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/*
Copyright (c) 2003-2012, Arvid Norberg
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 <vector>
#include <boost/limits.hpp>
#include <boost/bind.hpp>
#include <boost/cstdint.hpp>
#include <stdarg.h> // for va_start, va_end
#include "libtorrent/peer_connection.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/file.hpp"
#include "libtorrent/version.hpp"
#include "libtorrent/extensions.hpp"
#include "libtorrent/aux_/session_impl.hpp"
#include "libtorrent/policy.hpp"
#include "libtorrent/socket_type.hpp"
#include "libtorrent/assert.hpp"
#include "libtorrent/broadcast_socket.hpp"
#include "libtorrent/torrent.hpp"
#include "libtorrent/peer_info.hpp"
#include "libtorrent/bt_peer_connection.hpp"
#include "libtorrent/error.hpp"
#ifdef TORRENT_DEBUG
#include <set>
#endif
//#define TORRENT_CORRUPT_DATA
using boost::shared_ptr;
using libtorrent::aux::session_impl;
namespace libtorrent
{
int round_up8(int v)
{
return ((v & 7) == 0) ? v : v + (8 - (v & 7));
}
#if defined TORRENT_REQUEST_LOGGING
void write_request_log(FILE* f, sha1_hash const& ih
, peer_connection* p, peer_request const& r)
{
// the event format in the log is:
// uint64_t timestamp (microseconds)
// uint64_t info-hash prefix
// uint32_t peer identifier
// uint32_t piece
// uint32_t start offset
// uint32_t length
char event[32];
char* ptr = event;
detail::write_uint64(total_microseconds((time_now_hires() - min_time())), ptr);
memcpy(ptr, &ih[0], 8);
ptr += 8;
detail::write_uint32(boost::uint32_t(p), ptr);
detail::write_uint32(r.piece, ptr);
detail::write_uint32(r.start, ptr);
detail::write_uint32(r.length, ptr);
int ret = fwrite(event, 1, sizeof(event), f);
if (ret != sizeof(event))
{
fprintf(stderr, "ERROR writing to request log: (%d) %s\n"
, errno, strerror(errno));
}
}
#endif
// outbound connection
peer_connection::peer_connection(
session_impl& ses
, boost::weak_ptr<torrent> tor
, shared_ptr<socket_type> s
, tcp::endpoint const& endp
, policy::peer* peerinfo
, bool outgoing)
: m_ses(ses)
, m_max_out_request_queue(m_ses.settings().max_out_request_queue)
, m_work(ses.m_io_service)
, m_last_piece(time_now())
, m_last_request(time_now())
, m_last_incoming_request(min_time())
, m_last_unchoke(time_now())
, m_last_unchoked(time_now())
, m_last_choke(min_time())
, m_last_receive(time_now())
, m_last_sent(time_now())
, m_requested(min_time())
, m_remote_dl_update(time_now())
, m_connect(time_now())
, m_became_uninterested(time_now())
, m_became_uninteresting(time_now())
, m_free_upload(0)
, m_downloaded_at_last_round(0)
, m_uploaded_at_last_round(0)
, m_uploaded_at_last_unchoke(0)
, m_disk_recv_buffer(ses, 0)
, m_socket(s)
, m_remote(endp)
, m_torrent(tor)
, m_receiving_block(piece_block::invalid)
, m_last_seen_complete(0)
, m_timeout_extend(0)
, m_outstanding_bytes(0)
, m_extension_outstanding_bytes(0)
, m_queued_time_critical(0)
, m_num_pieces(0)
, m_timeout(m_ses.settings().peer_timeout)
, m_packet_size(0)
, m_soft_packet_size(0)
, m_recv_pos(0)
, m_disk_recv_buffer_size(0)
, m_reading_bytes(0)
, m_num_invalid_requests(0)
, m_priority(1)
, m_upload_limit(0)
, m_download_limit(0)
, m_peer_info(peerinfo)
, m_speed(slow)
, m_connection_ticket(-1)
, m_remote_bytes_dled(0)
, m_remote_dl_rate(0)
, m_outstanding_writing_bytes(0)
, m_download_rate_peak(0)
, m_upload_rate_peak(0)
, m_rtt(0)
, m_prefer_whole_pieces(0)
, m_desired_queue_size(2)
, m_fast_reconnect(false)
, m_outgoing(outgoing)
, m_received_listen_port(false)
, m_peer_interested(false)
, m_peer_choked(true)
, m_interesting(false)
, m_choked(true)
, m_failed(false)
, m_ignore_bandwidth_limits(false)
, m_ignore_unchoke_slots(false)
, m_have_all(false)
, m_disconnecting(false)
, m_connecting(outgoing)
, m_queued(outgoing)
, m_request_large_blocks(false)
, m_share_mode(false)
, m_upload_only(false)
, m_snubbed(false)
, m_bitfield_received(false)
, m_no_download(false)
, m_endgame_mode(false)
, m_sent_suggests(false)
, m_holepunch_mode(false)
, m_ignore_stats(false)
, m_corked(false)
, m_has_metadata(true)
, m_exceeded_limit(false)
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
, m_in_constructor(true)
, m_disconnect_started(false)
, m_initialized(false)
, m_in_use(1337)
, m_received_in_piece(0)
#endif
{
m_superseed_piece[0] = -1;
m_superseed_piece[1] = -1;
boost::shared_ptr<torrent> t = m_torrent.lock();
// if t is NULL, we better not be connecting, since
// we can't decrement the connecting counter
TORRENT_ASSERT(t || !m_connecting);
if (m_connecting && t) t->inc_num_connecting();
m_est_reciprocation_rate = m_ses.m_settings.default_est_reciprocation_rate;
#if TORRENT_USE_I2P
if (peerinfo && peerinfo->is_i2p_addr)
{
// quadruple the timeout for i2p peers
m_timeout *= 4;
}
#endif
m_channel_state[upload_channel] = peer_info::bw_idle;
m_channel_state[download_channel] = peer_info::bw_idle;
m_quota[0] = 0;
m_quota[1] = 0;
TORRENT_ASSERT(peerinfo == 0 || peerinfo->banned == false);
#ifndef TORRENT_DISABLE_RESOLVE_COUNTRIES
std::fill(m_country, m_country + 2, 0);
#ifndef TORRENT_DISABLE_GEO_IP
if (m_ses.has_country_db())
{
char const *country = m_ses.country_for_ip(m_remote.address());
if (country != 0)
{
m_country[0] = country[0];
m_country[1] = country[1];
}
}
#endif
#endif
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
error_code ec;
TORRENT_ASSERT(m_socket->remote_endpoint(ec) == m_remote || ec);
std::string log_name = m_remote.address().to_string(ec) + "_"
+ to_string(m_remote.port()).elems;
if (t) log_name = combine_path(to_hex(t->info_hash().to_string())
, log_name);
m_logger = m_ses.create_log(log_name, m_ses.listen_port());
peer_log("%s [ ep: %s type: %s seed: %d p: %p local: %s]"
, m_outgoing ? ">>> OUTGOING_CONNECTION" : "<<< INCOMING CONNECTION"
, print_endpoint(m_remote).c_str()
, m_socket->type_name()
, m_peer_info ? m_peer_info->seed : 0, m_peer_info
, print_endpoint(m_socket->local_endpoint(ec)).c_str());
#endif
#ifndef TORRENT_DISABLE_GEO_IP
m_inet_as_name = m_ses.as_name_for_ip(m_remote.address());
#endif
#ifdef TORRENT_DEBUG
piece_failed = false;
#endif
std::fill(m_peer_id.begin(), m_peer_id.end(), 0);
}
#ifdef TORRENT_DISK_STATS
void peer_connection::log_buffer_usage(char* buffer, int size, char const* label)
{
if (m_ses.m_disk_thread.is_disk_buffer(buffer))
m_ses.m_disk_thread.rename_buffer(buffer, label);
m_ses.m_buffer_usage_logger << log_time() << " append_send_buffer: " << size << std::endl;
m_ses.log_buffer_usage();
}
#endif
void peer_connection::increase_est_reciprocation_rate()
{
m_est_reciprocation_rate += m_est_reciprocation_rate
* m_ses.m_settings.increase_est_reciprocation_rate / 100;
}
void peer_connection::decrease_est_reciprocation_rate()
{
m_est_reciprocation_rate -= m_est_reciprocation_rate
* m_ses.m_settings.decrease_est_reciprocation_rate / 100;
}
bool peer_connection::bittyrant_unchoke_compare(
boost::intrusive_ptr<peer_connection const> const& p) const
{
TORRENT_ASSERT(p);
peer_connection const& rhs = *p;
size_type d1, d2, u1, u2;
// first compare how many bytes they've sent us
d1 = downloaded_in_last_round();
d2 = rhs.downloaded_in_last_round();
// divided by the number of bytes we've sent them
u1 = uploaded_in_last_round();
u2 = rhs.uploaded_in_last_round();
boost::shared_ptr<torrent> t1 = m_torrent.lock();
TORRENT_ASSERT(t1);
boost::shared_ptr<torrent> t2 = rhs.associated_torrent().lock();
TORRENT_ASSERT(t2);
// take torrent priority into account
d1 *= 1 + t1->priority();
d2 *= 1 + t2->priority();
d1 = d1 * 1000 / (std::max)(size_type(1), u1);
d2 = d2 * 1000 / (std::max)(size_type(1), u2);
if (d1 > d2) return true;
if (d1 < d2) return false;
// if both peers are still in their send quota or not in their send quota
// prioritize the one that has waited the longest to be unchoked
return m_last_unchoke < rhs.m_last_unchoke;
}
// return true if 'this' peer should be preferred to be unchoke over p
bool peer_connection::unchoke_compare(boost::intrusive_ptr<peer_connection const> const& p) const
{
TORRENT_ASSERT(p);
peer_connection const& rhs = *p;
// if one peer belongs to a higher priority torrent than the other one
// that one should be unchoked.
boost::shared_ptr<torrent> t1 = m_torrent.lock();
TORRENT_ASSERT(t1);
boost::shared_ptr<torrent> t2 = rhs.associated_torrent().lock();
TORRENT_ASSERT(t2);
if (t1->priority() != t2->priority())
return t1->priority() > t2->priority();
// compare how many bytes they've sent us
size_type c1;
size_type c2;
c1 = downloaded_in_last_round();
c2 = rhs.downloaded_in_last_round();
if (c1 != c2) return c1 > c2;
if (m_ses.settings().seed_choking_algorithm == session_settings::round_robin)
{
// the amount uploaded since unchoked (not just in the last round)
c1 = uploaded_since_unchoked();
c2 = rhs.uploaded_since_unchoked();
// the way the round-robin unchoker works is that it,
// by default, prioritizes any peer that is already unchoked.
// this maintain the status quo across unchoke rounds. However,
// peers that are unchoked, but have sent more than one quota
// since they were unchoked, they get de-prioritized.
int pieces = m_ses.settings().seeding_piece_quota;
// if a peer is already unchoked, and the number of bytes sent since it was unchoked
// is greater than the send quanta, then it's done with it' upload slot, and we
// can de-prioritize it
bool c1_quota_complete = !is_choked() && c1 > (std::max)(t1->torrent_file().piece_length() * pieces, 256 * 1024);
bool c2_quota_complete = !rhs.is_choked() && c2 > (std::max)(t2->torrent_file().piece_length() * pieces, 256 * 1024);
// if c2 has completed a quanta, it shuold be de-prioritized
// and vice versa
if (c1_quota_complete < c2_quota_complete) return true;
if (c1_quota_complete > c2_quota_complete) return false;
// if both peers have either completed a quanta, or not.
// keep unchoked peers prioritized over choked ones, to let
// peers keep working on uploading a full quanta
if (is_choked() < rhs.is_choked()) return true;
if (is_choked() > rhs.is_choked()) return false;
// if the peers are still identical (say, they're both waiting to be unchoked)
// fall through and rely on the logic to prioritize peers who have waited
// the longest to be unchoked
}
else if (m_ses.settings().seed_choking_algorithm == session_settings::fastest_upload)
{
c1 = uploaded_in_last_round();
c2 = rhs.uploaded_in_last_round();
// take torrent priority into account
c1 *= 1 + t1->priority();
c2 *= 1 + t2->priority();
if (c1 > c2) return true;
if (c2 > c1) return false;
}
else if (m_ses.settings().seed_choking_algorithm == session_settings::anti_leech)
{
// the anti-leech seeding algorithm ranks peers based on how many pieces
// they have, prefering to unchoke peers that just started and peers that
// are close to completing. Like this:
// ^
// | \ / |
// | \ / |
// | \ / |
// s | \ / |
// c | \ / |
// o | \ / |
// r | \ / |
// e | \ / |
// | \ / |
// | \ / |
// | \ / |
// | \ / |
// | V |
// +---------------------------+
// 0% num have pieces 100%
int t1_total = t1->torrent_file().num_pieces();
int t2_total = t2->torrent_file().num_pieces();
int score1 = (num_have_pieces() < t1_total / 2
? t1_total - num_have_pieces() : num_have_pieces()) * 1000 / t1_total;
int score2 = (rhs.num_have_pieces() < t2_total / 2
? t2_total - rhs.num_have_pieces() : rhs.num_have_pieces()) * 1000 / t2_total;
if (score1 > score2) return true;
if (score2 > score1) return false;
}
// prioritize the one that has waited the longest to be unchoked
// the round-robin unchoker relies on this logic. Don't change it
// without moving this into that unchoker logic
return m_last_unchoke < rhs.m_last_unchoke;
}
bool peer_connection::upload_rate_compare(peer_connection const* p) const
{
size_type c1;
size_type c2;
boost::shared_ptr<torrent> t1 = m_torrent.lock();
TORRENT_ASSERT(t1);
boost::shared_ptr<torrent> t2 = p->associated_torrent().lock();
TORRENT_ASSERT(t2);
c1 = uploaded_in_last_round();
c2 = p->uploaded_in_last_round();
// take torrent priority into account
c1 *= 1 + t1->priority();
c2 *= 1 + t2->priority();
return c1 > c2;
}
void peer_connection::reset_choke_counters()
{
m_downloaded_at_last_round= m_statistics.total_payload_download();
m_uploaded_at_last_round = m_statistics.total_payload_upload();
}
void peer_connection::start()
{
TORRENT_ASSERT(m_peer_info == 0 || m_peer_info->connection == this);
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!m_outgoing)
{
tcp::socket::non_blocking_io ioc(true);
error_code ec;
m_socket->io_control(ioc, ec);
if (ec)
{
disconnect(ec);
return;
}
m_remote = m_socket->remote_endpoint(ec);
if (ec)
{
disconnect(ec);
return;
}
TORRENT_ASSERT(m_remote.address() != address_v4::any());
if (m_remote.address().is_v4())
{
m_socket->set_option(type_of_service(m_ses.settings().peer_tos), ec);
#if defined TORRENT_VERBOSE_LOGGING
peer_log(">>> SET_TOS[ tos: %d e: %s ]", m_ses.settings().peer_tos, ec.message().c_str());
#endif
}
}
if (t && t->ready_for_connections())
{
init();
}
}
void peer_connection::update_interest()
{
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!t) return;
// if m_have_piece is 0, it means the connections
// have not been initialized yet. The interested
// flag will be updated once they are.
if (m_have_piece.size() == 0) return;
if (!t->ready_for_connections()) return;
bool interested = false;
if (!t->is_upload_only())
{
piece_picker const& p = t->picker();
int num_pieces = p.num_pieces();
for (int j = 0; j != num_pieces; ++j)
{
if (!p.have_piece(j)
&& t->piece_priority(j) > 0
&& m_have_piece[j])
{
interested = true;
break;
}
}
}
if (!interested) send_not_interested();
else t->get_policy().peer_is_interesting(*this);
TORRENT_ASSERT(in_handshake() || is_interesting() == interested);
}
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
void peer_connection::peer_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);
(*m_logger) << buf;
}
#endif
#ifndef TORRENT_DISABLE_EXTENSIONS
void peer_connection::add_extension(boost::shared_ptr<peer_plugin> ext)
{
m_extensions.push_back(ext);
}
peer_plugin const* peer_connection::find_plugin(char const* type)
{
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if (strcmp((*i)->type(), type) == 0) return (*i).get();
}
return 0;
}
#endif
void peer_connection::send_allowed_set()
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
if (t->super_seeding())
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** SKIPPING ALLOWED SET BECAUSE OF SUPER SEEDING");
#endif
return;
}
if (upload_only())
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** SKIPPING ALLOWED SET BECAUSE PEER IS UPLOAD ONLY");
#endif
return;
}
int num_allowed_pieces = m_ses.settings().allowed_fast_set_size;
if (num_allowed_pieces == 0) return;
int num_pieces = t->torrent_file().num_pieces();
if (num_allowed_pieces >= num_pieces)
{
// this is a special case where we have more allowed
// fast pieces than pieces in the torrent. Just send
// an allowed fast message for every single piece
for (int i = 0; i < num_pieces; ++i)
{
// there's no point in offering fast pieces
// that the peer already has
if (has_piece(i)) continue;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> ALLOWED_FAST [ %d ]", i);
#endif
write_allow_fast(i);
TORRENT_ASSERT(std::find(m_accept_fast.begin()
, m_accept_fast.end(), i)
== m_accept_fast.end());
if (m_accept_fast.empty()) m_accept_fast.reserve(10);
m_accept_fast.push_back(i);
}
return;
}
std::string x;
address const& addr = m_remote.address();
if (addr.is_v4())
{
address_v4::bytes_type bytes = addr.to_v4().to_bytes();
x.assign((char*)&bytes[0], bytes.size());
}
#if TORRENT_USE_IPV6
else
{
address_v6::bytes_type bytes = addr.to_v6().to_bytes();
x.assign((char*)&bytes[0], bytes.size());
}
#endif
x.append((char*)&t->torrent_file().info_hash()[0], 20);
sha1_hash hash = hasher(x.c_str(), x.size()).final();
for (;;)
{
char* p = (char*)&hash[0];
for (int i = 0; i < 5; ++i)
{
int piece = detail::read_uint32(p) % num_pieces;
if (std::find(m_accept_fast.begin(), m_accept_fast.end(), piece)
== m_accept_fast.end())
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> ALLOWED_FAST [ %d ]", piece);
#endif
write_allow_fast(piece);
if (m_accept_fast.empty()) m_accept_fast.reserve(10);
m_accept_fast.push_back(piece);
if (int(m_accept_fast.size()) >= num_allowed_pieces
|| int(m_accept_fast.size()) == num_pieces) return;
}
}
hash = hasher((char*)&hash[0], 20).final();
}
}
void peer_connection::on_metadata_impl()
{
boost::shared_ptr<torrent> t = associated_torrent().lock();
m_have_piece.resize(t->torrent_file().num_pieces(), m_have_all);
m_num_pieces = m_have_piece.count();
// now that we know how many pieces there are
// remove any invalid allowed_fast and suggest pieces
// now that we know what the number of pieces are
for (std::vector<int>::iterator i = m_allowed_fast.begin();
i != m_allowed_fast.end();)
{
if (*i < m_num_pieces)
{
++i;
continue;
}
i = m_allowed_fast.erase(i);
}
for (std::vector<int>::iterator i = m_suggested_pieces.begin();
i != m_suggested_pieces.end();)
{
if (*i < m_num_pieces)
{
++i;
continue;
}
i = m_suggested_pieces.erase(i);
}
on_metadata();
if (m_disconnecting) return;
}
void peer_connection::init()
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
TORRENT_ASSERT(t->valid_metadata());
TORRENT_ASSERT(t->ready_for_connections());
m_have_piece.resize(t->torrent_file().num_pieces(), m_have_all);
if (m_have_all) m_num_pieces = t->torrent_file().num_pieces();
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
TORRENT_ASSERT(!m_initialized);
m_initialized = true;
#endif
// now that we have a piece_picker,
// update it with this peer's pieces
TORRENT_ASSERT(m_num_pieces == m_have_piece.count());
if (m_num_pieces == int(m_have_piece.size()))
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** THIS IS A SEED [ p: %p ]", m_peer_info);
#endif
// if this is a web seed. we don't have a peer_info struct
t->get_policy().set_seed(m_peer_info, true);
m_upload_only = true;
t->peer_has_all(this);
if (t->is_upload_only()) send_not_interested();
else t->get_policy().peer_is_interesting(*this);
return;
}
// if we're a seed, we don't keep track of piece availability
if (!t->is_seed())
{
t->peer_has(m_have_piece, this);
bool interesting = false;
for (int i = 0; i < int(m_have_piece.size()); ++i)
{
if (m_have_piece[i])
{
// if the peer has a piece and we don't, the peer is interesting
if (!t->have_piece(i)
&& t->picker().piece_priority(i) != 0)
interesting = true;
}
}
if (interesting) t->get_policy().peer_is_interesting(*this);
else send_not_interested();
}
else
{
update_interest();
}
}
peer_connection::~peer_connection()
{
// INVARIANT_CHECK;
TORRENT_ASSERT(!m_in_constructor);
TORRENT_ASSERT(m_disconnecting);
TORRENT_ASSERT(m_disconnect_started);
TORRENT_ASSERT(m_ses.is_network_thread());
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
m_in_use = 0;
#endif
// defensive
boost::shared_ptr<torrent> t = m_torrent.lock();
// if t is NULL, we better not be connecting, since
// we can't decrement the connecting counter
TORRENT_ASSERT(t || !m_connecting);
// we should really have dealt with this already
TORRENT_ASSERT(!m_connecting);
if (m_connecting && t)
{
t->dec_num_connecting();
m_connecting = false;
}
m_disk_recv_buffer_size = 0;
#ifndef TORRENT_DISABLE_EXTENSIONS
m_extensions.clear();
#endif
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** CONNECTION CLOSED");
#endif
// TORRENT_ASSERT(!m_ses.has_peer(this));
TORRENT_ASSERT(m_request_queue.empty());
TORRENT_ASSERT(m_download_queue.empty());
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
for (aux::session_impl::torrent_map::const_iterator i = m_ses.m_torrents.begin()
, end(m_ses.m_torrents.end()); i != end; ++i)
TORRENT_ASSERT(!i->second->has_peer(this));
if (m_peer_info)
TORRENT_ASSERT(m_peer_info->connection == 0);
#endif
}
int peer_connection::picker_options() const
{
int ret = 0;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
if (!t) return 0;
if (t->is_sequential_download())
{
ret |= piece_picker::sequential | piece_picker::ignore_whole_pieces;
}
else if (t->num_have() < t->settings().initial_picker_threshold)
{
// if we have fewer pieces than a certain threshols
// don't pick rare pieces, just pick random ones,
// and prioritize finishing them
ret |= piece_picker::prioritize_partials;
}
else
{
ret |= piece_picker::rarest_first | piece_picker::speed_affinity;
}
if (m_snubbed)
{
// snubbed peers should request
// the common pieces first, just to make
// it more likely for all snubbed peers to
// request blocks from the same piece
ret |= piece_picker::reverse;
}
if (t->settings().prioritize_partial_pieces)
ret |= piece_picker::prioritize_partials;
if (on_parole()) ret |= piece_picker::on_parole
| piece_picker::prioritize_partials;
// only one of rarest_first, common_first and sequential can be set.
