left-over alerts in there.
if (m_alert_pointer_pos >= m_alert_pointers.size())
{
pop_alerts(&m_alert_pointers);
m_alert_pointer_pos = 0;
}
}
alert const* session_impl::pop_alert()
{
if (m_alert_pointer_pos >= m_alert_pointers.size())
{
pop_alerts();
if (m_alert_pointers.empty())
return NULL;
}
if (m_alert_pointers.empty()) return NULL;
// clone here to be backwards compatible, to make the client delete the
// alert object
return m_alert_pointers[m_alert_pointer_pos++];
}
void session_impl::pop_alerts(std::deque<alert*>* alerts)
{
alerts->clear();
if (m_alert_pointer_pos >= m_alert_pointers.size())
{
pop_alerts();
if (m_alert_pointers.empty())
return;
}
for (std::vector<alert*>::iterator i = m_alert_pointers.begin()
+ m_alert_pointer_pos, end(m_alert_pointers.end());
i != end; ++i)
{
alerts->push_back((*i)->clone().release());
}
m_alert_pointer_pos = m_alert_pointers.size();
}
#endif
alert* session_impl::wait_for_alert(time_duration max_wait)
{
return m_alerts.wait_for_alert(max_wait);
}
#ifndef TORRENT_NO_DEPRECATE
size_t session_impl::set_alert_queue_size_limit(size_t queue_size_limit_)
{
m_settings.set_int(settings_pack::alert_queue_size, queue_size_limit_);
return m_alerts.set_alert_queue_size_limit(queue_size_limit_);
}
#endif
void session_impl::start_lsd()
{
INVARIANT_CHECK;
if (m_lsd) return;
m_lsd = boost::make_shared<lsd>(boost::ref(m_io_service)
, boost::bind(&session_impl::on_lsd_peer, this, _1, _2)
#ifndef TORRENT_DISABLE_LOGGING
, boost::bind(&session_impl::on_lsd_log, this, _1)
#endif
);
error_code ec;
m_lsd->start(ec);
if (ec && m_alerts.should_post<lsd_error_alert>())
m_alerts.emplace_alert<lsd_error_alert>(ec);
}
#ifndef TORRENT_DISABLE_LOGGING
void session_impl::on_lsd_log(char const* log)
{
if (!m_alerts.should_post<log_alert>()) return;
m_alerts.emplace_alert<log_alert>(log);
}
#endif
natpmp* session_impl::start_natpmp()
{
INVARIANT_CHECK;
if (m_natpmp) return m_natpmp.get();
// the natpmp constructor may fail and call the callbacks
// into the session_impl.
m_natpmp = boost::make_shared<natpmp>(boost::ref(m_io_service)
, boost::bind(&session_impl::on_port_mapping
, this, _1, _2, _3, _4, _5, 0)
, boost::bind(&session_impl::on_port_map_log
, this, _1, 0));
m_natpmp->start();
int const ssl_port = ssl_listen_port();
if (m_listen_interface.port() > 0)
{
remap_tcp_ports(1, m_listen_interface.port(), ssl_port);
}
if (m_udp_socket.is_open())
{
m_udp_mapping[0] = m_natpmp->add_mapping(natpmp::udp
, m_listen_interface.port(), m_listen_interface.port());
}
#ifdef TORRENT_USE_OPENSSL
if (m_ssl_udp_socket.is_open() && ssl_port > 0)
{
m_ssl_udp_mapping[0] = m_natpmp->add_mapping(natpmp::udp
, ssl_port, ssl_port);
}
#endif
return m_natpmp.get();
}
upnp* session_impl::start_upnp()
{
INVARIANT_CHECK;
if (m_upnp) return m_upnp.get();
// the upnp constructor may fail and call the callbacks
m_upnp = boost::make_shared<upnp>(boost::ref(m_io_service)
, m_listen_interface.address()
, m_settings.get_bool(settings_pack::anonymous_mode)
