src/dawn_native/Queue.cpp - dawn - Git at Google

 // Copyright 2017 The Dawn Authors
 //
 // 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 "dawn_native/Queue.h"

 #include "common/Constants.h"
 #include "dawn_native/Buffer.h"
 #include "dawn_native/CommandBuffer.h"
 #include "dawn_native/CommandEncoder.h"
 #include "dawn_native/CommandValidation.h"
 #include "dawn_native/Commands.h"
 #include "dawn_native/CopyTextureForBrowserHelper.h"
 #include "dawn_native/Device.h"
 #include "dawn_native/DynamicUploader.h"
 #include "dawn_native/ExternalTexture.h"
 #include "dawn_native/ObjectType_autogen.h"
 #include "dawn_native/QuerySet.h"
 #include "dawn_native/RenderPassEncoder.h"
 #include "dawn_native/RenderPipeline.h"
 #include "dawn_native/Texture.h"
 #include "dawn_platform/DawnPlatform.h"
 #include "dawn_platform/tracing/TraceEvent.h"

 #include <cstring>

 namespace dawn_native {

     namespace {

         void CopyTextureData(uint8_t* dstPointer,
                              const uint8_t* srcPointer,
                              uint32_t depth,
                              uint32_t rowsPerImage,
                              uint64_t imageAdditionalStride,
                              uint32_t actualBytesPerRow,
                              uint32_t dstBytesPerRow,
                              uint32_t srcBytesPerRow) {
             bool copyWholeLayer =
                 actualBytesPerRow == dstBytesPerRow && dstBytesPerRow == srcBytesPerRow;
             bool copyWholeData = copyWholeLayer && imageAdditionalStride == 0;

             if (!copyWholeLayer) {  // copy row by row
                 for (uint32_t d = 0; d < depth; ++d) {
                     for (uint32_t h = 0; h < rowsPerImage; ++h) {
                         memcpy(dstPointer, srcPointer, actualBytesPerRow);
                         dstPointer += dstBytesPerRow;
                         srcPointer += srcBytesPerRow;
                     }
                     srcPointer += imageAdditionalStride;
                 }
             } else {
                 uint64_t layerSize = uint64_t(rowsPerImage) * actualBytesPerRow;
                 if (!copyWholeData) {  // copy layer by layer
                     for (uint32_t d = 0; d < depth; ++d) {
                         memcpy(dstPointer, srcPointer, layerSize);
                         dstPointer += layerSize;
                         srcPointer += layerSize + imageAdditionalStride;
                     }
                 } else {  // do a single copy
                     memcpy(dstPointer, srcPointer, layerSize * depth);
                 }
             }
         }

         ResultOrError<UploadHandle> UploadTextureDataAligningBytesPerRowAndOffset(
             DeviceBase* device,
             const void* data,
             uint32_t alignedBytesPerRow,
             uint32_t optimallyAlignedBytesPerRow,
             uint32_t alignedRowsPerImage,
             const TextureDataLayout& dataLayout,
             bool hasDepthOrStencil,
             const TexelBlockInfo& blockInfo,
             const Extent3D& writeSizePixel) {
             uint64_t newDataSizeBytes;
             DAWN_TRY_ASSIGN(
                 newDataSizeBytes,
                 ComputeRequiredBytesInCopy(blockInfo, writeSizePixel, optimallyAlignedBytesPerRow,
                                            alignedRowsPerImage));

             uint64_t optimalOffsetAlignment =
                 device->GetOptimalBufferToTextureCopyOffsetAlignment();
             ASSERT(IsPowerOfTwo(optimalOffsetAlignment));
             ASSERT(IsPowerOfTwo(blockInfo.byteSize));
             // We need the offset to be aligned to both optimalOffsetAlignment and blockByteSize,
             // since both of them are powers of two, we only need to align to the max value.
             uint64_t offsetAlignment =
                 std::max(optimalOffsetAlignment, uint64_t(blockInfo.byteSize));

             // For depth-stencil texture, buffer offset must be a multiple of 4, which is required
             // by WebGPU and Vulkan SPEC.
             if (hasDepthOrStencil) {
                 constexpr uint64_t kOffsetAlignmentForDepthStencil = 4;
                 offsetAlignment = std::max(offsetAlignment, kOffsetAlignmentForDepthStencil);
             }

             UploadHandle uploadHandle;
             DAWN_TRY_ASSIGN(uploadHandle, device->GetDynamicUploader()->Allocate(
                                               newDataSizeBytes, device->GetPendingCommandSerial(),
                                               offsetAlignment));
             ASSERT(uploadHandle.mappedBuffer != nullptr);

             uint8_t* dstPointer = static_cast<uint8_t*>(uploadHandle.mappedBuffer);
             const uint8_t* srcPointer = static_cast<const uint8_t*>(data);
             srcPointer += dataLayout.offset;

             uint32_t dataRowsPerImage = dataLayout.rowsPerImage;
             if (dataRowsPerImage == 0) {
                 dataRowsPerImage = writeSizePixel.height / blockInfo.height;
             }

             ASSERT(dataRowsPerImage >= alignedRowsPerImage);
             uint64_t imageAdditionalStride =
                 dataLayout.bytesPerRow * (dataRowsPerImage - alignedRowsPerImage);

