forked from premiere/premiere-libtorrent
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21 KiB
ReStructuredText
444 lines
21 KiB
ReStructuredText
=================
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libtorrent manual
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=================
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:Author: Arvid Norberg, arvid@libtorrent.org
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:Version: 1.1.7
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.. contents:: Table of contents
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:depth: 2
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:backlinks: none
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tuning libtorrent
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=================
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libtorrent expose most parameters used in the bittorrent engine for
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customization through the ``settings_pack``. This makes it possible to
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test and tweak the parameters for certain algorithms to make a client
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that fits a wide range of needs. From low memory embedded devices to
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servers seeding thousands of torrents. The default settings in libtorrent
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are tuned for an end-user bittorrent client running on a normal desktop
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computer.
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This document describes techniques to benchmark libtorrent performance
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and how parameters are likely to affect it.
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profiling
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=========
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libtorrent is instrumented with a number of counters and gauges you can have
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access to via the ``session_stats_alert``. First, enable these alerts in the
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alert mask::
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settings_pack p;
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p.set_int(settings_mask::alert_mask, alert::stats_notification);
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ses.apply_settings(p);
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Then print alerts to a file::
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std::vector<alert*> alerts;
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ses.pop_alerts(&alerts);
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for (auto* a : alerts) {
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std::cout << a->message() << "\n";
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}
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If you want to separate generic alerts from session stats, you can filter on the
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alert category in the alert, ``alert::category()``.
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The alerts with data will have the type ``session_stats_alert`` and there is one
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``session_log_alert`` that will be posted on startup containing the column names
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for all metrics. Logging this line will greatly simplify interpreting the output.
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The python scrip in ``tools/parse_session_stats.py`` can parse the resulting
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file and produce graphs of relevant stats. It requires gnuplot__.
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__ http://www.gnuplot.info
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reducing memory footprint
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=========================
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These are things you can do to reduce the memory footprint of libtorrent. You get
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some of this by basing your default ``settings_pack`` on the ``min_memory_usage()``
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setting preset function.
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Keep in mind that lowering memory usage will affect performance, always profile
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and benchmark your settings to determine if it's worth the trade-off.
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The typical buffer usage of libtorrent, for a single download, with the cache
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size set to 256 blocks (256 * 16 kiB = 4 MiB) is::
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read cache: 128.6 (2058 kiB)
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write cache: 103.5 (1656 kiB)
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receive buffers: 7.3 (117 kiB)
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send buffers: 4.8 (77 kiB)
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hash temp: 0.001 (19 Bytes)
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The receive buffers is proportional to the number of connections we make, and is
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limited by the total number of connections in the session (default is 200).
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The send buffers is proportional to the number of upload slots that are allowed
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in the session. The default is auto configured based on the observed upload rate.
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The read and write cache can be controlled (see section below).
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The "hash temp" entry size depends on whether or not hashing is optimized for
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speed or memory usage. In this test run it was optimized for memory usage.
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disable disk cache
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------------------
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The bulk of the memory libtorrent will use is used for the disk cache. To save
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the absolute most amount of memory, you can disable the cache by setting
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``settings_pack::cache_size`` to 0. You might want to consider using the cache
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but just disable caching read operations. You do this by settings
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``settings_pack::use_read_cache`` to false. This is the main factor in how much
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memory will be used by the client. Keep in mind that you will degrade performance
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by disabling the cache. You should benchmark the disk access in order to make an
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informed trade-off.
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remove torrents
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---------------
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Torrents that have been added to libtorrent will inevitably use up memory, even
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when it's paused. A paused torrent will not use any peer connection objects or
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any send or receive buffers though. Any added torrent holds the entire .torrent
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file in memory, it also remembers the entire list of peers that it's heard about
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(which can be fairly long unless it's capped). It also retains information about
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which blocks and pieces we have on disk, which can be significant for torrents
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with many pieces.
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If you need to minimize the memory footprint, consider removing torrents from
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the session rather than pausing them. This will likely only make a difference
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when you have a very large number of torrents in a session.
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The downside of removing them is that they will no longer be auto-managed. Paused
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auto managed torrents are scraped periodically, to determine which torrents are
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in the greatest need of seeding, and libtorrent will prioritize to seed those.
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socket buffer sizes
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-------------------
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You can make libtorrent explicitly set the kernel buffer sizes of all its peer
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sockets. If you set this to a low number, you may see reduced throughput, especially
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for high latency connections. It is however an opportunity to save memory per
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connection, and might be worth considering if you have a very large number of
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peer connections. This memory will not be visible in your process, this sets
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the amount of kernel memory is used for your sockets.
