/* Copyright (c) 2006, 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/pch.hpp" #include #include #include #include #include #include #include #include #include #ifdef _MSC_VER #pragma warning(push, 1) #endif #include #include #include #include #include #ifdef _MSC_VER #pragma warning(pop) #endif #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/ip_filter.hpp" #include "libtorrent/socket.hpp" #include "libtorrent/aux_/session_impl.hpp" #include "libtorrent/kademlia/dht_tracker.hpp" #include "libtorrent/enum_net.hpp" #ifndef TORRENT_DISABLE_ENCRYPTION #include 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 #ifdef _WIN32 // for ERROR_SEM_TIMEOUT #include #endif using boost::shared_ptr; using boost::weak_ptr; using boost::bind; using boost::mutex; using libtorrent::aux::session_impl; namespace libtorrent { namespace fs = boost::filesystem; namespace detail { std::string generate_auth_string(std::string const& user , std::string const& passwd) { if (user.empty()) return std::string(); return user + ":" + passwd; } } namespace aux { // This is the checker thread // it is looping in an infinite loop // until the session is aborted. It will // normally just block in a wait() call, // waiting for a signal from session that // there's a new torrent to check. void checker_impl::operator()() { eh_initializer(); // if we're currently performing a full file check, // this is the torrent being processed boost::shared_ptr processing; boost::shared_ptr t; for (;;) { // temporary torrent used while checking fastresume data try { t.reset(); { boost::mutex::scoped_lock l(m_mutex); INVARIANT_CHECK; // if the job queue is empty and // we shouldn't abort // wait for a signal while (m_torrents.empty() && !m_abort && !processing) m_cond.wait(l); if (m_abort) { // no lock is needed here, because the main thread // has already been shut down by now processing.reset(); t.reset(); std::for_each(m_torrents.begin(), m_torrents.end() , boost::bind(&torrent::abort , boost::bind(&shared_ptr::get , boost::bind(&piece_checker_data::torrent_ptr, _1)))); m_torrents.clear(); std::for_each(m_processing.begin(), m_processing.end() , boost::bind(&torrent::abort , boost::bind(&shared_ptr::get , boost::bind(&piece_checker_data::torrent_ptr, _1)))); m_processing.clear(); return; } if (!m_torrents.empty()) { t = m_torrents.front(); if (t->abort) { // make sure the locking order is // consistent to avoid dead locks // we need to lock the session because closing // torrents assume to have access to it l.unlock(); session_impl::mutex_t::scoped_lock l2(m_ses.m_mutex); l.lock(); t->torrent_ptr->abort(); m_torrents.pop_front(); continue; } } } if (t) { std::string error_msg; t->parse_resume_data(t->resume_data, t->torrent_ptr->torrent_file() , error_msg); // lock the session to add the new torrent session_impl::mutex_t::scoped_lock l(m_ses.m_mutex); if (!error_msg.empty() && m_ses.m_alerts.should_post(alert::warning)) { m_ses.m_alerts.post_alert(fastresume_rejected_alert( t->torrent_ptr->get_handle() , error_msg)); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_ses.m_logger) << "fastresume data for " << t->torrent_ptr->torrent_file().name() << " rejected: " << error_msg << "\n"; #endif } mutex::scoped_lock l2(m_mutex); if (m_torrents.empty() || m_torrents.front() != t) { // this means the torrent was removed right after it was // added. Abort the checking. t.reset(); continue; } // clear the resume data now that it has been used // (the fast resume data is now parsed and stored in t) t->resume_data = entry(); bool up_to_date = t->torrent_ptr->check_fastresume(*t); if (up_to_date) { INVARIANT_CHECK; TORRENT_ASSERT(!m_torrents.empty()); TORRENT_ASSERT(m_torrents.front() == t); t->torrent_ptr->files_checked(t->unfinished_pieces); m_torrents.pop_front(); // we cannot add the torrent if the session is aborted. if (!m_ses.is_aborted()) { m_ses.m_torrents.insert(std::make_pair(t->info_hash, t->torrent_ptr)); if (m_ses.m_alerts.should_post(alert::info)) { m_ses.m_alerts.post_alert(torrent_checked_alert( processing->torrent_ptr->get_handle() , "torrent finished checking")); } if (t->torrent_ptr->is_seed() && m_ses.m_alerts.should_post(alert::info)) { m_ses.m_alerts.post_alert(torrent_finished_alert( t->torrent_ptr->get_handle() , "torrent is complete")); } peer_id id; std::fill(id.begin(), id.end(), 0); for (std::vector::const_iterator i = t->peers.begin(); i != t->peers.end(); ++i) { t->torrent_ptr->get_policy().peer_from_tracker(*i, id , peer_info::resume_data, 0); } for (std::vector::const_iterator i = t->banned_peers.begin(); i != t->banned_peers.end(); ++i) { policy::peer* p = t->torrent_ptr->get_policy().peer_from_tracker(*i, id , peer_info::resume_data, 0); if (p) p->banned = true; } } else { t->torrent_ptr->abort(); } t.reset(); continue; } l.unlock(); // move the torrent from // m_torrents to m_processing TORRENT_ASSERT(m_torrents.front() == t); m_torrents.pop_front(); m_processing.push_back(t); if (!processing) { processing = t; processing->processing = true; t.reset(); } } } catch (const std::exception& e) { // This will happen if the storage fails to initialize // for example if one of the files has an invalid filename. session_impl::mutex_t::scoped_lock l(m_ses.m_mutex); mutex::scoped_lock l2(m_mutex); if (m_ses.m_alerts.should_post(alert::fatal)) { m_ses.m_alerts.post_alert( file_error_alert( t->torrent_ptr->get_handle() , e.what())); } t->torrent_ptr->abort(); TORRENT_ASSERT(!m_torrents.empty()); m_torrents.pop_front(); } catch(...) { #ifndef NDEBUG std::cerr << "error while checking resume data\n"; #endif mutex::scoped_lock l(m_mutex); TORRENT_ASSERT(!m_torrents.empty()); m_torrents.pop_front(); TORRENT_ASSERT(false); } if (!processing) continue; try { TORRENT_ASSERT(processing); float finished = false; float progress = 0.f; boost::tie(finished, progress) = processing->torrent_ptr->check_files(); { mutex::scoped_lock l2(m_mutex); INVARIANT_CHECK; processing->progress = progress; if (processing->abort) { TORRENT_ASSERT(!m_processing.empty()); TORRENT_ASSERT(m_processing.front() == processing); m_processing.pop_front(); // make sure the lock order is correct l2.unlock(); session_impl::mutex_t::scoped_lock l(m_ses.m_mutex); l2.lock(); processing->torrent_ptr->abort(); processing.reset(); if (!m_processing.empty()) { processing = m_processing.front(); processing->processing = true; } continue; } } if (finished) { // lock the session to add the new torrent session_impl::mutex_t::scoped_lock l(m_ses.m_mutex); mutex::scoped_lock l2(m_mutex); INVARIANT_CHECK; TORRENT_ASSERT(!m_processing.empty()); TORRENT_ASSERT(m_processing.front() == processing); // TODO: factor out the adding of torrents to the session // and to the checker thread to avoid duplicating the // check for abortion. if (!m_ses.is_aborted()) { processing->torrent_ptr->files_checked(processing->unfinished_pieces); m_ses.m_torrents.insert(std::make_pair( processing->info_hash, processing->torrent_ptr)); if (m_ses.m_alerts.should_post(alert::info)) { m_ses.m_alerts.post_alert(torrent_checked_alert( processing->torrent_ptr->get_handle() , "torrent finished checking")); } if (processing->torrent_ptr->is_seed() && m_ses.m_alerts.should_post(alert::info)) { m_ses.m_alerts.post_alert(torrent_finished_alert( processing->torrent_ptr->get_handle() , "torrent is complete")); } peer_id id; std::fill(id.begin(), id.end(), 0); for (std::vector::const_iterator i = processing->peers.begin(); i != processing->peers.end(); ++i) { processing->torrent_ptr->get_policy().peer_from_tracker(*i, id , peer_info::resume_data, 0); } for (std::vector::const_iterator i = processing->banned_peers.begin(); i != processing->banned_peers.end(); ++i) { policy::peer* p = processing->torrent_ptr->get_policy().peer_from_tracker(*i, id , peer_info::resume_data, 0); if (p) p->banned = true; } } else { processing->torrent_ptr->abort(); } processing.reset(); m_processing.pop_front(); if (!m_processing.empty()) { processing = m_processing.front(); processing->processing = true; } } } catch(std::exception const& e) { // This will happen if the storage fails to initialize session_impl::mutex_t::scoped_lock l(m_ses.m_mutex); mutex::scoped_lock l2(m_mutex); if (m_ses.m_alerts.should_post(alert::fatal)) { m_ses.m_alerts.post_alert( file_error_alert( processing->torrent_ptr->get_handle() , e.what())); } processing->torrent_ptr->abort(); if (!m_processing.empty() && m_processing.front() == processing) m_processing.pop_front(); processing.reset(); if (!m_processing.empty()) { processing = m_processing.front(); processing->processing = true; } } catch(...) { #ifndef NDEBUG std::cerr << "error while checking files\n"; #endif mutex::scoped_lock l(m_mutex); TORRENT_ASSERT(!m_processing.empty()); processing.reset(); m_processing.pop_front(); if (!m_processing.empty()) { processing = m_processing.front(); processing->processing = true; } TORRENT_ASSERT(false); } } } aux::piece_checker_data* checker_impl::find_torrent(sha1_hash const& info_hash) { INVARIANT_CHECK; for (std::deque >::iterator i = m_torrents.begin(); i != m_torrents.end(); ++i) { if ((*i)->info_hash == info_hash) return i->get(); } for (std::deque >::iterator i = m_processing.begin(); i != m_processing.end(); ++i) { if ((*i)->info_hash == info_hash) return i->get(); } return 0; } void checker_impl::remove_torrent(sha1_hash const& info_hash, int options) { INVARIANT_CHECK; for (std::deque >::iterator i = m_torrents.begin(); i != m_torrents.end(); ++i) { if ((*i)->info_hash == info_hash) { TORRENT_ASSERT((*i)->processing == false); if (options & session::delete_files) (*i)->torrent_ptr->delete_files(); m_torrents.erase(i); return; } } for (std::deque >::iterator i = m_processing.begin(); i != m_processing.end(); ++i) { if ((*i)->info_hash == info_hash) { TORRENT_ASSERT((*i)->processing == false); if (options & session::delete_files) (*i)->torrent_ptr->delete_files(); m_processing.erase(i); return; } } TORRENT_ASSERT(false); } #ifndef NDEBUG void checker_impl::check_invariant() const { for (std::deque >::const_iterator i = m_torrents.begin(); i != m_torrents.end(); ++i) { TORRENT_ASSERT(*i); TORRENT_ASSERT((*i)->torrent_ptr); } for (std::deque >::const_iterator i = m_processing.begin(); i != m_processing.end(); ++i) { TORRENT_ASSERT(*i); TORRENT_ASSERT((*i)->torrent_ptr); } } #endif struct seed_random_generator { seed_random_generator() { std::srand(total_microseconds(time_now() - min_time())); } }; session_impl::session_impl( std::pair listen_port_range , fingerprint const& cl_fprint , char const* listen_interface #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) , fs::path const& logpath #endif ) : m_send_buffers(send_buffer_size) , m_files(40) , m_strand(m_io_service) , m_half_open(m_io_service) , m_download_channel(m_io_service, peer_connection::download_channel) , m_upload_channel(m_io_service, peer_connection::upload_channel) , m_tracker_manager(m_settings, m_tracker_proxy) , m_listen_port_retries(listen_port_range.second - listen_port_range.first) , m_listen_interface(address::from_string(listen_interface), listen_port_range.first) , m_abort(false) , m_max_uploads(8) , m_max_connections(200) , m_num_unchoked(0) , m_unchoke_time_scaler(0) , m_optimistic_unchoke_time_scaler(0) , m_disconnect_time_scaler(0) , m_incoming_connection(false) , m_last_tick(time_now()) #ifndef TORRENT_DISABLE_DHT , m_dht_same_port(true) , m_external_udp_port(0) , m_dht_socket(m_io_service, bind(&session_impl::on_receive_udp, this, _1, _2, _3) , m_half_open) #endif , m_timer(m_io_service) , m_next_connect_torrent(0) #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) , m_logpath(logpath) #endif , m_checker_impl(*this) { #ifdef WIN32 // windows XP has a limit on the number of // simultaneous half-open TCP connections DWORD windows_version = ::GetVersion(); if ((windows_version & 0xff) >= 6) { // on vista the limit is 5 (in home edition) m_half_open.limit(4); } else { // on XP SP2 it's 10 m_half_open.limit(8); } #endif m_bandwidth_manager[peer_connection::download_channel] = &m_download_channel; m_bandwidth_manager[peer_connection::upload_channel] = &m_upload_channel; #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) m_logger = create_log("main_session", listen_port(), false); (*m_logger) << time_now_string() << "\n"; #endif #ifdef TORRENT_STATS m_stats_logger.open("session_stats.log", std::ios::trunc); m_stats_logger << "1. second\n" "2. upload rate\n" "3. download rate\n" "4. downloading torrents\n" "5. seeding torrents\n" "6. peers\n" "7. connecting peers\n" "8. disk block buffers\n" "\n"; m_buffer_usage_logger.open("buffer_stats.log", std::ios::trunc); m_second_counter = 0; #endif // ---- generate a peer id ---- static seed_random_generator seeder; m_key = rand() + (rand() << 15) + (rand() << 30); std::string print = cl_fprint.to_string(); TORRENT_ASSERT(print.length() <= 20); // the client's fingerprint std::copy( print.begin() , print.begin() + print.length() , m_peer_id.begin()); // http-accepted characters: static char const printable[] = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ" "abcdefghijklmnopqrstuvwxyz-_.!~*'()"; // the random number for (unsigned char* i = m_peer_id.begin() + print.length(); i != m_peer_id.end(); ++i) { *i = printable[rand() % (sizeof(printable)-1)]; } m_timer.expires_from_now(seconds(1)); m_timer.async_wait(m_strand.wrap( bind(&session_impl::second_tick, this, _1))); m_thread.reset(new boost::thread(boost::ref(*this))); m_checker_thread.reset(new boost::thread(boost::ref(m_checker_impl))); } #ifndef TORRENT_DISABLE_EXTENSIONS void session_impl::add_extension( boost::function(torrent*, void*)> ext) { m_extensions.push_back(ext); } #endif #ifndef TORRENT_DISABLE_DHT void session_impl::add_dht_node(udp::endpoint n) { if (m_dht) m_dht->add_node(n); } #endif void session_impl::abort() { mutex_t::scoped_lock l(m_mutex); if (m_abort) return; #if defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " *** ABORT CALLED ***\n"; #endif // abort the main thread m_abort = true; if (m_lsd) m_lsd->close(); if (m_upnp) m_upnp->close(); if (m_natpmp) m_natpmp->close(); #ifndef TORRENT_DISABLE_DHT if (m_dht) m_dht->stop(); m_dht_socket.close(); #endif m_timer.cancel(); // close the listen sockets for (std::list::iterator i = m_listen_sockets.begin() , end(m_listen_sockets.end()); i != end; ++i) { i->sock->close(); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " aborting all torrents\n"; #endif // abort all torrents for (torrent_map::iterator i = m_torrents.begin() , end(m_torrents.end()); i != end; ++i) { i->second->abort(); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " aborting all tracker requests\n"; #endif m_tracker_manager.abort_all_requests(); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " sending event=stopped to trackers\n"; int counter = 0; #endif for (torrent_map::iterator i = m_torrents.begin(); i != m_torrents.end(); ++i) { torrent& t = *i->second; if ((!t.is_paused() || t.should_request()) && !t.trackers().empty()) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) ++counter; #endif tracker_request req = t.generate_tracker_request(); TORRENT_ASSERT(req.event == tracker_request::stopped); req.listen_port = 0; if (!m_listen_sockets.empty()) req.listen_port = m_listen_sockets.front().external_port; req.key = m_key; std::string