libtorrent API Documentation

Author: Arvid Norberg, arvid@rasterbar.com
Version: 0.13

Table of contents

overview

The interface of libtorrent consists of a few classes. The main class is the session, it contains the main loop that serves all torrents.

The basic usage is as follows:

Each class and function is described in this manual.

primitive network types

There are a few typedefs in the libtorrent namespace which pulls in network types from the asio namespace. These are:

typedef asio::ip::address address;
typedef asio::ip::address_v4 address_v4;
typedef asio::ip::address_v6 address_v6;
using asio::ip::tcp;
using asio::ip::udp;

These are declared in the <libtorrent/socket.hpp> header.

The using statements will give easy access to:

tcp::endpoint
udp::endpoint

Which are the endpoint types used in libtorrent. An endpoint is an address with an associated port.

session

The session class has the following synopsis:

class session: public boost::noncopyable
{

        session(fingerprint const& print
                = libtorrent::fingerprint(
                "LT", 0, 1, 0, 0));

        session(
                fingerprint const& print
                , std::pair<int, int> listen_port_range
                , char const* listen_interface = 0);

        torrent_handle add_torrent(
                torrent_info const& ti
                , boost::filesystem::path const& save_path
                , entry const& resume_data = entry()
                , bool compact_mode = true
                , bool paused = false);

        torrent_handle add_torrent(
                char const* tracker_url
                , sha1_hash const& info_hash
                , char const* name
                , boost::filesystem::path const& save_path
                , entry const& resume_data = entry()
                , bool compact_mode = true
                , bool paused = true);

        session_proxy abort();

        void remove_torrent(torrent_handle const& h);
        torrent_handle find_torrent(sha_hash const& ih);
        std::vector<torrent_handle> get_torrents() const;

        void set_settings(session_settings const& settings);
        void set_pe_settings(pe_settings const& settings);

        void set_upload_rate_limit(int bytes_per_second);
        int upload_rate_limit() const;
        void set_download_rate_limit(int bytes_per_second);
        int download_rate_limit() const;
        void set_max_uploads(int limit);
        void set_max_connections(int limit);
        void set_max_half_open_connections(int limit);

        void set_peer_proxy(proxy_settings const& s);
        void set_web_seed_proxy(proxy_settings const& s);
        void set_tracker_proxy(proxy_settings const& s);

        proxy_settings const& peer_proxy() const;
        proxy_settings const& web_seed_proxy() const;
        proxy_settings const& tracker_proxy() const;

        int num_uploads() const;
        int num_connections() const;

        void set_ip_filter(ip_filter const& f);

        session_status status() const;

        bool is_listening() const;
        unsigned short listen_port() const;
        bool listen_on(
                std::pair<int, int> const& port_range
                , char const* interface = 0);

        std::auto_ptr<alert> pop_alert();
        void set_severity_level(alert::severity_t s);

        void add_extension(boost::function<
                boost::shared_ptr<torrent_plugin>(torrent*)> ext);

        void start_dht();
        void stop_dht();
        void set_dht_settings(
                dht_settings const& settings);
        entry dht_state() const;
        void add_dht_node(std::pair<std::string
                , int> const& node);
        void add_dht_router(std::pair<std::string
                , int> const& node);
};

Once it's created, the session object will spawn the main thread that will do all the work. The main thread will be idle as long it doesn't have any torrents to participate in.

session()

session(fingerprint const& print
        = libtorrent::fingerprint("LT", 0, 1, 0, 0));
session(fingerprint const& print
        , std::pair<int, int> listen_port_range
        , char const* listen_interface = 0);

If the fingerprint in the first overload is omited, the client will get a default fingerprint stating the version of libtorrent. The fingerprint is a short string that will be used in the peer-id to identify the client and the client's version. For more details see the fingerprint class. The constructor that only takes a fingerprint will not open a listen port for the session, to get it running you'll have to call session::listen_on(). The other constructor, that takes a port range and an interface as well as the fingerprint will automatically try to listen on a port on the given interface. For more information about the parameters, see listen_on() function.

~session()

The destructor of session will notify all trackers that our torrents have been shut down. If some trackers are down, they will time out. All this before the destructor of session returns. So, it's advised that any kind of interface (such as windows) are closed before destructing the session object. Because it can take a few second for it to finish. The timeout can be set with set_settings().

abort()

session_proxy abort();

In case you want to destruct the session asynchrounously, you can request a session destruction proxy. If you don't do this, the destructor of the session object will block while the trackers are contacted. If you keep one session_proxy to the session when destructing it, the destructor will not block, but start to close down the session, the destructor of the proxy will then synchronize the threads. So, the destruction of the session is performed from the session destructor call until the session_proxy destructor call. The session_proxy does not have any operations on it (since the session is being closed down, no operations are allowed on it). The only valid operation is calling the destructor:

class session_proxy
{
public:
        session_proxy();
        ~session_proxy()
};

add_torrent()

torrent_handle add_torrent(
        torrent_info const& ti
        , boost::filesystem::path const& save_path
        , entry const& resume_data = entry()
        , bool compact_mode = true
        , bool paused = false);

torrent_handle add_torrent(
        char const* tracker_url
        , sha1_hash const& info_hash
        , char const* name
        , boost::filesystem::path const& save_path
        , entry const& resume_data = entry()
        , bool compact_mode = true
        , bool paused = false);

You add torrents through the add_torrent() function where you give an object representing the information found in the torrent file and the path where you want to save the files. The save_path will be prepended to the directory structure in the torrent-file.

If the torrent you are trying to add already exists in the session (is either queued for checking, being checked or downloading) add_torrent() will throw duplicate_torrent which derives from std::exception.

The optional parameter, resume_data can be given if up to date fast-resume data is available. The fast-resume data can be acquired from a running torrent by calling torrent_handle::write_resume_data(). See fast resume.

The compact_mode parameter refers to the layout of the storage for this torrent. If set to true (default), the storage will grow as more pieces are downloaded, and pieces are rearranged to finally be in their correct places once the entire torrent has been downloaded. If it is false, the entire storage is allocated before download begins. I.e. the files contained in the torrent are filled with zeros, and each downloaded piece is put in its final place directly when downloaded. For more info, see storage allocation.

paused is a boolean that specifies whether or not the torrent is to be started in a paused state. I.e. it won't connect to the tracker or any of the peers until it's resumed. This is typically a good way of avoiding race conditions when setting configuration options on torrents before starting them.

The torrent_handle returned by add_torrent() can be used to retrieve information about the torrent's progress, its peers etc. It is also used to abort a torrent.

The second overload that takes a tracker url and an info-hash instead of metadata (torrent_info) can be used with torrents where (at least some) peers support the metadata extension. For the overload to be available, libtorrent must be built with extensions enabled (TORRENT_DISABLE_EXTENSIONS must not be defined). It also takes an optional name argument. This may be 0 in case no name should be assigned to the torrent. In case it's not 0, the name is used for the torrent as long as it doesn't have metadata. See torrent_handle::name.

remove_torrent() find_torrent() get_torrents()

void remove_torrent(torrent_handle const& h);
torrent_handle find_torrent(sha_hash const& ih);
std::vector<torrent_handle> get_torrents() const;

remove_torrent() will close all peer connections associated with the torrent and tell the tracker that we've stopped participating in the swarm.

find_torrent() looks for a torrent with the given info-hash. In case there is such a torrent in the session, a torrent_handle to that torrent is returned. In case the torrent cannot be found, an invalid torrent_handle is returned.

See torrent_handle::is_valid() to know if the torrent was found or not.

get_torrents() returns a vector of torrent_handles to all the torrents currently in the session.

set_upload_rate_limit() set_download_rate_limit() upload_rate_limit() download_rate_limit()

void set_upload_rate_limit(int bytes_per_second);
void set_download_rate_limit(int bytes_per_second);
int upload_rate_limit() const;
int download_rate_limit() const;

set_upload_rate_limit() set the maximum number of bytes allowed to be sent to peers per second. This bandwidth is distributed among all the peers. If you don't want to limit upload rate, you can set this to -1 (the default). set_download_rate_limit() works the same way but for download rate instead of upload rate. download_rate_limit() and upload_rate_limit() returns the previously set limits.

set_max_uploads() set_max_connections()

void set_max_uploads(int limit);
void set_max_connections(int limit);

These functions will set a global limit on the number of unchoked peers (uploads) and the number of connections opened. The number of connections is set to a hard minimum of at least two connections per torrent, so if you set a too low connections limit, and open too many torrents, the limit will not be met. The number of uploads is at least one per torrent.

num_uploads() num_connections()

int num_uploads() const;
int num_connections() const;

Returns the number of currently unchoked peers and the number of connections (including half-open ones) respectively.

set_max_half_open_connections()

void set_max_half_open_connections(int 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.

set_ip_filter()

void set_ip_filter(ip_filter const& filter);

Sets a filter that will be used to reject and accept incoming as well as outgoing connections based on their originating ip address. The default filter will allow connections to any ip address. To build a set of rules for which addresses are accepted and not, see ip_filter.

Each time a peer is blocked because of the IP filter, a peer_blocked_alert is generated.

status()

session_status status() const;

status() returns session wide-statistics and status. The session_status struct has the following members:

struct session_status
{
        bool has_incoming_connections;

        float upload_rate;
        float download_rate;

        float payload_upload_rate;
        float payload_download_rate;

        size_type total_download;
        size_type total_upload;

        size_type total_payload_download;
        size_type total_payload_upload;

        int num_peers;

        int dht_nodes;
        int dht_cache_nodes;
        int dht_torrents;
        int dht_global_nodes;
};

has_incoming_connections is false as long as no incoming connections have been established on the listening socket. Every time you change the listen port, this will be reset to false.

upload_rate, download_rate, payload_download_rate and payload_upload_rate are the total download and upload rates accumulated from all torrents. The payload versions is the payload download only.

total_download and total_upload are the total number of bytes downloaded and uploaded to and from all torrents. total_payload_download and total_payload_upload are the same thing but where only the payload is considered.

num_peers is the total number of peer connections this session has. This includes incoming connections that still hasn't sent their handshake or outgoing connections that still hasn't completed the TCP connection. This number may be slightly higher than the sum of all peers of all torrents because the incoming connections may not be assigned a torrent yet.

dht_nodes, dht_cache_nodes and dht_torrents are only available when built with DHT support. They are all set to 0 if the DHT isn't running. When the DHT is running, dht_nodes is set to the number of nodes in the routing table. This number only includes active nodes, not cache nodes. The dht_cache_nodes is set to the number of nodes in the node cache. These nodes are used to replace the regular nodes in the routing table in case any of them becomes unresponsive.

dht_torrents are the number of torrents tracked by the DHT at the moment.

dht_global_nodes is an estimation of the total number of nodes in the DHT network.

is_listening() listen_port() listen_on()

bool is_listening() const;
unsigned short listen_port() const;
bool listen_on(
        std::pair<int, int> const& port_range
        , char const* interface = 0);

is_listening() will tell you whether or not the session has successfully opened a listening port. If it hasn't, this function will return false, and then you can use listen_on() to make another try.

listen_port() returns the port we ended up listening on. Since you just pass a port-range to the constructor and to listen_on(), to know which port it ended up using, you have to ask the session using this function.

listen_on() will change the listen port and/or the listen interface. If the session is already listening on a port, this socket will be closed and a new socket will be opened with these new settings. The port range is the ports it will try to listen on, if the first port fails, it will continue trying the next port within the range and so on. The interface parameter can be left as 0, in that case the os will decide which interface to listen on, otherwise it should be the ip-address of the interface you want the listener socket bound to. listen_on() returns true if it managed to open the socket, and false if it failed. If it fails, it will also generate an appropriate alert (listen_failed_alert).