TORRENT_ASSERT((ret & piece_picker::rarest_first) ? 1 : 0
+ (ret & piece_picker::sequential) ? 1 : 0 <= 1);
return ret;
}
void peer_connection::fast_reconnect(bool r)
{
if (!peer_info_struct() || peer_info_struct()->fast_reconnects > 1)
return;
m_fast_reconnect = r;
peer_info_struct()->last_connected = m_ses.session_time();
int rewind = m_ses.settings().min_reconnect_time * m_ses.settings().max_failcount;
if (peer_info_struct()->last_connected < rewind) peer_info_struct()->last_connected = 0;
else peer_info_struct()->last_connected -= rewind;
if (peer_info_struct()->fast_reconnects < 15)
++peer_info_struct()->fast_reconnects;
}
void peer_connection::announce_piece(int index)
{
// dont announce during handshake
if (in_handshake()) return;
// remove suggested pieces once we have them
std::vector<int>::iterator i = std::find(
m_suggested_pieces.begin(), m_suggested_pieces.end(), index);
if (i != m_suggested_pieces.end()) m_suggested_pieces.erase(i);
// remove allowed fast pieces
i = std::find(m_allowed_fast.begin(), m_allowed_fast.end(), index);
if (i != m_allowed_fast.end()) m_allowed_fast.erase(i);
if (has_piece(index))
{
// if we got a piece that this peer has
// it might have been the last interesting
// piece this peer had. We might not be
// interested anymore
update_interest();
if (is_disconnecting()) return;
// optimization, don't send have messages
// to peers that already have the piece
if (!m_ses.settings().send_redundant_have)
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> HAVE [ piece: %d ] SUPRESSED", index);
#endif
return;
}
}
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> HAVE [ piece: %d ]", index);
#endif
write_have(index);
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#endif
}
bool peer_connection::has_piece(int i) const
{
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
TORRENT_ASSERT(t->valid_metadata());
TORRENT_ASSERT(i >= 0);
TORRENT_ASSERT(i < t->torrent_file().num_pieces());
return m_have_piece[i];
}
std::vector<pending_block> const& peer_connection::request_queue() const
{
return m_request_queue;
}
std::vector<pending_block> const& peer_connection::download_queue() const
{
return m_download_queue;
}
std::vector<peer_request> const& peer_connection::upload_queue() const
{
return m_requests;
}
time_duration peer_connection::download_queue_time(int extra_bytes) const
{
int rate = m_statistics.transfer_rate(stat::download_payload)
+ m_statistics.transfer_rate(stat::download_protocol);
// avoid division by zero
if (rate < 50) rate = 50;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
return seconds((m_outstanding_bytes + m_queued_time_critical * t->block_size()) / rate);
}
void peer_connection::add_stat(size_type downloaded, size_type uploaded)
{
m_statistics.add_stat(downloaded, uploaded);
}
bitfield const& peer_connection::get_bitfield() const
{
return m_have_piece;
}
void peer_connection::received_valid_data(int index)
{
// this fails because we haven't had time to disconnect
// seeds yet, and we might have just become one
// INVARIANT_CHECK;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
TORRENT_TRY {
(*i)->on_piece_pass(index);
} TORRENT_CATCH(std::exception&) {}
}
#endif
}
bool peer_connection::received_invalid_data(int index, bool single_peer)
{
INVARIANT_CHECK;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
TORRENT_TRY {
(*i)->on_piece_failed(index);
} TORRENT_CATCH(std::exception&) {}
}
#endif
return true;
}
size_type peer_connection::total_free_upload() const
{
return m_free_upload;
}
void peer_connection::add_free_upload(size_type free_upload)
{
INVARIANT_CHECK;
m_free_upload += free_upload;
}
// verifies a piece to see if it is valid (is within a valid range)
// and if it can correspond to a request generated by libtorrent.
bool peer_connection::verify_piece(const peer_request& p) const
{
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
TORRENT_ASSERT(t->valid_metadata());
torrent_info const& ti = t->torrent_file();
return p.piece >= 0
&& p.piece < ti.num_pieces()
&& p.start >= 0
&& p.start < ti.piece_length()
&& t->to_req(piece_block(p.piece, p.start / t->block_size())) == p;
}
void peer_connection::attach_to_torrent(sha1_hash const& ih, bool allow_encrypted)
{
INVARIANT_CHECK;
TORRENT_ASSERT(!m_disconnecting);
TORRENT_ASSERT(m_torrent.expired());
boost::weak_ptr<torrent> wpt = m_ses.find_torrent(ih);
boost::shared_ptr<torrent> t = wpt.lock();
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
// now that we know which torrent this peer belongs
// to. Move the log file into its directory
error_code ec;
std::string log_name = combine_path(to_hex(ih.to_string())
, m_remote.address().to_string(ec) + "_"
+ to_string(m_remote.port()).elems);
m_logger->move_log_file(m_ses.get_log_path(), log_name, m_ses.listen_port());
#endif
if (t && t->is_aborted())
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** the torrent has been aborted");
#endif
t.reset();
}
if (!t)
{
// we couldn't find the torrent!
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** couldn't find a torrent with the given info_hash: %s torrents:", to_hex(ih.to_string()).c_str());
session_impl::torrent_map const& torrents = m_ses.m_torrents;
for (session_impl::torrent_map::const_iterator i = torrents.begin()
, end(torrents.end()); i != end; ++i)
{
peer_log(" %s", to_hex(i->second->torrent_file().info_hash().to_string()).c_str());
}
#endif
disconnect(errors::invalid_info_hash, 1);
return;
}
if (t->is_paused() && (!t->is_auto_managed()
|| !m_ses.m_settings.incoming_starts_queued_torrents))
{
// paused torrents will not accept
// incoming connections unless they are auto managed
// and inconing_starts_queued_torrents is true
// torrents that have errors should always reject
// incoming peers
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("rejected connection to paused torrent");
#endif
disconnect(errors::torrent_paused, 2);
return;
}
#if TORRENT_USE_I2P
i2p_stream* i2ps = m_socket->get<i2p_stream>();
if (!i2ps && t->torrent_file().is_i2p() && !m_ses.m_settings.allow_i2p_mixed)
{
// the torrent is an i2p torrent, the peer is a regular peer
// and we don't allow mixed mode. Disconnect the peer.
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("rejected regular connection to i2p torrent");
#endif
disconnect(errors::peer_banned, 2);
return;
}
#endif // TORRENT_USE_I2P
TORRENT_ASSERT(m_torrent.expired());
if (t->is_paused()
&& m_ses.m_settings.incoming_starts_queued_torrents
&& !m_ses.is_paused()
&& !t->is_aborted()
&& !m_ses.is_aborted())
{
t->resume();
}
// check to make sure we don't have another connection with the same
// info_hash and peer_id. If we do. close this connection.
t->attach_peer(this);
if (m_disconnecting) return;
m_torrent = wpt;
if (m_exceeded_limit)
{
// find a peer in some torrent (presumably the one with most peers)
// and disconnect the lowest ranking peer
boost::weak_ptr<torrent> torr = m_ses.find_disconnect_candidate_torrent();
boost::shared_ptr<torrent> other_t = torr.lock();
if (other_t)
{
if (other_t->num_peers() <= t->num_peers())
{
disconnect(errors::too_many_connections);
return;
}
// find the lowest ranking peer and disconnect that
peer_connection* p = other_t->find_lowest_ranking_peer();
p->disconnect(errors::too_many_connections);
peer_disconnected_other();
}
else
{
disconnect(errors::too_many_connections);
return;
}
}
TORRENT_ASSERT(!m_torrent.expired());
// if the torrent isn't ready to accept
// connections yet, we'll have to wait with
// our initialization
if (t->ready_for_connections()) init();
TORRENT_ASSERT(!m_torrent.expired());
// assume the other end has no pieces
// if we don't have valid metadata yet,
// leave the vector unallocated
TORRENT_ASSERT(m_num_pieces == 0);
m_have_piece.clear_all();
TORRENT_ASSERT(!m_torrent.expired());
}
boost::uint32_t peer_connection::peer_rank() const
{
return m_peer_info->rank(m_ses.external_address()
, m_ses.listen_port());
}
// message handlers
// -----------------------------
// --------- KEEPALIVE ---------
// -----------------------------
void peer_connection::incoming_keepalive()
{
INVARIANT_CHECK;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== KEEPALIVE");
#endif
}
// -----------------------------
// ----------- CHOKE -----------
// -----------------------------
void peer_connection::incoming_choke()
{
INVARIANT_CHECK;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_choke()) return;
}
#endif
if (is_disconnecting()) return;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== CHOKE");
#endif
m_peer_choked = true;
set_endgame(false);
clear_request_queue();
}
void peer_connection::clear_request_queue()
{
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
// clear the requests that haven't been sent yet
if (peer_info_struct() == 0 || !peer_info_struct()->on_parole)
{
// if the peer is not in parole mode, clear the queued
// up block requests
if (!t->is_seed())
{
piece_picker& p = t->picker();
for (std::vector<pending_block>::const_iterator i = m_request_queue.begin()
, end(m_request_queue.end()); i != end; ++i)
{
p.abort_download(i->block, peer_info_struct());
}
}
m_request_queue.clear();
m_queued_time_critical = 0;
}
}
bool match_request(peer_request const& r, piece_block const& b, int block_size)
{
if (int(b.piece_index) != r.piece) return false;
if (int(b.block_index) != r.start / block_size) return false;
if (r.start % block_size != 0) return false;
return true;
}
// -----------------------------
// -------- REJECT PIECE -------
// -----------------------------
void peer_connection::incoming_reject_request(peer_request const& r)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== REJECT_PIECE [ piece: %d | s: %d | l: %d ]"
, r.piece, r.start, r.length);
#endif
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_reject(r)) return;
}
#endif
if (is_disconnecting()) return;
std::vector<pending_block>::iterator i = std::find_if(
m_download_queue.begin(), m_download_queue.end()
, boost::bind(match_request, boost::cref(r), boost::bind(&pending_block::block, _1)
, t->block_size()));
if (i != m_download_queue.end())
{
pending_block b = *i;
bool remove_from_picker = !i->timed_out && !i->not_wanted;
m_download_queue.erase(i);
TORRENT_ASSERT(m_outstanding_bytes >= r.length);
m_outstanding_bytes -= r.length;
if (m_outstanding_bytes < 0) m_outstanding_bytes = 0;
// if the peer is in parole mode, keep the request
if (peer_info_struct() && peer_info_struct()->on_parole)
{
// we should only add it if the block is marked as
// busy in the piece-picker
if (remove_from_picker)
m_request_queue.insert(m_request_queue.begin(), b);
}
else if (!t->is_seed() && remove_from_picker)
{
piece_picker& p = t->picker();
p.abort_download(b.block, peer_info_struct());
}
#if !defined TORRENT_DISABLE_INVARIANT_CHECKS && defined TORRENT_DEBUG
check_invariant();
#endif
}
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
else
{
peer_log("*** PIECE NOT IN REQUEST QUEUE");
}
#endif
if (has_peer_choked())
{
// if we're choked and we got a rejection of
// a piece in the allowed fast set, remove it
// from the allow fast set.
std::vector<int>::iterator i = std::find(
m_allowed_fast.begin(), m_allowed_fast.end(), r.piece);
if (i != m_allowed_fast.end()) m_allowed_fast.erase(i);
}
else
{
std::vector<int>::iterator i = std::find(m_suggested_pieces.begin()
, m_suggested_pieces.end(), r.piece);
if (i != m_suggested_pieces.end())
m_suggested_pieces.erase(i);
}
if (m_request_queue.empty() && m_download_queue.size() < 2)
{
#ifdef TORRENT_STATS
++m_ses.m_reject_piece_picks;
#endif
request_a_block(*t, *this);
send_block_requests();
}
}
// -----------------------------
// ------- SUGGEST PIECE -------
// -----------------------------
void peer_connection::incoming_suggest(int index)
{
INVARIANT_CHECK;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== SUGGEST_PIECE [ piece: %d ]", index);
#endif
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!t) return;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_suggest(index)) return;
}
#endif
if (is_disconnecting()) return;
if (index < 0)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("<== INVALID_SUGGEST_PIECE [ %d ]", index);
#endif
return;
}
if (t->valid_metadata())
{
if (index >= int(m_have_piece.size()))
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("<== INVALID_ALLOWED_FAST [ %d | s: %d ]"
, index, int(m_have_piece.size()));
#endif
return;
}
// if we already have the piece, we can
// ignore this message
if (t->have_piece(index))
return;
}
if (int(m_suggested_pieces.size()) > m_ses.m_settings.max_suggest_pieces)
m_suggested_pieces.erase(m_suggested_pieces.begin());
m_suggested_pieces.push_back(index);
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("** SUGGEST_PIECE [ piece: %d added to set: %d ]", index, int(m_suggested_pieces.size()));
#endif
}
// -----------------------------
// ---------- UNCHOKE ----------
// -----------------------------
void peer_connection::incoming_unchoke()
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_unchoke()) return;
}
#endif
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== UNCHOKE");
#endif
m_peer_choked = false;
m_last_unchoked = time_now();
if (is_disconnecting()) return;
if (is_interesting())
{
#ifdef TORRENT_STATS
++m_ses.m_unchoke_piece_picks;
#endif
request_a_block(*t, *this);
send_block_requests();
}
}
// -----------------------------
// -------- INTERESTED ---------
// -----------------------------
void peer_connection::incoming_interested()
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_interested()) return;
}
#endif
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== INTERESTED");
#endif
m_peer_interested = true;
if (is_disconnecting()) return;
// if the peer is ready to download stuff, it must have metadata
m_has_metadata = true;
disconnect_if_redundant();
if (is_disconnecting()) return;
if (is_choked() && !t->graceful_pause())
{
if (ignore_unchoke_slots())
{
// if this peer is expempted from the choker
// just unchoke it immediately
send_unchoke();
}
else if ((m_ses.num_uploads() < m_ses.settings().unchoke_slots_limit
|| m_ses.settings().unchoke_slots_limit < 0)
&& (t->ratio() == 0
|| share_diff() >= size_type(-free_upload_amount)
|| t->is_finished()))
{
// if the peer is choked and we have upload slots left,
// then unchoke it. Another condition that has to be met
// is that the torrent doesn't keep track of the individual
// up/down ratio for each peer (ratio == 0) or (if it does
// keep track) this particular connection isn't a leecher.
// If the peer was choked because it was leeching, don't
// unchoke it again.
// The exception to this last condition is if we're a seed.
// In that case we don't care if people are leeching, they
// can't pay for their downloads anyway.
m_ses.unchoke_peer(*this);
}
#if defined TORRENT_VERBOSE_LOGGING
else
{
std::string reason;
if (m_ses.num_uploads() >= m_ses.settings().unchoke_slots_limit
&& m_ses.settings().unchoke_slots_limit >= 0)
{
peer_log("DID NOT UNCHOKE [ the number of uploads (%d)"
"is more than or equal to the limit (%d) ]"
, m_ses.num_uploads(), m_ses.settings().unchoke_slots_limit);
}
else
{
peer_log("DID NOT UNCHOKE [ the share ratio (%d) is <= "
"free_upload_amount (%d) and we are not seeding and the ratio (%d) is non-zero"
, share_diff(), int(free_upload_amount), t->ratio());
}
}
#endif
}
#if defined TORRENT_VERBOSE_LOGGING
else if (t->graceful_pause())
{
peer_log("DID NOT UNCHOKE [ graceful pause mode ]");
}
#endif
}
// -----------------------------
// ------ NOT INTERESTED -------
// -----------------------------
void peer_connection::incoming_not_interested()
{
INVARIANT_CHECK;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_not_interested()) return;
}
#endif
m_became_uninterested = time_now();
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== NOT_INTERESTED");
#endif
m_peer_interested = false;
if (is_disconnecting()) return;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
if (!is_choked())
{
if (ignore_unchoke_slots())
{
send_choke();
}
else
{
if (m_peer_info && m_peer_info->optimistically_unchoked)
{
m_peer_info->optimistically_unchoked = false;
m_ses.m_optimistic_unchoke_time_scaler = 0;
}
m_ses.choke_peer(*this);
m_ses.m_unchoke_time_scaler = 0;
}
}
if (t->ratio() != 0.f)
{
TORRENT_ASSERT(share_diff() < (std::numeric_limits<size_type>::max)());
size_type diff = share_diff();
if (diff > 0 && is_seed())
{
// the peer is a seed and has sent
// us more than we have sent it back.
