/* * Copyright (C) 2010 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. */ #include #include #include #include #include #include #include #include #include #include #ifndef NO_BUFFERHUB #include #endif #include #include #include #include #include namespace android { // ---------------------------------------------------------------------------- using H2BGraphicBufferProducerV1_0 = ::android::hardware::graphics::bufferqueue::V1_0::utils:: H2BGraphicBufferProducer; using H2BGraphicBufferProducerV2_0 = ::android::hardware::graphics::bufferqueue::V2_0::utils:: H2BGraphicBufferProducer; enum { REQUEST_BUFFER = IBinder::FIRST_CALL_TRANSACTION, DEQUEUE_BUFFER, DETACH_BUFFER, DETACH_NEXT_BUFFER, ATTACH_BUFFER, QUEUE_BUFFER, CANCEL_BUFFER, QUERY, CONNECT, DISCONNECT, SET_SIDEBAND_STREAM, ALLOCATE_BUFFERS, ALLOW_ALLOCATION, SET_GENERATION_NUMBER, GET_CONSUMER_NAME, SET_MAX_DEQUEUED_BUFFER_COUNT, SET_ASYNC_MODE, SET_SHARED_BUFFER_MODE, SET_AUTO_REFRESH, SET_DEQUEUE_TIMEOUT, GET_LAST_QUEUED_BUFFER, GET_FRAME_TIMESTAMPS, GET_UNIQUE_ID, GET_CONSUMER_USAGE, SET_LEGACY_BUFFER_DROP, SET_AUTO_PREROTATION, REQUEST_BUFFERS, DEQUEUE_BUFFERS, DETACH_BUFFERS, ATTACH_BUFFERS, QUEUE_BUFFERS, CANCEL_BUFFERS, QUERY_MULTIPLE, GET_LAST_QUEUED_BUFFER2, }; class BpGraphicBufferProducer : public BpInterface { public: explicit BpGraphicBufferProducer(const sp& impl) : BpInterface(impl) { } ~BpGraphicBufferProducer() override; virtual status_t requestBuffer(int bufferIdx, sp* buf) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(bufferIdx); status_t result = remote()->transact(REQUEST_BUFFER, data, &reply); if (result != NO_ERROR) { return result; } bool nonNull = reply.readInt32(); if (nonNull) { *buf = new GraphicBuffer(); result = reply.read(**buf); if(result != NO_ERROR) { (*buf).clear(); return result; } } result = reply.readInt32(); return result; } virtual status_t requestBuffers( const std::vector& slots, std::vector* outputs) override { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32Vector(slots); status_t result = remote()->transact(REQUEST_BUFFERS, data, &reply); if (result != NO_ERROR) { return result; } result = reply.resizeOutVector(outputs); for (RequestBufferOutput& output : *outputs) { if (result != NO_ERROR) { return result; } result = reply.read(output); } return result; } virtual status_t setMaxDequeuedBufferCount(int maxDequeuedBuffers) { Parcel data, reply; data.writeInterfaceToken( IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(maxDequeuedBuffers); status_t result = remote()->transact(SET_MAX_DEQUEUED_BUFFER_COUNT, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32(); return result; } virtual status_t setAsyncMode(bool async) { Parcel data, reply; data.writeInterfaceToken( IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(async); status_t result = remote()->transact(SET_ASYNC_MODE, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32(); return result; } virtual status_t dequeueBuffer(int* buf, sp* fence, uint32_t width, uint32_t height, PixelFormat format, uint64_t usage, uint64_t* outBufferAge, FrameEventHistoryDelta* outTimestamps) { Parcel data, reply; bool getFrameTimestamps = (outTimestamps != nullptr); data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeUint32(width); data.writeUint32(height); data.writeInt32(static_cast(format)); data.writeUint64(usage); data.writeBool(getFrameTimestamps); status_t result = remote()->transact(DEQUEUE_BUFFER, data, &reply); if (result != NO_ERROR) { return result; } *buf = reply.readInt32(); *fence = new Fence(); result = reply.read(**fence); if (result != NO_ERROR) { fence->clear(); return result; } if (outBufferAge) { result = reply.readUint64(outBufferAge); } else { // Read the value even if outBufferAge is nullptr: uint64_t bufferAge; result = reply.readUint64(&bufferAge); } if (result != NO_ERROR) { ALOGE("IGBP::dequeueBuffer failed to read buffer age: %d", result); return result; } if (getFrameTimestamps) { result = reply.read(*outTimestamps); if (result != NO_ERROR) { ALOGE("IGBP::dequeueBuffer failed to read timestamps: %d", result); return result; } } result = reply.readInt32(); return result; } virtual status_t dequeueBuffers( const std::vector& inputs, std::vector* outputs) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeVectorSize(inputs); for (const auto& input : inputs) { data.write(input); } status_t result = remote()->transact(DEQUEUE_BUFFERS, data, &reply); if (result != NO_ERROR) { return result; } result = reply.resizeOutVector(outputs); for (auto& output : *outputs) { if (result != NO_ERROR) { return result; } result = reply.read(output); } return result; } virtual status_t detachBuffer(int slot) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(slot); status_t result = remote()->transact(DETACH_BUFFER, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32(); return result; } virtual status_t detachBuffers(const std::vector& slots, std::vector* results) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32Vector(slots); status_t result = remote()->transact(DETACH_BUFFERS, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32Vector(results); return result; } virtual status_t detachNextBuffer(sp* outBuffer, sp* outFence) { if (outBuffer == nullptr) { ALOGE("detachNextBuffer: outBuffer must not be NULL"); return BAD_VALUE; } else if (outFence == nullptr) { ALOGE("detachNextBuffer: outFence must not be NULL"); return BAD_VALUE; } Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); status_t result = remote()->transact(DETACH_NEXT_BUFFER, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32(); if (result == NO_ERROR) { bool nonNull = reply.readInt32(); if (nonNull) { *outBuffer = new GraphicBuffer; result = reply.read(**outBuffer); if (result != NO_ERROR) { outBuffer->clear(); return result; } } nonNull = reply.readInt32(); if (nonNull) { *outFence = new Fence; result = reply.read(**outFence); if (result != NO_ERROR) { outBuffer->clear(); outFence->clear(); return result; } } } return result; } virtual status_t attachBuffer(int* slot, const sp& buffer) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.write(*buffer.get()); status_t result = remote()->transact(ATTACH_BUFFER, data, &reply); if (result != NO_ERROR) { return result; } *slot = reply.readInt32(); result = reply.readInt32(); if (result == NO_ERROR && (*slot < 0 || *slot >= BufferQueueDefs::NUM_BUFFER_SLOTS)) { ALOGE("attachBuffer returned invalid slot %d", *slot); android_errorWriteLog(0x534e4554, "37478824"); return UNKNOWN_ERROR; } return result; } virtual status_t attachBuffers( const std::vector>& buffers, std::vector* outputs) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeVectorSize(buffers); for (const sp& buffer : buffers) { data.write(*buffer.get()); } status_t result = remote()->transact(ATTACH_BUFFERS, data, &reply); if (result != NO_ERROR) { return result; } result = reply.resizeOutVector(outputs); for (AttachBufferOutput& output : *outputs) { if (result != NO_ERROR) { return result; } result = reply.read(output); } if (result == NO_ERROR) { for (AttachBufferOutput& output : *outputs) { if (output.result == NO_ERROR && output.slot < 0) { ALOGE("attachBuffers returned invalid slot %d", output.slot); android_errorWriteLog(0x534e4554, "37478824"); output.result = UNKNOWN_ERROR; } } } return result; } virtual status_t queueBuffer(int buf, const QueueBufferInput& input, QueueBufferOutput* output) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(buf); data.write(input); status_t result = remote()->transact(QUEUE_BUFFER, data, &reply); if (result != NO_ERROR) { return result; } result = reply.read(*output); if (result != NO_ERROR) { return result; } result = reply.readInt32(); return result; } virtual status_t queueBuffers(const std::vector& inputs, std::vector* outputs) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeVectorSize(inputs); for (const QueueBufferInput& input : inputs) { data.write(input); } status_t result = remote()->transact(QUEUE_BUFFERS, data, &reply); if (result != NO_ERROR) { return result; } result = reply.resizeOutVector(outputs); for (QueueBufferOutput& output : *outputs) { if (result != NO_ERROR) { return result; } result = reply.read(output); } return result; } virtual status_t cancelBuffer(int buf, const sp& fence) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(buf); data.write(*fence.get()); status_t result = remote()->transact(CANCEL_BUFFER, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32(); return result; } virtual status_t cancelBuffers( const std::vector& inputs, std::vector* results) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeVectorSize(inputs); for (const CancelBufferInput& input : inputs) { data.write(input); } status_t result = remote()->transact(CANCEL_BUFFERS, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32Vector(results); return result; } virtual int query(int what, int* value) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(what); status_t result = remote()->transact(QUERY, data, &reply); if (result != NO_ERROR) { return result; } value[0] = reply.readInt32(); result = reply.readInt32(); return result; } virtual status_t query(const std::vector