The interface parameter can also be a hostname that will resolve to the device you want to listen on.

If you're also starting the DHT, it is a good idea to do that after you've called listen_on(), since the default listen port for the DHT is the same as the tcp listen socket. If you start the DHT first, it will assume the tcp port is free and open the udp socket on that port, then later, when listen_on() is called, it may turn out that the tcp port is in use. That results in the DHT and the bittorrent socket listening on different ports. If the DHT is active when listen_on is called, the udp port will be rebound to the new port, if it was configured to use the same port as the tcp socket, and if the listen_on call failed to bind to the same port that the udp uses.

The reason why it's a good idea to run the DHT and the bittorrent socket on the same port is because that is an assumption that may be used to increase performance. One way to accelerate the connecting of peers on windows may be to first ping all peers with a DHT ping packet, and connect to those that responds first. On windows one can only connect to a few peers at a time because of a built in limitation (in XP Service pack 2).

pop_alert() set_severity_level()

std::auto_ptr<alert> pop_alert();
void set_severity_level(alert::severity_t s);

pop_alert() is used to ask the session if any errors or events has occurred. With set_severity_level() you can filter how serious the event has to be for you to receive it through pop_alert(). For information, see alerts.

add_extension()

void add_extension(boost::function<
        boost::shared_ptr<torrent_plugin>(torrent*)> ext);

This function adds an extension to this session. The argument is a function object that is called with a torrent* and which should return a boost::shared_ptr<torrent_plugin>. To write custom plugins, see libtorrent plugins. The main plugins implemented in libtorrent are:

metadata extension
Allows peers to download the metadata (.torren files) from the swarm directly. Makes it possible to join a swarm with just a tracker and info-hash.
uTorrent peer exchange
Exchanges peers between clients.

To use these, imclude <libtorrent/extensions/metadata_transfer.hpp> or <libtorrent/extensions/ut_pex.hpp>. The functions to pass in to add_extension() are libtorrent::create_metadata_plugin and libtorrent::create_ut_pex_plugin respectively.

e.g.

ses.add_extension(&libtorrent::create_metadata_plugin);
ses.add_extension(&libtorrent::create_ut_pex_plugin);

set_settings() set_pe_settings()

void set_settings(session_settings const& settings);
void set_pe_settings(pe_settings const& settings);

Sets the session settings and the packet encryption settings respectively. See session_settings and pe_settings for more information on available options.

set_peer_proxy() set_web_seed_proxy() set_tracker_proxy() set_dht_proxy()

void set_peer_proxy(proxy_settings const& s);
void set_web_seed_proxy(proxy_settings const& s);
void set_tracker_proxy(proxy_settings const& s);
void set_dht_proxy(proxy_settings const& s);

The set_dht_proxy is not available when DHT is disabled. These functions sets the proxy settings for different kinds of connections, bittorrent peers, web seeds, trackers and the DHT traffic.

set_peer_proxy affects regular bittorrent peers. set_web_seed_proxy affects only web seeds. see HTTP seeding.

set_tracker_proxy only affects HTTP tracker connections (UDP tracker connections are affected if the given proxy supports UDP, e.g. SOCKS5).

set_dht_proxy affects the DHT messages. Since they are sent over UDP, it only has any effect if the proxy supports UDP.

For more information on what settings are available for proxies, see proxy_settings.

peer_proxy() web_seed_proxy() tracker_proxy() dht_proxy()

proxy_settings const& peer_proxy() const;
proxy_settings const& web_seed_proxy() const;
proxy_settings const& tracker_proxy() const;
proxy_settings const& dht_proxy() const;

These functions returns references to their respective current settings.

The dht_proxy is not available when DHT is disabled.

start_dht() stop_dht() set_dht_settings() dht_state()

void start_dht(entry const& startup_state);
void stop_dht();
void set_dht_settings(dht_settings const& settings);
entry dht_state() const;

These functions are not available in case TORRENT_DISABLE_DHT is defined. start_dht starts the dht node and makes the trackerless service available to torrents. The startup state is optional and can contain nodes and the node id from the previous session. The dht node state is a bencoded dictionary with the following entries:

nodes
A list of strings, where each string is a node endpoint encoded in binary. If the string is 6 bytes long, it is an IPv4 address of 4 bytes, encoded in network byte order (big endian), followed by a 2 byte port number (also network byte order). If the string is 18 bytes long, it is 16 bytes of IPv6 address followed by a 2 bytes port number (also network byte order).
node-id
The node id written as a readable string as a hexadecimal number.

dht_state will return the current state of the dht node, this can be used to start up the node again, passing this entry to start_dht. It is a good idea to save this to disk when the session is closed, and read it up again when starting.

If the port the DHT is supposed to listen on is already in use, and exception is thrown, asio::error.

stop_dht stops the dht node.

add_dht_node adds a node to the routing table. This can be used if your client has its own source of bootstrapping nodes.

set_dht_settings sets some parameters availavle to the dht node. The struct has the following members:

struct dht_settings
{
        int max_peers_reply;
        int search_branching;
        int service_port;
        int max_fail_count;
};

max_peers_reply is the maximum number of peers the node will send in response to a get_peers message from another node.

search_branching is 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.

service_port is the udp port the node will listen to. This will default to 0, which means the udp listen port will be the same as the tcp listen port. This is in general a good idea, since some NAT implementations reserves the udp port for any mapped tcp port, and vice versa. NAT-PMP guarantees this for example.

max_fail_count is 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.

add_dht_node() add_dht_router()

void add_dht_node(std::pair<std::string, int> const& node);
void add_dht_router(std::pair<std::string, int> const& node);

add_dht_node takes a host name and port pair. That endpoint will be pinged, and if a valid DHT reply is received, the node will be added to the routing table.

add_dht_router adds the given endpoint to a list of DHT router nodes. If a search is ever made while the routing table is empty, those nodes will be used as backups. Nodes in the router node list will also never be added to the regular routing table, which effectively means they are only used for bootstrapping, to keep the load off them.

An example routing node that you could typically add is router.bittorrent.com.

entry

The entry class represents one node in a bencoded hierarchy. It works as a variant type, it can be either a list, a dictionary (std::map), an integer or a string. This is its synopsis:

class entry
{
public:

        typedef std::map<std::string, entry> dictionary_type;
        typedef std::string string_type;
        typedef std::list<entry> list_type;
        typedef size_type integer_type;

        enum data_type
        {
                int_t,
                string_t,
                list_t,
                dictionary_t,
                undefined_t
        };

        data_type type() const;

        entry(dictionary_type const&);
        entry(string_type const&);
        entry(list_type const&);
        entry(integer_type const&);

        entry();
        entry(data_type t);
        entry(entry const& e);
        ~entry();

        void operator=(entry const& e);
        void operator=(dictionary_type const&);
        void operator=(string_type const&);
        void operator=(list_type const&);
        void operator=(integer_type const&);

        integer_type& integer();
        integer_type const& integer() const;
        string_type& string();
        string_type const& string() const;
        list_type& list();
        list_type const& list() const;
        dictionary_type& dict();
        dictionary_type const& dict() const;

        // these functions requires that the entry
        // is a dictionary, otherwise they will throw
        entry& operator[](char const* key);
        entry& operator[](std::string const& key);
        entry const& operator[](char const* key) const;
        entry const& operator[](std::string const& key) const;
        entry* find_key(char const* key);
        entry const* find_key(char const* key) const;

        void print(std::ostream& os, int indent = 0) const;
};

TODO: finish documentation of entry.

integer() string() list() dict() type()

integer_type& integer();
integer_type const& integer() const;
string_type& string();
string_type const& string() const;
list_type& list();
list_type const& list() const;
dictionary_type& dict();
dictionary_type const& dict() const;

The integer(), string(), list() and dict() functions are accessors that return the respective type. If the entry object isn't of the type you request, the accessor will throw type_error (which derives from std::runtime_error). You can ask an entry for its type through the type() function.

The print() function is there for debug purposes only.

If you want to create an entry you give it the type you want it to have in its constructor, and then use one of the non-const accessors to get a reference which you then can assign the value you want it to have.

The typical code to get info from a torrent file will then look like this:

entry torrent_file;
// ...

// throws if this is not a dictionary
entry::dictionary_type const& dict = torrent_file.dict();
entry::dictionary_type::const_iterator i;
i = dict.find("announce");
if (i != dict.end())
{
        std::string tracker_url = i->second.string();
        std::cout << tracker_url << "\n";
}

The following code is equivalent, but a little bit shorter:

entry torrent_file;
// ...

// throws if this is not a dictionary
if (entry* i = torrent_file.find_key("announce"))
{
        std::string tracker_url = i->string();
        std::cout << tracker_url << "\n";
}

To make it easier to extract information from a torrent file, the class torrent_info exists.

operator[]

entry& operator[](char const* key);
entry& operator[](std::string const& key);
entry const& operator[](char const* key) const;
entry const& operator[](std::string const& key) const;

All of these functions requires the entry to be a dictionary, if it isn't they will throw libtorrent::type_error.

The non-const versions of the operator[] will return a reference to either the existing element at the given key or, if there is no element with the given key, a reference to a newly inserted element at that key.

The const version of operator[] will only return a reference to an existing element at the given key. If the key is not found, it will throw libtorrent::type_error.

find_key()

entry* find_key(char const* key);
entry const* find_key(char const* key) const;

These functions requires the entry to be a dictionary, if it isn't they will throw libtorrent::type_error.

They will look for an element at the given key in the dictionary, if the element cannot be found, they will return 0. If an element with the given key is found, the return a pointer to it.

torrent_info

The torrent_info has the following synopsis:

class torrent_info
{
public:

        torrent_info();
        torrent_info(sha1_hash const& info_hash);
        torrent_info(entry const& torrent_file);

        entry create_torrent() const;
        void set_comment(char const* str);
        void set_piece_size(int size);
        void set_creator(char const* str);
        void set_hash(int index, sha1_hash const& h);
        void add_tracker(std::string const& url, int tier = 0);
        void add_file(boost::filesystem::path file, size_type size);
        void add_url_seed(std::string const& url);

        typedef std::vector<file_entry>::const_iterator file_iterator;
        typedef std::vector<file_entry>::const_reverse_iterator
                reverse_file_iterator;

        bool remap_files(std::vector<std::pair<std::string, libtorrent::size_type> > const& map);

        file_iterator begin_files(bool storage = false) const;
        file_iterator end_files(bool storage = false) const;
        reverse_file_iterator rbegin_files(bool storage = false) const;
        reverse_file_iterator rend_files(bool storage = false) const;

        int num_files(bool storage = false) const;
        file_entry const& file_at(int index, bool storage = false) const;

        std::vector<file_slice> map_block(int piece, size_type offset
                , int size, bool storage = false) const;
        peer_request map_file(int file_index, size_type file_offset
                , int size, bool storage = false) const;

        std::vector<announce_entry> const& trackers() const;

        bool priv() const;
        void set_priv(bool v);

        std::vector<std::string> const& url_seeds() const;

        size_type total_size() const;
        size_type piece_length() const;
        int num_pieces() const;
        sha1_hash const& info_hash() const;
        std::string const& name() const;
        std::string const& comment() const;
        std::string const& creator() const;

        std::vector<std::pair<std::string, int> > const& nodes() const;
        void add_node(std::pair<std::string, int> const& node);

        boost::optional<boost::posix_time::ptime>
        creation_date() const;

        void print(std::ostream& os) const;

        size_type piece_size(unsigned int index) const;
        sha1_hash const& hash_for_piece(unsigned int index) const;
};

torrent_info()

torrent_info();
torrent_info(sha1_hash const& info_hash);
torrent_info(entry const& torrent_file);

The default constructor of torrent_info is used when creating torrent files. It will initialize the object to an empty torrent, containing no files. The info hash will be set to 0 when this constructor is used. To use the empty torrent_info object, add files and piece hashes, announce URLs and optionally a creator tag and comment. To do this you use the members set_comment(), set_piece_size(), set_creator(), set_hash() etc.

