/* Copyright (c) 2003-2012, Arvid Norberg Copyright (c) 2007-2012, Arvid Norberg, Un Shyam All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the author nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "libtorrent/pch.hpp" #include #include #include #ifdef TORRENT_USE_OPENSSL #include // autp_ptr #endif #include "libtorrent/bt_peer_connection.hpp" #include "libtorrent/session.hpp" #include "libtorrent/identify_client.hpp" #include "libtorrent/entry.hpp" #include "libtorrent/bencode.hpp" #include "libtorrent/alert_types.hpp" #include "libtorrent/invariant_check.hpp" #include "libtorrent/io.hpp" #include "libtorrent/socket_io.hpp" #include "libtorrent/version.hpp" #include "libtorrent/extensions.hpp" #include "libtorrent/aux_/session_impl.hpp" #include "libtorrent/broadcast_socket.hpp" #include "libtorrent/escape_string.hpp" #include "libtorrent/peer_info.hpp" #include "libtorrent/random.hpp" #include "libtorrent/alloca.hpp" #ifndef TORRENT_DISABLE_ENCRYPTION #include "libtorrent/pe_crypto.hpp" #include "libtorrent/hasher.hpp" #endif using boost::shared_ptr; using libtorrent::aux::session_impl; namespace libtorrent { const bt_peer_connection::message_handler bt_peer_connection::m_message_handler[] = { &bt_peer_connection::on_choke, &bt_peer_connection::on_unchoke, &bt_peer_connection::on_interested, &bt_peer_connection::on_not_interested, &bt_peer_connection::on_have, &bt_peer_connection::on_bitfield, &bt_peer_connection::on_request, &bt_peer_connection::on_piece, &bt_peer_connection::on_cancel, &bt_peer_connection::on_dht_port, 0, 0, 0, // FAST extension messages &bt_peer_connection::on_suggest_piece, &bt_peer_connection::on_have_all, &bt_peer_connection::on_have_none, &bt_peer_connection::on_reject_request, &bt_peer_connection::on_allowed_fast, 0, 0, &bt_peer_connection::on_extended }; bt_peer_connection::bt_peer_connection( session_impl& ses , shared_ptr s , tcp::endpoint const& remote , policy::peer* peerinfo , boost::weak_ptr tor , bool outgoing) : peer_connection(ses, tor, s, remote , peerinfo, outgoing) , m_state(read_protocol_identifier) #ifndef TORRENT_DISABLE_EXTENSIONS , m_upload_only_id(0) , m_holepunch_id(0) , m_dont_have_id(0) , m_share_mode_id(0) , m_supports_extensions(false) #endif , m_supports_dht_port(false) , m_supports_fast(false) #ifndef TORRENT_DISABLE_ENCRYPTION , m_encrypted(false) , m_rc4_encrypted(false) , m_sync_bytes_read(0) #endif #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS , m_sent_bitfield(false) , m_in_constructor(true) , m_sent_handshake(false) #endif { #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** bt_peer_connection"); #endif #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_in_constructor = false; #endif memset(m_reserved_bits, 0, sizeof(m_reserved_bits)); } void bt_peer_connection::start() { peer_connection::start(); // start in the state where we are trying to read the // handshake from the other side reset_recv_buffer(20); setup_receive(); } bt_peer_connection::~bt_peer_connection() { TORRENT_ASSERT(m_ses.is_network_thread()); } void bt_peer_connection::on_connected() { #ifndef TORRENT_DISABLE_ENCRYPTION pe_settings::enc_policy out_enc_policy = m_ses.get_pe_settings().out_enc_policy; #ifdef TORRENT_USE_OPENSSL // never try an encrypted connection when already using SSL if (is_ssl(*get_socket())) out_enc_policy = pe_settings::disabled; #endif #ifdef TORRENT_VERBOSE_LOGGING char const* policy_name[] = {"forced", "enabled", "disabled"}; peer_log("*** outgoing encryption policy: %s", policy_name[out_enc_policy]); #endif if (out_enc_policy == pe_settings::forced) { write_pe1_2_dhkey(); if (is_disconnecting()) return; m_state = read_pe_dhkey; reset_recv_buffer(dh_key_len); setup_receive(); } else if (out_enc_policy == pe_settings::enabled) { TORRENT_ASSERT(peer_info_struct()); policy::peer* pi = peer_info_struct(); if (pi->pe_support == true) { // toggle encryption support flag, toggled back to // true if encrypted portion of the handshake // completes correctly pi->pe_support = false; // if this fails, we need to reconnect // fast. fast_reconnect(true); write_pe1_2_dhkey(); if (is_disconnecting()) return; m_state = read_pe_dhkey; reset_recv_buffer(dh_key_len); setup_receive(); } else // pi->pe_support == false { // toggled back to false if standard handshake // completes correctly (without encryption) pi->pe_support = true; write_handshake(); reset_recv_buffer(20); setup_receive(); } } else if (out_enc_policy == pe_settings::disabled) #endif { write_handshake(); // start in the state where we are trying to read the // handshake from the other side reset_recv_buffer(20); setup_receive(); } } void bt_peer_connection::on_metadata() { #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** ON_METADATA"); #endif // connections that are still in the handshake // will send their bitfield when the handshake // is done if (m_state < read_packet_size) return; boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); write_bitfield(); #ifndef TORRENT_DISABLE_DHT if (m_supports_dht_port && m_ses.m_dht) write_dht_port(m_ses.m_external_udp_port); #endif } void bt_peer_connection::write_dht_port(int listen_port) { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); #ifdef TORRENT_VERBOSE_LOGGING peer_log("==> DHT_PORT [ %d ]", listen_port); #endif char msg[] = {0,0,0,3, msg_dht_port, 0, 0}; char* ptr = msg + 5; detail::write_uint16(listen_port, ptr); send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_have_all() { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && !m_sent_bitfield); #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_sent_bitfield = true; #endif #ifdef TORRENT_VERBOSE_LOGGING peer_log("==> HAVE_ALL"); #endif char msg[] = {0,0,0,1, msg_have_all}; send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_have_none() { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && !m_sent_bitfield); #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_sent_bitfield = true; #endif #ifdef TORRENT_VERBOSE_LOGGING peer_log("==> HAVE_NONE"); #endif char msg[] = {0,0,0,1, msg_have_none}; send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_reject_request(peer_request const& r) { INVARIANT_CHECK; #ifdef TORRENT_STATS ++m_ses.m_piece_rejects; #endif if (!m_supports_fast) return; #ifdef TORRENT_VERBOSE_LOGGING peer_log("==> REJECT_PIECE [ piece: %d | s: %d | l: %d ]" , r.piece, r.start, r.length); #endif TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); TORRENT_ASSERT(associated_torrent().lock()->valid_metadata()); char msg[] = {0,0,0,13, msg_reject_request,0,0,0,0, 0,0,0,0, 0,0,0,0}; char* ptr = msg + 5; detail::write_int32(r.piece, ptr); // index detail::write_int32(r.start, ptr); // begin detail::write_int32(r.length, ptr); // length send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_allow_fast(int piece) { INVARIANT_CHECK; if (!m_supports_fast) return; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); TORRENT_ASSERT(associated_torrent().lock()->valid_metadata()); char msg[] = {0,0,0,5, msg_allowed_fast, 0, 0, 0, 0}; char* ptr = msg + 5; detail::write_int32(piece, ptr); send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_suggest(int piece) { INVARIANT_CHECK; if (!m_supports_fast) return; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); TORRENT_ASSERT(associated_torrent().lock()->valid_metadata()); boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); if (m_sent_suggested_pieces.empty()) m_sent_suggested_pieces.resize(t->torrent_file().num_pieces(), false); if (m_sent_suggested_pieces[piece]) return; m_sent_suggested_pieces.set_bit(piece); char msg[] = {0,0,0,5, msg_suggest_piece, 0, 0, 0, 0}; char* ptr = msg + 5; detail::write_int32(piece, ptr); send_buffer(msg, sizeof(msg)); } void bt_peer_connection::get_specific_peer_info(peer_info& p) const { TORRENT_ASSERT(!associated_torrent().expired()); if (is_interesting()) p.flags |= peer_info::interesting; if (is_choked()) p.flags |= peer_info::choked; if (is_peer_interested()) p.flags |= peer_info::remote_interested; if (has_peer_choked()) p.flags |= peer_info::remote_choked; if (support_extensions()) p.flags |= peer_info::supports_extensions; if (is_outgoing()) p.flags |= peer_info::local_connection; #if TORRENT_USE_I2P if (is_i2p(*get_socket())) p.flags |= peer_info::i2p_socket; #endif if (is_utp(*get_socket())) p.flags |= peer_info::utp_socket; #ifndef TORRENT_DISABLE_ENCRYPTION if (m_encrypted) { p.flags |= m_rc4_encrypted ? peer_info::rc4_encrypted : peer_info::plaintext_encrypted; } #endif if (!is_connecting() && in_handshake()) p.flags |= peer_info::handshake; if (is_connecting() && !is_queued()) p.flags |= peer_info::connecting; if (is_queued()) p.flags |= peer_info::queued; p.client = m_client_version; p.connection_type = is_utp(*get_socket()) ? peer_info::bittorrent_utp : peer_info::standard_bittorrent; } bool bt_peer_connection::in_handshake() const { return m_state < read_packet_size; } #ifndef TORRENT_DISABLE_ENCRYPTION void bt_peer_connection::write_pe1_2_dhkey() { INVARIANT_CHECK; TORRENT_ASSERT(!m_encrypted); TORRENT_ASSERT(!m_rc4_encrypted); TORRENT_ASSERT(!m_dh_key_exchange.get()); TORRENT_ASSERT(!m_sent_handshake); #ifdef TORRENT_VERBOSE_LOGGING if (is_outgoing()) peer_log("*** initiating encrypted handshake"); #endif m_dh_key_exchange.reset(new (std::nothrow) dh_key_exchange); if (!m_dh_key_exchange || !m_dh_key_exchange->good()) { disconnect(errors::no_memory); return; } int pad_size = random() % 512; #ifdef TORRENT_VERBOSE_LOGGING peer_log(" pad size: %d", pad_size); #endif char msg[dh_key_len + 512]; char* ptr = msg; int buf_size = dh_key_len + pad_size; memcpy(ptr, m_dh_key_exchange->get_local_key(), dh_key_len); ptr += dh_key_len; std::generate(ptr, ptr + pad_size, random); send_buffer(msg, buf_size); #ifdef TORRENT_VERBOSE_LOGGING peer_log(" sent DH key"); #endif } void bt_peer_connection::write_pe3_sync() { INVARIANT_CHECK; TORRENT_ASSERT(!m_encrypted); TORRENT_ASSERT(!m_rc4_encrypted); TORRENT_ASSERT(is_outgoing()); TORRENT_ASSERT(!m_sent_handshake); boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); hasher