inputs, std::vector* outputs) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32Vector(inputs); status_t result = remote()->transact(QUERY_MULTIPLE, data, &reply); if (result != NO_ERROR) { return result; } result = reply.resizeOutVector(outputs); for (QueryOutput& output : *outputs) { if (result != NO_ERROR) { return result; } result = reply.read(output); } return result; } virtual status_t connect(const sp& listener, int api, bool producerControlledByApp, QueueBufferOutput* output) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); if (listener != nullptr) { data.writeInt32(1); data.writeStrongBinder(IInterface::asBinder(listener)); } else { data.writeInt32(0); } data.writeInt32(api); data.writeInt32(producerControlledByApp); status_t result = remote()->transact(CONNECT, data, &reply); if (result != NO_ERROR) { return result; } reply.read(*output); result = reply.readInt32(); return result; } virtual status_t disconnect(int api, DisconnectMode mode) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(api); data.writeInt32(static_cast(mode)); status_t result =remote()->transact(DISCONNECT, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32(); return result; } virtual status_t setSidebandStream(const sp& stream) { Parcel data, reply; status_t result; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); if (stream.get()) { data.writeInt32(true); data.writeNativeHandle(stream->handle()); } else { data.writeInt32(false); } if ((result = remote()->transact(SET_SIDEBAND_STREAM, data, &reply)) == NO_ERROR) { result = reply.readInt32(); } return result; } virtual void allocateBuffers(uint32_t width, uint32_t height, PixelFormat format, uint64_t usage) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeUint32(width); data.writeUint32(height); data.writeInt32(static_cast(format)); data.writeUint64(usage); status_t result = remote()->transact(ALLOCATE_BUFFERS, data, &reply, IBinder::FLAG_ONEWAY); if (result != NO_ERROR) { ALOGE("allocateBuffers failed to transact: %d", result); } } virtual status_t allowAllocation(bool allow) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(static_cast(allow)); status_t result = remote()->transact(ALLOW_ALLOCATION, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32(); return result; } virtual status_t setGenerationNumber(uint32_t generationNumber) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeUint32(generationNumber); status_t result = remote()->transact(SET_GENERATION_NUMBER, data, &reply); if (result == NO_ERROR) { result = reply.readInt32(); } return result; } virtual String8 getConsumerName() const { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); status_t result = remote()->transact(GET_CONSUMER_NAME, data, &reply); if (result != NO_ERROR) { ALOGE("getConsumerName failed to transact: %d", result); return String8("TransactFailed"); } return reply.readString8(); } virtual status_t setSharedBufferMode(bool sharedBufferMode) { Parcel data, reply; data.writeInterfaceToken( IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(sharedBufferMode); status_t result = remote()->transact(SET_SHARED_BUFFER_MODE, data, &reply); if (result == NO_ERROR) { result = reply.readInt32(); } return result; } virtual status_t setAutoRefresh(bool autoRefresh) { Parcel data, reply; data.writeInterfaceToken( IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(autoRefresh); status_t result = remote()->transact(SET_AUTO_REFRESH, data, &reply); if (result == NO_ERROR) { result = reply.readInt32(); } return result; } virtual status_t setDequeueTimeout(nsecs_t timeout) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt64(timeout); status_t result = remote()->transact(SET_DEQUEUE_TIMEOUT, data, &reply); if (result != NO_ERROR) { ALOGE("setDequeueTimeout failed to transact: %d", result); return result; } return reply.readInt32(); } virtual status_t setLegacyBufferDrop(bool drop) { Parcel data, reply; data.writeInterfaceToken( IGraphicBufferProducer::getInterfaceDescriptor()); data.writeInt32(drop); status_t result = remote()->transact(SET_LEGACY_BUFFER_DROP, data, &reply); if (result != NO_ERROR) { return result; } result = reply.readInt32(); return result; } virtual status_t getLastQueuedBuffer(sp* outBuffer, sp* outFence, float outTransformMatrix[16]) override { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); status_t result = remote()->transact(GET_LAST_QUEUED_BUFFER, data, &reply); if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to transact: %d", result); return result; } result = reply.readInt32(); if (result != NO_ERROR) { return result; } bool hasBuffer = reply.readBool(); sp