premiere-libtorrent/include/libtorrent/session_settings.hpp

/*

Copyright (c) 2003-2016, Arvid Norberg
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#ifndef TORRENT_SESSION_SETTINGS_HPP_INCLUDED
#define TORRENT_SESSION_SETTINGS_HPP_INCLUDED

#include "libtorrent/version.hpp"
#include "libtorrent/config.hpp"
#include "libtorrent/settings_pack.hpp"
#include "libtorrent/aux_/proxy_settings.hpp"

#include <cstdint>
#include <string>
#include <vector>
#include <utility>

namespace libtorrent
{

#ifndef TORRENT_NO_DEPRECATE

	using aux::proxy_settings;

	// This holds most of the session-wide settings in libtorrent. Pass this
	// to session::set_settings() to change the settings, initialize it from
	// session::get_settings() to get the current settings.
	struct TORRENT_EXPORT session_settings
	{
		// initializes the session_settings to the default settings.
		session_settings(std::string const& user_agent = "libtorrent/"
			LIBTORRENT_VERSION);
		~session_settings();
#if __cplusplus >= 201103L
		session_settings(session_settings const&) = default;
		session_settings& operator=(session_settings const&) = default;
#endif

		// automatically set to the libtorrent version you're using in order to
		// be forward binary compatible. This field should not be changed.
		int version;

		// the client identification to the tracker. The recommended format of
		// this string is: "ClientName/ClientVersion
		// libtorrent/libtorrentVersion". This name will not only be used when
		// making HTTP requests, but also when sending extended headers to peers
		// that support that extension.
		std::string user_agent;

		// the number of seconds the tracker connection will wait from when it
		// sent the request until it considers the tracker to have timed-out.
		// Default value is 60 seconds.
		int tracker_completion_timeout;

		// the number of seconds to wait to receive any data from the tracker. If
		// no data is received for this number of seconds, the tracker will be
		// considered as having timed out. If a tracker is down, this is the kind
		// of timeout that will occur. The default value is 20 seconds.
		int tracker_receive_timeout;

		// the time to wait when sending a stopped message before considering a
		// tracker to have timed out. this is usually shorter, to make the client
		// quit faster
		//
		// This is given in seconds. Default is 10 seconds.
		int stop_tracker_timeout;

		// the maximum number of bytes in a tracker response. If a response size
		// passes this number it will be rejected and the connection will be
		// closed. On gzipped responses this size is measured on the uncompressed
		// data. So, if you get 20 bytes of gzip response that'll expand to 2
		// megs, it will be interrupted before the entire response has been
		// uncompressed (given your limit is lower than 2 megs). Default limit is
		// 1 megabyte.
		int tracker_maximum_response_length;

		// controls the number of seconds from a request is sent until it times
		// out if no piece response is returned.
		int piece_timeout;

		// the number of seconds one block (16kB) is expected to be received
		// within. If it's not, the block is requested from a different peer
		int request_timeout;

		// the length of the request queue given in the number of seconds it
		// should take for the other end to send all the pieces. i.e. the actual
		// number of requests depends on the download rate and this number.
		int request_queue_time;

		// the number of outstanding block requests a peer is allowed to queue up
		// in the client. If a peer sends more requests than this (before the
		// first one has been sent) the last request will be dropped. the higher
		// this is, the faster upload speeds the client can get to a single peer.
		int max_allowed_in_request_queue;

		// the maximum number of outstanding requests to send to a peer. This
		// limit takes precedence over request_queue_time. i.e. no matter the
		// download speed, the number of outstanding requests will never exceed
		// this limit.
		int max_out_request_queue;

		// if a whole piece can be downloaded in this number of seconds, or less,
		// the peer_connection will prefer to request whole pieces at a time from
		// this peer. The benefit of this is to better utilize disk caches by
		// doing localized accesses and also to make it easier to identify bad
		// peers if a piece fails the hash check.
		int whole_pieces_threshold;

		// the number of seconds to wait for any activity on the peer wire before
		// closing the connection due to time out. This defaults to 120 seconds,
		// since that's what's specified in the protocol specification. After
		// half the time out, a keep alive message is sent.
		int peer_timeout;

		// same as peer_timeout, but only applies to url-seeds. this is usually
		// set lower, because web servers are expected to be more reliable. This
		// value defaults to 20 seconds.
		int urlseed_timeout;

		// controls the pipelining with the web server. When using persistent
		// connections to HTTP 1.1 servers, the client is allowed to send more
		// requests before the first response is received. This number controls
		// the number of outstanding requests to use with url-seeds. Default is
		// 5.
		int urlseed_pipeline_size;

		// time to wait until a new retry takes place
		int urlseed_wait_retry;

		// sets the upper limit on the total number of files this session will
		// keep open. The reason why files are left open at all is that some anti
		// virus software hooks on every file close, and scans the file for
		// viruses. deferring the closing of the files will be the difference
		// between a usable system and a completely hogged down system. Most
		// operating systems also has a limit on the total number of file
		// descriptors a process may have open. It is usually a good idea to find
		// this limit and set the number of connections and the number of files
		// limits so their sum is slightly below it.
		int file_pool_size;

		// determines if connections from the same IP address as existing
		// connections should be rejected or not. Multiple connections from the
		// same IP address is not allowed by default, to prevent abusive behavior
		// by peers. It may be useful to allow such connections in cases where
		// simulations are run on the same machine, and all peers in a swarm has
		// the same IP address.
		bool allow_multiple_connections_per_ip;

		// the maximum times we try to connect to a peer before stop connecting
		// again. If a peer succeeds, its failcounter is reset. If a peer is
		// retrieved from a peer source (other than DHT) the failcount is
		// decremented by one, allowing another try.
		int max_failcount;

		// the number of seconds to wait to reconnect to a peer. this time is
		// multiplied with the failcount.
		int min_reconnect_time;

		// the number of seconds to wait after a connection attempt is initiated
		// to a peer until it is considered as having timed out. The default is
		// 10 seconds. This setting is especially important in case the number of
		// half-open connections are limited, since stale half-open connection
		// may delay the connection of other peers considerably.
		int peer_connect_timeout;

#ifndef TORRENT_NO_DEPRECATE
		// deprecated, use set_peer_class_filter() instead
		// if set to true, upload, download and unchoke limits
		// are ignored for peers on the local network.
		bool ignore_limits_on_local_network;
#endif

		// the number of connection attempts that are made per second. If a
		// number < 0 is specified, it will default to 200 connections per
		// second. If 0 is specified, it means don't make outgoing connections at
		// all.
		int connection_speed;

		// if this is set to true, have messages will be sent to peers that
		// already have the piece. This is typically not necessary, but it might
		// be necessary for collecting statistics in some cases. Default is
		// false.
		bool send_redundant_have;

		// prevents outgoing bitfields from being full. If the client is seed, a
		// few bits will be set to 0, and later filled in with have-messages.
		// This is an old attempt to prevent certain ISPs from stopping people
		// from seeding.
		bool lazy_bitfields;

		// if a peer is uninteresting and uninterested for longer than this
		// number of seconds, it will be disconnected. default is 10 minutes
		int inactivity_timeout;

		// the number of seconds between chokes/unchokes. On this interval, peers
		// are re-evaluated for being choked/unchoked. This is defined as 30
		// seconds in the protocol, and it should be significantly longer than
		// what it takes for TCP to ramp up to it's max rate.
		int unchoke_interval;

		// the number of seconds between each *optimistic* unchoke. On this
		// timer, the currently optimistically unchoked peer will change.
		int optimistic_unchoke_interval;