? "" : m_settings.get_str(settings_pack::user_agent)
, boost::bind(&session_impl::on_port_mapping
, this, _1, _2, _3, _4, _5, 1)
, boost::bind(&session_impl::on_port_map_log
, this, _1, 1)
, m_settings.get_bool(settings_pack::upnp_ignore_nonrouters));
m_upnp->start();
int ssl_port = ssl_listen_port();
m_upnp->discover_device();
if (m_listen_interface.port() > 0 || ssl_port > 0)
{
remap_tcp_ports(2, m_listen_interface.port(), ssl_port);
}
if (m_udp_socket.is_open())
{
m_udp_mapping[1] = m_upnp->add_mapping(upnp::udp
, m_listen_interface.port(), m_listen_interface.port());
}
#ifdef TORRENT_USE_OPENSSL
if (m_ssl_udp_socket.is_open() && ssl_port > 0)
{
m_ssl_udp_mapping[1] = m_upnp->add_mapping(upnp::udp
, ssl_port, ssl_port);
}
#endif
return m_upnp.get();
}
int session_impl::add_port_mapping(int t, int external_port
, int local_port)
{
int ret = 0;
if (m_upnp) ret = m_upnp->add_mapping(static_cast<upnp::protocol_type>(t), external_port
, local_port);
if (m_natpmp) ret = m_natpmp->add_mapping(static_cast<natpmp::protocol_type>(t), external_port
, local_port);
return ret;
}
void session_impl::delete_port_mapping(int handle)
{
if (m_upnp) m_upnp->delete_mapping(handle);
if (m_natpmp) m_natpmp->delete_mapping(handle);
}
void session_impl::stop_lsd()
{
if (m_lsd)
m_lsd->close();
m_lsd.reset();
}
void session_impl::stop_natpmp()
{
if (m_natpmp)
{
m_natpmp->close();
m_udp_mapping[0] = -1;
m_tcp_mapping[0] = -1;
#ifdef TORRENT_USE_OPENSSL
m_ssl_tcp_mapping[0] = -1;
m_ssl_udp_mapping[0] = -1;
#endif
}
m_natpmp.reset();
}
void session_impl::stop_upnp()
{
if (m_upnp)
{
m_upnp->close();
m_udp_mapping[1] = -1;
m_tcp_mapping[1] = -1;
#ifdef TORRENT_USE_OPENSSL
m_ssl_tcp_mapping[1] = -1;
m_ssl_udp_mapping[1] = -1;
#endif
}
m_upnp.reset();
}
external_ip const& session_impl::external_address() const
{
return m_external_ip;
}
// this is the DHT observer version. DHT is the implied source
void session_impl::set_external_address(address const& ip
, address const& source)
{
set_external_address(ip, source_dht, source);
}
address session_impl::external_address()
{
return m_external_ip.external_address(address_v4());
}
void session_impl::get_peers(sha1_hash const& ih)
{
if (!m_alerts.should_post<dht_get_peers_alert>()) return;
m_alerts.emplace_alert<dht_get_peers_alert>(ih);
}
void session_impl::announce(sha1_hash const& ih, address const& addr
, int port)
{
if (!m_alerts.should_post<dht_announce_alert>()) return;
m_alerts.emplace_alert<dht_announce_alert>(addr, port, ih);
}
void session_impl::outgoing_get_peers(sha1_hash const& target
, sha1_hash const& sent_target, udp::endpoint const& ep)
{
if (!m_alerts.should_post<dht_outgoing_get_peers_alert>()) return;
m_alerts.emplace_alert<dht_outgoing_get_peers_alert>(target, sent_target, ep);
}
// TODO: 2 perhaps DHT logging should be disabled by TORRENT_DISABLE_LOGGING
// too
TORRENT_FORMAT(3,4)
void session_impl::log(libtorrent::dht::dht_logger::module_t m, char const* fmt, ...)