buffer; if (hasBuffer) { buffer = new GraphicBuffer(); result = reply.read(*buffer); if (result == NO_ERROR) { result = reply.read(outTransformMatrix, sizeof(float) * 16); } } if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to read buffer: %d", result); return result; } sp fence(new Fence); result = reply.read(*fence); if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to read fence: %d", result); return result; } *outBuffer = buffer; *outFence = fence; return result; } virtual status_t getLastQueuedBuffer(sp* outBuffer, sp* outFence, Rect* outRect, uint32_t* outTransform) override { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); status_t result = remote()->transact(GET_LAST_QUEUED_BUFFER2, data, &reply); if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to transact: %d", result); return result; } status_t remoteError = NO_ERROR; result = reply.readInt32(&remoteError); if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to read status: %d", result); return result; } if (remoteError != NO_ERROR) { return remoteError; } bool hasBuffer = false; result = reply.readBool(&hasBuffer); if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to read buffer: %d", result); return result; } sp buffer; if (hasBuffer) { buffer = new GraphicBuffer(); result = reply.read(*buffer); if (result == NO_ERROR) { result = reply.read(*outRect); } if (result == NO_ERROR) { result = reply.readUint32(outTransform); } } if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to read buffer: %d", result); return result; } sp fence(new Fence); result = reply.read(*fence); if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to read fence: %d", result); return result; } *outBuffer = buffer; *outFence = fence; return result; } virtual void getFrameTimestamps(FrameEventHistoryDelta* outDelta) { Parcel data, reply; status_t result = data.writeInterfaceToken( IGraphicBufferProducer::getInterfaceDescriptor()); if (result != NO_ERROR) { ALOGE("IGBP::getFrameTimestamps failed to write token: %d", result); return; } result = remote()->transact(GET_FRAME_TIMESTAMPS, data, &reply); if (result != NO_ERROR) { ALOGE("IGBP::getFrameTimestamps failed to transact: %d", result); return; } result = reply.read(*outDelta); if (result != NO_ERROR) { ALOGE("IGBP::getFrameTimestamps failed to read timestamps: %d", result); } } virtual status_t getUniqueId(uint64_t* outId) const { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); status_t result = remote()->transact(GET_UNIQUE_ID, data, &reply); if (result != NO_ERROR) { ALOGE("getUniqueId failed to transact: %d", result); } status_t actualResult = NO_ERROR; result = reply.readInt32(&actualResult); if (result != NO_ERROR) { return result; } result = reply.readUint64(outId); if (result != NO_ERROR) { return result; } return actualResult; } virtual status_t getConsumerUsage(uint64_t* outUsage) const { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); status_t result = remote()->transact(GET_CONSUMER_USAGE, data, &reply); if (result != NO_ERROR) { ALOGE("getConsumerUsage failed to transact: %d", result); } status_t actualResult = NO_ERROR; result = reply.readInt32(&actualResult); if (result != NO_ERROR) { return result; } result = reply.readUint64(outUsage); if (result != NO_ERROR) { return result; } return actualResult; } virtual status_t setAutoPrerotation(bool autoPrerotation) { Parcel data, reply; data.writeInterfaceToken(IGraphicBufferProducer::getInterfaceDescriptor()); data.writeBool(autoPrerotation); status_t result = remote()->transact(SET_AUTO_PREROTATION, data, &reply); if (result == NO_ERROR) { result = reply.readInt32(); } return result; } }; // Out-of-line virtual method definition to trigger vtable emission in this // translation unit (see clang warning -Wweak-vtables) BpGraphicBufferProducer::~BpGraphicBufferProducer() {} class HpGraphicBufferProducer : public HpInterface< BpGraphicBufferProducer, H2BGraphicBufferProducerV1_0, H2BGraphicBufferProducerV2_0> { public: explicit HpGraphicBufferProducer(const sp& base) : PBase(base) {} status_t requestBuffer(int slot, sp* buf) override { return mBase->requestBuffer(slot, buf); } status_t requestBuffers( const std::vector& slots, std::vector* outputs) override { return mBase->requestBuffers(slots, outputs); } status_t setMaxDequeuedBufferCount(int maxDequeuedBuffers) override { return mBase->setMaxDequeuedBufferCount(maxDequeuedBuffers); } status_t setAsyncMode(bool async) override { return mBase->setAsyncMode(async); } status_t dequeueBuffer(int* slot, sp* fence, uint32_t w, uint32_t h, PixelFormat format, uint64_t