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Change this by setting ``settings_pack::recv_socket_buffer_size`` and
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``settings_pack::send_socket_buffer_size``.
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peer list size
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--------------
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The default maximum for the peer list is 4000 peers. For IPv4 peers, each peer
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entry uses 32 bytes, which ends up using 128 kB per torrent. If seeding 4 popular
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torrents, the peer lists alone uses about half a megabyte.
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The default limit is the same for paused torrents as well, so if you have a
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large number of paused torrents (that are popular) it will be even more
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significant.
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If you're short of memory, you should consider lowering the limit. 500 is probably
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enough. You can do this by setting ``settings_pack::max_peerlist_size`` to
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the max number of peers you want in a torrent's peer list. This limit applies per
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torrent. For 5 torrents, the total number of peers in peerlists will be 5 times
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the setting.
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You should also lower the same limit but for paused torrents. It might even make sense
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to set that even lower, since you only need a few peers to start up while waiting
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for the tracker and DHT to give you fresh ones. The max peer list size for paused
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torrents is set by ``settings_pack::max_paused_peerlist_size``.
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The drawback of lowering this number is that if you end up in a position where
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the tracker is down for an extended period of time, your only hope of finding live
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peers is to go through your list of all peers you've ever seen. Having a large
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peer list will also help increase performance when starting up, since the torrent
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can start connecting to peers in parallel with connecting to the tracker.
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send buffer watermark
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---------------------
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The send buffer watermark controls when libtorrent will ask the disk I/O thread
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to read blocks from disk, and append it to a peer's send buffer.
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When the send buffer has fewer than or equal number of bytes as
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``settings_pack::send_buffer_watermark``, the peer will ask the disk I/O thread
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for more data to send. The trade-off here is between wasting memory by having too
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much data in the send buffer, and hurting send rate by starving out the socket,
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waiting for the disk read operation to complete.
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If your main objective is memory usage and you're not concerned about being able
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to achieve high send rates, you can set the watermark to 9 bytes. This will guarantee
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that no more than a single (16 kiB) block will be on the send buffer at a time, for
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all peers. This is the least amount of memory possible for the send buffer.
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You should benchmark your max send rate when adjusting this setting. If you have
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a very fast disk, you are less likely see a performance hit.
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reduce executable size
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----------------------
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Compilers generally add a significant number of bytes to executables that make use
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of C++ exceptions. By disabling exceptions (-fno-exceptions on GCC), you can
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reduce the executable size with up to 45%. In order to build without exception
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support, you need to patch parts of boost.
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Also make sure to optimize for size when compiling.
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Another way of reducing the executable size is to disable code that isn't used.
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There are a number of ``TORRENT_*`` macros that control which features are included
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in libtorrent. If these macros are used to strip down libtorrent, make sure the same
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macros are defined when building libtorrent as when linking against it. If these
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are different the structures will look different from the libtorrent side and from
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the client side and memory corruption will follow.
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One, probably, safe macro to define is ``TORRENT_NO_DEPRECATE`` which removes all
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deprecated functions and struct members. As long as no deprecated functions are
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relied upon, this should be a simple way to eliminate a little bit of code.
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For all available options, see the `building libtorrent`_ secion.
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.. _`building libtorrent`: building.html
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high performance seeding
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========================
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In the case of a high volume seed, there are two main concerns. Performance and scalability.
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This translates into high send rates, and low memory and CPU usage per peer connection.
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file pool
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---------
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libtorrent keeps an LRU file cache. Each file that is opened, is stuck in the cache. The main
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purpose of this is because of anti-virus software that hooks on file-open and file close to
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scan the file. Anti-virus software that does that will significantly increase the cost of
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opening and closing files. However, for a high performance seed, the file open/close might
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be so frequent that it becomes a significant cost. It might therefore be a good idea to allow
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a large file descriptor cache. Adjust this though ``settings_pack::file_pool_size``.
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Don't forget to set a high rlimit for file descriptors in your process as well. This limit
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must be high enough to keep all connections and files open.
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disk cache
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----------
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You typically want to set the cache size to as high as possible. The
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``settings_pack::cache_size`` is specified in 16 kiB blocks. Since you're seeding,
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the cache would be useless unless you also set ``settings_pack::use_read_cache``
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to true.
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In order to increase the possibility of read cache hits, set the
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``settings_pack::cache_expiry`` to a large number. This won't degrade anything as
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long as the client is only seeding, and not downloading any torrents.