login = i->second->tracker_login(); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) boost::shared_ptr tl(new tracker_logger(*this)); m_tracker_loggers.push_back(tl); m_tracker_manager.queue_request(m_strand, m_half_open, req, login , m_listen_interface.address(), tl); #else m_tracker_manager.queue_request(m_strand, m_half_open, req, login , m_listen_interface.address()); #endif } } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " sent " << counter << " tracker stop requests\n"; #endif #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " aborting all connections (" << m_connections.size() << ")\n"; #endif // abort all connections while (!m_connections.empty()) { #ifndef NDEBUG int conn = m_connections.size(); #endif (*m_connections.begin())->disconnect(); TORRENT_ASSERT(conn == int(m_connections.size()) + 1); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " shutting down connection queue\n"; #endif m_half_open.close(); m_download_channel.close(); m_upload_channel.close(); mutex::scoped_lock l2(m_checker_impl.m_mutex); // abort the checker thread m_checker_impl.m_abort = true; } void session_impl::set_port_filter(port_filter const& f) { mutex_t::scoped_lock l(m_mutex); m_port_filter = f; } void session_impl::set_ip_filter(ip_filter const& f) { mutex_t::scoped_lock l(m_mutex); 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->ip_filter_updated(); } void session_impl::set_settings(session_settings const& s) { mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; TORRENT_ASSERT(s.connection_speed > 0); TORRENT_ASSERT(s.file_pool_size > 0); // less than 5 seconds unchoke interval is insane TORRENT_ASSERT(s.unchoke_interval >= 5); m_settings = s; m_files.resize(m_settings.file_pool_size); // replace all occurances of '\n' with ' '. std::string::iterator i = m_settings.user_agent.begin(); while ((i = std::find(i, m_settings.user_agent.end(), '\n')) != m_settings.user_agent.end()) *i = ' '; } tcp::endpoint session_impl::get_ipv6_interface() const { return m_ipv6_interface; } session_impl::listen_socket_t session_impl::setup_listener(tcp::endpoint ep , int retries, bool v6_only) { asio::error_code ec; listen_socket_t s; s.sock.reset(new socket_acceptor(m_io_service)); s.sock->open(ep.protocol(), ec); s.sock->set_option(socket_acceptor::reuse_address(true), ec); if (ep.protocol() == tcp::v6()) s.sock->set_option(v6only(v6_only), ec); s.sock->bind(ep, ec); while (ec && retries > 0) { ec = asio::error_code(); TORRENT_ASSERT(!ec); --retries; ep.port(ep.port() + 1); s.sock->bind(ep, ec); } if (ec) { // instead of giving up, try // let the OS pick a port ep.port(0); ec = asio::error_code(); s.sock->bind(ep, ec); } if (ec) { // not even that worked, give up if (m_alerts.should_post(alert::fatal)) { std::stringstream msg; msg << "cannot bind to interface '"; print_endpoint(msg, ep) << "' " << ec.message(); m_alerts.post_alert(listen_failed_alert(ep, msg.str())); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) std::stringstream msg; msg << "cannot bind to interface '"; print_endpoint(msg, ep) << "' " << ec.message(); (*m_logger) << msg.str() << "\n"; #endif return listen_socket_t(); } s.external_port = s.sock->local_endpoint(ec).port(); s.sock->listen(0, ec); if (ec) { if (m_alerts.should_post(alert::fatal)) { std::stringstream msg; msg << "cannot listen on interface '"; print_endpoint(msg, ep) << "' " << ec.message(); m_alerts.post_alert(listen_failed_alert(ep, msg.str())); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) std::stringstream msg; msg << "cannot listen on interface '"; print_endpoint(msg, ep) << "' " << ec.message(); (*m_logger) << msg.str() << "\n"; #endif return listen_socket_t(); } if (m_alerts.should_post(alert::fatal)) { std::string msg = "listening on interface " + boost::lexical_cast(ep); m_alerts.post_alert(listen_succeeded_alert(ep, msg)); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << "listening on: " << ep << " external port: " << s.external_port << "\n"; #endif return s; } void session_impl::open_listen_port() throw() { // close the open listen sockets m_listen_sockets.clear(); m_incoming_connection = false; if (is_any(m_listen_interface.address())) { // this means we should open two listen sockets // one for IPv4 and one for IPv6 listen_socket_t s = setup_listener( tcp::endpoint(address_v4::any(), m_listen_interface.port()) , m_listen_port_retries); if (s.sock) { m_listen_sockets.push_back(s); async_accept(s.sock); } s = setup_listener( tcp::endpoint(address_v6::any(), m_listen_interface.port()) , m_listen_port_retries, true); if (s.sock) { m_listen_sockets.push_back(s); async_accept(s.sock); } } else { // we should only open a single listen socket, that // binds to the given interface listen_socket_t s = setup_listener( m_listen_interface, m_listen_port_retries); if (s.sock) { m_listen_sockets.push_back(s); async_accept(s.sock); } } m_ipv6_interface = tcp::endpoint(); for (std::list::const_iterator i = m_listen_sockets.begin() , end(m_listen_sockets.end()); i != end; ++i) { asio::error_code ec; tcp::endpoint ep = i->sock->local_endpoint(ec); if (ec || ep.address().is_v4()) continue; if (ep.address().to_v6() != address_v6::any()) { // if we're listening on a specific address // pick it m_ipv6_interface = ep; } else { // if we're listening on any IPv6 address, enumerate them and // pick the first non-local address std::vector
const& ifs = enum_net_interfaces(m_io_service, ec); for (std::vector
::const_iterator i = ifs.begin() , end(ifs.end()); i != end; ++i) { if (i->is_v4() || i->to_v6().is_link_local() || i->to_v6().is_loopback()) continue; m_ipv6_interface = tcp::endpoint(*i, ep.port()); break; } break; } } if (!m_listen_sockets.empty()) { asio::error_code ec; tcp::endpoint local = m_listen_sockets.front().sock->local_endpoint(ec); if (!ec) { if (m_natpmp.get()) m_natpmp->set_mappings(local.port(), 0); if (m_upnp.get()) m_upnp->set_mappings(local.port(), 0); } } } void session_impl::on_receive_udp(udp::endpoint const& ep, char const* buf, int len) { if (len > 20 && *buf == 'd' && m_dht) { // this is probably a dht message m_dht->on_receive(ep, buf, len); } } void session_impl::async_accept(boost::shared_ptr const& listener) { shared_ptr c(new socket_type); c->instantiate(m_io_service); listener->async_accept(c->get() , bind(&session_impl::on_incoming_connection, this, c , boost::weak_ptr(listener), _1)); } void session_impl::on_incoming_connection(shared_ptr const& s , weak_ptr listen_socket, asio::error_code const& e) try { boost::shared_ptr listener = listen_socket.lock(); if (!listener) return; if (e == asio::error::operation_aborted) return; mutex_t::scoped_lock l(m_mutex); if (m_abort) return; asio::error_code ec; if (e) { tcp::endpoint ep = listener->local_endpoint(ec); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) std::string msg = "error accepting connection on '" + boost::lexical_cast(ep) + "' " + e.message(); (*m_logger) << msg << "\n"; #endif #ifdef _WIN32 // 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); return; } #endif if (m_alerts.should_post(alert::fatal)) { std::string msg = "error accepting connection on '" + boost::lexical_cast(ep) + "' " + ec.message(); m_alerts.post_alert(listen_failed_alert(ep, msg)); } return; } async_accept(listener); // we got a connection request! tcp::endpoint endp = s->remote_endpoint(ec); if (ec) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << endp << " <== INCOMING CONNECTION FAILED, could " "not retrieve remote endpoint " << ec.message() << "\n"; #endif return; } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " <== INCOMING CONNECTION " << endp << "\n"; #endif // 