src/dawn_native/CommandBufferStateTracker.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/CommandBufferStateTracker.h"

 #include "common/Assert.h"
 #include "common/BitSetIterator.h"
 #include "dawn_native/BindGroup.h"
 #include "dawn_native/ComputePassEncoder.h"
 #include "dawn_native/ComputePipeline.h"
 #include "dawn_native/Forward.h"
 #include "dawn_native/ObjectType_autogen.h"
 #include "dawn_native/PipelineLayout.h"
 #include "dawn_native/RenderPipeline.h"

 // TODO(dawn:563): None of the error messages in this file include the buffer objects they are
 // validating against. It would be nice to improve that, but difficult to do without incurring
 // additional tracking costs.

 namespace dawn_native {

     namespace {
         bool BufferSizesAtLeastAsBig(const ityp::span<uint32_t, uint64_t> unverifiedBufferSizes,
                                      const std::vector<uint64_t>& pipelineMinBufferSizes) {
             ASSERT(unverifiedBufferSizes.size() == pipelineMinBufferSizes.size());

             for (uint32_t i = 0; i < unverifiedBufferSizes.size(); ++i) {
                 if (unverifiedBufferSizes[i] < pipelineMinBufferSizes[i]) {
                     return false;
                 }
             }

             return true;
         }
     }  // namespace

     enum ValidationAspect {
         VALIDATION_ASPECT_PIPELINE,
         VALIDATION_ASPECT_BIND_GROUPS,
         VALIDATION_ASPECT_VERTEX_BUFFERS,
         VALIDATION_ASPECT_INDEX_BUFFER,

         VALIDATION_ASPECT_COUNT
     };
     static_assert(VALIDATION_ASPECT_COUNT == CommandBufferStateTracker::kNumAspects, "");

     static constexpr CommandBufferStateTracker::ValidationAspects kDispatchAspects =
         1 << VALIDATION_ASPECT_PIPELINE | 1 << VALIDATION_ASPECT_BIND_GROUPS;

     static constexpr CommandBufferStateTracker::ValidationAspects kDrawAspects =
         1 << VALIDATION_ASPECT_PIPELINE | 1 << VALIDATION_ASPECT_BIND_GROUPS |
         1 << VALIDATION_ASPECT_VERTEX_BUFFERS;

     static constexpr CommandBufferStateTracker::ValidationAspects kDrawIndexedAspects =
         1 << VALIDATION_ASPECT_PIPELINE | 1 << VALIDATION_ASPECT_BIND_GROUPS |
         1 << VALIDATION_ASPECT_VERTEX_BUFFERS | 1 << VALIDATION_ASPECT_INDEX_BUFFER;

     static constexpr CommandBufferStateTracker::ValidationAspects kLazyAspects =
         1 << VALIDATION_ASPECT_BIND_GROUPS | 1 << VALIDATION_ASPECT_VERTEX_BUFFERS |
         1 << VALIDATION_ASPECT_INDEX_BUFFER;

     MaybeError CommandBufferStateTracker::ValidateCanDispatch() {
         return ValidateOperation(kDispatchAspects);
     }

     MaybeError CommandBufferStateTracker::ValidateCanDraw() {
         return ValidateOperation(kDrawAspects);
     }

     MaybeError CommandBufferStateTracker::ValidateCanDrawIndexed() {
         return ValidateOperation(kDrawIndexedAspects);
     }

     MaybeError CommandBufferStateTracker::ValidateBufferInRangeForVertexBuffer(
         uint32_t vertexCount,
         uint32_t firstVertex) {
         RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();

         const ityp::bitset<VertexBufferSlot, kMaxVertexBuffers>&
             vertexBufferSlotsUsedAsVertexBuffer =
                 lastRenderPipeline->GetVertexBufferSlotsUsedAsVertexBuffer();

         for (auto usedSlotVertex : IterateBitSet(vertexBufferSlotsUsedAsVertexBuffer)) {
             const VertexBufferInfo& vertexBuffer =
                 lastRenderPipeline->GetVertexBuffer(usedSlotVertex);
             uint64_t arrayStride = vertexBuffer.arrayStride;
             uint64_t bufferSize = mVertexBufferSizes[usedSlotVertex];