The constructor that takes an info-hash is identical to the default constructor with the exception that it will initialize the info-hash to the given value. This is used internally when downloading torrents without the metadata. The metadata will be created by libtorrent as soon as it has been downloaded from the swarm.

The last constructor is the one that is used in most cases. It will create a torrent_info object from the information found in the given torrent_file. The entry represents a tree node in an bencoded file. To load an ordinary .torrent file into an entry, use bdecode(), see bdecode() bencode().

set_comment() set_piece_size() set_creator() set_hash() add_tracker() add_file()

void set_comment(char const* str);
void set_piece_size(int size);
void set_creator(char const* str);
void set_hash(int index, sha1_hash const& h);
void add_tracker(std::string const& url, int tier = 0);
void add_file(boost::filesystem::path file, size_type size);

These files are used when creating a torrent file. set_comment() will simply set the comment that belongs to this torrent. The comment can be retrieved with the comment() member. The string should be UTF-8 encoded.

set_piece_size() will set the size of each piece in this torrent. The piece size must be an even multiple of 2. i.e. usually something like 256 kiB, 512 kiB, 1024 kiB etc. The size is given in number of bytes.

set_creator() is an optional attribute that can be used to identify your application that was used to create the torrent file. The string should be UTF-8 encoded.

set_hash() writes the hash for the piece with the given piece-index. You have to call this function for every piece in the torrent. Usually the hasher is used to calculate the sha1-hash for a piece.

add_tracker() adds a tracker to the announce-list. The tier determines the order in which the trackers are to be tried. For more information see trackers().

add_file() adds a file to the torrent. The order in which you add files will determine the order in which they are placed in the torrent file. You have to add at least one file to the torrent. The path you give has to be a relative path from the root directory of the torrent. The size is given in bytes.

When you have added all the files and hashes to your torrent, you can generate an entry which then can be encoded as a .torrent file. You do this by calling create_torrent().

For a complete example of how to create a torrent from a file structure, see make_torrent.

create_torrent()

entry create_torrent();

Returns an entry representing the bencoded tree of data that makes up a .torrent file. You can save this data as a torrent file with bencode() (see bdecode() bencode()), for a complete example, see make_torrent.

This function is not const because it will also set the info-hash of the torrent_info object.

Note that a torrent file must include at least one file, and it must have at least one tracker url or at least one DHT node.

remap_files()

bool remap_files(std::vector<std::pair<std::string, libtorrent::size_type> > const& map);

This call will create a new mapping of the data in this torrent to other files. The torrent_info maintains 2 views of the file storage. One that is true to the torrent file, and one that represents what is actually saved on disk. This call will change what the files on disk are called.

The each entry in the vector map is a pair of a (relative) file path and the file's size.

The return value indicates if the remap was successful or not. True means success and false means failure. The sum of all the files passed in through map has to be exactly the same as the total_size of the torrent.

begin_files() end_files() rbegin_files() rend_files()

file_iterator begin_files(bool storage = false) const;
file_iterator end_files(bool storage = false) const;
reverse_file_iterator rbegin_files(bool storage = false) const;
reverse_file_iterator rend_files(bool storage = false) const;

This class will need some explanation. First of all, to get a list of all files in the torrent, you can use begin_files(), end_files(), rbegin_files() and rend_files(). These will give you standard vector iterators with the type file_entry.

The storage parameter specifies which view of the files you want. The default is false, which means you will see the content of the torrent file. If set to true, you will see the file that the storage class uses to save the files to disk. Typically these views are the same, but in case the files have been remapped, they may differ. For more info, see remap_files().

struct file_entry
{
        boost::filesystem::path path;
        size_type offset;
        size_type size;
        boost::shared_ptr<const boost::filesystem::path> orig_path;
};

The path is the full (relative) path of each file. i.e. if it is a multi-file torrent, all the files starts with a directory with the same name as torrent_info::name(). The filenames are encoded with UTF-8.

size is the size of the file (in bytes) and offset is the byte offset of the file within the torrent. i.e. the sum of all the sizes of the files before it in the list.

orig_path is set to 0 in case the path element is an exact copy of that found in the metadata. In case the path in the original metadata was incorrectly encoded, and had to be fixed in order to be acceptable utf-8, the original string is preserved in orig_path. The reason to keep it is to be able to reproduce the info-section exactly, with the correct info-hash.

num_files() file_at()

int num_files(bool storage = false) const;
file_entry const& file_at(int index, bool storage = false) const;

If you need index-access to files you can use the num_files() and file_at() to access files using indices.

The storage parameter specifies which view of the files you want. The default is false, which means you will see the content of the torrent file. If set to true, you will see the file that the storage class uses to save the files to disk. Typically these views are the same, but in case the files have been remapped, they may differ. For more info, see remap_files().

map_block()

std::vector<file_slice> map_block(int piece, size_type offset
        , int size, bool storage = false) const;

This function will map a piece index, a byte offset within that piece and a size (in bytes) into the corresponding files with offsets where that data for that piece is supposed to be stored.

The file slice struct looks like this:

struct file_slice
{
        int file_index;
        size_type offset;
        size_type size;
};

The file_index refers to the index of the file (in the torrent_info). To get the path and filename, use file_at() and give the file_index as argument. The offset is the byte offset in the file where the range starts, and size is the number of bytes this range is. The size + offset will never be greater than the file size.

The storage parameter specifies which view of the files you want. The default is false, which means you will see the content of the torrent file. If set to true, you will see the file that the storage class uses to save the files to disk. Typically these views are the same, but in case the files have been remapped, they may differ. For more info, see remap_files().

map_file()

peer_request map_file(int file_index, size_type file_offset
        , int size, bool storage = false) const;

This function will map a range in a specific file into a range in the torrent. The file_offset parameter is the offset in the file, given in bytes, where 0 is the start of the file. The peer_request structure looks like this:

struct peer_request
{
        int piece;
        int start;
        int length;
        bool operator==(peer_request const& r) const;
};

piece is the index of the piece in which the range starts. start is the offset within that piece where the range starts. length is the size of the range, in bytes.

The input range is assumed to be valid within the torrent. file_offset + size is not allowed to be greater than the file size. file_index must refer to a valid file, i.e. it cannot be >= num_files().

url_seeds() add_url_seed()

std::vector<std::string> const& url_seeds() const;
void add_url_seed(std::string const& url);

If there are any url-seeds in this torrent, url_seeds() will return a vector of those urls. If you're creating a torrent file, add_url_seed() adds one url to the list of url-seeds. Currently, the only transport protocol supported for the url is http.

The storage parameter specifies which view of the files you want. The default is false, which means you will see the content of the torrent file. If set to true, you will see the file that the storage class uses to save the files to disk. Typically these views are the same, but in case the files have been remapped, they may differ. For more info, see remap_files().

See HTTP seeding for more information.

print()

void print(std::ostream& os) const;

The print() function is there for debug purposes only. It will print the info from the torrent file to the given outstream. This function has been deprecated and will be removed from future releases.

trackers()

std::vector<announce_entry> const& trackers() const;

The trackers() function will return a sorted vector of announce_entry. Each announce entry contains a string, which is the tracker url, and a tier index. The tier index is the high-level priority. No matter which trackers that works or not, the ones with lower tier will always be tried before the one with higher tier number.

struct announce_entry
{
        announce_entry(std::string const& url);
        std::string url;
        int tier;
};

total_size() piece_length() piece_size() num_pieces()

size_type total_size() const;
size_type piece_length() const;
size_type piece_size(unsigned int index) const;
int num_pieces() const;

total_size(), piece_length() and num_pieces() returns the total number of bytes the torrent-file represents (all the files in it), the number of byte for each piece and the total number of pieces, respectively. The difference between piece_size() and piece_length() is that piece_size() takes the piece index as argument and gives you the exact size of that piece. It will always be the same as piece_length() except in the case of the last piece, which may be smaller.

hash_for_piece() info_hash()

size_type piece_size(unsigned int index) const;
sha1_hash const& hash_for_piece(unsigned int index) const;

hash_for_piece() takes a piece-index and returns the 20-bytes sha1-hash for that piece and info_hash() returns the 20-bytes sha1-hash for the info-section of the torrent file. For more information on the sha1_hash, see the big_number class. info_hash() will only return a valid hash if the torrent_info was read from a .torrent file or if an entry was created from it (through create_torrent).

name() comment() creation_date() creator()

std::string const& name() const;
std::string const& comment() const;
boost::optional<boost::posix_time::ptime> creation_date() const;

name() returns the name of the torrent.

comment() returns the comment associated with the torrent. If there's no comment, it will return an empty string. creation_date() returns a boost::posix_time::ptime object, representing the time when this torrent file was created. If there's no time stamp in the torrent file, this will return a date of January 1:st 1970.

Both the name and the comment is UTF-8 encoded strings.

creator() returns the creator string in the torrent. If there is no creator string it will return an empty string.

priv() set_priv()

bool priv() const;
void set_priv(bool v);

priv() returns true if this torrent is private. i.e., it should not be distributed on the trackerless network (the kademlia DHT).

set_priv() sets or clears the private flag on this torrent.

nodes()

std::vector<std::pair<std::string, int> > const& nodes() const;

If this torrent contains any DHT nodes, they are put in this vector in their original form (host name and port number).

add_node()

void add_node(std::pair<std::string, int> const& node);

This is used when creating torrent. Use this to add a known DHT node. It may be used, by the client, to bootstrap into the DHT network.

torrent_handle

You will usually have to store your torrent handles somewhere, since it's the object through which you retrieve information about the torrent and aborts the torrent. Its declaration looks like this:

struct torrent_handle
{
        torrent_handle();

        torrent_status status();
        void file_progress(std::vector<float>& fp);
        void get_download_queue(std::vector<partial_piece_info>& queue) const;
        void get_peer_info(std::vector<peer_info>& v) const;
        torrent_info const& get_torrent_info() const;
        bool is_valid() const;

        std::string name() const;

        entry write_resume_data() const;
        void force_reannounce() const;
        void connect_peer(asio::ip::tcp::endpoint const& adr, int source = 0) const;

        void set_tracker_login(std::string const& username
                , std::string const& password) const;

        std::vector<announce_entry> const& trackers() const;
        void replace_trackers(std::vector<announce_entry> const&);

        void add_url_seed(std::string const& url);
        void remove_url_seed(std::string const& url);
        std::set<std::string> url_seeds() const;

        void set_ratio(float ratio) const;
        void set_max_uploads(int max_uploads) const;
        void set_max_connections(int max_connections) const;
        void set_upload_limit(int limit) const;
        int upload_limit() const;
        void set_download_limit(int limit) const;
        int download_limit() const;
        void set_sequenced_download_threshold(int threshold) const;

        void set_peer_upload_limit(asio::ip::tcp::endpoint ip, int limit) const;
        void set_peer_download_limit(asio::ip::tcp::endpoint ip, int limit) const;

        void use_interface(char const* net_interface) const;

        void pause() const;
        void resume() const;
        bool is_paused() const;
        bool is_seed() const;

        void resolve_countries(bool r);
        bool resolve_countries() const;

        void piece_priority(int index, int priority) const;
        int piece_priority(int index) const;

        void prioritize_pieces(std::vector<int> const& pieces) const;
        std::vector<int> piece_priorities() const;

        void prioritize_files(std::vector<int> const& files) const;

        // these functions are deprecated
        void filter_piece(int index, bool filter) const;
        void filter_pieces(std::vector<bool> const& bitmask) const;
        bool is_piece_filtered(int index) const;
        std::vector<bool> filtered_pieces() const;
        void filter_files(std::vector<bool> const& files) const;

        bool has_metadata() const;

        boost::filesystem::path save_path() const;
        void move_storage(boost::filesystem::path const& save_path) const;

        sha1_hash info_hash() const;

        bool operator==(torrent_handle const&) const;
        bool operator!=(torrent_handle const&) const;
        bool operator<(torrent_handle const&) const;
};

The default constructor will initialize the handle to an invalid state. Which means you cannot perform any operation on it, unless you first assign it a valid handle. If you try to perform any operation on an uninitialized handle, it will throw invalid_handle.

