include/core/SkMesh.h - skia - Git at Google

 /*
  * Copyright 2021 Google LLC
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkMesh_DEFINED
 #define SkMesh_DEFINED

 #include "include/core/SkTypes.h"

 #ifdef SK_ENABLE_SKSL
 #include "include/core/SkAlphaType.h"
 #include "include/core/SkRect.h"
 #include "include/core/SkRefCnt.h"
 #include "include/core/SkSpan.h"
 #include "include/core/SkString.h"
 #include "include/effects/SkRuntimeEffect.h"

 #include <memory>
 #include <vector>

 class GrDirectContext;
 class SkColorSpace;
 class SkData;

 namespace SkSL { struct Program; }

 /**
  * A specification for custom meshes. Specifies the vertex buffer attributes and stride, the
  * vertex program that produces a user-defined set of varyings, a fragment program that ingests
  * the interpolated varyings and produces local coordinates and optionally a color.
  *
  * The signature of the vertex program must be:
  *   float2 main(Attributes, out Varyings)
  * where the return value is a local position that will be transformed by SkCanvas's matrix.
  *
  * The signature of the fragment program must be either:
  *   (float2|void) main(Varyings)
  * or
  *   (float2|void) main(Varyings, out (half4|float4) color)
  *
  * where the return value is the local coordinates that will be used to access SkShader. If the
  * return type is void then the interpolated position from vertex shader return is used as the local
  * coordinate. If the color variant is used it will be blended with SkShader (or SkPaint color in
  * absence of a shader) using the SkBlender provided to the SkCanvas draw call.
  *
  * The vertex and fragment programs may both contain uniforms. Uniforms with the same name are
  * assumed to be shared between stages. It is an error to specify uniforms in the vertex and
  * fragment program with the same name but different types, dimensionality, or layouts.
  */
 class SkMeshSpecification : public SkNVRefCnt<SkMeshSpecification> {
 public:
     /** These values are enforced when creating a specification. */
     static constexpr size_t kMaxStride       = 1024;
     static constexpr size_t kMaxAttributes   = 8;
     static constexpr size_t kStrideAlignment = 4;
     static constexpr size_t kOffsetAlignment = 4;
     static constexpr size_t kMaxVaryings     = 6;

     struct Attribute {
         enum class Type : uint32_t {  // CPU representation     Shader Type
             kFloat,                   // float                  float
             kFloat2,                  // two floats             float2
             kFloat3,                  // three floats           float3
             kFloat4,                  // four floats            float4
             kUByte4_unorm,            // four bytes             half4

             kLast = kUByte4_unorm
         };
         Type     type;
         size_t   offset;
         SkString name;
     };

     struct Varying {
         enum class Type : uint32_t {
             kFloat,   // "float"
             kFloat2,  // "float2"
             kFloat3,  // "float3"
             kFloat4,  // "float4"
             kHalf,    // "half"
             kHalf2,   // "half2"
             kHalf3,   // "half3"
             kHalf4,   // "half4"

             kLast = kHalf4
         };
         Type     type;
         SkString name;
     };

     using Uniform = SkRuntimeEffect::Uniform;

     ~SkMeshSpecification();

     struct Result {
         sk_sp<SkMeshSpecification> specification;
         SkString                   error;
     };