             if (arrayStride == 0) {
                 DAWN_INVALID_IF(vertexBuffer.usedBytesInStride > bufferSize,
                                 "Bound vertex buffer size (%u) at slot %u with an arrayStride of 0 "
                                 "is smaller than the required size for all attributes (%u)",
                                 bufferSize, static_cast<uint8_t>(usedSlotVertex),
                                 vertexBuffer.usedBytesInStride);
             } else {
                 uint64_t requiredSize =
                     (static_cast<uint64_t>(firstVertex) + vertexCount) * arrayStride;
                 // firstVertex and vertexCount are in uint32_t, and arrayStride must not
                 // be larger than kMaxVertexBufferArrayStride, which is currently 2048. So by
                 // doing checks in uint64_t we avoid overflows.
                 DAWN_INVALID_IF(
                     requiredSize > bufferSize,
                     "Vertex range (first: %u, count: %u) requires a larger buffer (%u) than the "
                     "bound buffer size (%u) of the vertex buffer at slot %u with stride (%u).",
                     firstVertex, vertexCount, requiredSize, bufferSize,
                     static_cast<uint8_t>(usedSlotVertex), arrayStride);
             }
         }

         return {};
     }

     MaybeError CommandBufferStateTracker::ValidateBufferInRangeForInstanceBuffer(
         uint32_t instanceCount,
         uint32_t firstInstance) {
         RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();

         const ityp::bitset<VertexBufferSlot, kMaxVertexBuffers>&
             vertexBufferSlotsUsedAsInstanceBuffer =
                 lastRenderPipeline->GetVertexBufferSlotsUsedAsInstanceBuffer();

         for (auto usedSlotInstance : IterateBitSet(vertexBufferSlotsUsedAsInstanceBuffer)) {
             const VertexBufferInfo& vertexBuffer =
                 lastRenderPipeline->GetVertexBuffer(usedSlotInstance);
             uint64_t arrayStride = vertexBuffer.arrayStride;
             uint64_t bufferSize = mVertexBufferSizes[usedSlotInstance];
             if (arrayStride == 0) {
                 DAWN_INVALID_IF(vertexBuffer.usedBytesInStride > bufferSize,
                                 "Bound vertex buffer size (%u) at slot %u with an arrayStride of 0 "
                                 "is smaller than the required size for all attributes (%u)",
                                 bufferSize, static_cast<uint8_t>(usedSlotInstance),
                                 vertexBuffer.usedBytesInStride);
             } else {
                 uint64_t requiredSize =
                     (static_cast<uint64_t>(firstInstance) + instanceCount) * arrayStride;
                 // firstInstance and instanceCount are in uint32_t, and arrayStride must
                 // not be larger than kMaxVertexBufferArrayStride, which is currently 2048.
                 // So by doing checks in uint64_t we avoid overflows.
                 DAWN_INVALID_IF(
                     requiredSize > bufferSize,
                     "Instance range (first: %u, count: %u) requires a larger buffer (%u) than the "
                     "bound buffer size (%u) of the vertex buffer at slot %u with stride (%u).",
                     firstInstance, instanceCount, requiredSize, bufferSize,
                     static_cast<uint8_t>(usedSlotInstance), arrayStride);
             }
         }

         return {};
     }

     MaybeError CommandBufferStateTracker::ValidateIndexBufferInRange(uint32_t indexCount,
                                                                      uint32_t firstIndex) {
         // Validate the range of index buffer
         // firstIndex and indexCount are in uint32_t, while IndexFormatSize is 2 (for
         // wgpu::IndexFormat::Uint16) or 4 (for wgpu::IndexFormat::Uint32), so by doing checks in
         // uint64_t we avoid overflows.
         DAWN_INVALID_IF(
             (static_cast<uint64_t>(firstIndex) + indexCount) * IndexFormatSize(mIndexFormat) >
                 mIndexBufferSize,
             "Index range (first: %u, count: %u, format: %s) does not fit in index buffer size "
             "(%u).",
             firstIndex, indexCount, mIndexFormat, mIndexBufferSize);
         return {};
     }

     MaybeError CommandBufferStateTracker::ValidateOperation(ValidationAspects requiredAspects) {
         // Fast return-true path if everything is good
         ValidationAspects missingAspects = requiredAspects & ~mAspects;
         if (missingAspects.none()) {
             return {};
         }

         // Generate an error immediately if a non-lazy aspect is missing as computing lazy aspects
         // requires the pipeline to be set.
         DAWN_TRY(CheckMissingAspects(missingAspects & ~kLazyAspects));

         RecomputeLazyAspects(missingAspects);