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_incoming_connection = true; if (m_ip_filter.access(endp.address()) & ip_filter::blocked) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << "filtered blocked ip\n"; #endif if (m_alerts.should_post(alert::info)) { m_alerts.post_alert(peer_blocked_alert(endp.address() , "incoming connection blocked by IP filter")); } return; } // don't allow more connections than the max setting if (num_connections() > max_connections()) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << "number of connections limit exceeded (conns: " << num_connections() << ", limit: " << max_connections() << "), connection rejected\n"; #endif return; } // check if we have any active torrents // if we don't reject the connection if (m_torrents.empty()) return; bool has_active_torrent = false; for (torrent_map::iterator i = m_torrents.begin() , end(m_torrents.end()); i != end; ++i) { if (!i->second->is_paused()) { has_active_torrent = true; break; } } if (!has_active_torrent) return; boost::intrusive_ptr c( new bt_peer_connection(*this, s, 0)); #ifndef NDEBUG c->m_in_constructor = false; #endif m_connections.insert(c); } catch (std::exception& exc) { #ifndef NDEBUG std::string err = exc.what(); #endif }; void session_impl::connection_failed(boost::intrusive_ptr const& peer , tcp::endpoint const& a, char const* message) #ifndef NDEBUG try #endif { mutex_t::scoped_lock l(m_mutex); // too expensive // INVARIANT_CHECK; connection_map::iterator p = m_connections.find(peer); // the connection may have been disconnected in the receive or send phase if (p == m_connections.end()) return; if (m_alerts.should_post(alert::debug)) { m_alerts.post_alert( peer_error_alert( a , (*p)->pid() , message)); } #if defined(TORRENT_VERBOSE_LOGGING) (*(*p)->m_logger) << "*** CONNECTION FAILED " << message << "\n"; #endif (*p)->set_failed(); (*p)->disconnect(); } #ifndef NDEBUG catch (...) { TORRENT_ASSERT(false); }; #endif void session_impl::close_connection(boost::intrusive_ptr const& p) { mutex_t::scoped_lock l(m_mutex); // too expensive // INVARIANT_CHECK; #if defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " CLOSING CONNECTION " << p->remote() << "\n"; #endif TORRENT_ASSERT(p->is_disconnecting()); connection_map::iterator i = m_connections.find(p); if (i != m_connections.end()) { if (!(*i)->is_choked()) --m_num_unchoked; m_connections.erase(i); } } void session_impl::set_peer_id(peer_id const& id) { mutex_t::scoped_lock l(m_mutex); m_peer_id = id; } void session_impl::set_key(int key) { mutex_t::scoped_lock l(m_mutex); m_key = key; } void session_impl::second_tick(asio::error_code const& e) try { session_impl::mutex_t::scoped_lock l(m_mutex); // too expensive // INVARIANT_CHECK; if (m_abort) return; if (e) { #if defined(TORRENT_LOGGING) (*m_logger) << "*** SECOND TIMER FAILED " << e.message() << "\n"; #endif abort(); return; } float tick_interval = total_microseconds(time_now() - m_last_tick) / 1000000.f; m_last_tick = time_now(); m_timer.expires_from_now(seconds(1)); m_timer.async_wait(m_strand.wrap( bind(&session_impl::second_tick, this, _1))); #ifdef TORRENT_STATS ++m_second_counter; int downloading_torrents = 0; int seeding_torrents = 0; for (torrent_map::iterator i = m_torrents.begin() , end(m_torrents.end()); i != end; ++i) { if (i->second->is_seed()) ++seeding_torrents; else ++downloading_torrents; } int num_complete_connections = 0; int num_half_open = 0; for (connection_map::iterator i = m_connections.begin() , end(m_connections.end()); i != end; ++i) { if ((*i)->is_connecting()) ++num_half_open; else ++num_complete_connections; } m_stats_logger << m_second_counter << "\t" << m_stat.upload_rate() << "\t" << m_stat.download_rate() << "\t" << downloading_torrents << "\t" << seeding_torrents << "\t" << num_complete_connections << "\t" << num_half_open << "\t" << m_disk_thread.disk_allocations() << "\t" << std::endl; #endif // let torrents connect to peers if they want to // if there are any torrents and any free slots // this loop will "hand out" max(connection_speed // , half_open.free_slots()) to the torrents, in a // round robin fashion, so that every torrent is // equallt likely to connect to a peer if (!m_torrents.empty() && m_half_open.free_slots() && num_connections() < m_max_connections) { // this is the maximum number of connections we will // attempt this tick int max_connections = m_settings.connection_speed; torrent_map::iterator i = m_torrents.begin(); if (m_next_connect_torrent < int(m_torrents.size())) std::advance(i, m_next_connect_torrent); else m_next_connect_torrent = 0; int steps_since_last_connect = 0; int num_torrents = int(m_torrents.size()); for (;;) { torrent& t = *i->second; if (t.want_more_peers()) { if (t.try_connect_peer()) { --max_connections; steps_since_last_connect = 0; } } ++m_next_connect_torrent; ++steps_since_last_connect; ++i; if (i == m_torrents.end()) { TORRENT_ASSERT(m_next_connect_torrent == num_torrents); i = m_torrents.begin(); m_next_connect_torrent = 0; } // if we have gone one whole loop without // handing out a single connection, break if (steps_since_last_connect > num_torrents) break; // if there are no more free connection slots, abort if (m_half_open.free_slots() == 0) break; // if we should not make any more connections // attempts this tick, abort if (max_connections == 0) break; // maintain the global limit on number of connections if (num_connections() >= m_max_connections) break; } } // do the second_tick() on each connection // this will update their statistics (download and upload speeds) // also purge sockets that have timed out // and keep sockets open by keeping them alive. for (connection_map::iterator i = m_connections.begin(); i != m_connections.end();) { // we need to do like this because j->second->disconnect() will // erase the connection from the map we're iterating connection_map::iterator j = i; ++i; // if this socket has timed out // close it. peer_connection& c = *j->get(); if (c.has_timed_out()) { if (m_alerts.should_post(alert::debug)) { m_alerts.post_alert( peer_error_alert( c.remote() , c.pid() , "connection timed out")); } #if defined(TORRENT_VERBOSE_LOGGING) (*c.m_logger) << "*** CONNECTION TIMED OUT\n"; #endif c.set_failed(); c.disconnect(); continue; } c.keep_alive(); } // check each torrent for tracker updates // TODO: do this in a timer-event in each torrent instead for (torrent_map::iterator i = m_torrents.begin(); i != m_torrents.end();) { torrent& t = *i->second; TORRENT_ASSERT(!t.is_aborted()); if (t.should_request()) { tracker_request req = t.generate_tracker_request(); req.listen_port = 0; if (!m_listen_sockets.empty()) req.listen_port = m_listen_sockets.front().external_port; req.key = m_key; m_tracker_manager.queue_request(m_strand, m_half_open, req , t.tracker_login(), m_listen_interface.address(), i->second); if (m_alerts.should_post(alert::info)) { m_alerts.post_alert( tracker_announce_alert( t.get_handle(), "tracker announce")); } } // second_tick() will set the used upload quota t.second_tick(m_stat, tick_interval); ++i; } m_stat.second_tick(tick_interval); // -------------------------------------------------------------- // unchoke set and optimistic unchoke calculations // -------------------------------------------------------------- m_unchoke_time_scaler--; if (m_unchoke_time_scaler <= 0 && !m_connections.empty()) { m_unchoke_time_scaler = settings().unchoke_interval; std::vector peers; for (connection_map::iterator i = m_connections.begin() , end(m_connections.end()); i != end; ++i) { peer_connection* p = i->get(); torrent* t = p->associated_torrent().lock().get(); if (!p->peer_info_struct() || t == 0 || !p->is_peer_interested() || p->is_disconnecting() || p->is_connecting() || (p->share_diff() < -free_upload_amount && !t->is_seed())) { if (!