usage, uint64_t* outBufferAge, FrameEventHistoryDelta* outTimestamps) override { return mBase->dequeueBuffer(slot, fence, w, h, format, usage, outBufferAge, outTimestamps); } status_t dequeueBuffers( const std::vector& inputs, std::vector* outputs) override { return mBase->dequeueBuffers(inputs, outputs); } status_t detachBuffer(int slot) override { return mBase->detachBuffer(slot); } status_t detachBuffers(const std::vector& slots, std::vector* results) override { return mBase->detachBuffers(slots, results); } status_t detachNextBuffer( sp* outBuffer, sp* outFence) override { return mBase->detachNextBuffer(outBuffer, outFence); } status_t attachBuffer( int* outSlot, const sp& buffer) override { return mBase->attachBuffer(outSlot, buffer); } status_t attachBuffers( const std::vector>& buffers, std::vector* outputs) override { return mBase->attachBuffers(buffers, outputs); } status_t queueBuffer( int slot, const QueueBufferInput& input, QueueBufferOutput* output) override { return mBase->queueBuffer(slot, input, output); } status_t queueBuffers(const std::vector& inputs, std::vector* outputs) override { return mBase->queueBuffers(inputs, outputs); } status_t cancelBuffer(int slot, const sp& fence) override { return mBase->cancelBuffer(slot, fence); } status_t cancelBuffers( const std::vector& inputs, std::vector* results) override { return mBase->cancelBuffers(inputs, results); } int query(int what, int* value) override { return mBase->query(what, value); } status_t query(const std::vector inputs, std::vector* outputs) override { return mBase->query(inputs, outputs); } status_t connect( const sp& listener, int api, bool producerControlledByApp, QueueBufferOutput* output) override { return mBase->connect(listener, api, producerControlledByApp, output); } status_t disconnect( int api, DisconnectMode mode = DisconnectMode::Api) override { return mBase->disconnect(api, mode); } status_t setSidebandStream(const sp& stream) override { return mBase->setSidebandStream(stream); } void allocateBuffers(uint32_t width, uint32_t height, PixelFormat format, uint64_t usage) override { return mBase->allocateBuffers(width, height, format, usage); } status_t allowAllocation(bool allow) override { return mBase->allowAllocation(allow); } status_t setGenerationNumber(uint32_t generationNumber) override { return mBase->setGenerationNumber(generationNumber); } String8 getConsumerName() const override { return mBase->getConsumerName(); } status_t setSharedBufferMode(bool sharedBufferMode) override { return mBase->setSharedBufferMode(sharedBufferMode); } status_t setAutoRefresh(bool autoRefresh) override { return mBase->setAutoRefresh(autoRefresh); } status_t setDequeueTimeout(nsecs_t timeout) override { return mBase->setDequeueTimeout(timeout); } status_t setLegacyBufferDrop(bool drop) override { return mBase->setLegacyBufferDrop(drop); } status_t getLastQueuedBuffer( sp* outBuffer, sp* outFence, float outTransformMatrix[16]) override { return mBase->getLastQueuedBuffer( outBuffer, outFence, outTransformMatrix); } status_t getLastQueuedBuffer(sp* outBuffer, sp* outFence, Rect* outRect, uint32_t* outTransform) override { return mBase->getLastQueuedBuffer(outBuffer, outFence, outRect, outTransform); } void getFrameTimestamps(FrameEventHistoryDelta* outDelta) override { return mBase->getFrameTimestamps(outDelta); } status_t getUniqueId(uint64_t* outId) const override { return mBase->getUniqueId(outId); } status_t getConsumerUsage(uint64_t* outUsage) const override { return mBase->getConsumerUsage(outUsage); } status_t setAutoPrerotation(bool autoPrerotation) override { return mBase->setAutoPrerotation(autoPrerotation); } }; IMPLEMENT_HYBRID_META_INTERFACE(GraphicBufferProducer, "android.gui.IGraphicBufferProducer"); // ---------------------------------------------------------------------- status_t IGraphicBufferProducer::setLegacyBufferDrop(bool drop) { // No-op for IGBP other than BufferQueue. (void) drop; return INVALID_OPERATION; } status_t IGraphicBufferProducer::setAutoPrerotation(bool autoPrerotation) { // No-op for IGBP other than BufferQueue. (void)autoPrerotation; return INVALID_OPERATION; } status_t IGraphicBufferProducer::exportToParcel(Parcel* parcel) { status_t res = OK; res = parcel->writeUint32(USE_BUFFER_QUEUE); if (res != NO_ERROR) { ALOGE("exportToParcel: Cannot write magic, res=%d.", res); return res; } return parcel->writeStrongBinder(IInterface::asBinder(this)); } /* static */ status_t IGraphicBufferProducer::exportToParcel(const sp& producer, Parcel* parcel) { if (parcel == nullptr) { ALOGE("exportToParcel: Invalid parcel object."); return BAD_VALUE; } if (producer == nullptr) { status_t res = OK; res = parcel->writeUint32(IGraphicBufferProducer::USE_BUFFER_QUEUE); if (res != NO_ERROR) return res; return parcel->writeStrongBinder(nullptr); } else { return producer->exportToParcel(parcel); } } /* static */ sp IGraphicBufferProducer::createFromParcel(const Parcel* parcel) { uint32_t outMagic = 0; status_t res = NO_ERROR; res = parcel->readUint32(&outMagic); if (res != NO_ERROR) { ALOGE("createFromParcel: Failed to read magic, error=%d.", res); return nullptr; } switch (outMagic) { case USE_BUFFER_QUEUE: { sp binder; res = parcel->readNullableStrongBinder(&binder); if (res != NO_ERROR) { ALOGE("createFromParcel: Can't read strong binder."); return nullptr; } return interface_cast(binder); } case USE_BUFFER_HUB: { ALOGE("createFromParcel: BufferHub not implemented."); #ifndef NO_BUFFERHUB dvr::ProducerQueueParcelable producerParcelable; res = producerParcelable.readFromParcel(parcel); if (res != NO_ERROR) { ALOGE("createFromParcel: Failed to read from parcel, error=%d", res); return nullptr; } return BufferHubProducer::Create(std::move(producerParcelable)); #else return nullptr; #endif } default: { ALOGE("createFromParcel: Unexpected mgaic: 0x%x.", outMagic); return nullptr; } } } // ---------------------------------------------------------------------------- status_t BnGraphicBufferProducer::onTransact( uint32_t code, const Parcel& data, Parcel* reply, uint32_t flags) { switch(code) { case REQUEST_BUFFER: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); int bufferIdx = data.readInt32(); sp buffer; int result = requestBuffer(bufferIdx, &buffer); reply->writeInt32(buffer != nullptr); if (buffer != nullptr) { reply->write(*buffer); } reply->writeInt32(result); return NO_ERROR; } case REQUEST_BUFFERS: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); std::vector slots; std::vector outputs; status_t result = data.readInt32Vector(&slots); if (result != NO_ERROR) { return result; } (void)requestBuffers(slots, &outputs); result = reply->writeVectorSize(outputs); for (const RequestBufferOutput& output : outputs) { if (result != NO_ERROR) { return result; } result = reply->write(output); } return result; } case SET_MAX_DEQUEUED_BUFFER_COUNT: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); int maxDequeuedBuffers = data.readInt32(); int result = setMaxDequeuedBufferCount(maxDequeuedBuffers); reply->writeInt32(result); return NO_ERROR; } case SET_ASYNC_MODE: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); bool async = data.readInt32(); int result = setAsyncMode(async); reply->writeInt32(result); return NO_ERROR; } case DEQUEUE_BUFFER: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); uint32_t width = data.readUint32(); uint32_t height = data.readUint32(); PixelFormat format = static_cast(data.readInt32()); uint64_t usage = data.readUint64(); uint64_t bufferAge = 0; bool getTimestamps = data.readBool(); int buf = 0; sp fence = Fence::NO_FENCE; FrameEventHistoryDelta frameTimestamps; int result = dequeueBuffer(&buf, &fence, width, height, format, usage, &bufferAge, getTimestamps ? &frameTimestamps : nullptr); if (fence == nullptr) { ALOGE("dequeueBuffer returned a NULL fence, setting to Fence::NO_FENCE"); fence = Fence::NO_FENCE; } reply->writeInt32(buf); reply->write(*fence); reply->writeUint64(bufferAge); if (getTimestamps) { reply->write(frameTimestamps); } reply->writeInt32(result); return NO_ERROR; } case DEQUEUE_BUFFERS: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); std::vector inputs; std::vector outputs; status_t result = data.resizeOutVector(&inputs); if (result != NO_ERROR) { return result; } for (DequeueBufferInput& input : inputs) { result = data.read(input); if (result != NO_ERROR) { return result; } } (void)dequeueBuffers(inputs, &outputs); result = reply->writeVectorSize(outputs); for (const DequeueBufferOutput& output : outputs) { if (result != NO_ERROR) { return result; } result = reply->write(output); } return result; } case DETACH_BUFFER: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); int slot = data.readInt32(); int result = detachBuffer(slot); reply->writeInt32(result); return NO_ERROR; } case DETACH_BUFFERS: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); std::vector slots; std::vector results; status_t result = data.readInt32Vector(&slots); if (result != NO_ERROR) { return result; } (void)detachBuffers(slots, &results); return reply->writeInt32Vector(results); } case DETACH_NEXT_BUFFER: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); sp buffer; sp