         DAWN_TRY(CheckMissingAspects(requiredAspects & ~mAspects));

         return {};
     }

     void CommandBufferStateTracker::RecomputeLazyAspects(ValidationAspects aspects) {
         ASSERT(mAspects[VALIDATION_ASPECT_PIPELINE]);
         ASSERT((aspects & ~kLazyAspects).none());

         if (aspects[VALIDATION_ASPECT_BIND_GROUPS]) {
             bool matches = true;

             for (BindGroupIndex i : IterateBitSet(mLastPipelineLayout->GetBindGroupLayoutsMask())) {
                 if (mBindgroups[i] == nullptr ||
                     mLastPipelineLayout->GetBindGroupLayout(i) != mBindgroups[i]->GetLayout() ||
                     !BufferSizesAtLeastAsBig(mBindgroups[i]->GetUnverifiedBufferSizes(),
                                              (*mMinBufferSizes)[i])) {
                     matches = false;
                     break;
                 }
             }

             if (matches) {
                 mAspects.set(VALIDATION_ASPECT_BIND_GROUPS);
             }
         }

         if (aspects[VALIDATION_ASPECT_VERTEX_BUFFERS]) {
             RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();

             const ityp::bitset<VertexBufferSlot, kMaxVertexBuffers>& requiredVertexBuffers =
                 lastRenderPipeline->GetVertexBufferSlotsUsed();
             if (IsSubset(requiredVertexBuffers, mVertexBufferSlotsUsed)) {
                 mAspects.set(VALIDATION_ASPECT_VERTEX_BUFFERS);
             }
         }

         if (aspects[VALIDATION_ASPECT_INDEX_BUFFER] && mIndexBufferSet) {
             RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();
             if (!IsStripPrimitiveTopology(lastRenderPipeline->GetPrimitiveTopology()) ||
                 mIndexFormat == lastRenderPipeline->GetStripIndexFormat()) {
                 mAspects.set(VALIDATION_ASPECT_INDEX_BUFFER);
             }
         }
     }

     MaybeError CommandBufferStateTracker::CheckMissingAspects(ValidationAspects aspects) {
         if (!aspects.any()) {
             return {};
         }

         DAWN_INVALID_IF(aspects[VALIDATION_ASPECT_PIPELINE], "No pipeline set.");

         if (DAWN_UNLIKELY(aspects[VALIDATION_ASPECT_INDEX_BUFFER])) {
             DAWN_INVALID_IF(!mIndexBufferSet, "Index buffer was not set.");

             RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();
             wgpu::IndexFormat pipelineIndexFormat = lastRenderPipeline->GetStripIndexFormat();
             DAWN_INVALID_IF(
                 IsStripPrimitiveTopology(lastRenderPipeline->GetPrimitiveTopology()) &&
                     mIndexFormat != pipelineIndexFormat,
                 "Strip index format (%s) of %s does not match index buffer format (%s).",
                 pipelineIndexFormat, lastRenderPipeline, mIndexFormat);

             // The chunk of code above should be similar to the one in |RecomputeLazyAspects|.
             // It returns the first invalid state found. We shouldn't be able to reach this line
             // because to have invalid aspects one of the above conditions must have failed earlier.
             // If this is reached, make sure lazy aspects and the error checks above are consistent.
             UNREACHABLE();
             return DAWN_FORMAT_VALIDATION_ERROR("Index buffer is invalid.");
         }

         // TODO(dawn:563): Indicate which slots were not set.
         DAWN_INVALID_IF(aspects[VALIDATION_ASPECT_VERTEX_BUFFERS],
                         "Vertex buffer slots required by %s were not set.", GetRenderPipeline());

         if (DAWN_UNLIKELY(aspects[VALIDATION_ASPECT_BIND_GROUPS])) {
             for (BindGroupIndex i : IterateBitSet(mLastPipelineLayout->GetBindGroupLayoutsMask())) {
                 ASSERT(HasPipeline());

                 DAWN_INVALID_IF(mBindgroups[i] == nullptr, "No bind group set at index %u.",
                                 static_cast<uint32_t>(i));

                 BindGroupLayoutBase* requiredBGL = mLastPipelineLayout->GetBindGroupLayout(i);
                 BindGroupLayoutBase* currentBGL = mBindgroups[i]->GetLayout();

                 DAWN_INVALID_IF(
                     requiredBGL->GetPipelineCompatibilityToken() != PipelineCompatibilityToken(0) &&
                         currentBGL->GetPipelineCompatibilityToken() !=
                             requiredBGL->GetPipelineCompatibilityToken(),
                     "The current pipeline (%s) was created with a default layout, and is not "
                     "compatible with the %s at index %u which uses a %s that was not created by "
                     "the pipeline. Either use the bind group layout returned by calling "
                     "getBindGroupLayout(%u) on the pipeline when creating the bind group, or "
                     "provide an explicit pipeline layout when creating the pipeline.",
                     mLastPipeline, mBindgroups[i], static_cast<uint32_t>(i), currentBGL,
                     static_cast<uint32_t>(i));