     /**
      * If successful the return is a specification and an empty error string. Otherwise, it is a
      * null specification a non-empty error string.
      *
      * @param attributes     The vertex attributes that will be consumed by 'vs'. Attributes need
      *                       not be tightly packed but attribute offsets must be aligned to
      *                       kOffsetAlignment and offset + size may not be greater than
      *                       'vertexStride'. At least one attribute is required.
      * @param vertexStride   The offset between successive attribute values. This must be aligned to
      *                       kStrideAlignment.
      * @param varyings       The varyings that will be written by 'vs' and read by 'fs'. This may
      *                       be empty.
      * @param vs             The vertex shader code that computes a vertex position and the varyings
      *                       from the attributes.
      * @param fs             The fragment code that computes a local coordinate and optionally a
      *                       color from the varyings. The local coordinate is used to sample
      *                       SkShader.
      * @param cs             The colorspace of the color produced by 'fs'. Ignored if 'fs's main()
      *                       function does not have a color out param.
      * @param at             The alpha type of the color produced by 'fs'. Ignored if 'fs's main()
      *                       function does not have a color out param. Cannot be kUnknown.
      */
     static Result Make(SkSpan<const Attribute> attributes,
                        size_t                  vertexStride,
                        SkSpan<const Varying>   varyings,
                        const SkString&         vs,
                        const SkString&         fs);
     static Result Make(SkSpan<const Attribute> attributes,
                        size_t                  vertexStride,
                        SkSpan<const Varying>   varyings,
                        const SkString&         vs,
                        const SkString&         fs,
                        sk_sp<SkColorSpace>     cs);
     static Result Make(SkSpan<const Attribute> attributes,
                        size_t                  vertexStride,
                        SkSpan<const Varying>   varyings,
                        const SkString&         vs,
                        const SkString&         fs,
                        sk_sp<SkColorSpace>     cs,
                        SkAlphaType             at);

     SkSpan<const Attribute> attributes() const { return SkSpan(fAttributes); }

     /**
      * Combined size of all 'uniform' variables. When creating a SkMesh with this specification
      * provide an SkData of this size, containing values for all of those variables. Use uniforms()
      * to get the offset of each uniform within the SkData.
      */
     size_t uniformSize() const;

     /**
      * Provides info about individual uniforms including the offset into an SkData where each
      * uniform value should be placed.
      */
     SkSpan<const Uniform> uniforms() const { return SkSpan(fUniforms); }

     /** Returns pointer to the named uniform variable's description, or nullptr if not found. */
     const Uniform* findUniform(std::string_view name) const;

     /** Returns pointer to the named attribute, or nullptr if not found. */
     const Attribute* findAttribute(std::string_view name) const;

     /** Returns pointer to the named varying, or nullptr if not found. */
     const Varying* findVarying(std::string_view name) const;

     size_t stride() const { return fStride; }

 private:
     friend struct SkMeshSpecificationPriv;

     enum class ColorType {
         kNone,
         kHalf4,
         kFloat4,
     };

     static Result MakeFromSourceWithStructs(SkSpan<const Attribute> attributes,
                                             size_t                  stride,
                                             SkSpan<const Varying>   varyings,
                                             const SkString&         vs,
                                             const SkString&         fs,
                                             sk_sp<SkColorSpace>     cs,
                                             SkAlphaType             at);

     SkMeshSpecification(SkSpan<const Attribute>,
                         size_t,
                         SkSpan<const Varying>,
                         std::vector<Uniform> uniforms,
                         std::unique_ptr<const SkSL::Program>,
                         std::unique_ptr<const SkSL::Program>,
                         ColorType,
                         bool hasLocalCoords,
                         sk_sp<SkColorSpace>,
                         SkAlphaType);

     SkMeshSpecification(const SkMeshSpecification&) = delete;
     SkMeshSpecification(SkMeshSpecification&&) = delete;

     SkMeshSpecification& operator=(const SkMeshSpecification&) = delete;
     SkMeshSpecification& operator=(SkMeshSpecification&&) = delete;

     const std::vector<Attribute>               fAttributes;
     const std::vector<Varying>                 fVaryings;
     const std::vector<Uniform>                 fUniforms;
     const std::unique_ptr<const SkSL::Program> fVS;
     const std::unique_ptr<const SkSL::Program> fFS;
     const size_t                               fStride;
           uint32_t                             fHash;
     const ColorType                            fColorType;
     const bool                                 fHasLocalCoords;
     const sk_sp<SkColorSpace>                  fColorSpace;
     const SkAlphaType                          fAlphaType;
 };