// consider the download as free download
t->add_free_upload(diff);
add_free_upload(-diff);
}
}
if (t->super_seeding())
{
// maybe we need to try another piece, to see if the peer
// is interested in us then
superseed_piece(-1, t->get_piece_to_super_seed(m_have_piece));
}
}
// -----------------------------
// ----------- HAVE ------------
// -----------------------------
void peer_connection::incoming_have(int index)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_have(index)) return;
}
#endif
if (is_disconnecting()) return;
// if we haven't received a bitfield, it was
// probably omitted, which is the same as 'have_none'
if (!m_bitfield_received) incoming_have_none();
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== HAVE [ piece: %d ]", index);
#endif
if (is_disconnecting()) return;
if (!t->valid_metadata() && index >= int(m_have_piece.size()))
{
if (index < 131072)
{
// if we don't have metadata
// and we might not have received a bitfield
// extend the bitmask to fit the new
// have message
m_have_piece.resize(index + 1, false);
}
else
{
// unless the index > 64k, in which case
// we just ignore it
return;
}
}
// if we got an invalid message, abort
if (index >= int(m_have_piece.size()) || index < 0)
{
disconnect(errors::invalid_have, 2);
return;
}
if (t->super_seeding() && !m_ses.settings().strict_super_seeding)
{
// if we're superseeding and the peer just told
// us that it completed the piece we're superseeding
// to it, change the superseeding piece for this peer
// if the peer optimizes out redundant have messages
// this will be handled when the peer sends not-interested
// instead.
if (super_seeded_piece(index))
{
superseed_piece(index, t->get_piece_to_super_seed(m_have_piece));
}
}
if (m_have_piece[index])
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log(" got redundant HAVE message for index: %d", index);
#endif
return;
}
m_have_piece.set_bit(index);
++m_num_pieces;
// if the peer is downloading stuff, it must have metadata
m_has_metadata = true;
// only update the piece_picker if
// we have the metadata and if
// we're not a seed (in which case
// we won't have a piece picker)
if (!t->valid_metadata()) return;
t->peer_has(index, this);
// this will disregard all have messages we get within
// the first two seconds. Since some clients implements
// lazy bitfields, these will not be reliable to use
// for an estimated peer download rate.
if (!peer_info_struct()
|| m_ses.session_time() - peer_info_struct()->last_connected > 2)
{
// update bytes downloaded since last timer
m_remote_bytes_dled += t->torrent_file().piece_size(index);
}
// it's important to not disconnect before we have
// updated the piece picker, otherwise we will incorrectly
// decrement the piece count without first incrementing it
if (is_seed())
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** THIS IS A SEED [ p: %p ]", m_peer_info);
#endif
t->seen_complete();
t->get_policy().set_seed(m_peer_info, true);
m_upload_only = true;
disconnect_if_redundant();
if (is_disconnecting()) return;
}
if (!t->have_piece(index)
&& !t->is_seed()
&& !is_interesting()
&& t->picker().piece_priority(index) != 0)
t->get_policy().peer_is_interesting(*this);
// if we're super seeding, this might mean that somebody
// forwarded this piece. In which case we need to give
// a new piece to that peer
if (t->super_seeding()
&& m_ses.settings().strict_super_seeding
&& (!super_seeded_piece(index) || t->num_peers() == 1))
{
for (torrent::peer_iterator i = t->begin()
, end(t->end()); i != end; ++i)
{
peer_connection* p = *i;
if (!p->super_seeded_piece(index)) continue;
if (!p->has_piece(index)) continue;
p->superseed_piece(index, t->get_piece_to_super_seed(p->get_bitfield()));
}
}
}
// -----------------------------
// -------- DONT HAVE ----------
// -----------------------------
void peer_connection::incoming_dont_have(int index)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_dont_have(index)) return;
}
#endif
if (is_disconnecting()) return;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== DONT_HAVE [ piece: %d ]", index);
#endif
if (is_disconnecting()) return;
// if we got an invalid message, abort
if (index >= int(m_have_piece.size()) || index < 0)
{
disconnect(errors::invalid_dont_have, 2);
return;
}
if (!m_have_piece[index])
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log(" got redundant DONT_HAVE message for index: %d", index);
#endif
return;
}
bool was_seed = is_seed();
m_have_piece.clear_bit(index);
TORRENT_ASSERT(m_num_pieces > 0);
--m_num_pieces;
// only update the piece_picker if
// we have the metadata and if
// we're not a seed (in which case
// we won't have a piece picker)
if (!t->valid_metadata()) return;
t->peer_lost(index, this);
if (was_seed)
t->get_policy().set_seed(m_peer_info, false);
}
// -----------------------------
// --------- BITFIELD ----------
// -----------------------------
void peer_connection::incoming_bitfield(bitfield const& bits)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_bitfield(bits)) return;
}
#endif
if (is_disconnecting()) return;
#ifdef TORRENT_VERBOSE_LOGGING
std::string bitfield_str;
bitfield_str.resize(bits.size());
for (int i = 0; i < int(bits.size()); ++i)
bitfield_str[i] = bits[i] ? '1' : '0';
peer_log("<== BITFIELD [ %s ]", bitfield_str.c_str());
#endif
// if we don't have the metedata, we cannot
// verify the bitfield size
if (t->valid_metadata()
&& (bits.size() + 7) / 8 != (m_have_piece.size() + 7) / 8)
{
disconnect(errors::invalid_bitfield_size, 2);
return;
}
if (m_bitfield_received)
{
// if we've already received a bitfield message
// we first need to count down all the pieces
// we believe the peer has first
t->peer_lost(m_have_piece, this);
}
m_bitfield_received = true;
// if we don't have metadata yet
// just remember the bitmask
// don't update the piecepicker
// (since it doesn't exist yet)
if (!t->ready_for_connections())
{
#ifdef TORRENT_VERBOSE_LOGGING
if (m_num_pieces == int(bits.size()))
peer_log("*** THIS IS A SEED [ p: %p ]", m_peer_info);
#endif
m_have_piece = bits;
m_num_pieces = bits.count();
t->get_policy().set_seed(m_peer_info, m_num_pieces == int(bits.size()));
return;
}
TORRENT_ASSERT(t->valid_metadata());
int num_pieces = bits.count();
if (num_pieces == int(m_have_piece.size()))
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** THIS IS A SEED [ p: %p ]", m_peer_info);
#endif
// if this is a web seed. we don't have a peer_info struct
t->get_policy().set_seed(m_peer_info, true);
m_upload_only = true;
m_have_piece.set_all();
m_num_pieces = num_pieces;
t->peer_has_all(this);
if (!t->is_upload_only())
t->get_policy().peer_is_interesting(*this);
disconnect_if_redundant();
return;
}
// let the torrent know which pieces the
// peer has
// if we're a seed, we don't keep track of piece availability
bool interesting = false;
t->peer_has(bits, this);
m_have_piece = bits;
m_num_pieces = num_pieces;
if (interesting) t->get_policy().peer_is_interesting(*this);
else if (upload_only()) disconnect(errors::upload_upload_connection);
}
void peer_connection::disconnect_if_redundant()
{
// we cannot disconnect in a constructor
TORRENT_ASSERT(m_in_constructor == false);
if (!m_ses.settings().close_redundant_connections) return;
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!t) return;
// if we don't have the metadata yet, don't disconnect
// also, if the peer doesn't have metadata we shouldn't
// disconnect it, since it may want to request the
// metadata from us
if (!t->valid_metadata() || !has_metadata()) return;
// don't close connections in share mode, we don't know if we need them
if (t->share_mode()) return;
if (m_upload_only && t->is_upload_only())
{
disconnect(errors::upload_upload_connection);
return;
}
if (m_upload_only
&& !m_interesting
&& m_bitfield_received
&& t->are_files_checked())
{
disconnect(errors::uninteresting_upload_peer);
return;
}
}
// -----------------------------
// ---------- REQUEST ----------
// -----------------------------
void peer_connection::incoming_request(peer_request const& r)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#ifdef TORRENT_STATS
++m_ses.m_piece_requests;
#endif
#if defined TORRENT_VERBOSE_LOGGING
peer_log("<== REQUEST [ piece: %d s: %d l: %d ]"
, r.piece, r.start, r.length);
#endif
if (t->super_seeding()
&& !super_seeded_piece(r.piece))
{
#ifdef TORRENT_STATS
++m_ses.m_invalid_piece_requests;
#endif
++m_num_invalid_requests;
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** INVALID_REQUEST [ piece not superseeded "
"i: %d t: %d n: %d h: %d ss1: %d ss2: %d ]"
, m_peer_interested
, int(t->torrent_file().piece_size(r.piece))
, t->torrent_file().num_pieces()
, t->have_piece(r.piece)
, m_superseed_piece[0]
, m_superseed_piece[1]);
#endif
write_reject_request(r);
if (t->alerts().should_post<invalid_request_alert>())
{
t->alerts().post_alert(invalid_request_alert(
t->get_handle(), m_remote, m_peer_id, r));
}
return;
}
// if we haven't received a bitfield, it was
// probably omitted, which is the same as 'have_none'
if (!m_bitfield_received) incoming_have_none();
if (is_disconnecting()) return;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_request(r)) return;
}
#endif
if (is_disconnecting()) return;
if (!t->valid_metadata())
{
#ifdef TORRENT_STATS
++m_ses.m_invalid_piece_requests;
#endif
// if we don't have valid metadata yet,
// we shouldn't get a request
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** INVALID_REQUEST [ we don't have metadata yet ]");
peer_log("==> REJECT_PIECE [ piece: %d s: %d l: %d ]"
, r.piece , r.start , r.length);
#endif
write_reject_request(r);
return;
}
if (int(m_requests.size()) > m_ses.settings().max_allowed_in_request_queue)
{
#ifdef TORRENT_STATS
++m_ses.m_max_piece_requests;
#endif
// don't allow clients to abuse our
// memory consumption.
// ignore requests if the client
// is making too many of them.
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** INVALID_REQUEST [ incoming request queue full %d ]"
, int(m_requests.size()));
peer_log("==> REJECT_PIECE [ piece: %d s: %d l: %d ]"
, r.piece , r.start , r.length);
#endif
write_reject_request(r);
return;
}
// make sure this request
// is legal and that the peer
// is not choked
if (r.piece >= 0
&& r.piece < t->torrent_file().num_pieces()
&& t->have_piece(r.piece)
&& r.start >= 0
&& r.start < t->torrent_file().piece_size(r.piece)
&& r.length > 0
&& r.length + r.start <= t->torrent_file().piece_size(r.piece)
&& m_peer_interested
&& r.length <= t->block_size())
{
// if we have choked the client
// ignore the request
if (m_choked && std::find(m_accept_fast.begin(), m_accept_fast.end()
, r.piece) == m_accept_fast.end())
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** REJECTING REQUEST [ peer choked and piece not in allowed fast set ]");
peer_log(" ==> REJECT_PIECE [ piece: %d | s: %d | l: %d ]"
, r.piece, r.start, r.length);
#endif
#ifdef TORRENT_STATS
++m_ses.m_choked_piece_requests;
#endif
write_reject_request(r);
time_duration since_choked = time_now() - m_last_choke;
// allow peers to send request up to 2 seconds after getting choked,
// the disconnect them
if (total_milliseconds(since_choked) > 2000)
{
disconnect(errors::too_many_requests_when_choked, 2);
return;
}
}
else
{
m_requests.push_back(r);
#ifdef TORRENT_REQUEST_LOGGING
if (m_ses.m_request_log)
write_request_log(m_ses.m_request_log, t->info_hash(), this, r);
#endif
m_last_incoming_request = time_now();
fill_send_buffer();
}
}
else
{
#ifdef TORRENT_STATS
++m_ses.m_invalid_piece_requests;
#endif
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** INVALID_REQUEST [ "
"i: %d t: %d n: %d h: %d block_limit: %d ]"
, m_peer_interested
, int(t->torrent_file().piece_size(r.piece))
, t->torrent_file().num_pieces()
, t->have_piece(r.piece)
, t->block_size());
peer_log("==> REJECT_PIECE [ piece: %d s: %d l: %d ]"
, r.piece , r.start , r.length);
#endif
write_reject_request(r);
++m_num_invalid_requests;
if (t->alerts().should_post<invalid_request_alert>())
{
t->alerts().post_alert(invalid_request_alert(
t->get_handle(), m_remote, m_peer_id, r));
}
}
}
void peer_connection::incoming_piece_fragment(int bytes)
{
m_last_piece = time_now();
TORRENT_ASSERT(m_outstanding_bytes >= bytes);
m_outstanding_bytes -= bytes;
if (m_outstanding_bytes < 0) m_outstanding_bytes = 0;
boost::shared_ptr<torrent> t = associated_torrent().lock();
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
TORRENT_ASSERT(m_received_in_piece + bytes <= t->block_size());
m_received_in_piece += bytes;
#endif
// progress of this torrent increased
t->state_updated();
#if !defined TORRENT_DISABLE_INVARIANT_CHECKS && defined TORRENT_DEBUG
check_invariant();
#endif
}
void peer_connection::start_receive_piece(peer_request const& r)
{
#if !defined TORRENT_DISABLE_INVARIANT_CHECKS && defined TORRENT_DEBUG
check_invariant();
#endif
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
buffer::const_interval recv_buffer = receive_buffer();
int recv_pos = recv_buffer.end - recv_buffer.begin;
TORRENT_ASSERT(recv_pos >= 9);
#endif
boost::shared_ptr<torrent> t = associated_torrent().lock();
TORRENT_ASSERT(t);
// piece_block can't necessarily hold large piece numbers
// so check that first
if (r.piece < 0
|| r.piece >= t->torrent_file().num_pieces()
|| r.start < 0
|| r.start > t->torrent_file().piece_length())
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** INVALID_PIECE [ piece: %d s: %d l: %d ]"
, r.piece, r.start, r.length);
#endif
disconnect(errors::invalid_piece, 2);
return;
}
piece_block b(r.piece, r.start / t->block_size());
m_receiving_block = b;
if (!verify_piece(r))
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** INVALID_PIECE [ piece: %d s: %d l: %d ]"
, r.piece, r.start, r.length);
#endif
disconnect(errors::invalid_piece, 2);
return;
}
bool in_req_queue = false;
for (std::vector<pending_block>::const_iterator i = m_download_queue.begin()
, end(m_download_queue.end()); i != end; ++i)
{
if (i->block != b) continue;
in_req_queue = true;
break;
}
// if this is not in the request queue, we have to
// assume our outstanding bytes includes this piece too
// if we're disconnecting, we shouldn't add pieces
if (!in_req_queue && !m_disconnecting)
{
for (std::vector<pending_block>::iterator i = m_request_queue.begin()
, end(m_request_queue.end()); i != end; ++i)
{
if (i->block != b) continue;
in_req_queue = true;
if (i - m_request_queue.begin() < m_queued_time_critical)
--m_queued_time_critical;
m_request_queue.erase(i);
break;
}
m_download_queue.insert(m_download_queue.begin(), b);
if (!in_req_queue)
{
if (t->alerts().should_post<unwanted_block_alert>())
{
t->alerts().post_alert(unwanted_block_alert(t->get_handle(), m_remote
, m_peer_id, b.block_index, b.piece_index));
}
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** The block we just got was not in the request queue ***");
#endif
TORRENT_ASSERT(m_download_queue.front().block == b);
m_download_queue.front().not_wanted = true;
}
m_outstanding_bytes += r.length;
}
}
#ifdef TORRENT_DEBUG
struct check_postcondition
{
check_postcondition(boost::shared_ptr<torrent> const& t_
, bool init_check = true): t(t_) { if (init_check) check(); }
~check_postcondition() { check(); }
void check()
{
if (!t->is_seed())
{
const int blocks_per_piece = static_cast<int>(
(t->torrent_file().piece_length() + t->block_size() - 1) / t->block_size());
std::vector<piece_picker::downloading_piece> const& dl_queue
= t->picker().get_download_queue();
for (std::vector<piece_picker::downloading_piece>::const_iterator i =
dl_queue.begin(); i != dl_queue.end(); ++i)
{
TORRENT_ASSERT(i->finished <= blocks_per_piece);
}
}
}
shared_ptr<torrent> t;
};
#endif
// -----------------------------
// ----------- PIECE -----------
// -----------------------------
void peer_connection::incoming_piece(peer_request const& p, char const* data)
{
char* buffer = m_ses.allocate_disk_buffer("receive buffer");
if (buffer == 0)
{
disconnect(errors::no_memory);
return;
}
disk_buffer_holder holder(m_ses, buffer);
std::memcpy(buffer, data, p.length);
incoming_piece(p, holder);
}
void peer_connection::incoming_piece(peer_request const& p, disk_buffer_holder& data)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
TORRENT_ASSERT(!m_disk_recv_buffer);
TORRENT_ASSERT(m_disk_recv_buffer_size == 0);
// we're not receiving any block right now
m_receiving_block = piece_block::invalid;
#ifdef TORRENT_CORRUPT_DATA
// corrupt all pieces from certain peers
if (m_remote.address().is_v4()
&& (m_remote.address().to_v4().to_ulong() & 0xf) == 0)
{
data.get()[0] = ~data.get()[0];
}
#endif
// if we haven't received a bitfield, it was
// probably omitted, which is the same as 'have_none'
if (!m_bitfield_received) incoming_have_none();
if (is_disconnecting()) return;
update_desired_queue_size();
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_piece(p, data))
{
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
TORRENT_ASSERT(m_received_in_piece == p.length);
m_received_in_piece = 0;
#endif
return;
}
}
#endif
if (is_disconnecting()) return;
#ifdef TORRENT_DEBUG
check_postcondition post_checker_(t);
#if !defined TORRENT_DISABLE_INVARIANT_CHECKS && defined TORRENT_EXPENSIVE_INVARIANT_CHECKS
t->check_invariant();
#endif
#endif
#ifdef TORRENT_VERBOSE_LOGGING
hasher h;
h.update(data.get(), p.length);
peer_log("<== PIECE [ piece: %d | s: %d | l: %d | ds: %d | qs: %d | q: %d | hash: %s ]"
, p.piece, p.start, p.length, statistics().download_rate()
, int(m_desired_queue_size), int(m_download_queue.size())
, to_hex(h.final().to_string()).c_str());
#endif
if (p.length == 0)
{
if (t->alerts().should_post<peer_error_alert>())
{
t->alerts().post_alert(peer_error_alert(t->get_handle(), m_remote
, m_peer_id, errors::peer_sent_empty_piece));
}
// This is used as a reject-request by bitcomet
incoming_reject_request(p);
return;
}
// if we're already seeding, don't bother,
// just ignore it
if (t->is_seed())
{
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
TORRENT_ASSERT(m_received_in_piece == p.length);
m_received_in_piece = 0;
#endif
if (!m_download_queue.empty()) m_download_queue.erase(m_download_queue.begin());
t->add_redundant_bytes(p.length, torrent::piece_seed);
return;
}
ptime now = time_now();
piece_picker& picker = t->picker();
piece_manager& fs = t->filesystem();
std::vector<piece_block> finished_blocks;
piece_block block_finished(p.piece, p.start / t->block_size());
TORRENT_ASSERT(verify_piece(p));
std::vector<pending_block>::iterator b
= std::find_if(
m_download_queue.begin()
, m_download_queue.end()
, has_block(block_finished));
if (b == m_download_queue.end())
{
if (t->alerts().should_post<unwanted_block_alert>())
{
t->alerts().post_alert(unwanted_block_alert(t->get_handle(), m_remote
, m_peer_id, block_finished.block_index, block_finished.piece_index));
}
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** The block we just got was not in the request queue ***");
#endif
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
TORRENT_ASSERT_VAL(m_received_in_piece == p.length, m_received_in_piece);
m_received_in_piece = 0;
#endif
t->add_redundant_bytes(p.length, torrent::piece_unknown);
return;
}
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
pending_block pending_b = *b;
#endif
int block_index = b - m_download_queue.begin();
TORRENT_ASSERT(m_download_queue[block_index] == pending_b);
for (int i = 0; i < block_index; ++i)
{
pending_block& qe = m_download_queue[i];
TORRENT_ASSERT(m_download_queue[block_index] == pending_b);
TORRENT_ASSERT(i < block_index);
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** SKIPPED_PIECE [ piece: %d b: %d dqs: %d ]"
, qe.block.piece_index, qe.block.block_index, int(m_desired_queue_size));
#endif
++qe.skipped;
// if the number of times a block is skipped by out of order
// blocks exceeds the size of the outstanding queue, assume that
// the other end dropped the request.
if (m_ses.m_settings.drop_skipped_requests
&& qe.skipped > m_desired_queue_size)
{
if (m_ses.m_alerts.should_post<request_dropped_alert>())
m_ses.m_alerts.post_alert(request_dropped_alert(t->get_handle()
, remote(), pid(), qe.block.block_index, qe.block.piece_index));
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** DROPPED_PIECE [ piece: %d b: %d dqs: %d skip: %d ]"
, qe.block.piece_index, qe.block.block_index
, int(m_desired_queue_size), qe.skipped);
#endif
if (!qe.timed_out && !qe.not_wanted)
picker.abort_download(qe.block, peer_info_struct());
TORRENT_ASSERT(m_outstanding_bytes >= t->to_req(qe.block).length);
m_outstanding_bytes -= t->to_req(qe.block).length;
if (m_outstanding_bytes < 0) m_outstanding_bytes = 0;
TORRENT_ASSERT(m_download_queue[block_index] == pending_b);
m_download_queue.erase(m_download_queue.begin() + i);
--i;
--block_index;
TORRENT_ASSERT(m_download_queue[block_index] == pending_b);
#if !defined TORRENT_DISABLE_INVARIANT_CHECKS && defined TORRENT_DEBUG
check_invariant();
#endif
}
}
TORRENT_ASSERT(int(m_download_queue.size()) > block_index);
b = m_download_queue.begin() + block_index;
TORRENT_ASSERT(*b == pending_b);
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
TORRENT_ASSERT_VAL(m_received_in_piece == p.length, m_received_in_piece);
m_received_in_piece = 0;
#endif
// if the block we got is already finished, then ignore it
if (picker.is_downloaded(block_finished))
{
torrent::wasted_reason_t reason;
if (b->timed_out) reason = torrent::piece_timed_out;
else if (b->not_wanted) reason = torrent::piece_cancelled;
else if (b->busy) reason = torrent::piece_end_game;
else reason = torrent::piece_unknown;
t->add_redundant_bytes(p.length, reason);
m_download_queue.erase(b);
m_timeout_extend = 0;
if (!m_download_queue.empty())
m_requested = now;
#ifdef TORRENT_STATS
++m_ses.m_incoming_redundant_piece_picks;
#endif
request_a_block(*t, *this);
send_block_requests();
return;
}
if (total_seconds(now - m_requested)
< m_ses.settings().request_timeout
&& m_snubbed)
{
m_snubbed = false;
if (m_ses.m_alerts.should_post<peer_unsnubbed_alert>())
{
m_ses.m_alerts.post_alert(peer_unsnubbed_alert(t->get_handle()
, m_remote, m_peer_id));
}
}
int write_queue_size = fs.async_write(p, data, boost::bind(&peer_connection::on_disk_write_complete
, self(), _1, _2, p, t));
m_outstanding_writing_bytes += p.length;
m_download_queue.erase(b);
if (write_queue_size / 16 / 1024 > m_ses.m_settings.cache_size / 2
&& m_ses.m_settings.cache_size > 5
&& (now - m_ses.m_last_disk_queue_performance_warning) > seconds(10)
&& m_ses.m_alerts.should_post<performance_alert>())
{
m_ses.m_last_disk_queue_performance_warning = now;
t->alerts().post_alert(performance_alert(t->get_handle()
, performance_alert::too_high_disk_queue_limit));
}
if (!m_ses.can_write_to_disk()
&& m_ses.settings().max_queued_disk_bytes
&& t->alerts().should_post<performance_alert>()
&& (now - m_ses.m_last_disk_performance_warning) > seconds(10))
{
m_ses.m_last_disk_performance_warning = now;
t->alerts().post_alert(performance_alert(t->get_handle()
, performance_alert::outstanding_disk_buffer_limit_reached));
}
if (!m_download_queue.empty())
{
m_timeout_extend = (std::max)(m_timeout_extend
- m_ses.settings().request_timeout, 0);
m_requested += seconds(m_ses.settings().request_timeout);
if (m_requested > now) m_requested = now;
}
else
{
m_timeout_extend = 0;
}
bool was_finished = picker.is_piece_finished(p.piece);
// did we request this block from any other peers?
bool multi = picker.num_peers(block_finished) > 1;
picker.mark_as_writing(block_finished, peer_info_struct());
TORRENT_ASSERT(picker.num_peers(block_finished) == 0);
// if we requested this block from other peers, cancel it now
if (multi) t->cancel_block(block_finished);
TORRENT_ASSERT(picker.num_peers(block_finished) == 0);
#if defined TORRENT_DEBUG && !defined TORRENT_DISABLE_INVARIANT_CHECKS \
&& defined TORRENT_EXPENSIVE_INVARIANT_CHECKS
t->check_invariant();
#endif
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
piece_picker::downloading_piece pi;
picker.piece_info(p.piece, pi);
int num_blocks = picker.blocks_in_piece(p.piece);
TORRENT_ASSERT(pi.writing + pi.finished + pi.requested <= num_blocks);
TORRENT_ASSERT(picker.is_piece_finished(p.piece) == (pi.writing + pi.finished == num_blocks));
#endif
// did we just finish the piece?