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There's a *guided cache* mode. This means the size of the read cache line that's
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stored in the cache is determined based on the upload rate to the peer that
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triggered the read operation. The idea being that slow peers don't use up a
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disproportional amount of space in the cache. This is enabled through
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``settings_pack::guided_read_cache``.
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In cases where the assumption is that the cache is only used as a read-ahead, and that no
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other peer will ever request the same block while it's still in the cache, the read
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cache can be set to be *volatile*. This means that every block that is requested out of
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the read cache is removed immediately. This saves a significant amount of cache space
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which can be used as read-ahead for other peers. To enable volatile read cache, set
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``settings_pack::volatile_read_cache`` to true.
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uTP-TCP mixed mode
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------------------
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libtorrent supports uTP_, which has a delay based congestion controller. In order to
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avoid having a single TCP bittorrent connection completely starve out any uTP connection,
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there is a mixed mode algorithm. This attempts to detect congestion on the uTP peers and
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throttle TCP to avoid it taking over all bandwidth. This balances the bandwidth resources
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between the two protocols. When running on a network where the bandwidth is in such an
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abundance that it's virtually infinite, this algorithm is no longer necessary, and might
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even be harmful to throughput. It is adviced to experiment with the
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``session_setting::mixed_mode_algorithm``, setting it to ``settings_pack::prefer_tcp``.
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This setting entirely disables the balancing and unthrottles all connections. On a typical
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home connection, this would mean that none of the benefits of uTP would be preserved
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(the modem's send buffer would be full at all times) and uTP connections would for the most
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part be squashed by the TCP traffic.
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.. _`uTP`: utp.html
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send buffer low watermark
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-------------------------
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libtorrent uses a low watermark for send buffers to determine when a new piece should
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be requested from the disk I/O subsystem, to be appended to the send buffer. The low
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watermark is determined based on the send rate of the socket. It needs to be large
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enough to not draining the socket's send buffer before the disk operation completes.
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The watermark is bound to a max value, to avoid buffer sizes growing out of control.
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The default max send buffer size might not be enough to sustain very high upload rates,
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and you might have to increase it. It's specified in bytes in
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``settings_pack::send_buffer_watermark``.
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peers
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-----
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First of all, in order to allow many connections, set the global connection limit
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high, ``settings_pack::connections_limit``. Also set the upload rate limit to
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infinite, ``settings_pack::upload_rate_limit``, 0 means infinite.
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When dealing with a large number of peers, it might be a good idea to have slightly
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stricter timeouts, to get rid of lingering connections as soon as possible.
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There are a couple of relevant settings: ``settings_pack::request_timeout``,
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``settings_pack::peer_timeout`` and ``settings_pack::inactivity_timeout``.
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For seeds that are critical for a delivery system, you most likely want to allow
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multiple connections from the same IP. That way two people from behind the same NAT
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can use the service simultaneously. This is controlled by
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``settings_pack::allow_multiple_connections_per_ip``.
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In order to always unchoke peers, turn off automatic unchoke by setting
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``settings_pack::choking_algorithm`` to ``fixed_slot_choker`` and set the number
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of upload slots to a large number via ``settings_pack::unchoke_slots_limit``,
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or use -1 (which means infinite).
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torrent limits
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--------------
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To seed thousands of torrents, you need to increase the ``settings_pack::active_limit``
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and ``settings_pack::active_seeds``.
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SHA-1 hashing
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-------------
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When downloading at very high rates, it is possible to have the CPU be the
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bottleneck for passing every downloaded byte through SHA-1. In order to enable
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calculating SHA-1 hashes in parallel, on multi-core systems, set
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``settings_pack::aio_threads`` to the number of threads libtorrent should
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perform I/O and do SHA-1 hashing in. Only if that thread is close to saturating
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one core does it make sense to increase the number of threads.
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scalability
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===========
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In order to make more efficient use of the libtorrent interface when running a large
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number of torrents simultaneously, one can use the ``session::get_torrent_status()`` call
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together with ``session::refresh_torrent_status()``. Keep in mind that every call into
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libtorrent that return some value have to block your thread while posting a message to
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the main network thread and then wait for a response (calls that don't return any data
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will simply post the message and then immediately return). The time this takes might
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become significant once you reach a few hundred torrents (depending on how many calls
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you make to each torrent and how often). ``get_torrent_status`` lets you query the
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status of all torrents in a single call. This will actually loop through all torrents
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and run a provided predicate function to determine whether or not to include it in
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the returned vector. If you have a lot of torrents, you might want to update the status
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of only certain torrents. For instance, you might only be interested in torrents that
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are being downloaded.