                 DAWN_INVALID_IF(
                     requiredBGL->GetPipelineCompatibilityToken() == PipelineCompatibilityToken(0) &&
                         currentBGL->GetPipelineCompatibilityToken() !=
                             PipelineCompatibilityToken(0),
                     "%s at index %u uses a %s which was created as part of the default layout for "
                     "a different pipeline than the current one (%s), and as a result is not "
                     "compatible. Use an explicit bind group layout when creating bind groups and "
                     "an explicit pipeline layout when creating pipelines to share bind groups "
                     "between pipelines.",
                     mBindgroups[i], static_cast<uint32_t>(i), currentBGL, mLastPipeline);

                 DAWN_INVALID_IF(
                     mLastPipelineLayout->GetBindGroupLayout(i) != mBindgroups[i]->GetLayout(),
                     "Bind group layout %s of pipeline layout %s does not match layout %s of bind "
                     "group %s at index %u.",
                     requiredBGL, mLastPipelineLayout, currentBGL, mBindgroups[i],
                     static_cast<uint32_t>(i));

                 // TODO(dawn:563): Report the binding sizes and which ones are failing.
                 DAWN_INVALID_IF(!BufferSizesAtLeastAsBig(mBindgroups[i]->GetUnverifiedBufferSizes(),
                                                          (*mMinBufferSizes)[i]),
                                 "Binding sizes are too small for bind group %s at index %u",
                                 mBindgroups[i], static_cast<uint32_t>(i));
             }

             // The chunk of code above should be similar to the one in |RecomputeLazyAspects|.
             // It returns the first invalid state found. We shouldn't be able to reach this line
             // because to have invalid aspects one of the above conditions must have failed earlier.
             // If this is reached, make sure lazy aspects and the error checks above are consistent.
             UNREACHABLE();
             return DAWN_FORMAT_VALIDATION_ERROR("Bind groups are invalid.");
         }

         UNREACHABLE();
     }

     void CommandBufferStateTracker::SetComputePipeline(ComputePipelineBase* pipeline) {
         SetPipelineCommon(pipeline);
     }

     void CommandBufferStateTracker::SetRenderPipeline(RenderPipelineBase* pipeline) {
         SetPipelineCommon(pipeline);
     }

     void CommandBufferStateTracker::SetBindGroup(BindGroupIndex index,
                                                  BindGroupBase* bindgroup,
                                                  uint32_t dynamicOffsetCount,
                                                  const uint32_t* dynamicOffsets) {
         mBindgroups[index] = bindgroup;
         mDynamicOffsets[index].assign(dynamicOffsets, dynamicOffsets + dynamicOffsetCount);
         mAspects.reset(VALIDATION_ASPECT_BIND_GROUPS);
     }

     void CommandBufferStateTracker::SetIndexBuffer(wgpu::IndexFormat format, uint64_t size) {
         mIndexBufferSet = true;
         mIndexFormat = format;
         mIndexBufferSize = size;
     }

     void CommandBufferStateTracker::SetVertexBuffer(VertexBufferSlot slot, uint64_t size) {
         mVertexBufferSlotsUsed.set(slot);
         mVertexBufferSizes[slot] = size;
     }

     void CommandBufferStateTracker::SetPipelineCommon(PipelineBase* pipeline) {
         mLastPipeline = pipeline;
         mLastPipelineLayout = pipeline != nullptr ? pipeline->GetLayout() : nullptr;
         mMinBufferSizes = pipeline != nullptr ? &pipeline->GetMinBufferSizes() : nullptr;

         mAspects.set(VALIDATION_ASPECT_PIPELINE);

         // Reset lazy aspects so they get recomputed on the next operation.
         mAspects &= ~kLazyAspects;
     }

     BindGroupBase* CommandBufferStateTracker::GetBindGroup(BindGroupIndex index) const {
         return mBindgroups[index];
     }

     const std::vector<uint32_t>& CommandBufferStateTracker::GetDynamicOffsets(
         BindGroupIndex index) const {
         return mDynamicOffsets[index];
     }

     bool CommandBufferStateTracker::HasPipeline() const {
         return mLastPipeline != nullptr;
     }

     RenderPipelineBase* CommandBufferStateTracker::GetRenderPipeline() const {
         ASSERT(HasPipeline() && mLastPipeline->GetType() == ObjectType::RenderPipeline);
         return static_cast<RenderPipelineBase*>(mLastPipeline);
     }

     ComputePipelineBase* CommandBufferStateTracker::GetComputePipeline() const {
         ASSERT(HasPipeline() && mLastPipeline->GetType() == ObjectType::ComputePipeline);
         return static_cast<ComputePipelineBase*>(mLastPipeline);
     }

     PipelineLayoutBase* CommandBufferStateTracker::GetPipelineLayout() const {
         return mLastPipelineLayout;
     }

     wgpu::IndexFormat CommandBufferStateTracker::GetIndexFormat() const {
         return mIndexFormat;
     }

     uint64_t CommandBufferStateTracker::GetIndexBufferSize() const {
         return mIndexBufferSize;
     }