		// the ip address passed along to trackers as the ``&ip=`` parameter. If
		// left as the default (an empty string), that parameter is omitted. Most
		// trackers ignore this argument. This is here for completeness for
		// edge-cases where it may be useful.
		std::string announce_ip;

		// the number of peers we want from each tracker request. It defines what
		// is sent as the ``&num_want=`` parameter to the tracker. Stopped
		// messages always send num_want=0. This setting control what to say in
		// the case where we actually want peers.
		int num_want;

		// specifies the number of pieces we need before we switch to rarest
		// first picking. This defaults to 4, which means the 4 first pieces in
		// any torrent are picked at random, the following pieces are picked in
		// rarest first order.
		int initial_picker_threshold;

		// the number of allowed pieces to send to choked peers that supports the
		// fast extensions
		int allowed_fast_set_size;

		// options for session_settings::suggest_mode.
		enum suggest_mode_t
		{
			// the default. will not send out suggest messages.
			no_piece_suggestions = 0,

			// send out suggest messages for the most recent pieces that are in
			// the read cache.
			suggest_read_cache = 1
		};

		// this determines which pieces will be suggested to peers suggest read
		// cache will make libtorrent suggest pieces that are fresh in the disk
		// read cache, to potentially lower disk access and increase the cache
		// hit ratio
		//
		// for options, see suggest_mode_t.
		int suggest_mode;

		// the maximum number of bytes a connection may have pending in the disk
		// write queue before its download rate is being throttled. This prevents
		// fast downloads to slow medias to allocate more memory indefinitely.
		// This should be set to at least 16 kB to not completely disrupt normal
		// downloads. If it's set to 0, you will be starving the disk thread and
		// nothing will be written to disk. this is a per session setting.
		//
		// When this limit is reached, the peer connections will stop reading
		// data from their sockets, until the disk thread catches up. Setting
		// this too low will severely limit your download rate.
		int max_queued_disk_bytes;

#ifndef TORRENT_NO_DEPRECATE
		// not used anymore
		int max_queued_disk_bytes_low_watermark;
#endif

		// the number of seconds to wait for a handshake response from a peer. If
		// no response is received within this time, the peer is disconnected.
		int handshake_timeout;

		// determines how the DHT is used. If this is true, the DHT will only be
		// used for torrents where all trackers in its tracker list has failed.
		// Either by an explicit error message or a time out. This is false by
		// default, which means the DHT is used by default regardless of if the
		// trackers fail or not.
		bool use_dht_as_fallback;

		// determines whether or not the torrent's piece hashes are kept in
		// memory after the torrent becomes a seed or not. If it is set to
		// ``true`` the hashes are freed once the torrent is a seed (they're not
		// needed anymore since the torrent won't download anything more). If
		// it's set to false they are not freed. If they are freed, the
		// torrent_info returned by get_torrent_info() will return an object that
		// may be incomplete, that cannot be passed back to async_add_torrent()
		// and add_torrent() for instance.
		bool free_torrent_hashes;

		// indicates whether or not the UPnP implementation should ignore any
		// broadcast response from a device whose address is not the configured
		// router for this machine. i.e. it's a way to not talk to other people's
		// routers by mistake.
		bool upnp_ignore_nonrouters;

		// This is the minimum send buffer target size (send buffer includes
		// bytes pending being read from disk). For good and snappy seeding
		// performance, set this fairly high, to at least fit a few blocks. This
		// is essentially the initial window size which will determine how fast
		// we can ramp up the send rate
		int send_buffer_low_watermark;

		// the upper limit of the send buffer low-watermark.
		//
		// if the send buffer has fewer bytes than this, we'll read another 16kB
		// block onto it. If set too small, upload rate capacity will suffer. If
		// set too high, memory will be wasted. The actual watermark may be lower
		// than this in case the upload rate is low, this is the upper limit.
		int send_buffer_watermark;

		// the current upload rate to a peer is multiplied by this factor to get
		// the send buffer watermark. The factor is specified as a percentage.
		// i.e. 50 indicates a factor of 0.5.
		//
		// This product is clamped to the send_buffer_watermark setting to not
		// exceed the max. For high speed upload, this should be set to a greater
		// value than 100. The default is 50.
		//
		// For high capacity connections, setting this higher can improve upload
		// performance and disk throughput. Setting it too high may waste RAM and
		// create a bias towards read jobs over write jobs.
		int send_buffer_watermark_factor;

		// the different choking algorithms available. Set
		// session_settings::choking_algorithm to one of these
		enum choking_algorithm_t
		{
			// the traditional choker with a fixed number of unchoke slots, as
			// specified by session::set_max_uploads()..
			fixed_slots_choker = 0,

#ifndef TORRENT_NO_DEPRECATE
			// opens at least the number of slots as specified by
			// session::set_max_uploads() but opens up more slots if the upload
			// capacity is not saturated. This unchoker will work just like the
			// ``fixed_slot_choker`` if there's no global upload rate limit set.
			auto_expand_choker = 1,
#endif

			// opens up unchoke slots based on the upload rate achieved to peers.
			// The more slots that are opened, the marginal upload rate required
			// to open up another slot increases.
			rate_based_choker = 1,

			// attempts to optimize download rate by finding the reciprocation
			// rate of each peer individually and prefers peers that gives the
			// highest *return on investment*. It still allocates all upload
			// capacity, but shuffles it around to the best peers first. For this
			// choker to be efficient, you need to set a global upload rate limit
			// session_settings::upload_rate_limit. For more information about
			// this choker, see the paper_.
			// 
			// .. _paper: http://bittyrant.cs.washington.edu/#papers
			bittyrant_choker  = 2
		};

		// specifies which algorithm to use to determine which peers to unchoke.
		// This setting replaces the deprecated settings ``auto_upload_slots``
		// and ``auto_upload_slots_rate_based``. For options, see
		// choking_algorithm_t.
		int choking_algorithm;

		// the different choking algorithms available when seeding. Set
		// session_settings::seed_choking_algorithm to one of these
		enum seed_choking_algorithm_t
		{
			// round-robins the peers that are unchoked when seeding. This
			// distributes the upload bandwidht uniformly and fairly. It minimizes
			// the ability for a peer to download everything without
			// redistributing it.
			round_robin,

			// unchokes the peers we can send to the fastest. This might be a bit
			// more reliable in utilizing all available capacity.
			fastest_upload,

			// prioritizes peers who have just started or are just about to finish
			// the download. The intention is to force peers in the middle of the
			// download to trade with each other.
			anti_leech
		};

		// controls the seeding unchoke behavior. For options, see
		// seed_choking_algorithm_t.
		int seed_choking_algorithm;

		// specifies if parole mode should be used. Parole mode means that peers
		// that participate in pieces that fail the hash check are put in a mode
		// where they are only allowed to download whole pieces. If the whole
		// piece a peer in parole mode fails the hash check, it is banned. If a
		// peer participates in a piece that passes the hash check, it is taken
		// out of parole mode.
		bool use_parole_mode;

		// the disk write and read  cache. It is specified in units of 16 KiB
		// blocks. Buffers that are part of a peer's send or receive buffer also
		// count against this limit. Send and receive buffers will never be
		// denied to be allocated, but they will cause the actual cached blocks
		// to be flushed or evicted. If this is set to -1, the cache size is
		// automatically set to the amount of physical RAM available in the
		// machine divided by 8. If the amount of physical RAM cannot be
		// determined, it's set to 1024 (= 16 MiB).
		// 
		// Disk buffers are allocated using a pool allocator, the number of
		// blocks that are allocated at a time when the pool needs to grow can be
		// specified in ``cache_buffer_chunk_size``. This defaults to 16 blocks.
		// Lower numbers saves memory at the expense of more heap allocations. It
		// must be at least 1.
		int cache_size;