h; sha1_hash const& info_hash = t->torrent_file().info_hash(); char const* const secret = m_dh_key_exchange->get_secret(); int pad_size = random() % 512; // synchash,skeyhash,vc,crypto_provide,len(pad),pad,len(ia) char msg[20 + 20 + 8 + 4 + 2 + 512 + 2]; char* ptr = msg; // sync hash (hash('req1',S)) h.reset(); h.update("req1",4); h.update(secret, dh_key_len); sha1_hash sync_hash = h.final(); memcpy(ptr, &sync_hash[0], 20); ptr += 20; // stream key obfuscated hash [ hash('req2',SKEY) xor hash('req3',S) ] h.reset(); h.update("req2",4); h.update((const char*)info_hash.begin(), 20); sha1_hash streamkey_hash = h.final(); h.reset(); h.update("req3",4); h.update(secret, dh_key_len); sha1_hash obfsc_hash = h.final(); obfsc_hash ^= streamkey_hash; memcpy(ptr, &obfsc_hash[0], 20); ptr += 20; // Discard DH key exchange data, setup RC4 keys init_pe_rc4_handler(secret, info_hash); m_dh_key_exchange.reset(); // secret should be invalid at this point // write the verification constant and crypto field int encrypt_size = sizeof(msg) - 512 + pad_size - 40; pe_settings::enc_level crypto_provide = m_ses.get_pe_settings().allowed_enc_level; // this is an invalid setting, but let's just make the best of the situation if ((crypto_provide & pe_settings::both) == 0) crypto_provide = pe_settings::both; #ifdef TORRENT_VERBOSE_LOGGING char const* level[] = {"plaintext", "rc4", "plaintext rc4"}; peer_log(" crypto provide : [ %s ]" , level[crypto_provide-1]); #endif write_pe_vc_cryptofield(ptr, encrypt_size, crypto_provide, pad_size); m_enc_handler->encrypt(ptr, encrypt_size); send_buffer(msg, sizeof(msg) - 512 + pad_size); } void bt_peer_connection::write_pe4_sync(int crypto_select) { INVARIANT_CHECK; TORRENT_ASSERT(!is_outgoing()); TORRENT_ASSERT(!m_encrypted); TORRENT_ASSERT(!m_rc4_encrypted); TORRENT_ASSERT(crypto_select == 0x02 || crypto_select == 0x01); TORRENT_ASSERT(!m_sent_handshake); int pad_size = random() % 512; const int buf_size = 8 + 4 + 2 + pad_size; char msg[512 + 8 + 4 + 2]; write_pe_vc_cryptofield(msg, sizeof(msg), crypto_select, pad_size); m_enc_handler->encrypt(msg, buf_size); send_buffer(msg, buf_size); // encryption method has been negotiated if (crypto_select == 0x02) m_rc4_encrypted = true; else // 0x01 m_rc4_encrypted = false; #ifdef TORRENT_VERBOSE_LOGGING peer_log(" crypto select : [ %s ]" , (crypto_select == 0x01) ? "plaintext" : "rc4"); #endif } void bt_peer_connection::write_pe_vc_cryptofield(char* write_buf, int len , int crypto_field, int pad_size) { INVARIANT_CHECK; TORRENT_ASSERT(crypto_field <= 0x03 && crypto_field > 0); // vc,crypto_field,len(pad),pad, (len(ia)) TORRENT_ASSERT((len >= 8+4+2+pad_size+2 && is_outgoing()) || (len >= 8+4+2+pad_size && !is_outgoing())); TORRENT_ASSERT(!m_sent_handshake); // encrypt(vc, crypto_provide/select, len(Pad), len(IA)) // len(pad) is zero for now, len(IA) only for outgoing connections // vc memset(write_buf, 0, 8); write_buf += 8; detail::write_uint32(crypto_field, write_buf); detail::write_uint16(pad_size, write_buf); // len (pad) // fill pad with zeroes std::generate(write_buf, write_buf + pad_size, &random); write_buf += pad_size; // append len(ia) if we are initiating if (is_outgoing()) detail::write_uint16(handshake_len, write_buf); // len(IA) } void bt_peer_connection::init_pe_rc4_handler(char const* secret, sha1_hash const& stream_key) { INVARIANT_CHECK; TORRENT_ASSERT(secret); hasher h; static const char keyA[] = "keyA"; static const char keyB[] = "keyB"; // encryption rc4 longkeys // outgoing connection : hash ('keyA',S,SKEY) // incoming connection : hash ('keyB',S,SKEY) if (is_outgoing()) h.update(keyA, 4); else h.update(keyB, 4); h.update(secret, dh_key_len); h.update((char const*)stream_key.begin(), 20); const sha1_hash local_key = h.final(); h.reset(); // decryption rc4 longkeys // outgoing connection : hash ('keyB',S,SKEY) // incoming connection : hash ('keyA',S,SKEY) if (is_outgoing()) h.update(keyB, 4); else h.update(keyA, 4); h.update(secret, dh_key_len); h.update((char const*)stream_key.begin(), 20); const sha1_hash remote_key = h.final(); TORRENT_ASSERT(!m_enc_handler.get()); m_enc_handler.reset(new (std::nothrow) rc4_handler); m_enc_handler->set_incoming_key(&remote_key[0], 20); m_enc_handler->set_outgoing_key(&local_key[0], 20); if (!m_enc_handler) { disconnect(errors::no_memory); return; } #ifdef TORRENT_VERBOSE_LOGGING peer_log(" computed RC4 keys"); #endif } int bt_peer_connection::get_syncoffset(char const* src, int src_size, char const* target, int target_size) const { TORRENT_ASSERT(target_size >= src_size); TORRENT_ASSERT(src_size > 0); TORRENT_ASSERT(src); TORRENT_ASSERT(target); int traverse_limit = target_size - src_size; // TODO: this could be optimized using knuth morris pratt for (int i = 0; i < traverse_limit; ++i) { char const* target_ptr = target + i; if (std::equal(src, src+src_size, target_ptr)) return i; } // // Partial sync // for (int i = 0; i < target_size; ++i) // { // // first is iterator in src[] at which mismatch occurs // // second is iterator in target[] at which mismatch occurs // std::pair ret; // int src_sync_size; // if (i > traverse_limit) // partial sync test // { // ret = std::mismatch(src, src + src_size - (i - traverse_limit), &target[i]); // src_sync_size = ret.first - src; // if (src_sync_size == (src_size - (i - traverse_limit))) // return i; // } // else // complete sync test // { // ret = std::mismatch(src, src + src_size, &target[i]); // src_sync_size = ret.first - src; // if (src_sync_size == src_size) // return i; // } // } // no complete sync return -1; } #endif // #ifndef TORRENT_DISABLE_ENCRYPTION void bt_peer_connection::append_const_send_buffer(char const* buffer, int size) { #ifndef TORRENT_DISABLE_ENCRYPTION if (m_encrypted && m_rc4_encrypted) { // if we're encrypting this buffer, we need to make a copy // since we'll mutate it char* buf = (char*)malloc(size); memcpy(buf, buffer, size); bt_append_send_buffer(buf, size, boost::bind(&::free, _1)); } else #endif { peer_connection::append_const_send_buffer(buffer, size); } } #ifndef TORRENT_DISABLE_ENCRYPTION void encrypt(char* buf, int len, void* userdata) { rc4_handler* rc4 = (rc4_handler*)userdata; rc4->encrypt(buf, len); } #endif void bt_peer_connection::send_buffer(char const* buf, int size, int flags , void (*f)(char*, int, void*), void* ud) { TORRENT_ASSERT(f == 0); TORRENT_ASSERT(ud == 0); TORRENT_ASSERT(buf); TORRENT_ASSERT(size > 0); void* userdata = 0; void (*fun)(char*, int, void*) = 0; #ifndef TORRENT_DISABLE_ENCRYPTION if (m_encrypted && m_rc4_encrypted) { fun = encrypt; userdata = m_enc_handler.get(); } #endif peer_connection::send_buffer(buf, size, flags, fun, userdata); } void bt_peer_connection::write_handshake() { INVARIANT_CHECK; TORRENT_ASSERT(!m_sent_handshake); #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_sent_handshake = true; #endif boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); // add handshake to the send buffer const char version_string[] = "BitTorrent protocol"; const int string_len = sizeof(version_string)-1; char handshake[1 + string_len + 8 + 20 + 20]; char* ptr = handshake; // length of version string detail::write_uint8(string_len, ptr); // protocol identifier memcpy(ptr, version_string, string_len); ptr += string_len; // 8 zeroes memset(ptr, 0, 8); #ifndef TORRENT_DISABLE_DHT // indicate that we support the DHT messages *(ptr + 7) |= 0x01; #endif #ifndef TORRENT_DISABLE_EXTENSIONS // we support extensions *(ptr + 5) |= 0x10; #endif if (m_ses.m_settings.support_merkle_torrents) { // we support merkle torrents *(ptr + 5) |= 0x08; } // we support FAST extension *(ptr + 7) |= 0x04; #ifdef TORRENT_VERBOSE_LOGGING std::string bitmask; for (int k = 0; k < 8; ++k) { for (int j = 0; j < 8; ++j) { if (ptr[k] & (0x80 >> j)) bitmask += '1'; else bitmask += '0'; } } peer_log("==> EXTENSION [ %s ]", bitmask.c_str()); #endif ptr += 8; // info hash sha1_hash const& ih = t->torrent_file().info_hash(); memcpy(ptr, &ih[0], 20); ptr += 20; // peer id if (m_ses.m_settings.anonymous_mode) { // in anonymous mode, every peer connection // has a unique peer-id for (int i = 0; i < 20; ++i) ptr[i] = random(); } else { memcpy(ptr, &m_ses.get_peer_id()[0], 20); } // ptr += 20; #ifdef TORRENT_VERBOSE_LOGGING peer_log("==> HANDSHAKE [ ih: %s ]", to_hex(ih.to_string()).c_str()); #endif send_buffer(handshake, sizeof(handshake)); } boost::optional bt_peer_connection::downloading_piece_progress() const { boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); buffer::const_interval recv_buffer = receive_buffer(); // are we currently receiving a 'piece' message? if (m_state != read_packet || recv_buffer.left() <= 9 || recv_buffer[0] != msg_piece) return boost::optional(); const char* ptr = recv_buffer.begin + 1; peer_request r; r.piece = detail::read_int32(ptr); r.start = detail::read_int32(ptr); r.length = packet_size() - 9; // is any of the piece message header data invalid? if (!verify_piece(r)) return boost::optional(); piece_block_progress p; p.piece_index = r.piece; p.block_index = r.start / t->block_size(); p.bytes_downloaded = recv_buffer.left() - 9; p.full_block_bytes = r.length; return boost::optional(p); } // message handlers // ----------------------------- // --------- KEEPALIVE --------- // ----------------------------- void bt_peer_connection::on_keepalive() { INVARIANT_CHECK; #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== KEEPALIVE"); #endif incoming_keepalive(); } // ----------------------------- // ----------- CHOKE ----------- // ----------------------------- void bt_peer_connection::on_choke(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); m_statistics.received_bytes(0, received); if (packet_size() != 1) { disconnect(errors::invalid_choke, 2); return; } if (!packet_finished()) return; incoming_choke(); if (is_disconnecting()) return; if (!m_supports_fast) { // we just got choked, and the peer that choked use // doesn't support fast extensions, so we have to // assume that the choke message implies that all // of our requests are rejected. Go through them and // pretend that we received reject request messages boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); while (!download_queue().empty()) { piece_block const& b = download_queue().front().block; peer_request r; r.piece = b.piece_index; r.start = b.block_index * t->block_size(); r.length = t->block_size(); // if it's the last piece, make sure to // set the length of the request to not // exceed the end of the torrent. This is // necessary in order to maintain a correct // m_outsanding_bytes if (r.piece == t->torrent_file().num_pieces() - 1) { r.length = (std::min)(t->torrent_file().piece_size( r.piece) - r.start, r.length); } incoming_reject_request(r); } } } // ----------------------------- // ---------- UNCHOKE ---------- // ----------------------------- void bt_peer_connection::on_unchoke(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); m_statistics.received_bytes(0, received); if (packet_size() != 1) { disconnect(errors::invalid_unchoke, 2); return; } if (!packet_finished()) return; incoming_unchoke(); } // ----------------------------- // -------- INTERESTED --------- // ----------------------------- void bt_peer_connection::on_interested(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); m_statistics.received_bytes(0, received); if (packet_size() != 1) { disconnect(errors::invalid_interested, 2); return; } if (!packet_finished()) return; incoming_interested(); } // ----------------------------- // ------ NOT INTERESTED ------- // ----------------------------- void bt_peer_connection::on_not_interested(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); m_statistics.received_bytes(0, received); if (packet_size() != 1) { disconnect(errors::invalid_not_interested, 2); return; } if (!packet_finished()) return; incoming_not_interested(); } // ----------------------------- // ----------- HAVE ------------ // ----------------------------- void bt_peer_connection::on_have(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); m_statistics.received_bytes(0, received); if (packet_size() != 5) { disconnect(errors::invalid_have, 2); return; } if (!packet_finished()) return; buffer::const_interval recv_buffer = receive_buffer(); const char* ptr = recv_buffer.begin + 1; int index = detail::read_int32(ptr); incoming_have(index); } // ----------------------------- // --------- BITFIELD ---------- // ----------------------------- void bt_peer_connection::on_bitfield(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); m_statistics.received_bytes(0, received); // if we don't have the metedata, we cannot // verify the bitfield size if (t->valid_metadata() && packet_size() - 1 != (t->torrent_file().num_pieces() + 7) / 8) { disconnect(errors::invalid_bitfield_size, 2); return; } if (!packet_finished()) return; buffer::const_interval recv_buffer = receive_buffer(); bitfield bits; bits.borrow_bytes((char*)recv_buffer.begin + 1 , t->valid_metadata()?get_bitfield().size():(packet_size()-1)*8); incoming_bitfield(bits); } // ----------------------------- // ---------- REQUEST ---------- // ----------------------------- void bt_peer_connection::on_request(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); m_statistics.received_bytes(0, received); if (packet_size() != 13) { disconnect(errors::invalid_request, 2); return; } if (!packet_finished()) return; buffer::const_interval recv_buffer = receive_buffer(); peer_request r; const char* ptr = recv_buffer.begin + 1; r.piece = detail::read_int32(ptr); r.start = detail::read_int32(ptr); r.length = detail::read_int32(ptr); incoming_request(r); } // ----------------------------- // ----------- PIECE ----------- // ----------------------------- void bt_peer_connection::on_piece(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); buffer::const_interval recv_buffer = receive_buffer(); int recv_pos = receive_pos(); // recv_buffer.end - recv_buffer.begin; boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); bool merkle = (unsigned char)recv_buffer.begin[0] == 250; if (merkle) { if (recv_pos == 1) { set_soft_packet_size(13); m_statistics.received_bytes(0, received); return; } if (recv_pos < 13) { m_statistics.received_bytes(0, received); return; } if (recv_pos == 13) { const char* ptr = recv_buffer.begin + 9; int list_size = detail::read_int32(ptr); // now we know how long the bencoded hash list is // and we can allocate the disk buffer and receive // into it if (list_size > packet_size() - 13) { disconnect(errors::invalid_hash_list, 2); return; } if (packet_size() - 13 - list_size > t->block_size()) { disconnect(errors::packet_too_large, 2); return; } TORRENT_ASSERT(!has_disk_receive_buffer()); if (!allocate_disk_receive_buffer(packet_size() - 13 - list_size)) { m_statistics.received_bytes(0, received); return; } } } else { if (recv_pos == 1) { TORRENT_ASSERT(!has_disk_receive_buffer()); if (packet_size() - 9 > t->block_size()) { disconnect(errors::packet_too_large, 2); return; } if (!allocate_disk_receive_buffer(packet_size() - 9)) { m_statistics.received_bytes(0, received); return; } } } TORRENT_ASSERT(has_disk_receive_buffer() || packet_size() == 9); // classify the received data as protocol chatter // or data payload for the statistics int piece_bytes = 0; int header_size = merkle?13:9; peer_request p; int list_size = 0; if (recv_pos >= header_size) { const char* ptr = recv_buffer.begin + 1; p.piece = detail::read_int32(ptr); p.start = detail::read_int32(ptr); if (merkle) { list_size = detail::read_int32(ptr); p.length = packet_size() - list_size - header_size; header_size += list_size; } else { p.length = packet_size() - header_size; } } if (recv_pos <= header_size) { // only received protocol data m_statistics.received_bytes(0, received); } else if (recv_pos - received >= header_size) { // only received payload data m_statistics.received_bytes(received, 0); piece_bytes = received; } else { // received a bit of both TORRENT_ASSERT(recv_pos - received < header_size); TORRENT_ASSERT(recv_pos > header_size); TORRENT_ASSERT(header_size - (recv_pos - received) <= header_size); m_statistics.received_bytes( recv_pos - header_size , header_size - (recv_pos - received)); piece_bytes = recv_pos - header_size; } if (recv_pos < header_size) return; #ifdef TORRENT_VERBOSE_LOGGING // peer_log("<== PIECE_FRAGMENT p: %d start: %d length: %d" // , p.piece, p.start, p.length); #endif if (recv_pos - received < header_size && recv_pos >= header_size) { // call this once, the first time the entire header // has been received start_receive_piece(p); if (is_disconnecting()) return; } TORRENT_ASSERT(has_disk_receive_buffer() || packet_size() == header_size); incoming_piece_fragment(piece_bytes); if (!packet_finished()) return; if (merkle && list_size > 0) { #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== HASHPIECE [ piece: %d list: %d ]", p.piece, list_size); #endif lazy_entry hash_list; error_code ec; if (lazy_bdecode(recv_buffer.begin + 13, recv_buffer.begin+ 13 + list_size , hash_list, ec) != 0) { disconnect(errors::invalid_hash_piece, 2); return; } // the list has this format: // [ [node-index, hash], [node-index, hash], ... ] if (hash_list.type() != lazy_entry::list_t) { disconnect(errors::invalid_hash_list, 2); return; } std::map nodes; for (int i = 0; i < hash_list.list_size(); ++i) { lazy_entry const* e = hash_list.list_at(i); if (e->type() != lazy_entry::list_t || e->list_size() != 2 || e->list_at(0)->type() != lazy_entry::int_t || e->list_at(1)->type() != lazy_entry::string_t || e->list_at(1)->string_length() != 20) continue; nodes.insert(std::make_pair(int(e->list_int_value_at(0)) , sha1_hash(e->list_at(1)->string_ptr()))); } if (!nodes.empty() && !t->add_merkle_nodes(nodes, p.piece)) { disconnect(errors::invalid_hash_piece, 2); return; } } disk_buffer_holder holder(m_ses, release_disk_receive_buffer()); incoming_piece(p, holder); } // ----------------------------- // ---------- CANCEL ----------- // ----------------------------- void bt_peer_connection::on_cancel(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); m_statistics.received_bytes(0, received); if (packet_size() != 13) { disconnect(errors::invalid_cancel, 2); return; } if (!packet_finished()) return; buffer::const_interval recv_buffer = receive_buffer(); peer_request r; const char* ptr = recv_buffer.begin + 1; r.piece = detail::read_int32(ptr); r.start = detail::read_int32(ptr); r.length = detail::read_int32(ptr); incoming_cancel(r); } // ----------------------------- // --------- DHT PORT ---------- // ----------------------------- void bt_peer_connection::on_dht_port(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); m_statistics.received_bytes(0, received); if (packet_size() != 3) { disconnect(errors::invalid_dht_port, 2); return; } if (!packet_finished()) return; buffer::const_interval recv_buffer = receive_buffer(); const char* ptr = recv_buffer.begin + 1; int listen_port = detail::read_uint16(ptr); incoming_dht_port(listen_port); if (!m_supports_dht_port) { m_supports_dht_port = true; #ifndef TORRENT_DISABLE_DHT if (m_supports_dht_port && m_ses.m_dht) write_dht_port(m_ses.m_external_udp_port); #endif } } void bt_peer_connection::on_suggest_piece(int received) { INVARIANT_CHECK; m_statistics.received_bytes(0, received); if (!m_supports_fast) { disconnect(errors::invalid_suggest, 2); return; } if (!packet_finished()) return; buffer::const_interval recv_buffer = receive_buffer(); const char* ptr = recv_buffer.begin + 1; int piece = detail::read_uint32(ptr); incoming_suggest(piece); } void bt_peer_connection::on_have_all(int received) { INVARIANT_CHECK; m_statistics.received_bytes(0, received); if (!m_supports_fast) { disconnect(errors::invalid_have_all, 2); return; } incoming_have_all(); } void bt_peer_connection::on_have_none(int