/* * Copyright 2018 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 namespace android { using namespace dvr; /* static */ sp BufferHubProducer::Create(const std::shared_ptr& queue) { sp producer = new BufferHubProducer; producer->queue_ = queue; return producer; } /* static */ sp BufferHubProducer::Create(ProducerQueueParcelable parcelable) { if (!parcelable.IsValid()) { ALOGE("BufferHubProducer::Create: Invalid producer parcelable."); return nullptr; } sp producer = new BufferHubProducer; producer->queue_ = ProducerQueue::Import(parcelable.TakeChannelHandle()); return producer; } status_t BufferHubProducer::requestBuffer(int slot, sp* buf) { ALOGV("requestBuffer: slot=%d", slot); std::unique_lock lock(mutex_); if (connected_api_ == kNoConnectedApi) { ALOGE("requestBuffer: BufferHubProducer has no connected producer"); return NO_INIT; } if (slot < 0 || slot >= max_buffer_count_) { ALOGE("requestBuffer: slot index %d out of range [0, %d)", slot, max_buffer_count_); return BAD_VALUE; } else if (!buffers_[slot].mBufferState.isDequeued()) { ALOGE("requestBuffer: slot %d is not owned by the producer (state = %s)", slot, buffers_[slot].mBufferState.string()); return BAD_VALUE; } else if (buffers_[slot].mGraphicBuffer != nullptr) { ALOGE("requestBuffer: slot %d is not empty.", slot); return BAD_VALUE; } else if (buffers_[slot].mProducerBuffer == nullptr) { ALOGE("requestBuffer: slot %d is not dequeued.", slot); return BAD_VALUE; } const auto& producer_buffer = buffers_[slot].mProducerBuffer; sp graphic_buffer = producer_buffer->buffer()->buffer(); buffers_[slot].mGraphicBuffer = graphic_buffer; buffers_[slot].mRequestBufferCalled = true; *buf = graphic_buffer; return NO_ERROR; } status_t BufferHubProducer::setMaxDequeuedBufferCount(int max_dequeued_buffers) { ALOGV("setMaxDequeuedBufferCount: max_dequeued_buffers=%d", max_dequeued_buffers); std::unique_lock lock(mutex_); if (max_dequeued_buffers <= 0 || max_dequeued_buffers > int(BufferHubQueue::kMaxQueueCapacity - kDefaultUndequeuedBuffers)) { ALOGE("setMaxDequeuedBufferCount: %d out of range (0, %zu]", max_dequeued_buffers, BufferHubQueue::kMaxQueueCapacity); return BAD_VALUE; } // The new dequeued_buffers count should not be violated by the number // of currently dequeued buffers. int dequeued_count = 0; for (const auto& buf : buffers_) { if (buf.mBufferState.isDequeued()) { dequeued_count++; } } if (dequeued_count > max_dequeued_buffers) { ALOGE("setMaxDequeuedBufferCount: the requested dequeued_buffers" "count (%d) exceeds the current dequeued buffer count (%d)", max_dequeued_buffers, dequeued_count); return BAD_VALUE; } max_dequeued_buffer_count_ = max_dequeued_buffers; return NO_ERROR; } status_t BufferHubProducer::setAsyncMode(bool async) { if (async) { // TODO(b/36724099) BufferHubQueue's consumer end always acquires the buffer // automatically and behaves differently from IGraphicBufferConsumer. Thus, // android::BufferQueue's async mode (a.k.a. allocating an additional buffer // to prevent dequeueBuffer from being blocking) technically does not apply // here. // // In Daydream, non-blocking producer side dequeue is guaranteed by careful // buffer consumer implementations. In another word, BufferHubQueue based // dequeueBuffer should never block whether setAsyncMode(true) is set or // not. // // See: IGraphicBufferProducer::setAsyncMode and // BufferQueueProducer::setAsyncMode