Warning

All operations on a torrent_handle may throw invalid_handle exception, in case the handle is no longer refering to a torrent. There are two exceptions, info_hash() and is_valid() will never throw. Since the torrents are processed by a background thread, there is no guarantee that a handle will remain valid between two calls.

piece_priority() prioritize_pieces() piece_priorities() prioritize_files()

void piece_priority(int index, int priority) const;
int piece_priority(int index) const;
void prioritize_pieces(std::vector<int> const& pieces) const;
std::vector<int> piece_priorities() const;
void prioritize_files(std::vector<int> const& files) const;

These functions are used to set and get the prioritiy of individual pieces. By default all pieces have priority 1. That means that the random rarest first algorithm is effectively active for all pieces. You may however change the priority of individual pieces. There are 8 different priority levels:

  1. piece is not downloaded at all
  2. normal priority. Download order is dependent on availability
  3. higher than normal priority. Pieces are preferred over pieces with the same availability, but not over pieces with lower availability
  4. pieces are as likely to be picked as partial pieces.
  5. pieces are preferred over partial pieces, but not over pieces with lower availability
  6. currently the same as 4
  7. piece is as likely to be picked as any piece with availability 1
  8. maximum priority, availability is disregarded, the piece is preferred over any other piece with lower priority

The exact definitions of these priorities are implementation details, and subject to change. The interface guarantees that higher number means higher priority, and that 0 means do not download.

piece_priority sets or gets the priority for an individual piece, specified by index.

prioritize_pieces takes a vector of integers, one integer per piece in the torrent. All the piece priorities will be updated with the priorities in the vector.

piece_priorities returns a vector with one element for each piece in the torrent. Each element is the current priority of that piece.

prioritize_files takes a vector that has at as many elements as there are files in the torrent. Each entry is the priority of that file. The function sets the priorities of all the pieces in the torrent based on the vector.

file_progress()

void file_progress(std::vector<float>& fp);

This function fills in the supplied vector with the progress (a value in the range [0, 1]) describing the download progress of each file in this torrent. The progress values are ordered the same as the files in the torrent_info. This operation is not very cheap.

save_path()

boost::filesystem::path save_path() const;

save_path() returns the path that was given to add_torrent() when this torrent was started.

move_storage()

void move_storage(boost::filesystem::path const& save_path) const;

Moves the file(s) that this torrent are currently seeding from or downloading to. This operation will only have the desired effect if the given save_path is located on the same drive as the original save path. Since disk IO is performed in a separate thread, this operation is also asynchronous. Once the operation completes, the storage_moved_alert is generated, with the new path as the message.

force_reannounce()

void force_reannounce() const;

force_reannounce() will force this torrent to do another tracker request, to receive new peers. If the torrent is invalid, queued or in checking mode, this functions will throw invalid_handle.

connect_peer()

void connect_peer(asio::ip::tcp::endpoint const& adr, int source = 0) const;

connect_peer() is a way to manually connect to peers that one believe is a part of the torrent. If the peer does not respond, or is not a member of this torrent, it will simply be disconnected. No harm can be done by using this other than an unnecessary connection attempt is made. If the torrent is uninitialized or in queued or checking mode, this will throw invalid_handle. The second (optional) argument will be bitwised ORed into the source mask of this peer. Typically this is one of the source flags in peer_info. i.e. tracker, pex, dht etc.

name()

std::string name() const;

Returns the name of the torrent. i.e. the name from the metadata associated with it. In case the torrent was started without metadata, and hasn't completely received it yet, it returns the name given to it when added to the session. See session::add_torrent.

set_ratio()

void set_ratio(float ratio) const;

set_ratio() sets the desired download / upload ratio. If set to 0, it is considered being infinite. i.e. the client will always upload as much as it can, no matter how much it gets back in return. With this setting it will work much like the standard clients.

Besides 0, the ratio can be set to any number greater than or equal to 1. It means how much to attempt to upload in return for each download. e.g. if set to 2, the client will try to upload 2 bytes for every byte received. The default setting for this is 0, which will make it work as a standard client.

set_upload_limit() set_download_limit() upload_limit() download_limit()

void set_upload_limit(int limit) const;
void set_download_limit(int limit) const;
int upload_limit() const;
int download_limit() const;

set_upload_limit will limit the upload bandwidth used by this particular torrent to the limit you set. It is given as the number of bytes per second the torrent is allowed to upload. set_download_limit works the same way but for download bandwidth instead of upload bandwidth. Note that setting a higher limit on a torrent then the global limit (session::set_upload_rate_limit) will not override the global rate limit. The torrent can never upload more than the global rate limit.

upload_limit and download_limit will return the current limit setting, for upload and download, respectively.

set_sequenced_download_threshold()

void set_sequenced_download_threshold(int threshold);

sequenced-download threshold is the limit on how popular a piece has to be (popular == inverse of rarity) to be downloaded in sequence instead of in random (rarest first) order. It can be used to tweak disk performance in settings where the random download property is less necessary. For example, if the threshold is 10, all pieces which 10 or more peers have, will be downloaded in index order. This setting defaults to 100, which means that it is disabled in practice.

Setting this threshold to a very small value will affect the piece distribution negatively in the swarm. It should basically only be used in situations where the random seeks on the disk is the download bottleneck.

set_peer_upload_limit() set_peer_download_limit()

void set_peer_upload_limit(asio::ip::tcp::endpoint ip, int limit) const;
void set_peer_download_limit(asio::ip::tcp::endpoint ip, int limit) const;

Works like set_upload_limit and set_download_limit respectively, but controls individual peer instead of the whole torrent.

pause() resume() is_paused()

void pause() const;
void resume() const;
bool is_paused() const;

pause(), and resume() will disconnect all peers and reconnect all peers respectively. When a torrent is paused, it will however remember all share ratios to all peers and remember all potential (not connected) peers. You can use is_paused() to determine if a torrent is currently paused. Torrents may be paused automatically if there is a file error (e.g. disk full) or something similar. See file_error_alert.

resolve_countries()

void resolve_countries(bool r);
bool resolve_countries() const;

Sets or gets the flag that derermines if countries should be resolved for the peers of this torrent. It defaults to false. If it is set to true, the peer_info structure for the peers in this torrent will have their country member set. See peer_info for more information on how to interpret this field.

is_seed()

bool is_seed() const;

Returns true if the torrent is in seed mode (i.e. if it has finished downloading).

has_metadata()

bool has_metadata() const;

Returns true if this torrent has metadata (either it was started from a .torrent file or the metadata has been downloaded). The only scenario where this can return false is when the torrent was started torrent-less (i.e. with just an info-hash and tracker ip). Note that if the torrent doesn't have metadata, the member get_torrent_info() will throw.

set_tracker_login()

void set_tracker_login(std::string const& username
        , std::string const& password) const;

set_tracker_login() sets a username and password that will be sent along in the HTTP-request of the tracker announce. Set this if the tracker requires authorization.

trackers() replace_trackers()

std::vector<announce_entry> const& trackers() const;
void replace_trackers(std::vector<announce_entry> const&) const;

trackers() will return the list of trackers for this torrent. The announce entry contains both a string url which specify the announce url for the tracker as well as an int tier, which is specifies the order in which this tracker is tried. If you want libtorrent to use another list of trackers for this torrent, you can use replace_trackers() which takes a list of the same form as the one returned from trackers() and will replace it. If you want an immediate effect, you have to call force_reannounce().

add_url_seed() remove_url_seed() url_seeds()

void add_url_seed(std::string const& url);
void remove_url_seed(std::string const& url);
std::set<std::string> url_seeds() const;

add_url_seed() adds another url to the torrent's list of url seeds. If the given url already exists in that list, the call has no effect. The torrent will connect to the server and try to download pieces from it, unless it's paused, queued, checking or seeding. remove_url_seed() removes the given url if it exists already. url_seeds() return a set of the url seeds currently in this torrent. Note that urls that fails may be removed automatically from the list.

See HTTP seeding for more information.

use_interface()

void use_interface(char const* net_interface) const;

use_interface() sets the network interface this torrent will use when it opens outgoing connections. By default, it uses the same interface as the session uses to listen on. The parameter must be a string containing an ip-address (either an IPv4 or IPv6 address). If the string does not conform to this format and exception is thrown.

info_hash()

sha1_hash info_hash() const;

info_hash() returns the info-hash for the torrent.

set_max_uploads() set_max_connections()

void set_max_uploads(int max_uploads) const;
void set_max_connections(int max_connections) const;

set_max_uploads() sets the maximum number of peers that's unchoked at the same time on this torrent. If you set this to -1, there will be no limit.

set_max_connections() sets the maximum number of connection this torrent will open. If all connections are used up, incoming connections may be refused or poor connections may be closed. This must be at least 2. The default is unlimited number of connections. If -1 is given to the function, it means unlimited.

write_resume_data()

entry write_resume_data() const;

write_resume_data() generates fast-resume data and returns it as an entry. This entry is suitable for being bencoded. For more information about how fast-resume works, see fast resume.

There are three cases where this function will just return an empty entry:

  1. The torrent handle is invalid.
  2. The torrent is checking (or is queued for checking) its storage, it will obviously not be ready to write resume data.
  3. The torrent hasn't received valid metadata and was started without metadata (see libtorrent's metadata from peers extension)

Note that by the time this function returns, the resume data may already be invalid if the torrent is still downloading! The recommended practice is to first pause the torrent, then generate the fast resume data, and then close it down. Since the disk IO is done in a separate thread, in order to synchronize, you shoule to wait for the torrent_paused_alert before you write the resume data.

It is still a good idea to save resume data periodically during download as well as when closing down. In full allocation mode the reume data is never invalidated by subsequent writes to the files, since pieces won't move around.

status()

torrent_status status() const;

status() will return a structure with information about the status of this torrent. If the torrent_handle is invalid, it will throw invalid_handle exception. See torrent_status.

get_download_queue()

void get_download_queue(std::vector<partial_piece_info>& queue) const;

get_download_queue() takes a non-const reference to a vector which it will fill with information about pieces that are partially downloaded or not downloaded at all but partially requested. The entry in the vector (partial_piece_info) looks like this:

struct partial_piece_info
{
        int piece_index;
        int blocks_in_piece;
        block_info blocks[256];
        enum state_t { none, slow, medium, fast };
        state_t piece_state;
};

piece_index is the index of the piece in question. blocks_in_piece is the number of blocks in this particular piece. This number will be the same for most pieces, but the last piece may have fewer blocks than the standard pieces.

piece_state is set to either fast, medium, slow or none. It tells which download rate category the peers downloading this piece falls into. none means that no peer is currently downloading any part of the piece. Peers prefer picking pieces from the same category as themselves. The reason for this is to keep the number of partially downloaded pieces down. Pieces set to none can be converted into any of fast, medium or slow as soon as a peer want to download from it.

struct block_info
{
        enum block_state_t
        { none, requested, writing, finished };

        tcp::endpoint peer;
        unsigned state:2;
        unsigned num_peers:14;
};

The block_info array contains data for each individual block in the piece. Each block has a state (state) which is any of:

  • none - This block has not been downloaded or requested form any peer.
  • requested - The block has been requested, but not completely downloaded yet.
  • writing - The block has been downloaded and is currently queued for being written to disk.
  • finished - The block has been written to disk.