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The intended use of these functions is to start off by calling ``get_torrent_status()``
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to get a list of all torrents that match your criteria. Then call ``refresh_torrent_status()``
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on that list. This will only refresh the status for the torrents in your list, and thus
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ignore all other torrents you might be running. This may save a significant amount of
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time, especially if the number of torrents you're interested in is small. In order to
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keep your list of interested torrents up to date, you can either call ``get_torrent_status()``
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from time to time, to include torrents you might have become interested in since the last
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time. In order to stop refreshing a certain torrent, simply remove it from the list.
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A more efficient way however, would be to subscribe to status alert notifications, and
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update your list based on these alerts. There are alerts for when torrents are added, removed,
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paused, resumed, completed etc. Doing this ensures that you only query status for the
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minimal set of torrents you are actually interested in.
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To get an update with only the torrents that have changed since last time, call
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``session::post_torrent_updates()``.
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benchmarking
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============
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There is a bunch of built-in instrumentation of libtorrent that can be used to get an insight
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into what it's doing and how well it performs. This instrumentation is enabled by defining
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preprocessor symbols when building.
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There are also a number of scripts that parses the log files and generates graphs (requires
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gnuplot and python).
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disk metrics
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------------
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To enable disk I/O instrumentation, define ``TORRENT_DISK_STATS`` when building. When built
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with this configuration libtorrent will create three log files, measuring various aspects of
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the disk I/O. The following table is an overview of these files and what they measure.
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+--------------------------+--------------------------------------------------------------+
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| filename | description |
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+==========================+==============================================================+
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| ``file_access.log`` | This is a low level log of read and write operations, with |
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| | timestamps and file offsets. The file offsets are byte |
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| | offsets in the torrent (not in any particular file, in the |
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| | case of a multi-file torrent). This can be used as an |
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| | estimate of the physical drive location. The purpose of |
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| | this log is to identify the amount of seeking the drive has |
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| | to do. |
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+--------------------------+--------------------------------------------------------------+
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file_access.log
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'''''''''''''''
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The disk access log is a binary file that can be parsed and converted to human
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readable by the script ``tools/parse_access_log.py``. This tool produces a
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graphical representation of the disk access and requires ``gnuplot``.
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understanding the disk threads
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==============================
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*This section is somewhat outdated, there are potentially more than one disk
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thread*
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All disk operations are funneled through a separate thread, referred to as the
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disk thread. The main interface to the disk thread is a queue where disk jobs
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are posted, and the results of these jobs are then posted back on the main
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thread's io_service.
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A disk job is essentially one of:
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1. write this block to disk, i.e. a write job. For the most part this is just a
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matter of sticking the block in the disk cache, but if we've run out of
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cache space or completed a whole piece, we'll also flush blocks to disk.
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This is typically very fast, since the OS just sticks these buffers in its
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write cache which will be flushed at a later time, presumably when the drive
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head will pass the place on the platter where the blocks go.
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2. read this block from disk. The first thing that happens is we look in the
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cache to see if the block is already in RAM. If it is, we'll return
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immediately with this block. If it's a cache miss, we'll have to hit the
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disk. Here we decide to defer this job. We find the physical offset on the
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drive for this block and insert the job in an ordered queue, sorted by the
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physical location. At a later time, once we don't have any more non-read
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jobs left in the queue, we pick one read job out of the ordered queue and
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service it. The order we pick jobs out of the queue is according to an
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elevator cursor moving up and down along the ordered queue of read jobs. If
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we have enough space in the cache we'll read read_cache_line_size number of
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blocks and stick those in the cache. This defaults to 32 blocks. If the
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system supports asynchronous I/O (Windows, Linux, Mac OS X, BSD, Solars for
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instance), jobs will be issued immediately to the OS. This especially
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increases read throughput, since the OS has a much greater flexibility to
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reorder the read jobs.
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Other disk job consist of operations that needs to be synchronized with the
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disk I/O, like renaming files, closing files, flushing the cache, updating the
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settings etc. These are relatively rare though.
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contributions
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=============
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If you have added instrumentation for some part of libtorrent that is not
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covered here, or if you have improved any of the parser scrips, please consider
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contributing it back to the project.
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If you have run tests and found that some algorithm or default value in
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libtorrent are suboptimal, please contribute that knowledge back as well, to
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allow us to improve the library.
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If you have additional suggestions on how to tune libtorrent for any specific
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use case, please let us know and we'll update this document.
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