		// this is the number of disk buffer blocks (16 kiB) that should be
		// allocated at a time. It must be at least 1. Lower number saves memory
		// at the expense of more heap allocations
		// setting this to zero means 'automatic', i.e. proportional
		// to the total disk cache size
		int cache_buffer_chunk_size;

		// the number of seconds a write cache entry sits idle in the cache
		// before it's forcefully flushed to disk.
		int cache_expiry;

		// when set to true (default), the disk cache is also used to cache
		// pieces read from disk. Blocks for writing pieces takes presedence.
		bool use_read_cache;
		bool use_write_cache;

		// this will make the disk cache never flush a write
		// piece if it would cause is to have to re-read it
		// once we want to calculate the piece hash
		bool dont_flush_write_cache;

		// the buffer modes to use for reading and writing. Set
		// session_settings::disk_io_read_mode and disk_io_write_mode to one of
		// these.
		enum io_buffer_mode_t
		{
			// This is the default and files are opened normally, with the OS
			// caching reads and writes.
			enable_os_cache = 0,
			// This will open files in unbuffered mode for files where every read
			// and write would be sector aligned. Using aligned disk offsets is a
			// requirement on some operating systems.
			disable_os_cache_for_aligned_files = 1,
			// This opens all files in unbuffered mode (if allowed by the
			// operating system). Linux and Windows, for instance, require disk
			// offsets to be sector aligned, and in those cases, this option is
			// the same as ``disable_os_caches_for_aligned_files``.
			disable_os_cache = 2
		};

		// determines how files are opened when they're in read only mode versus
		// read and write mode. For options, see io_buffer_mode_t.
		//
		// One reason to disable caching is that it may help the operating system
		// from growing its file cache indefinitely. Since some OSes only allow
		// aligned files to be opened in unbuffered mode, It is recommended to
		// make the largest file in a torrent the first file (with offset 0) or
		// use pad files to align all files to piece boundaries.
		int disk_io_write_mode;
		int disk_io_read_mode;

		// allocate separate, contiguous, buffers for read and write calls. Only
		// used where writev/readv cannot be used will use more RAM but may
		// improve performance
		bool coalesce_reads;
		bool coalesce_writes;

		// if set to something other than (0, 0) is a range of ports used to bind
		// outgoing sockets to. This may be useful for users whose router allows
		// them to assign QoS classes to traffic based on its local port. It is a
		// range instead of a single port because of the problems with failing to
		// reconnect to peers if a previous socket to that peer and port is in
		// ``TIME_WAIT`` state.
		// 
		//.. warning::
		//	setting outgoing ports will limit the ability to keep multiple
		//	connections to the same client, even for different torrents. It is not
		//	recommended to change this setting. Its main purpose is to use as an
		//	escape hatch for cheap routers with QoS capability but can only
		//	classify flows based on port numbers.
		int outgoing_port;
		int num_outgoing_ports;

		// determines the TOS byte set in the IP header of every packet sent to
		// peers (including web seeds). The default value for this is ``0x0`` (no
		// marking). One potentially useful TOS mark is ``0x20``, this represents
		// the *QBone scavenger service*. For more details, see QBSS_.
		// 
		// .. _`QBSS`: http://qbone.internet2.edu/qbss/
		char peer_tos;

		// for auto managed torrents, these are the limits they are subject to.
		// If there are too many torrents some of the auto managed ones will be
		// paused until some slots free up.
		// 
		// ``active_dht_limit`` and ``active_tracker_limit`` limits the number of
		// torrents that will be active on the DHT and their tracker. If the
		// active limit is set higher than these numbers, some torrents will be
		// "active" in the sense that they will accept incoming connections, but
		// not announce on the DHT or their trackers.
		//
		// ``active_lsd_limit`` is the max number of torrents to announce to the
		// local network over the local service discovery protocol. By default
		// this is 80, which is no more than one announce every 5 seconds
		// (assuming the default announce interval of 5 minutes).
		// 
		// ``active_limit`` is a hard limit on the number of active torrents.
		// This applies even to slow torrents.
		// 
		// You can have more torrents *active*, even though they are not
		// announced to the DHT, lsd or their tracker. If some peer knows about
		// you for any reason and tries to connect, it will still be accepted,
		// unless the torrent is paused, which means it won't accept any
		// connections.
		//
		// ``active_downloads`` and ``active_seeds`` controls how many active
		// seeding and downloading torrents the queuing mechanism allows. The
		// target number of active torrents is ``min(active_downloads +
		// active_seeds, active_limit)``. ``active_downloads`` and
		// ``active_seeds`` are upper limits on the number of downloading
		// torrents and seeding torrents respectively. Setting the value to -1
		// means unlimited.
		// 
		// For example if there are 10 seeding torrents and 10 downloading
		// torrents, and ``active_downloads`` is 4 and ``active_seeds`` is 4,
		// there will be 4 seeds active and 4 downloading torrents. If the
		// settings are ``active_downloads`` = 2 and ``active_seeds`` = 4, then
		// there will be 2 downloading torrents and 4 seeding torrents active.
		// Torrents that are not auto managed are also counted against these
		// limits. If there are non-auto managed torrents that use up all the
		// slots, no auto managed torrent will be activated.
		int active_downloads;
		int active_seeds;
		int active_dht_limit;
		int active_tracker_limit;
		int active_lsd_limit;
		int active_limit;

		// prefer seeding torrents when determining which torrents to give active
		// slots to, the default is false which gives preference to downloading
		// torrents
		bool auto_manage_prefer_seeds;

		// if true, torrents without any payload transfers are not subject to the
		// ``active_seeds`` and ``active_downloads`` limits. This is intended to
		// make it more likely to utilize all available bandwidth, and avoid
		// having torrents that don't transfer anything block the active slots.
		bool dont_count_slow_torrents;

		// the number of seconds in between recalculating which torrents to
		// activate and which ones to queue
		int auto_manage_interval;

		// when a seeding torrent reaches either the share ratio (bytes up /
		// bytes down) or the seed time ratio (seconds as seed / seconds as
		// downloader) or the seed time limit (seconds as seed) it is considered
		// done, and it will leave room for other torrents the default value for
		// share ratio is 2 the default seed time ratio is 7, because that's a
		// common asymmetry ratio on connections. these are specified as
		// percentages
		//
		//.. note::
		//	This is an out-dated option that doesn't make much sense. It will be
		//	removed in future versions of libtorrent
		float share_ratio_limit;

		// the seeding time / downloading time ratio limit for considering a
		// seeding torrent to have met the seed limit criteria. See queuing_.
		float seed_time_ratio_limit;

		// seed time limit is specified in seconds
		//
		// the limit on the time a torrent has been an active seed (specified in
		// seconds) before it is considered having met the seed limit criteria.
		// See queuing_.
		int seed_time_limit;