The peer field is the ip address of the peer this block was downloaded from. num_peers is the number of peers that is currently requesting this block. Typically this is 0 or 1, but at the end of the torrent blocks may be requested by more peers in parallel to speed things up.

get_peer_info()

void get_peer_info(std::vector<peer_info>&) const;

get_peer_info() takes a reference to a vector that will be cleared and filled with one entry for each peer connected to this torrent, given the handle is valid. If the torrent_handle is invalid, it will throw invalid_handle exception. Each entry in the vector contains information about that particular peer. See peer_info.

get_torrent_info()

torrent_info const& get_torrent_info() const;

Returns a const reference to the torrent_info object associated with this torrent. This reference is valid as long as the torrent_handle is valid, no longer. If the torrent_handle is invalid or if it doesn't have any metadata, invalid_handle exception will be thrown. The torrent may be in a state without metadata only if it was started without a .torrent file, i.e. by using the libtorrent extension of just supplying a tracker and info-hash.

is_valid()

bool is_valid() const;

Returns true if this handle refers to a valid torrent and false if it hasn't been initialized or if the torrent it refers to has been aborted. Note that a handle may become invalid after it has been added to the session. Usually this is because the storage for the torrent is somehow invalid or if the filenames are not allowed (and hence cannot be opened/created) on your filesystem. If such an error occurs, a file_error_alert is generated and all handles that refers to that torrent will become invalid.

TODO: document storage

torrent_status

It contains the following fields:

struct torrent_status
{
        enum state_t
        {
                queued_for_checking,
                checking_files,
                connecting_to_tracker,
                downloading,
                finished,
                seeding,
                allocating
        };

        state_t state;
        bool paused;
        float progress;
        boost::posix_time::time_duration next_announce;
        boost::posix_time::time_duration announce_interval;

        std::string current_tracker;

        size_type total_download;
        size_type total_upload;

        size_type total_payload_download;
        size_type total_payload_upload;

        size_type total_failed_bytes;
        size_type total_redundant_bytes;

        float download_rate;
        float upload_rate;

        float download_payload_rate;
        float upload_payload_rate;

        int num_peers;

        int num_complete;
        int num_incomplete;

        const std::vector<bool>* pieces;
        int num_pieces;

        size_type total_done;
        size_type total_wanted_done;
        size_type total_wanted;

        int num_seeds;
        float distributed_copies;

        int block_size;

        int num_uploads;
        int num_connections;
        int uploads_limit;
        int connections_limit;

        bool compact_mode;
};

progress is a value in the range [0, 1], that represents the progress of the torrent's current task. It may be checking files or downloading. The torrent's current task is in the state member, it will be one of the following:

queued_for_checking The torrent is in the queue for being checked. But there currently is another torrent that are being checked. This torrent will wait for its turn.
checking_files The torrent has not started its download yet, and is currently checking existing files.
connecting_to_tracker The torrent has sent a request to the tracker and is currently waiting for a response
downloading The torrent is being downloaded. This is the state most torrents will be in most of the time. The progress meter will tell how much of the files that has been downloaded.
finished In this state the torrent has finished downloading but still doesn't have the entire torrent. i.e. some pieces are filtered and won't get downloaded.
seeding In this state the torrent has finished downloading and is a pure seeder.
allocating If the torrent was started in full allocation mode, this indicates that the (disk) storage for the torrent is allocated.

When downloading, the progress is total_wanted_done / total_wanted.

paused is set to true if the torrent is paused and false otherwise.

next_announce is the time until the torrent will announce itself to the tracker. And announce_interval is the time the tracker want us to wait until we announce ourself again the next time.

current_tracker is the URL of the last working tracker. If no tracker request has been successful yet, it's set to an empty string.

total_download and total_upload is the number of bytes downloaded and uploaded to all peers, accumulated, this session only.

total_payload_download and total_payload_upload counts the amount of bytes send and received this session, but only the actual payload data (i.e the interesting data), these counters ignore any protocol overhead.

total_failed_bytes is the number of bytes that has been downloaded and that has failed the piece hash test. In other words, this is just how much crap that has been downloaded.

total_redundant_bytes is the number of bytes that has been downloaded even though that data already was downloaded. The reason for this is that in some situations the same data can be downloaded by mistake. When libtorrent sends requests to a peer, and the peer doesn't send a response within a certain timeout, libtorrent will re-request that block. Another situation when libtorrent may re-request blocks is when the requests it sends out are not replied in FIFO-order (it will re-request blocks that are skipped by an out of order block). This is supposed to be as low as possible.

pieces is the bitmask that represents which pieces we have (set to true) and the pieces we don't have. It's a pointer and may be set to 0 if the torrent isn't downloading or seeding.

num_pieces is the number of pieces that has been downloaded. It is equivalent to: std::accumulate(pieces->begin(), pieces->end()). So you don't have to count yourself. This can be used to see if anything has updated since last time if you want to keep a graph of the pieces up to date.

download_rate and upload_rate are the total rates for all peers for this torrent. These will usually have better precision than summing the rates from all peers. The rates are given as the number of bytes per second. The download_payload_rate and upload_payload_rate respectively is the total transfer rate of payload only, not counting protocol chatter. This might be slightly smaller than the other rates, but if projected over a long time (e.g. when calculating ETA:s) the difference may be noticeable.

num_peers is the number of peers this torrent currently is connected to. Peer connections that are in the half-open state (is attempting to connect) or are queued for later connection attempt do not count. Although they are visible in the peer list when you call get_peer_info().

num_complete and num_incomplete are set to -1 if the tracker did not send any scrape data in its announce reply. This data is optional and may not be available from all trackers. If these are not -1, they are the total number of peers that are seeding (complete) and the total number of peers that are still downloading (incomplete) this torrent.

total_done is the total number of bytes of the file(s) that we have. All this does not necessarily has to be downloaded during this session (that's total_download_payload).

total_wanted_done is the number of bytes we have downloaded, only counting the pieces that we actually want to download. i.e. excluding any pieces that we have but are filtered as not wanted.

total_wanted is the total number of bytes we want to download. This is also excluding pieces that have been filtered.

num_seeds is the number of peers that are seeding that this client is currently connected to.

distributed_copies is the number of distributed copies of the torrent. Note that one copy may be spread out among many peers. The integer part tells how many copies there are currently of the rarest piece(s) among the peers this client is connected to. The fractional part tells the share of pieces that have more copies than the rarest piece(s). For example: 2.5 would mean that the rarest pieces have only 2 copies among the peers this torrent is connected to, and that 50% of all the pieces have more than two copies.

If we are a seed, the piece picker is deallocated as an optimization, and piece availability is no longer tracked. In this case the distributed copies is set to -1.

block_size is the size of a block, in bytes. A block is a sub piece, it is the number of bytes that each piece request asks for and the number of bytes that each bit in the partial_piece_info's bitset represents (see get_download_queue()). This is typically 16 kB, but it may be larger if the pieces are larger.

num_uploads is the number of unchoked peers in this torrent.

num_connections is the number of peer connections this torrent has, including half-open connections that hasn't completed the bittorrent handshake yet. This is always <= num_peers.

uploads_limit is the set limit of upload slots (unchoked peers) for this torrent.

connections_limit is the set limit of number of connections for this torrent.

compact_mode is true if this torrent was started with compact allocation mode for its storage. False means it was started in full allocation mode.

peer_info

It contains the following fields:

struct peer_info
{
        enum
        {
                interesting = 0x1,
                choked = 0x2,
                remote_interested = 0x4,
                remote_choked = 0x8,
                supports_extensions = 0x10,
                local_connection = 0x20,
                handshake = 0x40,
                connecting = 0x80,
                queued = 0x100,
                on_parole = 0x200,
                seed = 0x400,
                optimistic_unchoke = 0x800,
                rc4_encrypted = 0x100000,
                plaintext_encrypted = 0x200000
        };

        unsigned int flags;

        enum peer_source_flags
        {
                tracker = 0x1,
                dht = 0x2,
                pex = 0x4,
                lsd = 0x8
        };

        int source;

        asio::ip::tcp::endpoint ip;
        float up_speed;
        float down_speed;
        float payload_up_speed;
        float payload_down_speed;
        size_type total_download;
        size_type total_upload;
        peer_id pid;
        std::vector<bool> pieces;
        int upload_limit;
        int download_limit;

        char country[2];

        size_type load_balancing;

        int download_queue_length;
        int upload_queue_length;

        int downloading_piece_index;
        int downloading_block_index;
        int downloading_progress;
        int downloading_total;

        std::string client;

        enum
        {
                standard_bittorrent = 0,
                web_seed = 1
        };
        int connection_type;
};

The flags attribute tells you in which state the peer is. It is set to any combination of the enums above. The following table describes each flag:

interesting we are interested in pieces from this peer.
choked we have choked this peer.
remote_interested the peer is interested in us
remote_choked the peer has choked us.
support_extensions means that this peer supports the extension protocol.
local_connection The connection was initiated by us, the peer has a listen port open, and that port is the same as in the address of this peer. If this flag is not set, this peer connection was opened by this peer connecting to us.
handshake The connection is opened, and waiting for the handshake. Until the handshake is done, the peer cannot be identified.
connecting The connection is in a half-open state (i.e. it is being connected).
queued The connection is currently queued for a connection attempt. This may happen if there is a limit set on the number of half-open TCP connections.
on_parole The peer has participated in a piece that failed the hash check, and is now "on parole", which means we're only requesting whole pieces from this peer until it either fails that piece or proves that it doesn't send bad data.
seed This peer is a seed (it has all the pieces).
optimistic_unchoke This peer is subject to an optimistic unchoke. It has been unchoked for a while to see if it might unchoke us in return an earn an upload/unchoke slot. If it doesn't within some period of time, it will be choked and another peer will be optimistically unchoked.

source is a combination of flags describing from which sources this peer was received. The flags are:

tracker The peer was received from the tracker.
dht The peer was received from the kademlia DHT.
pex The peer was received from the peer exchange extension.
lsd The peer was received from the local service discovery (The peer is on the local network).
resume_data The peer was added from the fast resume data.

The ip field is the IP-address to this peer. The type is an asio endpoint. For more info, see the asio documentation.

up_speed and down_speed contains the current upload and download speed we have to and from this peer (including any protocol messages). The transfer rates of payload data only are found in payload_up_speed and payload_down_speed. These figures are updated approximately once every second.

total_download and total_upload are the total number of bytes downloaded from and uploaded to this peer. These numbers do not include the protocol chatter, but only the payload data.

pid is the peer's id as used in the bit torrent protocol. This id can be used to extract 'fingerprints' from the peer. Sometimes it can tell you which client the peer is using. See identify_client()_

pieces is a vector of booleans that has as many entries as there are pieces in the torrent. Each boolean tells you if the peer has that piece (if it's set to true) or if the peer miss that piece (set to false).

seed is true if this peer is a seed.

upload_limit is the number of bytes per second we are allowed to send to this peer every second. It may be -1 if there's no local limit on the peer. The global limit and the torrent limit is always enforced anyway.

download_limit is the number of bytes per second this peer is allowed to receive. -1 means it's unlimited.

country is the two letter ISO 3166 country code for the country the peer is connected from. If the country hasn't been resolved yet, both chars are set to 0. If the resolution failed for some reason, the field is set to "--". If the resolution service returns an invalid country code, it is set to "!!". The countries.nerd.dk service is used to look up countries. This field will remain set to 0 unless the torrent is set to resolve countries, see resolve_countries().

load_balancing is a measurement of the balancing of free download (that we get) and free upload that we give. Every peer gets a certain amount of free upload, but this member says how much extra free upload this peer has got. If it is a negative number it means that this was a peer from which we have got this amount of free download.

download_queue_length is the number of piece-requests we have sent to this peer that hasn't been answered with a piece yet.

upload_queue_length is the number of piece-requests we have received from this peer that we haven't answered with a piece yet.