for more about original implementation. ALOGW("BufferHubProducer::setAsyncMode: BufferHubQueue should always be " "asynchronous. This call makes no effact."); return NO_ERROR; } return NO_ERROR; } status_t BufferHubProducer::dequeueBuffer(int* out_slot, sp* out_fence, uint32_t width, uint32_t height, PixelFormat format, uint64_t usage, uint64_t* /*outBufferAge*/, FrameEventHistoryDelta* /* out_timestamps */) { ALOGV("dequeueBuffer: w=%u, h=%u, format=%d, usage=%" PRIu64, width, height, format, usage); status_t ret; std::unique_lock lock(mutex_); if (connected_api_ == kNoConnectedApi) { ALOGE("dequeueBuffer: BufferQueue has no connected producer"); return NO_INIT; } const uint32_t kLayerCount = 1; if (int32_t(queue_->capacity()) < max_dequeued_buffer_count_ + kDefaultUndequeuedBuffers) { // Lazy allocation. When the capacity of |queue_| has not reached // |max_dequeued_buffer_count_|, allocate new buffer. // TODO(jwcai) To save memory, the really reasonable thing to do is to go // over existing slots and find first existing one to dequeue. ret = AllocateBuffer(width, height, kLayerCount, format, usage); if (ret < 0) return ret; } size_t slot = 0; std::shared_ptr producer_buffer; for (size_t retry = 0; retry < BufferHubQueue::kMaxQueueCapacity; retry++) { LocalHandle fence; auto buffer_status = queue_->Dequeue(dequeue_timeout_ms_, &slot, &fence); if (!buffer_status) return NO_MEMORY; producer_buffer = buffer_status.take(); if (!producer_buffer) return NO_MEMORY; if (width == producer_buffer->width() && height == producer_buffer->height() && uint32_t(format) == producer_buffer->format()) { // The producer queue returns a producer buffer matches the request. break; } // Needs reallocation. // TODO(jwcai) Consider use VLOG instead if we find this log is not useful. ALOGI("dequeueBuffer: requested buffer (w=%u, h=%u, format=%u) is different " "from the buffer returned at slot: %zu (w=%u, h=%u, format=%u). Need " "re-allocattion.", width, height, format, slot, producer_buffer->width(), producer_buffer->height(), producer_buffer->format()); // Mark the slot as reallocating, so that later we can set // BUFFER_NEEDS_REALLOCATION when the buffer actually get dequeued. buffers_[slot].mIsReallocating = true; // Remove the old buffer once the allocation before allocating its // replacement. RemoveBuffer(slot); // Allocate a new producer buffer with new buffer configs. Note that if // there are already multiple buffers in the queue, the next one returned // from |queue_->Dequeue| may not be the new buffer we just reallocated. // Retry up to BufferHubQueue::kMaxQueueCapacity times. ret = AllocateBuffer(width, height, kLayerCount, format, usage); if (ret < 0) return ret; } // With the BufferHub backed solution. Buffer slot returned from // |queue_->Dequeue| is guaranteed to avaiable for producer's use. // It's either in free state (if the buffer has never been used before) or // in queued state (if the buffer has been dequeued and queued back to // BufferHubQueue). LOG_ALWAYS_FATAL_IF((!buffers_[slot].mBufferState.isFree() && !buffers_[slot].mBufferState.isQueued()), "dequeueBuffer: slot %zu is not free or queued, actual state: %s.", slot, buffers_[slot].mBufferState.string()); buffers_[slot].mBufferState.freeQueued(); buffers_[slot].mBufferState.dequeue(); ALOGV("dequeueBuffer: slot=%zu", slot); // TODO(jwcai) Handle fence