             CopyTextureData(dstPointer, srcPointer, writeSizePixel.depthOrArrayLayers,
                             alignedRowsPerImage, imageAdditionalStride, alignedBytesPerRow,
                             optimallyAlignedBytesPerRow, dataLayout.bytesPerRow);

             return uploadHandle;
         }

         struct SubmittedWorkDone : QueueBase::TaskInFlight {
             SubmittedWorkDone(WGPUQueueWorkDoneCallback callback, void* userdata)
                 : mCallback(callback), mUserdata(userdata) {
             }
             void Finish() override {
                 ASSERT(mCallback != nullptr);
                 mCallback(WGPUQueueWorkDoneStatus_Success, mUserdata);
                 mCallback = nullptr;
             }
             void HandleDeviceLoss() override {
                 ASSERT(mCallback != nullptr);
                 mCallback(WGPUQueueWorkDoneStatus_DeviceLost, mUserdata);
                 mCallback = nullptr;
             }
             ~SubmittedWorkDone() override = default;

           private:
             WGPUQueueWorkDoneCallback mCallback = nullptr;
             void* mUserdata;
         };

         class ErrorQueue : public QueueBase {
           public:
             ErrorQueue(DeviceBase* device) : QueueBase(device, ObjectBase::kError) {
             }

           private:
             MaybeError SubmitImpl(uint32_t commandCount,
                                   CommandBufferBase* const* commands) override {
                 UNREACHABLE();
             }
         };
     }  // namespace

     // QueueBase

     QueueBase::TaskInFlight::~TaskInFlight() {
     }

     QueueBase::QueueBase(DeviceBase* device) : ApiObjectBase(device, kLabelNotImplemented) {
     }

     QueueBase::QueueBase(DeviceBase* device, ObjectBase::ErrorTag tag)
         : ApiObjectBase(device, tag) {
     }

     QueueBase::~QueueBase() {
         ASSERT(mTasksInFlight.Empty());
     }

     void QueueBase::DestroyImpl() {
     }

     // static
     QueueBase* QueueBase::MakeError(DeviceBase* device) {
         return new ErrorQueue(device);
     }

     ObjectType QueueBase::GetType() const {
         return ObjectType::Queue;
     }

     void QueueBase::APISubmit(uint32_t commandCount, CommandBufferBase* const* commands) {
         SubmitInternal(commandCount, commands);

         for (uint32_t i = 0; i < commandCount; ++i) {
             commands[i]->Destroy();
         }
     }

     void QueueBase::APIOnSubmittedWorkDone(uint64_t signalValue,
                                            WGPUQueueWorkDoneCallback callback,
                                            void* userdata) {
         // The error status depends on the type of error so we let the validation function choose it
         WGPUQueueWorkDoneStatus status;
         if (GetDevice()->ConsumedError(ValidateOnSubmittedWorkDone(signalValue, &status))) {
             callback(status, userdata);
             return;
         }

         std::unique_ptr<SubmittedWorkDone> task =
             std::make_unique<SubmittedWorkDone>(callback, userdata);

         // Technically we only need to wait for previously submitted work but OnSubmittedWorkDone is
         // also used to make sure ALL queue work is finished in tests, so we also wait for pending
         // commands (this is non-observable outside of tests so it's ok to do deviate a bit from the
         // spec).
         TrackTask(std::move(task), GetDevice()->GetPendingCommandSerial());
     }

     void QueueBase::TrackTask(std::unique_ptr<TaskInFlight> task, ExecutionSerial serial) {
         mTasksInFlight.Enqueue(std::move(task), serial);
         GetDevice()->AddFutureSerial(serial);
     }

     void QueueBase::Tick(ExecutionSerial finishedSerial) {
         // If a user calls Queue::Submit inside a task, for example in a Buffer::MapAsync callback,
         // then the device will be ticked, which in turns ticks the queue, causing reentrance here.
         // To prevent the reentrant call from invalidating mTasksInFlight while in use by the first
         // call, we remove the tasks to finish from the queue, update mTasksInFlight, then run the
         // callbacks.
         std::vector<std::unique_ptr<TaskInFlight>> tasks;
         for (auto& task : mTasksInFlight.IterateUpTo(finishedSerial)) {
             tasks.push_back(std::move(task));
         }
         mTasksInFlight.ClearUpTo(finishedSerial);

         for (auto& task : tasks) {
             task->Finish();
         }
     }

     void QueueBase::HandleDeviceLoss() {
         for (auto& task : mTasksInFlight.IterateAll()) {
             task->HandleDeviceLoss();
         }
         mTasksInFlight.Clear();
     }

     void QueueBase::APIWriteBuffer(BufferBase* buffer,
                                    uint64_t bufferOffset,
                                    const void* data,
                                    size_t size) {
         GetDevice()->ConsumedError(WriteBuffer(buffer, bufferOffset, data, size));
     }

     MaybeError QueueBase::WriteBuffer(BufferBase* buffer,
                                       uint64_t bufferOffset,
                                       const void* data,
                                       size_t size) {
         DAWN_TRY(GetDevice()->ValidateIsAlive());
         DAWN_TRY(GetDevice()->ValidateObject(this));
         DAWN_TRY(ValidateWriteBuffer(GetDevice(), buffer, bufferOffset, size));
         DAWN_TRY(buffer->ValidateCanUseOnQueueNow());
         return WriteBufferImpl(buffer, bufferOffset, data, size);
     }

