/* This file is part of Telegram Desktop, the official desktop application for the Telegram messaging service. For license and copyright information please follow this link: https://github.com/telegramdesktop/tdesktop/blob/master/LEGAL */ #include "media/streaming/media_streaming_reader.h" #include "media/streaming/media_streaming_common.h" #include "media/streaming/media_streaming_loader.h" #include "storage/cache/storage_cache_database.h" namespace Media { namespace Streaming { namespace { constexpr auto kPartSize = Loader::kPartSize; constexpr auto kPartsInSlice = 64; constexpr auto kInSlice = uint32(kPartsInSlice * kPartSize); constexpr auto kMaxPartsInHeader = 64; constexpr auto kMaxOnlyInHeader = 80 * kPartSize; constexpr auto kPartsOutsideFirstSliceGood = 8; constexpr auto kSlicesInMemory = 2; // 1 MB of parts are requested from cloud ahead of reading demand. constexpr auto kPreloadPartsAhead = 8; constexpr auto kDownloaderRequestsLimit = 4; using PartsMap = base::flat_map; struct ParsedCacheEntry { PartsMap parts; std::optional included; }; bool IsContiguousSerialization(int serializedSize, int maxSliceSize) { return !(serializedSize % kPartSize) || (serializedSize == maxSliceSize); } bool IsFullInHeader(int64 size) { return (size <= kMaxOnlyInHeader); } bool ComputeIsGoodHeader(int64 size, const PartsMap &header) { if (IsFullInHeader(size)) { return false; } const auto outsideFirstSliceIt = ranges::lower_bound( header, kInSlice, ranges::less(), &PartsMap::value_type::first); const auto outsideFirstSlice = end(header) - outsideFirstSliceIt; return (outsideFirstSlice <= kPartsOutsideFirstSliceGood); } int SlicesCount(uint32 size) { const auto result = (size + kInSlice - 1) / kInSlice; Ensures(result < 0x1FFU); return result; } int MaxSliceSize(int sliceNumber, uint32 size) { return !sliceNumber ? size : (sliceNumber == SlicesCount(size)) ? (size - (sliceNumber - 1) * kInSlice) : kInSlice; } bytes::const_span ParseComplexCachedMap( PartsMap &result, bytes::const_span data, int maxSize) { const auto takeInt = [&]() -> std::optional { if (data.size() < sizeof(uint32)) { return std::nullopt; } const auto bytes = data.data(); const auto result = *reinterpret_cast(bytes); data = data.subspan(sizeof(uint32)); return result; }; const auto takeBytes = [&](int count) { if (count <= 0 || data.size() < count) { return bytes::const_span(); } const auto result = data.subspan(0, count); data = data.subspan(count); return result; }; const auto maybeCount = takeInt(); if (!maybeCount) { return {}; } const auto count = *maybeCount; if (!count || count > (kMaxOnlyInHeader / kPartSize)) { return data; } for (auto i = 0; i != count; ++i) { const auto offset = takeInt().value_or(0); const auto size = takeInt().value_or(0); const auto bytes = takeBytes(size); if (offset >= maxSize || !size || size > maxSize || offset + size > maxSize || bytes.size() != size) { return {}; } result.try_emplace( offset, reinterpret_cast(bytes.data()), bytes.size()); } return data; } bytes::const_span ParseCachedMap( PartsMap &result, bytes::const_span data, int maxSize) { const auto size = int(data.size()); if (IsContiguousSerialization(size, maxSize)) { if (size > maxSize) { return {}; } for (auto offset = 0; offset < size; offset += kPartSize) { const auto part = data.subspan( offset, std::min(kPartSize, size - offset)); result.try_emplace( uint32(offset), reinterpret_cast(part.data()), part.size()); } return {}; } return ParseComplexCachedMap(result, data, maxSize); } ParsedCacheEntry ParseCacheEntry( bytes::const_span data, int sliceNumber, int64 size) { auto result = ParsedCacheEntry(); const auto remaining = ParseCachedMap( result.parts, data, MaxSliceSize(sliceNumber, size)); if (!sliceNumber && ComputeIsGoodHeader(size, result.parts)) { result.included = PartsMap(); ParseCachedMap(*result.included, remaining, MaxSliceSize(1, size)); } return result; } template // Range::value_type is Pair uint32 FindNotLoadedStart(Range &&parts, uint32 offset) { auto result = offset; for (const auto &part : parts) { const auto partStart = part.first; const auto partEnd = partStart + part.second.size(); if (partStart <= result && partEnd >= result) { result = partEnd; } else { break; } } return result; } template // Range::value_type is Pair void CopyLoaded( bytes::span buffer, Range &&parts, uint32 offset, uint32 till) { auto filled = offset; for (const auto &part : parts) { const auto bytes = bytes::make_span(part.second); const auto partStart = part.first; const auto partEnd = uint32(partStart + bytes.size()); const auto copyTill = std::min(partEnd, till); Assert(partStart <= filled && filled < copyTill); const auto from = filled - partStart; const auto copy = copyTill - filled; bytes::copy(buffer, bytes.subspan(from, copy)); buffer = buffer.subspan(copy); filled += copy; } } } // namespace template bool Reader::StackIntVector::add(uint32 value) { using namespace rpl::mappers; const auto i = ranges::find_if(_storage, _1 == uint32(-1)); if (i == end(_storage)) { return false; } *i = value; const auto next = i + 1; if (next != end(_storage)) { *next = -1; } return true; } template auto Reader::StackIntVector::values() const { using namespace rpl::mappers; return ranges::views::all( _storage ) | ranges::views::take_while(_1 != uint32(-1)); } struct Reader::CacheHelper { explicit CacheHelper(Storage::Cache::Key baseKey); Storage::Cache::Key key(int sliceNumber) const; const Storage::Cache::Key baseKey; QMutex mutex; base::flat_map results; std::vector sizes; std::atomic waiting = nullptr; }; Reader::CacheHelper::CacheHelper(Storage::Cache::Key baseKey) : baseKey(baseKey) { } Storage::Cache::Key Reader::CacheHelper::key(int sliceNumber) const { return Storage::Cache::Key{ baseKey.high, baseKey.low + sliceNumber }; } void Reader::Slice::processCacheData(PartsMap &&data) { Expects((flags & Flag::LoadingFromCache) != 0); Expects(!(flags & Flag::LoadedFromCache)); const auto guard = gsl::finally([&] { flags |= Flag::LoadedFromCache; flags &= ~Flag::LoadingFromCache; }); if (parts.empty()) { parts = std::move(data); } else { for (auto &[offset, bytes] : data) { parts.emplace(offset, std::move(bytes)); } } } void Reader::Slice::addPart(uint32 offset, QByteArray bytes) { Expects(!parts.contains(offset)); parts.emplace(offset, std::move(bytes)); if (flags & Flag::LoadedFromCache) { flags |= Flag::ChangedSinceCache; } } auto Reader::Slice::prepareFill( uint32 from, uint32 till) -> PrepareFillResult { auto result = PrepareFillResult(); result.ready = false; const auto fromOffset = (from / kPartSize) * kPartSize; const auto tillPart = (till + kPartSize - 1) / kPartSize; const auto preloadTillOffset = (tillPart + kPreloadPartsAhead) * kPartSize; const auto after = ranges::upper_bound( parts, from, ranges::less(), &PartsMap::value_type::first); if (after == begin(parts)) { result.offsetsFromLoader = offsetsFromLoader( fromOffset, preloadTillOffset); return result; } const auto start = after - 1; const auto finish = ranges::lower_bound( start, end(parts), till, ranges::less(), &PartsMap::value_type::first); const auto haveTill = FindNotLoadedStart( ranges::make_subrange(start, finish), fromOffset); if (haveTill < till) { result.offsetsFromLoader = offsetsFromLoader( haveTill, preloadTillOffset); return result; } result.ready = true; result.start = start; result.finish = finish; result.offsetsFromLoader = offsetsFromLoader( tillPart * kPartSize, preloadTillOffset); return result; } auto Reader::Slice::offsetsFromLoader(uint32 from, uint32 till) const -> StackIntVector { auto result = StackIntVector(); const auto after = ranges::upper_bound( parts, from, ranges::less(), &PartsMap::value_type::first); auto check = (after == begin(parts)) ? after : (after - 1); const auto end = parts.end(); for (auto offset = from; offset != till; offset += kPartSize) { while (check != end && check->first < offset) { ++check; } if (check != end && check->first == offset) { continue; } else if (!result.add(offset)) { break; } } return result; } Reader::Slices::Slices(uint32 size, bool useCache) : _size(size) { Expects(size > 0); if (useCache) { _header.flags |= Slice::Flag::LoadingFromCache; } else { _headerMode = HeaderMode::NoCache; } if (!isFullInHeader()) { _data.resize(SlicesCount(_size)); } } bool Reader::Slices::headerModeUnknown() const { return (_headerMode == HeaderMode::Unknown); } bool Reader::Slices::isFullInHeader() const { return IsFullInHeader(_size); } bool Reader::Slices::isGoodHeader() const { return (_headerMode == HeaderMode::Good); } bool Reader::Slices::computeIsGoodHeader() const { return ComputeIsGoodHeader(_size, _header.parts); } void Reader::Slices::headerDone(bool fromCache) { if (_headerMode != HeaderMode::Unknown) { return; } _headerMode = isFullInHeader() ? HeaderMode::Full : computeIsGoodHeader() ? HeaderMode::Good : HeaderMode::Small; if (!fromCache) { for (auto &slice : _data) { using Flag = Slice::Flag; Assert(!