// This file Copyright 2010-2022 Mnemosyne LLC. // It may be used under GPLv2 (SPDX: GPL-2.0-only), GPLv3 (SPDX: GPL-3.0-only), // or any future license endorsed by Mnemosyne LLC. // License text can be found in the licenses/ folder. #include // std::lldiv() #include // std::distance(), std::next(), std::prev() #include // std::numeric_limits::max() #include // std::accumulate() #include // std::make_pair() #include #include #include "transmission.h" #include "cache.h" #include "inout.h" #include "log.h" #include "torrent.h" #include "torrents.h" #include "tr-assert.h" #include "trevent.h" Cache::Key Cache::makeKey(tr_torrent const* torrent, tr_block_info::Location loc) noexcept { return std::make_pair(torrent->id(), loc.block); } std::pair Cache::findContiguous(CIter const begin, CIter const end, CIter const iter) noexcept { if (iter == end) { return std::make_pair(end, end); } auto span_begin = iter; for (auto key = iter->key;;) { if (span_begin == begin) { break; } --key.second; auto const prev = std::prev(span_begin); if (prev->key != key) { break; } } auto span_end = std::next(iter); for (auto key = iter->key;;) { if (span_end == end) { break; } ++key.second; if (span_end->key != key) { break; } } return std::make_pair(span_begin, span_end); } int Cache::writeContiguous(CIter const begin, CIter const end) const { // join the blocks together into contiguous memory `buf` auto buf = std::vector{}; auto const buflen = std::accumulate( begin, end, size_t{}, [](size_t sum, auto const& block) { return sum + std::size(*block.buf); }); buf.reserve(buflen); for (auto iter = begin; iter != end; ++iter) { TR_ASSERT(begin->key.first == iter->key.first); TR_ASSERT(begin->key.second + std::distance(begin, iter) == iter->key.second); buf.insert(std::end(buf), std::begin(*iter->buf), std::end(*iter->buf)); } TR_ASSERT(std::size(buf) == buflen); // save it auto* const tor = torrents_.get(begin->key.first); auto const loc = tor->blockLoc(begin->key.second); if (auto const err = tr_ioWrite(tor, loc, std::size(buf), std::data(buf)); err != 0) { return err; } ++disk_writes_; disk_write_bytes_ += std::size(buf); return {}; } size_t Cache::getMaxBlocks(int64_t max_bytes) noexcept { return std::lldiv(max_bytes, tr_block_info::BlockSize).quot; } int Cache::setLimit(int64_t new_limit) { max_bytes_ = new_limit; max_blocks_ = getMaxBlocks(new_limit); tr_logAddDebug(fmt::format("Maximum cache size set to {} ({} blocks)", tr_formatter_mem_B(max_bytes_), max_blocks_)); return cacheTrim(); } Cache::Cache(tr_torrents& torrents, int64_t max_bytes) : torrents_{ torrents } , max_blocks_(getMaxBlocks(max_bytes)) , max_bytes_(max_bytes) { } /*** **** ***/ void Cache::writeBlock(tr_torrent_id_t tor_id, tr_block_index_t block, std::unique_ptr>& data) { auto const key = Key{ tor_id, block }; auto iter = std::lower_bound(std::begin(blocks_), std::end(blocks_), key, CompareCacheBlockByKey{}); if (iter == std::end(blocks_) || iter->key != key) { iter = blocks_.emplace(iter); iter->key = key; } iter->time_added = tr_time(); iter->buf = std::move(data); ++cache_writes_; cache_write_bytes_ += std::size(*iter->buf); (void)cacheTrim(); } Cache::CIter Cache::getBlock(tr_torrent const* torrent, tr_block_info::Location loc) noexcept { if (auto const [begin, end] = std::equal_range( std::begin(blocks_), std::end(blocks_), makeKey(torrent, loc), CompareCacheBlockByKey{}); begin < end) { return begin; } return std::end(blocks_); } int Cache::readBlock(tr_torrent* torrent, tr_block_info::Location loc, uint32_t len, uint8_t* setme) { if (auto const iter = getBlock(torrent, loc); iter != std::end(blocks_)) { std::copy_n(std::begin(*iter->buf), len, setme); return {}; } return tr_ioRead(torrent, loc, len, setme); } int Cache::prefetchBlock(tr_torrent* torrent, tr_block_info::Location loc, uint32_t len) { if (auto const iter = getBlock(torrent, loc); iter != std::end(blocks_)) { return {}; // already have it } return tr_ioPrefetch(torrent, loc, len); } /*** **** ***/ int Cache::flushSpan(CIter const begin, CIter const end) { for (auto walk = begin; walk < end;) { auto const [contig_begin, contig_end] = findContiguous(begin, end, walk); if (auto const err = writeContiguous(contig_begin, contig_end); err != 0) { return err; } walk = contig_end; } blocks_.erase(begin, end); return {}; } int Cache::flushFile(tr_torrent* torrent, tr_file_index_t i) { auto const compare = CompareCacheBlockByKey{}; auto const tor_id = torrent->id(); auto const [block_begin, block_end] = tr_torGetFileBlockSpan(torrent, i); return flushSpan( std::lower_bound(std::begin(blocks_), std::end(blocks_), std::make_pair(tor_id, block_begin), compare), std::lower_bound(std::begin(blocks_), std::end(blocks_), std::make_pair(tor_id, block_end), compare)); } int Cache::flushTorrent(tr_torrent* torrent) { auto const compare = CompareCacheBlockByKey{}; auto const tor_id = torrent->id(); return flushSpan( std::lower_bound(std::begin(blocks_), std::end(blocks_), std::make_pair(tor_id, 0), compare), std::lower_bound(std::begin(blocks_), std::end(blocks_), std::make_pair(tor_id + 1, 0), compare)); } int Cache::flushOldest() { auto const oldest = std::min_element( std::begin(blocks_), std::end(blocks_), [](auto const& a, auto const& b) { return a.time_added < b.time_added; }); if (oldest == std::end(blocks_)) // nothing to flush { return 0; } auto const [begin, end] = findContiguous(std::begin(blocks_), std::end(blocks_), oldest); if (auto const err = writeContiguous(begin, end); err != 0) { return err; } blocks_.erase(begin, end); return 0; } int Cache::cacheTrim() { while (std::size(blocks_) > max_blocks_) { if (auto const err = flushOldest(); err != 0) { return err; } } return 0; }