		// controls a feature where libtorrent periodically can disconnect the
		// least useful peers in the hope of connecting to better ones.
		// ``peer_turnover_interval`` controls the interval of this optimistic
		// disconnect. It defaults to every 5 minutes, and is specified in
		// seconds.
		// 
		// ``peer_turnover`` Is the fraction of the peers that are disconnected.
		// This is a float where 1.f represents all peers an 0 represents no
		// peers. It defaults to 4% (i.e. 0.04f)
		//
		// ``peer_turnover_cutoff`` is the cut off trigger for optimistic
		// unchokes. If a torrent has more than this fraction of its connection
		// limit, the optimistic unchoke is triggered. This defaults to 90% (i.e.
		// 0.9f).
		int peer_turnover_interval;

		// the percentage of peers to disconnect every
		// turnover interval (if we're at the peer limit)
		// defaults to 4%
		// this is specified in percent
		float peer_turnover;

		// when we are connected to more than
		// limit * peer_turnover_cutoff peers
		// disconnect peer_turnover fraction
		// of the peers. It is specified in percent
		float peer_turnover_cutoff;

		// specifies whether libtorrent should close connections where both ends
		// have no utility in keeping the connection open. For instance if both
		// ends have completed their downloads, there's no point in keeping it
		// open. This defaults to ``true``.
		bool close_redundant_connections;

		// the number of seconds between scrapes of queued torrents (auto managed
		// and paused torrents). Auto managed torrents that are paused, are
		// scraped regularly in order to keep track of their downloader/seed
		// ratio. This ratio is used to determine which torrents to seed and
		// which to pause.
		int auto_scrape_interval;

		// the minimum number of seconds between any automatic scrape (regardless
		// of torrent). In case there are a large number of paused auto managed
		// torrents, this puts a limit on how often a scrape request is sent.
		int auto_scrape_min_interval;

		// the maximum number of peers in the list of known peers. These peers
		// are not necessarily connected, so this number should be much greater
		// than the maximum number of connected peers. Peers are evicted from the
		// cache when the list grows passed 90% of this limit, and once the size
		// hits the limit, peers are no longer added to the list. If this limit
		// is set to 0, there is no limit on how many peers we'll keep in the
		// peer list.
		int max_peerlist_size;

		// the max peer list size used for torrents that are paused. This default
		// to the same as ``max_peerlist_size``, but can be used to save memory
		// for paused torrents, since it's not as important for them to keep a
		// large peer list.
		int max_paused_peerlist_size;

		// the minimum allowed announce interval for a tracker. This is specified
		// in seconds, defaults to 5 minutes and is used as a sanity check on
		// what is returned from a tracker. It mitigates hammering misconfigured
		// trackers.
		int min_announce_interval;

		// If true, partial pieces are picked before pieces that are more rare.
		// If false, rare pieces are always prioritized, unless the number of
		// partial pieces is growing out of proportion.
		bool prioritize_partial_pieces;

		// the number of seconds a torrent is considered active after it was
		// started, regardless of upload and download speed. This is so that
		// newly started torrents are not considered inactive until they have a
		// fair chance to start downloading.
		int auto_manage_startup;

		// if set to true, the estimated TCP/IP overhead is drained from the rate
		// limiters, to avoid exceeding the limits with the total traffic
		bool rate_limit_ip_overhead;

		// controls how multi tracker torrents are treated. If this is set to
		// true, all trackers in the same tier are announced to in parallel. If
		// all trackers in tier 0 fails, all trackers in tier 1 are announced as
		// well. If it's set to false, the behavior is as defined by the multi
		// tracker specification. It defaults to false, which is the same
		// behavior previous versions of libtorrent has had as well.
		bool announce_to_all_trackers;

		// controls how multi tracker torrents are treated. When this is set to
		// true, one tracker from each tier is announced to. This is the uTorrent
		// behavior. This is false by default in order to comply with the
		// multi-tracker specification.
		bool announce_to_all_tiers;

		// true by default. It means that trackers may be rearranged in a way
		// that udp trackers are always tried before http trackers for the same
		// hostname. Setting this to fails means that the trackers' tier is
		// respected and there's no preference of one protocol over another.
		bool prefer_udp_trackers;

		// when this is set to true, a piece has to have been forwarded to a
		// third peer before another one is handed out. This is the traditional
		// definition of super seeding.
		bool strict_super_seeding;

		// the number of pieces to send to a peer, when seeding, before rotating
		// in another peer to the unchoke set. It defaults to 3 pieces, which
		// means that when seeding, any peer we've sent more than this number of
		// pieces to will be unchoked in favour of a choked peer.
		int seeding_piece_quota;

		// is a limit of the number of *sparse regions* in a torrent. A sparse
		// region is defined as a hole of pieces we have not yet downloaded, in
		// between pieces that have been downloaded. This is used as a hack for
		// windows vista which has a bug where you cannot write files with more
		// than a certain number of sparse regions. This limit is not hard, it
		// will be exceeded. Once it's exceeded, pieces that will maintain or
		// decrease the number of sparse regions are prioritized. To disable this
		// functionality, set this to 0. It defaults to 0 on all platforms except
		// windows.
		int max_sparse_regions;

		// if lock disk cache is set to true the disk cache that's in use, will
		// be locked in physical memory, preventing it from being swapped out.
		bool lock_disk_cache;

		// the number of piece requests we will reject in a row while a peer is
		// choked before the peer is considered abusive and is disconnected.
		int max_rejects;

		// specifies the buffer sizes set on peer sockets. 0 (which is the
		// default) means the OS default (i.e. don't change the buffer sizes).
		// The socket buffer sizes are changed using setsockopt() with
		// SOL_SOCKET/SO_RCVBUF and SO_SNDBUFFER.
		int recv_socket_buffer_size;
		int send_socket_buffer_size;

		// chooses between two ways of reading back piece data from disk when its
		// complete and needs to be verified against the piece hash. This happens
		// if some blocks were flushed to the disk out of order. Everything that
		// is flushed in order is hashed as it goes along. Optimizing for speed
		// will allocate space to fit all the remaining, unhashed, part of
		// the piece, reads the data into it in a single call and hashes it. This
		// is the default. If ``optimizing_hashing_for_speed`` is false, a single
		// block will be allocated (16 kB), and the unhashed parts of the piece
		// are read, one at a time, and hashed in this single block. This is
		// appropriate on systems that are memory constrained.
		bool optimize_hashing_for_speed;

		// the number of milliseconds to sleep
		// in between disk read operations when checking torrents. This defaults
		// to 0, but can be set to higher numbers to slow down the rate at which
		// data is read from the disk while checking. This may be useful for
		// background tasks that doesn't matter if they take a bit longer, as long
		// as they leave disk I/O time for other processes.
		int file_checks_delay_per_block;

		// the disk cache algorithms available. Set
		// session_settings::disk_cache_algorithm to one of these.
		enum disk_cache_algo_t
		{
			// This flushes the entire piece, in the write cache, that was least
			// recently written to.
			lru,

			// will flush the largest sequences of contiguous blocks from the
			// write cache, regardless of the piece's last use time.
			largest_contiguous,

			// will prioritize flushing blocks that will avoid having to read them
			// back in to verify the hash of the piece once it's done. This is
			// especially useful for high throughput setups, where reading from
			// the disk is especially expensive.
			avoid_readback
		};

		// tells the disk I/O thread which cache flush algorithm to use.
		// This is specified by the disk_cache_algo_t enum.
		disk_cache_algo_t disk_cache_algorithm;

		// the number of blocks to read into the read cache when a read cache
		// miss occurs. Setting this to 0 is essentially the same thing as
		// disabling read cache. The number of blocks read into the read cache is
		// always capped by the piece boundary.
		// 
		// When a piece in the write cache has ``write_cache_line_size``
		// contiguous blocks in it, they will be flushed. Setting this to 1
		// effectively disables the write cache.
		int read_cache_line_size;