     MaybeError QueueBase::WriteBufferImpl(BufferBase* buffer,
                                           uint64_t bufferOffset,
                                           const void* data,
                                           size_t size) {
         if (size == 0) {
             return {};
         }

         DeviceBase* device = GetDevice();

         UploadHandle uploadHandle;
         DAWN_TRY_ASSIGN(uploadHandle, device->GetDynamicUploader()->Allocate(
                                           size, device->GetPendingCommandSerial(),
                                           kCopyBufferToBufferOffsetAlignment));
         ASSERT(uploadHandle.mappedBuffer != nullptr);

         memcpy(uploadHandle.mappedBuffer, data, size);

         device->AddFutureSerial(device->GetPendingCommandSerial());

         return device->CopyFromStagingToBuffer(uploadHandle.stagingBuffer, uploadHandle.startOffset,
                                                buffer, bufferOffset, size);
     }

     void QueueBase::APIWriteTexture(const ImageCopyTexture* destination,
                                     const void* data,
                                     size_t dataSize,
                                     const TextureDataLayout* dataLayout,
                                     const Extent3D* writeSize) {
         GetDevice()->ConsumedError(
             WriteTextureInternal(destination, data, dataSize, *dataLayout, writeSize));
     }

     MaybeError QueueBase::WriteTextureInternal(const ImageCopyTexture* destination,
                                                const void* data,
                                                size_t dataSize,
                                                const TextureDataLayout& dataLayout,
                                                const Extent3D* writeSize) {
         DAWN_TRY(ValidateWriteTexture(destination, dataSize, dataLayout, writeSize));

         if (writeSize->width == 0 || writeSize->height == 0 || writeSize->depthOrArrayLayers == 0) {
             return {};
         }

         const TexelBlockInfo& blockInfo =
             destination->texture->GetFormat().GetAspectInfo(destination->aspect).block;
         TextureDataLayout layout = dataLayout;
         ApplyDefaultTextureDataLayoutOptions(&layout, blockInfo, *writeSize);
         return WriteTextureImpl(*destination, data, layout, *writeSize);
     }

     MaybeError QueueBase::WriteTextureImpl(const ImageCopyTexture& destination,
                                            const void* data,
                                            const TextureDataLayout& dataLayout,
                                            const Extent3D& writeSizePixel) {
         const Format& format = destination.texture->GetFormat();
         const TexelBlockInfo& blockInfo = format.GetAspectInfo(destination.aspect).block;

         // We are only copying the part of the data that will appear in the texture.
         // Note that validating texture copy range ensures that writeSizePixel->width and
         // writeSizePixel->height are multiples of blockWidth and blockHeight respectively.
         ASSERT(writeSizePixel.width % blockInfo.width == 0);
         ASSERT(writeSizePixel.height % blockInfo.height == 0);
         uint32_t alignedBytesPerRow = writeSizePixel.width / blockInfo.width * blockInfo.byteSize;
         uint32_t alignedRowsPerImage = writeSizePixel.height / blockInfo.height;

         uint32_t optimalBytesPerRowAlignment = GetDevice()->GetOptimalBytesPerRowAlignment();
         uint32_t optimallyAlignedBytesPerRow =
             Align(alignedBytesPerRow, optimalBytesPerRowAlignment);

         UploadHandle uploadHandle;
         DAWN_TRY_ASSIGN(uploadHandle,
                         UploadTextureDataAligningBytesPerRowAndOffset(
                             GetDevice(), data, alignedBytesPerRow, optimallyAlignedBytesPerRow,
                             alignedRowsPerImage, dataLayout, format.HasDepthOrStencil(), blockInfo,
                             writeSizePixel));

         TextureDataLayout passDataLayout = dataLayout;
         passDataLayout.offset = uploadHandle.startOffset;
         passDataLayout.bytesPerRow = optimallyAlignedBytesPerRow;
         passDataLayout.rowsPerImage = alignedRowsPerImage;

         TextureCopy textureCopy;
         textureCopy.texture = destination.texture;
         textureCopy.mipLevel = destination.mipLevel;
         textureCopy.origin = destination.origin;
         textureCopy.aspect = ConvertAspect(format, destination.aspect);

         DeviceBase* device = GetDevice();

         device->AddFutureSerial(device->GetPendingCommandSerial());

         return device->CopyFromStagingToTexture(uploadHandle.stagingBuffer, passDataLayout,
                                                 &textureCopy, writeSizePixel);
     }

     void QueueBase::APICopyTextureForBrowser(const ImageCopyTexture* source,
                                              const ImageCopyTexture* destination,
                                              const Extent3D* copySize,
                                              const CopyTextureForBrowserOptions* options) {
         GetDevice()->ConsumedError(
             CopyTextureForBrowserInternal(source, destination, copySize, options));
     }

     MaybeError QueueBase::CopyTextureForBrowserInternal(
         const ImageCopyTexture* source,
         const ImageCopyTexture* destination,
         const Extent3D* copySize,
         const CopyTextureForBrowserOptions* options) {
         if (GetDevice()->IsValidationEnabled()) {
             DAWN_TRY_CONTEXT(
                 ValidateCopyTextureForBrowser(GetDevice(), source, destination, copySize, options),
                 "validating CopyTextureForBrowser from %s to %s", source->texture,
                 destination->texture);
         }

         return DoCopyTextureForBrowser(GetDevice(), source, destination, copySize, options);
     }