fence; int32_t result = detachNextBuffer(&buffer, &fence); reply->writeInt32(result); if (result == NO_ERROR) { reply->writeInt32(buffer != nullptr); if (buffer != nullptr) { reply->write(*buffer); } reply->writeInt32(fence != nullptr); if (fence != nullptr) { reply->write(*fence); } } return NO_ERROR; } case ATTACH_BUFFER: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); sp buffer = new GraphicBuffer(); status_t result = data.read(*buffer.get()); int slot = 0; if (result == NO_ERROR) { result = attachBuffer(&slot, buffer); } reply->writeInt32(slot); reply->writeInt32(result); return NO_ERROR; } case ATTACH_BUFFERS: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); std::vector> buffers; status_t result = data.resizeOutVector(&buffers); if (result != NO_ERROR) { return result; } for (sp& buffer : buffers) { buffer = new GraphicBuffer(); result = data.read(*buffer.get()); if (result != NO_ERROR) { return result; } } std::vector outputs; (void)attachBuffers(buffers, &outputs); result = reply->writeVectorSize(outputs); for (const AttachBufferOutput& output : outputs) { if (result != NO_ERROR) { return result; } result = reply->write(output); } return result; } case QUEUE_BUFFER: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); int buf = data.readInt32(); QueueBufferInput input(data); QueueBufferOutput output; status_t result = queueBuffer(buf, input, &output); reply->write(output); reply->writeInt32(result); return NO_ERROR; } case QUEUE_BUFFERS: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); std::vector inputs; status_t result = data.resizeOutVector(&inputs); if (result != NO_ERROR) { return result; } for (QueueBufferInput& input : inputs) { result = data.read(input); if (result != NO_ERROR) { return result; } } std::vector outputs; (void)queueBuffers(inputs, &outputs); result = reply->writeVectorSize(outputs); for (const QueueBufferOutput& output : outputs) { if (result != NO_ERROR) { return result; } result = reply->write(output); } return result; } case CANCEL_BUFFER: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); int buf = data.readInt32(); sp fence = new Fence(); status_t result = data.read(*fence.get()); if (result == NO_ERROR) { result = cancelBuffer(buf, fence); } reply->writeInt32(result); return NO_ERROR; } case CANCEL_BUFFERS: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); std::vector inputs; status_t result = data.resizeOutVector(&inputs); for (CancelBufferInput& input : inputs) { if (result != NO_ERROR) { return result; } result = data.read(input); } if (result != NO_ERROR) { return result; } std::vector results; result = cancelBuffers(inputs, &results); if (result != NO_ERROR) { return result; } return reply->writeInt32Vector(results); } case QUERY: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); int value = 0; int what = data.readInt32(); int res = query(what, &value); reply->writeInt32(value); reply->writeInt32(res); return NO_ERROR; } case QUERY_MULTIPLE: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); std::vector inputs; status_t result = data.readInt32Vector(&inputs); if (result != NO_ERROR) { return result; } std::vector outputs; result = query(inputs, &outputs); if (result != NO_ERROR) { return result; } result = reply->writeVectorSize(outputs); for (const QueryOutput& output : outputs) { if (result != NO_ERROR) { return result; } result = reply->write(output); } return result; } case CONNECT: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); sp listener; if (data.readInt32() == 1) { listener = IProducerListener::asInterface(data.readStrongBinder()); } int api = data.readInt32(); bool producerControlledByApp = data.readInt32(); QueueBufferOutput output; status_t res = connect(listener, api, producerControlledByApp, &output); reply->write(output); reply->writeInt32(res); return NO_ERROR; } case DISCONNECT: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); int api = data.readInt32(); DisconnectMode mode = static_cast(data.readInt32()); status_t res = disconnect(api, mode); reply->writeInt32(res); return NO_ERROR; } case SET_SIDEBAND_STREAM: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); sp stream; if (data.readInt32()) { stream = NativeHandle::create(data.readNativeHandle(), true); } status_t result = setSidebandStream(stream); reply->writeInt32(result); return NO_ERROR; } case ALLOCATE_BUFFERS: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); uint32_t width = data.readUint32(); uint32_t height = data.readUint32(); PixelFormat format = static_cast(data.readInt32()); uint64_t usage = data.readUint64(); allocateBuffers(width, height, format, usage); return