(slice.flags & (Flag::LoadingFromCache | Flag::LoadedFromCache))); slice.flags |= Slice::Flag::LoadedFromCache; } } } int Reader::Slices::headerSize() const { return _header.parts.size() * kPartSize; } bool Reader::Slices::fullInCache() const { return _fullInCache; } int Reader::Slices::requestSliceSizesCount() const { if (!headerModeUnknown() || isFullInHeader()) { return 0; } return _data.size(); } bool Reader::Slices::headerWontBeFilled() const { return headerModeUnknown() && (_header.parts.size() >= kMaxPartsInHeader); } void Reader::Slices::applyHeaderCacheData() { using namespace rpl::mappers; const auto applyWhile = [&](auto &&predicate) { for (const auto &[offset, part] : _header.parts) { const auto index = int(offset / kInSlice); if (!predicate(index)) { break; } _data[index].addPart( offset - index * kInSlice, base::duplicate(part)); } }; if (_header.parts.empty()) { return; } else if (_headerMode == HeaderMode::Good) { // Always apply data to first block if it is cached in the header. applyWhile(_1 == 0); } else if (_headerMode != HeaderMode::Unknown) { return; } else if (isFullInHeader()) { headerDone(true); } else { applyWhile(_1 < int(_data.size())); headerDone(true); } } void Reader::Slices::processCacheResult(int sliceNumber, PartsMap &&result) { Expects(sliceNumber >= 0 && sliceNumber <= _data.size()); auto &slice = (sliceNumber ? _data[sliceNumber - 1] : _header); if (!sliceNumber && isGoodHeader()) { // We've loaded header slice because really we wanted first slice. if (!(_data[0].flags & Slice::Flag::LoadingFromCache)) { // We could've already unloaded this slice using LRU _usedSlices. return; } // So just process whole result even if we didn't want header really. slice.flags |= Slice::Flag::LoadingFromCache; slice.flags &= ~Slice::Flag::LoadedFromCache; } if (!(slice.flags & Slice::Flag::LoadingFromCache)) { // We could've already unloaded this slice using LRU _usedSlices. return; } slice.processCacheData(std::move(result)); checkSliceFullLoaded(sliceNumber); if (!sliceNumber) { applyHeaderCacheData(); if (isGoodHeader()) { // When we first read header we don't request the first slice. // But we get it, so let's apply it anyway. _data[0].flags |= Slice::Flag::LoadingFromCache; } } } void Reader::Slices::processCachedSizes(const std::vector &sizes) { Expects(sizes.size() == _data.size()); using Flag = Slice::Flag; const auto count = int(sizes.size()); auto loadedCount = 0; for (auto i = 0; i != count; ++i) { const auto sliceNumber = (i + 1); const auto sliceSize = (sliceNumber < _data.size()) ? kInSlice : (_size - (sliceNumber - 1) * kInSlice); const auto loaded = (sizes[i] == sliceSize); if (_data[i].flags & Flag::FullInCache) { ++loadedCount; } else if (loaded) { _data[i].flags |= Flag::FullInCache; ++loadedCount; } } _fullInCache = (loadedCount == count); } void Reader::Slices::checkSliceFullLoaded(int sliceNumber) { if (!sliceNumber && !isFullInHeader()) { return; } const auto partsCount = [&] { if (!sliceNumber) { return (_size + kPartSize - 1) / kPartSize; } return (sliceNumber < _data.size()) ? kPartsInSlice : ((_size - (sliceNumber - 1) * kInSlice + kPartSize - 1) / kPartSize); }(); auto &slice = (sliceNumber ? _data[sliceNumber - 1] : _header); const auto loaded = (slice.parts.size() == partsCount); using Flag = Slice::Flag; if ((slice.flags & Flag::FullInCache) && !loaded) { slice.flags &= ~Flag::FullInCache; _fullInCache = false; } else if (!(slice.flags & Flag::FullInCache) && loaded) { slice.flags |= Flag::FullInCache; _fullInCache = checkFullInCache(); } } bool Reader::Slices::checkFullInCache() const { using Flag = Slice::Flag; if (isFullInHeader()) { return (_header.flags & Flag::FullInCache); } return ranges::none_of(_data, [](const Slice &slice) { return !(slice.flags & Flag::FullInCache); }); } void Reader::Slices::processPart( uint32 offset, QByteArray &&bytes) { Expects(isFullInHeader() || (offset / kInSlice < _data.size())); if (isFullInHeader()) { _header.addPart(offset, bytes); checkSliceFullLoaded(0); return; } else if (_headerMode == HeaderMode::Unknown) { if (_header.parts.contains(offset)) { return; } else if (_header.parts.size() < kMaxPartsInHeader) { _header.addPart(offset, bytes); } } const auto index = offset / kInSlice; _data[index].addPart(offset - index * kInSlice, std::move(bytes)); checkSliceFullLoaded(index + 1); } auto Reader::Slices::fill(uint32 offset, bytes::span buffer) -> FillResult { Expects(!buffer.empty()); Expects(offset < _size); Expects(offset + buffer.size() <= _size); Expects(buffer.size() <= kInSlice); using Flag = Slice::Flag; if (_headerMode != HeaderMode::NoCache && !