/* Copyright (c) 2006-2012, 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 "../../src/util.h" #include #include #include #include #include #ifdef _MSC_VER #pragma warning(push, 1) #endif #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" #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/settings.hpp" #include "libtorrent/build_config.hpp" #include "libtorrent/extensions.hpp" #include "libtorrent/random.hpp" #include "libtorrent/magnet_uri.hpp" #if defined TORRENT_STATS && defined __MACH__ #include #endif #ifndef TORRENT_WINDOWS #include #endif #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING // for logging stat layout #include "libtorrent/stat.hpp" #include "libtorrent/struct_debug.hpp" // for logging the size of DHT structures #ifndef TORRENT_DISABLE_DHT #include #include #include #include #endif // TORRENT_DISABLE_DHT #include "libtorrent/http_tracker_connection.hpp" #include "libtorrent/udp_tracker_connection.hpp" #include "libtorrent/debug.hpp" #if TORRENT_USE_IOSTREAM namespace libtorrent { std::ofstream logger::log_file; std::string logger::open_filename; mutex logger::file_mutex; } #endif // TORRENT_USE_IOSTREAM #endif #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 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 #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 _async_ops; int _async_ops_nthreads = 0; mutex _async_ops_mutex; #endif 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 { #ifdef TORRENT_STATS void get_vm_stats(vm_statistics_data_t* vm_stat) { memset(vm_stat, 0, sizeof(*vm_stat)); #if defined __MACH__ mach_port_t host_port = mach_host_self(); mach_msg_type_number_t host_count = HOST_VM_INFO_COUNT; kern_return_t error = host_statistics(host_port, HOST_VM_INFO, (host_info_t)vm_stat, &host_count); #elif defined TORRENT_LINUX char buffer[4096]; char string[1024]; boost::uint32_t value; FILE* f = fopen("/proc/vmstat", "r"); int ret = 0; while ((ret = fscanf(f, "%s %u\n", string, &value)) != EOF) { if (ret != 2) continue; if (strcmp(string, "nr_active_anon") == 0) vm_stat->active_count += value; else if (strcmp(string, "nr_active_file") == 0) vm_stat->active_count += value; else if (strcmp(string, "nr_inactive_anon") == 0) vm_stat->inactive_count += value; else if (strcmp(string, "nr_inactive_file") == 0) vm_stat->inactive_count += value; else if (strcmp(string, "nr_free_pages") == 0) vm_stat->free_count = value; else if (strcmp(string, "nr_unevictable") == 0) vm_stat->wire_count = value; else if (strcmp(string, "pswpin") == 0) vm_stat->pageins = value; else if (strcmp(string, "pswpout") == 0) vm_stat->pageouts = value; else if (strcmp(string, "pgfault") == 0) vm_stat->faults = value; } fclose(f); #endif // TOOD: windows? } void get_thread_cpu_usage(thread_cpu_usage* tu) { #if defined __MACH__ task_thread_times_info t_info; mach_msg_type_number_t t_info_count = TASK_THREAD_TIMES_INFO_COUNT; task_info(mach_task_self(), TASK_THREAD_TIMES_INFO, (task_info_t)&t_info, &t_info_count); tu->user_time = min_time() + seconds(t_info.user_time.seconds) + microsec(t_info.user_time.microseconds); tu->system_time = min_time() + seconds(t_info.system_time.seconds) + microsec(t_info.system_time.microseconds); #elif defined TORRENT_LINUX struct rusage ru; getrusage(RUSAGE_THREAD, &ru); tu->user_time = min_time() + seconds(ru.ru_utime.tv_sec) + microsec(ru.ru_utime.tv_usec); tu->system_time = min_time() + seconds(ru.ru_stime.tv_sec) + microsec(ru.ru_stime.tv_usec); #elif defined TORRENT_WINDOWS FILETIME system_time; FILETIME user_time; FILETIME creation_time; FILETIME exit_time; GetThreadTimes(GetCurrentThread(), &creation_time, &exit_time, &user_time, &system_time); boost::uint64_t utime = (boost::uint64_t(user_time.dwHighDateTime) << 32) + user_time.dwLowDateTime; boost::uint64_t stime = (boost::uint64_t(system_time.dwHighDateTime) << 32) + system_time.dwLowDateTime; tu->user_time = min_time() + microsec(utime / 10); tu->system_time = min_time() + microsec(stime / 10); #endif } #endif //TORRENT_STATS struct seed_random_generator { seed_random_generator() { random_seed((unsigned int)total_microseconds(time_now_hires() - min_time())); } }; #define TORRENT_SETTING(t, x) {#x, offsetof(session_settings,x), t}, bencode_map_entry session_settings_map[] = { TORRENT_SETTING(std_string, user_agent) TORRENT_SETTING(integer, tracker_completion_timeout) TORRENT_SETTING(integer, tracker_receive_timeout) TORRENT_SETTING(integer, stop_tracker_timeout) TORRENT_SETTING(integer, tracker_maximum_response_length) TORRENT_SETTING(integer, piece_timeout) TORRENT_SETTING(integer, request_timeout) TORRENT_SETTING(integer, request_queue_time) TORRENT_SETTING(integer, max_allowed_in_request_queue) TORRENT_SETTING(integer, max_out_request_queue) TORRENT_SETTING(integer, whole_pieces_threshold) TORRENT_SETTING(integer, peer_timeout) TORRENT_SETTING(integer, urlseed_timeout) TORRENT_SETTING(integer, urlseed_pipeline_size) TORRENT_SETTING(integer, urlseed_wait_retry) TORRENT_SETTING(integer, file_pool_size) TORRENT_SETTING(boolean, allow_multiple_connections_per_ip) TORRENT_SETTING(integer, max_failcount) TORRENT_SETTING(integer, min_reconnect_time) TORRENT_SETTING(integer, peer_connect_timeout) TORRENT_SETTING(boolean, ignore_limits_on_local_network) TORRENT_SETTING(integer, connection_speed) TORRENT_SETTING(boolean, send_redundant_have) TORRENT_SETTING(boolean, lazy_bitfields) TORRENT_SETTING(integer, inactivity_timeout) TORRENT_SETTING(integer, unchoke_interval) TORRENT_SETTING(integer, optimistic_unchoke_interval) TORRENT_SETTING(std_string, announce_ip) TORRENT_SETTING(integer, num_want) TORRENT_SETTING(integer, initial_picker_threshold) TORRENT_SETTING(integer, allowed_fast_set_size) TORRENT_SETTING(integer, suggest_mode) TORRENT_SETTING(integer, max_queued_disk_bytes) TORRENT_SETTING(integer, max_queued_disk_bytes_low_watermark) TORRENT_SETTING(integer, handshake_timeout) #ifndef TORRENT_DISABLE_DHT TORRENT_SETTING(boolean, use_dht_as_fallback) #endif TORRENT_SETTING(boolean, free_torrent_hashes) TORRENT_SETTING(boolean, upnp_ignore_nonrouters) TORRENT_SETTING(integer, send_buffer_low_watermark) TORRENT_SETTING(integer, send_buffer_watermark) #ifndef TORRENT_NO_DEPRECATE TORRENT_SETTING(boolean, auto_upload_slots) TORRENT_SETTING(boolean, auto_upload_slots_rate_based) #endif TORRENT_SETTING(integer, choking_algorithm) TORRENT_SETTING(integer, seed_choking_algorithm) TORRENT_SETTING(boolean, use_parole_mode) TORRENT_SETTING(integer, cache_size) TORRENT_SETTING(integer, cache_buffer_chunk_size) TORRENT_SETTING(integer, cache_expiry) TORRENT_SETTING(boolean, use_read_cache) TORRENT_SETTING(boolean, explicit_read_cache) TORRENT_SETTING(integer, disk_io_write_mode) TORRENT_SETTING(integer, disk_io_read_mode) TORRENT_SETTING(boolean, coalesce_reads) TORRENT_SETTING(boolean, coalesce_writes) TORRENT_SETTING(character, peer_tos) TORRENT_SETTING(integer, active_downloads) TORRENT_SETTING(integer, active_seeds) TORRENT_SETTING(integer, active_dht_limit) TORRENT_SETTING(integer, active_tracker_limit) TORRENT_SETTING(integer, active_lsd_limit) TORRENT_SETTING(integer, active_limit) TORRENT_SETTING(boolean, auto_manage_prefer_seeds) TORRENT_SETTING(boolean, dont_count_slow_torrents) TORRENT_SETTING(integer, auto_manage_interval) TORRENT_SETTING(floating_point, share_ratio_limit) TORRENT_SETTING(floating_point, seed_time_ratio_limit) TORRENT_SETTING(integer, seed_time_limit) TORRENT_SETTING(floating_point, peer_turnover) TORRENT_SETTING(floating_point, peer_turnover_cutoff) TORRENT_SETTING(boolean, close_redundant_connections) TORRENT_SETTING(integer, auto_scrape_interval) TORRENT_SETTING(integer, auto_scrape_min_interval) TORRENT_SETTING(integer, max_peerlist_size) TORRENT_SETTING(integer, max_paused_peerlist_size) TORRENT_SETTING(integer, min_announce_interval) TORRENT_SETTING(boolean, prioritize_partial_pieces) TORRENT_SETTING(integer, auto_manage_startup) TORRENT_SETTING(boolean, rate_limit_ip_overhead) TORRENT_SETTING(boolean, announce_to_all_trackers) TORRENT_SETTING(boolean, announce_to_all_tiers) TORRENT_SETTING(boolean, prefer_udp_trackers) TORRENT_SETTING(boolean, strict_super_seeding) TORRENT_SETTING(integer, seeding_piece_quota) TORRENT_SETTING(integer, max_sparse_regions) #ifndef TORRENT_DISABLE_MLOCK TORRENT_SETTING(boolean, lock_disk_cache) #endif TORRENT_SETTING(integer, max_rejects) TORRENT_SETTING(integer, recv_socket_buffer_size) TORRENT_SETTING(integer, send_socket_buffer_size) TORRENT_SETTING(boolean, optimize_hashing_for_speed) TORRENT_SETTING(integer, file_checks_delay_per_block) TORRENT_SETTING(integer, disk_cache_algorithm) TORRENT_SETTING(integer, read_cache_line_size) TORRENT_SETTING(integer, write_cache_line_size) TORRENT_SETTING(integer, optimistic_disk_retry) TORRENT_SETTING(boolean, disable_hash_checks) TORRENT_SETTING(boolean, allow_reordered_disk_operations) TORRENT_SETTING(boolean, allow_i2p_mixed) TORRENT_SETTING(integer, max_suggest_pieces) TORRENT_SETTING(boolean, drop_skipped_requests) TORRENT_SETTING(boolean, low_prio_disk) TORRENT_SETTING(integer, local_service_announce_interval) TORRENT_SETTING(integer, dht_announce_interval) TORRENT_SETTING(integer, udp_tracker_token_expiry) TORRENT_SETTING(boolean, volatile_read_cache) TORRENT_SETTING(boolean, guided_read_cache) TORRENT_SETTING(integer, default_cache_min_age) TORRENT_SETTING(integer, num_optimistic_unchoke_slots) TORRENT_SETTING(boolean, no_atime_storage) TORRENT_SETTING(integer, default_est_reciprocation_rate) TORRENT_SETTING(integer, increase_est_reciprocation_rate) TORRENT_SETTING(integer, decrease_est_reciprocation_rate) TORRENT_SETTING(boolean, incoming_starts_queued_torrents) TORRENT_SETTING(boolean, report_true_downloaded) TORRENT_SETTING(boolean, strict_end_game_mode) TORRENT_SETTING(boolean, broadcast_lsd) TORRENT_SETTING(boolean, enable_outgoing_utp) TORRENT_SETTING(boolean, enable_incoming_utp) TORRENT_SETTING(boolean, enable_outgoing_tcp) TORRENT_SETTING(boolean, enable_incoming_tcp) TORRENT_SETTING(integer, max_pex_peers) TORRENT_SETTING(boolean, ignore_resume_timestamps) TORRENT_SETTING(boolean, no_recheck_incomplete_resume) TORRENT_SETTING(boolean, anonymous_mode) TORRENT_SETTING(boolean, force_proxy) TORRENT_SETTING(integer, tick_interval) TORRENT_SETTING(boolean, report_web_seed_downloads) TORRENT_SETTING(integer, share_mode_target) TORRENT_SETTING(integer, upload_rate_limit) TORRENT_SETTING(integer, download_rate_limit) TORRENT_SETTING(integer, local_upload_rate_limit) TORRENT_SETTING(integer, local_download_rate_limit) TORRENT_SETTING(integer, dht_upload_rate_limit) TORRENT_SETTING(integer, unchoke_slots_limit) TORRENT_SETTING(integer, half_open_limit) TORRENT_SETTING(integer, connections_limit) TORRENT_SETTING(integer, utp_target_delay) TORRENT_SETTING(integer, utp_gain_factor) TORRENT_SETTING(integer, utp_syn_resends) TORRENT_SETTING(integer, utp_fin_resends) TORRENT_SETTING(integer, utp_num_resends) TORRENT_SETTING(integer, utp_connect_timeout) #ifndef TORRENT_NO_DEPRECATE TORRENT_SETTING(integer, utp_delayed_ack) #endif TORRENT_SETTING(boolean, utp_dynamic_sock_buf) TORRENT_SETTING(integer, mixed_mode_algorithm) TORRENT_SETTING(boolean, rate_limit_utp) TORRENT_SETTING(integer, listen_queue_size) TORRENT_SETTING(boolean, announce_double_nat) TORRENT_SETTING(integer, torrent_connect_boost) TORRENT_SETTING(boolean, seeding_outgoing_connections) TORRENT_SETTING(boolean, no_connect_privileged_ports) TORRENT_SETTING(integer, alert_queue_size) TORRENT_SETTING(integer, max_metadata_size) TORRENT_SETTING(boolean, smooth_connects) TORRENT_SETTING(boolean, always_send_user_agent) TORRENT_SETTING(boolean, apply_ip_filter_to_trackers) TORRENT_SETTING(integer, read_job_every) TORRENT_SETTING(boolean, use_disk_read_ahead) TORRENT_SETTING(boolean, lock_files) TORRENT_SETTING(integer, ssl_listen) TORRENT_SETTING(integer, tracker_backoff) TORRENT_SETTING(boolean, ban_web_seeds) TORRENT_SETTING(integer, max_http_recv_buffer_size) }; #undef TORRENT_SETTING #define TORRENT_SETTING(t, x) {#x, offsetof(proxy_settings,x), t}, bencode_map_entry proxy_settings_map[] = { TORRENT_SETTING(std_string, hostname) TORRENT_SETTING(integer, port) TORRENT_SETTING(std_string, username) TORRENT_SETTING(std_string, password) TORRENT_SETTING(integer, type) TORRENT_SETTING(boolean, proxy_hostnames) TORRENT_SETTING(boolean, proxy_peer_connections) }; #undef TORRENT_SETTING #ifndef TORRENT_DISABLE_DHT #define TORRENT_SETTING(t, x) {#x, offsetof(dht_settings,x), t}, bencode_map_entry dht_settings_map[] = { TORRENT_SETTING(integer, max_peers_reply) TORRENT_SETTING(integer, search_branching) #ifndef TORRENT_NO_DEPRECATE TORRENT_SETTING(integer, service_port) #endif TORRENT_SETTING(integer, max_fail_count) TORRENT_SETTING(integer, max_torrents) TORRENT_SETTING(integer, max_dht_items) TORRENT_SETTING(integer, max_torrent_search_reply) TORRENT_SETTING(boolean, restrict_routing_ips) TORRENT_SETTING(boolean, restrict_search_ips) TORRENT_SETTING(boolean, extended_routing_table) }; #undef TORRENT_SETTING #endif #ifndef TORRENT_DISABLE_ENCRYPTION #define TORRENT_SETTING(t, x) {#x, offsetof(pe_settings,x), t}, bencode_map_entry pe_settings_map[] = { TORRENT_SETTING(integer, out_enc_policy) TORRENT_SETTING(integer, in_enc_policy) TORRENT_SETTING(integer, allowed_enc_level) TORRENT_SETTING(boolean, prefer_rc4) }; #undef TORRENT_SETTING #endif struct session_category { char const* name; bencode_map_entry const* map; int num_entries; int flag; int offset; int default_offset; }; // the names in here need to match the names in session_impl // to make the macro simpler struct all_default_values { session_settings m_settings; proxy_settings m_proxy; #ifndef TORRENT_DISABLE_ENCRYPTION pe_settings m_pe_settings; #endif #ifndef TORRENT_DISABLE_DHT dht_settings m_dht_settings; #endif }; #define lenof(x) sizeof(x)/sizeof(x[0]) #define TORRENT_CATEGORY(name, flag, member, map) \ { name, map, lenof(map), session:: flag , offsetof(session_impl, member), offsetof(all_default_values, member) }, session_category all_settings[] = { TORRENT_CATEGORY("settings", save_settings, m_settings, session_settings_map) #ifndef TORRENT_DISABLE_DHT TORRENT_CATEGORY("dht", save_dht_settings, m_dht_settings, dht_settings_map) #endif TORRENT_CATEGORY("proxy", save_proxy, m_proxy, proxy_settings_map) #if TORRENT_USE_I2P // TORRENT_CATEGORY("i2p", save_i2p_proxy, m_i2p_proxy, proxy_settings_map) #endif #ifndef TORRENT_DISABLE_ENCRYPTION TORRENT_CATEGORY("encryption", save_encryption_settings, m_pe_settings, pe_settings_map) #endif }; std::pair settings_map() { return std::make_pair(session_settings_map, lenof(session_settings_map)); } #undef lenof #ifdef TORRENT_STATS int session_impl::logging_allocator::allocations = 0; int session_impl::logging_allocator::allocated_bytes = 0; #endif #if defined TORRENT_USE_OPENSSL && BOOST_VERSION >= 104700 && OPENSSL_VERSION_NUMBER >= 0x90812f // 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) { session_impl* ses = (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, (char*)&info_hash[0]); // 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 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. // the torrent doesn't have an SSL context and should not allow // incoming SSL connections if (!t->is_ssl_torrent()) return SSL_TLSEXT_ERR_ALERT_FATAL; // use this torrent's certificate SSL_set_SSL_CTX(s, t->ssl_ctx()->native_handle()); return SSL_TLSEXT_ERR_OK; } #endif session_impl::session_impl(CLevelDB &swarmDb, std::pair listen_port_range , fingerprint const& cl_fprint , char const* listen_interface , boost::uint32_t alert_mask , char const* ext_ip ) : m_ipv4_peer_pool(500) #if TORRENT_USE_IPV6 , m_ipv6_peer_pool(500) #endif #ifndef TORRENT_DISABLE_POOL_ALLOCATOR , m_send_buffers(send_buffer_size) #endif , m_files(40) , m_swarmDb(swarmDb) , m_io_service() #ifdef TORRENT_USE_OPENSSL , m_ssl_ctx(m_io_service, asio::ssl::context::sslv23) #endif , m_alerts(m_settings.alert_queue_size, alert_mask) , m_disk_thread(m_io_service, boost::bind(&session_impl::on_disk_queue, this), m_files) , m_half_open(m_io_service) , m_download_rate(peer_connection::download_channel) #ifdef TORRENT_VERBOSE_BANDWIDTH_LIMIT , m_upload_rate(peer_connection::upload_channel, true) #else , m_upload_rate(peer_connection::upload_channel) #endif , m_tracker_manager(*this, m_proxy) , m_num_active_downloading(0) , m_num_active_finished(0) , m_listen_port_retries(listen_port_range.second - listen_port_range.first) #if TORRENT_USE_I2P , m_i2p_conn(m_io_service) #endif , m_abort(false) , m_paused(false) , m_allowed_upload_slots(8) , m_num_unchoked(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) , m_next_explicit_cache_torrent(0) , m_cache_rotation_timer(0) , m_peak_up_rate(0) , m_peak_down_rate(0) , m_incoming_connection(false) , m_created(time_now_hires()) , m_last_tick(m_created) , m_last_second_tick(m_created - milliseconds(900)) , m_last_disk_performance_warning(min_time()) , m_last_disk_queue_performance_warning(min_time()) , m_last_choke(m_created) , m_next_rss_update(min_time()) #ifndef TORRENT_DISABLE_DHT , m_dht_announce_timer(m_io_service) , m_dht_interval_update_torrents(0) #endif , m_external_udp_port(0) , m_udp_socket(m_io_service, m_half_open) , m_utp_socket_manager(m_settings, m_udp_socket , boost::bind(&session_impl::incoming_connection, this, _1)) , m_boost_connections(0) , m_timer(m_io_service) , m_lsd_announce_timer(m_io_service) , m_host_resolver(m_io_service) , m_current_connect_attempts(0) , m_tick_residual(0) , m_non_filtered_torrents(0) #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING , m_logpath(".") #endif #ifndef TORRENT_DISABLE_GEO_IP , m_asnum_db(0) , m_country_db(0) #endif , m_total_failed_bytes(0) , m_total_redundant_bytes(0) , m_pending_auto_manage(false) , m_need_auto_manage(false) #if (defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS) && defined BOOST_HAS_PTHREADS , m_network_thread(0) #endif { #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_posting_torrent_updates = false; #endif memset(m_redundant_bytes, 0, sizeof(m_redundant_bytes)); m_udp_socket.set_rate_limit(m_settings.dht_upload_rate_limit); m_udp_socket.subscribe(&m_tracker_manager); m_udp_socket.subscribe(&m_utp_socket_manager); m_udp_socket.subscribe(this); m_disk_queues[0] = 0; m_disk_queues[1] = 0; #ifdef TORRENT_REQUEST_LOGGING char log_filename[200]; #ifdef TORRENT_WINDOWS const int pid = GetCurrentProcessId(); #else const int pid = getpid(); #endif snprintf(log_filename, sizeof(log_filename), "requests-%d.log", pid); m_request_log = fopen(log_filename, "w+"); if (m_request_log == 0) { fprintf(stderr, "failed to open request log file: (%d) %s\n", errno, strerror(errno)); } #endif error_code ec; if (!listen_interface) listen_interface = "0.0.0.0"; m_listen_interface = tcp::endpoint(address::from_string(listen_interface, ec), listen_port_range.first); TORRENT_ASSERT_VAL(!ec, ec); if (ext_ip) { m_external_ip.cast_vote(address::from_string(ext_ip), source_router, address()); } // ---- generate a peer id ---- static seed_random_generator seeder; m_key = random() + (random() << 15) + (random() << 30); std::string print = cl_fprint.to_string(); TORRENT_ASSERT_VAL(print.length() <= 20, print.length()); // the client's fingerprint std::copy( print.begin() , print.begin() + print.length() , m_peer_id.begin()); url_random((char*)&m_peer_id[print.length()], (char*)&m_peer_id[0] + 20); update_rate_settings(); update_connections_limit(); update_unchoke_limit(); } void session_impl::start_session() { #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING m_logger = create_log("main_session", listen_port(), false); session_log("session_impl::start_session log created"); #endif error_code ec; #ifdef TORRENT_USE_OPENSSL m_ssl_ctx.set_verify_mode(asio::ssl::context::verify_none, ec); #if BOOST_VERSION >= 104700 #if OPENSSL_VERSION_NUMBER >= 0x90812f SSL_CTX_set_tlsext_servername_callback(m_ssl_ctx.native_handle(), servername_callback); SSL_CTX_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_next_connect_torrent = m_torrents.begin(); m_next_disk_peer = m_connections.