(*i)->is_choked() && t) { policy::peer* pi = p->peer_info_struct(); if (pi && pi->optimistically_unchoked) { pi->optimistically_unchoked = false; // force a new optimistic unchoke m_optimistic_unchoke_time_scaler = 0; } t->choke_peer(*(*i)); } continue; } peers.push_back(i->get()); } // sort the peers that are eligible for unchoke by download rate and secondary // by total upload. The reason for this is, if all torrents are being seeded, // the download rate will be 0, and the peers we have sent the least to should // be unchoked std::sort(peers.begin(), peers.end() , bind(&stat::total_payload_upload, bind(&peer_connection::statistics, _1)) < bind(&stat::total_payload_upload, bind(&peer_connection::statistics, _2))); std::stable_sort(peers.begin(), peers.end() , bind(&stat::download_payload_rate, bind(&peer_connection::statistics, _1)) > bind(&stat::download_payload_rate, bind(&peer_connection::statistics, _2))); // reserve one upload slot for optimistic unchokes int unchoke_set_size = m_max_uploads - 1; m_num_unchoked = 0; // go through all the peers and unchoke the first ones and choke // all the other ones. for (std::vector::iterator i = peers.begin() , end(peers.end()); i != end; ++i) { peer_connection* p = *i; TORRENT_ASSERT(p); torrent* t = p->associated_torrent().lock().get(); TORRENT_ASSERT(t); if (unchoke_set_size > 0) { if (p->is_choked()) { if (!t->unchoke_peer(*p)) continue; } --unchoke_set_size; ++m_num_unchoked; TORRENT_ASSERT(p->peer_info_struct()); if (p->peer_info_struct()->optimistically_unchoked) { // force a new optimistic unchoke m_optimistic_unchoke_time_scaler = 0; p->peer_info_struct()->optimistically_unchoked = false; } } else { TORRENT_ASSERT(p->peer_info_struct()); if (!p->is_choked() && !p->peer_info_struct()->optimistically_unchoked) t->choke_peer(*p); if (!p->is_choked()) ++m_num_unchoked; } } m_optimistic_unchoke_time_scaler--; if (m_optimistic_unchoke_time_scaler <= 0) { m_optimistic_unchoke_time_scaler = settings().optimistic_unchoke_multiplier; // find the peer that has been waiting the longest to be optimistically // unchoked connection_map::iterator current_optimistic_unchoke = m_connections.end(); connection_map::iterator optimistic_unchoke_candidate = m_connections.end(); ptime last_unchoke = max_time(); for (connection_map::iterator i = m_connections.begin() , end(m_connections.end()); i != end; ++i) { peer_connection* p = i->get(); TORRENT_ASSERT(p); policy::peer* pi = p->peer_info_struct(); if (!pi) continue; torrent* t = p->associated_torrent().lock().get(); if (!t) continue; if (pi->optimistically_unchoked) { TORRENT_ASSERT(!p->is_choked()); TORRENT_ASSERT(current_optimistic_unchoke == m_connections.end()); current_optimistic_unchoke = i; } if (pi->last_optimistically_unchoked < last_unchoke && !p->is_connecting() && !p->is_disconnecting() && p->is_peer_interested() && t->free_upload_slots() && p->is_choked()) { last_unchoke = pi->last_optimistically_unchoked; optimistic_unchoke_candidate = i; } } if (optimistic_unchoke_candidate != m_connections.end() && optimistic_unchoke_candidate != current_optimistic_unchoke) { if (current_optimistic_unchoke != m_connections.end()) { torrent* t = (*current_optimistic_unchoke)->associated_torrent().lock().get(); TORRENT_ASSERT(t); (*current_optimistic_unchoke)->peer_info_struct()->optimistically_unchoked = false; t->choke_peer(*current_optimistic_unchoke->get()); } else { ++m_num_unchoked; } torrent* t = (*optimistic_unchoke_candidate)->associated_torrent().lock().get(); TORRENT_ASSERT(t); bool ret = t->unchoke_peer(*optimistic_unchoke_candidate->get()); TORRENT_ASSERT(ret); (*optimistic_unchoke_candidate)->peer_info_struct()->optimistically_unchoked = true; } } } // -------------------------------------------------------------- // disconnect peers when we have too many // -------------------------------------------------------------- --m_disconnect_time_scaler; if (m_disconnect_time_scaler <= 0) { m_disconnect_time_scaler = 60; // every 60 seconds, disconnect the worst peer // if we have reached the connection limit if (num_connections() >= max_connections() && !m_torrents.empty()) { torrent_map::iterator i = std::max_element(m_torrents.begin(), m_torrents.end() , bind(&torrent::num_peers, bind(&torrent_map::value_type::second, _1)) < bind(&torrent::num_peers, bind(&torrent_map::value_type::second, _2))); TORRENT_ASSERT(i != m_torrents.end()); i->second->get_policy().disconnect_one_peer(); } } } catch (std::exception& exc) { #ifndef NDEBUG std::cerr << exc.what() << std::endl; TORRENT_ASSERT(false); #endif }; // msvc 7.1 seems to require this void session_impl::operator()() { eh_initializer(); { session_impl::mutex_t::scoped_lock l(m_mutex); if (m_listen_interface.port() != 0) open_listen_port(); } ptime timer = time_now(); do { try { m_io_service.run(); TORRENT_ASSERT(m_abort == true); } catch (std::exception& e) { #ifndef NDEBUG std::cerr << e.what() << "\n"; std::string err = e.what(); #endif TORRENT_ASSERT(false); } } while (!m_abort); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " locking mutex\n"; #endif session_impl::mutex_t::scoped_lock l(m_mutex); #ifndef NDEBUG for (torrent_map::iterator i = m_torrents.begin(); i != m_torrents.end(); ++i) { TORRENT_ASSERT(i->second->num_peers() == 0); } #endif #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " cleaning up torrents\n"; #endif m_torrents.clear(); TORRENT_ASSERT(m_torrents.empty()); TORRENT_ASSERT(m_connections.empty()); } // the return value from this function is valid only as long as the // session is locked! boost::weak_ptr session_impl::find_torrent(sha1_hash const& info_hash) { std::map >::iterator i = m_torrents.find(info_hash); #ifndef NDEBUG for (std::map >::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(); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) boost::shared_ptr session_impl::create_log(std::string const& name , int instance, bool append) { // current options are file_logger, cout_logger and null_logger return boost::shared_ptr(new logger(m_logpath, name + ".log", instance, append)); } #endif std::vector session_impl::get_torrents() { mutex_t::scoped_lock l(m_mutex); mutex::scoped_lock l2(m_checker_impl.m_mutex); std::vector ret; for (std::deque >::iterator i = m_checker_impl.m_torrents.begin() , end(m_checker_impl.m_torrents.end()); i != end; ++i) { if ((*i)->abort) continue; ret.push_back(torrent_handle(this, &m_checker_impl , (*i)->info_hash)); } for (std::deque >::iterator i = m_checker_impl.m_processing.begin() , end(m_checker_impl.m_processing.end()); i != end; ++i) { if ((*i)->abort) continue; ret.push_back(torrent_handle(this, &m_checker_impl , (*i)->info_hash)); } for (session_impl::torrent_map::iterator i = m_torrents.begin(), end(m_torrents.end()); i != end; ++i) { if (i->second->is_aborted()) continue; ret.push_back(torrent_handle(this, &m_checker_impl , i->first)); } return ret; } torrent_handle session_impl::find_torrent_handle(sha1_hash const& info_hash) { return torrent_handle(this, &m_checker_impl, info_hash); } torrent_handle session_impl::add_torrent( boost::intrusive_ptr ti , fs::path const& save_path , entry const& resume_data , storage_mode_t storage_mode , storage_constructor_type sc , bool paused , void* userdata) { TORRENT_ASSERT(!save_path.empty()); if (ti->begin_files() == ti->end_files()) throw std::runtime_error("no files in torrent"); // lock the session and the checker thread (the order is important!) mutex_t::scoped_lock l(m_mutex); mutex::scoped_lock