src/shaders/SkShaderBase.h - skia - Git at Google

 /*
  * Copyright 2017 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkShaderBase_DEFINED
 #define SkShaderBase_DEFINED

 #include "include/core/SkColor.h"
 #include "include/core/SkFlattenable.h"
 #include "include/core/SkMatrix.h"
 #include "include/core/SkPoint.h"
 #include "include/core/SkRefCnt.h"
 #include "include/core/SkScalar.h"
 #include "include/core/SkShader.h"
 #include "include/core/SkSurfaceProps.h"
 #include "include/core/SkTypes.h"
 #include "include/private/base/SkNoncopyable.h"

 #include <cstddef>
 #include <cstdint>
 #include <optional>
 #include <tuple>

 class SkArenaAlloc;
 class SkColorSpace;
 class SkImage;
 class SkRuntimeEffect;
 class SkWriteBuffer;
 enum SkColorType : int;
 enum class SkTileMode;
 struct SkDeserialProcs;
 struct SkStageRec;

 namespace SkShaders {
 /**
  * This is used to accumulate matrices, starting with the CTM, when building up
  * SkRasterPipeline or GrFragmentProcessor by walking the SkShader tree. It avoids
  * adding a matrix multiply for each individual matrix. It also handles the reverse matrix
  * concatenation order required by Android Framework, see b/256873449.
  *
  * This also tracks the dubious concept of a "total matrix", in the legacy Context/shadeSpan system.
  * That includes all the matrices encountered during traversal to the current shader, including ones
  * that have already been applied. The total matrix represents the transformation from the current
  * shader's coordinate space to device space. It is dubious because it doesn't account for SkShaders
  * that manipulate the coordinates passed to their children, which may not even be representable by
  * a matrix.
  *
  * The total matrix is used for mipmap level selection and a filter downgrade optimizations in
  * SkImageShader and sizing of the SkImage created by SkPictureShader. If we can remove usages
  * of the "total matrix" and if Android Framework could be updated to not use backwards local
  * matrix concatenation this could just be replaced by a simple SkMatrix or SkM44 passed down
  * during traversal.
  */
 class MatrixRec {
 public:
     MatrixRec() = default;

     explicit MatrixRec(const SkMatrix& ctm);

     /**
      * Returns a new MatrixRec that represents the existing total and pending matrix
      * pre-concat'ed with m.
      */
     [[nodiscard]] MatrixRec concat(const SkMatrix& m) const;

     /**
      * Appends a mul by the inverse of the pending local matrix to the pipeline. 'postInv' is an
      * additional matrix to post-apply to the inverted pending matrix. If the pending matrix is
      * not invertible the std::optional result won't have a value and the pipeline will be
      * unmodified.
      */
     [[nodiscard]] std::optional<MatrixRec> apply(const SkStageRec& rec,
                                                  const SkMatrix& postInv = {}) const;

     /**
      * FP matrices work differently than SkRasterPipeline. The starting coordinates provided to the
      * root SkShader's FP are already in local space. So we never apply the inverse CTM. This
      * returns the inverted pending local matrix with the provided postInv matrix applied after it.
      * If the pending local matrix cannot be inverted, the boolean is false.
      */
     std::tuple<SkMatrix, bool> applyForFragmentProcessor(const SkMatrix& postInv) const;

     /**
      * A parent FP may need to create a FP for its child by calling
      * SkShaderBase::asFragmentProcessor() and then pass the result to the apply() above.
      * This comes up when the parent needs to ensure pending matrices are applied before the
      * child because the parent is going to manipulate the coordinates *after* any pending
      * matrix and pass the resulting coords to the child. This function gets a MatrixRec that
      * reflects the state after this MatrixRec has bee applied but it does not apply it!
      * Example:
      * auto childFP = fChild->asFragmentProcessor(args, mrec.applied());
      * childFP = MakeAWrappingFPThatModifiesChildsCoords(std::move(childFP));
      * auto [success, parentFP] = mrec.apply(std::move(childFP));
      */
     MatrixRec applied() const;

     /** Call to indicate that the mapping from shader to device space is not known. */
     void markTotalMatrixInvalid() { fTotalMatrixIsValid = false; }

     /** Marks the CTM as already applied; can avoid re-seeding the shader unnecessarily. */
     void markCTMApplied() { fCTMApplied = true; }

     /**
      * Indicates whether the total matrix of a MatrixRec passed to a SkShader actually
      * represents the full transform between that shader's coordinate space and device space.
      */
     bool totalMatrixIsValid() const { return fTotalMatrixIsValid; }

