Source/ThirdParty/ANGLE/src/libANGLE/VertexArray.h - WebKit - Git at Google

 //
 // Copyright 2013 The ANGLE Project Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.
 //
 // This class contains prototypes for representing GLES 3 Vertex Array Objects:
 //
 //   The buffer objects that are to be used by the vertex stage of the GL are collected
 //   together to form a vertex array object. All state related to the definition of data used
 //   by the vertex processor is encapsulated in a vertex array object.
 //

 #ifndef LIBANGLE_VERTEXARRAY_H_
 #define LIBANGLE_VERTEXARRAY_H_

 #include "common/Optional.h"
 #include "libANGLE/Constants.h"
 #include "libANGLE/Debug.h"
 #include "libANGLE/Observer.h"
 #include "libANGLE/RefCountObject.h"
 #include "libANGLE/VertexAttribute.h"

 #include <vector>

 namespace rx
 {
 class GLImplFactory;
 class VertexArrayImpl;
 }  // namespace rx

 namespace gl
 {
 class Buffer;

 class VertexArrayState final : angle::NonCopyable
 {
   public:
     VertexArrayState(VertexArray *vertexArray, size_t maxAttribs, size_t maxBindings);
     ~VertexArrayState();

     const std::string &getLabel() const { return mLabel; }

     Buffer *getElementArrayBuffer() const { return mElementArrayBuffer.get(); }
     size_t getMaxAttribs() const { return mVertexAttributes.size(); }
     size_t getMaxBindings() const { return mVertexBindings.size(); }
     const AttributesMask &getEnabledAttributesMask() const { return mEnabledAttributesMask; }
     const std::vector<VertexAttribute> &getVertexAttributes() const { return mVertexAttributes; }
     const VertexAttribute &getVertexAttribute(size_t attribIndex) const
     {
         return mVertexAttributes[attribIndex];
     }
     const std::vector<VertexBinding> &getVertexBindings() const { return mVertexBindings; }
     const VertexBinding &getVertexBinding(size_t bindingIndex) const
     {
         return mVertexBindings[bindingIndex];
     }
     const VertexBinding &getBindingFromAttribIndex(size_t attribIndex) const
     {
         return mVertexBindings[mVertexAttributes[attribIndex].bindingIndex];
     }
     size_t getBindingIndexFromAttribIndex(size_t attribIndex) const
     {
         return mVertexAttributes[attribIndex].bindingIndex;
     }

     void setAttribBinding(const Context *context, size_t attribIndex, GLuint newBindingIndex);

     // Extra validation performed on the Vertex Array.
     bool hasEnabledNullPointerClientArray() const;

     // Get all the attributes in an AttributesMask that are using the given binding.
     AttributesMask getBindingToAttributesMask(GLuint bindingIndex) const;

   private:
     friend class VertexArray;
     std::string mLabel;
     std::vector<VertexAttribute> mVertexAttributes;
     SubjectBindingPointer<Buffer> mElementArrayBuffer;
     std::vector<VertexBinding> mVertexBindings;
     AttributesMask mEnabledAttributesMask;
     ComponentTypeMask mVertexAttributesTypeMask;

     // This is a performance optimization for buffer binding. Allows element array buffer updates.
     friend class State;

     // From the GLES 3.1 spec:
     // When a generic attribute array is sourced from client memory, the vertex attribute binding
     // state is ignored. Thus we don't have to worry about binding state when using client memory
     // attribs.
     gl::AttributesMask mClientMemoryAttribsMask;
     gl::AttributesMask mNullPointerClientMemoryAttribsMask;

     // Used for validation cache. Indexed by attribute.
     AttributesMask mCachedMappedArrayBuffers;
     AttributesMask mCachedEnabledMappedArrayBuffers;
 };

 class VertexArray final : public angle::ObserverInterface,
                           public LabeledObject,
                           public angle::Subject
 {
   public:
     // Dirty bits for VertexArrays use a heirarchical design. At the top level, each attribute
     // has a single dirty bit. Then an array of MAX_ATTRIBS dirty bits each has a dirty bit for
     // enabled/pointer/format/binding. Bindings are handled similarly. Note that because the
     // total number of dirty bits is 33, it will not be as fast on a 32-bit machine, which
     // can't support the advanced 64-bit scanning intrinsics. We could consider packing the
     // binding and attribute bits together if this becomes a problem.
     //
     // Special note on "DIRTY_ATTRIB_POINTER_BUFFER": this is a special case when the app
     // calls glVertexAttribPointer but only changes a VBO and/or offset binding. This allows
     // the Vulkan back-end to skip performing a pipeline change for performance.
     enum DirtyBitType
     {
         DIRTY_BIT_ELEMENT_ARRAY_BUFFER,
         DIRTY_BIT_ELEMENT_ARRAY_BUFFER_DATA,