		// whenever a contiguous range of this many blocks is found in the write
		// cache, it is flushed immediately
		int write_cache_line_size;

		// the number of seconds from a disk write errors occur on a torrent
		// until libtorrent will take it out of the upload mode, to test if the
		// error condition has been fixed.
		// 
		// libtorrent will only do this automatically for auto managed torrents.
		// 
		// You can explicitly take a torrent out of upload only mode using
		// set_upload_mode().
		int optimistic_disk_retry;

		// controls if downloaded pieces are verified against the piece hashes in
		// the torrent file or not. The default is false, i.e. to verify all
		// downloaded data. It may be useful to turn this off for performance
		// profiling and simulation scenarios. Do not disable the hash check for
		// regular bittorrent clients.
		bool disable_hash_checks;

		// if this is true, disk read operations are sorted by their physical
		// offset on disk before issued to the operating system. This is useful
		// if async I/O is not supported. It defaults to true if async I/O is not
		// supported and fals otherwise. disk I/O operations are likely to be
		// reordered regardless of this setting when async I/O is supported by
		// the OS.
		bool allow_reordered_disk_operations;

		// if this is true, i2p torrents are allowed to also get peers from other
		// sources than the tracker, and connect to regular IPs, not providing
		// any anonymization. This may be useful if the user is not interested in
		// the anonymization of i2p, but still wants to be able to connect to i2p
		// peers.
		bool allow_i2p_mixed;

		// the max number of suggested piece indices received from a peer that's
		// remembered. If a peer floods suggest messages, this limit prevents
		// libtorrent from using too much RAM. It defaults to 10.
		int max_suggest_pieces;

		// If set to true (it defaults to false), piece requests that have been
		// skipped enough times when piece messages are received, will be
		// considered lost. Requests are considered skipped when the returned
		// piece messages are re-ordered compared to the order of the requests.
		// This was an attempt to get out of dead-locks caused by BitComet peers
		// silently ignoring some requests. It may cause problems at high rates,
		// and high level of reordering in the uploading peer, that's why it's
		// disabled by default.
		bool drop_skipped_requests;

		// determines if the disk I/O should use a normal
		// or low priority policy. This defaults to true, which means that
		// it's low priority by default. Other processes doing disk I/O will
		// normally take priority in this mode. This is meant to improve the
		// overall responsiveness of the system while downloading in the
		// background. For high-performance server setups, this might not
		// be desirable.
		bool low_prio_disk;

		// the time between local
		// network announces for a torrent. By default, when local service
		// discovery is enabled a torrent announces itself every 5 minutes.
		// This interval is specified in seconds.
		int local_service_announce_interval;

		// the number of seconds between announcing
		// torrents to the distributed hash table (DHT). This is specified to
		// be 15 minutes which is its default.
		int dht_announce_interval;

		// the number of seconds libtorrent
		// will keep UDP tracker connection tokens around for. This is specified
		// to be 60 seconds, and defaults to that. The higher this value is, the
		// fewer packets have to be sent to the UDP tracker. In order for higher
		// values to work, the tracker needs to be configured to match the
		// expiration time for tokens.
		int udp_tracker_token_expiry;

		// if this is set to true, read cache blocks
		// that are hit by peer read requests are removed from the disk cache
		// to free up more space. This is useful if you don't expect the disk
		// cache to create any cache hits from other peers than the one who
		// triggered the cache line to be read into the cache in the first place.
		bool volatile_read_cache;

		// enables the disk cache to adjust the size
		// of a cache line generated by peers to depend on the upload rate
		// you are sending to that peer. The intention is to optimize the RAM
		// usage of the cache, to read ahead further for peers that you're
		// sending faster to.
		bool guided_read_cache;

		// the minimum number of seconds any read cache line is kept in the
		// cache. This defaults to one second but may be greater if
		// ``guided_read_cache`` is enabled. Having a lower bound on the time a
		// cache line stays in the cache is an attempt to avoid swapping the same
		// pieces in and out of the cache in case there is a shortage of spare
		// cache space.
		int default_cache_min_age;

		// the number of optimistic unchoke slots to use. It defaults to 0, which
		// means automatic. Having a higher number of optimistic unchoke slots
		// mean you will find the good peers faster but with the trade-off to use
		// up more bandwidth. When this is set to 0, libtorrent opens up 20% of
		// your allowed upload slots as optimistic unchoke slots.
		int num_optimistic_unchoke_slots;

		// this is a linux-only option and passes in the ``O_NOATIME`` to
		// ``open()`` when opening files. This may lead to some disk performance
		// improvements.
		bool no_atime_storage;

		// the assumed reciprocation rate from peers when using the BitTyrant
		// choker. This defaults to 14 kiB/s. If set too high, you will
		// over-estimate your peers and be more altruistic while finding the true
		// reciprocation rate, if it's set too low, you'll be too stingy and
		// waste finding the true reciprocation rate.
		int default_est_reciprocation_rate;

		// specifies how many percent the estimated reciprocation rate should be
		// increased by each unchoke interval a peer is still choking us back.
		// This defaults to 20%. This only applies to the BitTyrant choker.
		int increase_est_reciprocation_rate;

		// specifies how many percent the estimated reciprocation rate should be
		// decreased by each unchoke interval a peer unchokes us. This default to
		// 3%. This only applies to the BitTyrant choker.
		int decrease_est_reciprocation_rate;

		// defaults to false. If a torrent has been paused by the auto managed
		// feature in libtorrent, i.e. the torrent is paused and auto managed,
		// this feature affects whether or not it is automatically started on an
		// incoming connection. The main reason to queue torrents, is not to make
		// them unavailable, but to save on the overhead of announcing to the
		// trackers, the DHT and to avoid spreading one's unchoke slots too thin.
		// If a peer managed to find us, even though we're no in the torrent
		// anymore, this setting can make us start the torrent and serve it.
		bool incoming_starts_queued_torrents;

		// when set to true, the downloaded counter sent to trackers will include
		// the actual number of payload bytes downloaded including redundant
		// bytes. If set to false, it will not include any redundancy bytes
		bool report_true_downloaded;

		// defaults to true, and controls when a block may be requested twice. If
		// this is ``true``, a block may only be requested twice when there's ay
		// least one request to every piece that's left to download in the
		// torrent. This may slow down progress on some pieces sometimes, but it
		// may also avoid downloading a lot of redundant bytes. If this is
		// ``false``, libtorrent attempts to use each peer connection to its max,
		// by always requesting something, even if it means requesting something
		// that has been requested from another peer already.
		bool strict_end_game_mode;

		// if set to true, the local peer discovery (or Local Service Discovery)
		// will not only use IP multicast, but also broadcast its messages. This
		// can be useful when running on networks that don't support multicast.
		// Since broadcast messages might be expensive and disruptive on
		// networks, only every 8th announce uses broadcast.
		bool broadcast_lsd;

		// these all determines if libtorrent should attempt to make outgoing
		// connections of the specific type, or allow incoming connection. By
		// default all of them are enabled.
		bool enable_outgoing_utp;
		bool enable_incoming_utp;
		bool enable_outgoing_tcp;
		bool enable_incoming_tcp;

		// the max number of peers we accept from pex messages from a single peer.
		// this limits the number of concurrent peers any of our peers claims to
		// be connected to. If they claim to be connected to more than this, we'll
		// ignore any peer that exceeds this limit
		int max_pex_peers;