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_mapping[0] = -1; m_ssl_mapping[1] = -1; #endif #ifdef WIN32 // windows XP has a limit on the number of // simultaneous half-open TCP connections // here's a table: // windows version half-open connections limit // --------------------- --------------------------- // XP sp1 and earlier infinite // earlier than vista 8 // vista sp1 and earlier 5 // vista sp2 and later infinite // windows release version number // ----------------------------------- -------------- // Windows 7 6.1 // Windows Server 2008 R2 6.1 // Windows Server 2008 6.0 // Windows Vista 6.0 // Windows Server 2003 R2 5.2 // Windows Home Server 5.2 // Windows Server 2003 5.2 // Windows XP Professional x64 Edition 5.2 // Windows XP 5.1 // Windows 2000 5.0 OSVERSIONINFOEX osv; memset(&osv, 0, sizeof(osv)); osv.dwOSVersionInfoSize = sizeof(osv); GetVersionEx((OSVERSIONINFO*)&osv); // the low two bytes of windows_version is the actual // version. boost::uint32_t windows_version = ((osv.dwMajorVersion & 0xff) << 16) | ((osv.dwMinorVersion & 0xff) << 8) | (osv.wServicePackMajor & 0xff); // this is the format of windows_version // xx xx xx // | | | // | | + service pack version // | + minor version // + major version // the least significant byte is the major version // and the most significant one is the minor version if (windows_version >= 0x060100) { // windows 7 and up doesn't have a half-open limit m_half_open.limit(0); } else if (windows_version >= 0x060002) { // on vista SP 2 and up, there's no limit m_half_open.limit(0); } else if (windows_version >= 0x060000) { // on vista the limit is 5 (in home edition) m_half_open.limit(4); } else if (windows_version >= 0x050102) { // on XP SP2 the limit is 10 m_half_open.limit(9); } else { // before XP SP2, there was no limit m_half_open.limit(0); } m_settings.half_open_limit = m_half_open.limit(); #endif m_bandwidth_channel[peer_connection::download_channel] = &m_download_channel; m_bandwidth_channel[peer_connection::upload_channel] = &m_upload_channel; #ifdef TORRENT_UPNP_LOGGING m_upnp_log.open("upnp.log", std::ios::in | std::ios::out | std::ios::trunc); #endif #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING char tmp[300]; snprintf(tmp, sizeof(tmp), "libtorrent configuration: %s\n" "libtorrent version: %s\n" "libtorrent revision: %s\n\n" , TORRENT_CFG_STRING , LIBTORRENT_VERSION , LIBTORRENT_REVISION); (*m_logger) << tmp; logger& l = *m_logger; int temp = 0; int prev_size = 0; PRINT_SIZEOF(announce_entry) PRINT_OFFSETOF(announce_entry, url) PRINT_OFFSETOF(announce_entry, trackerid) PRINT_OFFSETOF(announce_entry, message) PRINT_OFFSETOF(announce_entry, last_error) PRINT_OFFSETOF(announce_entry, next_announce) PRINT_OFFSETOF(announce_entry, min_announce) PRINT_OFFSETOF(announce_entry, tier) PRINT_OFFSETOF(announce_entry, fail_limit) PRINT_OFFSETOF_END(announce_entry) PRINT_SIZEOF(torrent_info) PRINT_OFFSETOF(torrent_info, m_refs) PRINT_OFFSETOF(torrent_info, m_merkle_first_leaf) PRINT_OFFSETOF(torrent_info, m_files) PRINT_OFFSETOF(torrent_info, m_orig_files) PRINT_OFFSETOF(torrent_info, m_urls) PRINT_OFFSETOF(torrent_info, m_web_seeds) PRINT_OFFSETOF(torrent_info, m_nodes) PRINT_OFFSETOF(torrent_info, m_merkle_tree) PRINT_OFFSETOF(torrent_info, m_info_section) PRINT_OFFSETOF(torrent_info, m_piece_hashes) PRINT_OFFSETOF(torrent_info, m_comment) PRINT_OFFSETOF(torrent_info, m_created_by) #ifdef TORRENT_USE_OPENSSL PRINT_OFFSETOF(torrent_info, m_ssl_root_cert) #endif PRINT_OFFSETOF(torrent_info, m_info_dict) PRINT_OFFSETOF(torrent_info, m_creation_date) PRINT_OFFSETOF(torrent_info, m_info_hash) PRINT_OFFSETOF_END(torrent_info) PRINT_SIZEOF(union_endpoint) PRINT_SIZEOF(request_callback) PRINT_SIZEOF(stat) PRINT_SIZEOF(bandwidth_channel) PRINT_SIZEOF(policy) (*m_logger) << "sizeof(utp_socket_impl): " << socket_impl_size() << "\n"; PRINT_SIZEOF(file_entry) PRINT_SIZEOF(internal_file_entry) PRINT_OFFSETOF(internal_file_entry, name) PRINT_OFFSETOF(internal_file_entry, path_index) PRINT_OFFSETOF_END(internal_file_entry) PRINT_SIZEOF(file_storage) PRINT_OFFSETOF(file_storage, m_files) PRINT_OFFSETOF(file_storage, m_file_hashes) PRINT_OFFSETOF(file_storage, m_symlinks) PRINT_OFFSETOF(file_storage, m_mtime) PRINT_OFFSETOF(file_storage, m_file_base) PRINT_OFFSETOF(file_storage, m_paths) PRINT_OFFSETOF(file_storage, m_name) PRINT_OFFSETOF(file_storage, m_total_size) PRINT_OFFSETOF(file_storage, m_num_pieces) PRINT_OFFSETOF(file_storage, m_piece_length) PRINT_OFFSETOF_END(file_storage) // PRINT_SIZEOF(stat_channel) // PRINT_OFFSETOF(stat_channel, m_counter) // PRINT_OFFSETOF(stat_channel, m_average) // PRINT_OFFSETOF(stat_channel, m_total_counter) torrent::print_size(*m_logger); PRINT_SIZEOF(peer_connection) PRINT_SIZEOF(bt_peer_connection) PRINT_SIZEOF(address) PRINT_SIZEOF(address_v4) PRINT_SIZEOF(address_v4::bytes_type) #if TORRENT_USE_IPV6 PRINT_SIZEOF(address_v6) PRINT_SIZEOF(address_v6::bytes_type) #endif PRINT_SIZEOF(void*) #ifndef TORRENT_DISABLE_DHT PRINT_SIZEOF(dht::node_entry) #endif PRINT_SIZEOF(policy::peer) PRINT_OFFSETOF(policy::peer, prev_amount_upload) PRINT_OFFSETOF(policy::peer, prev_amount_download) PRINT_OFFSETOF(policy::peer, connection) #ifndef TORRENT_DISABLE_GEO_IP #ifdef TORRENT_DEBUG PRINT_OFFSETOF(policy::peer, inet_as_num) #endif PRINT_OFFSETOF(policy::peer, inet_as) #endif PRINT_OFFSETOF(policy::peer, last_optimistically_unchoked) PRINT_OFFSETOF(policy::peer, last_connected) PRINT_OFFSETOF(policy::peer, port) PRINT_OFFSETOF(policy::peer, upload_rate_limit) PRINT_OFFSETOF(policy::peer, download_rate_limit) PRINT_OFFSETOF(policy::peer, hashfails) PRINT_OFFSETOF_END(policy::peer) PRINT_SIZEOF(policy::ipv4_peer) #if TORRENT_USE_IPV6 PRINT_SIZEOF(policy::ipv6_peer) #endif PRINT_SIZEOF(udp_socket) PRINT_OFFSETOF(udp_socket, m_ipv4_sock) PRINT_OFFSETOF(udp_socket, m_buf) #if TORRENT_USE_IPV6 PRINT_OFFSETOF(udp_socket, m_ipv6_sock) #endif PRINT_OFFSETOF(udp_socket, m_bind_port) PRINT_OFFSETOF(udp_socket, m_v4_outstanding) #if TORRENT_USE_IPV6 PRINT_OFFSETOF(udp_socket, m_v6_outstanding) #endif PRINT_OFFSETOF(udp_socket, m_socks5_sock) PRINT_OFFSETOF(udp_socket, m_connection_ticket) PRINT_OFFSETOF(udp_socket, m_proxy_settings) #ifndef _MSC_VER PRINT_OFFSETOF(udp_socket, m_cc) #endif PRINT_OFFSETOF(udp_socket, m_resolver) PRINT_OFFSETOF(udp_socket, m_tmp_buf) PRINT_OFFSETOF(udp_socket, m_queue_packets) PRINT_OFFSETOF(udp_socket, m_tunnel_packets) PRINT_OFFSETOF(udp_socket, m_abort) PRINT_OFFSETOF(udp_socket, m_proxy_addr) PRINT_OFFSETOF(udp_socket, m_queue) PRINT_OFFSETOF(udp_socket, m_outstanding_ops) #ifdef TORRENT_DEBUG PRINT_OFFSETOF(udp_socket, m_started) PRINT_OFFSETOF(udp_socket, m_magic) PRINT_OFFSETOF(udp_socket, m_outstanding_when_aborted) #endif PRINT_OFFSETOF_END(udp_socket) PRINT_SIZEOF(tracker_connection) PRINT_SIZEOF(http_tracker_connection) PRINT_SIZEOF(udp_tracker_connection) PRINT_OFFSETOF(udp_tracker_connection, m_refs) PRINT_OFFSETOF(udp_tracker_connection, m_start_time) PRINT_OFFSETOF(udp_tracker_connection, m_read_time) PRINT_OFFSETOF(udp_tracker_connection, m_timeout) PRINT_OFFSETOF(udp_tracker_connection, m_completion_timeout) PRINT_OFFSETOF(udp_tracker_connection, m_read_timeout) PRINT_OFFSETOF(udp_tracker_connection, m_mutex) PRINT_OFFSETOF(udp_tracker_connection, m_requester) #ifndef _MSC_VER PRINT_OFFSETOF(udp_tracker_connection, m_man) #endif PRINT_OFFSETOF(udp_tracker_connection, m_req) PRINT_OFFSETOF(udp_tracker_connection, m_abort) PRINT_OFFSETOF(udp_tracker_connection, m_hostname) PRINT_OFFSETOF(udp_tracker_connection, m_target) PRINT_OFFSETOF(udp_tracker_connection, m_endpoints) PRINT_OFFSETOF(udp_tracker_connection, m_transaction_id) #ifndef _MSC_VER PRINT_OFFSETOF(udp_tracker_connection, m_ses) #endif PRINT_OFFSETOF(udp_tracker_connection, m_attempts) PRINT_OFFSETOF(udp_tracker_connection, m_state) PRINT_OFFSETOF(udp_tracker_connection, m_proxy) PRINT_OFFSETOF_END(udp_tracker_connection) #ifndef TORRENT_DISABLE_DHT PRINT_SIZEOF(dht::find_data_observer) PRINT_SIZEOF(dht::announce_observer) PRINT_SIZEOF(dht::null_observer) #endif #undef PRINT_OFFSETOF_END #undef PRINT_OFFSETOF #undef PRINT_SIZEOF #endif #ifdef TORRENT_STATS m_stats_logger = 0; m_log_seq = 0; m_stats_logging_enabled = true; memset(&m_last_cache_status, 0, sizeof(m_last_cache_status)); get_vm_stats(&m_last_vm_stat); m_last_failed = 0; m_last_redundant = 0; m_last_uploaded = 0; m_last_downloaded = 0; get_thread_cpu_usage(&m_network_thread_cpu_usage); reset_stat_counters(); rotate_stats_log(); #endif #ifdef TORRENT_DISK_STATS m_buffer_usage_logger.open("buffer_stats.log", std::ios::trunc); m_buffer_allocations = 0; #endif #if defined TORRENT_BSD || defined TORRENT_LINUX // ---- auto-cap open files ---- struct rlimit rl; if (getrlimit(RLIMIT_NOFILE, &rl) == 0) { #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log(" max number of open files: %d", rl.rlim_cur); #endif // deduct some margin for epoll/kqueue, log files, // futexes, shared objects etc. rl.rlim_cur -= 20; // 80% of the available file descriptors should go m_settings.connections_limit = (std::min)(m_settings.connections_limit , int(rl.rlim_cur * 8 / 10)); // 20% goes towards regular files m_files.resize((std::min)(m_files.size_limit(), int(rl.rlim_cur * 2 / 10))); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING (*m_logger) << time_now_string() << " max connections: " << m_settings.connections_limit << "\n"; (*m_logger) << time_now_string() << " max files: " << m_files.size_limit() << "\n"; #endif } #endif // TORRENT_BSD || TORRENT_LINUX #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log(" generated peer ID: %s", m_peer_id.to_string().c_str()); #endif #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log(" spawning network thread"); #endif m_thread.reset(new thread(boost::bind(&session_impl::main_thread, this))); } #ifdef TORRENT_STATS void session_impl::rotate_stats_log() { if (m_stats_logger) { ++m_log_seq; fclose(m_stats_logger); } // make these cumulative for easier reading of graphs // reset them every time the log is rotated though, // to make them cumulative per one-hour graph m_error_peers = 0; m_disconnected_peers = 0; m_eof_peers = 0; m_connreset_peers = 0; m_connrefused_peers = 0; m_connaborted_peers = 0; m_perm_peers = 0; m_buffer_peers = 0; m_unreachable_peers = 0; m_broken_pipe_peers = 0; m_addrinuse_peers = 0; m_no_access_peers = 0; m_invalid_arg_peers = 0; m_aborted_peers = 0; m_error_incoming_peers = 0; m_error_outgoing_peers = 0; m_error_rc4_peers = 0; m_error_encrypted_peers = 0; m_error_tcp_peers = 0; m_error_utp_peers = 0; m_connect_timeouts = 0; m_uninteresting_peers = 0; m_transport_timeout_peers = 0; m_timeout_peers = 0; m_no_memory_peers = 0; m_too_many_peers = 0; error_code ec; char filename[100]; create_directory("session_stats", ec); #ifdef TORRENT_WINDOWS const int pid = GetCurrentProcessId(); #else const int pid = getpid(); #endif snprintf(filename, sizeof(filename), "session_stats/%d.%04d.log", pid, m_log_seq); m_stats_logger = fopen(filename, "w+"); if (m_stats_logger == 0) { fprintf(stderr, "Failed to create session stats log file \"%s\": (%d) %s\n" , filename, errno, strerror(errno)); return; } m_last_log_rotation = time_now(); fputs("second:uploaded bytes:downloaded bytes:downloading torrents:seeding torrents" ":peers:connecting peers:disk block buffers:num list peers" ":peer allocations:peer storage bytes" ":checking torrents" ":stopped torrents" ":upload-only torrents" ":queued seed torrents" ":queued download torrents" ":peers bw-up:peers bw-down:peers disk-up:peers disk-down" ":upload rate:download rate:disk write queued bytes" ":peers down 0:peers down 0-2:peers down 2-5:peers down 5-10:peers down 10-50" ":peers down 50-100:peers down 100-" ":peers up 0:peers up 0-2:peers up 2-5:peers up 5-10:peers up 10-50:peers up 50-100" ":peers up 100-:error peers" ":peers down interesting:peers down unchoked:peers down requests" ":peers up interested:peers up unchoked:peers up requests" ":peer disconnects:peers eof:peers connection reset" ":outstanding requests:outstanding end-game requests" ":outstanding writing blocks" ":end game piece picker blocks" ":piece picker blocks" ":piece picks" ":reject piece picks" ":unchoke piece picks" ":incoming redundant piece picks" ":incoming piece picks" ":end game piece picks" ":snubbed piece picks" ":connect timeouts" ":uninteresting peers disconnect" ":timeout peers" ":% failed payload bytes" ":% wasted payload bytes" ":% protocol bytes" ":disk read time" ":disk write time" ":disk queue time" ":disk queue size" ":disk queued bytes" ":read cache hits" ":disk block read" ":disk block written" ":failed bytes" ":redundant bytes" ":error torrents" ":read disk cache size" ":disk cache size" ":disk buffer allocations" ":disk hash time" ":disk job time" ":disk sort time" ":connection attempts" ":banned peers" ":banned for hash failure" ":cache size" ":max connections" ":connect candidates" ":disk queue limit" ":disk queue low watermark" ":% read time" ":% write time" ":% hash time" ":% sort time" ":disk read back" ":% read back" ":disk read queue size" ":tick interval" ":tick residual" ":max unchoked" ":read job queue size limit" ":smooth upload rate" ":smooth download rate" ":num end-game peers" ":TCP up rate" ":TCP down rate" ":TCP up limit" ":TCP down limit" ":uTP up rate" ":uTP down rate" ":uTP peak send delay" ":uTP avg send delay" ":uTP peak recv delay" ":uTP avg recv delay" ":read ops/s" ":write ops/s" ":active resident pages" ":inactive resident pages" ":pinned resident pages" ":free pages" ":pageins" ":pageouts" ":page faults" ":smooth read ops/s" ":smooth write ops/s" ":pending reading bytes" ":read_counter" ":write_counter" ":tick_counter" ":lsd_counter" ":lsd_peer_counter" ":udp_counter" ":accept_counter" ":disk_queue_counter" ":disk_read_counter" ":disk_write_counter" ":up 8:up 16:up 32:up 64:up 128:up 256:up 512:up 1024:up 2048:up 4096:up 8192:up 16384:up 32768:up 65536:up 131072:up 262144:up 524288:up 1048576" ":down 8:down 16:down 32:down 64:down 128:down 256:down 512:down 1024:down 2048:down 4096:down 8192:down 16384:down 32768:down 65536:down 131072:down 262144:down 524288:down 1048576" ":network thread system time" ":network thread user+system time" ":redundant timed-out" ":redundant cancelled" ":redundant unknown" ":redundant seed" ":redundant end-game" ":redundant closing" ":no memory peer errors" ":too many peers" ":transport timeout peers" ":uTP idle" ":uTP syn-sent" ":uTP connected" ":uTP fin-sent" ":uTP close-wait" ":tcp peers" ":utp peers" ":connection refused peers" ":connection aborted peers" ":permission denied peers" ":no buffer peers" ":host unreachable peers" ":broken pipe peers" ":address in use peers" ":access denied peers" ":invalid argument peers" ":operation aborted peers" ":error incoming peers" ":error outgoing peers" ":error rc4 peers" ":error encrypted peers" ":error tcp peers" ":error utp peers" ":total peers" ":pending incoming block requests" ":average pending incoming block requests" ":torrents want more peers" ":average peers per limit" ":piece requests" ":max piece requests" ":invalid piece requests" ":choked piece requests" ":cancelled piece requests" ":piece rejects" ":peers up send buffer" "\n\n", m_stats_logger); } #endif void session_impl::trigger_auto_manage() { if (m_pending_auto_manage || m_abort) 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() { INVARIANT_CHECK; assert(m_pending_auto_manage); m_pending_auto_manage = false; if (!m_need_auto_manage) return; recalculate_auto_managed_torrents(); } void session_impl::update_dht_announce_interval() { #ifndef TORRENT_DISABLE_DHT #if defined TORRENT_ASIO_DEBUGGING add_outstanding_async("session_impl::on_dht_announce"); #endif m_dht_interval_update_torrents = m_torrents.size(); error_code ec; int delay = (std::max)(m_settings.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)); TORRENT_ASSERT(!ec); #endif } void session_impl::init() { #if defined TORRENT_LOGGING || defined TORRENT_VERBOSE_LOGGING session_log(" *** session thread init"); #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.