         // Dirty bits for attributes.
         DIRTY_BIT_ATTRIB_0,
         DIRTY_BIT_ATTRIB_MAX = DIRTY_BIT_ATTRIB_0 + gl::MAX_VERTEX_ATTRIBS,

         // Dirty bits for bindings.
         DIRTY_BIT_BINDING_0   = DIRTY_BIT_ATTRIB_MAX,
         DIRTY_BIT_BINDING_MAX = DIRTY_BIT_BINDING_0 + gl::MAX_VERTEX_ATTRIB_BINDINGS,

         // We keep separate dirty bits for bound buffers whose data changed since last update.
         DIRTY_BIT_BUFFER_DATA_0   = DIRTY_BIT_BINDING_MAX,
         DIRTY_BIT_BUFFER_DATA_MAX = DIRTY_BIT_BUFFER_DATA_0 + gl::MAX_VERTEX_ATTRIB_BINDINGS,

         DIRTY_BIT_UNKNOWN = DIRTY_BIT_BUFFER_DATA_MAX,
         DIRTY_BIT_MAX     = DIRTY_BIT_UNKNOWN,
     };

     // We want to keep the number of dirty bits within 64 to keep iteration times fast.
     static_assert(DIRTY_BIT_MAX <= 64, "Too many vertex array dirty bits.");

     enum DirtyAttribBitType
     {
         DIRTY_ATTRIB_ENABLED,
         DIRTY_ATTRIB_POINTER,
         DIRTY_ATTRIB_FORMAT,
         DIRTY_ATTRIB_BINDING,
         DIRTY_ATTRIB_POINTER_BUFFER,
         DIRTY_ATTRIB_UNKNOWN,
         DIRTY_ATTRIB_MAX = DIRTY_ATTRIB_UNKNOWN,
     };

     enum DirtyBindingBitType
     {
         DIRTY_BINDING_BUFFER,
         DIRTY_BINDING_DIVISOR,
         DIRTY_BINDING_UNKNOWN,
         DIRTY_BINDING_MAX = DIRTY_BINDING_UNKNOWN,
     };

     using DirtyBits             = angle::BitSet<DIRTY_BIT_MAX>;
     using DirtyAttribBits       = angle::BitSet<DIRTY_ATTRIB_MAX>;
     using DirtyBindingBits      = angle::BitSet<DIRTY_BINDING_MAX>;
     using DirtyAttribBitsArray  = std::array<DirtyAttribBits, gl::MAX_VERTEX_ATTRIBS>;
     using DirtyBindingBitsArray = std::array<DirtyBindingBits, gl::MAX_VERTEX_ATTRIB_BINDINGS>;

     VertexArray(rx::GLImplFactory *factory,
                 VertexArrayID id,
                 size_t maxAttribs,
                 size_t maxAttribBindings);

     void onDestroy(const Context *context);

     VertexArrayID id() const { return mId; }

     void setLabel(const Context *context, const std::string &label) override;
     const std::string &getLabel() const override;

     const VertexBinding &getVertexBinding(size_t bindingIndex) const;
     const VertexAttribute &getVertexAttribute(size_t attribIndex) const;
     const VertexBinding &getBindingFromAttribIndex(size_t attribIndex) const
     {
         return mState.getBindingFromAttribIndex(attribIndex);
     }