NO_ERROR; } case ALLOW_ALLOCATION: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); bool allow = static_cast(data.readInt32()); status_t result = allowAllocation(allow); reply->writeInt32(result); return NO_ERROR; } case SET_GENERATION_NUMBER: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); uint32_t generationNumber = data.readUint32(); status_t result = setGenerationNumber(generationNumber); reply->writeInt32(result); return NO_ERROR; } case GET_CONSUMER_NAME: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); reply->writeString8(getConsumerName()); return NO_ERROR; } case SET_SHARED_BUFFER_MODE: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); bool sharedBufferMode = data.readInt32(); status_t result = setSharedBufferMode(sharedBufferMode); reply->writeInt32(result); return NO_ERROR; } case SET_AUTO_REFRESH: { CHECK_INTERFACE(IGraphicBuffer, data, reply); bool autoRefresh = data.readInt32(); status_t result = setAutoRefresh(autoRefresh); reply->writeInt32(result); return NO_ERROR; } case SET_DEQUEUE_TIMEOUT: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); nsecs_t timeout = data.readInt64(); status_t result = setDequeueTimeout(timeout); reply->writeInt32(result); return NO_ERROR; } case GET_LAST_QUEUED_BUFFER: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); sp buffer(nullptr); sp fence(Fence::NO_FENCE); float transform[16] = {}; status_t result = getLastQueuedBuffer(&buffer, &fence, transform); reply->writeInt32(result); if (result != NO_ERROR) { return result; } if (!buffer.get()) { reply->writeBool(false); } else { reply->writeBool(true); result = reply->write(*buffer); if (result == NO_ERROR) { reply->write(transform, sizeof(float) * 16); } } if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to write buffer: %d", result); return result; } if (fence == nullptr) { ALOGE("getLastQueuedBuffer returned a NULL fence, setting to Fence::NO_FENCE"); fence = Fence::NO_FENCE; } result = reply->write(*fence); if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to write fence: %d", result); return result; } return NO_ERROR; } case GET_LAST_QUEUED_BUFFER2: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); sp buffer(nullptr); sp fence(Fence::NO_FENCE); Rect crop; uint32_t transform; status_t result = getLastQueuedBuffer(&buffer, &fence, &crop, &transform); reply->writeInt32(result); if (result != NO_ERROR) { return result; } if (!buffer.get()) { reply->writeBool(false); } else { reply->writeBool(true); result = reply->write(*buffer); if (result == NO_ERROR) { result = reply->write(crop); } if (result == NO_ERROR) { result = reply->writeUint32(transform); } } if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to write buffer: %d", result); return result; } if (fence == nullptr) { ALOGE("getLastQueuedBuffer returned a NULL fence, setting to Fence::NO_FENCE"); fence = Fence::NO_FENCE; } result = reply->write(*fence); if (result != NO_ERROR) { ALOGE("getLastQueuedBuffer failed to write fence: %d", result); return result; } return NO_ERROR; } case GET_FRAME_TIMESTAMPS: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); FrameEventHistoryDelta frameTimestamps; getFrameTimestamps(&frameTimestamps); status_t result = reply->write(frameTimestamps); if (result != NO_ERROR) { ALOGE("BnGBP::GET_FRAME_TIMESTAMPS failed to write buffer: %d", result); return result; } return NO_ERROR; } case GET_UNIQUE_ID: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); uint64_t outId = 0; status_t actualResult = getUniqueId(&outId); status_t result = reply->writeInt32(actualResult); if (result != NO_ERROR) { return result; } result = reply->writeUint64(outId); if (result != NO_ERROR) { return result; } return NO_ERROR; } case GET_CONSUMER_USAGE: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); uint64_t outUsage = 0; status_t actualResult = getConsumerUsage(&outUsage); status_t result = reply->writeInt32(actualResult); if (result != NO_ERROR) { return result; } result = reply->writeUint64(outUsage); if (result != NO_ERROR) { return result; } return NO_ERROR; } case SET_LEGACY_BUFFER_DROP: { CHECK_INTERFACE(IGraphicBufferProducer, data, reply); bool drop = data.readInt32(); int result = setLegacyBufferDrop(drop); reply->writeInt32(result); return NO_ERROR; } case SET_AUTO_PREROTATION: { CHECK_INTERFACE(IGraphicBuffer, data, reply); bool autoPrerotation = data.readBool(); status_t result = setAutoPrerotation(autoPrerotation); reply->writeInt32(result); return NO_ERROR; } } return BBinder::onTransact(code, data, reply, flags); } }; // namespace android