 /**
  * A vertex buffer, a topology, optionally an index buffer, and a compatible SkMeshSpecification.
  *
  * The data in the vertex buffer is expected to contain the attributes described by the spec
  * for vertexCount vertices beginning at vertexOffset. vertexOffset must be aligned to the
  * SkMeshSpecification's vertex stride. The size of the buffer must be at least vertexOffset +
  * spec->stride()*vertexCount (even if vertex attributes contains pad at the end of the stride). If
  * the specified bounds does not contain all the points output by the spec's vertex program when
  * applied to the vertices in the custom mesh then the result is undefined.
  *
  * MakeIndexed may be used to create an indexed mesh. indexCount indices are read from the index
  * buffer at the specified offset which must be aligned to 2. The indices are always unsigned 16bit
  * integers. The index count must be at least 3.
  *
  * If Make() is used the implicit index sequence is 0, 1, 2, 3, ... and vertexCount must be at least
  * 3.
  *
  * Both Make() and MakeIndexed() take a SkData with the uniform values. See
  * SkMeshSpecification::uniformSize() and SkMeshSpecification::uniforms() for sizing and packing
  * uniforms into the SkData.
  */
 class SkMesh {
 public:
     class IndexBuffer  : public SkRefCnt {
     public:
         virtual size_t size() const = 0;

         /**
          * Modifies the data in the IndexBuffer by copying size bytes from data into the buffer
          * at offset. Fails if offset + size > this->size() or if either offset or size is not
          * aligned to 4 bytes. The GrDirectContext* must match that used to create the buffer. We
          * take it as a parameter to emphasize that the context must be used to update the data and
          * thus the context must be valid for the current thread.
          */
         bool update(GrDirectContext*, const void* data, size_t offset, size_t size);

     private:
         virtual bool onUpdate(GrDirectContext*, const void* data, size_t offset, size_t size) = 0;
     };

     class VertexBuffer : public SkRefCnt {
     public:
         virtual size_t size() const = 0;

         /**
          * Modifies the data in the IndexBuffer by copying size bytes from data into the buffer
          * at offset. Fails if offset + size > this->size() or if either offset or size is not
          * aligned to 4 bytes. The GrDirectContext* must match that used to create the buffer. We
          * take it as a parameter to emphasize that the context must be used to update the data and
          * thus the context must be valid for the current thread.
          */
         bool update(GrDirectContext*, const void* data, size_t offset, size_t size);

     private:
         virtual bool onUpdate(GrDirectContext*, const void* data, size_t offset, size_t size) = 0;
     };

     SkMesh();
     ~SkMesh();

     SkMesh(const SkMesh&);
     SkMesh(SkMesh&&);

     SkMesh& operator=(const SkMesh&);
     SkMesh& operator=(SkMesh&&);

     /**
      * Makes an index buffer to be used with SkMeshes. The buffer may be CPU- or GPU-backed
      * depending on whether GrDirectContext* is nullptr.
      *
      * @param  GrDirectContext*  If nullptr a CPU-backed object is returned. Otherwise, the data is
      *                           uploaded to the GPU and a GPU-backed buffer is returned. It may
      *                           only be used to draw into SkSurfaces that are backed by the passed
      *                           GrDirectContext.
      * @param  data              The data used to populate the buffer, or nullptr to create a zero-
      *                           initialized buffer.
      * @param  size              Both the size of the data in 'data' and the size of the resulting
      *                           buffer.
      */
     static sk_sp<IndexBuffer> MakeIndexBuffer(GrDirectContext*, const void* data, size_t size);

     /** Deprecated in favor of const void* and size_t version above. */
     static sk_sp<IndexBuffer> MakeIndexBuffer(GrDirectContext*, sk_sp<const SkData>);

     /**
      * Makes a vertex buffer to be used with SkMeshes. The buffer may be CPU- or GPU-backed
      * depending on whether GrDirectContext* is nullptr.
      *
      * @param  GrDirectContext*  If nullptr a CPU-backed object is returned. Otherwise, the data is
      *                           uploaded to the GPU and a GPU-backed buffer is returned. It may
      *                           only be used to draw into SkSurfaces that are backed by the passed
      *                           GrDirectContext.
      * @param  data              The data used to populate the buffer, or nullptr to create a zero-
      *                           initialized buffer.
      * @param  size              Both the size of the data in 'data' and the size of the resulting
      *                           buffer.
      */
     static sk_sp<VertexBuffer> MakeVertexBuffer(GrDirectContext*, const void*, size_t size);