     MaybeError QueueBase::ValidateSubmit(uint32_t commandCount,
                                          CommandBufferBase* const* commands) const {
         TRACE_EVENT0(GetDevice()->GetPlatform(), Validation, "Queue::ValidateSubmit");
         DAWN_TRY(GetDevice()->ValidateObject(this));

         for (uint32_t i = 0; i < commandCount; ++i) {
             DAWN_TRY(GetDevice()->ValidateObject(commands[i]));
             DAWN_TRY(commands[i]->ValidateCanUseInSubmitNow());

             const CommandBufferResourceUsage& usages = commands[i]->GetResourceUsages();

             for (const SyncScopeResourceUsage& scope : usages.renderPasses) {
                 for (const BufferBase* buffer : scope.buffers) {
                     DAWN_TRY(buffer->ValidateCanUseOnQueueNow());
                 }

                 for (const TextureBase* texture : scope.textures) {
                     DAWN_TRY(texture->ValidateCanUseInSubmitNow());
                 }

                 for (const ExternalTextureBase* externalTexture : scope.externalTextures) {
                     DAWN_TRY(externalTexture->ValidateCanUseInSubmitNow());
                 }
             }

             for (const ComputePassResourceUsage& pass : usages.computePasses) {
                 for (const BufferBase* buffer : pass.referencedBuffers) {
                     DAWN_TRY(buffer->ValidateCanUseOnQueueNow());
                 }
                 for (const TextureBase* texture : pass.referencedTextures) {
                     DAWN_TRY(texture->ValidateCanUseInSubmitNow());
                 }
                 for (const ExternalTextureBase* externalTexture : pass.referencedExternalTextures) {
                     DAWN_TRY(externalTexture->ValidateCanUseInSubmitNow());
                 }
             }

             for (const BufferBase* buffer : usages.topLevelBuffers) {
                 DAWN_TRY(buffer->ValidateCanUseOnQueueNow());
             }
             for (const TextureBase* texture : usages.topLevelTextures) {
                 DAWN_TRY(texture->ValidateCanUseInSubmitNow());
             }
             for (const QuerySetBase* querySet : usages.usedQuerySets) {
                 DAWN_TRY(querySet->ValidateCanUseInSubmitNow());
             }
         }

         return {};
     }

     MaybeError QueueBase::ValidateOnSubmittedWorkDone(uint64_t signalValue,
                                                       WGPUQueueWorkDoneStatus* status) const {
         *status = WGPUQueueWorkDoneStatus_DeviceLost;
         DAWN_TRY(GetDevice()->ValidateIsAlive());

         *status = WGPUQueueWorkDoneStatus_Error;
         DAWN_TRY(GetDevice()->ValidateObject(this));

         DAWN_INVALID_IF(signalValue != 0, "SignalValue (%u) is not 0.", signalValue);

         return {};
     }

     MaybeError QueueBase::ValidateWriteTexture(const ImageCopyTexture* destination,
                                                size_t dataSize,
                                                const TextureDataLayout& dataLayout,
                                                const Extent3D* writeSize) const {
         DAWN_TRY(GetDevice()->ValidateIsAlive());
         DAWN_TRY(GetDevice()->ValidateObject(this));
         DAWN_TRY(GetDevice()->ValidateObject(destination->texture));

         DAWN_TRY(ValidateImageCopyTexture(GetDevice(), *destination, *writeSize));

         DAWN_INVALID_IF(dataLayout.offset > dataSize,
                         "Data offset (%u) is greater than the data size (%u).", dataLayout.offset,
                         dataSize);

         DAWN_INVALID_IF(!(destination->texture->GetUsage() & wgpu::TextureUsage::CopyDst),
                         "Usage (%s) of %s does not include %s.", destination->texture->GetUsage(),
                         destination->texture, wgpu::TextureUsage::CopyDst);

         DAWN_INVALID_IF(destination->texture->GetSampleCount() > 1,
                         "Sample count (%u) of %s is not 1", destination->texture->GetSampleCount(),
                         destination->texture);

         DAWN_TRY(ValidateLinearToDepthStencilCopyRestrictions(*destination));
         // We validate texture copy range before validating linear texture data,
         // because in the latter we divide copyExtent.width by blockWidth and
         // copyExtent.height by blockHeight while the divisibility conditions are
         // checked in validating texture copy range.
         DAWN_TRY(ValidateTextureCopyRange(GetDevice(), *destination, *writeSize));

         const TexelBlockInfo& blockInfo =
             destination->texture->GetFormat().GetAspectInfo(destination->aspect).block;

         DAWN_TRY(ValidateLinearTextureData(dataLayout, dataSize, blockInfo, *writeSize));

         DAWN_TRY(destination->texture->ValidateCanUseInSubmitNow());

         return {};
     }

     void QueueBase::SubmitInternal(uint32_t commandCount, CommandBufferBase* const* commands) {
         DeviceBase* device = GetDevice();
         if (device->ConsumedError(device->ValidateIsAlive())) {
             // If device is lost, don't let any commands be submitted
             return;
         }