     // Returns true if the function finds and detaches a bound buffer.
     bool detachBuffer(const Context *context, BufferID bufferID);

     void setVertexAttribDivisor(const Context *context, size_t index, GLuint divisor);
     void enableAttribute(size_t attribIndex, bool enabledState);

     void setVertexAttribPointer(const Context *context,
                                 size_t attribIndex,
                                 Buffer *boundBuffer,
                                 GLint size,
                                 VertexAttribType type,
                                 bool normalized,
                                 GLsizei stride,
                                 const void *pointer);

     void setVertexAttribIPointer(const Context *context,
                                  size_t attribIndex,
                                  Buffer *boundBuffer,
                                  GLint size,
                                  VertexAttribType type,
                                  GLsizei stride,
                                  const void *pointer);

     void setVertexAttribFormat(size_t attribIndex,
                                GLint size,
                                VertexAttribType type,
                                bool normalized,
                                bool pureInteger,
                                GLuint relativeOffset);
     void bindVertexBuffer(const Context *context,
                           size_t bindingIndex,
                           Buffer *boundBuffer,
                           GLintptr offset,
                           GLsizei stride);
     void setVertexAttribBinding(const Context *context, size_t attribIndex, GLuint bindingIndex);
     void setVertexBindingDivisor(size_t bindingIndex, GLuint divisor);

     Buffer *getElementArrayBuffer() const { return mState.getElementArrayBuffer(); }
     size_t getMaxAttribs() const { return mState.getMaxAttribs(); }
     size_t getMaxBindings() const { return mState.getMaxBindings(); }

     const std::vector<VertexAttribute> &getVertexAttributes() const
     {
         return mState.getVertexAttributes();
     }
     const std::vector<VertexBinding> &getVertexBindings() const
     {
         return mState.getVertexBindings();
     }

     rx::VertexArrayImpl *getImplementation() const { return mVertexArray; }

     const AttributesMask &getEnabledAttributesMask() const
     {
         return mState.getEnabledAttributesMask();
     }

     gl::AttributesMask getClientAttribsMask() const { return mState.mClientMemoryAttribsMask; }

     bool hasEnabledNullPointerClientArray() const
     {
         return mState.hasEnabledNullPointerClientArray();
     }

     bool hasMappedEnabledArrayBuffer() const
     {
         return mState.mCachedEnabledMappedArrayBuffers.any();
     }

     // Observer implementation
     void onSubjectStateChange(angle::SubjectIndex index, angle::SubjectMessage message) override;

     static size_t GetVertexIndexFromDirtyBit(size_t dirtyBit);

     angle::Result syncState(const Context *context);
     bool hasAnyDirtyBit() const { return mDirtyBits.any(); }

     ComponentTypeMask getAttributesTypeMask() const { return mState.mVertexAttributesTypeMask; }
     AttributesMask getAttributesMask() const { return mState.mEnabledAttributesMask; }

     void onBindingChanged(const Context *context, int incr);
     bool hasTransformFeedbackBindingConflict(const gl::Context *context) const;

     ANGLE_INLINE angle::Result getIndexRange(const Context *context,
                                              DrawElementsType type,
                                              GLsizei indexCount,
                                              const void *indices,
                                              IndexRange *indexRangeOut) const
     {
         Buffer *elementArrayBuffer = mState.mElementArrayBuffer.get();
         if (elementArrayBuffer && mIndexRangeCache.get(type, indexCount, indices, indexRangeOut))
         {
             return angle::Result::Continue;
         }

         return getIndexRangeImpl(context, type, indexCount, indices, indexRangeOut);
     }

     void setBufferAccessValidationEnabled(bool enabled)
     {
         mBufferAccessValidationEnabled = enabled;
     }

   private:
     ~VertexArray() override;

     // This is a performance optimization for buffer binding. Allows element array buffer updates.
     friend class State;

     void setDirtyAttribBit(size_t attribIndex, DirtyAttribBitType dirtyAttribBit);
     void setDirtyBindingBit(size_t bindingIndex, DirtyBindingBitType dirtyBindingBit);

     DirtyBitType getDirtyBitFromIndex(bool contentsChanged, angle::SubjectIndex index) const;
     void setDependentDirtyBit(bool contentsChanged, angle::SubjectIndex index);

     // These are used to optimize draw call validation.
     void updateCachedBufferBindingSize(VertexBinding *binding);
     void updateCachedTransformFeedbackBindingValidation(size_t bindingIndex, const Buffer *buffer);
     void updateCachedMappedArrayBuffers(bool isMapped, const AttributesMask &boundAttributesMask);
     void updateCachedMappedArrayBuffersBinding(const VertexBinding &binding);

     angle::Result getIndexRangeImpl(const Context *context,
                                     DrawElementsType type,
                                     GLsizei indexCount,
                                     const void *indices,
                                     IndexRange *indexRangeOut) const;

     void setVertexAttribPointerImpl(const Context *context,
                                     ComponentType componentType,
                                     bool pureInteger,
                                     size_t attribIndex,
                                     Buffer *boundBuffer,
                                     GLint size,
                                     VertexAttribType type,
                                     bool normalized,
                                     GLsizei stride,
                                     const void *pointer);