     /** Deprecated in favor of const void* and size_t version above. */
     static sk_sp<VertexBuffer> MakeVertexBuffer(GrDirectContext*, sk_sp<const SkData>);

     enum class Mode { kTriangles, kTriangleStrip };

     static SkMesh Make(sk_sp<SkMeshSpecification>,
                        Mode,
                        sk_sp<VertexBuffer>,
                        size_t vertexCount,
                        size_t vertexOffset,
                        sk_sp<const SkData> uniforms,
                        const SkRect& bounds);

     static SkMesh MakeIndexed(sk_sp<SkMeshSpecification>,
                               Mode,
                               sk_sp<VertexBuffer>,
                               size_t vertexCount,
                               size_t vertexOffset,
                               sk_sp<IndexBuffer>,
                               size_t indexCount,
                               size_t indexOffset,
                               sk_sp<const SkData> uniforms,
                               const SkRect& bounds);

     sk_sp<SkMeshSpecification> refSpec() const { return fSpec; }
     SkMeshSpecification* spec() const { return fSpec.get(); }

     Mode mode() const { return fMode; }

     sk_sp<VertexBuffer> refVertexBuffer() const { return fVB; }
     VertexBuffer* vertexBuffer() const { return fVB.get(); }

     size_t vertexOffset() const { return fVOffset; }
     size_t vertexCount()  const { return fVCount;  }

     sk_sp<IndexBuffer> refIndexBuffer() const { return fIB; }
     IndexBuffer* indexBuffer() const { return fIB.get(); }

     size_t indexOffset() const { return fIOffset; }
     size_t indexCount()  const { return fICount;  }

     sk_sp<const SkData> refUniforms() const { return fUniforms; }
     const SkData* uniforms() const { return fUniforms.get(); }

     SkRect bounds() const { return fBounds; }

     bool isValid() const;

 private:
     friend struct SkMeshPriv;

     bool validate() const;

     sk_sp<SkMeshSpecification> fSpec;

     sk_sp<VertexBuffer> fVB;
     sk_sp<IndexBuffer>  fIB;

     sk_sp<const SkData> fUniforms;

     size_t fVOffset = 0;  // Must be a multiple of spec->stride()
     size_t fVCount  = 0;

     size_t fIOffset = 0;  // Must be a multiple of sizeof(uint16_t)
     size_t fICount  = 0;

     Mode fMode = Mode::kTriangles;

     SkRect fBounds = SkRect::MakeEmpty();
 };

 #endif  // SK_ENABLE_SKSL

 #endif
	/*
	* Copyright 2021 Google LLC
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkMesh_DEFINED
	#define SkMesh_DEFINED

	#include "include/core/SkTypes.h"

	#ifdef SK_ENABLE_SKSL
	#include "include/core/SkAlphaType.h"
	#include "include/core/SkRect.h"
	#include "include/core/SkRefCnt.h"
	#include "include/core/SkSpan.h"
	#include "include/core/SkString.h"
	#include "include/effects/SkRuntimeEffect.h"

	#include <memory>
	#include <vector>

	class GrDirectContext;
	class SkColorSpace;
	class SkData;

	namespace SkSL { struct Program; }

	/**
	* A specification for custom meshes. Specifies the vertex buffer attributes and stride, the
	* vertex program that produces a user-defined set of varyings, a fragment program that ingests
	* the interpolated varyings and produces local coordinates and optionally a color.
	*
	* The signature of the vertex program must be:
	* float2 main(Attributes, out Varyings)
	* where the return value is a local position that will be transformed by SkCanvas's matrix.
	*
	* The signature of the fragment program must be either:
	* (float2\|void) main(Varyings)
	* or
	* (float2\|void) main(Varyings, out (half4\|float4) color)
	*
	* where the return value is the local coordinates that will be used to access SkShader. If the
	* return type is void then the interpolated position from vertex shader return is used as the local
	* coordinate. If the color variant is used it will be blended with SkShader (or SkPaint color in
	* absence of a shader) using the SkBlender provided to the SkCanvas draw call.
	*
	* The vertex and fragment programs may both contain uniforms. Uniforms with the same name are
	* assumed to be shared between stages. It is an error to specify uniforms in the vertex and
	* fragment program with the same name but different types, dimensionality, or layouts.
	*/
	class SkMeshSpecification : public SkNVRefCnt<SkMeshSpecification> {
	public:
	/** These values are enforced when creating a specification. */
	static constexpr size_t kMaxStride = 1024;
	static constexpr size_t kMaxAttributes = 8;
	static constexpr size_t kStrideAlignment = 4;
	static constexpr size_t kOffsetAlignment = 4;
	static constexpr size_t kMaxVaryings = 6;