received) { INVARIANT_CHECK; m_statistics.received_bytes(0, received); if (!m_supports_fast) { disconnect(errors::invalid_have_none, 2); return; } incoming_have_none(); } void bt_peer_connection::on_reject_request(int received) { INVARIANT_CHECK; m_statistics.received_bytes(0, received); if (!m_supports_fast) { disconnect(errors::invalid_reject, 2); return; } if (!packet_finished()) return; buffer::const_interval recv_buffer = receive_buffer(); peer_request r; const char* ptr = recv_buffer.begin + 1; r.piece = detail::read_int32(ptr); r.start = detail::read_int32(ptr); r.length = detail::read_int32(ptr); incoming_reject_request(r); } void bt_peer_connection::on_allowed_fast(int received) { INVARIANT_CHECK; m_statistics.received_bytes(0, received); if (!m_supports_fast) { disconnect(errors::invalid_allow_fast, 2); return; } if (!packet_finished()) return; buffer::const_interval recv_buffer = receive_buffer(); const char* ptr = recv_buffer.begin + 1; int index = detail::read_int32(ptr); incoming_allowed_fast(index); } // ----------------------------- // -------- RENDEZVOUS --------- // ----------------------------- #ifndef TORRENT_DISABLE_EXTENSIONS void bt_peer_connection::on_holepunch() { INVARIANT_CHECK; if (!packet_finished()) return; // we can't accept holepunch messages from peers // that don't support the holepunch extension // because we wouldn't be able to respond if (m_holepunch_id == 0) return; buffer::const_interval recv_buffer = receive_buffer(); TORRENT_ASSERT(*recv_buffer.begin == msg_extended); ++recv_buffer.begin; TORRENT_ASSERT(*recv_buffer.begin == holepunch_msg); ++recv_buffer.begin; const char* ptr = recv_buffer.begin; // ignore invalid messages if (recv_buffer.left() < 2) return; int msg_type = detail::read_uint8(ptr); int addr_type = detail::read_uint8(ptr); tcp::endpoint ep; if (addr_type == 0) { if (recv_buffer.left() < 2 + 4 + 2) return; // IPv4 address ep = detail::read_v4_endpoint(ptr); } #if TORRENT_USE_IPV6 else if (addr_type == 1) { // IPv6 address if (recv_buffer.left() < 2 + 18 + 2) return; ep = detail::read_v6_endpoint(ptr); } #endif else { #if defined TORRENT_VERBOSE_LOGGING error_code ec; static const char* hp_msg_name[] = {"rendezvous", "connect", "failed"}; peer_log("<== HOLEPUNCH [ msg: %s from %s to: unknown address type ]" , (msg_type >= 0 && msg_type < 3 ? hp_msg_name[msg_type] : "unknown message type") , print_address(remote().address()).c_str()); #endif return; // unknown address type } boost::shared_ptr t = associated_torrent().lock(); if (!t) return; switch (msg_type) { case hp_rendezvous: // rendezvous { #if defined TORRENT_VERBOSE_LOGGING peer_log("<== HOLEPUNCH [ msg: rendezvous to: %s ]" , print_address(ep.address()).c_str()); #endif // this peer is asking us to introduce it to // the peer at 'ep'. We need to find which of // our connections points to that endpoint bt_peer_connection* p = t->find_peer(ep); if (p == 0) { // we're not connected to this peer write_holepunch_msg(hp_failed, ep, hp_not_connected); break; } if (!p->supports_holepunch()) { write_holepunch_msg(hp_failed, ep, hp_no_support); break; } if (p == this) { write_holepunch_msg(hp_failed, ep, hp_no_self); break; } write_holepunch_msg(hp_connect, ep, 0); p->write_holepunch_msg(hp_connect, remote(), 0); } break; case hp_connect: { // add or find the peer with this endpoint policy::peer* p = t->get_policy().add_peer(ep, peer_id(0), peer_info::pex, 0); if (p == 0 || p->connection) { #if defined TORRENT_VERBOSE_LOGGING peer_log("<== HOLEPUNCH [ msg:connect to: %s error: failed to add peer ]" , print_address(ep.address()).c_str()); #endif // we either couldn't add this peer, or it's // already connected. Just ignore the connect message break; } if (p->banned) { #if defined TORRENT_VERBOSE_LOGGING peer_log("<== HOLEPUNCH [ msg:connect to: %s error: peer banned ]" , print_address(ep.address()).c_str()); #endif // this peer is banned, don't connect to it break; } // to make sure we use the uTP protocol p->supports_utp = true; // #error make sure we make this a connection candidate // in case it has too many failures for instance t->connect_to_peer(p, true); // mark this connection to be in holepunch mode // so that it will retry faster and stick to uTP while it's // retrying if (p->connection) p->connection->set_holepunch_mode(); #if defined TORRENT_VERBOSE_LOGGING peer_log("<== HOLEPUNCH [ msg:connect to: %s ]" , print_address(ep.address()).c_str()); #endif } break; case hp_failed: { boost::uint32_t error = detail::read_uint32(ptr); #if defined TORRENT_VERBOSE_LOGGING error_code ec; char const* err_msg[] = {"no such peer", "not connected", "no support", "no self"}; peer_log("<== HOLEPUNCH [ msg:failed error: %d msg: %s ]", error , ((error > 0 && error < 5)?err_msg[error-1]:"unknown message id")); #endif // #error deal with holepunch errors (void)error; } break; #if defined TORRENT_VERBOSE_LOGGING default: { error_code ec; peer_log("<== HOLEPUNCH [ msg: unknown message type (%d) to: %s ]" , msg_type, print_address(ep.address()).c_str()); } #endif } } void bt_peer_connection::write_holepunch_msg(int type, tcp::endpoint const& ep, int error) { char buf[35]; char* ptr = buf + 6; detail::write_uint8(type, ptr); if (ep.address().is_v4()) detail::write_uint8(0, ptr); else detail::write_uint8(1, ptr); detail::write_endpoint(ep, ptr); #if defined TORRENT_VERBOSE_LOGGING error_code ec; static const char* hp_msg_name[] = {"rendezvous", "connect", "failed"}; static const char* hp_error_string[] = {"", "no such peer", "not connected", "no support", "no self"}; peer_log("==> HOLEPUNCH [ msg: %s to: %s error: %s ]" , (type >= 0 && type < 3 ? hp_msg_name[type] : "unknown message type") , print_address(ep.address()).c_str() , hp_error_string[error]); #endif if (type == hp_failed) { detail::write_uint32(error, ptr); } // write the packet length and type char* hdr = buf; detail::write_uint32(ptr - buf - 4, hdr); detail::write_uint8(msg_extended, hdr); detail::write_uint8(m_holepunch_id, hdr); TORRENT_ASSERT(ptr <= buf + sizeof(buf)); send_buffer(buf, ptr - buf); } #endif // TORRENT_DISABLE_EXTENSIONS // ----------------------------- // --------- EXTENDED ---------- // ----------------------------- void bt_peer_connection::on_extended(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); m_statistics.received_bytes(0, received); if (packet_size() < 2) { disconnect(errors::invalid_extended, 2); return; } if (associated_torrent().expired()) { disconnect(errors::invalid_extended, 2); return; } buffer::const_interval recv_buffer = receive_buffer(); if (recv_buffer.left() < 2) return; TORRENT_ASSERT(*recv_buffer.begin == msg_extended); ++recv_buffer.begin; int extended_id = detail::read_uint8(recv_buffer.begin); if (extended_id == 0) { on_extended_handshake(); disconnect_if_redundant(); return; } if (extended_id == upload_only_msg) { if (!packet_finished()) return; if (packet_size() != 3) { #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== UPLOAD_ONLY [ ERROR: unexpected packet size: %d ]", packet_size()); #endif return; } bool ul = detail::read_uint8(recv_buffer.begin) != 0; #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== UPLOAD_ONLY [ %s ]", (ul?"true":"false")); #endif set_upload_only(ul); return; } if (extended_id == share_mode_msg) { if (!packet_finished()) return; if (packet_size() != 3) { #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== SHARE_MODE [ ERROR: unexpected packet size: %d ]", packet_size()); #endif return; } bool sm = detail::read_uint8(recv_buffer.begin) != 0; #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== SHARE_MODE [ %s ]", (sm?"true":"false")); #endif set_share_mode(sm); return; } if (extended_id == holepunch_msg) { if (!packet_finished()) return; #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== HOLEPUNCH"); #endif on_holepunch(); return; } if (extended_id == dont_have_msg) { if (!packet_finished()) return; if (packet_size() != 6) { #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== DONT_HAVE [ ERROR: unexpected packet size: %d ]", packet_size()); #endif return; } int piece = detail::read_uint32(recv_buffer.begin) != 0; incoming_dont_have(piece); return; } #ifdef TORRENT_VERBOSE_LOGGING if (packet_finished()) peer_log("<== EXTENSION MESSAGE [ msg: %d size: %d ]" , extended_id, packet_size()); #endif #ifndef TORRENT_DISABLE_EXTENSIONS for (extension_list_t::iterator i = m_extensions.begin() , end(m_extensions.end()); i != end; ++i) { if ((*i)->on_extended(packet_size() - 2, extended_id , recv_buffer)) return; } #endif disconnect(errors::invalid_message, 2); return; } void bt_peer_connection::on_extended_handshake() { if (!packet_finished()) return; boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); buffer::const_interval recv_buffer = receive_buffer(); lazy_entry root; error_code ec; int pos; int ret = lazy_bdecode(recv_buffer.begin + 2, recv_buffer.end, root, ec, &pos); if (ret != 0 || ec || root.type() != lazy_entry::dict_t) { #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** invalid extended handshake: %s pos: %d" , ec.message().c_str(), pos); #endif return; } #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== EXTENDED HANDSHAKE: %s", print_entry(root).c_str()); #endif #ifndef TORRENT_DISABLE_EXTENSIONS for (extension_list_t::iterator i = m_extensions.begin(); !m_extensions.empty() && i != m_extensions.end();) { // a false return value means that the extension // isn't supported by the other end. So, it is removed. if (!