properly. |BufferHub| has full fence support, we // just need to exopose that through |BufferHubQueue| once we need fence. *out_fence = Fence::NO_FENCE; *out_slot = int(slot); ret = NO_ERROR; if (buffers_[slot].mIsReallocating) { ret |= BUFFER_NEEDS_REALLOCATION; buffers_[slot].mIsReallocating = false; } return ret; } status_t BufferHubProducer::detachBuffer(int slot) { ALOGV("detachBuffer: slot=%d", slot); std::unique_lock lock(mutex_); return DetachBufferLocked(static_cast(slot)); } status_t BufferHubProducer::DetachBufferLocked(size_t slot) { if (connected_api_ == kNoConnectedApi) { ALOGE("detachBuffer: BufferHubProducer is not connected."); return NO_INIT; } if (slot >= static_cast(max_buffer_count_)) { ALOGE("detachBuffer: slot index %zu out of range [0, %d)", slot, max_buffer_count_); return BAD_VALUE; } else if (!buffers_[slot].mBufferState.isDequeued()) { ALOGE("detachBuffer: slot %zu is not owned by the producer (state = %s)", slot, buffers_[slot].mBufferState.string()); return BAD_VALUE; } else if (!buffers_[slot].mRequestBufferCalled) { ALOGE("detachBuffer: buffer in slot %zu has not been requested", slot); return BAD_VALUE; } std::shared_ptr producer_buffer = queue_->GetBuffer(slot); if (producer_buffer == nullptr || producer_buffer->buffer() == nullptr) { ALOGE("detachBuffer: Invalid ProducerBuffer at slot %zu.", slot); return BAD_VALUE; } sp graphic_buffer = producer_buffer->buffer()->buffer(); if (graphic_buffer == nullptr) { ALOGE("detachBuffer: Invalid GraphicBuffer at slot %zu.", slot); return BAD_VALUE; } // Remove the ProducerBuffer from the ProducerQueue. status_t error = RemoveBuffer(slot); if (error != NO_ERROR) { ALOGE("detachBuffer: Failed to remove buffer, slot=%zu, error=%d.", slot, error); return error; } // Here we need to convert the existing ProducerBuffer into a DetachedBufferHandle and inject // the handle into the GraphicBuffer object at the requested slot. auto status_or_handle = producer_buffer->Detach(); if (!status_or_handle.ok()) { ALOGE("detachBuffer: Failed to detach from a ProducerBuffer at slot %zu, error=%d.", slot, status_or_handle.error()); return BAD_VALUE; } // TODO(b/70912269): Reimplement BufferHubProducer::DetachBufferLocked() once GraphicBuffer can // be directly backed by BufferHub. return INVALID_OPERATION; } status_t BufferHubProducer::detachNextBuffer(sp* out_buffer, sp* out_fence) { ALOGV("detachNextBuffer."); if (out_buffer == nullptr || out_fence == nullptr) { ALOGE("detachNextBuffer: Invalid parameter: out_buffer=%p, out_fence=%p", out_buffer, out_fence); return BAD_VALUE; } std::unique_lock lock(mutex_); if (connected_api_ == kNoConnectedApi) { ALOGE("detachNextBuffer: BufferHubProducer is not connected."); return NO_INIT; } // detachNextBuffer is equivalent to calling dequeueBuffer, requestBuffer, and detachBuffer in // sequence, except for two things: // // 1) It is unnecessary to know the dimensions, format, or usage of the next buffer, i.e. the // function just returns whatever ProducerBuffer is available from the ProducerQueue and no // buffer allocation or re-allocation will happen. // 2) It will not block, since if it cannot find an appropriate buffer to return, it will return // an error instead. size_t slot = 0; LocalHandle fence; // First, dequeue a ProducerBuffer from the ProducerQueue with no timeout. Report error // immediately if ProducerQueue::Dequeue() fails. auto