	struct Attribute {
	enum class Type : uint32_t { // CPU representation Shader Type
	kFloat, // float float
	kFloat2, // two floats float2
	kFloat3, // three floats float3
	kFloat4, // four floats float4
	kUByte4_unorm, // four bytes half4

	kLast = kUByte4_unorm
	};
	Type type;
	size_t offset;
	SkString name;
	};

	struct Varying {
	enum class Type : uint32_t {
	kFloat, // "float"
	kFloat2, // "float2"
	kFloat3, // "float3"
	kFloat4, // "float4"
	kHalf, // "half"
	kHalf2, // "half2"
	kHalf3, // "half3"
	kHalf4, // "half4"

	kLast = kHalf4
	};
	Type type;
	SkString name;
	};

	using Uniform = SkRuntimeEffect::Uniform;

	~SkMeshSpecification();

	struct Result {
	sk_sp<SkMeshSpecification> specification;
	SkString error;
	};

	/**
	* If successful the return is a specification and an empty error string. Otherwise, it is a
	* null specification a non-empty error string.
	*
	* @param attributes The vertex attributes that will be consumed by 'vs'. Attributes need
	* not be tightly packed but attribute offsets must be aligned to
	* kOffsetAlignment and offset + size may not be greater than
	* 'vertexStride'. At least one attribute is required.
	* @param vertexStride The offset between successive attribute values. This must be aligned to
	* kStrideAlignment.
	* @param varyings The varyings that will be written by 'vs' and read by 'fs'. This may
	* be empty.
	* @param vs The vertex shader code that computes a vertex position and the varyings
	* from the attributes.
	* @param fs The fragment code that computes a local coordinate and optionally a
	* color from the varyings. The local coordinate is used to sample
	* SkShader.
	* @param cs The colorspace of the color produced by 'fs'. Ignored if 'fs's main()
	* function does not have a color out param.
	* @param at The alpha type of the color produced by 'fs'. Ignored if 'fs's main()
	* function does not have a color out param. Cannot be kUnknown.
	*/
	static Result Make(SkSpan<const Attribute> attributes,
	size_t vertexStride,
	SkSpan<const Varying> varyings,
	const SkString& vs,
	const SkString& fs);
	static Result Make(SkSpan<const Attribute> attributes,
	size_t vertexStride,
	SkSpan<const Varying> varyings,
	const SkString& vs,
	const SkString& fs,
	sk_sp<SkColorSpace> cs);
	static Result Make(SkSpan<const Attribute> attributes,
	size_t vertexStride,
	SkSpan<const Varying> varyings,
	const SkString& vs,
	const SkString& fs,
	sk_sp<SkColorSpace> cs,
	SkAlphaType at);

	SkSpan<const Attribute> attributes() const { return SkSpan(fAttributes); }

	/**
	* Combined size of all 'uniform' variables. When creating a SkMesh with this specification
	* provide an SkData of this size, containing values for all of those variables. Use uniforms()
	* to get the offset of each uniform within the SkData.
	*/
	size_t uniformSize() const;

	/**
	* Provides info about individual uniforms including the offset into an SkData where each
	* uniform value should be placed.
	*/
	SkSpan<const Uniform> uniforms() const { return SkSpan(fUniforms); }

	/** Returns pointer to the named uniform variable's description, or nullptr if not found. */
	const Uniform* findUniform(std::string_view name) const;

	/** Returns pointer to the named attribute, or nullptr if not found. */
	const Attribute* findAttribute(std::string_view name) const;

	/** Returns pointer to the named varying, or nullptr if not found. */
	const Varying* findVarying(std::string_view name) const;

	size_t stride() const { return fStride; }

	private:
	friend struct SkMeshSpecificationPriv;

	enum class ColorType {
	kNone,
	kHalf4,
	kFloat4,
	};

	static Result MakeFromSourceWithStructs(SkSpan<const Attribute> attributes,
	size_t stride,
	SkSpan<const Varying> varyings,
	const SkString& vs,
	const SkString& fs,
	sk_sp<SkColorSpace> cs,
	SkAlphaType at);