(*i)->on_extension_handshake(root)) i = m_extensions.erase(i); else ++i; } if (is_disconnecting()) return; // upload_only if (lazy_entry const* m = root.dict_find_dict("m")) { m_upload_only_id = boost::uint8_t(m->dict_find_int_value("upload_only", 0)); m_holepunch_id = boost::uint8_t(m->dict_find_int_value("ut_holepunch", 0)); m_dont_have_id = boost::uint8_t(m->dict_find_int_value("lt_donthave", 0)); } #endif // there is supposed to be a remote listen port int listen_port = int(root.dict_find_int_value("p")); if (listen_port > 0 && peer_info_struct() != 0) { t->get_policy().update_peer_port(listen_port , peer_info_struct(), peer_info::incoming); received_listen_port(); if (is_disconnecting()) return; } // there should be a version too // but where do we put that info? int last_seen_complete = boost::uint8_t(root.dict_find_int_value("complete_ago", -1)); if (last_seen_complete >= 0) set_last_seen_complete(last_seen_complete); std::string client_info = root.dict_find_string_value("v"); if (!client_info.empty()) m_client_version = client_info; int reqq = int(root.dict_find_int_value("reqq")); if (reqq > 0) max_out_request_queue(reqq); if (root.dict_find_int_value("upload_only", 0)) set_upload_only(true); if (m_ses.m_settings.support_share_mode && root.dict_find_int_value("share_mode", 0)) set_share_mode(true); std::string myip = root.dict_find_string_value("yourip"); if (!myip.empty()) { if (myip.size() == address_v4::bytes_type().size()) { address_v4::bytes_type bytes; std::copy(myip.begin(), myip.end(), bytes.begin()); m_ses.set_external_address(address_v4(bytes) , aux::session_impl::source_peer, remote().address()); } #if TORRENT_USE_IPV6 else if (myip.size() == address_v6::bytes_type().size()) { address_v6::bytes_type bytes; std::copy(myip.begin(), myip.end(), bytes.begin()); address_v6 ipv6_address(bytes); if (ipv6_address.is_v4_mapped()) m_ses.set_external_address(ipv6_address.to_v4() , aux::session_impl::source_peer, remote().address()); else m_ses.set_external_address(ipv6_address , aux::session_impl::source_peer, remote().address()); } #endif } // if we're finished and this peer is uploading only // disconnect it if (t->is_finished() && upload_only() && t->settings().close_redundant_connections && !t->share_mode()) disconnect(errors::upload_upload_connection); } bool bt_peer_connection::dispatch_message(int received) { INVARIANT_CHECK; TORRENT_ASSERT(received > 0); // this means the connection has been closed already if (associated_torrent().expired()) { m_statistics.received_bytes(0, received); return false; } buffer::const_interval recv_buffer = receive_buffer(); TORRENT_ASSERT(recv_buffer.left() >= 1); int packet_type = (unsigned char)recv_buffer[0]; if (m_ses.m_settings.support_merkle_torrents && packet_type == 250) packet_type = msg_piece; if (packet_type < 0 || packet_type >= num_supported_messages || m_message_handler[packet_type] == 0) { #ifndef TORRENT_DISABLE_EXTENSIONS for (extension_list_t::iterator i = m_extensions.begin() , end(m_extensions.end()); i != end; ++i) { if ((*i)->on_unknown_message(packet_size(), packet_type , buffer::const_interval(recv_buffer.begin+1 , recv_buffer.end))) return packet_finished(); } #endif m_statistics.received_bytes(0, received); // What's going on here?! // break in debug builds to allow investigation // TORRENT_ASSERT(false); disconnect(errors::invalid_message); return packet_finished(); } TORRENT_ASSERT(m_message_handler[packet_type] != 0); #ifdef TORRENT_DEBUG size_type cur_payload_dl = m_statistics.last_payload_downloaded(); size_type cur_protocol_dl = m_statistics.last_protocol_downloaded(); #endif // call the correct handler for this packet type (this->*m_message_handler[packet_type])(received); #ifdef TORRENT_DEBUG TORRENT_ASSERT(m_statistics.last_payload_downloaded() - cur_payload_dl >= 0); TORRENT_ASSERT(m_statistics.last_protocol_downloaded() - cur_protocol_dl >= 0); size_type stats_diff = m_statistics.last_payload_downloaded() - cur_payload_dl + m_statistics.last_protocol_downloaded() - cur_protocol_dl; TORRENT_ASSERT(stats_diff == received); #endif return packet_finished(); } #ifndef TORRENT_DISABLE_EXTENSIONS void bt_peer_connection::write_upload_only() { INVARIANT_CHECK; boost::shared_ptr t = associated_torrent().lock(); if (m_upload_only_id == 0) return; if (t->share_mode()) return; // if we send upload-only, the other end is very likely to disconnect // us, at least if it's a seed. If we don't want to close redundant // connections, don't sent upload-only if (!m_ses.settings().close_redundant_connections) return; char msg[7] = {0, 0, 0, 3, msg_extended}; char* ptr = msg + 5; detail::write_uint8(m_upload_only_id, ptr); // if we're super seeding, we don't want to make peers // think that we only have a single piece and is upload // only, since they might disconnect immediately when // they have downloaded a single piece, although we'll // make another piece available detail::write_uint8(t->is_upload_only() && !t->super_seeding(), ptr); send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_share_mode() { INVARIANT_CHECK; boost::shared_ptr t = associated_torrent().lock(); if (m_share_mode_id == 0) return; char msg[7] = {0, 0, 0, 3, msg_extended}; char* ptr = msg + 5; detail::write_uint8(m_share_mode_id, ptr); detail::write_uint8(t->share_mode(), ptr); send_buffer(msg, sizeof(msg)); } #endif void bt_peer_connection::write_keepalive() { INVARIANT_CHECK; // Don't require the bitfield to have been sent at this point // the case where m_sent_bitfield may not be true is if the // torrent doesn't have any metadata, and a peer is timimg out. // then the keep-alive message will be sent before the bitfield // this is a violation to the original protocol, but necessary // for the metadata extension. TORRENT_ASSERT(m_sent_handshake); char msg[] = {0,0,0,0}; send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_cancel(peer_request const& r) { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); TORRENT_ASSERT(associated_torrent().lock()->valid_metadata()); char msg[17] = {0,0,0,13, msg_cancel}; char* ptr = msg + 5; detail::write_int32(r.piece, ptr); // index detail::write_int32(r.start, ptr); // begin detail::write_int32(r.length, ptr); // length send_buffer(msg, sizeof(msg)); if (!m_supports_fast) incoming_reject_request(r); } void bt_peer_connection::write_request(peer_request const& r) { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); TORRENT_ASSERT(associated_torrent().lock()->valid_metadata()); char msg[17] = {0,0,0,13, msg_request}; char* ptr = msg + 5; detail::write_int32(r.piece, ptr); // index detail::write_int32(r.start, ptr); // begin detail::write_int32(r.length, ptr); // length send_buffer(msg, sizeof(msg), message_type_request); } void bt_peer_connection::write_bitfield() { INVARIANT_CHECK; boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); TORRENT_ASSERT(m_sent_handshake && !m_sent_bitfield); TORRENT_ASSERT(t->valid_metadata()); // in this case, have_all or have_none should be sent instead TORRENT_ASSERT(!m_supports_fast || !t->is_seed() || t->num_have() != 0); if (t->super_seeding()) { if (m_supports_fast) write_have_none(); // if we are super seeding, pretend to not have any piece // and don't send a bitfield #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_sent_bitfield = true; #endif // bootstrap superseeding by sending two have message superseed_piece(-1, t->get_piece_to_super_seed(get_bitfield())); superseed_piece(-1, t->get_piece_to_super_seed(get_bitfield())); return; } else if (m_supports_fast && t->is_seed()) { write_have_all(); send_allowed_set(); return; } else if (m_supports_fast && t->num_have() == 0) { write_have_none(); send_allowed_set(); return; } else if (t->num_have() == 0) { // don't send a bitfield if we don't have any pieces #ifdef TORRENT_VERBOSE_LOGGING peer_log(" *** NOT SENDING BITFIELD"); #endif #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_sent_bitfield = true; #endif return; } int num_pieces = t->torrent_file().num_pieces(); int lazy_pieces[50]; int num_lazy_pieces = 0; int lazy_piece = 0; if (t->is_seed() && m_ses.settings().lazy_bitfields #ifndef TORRENT_DISABLE_ENCRYPTION && !m_encrypted #endif ) { num_lazy_pieces = (std::min)(50, num_pieces / 10); if (num_lazy_pieces < 1) num_lazy_pieces = 1; for (int i = 0; i < num_pieces; ++i) { if (int(random() % (num_pieces - i)) >= num_lazy_pieces - lazy_piece) continue; lazy_pieces[lazy_piece++] = i; } TORRENT_ASSERT(lazy_piece == num_lazy_pieces); } const int packet_size = (num_pieces + 7) / 8 + 5; char* msg = TORRENT_ALLOCA(char, packet_size); if (msg == 0) return; // out of memory unsigned char* ptr = (unsigned char*)msg; detail::write_int32(packet_size - 4, ptr); detail::write_uint8(msg_bitfield, ptr); if (t->is_seed()) { memset(ptr, 0xff, packet_size - 5); // Clear trailing bits unsigned char *p = ((unsigned char *)msg) + packet_size - 1; *p = (0xff << ((8 - (num_pieces & 7)) & 7)) & 0xff; } else { memset(ptr, 0, packet_size - 5); piece_picker const& p = t->picker(); int mask = 0x80; for (int i = 0; i < num_pieces; ++i) { if (p.have_piece(i)) *ptr |= mask; mask >>= 1; if (mask == 0) { mask = 0x80; ++ptr; } } } for (int c = 0; c < num_lazy_pieces; ++c) msg[5 + lazy_pieces[c] / 8] &= ~(0x80 >> (lazy_pieces[c] & 7)); #ifdef TORRENT_VERBOSE_LOGGING std::string bitfield_string; bitfield_string.resize(num_pieces); for (int k = 0; k < num_pieces; ++k) { if (msg[5 + k / 8] & (0x80 >> (k % 8))) bitfield_string[k] = '1'; else bitfield_string[k] = '0'; } peer_log("==> BITFIELD [ %s ]", bitfield_string.c_str()); #endif #if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS m_sent_bitfield = true; #endif send_buffer(msg, packet_size); if (num_lazy_pieces > 0) { for (int i = 0; i < num_lazy_pieces; ++i) { #ifdef TORRENT_VERBOSE_LOGGING peer_log("==> HAVE [ piece: %d ]", lazy_pieces[i]); #endif write_have(lazy_pieces[i]); } // TODO: if we're finished, send upload_only message } if (m_supports_fast) send_allowed_set(); } #ifndef TORRENT_DISABLE_EXTENSIONS void bt_peer_connection::write_extensions() { INVARIANT_CHECK; TORRENT_ASSERT(m_supports_extensions); TORRENT_ASSERT(m_sent_handshake); entry handshake; entry::dictionary_type& m = handshake["m"].dict(); // only send the port in case we bade the connection // on incoming connections the other end already knows // our listen port if (!m_ses.m_settings.anonymous_mode) { if (is_outgoing()) handshake["p"] = m_ses.listen_port(); handshake["v"] = m_ses.settings().handshake_client_version.empty() ? m_ses.settings().user_agent : m_ses.settings().handshake_client_version; } std::string remote_address; std::back_insert_iterator out(remote_address); detail::write_address(remote().address(), out); handshake["yourip"] = remote_address; handshake["reqq"] = m_ses.settings().max_allowed_in_request_queue; boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); m["upload_only"] = upload_only_msg; m["ut_holepunch"] = holepunch_msg; if (m_ses.m_settings.support_share_mode) m["share_mode"] = share_mode_msg; m["lt_donthave"] = dont_have_msg; int complete_ago = -1; if (t->last_seen_complete() > 0) complete_ago = t->time_since_complete(); handshake["complete_ago"] = complete_ago; // if we're using lazy bitfields or if we're super seeding, don't say // we're upload only, since it might make peers disconnect // don't tell anyone we're upload only when in share mode // we want to stay connected to seeds // if we're super seeding, we don't want to make peers // think that we only have a single piece and is upload // only, since they might disconnect immediately when // they have downloaded a single piece, although we'll // make another piece available if (t->is_upload_only() && !t->share_mode() && !t->super_seeding() && (!m_ses.settings().lazy_bitfields #ifndef TORRENT_DISABLE_ENCRYPTION || m_encrypted #endif )) handshake["upload_only"] = 1; if (m_ses.m_settings.support_share_mode && t->share_mode()) handshake["share_mode"] = 1; if (!m_ses.m_settings.anonymous_mode) { tcp::endpoint ep = m_ses.get_ipv6_interface(); if (!is_any(ep.address())) { std::string ipv6_address; std::back_insert_iterator out(ipv6_address); detail::write_address(ep.address(), out); handshake["ipv6"] = ipv6_address; } } // loop backwards, to make the first extension be the last // to fill in the handshake (i.e. give the first extensions priority) for (extension_list_t::reverse_iterator i = m_extensions.rbegin() , end(m_extensions.rend()); i != end; ++i) { (*i)->add_handshake(handshake); } #ifndef NDEBUG // make sure there are not conflicting extensions std::set ext; for (entry::dictionary_type::const_iterator i = m.begin() , end(m.end()); i != end; ++i) { if (i->second.type() != entry::int_t) continue; int val = int(i->second.integer()); TORRENT_ASSERT(ext.find(val) == ext.end()); ext.insert(val); } #endif std::vector dict_msg; bencode(std::back_inserter(dict_msg), handshake); char msg[6]; char* ptr = msg; // write the length of the message detail::write_int32((int)dict_msg.size() + 2, ptr); detail::write_uint8(msg_extended, ptr); // signal handshake message detail::write_uint8(0, ptr); send_buffer(msg, sizeof(msg)); send_buffer(&dict_msg[0], dict_msg.size()); #if defined TORRENT_VERBOSE_LOGGING std::stringstream handshake_str; handshake.print(handshake_str); peer_log("==> EXTENDED HANDSHAKE: %s", handshake_str.str().c_str()); #endif } #endif void bt_peer_connection::write_choke() { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); if (is_choked()) return; char msg[] = {0,0,0,1,msg_choke}; send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_unchoke() { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); char msg[] = {0,0,0,1,msg_unchoke}; send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_interested() { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); char msg[] = {0,0,0,1,msg_interested}; send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_not_interested() { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); char msg[] = {0,0,0,1,msg_not_interested}; send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_have(int index) { INVARIANT_CHECK; TORRENT_ASSERT(associated_torrent().lock()->valid_metadata()); TORRENT_ASSERT(index >= 0); TORRENT_ASSERT(index < associated_torrent().lock()->torrent_file().num_pieces()); TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); char msg[] = {0,0,0,5,msg_have,0,0,0,0}; char* ptr = msg + 5; detail::write_int32(index, ptr); send_buffer(msg, sizeof(msg)); } void bt_peer_connection::write_piece(peer_request const& r, disk_buffer_holder& buffer) { INVARIANT_CHECK; TORRENT_ASSERT(m_sent_handshake && m_sent_bitfield); boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); bool merkle = t->torrent_file().is_merkle_torrent() && r.start == 0; // the hash piece looks like this: // uint8_t msg // uint32_t piece index // uint32_t start // uint32_t list len // var bencoded list // var piece data char msg[4 + 1 + 4 + 4 + 4]; char* ptr = msg; TORRENT_ASSERT(r.length <= 16 * 1024); detail::write_int32(r.length + 1 + 4 + 4, ptr); if (m_ses.m_settings.support_merkle_torrents && merkle) detail::write_uint8(250, ptr); else detail::write_uint8(msg_piece, ptr); detail::write_int32(r.piece, ptr); detail::write_int32(r.start, ptr); // if this is a merkle torrent and the start offset // is 0, we need to include the merkle node hashes if (merkle) { std::vector piece_list_buf; entry piece_list; entry::list_type& l = piece_list.list(); std::map merkle_node_list = t->torrent_file().build_merkle_list(r.piece); for (std::map::iterator i = merkle_node_list.begin() , end(merkle_node_list.end()); i != end; ++i) { l.push_back(entry(entry::list_t)); l.back().list().push_back(i->first); l.back().list().push_back(i->second.to_string()); } bencode(std::back_inserter(piece_list_buf), piece_list); detail::write_int32(piece_list_buf.size(), ptr); char* ptr = msg; detail::write_int32(r.length + 1 + 4 + 4 + 4 + piece_list_buf.size(), ptr); send_buffer(msg, 17); send_buffer(&piece_list_buf[0], piece_list_buf.size()); } else { send_buffer(msg, 13); } bt_append_send_buffer(buffer.get(), r.length , boost::bind(&session_impl::free_disk_buffer , boost::ref(m_ses), _1)); buffer.release(); m_payloads.push_back(range(send_buffer_size() - r.length, r.length)); setup_send(); } namespace { struct match_peer_id { match_peer_id(peer_id const& id, peer_connection const* pc) : m_id(id), m_pc(pc) { TORRENT_ASSERT(pc); } bool operator()(policy::peer const* p) const { return p->connection != m_pc && p->connection && p->connection->pid() == m_id && !p->connection->pid().is_all_zeros() && p->address() == m_pc->remote().address(); } peer_id const& m_id; peer_connection const* m_pc; }; } // -------------------------- // RECEIVE DATA // -------------------------- void bt_peer_connection::on_receive(error_code const& error , std::size_t bytes_transferred) { INVARIANT_CHECK; if (error) { m_statistics.received_bytes(0, bytes_transferred); return; } boost::shared_ptr t = associated_torrent().lock(); #ifndef TORRENT_DISABLE_ENCRYPTION TORRENT_ASSERT(in_handshake() || !m_rc4_encrypted || m_encrypted); if (m_rc4_encrypted && m_encrypted) { std::pair wr_buf = wr_recv_buffers(bytes_transferred); m_enc_handler->decrypt(wr_buf.first.begin, wr_buf.first.left()); if (wr_buf.second.left()) m_enc_handler->decrypt(wr_buf.second.begin, wr_buf.second.left()); } #endif buffer::const_interval recv_buffer = receive_buffer(); #ifndef TORRENT_DISABLE_ENCRYPTION // m_state is set to read_pe_dhkey in initial state // (read_protocol_identifier) for incoming, or in constructor // for outgoing if (m_state == read_pe_dhkey) { m_statistics.received_bytes(0, bytes_transferred); TORRENT_ASSERT(!m_encrypted); TORRENT_ASSERT(!m_rc4_encrypted); TORRENT_ASSERT(packet_size() == dh_key_len); TORRENT_ASSERT(recv_buffer == receive_buffer()); if (!packet_finished()) return; // write our dh public key. m_dh_key_exchange is // initialized in write_pe1_2_dhkey() if (!is_outgoing()) write_pe1_2_dhkey(); if (is_disconnecting()) return; // read dh key, generate shared secret if (m_dh_key_exchange->compute_secret(recv_buffer.begin) == -1) { disconnect(errors::no_memory); return; } #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** received DH key"); #endif // PadA/B can be a max of 512 bytes, and 20 bytes more for // the sync hash (if incoming), or 8 bytes more for the // encrypted verification constant (if outgoing). Instead // of requesting the maximum possible, request the maximum // possible to ensure we do not overshoot the standard // handshake. if (is_outgoing()) { m_state = read_pe_syncvc; write_pe3_sync(); // initial payload is the standard handshake, this is // always rc4 if sent here. m_rc4_encrypted is flagged // again according to peer selection. m_rc4_encrypted = true; m_encrypted = true; write_handshake(); m_rc4_encrypted = false; m_encrypted = false; // vc,crypto_select,len(pad),pad, encrypt(handshake) // 8+4+2+0+handshake_len reset_recv_buffer(8+4+2+0+handshake_len); } else { // already written dh key m_state = read_pe_synchash; // synchash,skeyhash,vc,crypto_provide,len(pad),pad,encrypt(handshake) reset_recv_buffer(20+20+8+4+2+0+handshake_len); } TORRENT_ASSERT(!packet_finished()); return; } // cannot fall through into if (m_state == read_pe_synchash) { TORRENT_ASSERT(!m_encrypted); TORRENT_ASSERT(!m_rc4_encrypted); TORRENT_ASSERT(!is_outgoing()); TORRENT_ASSERT(recv_buffer == receive_buffer()); if (recv_buffer.left() < 20) { m_statistics.received_bytes(0, bytes_transferred); if (packet_finished()) disconnect(errors::sync_hash_not_found, 1); return; } if (!m_sync_hash.get()) { TORRENT_ASSERT(m_sync_bytes_read == 0); hasher h; // compute synchash (hash('req1',S)) h.update("req1", 4); h.update(m_dh_key_exchange->get_secret(), dh_key_len); m_sync_hash.reset(new (std::nothrow) sha1_hash(h.final())); if (!m_sync_hash) { m_statistics.received_bytes(0, bytes_transferred); disconnect(errors::no_memory); return; } } int syncoffset = get_syncoffset((char*)m_sync_hash->begin(), 20 , recv_buffer.begin, recv_buffer.left()); // No sync if (syncoffset == -1) { m_statistics.received_bytes(0, bytes_transferred); std::size_t bytes_processed = recv_buffer.left() - 20; m_sync_bytes_read += bytes_processed; if (m_sync_bytes_read >= 512) { disconnect(errors::sync_hash_not_found, 1); return; } cut_receive_buffer(bytes_processed, (std::min)(packet_size() , (512+20) - m_sync_bytes_read)); TORRENT_ASSERT(!packet_finished()); return; } // found