		// determines if the storage, when loading resume data files, should
		// verify that the file modification time with the timestamps in the
		// resume data. This defaults to false, which means timestamps are taken
		// into account, and resume data is less likely to accepted (torrents are
		// more likely to be fully checked when loaded). It might be useful to
		// set this to true if your network is faster than your disk, and it
		// would be faster to redownload potentially missed pieces than to go
		// through the whole storage to look for them.
		bool ignore_resume_timestamps;

		// determines if the storage should check the whole files when resume
		// data is incomplete or missing or whether it should simply assume we
		// don't have any of the data. By default, this is determined by the
		// existence of any of the files. By setting this setting to true, the
		// files won't be checked, but will go straight to download mode.
		bool no_recheck_incomplete_resume;

		// defaults to false. When set to true, the client tries to hide its
		// identity to a certain degree. The peer-ID will no longer include the
		// client's fingerprint. The user-agent will be reset to an empty string.
		// It will also try to not leak other identifying information, such as
		// your local listen port, your IP etc.
		// 
		// If you're using I2P, a VPN or a proxy, it might make sense to enable
		// anonymous mode.
		bool anonymous_mode;

		// disables any communication that's not going over a proxy. Enabling
		// this requires a proxy to be configured as well, see
		// ``set_proxy_settings``. The listen sockets are closed, and incoming
		// connections will only be accepted through a SOCKS5 or I2P proxy (if a
		// peer proxy is set up and is run on the same machine as the tracker
		// proxy). This setting also disabled peer country lookups, since those
		// are done via DNS lookups that aren't supported by proxies.
		bool force_proxy;

		// specifies the number of milliseconds between internal ticks. This is
		// the frequency with which bandwidth quota is distributed to peers. It
		// should not be more than one second (i.e. 1000 ms). Setting this to a
		// low value (around 100) means higher resolution bandwidth quota
		// distribution, setting it to a higher value saves CPU cycles.
		int tick_interval;

		// specifies whether downloads from web seeds is reported to the
		// tracker or not. Defaults to on
		bool report_web_seed_downloads;

		// specifies the target share ratio for share mode torrents. This
		// defaults to 3, meaning we'll try to upload 3 times as much as we
		// download. Setting this very high, will make it very conservative and
		// you might end up not downloading anything ever (and not affecting your
		// share ratio). It does not make any sense to set this any lower than 2.
		// For instance, if only 3 peers need to download the rarest piece, it's
		// impossible to download a single piece and upload it more than 3 times.
		// If the share_mode_target is set to more than 3, nothing is downloaded.
		int share_mode_target;

		// sets the session-global limits of upload and download rate limits, in
		// bytes per second. The local rates refer to peers on the local network.
		// By default peers on the local network are not rate limited.
		// 
		// These rate limits are only used for local peers (peers within the same
		// subnet as the client itself) and it is only used when
		// ``session_settings::ignore_limits_on_local_network`` is set to true
		// (which it is by default). These rate limits default to unthrottled,
		// but can be useful in case you want to treat local peers
		// preferentially, but not quite unthrottled.
		// 
		// A value of 0 means unlimited.
		int upload_rate_limit;
		int download_rate_limit;
		int local_upload_rate_limit;
		int local_download_rate_limit;

		// sets the rate limit on the DHT. This is specified in bytes per second
		// and defaults to 4000. For busy boxes with lots of torrents that
		// requires more DHT traffic, this should be raised.
		int dht_upload_rate_limit;

		// the max number of unchoked peers in the session. The number of unchoke
		// slots may be ignored depending on what ``choking_algorithm`` is set
		// to. A value of -1 means infinite.
		int unchoke_slots_limit;

		// sets the maximum number of half-open connections libtorrent will have
		// when connecting to peers. A half-open connection is one where
		// connect() has been called, but the connection still hasn't been
		// established (nor failed). Windows XP Service Pack 2 sets a default,
		// system wide, limit of the number of half-open connections to 10. So,
		// this limit can be used to work nicer together with other network
		// applications on that system. The default is to have no limit, and
		// passing -1 as the limit, means to have no limit. When limiting the
		// number of simultaneous connection attempts, peers will be put in a
		// queue waiting for their turn to get connected.
		int half_open_limit;

		// sets a global limit on the number of connections opened. The number of
		// connections is set to a hard minimum of at least two per torrent, so
		// if you set a too low connections limit, and open too many torrents,
		// the limit will not be met.
		int connections_limit;

		// the number of extra incoming connections allowed temporarily, in order
		// to support replacing peers
		int connections_slack;

		// the target delay for uTP sockets in milliseconds. A high value will
		// make uTP connections more aggressive and cause longer queues in the
		// upload bottleneck. It cannot be too low, since the noise in the
		// measurements would cause it to send too slow. The default is 50
		// milliseconds.
		int utp_target_delay;

		// the number of bytes the uTP congestion window can increase at the most
		// in one RTT. This defaults to 300 bytes. If this is set too high, the
		// congestion controller reacts too hard to noise and will not be stable,
		// if it's set too low, it will react slow to congestion and not back off
		// as fast.
		int utp_gain_factor;

		// the shortest allowed uTP socket timeout, specified in milliseconds.
		// This defaults to 500 milliseconds. The timeout depends on the RTT of
		// the connection, but is never smaller than this value. A connection
		// times out when every packet in a window is lost, or when a packet is
		// lost twice in a row (i.e. the resent packet is lost as well).
		// 
		// The shorter the timeout is, the faster the connection will recover
		// from this situation, assuming the RTT is low enough.
		int utp_min_timeout;

		// the number of SYN packets that are sent (and timed out) before
		// giving up and closing the socket.
		int utp_syn_resends;

		// the number of resent packets sent on a closed socket before giving up
		int utp_fin_resends;

		// the number of times a packet is sent (and lossed or timed out)
		// before giving up and closing the connection.
		int utp_num_resends;

		// the number of milliseconds of timeout for the initial SYN packet for
		// uTP connections. For each timed out packet (in a row), the timeout is
		// doubled.
		int utp_connect_timeout;

#ifndef TORRENT_NO_DEPRECATE
		// number of milliseconds of delaying ACKing packets the most
		int utp_delayed_ack;
#endif

		// controls if the uTP socket manager is allowed to increase the socket
		// buffer if a network interface with a large MTU is used (such as
		// loopback or ethernet jumbo frames). This defaults to true and might
		// improve uTP throughput. For RAM constrained systems, disabling this
		// typically saves around 30kB in user space and probably around 400kB in
		// kernel socket buffers (it adjusts the send and receive buffer size on
		// the kernel socket, both for IPv4 and IPv6).
		bool utp_dynamic_sock_buf;

		// controls how the congestion window is changed when a packet loss is
		// experienced. It's specified as a percentage multiplier for ``cwnd``.
		// By default it's set to 50 (i.e. cut in half). Do not change this value
		// unless you know what you're doing. Never set it higher than 100.
		int utp_loss_multiplier;

		// the options for session_settings::mixed_mode_algorithm.
		enum bandwidth_mixed_algo_t
		{
			// disables the mixed mode bandwidth balancing
			prefer_tcp = 0,

			// does not throttle uTP, throttles TCP to the same proportion
			// of throughput as there are TCP connections
			peer_proportional = 1
		};