	SkMeshSpecification(SkSpan<const Attribute>,
	size_t,
	SkSpan<const Varying>,
	std::vector<Uniform> uniforms,
	std::unique_ptr<const SkSL::Program>,
	std::unique_ptr<const SkSL::Program>,
	ColorType,
	bool hasLocalCoords,
	sk_sp<SkColorSpace>,
	SkAlphaType);

	SkMeshSpecification(const SkMeshSpecification&) = delete;
	SkMeshSpecification(SkMeshSpecification&&) = delete;

	SkMeshSpecification& operator=(const SkMeshSpecification&) = delete;
	SkMeshSpecification& operator=(SkMeshSpecification&&) = delete;

	const std::vector<Attribute> fAttributes;
	const std::vector<Varying> fVaryings;
	const std::vector<Uniform> fUniforms;
	const std::unique_ptr<const SkSL::Program> fVS;
	const std::unique_ptr<const SkSL::Program> fFS;
	const size_t fStride;
	uint32_t fHash;
	const ColorType fColorType;
	const bool fHasLocalCoords;
	const sk_sp<SkColorSpace> fColorSpace;
	const SkAlphaType fAlphaType;
	};

	/**
	* A vertex buffer, a topology, optionally an index buffer, and a compatible SkMeshSpecification.
	*
	* The data in the vertex buffer is expected to contain the attributes described by the spec
	* for vertexCount vertices beginning at vertexOffset. vertexOffset must be aligned to the
	* SkMeshSpecification's vertex stride. The size of the buffer must be at least vertexOffset +
	* spec->stride()*vertexCount (even if vertex attributes contains pad at the end of the stride). If
	* the specified bounds does not contain all the points output by the spec's vertex program when
	* applied to the vertices in the custom mesh then the result is undefined.
	*
	* MakeIndexed may be used to create an indexed mesh. indexCount indices are read from the index
	* buffer at the specified offset which must be aligned to 2. The indices are always unsigned 16bit
	* integers. The index count must be at least 3.
	*
	* If Make() is used the implicit index sequence is 0, 1, 2, 3, ... and vertexCount must be at least
	* 3.
	*
	* Both Make() and MakeIndexed() take a SkData with the uniform values. See
	* SkMeshSpecification::uniformSize() and SkMeshSpecification::uniforms() for sizing and packing
	* uniforms into the SkData.
	*/
	class SkMesh {
	public:
	class IndexBuffer : public SkRefCnt {
	public:
	virtual size_t size() const = 0;

	/**
	* Modifies the data in the IndexBuffer by copying size bytes from data into the buffer
	* at offset. Fails if offset + size > this->size() or if either offset or size is not
	* aligned to 4 bytes. The GrDirectContext* must match that used to create the buffer. We
	* take it as a parameter to emphasize that the context must be used to update the data and
	* thus the context must be valid for the current thread.
	*/
	bool update(GrDirectContext, const void data, size_t offset, size_t size);

	private:
	virtual bool onUpdate(GrDirectContext, const void data, size_t offset, size_t size) = 0;
	};

	class VertexBuffer : public SkRefCnt {
	public:
	virtual size_t size() const = 0;

	/**
	* Modifies the data in the IndexBuffer by copying size bytes from data into the buffer
	* at offset. Fails if offset + size > this->size() or if either offset or size is not
	* aligned to 4 bytes. The GrDirectContext* must match that used to create the buffer. We
	* take it as a parameter to emphasize that the context must be used to update the data and
	* thus the context must be valid for the current thread.
	*/
	bool update(GrDirectContext, const void data, size_t offset, size_t size);

	private:
	virtual bool onUpdate(GrDirectContext, const void data, size_t offset, size_t size) = 0;
	};

	SkMesh();
	~SkMesh();

	SkMesh(const SkMesh&);
	SkMesh(SkMesh&&);

	SkMesh& operator=(const SkMesh&);
	SkMesh& operator=(SkMesh&&);