complete sync else { std::size_t bytes_processed = syncoffset + 20; #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** sync point (hash) found at offset %d" , m_sync_bytes_read + bytes_processed - 20); #endif m_state = read_pe_skey_vc; // skey,vc - 28 bytes m_sync_hash.reset(); int transferred_used = bytes_processed - recv_buffer.left() + bytes_transferred; TORRENT_ASSERT(transferred_used <= int(bytes_transferred)); m_statistics.received_bytes(0, transferred_used); bytes_transferred -= transferred_used; cut_receive_buffer(bytes_processed, 28); } } if (m_state == read_pe_skey_vc) { m_statistics.received_bytes(0, bytes_transferred); bytes_transferred = 0; TORRENT_ASSERT(!m_encrypted); TORRENT_ASSERT(!m_rc4_encrypted); TORRENT_ASSERT(!is_outgoing()); TORRENT_ASSERT(packet_size() == 28); if (!packet_finished()) return; recv_buffer = receive_buffer(); aux::session_impl::torrent_map::const_iterator i; for (i = m_ses.m_torrents.begin(); i != m_ses.m_torrents.end(); ++i) { torrent const& ti = *i->second; sha1_hash const& skey_hash = ti.obfuscated_hash(); sha1_hash obfs_hash = m_dh_key_exchange->get_hash_xor_mask(); obfs_hash ^= skey_hash; if (std::equal(recv_buffer.begin, recv_buffer.begin + 20, (char*)&obfs_hash[0])) { if (!t) { attach_to_torrent(ti.info_hash(), false); if (is_disconnecting()) return; t = associated_torrent().lock(); TORRENT_ASSERT(t); } init_pe_rc4_handler(m_dh_key_exchange->get_secret(), ti.info_hash()); #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** stream key found, torrent located"); #endif break; } } if (!m_enc_handler.get()) { disconnect(errors::invalid_info_hash, 1); return; } // verify constant buffer::interval wr_recv_buf = wr_recv_buffer(); m_enc_handler->decrypt(wr_recv_buf.begin + 20, 8); wr_recv_buf.begin += 28; const char sh_vc[] = {0,0,0,0, 0,0,0,0}; if (!std::equal(sh_vc, sh_vc+8, recv_buffer.begin + 20)) { disconnect(errors::invalid_encryption_constant, 2); return; } #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** verification constant found"); #endif m_state = read_pe_cryptofield; reset_recv_buffer(4 + 2); } // cannot fall through into if (m_state == read_pe_syncvc) { TORRENT_ASSERT(is_outgoing()); TORRENT_ASSERT(!m_encrypted); TORRENT_ASSERT(!m_rc4_encrypted); TORRENT_ASSERT(recv_buffer == receive_buffer()); if (recv_buffer.left() < 8) { m_statistics.received_bytes(0, bytes_transferred); if (packet_finished()) disconnect(errors::invalid_encryption_constant, 2); return; } // generate the verification constant if (!m_sync_vc.get()) { TORRENT_ASSERT(m_sync_bytes_read == 0); m_sync_vc.reset(new (std::nothrow) char[8]); if (!m_sync_vc) { disconnect(errors::no_memory); return; } std::fill(m_sync_vc.get(), m_sync_vc.get() + 8, 0); m_enc_handler->decrypt(m_sync_vc.get(), 8); } TORRENT_ASSERT(m_sync_vc.get()); int syncoffset = get_syncoffset(m_sync_vc.get(), 8 , recv_buffer.begin, recv_buffer.left()); // No sync if (syncoffset == -1) { std::size_t bytes_processed = recv_buffer.left() - 8; m_sync_bytes_read += bytes_processed; m_statistics.received_bytes(0, bytes_transferred); if (m_sync_bytes_read >= 512) { disconnect(errors::invalid_encryption_constant, 2); return; } cut_receive_buffer(bytes_processed, (std::min)(packet_size() , (512+8) - m_sync_bytes_read)); TORRENT_ASSERT(!packet_finished()); } // found complete sync else { std::size_t bytes_processed = syncoffset + 8; #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** sync point (verification constant) found at offset %d" , m_sync_bytes_read + bytes_processed - 8); #endif int transferred_used = bytes_processed - recv_buffer.left() + bytes_transferred; TORRENT_ASSERT(transferred_used <= int(bytes_transferred)); m_statistics.received_bytes(0, transferred_used); bytes_transferred -= transferred_used; cut_receive_buffer(bytes_processed, 4 + 2); // delete verification constant m_sync_vc.reset(); m_state = read_pe_cryptofield; // fall through } } if (m_state == read_pe_cryptofield) // local/remote { TORRENT_ASSERT(!m_encrypted); TORRENT_ASSERT(!m_rc4_encrypted); TORRENT_ASSERT(packet_size() == 4+2); m_statistics.received_bytes(0, bytes_transferred); bytes_transferred = 0; if (!packet_finished()) return; buffer::interval wr_buf = wr_recv_buffer(); m_enc_handler->decrypt(wr_buf.begin, packet_size()); recv_buffer = receive_buffer(); int crypto_field = detail::read_int32(recv_buffer.begin); #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** crypto %s : [%s%s ]" , is_outgoing() ? "select" : "provide" , (crypto_field & 1) ? " plaintext" : "" , (crypto_field & 2) ? " rc4" : ""); #endif if (!is_outgoing()) { // select a crypto method int allowed_encryption = m_ses.get_pe_settings().allowed_enc_level; int crypto_select = crypto_field & allowed_encryption; // when prefer_rc4 is set, keep the most significant bit // otherwise keep the least significant one if (m_ses.get_pe_settings().prefer_rc4) { int mask = INT_MAX; while (crypto_select & (mask << 1)) { mask <<= 1; crypto_select = crypto_select & mask; } } else { int mask = INT_MAX; while (crypto_select & (mask >> 1)) { mask >>= 1; crypto_select = crypto_select & mask; } } if (crypto_select == 0) { disconnect(errors::unsupported_encryption_mode, 1); return; } // write the pe4 step write_pe4_sync(crypto_select); } else // is_outgoing() { // check if crypto select is valid int allowed_encryption = m_ses.get_pe_settings().allowed_enc_level; crypto_field &= allowed_encryption; if (crypto_field == 0) { // we don't allow any of the offered encryption levels disconnect(errors::unsupported_encryption_mode_selected, 2); return; } if (crypto_field == pe_settings::plaintext) m_rc4_encrypted = false; else if (crypto_field == pe_settings::rc4) m_rc4_encrypted = true; } int len_pad = detail::read_int16(recv_buffer.begin); if (len_pad < 0 || len_pad > 512) { disconnect(errors::invalid_pad_size, 2); return; } m_state = read_pe_pad; if (!is_outgoing()) reset_recv_buffer(len_pad + 2); // len(IA) at the end of pad else { if (len_pad == 0) { m_encrypted = true; m_state = init_bt_handshake; } else reset_recv_buffer(len_pad); } } if (m_state == read_pe_pad) { TORRENT_ASSERT(!m_encrypted); m_statistics.received_bytes(0, bytes_transferred); bytes_transferred = 0; if (!packet_finished()) return; int pad_size = is_outgoing() ? packet_size() : packet_size() - 2; buffer::interval wr_buf = wr_recv_buffer(); m_enc_handler->decrypt(wr_buf.begin, packet_size()); recv_buffer = receive_buffer(); if (!is_outgoing()) { recv_buffer.begin += pad_size; int len_ia = detail::read_int16(recv_buffer.begin); if (len_ia < 0) { disconnect(errors::invalid_encrypt_handshake, 2); return; } #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** len(IA) : %d", len_ia); #endif if (len_ia == 0) { // everything after this is Encrypt2 m_encrypted = true; m_state = init_bt_handshake; } else { m_state = read_pe_ia; reset_recv_buffer(len_ia); } } else // is_outgoing() { // everything that arrives after this is Encrypt2 m_encrypted = true; m_state = init_bt_handshake; } } if (m_state == read_pe_ia) { m_statistics.received_bytes(0, bytes_transferred); bytes_transferred = 0; TORRENT_ASSERT(!is_outgoing()); TORRENT_ASSERT(!m_encrypted); if (!packet_finished()) return; // ia is always rc4, so decrypt it buffer::interval wr_buf = wr_recv_buffer(); m_enc_handler->decrypt(wr_buf.begin, packet_size()); #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** decrypted ia : %d bytes", packet_size()); #endif if (!m_rc4_encrypted) { m_enc_handler.reset(); #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** destroyed rc4 keys"); #endif } // everything that arrives after this is encrypted m_encrypted = true; m_state = read_protocol_identifier; cut_receive_buffer(0, 20); } if (m_state == init_bt_handshake) { m_statistics.received_bytes(0, bytes_transferred); bytes_transferred = 0; TORRENT_ASSERT(m_encrypted); // decrypt remaining received bytes if (m_rc4_encrypted) { buffer::interval wr_buf = wr_recv_buffer(); wr_buf.begin += packet_size(); m_enc_handler->decrypt(wr_buf.begin, wr_buf.left()); #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** decrypted remaining %d bytes", wr_buf.left()); #endif } else // !m_rc4_encrypted { m_enc_handler.reset(); #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** destroyed encryption handler"); #endif } // payload stream, start with 20 handshake bytes m_state = read_protocol_identifier; reset_recv_buffer(20); // encrypted portion of handshake completed, toggle // peer_info pe_support flag back to true if (is_outgoing() && m_ses.get_pe_settings().out_enc_policy == pe_settings::enabled) { policy::peer* pi = peer_info_struct(); TORRENT_ASSERT(pi); pi->pe_support = true; } } #endif // #ifndef TORRENT_DISABLE_ENCRYPTION if (m_state == read_protocol_identifier) { m_statistics.received_bytes(0, bytes_transferred); bytes_transferred = 0; TORRENT_ASSERT(packet_size() == 20); if (!packet_finished()) return; recv_buffer = receive_buffer(); int packet_size = recv_buffer[0]; const char protocol_string[] = "\x13" "BitTorrent protocol"; if (packet_size != 19 || memcmp(recv_buffer.begin, protocol_string, 20) != 0) { #ifndef TORRENT_DISABLE_ENCRYPTION #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** unrecognized protocol header"); #endif #ifdef TORRENT_USE_OPENSSL if (is_ssl(*get_socket())) { #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** SSL peers are not allowed to use any other encryption"); #endif disconnect(errors::invalid_info_hash, 1); return; } #endif // TORRENT_USE_OPENSSL if (!is_outgoing() && m_ses.get_pe_settings().in_enc_policy == pe_settings::disabled) { disconnect(errors::no_incoming_encrypted); return; } // Don't attempt to perform an encrypted handshake // within an encrypted connection. For local connections, // we're expected to already have passed the encrypted // handshake by this point if (m_encrypted || is_outgoing()) { disconnect(errors::invalid_info_hash, 1); return; } #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** attempting