 }  // 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/CommandBufferStateTracker.h"

	#include "common/Assert.h"
	#include "common/BitSetIterator.h"
	#include "dawn_native/BindGroup.h"
	#include "dawn_native/ComputePassEncoder.h"
	#include "dawn_native/ComputePipeline.h"
	#include "dawn_native/Forward.h"
	#include "dawn_native/ObjectType_autogen.h"
	#include "dawn_native/PipelineLayout.h"
	#include "dawn_native/RenderPipeline.h"

	// TODO(dawn:563): None of the error messages in this file include the buffer objects they are
	// validating against. It would be nice to improve that, but difficult to do without incurring
	// additional tracking costs.

	namespace dawn_native {

	namespace {
	bool BufferSizesAtLeastAsBig(const ityp::span<uint32_t, uint64_t> unverifiedBufferSizes,
	const std::vector<uint64_t>& pipelineMinBufferSizes) {
	ASSERT(unverifiedBufferSizes.size() == pipelineMinBufferSizes.size());

	for (uint32_t i = 0; i < unverifiedBufferSizes.size(); ++i) {
	if (unverifiedBufferSizes[i] < pipelineMinBufferSizes[i]) {
	return false;
	}
	}

	return true;
	}
	} // namespace

	enum ValidationAspect {
	VALIDATION_ASPECT_PIPELINE,
	VALIDATION_ASPECT_BIND_GROUPS,
	VALIDATION_ASPECT_VERTEX_BUFFERS,
	VALIDATION_ASPECT_INDEX_BUFFER,

	VALIDATION_ASPECT_COUNT
	};
	static_assert(VALIDATION_ASPECT_COUNT == CommandBufferStateTracker::kNumAspects, "");

	static constexpr CommandBufferStateTracker::ValidationAspects kDispatchAspects =
	1 << VALIDATION_ASPECT_PIPELINE \| 1 << VALIDATION_ASPECT_BIND_GROUPS;

	static constexpr CommandBufferStateTracker::ValidationAspects kDrawAspects =
	1 << VALIDATION_ASPECT_PIPELINE \| 1 << VALIDATION_ASPECT_BIND_GROUPS \|
	1 << VALIDATION_ASPECT_VERTEX_BUFFERS;

	static constexpr CommandBufferStateTracker::ValidationAspects kDrawIndexedAspects =
	1 << VALIDATION_ASPECT_PIPELINE \| 1 << VALIDATION_ASPECT_BIND_GROUPS \|
	1 << VALIDATION_ASPECT_VERTEX_BUFFERS \| 1 << VALIDATION_ASPECT_INDEX_BUFFER;

	static constexpr CommandBufferStateTracker::ValidationAspects kLazyAspects =
	1 << VALIDATION_ASPECT_BIND_GROUPS \| 1 << VALIDATION_ASPECT_VERTEX_BUFFERS \|
	1 << VALIDATION_ASPECT_INDEX_BUFFER;

	MaybeError CommandBufferStateTracker::ValidateCanDispatch() {
	return ValidateOperation(kDispatchAspects);
	}

	MaybeError CommandBufferStateTracker::ValidateCanDraw() {
	return ValidateOperation(kDrawAspects);
	}

	MaybeError CommandBufferStateTracker::ValidateCanDrawIndexed() {
	return ValidateOperation(kDrawIndexedAspects);
	}

	MaybeError CommandBufferStateTracker::ValidateBufferInRangeForVertexBuffer(
	uint32_t vertexCount,
	uint32_t firstVertex) {
	RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();

	const ityp::bitset<VertexBufferSlot, kMaxVertexBuffers>&
	vertexBufferSlotsUsedAsVertexBuffer =
	lastRenderPipeline->GetVertexBufferSlotsUsedAsVertexBuffer();

	for (auto usedSlotVertex : IterateBitSet(vertexBufferSlotsUsedAsVertexBuffer)) {
	const VertexBufferInfo& vertexBuffer =
	lastRenderPipeline->GetVertexBuffer(usedSlotVertex);
	uint64_t arrayStride = vertexBuffer.arrayStride;
	uint64_t bufferSize = mVertexBufferSizes[usedSlotVertex];