         TRACE_EVENT0(device->GetPlatform(), General, "Queue::Submit");
         if (device->IsValidationEnabled() &&
             device->ConsumedError(ValidateSubmit(commandCount, commands))) {
             return;
         }
         ASSERT(!IsError());

         if (device->ConsumedError(SubmitImpl(commandCount, commands))) {
             return;
         }
     }

 }  // namespace dawn_native
	// Copyright 2017 The Dawn Authors
	//
	// 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 "dawn_native/Queue.h"

	#include "common/Constants.h"
	#include "dawn_native/Buffer.h"
	#include "dawn_native/CommandBuffer.h"
	#include "dawn_native/CommandEncoder.h"
	#include "dawn_native/CommandValidation.h"
	#include "dawn_native/Commands.h"
	#include "dawn_native/CopyTextureForBrowserHelper.h"
	#include "dawn_native/Device.h"
	#include "dawn_native/DynamicUploader.h"
	#include "dawn_native/ExternalTexture.h"
	#include "dawn_native/ObjectType_autogen.h"
	#include "dawn_native/QuerySet.h"
	#include "dawn_native/RenderPassEncoder.h"
	#include "dawn_native/RenderPipeline.h"
	#include "dawn_native/Texture.h"
	#include "dawn_platform/DawnPlatform.h"
	#include "dawn_platform/tracing/TraceEvent.h"

	#include <cstring>

	namespace dawn_native {

	namespace {

	void CopyTextureData(uint8_t* dstPointer,
	const uint8_t* srcPointer,
	uint32_t depth,
	uint32_t rowsPerImage,
	uint64_t imageAdditionalStride,
	uint32_t actualBytesPerRow,
	uint32_t dstBytesPerRow,
	uint32_t srcBytesPerRow) {
	bool copyWholeLayer =
	actualBytesPerRow == dstBytesPerRow && dstBytesPerRow == srcBytesPerRow;
	bool copyWholeData = copyWholeLayer && imageAdditionalStride == 0;

	if (!copyWholeLayer) { // copy row by row
	for (uint32_t d = 0; d < depth; ++d) {
	for (uint32_t h = 0; h < rowsPerImage; ++h) {
	memcpy(dstPointer, srcPointer, actualBytesPerRow);
	dstPointer += dstBytesPerRow;
	srcPointer += srcBytesPerRow;
	}
	srcPointer += imageAdditionalStride;
	}
	} else {
	uint64_t layerSize = uint64_t(rowsPerImage) * actualBytesPerRow;
	if (!copyWholeData) { // copy layer by layer
	for (uint32_t d = 0; d < depth; ++d) {
	memcpy(dstPointer, srcPointer, layerSize);
	dstPointer += layerSize;
	srcPointer += layerSize + imageAdditionalStride;
	}
	} else { // do a single copy
	memcpy(dstPointer, srcPointer, layerSize * depth);
	}
	}
	}

	ResultOrError<UploadHandle> UploadTextureDataAligningBytesPerRowAndOffset(
	DeviceBase* device,
	const void* data,
	uint32_t alignedBytesPerRow,
	uint32_t optimallyAlignedBytesPerRow,
	uint32_t alignedRowsPerImage,
	const TextureDataLayout& dataLayout,
	bool hasDepthOrStencil,
	const TexelBlockInfo& blockInfo,
	const Extent3D& writeSizePixel) {
	uint64_t newDataSizeBytes;
	DAWN_TRY_ASSIGN(
	newDataSizeBytes,
	ComputeRequiredBytesInCopy(blockInfo, writeSizePixel, optimallyAlignedBytesPerRow,
	alignedRowsPerImage));

	uint64_t optimalOffsetAlignment =
	device->GetOptimalBufferToTextureCopyOffsetAlignment();
	ASSERT(IsPowerOfTwo(optimalOffsetAlignment));
	ASSERT(IsPowerOfTwo(blockInfo.byteSize));
	// We need the offset to be aligned to both optimalOffsetAlignment and blockByteSize,
	// since both of them are powers of two, we only need to align to the max value.
	uint64_t offsetAlignment =
	std::max(optimalOffsetAlignment, uint64_t(blockInfo.byteSize));

	// For depth-stencil texture, buffer offset must be a multiple of 4, which is required
	// by WebGPU and Vulkan SPEC.
	if (hasDepthOrStencil) {
	constexpr uint64_t kOffsetAlignmentForDepthStencil = 4;
	offsetAlignment = std::max(offsetAlignment, kOffsetAlignmentForDepthStencil);
	}

	UploadHandle uploadHandle;
	DAWN_TRY_ASSIGN(uploadHandle, device->GetDynamicUploader()->Allocate(
	newDataSizeBytes, device->GetPendingCommandSerial(),
	offsetAlignment));
	ASSERT(uploadHandle.mappedBuffer != nullptr);

	uint8_t* dstPointer = static_cast<uint8_t*>(uploadHandle.mappedBuffer);
	const uint8_t* srcPointer = static_cast<const uint8_t*>(data);
	srcPointer += dataLayout.offset;

	uint32_t dataRowsPerImage = dataLayout.rowsPerImage;
	if (dataRowsPerImage == 0) {
	dataRowsPerImage = writeSizePixel.height / blockInfo.height;
	}

	ASSERT(dataRowsPerImage >= alignedRowsPerImage);
	uint64_t imageAdditionalStride =
	dataLayout.bytesPerRow * (dataRowsPerImage - alignedRowsPerImage);