{
if (!m_alerts.should_post<dht_log_alert>()) return;
va_list v;
va_start(v, fmt);
char buf[1024];
vsnprintf(buf, sizeof(buf), fmt, v);
va_end(v);
m_alerts.emplace_alert<dht_log_alert>(static_cast<dht_log_alert::dht_module_t>(m), buf);
}
void session_impl::log_packet(message_direction_t dir, char const* pkt, int len
, udp::endpoint node)
{
if (!m_alerts.should_post<dht_pkt_alert>()) return;
dht_pkt_alert::direction_t d = dir == dht_logger::incoming_message
? dht_pkt_alert::incoming : dht_pkt_alert::outgoing;
m_alerts.emplace_alert<dht_pkt_alert>(pkt, len, d, node);
}
bool session_impl::on_dht_request(char const* query, int query_len
, dht::msg const& request, entry& response)
{
#ifndef TORRENT_DISABLE_EXTENSIONS
if (query_len > max_dht_query_length) return false;
for (m_extension_dht_queries_t::iterator i = m_extension_dht_queries.begin();
i != m_extension_dht_queries.end(); ++i)
{
if (query_len == i->query_len
&& memcmp(i->query.data(), query, query_len) == 0
&& i->handler(request.addr, request.message, response))
return true;
}
#else
TORRENT_UNUSED(query);
TORRENT_UNUSED(query_len);
TORRENT_UNUSED(request);
TORRENT_UNUSED(response);
#endif
return false;
}
void session_impl::set_external_address(address const& ip
, int source_type, address const& source)
{
#ifndef TORRENT_DISABLE_LOGGING
session_log(": set_external_address(%s, %d, %s)", print_address(ip).c_str()
, source_type, print_address(source).c_str());
#endif
if (!m_external_ip.cast_vote(ip, source_type, source)) return;
#ifndef TORRENT_DISABLE_LOGGING
session_log(" external IP updated");
#endif
if (m_alerts.should_post<external_ip_alert>())
m_alerts.emplace_alert<external_ip_alert>(ip);
for (torrent_map::iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
i->second->new_external_ip();
}
// since we have a new external IP now, we need to
// restart the DHT with a new node ID
#ifndef TORRENT_DISABLE_DHT
if (m_dht) m_dht->update_node_id();
#endif
}
// decrement the refcount of the block in the disk cache
// since the network thread doesn't need it anymore
void session_impl::reclaim_block(block_cache_reference ref)
{
m_disk_thread.reclaim_block(ref);
}
char* session_impl::allocate_disk_buffer(char const* category)
{
return m_disk_thread.allocate_disk_buffer(category);
}
void session_impl::free_disk_buffer(char* buf)
{
m_disk_thread.free_disk_buffer(buf);
}
char* session_impl::allocate_disk_buffer(bool& exceeded
, boost::shared_ptr<disk_observer> o
, char const* category)
{
return m_disk_thread.allocate_disk_buffer(exceeded, o, category);
}
char* session_impl::allocate_buffer()
{
TORRENT_ASSERT(is_single_thread());
#ifdef TORRENT_DISABLE_POOL_ALLOCATOR
int num_bytes = send_buffer_size();
return static_cast<char*>(malloc(num_bytes));
#else
return static_cast<char*>(m_send_buffers.malloc());
#endif
}
void session_impl::free_buffer(char* buf)
{
TORRENT_ASSERT(is_single_thread());
#ifdef TORRENT_DISABLE_POOL_ALLOCATOR
free(buf);
#else
m_send_buffers.free(buf);
#endif
}
#if TORRENT_USE_INVARIANT_CHECKS
void session_impl::check_invariant() const
{
TORRENT_ASSERT(is_single_thread());
int loaded_limit = m_settings.get_int(settings_pack::active_loaded_limit);
TORRENT_ASSERT(m_num_save_resume <= loaded_limit);
// if (m_num_save_resume < loaded_limit)
// TORRENT_ASSERT(m_save_resume_queue.empty());
TORRENT_ASSERT(m_torrents.size() >= m_torrent_lru.size());
if (m_settings.get_int(settings_pack::unchoke_slots_limit) < 0