     /**
      * Gets the total transform from the current shader's space to device space. This may or
      * may not be valid. Shaders should avoid making decisions based on this matrix if
      * totalMatrixIsValid() is false.
      */
     SkMatrix totalMatrix() const { return SkMatrix::Concat(fCTM, fTotalLocalMatrix); }

     /** Gets the inverse of totalMatrix(), if invertible. */
     [[nodiscard]] bool totalInverse(SkMatrix* out) const {
         return this->totalMatrix().invert(out);
     }

     /** Is there a transform that has not yet been applied by a parent shader? */
     bool hasPendingMatrix() const {
         return (!fCTMApplied && !fCTM.isIdentity()) || !fPendingLocalMatrix.isIdentity();
     }

     /** When generating raster pipeline, have the device coordinates been seeded? */
     bool rasterPipelineCoordsAreSeeded() const { return fCTMApplied; }

 private:
     MatrixRec(const SkMatrix& ctm,
               const SkMatrix& totalLocalMatrix,
               const SkMatrix& pendingLocalMatrix,
               bool totalIsValid,
               bool ctmApplied)
             : fCTM(ctm)
             , fTotalLocalMatrix(totalLocalMatrix)
             , fPendingLocalMatrix(pendingLocalMatrix)
             , fTotalMatrixIsValid(totalIsValid)
             , fCTMApplied(ctmApplied) {}

     const SkMatrix fCTM;

     // Concatenation of all local matrices, including those already applied.
     const SkMatrix fTotalLocalMatrix;

     // The accumulated local matrices from walking down the shader hierarchy that have NOT yet
     // been incorporated into the SkRasterPipeline.
     const SkMatrix fPendingLocalMatrix;

     bool fTotalMatrixIsValid = true;

     // Tracks whether the CTM has already been applied (and in raster pipeline whether the
     // device coords have been seeded.)
     bool fCTMApplied = false;
 };

 }  // namespace SkShaders

 #define SK_ALL_SHADERS(M) \
     M(Blend)              \
     M(CTM)                \
     M(Color)              \
     M(Color4)             \
     M(ColorFilter)        \
     M(CoordClamp)         \
     M(Empty)              \
     M(GradientBase)       \
     M(Image)              \
     M(LocalMatrix)        \
     M(PerlinNoise)        \
     M(Picture)            \
     M(Runtime)            \
     M(Transform)          \
     M(TriColor)           \
     M(WorkingColorSpace)

 #define SK_ALL_GRADIENTS(M) \
     M(Conical)              \
     M(Linear)               \
     M(Radial)               \
     M(Sweep)

 class SkShaderBase : public SkShader {
 public:
     ~SkShaderBase() override;

     sk_sp<SkShader> makeInvertAlpha() const;
     sk_sp<SkShader> makeWithCTM(const SkMatrix&) const;  // owns its own ctm

     /**
      *  Returns true if the shader is guaranteed to produce only a single color.
      *  Subclasses can override this to allow loop-hoisting optimization.
      */
     virtual bool isConstant() const { return false; }

     enum class ShaderType {
 #define M(type) k##type,
         SK_ALL_SHADERS(M)
 #undef M
     };

     virtual ShaderType type() const = 0;

     enum class GradientType {
         kNone,
 #define M(type) k##type,
         SK_ALL_GRADIENTS(M)
 #undef M
     };

     /**
      *  If the shader subclass can be represented as a gradient, asGradient
      *  returns the matching GradientType enum (or GradientType::kNone if it
      *  cannot). Also, if info is not null, asGradient populates info with
      *  the relevant (see below) parameters for the gradient.  fColorCount
      *  is both an input and output parameter.  On input, it indicates how
      *  many entries in fColors and fColorOffsets can be used, if they are
      *  non-NULL.  After asGradient has run, fColorCount indicates how
      *  many color-offset pairs there are in the gradient.  If there is
      *  insufficient space to store all of the color-offset pairs, fColors
      *  and fColorOffsets will not be altered.  fColorOffsets specifies
      *  where on the range of 0 to 1 to transition to the given color.
      *  The meaning of fPoint and fRadius is dependent on the type of gradient.
      *
      *  None:
      *      info is ignored.
      *  Color:
      *      fColorOffsets[0] is meaningless.
      *  Linear:
      *      fPoint[0] and fPoint[1] are the end-points of the gradient
      *  Radial:
      *      fPoint[0] and fRadius[0] are the center and radius
      *  Conical:
      *      fPoint[0] and fRadius[0] are the center and radius of the 1st circle
      *      fPoint[1] and fRadius[1] are the center and radius of the 2nd circle
      *  Sweep:
      *      fPoint[0] is the center of the sweep.
      */
     struct GradientInfo {
         int         fColorCount    = 0;        //!< In-out parameter, specifies passed size
                                                //   of fColors/fColorOffsets on input, and
                                                //   actual number of colors/offsets on
                                                //   output.
         SkColor*    fColors        = nullptr;  //!< The colors in the gradient.
         SkScalar*   fColorOffsets  = nullptr;  //!< The unit offset for color transitions.
         SkPoint     fPoint[2];                 //!< Type specific, see above.
         SkScalar    fRadius[2];                //!< Type specific, see above.
         SkTileMode  fTileMode;
         uint32_t    fGradientFlags = 0;        //!< see SkGradientShader::Flags
     };