	CopyTextureData(dstPointer, srcPointer, writeSizePixel.depthOrArrayLayers,
	alignedRowsPerImage, imageAdditionalStride, alignedBytesPerRow,
	optimallyAlignedBytesPerRow, dataLayout.bytesPerRow);

	return uploadHandle;
	}

	struct SubmittedWorkDone : QueueBase::TaskInFlight {
	SubmittedWorkDone(WGPUQueueWorkDoneCallback callback, void* userdata)
	: mCallback(callback), mUserdata(userdata) {
	}
	void Finish() override {
	ASSERT(mCallback != nullptr);
	mCallback(WGPUQueueWorkDoneStatus_Success, mUserdata);
	mCallback = nullptr;
	}
	void HandleDeviceLoss() override {
	ASSERT(mCallback != nullptr);
	mCallback(WGPUQueueWorkDoneStatus_DeviceLost, mUserdata);
	mCallback = nullptr;
	}
	~SubmittedWorkDone() override = default;

	private:
	WGPUQueueWorkDoneCallback mCallback = nullptr;
	void* mUserdata;
	};

	class ErrorQueue : public QueueBase {
	public:
	ErrorQueue(DeviceBase* device) : QueueBase(device, ObjectBase::kError) {
	}

	private:
	MaybeError SubmitImpl(uint32_t commandCount,
	CommandBufferBase* const* commands) override {
	UNREACHABLE();
	}
	};
	} // namespace

	// QueueBase

	QueueBase::TaskInFlight::~TaskInFlight() {
	}

	QueueBase::QueueBase(DeviceBase* device) : ApiObjectBase(device, kLabelNotImplemented) {
	}

	QueueBase::QueueBase(DeviceBase* device, ObjectBase::ErrorTag tag)
	: ApiObjectBase(device, tag) {
	}

	QueueBase::~QueueBase() {
	ASSERT(mTasksInFlight.Empty());
	}

	void QueueBase::DestroyImpl() {
	}

	// static
	QueueBase* QueueBase::MakeError(DeviceBase* device) {
	return new ErrorQueue(device);
	}

	ObjectType QueueBase::GetType() const {
	return ObjectType::Queue;
	}

	void QueueBase::APISubmit(uint32_t commandCount, CommandBufferBase* const* commands) {
	SubmitInternal(commandCount, commands);

	for (uint32_t i = 0; i < commandCount; ++i) {
	commands[i]->Destroy();
	}
	}

	void QueueBase::APIOnSubmittedWorkDone(uint64_t signalValue,
	WGPUQueueWorkDoneCallback callback,
	void* userdata) {
	// The error status depends on the type of error so we let the validation function choose it
	WGPUQueueWorkDoneStatus status;
	if (GetDevice()->ConsumedError(ValidateOnSubmittedWorkDone(signalValue, &status))) {
	callback(status, userdata);
	return;
	}

	std::unique_ptr<SubmittedWorkDone> task =
	std::make_unique<SubmittedWorkDone>(callback, userdata);

	// Technically we only need to wait for previously submitted work but OnSubmittedWorkDone is
	// also used to make sure ALL queue work is finished in tests, so we also wait for pending
	// commands (this is non-observable outside of tests so it's ok to do deviate a bit from the
	// spec).
	TrackTask(std::move(task), GetDevice()->GetPendingCommandSerial());
	}

	void QueueBase::TrackTask(std::unique_ptr<TaskInFlight> task, ExecutionSerial serial) {
	mTasksInFlight.Enqueue(std::move(task), serial);
	GetDevice()->AddFutureSerial(serial);
	}

	void QueueBase::Tick(ExecutionSerial finishedSerial) {
	// If a user calls Queue::Submit inside a task, for example in a Buffer::MapAsync callback,
	// then the device will be ticked, which in turns ticks the queue, causing reentrance here.
	// To prevent the reentrant call from invalidating mTasksInFlight while in use by the first
	// call, we remove the tasks to finish from the queue, update mTasksInFlight, then run the
	// callbacks.
	std::vector<std::unique_ptr<TaskInFlight>> tasks;
	for (auto& task : mTasksInFlight.IterateUpTo(finishedSerial)) {
	tasks.push_back(std::move(task));
	}
	mTasksInFlight.ClearUpTo(finishedSerial);

	for (auto& task : tasks) {
	task->Finish();
	}
	}

	void QueueBase::HandleDeviceLoss() {
	for (auto& task : mTasksInFlight.IterateAll()) {
	task->HandleDeviceLoss();
	}
	mTasksInFlight.Clear();
	}

	void QueueBase::APIWriteBuffer(BufferBase* buffer,
	uint64_t bufferOffset,
	const void* data,
	size_t size) {
	GetDevice()->ConsumedError(WriteBuffer(buffer, bufferOffset, data, size));
	}

	MaybeError QueueBase::WriteBuffer(BufferBase* buffer,
	uint64_t bufferOffset,
	const void* data,
	size_t size) {
	DAWN_TRY(GetDevice()->ValidateIsAlive());
	DAWN_TRY(GetDevice()->ValidateObject(this));
	DAWN_TRY(ValidateWriteBuffer(GetDevice(), buffer, bufferOffset, size));
	DAWN_TRY(buffer->ValidateCanUseOnQueueNow());
	return WriteBufferImpl(buffer, bufferOffset, data, size);
	}