		// determines how to treat TCP connections when there are uTP
		// connections. Since uTP is designed to yield to TCP, there's an
		// inherent problem when using swarms that have both TCP and uTP
		// connections. If nothing is done, uTP connections would often be
		// starved out for bandwidth by the TCP connections. This mode is
		// ``prefer_tcp``. The ``peer_proportional`` mode simply looks at the
		// current throughput and rate limits all TCP connections to their
		// proportional share based on how many of the connections are TCP. This
		// works best if uTP connections are not rate limited by the global rate
		// limiter, see rate_limit_utp.
		//
		// see bandwidth_mixed_algo_t for options.
		int mixed_mode_algorithm;

#ifndef TORRENT_NO_DEPRECATE
		// deprecated, use set_peer_class_filter() instead
		// set to true if uTP connections should be rate limited
		// defaults to false
		bool rate_limit_utp;
#endif

		// the value passed in to listen() for the listen socket. It is the
		// number of outstanding incoming connections to queue up while we're not
		// actively waiting for a connection to be accepted. The default is 5
		// which should be sufficient for any normal client. If this is a high
		// performance server which expects to receive a lot of connections, or
		// used in a simulator or test, it might make sense to raise this number.
		// It will not take affect until listen_on() is called again (or for the
		// first time).
		int listen_queue_size;

		// if true, the ``&ip=`` argument in tracker requests (unless otherwise
		// specified) will be set to the intermediate IP address, if the user is
		// double NATed. If ther user is not double NATed, this option has no
		// affect.
		bool announce_double_nat;

		// the number of peers to try to connect to immediately when the first
		// tracker response is received for a torrent. This is a boost to given
		// to new torrents to accelerate them starting up. The normal connect
		// scheduler is run once every second, this allows peers to be connected
		// immediately instead of waiting for the session tick to trigger
		// connections.
		int torrent_connect_boost;

		// determines if seeding (and finished) torrents should attempt to make
		// outgoing connections or not. By default this is true. It may be set to
		// false in very specific applications where the cost of making outgoing
		// connections is high, and there are no or small benefits of doing so.
		// For instance, if no nodes are behind a firewall or a NAT, seeds don't
		// need to make outgoing connections.
		bool seeding_outgoing_connections;

		// if true (which is the default), libtorrent will not connect to any
		// peers on privileged ports (<= 1023). This can mitigate using
		// bittorrent swarms for certain DDoS attacks.
		bool no_connect_privileged_ports;

		// the maximum number of alerts queued up internally. If alerts are not
		// popped, the queue will eventually fill up to this level. This defaults
		// to 1000.
		int alert_queue_size;

		// the maximum allowed size (in bytes) to be received
		// by the metadata extension, i.e. magnet links. It defaults to 1 MiB.
		int max_metadata_size;

		// true by default, which means the number of connection attempts per
		// second may be limited to below the ``connection_speed``, in case we're
		// close to bump up against the limit of number of connections. The
		// intention of this setting is to more evenly distribute our connection
		// attempts over time, instead of attempting to connect in batches, and
		// timing them out in batches.
		bool smooth_connects;

		// defaults to false. When set to true, web connections will include a
		// user-agent with every request, as opposed to just the first request in
		// a connection.
		bool always_send_user_agent;

		// defaults to true. It determines whether the IP filter applies to
		// trackers as well as peers. If this is set to false, trackers are
		// exempt from the IP filter (if there is one). If no IP filter is set,
		// this setting is irrelevant.
		bool apply_ip_filter_to_trackers;

		// used to avoid starvation of read jobs in the disk I/O thread. By
		// default, read jobs are deferred, sorted by physical disk location and
		// serviced once all write jobs have been issued. In scenarios where the
		// download rate is enough to saturate the disk, there's a risk the read
		// jobs will never be serviced. With this setting, every *x* write job,
		// issued in a row, will instead pick one read job off of the sorted
		// queue, where *x* is ``read_job_every``.
		int read_job_every;

		// defaults to true and will attempt to optimize disk reads by giving the
		// operating system heads up of disk read requests as they are queued in
		// the disk job queue. This gives a significant performance boost for
		// seeding.
		bool use_disk_read_ahead;

		// determines whether or not to lock files which libtorrent is
		// downloading to or seeding from. This is implemented using
		// ``fcntl(F_SETLK)`` on unix systems and by not passing in
		// ``SHARE_READ`` and ``SHARE_WRITE`` on windows. This might prevent 3rd
		// party processes from corrupting the files under libtorrent's feet.
		bool lock_files;

		// the number of threads to use for hash checking of pieces
		// defaults to 1. If set to 0, the disk thread is used for hashing
		int hashing_threads;

		// the number of blocks to keep outstanding at any given time when
		// checking torrents. Higher numbers give faster re-checks but uses
		// more memory. Specified in number of 16 kiB blocks
		int checking_mem_usage;

		// if set to > 0, pieces will be announced to other peers before they are
		// fully downloaded (and before they are hash checked). The intention is
		// to gain 1.5 potential round trip times per downloaded piece. When
		// non-zero, this indicates how many milliseconds in advance pieces
		// should be announced, before they are expected to be completed.
		int predictive_piece_announce;

		// when false, bytes off the socket is received directly into the disk
		// buffer. This requires many more calls to recv(). When using a
		// contiguous recv buffer, the download rate can be much higher
		bool contiguous_recv_buffer;

		//#error this should not be an option, it should depend on whether or not we're seeding or downloading

		// for some aio back-ends, the number of io-threads to use
		int aio_threads;
		// for some aio back-ends, the max number of outstanding jobs
		int aio_max;

		// the number of threads to use to call async_write_some on peer sockets.
		// When seeding at extremely high speeds, using 2 or more threads here
		// may make sense. Also when using SSL peer connections
		int network_threads;

		// if this is set, it is interpreted as a file path to where to create an
		// mmaped file to back the disk cache. this is mostly useful to introduce
		// another caching layer between RAM and hard drives. Typically you would
		// point this to an SSD drive.
		std::string mmap_cache;

		// sets the listen port for SSL connections. If this is set to 0, no SSL
		// listen port is opened. Otherwise a socket is opened on this port. This
		// setting is only taken into account when opening the regular listen
		// port, and won't re-open the listen socket simply by changing this
		// setting.
		// 
		// if this is 0, outgoing SSL connections are disabled
		// 
		// It defaults to port 4433.
		int ssl_listen;

		// ``tracker_backoff`` determines how aggressively to back off from
		// retrying failing trackers. This value determines *x* in the following
		// formula, determining the number of seconds to wait until the next
		// retry:
		// 
		// 	delay = 5 + 5 * x / 100 * fails^2
		// 
		// It defaults to 250.
		// 
		// This setting may be useful to make libtorrent more or less aggressive
		// in hitting trackers.
		// 
		int tracker_backoff;

		// enables banning web seeds. By default, web seeds that send corrupt
		// data are banned.
		bool ban_web_seeds;

		// specifies the max number of bytes to receive into RAM buffers when
		// downloading stuff over HTTP. Specifically when specifying a URL to a
		// .torrent file when adding a torrent or when announcing to an HTTP
		// tracker. The default is 2 MiB.
		int max_http_recv_buffer_size;

		// enables or disables the share mode extension. This is enabled by
		// default.
		bool support_share_mode;

		// enables or disables the merkle tree torrent support. This is enabled
		// by default.
		bool support_merkle_torrents;

		// enables or disables reporting redundant bytes to the tracker. This is
		// enabled by default.
		bool report_redundant_bytes;

		// the version string to advertise for this client in the peer protocol
		// handshake. If this is empty the user_agent is used
		std::string handshake_client_version;