status_or_buffer = queue_->Dequeue(/*timeout=*/0, &slot, &fence); if (!status_or_buffer.ok()) { ALOGE("detachNextBuffer: Failed to dequeue buffer, error=%d.", status_or_buffer.error()); return NO_MEMORY; } std::shared_ptr producer_buffer = status_or_buffer.take(); if (producer_buffer == nullptr) { ALOGE("detachNextBuffer: Dequeued buffer is null."); return NO_MEMORY; } // With the BufferHub backed solution, slot returned from |queue_->Dequeue| is guaranteed to // be available for producer's use. It's either in free state (if the buffer has never been used // before) or in queued state (if the buffer has been dequeued and queued back to // BufferHubQueue). if (!buffers_[slot].mBufferState.isFree() && !buffers_[slot].mBufferState.isQueued()) { ALOGE("detachNextBuffer: slot %zu is not free or queued, actual state: %s.", slot, buffers_[slot].mBufferState.string()); return BAD_VALUE; } if (buffers_[slot].mProducerBuffer == nullptr) { ALOGE("detachNextBuffer: ProducerBuffer at slot %zu is null.", slot); return BAD_VALUE; } if (buffers_[slot].mProducerBuffer->id() != producer_buffer->id()) { ALOGE("detachNextBuffer: ProducerBuffer at slot %zu has mismatched id, actual: " "%d, expected: %d.", slot, buffers_[slot].mProducerBuffer->id(), producer_buffer->id()); return BAD_VALUE; } ALOGV("detachNextBuffer: slot=%zu", slot); buffers_[slot].mBufferState.freeQueued(); buffers_[slot].mBufferState.dequeue(); // Second, request the buffer. sp graphic_buffer = producer_buffer->buffer()->buffer(); buffers_[slot].mGraphicBuffer = producer_buffer->buffer()->buffer(); // Finally, detach the buffer and then return. status_t error = DetachBufferLocked(slot); if (error == NO_ERROR) { *out_fence = new Fence(fence.Release()); *out_buffer = graphic_buffer; } return error; } status_t BufferHubProducer::attachBuffer(int* out_slot, const sp& buffer) { // In the BufferHub design, all buffers are allocated and owned by the BufferHub. Thus only // GraphicBuffers that are originated from BufferHub can be attached to a BufferHubProducer. ALOGV("queueBuffer: buffer=%p", buffer.get()); if (out_slot == nullptr) { ALOGE("attachBuffer: out_slot cannot be NULL."); return BAD_VALUE; } if (buffer == nullptr) { ALOGE("attachBuffer: invalid GraphicBuffer."); return BAD_VALUE; } std::unique_lock lock(mutex_); if (connected_api_ == kNoConnectedApi) { ALOGE("attachBuffer: BufferQueue has no connected producer"); return NO_INIT; } // Before attaching the buffer, caller is supposed to call // IGraphicBufferProducer::setGenerationNumber to inform the // BufferHubProducer the next generation number. if (buffer->getGenerationNumber() != generation_number_) { ALOGE("attachBuffer: Mismatched generation number, buffer: %u, queue: %u.", buffer->getGenerationNumber(), generation_number_); return BAD_VALUE; } // TODO(b/70912269): Reimplement BufferHubProducer::DetachBufferLocked() once GraphicBuffer can // be directly backed by BufferHub. return INVALID_OPERATION; } status_t BufferHubProducer::queueBuffer(int slot, const QueueBufferInput& input, QueueBufferOutput* output) { ALOGV("queueBuffer: slot %d", slot); if (output == nullptr) { return BAD_VALUE; } int64_t timestamp; bool is_auto_timestamp; android_dataspace dataspace; Rect crop(Rect::EMPTY_RECT); int scaling_mode; uint32_t transform; sp fence; input.deflate(×tamp, &is_auto_timestamp, &dataspace, &crop, &scaling_mode, &transform, &fence); // Check