	if (arrayStride == 0) {
	DAWN_INVALID_IF(vertexBuffer.usedBytesInStride > bufferSize,
	"Bound vertex buffer size (%u) at slot %u with an arrayStride of 0 "
	"is smaller than the required size for all attributes (%u)",
	bufferSize, static_cast<uint8_t>(usedSlotVertex),
	vertexBuffer.usedBytesInStride);
	} else {
	uint64_t requiredSize =
	(static_cast<uint64_t>(firstVertex) + vertexCount) * arrayStride;
	// firstVertex and vertexCount are in uint32_t, and arrayStride must not
	// be larger than kMaxVertexBufferArrayStride, which is currently 2048. So by
	// doing checks in uint64_t we avoid overflows.
	DAWN_INVALID_IF(
	requiredSize > bufferSize,
	"Vertex range (first: %u, count: %u) requires a larger buffer (%u) than the "
	"bound buffer size (%u) of the vertex buffer at slot %u with stride (%u).",
	firstVertex, vertexCount, requiredSize, bufferSize,
	static_cast<uint8_t>(usedSlotVertex), arrayStride);
	}
	}

	return {};
	}

	MaybeError CommandBufferStateTracker::ValidateBufferInRangeForInstanceBuffer(
	uint32_t instanceCount,
	uint32_t firstInstance) {
	RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();

	const ityp::bitset<VertexBufferSlot, kMaxVertexBuffers>&
	vertexBufferSlotsUsedAsInstanceBuffer =
	lastRenderPipeline->GetVertexBufferSlotsUsedAsInstanceBuffer();

	for (auto usedSlotInstance : IterateBitSet(vertexBufferSlotsUsedAsInstanceBuffer)) {
	const VertexBufferInfo& vertexBuffer =
	lastRenderPipeline->GetVertexBuffer(usedSlotInstance);
	uint64_t arrayStride = vertexBuffer.arrayStride;
	uint64_t bufferSize = mVertexBufferSizes[usedSlotInstance];
	if (arrayStride == 0) {
	DAWN_INVALID_IF(vertexBuffer.usedBytesInStride > bufferSize,
	"Bound vertex buffer size (%u) at slot %u with an arrayStride of 0 "
	"is smaller than the required size for all attributes (%u)",
	bufferSize, static_cast<uint8_t>(usedSlotInstance),
	vertexBuffer.usedBytesInStride);
	} else {
	uint64_t requiredSize =
	(static_cast<uint64_t>(firstInstance) + instanceCount) * arrayStride;
	// firstInstance and instanceCount are in uint32_t, and arrayStride must
	// not be larger than kMaxVertexBufferArrayStride, which is currently 2048.
	// So by doing checks in uint64_t we avoid overflows.
	DAWN_INVALID_IF(
	requiredSize > bufferSize,
	"Instance range (first: %u, count: %u) requires a larger buffer (%u) than the "
	"bound buffer size (%u) of the vertex buffer at slot %u with stride (%u).",
	firstInstance, instanceCount, requiredSize, bufferSize,
	static_cast<uint8_t>(usedSlotInstance), arrayStride);
	}
	}

	return {};
	}

	MaybeError CommandBufferStateTracker::ValidateIndexBufferInRange(uint32_t indexCount,
	uint32_t firstIndex) {
	// Validate the range of index buffer
	// firstIndex and indexCount are in uint32_t, while IndexFormatSize is 2 (for
	// wgpu::IndexFormat::Uint16) or 4 (for wgpu::IndexFormat::Uint32), so by doing checks in
	// uint64_t we avoid overflows.
	DAWN_INVALID_IF(
	(static_cast<uint64_t>(firstIndex) + indexCount) * IndexFormatSize(mIndexFormat) >
	mIndexBufferSize,
	"Index range (first: %u, count: %u, format: %s) does not fit in index buffer size "
	"(%u).",
	firstIndex, indexCount, mIndexFormat, mIndexBufferSize);
	return {};
	}

	MaybeError CommandBufferStateTracker::ValidateOperation(ValidationAspects requiredAspects) {
	// Fast return-true path if everything is good
	ValidationAspects missingAspects = requiredAspects & ~mAspects;
	if (missingAspects.none()) {
	return {};
	}

	// Generate an error immediately if a non-lazy aspect is missing as computing lazy aspects
	// requires the pipeline to be set.
	DAWN_TRY(CheckMissingAspects(missingAspects & ~kLazyAspects));

	RecomputeLazyAspects(missingAspects);