// this means all blocks are either written
// to disk or are in the disk write cache
if (picker.is_piece_finished(p.piece) && !was_finished)
{
#ifdef TORRENT_DEBUG
check_postcondition post_checker2_(t, false);
#endif
t->async_verify_piece(p.piece, boost::bind(&torrent::piece_finished, t
, p.piece, _1));
}
if (is_disconnecting()) return;
#ifdef TORRENT_STATS
++m_ses.m_incoming_piece_picks;
#endif
request_a_block(*t, *this);
send_block_requests();
}
void peer_connection::on_disk_write_complete(int ret, disk_io_job const& j
, peer_request p, boost::shared_ptr<torrent> t)
{
#ifdef TORRENT_STATS
++m_ses.m_num_messages[aux::session_impl::on_disk_write_counter];
#endif
TORRENT_ASSERT(m_ses.is_network_thread());
// flush send buffer at the end of this scope
// TODO: 1 peers should really be corked/uncorked outside of
// all completed disk operations
cork _c(*this);
INVARIANT_CHECK;
m_outstanding_writing_bytes -= p.length;
TORRENT_ASSERT(m_outstanding_writing_bytes >= 0);
#if defined(TORRENT_VERBOSE_LOGGING) || defined(TORRENT_LOGGING)
// (*m_ses.m_logger) << time_now_string() << " *** DISK_WRITE_COMPLETE [ p: "
// << p.piece << " o: " << p.start << " ]\n";
#endif
if (!t)
{
disconnect(j.error);
return;
}
// in case the outstanding bytes just dropped down
// to allow to receive more data
setup_receive(read_async);
piece_block block_finished(p.piece, p.start / t->block_size());
if (ret == -1)
{
// handle_disk_error may disconnect us
t->handle_disk_error(j, this);
return;
}
if (!t->has_picker()) return;
piece_picker& picker = t->picker();
TORRENT_ASSERT(p.piece == j.piece);
TORRENT_ASSERT(p.start == j.offset);
TORRENT_ASSERT(picker.num_peers(block_finished) == 0);
picker.mark_as_finished(block_finished, peer_info_struct());
if (t->alerts().should_post<block_finished_alert>())
{
t->alerts().post_alert(block_finished_alert(t->get_handle(),
remote(), pid(), block_finished.block_index, block_finished.piece_index));
}
if (t->is_aborted()) return;
}
// -----------------------------
// ---------- CANCEL -----------
// -----------------------------
void peer_connection::incoming_cancel(peer_request const& r)
{
INVARIANT_CHECK;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_cancel(r)) return;
}
#endif
if (is_disconnecting()) return;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== CANCEL [ piece: %d | s: %d | l: %d ]", r.piece, r.start, r.length);
#endif
std::vector<peer_request>::iterator i
= std::find(m_requests.begin(), m_requests.end(), r);
if (i != m_requests.end())
{
#ifdef TORRENT_STATS
++m_ses.m_cancelled_piece_requests;
#endif
m_requests.erase(i);
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> REJECT_PIECE [ piece: %d s: %d l: %d ]"
, r.piece , r.start , r.length);
#endif
write_reject_request(r);
}
else
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** GOT CANCEL NOT IN THE QUEUE");
#endif
}
}
// -----------------------------
// --------- DHT PORT ----------
// -----------------------------
void peer_connection::incoming_dht_port(int listen_port)
{
INVARIANT_CHECK;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== DHT_PORT [ p: %d ]", listen_port);
#endif
#ifndef TORRENT_DISABLE_DHT
m_ses.add_dht_node(udp::endpoint(
m_remote.address(), listen_port));
#endif
}
// -----------------------------
// --------- HAVE ALL ----------
// -----------------------------
void peer_connection::incoming_have_all()
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
// we cannot disconnect in a constructor, and
// this function may end up doing that
TORRENT_ASSERT(m_in_constructor == false);
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== HAVE_ALL");
#endif
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_have_all()) return;
}
#endif
if (is_disconnecting()) return;
if (m_bitfield_received)
t->peer_lost(m_have_piece, this);
m_have_all = true;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** THIS IS A SEED [ p: %p ]", m_peer_info);
#endif
t->get_policy().set_seed(m_peer_info, true);
m_upload_only = true;
m_bitfield_received = true;
// if we don't have metadata yet
// just remember the bitmask
// don't update the piecepicker
// (since it doesn't exist yet)
if (!t->ready_for_connections())
{
// assume seeds are interesting when we
// don't even have the metadata
t->get_policy().peer_is_interesting(*this);
disconnect_if_redundant();
// TODO: this might need something more
// so that once we have the metadata
// we can construct a full bitfield
return;
}
TORRENT_ASSERT(!m_have_piece.empty());
m_have_piece.set_all();
m_num_pieces = m_have_piece.size();
t->peer_has_all(this);
// if we're finished, we're not interested
if (t->is_upload_only()) send_not_interested();
else t->get_policy().peer_is_interesting(*this);
disconnect_if_redundant();
}
// -----------------------------
// --------- HAVE NONE ---------
// -----------------------------
void peer_connection::incoming_have_none()
{
INVARIANT_CHECK;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== HAVE_NONE");
#endif
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_have_none()) return;
}
#endif
if (is_disconnecting()) return;
if (m_bitfield_received)
t->peer_lost(m_have_piece, this);
t->get_policy().set_seed(m_peer_info, false);
m_bitfield_received = true;
m_have_piece.clear_all();
m_num_pieces = 0;
// if the peer is ready to download stuff, it must have metadata
m_has_metadata = true;
// we're never interested in a peer that doesn't have anything
send_not_interested();
TORRENT_ASSERT(!m_have_piece.empty() || !t->ready_for_connections());
disconnect_if_redundant();
}
// -----------------------------
// ------- ALLOWED FAST --------
// -----------------------------
void peer_connection::incoming_allowed_fast(int index)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<== ALLOWED_FAST [ %d ]", index);
#endif
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((*i)->on_allowed_fast(index)) return;
}
#endif
if (is_disconnecting()) return;
if (index < 0)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("<== INVALID_ALLOWED_FAST [ %d ]", index);
#endif
return;
}
if (t->valid_metadata())
{
if (index >= int(m_have_piece.size()))
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("<== INVALID_ALLOWED_FAST [ %d | s: %d ]"
, index, int(m_have_piece.size()));
#endif
return;
}
// if we already have the piece, we can
// ignore this message
if (t->have_piece(index))
return;
}
// if we don't have the metadata, we'll verify
// this piece index later
m_allowed_fast.push_back(index);
// if the peer has the piece and we want
// to download it, request it
if (int(m_have_piece.size()) > index
&& m_have_piece[index]
&& t->valid_metadata()
&& t->has_picker()
&& t->picker().piece_priority(index) > 0)
{
t->get_policy().peer_is_interesting(*this);
}
}
std::vector<int> const& peer_connection::allowed_fast()
{
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
// TODO: sort the allowed fast set in priority order
return m_allowed_fast;
}
bool peer_connection::can_request_time_critical() const
{
if (has_peer_choked() || !is_interesting()) return false;
if ((int)m_download_queue.size() + (int)m_request_queue.size()
> m_desired_queue_size * 2) return false;
if (on_parole()) return false;
if (m_disconnecting) return false;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
if (t->upload_mode()) return false;
return true;
}
void peer_connection::make_time_critical(piece_block const& block)
{
std::vector<pending_block>::iterator rit = std::find_if(m_request_queue.begin()
, m_request_queue.end(), has_block(block));
if (rit == m_request_queue.end()) return;
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
TORRENT_ASSERT(t->has_picker());
TORRENT_ASSERT(t->picker().is_requested(block));
#endif
// ignore it if it's already time critical
if (rit - m_request_queue.begin() < m_queued_time_critical) return;
pending_block b = *rit;
m_request_queue.erase(rit);
m_request_queue.insert(m_request_queue.begin() + m_queued_time_critical, b);
++m_queued_time_critical;
}
bool peer_connection::add_request(piece_block const& block, int flags)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
TORRENT_ASSERT(!m_disconnecting);
TORRENT_ASSERT(t->valid_metadata());
TORRENT_ASSERT(block.block_index != piece_block::invalid.block_index);
TORRENT_ASSERT(block.piece_index != piece_block::invalid.piece_index);
TORRENT_ASSERT(int(block.piece_index) < t->torrent_file().num_pieces());
TORRENT_ASSERT(int(block.block_index) < t->torrent_file().piece_size(block.piece_index));
TORRENT_ASSERT(!t->picker().is_requested(block) || (t->picker().num_peers(block) > 0));
TORRENT_ASSERT(!t->have_piece(block.piece_index));
TORRENT_ASSERT(std::find_if(m_download_queue.begin(), m_download_queue.end()
, has_block(block)) == m_download_queue.end());
TORRENT_ASSERT(std::find(m_request_queue.begin(), m_request_queue.end()
, block) == m_request_queue.end());
if (t->upload_mode()) return false;
if (m_disconnecting) return false;
piece_picker::piece_state_t state;
peer_speed_t speed = peer_speed();
char const* speedmsg = 0;
if (speed == fast)
{
speedmsg = "fast";
state = piece_picker::fast;
}
else if (speed == medium)
{
speedmsg = "medium";
state = piece_picker::medium;
}
else
{
speedmsg = "slow";
state = piece_picker::slow;
}
if (flags & req_busy)
{
// this block is busy (i.e. it has been requested
// from another peer already). Only allow one busy
// request in the pipeline at the time
for (std::vector<pending_block>::const_iterator i = m_download_queue.begin()
, end(m_download_queue.end()); i != end; ++i)
{
if (i->busy) return false;
}
for (std::vector<pending_block>::const_iterator i = m_request_queue.begin()
, end(m_request_queue.end()); i != end; ++i)
{
if (i->busy) return false;
}
}
if (!t->picker().mark_as_downloading(block, peer_info_struct(), state))
return false;
if (t->alerts().should_post<block_downloading_alert>())
{
t->alerts().post_alert(block_downloading_alert(t->get_handle(),
remote(), pid(), speedmsg, block.block_index, block.piece_index));
}
pending_block pb(block);
pb.busy = (flags & req_busy) ? true : false;
if (flags & req_time_critical)
{
m_request_queue.insert(m_request_queue.begin() + m_queued_time_critical
, pb);
++m_queued_time_critical;
}
else
{
m_request_queue.push_back(pb);
}
return true;
}
void peer_connection::cancel_all_requests()
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
// this peer might be disconnecting
if (!t) return;
TORRENT_ASSERT(t->valid_metadata());
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** CANCEL ALL REQUESTS");
#endif
while (!m_request_queue.empty())
{
t->picker().abort_download(m_request_queue.back().block, peer_info_struct());
m_request_queue.pop_back();
}
m_queued_time_critical = 0;
// make a local temporary copy of the download queue, since it
// may be modified when we call write_cancel (for peers that don't
// support the FAST extensions).
std::vector<pending_block> temp_copy = m_download_queue;
for (std::vector<pending_block>::iterator i = temp_copy.begin()
, end(temp_copy.end()); i != end; ++i)
{
piece_block b = i->block;
int block_offset = b.block_index * t->block_size();
int block_size
= (std::min)(t->torrent_file().piece_size(b.piece_index)-block_offset,
t->block_size());
TORRENT_ASSERT(block_size > 0);
TORRENT_ASSERT(block_size <= t->block_size());
// we can't cancel the piece if we've started receiving it
if (m_receiving_block == b) continue;
peer_request r;
r.piece = b.piece_index;
r.start = block_offset;
r.length = block_size;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> CANCEL [ piece: %d s: %d l: %d b: %d ]"
, b.piece_index, block_offset, block_size, b.block_index);
#endif
write_cancel(r);
}
}
void peer_connection::cancel_request(piece_block const& block, bool force)
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
// this peer might be disconnecting
if (!t) return;
TORRENT_ASSERT(t->valid_metadata());
TORRENT_ASSERT(block.block_index != piece_block::invalid.block_index);
TORRENT_ASSERT(block.piece_index != piece_block::invalid.piece_index);
TORRENT_ASSERT(int(block.piece_index) < t->torrent_file().num_pieces());
TORRENT_ASSERT(int(block.block_index) < t->torrent_file().piece_size(block.piece_index));
// if all the peers that requested this block has been
// cancelled, then just ignore the cancel.
if (!t->picker().is_requested(block)) return;
std::vector<pending_block>::iterator it
= std::find_if(m_download_queue.begin(), m_download_queue.end(), has_block(block));
if (it == m_download_queue.end())
{
std::vector<pending_block>::iterator rit = std::find_if(m_request_queue.begin()
, m_request_queue.end(), has_block(block));
// when a multi block is received, it is cancelled
// from all peers, so if this one hasn't requested
// the block, just ignore to cancel it.
if (rit == m_request_queue.end()) return;
if (rit - m_request_queue.begin() < m_queued_time_critical)
--m_queued_time_critical;
t->picker().abort_download(block, peer_info_struct());
m_request_queue.erase(rit);
// since we found it in the request queue, it means it hasn't been
// sent yet, so we don't have to send a cancel.
return;
}
int block_offset = block.block_index * t->block_size();
int block_size
= (std::min)(t->torrent_file().piece_size(block.piece_index)-block_offset,
t->block_size());
TORRENT_ASSERT(block_size > 0);
TORRENT_ASSERT(block_size <= t->block_size());
if (force) t->picker().abort_download(block, peer_info_struct());
if (m_outstanding_bytes < block_size) return;
peer_request r;
r.piece = block.piece_index;
r.start = block_offset;
r.length = block_size;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> CANCEL [ piece: %d s: %d l: %d b: %d ]"
, block.piece_index, block_offset, block_size, block.block_index);
#endif
write_cancel(r);
}
bool peer_connection::send_choke()
{
INVARIANT_CHECK;
if (m_peer_info && m_peer_info->optimistically_unchoked)
m_peer_info->optimistically_unchoked = false;
if (m_choked) return false;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> CHOKE");
#endif
write_choke();
m_choked = true;
m_last_choke = time_now();
m_num_invalid_requests = 0;
// reject the requests we have in the queue
// except the allowed fast pieces
for (std::vector<peer_request>::iterator i = m_requests.begin();
i != m_requests.end();)
{
if (std::find(m_accept_fast.begin(), m_accept_fast.end(), i->piece)
!= m_accept_fast.end())
{
++i;
continue;
}
peer_request const& r = *i;
#ifdef TORRENT_STATS
++m_ses.m_choked_piece_requests;
#endif
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> REJECT_PIECE [ piece: %d s: %d l: %d ]"
, r.piece , r.start , r.length);
#endif
write_reject_request(r);
i = m_requests.erase(i);
}
return true;
}
bool peer_connection::send_unchoke()
{
INVARIANT_CHECK;
if (!m_choked) return false;
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!t->ready_for_connections()) return false;
if (!m_sent_suggests)
{
std::vector<int> ret;
t->get_suggested_pieces(ret);
for (std::vector<int>::iterator i = ret.begin()
, end(ret.end()); i != end; ++i)
{
TORRENT_ASSERT(*i >= 0);
send_suggest(*i);
}
m_sent_suggests = true;
}
m_last_unchoke = time_now();
write_unchoke();
m_choked = false;
m_uploaded_at_last_unchoke = m_statistics.total_payload_upload();
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> UNCHOKE");
#endif
return true;
}
void peer_connection::send_interested()
{
if (m_interesting) return;
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!t->ready_for_connections()) return;
m_interesting = true;
write_interested();
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> INTERESTED");
#endif
}
void peer_connection::send_not_interested()
{
// we cannot disconnect in a constructor, and
// this function may end up doing that
TORRENT_ASSERT(m_in_constructor == false);
if (!m_interesting)
{
disconnect_if_redundant();
return;
}
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!t->ready_for_connections()) return;
m_interesting = false;
write_not_interested();
m_became_uninteresting = time_now();
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> NOT_INTERESTED");
#endif
disconnect_if_redundant();
}
void peer_connection::send_suggest(int piece)
{
if (m_connecting) return;
if (in_handshake()) return;
// don't suggest a piece that the peer already has
// don't suggest anything to a peer that isn't interested
if (has_piece(piece)
|| !m_peer_interested)
return;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> SUGGEST [ %d ]", piece);
#endif
write_suggest(piece);
}
void peer_connection::send_block_requests()
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
if (m_disconnecting) return;
if (t->graceful_pause() && m_outstanding_bytes == 0)
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** GRACEFUL PAUSE [ NO MORE DOWNLOAD ]");
#endif
disconnect(errors::torrent_paused);
return;
}
// we can't download pieces in these states
if (t->state() == torrent_status::checking_files
|| t->state() == torrent_status::checking_resume_data
|| t->state() == torrent_status::downloading_metadata
|| t->state() == torrent_status::allocating)
return;
if ((int)m_download_queue.size() >= m_desired_queue_size
|| t->upload_mode()) return;
bool empty_download_queue = m_download_queue.empty();
while (!m_request_queue.empty()
&& ((int)m_download_queue.size() < m_desired_queue_size
|| m_queued_time_critical > 0))
{
pending_block block = m_request_queue.front();
m_request_queue.erase(m_request_queue.begin());
if (m_queued_time_critical) --m_queued_time_critical;
// if we're a seed, we don't have a piece picker
// so we don't have to worry about invariants getting
// out of sync with it
if (!t->has_picker()) continue;
// this can happen if a block times out, is re-requested and
// then arrives "unexpectedly"
if (t->picker().is_finished(block.block)
|| t->picker().is_downloaded(block.block))
{
t->picker().abort_download(block.block, peer_info_struct());
continue;
}
int block_offset = block.block.block_index * t->block_size();
int block_size = (std::min)(t->torrent_file().piece_size(
block.block.piece_index) - block_offset, t->block_size());
TORRENT_ASSERT(block_size > 0);
TORRENT_ASSERT(block_size <= t->block_size());
peer_request r;
r.piece = block.block.piece_index;
r.start = block_offset;
r.length = block_size;
TORRENT_ASSERT(verify_piece(t->to_req(block.block)));
m_download_queue.push_back(block);
m_outstanding_bytes += block_size;
#if !defined TORRENT_DISABLE_INVARIANT_CHECKS && defined TORRENT_DEBUG
check_invariant();
#endif
/*
#ifdef TORRENT_VERBOSE_LOGGING
(*m_logger) << time_now_string()
<< " *** REQUEST-QUEUE** [ "
"piece: " << block.piece_index << " | "
"block: " << block.block_index << " ]\n";
#endif
*/
// if we are requesting large blocks, merge the smaller
// blocks that are in the same piece into larger requests
if (m_request_large_blocks)
{
int blocks_per_piece = t->torrent_file().piece_length() / t->block_size();
while (!m_request_queue.empty())
{
// check to see if this block is connected to the previous one
// if it is, merge them, otherwise, break this merge loop
pending_block const& front = m_request_queue.front();
if (front.block.piece_index * blocks_per_piece + front.block.block_index
!= block.block.piece_index * blocks_per_piece + block.block.block_index + 1)
break;
block = m_request_queue.front();
m_request_queue.erase(m_request_queue.begin());
TORRENT_ASSERT(verify_piece(t->to_req(block.block)));
m_download_queue.push_back(block);
if (m_queued_time_critical) --m_queued_time_critical;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** MERGING REQUEST [ piece: %d block: %d ]"
, block.block.piece_index, block.block.block_index);
#endif
block_offset = block.block.block_index * t->block_size();
block_size = (std::min)(t->torrent_file().piece_size(
block.block.piece_index) - block_offset, t->block_size());
TORRENT_ASSERT(block_size > 0);
TORRENT_ASSERT(block_size <= t->block_size());
r.length += block_size;
m_outstanding_bytes += block_size;
#if !defined TORRENT_DISABLE_INVARIANT_CHECKS && defined TORRENT_DEBUG
check_invariant();
#endif
}
}
// the verification will fail for coalesced blocks
TORRENT_ASSERT(verify_piece(r) || m_request_large_blocks);
#ifndef TORRENT_DISABLE_EXTENSIONS
bool handled = false;
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
if ((handled = (*i)->write_request(r))) break;
}
if (is_disconnecting()) return;
if (!handled)
#endif
{
write_request(r);
m_last_request = time_now();
}
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> REQUEST [ piece: %d | s: %d | l: %d | ds: %d B/s | "
"dqs: %d rqs: %d blk: %s ]"
, r.piece, r.start, r.length, statistics().download_rate()
, int(m_desired_queue_size), int(m_download_queue.size())
, m_request_large_blocks?"large":"single");
#endif
}
m_last_piece = time_now();
if (!m_download_queue.empty()
&& empty_download_queue)
{
// This means we just added a request to this connection
m_requested = time_now();
}
}
void peer_connection::on_timeout()
{
TORRENT_ASSERT(m_ses.is_network_thread());
connect_failed(errors::timed_out);
}
void peer_connection::connect_failed(error_code const& e)
{
TORRENT_ASSERT(e);
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("CONNECTION FAILED: %s", print_endpoint(m_remote).c_str());
#endif
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << time_now_string() << " CONNECTION FAILED: " << print_endpoint(m_remote) << "\n";
#endif
#ifdef TORRENT_STATS
++m_ses.m_connect_timeouts;
#endif
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(!m_connecting || t);
if (m_connecting && t)
{
t->dec_num_connecting();
m_connecting = false;
}
if (m_connection_ticket != -1)
{
m_ses.m_half_open.done(m_connection_ticket);
}
// a connection attempt using uTP just failed
// mark this peer as not supporting uTP
// we'll never try it again (unless we're trying holepunch)
if (is_utp(*m_socket)
&& m_peer_info
&& m_peer_info->supports_utp
&& !m_holepunch_mode)
{
m_peer_info->supports_utp = false;
// reconnect immediately using TCP
policy::peer* pi = peer_info_struct();
boost::shared_ptr<torrent> t = m_torrent.lock();
fast_reconnect(true);
disconnect(e, 0);
if (t && pi) t->connect_to_peer(pi, true);
return;
}
if (m_holepunch_mode)
fast_reconnect(true);
#ifndef TORRENT_DISABLE_EXTENSIONS
if ((!is_utp(*m_socket)
|| !m_ses.m_settings.enable_outgoing_tcp)
&& m_peer_info
&& m_peer_info->supports_holepunch
&& !m_holepunch_mode)
{
boost::shared_ptr<torrent> t = m_torrent.lock();
// see if we can try a holepunch
bt_peer_connection* p = t->find_introducer(remote());
if (p)
p->write_holepunch_msg(bt_peer_connection::hp_rendezvous, remote(), 0);
}
#endif
disconnect(e, 1);
return;
}
// the error argument defaults to 0, which means deliberate disconnect
// 1 means unexpected disconnect/error
// 2 protocol error (client sent something invalid)
void peer_connection::disconnect(error_code const& ec, int error)
{
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
m_disconnect_started = true;
#endif
if (m_disconnecting) return;
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
switch (error)
{
case 0:
peer_log("*** CONNECTION CLOSED %s", ec.message().c_str());
break;
case 1:
peer_log("*** CONNECTION FAILED %s", ec.message().c_str());
break;
case 2:
peer_log("*** PEER ERROR %s", ec.message().c_str());
break;
}
#endif
// for incoming connections, we get invalid argument errors
// when asking for the remote endpoint and the socket already
// closed, which is an edge case, but possible to happen when
// a peer makes a TCP and uTP connection in parallel.