(_header.flags & Flag::LoadedFromCache)) { // Waiting for initial cache query. Assert(waitingForHeaderCache()); return {}; } else if (isFullInHeader()) { return fillFromHeader(offset, buffer); } auto result = FillResult(); const auto till = uint32(offset + buffer.size()); const auto fromSlice = offset / kInSlice; const auto tillSlice = (till + kInSlice - 1) / kInSlice; Assert((fromSlice + 1 == tillSlice || fromSlice + 2 == tillSlice) && tillSlice <= _data.size()); const auto cacheNotLoaded = [&](int sliceIndex) { return (_headerMode != HeaderMode::NoCache) && (_headerMode != HeaderMode::Unknown) && !(_data[sliceIndex].flags & Flag::LoadedFromCache); }; const auto handlePrepareResult = [&]( int sliceIndex, const Slice::PrepareFillResult &prepared) { if (cacheNotLoaded(sliceIndex)) { return; } for (const auto offset : prepared.offsetsFromLoader.values()) { const auto full = offset + sliceIndex * kInSlice; if (offset < kInSlice && full < _size) { result.offsetsFromLoader.add(full); } } }; const auto handleReadFromCache = [&](int sliceIndex) { if (cacheNotLoaded(sliceIndex)) { if (!(_data[sliceIndex].flags & Flag::LoadingFromCache)) { _data[sliceIndex].flags |= Flag::LoadingFromCache; result.sliceNumbersFromCache.add(sliceIndex + 1); } result.state = FillState::WaitingCache; } }; const auto firstFrom = offset - fromSlice * kInSlice; const auto firstTill = std::min(kInSlice, till - fromSlice * kInSlice); const auto secondFrom = 0; const auto secondTill = (till > (fromSlice + 1) * kInSlice) ? (till - (fromSlice + 1) * kInSlice) : 0; const auto first = _data[fromSlice].prepareFill(firstFrom, firstTill); const auto second = (fromSlice + 1 < tillSlice) ? _data[fromSlice + 1].prepareFill(secondFrom, secondTill) : Slice::PrepareFillResult(); handlePrepareResult(fromSlice, first); if (fromSlice + 1 < tillSlice) { handlePrepareResult(fromSlice + 1, second); } if (first.ready && second.ready) { markSliceUsed(fromSlice); CopyLoaded( buffer, ranges::make_subrange(first.start, first.finish), firstFrom, firstTill); if (fromSlice + 1 < tillSlice) { markSliceUsed(fromSlice + 1); CopyLoaded( buffer.subspan(firstTill - firstFrom), ranges::make_subrange(second.start, second.finish), secondFrom, secondTill); } result.toCache = serializeAndUnloadUnused(); result.state = FillState::Success; } else { handleReadFromCache(fromSlice); if (fromSlice + 1 < tillSlice) { handleReadFromCache(fromSlice + 1); } } return result; } auto Reader::Slices::fillFromHeader(uint32 offset, bytes::span buffer) -> FillResult { auto result = FillResult(); const auto from = offset; const auto till = uint32(offset + buffer.size()); const auto prepared = _header.prepareFill(from, till); for (const auto full : prepared.offsetsFromLoader.values()) { if (full < _size) { result.offsetsFromLoader.add(full); } } if (prepared.ready) { CopyLoaded( buffer, ranges::make_subrange(prepared.start, prepared.finish), from, till); result.state = FillState::Success; } return result; } QByteArray Reader::Slices::partForDownloader(uint32 offset) const { Expects(offset < _size); if (const auto i = _header.parts.find(offset); i != end(_header.parts)) { return i->second; } else if (isFullInHeader()) { return QByteArray(); } const auto index = offset / kInSlice; const auto &slice = _data[index]; const auto i = slice.parts.find(offset - index * kInSlice); return (i != end(slice.parts)) ? i->second : QByteArray(); } bool Reader::Slices::waitingForHeaderCache() const { return (_header.flags & Slice::Flag::LoadingFromCache); } bool Reader::Slices::readCacheForDownloaderRequired(uint32 offset) { Expects(offset < _size); Expects(!waitingForHeaderCache()); if (isFullInHeader()) { return false; } const auto index = offset / kInSlice; auto &slice = _data[index]; return !(slice.flags & Slice::Flag::LoadedFromCache); } void Reader::Slices::markSliceUsed(int sliceIndex) { const auto i = ranges::find(_usedSlices, sliceIndex); const auto end = _usedSlices.end(); if (i == end) { _usedSlices.push_back(sliceIndex); } else { const auto next = i + 1; if (next != end) { std::rotate(i, next, end); } } } int Reader::Slices::maxSliceSize(int sliceNumber) const { return MaxSliceSize(sliceNumber, _size); } Reader::SerializedSlice Reader::Slices::serializeAndUnloadUnused() { using Flag = Slice::Flag; if (_headerMode == HeaderMode::Unknown || _usedSlices.size() <= kSlicesInMemory) { return {}; } const auto purgeSlice = _usedSlices.front(); _usedSlices.pop_front(); if (!