&& m_settings.get_int(settings_pack::choking_algorithm) == settings_pack::fixed_slots_choker)
TORRENT_ASSERT(m_stats_counters[counters::num_unchoke_slots] == (std::numeric_limits<int>::max)());
for (int l = 0; l < num_torrent_lists; ++l)
{
std::vector<torrent*> const& list = m_torrent_lists[l];
for (std::vector<torrent*>::const_iterator i = list.begin()
, end(list.end()); i != end; ++i)
{
TORRENT_ASSERT((*i)->m_links[l].in_list());
}
}
#if TORRENT_HAS_BOOST_UNORDERED
boost::unordered_set<torrent*> unique_torrents;
#else
std::set<torrent*> unique_torrents;
#endif
for (list_iterator<torrent> i = m_torrent_lru.iterate(); i.get(); i.next())
{
torrent* t = i.get();
TORRENT_ASSERT(t->is_loaded());
TORRENT_ASSERT(unique_torrents.count(t) == 0);
unique_torrents.insert(t);
}
TORRENT_ASSERT(unique_torrents.size() == m_torrent_lru.size());
int torrent_state_gauges[counters::num_error_torrents - counters::num_checking_torrents + 1];
memset(torrent_state_gauges, 0, sizeof(torrent_state_gauges));
#if defined TORRENT_EXPENSIVE_INVARIANT_CHECKS
#if TORRENT_HAS_BOOST_UNORDERED
boost::unordered_set<int> unique;
#else
std::set<int> unique;
#endif
#endif
int num_active_downloading = 0;
int num_active_finished = 0;
int total_downloaders = 0;
for (torrent_map::const_iterator i = m_torrents.begin()
, end(m_torrents.end()); i != end; ++i)
{
boost::shared_ptr<torrent> t = i->second;
if (t->want_peers_download()) ++num_active_downloading;
if (t->want_peers_finished()) ++num_active_finished;
TORRENT_ASSERT(!(t->want_peers_download() && t->want_peers_finished()));
++torrent_state_gauges[t->current_stats_state() - counters::num_checking_torrents];
int pos = t->queue_position();
if (pos < 0)
{
TORRENT_ASSERT(pos == -1);
continue;
}
++total_downloaders;
#if defined TORRENT_EXPENSIVE_INVARIANT_CHECKS
unique.insert(t->queue_position());
#endif
}
for (int i = 0, j = counters::num_checking_torrents;
j < counters::num_error_torrents + 1; ++i, ++j)
{
TORRENT_ASSERT(torrent_state_gauges[i] == m_stats_counters[j]);
}
#if defined TORRENT_EXPENSIVE_INVARIANT_CHECKS
TORRENT_ASSERT(int(unique.size()) == total_downloaders);
#endif
TORRENT_ASSERT(num_active_downloading == m_torrent_lists[torrent_want_peers_download].size());
TORRENT_ASSERT(num_active_finished == m_torrent_lists[torrent_want_peers_finished].size());
#if TORRENT_HAS_BOOST_UNORDERED
boost::unordered_set<peer_connection*> unique_peers;
#else
std::set<peer_connection*> unique_peers;
#endif
TORRENT_ASSERT(m_settings.get_int(settings_pack::connections_limit) > 0);
int unchokes = 0;
int unchokes_all = 0;
int num_optimistic = 0;
int disk_queue[2] = {0, 0};
for (connection_map::const_iterator i = m_connections.begin();
i != m_connections.end(); ++i)
{
TORRENT_ASSERT(*i);
boost::shared_ptr<torrent> t = (*i)->associated_torrent().lock();
TORRENT_ASSERT(unique_peers.find(i->get()) == unique_peers.end());
unique_peers.insert(i->get());
if ((*i)->m_channel_state[0] & peer_info::bw_disk) ++disk_queue[0];
if ((*i)->m_channel_state[1] & peer_info::bw_disk) ++disk_queue[1];
peer_connection* p = i->get();
TORRENT_ASSERT(!p->is_disconnecting());
if (p->ignore_unchoke_slots())
{
if (!p->is_choked()) ++unchokes_all;
continue;
}
if (!p->is_choked())
{
++unchokes;
++unchokes_all;
}
if (p->peer_info_struct()
&& p->peer_info_struct()->optimistically_unchoked)
{
++num_optimistic;
TORRENT_ASSERT(!p->is_choked());
}
}
for (std::vector<boost::shared_ptr<peer_connection> >::const_iterator i