     // These two functions return true if the state was dirty.
     bool setVertexAttribFormatImpl(VertexAttribute *attrib,
                                    GLint size,
                                    VertexAttribType type,
                                    bool normalized,
                                    bool pureInteger,
                                    GLuint relativeOffset);
     bool bindVertexBufferImpl(const Context *context,
                               size_t bindingIndex,
                               Buffer *boundBuffer,
                               GLintptr offset,
                               GLsizei stride);

     VertexArrayID mId;

     VertexArrayState mState;
     DirtyBits mDirtyBits;
     DirtyAttribBitsArray mDirtyAttribBits;
     DirtyBindingBitsArray mDirtyBindingBits;
     Optional<DirtyBits> mDirtyBitsGuard;

     rx::VertexArrayImpl *mVertexArray;

     std::vector<angle::ObserverBinding> mArrayBufferObserverBindings;

     AttributesMask mCachedTransformFeedbackConflictedBindingsMask;

     class IndexRangeCache final : angle::NonCopyable
     {
       public:
         IndexRangeCache();

         void invalidate() { mTypeKey = DrawElementsType::InvalidEnum; }

         bool get(DrawElementsType type,
                  GLsizei indexCount,
                  const void *indices,
                  IndexRange *indexRangeOut)
         {
             size_t offset = reinterpret_cast<uintptr_t>(indices);
             if (mTypeKey == type && mIndexCountKey == indexCount && mOffsetKey == offset)
             {
                 *indexRangeOut = mPayload;
                 return true;
             }

             return false;
         }

         void put(DrawElementsType type,
                  GLsizei indexCount,
                  size_t offset,
                  const IndexRange &indexRange);

       private:
         DrawElementsType mTypeKey;
         GLsizei mIndexCountKey;
         size_t mOffsetKey;
         IndexRange mPayload;
     };

     mutable IndexRangeCache mIndexRangeCache;
     bool mBufferAccessValidationEnabled;
 };

 }  // namespace gl

 #endif  // LIBANGLE_VERTEXARRAY_H_
	//
	// Copyright 2013 The ANGLE Project Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.
	//
	// This class contains prototypes for representing GLES 3 Vertex Array Objects:
	//
	// The buffer objects that are to be used by the vertex stage of the GL are collected
	// together to form a vertex array object. All state related to the definition of data used
	// by the vertex processor is encapsulated in a vertex array object.
	//

	#ifndef LIBANGLE_VERTEXARRAY_H_
	#define LIBANGLE_VERTEXARRAY_H_

	#include "common/Optional.h"
	#include "libANGLE/Constants.h"
	#include "libANGLE/Debug.h"
	#include "libANGLE/Observer.h"
	#include "libANGLE/RefCountObject.h"
	#include "libANGLE/VertexAttribute.h"

	#include <vector>

	namespace rx
	{
	class GLImplFactory;
	class VertexArrayImpl;
	} // namespace rx

	namespace gl
	{
	class Buffer;

	class VertexArrayState final : angle::NonCopyable
	{
	public:
	VertexArrayState(VertexArray *vertexArray, size_t maxAttribs, size_t maxBindings);
	~VertexArrayState();

	const std::string &getLabel() const { return mLabel; }

	Buffer *getElementArrayBuffer() const { return mElementArrayBuffer.get(); }
	size_t getMaxAttribs() const { return mVertexAttributes.size(); }
	size_t getMaxBindings() const { return mVertexBindings.size(); }
	const AttributesMask &getEnabledAttributesMask() const { return mEnabledAttributesMask; }
	const std::vector<VertexAttribute> &getVertexAttributes() const { return mVertexAttributes; }
	const VertexAttribute &getVertexAttribute(size_t attribIndex) const
	{
	return mVertexAttributes[attribIndex];
	}
	const std::vector<VertexBinding> &getVertexBindings() const { return mVertexBindings; }
	const VertexBinding &getVertexBinding(size_t bindingIndex) const
	{
	return mVertexBindings[bindingIndex];
	}
	const VertexBinding &getBindingFromAttribIndex(size_t attribIndex) const
	{
	return mVertexBindings[mVertexAttributes[attribIndex].bindingIndex];
	}
	size_t getBindingIndexFromAttribIndex(size_t attribIndex) const
	{
	return mVertexAttributes[attribIndex].bindingIndex;
	}

	void setAttribBinding(const Context *context, size_t attribIndex, GLuint newBindingIndex);