(_data[purgeSlice].flags & Flag::LoadedFromCache)) { // If the only data in this slice was from _header, just leave it. return {}; } const auto noNeedToSaveToCache = [&] { if (_headerMode == HeaderMode::NoCache) { // Cache is not used. return true; } else if (!(_data[purgeSlice].flags & Flag::ChangedSinceCache)) { // If no data was changed we should still save first slice, // if header data was changed since loading from cache. // Otherwise in destructor we won't be able to unload header. if (!isGoodHeader() || (purgeSlice > 0) || (!(_header.flags & Flag::ChangedSinceCache))) { return true; } } return false; }(); if (noNeedToSaveToCache) { unloadSlice(_data[purgeSlice]); return {}; } return serializeAndUnloadSlice(purgeSlice + 1); } Reader::SerializedSlice Reader::Slices::serializeAndUnloadSlice( int sliceNumber) { Expects(_headerMode != HeaderMode::Unknown); Expects(_headerMode != HeaderMode::NoCache); Expects(sliceNumber >= 0 && sliceNumber <= _data.size()); if (isGoodHeader() && (sliceNumber == 1)) { return serializeAndUnloadSlice(0); } const auto writeHeaderAndSlice = isGoodHeader() && !sliceNumber; auto &slice = sliceNumber ? _data[sliceNumber - 1] : _header; const auto count = slice.parts.size(); Assert(count > 0); auto result = SerializedSlice(); result.number = sliceNumber; // We always use complex serialization for header + first slice. const auto continuousTill = writeHeaderAndSlice ? 0 : FindNotLoadedStart(slice.parts, 0); const auto continuous = (continuousTill > slice.parts.back().first); if (continuous) { // All data is continuous. result.data.reserve(count * kPartSize); for (const auto &[offset, part] : slice.parts) { result.data.append(part); } } else { result.data = serializeComplexSlice(slice); if (writeHeaderAndSlice) { result.data.append(serializeAndUnloadFirstSliceNoHeader()); } // Make sure this data won't be taken for full continuous data. const auto maxSize = maxSliceSize(sliceNumber); while (IsContiguousSerialization(result.data.size(), maxSize)) { result.data.push_back(char(0)); } } // We may serialize header in the middle of streaming, if we use // HeaderMode::Good and we unload first slice. We still require // header data to continue working, so don't really unload the header. if (sliceNumber) { unloadSlice(slice); } else { slice.flags &= ~Slice::Flag::ChangedSinceCache; } return result; } void Reader::Slices::unloadSlice(Slice &slice) const { const auto full = (slice.flags & Slice::Flag::FullInCache); slice = Slice(); if (full) { slice.flags |= Slice::Flag::FullInCache; } } QByteArray Reader::Slices::serializeComplexSlice(const Slice &slice) const { auto result = QByteArray(); const auto count = slice.parts.size(); const auto intSize = sizeof(int32); result.reserve(count * kPartSize + 2 * intSize * (count + 1)); const auto appendInt = [&](int value) { auto serialized = int32(value); result.append( reinterpret_cast(&serialized), intSize); }; appendInt(count); for (const auto &[offset, part] : slice.parts) { appendInt(offset); appendInt(part.size()); result.append(part); } return result; } QByteArray Reader::Slices::serializeAndUnloadFirstSliceNoHeader() { Expects(_data[0].flags & Slice::Flag::LoadedFromCache); auto &slice = _data[0]; for (const auto &[offset, part] : _header.parts) { slice.parts.erase(offset); } auto result = serializeComplexSlice(slice); unloadSlice(slice); return result; } Reader::SerializedSlice Reader::Slices::unloadToCache() { if (_headerMode == HeaderMode::Unknown || _headerMode == HeaderMode::NoCache) { return {}; } if (_header.flags & Slice::Flag::ChangedSinceCache) { return serializeAndUnloadSlice(0); } for (auto i = 0, count = int(_data.size()); i != count; ++i) { if (_data[i].flags & Slice::Flag::ChangedSinceCache) { return serializeAndUnloadSlice(i + 1); } } return {}; } Reader::Reader( std::unique_ptr loader, Storage::Cache::Database *cache) : _loader(std::move(loader)) , _cache(cache) , _cacheHelper(cache ? InitCacheHelper(_loader->baseCacheKey()) : nullptr) , _slices(_loader->size(), _cacheHelper != nullptr) { _loader->parts( ) | rpl::start_with_next([=](LoadedPart &&part) { if (_attachedDownloader) { _partsForDownloader.fire_copy(part); } if (_streamingActive) { _loadedParts.emplace(std::move(part)); } if (const auto waiting = _waiting.load(std::memory_order_acquire)) { _waiting.store(nullptr, std::memory_order_release); waiting->release(); } }, _lifetime); if (_cacheHelper) { readFromCache(0); } } void Reader::startSleep(not_null wake) { _sleeping.store(wake, std::memory_order_release); processDownloaderRequests(); } void Reader::wakeFromSleep() { if (const auto sleeping = _sleeping.load(std::memory_order_acquire)) { _sleeping.store(nullptr, std::memory_order_release); sleeping->release(); } } void Reader::stopSleep() { _sleeping.store(nullptr, std::memory_order_release); } void Reader::stopStreamingAsync() { _stopStreamingAsync = true; crl::on_main(this, [=] { if (_stopStreamingAsync) { stopStreaming(false); } }); } void Reader::tryRemoveLoaderAsync() { _loader->tryRemoveFromQueue(); } void Reader::startStreaming() { _streamingActive = true; refreshLoaderPriority(); } void Reader::stopStreaming(bool stillActive) { Expects(_sleeping == nullptr); _stopStreamingAsync = false; _waiting.store(nullptr, std::memory_order_release); if (!stillActive) { _streamingActive = false; refreshLoaderPriority(); _loadingOffsets.clear(); processDownloaderRequests(); } } rpl::producer Reader::partsForDownloader() const { return _partsForDownloader.events(); } void Reader::loadForDownloader( not_null downloader, int64 offset) { Expects(offset >= 0 && offset <= std::numeric_limits::max()); if (_attachedDownloader != downloader) { if (_attachedDownloader) { cancelForDownloader(_attachedDownloader); } _attachedDownloader = downloader; _loader->attachDownloader(downloader); } _downloaderOffsetRequests.emplace(uint32(offset)); if (_streamingActive) { wakeFromSleep(); } else { processDownloaderRequests(); } } void Reader::doneForDownloader(int64 offset) { Expects(offset >= 0 && offset <= std::numeric_limits::max()); _downloaderOffsetAcks.emplace(offset); if (!_streamingActive) { processDownloaderRequests(); } } void Reader::cancelForDownloader( not_null downloader) { if (_attachedDownloader == downloader) { _downloaderOffsetRequests.take(); _attachedDownloader = nullptr; _loader->clearAttachedDownloader(); } } void Reader::enqueueDownloaderOffsets() { auto offsets = _downloaderOffsetRequests.take(); if (!empty(offsets)) { if (!empty(_offsetsForDownloader)) { _offsetsForDownloader.insert( end(_offsetsForDownloader), std::make_move_iterator(begin(offsets)), std::make_move_iterator(end(offsets))); checkForDownloaderChange(offsets.size() + 1); } else { _offsetsForDownloader = std::move(offsets); checkForDownloaderChange(offsets.size()); } } } void Reader::checkForDownloaderChange(int checkItemsCount) { Expects(checkItemsCount <= _offsetsForDownloader.size()); // If a requested offset is less-or-equal of some previously requested // offset, it means that the downloader was changed, ignore old offsets. const auto end = _offsetsForDownloader.end(); const auto changed = std::adjacent_find( end - checkItemsCount, end, [](int first, int second) { return (second <= first); }); if (changed != end) { _offsetsForDownloader.erase( begin(_offsetsForDownloader), changed + 1); _downloaderReadCache.clear(); _downloaderOffsetAcks.take(); } } void Reader::checkForDownloaderReadyOffsets() { // If a requested part is available right now we simply fire it on the // main thread, until the first not-available-right-now offset is found. const auto unavailableInBytes = [&](uint32 offset, QByteArray &&bytes) { if (bytes.isEmpty()) { return true; } crl::on_main(this, [=, bytes = std::move(bytes)]() mutable { _partsForDownloader.fire({ int64(offset), std::move(bytes) }); }); return false; }; const auto unavailableInCache = [&](uint32 offset) { const auto index = (offset / kInSlice); const auto sliceNumber = index + 1; const auto i = _downloaderReadCache.find(sliceNumber); if (i == end(_downloaderReadCache) || !i->second) { return true; } const auto j = i->second->find(offset - index * kInSlice); if (j == end(*i->second)) { return true; } return unavailableInBytes(offset, std::move(j->second)); }; const auto unavailable = [&](uint32 offset) { return unavailableInBytes(offset, _slices.partForDownloader(offset)) && unavailableInCache(offset); }; _offsetsForDownloader.erase( begin(_offsetsForDownloader), ranges::find_if(_offsetsForDownloader, unavailable)); } void