You can know which piece, and which part of that piece, that is currently being downloaded from a specific peer by looking at the next four members. downloading_piece_index is the index of the piece that is currently being downloaded. This may be set to -1 if there's currently no piece downloading from this peer. If it is >= 0, the other three members are valid. downloading_block_index is the index of the block (or sub-piece) that is being downloaded. downloading_progress is the number of bytes of this block we have received from the peer, and downloading_total is the total number of bytes in this block.

client is a string describing the software at the other end of the connection. In some cases this information is not available, then it will contain a string that may give away something about which software is running in the other end. In the case of a web seed, the server type and version will be a part of this string.

connection_type can currently be one of standard_bittorrent or web_seed. These are currently the only implemented protocols.

session_settings

You have some control over tracker requests through the session_settings object. You create it and fill it with your settings and then use session::set_settings() to apply them. You have control over proxy and authorization settings and also the user-agent that will be sent to the tracker. The user-agent is a good way to identify your client.

struct session_settings
{
        session_settings();
        std::string user_agent;
        int tracker_completion_timeout;
        int tracker_receive_timeout;
        int stop_tracker_timeout;
        int tracker_maximum_response_length;

        int piece_timeout;
        float request_queue_time;
        int max_allowed_in_request_queue;
        int max_out_request_queue;
        int whole_pieces_threshold;
        int peer_timeout;
        int urlseed_timeout;
        int urlseed_pipeline_size;
        int file_pool_size;
        bool allow_multiple_connections_per_ip;
        int max_failcount;
        int min_reconnect_time;
        int peer_connect_timeout;
        bool ignore_limits_on_local_network;
        int connection_speed;
        int send_redundant_have;
        bool lazy_bitfields;
        int inactivity_timeout;
        bool use_dht_as_fallback;
};

user_agent this is 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.

tracker_completion_timeout is 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.

tracker_receive_timeout is 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.

stop_tracker_timeout is the time to wait for tracker responses when shutting down the session object. This is given in seconds. Default is 10 seconds.

tracker_maximum_response_length is 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.

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

request_queue_time is 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.

max_allowed_in_request_queue is 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 handled) the last request will be dropped. The higher this is, the faster upload speeds the client can get to a single peer.

max_out_request_queue is 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.

whole_pieces_threshold is a limit in seconds. if a whole piece can be downloaded in at least this number of seconds from a specific peer, the peer_connection will prefer requesting 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.

peer_timeout is the number of seconds the peer connection should wait (for any activity on the peer connection) before closing it 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.

urlseed_timeout is the same as peer_timeout but applies only to url seeds. This value defaults to 20 seconds.

urlseed_pipeline_size 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.

file_pool_size is the 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.

allow_multiple_connections_per_ip 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 machie, and all peers in a swarm has the same IP address.

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

min_reconnect_time is the time to wait between connection attempts. If the peer fails, the time is multiplied by fail counter.

peer_connect_timeout 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.

ignore_limits_on_local_network, if set to true, upload, download and unchoke limits are ignored for peers on the local network.

connection_speed is the number of connection attempts that are made per second.

send_redundant_have controls if 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.

lazy_bitfields 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 to prevent certain ISPs from stopping people from seeding.

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

use_dht_as_fallback determines how the DHT is used. If this is true (which it is by default), 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.

pe_settings

The pe_settings structure is used to control the settings related to peer protocol encryption:

struct pe_settings
{
        pe_settings();

        enum enc_policy
        {
                forced,
                enabled,
                disabled
        };

        enum enc_level
        {
                plaintext,
                rc4,
                both
        };

        enc_policy out_enc_policy;
        enc_policy in_enc_policy;
        enc_level allowed_enc_level;
        bool prefer_rc4;
};

in_enc_policy and out_enc_policy control the settings for incoming and outgoing connections respectively. The settings for these are:

  • forced - 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.
  • enabled - 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.
  • disabled - only non-encrypted connections are allowed.

allowed_enc_level 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. The settings are:

  • plaintext - only the handshake is encrypted, the bulk of the traffic remains unchanged.
  • rc4 - the entire stream is encrypted with RC4
  • both - both RC4 and plaintext connections are allowed.

prefer_rc4 can be set to true if you want to prefer the RC4 encrypted stream.

proxy_settings

The proxy_settings structs contains the information needed to direct certain traffic to a proxy.

struct proxy_settings
{
        proxy_settings();

        std::string hostname;
        int port;

        std::string username;
        std::string password;

        enum proxy_type
        {
                none,
                socks4,
                socks5,
                socks5_pw,
                http,
                http_pw
        };

        proxy_type type;
};

hostname is the name or IP of the proxy server. port is the port number the proxy listens to. If required, username and password can be set to authenticate with the proxy.

The type tells libtorrent what kind of proxy server it is. The following options are available:

  • none - This is the default, no proxy server is used, all other fields are ignored.
  • socks4 - The server is assumed to be a SOCKS4 server that requires a username.
  • socks5 - The server is assumed to be a SOCKS5 server (RFC 1928) that does not require any authentication. The username and password are ignored.
  • socks5_pw - The server is assumed to be a SOCKS5 server that supports plain text username and password authentication (RFC 1929). The username and password specified may be sent to the proxy if it requires.
  • http - The server is assumed to be an HTTP proxy. If the transport used for the connection is non-HTTP, the server is assumed to support the CONNECT method. i.e. for web seeds and HTTP trackers, a plain proxy will suffice. The proxy is assumed to not require authorization. The username and password will not be used.
  • http_pw - The server is assumed to be an HTTP proxy that requires user authorization. The username and password will be sent to the proxy.

ip_filter

The ip_filter class is a set of rules that uniquely categorizes all ip addresses as allowed or disallowed. The default constructor creates a single rule that allows all addresses (0.0.0.0 - 255.255.255.255 for the IPv4 range, and the equivalent range covering all addresses for the IPv6 range).

template <class Addr>
struct ip_range
{
        Addr first;
        Addr last;
        int flags;
};

class ip_filter
{
public:
        enum access_flags { blocked = 1 };

        ip_filter();
        void add_rule(address first, address last, int flags);
        int access(address const& addr) const;

        typedef boost::tuple<std::vector<ip_range<address_v4> >
                , std::vector<ip_range<address_v6> > > filter_tuple_t;

        filter_tuple_t export_filter() const;
};

ip_filter()

ip_filter()

Creates a default filter that doesn't filter any address.

postcondition: access(x) == 0 for every x

add_rule()

void add_rule(address first, address last, int flags);

Adds a rule to the filter. first and last defines a range of ip addresses that will be marked with the given flags. The flags can currently be 0, which means allowed, or ip_filter::blocked, which means disallowed.

precondition: first.is_v4() == last.is_v4() && first.is_v6() == last.is_v6()

postcondition: access(x) == flags for every x in the range [first, last]

This means that in a case of overlapping ranges, the last one applied takes precedence.

access()

int access(address const& addr) const;

Returns the access permissions for the given address (addr). The permission can currently be 0 or ip_filter::blocked. The complexity of this operation is O(log n), where n is the minimum number of non-overlapping ranges to describe the current filter.

export_filter()

boost::tuple<std::vector<ip_range<address_v4> >
        , std::vector<ip_range<address_v6> > > export_filter() const;

This function will return the current state of the filter in the minimum number of ranges possible. They are sorted from ranges in low addresses to high addresses. Each entry in the returned vector is a range with the access control specified in its flags field.

The return value is a tuple containing two range-lists. One for IPv4 addresses and one for IPv6 addresses.

big_number

Both the peer_id and sha1_hash types are typedefs of the class big_number. It represents 20 bytes of data. Its synopsis follows:

class big_number
{
public:
        bool operator==(const big_number& n) const;
        bool operator!=(const big_number& n) const;
        bool operator<(const big_number& n) const;

        const unsigned char* begin() const;
        const unsigned char* end() const;

        unsigned char* begin();
        unsigned char* end();
};

The iterators gives you access to individual bytes.

hasher

This class creates sha1-hashes. Its declaration looks like this:

class hasher
{
public:
        hasher();
        hasher(char const* data, unsigned int len);

        void update(char const* data, unsigned int len);
        sha1_hash final();
        void reset();
};

You use it by first instantiating it, then call update() to feed it with data. i.e. you don't have to keep the entire buffer of which you want to create the hash in memory. You can feed the hasher parts of it at a time. When You have fed the hasher with all the data, you call final() and it will return the sha1-hash of the data.

The constructor that takes a char const* and an integer will construct the sha1 context and feed it the data passed in.

If you want to reuse the hasher object once you have created a hash, you have to call reset() to reinitialize it.

The sha1-algorithm used was implemented by Steve Reid and released as public domain. For more info, see src/sha1.cpp.

fingerprint

The fingerprint class represents information about a client and its version. It is used to encode this information into the client's peer id.

This is the class declaration:

struct fingerprint
{
        fingerprint(const char* id_string, int major, int minor
                , int revision, int tag);

        std::string to_string() const;

        char name[2];
        char major_version;
        char minor_version;
        char revision_version;
        char tag_version;

};

The constructor takes a char const* that should point to a string constant containing exactly two characters. These are the characters that should be unique for your client. Make sure not to clash with anybody else. Here are some taken id's:

id chars client
'AZ' Azureus
'LT' libtorrent (default)
'BX' BittorrentX
'MT' Moonlight Torrent
'TS' Torrent Storm
'SS' Swarm Scope
'XT' Xan Torrent

There's currently an informal directory of client id's here.

The major, minor, revision and tag parameters are used to identify the version of your client. All these numbers must be within the range [0, 9].

to_string() will generate the actual string put in the peer-id, and return it.

free functions

identify_client()

std::string identify_client(peer_id const& id);

This function is declared in the header <libtorrent/identify_client.hpp>. It can can be used to extract a string describing a client version from its peer-id. It will recognize most clients that have this kind of identification in the peer-id.

client_fingerprint()

boost::optional<fingerprint> client_fingerprint(peer_id const& p);

Returns an optional fingerprint if any can be identified from the peer id. This can be used to automate the identification of clients. It will not be able to identify peers with non- standard encodings. Only Azureus style, Shadow's style and Mainline style. This function is declared in the header <libtorrent/identify_client.hpp>.

bdecode() bencode()

template<class InIt> entry bdecode(InIt start, InIt end);
template<class OutIt> void bencode(OutIt out, const entry& e);

These functions will encode data to bencoded or decode bencoded data.

The entry class is the internal representation of the bencoded data and it can be used to retrieve information, an entry can also be build by the program and given to bencode() to encode it into the OutIt iterator.

The OutIt and InIt are iterators (InputIterator and OutputIterator respectively). They are templates and are usually instantiated as ostream_iterator, back_insert_iterator or istream_iterator. These functions will assume that the iterator refers to a character (char). So, if you want to encode entry e into a buffer in memory, you can do it like this:

std::vector<char> buffer;
bencode(std::back_inserter(buf), e);

If you want to decode a torrent file from a buffer in memory, you can do it like this:

std::vector<char> buffer;
// ...
entry e = bdecode(buf.begin(), buf.end());

Or, if you have a raw char buffer:

const char* buf;
// ...
entry e = bdecode(buf, buf + data_size);

Now we just need to know how to retrieve information from the entry.