		// if this is true, the disk cache uses a pool allocator for disk cache
		// blocks. Enabling this improves performance of the disk cache with the
		// side effect that the disk cache is less likely and slower at returning
		// memory to the kernel when cache pressure is low.
		bool use_disk_cache_pool;

		// the download and upload rate limits for a torrent to be considered
		// active by the queuing mechanism. A torrent whose download rate is less
		// than ``inactive_down_rate`` and whose upload rate is less than
		// ``inactive_up_rate`` for ``auto_manage_startup`` seconds, is
		// considered inactive, and another queued torrent may be startert.
		// This logic is disabled if ``dont_count_slow_torrents`` is false.
		int inactive_down_rate;
		int inactive_up_rate;
	};
#endif

	// structure used to hold configuration options for the DHT
	//
	// The ``dht_settings`` struct used to contain a ``service_port`` member to
	// control which port the DHT would listen on and send messages from. This
	// field is deprecated and ignored. libtorrent always tries to open the UDP
	// socket on the same port as the TCP socket.
	struct TORRENT_EXPORT dht_settings
	{
		// initialized dht_settings to the default values
		dht_settings()
			: max_peers_reply(100)
			, search_branching(5)
#ifndef TORRENT_NO_DEPRECATE
			, service_port(0)
#endif
			, max_fail_count(20)
			, max_torrents(2000)
			, max_dht_items(700)
			, max_peers(5000)
			, max_torrent_search_reply(20)
			, restrict_routing_ips(true)
			, restrict_search_ips(true)
			, extended_routing_table(true)
			, aggressive_lookups(true)
			, privacy_lookups(false)
			, enforce_node_id(false)
			, ignore_dark_internet(true)
			, block_timeout(5 * 60)
			, block_ratelimit(5)
			, read_only(false)
			, item_lifetime(0)
			, upload_rate_limit(8000)
		{}

		// the maximum number of peers to send in a reply to ``get_peers``
		int max_peers_reply;

		// the number of concurrent search request the node will send when
		// announcing and refreshing the routing table. This parameter is called
		// alpha in the kademlia paper
		int search_branching;

#ifndef TORRENT_NO_DEPRECATE
		// the listen port for the dht. This is a UDP port. zero means use the
		// same as the tcp interface
		int service_port;
#endif

		// the maximum number of failed tries to contact a node before it is
		// removed from the routing table. If there are known working nodes that
		// are ready to replace a failing node, it will be replaced immediately,
		// this limit is only used to clear out nodes that don't have any node
		// that can replace them.
		int max_fail_count;

		// the total number of torrents to track from the DHT. This is simply an
		// upper limit to make sure malicious DHT nodes cannot make us allocate
		// an unbounded amount of memory.
		int max_torrents;

		// max number of items the DHT will store
		int max_dht_items;

		// the max number of peers to store per torrent (for the DHT)
		int max_peers;

		// the max number of torrents to return in a torrent search query to the
		// DHT
		int max_torrent_search_reply;

		// determines if the routing table entries should restrict entries to one
		// per IP. This defaults to true, which helps mitigate some attacks on
		// the DHT. It prevents adding multiple nodes with IPs with a very close
		// CIDR distance.
		//
		// when set, nodes whose IP address that's in the same /24 (or /64 for
		// IPv6) range in the same routing table bucket. This is an attempt to
		// mitigate node ID spoofing attacks also restrict any IP to only have a
		// single entry in the whole routing table
		bool restrict_routing_ips;

		// determines if DHT searches should prevent adding nodes with IPs with
		// very close CIDR distance. This also defaults to true and helps
		// mitigate certain attacks on the DHT.
		bool restrict_search_ips;

		// makes the first buckets in the DHT routing table fit 128, 64, 32 and
		// 16 nodes respectively, as opposed to the standard size of 8. All other
		// buckets have size 8 still.
		bool extended_routing_table;

		// slightly changes the lookup behavior in terms of how many outstanding
		// requests we keep. Instead of having branch factor be a hard limit, we
		// always keep *branch factor* outstanding requests to the closest nodes.
		// i.e. every time we get results back with closer nodes, we query them
		// right away. It lowers the lookup times at the cost of more outstanding
		// queries.
		bool aggressive_lookups;

		// when set, perform lookups in a way that is slightly more expensive,
		// but which minimizes the amount of information leaked about you.
		bool privacy_lookups;

		// when set, node's whose IDs that are not correctly generated based on
		// its external IP are ignored. When a query arrives from such node, an
		// error message is returned with a message saying "invalid node ID".
		bool enforce_node_id;

		// ignore DHT messages from parts of the internet we wouldn't expect to
		// see any traffic from
		bool ignore_dark_internet;

		// the number of seconds a DHT node is banned if it exceeds the rate
		// limit. The rate limit is averaged over 10 seconds to allow for bursts
		// above the limit.
		int block_timeout;

		// the max number of packets per second a DHT node is allowed to send
		// without getting banned.
		int block_ratelimit;

		// when set, the other nodes won't keep this node in their routing
		// tables, it's meant for low-power and/or ephemeral devices that
		// cannot support the DHT, it is also useful for mobile devices which
		// are sensitive to network traffic and battery life.
		// this node no longer responds to 'query' messages, and will place a
		// 'ro' key (value = 1) in the top-level message dictionary of outgoing
		// query messages.
		bool read_only;

		// the number of seconds a immutable/mutable item will be expired.
		// default is 0, means never expires.
		int item_lifetime;

		// the number of bytes per second (on average) the DHT is allowed to send.
		// If the incoming requests causes to many bytes to be sent in responses,
		// incoming requests will be dropped until the quota has been replenished.
		int upload_rate_limit;
	};


#ifndef TORRENT_NO_DEPRECATE
	// The ``pe_settings`` structure is used to control the settings related
	// to peer protocol encryption.
	struct TORRENT_EXPORT pe_settings
	{
		// initializes the encryption settings with the default values
		pe_settings()
			: out_enc_policy(enabled)
			, in_enc_policy(enabled)
			, allowed_enc_level(both)
			, prefer_rc4(false)
		{}

		// the encoding policy options for use with pe_settings::out_enc_policy
		// and pe_settings::in_enc_policy.
		enum enc_policy
		{
			// Only encrypted connections are allowed. Incoming connections that
			// are not encrypted are closed and if the encrypted outgoing
			// connection fails, a non-encrypted retry will not be made.
			forced,

			// encrypted connections are enabled, but non-encrypted connections
			// are allowed. An incoming non-encrypted connection will be accepted,
			// and if an outgoing encrypted connection fails, a non- encrypted
			// connection will be tried.
			enabled,

			// only non-encrypted connections are allowed.
			disabled
		};

		// the encryption levels, to be used with pe_settings::allowed_enc_level.
		enum enc_level
		{
			// use only plaintext encryption
			plaintext = 1,
			// use only rc4 encryption
			rc4 = 2,
			// allow both
			both = 3
		};

		// control the settings for incoming
		// and outgoing connections respectively.
		// see enc_policy enum for the available options.
		std::uint8_t out_enc_policy;
		std::uint8_t in_enc_policy;

		// determines the encryption level of the
		// connections.  This setting will adjust which encryption scheme is
		// offered to the other peer, as well as which encryption scheme is
		// selected by the client. See enc_level enum for options.
		std::uint8_t allowed_enc_level;

		// if the allowed encryption level is both, setting this to
		// true will prefer rc4 if both methods are offered, plaintext
		// otherwise
		bool prefer_rc4;
	};
#endif // TORRENT_NO_DEPRECATE

}

#endif