input scaling mode is valid. switch (scaling_mode) { case NATIVE_WINDOW_SCALING_MODE_FREEZE: case NATIVE_WINDOW_SCALING_MODE_SCALE_TO_WINDOW: case NATIVE_WINDOW_SCALING_MODE_SCALE_CROP: case NATIVE_WINDOW_SCALING_MODE_NO_SCALE_CROP: break; default: ALOGE("queueBuffer: unknown scaling mode %d", scaling_mode); return BAD_VALUE; } // Check input fence is valid. if (fence == nullptr) { ALOGE("queueBuffer: fence is NULL"); return BAD_VALUE; } std::unique_lock lock(mutex_); if (connected_api_ == kNoConnectedApi) { ALOGE("queueBuffer: BufferQueue has no connected producer"); return NO_INIT; } if (slot < 0 || slot >= max_buffer_count_) { ALOGE("queueBuffer: slot index %d out of range [0, %d)", slot, max_buffer_count_); return BAD_VALUE; } else if (!buffers_[slot].mBufferState.isDequeued()) { ALOGE("queueBuffer: slot %d is not owned by the producer (state = %s)", slot, buffers_[slot].mBufferState.string()); return BAD_VALUE; } else if ((!buffers_[slot].mRequestBufferCalled || buffers_[slot].mGraphicBuffer == nullptr)) { ALOGE("queueBuffer: slot %d is not requested (mRequestBufferCalled=%d, " "mGraphicBuffer=%p)", slot, buffers_[slot].mRequestBufferCalled, buffers_[slot].mGraphicBuffer.get()); return BAD_VALUE; } // Post the producer buffer with timestamp in the metadata. const auto& producer_buffer = buffers_[slot].mProducerBuffer; // Check input crop is not out of boundary of current buffer. Rect buffer_rect(producer_buffer->width(), producer_buffer->height()); Rect cropped_rect(Rect::EMPTY_RECT); crop.intersect(buffer_rect, &cropped_rect); if (cropped_rect != crop) { ALOGE("queueBuffer: slot %d has out-of-boundary crop.", slot); return BAD_VALUE; } LocalHandle fence_fd(fence->isValid() ? fence->dup() : -1); DvrNativeBufferMetadata meta_data; meta_data.timestamp = timestamp; meta_data.is_auto_timestamp = int32_t(is_auto_timestamp); meta_data.dataspace = int32_t(dataspace); meta_data.crop_left = crop.left; meta_data.crop_top = crop.top; meta_data.crop_right = crop.right; meta_data.crop_bottom = crop.bottom; meta_data.scaling_mode = int32_t(scaling_mode); meta_data.transform = int32_t(transform); producer_buffer->PostAsync(&meta_data, fence_fd); buffers_[slot].mBufferState.queue(); output->width = producer_buffer->width(); output->height = producer_buffer->height(); output->transformHint = 0; // default value, we don't use it yet. // |numPendingBuffers| counts of the number of buffers that has been enqueued // by the producer but not yet acquired by the consumer. Due to the nature // of BufferHubQueue design, this is hard to trace from the producer's client // side, but it's safe to assume it's zero. output->numPendingBuffers = 0; // Note that we are not setting nextFrameNumber here as it seems to be only // used by surface flinger. See more at b/22802885, ag/791760. output->nextFrameNumber = 0; return NO_ERROR; } status_t BufferHubProducer::cancelBuffer(int slot, const sp& fence) { ALOGV(__FUNCTION__); std::unique_lock lock(mutex_); if (connected_api_ == kNoConnectedApi) { ALOGE("cancelBuffer: BufferQueue has no connected producer"); return NO_INIT; } if (slot < 0 || slot >= max_buffer_count_) { ALOGE("cancelBuffer: slot index %d out of range [0, %d)", slot, max_buffer_count_); return BAD_VALUE; } else if (!buffers_[slot].mBufferState.isDequeued()) { ALOGE("cancelBuffer: slot %d is not owned by the producer (state = %s)", slot, buffers_[slot].mBufferState.string()); return BAD_VALUE; } else if (fence == nullptr) { ALOGE("cancelBuffer: fence is NULL"); return BAD_VALUE; } auto producer_buffer = buffers_[slot].mProducerBuffer; queue_->Enqueue(producer_buffer, size_t(slot), 0U); buffers_[slot].mBufferState.cancel(); buffers_[slot].mFence = fence; ALOGV("cancelBuffer: slot %d", slot); return NO_ERROR; } status_t BufferHubProducer::query(int what, int* out_value) { ALOGV(__FUNCTION__); std::unique_lock lock(mutex_); if (out_value == nullptr) { ALOGE("query: out_value was NULL"); return BAD_VALUE; } int value = 0; switch (what) { case NATIVE_WINDOW_MIN_UNDEQUEUED_BUFFERS: // TODO(b/36187402) This should be the maximum number of buffers that this // producer queue's consumer can acquire. Set to be at least one. Need to // find a way to set from the consumer side. value = kDefaultUndequeuedBuffers; break; case NATIVE_WINDOW_BUFFER_AGE: value = 0; break; case NATIVE_WINDOW_WIDTH: value = int32_t(queue_->default_width()); break; case NATIVE_WINDOW_HEIGHT: value = int32_t(queue_->default_height()); break; case NATIVE_WINDOW_FORMAT: value = int32_t(queue_->default_format()); break; case NATIVE_WINDOW_CONSUMER_RUNNING_BEHIND: // BufferHubQueue is always operating in async mode, thus semantically // consumer can never be running behind. See BufferQueueCore.cpp core // for more information about the original meaning of this flag. value = 0; break; case NATIVE_WINDOW_CONSUMER_USAGE_BITS: // TODO(jwcai) This is currently not implement as we don't need // IGraphicBufferConsumer parity. value = 0; break; case NATIVE_WINDOW_DEFAULT_DATASPACE: // TODO(jwcai) Return the default value android::BufferQueue is using as // there is no way dvr::ConsumerQueue can set it. value = 0; // HAL_DATASPACE_UNKNOWN break; case NATIVE_WINDOW_STICKY_TRANSFORM: // TODO(jwcai) Return the default value android::BufferQueue is using as // there is no way dvr::ConsumerQueue can set it. value = 0; break; case NATIVE_WINDOW_CONSUMER_IS_PROTECTED: // In Daydream's implementation, the consumer end (i.e. VR Compostior) // knows how to handle protected buffers. value = 1; break; default: return BAD_VALUE; } ALOGV("query: key=%d, v=%d", what, value); *out_value = value; return NO_ERROR; } status_t BufferHubProducer::connect(const sp& /* listener */, int api, bool /* producer_controlled_by_app */, QueueBufferOutput* output) { // Consumer interaction are actually handled by buffer hub, and we need // to maintain consumer operations here. We only need to perform basic input // parameter checks here. ALOGV(__FUNCTION__); if (output == nullptr) { return BAD_VALUE; } std::unique_lock lock(mutex_); if (connected_api_ != kNoConnectedApi) { return BAD_VALUE; } if (!queue_->is_connected()) { ALOGE("BufferHubProducer::connect: This BufferHubProducer is not " "connected to bufferhud. Has it been taken out as a parcelable?"); return BAD_VALUE; } switch (api) { case NATIVE_WINDOW_API_EGL: case NATIVE_WINDOW_API_CPU: case NATIVE_WINDOW_API_MEDIA: case NATIVE_WINDOW_API_CAMERA: connected_api_ = api; output->width = queue_->default_width(); output->height = queue_->default_height(); // default values, we don't use them yet. output->transformHint = 0; output->numPendingBuffers = 0; output->nextFrameNumber = 0; output->bufferReplaced = false; break; default: ALOGE("BufferHubProducer::connect: unknow API %d", api); return BAD_VALUE; } return NO_ERROR; } status_t BufferHubProducer::disconnect(int api, DisconnectMode /*mode*/) { // Consumer interaction are actually handled by buffer hub, and we need // to maintain consumer operations here. We only need to perform basic input // parameter checks here. ALOGV(__FUNCTION__); std::unique_lock lock(mutex_); if (kNoConnectedApi == connected_api_) { return NO_INIT; } else if (api != connected_api_) { return BAD_VALUE; } FreeAllBuffers(); connected_api_ = kNoConnectedApi; return NO_ERROR; } status_t BufferHubProducer::setSidebandStream(const sp& stream) { if (stream != nullptr) { // TODO(jwcai) Investigate how is is used, maybe use BufferHubBuffer's // metadata. ALOGE("SidebandStream is not currently supported."); return INVALID_OPERATION; } return NO_ERROR; } void BufferHubProducer::allocateBuffers(uint32_t /* width */, uint32_t /* height */, PixelFormat /* format */, uint64_t /* usage */) { // TODO(jwcai) |allocateBuffers| aims to preallocate up to the maximum number // of buffers permitted by the current BufferQueue configuration (aka // |max_buffer_count_|). ALOGE("BufferHubProducer::allocateBuffers not implemented."); } status_t BufferHubProducer::allowAllocation(bool /* allow */) { ALOGE("BufferHubProducer::allowAllocation not implemented."); return INVALID_OPERATION; } status_t BufferHubProducer::setGenerationNumber(uint32_t generation_number) { ALOGV(__FUNCTION__); std::unique_lock lock(mutex_); generation_number_ = generation_number; return NO_ERROR; } String8 BufferHubProducer::getConsumerName() const { // BufferHub based implementation could have one to many producer/consumer // relationship, thus |getConsumerName| from the producer side does not // make any sense. ALOGE("BufferHubProducer::getConsumerName not supported."); return String8("BufferHubQueue::StubConsumer"); } status_t BufferHubProducer::setSharedBufferMode(bool shared_buffer_mode) { if (shared_buffer_mode) { ALOGE("BufferHubProducer::setSharedBufferMode(true) is not supported."); // TODO(b/36373181) Front buffer mode for buffer hub queue as ANativeWindow. return INVALID_OPERATION; } // Setting to default should just work as a no-op. return NO_ERROR; } status_t BufferHubProducer::setAutoRefresh(bool auto_refresh) { if (auto_refresh) { ALOGE("BufferHubProducer::setAutoRefresh(true) is not supported."); return INVALID_OPERATION; } // Setting to default should just work as a no-op. return NO_ERROR; } status_t BufferHubProducer::setDequeueTimeout(nsecs_t timeout) { ALOGV(__FUNCTION__); std::unique_lock lock(mutex_); dequeue_timeout_ms_ = static_cast(timeout / (1000 * 1000)); return NO_ERROR; } status_t BufferHubProducer::getLastQueuedBuffer(sp* /* out_buffer */, sp* /* out_fence */, float /*out_transform_matrix*/[16]) { ALOGE("BufferHubProducer::getLastQueuedBuffer not implemented."); return INVALID_OPERATION; } void BufferHubProducer::getFrameTimestamps(FrameEventHistoryDelta* /*outDelta*/) { ALOGE("BufferHubProducer::getFrameTimestamps not implemented."); } status_t BufferHubProducer::getUniqueId(uint64_t* out_id) const { ALOGV(__FUNCTION__); *out_id = unique_id_; return NO_ERROR; } status_t BufferHubProducer::getConsumerUsage(uint64_t* out_usage) const { ALOGV(__FUNCTION__); // same value as returned by querying NATIVE_WINDOW_CONSUMER_USAGE_BITS *out_usage = 0; return NO_ERROR; } status_t