	// Extra validation performed on the Vertex Array.
	bool hasEnabledNullPointerClientArray() const;

	// Get all the attributes in an AttributesMask that are using the given binding.
	AttributesMask getBindingToAttributesMask(GLuint bindingIndex) const;

	private:
	friend class VertexArray;
	std::string mLabel;
	std::vector<VertexAttribute> mVertexAttributes;
	SubjectBindingPointer<Buffer> mElementArrayBuffer;
	std::vector<VertexBinding> mVertexBindings;
	AttributesMask mEnabledAttributesMask;
	ComponentTypeMask mVertexAttributesTypeMask;

	// This is a performance optimization for buffer binding. Allows element array buffer updates.
	friend class State;

	// From the GLES 3.1 spec:
	// When a generic attribute array is sourced from client memory, the vertex attribute binding
	// state is ignored. Thus we don't have to worry about binding state when using client memory
	// attribs.
	gl::AttributesMask mClientMemoryAttribsMask;
	gl::AttributesMask mNullPointerClientMemoryAttribsMask;

	// Used for validation cache. Indexed by attribute.
	AttributesMask mCachedMappedArrayBuffers;
	AttributesMask mCachedEnabledMappedArrayBuffers;
	};

	class VertexArray final : public angle::ObserverInterface,
	public LabeledObject,
	public angle::Subject
	{
	public:
	// Dirty bits for VertexArrays use a heirarchical design. At the top level, each attribute
	// has a single dirty bit. Then an array of MAX_ATTRIBS dirty bits each has a dirty bit for
	// enabled/pointer/format/binding. Bindings are handled similarly. Note that because the
	// total number of dirty bits is 33, it will not be as fast on a 32-bit machine, which
	// can't support the advanced 64-bit scanning intrinsics. We could consider packing the
	// binding and attribute bits together if this becomes a problem.
	//
	// Special note on "DIRTY_ATTRIB_POINTER_BUFFER": this is a special case when the app
	// calls glVertexAttribPointer but only changes a VBO and/or offset binding. This allows
	// the Vulkan back-end to skip performing a pipeline change for performance.
	enum DirtyBitType
	{
	DIRTY_BIT_ELEMENT_ARRAY_BUFFER,
	DIRTY_BIT_ELEMENT_ARRAY_BUFFER_DATA,

	// Dirty bits for attributes.
	DIRTY_BIT_ATTRIB_0,
	DIRTY_BIT_ATTRIB_MAX = DIRTY_BIT_ATTRIB_0 + gl::MAX_VERTEX_ATTRIBS,

	// Dirty bits for bindings.
	DIRTY_BIT_BINDING_0 = DIRTY_BIT_ATTRIB_MAX,
	DIRTY_BIT_BINDING_MAX = DIRTY_BIT_BINDING_0 + gl::MAX_VERTEX_ATTRIB_BINDINGS,

	// We keep separate dirty bits for bound buffers whose data changed since last update.
	DIRTY_BIT_BUFFER_DATA_0 = DIRTY_BIT_BINDING_MAX,
	DIRTY_BIT_BUFFER_DATA_MAX = DIRTY_BIT_BUFFER_DATA_0 + gl::MAX_VERTEX_ATTRIB_BINDINGS,

	DIRTY_BIT_UNKNOWN = DIRTY_BIT_BUFFER_DATA_MAX,
	DIRTY_BIT_MAX = DIRTY_BIT_UNKNOWN,
	};