If bdecode() encounters invalid encoded data in the range given to it it will throw invalid_encoding.

supports_sparse_files()

bool supports_sparse_files(boost::filesystem::path const&);

The path is expected to be the path to the directory where you will want to store sparse files. The return value is true if the file system supports sparse files or if it supports automatic zero filling of files. The main characteristics that is tested by this function is not the storage aspects of sparse files, but rather the support for seeking passed end of file and write data there, with expected behavior.

alerts

The pop_alert() function on session is the interface for retrieving alerts, warnings, messages and errors from libtorrent. If there hasn't occurred any errors (matching your severity level) pop_alert() will return a zero pointer. If there has been some error, it will return a pointer to an alert object describing it. You can then use the alert object and query it for information about the error or message. To retrieve any alerts, you have to select a severity level using session::set_severity_level(). It defaults to alert::none, which means that you don't get any messages at all, ever. You have the following levels to select among:

none No alert will ever have this severity level, which effectively filters all messages.
fatal Fatal errors will have this severity level. Examples can be disk full or something else that will make it impossible to continue normal execution.
critical Signals errors that requires user interaction or messages that almost never should be ignored. For example, a chat message received from another peer is announced as severity critical.
warning Messages with the warning severity can be a tracker that times out or responds with invalid data. It will be retried automatically, and the possible next tracker in a multitracker sequence will be tried. It does not require any user interaction.
info Events that can be considered normal, but still deserves an event. This could be a piece hash that fails.
debug This will include a lot of debug events that can be used both for debugging libtorrent but also when debugging other clients that are connected to libtorrent. It will report strange behaviors among the connected peers.

When setting a severity level, you will receive messages of that severity and all messages that are more sever. If you set alert::none (the default) you will not receive any events at all.

When you set a severity level other than none, you have the responsibility to call pop_alert() from time to time. If you don't do that, the alert queue will just grow.

When you get an alert, you can use typeid() or dynamic_cast<> to get more detailed information on exactly which type it is. i.e. what kind of error it is. You can also use a dispatcher mechanism that's available in libtorrent.

All alert types are defined in the <libtorrent/alert_types.hpp> header file.

The alert class is the base class that specific messages are derived from. This is its synopsis:

class alert
{
public:

        enum severity_t { debug, info, warning, critical, fatal, none };

        alert(severity_t severity, std::string const& msg);
        virtual ~alert();

        std::string const& msg() const;
        severity_t severity() const;

        virtual std::auto_ptr<alert> clone() const = 0;
};

This means that all alerts have at least a string describing it. They also have a severity level that can be used to sort them or present them to the user in different ways.

There's another alert base class that all most alerts derives from, all the alerts that are generated for a specific torrent are derived from:

struct torrent_alert: alert
{
        torrent_alert(torrent_handle const& h, severity_t s, std::string const& msg);

        torrent_handle handle;
};

The specific alerts, that all derives from alert, are:

listen_failed_alert

This alert is generated when none of the ports, given in the port range, to session can be opened for listening. This alert is generated as severity level fatal.

struct listen_failed_alert: alert
{
        listen_failed_alert(const std::string& msg);
        virtual std::auto_ptr<alert> clone() const;
};

portmap_error_alert

This alert is generated when a NAT router was successfully found but some part of the port mapping request failed. It contains a text message that may help the user figure out what is wrong. This alert is not generated in case it appears the client is not running on a NAT:ed network or if it appears there is no NAT router that can be remote controlled to add port mappings.

The alert is generated as severity warning, since it should be displayed to the user somehow, and could mean reduced preformance.

struct portmap_error_alert: alert
{
        portmap_error_alert(const std::string& msg);
        virtual std::auto_ptr<alert> clone() const;
};

portmap_alert

This alert is generated when a NAT router was successfully found and a port was successfully mapped on it. On a NAT:ed network with a NAT-PMP capable router, this is typically generated once when mapping the TCP port and, if DHT is enabled, when the UDP port is mapped. This is merely an informational alert, and is generated at severity level info.

struct portmap_alert: alert
{
        portmap_alert(const std::string& msg);
        virtual std::auto_ptr<alert> clone() const;
};

file_error_alert

If the storage fails to read or write files that it needs access to, this alert is generated and the torrent is paused. It is generated as severity level fatal.

struct file_error_alert: torrent_alert
{
        file_error_alert(
                const torrent_handle& h
                , const std::string& msg);

        virtual std::auto_ptr<alert> clone() const;
};

tracker_announce_alert

This alert is generated each time a tracker announce is sent (or attempted to be sent). It is generated at severity level info.

struct tracker_announce_alert: torrent_alert
{
        tracker_announce_alert(
                const torrent_handle& h
                , const std::string& msg);

        virtual std::auto_ptr<alert> clone() const;
};

tracker_alert

This alert is generated on tracker time outs, premature disconnects, invalid response or a HTTP response other than "200 OK". From the alert you can get the handle to the torrent the tracker belongs to. This alert is generated as severity level warning.

The times_in_row member says how many times in a row this tracker has failed. status_code is the code returned from the HTTP server. 401 means the tracker needs authentication, 404 means not found etc. If the tracker timed out, the code will be set to 0.

struct tracker_alert: torrent_alert
{
        tracker_alert(torrent_handle const& h, int times, int status
                , const std::string& msg);
        virtual std::auto_ptr<alert> clone() const;

        int times_in_row;
        int status_code;
};

tracker_reply_alert

This alert is only for informational purpose. It is generated when a tracker announce succeeds. It is generated regardless what kind of tracker was used, be it UDP, HTTP or the DHT. It is generated with severity level info.

struct tracker_reply_alert: torrent_alert
{
        tracker_reply_alert(const torrent_handle& h
                , int num_peers
                , const std::string& msg);

        int num_peers;

        virtual std::auto_ptr<alert> clone() const;
};

The num_peers tells how many peers were returned from the tracker. This is not necessarily all new peers, some of them may already be connected.

tracker_warning_alert

This alert is triggered if the tracker reply contains a warning field. Usually this means that the tracker announce was successful, but the tracker has a message to the client. The message string in the alert will contain the warning message from the tracker. It is generated with severity level warning.

struct tracker_warning_alert: torrent_alert
{
        tracker_warning_alert(torrent_handle const& h
                , std::string const& msg);

        virtual std::auto_ptr<alert> clone() const;
};

url_seed_alert

This alert is generated when a HTTP seed name lookup fails. This alert is generated as severity level warning.

It contains url to the HTTP seed that failed along with an error message.

struct url_seed_alert: torrent_alert
{
        url_seed_alert(torrent_handle const& h, std::string const& url
                , const std::string& msg);
        virtual std::auto_ptr<alert> clone() const;

        std::string url;
};

hash_failed_alert

This alert is generated when a finished piece fails its hash check. You can get the handle to the torrent which got the failed piece and the index of the piece itself from the alert. This alert is generated as severity level info.

struct hash_failed_alert: torrent_alert
{
        hash_failed_alert(
                torrent_handle const& h
                , int index
                , const std::string& msg);

        virtual std::auto_ptr<alert> clone() const;

        int piece_index;
};

peer_ban_alert

This alert is generated when a peer is banned because it has sent too many corrupt pieces to us. It is generated at severity level info. The handle member is a torrent_handle to the torrent that this peer was a member of.

struct peer_ban_alert: torrent_alert
{
        peer_ban_alert(
                asio::ip::tcp::endpoint const& pip
                , torrent_handle h
                , const std::string& msg);

        virtual std::auto_ptr<alert> clone() const;

        asio::ip::tcp::endpoint ip;
};

peer_error_alert

This alert is generated when a peer sends invalid data over the peer-peer protocol. The peer will be disconnected, but you get its ip address from the alert, to identify it. This alert is generated as severity level debug.

struct peer_error_alert: alert
{
        peer_error_alert(
                asio::ip::tcp::endpoint const& pip
                , peer_id const& pid
                , const std::string& msg);

        virtual std::auto_ptr<alert> clone() const;
        asio::ip::tcp::endpoint ip;
        peer_id id;
};

invalid_request_alert

This is a debug alert that is generated by an incoming invalid piece request. The handle is a handle to the torrent the peer is a member of. Ïp is the address of the peer and the request is the actual incoming request from the peer. The alert is generated as severity level debug.

struct invalid_request_alert: torrent_alert
{
        invalid_request_alert(
                peer_request const& r
                , torrent_handle const& h
                , asio::ip::tcp::endpoint const& send
                , peer_id const& pid
                , std::string const& msg);

        virtual std::auto_ptr<alert> clone() const;

        asio::ip::tcp::endpoint ip;
        peer_request request;
        peer_id id;
};


struct peer_request
{
        int piece;
        int start;
        int length;
        bool operator==(peer_request const& r) const;
};

The peer_request contains the values the client sent in its request message. piece is the index of the piece it want data from, start is the offset within the piece where the data should be read, and length is the amount of data it wants.

torrent_finished_alert

This alert is generated when a torrent switches from being a downloader to a seed. It will only be generated once per torrent. It contains a torrent_handle to the torrent in question. This alert is generated as severity level info.

struct torrent_finished_alert: torrent_alert
{
        torrent_finished_alert(
                const torrent_handle& h
                , const std::string& msg);

        virtual std::auto_ptr<alert> clone() const;
};

metadata_failed_alert

This alert is generated when the metadata has been completely received and the info-hash failed to match it. i.e. the metadata that was received was corrupt. libtorrent will automatically retry to fetch it in this case. This is only relevant when running a torrent-less download, with the metadata extension provided by libtorrent. It is generated at severity level info.

struct metadata_failed_alert: torrent_alert
{
        metadata_failed_alert(
                torrent_handle const& h
                , std::string const& msg);

        virtual std::auto_ptr<alert> clone() const;
};

metadata_received_alert

This alert is generated when the metadata has been completely received and the torrent can start downloading. It is not generated on torrents that are started with metadata, but only those that needs to download it from peers (when utilizing the libtorrent extension). It is generated at severity level info.

struct metadata_received_alert: torrent_alert
{
        metadata_received_alert(
                torrent_handle const_& h
                , std::string const& msg);

        virtual std::auto_ptr<alert> clone() const;
};

fastresume_rejected_alert

This alert is generated when a fastresume file has been passed to add_torrent but the files on disk did not match the fastresume file. The string explains the reason why the resume file was rejected. It is generated at severity level warning.

struct fastresume_rejected_alert: torrent_alert
{
        fastresume_rejected_alert(torrent_handle const& h
                , std::string const& msg);

        virtual std::auto_ptr<alert> clone() const;
};

peer_blocked_alert

This alert is generated when a peer is blocked by the IP filter. It has the severity leve info. The ip member is the address that was blocked.

struct peer_blocked_alert: alert
{
        peer_blocked_alert(address const& ip_
                , std::string const& msg);

        address ip;

        virtual std::auto_ptr<alert> clone() const;
};

storage_moved_alert

The storage_moved_alert is generated when all the disk IO has completed and the files have been moved, as an effect of a call to torrent_handle::move_storage. This is useful to synchronize with the actual disk.

struct storage_moved_alert: torrent_alert
{
        storage_moved_alert(torrent_handle const& h, std::string const& path);
        virtual std::auto_ptr<alert> clone() const;
};

torrent_paused_alert

This alert is generated as a response to a torrent_handle::pause request. It is generated once all disk IO is complete and the files in the torrent have been closed. This is useful for synchronizing with the disk.

struct torrent_paused_alert: torrent_alert
{
        torrent_paused_alert(torrent_handle const& h, std::string const& msg);
        virtual std::auto_ptr<alert> clone() const;
};

dispatcher

The handle_alert class is defined in <libtorrent/alert.hpp>.