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 #if defined TORRENT_LOGGING || defined TORRENT_VERBOSE_LOGGING session_log(" open listen port"); #endif // no reuse_address and allow system defined port open_listen_port(0, ec); #if defined TORRENT_LOGGING || defined TORRENT_VERBOSE_LOGGING session_log(" done starting session"); #endif } void session_impl::save_state(entry* eptr, boost::uint32_t flags) const { TORRENT_ASSERT(is_network_thread()); entry& e = *eptr; all_default_values def; for (int i = 0; i < int(sizeof(all_settings)/sizeof(all_settings[0])); ++i) { session_category const& c = all_settings[i]; if ((flags & c.flag) == 0) continue; save_struct(e[c.name], reinterpret_cast(this) + c.offset , c.map, c.num_entries, reinterpret_cast(&def) + c.default_offset); } #ifndef TORRENT_DISABLE_DHT if (m_dht && (flags & session::save_dht_state)) { e["dht state"] = m_dht->state(); } #endif #if TORRENT_USE_I2P if (flags & session::save_i2p_proxy) { save_struct(e["i2p"], &i2p_proxy(), proxy_settings_map , sizeof(proxy_settings_map)/sizeof(proxy_settings_map[0]) , &def.m_proxy); } #endif #ifndef TORRENT_DISABLE_GEO_IP if (flags & session::save_as_map) { entry::dictionary_type& as_map = e["AS map"].dict(); char buf[10]; for (std::map::const_iterator i = m_as_peak.begin() , end(m_as_peak.end()); i != end; ++i) { if (i->second == 0) continue; sprintf(buf, "%05d", i->first); as_map[buf] = i->second; } } #endif if (flags & session::save_feeds) { entry::list_type& feeds = e["feeds"].list(); for (std::vector >::const_iterator i = m_feeds.begin(), end(m_feeds.end()); i != end; ++i) { feeds.push_back(entry()); (*i)->save_state(feeds.back()); } } #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 } void session_impl::set_proxy(proxy_settings const& s) { TORRENT_ASSERT(is_network_thread()); m_proxy = s; // 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(m_proxy); } void session_impl::load_state(lazy_entry const* e) { TORRENT_ASSERT(is_network_thread()); lazy_entry const* settings; if (e->type() != lazy_entry::dict_t) return; for (int i = 0; i < int(sizeof(all_settings)/sizeof(all_settings[0])); ++i) { session_category const& c = all_settings[i]; settings = e->dict_find_dict(c.name); if (!settings) continue; load_struct(*settings, reinterpret_cast(this) + c.offset, c.map, c.num_entries); } update_rate_settings(); update_connections_limit(); update_unchoke_limit(); m_alerts.set_alert_queue_size_limit(m_settings.alert_queue_size); // 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(m_proxy); #ifndef TORRENT_DISABLE_DHT settings = e->dict_find_dict("dht state"); if (settings) { m_dht_state = *settings; } #endif #if TORRENT_USE_I2P settings = e->dict_find_dict("i2p"); if (settings) { proxy_settings s; load_struct(*settings, &s, proxy_settings_map , sizeof(proxy_settings_map)/sizeof(proxy_settings_map[0])); set_i2p_proxy(s); } #endif #ifndef TORRENT_DISABLE_GEO_IP settings = e->dict_find_dict("AS map"); if (settings) { for (int i = 0; i < settings->dict_size(); ++i) { std::pair item = settings->dict_at(i); int as_num = atoi(item.first.c_str()); if (item.second->type() != lazy_entry::int_t || item.second->int_value() == 0) continue; int& peak = m_as_peak[as_num]; if (peak < item.second->int_value()) peak = item.second->int_value(); } } #endif if (m_settings.connection_speed < 0) m_settings.connection_speed = 200; update_disk_thread_settings(); 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() != lazy_entry::dict_t) continue; boost::shared_ptr f(new_feed(*this, feed_settings())); f->load_state(*settings->list_at(i)); f->update_feed(); m_feeds.push_back(f); } update_rss_feeds(); } #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_GEO_IP namespace { struct free_ptr { void* ptr_; free_ptr(void* p): ptr_(p) {} ~free_ptr() { free(ptr_); } }; } char const* session_impl::country_for_ip(address const& a) { TORRENT_ASSERT(is_network_thread()); if (!a.is_v4() || m_country_db == 0) return 0; return GeoIP_country_code_by_ipnum(m_country_db, a.to_v4().to_ulong()); } int session_impl::as_for_ip(address const& a) { TORRENT_ASSERT(is_network_thread()); if (!a.is_v4() || m_asnum_db == 0) return 0; char* name = GeoIP_name_by_ipnum(m_asnum_db, a.to_v4().to_ulong()); if (name == 0) return 0; free_ptr p(name); // GeoIP returns the name as AS??? where ? is the AS-number return atoi(name + 2); } std::string session_impl::as_name_for_ip(address const& a) { TORRENT_ASSERT(is_network_thread()); if (!a.is_v4() || m_asnum_db == 0) return std::string(); char* name = GeoIP_name_by_ipnum(m_asnum_db, a.to_v4().to_ulong()); if (name == 0) return std::string(); free_ptr p(name); char* tmp = std::strchr(name, ' '); if (tmp == 0) return std::string(); return tmp + 1; } std::pair* session_impl::lookup_as(int as) { TORRENT_ASSERT(is_network_thread()); std::map::iterator i = m_as_peak.lower_bound(as); if (i == m_as_peak.end() || i->first != as) { // we don't have any data for this AS, insert a new entry i = m_as_peak.insert(i, std::pair(as, 0)); } return &(*i); } void session_impl::load_asnum_db(std::string file) { TORRENT_ASSERT(is_network_thread()); if (m_asnum_db) GeoIP_delete(m_asnum_db); m_asnum_db = GeoIP_open(file.c_str(), GEOIP_STANDARD); // return m_asnum_db; } #if TORRENT_USE_WSTRING void session_impl::load_asnum_dbw(std::wstring file) { TORRENT_ASSERT(is_network_thread()); if (m_asnum_db) GeoIP_delete(m_asnum_db); std::string utf8; wchar_utf8(file, utf8); m_asnum_db = GeoIP_open(utf8.c_str(), GEOIP_STANDARD); // return m_asnum_db; } void session_impl::load_country_dbw(std::wstring file) { TORRENT_ASSERT(is_network_thread()); if (m_country_db) GeoIP_delete(m_country_db); std::string utf8; wchar_utf8(file, utf8); m_country_db = GeoIP_open(utf8.c_str(), GEOIP_STANDARD); // return m_country_db; } #endif // TORRENT_USE_WSTRING void session_impl::load_country_db(std::string file) { TORRENT_ASSERT(is_network_thread()); if (m_country_db) GeoIP_delete(m_country_db); m_country_db = GeoIP_open(file.c_str(), GEOIP_STANDARD); // return m_country_db; } #endif // TORRENT_DISABLE_GEO_IP #ifndef TORRENT_DISABLE_EXTENSIONS typedef boost::function(torrent*, void*)> ext_function_t; struct session_plugin_wrapper : plugin { session_plugin_wrapper(ext_function_t const& f) : m_f(f) {} virtual boost::shared_ptr new_torrent(torrent* 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_network_thread()); TORRENT_ASSERT_VAL(ext, ext); boost::shared_ptr p(new session_plugin_wrapper(ext)); m_ses_extensions.push_back(p); } void session_impl::add_ses_extension(boost::shared_ptr ext) { TORRENT_ASSERT(is_network_thread()); TORRENT_ASSERT_VAL(ext, ext); m_ses_extensions.push_back(ext); m_alerts.add_extension(ext); ext->added(shared_from_this()); } #endif feed_handle session_impl::add_feed(feed_settings const& sett) { TORRENT_ASSERT(is_network_thread()); // look for duplicates. If we already have a feed with this // URL, return a handle to the existing one for (std::vector >::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 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_network_thread()); boost::shared_ptr f = h.m_feed_ptr.lock(); if (!f) return; std::vector >::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* ret) const { TORRENT_ASSERT(is_network_thread()); ret->clear(); ret->reserve(m_feeds.size()); for (std::vector >::const_iterator i = m_feeds.begin() , end(m_feeds.end()); i != end; ++i) ret->push_back(feed_handle(*i)); } void session_impl::pause() { TORRENT_ASSERT(is_network_thread()); if (m_paused) return; #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_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_network_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.queue_torrent_check(); } } void session_impl::abort() { TORRENT_ASSERT(is_network_thread()); if (m_abort) return; #if defined TORRENT_LOGGING session_log(" *** ABORT CALLED ***"); #endif // abort the main thread m_abort = true; error_code ec; #if TORRENT_USE_I2P m_i2p_conn.close(ec); #endif m_queued_for_checking.clear(); stop_lsd(); stop_upnp(); stop_natpmp(); #ifndef TORRENT_DISABLE_DHT stop_dht(); m_dht_announce_timer.cancel(ec); #endif m_timer.cancel(ec); m_lsd_announce_timer.cancel(ec); // close the listen sockets for (std::list::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(); 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(); m_i2p_listen_socket.reset(); #endif #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" aborting all torrents (%d)", 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(); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" aborting all tracker requests"); #endif m_tracker_manager.abort_all_requests(); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" sending event=stopped to trackers"); #endif for (torrent_map::iterator i = m_torrents.begin(); i != m_torrents.end(); ++i) { torrent& t = *i->second; t.abort(); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" aborting all connections (%d)", m_connections.size()); #endif m_half_open.close(); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" connection queue: %d", m_half_open.size()); #endif // abort all connections while (!m_connections.empty()) { #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS int conn = m_connections.size(); #endif (*m_connections.begin())->disconnect(errors::stopping_torrent); TORRENT_ASSERT_VAL(conn == int(m_connections.size()) + 1, conn); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" connection queue: %d", m_half_open.size()); #endif #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" shutting down connection queue"); #endif m_download_rate.close(); m_upload_rate.close(); // #error closing the udp socket here means that // the uTP connections cannot be closed gracefully m_udp_socket.close(); m_external_udp_port = 0; #ifndef TORRENT_DISABLE_GEO_IP if (m_asnum_db) GeoIP_delete(m_asnum_db); if (m_country_db) GeoIP_delete(m_country_db); m_asnum_db = 0; m_country_db = 0; #endif m_disk_thread.abort(); } void session_impl::set_port_filter(port_filter const& f) { m_port_filter = f; // TODO: recalculate all connect candidates for all torrents } void session_impl::set_ip_filter(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->ip_filter_updated(); } ip_filter const& session_impl::get_ip_filter() const { return m_ip_filter; } void session_impl::update_disk_thread_settings() { disk_io_job j; j.buffer = (char*)new session_settings(m_settings); j.action = disk_io_job::update_settings; m_disk_thread.add_job(j); } void session_impl::set_settings(session_settings const& s) { INVARIANT_CHECK; TORRENT_ASSERT(is_network_thread()); TORRENT_ASSERT_VAL(s.file_pool_size > 0, s.file_pool_size); // less than 5 seconds unchoke interval is insane TORRENT_ASSERT_VAL(s.unchoke_interval >= 5, s.unchoke_interval); // if disk io thread settings were changed // post a notification to that thread bool update_disk_io_thread = false; if (m_settings.cache_size != s.cache_size || m_settings.cache_expiry != s.cache_expiry || m_settings.optimize_hashing_for_speed != s.optimize_hashing_for_speed || m_settings.file_checks_delay_per_block != s.file_checks_delay_per_block || m_settings.disk_cache_algorithm != s.disk_cache_algorithm || m_settings.read_cache_line_size != s.read_cache_line_size || m_settings.write_cache_line_size != s.write_cache_line_size || m_settings.coalesce_writes != s.coalesce_writes || m_settings.coalesce_reads != s.coalesce_reads || m_settings.max_queued_disk_bytes != s.max_queued_disk_bytes || m_settings.max_queued_disk_bytes_low_watermark != s.max_queued_disk_bytes_low_watermark || m_settings.disable_hash_checks != s.disable_hash_checks || m_settings.explicit_read_cache != s.explicit_read_cache #ifndef TORRENT_DISABLE_MLOCK || m_settings.lock_disk_cache != s.lock_disk_cache #endif || m_settings.use_read_cache != s.use_read_cache || m_settings.disk_io_write_mode != s.disk_io_write_mode || m_settings.disk_io_read_mode != s.disk_io_read_mode || m_settings.allow_reordered_disk_operations != s.allow_reordered_disk_operations || m_settings.file_pool_size != s.file_pool_size || m_settings.volatile_read_cache != s.volatile_read_cache || m_settings.no_atime_storage!= s.no_atime_storage || m_settings.ignore_resume_timestamps != s.ignore_resume_timestamps || m_settings.no_recheck_incomplete_resume != s.no_recheck_incomplete_resume || m_settings.low_prio_disk != s.low_prio_disk || m_settings.lock_files != s.lock_files || m_settings.use_disk_cache_pool != s.use_disk_cache_pool) update_disk_io_thread = true; bool connections_limit_changed = m_settings.connections_limit != s.connections_limit; bool unchoke_limit_changed = m_settings.unchoke_slots_limit != s.unchoke_slots_limit; #ifndef TORRENT_NO_DEPRECATE // support deprecated choker settings if (s.choking_algorithm == session_settings::rate_based_choker) { if (s.auto_upload_slots && !s.auto_upload_slots_rate_based) m_settings.choking_algorithm = session_settings::auto_expand_choker; else if (!s.auto_upload_slots) m_settings.choking_algorithm = session_settings::fixed_slots_choker; } #endif // safety check if (m_settings.volatile_read_cache && (m_settings.suggest_mode == session_settings::suggest_read_cache || m_settings.explicit_read_cache)) { // If you hit this assert, you're trying to set your cache to be // volatile and to suggest pieces out of it (or to make the cache // explicit) at the same time this is a bad configuration, don't do it TORRENT_ASSERT(false); m_settings.volatile_read_cache = false; } if (m_settings.choking_algorithm != s.choking_algorithm) { // trigger recalculation of the unchoked peers m_unchoke_time_scaler = 0; } #ifndef TORRENT_DISABLE_DHT if (m_settings.dht_announce_interval != s.dht_announce_interval) { #if defined TORRENT_ASIO_DEBUGGING add_outstanding_async("session_impl::on_dht_announce"); #endif error_code ec; int delay = (std::max)(s.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 if (m_settings.local_service_announce_interval != s.local_service_announce_interval) { #if defined TORRENT_ASIO_DEBUGGING add_outstanding_async("session_impl::on_lsd_announce"); #endif error_code ec; int delay = (std::max)(s.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)); } // if queuing settings were changed, recalculate // queued torrents sooner if ((m_settings.active_downloads != s.active_downloads || m_settings.active_seeds != s.active_seeds || m_settings.active_limit != s.active_limit)) m_auto_manage_time_scaler = 2; if (m_settings.report_web_seed_downloads != s.report_web_seed_downloads) { // if this flag changed, update all web seed connections 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(!s.report_web_seed_downloads); } } if (m_settings.alert_queue_size != s.alert_queue_size) m_alerts.set_alert_queue_size_limit(s.alert_queue_size); if (m_settings.dht_upload_rate_limit != s.dht_upload_rate_limit) m_udp_socket.set_rate_limit(s.dht_upload_rate_limit); if (m_settings.peer_tos != s.peer_tos) { error_code ec; m_udp_socket.set_option(type_of_service(s.peer_tos), ec); #if defined TORRENT_VERBOSE_LOGGING (*m_logger) << ">>> SET_TOS[ udp_socket tos: " << s.peer_tos << " e: " << ec.message() << " ]\n"; #endif } m_settings = s; if (m_settings.cache_buffer_chunk_size <= 0) m_settings.cache_buffer_chunk_size = 1; update_rate_settings(); if (connections_limit_changed) update_connections_limit(); if (unchoke_limit_changed) update_unchoke_limit(); bool anonymous_mode = (m_settings.anonymous_mode != s.anonymous_mode && s.anonymous_mode); if (anonymous_mode) { m_settings.user_agent.clear(); url_random((char*)&m_peer_id[0], (char*)&m_peer_id[0] + 20); } bool force_proxy = (m_settings.force_proxy != s.force_proxy && s.force_proxy); m_udp_socket.set_force_proxy(s.force_proxy); // in force_proxy mode, we don't want to accept any incoming // connections, except through a proxy. if (force_proxy) { stop_lsd(); stop_upnp(); stop_natpmp(); #ifndef TORRENT_DISABLE_DHT stop_dht(); #endif // close the listen sockets error_code ec; for (std::list::iterator i = m_listen_sockets.begin() , end(m_listen_sockets.end()); i != end; ++i) i->sock->close(ec); m_listen_sockets.clear(); } if (m_settings.connection_speed < 0) m_settings.connection_speed = 200; if (update_disk_io_thread) update_disk_thread_settings(); if (m_settings.num_optimistic_unchoke_slots >= m_allowed_upload_slots / 2) { if (m_alerts.should_post()) m_alerts.post_alert(performance_alert(torrent_handle() , performance_alert::too_many_optimistic_unchoke_slots)); } if (s.choking_algorithm == session_settings::fixed_slots_choker) m_allowed_upload_slots = m_settings.unchoke_slots_limit; else if (s.choking_algorithm == session_settings::auto_expand_choker && m_allowed_upload_slots < m_settings.unchoke_slots_limit) m_allowed_upload_slots = m_settings.unchoke_slots_limit; if (m_allowed_upload_slots < 0) m_allowed_upload_slots = (std::numeric_limits::max)(); // 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; } tcp::endpoint session_impl::get_ipv4_interface() const { return m_ipv4_interface; } void session_impl::setup_listener(listen_socket_t* s, tcp::endpoint ep , int& retries, bool v6_only, int flags, error_code& ec) { int last_op = 0; s->sock.reset(new socket_acceptor(m_io_service)); s->sock->open(ep.protocol(), ec); last_op = listen_failed_alert::open; if (ec) { if (m_alerts.should_post()) m_alerts.post_alert(listen_failed_alert(ep, last_op, ec)); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log("failed to open socket: %s: %s" , print_endpoint(ep).c_str(), ec.message().c_str()); #endif return; } error_code err; // ignore errors here s->sock->set_option(socket_acceptor::reuse_address(true), err); #if TORRENT_USE_IPV6 if (ep.protocol() == tcp::v6()) { error_code err; // ignore errors here #ifdef IPV6_V6ONLY s->sock->set_option(v6only(v6_only), err); #endif #ifdef TORRENT_WINDOWS #ifndef PROTECTION_LEVEL_UNRESTRICTED #define PROTECTION_LEVEL_UNRESTRICTED 10 #endif // enable Teredo on windows s->sock->set_option(v6_protection_level(PROTECTION_LEVEL_UNRESTRICTED), err); #endif } #endif s->sock->bind(ep, ec); while (ec && retries > 0) { #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log("failed to bind to interface \"%s\": %s" , print_endpoint(ep).c_str(), ec.message().c_str()); #endif ec.clear(); TORRENT_ASSERT_VAL(!ec, ec); --retries; ep.port(ep.port() + 1); s->sock->bind(ep, ec); last_op = listen_failed_alert::bind; } if (ec && !