Reader::processDownloaderRequests() { processCacheResults(); enqueueDownloaderOffsets(); checkForDownloaderReadyOffsets(); pruneDoneDownloaderRequests(); if (!empty(_offsetsForDownloader)) { pruneDownloaderCache(_offsetsForDownloader.front()); sendDownloaderRequests(); } } void Reader::pruneDownloaderCache(uint32 minimalOffset) { const auto minimalSliceNumber = (minimalOffset / kInSlice) + 1; const auto removeTill = ranges::lower_bound( _downloaderReadCache, minimalSliceNumber, ranges::less(), &base::flat_map>::value_type::first); _downloaderReadCache.erase(_downloaderReadCache.begin(), removeTill); } void Reader::pruneDoneDownloaderRequests() { for (const auto done : _downloaderOffsetAcks.take()) { _downloaderOffsetsRequested.remove(done); const auto i = ranges::find(_offsetsForDownloader, done); if (i != end(_offsetsForDownloader)) { _offsetsForDownloader.erase(i); } } } void Reader::sendDownloaderRequests() { auto &&offsets = ranges::views::all( _offsetsForDownloader ) | ranges::views::take(kDownloaderRequestsLimit); for (const auto offset : offsets) { if ((!_cacheHelper || !downloaderWaitForCachedSlice(offset)) && _downloaderOffsetsRequested.emplace(offset).second) { _loader->load(offset); } } } bool Reader::downloaderWaitForCachedSlice(uint32 offset) { if (_slices.waitingForHeaderCache()) { return true; } if (!_slices.readCacheForDownloaderRequired(offset)) { return false; } const auto sliceNumber = (offset / kInSlice) + 1; auto i = _downloaderReadCache.find(sliceNumber); if (i == _downloaderReadCache.end()) { // If we didn't request that slice yet, try requesting it. // If there is no need to (header mode is unknown) - place empty map. // Otherwise place std::nullopt and wait for the cache result. i = _downloaderReadCache.emplace( sliceNumber, (readFromCacheForDownloader(sliceNumber) ? std::nullopt : std::make_optional(PartsMap()))).first; } return !i->second; } void Reader::checkCacheResultsForDownloader() { if (_streamingActive) { return; } processDownloaderRequests(); } void Reader::setLoaderPriority(int priority) { if (_realPriority == priority) { return; } _realPriority = priority; refreshLoaderPriority(); } void Reader::refreshLoaderPriority() { _loader->setPriority(_streamingActive ? _realPriority : 0); } bool Reader::isRemoteLoader() const { return _loader->baseCacheKey().valid(); } std::shared_ptr Reader::InitCacheHelper( Storage::Cache::Key baseKey) { if (!baseKey) { return nullptr; } return std::make_shared(baseKey); } // 0 is for headerData, slice index = sliceNumber - 1. void Reader::readFromCache(int sliceNumber) { Expects(_cache != nullptr); Expects(_cacheHelper != nullptr); Expects(!sliceNumber || !_slices.headerModeUnknown()); if (sliceNumber == 1 && _slices.isGoodHeader()) { return readFromCache(0); } const auto size = _loader->size(); const auto key = _cacheHelper->key(sliceNumber); const auto cache = std::weak_ptr(_cacheHelper); const auto weak = base::make_weak(this); const auto ready = [=]( QByteArray &&result, std::vector &&sizes = {}) { crl::async([ =, result = std::move(result), sizes = std::move(sizes) ]() mutable{ auto entry = ParseCacheEntry( bytes::make_span(result), sliceNumber, size); if (const auto strong = cache.lock()) { QMutexLocker lock(&strong->mutex); strong->results.emplace(sliceNumber, std::move(entry.parts)); if (!sliceNumber && entry.included) { strong->results.emplace(1, std::move(*entry.included)); } strong->sizes = std::move(sizes); if (const auto waiting = strong->waiting.load()) { strong->waiting.store(nullptr, std::memory_order_release); waiting->release(); } else { crl::on_main(weak, [=] { checkCacheResultsForDownloader(); }); } } }); }; auto keys = std::vector(); const auto count = _slices.requestSliceSizesCount(); for (auto i = 0; i != count; ++i) { keys.push_back(_cacheHelper->key(i + 1)); } _cache->getWithSizes(key, std::move(keys), ready); } bool Reader::readFromCacheForDownloader(int sliceNumber) { Expects(_cacheHelper != nullptr); Expects(sliceNumber > 0); if (_slices.headerModeUnknown()) { return false; } readFromCache(sliceNumber); return true; } void Reader::putToCache(SerializedSlice &&slice) { Expects(_cache != nullptr); Expects(_cacheHelper != nullptr); Expects(slice.number >= 0); _cache->put(_cacheHelper->key(slice.number), std::move(slice.data)); } int64 Reader::size() const { return _loader->size(); } std::optional Reader::streamingError() const { return _streamingError; } void Reader::headerDone() { _slices.headerDone(false); } int Reader::headerSize() const { return _slices.headerSize(); } bool Reader::fullInCache() const { return _slices.fullInCache(); } Reader::FillState Reader::fill( int64 offset, bytes::span buffer, not_null notify) { Expects(offset + buffer.size() <= size()); Expects(offset >= 0 && size() <= std::numeric_limits::max()); const auto startWaiting = [&] { if (_cacheHelper) { _cacheHelper->waiting = notify.get(); } _waiting.store(notify.get(), std::memory_order_release); }; const auto clearWaiting = [&] { _waiting.store(nullptr, std::memory_order_release); if (_cacheHelper) { _cacheHelper->waiting.store(nullptr, std::memory_order_release); } }; const auto done = [&] { clearWaiting(); return FillState::Success; }; const auto failed = [&] { clearWaiting(); notify->release(); return FillState::Failed; }; checkForSomethingMoreReceived(); if (_streamingError) { return FillState::Failed; } auto lastResult = FillState(); do { lastResult = fillFromSlices(uint32(offset), buffer); if (lastResult == FillState::Success) { return done(); } startWaiting(); } while (checkForSomethingMoreReceived()); return _streamingError ? failed() : lastResult; } Reader::FillState Reader::fillFromSlices(uint32 offset, bytes::span buffer) { using namespace rpl::mappers; auto result = _slices.fill(offset, buffer); if (result.state != FillState::Success && _slices.headerWontBeFilled()) { _streamingError = Error::NotStreamable; return FillState::Failed; } for (const auto sliceNumber : result.sliceNumbersFromCache.values()) { readFromCache(sliceNumber); } if (_cacheHelper && result.toCache.number >= 0) { // If we put to cache the header (number == 0) that means we're in // HeaderMode::Good and really are putting the first slice to cache. Assert(result.toCache.number > 0 || _slices.isGoodHeader()); const auto index = std::max(result.toCache.number, 1) - 1; cancelLoadInRange(index * kInSlice, (index + 1) * kInSlice); putToCache(std::move(result.toCache)); } auto checkPriority = true; for (const auto offset : result.offsetsFromLoader.values()) { if (checkPriority) { checkLoadWillBeFirst(offset); checkPriority = false; } loadAtOffset(offset); } return result.state; } void Reader::cancelLoadInRange(uint32 from, uint32 till) { Expects(from < till); for (const auto offset : _loadingOffsets.takeInRange(from, till)) { if (!_downloaderOffsetsRequested.contains(offset)) { _loader->cancel(offset); } } } void Reader::checkLoadWillBeFirst(uint32 offset) { if (_loadingOffsets.front().value_or(offset) != offset) { _loadingOffsets.resetPriorities(); _loader->resetPriorities(); } } bool Reader::processCacheResults() { if (!_cacheHelper) { return false; } QMutexLocker lock(&_cacheHelper->mutex); auto loaded = base::take(_cacheHelper->results); auto sizes = base::take(_cacheHelper->sizes); lock.unlock(); for (auto &[sliceNumber, cachedParts] : _downloaderReadCache) { if (!cachedParts) { const auto i = loaded.find(sliceNumber); if (i != end(loaded)) { cachedParts = i->second; } } } if (_streamingError) { return false; } for (auto &[sliceNumber, result] : loaded) { _slices.processCacheResult(sliceNumber, std::move(result)); } if (!sizes.empty()) { _slices.processCachedSizes(sizes); } if (!loaded.empty() && (loaded.front().first == 0) && _slices.isGoodHeader()) { Assert(loaded.size() > 1); Assert((loaded.begin() + 1)->first == 1); } return !loaded.empty(); } bool Reader::processLoadedParts() { if (_streamingError) { return false; } auto loaded = _loadedParts.take(); for (auto &part : loaded) { if (!part.valid(size())) { _streamingError = Error::LoadFailed; return false; } else if (!_loadingOffsets.remove(part.offset)) { continue; } _slices.processPart( part.offset, std::move(part.bytes)); } return !loaded.empty(); } bool Reader::checkForSomethingMoreReceived() { const auto result1 = processCacheResults(); const auto result2 = processLoadedParts(); return result1 || result2; } void Reader::loadAtOffset(uint32 offset) { if (_loadingOffsets.add(offset)) { _loader->load(offset); } } void Reader::finalizeCache() { if (!_cacheHelper) { return; } Assert(_cache != nullptr); if (_cacheHelper->waiting != nullptr) { QMutexLocker lock(&_cacheHelper->mutex); _cacheHelper->waiting.store(nullptr, std::memory_order_release); } auto toCache = _slices.unloadToCache(); while (toCache.number >= 0) { putToCache(std::move(toCache)); toCache = _slices.unloadToCache(); } _cache->sync(); } Reader::~Reader() { finalizeCache(); } } // namespace Streaming } // namespace Media