	// We want to keep the number of dirty bits within 64 to keep iteration times fast.
	static_assert(DIRTY_BIT_MAX <= 64, "Too many vertex array dirty bits.");

	enum DirtyAttribBitType
	{
	DIRTY_ATTRIB_ENABLED,
	DIRTY_ATTRIB_POINTER,
	DIRTY_ATTRIB_FORMAT,
	DIRTY_ATTRIB_BINDING,
	DIRTY_ATTRIB_POINTER_BUFFER,
	DIRTY_ATTRIB_UNKNOWN,
	DIRTY_ATTRIB_MAX = DIRTY_ATTRIB_UNKNOWN,
	};

	enum DirtyBindingBitType
	{
	DIRTY_BINDING_BUFFER,
	DIRTY_BINDING_DIVISOR,
	DIRTY_BINDING_UNKNOWN,
	DIRTY_BINDING_MAX = DIRTY_BINDING_UNKNOWN,
	};

	using DirtyBits = angle::BitSet<DIRTY_BIT_MAX>;
	using DirtyAttribBits = angle::BitSet<DIRTY_ATTRIB_MAX>;
	using DirtyBindingBits = angle::BitSet<DIRTY_BINDING_MAX>;
	using DirtyAttribBitsArray = std::array<DirtyAttribBits, gl::MAX_VERTEX_ATTRIBS>;
	using DirtyBindingBitsArray = std::array<DirtyBindingBits, gl::MAX_VERTEX_ATTRIB_BINDINGS>;

	VertexArray(rx::GLImplFactory *factory,
	VertexArrayID id,
	size_t maxAttribs,
	size_t maxAttribBindings);

	void onDestroy(const Context *context);

	VertexArrayID id() const { return mId; }

	void setLabel(const Context *context, const std::string &label) override;
	const std::string &getLabel() const override;

	const VertexBinding &getVertexBinding(size_t bindingIndex) const;
	const VertexAttribute &getVertexAttribute(size_t attribIndex) const;
	const VertexBinding &getBindingFromAttribIndex(size_t attribIndex) const
	{
	return mState.getBindingFromAttribIndex(attribIndex);
	}

	// Returns true if the function finds and detaches a bound buffer.
	bool detachBuffer(const Context *context, BufferID bufferID);

	void setVertexAttribDivisor(const Context *context, size_t index, GLuint divisor);
	void enableAttribute(size_t attribIndex, bool enabledState);

	void setVertexAttribPointer(const Context *context,
	size_t attribIndex,
	Buffer *boundBuffer,
	GLint size,
	VertexAttribType type,
	bool normalized,
	GLsizei stride,
	const void *pointer);

	void setVertexAttribIPointer(const Context *context,
	size_t attribIndex,
	Buffer *boundBuffer,
	GLint size,
	VertexAttribType type,
	GLsizei stride,
	const void *pointer);

	void setVertexAttribFormat(size_t attribIndex,
	GLint size,
	VertexAttribType type,
	bool normalized,
	bool pureInteger,
	GLuint relativeOffset);
	void bindVertexBuffer(const Context *context,
	size_t bindingIndex,
	Buffer *boundBuffer,
	GLintptr offset,
	GLsizei stride);
	void setVertexAttribBinding(const Context *context, size_t attribIndex, GLuint bindingIndex);
	void setVertexBindingDivisor(size_t bindingIndex, GLuint divisor);

	Buffer *getElementArrayBuffer() const { return mState.getElementArrayBuffer(); }
	size_t getMaxAttribs() const { return mState.getMaxAttribs(); }
	size_t getMaxBindings() const { return mState.getMaxBindings(); }

	const std::vector<VertexAttribute> &getVertexAttributes() const
	{
	return mState.getVertexAttributes();
	}
	const std::vector<VertexBinding> &getVertexBindings() const
	{
	return mState.getVertexBindings();
	}

	rx::VertexArrayImpl *getImplementation() const { return mVertexArray; }

	const AttributesMask &getEnabledAttributesMask() const
	{
	return mState.getEnabledAttributesMask();
	}

	gl::AttributesMask getClientAttribsMask() const { return mState.mClientMemoryAttribsMask; }

	bool hasEnabledNullPointerClientArray() const
	{
	return mState.hasEnabledNullPointerClientArray();
	}

	bool hasMappedEnabledArrayBuffer() const
	{
	return mState.mCachedEnabledMappedArrayBuffers.any();
	}

	// Observer implementation
	void onSubjectStateChange(angle::SubjectIndex index, angle::SubjectMessage message) override;

	static size_t GetVertexIndexFromDirtyBit(size_t dirtyBit);

	angle::Result syncState(const Context *context);
	bool hasAnyDirtyBit() const { return mDirtyBits.any(); }