	/**
	* Makes an index buffer to be used with SkMeshes. The buffer may be CPU- or GPU-backed
	* depending on whether GrDirectContext* is nullptr.
	*
	* @param GrDirectContext* If nullptr a CPU-backed object is returned. Otherwise, the data is
	* uploaded to the GPU and a GPU-backed buffer is returned. It may
	* only be used to draw into SkSurfaces that are backed by the passed
	* GrDirectContext.
	* @param data The data used to populate the buffer, or nullptr to create a zero-
	* initialized buffer.
	* @param size Both the size of the data in 'data' and the size of the resulting
	* buffer.
	*/
	static sk_sp<IndexBuffer> MakeIndexBuffer(GrDirectContext, const void data, size_t size);

	/** Deprecated in favor of const void* and size_t version above. */
	static sk_sp<IndexBuffer> MakeIndexBuffer(GrDirectContext*, sk_sp<const SkData>);

	/**
	* Makes a vertex buffer to be used with SkMeshes. The buffer may be CPU- or GPU-backed
	* depending on whether GrDirectContext* is nullptr.
	*
	* @param GrDirectContext* If nullptr a CPU-backed object is returned. Otherwise, the data is
	* uploaded to the GPU and a GPU-backed buffer is returned. It may
	* only be used to draw into SkSurfaces that are backed by the passed
	* GrDirectContext.
	* @param data The data used to populate the buffer, or nullptr to create a zero-
	* initialized buffer.
	* @param size Both the size of the data in 'data' and the size of the resulting
	* buffer.
	*/
	static sk_sp<VertexBuffer> MakeVertexBuffer(GrDirectContext, const void, size_t size);

	/** Deprecated in favor of const void* and size_t version above. */
	static sk_sp<VertexBuffer> MakeVertexBuffer(GrDirectContext*, sk_sp<const SkData>);

	enum class Mode { kTriangles, kTriangleStrip };

	static SkMesh Make(sk_sp<SkMeshSpecification>,
	Mode,
	sk_sp<VertexBuffer>,
	size_t vertexCount,
	size_t vertexOffset,
	sk_sp<const SkData> uniforms,
	const SkRect& bounds);

	static SkMesh MakeIndexed(sk_sp<SkMeshSpecification>,
	Mode,
	sk_sp<VertexBuffer>,
	size_t vertexCount,
	size_t vertexOffset,
	sk_sp<IndexBuffer>,
	size_t indexCount,
	size_t indexOffset,
	sk_sp<const SkData> uniforms,
	const SkRect& bounds);

	sk_sp<SkMeshSpecification> refSpec() const { return fSpec; }
	SkMeshSpecification* spec() const { return fSpec.get(); }

	Mode mode() const { return fMode; }

	sk_sp<VertexBuffer> refVertexBuffer() const { return fVB; }
	VertexBuffer* vertexBuffer() const { return fVB.get(); }

	size_t vertexOffset() const { return fVOffset; }
	size_t vertexCount() const { return fVCount; }

	sk_sp<IndexBuffer> refIndexBuffer() const { return fIB; }
	IndexBuffer* indexBuffer() const { return fIB.get(); }

	size_t indexOffset() const { return fIOffset; }
	size_t indexCount() const { return fICount; }

	sk_sp<const SkData> refUniforms() const { return fUniforms; }
	const SkData* uniforms() const { return fUniforms.get(); }

	SkRect bounds() const { return fBounds; }

	bool isValid() const;

	private:
	friend struct SkMeshPriv;

	bool validate() const;

	sk_sp<SkMeshSpecification> fSpec;

	sk_sp<VertexBuffer> fVB;
	sk_sp<IndexBuffer> fIB;

	sk_sp<const SkData> fUniforms;

	size_t fVOffset = 0; // Must be a multiple of spec->stride()
	size_t fVCount = 0;

	size_t fIOffset = 0; // Must be a multiple of sizeof(uint16_t)
	size_t fICount = 0;

	Mode fMode = Mode::kTriangles;

	SkRect fBounds = SkRect::MakeEmpty();
	};

	#endif // SK_ENABLE_SKSL

	#endif