/* Copyright (c) 2006-2016, Arvid Norberg All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the author nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "libtorrent/config.hpp" #include "libtorrent/assert.hpp" #include "libtorrent/file_pool.hpp" #include "libtorrent/error_code.hpp" #include "libtorrent/file_storage.hpp" #include "libtorrent/units.hpp" #include "libtorrent/disk_interface.hpp" #include "libtorrent/aux_/path.hpp" #ifdef TORRENT_WINDOWS #include "libtorrent/aux_/win_util.hpp" #endif #include namespace libtorrent { file_pool::file_pool(int size) : m_size(size) {} file_pool::~file_pool() = default; #ifdef TORRENT_WINDOWS void set_low_priority(file_handle const& f) { // file prio is only supported on vista and up // so load the functions dynamically typedef enum { FileBasicInfo, FileStandardInfo, FileNameInfo, FileRenameInfo, FileDispositionInfo, FileAllocationInfo, FileEndOfFileInfo, FileStreamInfo, FileCompressionInfo, FileAttributeTagInfo, FileIdBothDirectoryInfo, FileIdBothDirectoryRestartInfo, FileIoPriorityHintInfo, FileRemoteProtocolInfo, MaximumFileInfoByHandleClass } FILE_INFO_BY_HANDLE_CLASS_LOCAL; typedef enum { IoPriorityHintVeryLow = 0, IoPriorityHintLow, IoPriorityHintNormal, MaximumIoPriorityHintType } PRIORITY_HINT_LOCAL; typedef struct { PRIORITY_HINT_LOCAL PriorityHint; } FILE_IO_PRIORITY_HINT_INFO_LOCAL; typedef BOOL (WINAPI *SetFileInformationByHandle_t)(HANDLE hFile, FILE_INFO_BY_HANDLE_CLASS_LOCAL FileInformationClass, LPVOID lpFileInformation, DWORD dwBufferSize); auto SetFileInformationByHandle = aux::get_library_procedure("SetFileInformationByHandle"); if (SetFileInformationByHandle == nullptr) return; FILE_IO_PRIORITY_HINT_INFO_LOCAL io_hint; io_hint.PriorityHint = IoPriorityHintLow; SetFileInformationByHandle(f->native_handle(), FileIoPriorityHintInfo, &io_hint, sizeof(io_hint)); } #endif // TORRENT_WINDOWS file_handle file_pool::open_file(storage_index_t st, std::string const& p , file_index_t const file_index, file_storage const& fs , std::uint32_t const m, error_code& ec) { // potentially used to hold a reference to a file object that's // about to be destructed. If we have such object we assign it to // this member to be destructed after we release the std::mutex. On some // operating systems (such as OSX) closing a file may take a long // time. We don't want to hold the std::mutex for that. file_handle defer_destruction; std::unique_lock l(m_mutex); #if TORRENT_USE_ASSERTS // we're not allowed to open a file // from a deleted storage! TORRENT_ASSERT(std::find(m_deleted_storages.begin(), m_deleted_storages.end() , std::make_pair(fs.name(), static_cast(&fs))) == m_deleted_storages.end()); #endif TORRENT_ASSERT(is_complete(p)); TORRENT_ASSERT((m & file::rw_mask) == file::read_only || (m & file::rw_mask) == file::read_write); auto const i = m_files.find(std::make_pair(st, file_index)); if (i != m_files.end()) { lru_file_entry& e = i->second; e.last_use = aux::time_now(); // if we asked for a file in write mode, // and the cached file is is not opened in // write mode, re-open it if ((((e.mode & file::rw_mask) != file::read_write) && ((m & file::rw_mask) == file::read_write)) || (e.mode & file::random_access) != (m & file::random_access)) { file_handle new_file = std::make_shared(); std::string full_path = fs.file_path(file_index, p); if (!new_file->open(full_path, m, ec)) return file_handle(); #ifdef TORRENT_WINDOWS if (m_low_prio_io) set_low_priority(new_file); #endif TORRENT_ASSERT(new_file->is_open()); defer_destruction = std::move(e.file_ptr); e.file_ptr = std::move(new_file); e.mode = m; } return e.file_ptr; } lru_file_entry e; e.file_ptr = std::make_shared(); if (!e.file_ptr) { ec = error_code(boost::system::errc::not_enough_memory, generic_category()); return file_handle(); } std::string full_path = fs.file_path(file_index, p); if (!e.file_ptr->open(full_path, m, ec)) return file_handle(); #ifdef TORRENT_WINDOWS if (m_low_prio_io) set_low_priority(e.file_ptr); #endif e.mode = m; file_handle file_ptr = e.file_ptr; m_files.insert(std::make_pair(std::make_pair(st, file_index), e)); TORRENT_ASSERT(file_ptr->is_open()); if (int(m_files.size()) >= m_size) { // the file cache is at its maximum size, close // the least recently used (lru) file from it remove_oldest(l); } return file_ptr; } namespace { std::uint32_t to_file_open_mode(std::uint32_t const mode) { std::uint32_t ret = 0; switch (mode & file::rw_mask) { case file::read_only: ret = file_open_mode::read_only; break; case file::write_only: ret = file_open_mode::write_only; break; case file::read_write: ret = file_open_mode::read_write; break; } if (mode & file::sparse) ret |= file_open_mode::sparse; if (mode & file::no_atime) ret |= file_open_mode::no_atime; if (mode & file::random_access) ret |= file_open_mode::random_access; if (mode & file::lock_file) ret |= file_open_mode::locked; return ret; } } std::vector file_pool::get_status(storage_index_t const st) const { std::vector ret; { std::unique_lock l(m_mutex); auto const start = m_files.lower_bound(std::make_pair(st, file_index_t(0))); auto const end = m_files.upper_bound(std::make_pair(st , std::numeric_limits::max())); for (auto i = start; i != end; ++i) { ret.push_back({i->first.second, to_file_open_mode(i->second.mode) , i->second.last_use}); } } return ret; } void file_pool::remove_oldest(std::unique_lock& l) { using value_type = decltype(m_files)::value_type; auto const i = std::min_element(m_files.begin(), m_files.end() , [] (value_type const& lhs, value_type const& rhs) { return lhs.second.last_use < rhs.second.last_use; }); if (i == m_files.end()) return; file_handle file_ptr = i->second.file_ptr; m_files.erase(i); // closing a file may be long running operation (mac os x) l.unlock(); file_ptr.reset(); l.lock(); } void file_pool::release(storage_index_t const st, file_index_t file_index) { std::unique_lock l(m_mutex); auto const i = m_files.find(std::make_pair(st, file_index)); if (i == m_files.end()) return; file_handle file_ptr = i->second.file_ptr; m_files.erase(i); // closing a file may take a long time (mac os x), so make sure // we're not holding the mutex l.unlock(); file_ptr.reset(); } // closes files belonging to the specified // storage, or all if none is specified. void file_pool::release() { std::unique_lock l(m_mutex); m_files.clear(); l.unlock(); } void file_pool::release(storage_index_t const st) { std::unique_lock l(m_mutex); auto const begin = m_files.lower_bound(std::make_pair(st, file_index_t(0))); auto const end = m_files.upper_bound(std::make_pair(st , std::numeric_limits::max())); std::vector to_close; for (auto it = begin; it != end; ++it) to_close.push_back(std::move(it->second.file_ptr)); if (!to_close.empty()) m_files.erase(begin, end); l.unlock(); // the files are closed here while the lock is not held } #if TORRENT_USE_ASSERTS void file_pool::mark_deleted(file_storage const& fs) { std::unique_lock l(m_mutex); m_deleted_storages.push_back(std::make_pair(fs.name() , static_cast(&fs))); if(m_deleted_storages.size() > 100) m_deleted_storages.erase(m_deleted_storages.begin()); } bool file_pool::assert_idle_files(storage_index_t const st) const { std::unique_lock l(m_mutex); for (auto const& i : m_files) { if (i.first.first == st && !i.second.file_ptr.unique()) return false; } return true; } #endif void file_pool::resize(int size) { std::unique_lock l(m_mutex); TORRENT_ASSERT(size > 0); if (size == m_size) return; m_size = size; if (int(m_files.size()) <= m_size) return; // close the least recently used files while (int(m_files.size()) > m_size) remove_oldest(l); } void file_pool::close_oldest() { std::unique_lock l(m_mutex); using value_type = decltype(m_files)::value_type; auto const i = std::min_element(m_files.begin(), m_files.end() , [] (value_type const& lhs, value_type const& rhs) { return lhs.second.opened < rhs.second.opened; }); if (i == m_files.end()) return; file_handle file_ptr = i->second.file_ptr; m_files.erase(i); // closing a file may be long running operation (mac os x) l.unlock(); file_ptr.reset(); l.lock(); } }