(flags & session::listen_no_system_port)) { // instead of giving up, trying // let the OS pick a port ep.port(0); ec = error_code(); s->sock->bind(ep, ec); last_op = listen_failed_alert::bind; } if (ec) { // not even that worked, give up if (m_alerts.should_post()) m_alerts.post_alert(listen_failed_alert(ep, last_op, ec)); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log("cannot bind to interface \"%s\": %s" , print_endpoint(ep).c_str(), ec.message().c_str()); #endif return; } s->external_port = s->sock->local_endpoint(ec).port(); last_op = listen_failed_alert::get_peer_name; if (!ec) { s->sock->listen(m_settings.listen_queue_size, ec); last_op = listen_failed_alert::listen; } if (ec) { if (m_alerts.should_post()) m_alerts.post_alert(listen_failed_alert(ep, last_op, ec)); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log("cannot listen on interface \"%s\": %s" , print_endpoint(ep).c_str(), ec.message().c_str()); #endif return; } // if we asked the system to listen on port 0, which // socket did it end up choosing? if (ep.port() == 0) { ep.port(s->sock->local_endpoint(ec).port()); last_op = listen_failed_alert::get_peer_name; if (ec) { if (m_alerts.should_post()) m_alerts.post_alert(listen_failed_alert(ep, last_op, ec)); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING char msg[200]; snprintf(msg, 200, "failed to get peer name \"%s\": %s" , print_endpoint(ep).c_str(), ec.message().c_str()); (*m_logger) << time_now_string() << msg << "\n"; #endif } } if (m_alerts.should_post()) m_alerts.post_alert(listen_succeeded_alert(ep)); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log(" listening on: %s external port: %d" , print_endpoint(ep).c_str(), s->external_port); #endif } void session_impl::open_listen_port(int flags, error_code& ec) { TORRENT_ASSERT(is_network_thread()); TORRENT_ASSERT(!m_abort); retry: // close the open listen sockets // close the listen sockets for (std::list::iterator i = m_listen_sockets.begin() , end(m_listen_sockets.end()); i != end; ++i) i->sock->close(ec); m_listen_sockets.clear(); m_incoming_connection = false; ec.clear(); if (m_abort) return; m_ipv6_interface = tcp::endpoint(); m_ipv4_interface = tcp::endpoint(); #ifdef TORRENT_USE_OPENSSL tcp::endpoint ssl_interface = m_listen_interface; ssl_interface.port(m_settings.ssl_listen); #endif 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(&s, tcp::endpoint(address_v4::any(), m_listen_interface.port()) , m_listen_port_retries, false, flags, ec); if (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.ssl_listen) { listen_socket_t s; s.ssl = true; int retries = 10; setup_listener(&s, ssl_interface, retries, false, flags, ec); if (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()) { setup_listener(&s, tcp::endpoint(address_v6::any(), m_listen_interface.port()) , m_listen_port_retries, true, flags, ec); if (s.sock) { TORRENT_ASSERT(!m_abort); m_listen_sockets.push_back(s); } #ifdef TORRENT_USE_OPENSSL if (m_settings.ssl_listen) { listen_socket_t s; s.ssl = true; int retries = 10; setup_listener(&s, tcp::endpoint(address_v6::any(), ssl_interface.port()) , retries, false, flags, ec); if (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 ifs = enum_net_interfaces(m_io_service, ec); for (std::vector::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 { // we should only open a single listen socket, that // binds to the given interface listen_socket_t s; setup_listener(&s, m_listen_interface, m_listen_port_retries, false, flags, ec); if (s.sock) { TORRENT_ASSERT(!m_abort); m_listen_sockets.push_back(s); if (m_listen_interface.address().is_v6()) m_ipv6_interface = m_listen_interface; else m_ipv4_interface = m_listen_interface; } #ifdef TORRENT_USE_OPENSSL if (m_settings.ssl_listen) { listen_socket_t s; s.ssl = true; int retries = 10; setup_listener(&s, ssl_interface, retries, false, flags, ec); if (s.sock) { TORRENT_ASSERT(!m_abort); m_listen_sockets.push_back(s); } } #endif } m_udp_socket.bind(udp::endpoint(m_listen_interface.address(), m_listen_interface.port()), ec); if (ec) { #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log("cannot bind to UDP interface \"%s\": %s" , print_endpoint(m_listen_interface).c_str(), ec.message().c_str()); #endif if (m_listen_port_retries > 0) { m_listen_interface.port(m_listen_interface.port() + 1); --m_listen_port_retries; goto retry; } if (m_alerts.should_post()) m_alerts.post_alert(listen_failed_alert(m_listen_interface , listen_failed_alert::bind, ec)); } else { m_external_udp_port = m_udp_socket.local_port(); maybe_update_udp_mapping(0, m_listen_interface.port(), m_listen_interface.port()); maybe_update_udp_mapping(1, m_listen_interface.port(), m_listen_interface.port()); } m_udp_socket.set_option(type_of_service(m_settings.peer_tos), ec); #if defined TORRENT_VERBOSE_LOGGING (*m_logger) << ">>> SET_TOS[ udp_socket tos: " << m_settings.peer_tos << " e: " << ec.message() << " ]\n"; #endif ec.clear(); // initiate accepting on the listen sockets for (std::list::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()); } #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING m_logger = create_log("main_session", listen_port(), false); #endif } void session_impl::remap_tcp_ports(boost::uint32_t mask, int tcp_port, int ssl_port) { if ((mask & 1) && m_natpmp.get()) { 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_mapping[0] != -1) m_natpmp->delete_mapping(m_ssl_mapping[0]); m_ssl_mapping[0] = m_natpmp->add_mapping(natpmp::tcp, ssl_port, ssl_port); #endif } if ((mask & 2) && m_upnp.get()) { 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_mapping[1] != -1) m_upnp->delete_mapping(m_ssl_mapping[1]); m_ssl_mapping[1] = m_upnp->add_mapping(upnp::tcp, ssl_port, ssl_port); #endif } } void session_impl::open_new_incoming_socks_connection() { if (m_proxy.type != proxy_settings::socks5 && m_proxy.type != proxy_settings::socks5_pw && m_proxy.type != proxy_settings::socks4) return; if (m_socks_listen_socket) return; m_socks_listen_socket = boost::shared_ptr(new socket_type(m_io_service)); bool ret = instantiate_connection(m_io_service, m_proxy , *m_socks_listen_socket); TORRENT_ASSERT_VAL(ret, ret); #if defined TORRENT_ASIO_DEBUGGING add_outstanding_async("session_impl::on_socks_accept"); #endif socks5_stream& s = *m_socks_listen_socket->get(); s.set_command(2); // 2 means BIND (as opposed to CONNECT) m_socks_listen_port = m_listen_interface.port(); if (m_socks_listen_port == 0) m_socks_listen_port = 2000 + random() % 60000; s.async_connect(tcp::endpoint(address_v4::any(), m_socks_listen_port) , boost::bind(&session_impl::on_socks_accept, this, m_socks_listen_socket, _1)); } #if TORRENT_USE_I2P void session_impl::on_i2p_open(error_code const& ec) { 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(new socket_type(m_io_service)); bool ret = instantiate_connection(m_io_service, m_i2p_conn.proxy() , *m_i2p_listen_socket); TORRENT_ASSERT_VAL(ret, ret); #if defined TORRENT_ASIO_DEBUGGING add_outstanding_async("session_impl::on_i2p_accept"); #endif i2p_stream& s = *m_i2p_listen_socket->get(); 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 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 == asio::error::operation_aborted) return; if (e) { if (m_alerts.should_post()) m_alerts.post_alert(listen_failed_alert(tcp::endpoint( address_v4::any(), m_listen_interface.port()), listen_failed_alert::accept, e)); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_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* buf, int size) { #ifdef TORRENT_STATS ++m_num_messages[on_udp_counter]; #endif if (ec) { // don't bubble up operation aborted errors to the user if (ec != asio::error::operation_aborted && m_alerts.should_post()) m_alerts.post_alert(udp_error_alert(ep, ec)); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_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 const& listener, bool ssl) { TORRENT_ASSERT(!m_abort); shared_ptr c(new socket_type(m_io_service)); stream_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 >(m_io_service, &m_ssl_ctx); str = &c->get >()->next_layer(); } else #endif { c->instantiate(m_io_service); str = c->get(); } #if defined TORRENT_ASIO_DEBUGGING add_outstanding_async("session_impl::on_accept_connection"); #endif listener->async_accept(*str , boost::bind(&session_impl::on_accept_connection, this, c , boost::weak_ptr(listener), _1, ssl)); } void session_impl::on_accept_connection(shared_ptr const& s , weak_ptr listen_socket, error_code const& e, bool ssl) { #if defined TORRENT_ASIO_DEBUGGING complete_async("session_impl::on_accept_connection"); #endif #ifdef TORRENT_STATS ++m_num_messages[on_accept_counter]; #endif TORRENT_ASSERT(is_network_thread()); boost::shared_ptr listener = listen_socket.lock(); if (!listener) return; if (e == asio::error::operation_aborted) return; if (m_abort) return; error_code ec; if (e) { tcp::endpoint ep = listener->local_endpoint(ec); #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_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.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))); if (m_alerts.should_post()) m_alerts.post_alert(performance_alert( torrent_handle(), performance_alert::too_few_file_descriptors)); if (i != m_torrents.end()) { i->second->disconnect_peers(1, e); } m_settings.connections_limit = m_connections.size(); } // try again, but still alert the user of the problem async_accept(listener, ssl); } if (m_alerts.should_post()) m_alerts.post_alert(listen_failed_alert(ep, listen_failed_alert::accept, e)); return; } async_accept(listener, ssl); #ifdef TORRENT_USE_OPENSSL if (ssl) { // for SSL connections, incoming_connection() is called // after the handshake is done s->get >()->async_accept_handshake( boost::bind(&session_impl::ssl_handshake, this, _1, s)); } else #endif { incoming_connection(s); } } #ifdef TORRENT_USE_OPENSSL // to test SSL connections, one can use this openssl command template: // // openssl s_client -cert .pem -key .pem \ // -CAfile .pem -debug -connect 127.0.0.1:4433 -tls1 \ // -servername void session_impl::ssl_handshake(error_code const& ec, boost::shared_ptr s) { error_code e; tcp::endpoint endp = s->remote_endpoint(e); if (e) return; #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_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()) { m_alerts.post_alert(peer_error_alert(torrent_handle(), endp , peer_id(), ec)); } return; } incoming_connection(s); } #endif // TORRENT_USE_OPENSSL void session_impl::incoming_connection(boost::shared_ptr const& s) { TORRENT_ASSERT(is_network_thread()); #ifdef TORRENT_USE_OPENSSL // add the current time to the PRNG, to add more unpredictability boost::uint64_t now = total_microseconds(time_now_hires() - min_time()); // assume 12 bits of entropy (i.e. about 8 milliseconds) RAND_add(&now, 8, 1.5); #endif if (m_paused) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_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) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log("%s <== INCOMING CONNECTION FAILED, could " "not retrieve remote endpoint " , print_endpoint(endp).c_str(), ec.message().c_str()); #endif return; } TORRENT_ASSERT(endp.address() != address_v4::any()); /* #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" <== INCOMING CONNECTION %s type: %s" , print_endpoint(endp).c_str(), s->type_name()); #endif */ if (m_alerts.should_post()) { m_alerts.post_alert(incoming_connection_alert(s->type(), endp)); } if (!m_settings.enable_incoming_utp && s->get()) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" rejected uTP connection"); #endif if (m_alerts.should_post()) m_alerts.post_alert(peer_blocked_alert(torrent_handle(), endp.address())); return; } if (!m_settings.enable_incoming_tcp && s->get()) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" rejected TCP connection"); #endif if (m_alerts.should_post()) m_alerts.post_alert(peer_blocked_alert(torrent_handle(), endp.address())); 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_incoming_connection = true; // this filter is ignored if a single torrent // is set to ignore the filter, since this peer might be // for that torrent if (m_non_filtered_torrents == 0 && (m_ip_filter.access(endp.address()) & ip_filter::blocked)) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log("filtered blocked ip"); #endif if (m_alerts.should_post()) m_alerts.post_alert(peer_blocked_alert(torrent_handle(), endp.address())); return; } // check if we have any active torrents // if we don't reject the connection if (m_torrents.empty()) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" There are no torrents, disconnect"); #endif return; } // don't allow more connections than the max setting bool reject = false; if (m_settings.ignore_limits_on_local_network && is_local(endp.address())) reject = m_settings.connections_limit < INT_MAX / 12 && num_connections() >= m_settings.connections_limit * 12 / 10; else reject = num_connections() >= m_settings.connections_limit + m_settings.connections_slack; if (reject) { if (m_alerts.should_post()) { m_alerts.post_alert( peer_disconnected_alert(torrent_handle(), endp, peer_id() , error_code(errors::too_many_connections, get_libtorrent_category()))); } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log("number of connections limit exceeded (conns: %d" ", limit: %d slack: %d), connection rejected\n" , num_connections(), m_settings.connections_limit, m_settings.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.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) { #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" There are no _active_ torrents, disconnect"); #endif return; } } setup_socket_buffers(*s); boost::intrusive_ptr c( new bt_peer_connection(*this, s, endp, 0)); #if defined TORRENT_DEBUG || TORRENT_RELEASE_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() >= m_settings.connections_limit) c->peer_exceeds_limit(); m_connections.insert(c); c->start(); // update the next disk peer round-robin cursor if (m_next_disk_peer == m_connections.end()) m_next_disk_peer = m_connections.begin(); } } void session_impl::setup_socket_buffers(socket_type& s) { error_code ec; if (m_settings.send_socket_buffer_size) { stream_socket::send_buffer_size option( m_settings.send_socket_buffer_size); s.set_option(option, ec); } if (m_settings.recv_socket_buffer_size) { stream_socket::receive_buffer_size option( m_settings.recv_socket_buffer_size); s.set_option(option, ec); } } void session_impl::on_socks_accept(boost::shared_ptr const& s , error_code const& e) { #if defined TORRENT_ASIO_DEBUGGING complete_async("session_impl::on_socks_accept"); #endif m_socks_listen_socket.reset(); if (e == asio::error::operation_aborted) return; if (e) { if (m_alerts.should_post()) m_alerts.post_alert(listen_failed_alert(tcp::endpoint( address_v4::any(), m_listen_interface.port()), listen_failed_alert::accept, e)); return; } open_new_incoming_socks_connection(); incoming_connection(s); } void session_impl::close_connection(peer_connection const* p , error_code const& ec) { TORRENT_ASSERT(is_network_thread()); // 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 #if defined(TORRENT_LOGGING) /* session_log(" CLOSING CONNECTION %s : %s" , print_endpoint(p->remote()).c_str(), ec.message().c_str()); */ #endif TORRENT_ASSERT(p->is_disconnecting()); if (!p->is_choked() && !p->ignore_unchoke_slots()) --m_num_unchoked; TORRENT_ASSERT(p->refcount() > 0); boost::intrusive_ptr sp((peer_connection*)p); connection_map::iterator i = m_connections.find(sp); // make sure the next disk peer round-robin cursor stays valid if (m_next_disk_peer == i) ++m_next_disk_peer; if (i != m_connections.end()) m_connections.erase(i); if (m_next_disk_peer == m_connections.end()) m_next_disk_peer = m_connections.begin(); } // implements alert_dispatcher bool session_impl::post_alert(alert* a) { if (!m_alerts.should_post(a)) return false; m_alerts.post_alert_ptr(a); return true; } void session_impl::set_peer_id(peer_id const& id) { m_peer_id = id; } void session_impl::set_key(int key) { m_key = key; } void session_impl::unchoke_peer(peer_connection& c) { TORRENT_ASSERT(!c.ignore_unchoke_slots()); torrent* t = c.associated_torrent().lock().get(); TORRENT_ASSERT(t); if (t->unchoke_peer(c)) ++m_num_unchoked; } void session_impl::choke_peer(peer_connection& c) { TORRENT_ASSERT(!c.ignore_unchoke_slots()); torrent* t = c.associated_torrent().lock().get(); TORRENT_ASSERT(t); if (t->choke_peer(c)) --m_num_unchoked; } int session_impl::next_port() { std::pair const& out_ports = m_settings.outgoing_ports; 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; #if defined TORRENT_LOGGING session_log(" *** BINDING OUTGOING CONNECTION [ port: %d ]", port); #endif return port; } // this function is called from the disk-io thread // when the disk queue is low enough to post new // write jobs to it. It will go through all peer // connections that are blocked on the disk and // wake them up void session_impl::on_disk_queue() { #ifdef TORRENT_STATS ++m_num_messages[on_disk_queue_counter]; #endif TORRENT_ASSERT(is_network_thread()); // just to play it safe if (m_next_disk_peer == m_connections.end()) m_next_disk_peer = m_connections.begin(); // never loop more times than there are connections // keep in mind that connections may disconnect // while we're looping, that's why this is a reliable // way of limiting it int limit = m_connections.size(); while (m_next_disk_peer != m_connections.end() && limit > 0 && can_write_to_disk()) { --limit; peer_connection* p = m_next_disk_peer->get(); ++m_next_disk_peer; if (m_next_disk_peer == m_connections.end()) m_next_disk_peer = m_connections.begin(); if ((p->m_channel_state[peer_connection::download_channel] & peer_info::bw_disk) == 0) continue; p->on_disk(); } } // used to cache the current time // every 100 ms. This is cheaper // than a system call and can be // used where more accurate time // is not necessary extern ptime g_current_time; initialize_timer::initialize_timer() { g_current_time = time_now_hires(); } void session_impl::on_tick(error_code const& e) { #if defined TORRENT_ASIO_DEBUGGING complete_async("session_impl::on_tick"); #endif #ifdef TORRENT_STATS ++m_num_messages[on_tick_counter]; #endif TORRENT_ASSERT(is_network_thread()); ptime now = time_now_hires(); aux::g_current_time = now; // too expensive // INVARIANT_CHECK; // we have to keep ticking the utp socket manager // until they're all closed if (m_abort && m_utp_socket_manager.num_sockets() == 0) { #if defined TORRENT_ASIO_DEBUGGING fprintf(stderr, "uTP sockets left: %d\n", m_utp_socket_manager.num_sockets()); #endif return; } if (e == asio::error::operation_aborted) return; if (e) { #if defined TORRENT_LOGGING || defined TORRENT_VERBOSE_LOGGING session_log("*** TICK TIMER FAILED %s", e.message().c_str()); #endif ::abort(); return; } #if defined TORRENT_ASIO_DEBUGGING add_outstanding_async("session_impl::on_tick"); #endif error_code ec; m_timer.expires_at(now + milliseconds(m_settings.tick_interval), ec); m_timer.async_wait(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); // only tick the following once per second if (now - m_last_second_tick < seconds(1)) return; #ifndef TORRENT_DISABLE_DHT if (m_dht_interval_update_torrents < 40 && m_dht_interval_update_torrents != m_torrents.size()) update_dht_announce_interval(); #endif int tick_interval_ms = total_milliseconds(now - m_last_second_tick); m_last_second_tick = now; m_tick_residual += tick_interval_ms - 1000; int session_time = total_seconds(now - m_created); if (session_time > 65000) { // we're getting close to the point where our timestamps // in policy::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) { policy& p = i->second->get_policy(); for (policy::iterator j = p.begin_peer() , end(p.end_peer()); j != end; ++j) { policy::peer* pe = *j; if (pe->last_optimistically_unchoked < four_hours) pe->last_optimistically_unchoked = 0; else pe->last_optimistically_unchoked -= four_hours; if (pe->last_connected < four_hours) pe->last_connected = 0; else pe->last_connected -= four_hours; } } } #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)->on_tick(); } TORRENT_CATCH(std::exception&) {} } #endif // don't do any of the following while we're shutting down if (m_abort) return; // -------------------------------------------------------------- // RSS feeds // -------------------------------------------------------------- if (now > m_next_rss_update) update_rss_feeds(); switch (m_settings.mixed_mode_algorithm) { case session_settings::prefer_tcp: m_tcp_upload_channel.throttle(0); m_tcp_download_channel.throttle(0); break; case session_settings::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]; } bandwidth_channel* tcp_channel[] = { &m_tcp_upload_channel, &m_tcp_download_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 = (std::max)(stat_rate[i], lower_limit[i]); tcp_channel[i]->throttle(int(rate * num_peers[0][i] / total_peers)); } } } break; } // -------------------------------------------------------------- // auto managed torrent // -------------------------------------------------------------- if (!m_paused) m_auto_manage_time_scaler--; if (m_auto_manage_time_scaler < 0) { // [MF] first torrent is sent to the end of the queue torrent* first = NULL; for (torrent_map::iterator i = m_torrents.begin() , end(m_torrents.end()); i != end; ++i) { torrent* t = i->second.get(); TORRENT_ASSERT(t); // checking torrents are not subject to auto-management if (t->state() == torrent_status::checking_files || t->state() == torrent_status::queued_for_checking) { if (t->is_auto_managed() && t->is_paused()) t->resume(); continue; } if (t->is_auto_managed() && !t->has_error()) { if( !first || t->sequence_number() < first->sequence_number() ) first = t; } } if( first ) first->set_queue_position((std::numeric_limits::max)()); m_auto_manage_time_scaler = settings().