BufferHubProducer::TakeAsParcelable(ProducerQueueParcelable* out_parcelable) { if (!out_parcelable || out_parcelable->IsValid()) return BAD_VALUE; if (connected_api_ != kNoConnectedApi) { ALOGE("BufferHubProducer::TakeAsParcelable: BufferHubProducer has " "connected client. Must disconnect first."); return BAD_VALUE; } if (!queue_->is_connected()) { ALOGE("BufferHubProducer::TakeAsParcelable: This BufferHubProducer " "is not connected to bufferhud. Has it been taken out as a " "parcelable?"); return BAD_VALUE; } auto status = queue_->TakeAsParcelable(); if (!status) { ALOGE("BufferHubProducer::TakeAsParcelable: Failed to take out " "ProducuerQueueParcelable from the producer queue, error: %s.", status.GetErrorMessage().c_str()); return BAD_VALUE; } *out_parcelable = status.take(); return NO_ERROR; } status_t BufferHubProducer::AllocateBuffer(uint32_t width, uint32_t height, uint32_t layer_count, PixelFormat format, uint64_t usage) { auto status = queue_->AllocateBuffer(width, height, layer_count, uint32_t(format), usage); if (!status) { ALOGE("BufferHubProducer::AllocateBuffer: Failed to allocate buffer: %s", status.GetErrorMessage().c_str()); return NO_MEMORY; } size_t slot = status.get(); auto producer_buffer = queue_->GetBuffer(slot); LOG_ALWAYS_FATAL_IF(producer_buffer == nullptr, "Failed to get the producer buffer at slot: %zu", slot); buffers_[slot].mProducerBuffer = producer_buffer; return NO_ERROR; } status_t BufferHubProducer::RemoveBuffer(size_t slot) { auto status = queue_->RemoveBuffer(slot); if (!status) { ALOGE("BufferHubProducer::RemoveBuffer: Failed to remove buffer at slot: %zu, error: %s.", slot, status.GetErrorMessage().c_str()); return INVALID_OPERATION; } // Reset in memory objects related the the buffer. buffers_[slot].mProducerBuffer = nullptr; buffers_[slot].mBufferState.detachProducer(); buffers_[slot].mFence = Fence::NO_FENCE; buffers_[slot].mGraphicBuffer = nullptr; buffers_[slot].mRequestBufferCalled = false; return NO_ERROR; } status_t BufferHubProducer::FreeAllBuffers() { for (size_t slot = 0; slot < BufferHubQueue::kMaxQueueCapacity; slot++) { // Reset in memory objects related the the buffer. buffers_[slot].mProducerBuffer = nullptr; buffers_[slot].mBufferState.reset(); buffers_[slot].mFence = Fence::NO_FENCE; buffers_[slot].mGraphicBuffer = nullptr; buffers_[slot].mRequestBufferCalled = false; } auto status = queue_->FreeAllBuffers(); if (!status) { ALOGE("BufferHubProducer::FreeAllBuffers: Failed to free all buffers on " "the queue: %s", status.GetErrorMessage().c_str()); } if (queue_->capacity() != 0 || queue_->count() != 0) { LOG_ALWAYS_FATAL("BufferHubProducer::FreeAllBuffers: Not all buffers are freed."); } return NO_ERROR; } status_t BufferHubProducer::exportToParcel(Parcel* parcel) { status_t res = TakeAsParcelable(&pending_producer_parcelable_); if (res != NO_ERROR) return res; if (!pending_producer_parcelable_.IsValid()) { ALOGE("BufferHubProducer::exportToParcel: Invalid parcelable object."); return BAD_VALUE; } res = parcel->writeUint32(USE_BUFFER_HUB); if (res != NO_ERROR) { ALOGE("BufferHubProducer::exportToParcel: Cannot write magic, res=%d.", res); return res; } return pending_producer_parcelable_.writeToParcel(parcel); } IBinder* BufferHubProducer::onAsBinder() { ALOGE("BufferHubProducer::onAsBinder: BufferHubProducer should never be used as an Binder " "object."); return nullptr; } } // namespace android