// for outgoing connections however, why would we get this?
TORRENT_ASSERT(ec != error::invalid_argument || !m_outgoing);
#ifdef TORRENT_STATS
++m_ses.m_disconnected_peers;
if (error == 2) ++m_ses.m_error_peers;
if (ec == error::connection_reset) ++m_ses.m_connreset_peers;
else if (ec == error::eof) ++m_ses.m_eof_peers;
else if (ec == error::connection_refused) ++m_ses.m_connrefused_peers;
else if (ec == error::connection_aborted) ++m_ses.m_connaborted_peers;
else if (ec == error::no_permission) ++m_ses.m_perm_peers;
else if (ec == error::no_buffer_space) ++m_ses.m_buffer_peers;
else if (ec == error::host_unreachable) ++m_ses.m_unreachable_peers;
else if (ec == error::broken_pipe) ++m_ses.m_broken_pipe_peers;
else if (ec == error::address_in_use) ++m_ses.m_addrinuse_peers;
else if (ec == error::access_denied) ++m_ses.m_no_access_peers;
else if (ec == error::invalid_argument) ++m_ses.m_invalid_arg_peers;
else if (ec == error::operation_aborted) ++m_ses.m_aborted_peers;
else if (ec == error_code(errors::upload_upload_connection)
|| ec == error_code(errors::uninteresting_upload_peer)
|| ec == error_code(errors::torrent_aborted)
|| ec == error_code(errors::self_connection)
|| ec == error_code(errors::torrent_paused))
++m_ses.m_uninteresting_peers;
if (ec == error_code(errors::timed_out)
|| ec == error::timed_out)
++m_ses.m_transport_timeout_peers;
if (ec == error_code(errors::timed_out_inactivity)
|| ec == error_code(errors::timed_out_no_request)
|| ec == error_code(errors::timed_out_no_interest))
++m_ses.m_timeout_peers;
if (ec == error_code(errors::no_memory))
++m_ses.m_no_memory_peers;
if (ec == error_code(errors::too_many_connections))
++m_ses.m_too_many_peers;
if (ec == error_code(errors::timed_out_no_handshake))
++m_ses.m_connect_timeouts;
if (is_utp(*m_socket)) ++m_ses.m_error_utp_peers;
else ++m_ses.m_error_tcp_peers;
if (m_outgoing) ++m_ses.m_error_outgoing_peers;
else ++m_ses.m_error_incoming_peers;
#ifndef TORRENT_DISABLE_ENCRYPTION
if (type() == bittorrent_connection)
{
bt_peer_connection* bt = static_cast<bt_peer_connection*>(this);
if (bt->supports_encryption()) ++m_ses.m_error_encrypted_peers;
if (bt->rc4_encrypted() && bt->supports_encryption()) ++m_ses.m_error_rc4_peers;
}
#endif // TORRENT_DISABLE_ENCRYPTION
#endif
// we cannot do this in a constructor
TORRENT_ASSERT(m_in_constructor == false);
if (error > 0) m_failed = true;
boost::intrusive_ptr<peer_connection> me(this);
INVARIANT_CHECK;
if (m_channel_state[upload_channel] & peer_info::bw_disk)
{
m_ses.dec_disk_queue(upload_channel);
m_channel_state[upload_channel] &= ~peer_info::bw_disk;
}
if (m_channel_state[download_channel] & peer_info::bw_disk)
{
m_ses.dec_disk_queue(download_channel);
m_channel_state[download_channel] &= ~peer_info::bw_disk;
}
boost::shared_ptr<torrent> t = m_torrent.lock();
if (m_connecting)
{
t->dec_num_connecting();
m_connecting = false;
}
if (m_connection_ticket >= 0)
{
m_ses.m_half_open.done(m_connection_ticket);
m_connection_ticket = -1;
}
torrent_handle handle;
if (t) handle = t->get_handle();
if (ec == error::address_in_use
&& m_ses.m_settings.outgoing_ports.first != 0)
{
if (m_ses.m_alerts.should_post<performance_alert>())
m_ses.m_alerts.post_alert(performance_alert(
handle, performance_alert::too_few_outgoing_ports));
}
if (ec)
{
if ((error > 1 || ec.category() == socks_category)
&& m_ses.m_alerts.should_post<peer_error_alert>())
{
m_ses.m_alerts.post_alert(
peer_error_alert(handle, remote(), pid(), ec));
}
else if (error <= 1 && m_ses.m_alerts.should_post<peer_disconnected_alert>())
{
m_ses.m_alerts.post_alert(
peer_disconnected_alert(handle, remote(), pid(), ec));
}
}
if (t)
{
// make sure we keep all the stats!
if (!m_ignore_stats)
{
t->add_stats(statistics());
// report any partially received payload as redundant
boost::optional<piece_block_progress> pbp = downloading_piece_progress();
if (pbp
&& pbp->bytes_downloaded > 0
&& pbp->bytes_downloaded < pbp->full_block_bytes)
{
t->add_redundant_bytes(pbp->bytes_downloaded, torrent::piece_closing);
}
}
if (t->has_picker())
{
piece_picker& picker = t->picker();
while (!m_download_queue.empty())
{
pending_block& qe = m_download_queue.back();
if (!qe.timed_out && !qe.not_wanted)
picker.abort_download(qe.block, peer_info_struct());
m_outstanding_bytes -= t->to_req(qe.block).length;
if (m_outstanding_bytes < 0) m_outstanding_bytes = 0;
m_download_queue.pop_back();
}
while (!m_request_queue.empty())
{
picker.abort_download(m_request_queue.back().block, peer_info_struct());
m_request_queue.pop_back();
}
}
else
{
m_download_queue.clear();
m_request_queue.clear();
m_outstanding_bytes = 0;
}
m_queued_time_critical = 0;
#if !defined TORRENT_DISABLE_INVARIANT_CHECKS && defined TORRENT_DEBUG
check_invariant();
#endif
t->remove_peer(this);
m_torrent.reset();
}
else
{
TORRENT_ASSERT(m_download_queue.empty());
TORRENT_ASSERT(m_request_queue.empty());
}
#if defined TORRENT_DEBUG && defined TORRENT_EXPENSIVE_INVARIANT_CHECKS
// since this connection doesn't have a torrent reference
// no torrent should have a reference to this connection either
for (aux::session_impl::torrent_map::const_iterator i = m_ses.m_torrents.begin()
, end(m_ses.m_torrents.end()); i != end; ++i)
TORRENT_ASSERT(!i->second->has_peer(this));
#endif
m_disconnecting = true;
error_code e;
async_shutdown(*m_socket, m_socket);
m_ses.close_connection(this, ec);
// we should only disconnect while we still have
// at least one reference left to the connection
TORRENT_ASSERT(refcount() > 0);
}
int peer_connection::get_upload_limit() const
{
return m_upload_limit;
}
int peer_connection::get_download_limit() const
{
return m_download_limit;
}
void peer_connection::set_upload_limit(int limit)
{
TORRENT_ASSERT(limit >= -1);
if (limit < 0) limit = 0;
if (limit < 10 && limit > 0) limit = 10;
m_upload_limit = limit;
m_bandwidth_channel[upload_channel].throttle(m_upload_limit);
}
void peer_connection::set_download_limit(int limit)
{
TORRENT_ASSERT(limit >= -1);
if (limit < 0) limit = 0;
if (limit < 10 && limit > 0) limit = 10;
m_download_limit = limit;
m_bandwidth_channel[download_channel].throttle(m_download_limit);
}
size_type peer_connection::share_diff() const
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
float ratio = t->ratio();
// if we have an infinite ratio, just say we have downloaded
// much more than we have uploaded. And we'll keep uploading.
if (ratio == 0.f)
return (std::numeric_limits<size_type>::max)();
return m_free_upload
+ static_cast<size_type>(m_statistics.total_payload_download() * ratio)
- m_statistics.total_payload_upload();
}
bool peer_connection::ignore_unchoke_slots() const
{
return m_ignore_unchoke_slots
|| (m_ses.settings().ignore_limits_on_local_network
&& on_local_network()
&& m_ses.m_local_upload_channel.throttle() == 0);
}
// defined in upnp.cpp
bool is_local(address const& a);
bool peer_connection::on_local_network() const
{
if (libtorrent::is_local(m_remote.address())
|| is_loopback(m_remote.address())) return true;
return false;
}
void peer_connection::get_peer_info(peer_info& p) const
{
TORRENT_ASSERT(!associated_torrent().expired());
ptime now = time_now();
p.download_rate_peak = m_download_rate_peak;
p.upload_rate_peak = m_upload_rate_peak;
p.rtt = m_rtt;
p.down_speed = statistics().download_rate();
p.up_speed = statistics().upload_rate();
p.payload_down_speed = statistics().download_payload_rate();
p.payload_up_speed = statistics().upload_payload_rate();
p.pid = pid();
p.ip = remote();
p.pending_disk_bytes = m_outstanding_writing_bytes;
p.send_quota = m_quota[upload_channel];
p.receive_quota = m_quota[download_channel];
p.num_pieces = m_num_pieces;
if (m_download_queue.empty()) p.request_timeout = -1;
else p.request_timeout = total_seconds(m_requested - now) + m_ses.settings().request_timeout
+ m_timeout_extend;
#ifndef TORRENT_DISABLE_GEO_IP
p.inet_as_name = m_inet_as_name;
#endif
p.download_queue_time = download_queue_time();
p.queue_bytes = m_outstanding_bytes;
#ifndef TORRENT_DISABLE_RESOLVE_COUNTRIES
p.country[0] = m_country[0];
p.country[1] = m_country[1];
#else
std::fill(p.country, p.country + 2, 0);
#endif
p.total_download = statistics().total_payload_download();
p.total_upload = statistics().total_payload_upload();
if (m_bandwidth_channel[upload_channel].throttle() == 0)
p.upload_limit = -1;
else
p.upload_limit = m_bandwidth_channel[upload_channel].throttle();
if (m_bandwidth_channel[download_channel].throttle() == 0)
p.download_limit = -1;
else
p.download_limit = m_bandwidth_channel[download_channel].throttle();
p.load_balancing = total_free_upload();
p.download_queue_length = int(download_queue().size() + m_request_queue.size());
p.requests_in_buffer = int(m_requests_in_buffer.size() + m_request_queue.size());
p.target_dl_queue_length = int(desired_queue_size());
p.upload_queue_length = int(upload_queue().size());
p.timed_out_requests = 0;
p.busy_requests = 0;
for (std::vector<pending_block>::const_iterator i = m_download_queue.begin()
, end(m_download_queue.end()); i != end; ++i)
{
if (i->timed_out) ++p.timed_out_requests;
if (i->busy) ++p.busy_requests;
}
if (boost::optional<piece_block_progress> ret = downloading_piece_progress())
{
p.downloading_piece_index = ret->piece_index;
p.downloading_block_index = ret->block_index;
p.downloading_progress = ret->bytes_downloaded;
p.downloading_total = ret->full_block_bytes;
}
else
{
p.downloading_piece_index = -1;
p.downloading_block_index = -1;
p.downloading_progress = 0;
p.downloading_total = 0;
}
p.pieces = get_bitfield();
p.last_request = now - m_last_request;
p.last_active = now - (std::max)(m_last_sent, m_last_receive);
// this will set the flags so that we can update them later
p.flags = 0;
get_specific_peer_info(p);
p.flags |= is_seed() ? peer_info::seed : 0;
p.flags |= m_snubbed ? peer_info::snubbed : 0;
p.flags |= m_upload_only ? peer_info::upload_only : 0;
p.flags |= m_endgame_mode ? peer_info::endgame_mode : 0;
p.flags |= m_holepunch_mode ? peer_info::holepunched : 0;
if (peer_info_struct())
{
policy::peer* pi = peer_info_struct();
TORRENT_ASSERT(pi->in_use);
p.source = pi->source;
p.failcount = pi->failcount;
p.num_hashfails = pi->hashfails;
p.flags |= pi->on_parole ? peer_info::on_parole : 0;
p.flags |= pi->optimistically_unchoked ? peer_info::optimistic_unchoke : 0;
#ifndef TORRENT_DISABLE_GEO_IP
p.inet_as = pi->inet_as ? pi->inet_as->first : 0xffff;
#endif
}
else
{
p.source = 0;
p.failcount = 0;
p.num_hashfails = 0;
#ifndef TORRENT_DISABLE_GEO_IP
p.inet_as = 0xffff;
#endif
}
p.remote_dl_rate = m_remote_dl_rate;
p.send_buffer_size = m_send_buffer.capacity();
p.used_send_buffer = m_send_buffer.size();
p.receive_buffer_size = m_recv_buffer.capacity() + m_disk_recv_buffer_size;
p.used_receive_buffer = m_recv_pos;
p.write_state = m_channel_state[upload_channel];
p.read_state = m_channel_state[download_channel];
// pieces may be empty if we don't have metadata yet
if (p.pieces.size() == 0)
{
p.progress = 0.f;
p.progress_ppm = 0;
}
else
{
#if TORRENT_NO_FPU
p.progress = 0.f;
#else
p.progress = (float)p.pieces.count() / (float)p.pieces.size();
#endif
p.progress_ppm = boost::uint64_t(p.pieces.count()) * 1000000 / p.pieces.size();
}
p.estimated_reciprocation_rate = m_est_reciprocation_rate;
error_code ec;
p.local_endpoint = get_socket()->local_endpoint(ec);
}
// allocates a disk buffer of size 'disk_buffer_size' and replaces the
// end of the current receive buffer with it. i.e. the receive pos
// must be <= packet_size - disk_buffer_size
// the disk buffer can be accessed through release_disk_receive_buffer()
// when it is queried, the responsibility to free it is transferred
// to the caller
bool peer_connection::allocate_disk_receive_buffer(int disk_buffer_size)
{
INVARIANT_CHECK;
TORRENT_ASSERT(m_packet_size > 0);
TORRENT_ASSERT(m_recv_pos <= m_packet_size - disk_buffer_size);
TORRENT_ASSERT(!m_disk_recv_buffer);
TORRENT_ASSERT(disk_buffer_size <= 16 * 1024);
if (disk_buffer_size == 0) return true;
if (disk_buffer_size > 16 * 1024)
{
disconnect(errors::invalid_piece_size, 2);
return false;
}
// first free the old buffer
m_disk_recv_buffer.reset();
// then allocate a new one
m_disk_recv_buffer.reset(m_ses.allocate_disk_buffer("receive buffer"));
if (!m_disk_recv_buffer)
{
disconnect(errors::no_memory);
return false;
}
m_disk_recv_buffer_size = disk_buffer_size;
return true;
}
char* peer_connection::release_disk_receive_buffer()
{
m_disk_recv_buffer_size = 0;
return m_disk_recv_buffer.release();
}
// size = the packet size to remove from the receive buffer
// packet_size = the next packet size to receive in the buffer
void peer_connection::cut_receive_buffer(int size, int packet_size, int offset)
{
INVARIANT_CHECK;
TORRENT_ASSERT(packet_size > 0);
TORRENT_ASSERT(int(m_recv_buffer.size()) >= size);
TORRENT_ASSERT(int(m_recv_buffer.size()) >= m_recv_pos);
TORRENT_ASSERT(m_recv_pos >= size + offset);
TORRENT_ASSERT(offset >= 0);
if (size > 0)
std::memmove(&m_recv_buffer[0] + offset, &m_recv_buffer[0] + offset + size, m_recv_pos - size - offset);
m_recv_pos -= size;
#ifdef TORRENT_DEBUG
std::fill(m_recv_buffer.begin() + m_recv_pos, m_recv_buffer.end(), 0);
#endif
m_packet_size = packet_size;
}
void peer_connection::superseed_piece(int replace_piece, int new_piece)
{
if (new_piece == -1)
{
if (m_superseed_piece[0] == -1) return;
m_superseed_piece[0] = -1;
m_superseed_piece[1] = -1;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("*** ending super seed mode");
#endif
boost::shared_ptr<torrent> t = m_torrent.lock();
assert(t);
// TODO: we should probably just send a HAVE_ALL here
for (int i = 0; i < int(m_have_piece.size()); ++i)
{
if (m_have_piece[i] || !t->have_piece(i)) continue;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> HAVE [ piece: %d] (ending super seed)", i);
#endif
write_have(i);
}
return;
}
assert(!has_piece(new_piece));
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> HAVE [ piece: %d ] (super seed)", new_piece);
#endif
write_have(new_piece);
if (replace_piece >= 0)
{
// move the piece we're replacing to the tail
if (m_superseed_piece[0] == replace_piece)
std::swap(m_superseed_piece[0], m_superseed_piece[1]);
}
m_superseed_piece[1] = m_superseed_piece[0];
m_superseed_piece[0] = new_piece;
}
void peer_connection::update_desired_queue_size()
{
if (m_snubbed)
{
m_desired_queue_size = 1;
return;
}
int download_rate = statistics().download_rate();
// calculate the desired download queue size
const int queue_time = m_ses.settings().request_queue_time;
// (if the latency is more than this, the download will stall)
// so, the queue size is queue_time * down_rate / 16 kiB
// (16 kB is the size of each request)
// the minimum number of requests is 2 and the maximum is 48
// the block size doesn't have to be 16. So we first query the
// torrent for it
boost::shared_ptr<torrent> t = m_torrent.lock();
const int block_size = t->block_size();
TORRENT_ASSERT(block_size > 0);
m_desired_queue_size = queue_time * download_rate / block_size;
if (m_desired_queue_size > m_max_out_request_queue)
m_desired_queue_size = m_max_out_request_queue;
if (m_desired_queue_size < min_request_queue)
m_desired_queue_size = min_request_queue;
}
void peer_connection::second_tick(int tick_interval_ms)
{
ptime now = time_now();
boost::intrusive_ptr<peer_connection> me(self());
// the invariant check must be run before me is destructed
// in case the peer got disconnected
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
// drain the IP overhead from the bandwidth limiters
if (m_ses.m_settings.rate_limit_ip_overhead)
{
int download_overhead = m_statistics.download_ip_overhead();
int upload_overhead = m_statistics.upload_ip_overhead();
m_bandwidth_channel[download_channel].use_quota(download_overhead);
m_bandwidth_channel[upload_channel].use_quota(upload_overhead);
bandwidth_channel* upc = 0;
bandwidth_channel* downc = 0;
if (m_ignore_bandwidth_limits)
{
upc = &m_ses.m_local_upload_channel;
downc = &m_ses.m_local_download_channel;
}
else
{
upc = &m_ses.m_upload_channel;
downc = &m_ses.m_download_channel;
}
int up_limit = m_bandwidth_channel[upload_channel].throttle();
int down_limit = m_bandwidth_channel[download_channel].throttle();
if (t)
{
if (!m_ignore_bandwidth_limits)
{
t->m_bandwidth_channel[download_channel].use_quota(download_overhead);
t->m_bandwidth_channel[upload_channel].use_quota(upload_overhead);
}
if (down_limit > 0
&& download_overhead >= down_limit
&& t->alerts().should_post<performance_alert>())
{
t->alerts().post_alert(performance_alert(t->get_handle()
, performance_alert::download_limit_too_low));
}
if (up_limit > 0
&& upload_overhead >= up_limit
&& t->alerts().should_post<performance_alert>())
{
t->alerts().post_alert(performance_alert(t->get_handle()
, performance_alert::upload_limit_too_low));
}
}
downc->use_quota(download_overhead);
upc->use_quota(upload_overhead);
}
if (!t || m_disconnecting)
{
m_ses.m_half_open.done(m_connection_ticket);
if (m_connection_ticket >= -1) m_connection_ticket = -1;
TORRENT_ASSERT(t || !m_connecting);
if (m_connecting && t)
{
t->dec_num_connecting();
m_connecting = false;
}
disconnect(errors::torrent_aborted);
return;
}
if (m_endgame_mode
&& m_interesting
&& m_download_queue.empty()
&& m_request_queue.empty()
&& total_seconds(now - m_last_request) >= 5)
{
// this happens when we're in strict end-game
// mode and the peer could not request any blocks
// because they were all taken but there were still
// unrequested blocks. Now, 5 seconds later, there
// might not be any unrequested blocks anymore, so
// we should try to pick another block to see
// if we can pick a busy one
#ifdef TORRENT_STATS
++m_ses.m_end_game_piece_picks;
#endif
m_last_request = now;
request_a_block(*t, *this);
if (m_disconnecting) return;
send_block_requests();
}
on_tick();
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
(*i)->tick();
}
if (is_disconnecting()) return;
#endif
// if the peer hasn't said a thing for a certain
// time, it is considered to have timed out
time_duration d;
d = (std::min)(now - m_last_receive, now - m_last_sent);
// if we can't read, it means we're blocked on the rate-limiter
// or the disk, not the peer itself. In this case, don't blame
// the peer and disconnect it
bool may_timeout = (m_channel_state[download_channel] & peer_info::bw_network);
if (may_timeout && d > seconds(m_timeout) && !m_connecting)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** LAST ACTIVITY [ %d seconds ago ] ***", int(total_seconds(d)));
#endif
disconnect(errors::timed_out_inactivity);
return;
}
// do not stall waiting for a handshake
if (may_timeout
&& !m_connecting
&& in_handshake()
&& d > seconds(m_ses.settings().handshake_timeout))
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** NO HANDSHAKE [ waited %d seconds ] ***", int(total_seconds(d)));
#endif
disconnect(errors::timed_out_no_handshake);
return;
}
// disconnect peers that we unchoked, but
// they didn't send a request within 20 seconds.