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 if (m_last_tick - p->connected_time() > seconds(m_settings.handshake_timeout)) p->disconnect(errors::timed_out); } // -------------------------------------------------------------- // second_tick every torrent // -------------------------------------------------------------- int congested_torrents = 0; int uncongested_torrents = 0; // count the number of seeding torrents vs. downloading // torrents we are running int num_seeds = 0; int num_downloads = 0; // count the number of peers of downloading torrents int num_downloads_peers = 0; torrent_map::iterator least_recently_scraped = m_torrents.end(); int num_paused_auto_managed = 0; int num_checking = 0; int num_queued = 0; for (torrent_map::iterator i = m_torrents.begin(); i != m_torrents.end();) { torrent& t = *i->second; TORRENT_ASSERT(!t.is_aborted()); if (t.statistics().upload_rate() * 11 / 10 > t.upload_limit()) ++congested_torrents; else ++uncongested_torrents; if (t.state() == torrent_status::checking_files) ++num_checking; else if (t.state() == torrent_status::queued_for_checking && !t.is_paused()) ++num_queued; if (t.is_auto_managed() && t.is_paused() && !t.has_error()) { ++num_paused_auto_managed; if (least_recently_scraped == m_torrents.end() || least_recently_scraped->second->seconds_since_last_scrape() < t.seconds_since_last_scrape()) { least_recently_scraped = i; } } if (t.is_finished()) { ++num_seeds; } else { ++num_downloads; num_downloads_peers += t.num_peers(); } t.second_tick(m_stat, tick_interval_ms); ++i; } // some people claim that there sometimes can be cases where // there is no torrent being checked, but there are torrents // waiting to be checked. I have never seen this, and I can't // see a way for it to happen. But, if it does, start one of // the queued torrents if (num_checking == 0 && num_queued > 0 && !m_paused) { TORRENT_ASSERT(false); check_queue_t::iterator i = std::min_element(m_queued_for_checking.begin() , m_queued_for_checking.end(), boost::bind(&torrent::queue_position, _1) < boost::bind(&torrent::queue_position, _2)); if (i != m_queued_for_checking.end()) { (*i)->start_checking(); } } #ifndef TORRENT_DISABLE_DHT if (m_dht) { int dht_down; int dht_up; m_dht->network_stats(dht_up, dht_down); m_stat.sent_dht_bytes(dht_up); m_stat.received_dht_bytes(dht_down); } #endif if (m_settings.rate_limit_ip_overhead) { m_download_channel.use_quota( #ifndef TORRENT_DISABLE_DHT m_stat.download_dht() + #endif m_stat.download_tracker()); m_upload_channel.use_quota( #ifndef TORRENT_DISABLE_DHT m_stat.upload_dht() + #endif m_stat.upload_tracker()); int up_limit = m_upload_channel.throttle(); int down_limit = m_download_channel.throttle(); if (down_limit > 0 && m_stat.download_ip_overhead() >= down_limit && m_alerts.should_post()) { m_alerts.post_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()) { m_alerts.post_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); TORRENT_ASSERT(least_recently_scraped == m_torrents.end() || (least_recently_scraped->second->is_paused() && least_recently_scraped->second->is_auto_managed())); #ifdef TORRENT_STATS if (m_stats_logging_enabled) { print_log_line(tick_interval_ms, now); } #endif // -------------------------------------------------------------- // scrape paused torrents that are auto managed // (unless the session is paused) // -------------------------------------------------------------- if (!is_paused()) { --m_auto_scrape_time_scaler; if (m_auto_scrape_time_scaler <= 0) { m_auto_scrape_time_scaler = m_settings.auto_scrape_interval / (std::max)(1, num_paused_auto_managed); if (m_auto_scrape_time_scaler < m_settings.auto_scrape_min_interval) m_auto_scrape_time_scaler = m_settings.auto_scrape_min_interval; if (least_recently_scraped != m_torrents.end()) { least_recently_scraped->second->scrape_tracker(); } } } // -------------------------------------------------------------- // refresh explicit disk read cache // -------------------------------------------------------------- --m_cache_rotation_timer; if (m_settings.explicit_read_cache && m_cache_rotation_timer <= 0) { m_cache_rotation_timer = m_settings.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.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; } // -------------------------------------------------------------- // connect new peers // -------------------------------------------------------------- try_connect_more_peers(num_downloads, num_downloads_peers); // -------------------------------------------------------------- // unchoke set calculations // -------------------------------------------------------------- m_unchoke_time_scaler--; if (m_unchoke_time_scaler <= 0 && !m_connections.empty()) { m_unchoke_time_scaler = settings().unchoke_interval; recalculate_unchoke_slots(congested_torrents , uncongested_torrents); } // -------------------------------------------------------------- // optimistic unchoke calculation // -------------------------------------------------------------- m_optimistic_unchoke_time_scaler--; if (m_optimistic_unchoke_time_scaler <= 0) { m_optimistic_unchoke_time_scaler = settings().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.peer_turnover_interval; if (num_connections() >= m_settings.connections_limit * m_settings.peer_turnover_cutoff && !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.peer_turnover), 1) , i->second->get_policy().num_connect_candidates()); i->second->disconnect_peers(peers_to_disconnect , error_code(errors::optimistic_disconnect, get_libtorrent_category())); } 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 t = i->second; if (t->num_peers() < t->max_connections() * m_settings.peer_turnover_cutoff) continue; int peers_to_disconnect = (std::min)((std::max)(int(i->second->num_peers() * m_settings.peer_turnover), 1) , i->second->get_policy().num_connect_candidates()); t->disconnect_peers(peers_to_disconnect , error_code(errors::optimistic_disconnect, get_libtorrent_category())); } } } while (m_tick_residual >= 1000) m_tick_residual -= 1000; // m_peer_pool.release_memory(); } #ifdef TORRENT_STATS void session_impl::enable_stats_logging(bool s) { if (m_stats_logging_enabled == s) return; m_stats_logging_enabled = s; reset_stat_counters(); if (!s) { if (m_stats_logger) fclose(m_stats_logger); m_stats_logger = 0; } else { rotate_stats_log(); get_thread_cpu_usage(&m_network_thread_cpu_usage); } } void session_impl::reset_stat_counters() { m_end_game_piece_picker_blocks = 0; m_piece_picker_blocks = 0; m_piece_picks = 0; m_reject_piece_picks = 0; m_unchoke_piece_picks = 0; m_incoming_redundant_piece_picks = 0; m_incoming_piece_picks = 0; m_end_game_piece_picks = 0; m_snubbed_piece_picks = 0; m_connection_attempts = 0; m_num_banned_peers = 0; m_banned_for_hash_failure = 0; m_piece_requests = 0; m_max_piece_requests = 0; m_invalid_piece_requests = 0; m_choked_piece_requests = 0; m_cancelled_piece_requests = 0; m_piece_rejects = 0; memset(m_num_messages, 0, sizeof(m_num_messages)); memset(m_send_buffer_sizes, 0, sizeof(m_send_buffer_sizes)); memset(m_recv_buffer_sizes, 0, sizeof(m_recv_buffer_sizes)); } void session_impl::print_log_line(int tick_interval_ms, ptime now) { int connect_candidates = 0; int checking_torrents = 0; int stopped_torrents = 0; int upload_only_torrents = 0; int downloading_torrents = 0; int seeding_torrents = 0; int queued_seed_torrents = 0; int queued_download_torrents = 0; int error_torrents = 0; int num_peers = 0; int peer_dl_rate_buckets[7]; int peer_ul_rate_buckets[7]; memset(peer_dl_rate_buckets, 0, sizeof(peer_dl_rate_buckets)); memset(peer_ul_rate_buckets, 0, sizeof(peer_ul_rate_buckets)); int outstanding_requests = 0; int outstanding_end_game_requests = 0; int outstanding_write_blocks = 0; int peers_up_interested = 0; int peers_down_interesting = 0; int peers_up_requests = 0; int peers_down_requests = 0; int peers_up_send_buffer = 0; // number of torrents that want more peers int num_want_more_peers = 0; // number of peers among torrents with a peer limit int num_limited_peers = 0; // sum of limits of all torrents with a peer limit int total_peers_limit = 0; std::vector dq; for (torrent_map::iterator i = m_torrents.begin() , end(m_torrents.end()); i != end; ++i) { torrent* t = i->second.get(); int connection_slots = (std::max)(t->max_connections() - t->num_peers(), 0); int candidates = t->get_policy().num_connect_candidates(); connect_candidates += (std::min)(candidates, connection_slots); num_peers += t->get_policy().num_peers(); if (t->want_more_peers()) ++num_want_more_peers; if (t->max_connections() > 0) { num_limited_peers += t->num_peers(); num_limited_peers += t->max_connections(); } if (t->has_error()) ++error_torrents; else { if (t->is_paused()) { if (!t->is_auto_managed()) ++stopped_torrents; else { if (t->is_seed()) ++queued_seed_torrents; else ++queued_download_torrents; } } else { if (i->second->state() == torrent_status::checking_files || i->second->state() == torrent_status::queued_for_checking) ++checking_torrents; else if (i->second->is_seed()) ++seeding_torrents; else if (i->second->is_upload_only()) ++upload_only_torrents; else ++downloading_torrents; } } dq.clear(); i->second->get_download_queue(&dq); for (std::vector::iterator j = dq.begin() , end(dq.end()); j != end; ++j) { for (int k = 0; k < j->blocks_in_piece; ++k) { block_info& bi = j->blocks[k]; if (bi.state == block_info::requested) { ++outstanding_requests; if (bi.num_peers > 1) ++outstanding_end_game_requests; } else if (bi.state == block_info::writing) ++outstanding_write_blocks; } } } int tcp_up_rate = 0; int tcp_down_rate = 0; int utp_up_rate = 0; int utp_down_rate = 0; int utp_peak_send_delay = 0; int utp_peak_recv_delay = 0; boost::uint64_t utp_send_delay_sum = 0; boost::uint64_t utp_recv_delay_sum = 0; int num_utp_peers = 0; int num_tcp_peers = 0; int utp_num_delay_sockets = 0; int utp_num_recv_delay_sockets = 0; int num_complete_connections = 0; int num_half_open = 0; int peers_down_unchoked = 0; int peers_up_unchoked = 0; int num_end_game_peers = 0; int reading_bytes = 0; int pending_incoming_reqs = 0; for (connection_map::iterator i = m_connections.begin() , end(m_connections.end()); i != end; ++i) { peer_connection* p = i->get(); if (p->is_connecting()) { ++num_half_open; continue; } ++num_complete_connections; if (!p->is_choked()) ++peers_up_unchoked; if (!p->has_peer_choked()) ++peers_down_unchoked; if (!p->download_queue().empty()) ++peers_down_requests; if (p->is_peer_interested()) ++peers_up_interested; if (p->is_interesting()) ++peers_down_interesting; if (p->send_buffer_size() > 100 || !p->upload_queue().empty() || p->num_reading_bytes() > 0) ++peers_up_requests; if (p->endgame()) ++num_end_game_peers; reading_bytes += p->num_reading_bytes(); pending_incoming_reqs += int(p->upload_queue().size()); int dl_bucket = 0; int dl_rate = p->statistics().download_payload_rate(); if (dl_rate == 0) dl_bucket = 0; else if (dl_rate < 2000) dl_bucket = 1; else if (dl_rate < 5000) dl_bucket = 2; else if (dl_rate < 10000) dl_bucket = 3; else if (dl_rate < 50000) dl_bucket = 4; else if (dl_rate < 100000) dl_bucket = 5; else dl_bucket = 6; int ul_rate = p->statistics().upload_payload_rate(); int ul_bucket = 0; if (ul_rate == 0) ul_bucket = 0; else if (ul_rate < 2000) ul_bucket = 1; else if (ul_rate < 5000) ul_bucket = 2; else if (ul_rate < 10000) ul_bucket = 3; else if (ul_rate < 50000) ul_bucket = 4; else if (ul_rate < 100000) ul_bucket = 5; else ul_bucket = 6; ++peer_dl_rate_buckets[dl_bucket]; ++peer_ul_rate_buckets[ul_bucket]; boost::uint64_t upload_rate = int(p->statistics().upload_rate()); int buffer_size_watermark = upload_rate * m_settings.send_buffer_watermark_factor / 100; if (buffer_size_watermark < m_settings.send_buffer_low_watermark) buffer_size_watermark = m_settings.send_buffer_low_watermark; else if (buffer_size_watermark > m_settings.send_buffer_watermark) buffer_size_watermark = m_settings.send_buffer_watermark; if (p->send_buffer_size() + p->num_reading_bytes() >= buffer_size_watermark) ++peers_up_send_buffer; utp_stream* utp_socket = p->get_socket()->get(); #ifdef TORRENT_USE_OPENSSL if (!utp_socket) { ssl_stream* ssl_str = p->get_socket()->get >(); if (ssl_str) utp_socket = &ssl_str->next_layer(); } #endif if (utp_socket) { utp_up_rate += ul_rate; utp_down_rate += dl_rate; int send_delay = utp_socket->send_delay(); int recv_delay = utp_socket->recv_delay(); utp_peak_send_delay = (std::max)(utp_peak_send_delay, send_delay); utp_peak_recv_delay = (std::max)(utp_peak_recv_delay, recv_delay); if (send_delay > 0) { utp_send_delay_sum += send_delay; ++utp_num_delay_sockets; } if (recv_delay > 0) { utp_recv_delay_sum += recv_delay; ++utp_num_recv_delay_sockets; } ++num_utp_peers; } else { tcp_up_rate += ul_rate; tcp_down_rate += dl_rate; ++num_tcp_peers; } } int low_watermark = m_settings.max_queued_disk_bytes_low_watermark == 0 || m_settings.max_queued_disk_bytes_low_watermark >= m_settings.max_queued_disk_bytes ? size_type(m_settings.max_queued_disk_bytes) * 7 / 8 : m_settings.max_queued_disk_bytes_low_watermark; if (now - m_last_log_rotation > hours(1)) rotate_stats_log(); // system memory stats vm_statistics_data_t vm_stat; get_vm_stats(&vm_stat); thread_cpu_usage cur_cpu_usage; get_thread_cpu_usage(&cur_cpu_usage); if (m_stats_logger) { cache_status cs = m_disk_thread.status(); session_status sst = status(); m_read_ops.add_sample((cs.reads - m_last_cache_status.reads) * 1000.0 / float(tick_interval_ms)); m_write_ops.add_sample((cs.writes - m_last_cache_status.writes) * 1000.0 / float(tick_interval_ms)); int total_job_time = cs.cumulative_job_time == 0 ? 1 : cs.cumulative_job_time; #define STAT_LOG(type, val) fprintf(m_stats_logger, "%" #type "\t", val) STAT_LOG(f, total_milliseconds(now - m_last_log_rotation) / 1000.f); size_type uploaded = m_stat.total_upload() - m_last_uploaded; STAT_LOG(d, int(uploaded)); size_type downloaded = m_stat.total_download() - m_last_downloaded; STAT_LOG(d, int(downloaded)); STAT_LOG(d, downloading_torrents); STAT_LOG(d, seeding_torrents); STAT_LOG(d, num_complete_connections); STAT_LOG(d, num_half_open); STAT_LOG(d, m_disk_thread.disk_allocations()); STAT_LOG(d, num_peers); STAT_LOG(d, logging_allocator::allocations); STAT_LOG(d, logging_allocator::allocated_bytes); STAT_LOG(d, checking_torrents); STAT_LOG(d, stopped_torrents); STAT_LOG(d, upload_only_torrents); STAT_LOG(d, queued_seed_torrents); STAT_LOG(d, queued_download_torrents); STAT_LOG(d, m_upload_rate.queue_size()); STAT_LOG(d, m_download_rate.queue_size()); STAT_LOG(d, m_disk_queues[peer_connection::upload_channel]); STAT_LOG(d, m_disk_queues[peer_connection::download_channel]); STAT_LOG(d, m_stat.upload_rate()); STAT_LOG(d, m_stat.download_rate()); STAT_LOG(d, int(m_disk_thread.queue_buffer_size())); STAT_LOG(d, peer_dl_rate_buckets[0]); STAT_LOG(d, peer_dl_rate_buckets[1]); STAT_LOG(d, peer_dl_rate_buckets[2]); STAT_LOG(d, peer_dl_rate_buckets[3]); STAT_LOG(d, peer_dl_rate_buckets[4]); STAT_LOG(d, peer_dl_rate_buckets[5]); STAT_LOG(d, peer_dl_rate_buckets[6]); STAT_LOG(d, peer_ul_rate_buckets[0]); STAT_LOG(d, peer_ul_rate_buckets[1]); STAT_LOG(d, peer_ul_rate_buckets[2]); STAT_LOG(d, peer_ul_rate_buckets[3]); STAT_LOG(d, peer_ul_rate_buckets[4]); STAT_LOG(d, peer_ul_rate_buckets[5]); STAT_LOG(d, peer_ul_rate_buckets[6]); STAT_LOG(d, m_error_peers); STAT_LOG(d, peers_down_interesting); STAT_LOG(d, peers_down_unchoked); STAT_LOG(d, peers_down_requests); STAT_LOG(d, peers_up_interested); STAT_LOG(d, peers_up_unchoked); STAT_LOG(d, peers_up_requests); STAT_LOG(d, m_disconnected_peers); STAT_LOG(d, m_eof_peers); STAT_LOG(d, m_connreset_peers); STAT_LOG(d, outstanding_requests); STAT_LOG(d, outstanding_end_game_requests); STAT_LOG(d, outstanding_write_blocks); STAT_LOG(d, m_end_game_piece_picker_blocks); STAT_LOG(d, m_piece_picker_blocks); STAT_LOG(d, m_piece_picks); STAT_LOG(d, m_reject_piece_picks); STAT_LOG(d, m_unchoke_piece_picks); STAT_LOG(d, m_incoming_redundant_piece_picks); STAT_LOG(d, m_incoming_piece_picks); STAT_LOG(d, m_end_game_piece_picks); STAT_LOG(d, m_snubbed_piece_picks); STAT_LOG(d, m_connect_timeouts); STAT_LOG(d, m_uninteresting_peers); STAT_LOG(d, m_timeout_peers); STAT_LOG(f, (float(m_total_failed_bytes) * 100.f / (m_stat.total_payload_download() == 0 ? 1 : m_stat.total_payload_download()))); STAT_LOG(f, (float(m_total_redundant_bytes) * 100.f / (m_stat.total_payload_download() == 0 ? 1 : m_stat.total_payload_download()))); STAT_LOG(f, (float(m_stat.total_protocol_download()) * 100.f / (m_stat.total_download() == 0 ? 1 : m_stat.total_download()))); STAT_LOG(f, float(cs.average_read_time) / 1000000.f); STAT_LOG(f, float(cs.average_write_time) / 1000000.f); STAT_LOG(f, float(cs.average_queue_time) / 1000000.f); STAT_LOG(d, int(cs.job_queue_length)); STAT_LOG(d, int(cs.queued_bytes)); STAT_LOG(d, int(cs.blocks_read_hit - m_last_cache_status.blocks_read_hit)); STAT_LOG(d, int(cs.blocks_read - m_last_cache_status.blocks_read)); STAT_LOG(d, int(cs.blocks_written - m_last_cache_status.blocks_written)); STAT_LOG(d, int(m_total_failed_bytes - m_last_failed)); STAT_LOG(d, int(m_total_redundant_bytes - m_last_redundant)); STAT_LOG(d, error_torrents); STAT_LOG(d, cs.read_cache_size); STAT_LOG(d, cs.cache_size); STAT_LOG(d, cs.total_used_buffers); STAT_LOG(f, float(cs.average_hash_time) / 1000000.f); STAT_LOG(f, float(cs.average_job_time) / 1000000.f); STAT_LOG(f, float(cs.average_sort_time) / 1000000.f); STAT_LOG(d, m_connection_attempts); STAT_LOG(d, m_num_banned_peers); STAT_LOG(d, m_banned_for_hash_failure); STAT_LOG(d, m_settings.cache_size); STAT_LOG(d, m_settings.connections_limit); STAT_LOG(d, connect_candidates); STAT_LOG(d, int(m_settings.max_queued_disk_bytes)); STAT_LOG(d, low_watermark); STAT_LOG(f, float(cs.cumulative_read_time * 100.f / total_job_time)); STAT_LOG(f, float(cs.cumulative_write_time * 100.f / total_job_time)); STAT_LOG(f, float(cs.cumulative_hash_time * 100.f / total_job_time)); STAT_LOG(f, float(cs.cumulative_sort_time * 100.f / total_job_time)); STAT_LOG(d, int(cs.total_read_back - m_last_cache_status.total_read_back)); STAT_LOG(f, float(cs.total_read_back * 100.f / (cs.blocks_written == 0 ? 