encrypted connection"); #endif m_state = read_pe_dhkey; cut_receive_buffer(0, dh_key_len); TORRENT_ASSERT(!packet_finished()); return; #else disconnect(errors::invalid_info_hash, 1); return; #endif // TORRENT_DISABLE_ENCRYPTION } else { #ifndef TORRENT_DISABLE_ENCRYPTION TORRENT_ASSERT(m_state != read_pe_dhkey); if (!is_outgoing() && m_ses.get_pe_settings().in_enc_policy == pe_settings::forced && !m_encrypted && !is_ssl(*get_socket())) { disconnect(errors::no_incoming_regular); return; } #endif #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== BitTorrent protocol"); #endif } m_state = read_info_hash; reset_recv_buffer(28); } // fall through if (m_state == read_info_hash) { m_statistics.received_bytes(0, bytes_transferred); bytes_transferred = 0; TORRENT_ASSERT(packet_size() == 28); if (!packet_finished()) return; recv_buffer = receive_buffer(); #ifdef TORRENT_VERBOSE_LOGGING std::string extensions; extensions.resize(8 * 8); for (int i=0; i < 8; ++i) { for (int j=0; j < 8; ++j) { if (recv_buffer[i] & (0x80 >> j)) extensions[i*8+j] = '1'; else extensions[i*8+j] = '0'; } } peer_log("<== EXTENSIONS [ %s ext: %s%s%s]" , extensions.c_str() , (recv_buffer[7] & 0x01) ? "DHT " : "" , (recv_buffer[7] & 0x04) ? "FAST " : "" , (recv_buffer[5] & 0x10) ? "extension " : ""); #endif #ifndef TORRENT_DISABLE_EXTENSIONS std::memcpy(m_reserved_bits, recv_buffer.begin, 8); if ((recv_buffer[5] & 0x10)) m_supports_extensions = true; #endif if (recv_buffer[7] & 0x01) m_supports_dht_port = true; if (recv_buffer[7] & 0x04) m_supports_fast = true; // ok, now we have got enough of the handshake. Is this connection // attached to a torrent? if (!t) { // now, we have to see if there's a torrent with the // info_hash we got from the peer sha1_hash info_hash; std::copy(recv_buffer.begin + 8, recv_buffer.begin + 28 , (char*)info_hash.begin()); #ifndef TORRENT_DISABLE_ENCRYPTION bool allow_encrypted = m_encrypted && m_rc4_encrypted; #else bool allow_encrypted = true; #endif attach_to_torrent(info_hash, allow_encrypted); if (is_disconnecting()) return; } else { // verify info hash if (!std::equal(recv_buffer.begin + 8, recv_buffer.begin + 28 , (const char*)t->torrent_file().info_hash().begin())) { #ifdef TORRENT_VERBOSE_LOGGING peer_log("*** received invalid info_hash"); #endif disconnect(errors::invalid_info_hash, 1); return; } #ifdef TORRENT_VERBOSE_LOGGING peer_log("<<< info_hash received"); #endif } t = associated_torrent().lock(); TORRENT_ASSERT(t); // if this is a local connection, we have already // sent the handshake if (!is_outgoing()) write_handshake(); // if (t->valid_metadata()) // write_bitfield(); TORRENT_ASSERT(m_sent_handshake); if (is_disconnecting()) return; TORRENT_ASSERT(t->get_policy().has_connection(this)); m_state = read_peer_id; reset_recv_buffer(20); } // fall through if (m_state == read_peer_id) { TORRENT_ASSERT(m_sent_handshake); m_statistics.received_bytes(0, bytes_transferred); // bytes_transferred = 0; if (!t) { TORRENT_ASSERT(!packet_finished()); // TODO return; } TORRENT_ASSERT(packet_size() == 20); if (!packet_finished()) return; recv_buffer = receive_buffer(); #ifdef TORRENT_VERBOSE_LOGGING { char hex_pid[41]; to_hex(recv_buffer.begin, 20, hex_pid); hex_pid[40] = 0; char ascii_pid[21]; ascii_pid[20] = 0; for (int i = 0; i != 20; ++i) { if (is_print(recv_buffer.begin[i])) ascii_pid[i] = recv_buffer.begin[i]; else ascii_pid[i] = '.'; } peer_log("<<< received peer_id: %s client: %s\nas ascii: %s\n" , hex_pid, identify_client(peer_id(recv_buffer.begin)).c_str(), ascii_pid); } #endif peer_id pid; std::copy(recv_buffer.begin, recv_buffer.begin + 20, (char*)pid.begin()); set_pid(pid); if (t->settings().allow_multiple_connections_per_ip) { // now, let's see if this connection should be closed policy& p = t->get_policy(); policy::iterator i = std::find_if(p.begin_peer(), p.end_peer() , match_peer_id(pid, this)); if (i != p.end_peer()) { TORRENT_ASSERT((*i)->connection->pid() == pid); // we found another connection with the same peer-id // which connection should be closed in order to be // sure that the other end closes the same connection? // the peer with greatest peer-id is the one allowed to // initiate connections. So, if our peer-id is greater than // the others, we should close the incoming connection, // if not, we should close the outgoing one. if (pid < m_ses.get_peer_id() && is_outgoing()) { (*i)->connection->disconnect(errors::duplicate_peer_id); } else { disconnect(errors::duplicate_peer_id); return; } } } // disconnect if the peer has the same peer-id as ourself // since it most likely is ourself then if (pid == m_ses.get_peer_id()) { if (peer_info_struct()) t->get_policy().ban_peer(peer_info_struct()); disconnect(errors::self_connection, 1); return; } m_client_version = identify_client(pid); boost::optional f = client_fingerprint(pid); if (f && std::equal(f->name, f->name + 2, "BC")) { // if this is a bitcomet client, lower the request queue size limit if (max_out_request_queue() > 50) max_out_request_queue(50); } #ifndef TORRENT_DISABLE_EXTENSIONS for (extension_list_t::iterator i = m_extensions.begin() , end(m_extensions.end()); i != end;) { if (!(*i)->on_handshake(m_reserved_bits)) { i = m_extensions.erase(i); } else { ++i; } } if (is_disconnecting()) return; if (m_supports_extensions) write_extensions(); #endif #ifdef TORRENT_VERBOSE_LOGGING peer_log("<== HANDSHAKE"); #endif // consider this a successful connection, reset the failcount if (peer_info_struct()) t->get_policy().set_failcount(peer_info_struct(), 0); #ifndef TORRENT_DISABLE_ENCRYPTION // Toggle pe_support back to false if this is a // standard successful connection if (is_outgoing() && !m_encrypted && m_ses.get_pe_settings().out_enc_policy == pe_settings::enabled) { policy::peer* pi = peer_info_struct(); TORRENT_ASSERT(pi); pi->pe_support = false; } #endif m_state = read_packet_size; reset_recv_buffer(5); if (t->ready_for_connections()) { write_bitfield(); #ifndef TORRENT_DISABLE_DHT if (m_supports_dht_port && m_ses.m_dht) write_dht_port(m_ses.m_external_udp_port); #endif } TORRENT_ASSERT(!packet_finished()); return; } // cannot fall through into if (m_state == read_packet_size) { // Make sure this is not fallen though into TORRENT_ASSERT(recv_buffer == receive_buffer()); TORRENT_ASSERT(packet_size() == 5); if (!t) return; if (recv_buffer.left() < 4) { m_statistics.received_bytes(0, bytes_transferred); return; } int transferred_used = 4 - recv_buffer.left() + bytes_transferred; TORRENT_ASSERT(transferred_used <= int(bytes_transferred)); m_statistics.received_bytes(0, transferred_used); bytes_transferred -= transferred_used; const char* ptr = recv_buffer.begin; int packet_size = detail::read_int32(ptr); // don't accept packets larger than 1 MB if (packet_size > 1024*1024 || packet_size < 0) { m_statistics.received_bytes(0, bytes_transferred); // packet too large disconnect(errors::packet_too_large, 2); return; } if (packet_size == 0) { m_statistics.received_bytes(0, bytes_transferred); incoming_keepalive(); if (is_disconnecting()) return; // keepalive message m_state = read_packet_size; cut_receive_buffer(4, 5); return; } else { if (recv_buffer.left() < 5) return; m_state = read_packet; cut_receive_buffer(4, packet_size); TORRENT_ASSERT(bytes_transferred == 1); recv_buffer = receive_buffer(); TORRENT_ASSERT(recv_buffer.left() == 1); } } if (m_state == read_packet) { TORRENT_ASSERT(recv_buffer == receive_buffer()); if (!t) { m_statistics.received_bytes(0, bytes_transferred); disconnect(errors::torrent_removed, 1); return; } #ifdef TORRENT_DEBUG size_type cur_payload_dl = m_statistics.last_payload_downloaded(); size_type cur_protocol_dl = m_statistics.last_protocol_downloaded(); #endif if (dispatch_message(bytes_transferred)) { m_state = read_packet_size; reset_recv_buffer(5); } #ifdef TORRENT_DEBUG TORRENT_ASSERT(m_statistics.last_payload_downloaded() - cur_payload_dl >= 0); TORRENT_ASSERT(m_statistics.last_protocol_downloaded() - cur_protocol_dl >= 0); size_type stats_diff = m_statistics.last_payload_downloaded() - cur_payload_dl + m_statistics.last_protocol_downloaded() - cur_protocol_dl; TORRENT_ASSERT(stats_diff == size_type(bytes_transferred)); #endif TORRENT_ASSERT(!packet_finished()); return; } TORRENT_ASSERT(!packet_finished()); } // -------------------------- // SEND DATA // -------------------------- void bt_peer_connection::on_sent(error_code const& error , std::size_t bytes_transferred) { INVARIANT_CHECK; if (error) { m_statistics.sent_bytes(0, bytes_transferred); return; } // manage the payload markers int amount_payload = 0; if (!m_payloads.empty()) { for (std::vector::iterator i = m_payloads.begin(); i != m_payloads.end(); ++i) { i->start -= bytes_transferred; if (i->start < 0) { if (i->start + i->length <= 0) { amount_payload += i->length; } else { amount_payload += -i->start; i->length -= -i->start; i->start = 0; } } } } // TODO: move the erasing into the loop above // remove all payload ranges that has been sent m_payloads.erase( std::remove_if(m_payloads.begin(), m_payloads.end(), range_below_zero) , m_payloads.end()); TORRENT_ASSERT(amount_payload <= (int)bytes_transferred); m_statistics.sent_bytes(amount_payload, bytes_transferred - amount_payload); if (amount_payload > 0) { boost::shared_ptr t = associated_torrent().lock(); TORRENT_ASSERT(t); if (t) t->update_last_upload(); } } #if defined TORRENT_DEBUG && !defined TORRENT_DISABLE_INVARIANT_CHECKS void bt_peer_connection::check_invariant() const { boost::shared_ptr t = associated_torrent().lock(); #ifndef TORRENT_DISABLE_ENCRYPTION TORRENT_ASSERT( (bool(m_state != read_pe_dhkey) || m_dh_key_exchange.get()) || !is_outgoing()); TORRENT_ASSERT(!m_rc4_encrypted || m_enc_handler.get()); #endif if (!in_handshake()) { TORRENT_ASSERT(m_sent_handshake); } if (!m_payloads.empty()) { for (std::vector::const_iterator i = m_payloads.begin(); i != m_payloads.end() - 1; ++i) { TORRENT_ASSERT(i->start + i->length <= (i+1)->start); } } } #endif }