/* * Copyright (C) 2022 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #define LOG_TAG "AidlBufferPool" //#define LOG_NDEBUG 0 #include #include #include #include #include #include #include "Accessor.h" #include "BufferPool.h" #include "Connection.h" #include "DataHelper.h" namespace aidl::android::hardware::media::bufferpool2::implementation { namespace { static constexpr int64_t kCleanUpDurationMs = 500; // 0.5 sec static constexpr int64_t kLogDurationMs = 5000; // 5 secs static constexpr size_t kMinAllocBytesForEviction = 1024*1024*15; static constexpr size_t kMinBufferCountForEviction = 25; static constexpr size_t kMaxUnusedBufferCount = 64; static constexpr size_t kUnusedBufferCountTarget = kMaxUnusedBufferCount - 16; } BufferPool::BufferPool() : mTimestampMs(::android::elapsedRealtime()), mLastCleanUpMs(mTimestampMs), mLastLogMs(mTimestampMs), mSeq(0), mStartSeq(0) { mValid = mInvalidationChannel.isValid(); } // Statistics helper template int percentage(T base, S total) { return int(total ? 0.5 + 100. * static_cast(base) / total : 0); } std::atomic BufferPool::Invalidation::sInvSeqId(0); BufferPool::~BufferPool() { std::lock_guard lock(mMutex); ALOGD("Destruction - bufferpool2 %p " "cached: %zu/%zuM, %zu/%d%% in use; " "allocs: %zu, %d%% recycled; " "transfers: %zu, %d%% unfetched", this, mStats.mBuffersCached, mStats.mSizeCached >> 20, mStats.mBuffersInUse, percentage(mStats.mBuffersInUse, mStats.mBuffersCached), mStats.mTotalAllocations, percentage(mStats.mTotalRecycles, mStats.mTotalAllocations), mStats.mTotalTransfers, percentage(mStats.mTotalTransfers - mStats.mTotalFetches, mStats.mTotalTransfers)); } void BufferPool::Invalidation::onConnect( ConnectionId conId, const std::shared_ptr& observer) { mAcks[conId] = mInvalidationId; // starts from current invalidationId mObservers.insert(std::make_pair(conId, observer)); } void BufferPool::Invalidation::onClose(ConnectionId conId) { mAcks.erase(conId); mObservers.erase(conId); } void BufferPool::Invalidation::onAck( ConnectionId conId, uint32_t msgId) { auto it = mAcks.find(conId); if (it == mAcks.end()) { ALOGW("ACK from inconsistent connection! %lld", (long long)conId); return; } if (isMessageLater(msgId, it->second)) { mAcks[conId] = msgId; } } void BufferPool::Invalidation::onBufferInvalidated( BufferId bufferId, BufferInvalidationChannel &channel) { for (auto it = mPendings.begin(); it != mPendings.end();) { if (it->isInvalidated(bufferId)) { uint32_t msgId = 0; if (it->mNeedsAck) { if (mInvalidationId == UINT_MAX) { // wrap happens; mInvalidationId = 0; } msgId = ++mInvalidationId; } channel.postInvalidation(msgId, it->mFrom, it->mTo); it = mPendings.erase(it); continue; } ++it; } } void BufferPool::Invalidation::onInvalidationRequest( bool needsAck, uint32_t from, uint32_t to, size_t left, BufferInvalidationChannel &channel, const std::shared_ptr &impl) { uint32_t msgId = 0; if (needsAck) { if (mInvalidationId == UINT_MAX) { //wrap happens mInvalidationId = 0; } msgId = ++mInvalidationId; } ALOGV("bufferpool2 invalidation requested and queued"); if (left == 0) { channel.postInvalidation(msgId, from, to); } else { ALOGV("bufferpoo2 invalidation requested and pending"); Pending pending(needsAck, from, to, left, impl); mPendings.push_back(pending); } Accessor::sInvalidator->addAccessor(mId, impl); } void BufferPool::Invalidation::onHandleAck( std::map> *observers, uint32_t *invalidationId) { if (mInvalidationId != 0) { *invalidationId = mInvalidationId; std::set deads; for (auto it = mAcks.begin(); it != mAcks.end(); ++it) { if (it->second != mInvalidationId) { const std::shared_ptr observer = mObservers[it->first]; if (observer) { observers->emplace(it->first, observer); ALOGV("connection %lld will call observer (%u: %u)", (long