l2(m_checker_impl.m_mutex); // INVARIANT_CHECK; if (is_aborted()) throw std::runtime_error("session is closing"); // is the torrent already active? if (!find_torrent(ti->info_hash()).expired()) throw duplicate_torrent(); // is the torrent currently being checked? if (m_checker_impl.find_torrent(ti->info_hash())) throw duplicate_torrent(); // create the torrent and the data associated with // the checker thread and store it before starting // the thread boost::shared_ptr torrent_ptr( new torrent(*this, m_checker_impl, ti, save_path , m_listen_interface, storage_mode, 16 * 1024 , sc, paused)); torrent_ptr->start(); #ifndef TORRENT_DISABLE_EXTENSIONS for (extension_list_t::iterator i = m_extensions.begin() , end(m_extensions.end()); i != end; ++i) { boost::shared_ptr tp((*i)(torrent_ptr.get(), userdata)); if (tp) torrent_ptr->add_extension(tp); } #endif boost::shared_ptr d( new aux::piece_checker_data); d->torrent_ptr = torrent_ptr; d->save_path = save_path; d->info_hash = ti->info_hash(); d->resume_data = resume_data; #ifndef TORRENT_DISABLE_DHT if (m_dht) { torrent_info::nodes_t const& nodes = ti->nodes(); std::for_each(nodes.begin(), nodes.end(), bind( (void(dht::dht_tracker::*)(std::pair const&)) &dht::dht_tracker::add_node , boost::ref(m_dht), _1)); } #endif // add the torrent to the queue to be checked m_checker_impl.m_torrents.push_back(d); // and notify the thread that it got another // job in its queue m_checker_impl.m_cond.notify_one(); return torrent_handle(this, &m_checker_impl, ti->info_hash()); } torrent_handle session_impl::add_torrent( char const* tracker_url , sha1_hash const& info_hash , char const* name , fs::path const& save_path , entry const& , storage_mode_t storage_mode , storage_constructor_type sc , bool paused , void* userdata) { // TODO: support resume data in this case TORRENT_ASSERT(!save_path.empty()); { // lock the checker_thread mutex::scoped_lock l(m_checker_impl.m_mutex); // is the torrent currently being checked? if (m_checker_impl.find_torrent(info_hash)) throw duplicate_torrent(); } // lock the session session_impl::mutex_t::scoped_lock l(m_mutex); // INVARIANT_CHECK; // is the torrent already active? if (!find_torrent(info_hash).expired()) throw duplicate_torrent(); // you cannot add new torrents to a session that is closing down TORRENT_ASSERT(!is_aborted()); // create the torrent and the data associated with // the checker thread and store it before starting // the thread boost::shared_ptr torrent_ptr( new torrent(*this, m_checker_impl, tracker_url, info_hash, name , save_path, m_listen_interface, storage_mode, 16 * 1024 , sc, paused)); torrent_ptr->start(); #ifndef TORRENT_DISABLE_EXTENSIONS for (extension_list_t::iterator i = m_extensions.begin() , end(m_extensions.end()); i != end; ++i) { boost::shared_ptr tp((*i)(torrent_ptr.get(), userdata)); if (tp) torrent_ptr->add_extension(tp); } #endif m_torrents.insert( std::make_pair(info_hash, torrent_ptr)).first; return torrent_handle(this, &m_checker_impl, info_hash); } void session_impl::remove_torrent(const torrent_handle& h, int options) { if (h.m_ses != this) return; TORRENT_ASSERT(h.m_chk == &m_checker_impl || h.m_chk == 0); TORRENT_ASSERT(h.m_ses != 0); mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; session_impl::torrent_map::iterator i = m_torrents.find(h.m_info_hash); if (i != m_torrents.end()) { torrent& t = *i->second; if (options & session::delete_files) t.delete_files(); t.abort(); if ((!t.is_paused() || t.should_request()) && !t.trackers().empty()) { tracker_request req = t.generate_tracker_request(); TORRENT_ASSERT(req.event == tracker_request::stopped); TORRENT_ASSERT(!m_listen_sockets.empty()); req.listen_port = 0; if (!m_listen_sockets.empty()) req.listen_port = m_listen_sockets.front().external_port; req.key = m_key; #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) boost::shared_ptr tl(new tracker_logger(*this)); m_tracker_loggers.push_back(tl); m_tracker_manager.queue_request(m_strand, m_half_open, req , t.tracker_login(), m_listen_interface.address(), tl); #else m_tracker_manager.queue_request(m_strand, m_half_open, req , t.tracker_login(), m_listen_interface.address()); #endif if (m_alerts.should_post(alert::info)) { m_alerts.post_alert( tracker_announce_alert( t.get_handle(), "tracker announce, event=stopped")); } } #ifndef NDEBUG sha1_hash i_hash = t.torrent_file().info_hash(); #endif m_torrents.erase(i); TORRENT_ASSERT(m_torrents.find(i_hash) == m_torrents.end()); return; } if (h.m_chk) { mutex::scoped_lock l(m_checker_impl.m_mutex); aux::piece_checker_data* d = m_checker_impl.find_torrent(h.m_info_hash); if (d != 0) { if (d->processing) d->abort = true; else m_checker_impl.remove_torrent(h.m_info_hash, options); return; } } } bool session_impl::listen_on( std::pair const& port_range , const char* net_interface) { session_impl::mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; tcp::endpoint new_interface; if (net_interface && std::strlen(net_interface) > 0) new_interface = tcp::endpoint(address::from_string(net_interface), port_range.first); else new_interface = tcp::endpoint(address_v4::any(), port_range.first); m_listen_port_retries = port_range.second - port_range.first; // if the interface is the same and the socket is open // don't do anything if (new_interface == m_listen_interface && !m_listen_sockets.empty()) return true; m_listen_interface = new_interface; open_listen_port(); bool new_listen_address = m_listen_interface.address() != new_interface.address(); #ifndef TORRENT_DISABLE_DHT if ((new_listen_address || m_dht_same_port) && m_dht) { if (m_dht_same_port) m_dht_settings.service_port = new_interface.port(); // the listen interface changed, rebind the dht listen socket as well m_dht_socket.bind(m_dht_settings.service_port); if (m_natpmp.get()) m_natpmp->set_mappings(0, m_dht_settings.service_port); if (m_upnp.get()) m_upnp->set_mappings(0, m_dht_settings.service_port); } #endif #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) m_logger = create_log("main_session", listen_port(), false); (*m_logger) << time_now_string() << "\n"; #endif return !m_listen_sockets.empty(); } unsigned short session_impl::listen_port() const { mutex_t::scoped_lock l(m_mutex); if (m_listen_sockets.empty()) return 0; return m_listen_sockets.front().external_port;; } void session_impl::announce_lsd(sha1_hash const& ih) { mutex_t::scoped_lock l(m_mutex); // use internal listen port for local peers if (m_lsd.get()) m_lsd->announce(ih, m_listen_interface.port()); } void session_impl::on_lsd_peer(tcp::endpoint peer, sha1_hash const& ih) { mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; boost::shared_ptr t = find_torrent(ih).lock(); if (!t) return; // don't add peers from lsd to private torrents if (t->torrent_file().priv()) return; #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << ": added peer from local discovery: " << peer << "\n"; #endif t->get_policy().peer_from_tracker(peer, peer_id(0), peer_info::lsd, 0); } void session_impl::on_port_mapping(int tcp_port, int udp_port , std::string const& errmsg) { #ifndef TORRENT_DISABLE_DHT if (udp_port != 0) { m_external_udp_port = udp_port; m_dht_settings.service_port = udp_port; if (m_alerts.should_post(alert::info)) { std::stringstream msg; msg << "successfully mapped UDP port " << udp_port; m_alerts.post_alert(portmap_alert(msg.str())); } } #endif if (tcp_port != 0) { if (!m_listen_sockets.empty()) m_listen_sockets.front().external_port = tcp_port; if (m_alerts.should_post(alert::info)) { std::stringstream msg; msg << "successfully mapped TCP port " << tcp_port; m_alerts.post_alert(portmap_alert(msg.str())); } } if (!errmsg.empty()) { if (m_alerts.should_post(alert::warning)) { std::stringstream msg; msg << "Error while mapping ports on NAT router: " << errmsg; m_alerts.post_alert(portmap_error_alert(msg.str())); } } } session_status session_impl::status() const { mutex_t::scoped_lock l(m_mutex); // INVARIANT_CHECK; session_status s; s.has_incoming_connections = m_incoming_connection; s.num_peers = (int)m_connections.size(); s.download_rate = m_stat.download_rate(); s.upload_rate = m_stat.upload_rate(); s.payload_download_rate = m_stat.download_payload_rate(); s.payload_upload_rate = m_stat.upload_payload_rate(); s.total_download = m_stat.total_protocol_download() + m_stat.total_payload_download(); s.total_upload = m_stat.total_protocol_upload() + m_stat.total_payload_upload(); s.total_payload_download = m_stat.total_payload_download(); s.total_payload_upload = m_stat.total_payload_upload(); #ifndef TORRENT_DISABLE_DHT if (m_dht) { m_dht->dht_status(s); } else { s.dht_nodes = 0; s.dht_node_cache = 0; s.dht_torrents = 0; s.dht_global_nodes = 0; } #endif return s; } #ifndef TORRENT_DISABLE_DHT void session_impl::start_dht(entry const& startup_state) { mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; if (m_dht) { m_dht->stop(); m_dht = 0; } if (m_dht_settings.service_port == 0 || m_dht_same_port) { m_dht_same_port = true; // if you hit this assert you are trying to start the // DHT with the same port as the tcp listen port // (which is default) _before_ you have opened the // tcp listen port (so there is no configured port to use) // basically, make sure you call listen_on() before // start_dht(). See documentation for listen_on() for // more information. TORRENT_ASSERT(m_listen_interface.port() > 0); m_dht_settings.service_port = m_listen_interface.port(); } m_external_udp_port = m_dht_settings.service_port; if (m_natpmp.get()) m_natpmp->set_mappings(0, m_dht_settings.service_port); if (m_upnp.get()) m_upnp->set_mappings(0, m_dht_settings.service_port); m_dht = new dht::dht_tracker(m_dht_socket, m_dht_settings, startup_state); if (!m_dht_socket.is_open() || m_dht_socket.local_port() != m_dht_settings.service_port) { m_dht_socket.bind(m_dht_settings.service_port); } } void session_impl::stop_dht() { mutex_t::scoped_lock l(m_mutex); if (!m_dht) return; m_dht->stop(); m_dht = 0; } void session_impl::set_dht_settings(dht_settings const& settings) { mutex_t::scoped_lock l(m_mutex); // only change the dht listen port in case the settings // contains a vaiid port, and if it is different from // the current setting if (settings.service_port != 0) m_dht_same_port = false; else m_dht_same_port = true; if (!m_dht_same_port && settings.service_port != m_dht_settings.service_port && m_dht) { m_dht_socket.bind(settings.service_port); if (m_natpmp.get()) m_natpmp->set_mappings(0, m_dht_settings.service_port); if (m_upnp.get()) m_upnp->set_mappings(0, m_dht_settings.service_port); m_external_udp_port = settings.service_port; } m_dht_settings = settings; if (m_dht_same_port) m_dht_settings.service_port = m_listen_interface.port(); } entry session_impl::dht_state() const { mutex_t::scoped_lock l(m_mutex); if (!m_dht) return entry(); return m_dht->state(); } void session_impl::add_dht_node(std::pair const& node) { TORRENT_ASSERT(m_dht); mutex_t::scoped_lock l(m_mutex); m_dht->add_node(node); } void session_impl::add_dht_router(std::pair const& node) { TORRENT_ASSERT(m_dht); mutex_t::scoped_lock l(m_mutex); m_dht->add_router_node(node); } #endif #ifndef TORRENT_DISABLE_ENCRYPTION void session_impl::set_pe_settings(pe_settings const& settings) { mutex_t::scoped_lock l(m_mutex); m_pe_settings = settings; } #endif bool session_impl::is_listening() const { mutex_t::scoped_lock l(m_mutex); return !m_listen_sockets.empty(); } session_impl::~session_impl() { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << "\n\n *** shutting down session *** \n\n"; #endif abort(); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " waiting for main thread\n"; #endif m_thread->join(); TORRENT_ASSERT(m_torrents.empty()); // it's important that the main thread is closed completely before // the checker thread is terminated. Because all the connections // have to be closed and removed from the torrents before they // can be destructed. (because the weak pointers in the // peer_connections will be invalidated when the torrents are // destructed and then the invariant will be broken). { mutex::scoped_lock l(m_checker_impl.m_mutex); // abort the checker thread m_checker_impl.m_abort = true; // abort the currently checking torrent if (!m_checker_impl.m_torrents.empty()) { m_checker_impl.m_torrents.front()->abort = true; } m_checker_impl.m_cond.notify_one(); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " waiting for checker thread\n"; #endif m_checker_thread->join(); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " waiting for disk io thread\n"; #endif m_disk_thread.join(); TORRENT_ASSERT(m_torrents.empty()); TORRENT_ASSERT(m_connections.empty()); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) (*m_logger) << time_now_string() << " shutdown complete!\n"; #endif } void session_impl::set_max_uploads(int limit) { TORRENT_ASSERT(limit > 0 || limit == -1); mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; if (limit <= 0) limit = (std::numeric_limits::max)(); m_max_uploads = limit; } void session_impl::set_max_connections(int limit) { TORRENT_ASSERT(limit > 0 || limit == -1); mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; if (limit <= 0) limit = (std::numeric_limits::max)(); m_max_connections = limit; } void session_impl::set_max_half_open_connections(int limit) { TORRENT_ASSERT(limit > 0 || limit == -1); mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; if (limit <= 0) limit = (std::numeric_limits::max)(); m_half_open.limit(limit); } void session_impl::set_download_rate_limit(int bytes_per_second) { TORRENT_ASSERT(bytes_per_second > 0 || bytes_per_second == -1); mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; if (bytes_per_second <= 0) bytes_per_second = bandwidth_limit::inf; m_bandwidth_manager[peer_connection::download_channel]->throttle(bytes_per_second); } void session_impl::set_upload_rate_limit(int bytes_per_second) { TORRENT_ASSERT(bytes_per_second > 0 || bytes_per_second == -1); mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; if (bytes_per_second <= 0) bytes_per_second = bandwidth_limit::inf; m_bandwidth_manager[peer_connection::upload_channel]->throttle(bytes_per_second); } std::auto_ptr session_impl::pop_alert() { mutex_t::scoped_lock l(m_mutex); // too expensive // INVARIANT_CHECK; if (m_alerts.pending()) return m_alerts.get(); return std::auto_ptr(0); } alert const* session_impl::wait_for_alert(time_duration max_wait) { return m_alerts.wait_for_alert(max_wait); } void session_impl::set_severity_level(alert::severity_t s) { mutex_t::scoped_lock l(m_mutex); m_alerts.set_severity(s); } int session_impl::upload_rate_limit() const { mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; int ret = m_bandwidth_manager[peer_connection::upload_channel]->throttle(); return ret == (std::numeric_limits::max)() ? -1 : ret; } int session_impl::download_rate_limit() const { mutex_t::scoped_lock l(m_mutex); int ret = m_bandwidth_manager[peer_connection::download_channel]->throttle(); return ret == (std::numeric_limits::max)() ? -1 : ret; } void session_impl::start_lsd() { mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; if (m_lsd) return; m_lsd = new lsd(m_io_service , m_listen_interface.address() , bind(&session_impl::on_lsd_peer, this, _1, _2)); } void session_impl::start_natpmp() { mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; if (m_natpmp) return; m_natpmp = new natpmp(m_io_service , m_listen_interface.address() , bind(&session_impl::on_port_mapping , this, _1, _2, _3)); m_natpmp->set_mappings(m_listen_interface.port(), #ifndef TORRENT_DISABLE_DHT m_dht ? m_dht_settings.service_port : #endif 0); } void session_impl::start_upnp() { mutex_t::scoped_lock l(m_mutex); INVARIANT_CHECK; if (m_upnp) return; m_upnp = new upnp(m_io_service, m_half_open , m_listen_interface.address() , m_settings.user_agent , bind(&session_impl::on_port_mapping , this, _1, _2, _3)); m_upnp->discover_device(); m_upnp->set_mappings(m_listen_interface.port(), #ifndef TORRENT_DISABLE_DHT m_dht ? m_dht_settings.service_port : #endif 0); } void session_impl::stop_lsd() { mutex_t::scoped_lock l(m_mutex); if (m_lsd.get()) m_lsd->close(); m_lsd = 0; } void session_impl::stop_natpmp() { mutex_t::scoped_lock l(m_mutex); if (m_natpmp.get()) m_natpmp->close(); m_natpmp = 0; } void session_impl::stop_upnp() { mutex_t::scoped_lock l(m_mutex); if (m_upnp.get()) m_upnp->close(); m_upnp = 0; } void session_impl::free_disk_buffer(char* buf) { m_disk_thread.free_buffer(buf); } std::pair session_impl::allocate_buffer(int size) { int num_buffers = (size + send_buffer_size - 1) / send_buffer_size; #ifdef TORRENT_STATS m_buffer_allocations += num_buffers; m_buffer_usage_logger << log_time() << " protocol_buffer: " << (m_buffer_allocations * send_buffer_size) << std::endl; #endif return std::make_pair((char*)m_send_buffers.ordered_malloc(num_buffers) , num_buffers * send_buffer_size); } void session_impl::free_buffer(char* buf, int size) { TORRENT_ASSERT(size % send_buffer_size == 0); int num_buffers = size / send_buffer_size; #ifdef TORRENT_STATS m_buffer_allocations -= num_buffers; TORRENT_ASSERT(m_buffer_allocations >= 0); m_buffer_usage_logger << log_time() << " protocol_buffer: " << (m_buffer_allocations * send_buffer_size) << std::endl; #endif m_send_buffers.ordered_free(buf, num_buffers); } #ifndef NDEBUG void session_impl::check_invariant() const { TORRENT_ASSERT(m_max_connections > 0); TORRENT_ASSERT(m_max_uploads > 0); int unchokes = 0; int num_optimistic = 0; for (connection_map::const_iterator i = m_connections.begin(); i != m_connections.end(); ++i) { TORRENT_ASSERT(*i); boost::shared_ptr t = (*i)->associated_torrent().lock(); peer_connection* p = i->get(); if (!p->is_choked()) ++unchokes; if (p->peer_info_struct() && p->peer_info_struct()->optimistically_unchoked) { ++num_optimistic; TORRENT_ASSERT(!p->is_choked()); } if (t && p->peer_info_struct()) { TORRENT_ASSERT(t->get_policy().has_connection(p)); } } TORRENT_ASSERT(num_optimistic == 0 || num_optimistic == 1); if (m_num_unchoked != unchokes) { TORRENT_ASSERT(false); } for (std::map >::const_iterator j = m_torrents.begin(); j != m_torrents.end(); ++j) { TORRENT_ASSERT(boost::get_pointer(j->second)); } } #endif void piece_checker_data::parse_resume_data( const entry& resume_data , const torrent_info& info , std::string& error) { // if we don't have any resume data, return if (resume_data.type() == entry::undefined_t) return; entry rd = resume_data; try { if (rd["file-format"].string() != "libtorrent resume file") { error = "missing file format tag"; return; } if (rd["file-version"].integer() > 1) { error = "incompatible file version " + boost::lexical_cast(rd["file-version"].integer()); return; } // verify info_hash sha1_hash hash = rd["info-hash"].string(); if (hash != info.info_hash()) { error = "mismatching info-hash: " + boost::lexical_cast(hash); return; } // the peers if (entry* peers_entry = rd.find_key("peers")) { entry::list_type& peer_list = peers_entry->list(); std::vector tmp_peers; tmp_peers.reserve(peer_list.size()); for (entry::list_type::iterator i = peer_list.begin(); i != peer_list.end(); ++i) { tcp::endpoint a( address::from_string((*i)["ip"].string()) , (unsigned short)(*i)["port"].integer()); tmp_peers.push_back(a); } peers.swap(tmp_peers); } if (entry* banned_peers_entry = rd.find_key("banned_peers")) { entry::list_type& peer_list = banned_peers_entry->list(); std::vector tmp_peers; tmp_peers.reserve(peer_list.size()); for (entry::list_type::iterator i = peer_list.begin(); i != peer_list.end(); ++i) { tcp::endpoint a( address::from_string((*i)["ip"].string()) , (unsigned short)(*i)["port"].integer()); tmp_peers.push_back(a); } banned_peers.swap(tmp_peers); } // read piece map const entry::list_type& slots = rd["slots"].list(); if ((int)slots.size() > info.num_pieces()) { error = "file has more slots than torrent (slots: " + boost::lexical_cast(slots.size()) + " size: " + boost::lexical_cast(info.num_pieces()) + " )"; return; } std::vector tmp_pieces; tmp_pieces.reserve(slots.size()); for (entry::list_type::const_iterator i = slots.begin(); i != slots.end(); ++i) { int index = (int)i->integer(); if (index >= info.num_pieces() || index < -2) { error = "too high index number in slot map (index: " + boost::lexical_cast(index) + " size: " + boost::lexical_cast(info.num_pieces()) + ")"; return; } tmp_pieces.push_back(index); } // only bother to check the partial pieces if we have the same block size // as in the fast resume data. If the blocksize has changed, then throw // away all partial pieces. std::vector tmp_unfinished; int num_blocks_per_piece = (int)rd["blocks per piece"].integer(); if (num_blocks_per_piece == info.piece_length() / torrent_ptr->block_size()) { // the unfinished pieces entry::list_type& unfinished = rd["unfinished"].list(); int unfinished_size = int(unfinished.size()); block_info.resize(num_blocks_per_piece * unfinished_size); tmp_unfinished.reserve(unfinished_size); int index = 0; for (entry::list_type::iterator i = unfinished.begin(); i != unfinished.end(); ++i, ++index) { piece_picker::downloading_piece p; p.info = &block_info[index * num_blocks_per_piece]; p.index = (int)(*i)["piece"].integer(); if (p.index < 0 || p.index >= info.num_pieces()) { error = "invalid piece index in unfinished piece list (index: " + boost::lexical_cast(p.index) + " size: " + boost::lexical_cast(info.num_pieces()) + ")"; return; } const std::string& bitmask = (*i)["bitmask"].string(); const int num_bitmask_bytes = (std::max)(num_blocks_per_piece / 8, 1); if ((int)bitmask.size() != num_bitmask_bytes) { error = "invalid size of bitmask (" + boost::lexical_cast(bitmask.size()) + ")"; return; } for (int j = 0; j < num_bitmask_bytes; ++j) { unsigned char bits = bitmask[j]; int num_bits = (std::min)(num_blocks_per_piece - j*8, 8); for (int k = 0; k < num_bits; ++k) { const int bit = j * 8 + k; if (bits & (1 << k)) { p.info[bit].state = piece_picker::block_info::state_finished; ++p.finished; } } } if (p.finished == 0) continue; std::vector::iterator slot_iter = std::find(tmp_pieces.begin(), tmp_pieces.end(), p.index); if (slot_iter == tmp_pieces.end()) { // this piece is marked as unfinished // but doesn't have any storage error = "piece " + boost::lexical_cast(p.index) + " is " "marked as unfinished, but doesn't have any storage"; return; } TORRENT_ASSERT(*slot_iter == p.index); int slot_index = static_cast(slot_iter - tmp_pieces.begin()); unsigned long adler = torrent_ptr->filesystem().piece_crc( slot_index , torrent_ptr->block_size() , p.info); const entry& ad = (*i)["adler32"]; // crc's didn't match, don't use the resume data if (ad.integer() != entry::integer_type(adler)) { error = "checksum mismatch on piece " + boost::lexical_cast(p.index); return; } tmp_unfinished.push_back(p); } } if (!torrent_ptr->verify_resume_data(rd, error)) return; piece_map.swap(tmp_pieces); unfinished_pieces.swap(tmp_unfinished); } catch (invalid_encoding&) { return; } catch (type_error&) { return; } catch (file_error&) { return; } } }}