// but only if we're a seed
d = now - (std::max)(m_last_unchoke, m_last_incoming_request);
if (may_timeout
&& !m_connecting
&& m_requests.empty()
&& m_reading_bytes == 0
&& !m_choked
&& m_peer_interested
&& t && t->is_upload_only()
&& d > seconds(20))
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** NO REQUEST [ waited %d seconds ] ***", int(total_seconds(d)));
#endif
disconnect(errors::timed_out_no_request);
return;
}
// if the peer hasn't become interested and we haven't
// become interested in the peer for 10 minutes, it
// has also timed out.
time_duration d1;
time_duration d2;
d1 = now - m_became_uninterested;
d2 = now - m_became_uninteresting;
time_duration time_limit = seconds(
m_ses.settings().inactivity_timeout);
// don't bother disconnect peers we haven't been interested
// in (and that hasn't been interested in us) for a while
// unless we have used up all our connection slots
if (may_timeout
&& !m_interesting
&& !m_peer_interested
&& d1 > time_limit
&& d2 > time_limit
&& (m_ses.num_connections() >= m_ses.settings().connections_limit
|| (t && t->num_peers() >= t->max_connections())))
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** MUTUAL NO INTEREST [ t1: %d t2: %d ]"
, total_seconds(d1), total_seconds(d2));
#endif
disconnect(errors::timed_out_no_interest);
return;
}
if (may_timeout
&& !m_download_queue.empty()
&& m_quota[download_channel] > 0
&& now > m_requested + seconds(m_ses.settings().request_timeout
+ m_timeout_extend))
{
snub_peer();
}
// if we haven't sent something in too long, send a keep-alive
keep_alive();
m_ignore_bandwidth_limits = m_ses.settings().ignore_limits_on_local_network
&& on_local_network();
m_statistics.second_tick(tick_interval_ms);
if (m_statistics.upload_payload_rate() > m_upload_rate_peak)
{
m_upload_rate_peak = m_statistics.upload_payload_rate();
}
if (m_statistics.download_payload_rate() > m_download_rate_peak)
{
m_download_rate_peak = m_statistics.download_payload_rate();
#ifndef TORRENT_DISABLE_GEO_IP
if (peer_info_struct())
{
std::pair<const int, int>* as_stats = peer_info_struct()->inet_as;
if (as_stats && as_stats->second < m_download_rate_peak)
as_stats->second = m_download_rate_peak;
}
#endif
}
if (is_disconnecting()) return;
if (!t->ready_for_connections()) return;
update_desired_queue_size();
if (m_desired_queue_size == m_max_out_request_queue
&& t->alerts().should_post<performance_alert>())
{
t->alerts().post_alert(performance_alert(t->get_handle()
, performance_alert::outstanding_request_limit_reached));
}
int piece_timeout = m_ses.settings().piece_timeout;
int rate_limit = INT_MAX;
if (m_bandwidth_channel[download_channel].throttle() > 0)
rate_limit = (std::min)(m_bandwidth_channel[download_channel].throttle(), rate_limit);
if (t->bandwidth_throttle(download_channel) > 0)
rate_limit = (std::min)(t->bandwidth_throttle(download_channel) / t->num_peers(), rate_limit);
if (m_ses.m_download_channel.throttle() > 0)
rate_limit = (std::min)(m_ses.m_download_channel.throttle()
/ m_ses.num_connections(), rate_limit);
// rate_limit is an approximation of what this connection is
// allowed to download. If it is impossible to beat the piece
// timeout at this rate, adjust it to be realistic
const int block_size = t->block_size();
int rate_limit_timeout = rate_limit / block_size;
if (piece_timeout < rate_limit_timeout) piece_timeout = rate_limit_timeout;
if (!m_download_queue.empty()
&& m_quota[download_channel] > 0
&& now - m_last_piece > seconds(piece_timeout + m_timeout_extend))
{
// this peer isn't sending the pieces we've
// requested (this has been observed by BitComet)
// in this case we'll clear our download queue and
// re-request the blocks.
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** PIECE_REQUEST TIMED OUT [ %d time: %d to: %d extend: %d ]"
, (int)m_download_queue.size(), total_seconds(now - m_last_piece)
, piece_timeout, m_timeout_extend);
#endif
snub_peer();
}
// If the client sends more data
// we send it data faster, otherwise, slower.
// It will also depend on how much data the
// client has sent us. This is the mean to
// maintain the share ratio given by m_ratio
// with all peers.
if (t->is_upload_only() || is_choked() || t->ratio() == 0.0f)
{
// if we have downloaded more than one piece more
// than we have uploaded OR if we are a seed
// have an unlimited upload rate
m_bandwidth_channel[upload_channel].throttle(m_upload_limit);
}
else
{
size_type bias = 0x10000 + 2 * t->block_size() + m_free_upload;
const int break_even_time = 15; // seconds.
size_type have_uploaded = m_statistics.total_payload_upload();
size_type have_downloaded = m_statistics.total_payload_download();
int download_speed = m_statistics.download_rate();
size_type soon_downloaded =
have_downloaded + (size_type)(download_speed * (break_even_time + break_even_time / 2));
if (t->ratio() != 1.f)
soon_downloaded = size_type(soon_downloaded * t->ratio());
TORRENT_ASSERT((soon_downloaded - have_uploaded + bias) / break_even_time < INT_MAX);
int upload_speed_limit = int((soon_downloaded - have_uploaded
+ bias) / break_even_time);
if (m_upload_limit > 0 && m_upload_limit < upload_speed_limit)
upload_speed_limit = m_upload_limit;
upload_speed_limit = (std::min)(upload_speed_limit, (std::numeric_limits<int>::max)());
m_bandwidth_channel[upload_channel].throttle(
(std::min)((std::max)(upload_speed_limit, 10), m_upload_limit));
}
// update once every minute
if (now - m_remote_dl_update >= seconds(60))
{
if (m_remote_dl_rate > 0)
m_remote_dl_rate = (m_remote_dl_rate * 2 / 3) +
((m_remote_bytes_dled / 3) / 60);
else
m_remote_dl_rate = m_remote_bytes_dled / 60;
m_remote_bytes_dled = 0;
m_remote_dl_update = now;
}
fill_send_buffer();
}
void peer_connection::snub_peer()
{
INVARIANT_CHECK;
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
if (!m_snubbed)
{
m_snubbed = true;
if (m_ses.m_alerts.should_post<peer_snubbed_alert>())
{
m_ses.m_alerts.post_alert(peer_snubbed_alert(t->get_handle()
, m_remote, m_peer_id));
}
}
m_desired_queue_size = 1;
if (on_parole())
{
m_timeout_extend += m_ses.settings().request_timeout;
return;
}
if (!t->has_picker()) return;
piece_picker& picker = t->picker();
// first, if we have any unsent requests, just
// wipe those out
while (!m_request_queue.empty())
{
t->picker().abort_download(m_request_queue.back().block, peer_info_struct());
m_request_queue.pop_back();
}
m_queued_time_critical = 0;
TORRENT_ASSERT(!m_download_queue.empty());
// request a new block before removing the previous
// one, in order to prevent it from
// picking the same block again, stalling the
// same piece indefinitely.
m_desired_queue_size = 2;
#ifdef TORRENT_STATS
++m_ses.m_snubbed_piece_picks;
#endif
request_a_block(*t, *this);
// the block we just picked (potentially)
// hasn't been put in m_download_queue yet.
// it's in m_request_queue and will be sent
// once send_block_requests() is called.
m_desired_queue_size = 1;
// time out the last request eligible
// block in the queue
int i = m_download_queue.size() - 1;
for (; i >= 0; --i)
{
if (!m_download_queue[i].timed_out
&& !m_download_queue[i].not_wanted)
break;
}
if (i >= 0)
{
pending_block& qe = m_download_queue[i];
piece_block r = qe.block;
// only time out a request if it blocks the piece
// from being completed (i.e. no free blocks to
// request from it)
piece_picker::downloading_piece p;
picker.piece_info(qe.block.piece_index, p);
int free_blocks = picker.blocks_in_piece(qe.block.piece_index)
- p.finished - p.writing - p.requested;
if (free_blocks > 0)
{
m_timeout_extend += m_ses.settings().request_timeout;
return;
}
if (m_ses.m_alerts.should_post<block_timeout_alert>())
{
m_ses.m_alerts.post_alert(block_timeout_alert(t->get_handle()
, remote(), pid(), qe.block.block_index, qe.block.piece_index));
}
qe.timed_out = true;
picker.abort_download(r, peer_info_struct());
}
send_block_requests();
}
std::pair<int, int> peer_connection::preferred_caching() const
{
int line_size = 0;
int expiry = 0;
if (m_ses.m_settings.guided_read_cache)
{
boost::shared_ptr<torrent> t = m_torrent.lock();
int upload_rate = m_statistics.upload_payload_rate();
if (upload_rate == 0) upload_rate = 1;
int num_uploads = m_ses.num_uploads();
if (num_uploads == 0) num_uploads = 1;
// assume half of the cache is write cache if we're downloading
// this torrent as well
int cache_size = m_ses.m_settings.cache_size / num_uploads;
if (!t->is_upload_only()) cache_size /= 2;
// cache_size is the amount of cache we have per peer. The
// cache line should not be greater than this
// try to avoid locking caches for more than a couple of seconds
expiry = cache_size * 16 * 1024 / upload_rate;
if (expiry < 1) expiry = 1;
else if (expiry > 10) expiry = 10;
line_size = cache_size;
}
return std::make_pair(line_size, expiry);
}
void peer_connection::fill_send_buffer()
{
#ifdef TORRENT_EXPENSIVE_INVARIANT_CHECKS
INVARIANT_CHECK;
#endif
bool sent_a_piece = false;
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!t) return;
// only add new piece-chunks if the send buffer is small enough
// otherwise there will be no end to how large it will be!
boost::uint64_t upload_rate = int(m_statistics.upload_rate());
int buffer_size_watermark = upload_rate
* m_ses.settings().send_buffer_watermark_factor / 100;
if (buffer_size_watermark < m_ses.settings().send_buffer_low_watermark)
{
buffer_size_watermark = m_ses.settings().send_buffer_low_watermark;
}
else if (buffer_size_watermark > m_ses.settings().send_buffer_watermark)
{
buffer_size_watermark = m_ses.settings().send_buffer_watermark;
}
while (!m_requests.empty()
&& (send_buffer_size() + m_reading_bytes < buffer_size_watermark))
{
TORRENT_ASSERT(t->ready_for_connections());
peer_request& r = m_requests.front();
TORRENT_ASSERT(r.piece >= 0);
TORRENT_ASSERT(r.piece < (int)m_have_piece.size());
TORRENT_ASSERT(t->have_piece(r.piece));
TORRENT_ASSERT(r.start + r.length <= t->torrent_file().piece_size(r.piece));
TORRENT_ASSERT(r.length > 0 && r.start >= 0);
std::pair<int, int> cache = preferred_caching();
if (!t->seed_mode() || t->verified_piece(r.piece))
{
t->filesystem().async_read(r, boost::bind(&peer_connection::on_disk_read_complete
, self(), _1, _2, r), cache.first, cache.second);
}
else
{
// this means we're in seed mode and we haven't yet
// verified this piece (r.piece)
t->filesystem().async_read_and_hash(r, boost::bind(&peer_connection::on_disk_read_complete
, self(), _1, _2, r), cache.second);
t->verified(r.piece);
}
m_reading_bytes += r.length;
m_requests.erase(m_requests.begin());
sent_a_piece = true;
}
if (t->share_mode() && sent_a_piece)
t->recalc_share_mode();
}
void peer_connection::on_disk_read_complete(int ret, disk_io_job const& j, peer_request r)
{
// flush send buffer at the end of this scope
// TODO: peers should really be corked/uncorked outside of
// all completed disk operations
cork _c(*this);
#ifdef TORRENT_STATS
++m_ses.m_num_messages[aux::session_impl::on_disk_read_counter];
#endif
TORRENT_ASSERT(m_ses.is_network_thread());
m_reading_bytes -= r.length;
disk_buffer_holder buffer(m_ses, j.buffer);
#if TORRENT_DISK_STATS
if (j.buffer) m_ses.m_disk_thread.rename_buffer(j.buffer, "received send buffer");
#endif
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!t)
{
disconnect(j.error);
return;
}
if (ret != r.length)
{
if (ret == -3)
{
#if defined TORRENT_VERBOSE_LOGGING
peer_log("==> REJECT_PIECE [ piece: %d s: %d l: %d ]"
, r.piece , r.start , r.length);
#endif
write_reject_request(r);
if (t->seed_mode()) t->leave_seed_mode(false);
}
else
{
// handle_disk_error may disconnect us
t->handle_disk_error(j, this);
}
return;
}
if (t)
{
if (t->seed_mode() && t->all_verified())
t->leave_seed_mode(true);
}
#if defined TORRENT_VERBOSE_LOGGING
peer_log("==> PIECE [ piece: %d s: %d l: %d ]"
, r.piece, r.start, r.length);
#endif
#if TORRENT_DISK_STATS
if (j.buffer) m_ses.m_disk_thread.rename_buffer(j.buffer, "dispatched send buffer");
#endif
write_piece(r, buffer);
}
void peer_connection::assign_bandwidth(int channel, int amount)
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("%s ASSIGN BANDWIDHT [ bytes: %d ]"
, channel == upload_channel ? ">>>" : "<<<", amount);
#endif
TORRENT_ASSERT(amount > 0);
m_quota[channel] += amount;
TORRENT_ASSERT(m_channel_state[channel] & peer_info::bw_limit);
m_channel_state[channel] &= ~peer_info::bw_limit;
if (channel == upload_channel)
{
setup_send();
}
else if (channel == download_channel)
{
setup_receive();
}
}
int peer_connection::request_upload_bandwidth(
bandwidth_channel* bwc1
, bandwidth_channel* bwc2
, bandwidth_channel* bwc3
, bandwidth_channel* bwc4)
{
// we can only have one outstanding bandwidth request at a time
if (m_channel_state[upload_channel] & peer_info::bw_limit) return 0;
int bytes = (std::max)(m_send_buffer.size(), m_statistics.upload_rate() * 2
* m_ses.m_settings.tick_interval / 1000);
// we already have quota for the bytes we want to send
if (m_quota[upload_channel] >= bytes) return 0;
// deduct the bytes we already have quota for
bytes -= m_quota[upload_channel];
shared_ptr<torrent> t = m_torrent.lock();
int priority;
if (t && m_ses.m_settings.choking_algorithm == session_settings::bittyrant_choker
&& !t->upload_mode() && !t->is_upload_only())
{
// when we use the bittyrant choker, the priority of a peer
// is decided based on the estimated reciprocation rate and
// the share it represents of the total upload rate capacity
// the torrent priority is taken into account when unchoking peers
int upload_capacity = m_ses.settings().upload_rate_limit;
if (upload_capacity == 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 = (std::max)(20000, m_ses.m_peak_up_rate + 10000);
}
int estimated_reciprocation_rate = m_est_reciprocation_rate;
// we cannot send faster than our upload rate anyway
if (estimated_reciprocation_rate < upload_capacity)
estimated_reciprocation_rate = upload_capacity;
priority = (boost::uint64_t(estimated_reciprocation_rate) << 14) / upload_capacity;
if (priority > 0xffff) priority = 0xffff;
}
else
{
priority = 1 + is_interesting() * 2 + m_requests_in_buffer.size();
if (priority > 255) priority = 255;
priority += t ? t->priority() << 8 : 0;
}
TORRENT_ASSERT(priority <= 0xffff);
// peers that we are not interested in are non-prioritized
#ifdef TORRENT_VERBOSE_LOGGING
peer_log(">>> REQUEST_BANDWIDTH [ upload: %d prio: %d "
"channels: %p %p %p %p limits: %d %d %d %d ignore: %d ]"
, int(m_send_buffer.size()), priority
, bwc1, bwc2, bwc3, bwc4
, (bwc1?bwc1->throttle():0)
, (bwc2?bwc2->throttle():0)
, (bwc3?bwc3->throttle():0)
, (bwc4?bwc4->throttle():0)
, m_ignore_bandwidth_limits);
#endif
int ret = m_ses.m_upload_rate.request_bandwidth(self()
, bytes
, priority
, bwc1, bwc2, bwc3, bwc4);
if (ret == 0)
{
m_channel_state[upload_channel] |= peer_info::bw_limit;
}
else
{
m_quota[upload_channel] += ret;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log(">>> ASSIGN BANDWIDTH [ bytes: %d ]", ret);
#endif
}
return ret;
}
int peer_connection::request_download_bandwidth(
bandwidth_channel* bwc1
, bandwidth_channel* bwc2
, bandwidth_channel* bwc3
, bandwidth_channel* bwc4)
{
// we can only have one outstanding bandwidth request at a time
if (m_channel_state[download_channel] & peer_info::bw_limit) return 0;