	MaybeError QueueBase::WriteBufferImpl(BufferBase* buffer,
	uint64_t bufferOffset,
	const void* data,
	size_t size) {
	if (size == 0) {
	return {};
	}

	DeviceBase* device = GetDevice();

	UploadHandle uploadHandle;
	DAWN_TRY_ASSIGN(uploadHandle, device->GetDynamicUploader()->Allocate(
	size, device->GetPendingCommandSerial(),
	kCopyBufferToBufferOffsetAlignment));
	ASSERT(uploadHandle.mappedBuffer != nullptr);

	memcpy(uploadHandle.mappedBuffer, data, size);

	device->AddFutureSerial(device->GetPendingCommandSerial());

	return device->CopyFromStagingToBuffer(uploadHandle.stagingBuffer, uploadHandle.startOffset,
	buffer, bufferOffset, size);
	}

	void QueueBase::APIWriteTexture(const ImageCopyTexture* destination,
	const void* data,
	size_t dataSize,
	const TextureDataLayout* dataLayout,
	const Extent3D* writeSize) {
	GetDevice()->ConsumedError(
	WriteTextureInternal(destination, data, dataSize, *dataLayout, writeSize));
	}

	MaybeError QueueBase::WriteTextureInternal(const ImageCopyTexture* destination,
	const void* data,
	size_t dataSize,
	const TextureDataLayout& dataLayout,
	const Extent3D* writeSize) {
	DAWN_TRY(ValidateWriteTexture(destination, dataSize, dataLayout, writeSize));

	if (writeSize->width == 0 \|\| writeSize->height == 0 \|\| writeSize->depthOrArrayLayers == 0) {
	return {};
	}

	const TexelBlockInfo& blockInfo =
	destination->texture->GetFormat().GetAspectInfo(destination->aspect).block;
	TextureDataLayout layout = dataLayout;
	ApplyDefaultTextureDataLayoutOptions(&layout, blockInfo, *writeSize);
	return WriteTextureImpl(destination, data, layout, writeSize);
	}

	MaybeError QueueBase::WriteTextureImpl(const ImageCopyTexture& destination,
	const void* data,
	const TextureDataLayout& dataLayout,
	const Extent3D& writeSizePixel) {
	const Format& format = destination.texture->GetFormat();
	const TexelBlockInfo& blockInfo = format.GetAspectInfo(destination.aspect).block;

	// We are only copying the part of the data that will appear in the texture.
	// Note that validating texture copy range ensures that writeSizePixel->width and
	// writeSizePixel->height are multiples of blockWidth and blockHeight respectively.
	ASSERT(writeSizePixel.width % blockInfo.width == 0);
	ASSERT(writeSizePixel.height % blockInfo.height == 0);
	uint32_t alignedBytesPerRow = writeSizePixel.width / blockInfo.width * blockInfo.byteSize;
	uint32_t alignedRowsPerImage = writeSizePixel.height / blockInfo.height;

	uint32_t optimalBytesPerRowAlignment = GetDevice()->GetOptimalBytesPerRowAlignment();
	uint32_t optimallyAlignedBytesPerRow =
	Align(alignedBytesPerRow, optimalBytesPerRowAlignment);

	UploadHandle uploadHandle;
	DAWN_TRY_ASSIGN(uploadHandle,
	UploadTextureDataAligningBytesPerRowAndOffset(
	GetDevice(), data, alignedBytesPerRow, optimallyAlignedBytesPerRow,
	alignedRowsPerImage, dataLayout, format.HasDepthOrStencil(), blockInfo,
	writeSizePixel));

	TextureDataLayout passDataLayout = dataLayout;
	passDataLayout.offset = uploadHandle.startOffset;
	passDataLayout.bytesPerRow = optimallyAlignedBytesPerRow;
	passDataLayout.rowsPerImage = alignedRowsPerImage;

	TextureCopy textureCopy;
	textureCopy.texture = destination.texture;
	textureCopy.mipLevel = destination.mipLevel;
	textureCopy.origin = destination.origin;
	textureCopy.aspect = ConvertAspect(format, destination.aspect);

	DeviceBase* device = GetDevice();

	device->AddFutureSerial(device->GetPendingCommandSerial());

	return device->CopyFromStagingToTexture(uploadHandle.stagingBuffer, passDataLayout,
	&textureCopy, writeSizePixel);
	}

	void QueueBase::APICopyTextureForBrowser(const ImageCopyTexture* source,
	const ImageCopyTexture* destination,
	const Extent3D* copySize,
	const CopyTextureForBrowserOptions* options) {
	GetDevice()->ConsumedError(
	CopyTextureForBrowserInternal(source, destination, copySize, options));
	}

	MaybeError QueueBase::CopyTextureForBrowserInternal(
	const ImageCopyTexture* source,
	const ImageCopyTexture* destination,
	const Extent3D* copySize,
	const CopyTextureForBrowserOptions* options) {
	if (GetDevice()->IsValidationEnabled()) {
	DAWN_TRY_CONTEXT(
	ValidateCopyTextureForBrowser(GetDevice(), source, destination, copySize, options),
	"validating CopyTextureForBrowser from %s to %s", source->texture,
	destination->texture);
	}

	return DoCopyTextureForBrowser(GetDevice(), source, destination, copySize, options);
	}