Examples usage:

struct my_handler
{
        void operator()(portmap_error_alert const& a)
        {
                std::cout << "Portmapper: " << a.msg << std::endl;
        }

        void operator()(tracker_warning_alert const& a)
        {
                std::cout << "Tracker warning: " << a.msg << std::endl;
        }

        void operator()(torrent_finished_alert const& a)
        {
                // write fast resume data
                // ...

                std::cout << a.handle.get_torrent_info().name() << "completed"
                        << std::endl;
        }
};
std::auto_ptr<alert> a;
a = ses.pop_alert();
my_handler h;
while (a.get())
{
        handle_alert<portmap_error_alert
                , tracker_warning_alert
                , torrent_finished_alert
        >::handle_alert(h, a);
        a = ses.pop_alert();
}

In this example 3 alert types are used. You can use any number of template parameters to select between more types. If the number of types are more than 15, you can define TORRENT_MAX_ALERT_TYPES to a greater number before including <libtorrent/alert.hpp>.

exceptions

There are a number of exceptions that can be thrown from different places in libtorrent, here's a complete list with description.

invalid_handle

This exception is thrown when querying information from a torrent_handle that hasn't been initialized or that has become invalid.

struct invalid_handle: std::exception
{
        const char* what() const throw();
};

duplicate_torrent

This is thrown by add_torrent() if the torrent already has been added to the session.

struct duplicate_torrent: std::exception
{
        const char* what() const throw();
};

invalid_encoding

This is thrown by bdecode() if the input data is not a valid bencoding.

struct invalid_encoding: std::exception
{
        const char* what() const throw();
};

type_error

This is thrown from the accessors of entry if the data type of the entry doesn't match the type you want to extract from it.

struct type_error: std::runtime_error
{
        type_error(const char* error);
};

invalid_torrent_file

This exception is thrown from the constructor of torrent_info if the given bencoded information doesn't meet the requirements on what information has to be present in a torrent file.

struct invalid_torrent_file: std::exception
{
        const char* what() const throw();
};

fast resume

The fast resume mechanism is a way to remember which pieces are downloaded and where they are put between sessions. You can generate fast resume data by calling torrent_handle::write_resume_data() on torrent_handle. You can then save this data to disk and use it when resuming the torrent. libtorrent will not check the piece hashes then, and rely on the information given in the fast-resume data. The fast-resume data also contains information about which blocks, in the unfinished pieces, were downloaded, so it will not have to start from scratch on the partially downloaded pieces.

To use the fast-resume data you simply give it to add_torrent(), and it will skip the time consuming checks. It may have to do the checking anyway, if the fast-resume data is corrupt or doesn't fit the storage for that torrent, then it will not trust the fast-resume data and just do the checking.

file format

The file format is a bencoded dictionary containing the following fields:

file-format string: "libtorrent resume file"
file-version integer: 1
info-hash string, the info hash of the torrent this data is saved for.
blocks per piece integer, the number of blocks per piece. Must be: piece_size / (16 * 1024). Clamped to be within the range [1, 256]. It is the number of blocks per (normal sized) piece. Usually each block is 16 * 1024 bytes in size. But if piece size is greater than 4 megabytes, the block size will increase.
slots

list of integers. The list maps slots to piece indices. It tells which piece is on which slot. If piece index is -2 it means it is free, that there's no piece there. If it is -1, means the slot isn't allocated on disk yet. The pieces have to meet the following requirement:

If there's a slot at the position of the piece index, the piece must be located in that slot.

peers

list of dictionaries. Each dictionary has the following layout:

ip string, the ip address of the peer. This is not a binary representation of the ip address, but the string representation. It may be an IPv6 string or an IPv4 string.
port integer, the listen port of the peer

These are the local peers we were connected to when this fast-resume data was saved.

unfinished

list of dictionaries. Each dictionary represents an piece, and has the following layout:

piece integer, the index of the piece this entry refers to.
bitmask string, a binary bitmask representing the blocks that have been downloaded in this piece.
adler32 The adler32 checksum of the data in the blocks specified by bitmask.
file sizes list where each entry corresponds to a file in the file list in the metadata. Each entry has a list of two values, the first value is the size of the file in bytes, the second is the time stamp when the last time someone wrote to it. This information is used to compare with the files on disk. All the files must match exactly this information in order to consider the resume data as current. Otherwise a full re-check is issued.
allocation The allocation mode for the storage. Can be either full or compact. If this is full, the file sizes and timestamps are disregarded. Pieces are assumed not to have moved around even if the files have been modified after the last resume data checkpoint.

threads

libtorrent starts 2 or 3 threads.

  • The first thread is the main thread that will sit idle in a select() call most of the time. This thread runs the main loop that will send and receive data on all connections.
  • The second thread is a hash-check thread. Whenever a torrent is added it will first be passed to this thread for checking the files that may already have been downloaded. If there is any resume data this thread will make sure it is valid and matches the files. Once the torrent has been checked, it is passed on to the main thread that will start it. The hash-check thread has a queue of torrents, it will only check one torrent at a time.
  • The third thread is spawned by asio on systems that don't support non-blocking host name resolution to simulate non-blocking behavior.

storage allocation

There are two modes in which storage (files on disk) are allocated in libtorrent.

  • The traditional full allocation mode, where the entire files are filled up with zeros before anything is downloaded. libtorrent will look for sparse files support in the filesystem that is used for storage, and use sparse files or file system zero fill support if present. This means that on NTFS, full allocation mode will only allocate storage for the downloaded pieces.
  • And the compact allocation mode, where only files are allocated for actual pieces that have been downloaded. This is the default allocation mode in libtorrent.

The allocation mode is selected when a torrent is started. It is passed as a boolean argument to session::add_torrent() (see add_torrent()). These two modes have different drawbacks and benefits.

The decision to use full allocation or compact allocation typically depends on whether any files are filtered and if the filesystem supports sparse files.

To know if the filesystem supports sparse files (and to know if libtorrent believes the filesystem supports sparse files), see supports_sparse_files().

full allocation

When a torrent is started in full allocation mode, the checker thread (see threads) will make sure that the entire storage is allocated, and fill any gaps with zeros. This will be skipped if the filesystem supports sparse files or automatic zero filling. It will of course still check for existing pieces and fast resume data. The main drawbacks of this mode are:

  • It may take longer to start the torrent, since it will need to fill the files with zeros on some systems. This delay is linearly dependent on the size of the download.
  • The download may occupy unnecessary disk space between download sessions. In case sparse files are not supported.
  • Disk caches usually perform extremely poorly with random access to large files and may slow down a download considerably.

The benefits of this mode are:

  • Downloaded pieces are written directly to their final place in the files and the total number of disk operations will be fewer and may also play nicer to filesystems' file allocation, and reduce fragmentation.
  • No risk of a download failing because of a full disk during download. Unless sparse files are being used.
  • The fast resume data will be more likely to be usable, regardless of crashes or out of date data, since pieces won't move around.
  • Can be used with the filter files feature.

compact allocation

The compact allocation will only allocate as much storage as it needs to keep the pieces downloaded so far. This means that pieces will be moved around to be placed at their final position in the files while downloading (to make sure the completed download has all its pieces in the correct place). So, the main drawbacks are:

  • More disk operations while downloading since pieces are moved around.
  • Potentially more fragmentation in the filesystem.
  • Cannot be used while filtering files.

The benefits though, are:

  • No startup delay, since the files doesn't need allocating.
  • The download will not use unnecessary disk space.
  • Disk caches perform much better than in full allocation and raises the download speed limit imposed by the disk.
  • Works well on filesystems that doesn't support sparse files.

The algorithm that is used when allocating pieces and slots isn't very complicated. For the interested, a description follows.

storing a piece:

  1. let A be a newly downloaded piece, with index n.
  2. let s be the number of slots allocated in the file we're downloading to. (the number of pieces it has room for).
  3. if n >= s then allocate a new slot and put the piece there.
  4. if n < s then allocate a new slot, move the data at slot n to the new slot and put A in slot n.

allocating a new slot:

  1. if there's an unassigned slot (a slot that doesn't contain any piece), return that slot index.
  2. append the new slot at the end of the file (or find an unused slot).
  3. let i be the index of newly allocated slot
  4. if we have downloaded piece index i already (to slot j) then
    1. move the data at slot j to slot i.
    2. return slot index j as the newly allocated free slot.
  5. return i as the newly allocated slot.

extensions

These extensions all operates within the extension protocol. The name of the extension is the name used in the extension-list packets, and the payload is the data in the extended message (not counting the length-prefix, message-id nor extension-id).

Note that since this protocol relies on one of the reserved bits in the handshake, it may be incompatible with future versions of the mainline bittorrent client.

These are the extensions that are currently implemented.

metadata from peers

Extension name: "LT_metadata"

The point with this extension is that you don't have to distribute the metadata (.torrent-file) separately. The metadata can be distributed through the bittorrent swarm. The only thing you need to download such a torrent is the tracker url and the info-hash of the torrent.

It works by assuming that the initial seeder has the metadata and that the metadata will propagate through the network as more peers join.

There are three kinds of messages in the metadata extension. These packets are put as payload to the extension message. The three packets are:

  • request metadata
  • metadata
  • don't have metadata

request metadata:

size name description
uint8_t msg_type Determines the kind of message this is 0 means 'request metadata'
uint8_t start The start of the metadata block that is requested. It is given in 256:ths of the total size of the metadata, since the requesting client don't know the size of the metadata.
uint8_t size The size of the metadata block that is requested. This is also given in 256:ths of the total size of the metadata. The size is given as size-1. That means that if this field is set 0, the request wants one 256:th of the metadata.

metadata:

size name description
uint8_t msg_type 1 means 'metadata'
int32_t total_size The total size of the metadata, given in number of bytes.
int32_t offset The offset of where the metadata block in this message belongs in the final metadata. This is given in bytes.
uint8_t[] metadata The actual metadata block. The size of this part is given implicit by the length prefix in the bittorrent protocol packet.

Don't have metadata:

size name description
uint8_t msg_type 2 means 'I don't have metadata'. This message is sent as a reply to a metadata request if the the client doesn't have any metadata.

HTTP seeding

The HTTP seed extension implements this specification.

The libtorrent implementation assumes that, if the URL ends with a slash ('/'), the filename should be appended to it in order to request pieces from that file. The way this works is that if the torrent is a single-file torrent, only that filename is appended. If the torrent is a multi-file torrent, the torrent's name '/' the file name is appended. This is the same directory structure that libtorrent will download torrents into.

filename checks

Boost.Filesystem will by default check all its paths to make sure they conform to filename requirements on many platforms. If you don't want this check, you can set it to either only check for native filesystem requirements or turn it off altogether. You can use:

boost::filesystem::path::default_name_check(boost::filesystem::native);

for example. For more information, see the Boost.Filesystem docs.

acknowledgments

Written by Arvid Norberg. Copyright © 2003-2006

Contributions by Magnus Jonsson, Daniel Wallin and Cory Nelson

Lots of testing, suggestions and contributions by Massaroddel and Tianhao Qiu.

Big thanks to Michael Wojciechowski and Peter Koeleman for making the autotools scripts.

Thanks to Reimond Retz for bugfixes, suggestions and testing

Thanks to University of Ume for providing development and test hardware.

Project is hosted by sourceforge.

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