int bytes = (std::max)((std::max)(m_outstanding_bytes, m_packet_size - m_recv_pos) + 30
, m_statistics.download_rate() * 2 * m_ses.m_settings.tick_interval / 1000);
// we already have enough quota
if (m_quota[download_channel] >= bytes) return 0;
// deduct the bytes we already have quota for
bytes -= m_quota[download_channel];
shared_ptr<torrent> t = m_torrent.lock();
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<<< REQUEST_BANDWIDTH [ download: %d prio: %d "
"channels: %p %p %p %p limits: %d %d %d %d ignore: %d ]"
, int(m_download_queue.size() * 16 * 1024 + 30), m_priority
, bwc1, bwc2, bwc3, bwc4
, (bwc1?bwc1->throttle():0)
, (bwc2?bwc2->throttle():0)
, (bwc3?bwc3->throttle():0)
, (bwc4?bwc4->throttle():0)
, m_ignore_bandwidth_limits);
#endif
TORRENT_ASSERT(m_priority <= 255);
int priority = m_priority + (t ? (t->priority() << 8) : 0);
TORRENT_ASSERT(m_outstanding_bytes >= 0);
TORRENT_ASSERT((m_channel_state[download_channel] & peer_info::bw_limit) == 0);
int ret = m_ses.m_download_rate.request_bandwidth(self()
, bytes, priority, bwc1, bwc2, bwc3, bwc4);
if (ret == 0)
{
m_channel_state[download_channel] |= peer_info::bw_limit;
}
else
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<<< ASSIGN BANDWIDTH [ bytes: %d ]", ret);
#endif
m_quota[download_channel] += ret;
}
return ret;
}
void peer_connection::uncork_socket()
{
if (!m_corked) return;
m_corked = false;
setup_send();
}
void peer_connection::setup_send()
{
if (m_disconnecting) return;
shared_ptr<torrent> t = m_torrent.lock();
// we may want to request more quota at this point
int ret = 0;
bool utp = m_socket->get<utp_stream>() != 0;
bool ignore_limits = m_ignore_bandwidth_limits
|| (!m_ses.m_settings.rate_limit_utp && utp);
if (!ignore_limits)
{
// in this case, we have data to send, but no
// bandwidth. So, we simply request bandwidth
// from the bandwidth manager
ret = request_upload_bandwidth(
&m_ses.m_upload_channel
, t ? &t->m_bandwidth_channel[upload_channel] : 0
, &m_bandwidth_channel[upload_channel]
, !utp ? &m_ses.m_tcp_upload_channel : 0);
}
else
{
// in this case, we're a local peer, and the settings
// are set to ignore rate limits for local peers. So,
// instead we rate limit ourself against the special
// global bandwidth channel for local peers, which defaults
// to unthrottled
ret = request_upload_bandwidth(&m_ses.m_local_upload_channel
, &m_bandwidth_channel[upload_channel]);
}
if (m_channel_state[upload_channel] & peer_info::bw_network) return;
if (m_quota[upload_channel] == 0
&& !m_send_buffer.empty()
&& !m_connecting)
{
return;
}
int quota_left = m_quota[upload_channel];
if (m_send_buffer.empty()
&& m_reading_bytes > 0
&& quota_left > 0)
{
if ((m_channel_state[upload_channel] & peer_info::bw_disk) == 0)
m_ses.inc_disk_queue(upload_channel);
m_channel_state[upload_channel] |= peer_info::bw_disk;
if (!m_connecting
&& !m_requests.empty()
&& m_reading_bytes > m_ses.settings().send_buffer_watermark - 0x4000)
{
// we're stalled on the disk. We want to write and we can write
// but our send buffer is empty, waiting to be refilled from the disk
// this either means the disk is slower than the network connection
// or that our send buffer watermark is too small, because we can
// send it all before the disk gets back to us. That's why we only
// trigger this if we've also filled the allowed send buffer. The
// first request would not fill it all the way up because of the
// upload rate being virtually 0. If m_requests is empty, it doesn't
// matter anyway, because we don't have any more requests from the
// peer to hang on to the disk
if (m_ses.m_alerts.should_post<performance_alert>())
{
m_ses.m_alerts.post_alert(performance_alert(t->get_handle()
, performance_alert::send_buffer_watermark_too_low));
}
}
}
else
{
if (m_channel_state[upload_channel] & peer_info::bw_disk)
m_ses.dec_disk_queue(upload_channel);
m_channel_state[upload_channel] &= ~peer_info::bw_disk;
}
if (!can_write())
{
#ifdef TORRENT_VERBOSE_LOGGING
if (m_send_buffer.empty())
{
peer_log(">>> SEND BUFFER DEPLETED ["
" quota: %d ignore: %s buf: %d connecting: %s disconnecting: %s pending_disk: %d ]"
, m_quota[upload_channel], m_ignore_bandwidth_limits?"yes":"no"
, int(m_send_buffer.size()), m_connecting?"yes":"no"
, m_disconnecting?"yes":"no", m_reading_bytes);
}
else
{
peer_log(">>> CANNOT WRITE ["
" quota: %d ignore: %s buf: %d connecting: %s disconnecting: %s pending_disk: %d ]"
, m_quota[upload_channel], m_ignore_bandwidth_limits?"yes":"no"
, int(m_send_buffer.size()), m_connecting?"yes":"no"
, m_disconnecting?"yes":"no", m_reading_bytes);
}
#endif
return;
}
// send the actual buffer
int amount_to_send = m_send_buffer.size();
if (amount_to_send > quota_left)
amount_to_send = quota_left;
TORRENT_ASSERT(amount_to_send > 0);
if (m_corked)
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log(">>> CORKED WRITE [ bytes: %d ]", amount_to_send);
#endif
return;
}
TORRENT_ASSERT((m_channel_state[upload_channel] & peer_info::bw_network) == 0);
#ifdef TORRENT_VERBOSE_LOGGING
peer_log(">>> ASYNC_WRITE [ bytes: %d ]", amount_to_send);
#endif
std::list<asio::const_buffer> const& vec = m_send_buffer.build_iovec(amount_to_send);
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("peer_connection::on_send_data");
#endif
m_socket->async_write_some(
vec, make_write_handler(boost::bind(
&peer_connection::on_send_data, self(), _1, _2)));
m_channel_state[upload_channel] |= peer_info::bw_network;
}
void peer_connection::on_disk()
{
if ((m_channel_state[download_channel] & peer_info::bw_disk) == 0) return;
boost::intrusive_ptr<peer_connection> me(this);
m_ses.dec_disk_queue(download_channel);
m_channel_state[download_channel] &= ~peer_info::bw_disk;
setup_receive(read_async);
}
void peer_connection::setup_receive(sync_t sync)
{
INVARIANT_CHECK;
if (m_disconnecting) return;
shared_ptr<torrent> t = m_torrent.lock();
// we may want to request more quota at this point
int ret = 0;
bool utp = m_socket->get<utp_stream>() != 0;
bool ignore_limits = m_ignore_bandwidth_limits
|| (!m_ses.m_settings.rate_limit_utp && utp);
if (!ignore_limits)
{
// in this case, we have outstanding data to
// receive, but no bandwidth quota. So, we simply
// request bandwidth from the bandwidth manager
ret = request_download_bandwidth(
&m_ses.m_download_channel
, t ? &t->m_bandwidth_channel[download_channel] : 0
, &m_bandwidth_channel[download_channel]
, !utp ? &m_ses.m_tcp_download_channel : 0);
}
else
{
// in this case, we're a local peer, and the settings
// are set to ignore rate limits for local peers. So,
// instead we rate limit ourself against the special
// global bandwidth channel for local peers, which defaults
// to unthrottled
ret = request_download_bandwidth(&m_ses.m_local_download_channel
, &m_bandwidth_channel[download_channel]);
}
if (m_channel_state[download_channel] & peer_info::bw_network) return;
if (m_quota[download_channel] == 0
&& !m_connecting)
{
return;
}
if (!can_read(&m_channel_state[download_channel]))
{
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<<< CANNOT READ [ quota: %d ignore: %s "
"can-write-to-disk: %s queue-limit: %d disconnecting: %s ]"
, m_quota[download_channel]
, (m_ignore_bandwidth_limits?"yes":"no")
, (m_ses.can_write_to_disk()?"yes":"no")
, m_ses.settings().max_queued_disk_bytes
, (m_disconnecting?"yes":"no"));
#endif
// if we block reading, waiting for the disk, we will wake up
// by the disk_io_thread posting a message every time it drops
// from being at or exceeding the limit down to below the limit
return;
}
error_code ec;
try_read(read_async, ec);
}
size_t peer_connection::try_read(sync_t s, error_code& ec)
{
TORRENT_ASSERT(m_packet_size > 0);
int max_receive = m_packet_size - m_recv_pos;
TORRENT_ASSERT(max_receive >= 0);
if (m_recv_pos >= m_soft_packet_size) m_soft_packet_size = 0;
if (m_soft_packet_size && max_receive > m_soft_packet_size - m_recv_pos)
max_receive = m_soft_packet_size - m_recv_pos;
int quota_left = m_quota[download_channel];
if (max_receive > quota_left)
max_receive = quota_left;
if (max_receive == 0)
{
ec = asio::error::would_block;
return 0;
}
TORRENT_ASSERT(m_recv_pos >= 0);
TORRENT_ASSERT(m_packet_size > 0);
if (!can_read())
{
ec = asio::error::would_block;
return 0;
}
int regular_buffer_size = m_packet_size - m_disk_recv_buffer_size;
if (int(m_recv_buffer.size()) < regular_buffer_size)
m_recv_buffer.resize(round_up8(regular_buffer_size));
boost::array<asio::mutable_buffer, 2> vec;
int num_bufs = 0;
if (!m_disk_recv_buffer || regular_buffer_size >= m_recv_pos + max_receive)
{
// only receive into regular buffer
TORRENT_ASSERT(m_recv_pos + max_receive <= int(m_recv_buffer.size()));
vec[0] = asio::buffer(&m_recv_buffer[m_recv_pos], max_receive);
num_bufs = 1;
}
else if (m_recv_pos >= regular_buffer_size)
{
// only receive into disk buffer
TORRENT_ASSERT(m_recv_pos - regular_buffer_size >= 0);
TORRENT_ASSERT(m_recv_pos - regular_buffer_size + max_receive <= m_disk_recv_buffer_size);
vec[0] = asio::buffer(m_disk_recv_buffer.get() + m_recv_pos - regular_buffer_size, max_receive);
num_bufs = 1;
}
else
{
// receive into both regular and disk buffer
TORRENT_ASSERT(max_receive + m_recv_pos > regular_buffer_size);
TORRENT_ASSERT(m_recv_pos < regular_buffer_size);
TORRENT_ASSERT(max_receive - regular_buffer_size
+ m_recv_pos <= m_disk_recv_buffer_size);
vec[0] = asio::buffer(&m_recv_buffer[m_recv_pos]
, regular_buffer_size - m_recv_pos);
vec[1] = asio::buffer(m_disk_recv_buffer.get()
, max_receive - regular_buffer_size + m_recv_pos);
num_bufs = 2;
}
if (s == read_async)
{
TORRENT_ASSERT((m_channel_state[download_channel] & peer_info::bw_network) == 0);
m_channel_state[download_channel] |= peer_info::bw_network;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<<< ASYNC_READ [ max: %d bytes ]", max_receive);
#endif
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("peer_connection::on_receive_data");
#endif
if (num_bufs == 1)
{
m_socket->async_read_some(
asio::mutable_buffers_1(vec[0]), make_read_handler(
boost::bind(&peer_connection::on_receive_data, self(), _1, _2)));
}
else
{
m_socket->async_read_some(
vec, make_read_handler(
boost::bind(&peer_connection::on_receive_data, self(), _1, _2)));
}
return 0;
}
size_t ret = 0;
if (num_bufs == 1)
{
ret = m_socket->read_some(asio::mutable_buffers_1(vec[0]), ec);
}
else
{
ret = m_socket->read_some(vec, ec);
}
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<<< SYNC_READ [ max: %d ret: %d e: %s ]", max_receive, ret, ec ? ec.message().c_str() : "");
#endif
return ret;
}
#ifndef TORRENT_DISABLE_ENCRYPTION
// returns the last 'bytes' from the receive buffer
std::pair<buffer::interval, buffer::interval> peer_connection::wr_recv_buffers(int bytes)
{
TORRENT_ASSERT(bytes <= m_recv_pos);
std::pair<buffer::interval, buffer::interval> vec;
int regular_buffer_size = m_packet_size - m_disk_recv_buffer_size;
TORRENT_ASSERT(regular_buffer_size >= 0);
if (!m_disk_recv_buffer || regular_buffer_size >= m_recv_pos)
{
vec.first = buffer::interval(&m_recv_buffer[0]
+ m_recv_pos - bytes, &m_recv_buffer[0] + m_recv_pos);
vec.second = buffer::interval(0,0);
}
else if (m_recv_pos - bytes >= regular_buffer_size)
{
vec.first = buffer::interval(m_disk_recv_buffer.get() + m_recv_pos
- regular_buffer_size - bytes, m_disk_recv_buffer.get() + m_recv_pos
- regular_buffer_size);
vec.second = buffer::interval(0,0);
}
else
{
TORRENT_ASSERT(m_recv_pos - bytes < regular_buffer_size);
TORRENT_ASSERT(m_recv_pos > regular_buffer_size);
vec.first = buffer::interval(&m_recv_buffer[0] + m_recv_pos - bytes
, &m_recv_buffer[0] + regular_buffer_size);
vec.second = buffer::interval(m_disk_recv_buffer.get()
, m_disk_recv_buffer.get() + m_recv_pos - regular_buffer_size);
}
TORRENT_ASSERT(vec.first.left() + vec.second.left() == bytes);
return vec;
}
#endif
void peer_connection::reset_recv_buffer(int packet_size)
{
TORRENT_ASSERT(packet_size > 0);
if (m_recv_pos > m_packet_size)
{
cut_receive_buffer(m_packet_size, packet_size);
return;
}
m_recv_pos = 0;
m_packet_size = packet_size;
}
void nop(char*) {}
void peer_connection::append_const_send_buffer(char const* buffer, int size)
{
m_send_buffer.append_buffer((char*)buffer, size, size, &nop);
#if defined TORRENT_STATS && defined TORRENT_DISK_STATS
m_ses.m_buffer_usage_logger << log_time() << " append_const_send_buffer: " << size << std::endl;
m_ses.log_buffer_usage();
#endif
}
void peer_connection::send_buffer(char const* buf, int size, int flags
, void (*fun)(char*, int, void*), void* userdata)
{
if (flags == message_type_request)
m_requests_in_buffer.push_back(m_send_buffer.size() + size);
int free_space = m_send_buffer.space_in_last_buffer();
if (free_space > size) free_space = size;
if (free_space > 0)
{
char* dst = m_send_buffer.append(buf, free_space);
TORRENT_ASSERT(dst != 0);
if (fun) fun(dst, free_space, userdata);
size -= free_space;
buf += free_space;
#if defined TORRENT_STATS && defined TORRENT_DISK_STATS
m_ses.m_buffer_usage_logger << log_time() << " send_buffer: "
<< free_space << std::endl;
m_ses.log_buffer_usage();
#endif
}
if (size <= 0) return;
#if defined TORRENT_STATS && defined TORRENT_DISK_STATS
m_ses.m_buffer_usage_logger << log_time() << " send_buffer_alloc: " << size << std::endl;
m_ses.log_buffer_usage();
#endif
int i = 0;
while (size > 0)
{
char* chain_buf = m_ses.allocate_buffer();
if (chain_buf == 0)
{
disconnect(errors::no_memory);
return;
}
int buf_size = (std::min)(int(aux::session_impl::send_buffer_size), size);
memcpy(chain_buf, buf, buf_size);
if (fun) fun(chain_buf, buf_size, userdata);
buf += buf_size;
size -= buf_size;
m_send_buffer.append_buffer(chain_buf, aux::session_impl::send_buffer_size, buf_size
, boost::bind(&session_impl::free_buffer, boost::ref(m_ses), _1));
++i;
}
setup_send();
}
template<class T>
struct set_to_zero
{
set_to_zero(T& v, bool cond): m_val(v), m_cond(cond) {}
void fire() { if (!m_cond) return; m_cond = false; m_val = 0; }
~set_to_zero() { if (m_cond) m_val = 0; }
private:
T& m_val;
bool m_cond;
};
// --------------------------
// RECEIVE DATA
// --------------------------
void peer_connection::on_receive_data(const error_code& error
, std::size_t bytes_transferred)
{
#ifdef TORRENT_STATS
++m_ses.m_num_messages[aux::session_impl::on_read_counter];
int size = 8;
int index = 0;
while (bytes_transferred > size + 13) { size <<= 1; ++index; }
int num_max = sizeof(m_ses.m_recv_buffer_sizes)/sizeof(m_ses.m_recv_buffer_sizes[0]);
if (index >= num_max) index = num_max - 1;
++m_ses.m_recv_buffer_sizes[index];
#endif
TORRENT_ASSERT(m_ses.is_network_thread());
// keep ourselves alive in until this function exits in
// case we disconnect
// this needs to be created before the invariant check,
// to keep the object alive through the exit check
boost::intrusive_ptr<peer_connection> me(self());
// flush the send buffer at the end of this function
cork _c(*this);
INVARIANT_CHECK;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<<< ON_RECEIVE_DATA [ bytes: %d error: %s ]"
, bytes_transferred, error.message().c_str());
#endif
#if defined TORRENT_ASIO_DEBUGGING
complete_async("peer_connection::on_receive_data");
#endif
// leave this bit set until we're done looping, reading from the socket.
// that way we don't trigger any async read calls until the end of this
// function.