long)it->first, it->second, mInvalidationId); // N.B: onMessage will be called later. ignore possibility of // onMessage# oneway call being lost. it->second = mInvalidationId; } else { ALOGV("bufferpool2 observer died %lld", (long long)it->first); deads.insert(it->first); } } } if (deads.size() > 0) { for (auto it = deads.begin(); it != deads.end(); ++it) { onClose(*it); } } } if (mPendings.size() == 0) { // All invalidation Ids are synced and no more pending invalidations. Accessor::sInvalidator->delAccessor(mId); } } bool BufferPool::handleOwnBuffer( ConnectionId connectionId, BufferId bufferId) { bool added = insert(&mUsingBuffers, connectionId, bufferId); if (added) { auto iter = mBuffers.find(bufferId); iter->second->mOwnerCount++; } insert(&mUsingConnections, bufferId, connectionId); return added; } bool BufferPool::handleReleaseBuffer( ConnectionId connectionId, BufferId bufferId) { bool deleted = erase(&mUsingBuffers, connectionId, bufferId); if (deleted) { auto iter = mBuffers.find(bufferId); iter->second->mOwnerCount--; if (iter->second->mOwnerCount == 0 && iter->second->mTransactionCount == 0) { if (!iter->second->mInvalidated) { mStats.onBufferUnused(iter->second->mAllocSize); mFreeBuffers.insert(bufferId); } else { mStats.onBufferUnused(iter->second->mAllocSize); mStats.onBufferEvicted(iter->second->mAllocSize); mBuffers.erase(iter); mInvalidation.onBufferInvalidated(bufferId, mInvalidationChannel); } } } erase(&mUsingConnections, bufferId, connectionId); ALOGV("release buffer %u : %d", bufferId, deleted); return deleted; } bool BufferPool::handleTransferTo(const BufferStatusMessage &message) { auto completed = mCompletedTransactions.find( message.transactionId); if (completed != mCompletedTransactions.end()) { // already completed mCompletedTransactions.erase(completed); return true; } // the buffer should exist and be owned. auto bufferIter = mBuffers.find(message.bufferId); if (bufferIter == mBuffers.end() || !contains(&mUsingBuffers, message.connectionId, FromAidl(message.bufferId))) { return false; } auto found = mTransactions.find(message.transactionId); if (found != mTransactions.end()) { // transfer_from was received earlier. found->second->mSender = message.connectionId; found->second->mSenderValidated = true; return true; } if (mConnectionIds.find(message.targetConnectionId) == mConnectionIds.end()) { // N.B: it could be fake or receive connection already closed. ALOGD("bufferpool2 %p receiver connection %lld is no longer valid", this, (long long)message.targetConnectionId); return false; } mStats.onBufferSent(); mTransactions.insert(std::make_pair( message.transactionId, std::make_unique(message, mTimestampMs))); insert(&mPendingTransactions, message.targetConnectionId, FromAidl(message.transactionId)); bufferIter->second->mTransactionCount++; return true; } bool BufferPool::handleTransferFrom(const BufferStatusMessage &message) { auto found = mTransactions.find(message.transactionId); if (found == mTransactions.end()) { // TODO: is it feasible to check ownership here? mStats.onBufferSent(); mTransactions.insert(std::make_pair( message.transactionId, std::make_unique(message, mTimestampMs))); insert(&mPendingTransactions, message.connectionId, FromAidl(message.transactionId)); auto bufferIter = mBuffers.find(message.bufferId); bufferIter->second->mTransactionCount++; } else { if (message.connectionId == found->second->mReceiver) { found->second->mStatus = BufferStatus::TRANSFER_FROM; } } return true; } bool BufferPool::handleTransferResult(const BufferStatusMessage &message) { auto found = mTransactions.find(message.transactionId); if (found != mTransactions.end()) { bool deleted = erase(&mPendingTransactions, message.connectionId, FromAidl(message.transactionId)); if (deleted) { if (!found->second->mSenderValidated) { mCompletedTransactions.insert(message.transactionId); } auto bufferIter = mBuffers.find(message.bufferId); if (message.status == BufferStatus::TRANSFER_OK) { handleOwnBuffer(message.connectionId, message.bufferId); } bufferIter->second->mTransactionCount--; if (bufferIter->second->mOwnerCount == 0 && bufferIter->second->mTransactionCount == 0) { if (!bufferIter->second->mInvalidated) { mStats.onBufferUnused(bufferIter->second->mAllocSize); mFreeBuffers.insert(message.bufferId); } else { mStats.onBufferUnused(bufferIter->second->mAllocSize); mStats.onBufferEvicted(bufferIter->second->mAllocSize); mBuffers.erase(bufferIter); mInvalidation.onBufferInvalidated(message.bufferId, mInvalidationChannel); } } mTransactions.erase(found); } ALOGV("transfer finished %llu %u - %d", (unsigned long long)message.transactionId, message.bufferId, deleted); return deleted; } ALOGV("transfer not found %llu %u", (unsigned long long)message.transactionId, message.bufferId); return false; } void BufferPool::processStatusMessages() { std::vector messages; mObserver.getBufferStatusChanges(messages); mTimestampMs = ::android::elapsedRealtime(); for (BufferStatusMessage& message: messages) { bool ret = false; switch (message.status) { case BufferStatus::NOT_USED: ret = handleReleaseBuffer( message.connectionId, message.bufferId); break; case BufferStatus::USED: // not happening break; case BufferStatus::TRANSFER_TO: ret = handleTransferTo(message); break; case BufferStatus::TRANSFER_FROM: ret = handleTransferFrom(message); break; case BufferStatus::TRANSFER_TIMEOUT: // TODO break; case BufferStatus::TRANSFER_LOST: // TODO break; case BufferStatus::TRANSFER_FETCH: // not happening break; case BufferStatus::TRANSFER_OK: case BufferStatus::TRANSFER_ERROR: ret = handleTransferResult(message); break; case BufferStatus::INVALIDATION_ACK: mInvalidation.onAck(message.connectionId, message.bufferId); ret = true; break; } if (ret == false) { ALOGW("buffer status message processing failure - message : %d connection : %lld", message.status, (long long)message.connectionId); } } messages.clear(); } bool BufferPool::handleClose(ConnectionId connectionId) { // Cleaning buffers auto buffers = mUsingBuffers.find(connectionId); if (buffers != mUsingBuffers.end()) { for (const BufferId& bufferId : buffers->second) { bool deleted = erase(&mUsingConnections, bufferId, connectionId); if (deleted) { auto bufferIter = mBuffers.find(bufferId); bufferIter->second->mOwnerCount--; if (bufferIter->second->mOwnerCount == 0 && bufferIter->second->mTransactionCount == 0) { // TODO: handle freebuffer insert fail if (!bufferIter->second->mInvalidated) { mStats.onBufferUnused(bufferIter->second->mAllocSize); mFreeBuffers.insert(bufferId); } else { mStats.onBufferUnused(bufferIter->second->mAllocSize); mStats.onBufferEvicted(bufferIter->second->mAllocSize); mBuffers.erase(bufferIter); mInvalidation.onBufferInvalidated(bufferId, mInvalidationChannel); } } } } mUsingBuffers.erase(buffers); } // Cleaning transactions auto pending = mPendingTransactions.find(connectionId); if (pending != mPendingTransactions.end()) { for (const TransactionId& transactionId : pending->second) { auto iter = mTransactions.find(transactionId); if (iter != mTransactions.end()) { if (!iter->second->mSenderValidated) { mCompletedTransactions.insert(transactionId); } BufferId bufferId = iter->second->mBufferId; auto bufferIter = mBuffers.find(bufferId); bufferIter->second->mTransactionCount--; if (bufferIter->second->mOwnerCount == 0 && bufferIter->second->mTransactionCount == 0) { // TODO: handle freebuffer insert fail if (!bufferIter->second->mInvalidated) { mStats.onBufferUnused(bufferIter->second->mAllocSize); mFreeBuffers.insert(bufferId); } else { mStats.onBufferUnused(bufferIter->second->mAllocSize); mStats.onBufferEvicted(bufferIter->second->mAllocSize); mBuffers.erase(bufferIter); mInvalidation.onBufferInvalidated(bufferId, mInvalidationChannel); } } mTransactions.erase(iter); } } } mConnectionIds.erase(connectionId); return true; } bool BufferPool::getFreeBuffer( const std::shared_ptr &allocator, const std::vector ¶ms, BufferId *pId, const native_handle_t** handle) { auto bufferIt = mFreeBuffers.begin(); for (;bufferIt != mFreeBuffers.end(); ++bufferIt) { BufferId bufferId = *bufferIt; if (allocator->compatible(params, mBuffers[bufferId]->mConfig)) { break; } } if (bufferIt != mFreeBuffers.end()) { BufferId id = *bufferIt; mFreeBuffers.erase(bufferIt); mStats.onBufferRecycled(mBuffers[id]->mAllocSize); *handle = mBuffers[id]->handle(); *pId = id; ALOGV("recycle a buffer %u %p", id, *handle); return true; } return false; } BufferPoolStatus BufferPool::addNewBuffer( const std::shared_ptr &alloc, const size_t allocSize, const std::vector ¶ms, BufferId *pId, const native_handle_t** handle) { BufferId bufferId = mSeq++; if (mSeq == Connection::SYNC_BUFFERID) { mSeq = 0; } std::unique_ptr buffer = std::make_unique( bufferId, alloc, allocSize, params); if (buffer) { auto res = mBuffers.insert(std::make_pair( bufferId, std::move(buffer))); if (res.second) { mStats.onBufferAllocated(allocSize); *handle = alloc->handle(); *pId = bufferId; return ResultStatus::OK; } } return ResultStatus::NO_MEMORY; } void BufferPool::cleanUp(bool clearCache) { if (clearCache || mTimestampMs > mLastCleanUpMs + kCleanUpDurationMs || mStats.buffersNotInUse() > kMaxUnusedBufferCount) { mLastCleanUpMs = mTimestampMs; if (mTimestampMs > mLastLogMs + kLogDurationMs || mStats.buffersNotInUse() > kMaxUnusedBufferCount) { mLastLogMs = mTimestampMs; ALOGD("bufferpool2 %p : %zu(%zu size) total buffers - " "%zu(%zu size) used buffers - %zu/%zu (recycle/alloc) - " "%zu/%zu (fetch/transfer)", this, mStats.mBuffersCached, mStats.mSizeCached, mStats.mBuffersInUse, mStats.mSizeInUse, mStats.mTotalRecycles, mStats.mTotalAllocations, mStats.mTotalFetches, mStats.mTotalTransfers); } for (auto freeIt = mFreeBuffers.begin(); freeIt != mFreeBuffers.end();) { if (!clearCache && mStats.buffersNotInUse() <= kUnusedBufferCountTarget && (mStats.mSizeCached < kMinAllocBytesForEviction || mBuffers.size() < kMinBufferCountForEviction)) { break; } auto it = mBuffers.find(*freeIt); if (it != mBuffers.end() && it->second->mOwnerCount == 0 && it->second->mTransactionCount == 0) { mStats.onBufferEvicted(it->second->mAllocSize); mBuffers.erase(it); freeIt = mFreeBuffers.erase(freeIt); } else { ++freeIt; ALOGW("bufferpool2 inconsistent!"); } } } } void BufferPool::invalidate( bool needsAck, BufferId from, BufferId to, const std::shared_ptr &impl) { for (auto freeIt = mFreeBuffers.begin(); freeIt != mFreeBuffers.end();) { if (isBufferInRange(from, to, *freeIt)) { auto it = mBuffers.find(*freeIt); if (it != mBuffers.end() && it->second->mOwnerCount == 0 && it->second->mTransactionCount == 0) { mStats.onBufferEvicted(it->second->mAllocSize); mBuffers.erase(it); freeIt = mFreeBuffers.erase(freeIt); continue; } else { ALOGW("bufferpool2 inconsistent!"); } } ++freeIt; } size_t left = 0; for (auto it = mBuffers.begin(); it != mBuffers.end(); ++it) { if (isBufferInRange(from, to, it->first)) { it->second->invalidate(); ++left; } } mInvalidation.onInvalidationRequest(needsAck, from, to, left, mInvalidationChannel, impl); } void BufferPool::flush(const std::shared_ptr &impl) { BufferId from = mStartSeq; BufferId to = mSeq; mStartSeq = mSeq; // TODO: needsAck params ALOGV("buffer invalidation request bp:%u %u %u", mInvalidation.mId, from, to); if (from != to) { invalidate(true, from, to, impl); } } } // namespace aidl::android::hardware::media::bufferpool2::implementation