	ComponentTypeMask getAttributesTypeMask() const { return mState.mVertexAttributesTypeMask; }
	AttributesMask getAttributesMask() const { return mState.mEnabledAttributesMask; }

	void onBindingChanged(const Context *context, int incr);
	bool hasTransformFeedbackBindingConflict(const gl::Context *context) const;

	ANGLE_INLINE angle::Result getIndexRange(const Context *context,
	DrawElementsType type,
	GLsizei indexCount,
	const void *indices,
	IndexRange *indexRangeOut) const
	{
	Buffer *elementArrayBuffer = mState.mElementArrayBuffer.get();
	if (elementArrayBuffer && mIndexRangeCache.get(type, indexCount, indices, indexRangeOut))
	{
	return angle::Result::Continue;
	}

	return getIndexRangeImpl(context, type, indexCount, indices, indexRangeOut);
	}

	void setBufferAccessValidationEnabled(bool enabled)
	{
	mBufferAccessValidationEnabled = enabled;
	}

	private:
	~VertexArray() override;

	// This is a performance optimization for buffer binding. Allows element array buffer updates.
	friend class State;

	void setDirtyAttribBit(size_t attribIndex, DirtyAttribBitType dirtyAttribBit);
	void setDirtyBindingBit(size_t bindingIndex, DirtyBindingBitType dirtyBindingBit);

	DirtyBitType getDirtyBitFromIndex(bool contentsChanged, angle::SubjectIndex index) const;
	void setDependentDirtyBit(bool contentsChanged, angle::SubjectIndex index);

	// These are used to optimize draw call validation.
	void updateCachedBufferBindingSize(VertexBinding *binding);
	void updateCachedTransformFeedbackBindingValidation(size_t bindingIndex, const Buffer *buffer);
	void updateCachedMappedArrayBuffers(bool isMapped, const AttributesMask &boundAttributesMask);
	void updateCachedMappedArrayBuffersBinding(const VertexBinding &binding);

	angle::Result getIndexRangeImpl(const Context *context,
	DrawElementsType type,
	GLsizei indexCount,
	const void *indices,
	IndexRange *indexRangeOut) const;

	void setVertexAttribPointerImpl(const Context *context,
	ComponentType componentType,
	bool pureInteger,
	size_t attribIndex,
	Buffer *boundBuffer,
	GLint size,
	VertexAttribType type,
	bool normalized,
	GLsizei stride,
	const void *pointer);

	// These two functions return true if the state was dirty.
	bool setVertexAttribFormatImpl(VertexAttribute *attrib,
	GLint size,
	VertexAttribType type,
	bool normalized,
	bool pureInteger,
	GLuint relativeOffset);
	bool bindVertexBufferImpl(const Context *context,
	size_t bindingIndex,
	Buffer *boundBuffer,
	GLintptr offset,
	GLsizei stride);

	VertexArrayID mId;

	VertexArrayState mState;
	DirtyBits mDirtyBits;
	DirtyAttribBitsArray mDirtyAttribBits;
	DirtyBindingBitsArray mDirtyBindingBits;
	Optional<DirtyBits> mDirtyBitsGuard;

	rx::VertexArrayImpl *mVertexArray;

	std::vector<angle::ObserverBinding> mArrayBufferObserverBindings;

	AttributesMask mCachedTransformFeedbackConflictedBindingsMask;

	class IndexRangeCache final : angle::NonCopyable
	{
	public:
	IndexRangeCache();

	void invalidate() { mTypeKey = DrawElementsType::InvalidEnum; }

	bool get(DrawElementsType type,
	GLsizei indexCount,
	const void *indices,
	IndexRange *indexRangeOut)
	{
	size_t offset = reinterpret_cast<uintptr_t>(indices);
	if (mTypeKey == type && mIndexCountKey == indexCount && mOffsetKey == offset)
	{
	*indexRangeOut = mPayload;
	return true;
	}

	return false;
	}

	void put(DrawElementsType type,
	GLsizei indexCount,
	size_t offset,
	const IndexRange &indexRange);

	private:
	DrawElementsType mTypeKey;
	GLsizei mIndexCountKey;
	size_t mOffsetKey;
	IndexRange mPayload;
	};

	mutable IndexRangeCache mIndexRangeCache;
	bool mBufferAccessValidationEnabled;
	};

	} // namespace gl

	#endif // LIBANGLE_VERTEXARRAY_H_