TORRENT_ASSERT(m_channel_state[download_channel] & peer_info::bw_network);
int bytes_in_loop = bytes_transferred;
if (m_extension_outstanding_bytes > 0)
m_extension_outstanding_bytes -= (std::min)(m_extension_outstanding_bytes, int(bytes_transferred));
if (error)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("*** ERROR [ in peer_connection::on_receive_data error: %s ]"
, error.message().c_str());
#endif
m_statistics.trancieve_ip_packet(bytes_in_loop, m_remote.address().is_v6());
on_receive(error, bytes_transferred);
disconnect(error);
return;
}
int num_loops = 0;
do
{
TORRENT_ASSERT(int(m_recv_pos + bytes_transferred) <= m_packet_size);
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("<<< read %d bytes", int(bytes_transferred));
#endif
// correct the dl quota usage, if not all of the buffer was actually read
TORRENT_ASSERT(int(bytes_transferred) <= m_quota[download_channel]);
m_quota[download_channel] -= bytes_transferred;
if (m_disconnecting)
{
m_statistics.trancieve_ip_packet(bytes_in_loop, m_remote.address().is_v6());
return;
}
TORRENT_ASSERT(m_packet_size > 0);
TORRENT_ASSERT(bytes_transferred > 0);
m_last_receive = time_now();
m_recv_pos += bytes_transferred;
TORRENT_ASSERT(m_recv_pos <= int(m_recv_buffer.size()
+ m_disk_recv_buffer_size));
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
size_type cur_payload_dl = m_statistics.last_payload_downloaded();
size_type cur_protocol_dl = m_statistics.last_protocol_downloaded();
#endif
{
INVARIANT_CHECK;
on_receive(error, bytes_transferred);
}
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
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 == int(bytes_transferred));
#endif
if (m_disconnecting) return;
TORRENT_ASSERT(m_packet_size > 0);
if (m_peer_choked
&& m_recv_pos == 0
&& (m_recv_buffer.capacity() - m_packet_size) > 128)
{
// round up to an even 8 bytes since that's the RC4 blocksize
buffer(round_up8(m_packet_size)).swap(m_recv_buffer);
}
if (m_recv_pos >= m_soft_packet_size) m_soft_packet_size = 0;
if (num_loops > 20) break;
error_code ec;
bytes_transferred = try_read(read_sync, ec);
TORRENT_ASSERT(bytes_transferred > 0 || ec);
if (ec && ec != asio::error::would_block)
{
m_statistics.trancieve_ip_packet(bytes_in_loop, m_remote.address().is_v6());
disconnect(ec);
return;
}
if (ec == asio::error::would_block) break;
bytes_in_loop += bytes_transferred;
++num_loops;
}
while (bytes_transferred > 0);
if (is_seed())
{
boost::shared_ptr<torrent> t = m_torrent.lock();
if (t) t->seen_complete();
}
m_statistics.trancieve_ip_packet(bytes_in_loop, m_remote.address().is_v6());
// allow reading from the socket again
TORRENT_ASSERT(m_channel_state[download_channel] & peer_info::bw_network);
m_channel_state[download_channel] &= ~peer_info::bw_network;
setup_receive(read_async);
}
bool peer_connection::can_write() const
{
// if we have requests or pending data to be sent or announcements to be made
// we want to send data
return !m_send_buffer.empty()
&& m_quota[upload_channel] > 0
&& !m_connecting;
}
bool peer_connection::can_read(char* state) const
{
boost::shared_ptr<torrent> t = m_torrent.lock();
bool bw_limit = m_quota[download_channel] > 0;
if (!bw_limit) return false;
bool disk = m_ses.settings().max_queued_disk_bytes == 0
|| m_ses.can_write_to_disk()
// don't block this peer because of disk saturation
// if we're not downloading any pieces from it
|| m_outstanding_bytes == 0;
if (!disk)
{
if (state)
{
if ((*state & peer_info::bw_disk) == 0)
m_ses.inc_disk_queue(download_channel);
*state |= peer_info::bw_disk;
}
return false;
}
return !m_connecting && !m_disconnecting;
}
void peer_connection::on_connect(int ticket)
{
TORRENT_ASSERT(m_ses.is_network_thread());
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
// in case we disconnect here, we need to
// keep the connection alive until the
// exit invariant check is run
boost::intrusive_ptr<peer_connection> me(self());
#endif
INVARIANT_CHECK;
error_code ec;
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << time_now_string() << " ON_CONNECT: " << print_endpoint(m_remote) << "\n";
#endif
if (ticket == -1)
{
disconnect(asio::error::operation_aborted);
return;
}
m_connection_ticket = ticket;
boost::shared_ptr<torrent> t = m_torrent.lock();
m_queued = false;
if (!t)
{
TORRENT_ASSERT(!m_connecting);
disconnect(errors::torrent_aborted);
return;
}
TORRENT_ASSERT(m_connecting);
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log(">>> OPEN [ protocol: %s ]", (m_remote.address().is_v4()?"IPv4":"IPv6"));
#endif
m_socket->open(m_remote.protocol(), ec);
if (ec)
{
disconnect(ec);
return;
}
tcp::endpoint bind_interface = t->get_interface();
std::pair<int, int> const& out_ports = m_ses.settings().outgoing_ports;
if (out_ports.first > 0 && out_ports.second >= out_ports.first)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log(">>> SET_REUSE_ADDRESS");
#endif
m_socket->set_option(socket_acceptor::reuse_address(true), ec);
// ignore errors because the underlying socket may not
// be opened yet. This happens when we're routing through
// a proxy. In that case, we don't yet know the address of
// the proxy server, and more importantly, we don't know
// the address family of its address. This means we can't
// open the socket yet. The socks abstraction layer defers
// opening it.
ec.clear();
bind_interface.port(m_ses.next_port());
}
// if we're not binding to a specific interface, bind
// to the same protocol family as the target endpoint
if (is_any(bind_interface.address()))
{
#if TORRENT_USE_IPV6
if (m_remote.address().is_v6())
bind_interface.address(address_v6::any());
else
#endif
bind_interface.address(address_v4::any());
}
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log(">>> BIND [ ep: %s ]", print_endpoint(bind_interface).c_str());
#endif
m_socket->bind(bind_interface, ec);
if (ec)
{
disconnect(ec);
return;
}
#if defined TORRENT_VERBOSE_LOGGING
peer_log(">>> ASYNC_CONNECT [ dst: %s ]", print_endpoint(m_remote).c_str());
#endif
#if defined TORRENT_ASIO_DEBUGGING
add_outstanding_async("peer_connection::on_connection_complete");
#endif
m_socket->async_connect(m_remote
, boost::bind(&peer_connection::on_connection_complete, self(), _1));
m_connect = time_now_hires();
m_statistics.sent_syn(m_remote.address().is_v6());
if (t->alerts().should_post<peer_connect_alert>())
{
t->alerts().post_alert(peer_connect_alert(
t->get_handle(), remote(), pid()));
}
#if defined TORRENT_VERBOSE_LOGGING
peer_log("*** LOCAL ENDPOINT[ e: %s ]", print_endpoint(m_socket->local_endpoint(ec)).c_str());
#endif
}
void peer_connection::on_connection_complete(error_code const& e)
{
#if defined TORRENT_ASIO_DEBUGGING
complete_async("peer_connection::on_connection_complete");
#endif
ptime completed = time_now_hires();
TORRENT_ASSERT(m_ses.is_network_thread());
INVARIANT_CHECK;
m_rtt = total_milliseconds(completed - m_connect);
#ifdef TORRENT_USE_OPENSSL
// add this RTT to the PRNG seed, to add more unpredictability
boost::uint64_t now = total_microseconds(completed - m_connect);
// assume 12 bits of entropy (i.e. about 8 milliseconds)
RAND_add(&now, 8, 1.5);
#endif
if (m_disconnecting) return;
error_code ec;
if (e)
{
connect_failed(e);
return;
}
// if t is NULL, we better not be connecting, since
// we can't decrement the connecting counter
boost::shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t || !m_connecting);
if (m_connecting && t)
{
t->dec_num_connecting();
m_connecting = false;
}
m_ses.m_half_open.done(m_connection_ticket);
if (m_disconnecting) return;
m_last_receive = time_now();
if (is_utp(*m_socket) && m_peer_info)
{
m_peer_info->confirmed_supports_utp = true;
m_peer_info->supports_utp = false;
}
// this means the connection just succeeded
m_statistics.received_synack(m_remote.address().is_v6());
TORRENT_ASSERT(m_socket);
#if defined TORRENT_VERBOSE_LOGGING
peer_log(">>> COMPLETED [ ep: %s rtt: %d ]", print_endpoint(m_remote).c_str(), m_rtt);
#endif
// set the socket to non-blocking, so that we can
// read the entire buffer on each read event we get
tcp::socket::non_blocking_io ioc(true);
#if defined TORRENT_VERBOSE_LOGGING
peer_log("*** SET NON-BLOCKING");
#endif
m_socket->io_control(ioc, ec);
if (ec)
{
disconnect(ec);
return;
}
if (m_remote == m_socket->local_endpoint(ec))
{
// if the remote endpoint is the same as the local endpoint, we're connected
// to ourselves
if (m_peer_info && t) t->get_policy().ban_peer(m_peer_info);
disconnect(errors::self_connection, 1);
return;
}
if (m_remote.address().is_v4())
{
error_code ec;
m_socket->set_option(type_of_service(m_ses.settings().peer_tos), ec);
#if defined TORRENT_VERBOSE_LOGGING
peer_log(">>> SET_TOS[ tos: %d e: %s ]", m_ses.settings().peer_tos, ec.message().c_str());
#endif
}
on_connected();
setup_send();
setup_receive();
}
// --------------------------
// SEND DATA
// --------------------------
void peer_connection::on_send_data(error_code const& error
, std::size_t bytes_transferred)
{
#ifdef TORRENT_STATS
++m_ses.m_num_messages[aux::session_impl::on_write_counter];
int size = 8;
int index = 0;
while (bytes_transferred > size + 13) { size <<= 1; ++index; }
int num_max = sizeof(m_ses.m_send_buffer_sizes)/sizeof(m_ses.m_send_buffer_sizes[0]);
if (index >= num_max) index = num_max - 1;
++m_ses.m_send_buffer_sizes[index];
#endif
TORRENT_ASSERT(m_ses.is_network_thread());
#if defined TORRENT_VERBOSE_LOGGING
peer_log("*** ON_SEND_DATA [ bytes: %d error: %s ]"
, int(bytes_transferred), error.message().c_str());
#endif
INVARIANT_CHECK;
#if defined TORRENT_ASIO_DEBUGGING
complete_async("peer_connection::on_send_data");
#endif
// keep ourselves alive in until this function exits in
// case we disconnect
boost::intrusive_ptr<peer_connection> me(self());
TORRENT_ASSERT(m_channel_state[upload_channel] & peer_info::bw_network);
m_send_buffer.pop_front(bytes_transferred);
for (std::vector<int>::iterator i = m_requests_in_buffer.begin()
, end(m_requests_in_buffer.end()); i != end; ++i)
*i -= bytes_transferred;
while (!m_requests_in_buffer.empty()
&& m_requests_in_buffer.front() <= 0)
m_requests_in_buffer.erase(m_requests_in_buffer.begin());
m_channel_state[upload_channel] &= ~peer_info::bw_network;
TORRENT_ASSERT(int(bytes_transferred) <= m_quota[upload_channel]);
m_quota[upload_channel] -= bytes_transferred;
m_statistics.trancieve_ip_packet(bytes_transferred, m_remote.address().is_v6());
#ifdef TORRENT_VERBOSE_LOGGING
peer_log(">>> wrote %d bytes", int(bytes_transferred));
#endif
if (error)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
peer_log("**ERROR**: %s [in peer_connection::on_send_data]", error.message().c_str());
#endif
disconnect(error);
return;
}
if (m_disconnecting) return;
TORRENT_ASSERT(!m_connecting);
TORRENT_ASSERT(bytes_transferred > 0);
m_last_sent = time_now();
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
size_type cur_payload_ul = m_statistics.last_payload_uploaded();
size_type cur_protocol_ul = m_statistics.last_protocol_uploaded();
#endif
on_sent(error, bytes_transferred);
#if defined TORRENT_DEBUG || TORRENT_RELEASE_ASSERTS
TORRENT_ASSERT(m_statistics.last_payload_uploaded() - cur_payload_ul >= 0);
TORRENT_ASSERT(m_statistics.last_protocol_uploaded() - cur_protocol_ul >= 0);
size_type stats_diff = m_statistics.last_payload_uploaded() - cur_payload_ul
+ m_statistics.last_protocol_uploaded() - cur_protocol_ul;
TORRENT_ASSERT(stats_diff == int(bytes_transferred));
#endif
fill_send_buffer();
setup_send();
}
#if defined TORRENT_DEBUG && !defined TORRENT_DISABLE_INVARIANT_CHECKS
struct peer_count_t
{
peer_count_t(): num_peers(0), num_peers_with_timeouts(0), num_peers_with_nowant(0), num_not_requested(0) {}
int num_peers;
int num_peers_with_timeouts;
int num_peers_with_nowant;
int num_not_requested;
// std::vector<peer_connection const*> peers;
};
void peer_connection::check_invariant() const
{
TORRENT_ASSERT(m_in_use == 1337);
TORRENT_ASSERT(m_queued_time_critical <= int(m_request_queue.size()));
TORRENT_ASSERT(bool(m_disk_recv_buffer) == (m_disk_recv_buffer_size > 0));
TORRENT_ASSERT(m_upload_limit >= 0);
TORRENT_ASSERT(m_download_limit >= 0);
boost::shared_ptr<torrent> t = m_torrent.lock();
if (!m_disconnect_started && m_initialized)
{
// none of this matters if we're disconnecting anyway
if (t->is_finished())
TORRENT_ASSERT(!is_interesting());
if (is_seed())
TORRENT_ASSERT(upload_only());
}
if (m_disconnecting)
{
TORRENT_ASSERT(m_download_queue.empty());
TORRENT_ASSERT(m_request_queue.empty());
TORRENT_ASSERT(!t);
TORRENT_ASSERT(m_disconnect_started);
}
else if (!m_in_constructor)
{
TORRENT_ASSERT(m_ses.has_peer((peer_connection*)this));
}
TORRENT_ASSERT(m_outstanding_bytes >= 0);
if (t && t->valid_metadata() && !m_disconnecting)
{
torrent_info const& ti = t->torrent_file();
// if the piece is fully downloaded, we might have popped it from the
// download queue already
int outstanding_bytes = 0;
bool in_download_queue = false;
int block_size = t->block_size();
piece_block last_block(ti.num_pieces()-1
, (ti.piece_size(ti.num_pieces()-1) + block_size - 1) / block_size);
for (std::vector<pending_block>::const_iterator i = m_download_queue.begin()
, end(m_download_queue.end()); i != end; ++i)
{
TORRENT_ASSERT(i->block.piece_index <= last_block.piece_index);
TORRENT_ASSERT(i->block.piece_index < last_block.piece_index
|| i->block.block_index <= last_block.block_index);
if (m_received_in_piece && i == m_download_queue.begin())
{
in_download_queue = true;
// this assert is not correct since block may have different sizes
// and may not be returned in the order they were requested
// TORRENT_ASSERT(t->to_req(i->block).length >= m_received_in_piece);
outstanding_bytes += t->to_req(i->block).length - m_received_in_piece;
}
else
{
outstanding_bytes += t->to_req(i->block).length;
}
}
//if (p && p->bytes_downloaded < p->full_block_bytes) TORRENT_ASSERT(in_download_queue);
TORRENT_ASSERT(m_outstanding_bytes == outstanding_bytes);
}
std::set<piece_block> unique;
std::transform(m_download_queue.begin(), m_download_queue.end()
, std::inserter(unique, unique.begin()), boost::bind(&pending_block::block, _1));
std::transform(m_request_queue.begin(), m_request_queue.end()
, std::inserter(unique, unique.begin()), boost::bind(&pending_block::block, _1));
TORRENT_ASSERT(unique.size() == m_download_queue.size() + m_request_queue.size());
if (m_peer_info)
{
TORRENT_ASSERT(m_peer_info->prev_amount_upload == 0);
TORRENT_ASSERT(m_peer_info->prev_amount_download == 0);
TORRENT_ASSERT(m_peer_info->connection == this
|| m_peer_info->connection == 0);
if (m_peer_info->optimistically_unchoked)
TORRENT_ASSERT(!is_choked());
}
TORRENT_ASSERT(m_have_piece.count() == m_num_pieces);
if (!t)
{
#ifdef TORRENT_EXPENSIVE_INVARIANT_CHECKS
// since this connection doesn't have a torrent reference
// no torrent should have a reference to this connection either
for (aux::session_impl::torrent_map::const_iterator i = m_ses.m_torrents.begin()
, end(m_ses.m_torrents.end()); i != end; ++i)
TORRENT_ASSERT(!i->second->has_peer((peer_connection*)this));
#endif
return;
}
if (t->ready_for_connections() && m_initialized)
TORRENT_ASSERT(t->torrent_file().num_pieces() == int(m_have_piece.size()));
// in share mode we don't close redundant connections
if (m_ses.settings().close_redundant_connections && !t->share_mode())
{
// make sure upload only peers are disconnected
if (t->is_upload_only()
&& m_upload_only
&& t->valid_metadata()
&& has_metadata())
TORRENT_ASSERT(m_disconnect_started || t->graceful_pause() || t->has_error());
if (m_upload_only
&& !m_interesting
&& m_bitfield_received
&& t->are_files_checked()
&& t->valid_metadata()
&& has_metadata())
TORRENT_ASSERT(m_disconnect_started);
}
if (!m_disconnect_started && m_initialized && m_ses.settings().close_redundant_connections)
{
// none of this matters if we're disconnecting anyway
if (t->is_upload_only())
TORRENT_ASSERT(!m_interesting || t->graceful_pause() || t->has_error());
if (is_seed())
TORRENT_ASSERT(m_upload_only);
}
if (t->has_picker())
{
std::map<piece_block, peer_count_t> num_requests;
for (torrent::const_peer_iterator i = t->begin(); i != t->end(); ++i)
{
// make sure this peer is not a dangling pointer
#ifdef TORRENT_EXPENSIVE_INVARIANT_CHECKS
TORRENT_ASSERT(m_ses.has_peer(*i));
#endif
peer_connection const& p = *(*i);
for (std::vector<pending_block>::const_iterator i = p.request_queue().begin()
, end(p.request_queue().end()); i != end; ++i)
{
++num_requests[i->block].num_peers;
++num_requests[i->block].num_peers_with_timeouts;
++num_requests[i->block].num_peers_with_nowant;
++num_requests[i->block].num_not_requested;
// num_requests[i->block].peers.push_back(&p);
}
for (std::vector<pending_block>::const_iterator i = p.download_queue().begin()
, end(p.download_queue().end()); i != end; ++i)
{
if (!i->not_wanted && !i->timed_out) ++num_requests[i->block].num_peers;
if (i->timed_out) ++num_requests[i->block].num_peers_with_timeouts;
if (i->not_wanted) ++num_requests[i->block].num_peers_with_nowant;
// num_requests[i->block].peers.push_back(&p);
}
}
for (std::map<piece_block, peer_count_t>::iterator i = num_requests.begin()
, end(num_requests.end()); i != end; ++i)
{
piece_block b = i->first;
peer_count_t const& pc = i->second;
int count = pc.num_peers;
int count_with_timeouts = pc.num_peers_with_timeouts;
int count_with_nowant = pc.num_peers_with_nowant;
(void)count_with_timeouts;
(void)count_with_nowant;
int picker_count = t->picker().num_peers(b);
if (!t->picker().is_downloaded(b))
TORRENT_ASSERT(picker_count == count);
}
}
#ifdef TORRENT_EXPENSIVE_INVARIANT_CHECKS
if (m_peer_info && type() == bittorrent_connection)
{
policy::const_iterator i = t->get_policy().begin_peer();
policy::const_iterator end = t->get_policy().end_peer();
for (; i != end; ++i)
{
if (*i == m_peer_info) break;
}
TORRENT_ASSERT(i != end);
}
#endif
if (t->has_picker() && !t->is_aborted())
{
// make sure that pieces that have completed the download
// of all their blocks are in the disk io thread's queue
// to be checked.
const std::vector<piece_picker::downloading_piece>& dl_queue
= t->picker().get_download_queue();
for (std::vector<piece_picker::downloading_piece>::const_iterator i =
dl_queue.begin(); i != dl_queue.end(); ++i)
{
const int blocks_per_piece = t->picker().blocks_in_piece(i->index);
bool complete = true;
for (int j = 0; j < blocks_per_piece; ++j)
{
if (i->info[j].state == piece_picker::block_info::state_finished)
continue;
complete = false;
break;
}
/*
// this invariant is not valid anymore since the completion event
// might be queued in the io service
if (complete && !piece_failed)
{
disk_io_job ret = m_ses.m_disk_thread.find_job(
&t->filesystem(), -1, i->index);
TORRENT_ASSERT(ret.action == disk_io_job::hash || ret.action == disk_io_job::write);
TORRENT_ASSERT(ret.piece == i->index);
}
*/
}
}
// extremely expensive invariant check
/*
if (!t->is_seed())
{
piece_picker& p = t->picker();
const std::vector<piece_picker::downloading_piece>& dlq = p.get_download_queue();
const int blocks_per_piece = static_cast<int>(
t->torrent_file().piece_length() / t->block_size());
for (std::vector<piece_picker::downloading_piece>::const_iterator i =
dlq.begin(); i != dlq.end(); ++i)
{
for (int j = 0; j < blocks_per_piece; ++j)
{
if (std::find(m_request_queue.begin(), m_request_queue.end()
, piece_block(i->index, j)) != m_request_queue.end()
||
std::find(m_download_queue.begin(), m_download_queue.end()
, piece_block(i->index, j)) != m_download_queue.end())
{
TORRENT_ASSERT(i->info[j].peer == m_remote);
}
else
{
TORRENT_ASSERT(i->info[j].peer != m_remote || i->info[j].finished);
}
}
}
}
*/
}
#endif
peer_connection::peer_speed_t peer_connection::peer_speed()
{
shared_ptr<torrent> t = m_torrent.lock();
TORRENT_ASSERT(t);
int download_rate = int(statistics().download_payload_rate());
int torrent_download_rate = int(t->statistics().download_payload_rate());
if (download_rate > 512 && download_rate > torrent_download_rate / 16)
m_speed = fast;
else if (download_rate > 4096 && download_rate > torrent_download_rate / 64)
m_speed = medium;
else if (download_rate < torrent_download_rate / 15 && m_speed == fast)
m_speed = medium;
else
m_speed = slow;
return m_speed;
}
void peer_connection::keep_alive()
{
#ifdef TORRENT_EXPENSIVE_INVARIANT_CHECKS
INVARIANT_CHECK;
#endif
time_duration d;
d = time_now() - m_last_sent;
if (total_seconds(d) < m_timeout / 2) return;
if (m_connecting) return;
if (in_handshake()) return;
// if the last send has not completed yet, do not send a keep
// alive
if (m_channel_state[upload_channel] & peer_info::bw_network) return;
#ifdef TORRENT_VERBOSE_LOGGING
peer_log("==> KEEPALIVE");
#endif
m_last_sent = time_now();
write_keepalive();
}
bool peer_connection::is_seed() const
{
// if m_num_pieces == 0, we probably don't have the
// metadata yet.
boost::shared_ptr<torrent> t = m_torrent.lock();
return m_num_pieces == (int)m_have_piece.size() && m_num_pieces > 0 && t && t->valid_metadata();
}
void peer_connection::set_share_mode(bool u)
{
// if the peer is a seed, ignore share mode messages
if (is_seed()) return;
m_share_mode = u;
}
void peer_connection::set_upload_only(bool u)
{
// if the peer is a seed, don't allow setting
// upload_only to false
if (m_upload_only || is_seed()) return;
m_upload_only = u;
boost::shared_ptr<torrent> t = associated_torrent().lock();
t->get_policy().set_seed(m_peer_info, u);
disconnect_if_redundant();
}
}