= m_undead_peers.begin(); i != m_undead_peers.end(); ++i)
{
peer_connection* p = i->get();
if (p->ignore_unchoke_slots())
{
if (!p->is_choked()) ++unchokes_all;
continue;
}
if (!p->is_choked())
{
++unchokes_all;
++unchokes;
}
if (p->peer_info_struct()
&& p->peer_info_struct()->optimistically_unchoked)
{
++num_optimistic;
TORRENT_ASSERT(!p->is_choked());
}
}
TORRENT_ASSERT(disk_queue[peer_connection::download_channel]
== m_stats_counters[counters::num_peers_down_disk]);
TORRENT_ASSERT(disk_queue[peer_connection::upload_channel]
== m_stats_counters[counters::num_peers_up_disk]);
if (m_settings.get_int(settings_pack::num_optimistic_unchoke_slots))
{
TORRENT_ASSERT(num_optimistic <= m_settings.get_int(
settings_pack::num_optimistic_unchoke_slots));
}
int const unchoked_counter_all = m_stats_counters[counters::num_peers_up_unchoked_all];
int const unchoked_counter = m_stats_counters[counters::num_peers_up_unchoked];
int const unchoked_counter_optimistic
= m_stats_counters[counters::num_peers_up_unchoked_optimistic];
TORRENT_ASSERT_VAL(unchoked_counter_all == unchokes_all, unchokes_all);
TORRENT_ASSERT_VAL(unchoked_counter == unchokes, unchokes);
TORRENT_ASSERT_VAL(unchoked_counter_optimistic == num_optimistic, num_optimistic);
for (torrent_map::const_iterator j
= m_torrents.begin(); j != m_torrents.end(); ++j)
{
TORRENT_ASSERT(boost::get_pointer(j->second));
}
}
#endif // TORRENT_USE_INVARIANT_CHECKS
#ifndef TORRENT_DISABLE_LOGGING
tracker_logger::tracker_logger(session_interface& ses): m_ses(ses) {}
void tracker_logger::tracker_warning(tracker_request const&
, std::string const& str)
{
debug_log("*** tracker warning: %s", str.c_str());
}
void tracker_logger::tracker_response(tracker_request const&
, libtorrent::address const& tracker_ip
, std::list<address> const& tracker_ips
, struct tracker_response const& resp)
{
TORRENT_UNUSED(tracker_ips);
debug_log("TRACKER RESPONSE\n"
"interval: %d\n"
"external ip: %s\n"
"we connected to: %s\n"
"peers:"
, resp.interval
, print_address(resp.external_ip).c_str()
, print_address(tracker_ip).c_str());
for (std::vector<peer_entry>::const_iterator i = resp.peers.begin();
i != resp.peers.end(); ++i)
{
debug_log(" %16s %5d %s %s", i->hostname.c_str(), i->port
, i->pid.is_all_zeros()?"":to_hex(i->pid.to_string()).c_str()
, identify_client(i->pid).c_str());
}
for (std::vector<ipv4_peer_entry>::const_iterator i = resp.peers4.begin();
i != resp.peers4.end(); ++i)
{
debug_log(" %s:%d", print_address(address_v4(i->ip)).c_str(), i->port);
}
#if TORRENT_USE_IPV6
for (std::vector<ipv6_peer_entry>::const_iterator i = resp.peers6.begin();
i != resp.peers6.end(); ++i)
{
debug_log(" [%s]:%d", print_address(address_v6(i->ip)).c_str(), i->port);
}
#endif
}
void tracker_logger::tracker_request_timed_out(
tracker_request const&)
{
debug_log("*** tracker timed out");
}
void tracker_logger::tracker_request_error(tracker_request const&
, int response_code, error_code const& ec, const std::string& str
, int retry_interval)
{
TORRENT_UNUSED(retry_interval);
debug_log("*** tracker error: %d: %s %s"
, response_code, ec.message().c_str(), str.c_str());
}
void tracker_logger::debug_log(const char* fmt, ...) const
{
va_list v;
va_start(v, fmt);
char usr[1024];
vsnprintf(usr, sizeof(usr), fmt, v);
va_end(v);
m_ses.session_log("%s", usr);
}
#endif // TORRENT_DISABLE_LOGGING
}}
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