	DAWN_TRY(CheckMissingAspects(requiredAspects & ~mAspects));

	return {};
	}

	void CommandBufferStateTracker::RecomputeLazyAspects(ValidationAspects aspects) {
	ASSERT(mAspects[VALIDATION_ASPECT_PIPELINE]);
	ASSERT((aspects & ~kLazyAspects).none());

	if (aspects[VALIDATION_ASPECT_BIND_GROUPS]) {
	bool matches = true;

	for (BindGroupIndex i : IterateBitSet(mLastPipelineLayout->GetBindGroupLayoutsMask())) {
	if (mBindgroups[i] == nullptr \|\|
	mLastPipelineLayout->GetBindGroupLayout(i) != mBindgroups[i]->GetLayout() \|\|
	!BufferSizesAtLeastAsBig(mBindgroups[i]->GetUnverifiedBufferSizes(),
	(*mMinBufferSizes)[i])) {
	matches = false;
	break;
	}
	}

	if (matches) {
	mAspects.set(VALIDATION_ASPECT_BIND_GROUPS);
	}
	}

	if (aspects[VALIDATION_ASPECT_VERTEX_BUFFERS]) {
	RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();

	const ityp::bitset<VertexBufferSlot, kMaxVertexBuffers>& requiredVertexBuffers =
	lastRenderPipeline->GetVertexBufferSlotsUsed();
	if (IsSubset(requiredVertexBuffers, mVertexBufferSlotsUsed)) {
	mAspects.set(VALIDATION_ASPECT_VERTEX_BUFFERS);
	}
	}

	if (aspects[VALIDATION_ASPECT_INDEX_BUFFER] && mIndexBufferSet) {
	RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();
	if (!IsStripPrimitiveTopology(lastRenderPipeline->GetPrimitiveTopology()) \|\|
	mIndexFormat == lastRenderPipeline->GetStripIndexFormat()) {
	mAspects.set(VALIDATION_ASPECT_INDEX_BUFFER);
	}
	}
	}

	MaybeError CommandBufferStateTracker::CheckMissingAspects(ValidationAspects aspects) {
	if (!aspects.any()) {
	return {};
	}

	DAWN_INVALID_IF(aspects[VALIDATION_ASPECT_PIPELINE], "No pipeline set.");

	if (DAWN_UNLIKELY(aspects[VALIDATION_ASPECT_INDEX_BUFFER])) {
	DAWN_INVALID_IF(!mIndexBufferSet, "Index buffer was not set.");

	RenderPipelineBase* lastRenderPipeline = GetRenderPipeline();
	wgpu::IndexFormat pipelineIndexFormat = lastRenderPipeline->GetStripIndexFormat();
	DAWN_INVALID_IF(
	IsStripPrimitiveTopology(lastRenderPipeline->GetPrimitiveTopology()) &&
	mIndexFormat != pipelineIndexFormat,
	"Strip index format (%s) of %s does not match index buffer format (%s).",
	pipelineIndexFormat, lastRenderPipeline, mIndexFormat);

	// The chunk of code above should be similar to the one in \|RecomputeLazyAspects\|.
	// It returns the first invalid state found. We shouldn't be able to reach this line
	// because to have invalid aspects one of the above conditions must have failed earlier.
	// If this is reached, make sure lazy aspects and the error checks above are consistent.
	UNREACHABLE();
	return DAWN_FORMAT_VALIDATION_ERROR("Index buffer is invalid.");
	}

	// TODO(dawn:563): Indicate which slots were not set.
	DAWN_INVALID_IF(aspects[VALIDATION_ASPECT_VERTEX_BUFFERS],
	"Vertex buffer slots required by %s were not set.", GetRenderPipeline());

	if (DAWN_UNLIKELY(aspects[VALIDATION_ASPECT_BIND_GROUPS])) {
	for (BindGroupIndex i : IterateBitSet(mLastPipelineLayout->GetBindGroupLayoutsMask())) {
	ASSERT(HasPipeline());

	DAWN_INVALID_IF(mBindgroups[i] == nullptr, "No bind group set at index %u.",
	static_cast<uint32_t>(i));

	BindGroupLayoutBase* requiredBGL = mLastPipelineLayout->GetBindGroupLayout(i);
	BindGroupLayoutBase* currentBGL = mBindgroups[i]->GetLayout();

	DAWN_INVALID_IF(
	requiredBGL->GetPipelineCompatibilityToken() != PipelineCompatibilityToken(0) &&
	currentBGL->GetPipelineCompatibilityToken() !=
	requiredBGL->GetPipelineCompatibilityToken(),
	"The current pipeline (%s) was created with a default layout, and is not "
	"compatible with the %s at index %u which uses a %s that was not created by "
	"the pipeline. Either use the bind group layout returned by calling "
	"getBindGroupLayout(%u) on the pipeline when creating the bind group, or "
	"provide an explicit pipeline layout when creating the pipeline.",
	mLastPipeline, mBindgroups[i], static_cast<uint32_t>(i), currentBGL,
	static_cast<uint32_t>(i));