	MaybeError QueueBase::ValidateSubmit(uint32_t commandCount,
	CommandBufferBase* const* commands) const {
	TRACE_EVENT0(GetDevice()->GetPlatform(), Validation, "Queue::ValidateSubmit");
	DAWN_TRY(GetDevice()->ValidateObject(this));

	for (uint32_t i = 0; i < commandCount; ++i) {
	DAWN_TRY(GetDevice()->ValidateObject(commands[i]));
	DAWN_TRY(commands[i]->ValidateCanUseInSubmitNow());

	const CommandBufferResourceUsage& usages = commands[i]->GetResourceUsages();

	for (const SyncScopeResourceUsage& scope : usages.renderPasses) {
	for (const BufferBase* buffer : scope.buffers) {
	DAWN_TRY(buffer->ValidateCanUseOnQueueNow());
	}

	for (const TextureBase* texture : scope.textures) {
	DAWN_TRY(texture->ValidateCanUseInSubmitNow());
	}

	for (const ExternalTextureBase* externalTexture : scope.externalTextures) {
	DAWN_TRY(externalTexture->ValidateCanUseInSubmitNow());
	}
	}

	for (const ComputePassResourceUsage& pass : usages.computePasses) {
	for (const BufferBase* buffer : pass.referencedBuffers) {
	DAWN_TRY(buffer->ValidateCanUseOnQueueNow());
	}
	for (const TextureBase* texture : pass.referencedTextures) {
	DAWN_TRY(texture->ValidateCanUseInSubmitNow());
	}
	for (const ExternalTextureBase* externalTexture : pass.referencedExternalTextures) {
	DAWN_TRY(externalTexture->ValidateCanUseInSubmitNow());
	}
	}

	for (const BufferBase* buffer : usages.topLevelBuffers) {
	DAWN_TRY(buffer->ValidateCanUseOnQueueNow());
	}
	for (const TextureBase* texture : usages.topLevelTextures) {
	DAWN_TRY(texture->ValidateCanUseInSubmitNow());
	}
	for (const QuerySetBase* querySet : usages.usedQuerySets) {
	DAWN_TRY(querySet->ValidateCanUseInSubmitNow());
	}
	}

	return {};
	}

	MaybeError QueueBase::ValidateOnSubmittedWorkDone(uint64_t signalValue,
	WGPUQueueWorkDoneStatus* status) const {
	*status = WGPUQueueWorkDoneStatus_DeviceLost;
	DAWN_TRY(GetDevice()->ValidateIsAlive());

	*status = WGPUQueueWorkDoneStatus_Error;
	DAWN_TRY(GetDevice()->ValidateObject(this));

	DAWN_INVALID_IF(signalValue != 0, "SignalValue (%u) is not 0.", signalValue);

	return {};
	}

	MaybeError QueueBase::ValidateWriteTexture(const ImageCopyTexture* destination,
	size_t dataSize,
	const TextureDataLayout& dataLayout,
	const Extent3D* writeSize) const {
	DAWN_TRY(GetDevice()->ValidateIsAlive());
	DAWN_TRY(GetDevice()->ValidateObject(this));
	DAWN_TRY(GetDevice()->ValidateObject(destination->texture));

	DAWN_TRY(ValidateImageCopyTexture(GetDevice(), destination, writeSize));

	DAWN_INVALID_IF(dataLayout.offset > dataSize,
	"Data offset (%u) is greater than the data size (%u).", dataLayout.offset,
	dataSize);

	DAWN_INVALID_IF(!(destination->texture->GetUsage() & wgpu::TextureUsage::CopyDst),
	"Usage (%s) of %s does not include %s.", destination->texture->GetUsage(),
	destination->texture, wgpu::TextureUsage::CopyDst);

	DAWN_INVALID_IF(destination->texture->GetSampleCount() > 1,
	"Sample count (%u) of %s is not 1", destination->texture->GetSampleCount(),
	destination->texture);

	DAWN_TRY(ValidateLinearToDepthStencilCopyRestrictions(*destination));
	// We validate texture copy range before validating linear texture data,
	// because in the latter we divide copyExtent.width by blockWidth and
	// copyExtent.height by blockHeight while the divisibility conditions are
	// checked in validating texture copy range.
	DAWN_TRY(ValidateTextureCopyRange(GetDevice(), destination, writeSize));

	const TexelBlockInfo& blockInfo =
	destination->texture->GetFormat().GetAspectInfo(destination->aspect).block;

	DAWN_TRY(ValidateLinearTextureData(dataLayout, dataSize, blockInfo, *writeSize));

	DAWN_TRY(destination->texture->ValidateCanUseInSubmitNow());

	return {};
	}

	void QueueBase::SubmitInternal(uint32_t commandCount, CommandBufferBase* const* commands) {
	DeviceBase* device = GetDevice();
	if (device->ConsumedError(device->ValidateIsAlive())) {
	// If device is lost, don't let any commands be submitted
	return;
	}

	TRACE_EVENT0(device->GetPlatform(), General, "Queue::Submit");
	if (device->IsValidationEnabled() &&
	device->ConsumedError(ValidateSubmit(commandCount, commands))) {
	return;
	}
	ASSERT(!IsError());

	if (device->ConsumedError(SubmitImpl(commandCount, commands))) {
	return;
	}
	}

	} // namespace dawn_native