1: cs.blocks_written))); STAT_LOG(d, cs.read_queue_size); STAT_LOG(f, float(tick_interval_ms) / 1000.f); STAT_LOG(f, float(m_tick_residual) / 1000.f); STAT_LOG(d, m_allowed_upload_slots); STAT_LOG(d, m_settings.unchoke_slots_limit * 2); STAT_LOG(d, m_stat.low_pass_upload_rate()); STAT_LOG(d, m_stat.low_pass_download_rate()); STAT_LOG(d, num_end_game_peers); STAT_LOG(d, tcp_up_rate); STAT_LOG(d, tcp_down_rate); STAT_LOG(d, int(m_tcp_upload_channel.throttle())); STAT_LOG(d, int(m_tcp_download_channel.throttle())); STAT_LOG(d, utp_up_rate); STAT_LOG(d, utp_down_rate); STAT_LOG(f, float(utp_peak_send_delay) / 1000000.f); STAT_LOG(f, float(utp_num_delay_sockets ? float(utp_send_delay_sum) / float(utp_num_delay_sockets) : 0) / 1000000.f); STAT_LOG(f, float(utp_peak_recv_delay) / 1000000.f); STAT_LOG(f, float(utp_num_recv_delay_sockets ? float(utp_recv_delay_sum) / float(utp_num_recv_delay_sockets) : 0) / 1000000.f); STAT_LOG(f, float(cs.reads - m_last_cache_status.reads) * 1000.0 / float(tick_interval_ms)); STAT_LOG(f, float(cs.writes - m_last_cache_status.writes) * 1000.0 / float(tick_interval_ms)); STAT_LOG(d, int(vm_stat.active_count)); STAT_LOG(d, int(vm_stat.inactive_count)); STAT_LOG(d, int(vm_stat.wire_count)); STAT_LOG(d, int(vm_stat.free_count)); STAT_LOG(d, int(vm_stat.pageins - m_last_vm_stat.pageins)); STAT_LOG(d, int(vm_stat.pageouts - m_last_vm_stat.pageouts)); STAT_LOG(d, int(vm_stat.faults - m_last_vm_stat.faults)); STAT_LOG(d, m_read_ops.mean()); STAT_LOG(d, m_write_ops.mean()); STAT_LOG(d, reading_bytes); for (int i = 0; i < max_messages; ++i) STAT_LOG(d, m_num_messages[i]); int num_max = sizeof(m_send_buffer_sizes)/sizeof(m_send_buffer_sizes[0]); for (int i = 0; i < num_max; ++i) STAT_LOG(d, m_send_buffer_sizes[i]); num_max = sizeof(m_recv_buffer_sizes)/sizeof(m_recv_buffer_sizes[0]); for (int i = 0; i < num_max; ++i) STAT_LOG(d, m_recv_buffer_sizes[i]); STAT_LOG(f, total_microseconds(cur_cpu_usage.user_time - m_network_thread_cpu_usage.user_time) / double(tick_interval_ms * 10)); STAT_LOG(f, (total_microseconds(cur_cpu_usage.system_time - m_network_thread_cpu_usage.system_time) + total_microseconds(cur_cpu_usage.user_time - m_network_thread_cpu_usage.user_time)) / double(tick_interval_ms * 10)); for (int i = 0; i < torrent::waste_reason_max; ++i) STAT_LOG(f, (m_redundant_bytes[i] * 100.) / double(m_total_redundant_bytes == 0 ? 1 : m_total_redundant_bytes)); STAT_LOG(d, m_no_memory_peers); STAT_LOG(d, m_too_many_peers); STAT_LOG(d, m_transport_timeout_peers); STAT_LOG(d, sst.utp_stats.num_idle); STAT_LOG(d, sst.utp_stats.num_syn_sent); STAT_LOG(d, sst.utp_stats.num_connected); STAT_LOG(d, sst.utp_stats.num_fin_sent); STAT_LOG(d, sst.utp_stats.num_close_wait); STAT_LOG(d, num_tcp_peers); STAT_LOG(d, num_utp_peers); STAT_LOG(d, m_connrefused_peers); STAT_LOG(d, m_connaborted_peers); STAT_LOG(d, m_perm_peers); STAT_LOG(d, m_buffer_peers); STAT_LOG(d, m_unreachable_peers); STAT_LOG(d, m_broken_pipe_peers); STAT_LOG(d, m_addrinuse_peers); STAT_LOG(d, m_no_access_peers); STAT_LOG(d, m_invalid_arg_peers); STAT_LOG(d, m_aborted_peers); STAT_LOG(d, m_error_incoming_peers); STAT_LOG(d, m_error_outgoing_peers); STAT_LOG(d, m_error_rc4_peers); STAT_LOG(d, m_error_encrypted_peers); STAT_LOG(d, m_error_tcp_peers); STAT_LOG(d, m_error_utp_peers); STAT_LOG(d, int(m_connections.size())); STAT_LOG(d, pending_incoming_reqs); STAT_LOG(f, num_complete_connections == 0 ? 0.f : (float(pending_incoming_reqs) / num_complete_connections)); STAT_LOG(d, num_want_more_peers); STAT_LOG(f, total_peers_limit == 0 ? 0 : float(num_limited_peers) / total_peers_limit); STAT_LOG(d, m_piece_requests); STAT_LOG(d, m_max_piece_requests); STAT_LOG(d, m_invalid_piece_requests); STAT_LOG(d, m_choked_piece_requests); STAT_LOG(d, m_cancelled_piece_requests); STAT_LOG(d, m_piece_rejects); STAT_LOG(d, peers_up_send_buffer); fprintf(m_stats_logger, "\n"); #undef STAT_LOG m_last_cache_status = cs; m_last_vm_stat = vm_stat; m_network_thread_cpu_usage = cur_cpu_usage; m_last_failed = m_total_failed_bytes; m_last_redundant = m_total_redundant_bytes; m_last_uploaded = m_stat.total_upload(); m_last_downloaded = m_stat.total_download(); } reset_stat_counters(); } #endif // TORRENT_STATS void session_impl::update_rss_feeds() { time_t now_posix = time(0); ptime min_update = max_time(); ptime now = time_now(); for (std::vector >::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); ptime next_update = now + seconds(delta); if (next_update < min_update) min_update = next_update; } m_next_rss_update = min_update; } void session_impl::prioritize_connections(boost::weak_ptr 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_network_thread()); if (m_dht) m_dht->add_node(n); } void session_impl::prioritize_dht(boost::weak_ptr t) { m_dht_torrents.push_back(t); // trigger a DHT announce right away if we just // added a new torrent and there's no back-log 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_network_thread()); if (e) return; if (m_abort) return; #if defined TORRENT_ASIO_DEBUGGING add_outstanding_async("session_impl::on_dht_announce"); #endif // announce to DHT every 15 minutes int delay = (std::max)(m_settings.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); } 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 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(); ++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 #ifdef TORRENT_STATS ++m_num_messages[on_lsd_counter]; #endif TORRENT_ASSERT(is_network_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.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(); } namespace { bool is_active(torrent* t, session_settings const& s) { // if we count slow torrents, every torrent // is considered active if (!s.dont_count_slow_torrents) return true; // if the torrent started less than 2 minutes // ago (default), let it count as active since // the rates are probably not accurate yet if (time_now() - t->started() < seconds(s.auto_manage_startup)) return true; return t->statistics().upload_payload_rate() != 0.f || t->statistics().download_payload_rate() != 0.f; } } void session_impl::auto_manage_torrents(std::vector& list , int& dht_limit, int& tracker_limit, int& lsd_limit , int& hard_limit, int type_limit) { for (std::vector::iterator i = list.begin() , end(list.end()); i != end; ++i) { torrent* t = *i; if ((t->state() == torrent_status::checking_files || t->state() == torrent_status::queued_for_checking)) continue; --dht_limit; --lsd_limit; --tracker_limit; t->set_announce_to_dht(dht_limit >= 0); t->set_announce_to_trackers(tracker_limit >= 0); t->set_announce_to_lsd(lsd_limit >= 0); if (!t->is_paused() && !is_active(t, settings()) && hard_limit > 0) { --hard_limit; continue; } if (type_limit > 0 && hard_limit > 0) { --hard_limit; --type_limit; #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING //t->log_to_all_peers("AUTO MANAGER STARTING TORRENT"); #endif t->set_allow_peers(true); } else { #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING //t->log_to_all_peers("AUTO MANAGER PAUSING TORRENT"); #endif // use graceful pause for auto-managed torrents t->set_allow_peers(false, true); } } } void session_impl::recalculate_auto_managed_torrents() { INVARIANT_CHECK; m_need_auto_manage = false; // these vectors are filled with auto managed torrents std::vector downloaders; downloaders.reserve(m_torrents.size()); std::vector seeds; seeds.reserve(m_torrents.size()); // these counters are set to the number of torrents // of each kind we're allowed to have active int num_downloaders = settings().active_downloads; int num_seeds = settings().active_seeds; int dht_limit = settings().active_dht_limit; int tracker_limit = settings().active_tracker_limit; int lsd_limit = settings().active_lsd_limit; int hard_limit = settings().active_limit; if (num_downloaders == -1) num_downloaders = (std::numeric_limits::max)(); if (num_seeds == -1) num_seeds = (std::numeric_limits::max)(); if (hard_limit == -1) hard_limit = (std::numeric_limits::max)(); if (dht_limit == -1) dht_limit = (std::numeric_limits::max)(); if (lsd_limit == -1) lsd_limit = (std::numeric_limits::max)(); if (tracker_limit == -1) tracker_limit = (std::numeric_limits::max)(); for (torrent_map::iterator i = m_torrents.begin() , end(m_torrents.end()); i != end; ++i) { torrent* t = i->second.get(); TORRENT_ASSERT(t); // checking torrents are not subject to auto-management if (t->state() == torrent_status::checking_files || t->state() == torrent_status::queued_for_checking) { if (t->is_auto_managed() && t->is_paused()) t->resume(); continue; } if (t->is_auto_managed() && !t->has_error()) { TORRENT_ASSERT(t->m_resume_data_loaded || !t->valid_metadata()); // this torrent is auto managed, add it to // the list (depending on if it's a seed or not) if (t->is_finished()) seeds.push_back(t); else downloaders.push_back(t); } //else if (!t->is_paused()) // [MF] don't check non-auto managed torrents against limits for now. // FIXME: another strategy is required as definitive fix. else if (!t->is_paused() && t->is_auto_managed()) { TORRENT_ASSERT(t->m_resume_data_loaded || !t->valid_metadata()); --hard_limit; if (is_active(t, settings())) { // this is not an auto managed torrent, // if it's running and active, decrease the // counters. if (t->is_finished()) --num_seeds; else --num_downloaders; } } } bool handled_by_extension = false; #ifndef TORRENT_DISABLE_EXTENSIONS // TODO: 0 allow extensions to sort torrents for queuing #endif if (!handled_by_extension) { std::sort(downloaders.begin(), downloaders.end() , boost::bind(&torrent::sequence_number, _1) < boost::bind(&torrent::sequence_number, _2)); std::sort(seeds.begin(), seeds.end() , boost::bind(&torrent::seed_rank, _1, boost::ref(m_settings)) > boost::bind(&torrent::seed_rank, _2, boost::ref(m_settings))); } if (settings().auto_manage_prefer_seeds) { auto_manage_torrents(seeds, dht_limit, tracker_limit, lsd_limit , hard_limit, num_seeds); auto_manage_torrents(downloaders, dht_limit, tracker_limit, lsd_limit , hard_limit, num_downloaders); } else { auto_manage_torrents(downloaders, dht_limit, tracker_limit, lsd_limit , hard_limit, num_downloaders); auto_manage_torrents(seeds, dht_limit, tracker_limit, lsd_limit , hard_limit, num_seeds); } } void session_impl::recalculate_optimistic_unchoke_slots() { TORRENT_ASSERT(is_network_thread()); if (m_allowed_upload_slots == 0) return; std::vector opt_unchoke; 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; if (pi->web_seed) continue; torrent* t = p->associated_torrent().lock().get(); if (!t) continue; if (t->is_paused()) continue; if (pi->optimistically_unchoked) { TORRENT_ASSERT(!p->is_choked()); opt_unchoke.push_back(pi); } if (!p->is_connecting() && !p->is_disconnecting() && p->is_peer_interested() && t->free_upload_slots() && p->is_choked() && !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 // avoid having a bias towards peers that happen to be sorted first std::random_shuffle(opt_unchoke.begin(), opt_unchoke.end()); // sort all candidates based on when they were last optimistically // unchoked. std::sort(opt_unchoke.begin(), opt_unchoke.end() , boost::bind(&policy::peer::last_optimistically_unchoked, _1) < boost::bind(&policy::peer::last_optimistically_unchoked, _2)); int num_opt_unchoke = m_settings.num_optimistic_unchoke_slots; if (num_opt_unchoke == 0) num_opt_unchoke = (std::max)(1, m_allowed_upload_slots / 5); // unchoke the first num_opt_unchoke peers in the candidate set // and make sure that the others are choked for (std::vector::iterator i = opt_unchoke.begin() , end(opt_unchoke.end()); i != end; ++i) { policy::peer* pi = *i; if (num_opt_unchoke > 0) { --num_opt_unchoke; if (!pi->optimistically_unchoked) { torrent* t = pi->connection->associated_torrent().lock().get(); bool ret = t->unchoke_peer(*pi->connection, true); if (ret) { pi->optimistically_unchoked = true; ++m_num_unchoked; pi->last_optimistically_unchoked = session_time(); } else { // we failed to unchoke it, increment the count again ++num_opt_unchoke; } } } else { if (pi->optimistically_unchoked) { torrent* t = pi->connection->associated_torrent().lock().get(); pi->optimistically_unchoked = false; t->choke_peer(*pi->connection); --m_num_unchoked; } } } } void session_impl::try_connect_more_peers(int num_downloads, int num_downloads_peers) { // 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 // equally likely to connect to a peer int free_slots = m_half_open.free_slots(); int max_connections = m_settings.connection_speed; // 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; } } // 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 int limit = (std::min)(m_settings.connections_limit - num_connections(), free_slots); if (m_settings.smooth_connects && max_connections > (limit+1) / 2) max_connections = (limit+1) / 2; // TODO: use a lower limit than m_settings.connections_limit // to allocate the to 10% or so of connection slots for incoming // connections if (!m_torrents.empty() && free_slots > -m_half_open.limit() && num_connections() < m_settings.connections_limit && !m_abort && m_settings.connection_speed > 0 && max_connections > 0) { // this is the maximum number of connections we will // attempt this tick int average_peers = 0; if (num_downloads > 0) average_peers = num_downloads_peers / num_downloads; if (m_next_connect_torrent == m_torrents.end()) m_next_connect_torrent = m_torrents.begin(); int steps_since_last_connect = 0; int num_torrents = int(m_torrents.size()); for (;;) { torrent& t = *m_next_connect_torrent->second; if (t.want_more_peers()) { TORRENT_ASSERT(t.allows_peers()); // have a bias to give more connection attempts // to downloading torrents than seed, and even // more to downloading torrents with less than // average number of connections int num_attempts = 1; if (!t.is_finished()) { // TODO: make this bias configurable // TODO: also take average_peers into account, to create a bias for downloading torrents with < average peers TORRENT_ASSERT(m_num_active_downloading > 0); num_attempts += m_num_active_finished / m_num_active_downloading; } while (m_current_connect_attempts < num_attempts) { TORRENT_TRY { ++m_current_connect_attempts; if (t.try_connect_peer()) { --max_connections; --free_slots; steps_since_last_connect = 0; #ifdef TORRENT_STATS ++m_connection_attempts; #endif } } 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.connections_limit = num_connections(); if (m_settings.connections_limit < 2) m_settings.connections_limit = 2; } if (!t.want_more_peers()) break; if (free_slots <= -m_half_open.limit()) return; if (max_connections == 0) return; if (num_connections() >= m_settings.connections_limit) return; } } ++m_next_connect_torrent; m_current_connect_attempts = 0; ++steps_since_last_connect; if (m_next_connect_torrent == m_torrents.end()) m_next_connect_torrent = m_torrents.begin(); // if we have gone a whole loop without // handing out a single connection, break if (steps_since_last_connect > num_torrents + 1) break; // if there are no more free connection slots, abort if (free_slots <= -m_half_open.limit()) 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_settings.connections_limit) break; } } } void session_impl::recalculate_unchoke_slots(int congested_torrents , int uncongested_torrents) { TORRENT_ASSERT(is_network_thread()); INVARIANT_CHECK; ptime now = time_now(); time_duration unchoke_interval = now - m_last_choke; m_last_choke = now; // build list of all peers that are // unchokable. std::vector peers; for (connection_map::iterator i = m_connections.begin(); i != m_connections.end();) { boost::intrusive_ptr p = *i; TORRENT_ASSERT(p); ++i; torrent* t = p->associated_torrent().lock().get(); policy::peer* pi = p->peer_info_struct(); if (p->ignore_unchoke_slots() || t == 0 || pi == 0 || pi->web_seed || t->is_paused()) continue; if (m_settings.choking_algorithm == session_settings::bittyrant_choker) { if (!p->is_choked() && p->is_interesting()) { if (!p->has_peer_choked()) { // we're unchoked, we may want to lower our estimated // reciprocation rate p->decrease_est_reciprocation_rate(); } else { // we've unchoked this peer, and it hasn't reciprocated // we may want to increase our estimated reciprocation rate p->increase_est_reciprocation_rate(); } } } if (!p->is_peer_interested() || p->is_disconnecting() || p->is_connecting() || (p->share_diff() < -free_upload_amount && !t->is_seed())) { // this peer is not unchokable. So, if it's unchoked // already, make sure to choke it. if (p->is_choked()) continue; if (pi && pi->optimistically_unchoked) { pi->optimistically_unchoked = false; // force a new optimistic unchoke m_optimistic_unchoke_time_scaler = 0; } t->choke_peer(*p); continue; } peers.push_back(p.get()); } if (m_settings.choking_algorithm == session_settings::rate_based_choker) { m_allowed_upload_slots = 0; std::sort(peers.begin(), peers.end() , boost::bind(&peer_connection::upload_rate_compare, _1, _2)); #ifdef TORRENT_DEBUG for (std::vector::const_iterator i = peers.begin() , end(peers.end()), prev(peers.end()); i != end; ++i) { if (prev != end) { boost::shared_ptr t1 = (*prev)->associated_torrent().lock(); TORRENT_ASSERT(t1); boost::shared_ptr t2 = (*i)->associated_torrent().lock(); TORRENT_ASSERT(t2); TORRENT_ASSERT((*prev)->uploaded_in_last_round() * 1000 * (1 + t1->priority()) / total_milliseconds(unchoke_interval) >= (*i)->uploaded_in_last_round() * 1000 * (1 + t2->priority()) / total_milliseconds(unchoke_interval)); } prev = i; } #endif // TODO: make configurable int rate_threshold = 1024; for (std::vector::const_iterator i = peers.begin() , end(peers.end()); i != end; ++i) { peer_connection const& p = **i; int rate = int(p.uploaded_in_last_round() * 1000 / total_milliseconds(unchoke_interval)); if (rate < rate_threshold) break; ++m_allowed_upload_slots; // TODO: make configurable rate_threshold += 1024; } // allow one optimistic unchoke ++m_allowed_upload_slots; } if (m_settings.choking_algorithm == session_settings::bittyrant_choker) { // if we're using the bittyrant choker, sort peers by their return // on investment. i.e. download rate / upload rate std::sort(peers.begin(), peers.end() , boost::bind(&peer_connection::bittyrant_unchoke_compare, _1, _2)); } else { // sorts 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() , boost::bind(&peer_connection::unchoke_compare, _1, _2)); } // auto unchoke int upload_limit = m_bandwidth_channel[peer_connection::upload_channel]->throttle(); if (m_settings.choking_algorithm == session_settings::auto_expand_choker && upload_limit > 0) { // if our current upload rate is less than 90% of our // limit AND most torrents are not "congested", i.e. // they are not holding back because of a per-torrent // limit if (m_stat.upload_rate() < upload_limit * 0.9f && m_allowed_upload_slots <= m_num_unchoked + 1 && congested_torrents < uncongested_torrents && m_upload_rate.queue_size() < 2) { ++m_allowed_upload_slots; } else if (m_upload_rate.queue_size() > 1 && m_allowed_upload_slots > m_settings.unchoke_slots_limit && m_settings.unchoke_slots_limit >= 0) { --m_allowed_upload_slots; } } int num_opt_unchoke = m_settings.num_optimistic_unchoke_slots; if (num_opt_unchoke == 0) num_opt_unchoke = (std::max)(1, m_allowed_upload_slots / 5); // reserve some upload slots for optimistic unchokes int unchoke_set_size = m_allowed_upload_slots - num_opt_unchoke; int upload_capacity_left = 0; if (m_settings.choking_algorithm == session_settings::bittyrant_choker) { upload_capacity_left = m_upload_channel.throttle(); if (upload_capacity_left == 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 upload_capacity_left = (std::max)(20000, m_peak_up_rate + 10000); if (m_alerts.should_post()) m_alerts.post_alert(performance_alert(torrent_handle() , performance_alert::bittyrant_with_no_uplimit)); } } 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_ASSERT(!p->ignore_unchoke_slots()); // this will update the m_uploaded_at_last_unchoke // #error this should be called for all peers! p->reset_choke_counters(); torrent* t = p->associated_torrent().lock().get(); TORRENT_ASSERT(t); // if this peer should be unchoked depends on different things // in different unchoked schemes bool unchoke = false; if (m_settings.choking_algorithm == session_settings::bittyrant_choker) { unchoke = p->est_reciprocation_rate() <= upload_capacity_left; } else { unchoke = unchoke_set_size > 0; } if (unchoke) { upload_capacity_left -= p->est_reciprocation_rate(); // yes, this peer should be unchoked 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 // since this one just got promoted into the // proper unchoke set m_optimistic_unchoke_time_scaler = 0; p->peer_info_struct()->optimistically_unchoked = false; } } else { // no, this peer should be shoked 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; } } } #if defined _MSC_VER && defined TORRENT_DEBUG static void straight_to_debugger(unsigned int, _EXCEPTION_POINTERS*) { throw; } #endif void session_impl::main_thread() { #if defined _MSC_VER && defined TORRENT_DEBUG // workaround for microsofts // hardware exceptions that makes // it hard to debug stuff ::_set_se_translator(straight_to_debugger); #endif #if (defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS) && defined BOOST_HAS_PTHREADS m_network_thread = pthread_self(); #endif TORRENT_ASSERT(is_network_thread()); // initialize async operations init(); bool stop_loop = false; while (!stop_loop) { error_code ec; m_io_service.run(ec); if (ec) { #ifdef TORRENT_DEBUG fprintf(stderr, "%s\n", ec.message().c_str()); std::string err = ec.message(); #endif TORRENT_ASSERT(false); } m_io_service.reset(); stop_loop = m_abort; } #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log(" locking mutex"); #endif /* #ifdef TORRENT_DEBUG 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) session_log(" cleaning up torrents"); #endif m_torrents.clear(); TORRENT_ASSERT(m_torrents.empty()); TORRENT_ASSERT(m_connections.empty()); #if (defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS) && defined BOOST_HAS_PTHREADS m_network_thread = 0; #endif } // 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) const { TORRENT_ASSERT(is_network_thread()); torrent_map::const_iterator i = m_torrents.find(info_hash); #ifdef TORRENT_DEBUG 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(); } boost::weak_ptr session_impl::find_torrent(std::string const& uuid) const { TORRENT_ASSERT(is_network_thread()); std::map >::const_iterator i = m_uuids.find(uuid); if (i != m_uuids.end()) return i->second; return boost::weak_ptr(); } // 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(); } boost::weak_ptr session_impl::find_disconnect_candidate_torrent() const { aux::session_impl::torrent_map::const_iterator i = std::min_element(m_torrents.begin(), m_torrents.end() , boost::bind(&compare_disconnect_torrent, _1, _2)); TORRENT_ASSERT(i != m_torrents.end()); if (i == m_torrents.end()) return boost::shared_ptr(); return i->second; } #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING boost::shared_ptr session_impl::create_log(std::string const& name , int instance, bool append) { error_code ec; // current options are file_logger, cout_logger and null_logger return boost::shared_ptr(new logger(m_logpath, name, instance, append)); } void session_impl::session_log(char const* fmt, ...) const { if (!m_logger) return; va_list v; va_start(v, fmt); char usr[400]; vsnprintf(usr, sizeof(usr), fmt, v); va_end(v); char buf[450]; snprintf(buf, sizeof(buf), "%s: %s\n", time_now_string(), usr); // printf is the bitcoin/util.h logger printf("%s", buf); //(*m_logger) << buf; } #endif void session_impl::get_torrent_status(std::vector* ret , boost::function 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* ret , boost::uint32_t flags) const { for (std::vector::iterator i = ret->begin(), end(ret->end()); i != end; ++i) { boost::shared_ptr t = i->handle.m_torrent.lock(); if (!t) continue; t->status(&*i, flags); } } void session_impl::post_torrent_updates() { INVARIANT_CHECK; TORRENT_ASSERT(is_network_thread()); std::auto_ptr alert(new state_update_alert()); alert->status.reserve(m_state_updates.size()); #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_posting_torrent_updates = true; #endif for (std::vector >::iterator i = m_state_updates.begin() , end(m_state_updates.end()); i != end; ++i) { boost::shared_ptr t = i->lock(); if (!t) continue; alert->status.push_back(torrent_status()); t->status(&alert->status.back(), 0xffffffff); t->clear_in_state_update(); } m_state_updates.clear(); #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_posting_torrent_updates = false; #endif m_alerts.post_alert_ptr(alert.release()); } std::vector session_impl::get_torrents() const { std::vector 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) { error_code ec; torrent_handle handle = add_torrent(*params, ec); delete params; } torrent_handle session_impl::add_torrent(add_torrent_params const& p , error_code& ec) { torrent_handle h = add_torrent_impl(p, ec); m_alerts.post_alert(add_torrent_alert(h, p, ec)); return h; } torrent_handle session_impl::add_torrent_impl(add_torrent_params const& p , error_code& ec) { TORRENT_ASSERT(!p.save_path.empty()); #ifndef TORRENT_NO_DEPRECATE p.update_flags(); #endif add_torrent_params params = p; if (string_begins_no_case("magnet:", params.url.c_str())) { parse_magnet_uri(params.url, params, ec); if (ec) return torrent_handle(); params.url.clear(); } if (params.ti && params.ti->is_valid() && params.ti->num_files() == 0) { ec = errors::no_files_in_torrent; return torrent_handle(); } #ifndef TORRENT_DISABLE_DHT // add p.dht_nodes to the DHT, if enabled if (m_dht && !p.dht_nodes.empty()) { for (std::vector >::const_iterator i = p.dht_nodes.begin() , end(p.dht_nodes.end()); i != end; ++i) m_dht->add_node(*i); } #endif // INVARIANT_CHECK; if (is_aborted()) { ec = errors::session_is_closing; return torrent_handle(); } // figure out the info hash of the torrent sha1_hash const* ih = 0; sha1_hash tmp; if (params.ti) ih = ¶ms.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 tmp = hasher(¶ms.url[0], params.url.size()).final(); ih = &tmp; } else ih = ¶ms.info_hash; // we don't have a torrent file. If the user provided // resume data, there may be some metadata in there if ((!params.ti || !params.ti->is_valid()) && !params.resume_data.empty()) { int pos; error_code ec; lazy_entry tmp; lazy_entry const* info = 0; #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING session_log("adding magnet link with resume data"); #endif if (lazy_bdecode(¶ms.resume_data[0], ¶ms.resume_data[0] + params.resume_data.size(), tmp, ec, &pos) == 0 && tmp.type() == lazy_entry::dict_t /* && (info = tmp.dict_find_dict("info")) */) { #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_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 /* [MF] std::pair buf = info->data_section(); sha1_hash resume_ih = hasher(buf.first, buf.second).final(); */ std::string info_hash = tmp.dict_find_string_value("info-hash"); sha1_hash resume_ih = sha1_hash(info_hash); // 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()) { #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING session_log("info-hash matched"); #endif params.ti = new torrent_info(resume_ih, params.name); /* if (params.ti->parse_info_section(*info, ec, 0)) { #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_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; ih = ¶ms.info_hash; } else { #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log("failed to load metadata from resume file: %s" , ec.message().c_str()); #endif } */ } #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING else { session_log("metadata info-hash failed"); } #endif } #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING else { session_log("no metadata found"); } #endif } // is the torrent already active? boost::shared_ptr torrent_ptr = find_torrent(*ih).lock(); if (!torrent_ptr && !params.uuid.empty()) torrent_ptr = find_torrent(params.uuid).lock(); // TODO: 2 if we still can't find the torrent, we should probably look for it by url here 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 torrent_handle(torrent_ptr); } ec = errors::duplicate_torrent; return torrent_handle(); } int queue_pos = 0; for (torrent_map::const_iterator i = m_torrents.begin() , end(m_torrents.end()); i != end; ++i) { int pos = i->second->queue_position(); if (pos >= queue_pos) queue_pos = pos + 1; } torrent_ptr.reset(new torrent(*this, m_listen_interface , 16 * 1024, queue_pos, params, *ih)); torrent_ptr->start(); #ifndef TORRENT_DISABLE_EXTENSIONS for (ses_extension_list_t::iterator i = m_ses_extensions.begin() , end(m_ses_extensions.end()); i != end; ++i) { boost::shared_ptr tp((*i)->new_torrent(torrent_ptr.get(), params.userdata)); if (tp) torrent_ptr->add_extension(tp); } #endif #ifndef TORRENT_DISABLE_DHT if (m_dht && params.ti) { torrent_info::nodes_t const& nodes = params.ti->nodes(); std::for_each(nodes.begin(), nodes.end(), boost::bind( (void(dht::dht_tracker::*)(std::pair const&)) &dht::dht_tracker::add_node , boost::ref(m_dht), _1)); } #endif m_torrents.insert(std::make_pair(*ih, torrent_ptr)); if (!params.uuid.empty() || !params.url.empty()) m_uuids.insert(std::make_pair(params.uuid.empty() ? params.url : params.uuid, torrent_ptr)); if (m_alerts.should_post()) m_alerts.post_alert(torrent_added_alert(torrent_ptr->get_handle())); // 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) trigger_auto_manage(); return torrent_handle(torrent_ptr); } void session_impl::queue_check_torrent(boost::shared_ptr const& t) { if (m_abort) return; TORRENT_ASSERT(t->should_check_files()); TORRENT_ASSERT(t->state() != torrent_status::checking_files); if (m_queued_for_checking.empty()) t->start_checking(); else t->set_state(torrent_status::queued_for_checking); TORRENT_ASSERT(std::find(m_queued_for_checking.begin() , m_queued_for_checking.end(), t) == m_queued_for_checking.end()); m_queued_for_checking.push_back(t); } void session_impl::dequeue_check_torrent(boost::shared_ptr const& t) { INVARIANT_CHECK; TORRENT_ASSERT(t->state() == torrent_status::checking_files || t->state() == torrent_status::queued_for_checking); if (m_queued_for_checking.empty()) return; boost::shared_ptr next_check = *m_queued_for_checking.begin(); check_queue_t::iterator done = m_queued_for_checking.end(); for (check_queue_t::iterator i = m_queued_for_checking.begin() , end(m_queued_for_checking.end()); i != end; ++i) { // the reason m_paused is in there is because when the session // is paused, all torrents that are queued ar all of a sudden // not supposed to be queued anymore. The first torrent that gets // removed from the queue will hence trigger this assert, without // the m_paused exception TORRENT_ASSERT(*i == t || (*i)->should_check_files() || m_paused); if (*i == t) done = i; else if (next_check == t || next_check->queue_position() > (*i)->queue_position()) next_check = *i; } TORRENT_ASSERT(next_check != t || m_queued_for_checking.size() == 1); // only start a new one if we removed the one that is checking TORRENT_ASSERT(done != m_queued_for_checking.end()); if (done == m_queued_for_checking.end()) return; if (next_check != t && t->state() == torrent_status::checking_files && !m_paused) { next_check->start_checking(); } m_queued_for_checking.erase(done); } void session_impl::remove_torrent(const torrent_handle& h, int options) { INVARIANT_CHECK; boost::shared_ptr tptr = h.m_torrent.lock(); if (!tptr) return; remove_torrent_impl(tptr, options); if (m_alerts.should_post()) m_alerts.post_alert(torrent_removed_alert(tptr->get_handle(), tptr->info_hash())); tptr->abort(); tptr->set_queue_position(-1); } void session_impl::remove_torrent_impl(boost::shared_ptr tptr, int options) { // remove from uuid list if (!tptr->uuid().empty()) { std::map >::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 & session::delete_files) { if (!t.delete_files()) { if (m_alerts.should_post()) m_alerts.post_alert(torrent_delete_failed_alert(t.get_handle(), error_code())); } } tptr->update_guage(); #if defined TORRENT_DEBUG || TORRENT_RELEASE_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; if (i == m_next_connect_torrent) ++m_next_connect_torrent; m_torrents.erase(i); #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(); if (m_next_connect_torrent == m_torrents.end()) m_next_connect_torrent = m_torrents.begin(); std::list >::iterator k = std::find(m_queued_for_checking.begin(), m_queued_for_checking.end(), tptr); if (k != m_queued_for_checking.end()) m_queued_for_checking.erase(k); TORRENT_ASSERT(m_torrents.find(i_hash) == m_torrents.end()); } void session_impl::listen_on( std::pair const& port_range , error_code& ec , const char* net_interface, int flags) { INVARIANT_CHECK; tcp::endpoint new_interface; if (net_interface && std::strlen(net_interface) > 0) { new_interface = tcp::endpoint(address::from_string(net_interface, ec), port_range.first); if (ec) { if (m_alerts.should_post()) m_alerts.post_alert(listen_failed_alert(new_interface, listen_failed_alert::parse_addr, ec)); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING session_log("listen_on: %s failed: %s" , net_interface, ec.message().c_str()); #endif return; } } 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; m_listen_interface = new_interface; open_listen_port(flags, ec); #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING m_logger = create_log("main_session", listen_port(), false); session_log("session_impl::listen_on log created"); #endif } address session_impl::listen_address() const { for (std::list::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_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.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() && m_proxy.hostname == m_proxy.hostname) 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.force_proxy) return 0; if (m_listen_sockets.empty()) return 0; for (std::list::const_iterator i = m_listen_sockets.begin() , end(m_listen_sockets.end()); i != end; ++i) { if (i->ssl) return i->external_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.get()) m_lsd->announce(ih, port, broadcast); } void session_impl::on_lsd_peer(tcp::endpoint peer, sha1_hash const& ih) { #ifdef TORRENT_STATS ++m_num_messages[on_lsd_peer_counter]; #endif TORRENT_ASSERT(is_network_thread()); 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() || (t->torrent_file().is_i2p() && !m_settings.allow_i2p_mixed)) return; #if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING) session_log("added peer from local discovery: %s", print_endpoint(peer).c_str()); #endif t->get_policy().add_peer(peer, peer_id(0), peer_info::lsd, 0); if (m_alerts.should_post()) m_alerts.post_alert(lsd_peer_alert(t->get_handle(), peer)); } void session_impl::on_port_map_log( char const* msg, int map_transport) { TORRENT_ASSERT(map_transport >= 0 && map_transport <= 1); // log message #ifdef TORRENT_UPNP_LOGGING char const* transport_names[] = {"NAT-PMP", "UPnP"}; m_upnp_log << time_now_string() << " " << transport_names[map_transport] << ": " << msg; #endif if (m_alerts.should_post()) m_alerts.post_alert(portmap_log_alert(map_transport, msg)); } void session_impl::on_port_mapping(int mapping, address const& ip, int port , error_code const& ec, int map_transport) { TORRENT_ASSERT(is_network_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()) m_alerts.post_alert(portmap_alert(mapping, port , map_transport)); 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()) m_alerts.post_alert(portmap_alert(mapping, port , map_transport)); return; } if (ec) { if (m_alerts.should_post()) m_alerts.post_alert(portmap_error_alert(mapping , map_transport, ec)); } else { if (m_alerts.should_post()) m_alerts.post_alert(portmap_alert(mapping, port , map_transport)); } } session_status session_impl::status() const { // INVARIANT_CHECK; TORRENT_ASSERT(is_network_thread()); session_status s; s.optimistic_unchoke_counter = m_optimistic_unchoke_time_scaler; s.unchoke_counter = m_unchoke_time_scaler; s.num_peers = (int)m_connections.size(); s.num_unchoked = m_num_unchoked; s.allowed_upload_slots = m_allowed_upload_slots; s.total_redundant_bytes = m_total_redundant_bytes; s.total_failed_bytes = m_total_failed_bytes; s.up_bandwidth_queue = m_upload_rate.queue_size(); s.down_bandwidth_queue = m_download_rate.queue_size(); s.up_bandwidth_bytes_queue = m_upload_rate.queued_bytes(); s.down_bandwidth_bytes_queue = m_download_rate.queued_bytes(); s.disk_write_queue = m_disk_queues[peer_connection::download_channel]; s.disk_read_queue = m_disk_queues[peer_connection::upload_channel]; s.has_incoming_connections = m_incoming_connection; // 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); #ifndef TORRENT_DISABLE_FULL_STATS // 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); #ifndef TORRENT_DISABLE_DHT // DHT protocol s.dht_download_rate = m_stat.transfer_rate(stat::download_dht_protocol); s.total_dht_download = m_stat.total_transfer(stat::download_dht_protocol); s.dht_upload_rate = m_stat.transfer_rate(stat::upload_dht_protocol); s.total_dht_upload = m_stat.total_transfer(stat::upload_dht_protocol); #else s.dht_download_rate = 0; s.total_dht_download = 0; s.dht_upload_rate = 0; s.total_dht_upload = 0; #endif // TORRENT_DISABLE_DHT // tracker s.tracker_download_rate = m_stat.transfer_rate(stat::download_tracker_protocol); s.total_tracker_download = m_stat.total_transfer(stat::download_tracker_protocol); s.tracker_upload_rate = m_stat.transfer_rate(stat::upload_tracker_protocol); s.total_tracker_upload = m_stat.total_transfer(stat::upload_tracker_protocol); #else // IP-overhead s.ip_overhead_download_rate = 0; s.total_ip_overhead_download = 0; s.ip_overhead_upload_rate = 0; s.total_ip_overhead_upload = 0; // DHT protocol s.dht_download_rate = 0; s.total_dht_download = 0; s.dht_upload_rate = 0; s.total_dht_upload = 0; // tracker s.tracker_download_rate = 0; s.total_tracker_download = 0; s.tracker_upload_rate = 0; s.total_tracker_upload = 0; #endif #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; } m_utp_socket_manager.get_status(s.utp_stats); int peerlist_size = 0; for (torrent_map::const_iterator i = m_torrents.begin() , end(m_torrents.end()); i != end; ++i) { peerlist_size += i->second->get_policy().num_peers(); } s.peerlist_size = peerlist_size; return s; } #ifndef TORRENT_DISABLE_DHT void session_impl::start_dht() { start_dht(m_dht_state); } void session_impl::start_dht(entry const& startup_state) { INVARIANT_CHECK; stop_dht(); m_dht = new dht::dht_tracker(*this, m_udp_socket, m_dht_settings, &startup_state); for (std::list::iterator i = m_dht_router_nodes.begin() , end(m_dht_router_nodes.end()); i != end; ++i) { m_dht->add_router_node(*i); } m_dht->start(startup_state); m_udp_socket.subscribe(m_dht.get()); } void session_impl::stop_dht() { if (!m_dht) return; /* FIXME: good idea... unfortunately it doesnt work. if( m_dht->refresh_storage() ) { // a small chance to refresh to suceed sleep(5000); } */ m_udp_socket.unsubscribe(m_dht.get()); m_dht->stop(); m_dht = 0; } void session_impl::set_dht_settings(dht_settings const& settings) { m_dht_settings = settings; } #ifndef TORRENT_NO_DEPRECATE entry session_impl::dht_state() const { if (!m_dht) return entry(); return m_dht->state(); } #endif void session_impl::add_dht_node_name(std::pair const& node) { if (m_dht) m_dht->add_node(node); } void session_impl::add_dht_router(std::pair const& node) { #if defined TORRENT_ASIO_DEBUGGING add_outstanding_async("session_impl::on_dht_router_name_lookup"); #endif char port[7]; snprintf(port, sizeof(port), "%d", node.second); tcp::resolver::query q(node.first, port); m_host_resolver.async_resolve(q, boost::bind(&session_impl::on_dht_router_name_lookup, this, _1, _2)); } void session_impl::dht_putData(std::string const &username, std::string const &resource, bool multi, entry const &value, std::string const &sig_user, boost::int64_t timeutc, int seq) { if (m_dht) m_dht->putData(username, resource, multi, value, sig_user, timeutc, seq); } void post_dht_getData(aux::session_impl *si, entry::list_type const&lst) { if( si->m_alerts.should_post() ) { si->m_alerts.post_alert(dht_reply_data_alert(lst)); } } void getDataDone_fun(aux::session_impl *si, std::string const &username, std::string const &resource, bool multi, bool is_neighbor, bool got_data) { if( si->m_alerts.should_post() ) { si->m_alerts.post_alert( dht_reply_data_done_alert(username, resource, multi, is_neighbor, got_data)); } } void session_impl::dht_getData(std::string const &username, std::string const &resource, bool multi) { if (m_dht) m_dht->getData(username, resource, multi, boost::bind( post_dht_getData, this, _1), boost::bind( getDataDone_fun, this, username, resource, multi, _1, _2)); } void session_impl::on_dht_router_name_lookup(error_code const& e , tcp::resolver::iterator host) { #if defined TORRENT_ASIO_DEBUGGING complete_async("session_impl::on_dht_router_name_lookup"); #endif // TODO: 1 report errors as alerts if (e) return; while (host != tcp::resolver::iterator()) { // router nodes should be added before the DHT is started (and bootstrapped) udp::endpoint ep(host->endpoint().address(), host->endpoint().port()); if (m_dht) m_dht->add_router_node(ep); m_dht_router_nodes.push_back(ep); ++host; } } #endif void session_impl::maybe_update_udp_mapping(int nat, int local_port, int external_port) { int local, external, protocol; if (nat == 0 && m_natpmp.get()) { if (m_udp_mapping[nat] != -1) { if (m_natpmp->get_mapping(m_udp_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(m_udp_mapping[nat]); } m_udp_mapping[nat] = m_natpmp->add_mapping(natpmp::udp , local_port, external_port); return; } else if (nat == 1 && m_upnp.get()) { if (m_udp_mapping[nat] != -1) { if (m_upnp->get_mapping(m_udp_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(m_udp_mapping[nat]); } m_udp_mapping[nat] = m_upnp->add_mapping(upnp::udp , local_port, external_port); return; } } #ifndef TORRENT_DISABLE_ENCRYPTION void session_impl::set_pe_settings(pe_settings const& settings) { m_pe_settings = settings; } #endif bool session_impl::is_listening() const { return !m_listen_sockets.empty(); } session_impl::~session_impl() { m_io_service.post(boost::bind(&session_impl::abort, this)); // we need to wait for the disk-io thread to // die first, to make sure it won't post any // more messages to the io_service containing references // to disk_io_pool inside the disk_io_thread. Once // the main thread has handled all the outstanding requests // we know it's safe to destruct the disk thread. m_disk_thread.join(); #if defined TORRENT_ASIO_DEBUGGING int counter = 0; while (log_async()) { sleep(1000); ++counter; printf("\n==== Waiting to shut down: %d ==== conn-queue: %d connecting: %d timeout (next: %f max: %f)\n\n" , counter, m_half_open.size(), m_half_open.num_connecting(), m_half_open.next_timeout() , m_half_open.max_timeout()); } async_dec_threads(); #endif if (m_thread) m_thread->join(); m_udp_socket.unsubscribe(this); m_udp_socket.unsubscribe(&m_utp_socket_manager); m_udp_socket.unsubscribe(&m_tracker_manager); TORRENT_ASSERT(m_torrents.empty()); TORRENT_ASSERT(m_connections.empty()); TORRENT_ASSERT(m_connections.empty()); #ifdef TORRENT_REQUEST_LOGGING if (m_request_log) fclose(m_request_log); #endif #ifdef TORRENT_STATS if (m_stats_logger) fclose(m_stats_logger); #endif } #ifndef TORRENT_NO_DEPRECATE int session_impl::max_connections() const { return m_settings.connections_limit; } int session_impl::max_uploads() const { return m_settings.unchoke_slots_limit; } int session_impl::max_half_open_connections() const { return m_settings.half_open_limit; } void session_impl::set_local_download_rate_limit(int bytes_per_second) { session_settings s = m_settings; s.local_download_rate_limit = bytes_per_second; set_settings(s); } void session_impl::set_local_upload_rate_limit(int bytes_per_second) { session_settings s = m_settings; s.local_upload_rate_limit = bytes_per_second; set_settings(s); } void session_impl::set_download_rate_limit(int bytes_per_second) { session_settings s = m_settings; s.download_rate_limit = bytes_per_second; set_settings(s); } void session_impl::set_upload_rate_limit(int bytes_per_second) { session_settings s = m_settings; s.upload_rate_limit = bytes_per_second; set_settings(s); } void session_impl::set_max_half_open_connections(int limit) { session_settings s = m_settings; s.half_open_limit = limit; set_settings(s); } void session_impl::set_max_connections(int limit) { session_settings s = m_settings; s.connections_limit = limit; set_settings(s); } void session_impl::set_max_uploads(int limit) { session_settings s = m_settings; s.unchoke_slots_limit = limit; set_settings(s); } int session_impl::local_upload_rate_limit() const { return m_local_upload_channel.throttle(); } int session_impl::local_download_rate_limit() const { return m_local_download_channel.throttle(); } int session_impl::upload_rate_limit() const { return m_upload_channel.throttle(); } int session_impl::download_rate_limit() const { return m_download_channel.throttle(); } #endif void session_impl::update_unchoke_limit() { m_allowed_upload_slots = m_settings.unchoke_slots_limit; if (m_allowed_upload_slots < 0) m_allowed_upload_slots = (std::numeric_limits::max)(); if (m_settings.num_optimistic_unchoke_slots >= m_allowed_upload_slots / 2) { if (m_alerts.should_post()) m_alerts.post_alert(performance_alert(torrent_handle() , performance_alert::too_many_optimistic_unchoke_slots)); } } void session_impl::update_rate_settings() { if (m_settings.half_open_limit <= 0) m_settings.half_open_limit = (std::numeric_limits::max)(); m_half_open.limit(m_settings.half_open_limit); if (m_settings.local_download_rate_limit < 0) m_settings.local_download_rate_limit = 0; m_local_download_channel.throttle(m_settings.local_download_rate_limit); if (m_settings.local_upload_rate_limit < 0) m_settings.local_upload_rate_limit = 0; m_local_upload_channel.throttle(m_settings.local_upload_rate_limit); if (m_settings.download_rate_limit < 0) m_settings.download_rate_limit = 0; m_download_channel.throttle(m_settings.download_rate_limit); if (m_settings.upload_rate_limit < 0) m_settings.upload_rate_limit = 0; m_upload_channel.throttle(m_settings.upload_rate_limit); } void session_impl::update_connections_limit() { if (m_settings.connections_limit <= 0) { m_settings.connections_limit = (std::numeric_limits::max)(); #if TORRENT_USE_RLIMIT rlimit l; if (getrlimit(RLIMIT_NOFILE, &l) == 0 && l.rlim_cur != RLIM_INFINITY) { m_settings.connections_limit = l.rlim_cur - m_settings.file_pool_size; if (m_settings.connections_limit < 5) m_settings.connections_limit = 5; } #endif } if (num_connections() > m_settings.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.connections_limit; int last_average = 0; int average = m_settings.connections_limit / m_torrents.size(); // the number of slots that are unused by torrents int extra = m_settings.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 , error_code(errors::too_many_connections, get_libtorrent_category())); } } } void session_impl::set_alert_dispatch(boost::function)> const& fun) { m_alerts.set_dispatch_function(fun); } std::auto_ptr session_impl::pop_alert() { return m_alerts.get(); } void session_impl::pop_alerts(std::deque* alerts) { m_alerts.get_all(alerts); } alert const* session_impl::wait_for_alert(time_duration max_wait) { return m_alerts.wait_for_alert(max_wait); } void session_impl::set_alert_mask(boost::uint32_t m) { m_alerts.set_alert_mask(m); } #ifndef TORRENT_NO_DEPRECATE size_t session_impl::set_alert_queue_size_limit(size_t queue_size_limit_) { m_settings.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 = new lsd(m_io_service , m_listen_interface.address() , boost::bind(&session_impl::on_lsd_peer, this, _1, _2)); } 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. natpmp* n = new (std::nothrow) natpmp(m_io_service , m_listen_interface.address() , boost::bind(&session_impl::on_port_mapping , this, _1, _2, _3, _4, 0) , boost::bind(&session_impl::on_port_map_log , this, _1, 0)); if (n == 0) return 0; m_natpmp = n; if (m_listen_interface.port() > 0) { remap_tcp_ports(1, m_listen_interface.port(), ssl_listen_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()); } return n; } upnp* session_impl::start_upnp() { INVARIANT_CHECK; if (m_upnp) return m_upnp.get(); // the upnp constructor may fail and call the callbacks upnp* u = new (std::nothrow) upnp(m_io_service , m_half_open , m_listen_interface.address() , m_settings.user_agent , boost::bind(&session_impl::on_port_mapping , this, _1, _2, _3, _4, 1) , boost::bind(&session_impl::on_port_map_log , this, _1, 1) , m_settings.upnp_ignore_nonrouters); if (u == 0) return 0; m_upnp = u; m_upnp->discover_device(); if (m_listen_interface.port() > 0 || ssl_listen_port() > 0) { remap_tcp_ports(2, m_listen_interface.port(), ssl_listen_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()); } return u; } void session_impl::stop_lsd() { if (m_lsd.get()) m_lsd->close(); m_lsd = 0; } void session_impl::stop_natpmp() { if (m_natpmp.get()) m_natpmp->close(); m_natpmp = 0; } void session_impl::stop_upnp() { if (m_upnp.get()) { m_upnp->close(); m_udp_mapping[1] = -1; m_tcp_mapping[1] = -1; #ifdef TORRENT_USE_OPENSSL m_ssl_mapping[1] = -1; #endif } m_upnp = 0; } 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); } void session_impl::set_external_address(address const& ip , int source_type, address const& source) { #if defined TORRENT_VERBOSE_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; #if defined TORRENT_VERBOSE_LOGGING session_log(" external IP updated"); #endif if (m_alerts.should_post()) m_alerts.post_alert(external_ip_alert(ip)); // since we have a new external IP now, we need to // restart the DHT with a new node ID #ifndef TORRENT_DISABLE_DHT // TODO: 1 we only need to do this if our global IPv4 address has changed // since the DHT (currently) only supports IPv4. Since restarting the DHT // is kind of expensive, it would be nice to not do it unnecessarily if (m_dht) { entry s = m_dht->state(); int cur_state = 0; int prev_state = 0; entry* nodes1 = s.find_key("nodes"); if (nodes1 && nodes1->type() == entry::list_t) cur_state = nodes1->list().size(); entry* nodes2 = m_dht_state.find_key("nodes"); if (nodes2 && nodes2->type() == entry::list_t) prev_state = nodes2->list().size(); if (cur_state > prev_state) m_dht_state = s; start_dht(m_dht_state); } #endif } void session_impl::free_disk_buffer(char* buf) { m_disk_thread.free_buffer(buf); } char* session_impl::allocate_disk_buffer(char const* category) { return m_disk_thread.allocate_buffer(category); } char* session_impl::allocate_buffer() { TORRENT_ASSERT(is_network_thread()); #ifdef TORRENT_DISK_STATS TORRENT_ASSERT(m_buffer_allocations >= 0); m_buffer_allocations++; m_buffer_usage_logger << log_time() << " protocol_buffer: " << (m_buffer_allocations * send_buffer_size) << std::endl; #endif #ifdef TORRENT_DISABLE_POOL_ALLOCATOR int num_bytes = send_buffer_size; return (char*)malloc(num_bytes); #else return (char*)m_send_buffers.malloc(); #endif } #ifdef TORRENT_DISK_STATS void session_impl::log_buffer_usage() { TORRENT_ASSERT(is_network_thread()); int send_buffer_capacity = 0; int used_send_buffer = 0; for (connection_map::const_iterator i = m_connections.begin() , end(m_connections.end()); i != end; ++i) { send_buffer_capacity += (*i)->send_buffer_capacity(); used_send_buffer += (*i)->send_buffer_size(); } TORRENT_ASSERT(send_buffer_capacity >= used_send_buffer); m_buffer_usage_logger << log_time() << " send_buffer_size: " << send_buffer_capacity << std::endl; m_buffer_usage_logger << log_time() << " used_send_buffer: " << used_send_buffer << std::endl; m_buffer_usage_logger << log_time() << " send_buffer_utilization: " << (used_send_buffer * 100.f / send_buffer_capacity) << std::endl; } #endif void session_impl::free_buffer(char* buf) { TORRENT_ASSERT(is_network_thread()); #ifdef TORRENT_DISK_STATS m_buffer_allocations--; TORRENT_ASSERT(m_buffer_allocations >= 0); m_buffer_usage_logger << log_time() << " protocol_buffer: " << (m_buffer_allocations * send_buffer_size) << std::endl; #endif #ifdef TORRENT_DISABLE_POOL_ALLOCATOR free(buf); #else m_send_buffers.free(buf); #endif } #if defined TORRENT_DEBUG && !defined TORRENT_DISABLE_INVARIANT_CHECKS void session_impl::check_invariant() const { TORRENT_ASSERT(is_network_thread()); if (m_settings.unchoke_slots_limit < 0 && m_settings.choking_algorithm == session_settings::fixed_slots_choker) TORRENT_ASSERT(m_allowed_upload_slots == (std::numeric_limits::max)()); int num_checking = 0; int num_queued_for_checking = 0; for (check_queue_t::const_iterator i = m_queued_for_checking.begin() , end(m_queued_for_checking.end()); i != end; ++i) { if ((*i)->state() == torrent_status::checking_files) ++num_checking; else if ((*i)->state() == torrent_status::queued_for_checking) { ++num_queued_for_checking; } } // the queue is either empty, or it has exactly one checking torrent in it TORRENT_ASSERT(m_queued_for_checking.empty() || num_checking == 1 || (m_paused && num_checking == 0)); // TORRENT_ASSERT(m_queued_for_checking.size() == num_queued_for_checking); std::set unique; 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 t = i->second; if (t->is_active_download()) ++num_active_downloading; else if (t->is_active_finished()) ++num_active_finished; int pos = t->queue_position(); if (pos < 0) { TORRENT_ASSERT(pos == -1); continue; } ++total_downloaders; unique.insert(t->queue_position()); } TORRENT_ASSERT(int(unique.size()) == total_downloaders); TORRENT_ASSERT(num_active_downloading == m_num_active_downloading); TORRENT_ASSERT(num_active_finished == m_num_active_finished); std::set unique_peers; TORRENT_ASSERT(m_settings.connections_limit > 0); if (m_settings.choking_algorithm == session_settings::auto_expand_choker) TORRENT_ASSERT(m_allowed_upload_slots >= m_settings.unchoke_slots_limit); int unchokes = 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 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()) continue; 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() && !p->peer_info_struct()->web_seed) { TORRENT_ASSERT(t->get_policy().has_connection(p)); } } TORRENT_ASSERT(disk_queue[0] == m_disk_queues[0]); TORRENT_ASSERT(disk_queue[1] == m_disk_queues[1]); if (m_settings.num_optimistic_unchoke_slots) { TORRENT_ASSERT(num_optimistic <= m_settings.num_optimistic_unchoke_slots); } if (m_num_unchoked != unchokes) { TORRENT_ASSERT(false); } for (torrent_map::const_iterator j = m_torrents.begin(); j != m_torrents.end(); ++j) { TORRENT_ASSERT(boost::get_pointer(j->second)); } } #endif #if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING tracker_logger::tracker_logger(session_impl& ses): m_ses(ses) {} void tracker_logger::tracker_warning(tracker_request const& req , 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
const& ip_list , std::vector& peers , int interval , int min_interval , int complete , int incomplete , int downloaded , address const& external_ip , std::string const& tracker_id) { std::string s; s = "TRACKER RESPONSE:\n"; char tmp[200]; snprintf(tmp, 200, "interval: %d\nmin_interval: %d\npeers:\n", interval, min_interval); s += tmp; for (std::vector::const_iterator i = peers.begin(); i != peers.end(); ++i) { char pid[41]; to_hex((const char*)&i->pid[0], 20, pid); if (i->pid.is_all_zeros()) pid[0] = 0; snprintf(tmp, 200, " %-16s %-5d %s\n", i->ip.c_str(), i->port, pid); s += tmp; } snprintf(tmp, 200, "external ip: %s\n", print_address(external_ip).c_str()); s += tmp; debug_log("%s", s.c_str()); } void tracker_logger::tracker_request_timed_out( tracker_request const&) { debug_log("*** tracker timed out"); } void tracker_logger::tracker_request_error(tracker_request const& r , int response_code, error_code const& ec, const std::string& str , int 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 { if (!m_ses.m_logger) return; va_list v; va_start(v, fmt); char usr[1024]; vsnprintf(usr, sizeof(usr), fmt, v); va_end(v); char buf[1280]; snprintf(buf, sizeof(buf), "%s: %s\n", time_now_string(), usr); // printf is the bitcoin/util.h logger printf("%s", buf); //(*m_ses.m_logger) << buf; } #endif }}