	DAWN_INVALID_IF(
	requiredBGL->GetPipelineCompatibilityToken() == PipelineCompatibilityToken(0) &&
	currentBGL->GetPipelineCompatibilityToken() !=
	PipelineCompatibilityToken(0),
	"%s at index %u uses a %s which was created as part of the default layout for "
	"a different pipeline than the current one (%s), and as a result is not "
	"compatible. Use an explicit bind group layout when creating bind groups and "
	"an explicit pipeline layout when creating pipelines to share bind groups "
	"between pipelines.",
	mBindgroups[i], static_cast<uint32_t>(i), currentBGL, mLastPipeline);

	DAWN_INVALID_IF(
	mLastPipelineLayout->GetBindGroupLayout(i) != mBindgroups[i]->GetLayout(),
	"Bind group layout %s of pipeline layout %s does not match layout %s of bind "
	"group %s at index %u.",
	requiredBGL, mLastPipelineLayout, currentBGL, mBindgroups[i],
	static_cast<uint32_t>(i));

	// TODO(dawn:563): Report the binding sizes and which ones are failing.
	DAWN_INVALID_IF(!BufferSizesAtLeastAsBig(mBindgroups[i]->GetUnverifiedBufferSizes(),
	(*mMinBufferSizes)[i]),
	"Binding sizes are too small for bind group %s at index %u",
	mBindgroups[i], static_cast<uint32_t>(i));
	}

	// The chunk of code above should be similar to the one in \|RecomputeLazyAspects\|.
	// It returns the first invalid state found. We shouldn't be able to reach this line
	// because to have invalid aspects one of the above conditions must have failed earlier.
	// If this is reached, make sure lazy aspects and the error checks above are consistent.
	UNREACHABLE();
	return DAWN_FORMAT_VALIDATION_ERROR("Bind groups are invalid.");
	}

	UNREACHABLE();
	}

	void CommandBufferStateTracker::SetComputePipeline(ComputePipelineBase* pipeline) {
	SetPipelineCommon(pipeline);
	}

	void CommandBufferStateTracker::SetRenderPipeline(RenderPipelineBase* pipeline) {
	SetPipelineCommon(pipeline);
	}

	void CommandBufferStateTracker::SetBindGroup(BindGroupIndex index,
	BindGroupBase* bindgroup,
	uint32_t dynamicOffsetCount,
	const uint32_t* dynamicOffsets) {
	mBindgroups[index] = bindgroup;
	mDynamicOffsets[index].assign(dynamicOffsets, dynamicOffsets + dynamicOffsetCount);
	mAspects.reset(VALIDATION_ASPECT_BIND_GROUPS);
	}

	void CommandBufferStateTracker::SetIndexBuffer(wgpu::IndexFormat format, uint64_t size) {
	mIndexBufferSet = true;
	mIndexFormat = format;
	mIndexBufferSize = size;
	}

	void CommandBufferStateTracker::SetVertexBuffer(VertexBufferSlot slot, uint64_t size) {
	mVertexBufferSlotsUsed.set(slot);
	mVertexBufferSizes[slot] = size;
	}

	void CommandBufferStateTracker::SetPipelineCommon(PipelineBase* pipeline) {
	mLastPipeline = pipeline;
	mLastPipelineLayout = pipeline != nullptr ? pipeline->GetLayout() : nullptr;
	mMinBufferSizes = pipeline != nullptr ? &pipeline->GetMinBufferSizes() : nullptr;

	mAspects.set(VALIDATION_ASPECT_PIPELINE);

	// Reset lazy aspects so they get recomputed on the next operation.
	mAspects &= ~kLazyAspects;
	}

	BindGroupBase* CommandBufferStateTracker::GetBindGroup(BindGroupIndex index) const {
	return mBindgroups[index];
	}

	const std::vector<uint32_t>& CommandBufferStateTracker::GetDynamicOffsets(
	BindGroupIndex index) const {
	return mDynamicOffsets[index];
	}

	bool CommandBufferStateTracker::HasPipeline() const {
	return mLastPipeline != nullptr;
	}

	RenderPipelineBase* CommandBufferStateTracker::GetRenderPipeline() const {
	ASSERT(HasPipeline() && mLastPipeline->GetType() == ObjectType::RenderPipeline);
	return static_cast<RenderPipelineBase*>(mLastPipeline);
	}

	ComputePipelineBase* CommandBufferStateTracker::GetComputePipeline() const {
	ASSERT(HasPipeline() && mLastPipeline->GetType() == ObjectType::ComputePipeline);
	return static_cast<ComputePipelineBase*>(mLastPipeline);
	}

	PipelineLayoutBase* CommandBufferStateTracker::GetPipelineLayout() const {
	return mLastPipelineLayout;
	}

	wgpu::IndexFormat CommandBufferStateTracker::GetIndexFormat() const {
	return mIndexFormat;
	}

	uint64_t CommandBufferStateTracker::GetIndexBufferSize() const {
	return mIndexBufferSize;
	}

	} // namespace dawn_native