     virtual GradientType asGradient(GradientInfo* info    = nullptr,
                                     SkMatrix* localMatrix = nullptr) const {
         return GradientType::kNone;
     }

     enum Flags {
         //!< set if all of the colors will be opaque
         kOpaqueAlpha_Flag = 1 << 0,
     };

     /**
      *  ContextRec acts as a parameter bundle for creating Contexts.
      */
     struct ContextRec {
         ContextRec(SkAlpha paintAlpha,
                    const SkShaders::MatrixRec& matrixRec,
                    SkColorType dstColorType,
                    SkColorSpace* dstColorSpace,
                    const SkSurfaceProps& props)
                 : fMatrixRec(matrixRec)
                 , fDstColorType(dstColorType)
                 , fDstColorSpace(dstColorSpace)
                 , fProps(props)
                 , fPaintAlpha(paintAlpha) {}

         static ContextRec Concat(const ContextRec& parentRec, const SkMatrix& localM) {
             return {parentRec.fPaintAlpha,
                     parentRec.fMatrixRec.concat(localM),
                     parentRec.fDstColorType,
                     parentRec.fDstColorSpace,
                     parentRec.fProps};
         }

         const SkShaders::MatrixRec fMatrixRec;
         SkColorType                fDstColorType;   // the color type of the dest surface
         SkColorSpace*              fDstColorSpace;  // the color space of the dest surface (if any)
         SkSurfaceProps             fProps;          // props of the dest surface
         SkAlpha                    fPaintAlpha;

         bool isLegacyCompatible(SkColorSpace* shadersColorSpace) const;
     };

     class Context : public ::SkNoncopyable {
     public:
         Context(const SkShaderBase& shader, const ContextRec&);

         virtual ~Context();

         /**
          *  Called sometimes before drawing with this shader. Return the type of
          *  alpha your shader will return. The default implementation returns 0.
          *  Your subclass should override if it can (even sometimes) report a
          *  non-zero value, since that will enable various blitters to perform
          *  faster.
          */
         virtual uint32_t getFlags() const { return 0; }

         /**
          *  Called for each span of the object being drawn. Your subclass should
          *  set the appropriate colors (with premultiplied alpha) that correspond
          *  to the specified device coordinates.
          */
         virtual void shadeSpan(int x, int y, SkPMColor[], int count) = 0;

     protected:
         // Reference to shader, so we don't have to dupe information.
         const SkShaderBase& fShader;

         uint8_t         getPaintAlpha() const { return fPaintAlpha; }
         const SkMatrix& getTotalInverse() const { return fTotalInverse; }

     private:
         SkMatrix    fTotalInverse;
         uint8_t     fPaintAlpha;
     };

     /**
      * Make a context using the memory provided by the arena.
      *
      * @return pointer to context or nullptr if can't be created
      */
     Context* makeContext(const ContextRec&, SkArenaAlloc*) const;

     /**
      *  If the shader can represent its "average" luminance in a single color, return true and
      *  if color is not NULL, return that color. If it cannot, return false and ignore the color
      *  parameter.
      *
      *  Note: if this returns true, the returned color will always be opaque, as only the RGB
      *  components are used to compute luminance.
      */
     bool asLuminanceColor(SkColor4f*) const;

     /**
      * If this returns false, then we draw nothing (do not fall back to shader context). This should
      * only be called on a root-level effect. It assumes that the initial device coordinates have
      * not yet been seeded.
      */
     [[nodiscard]] bool appendRootStages(const SkStageRec& rec, const SkMatrix& ctm) const;

     /**
      * Adds stages to implement this shader. To ensure that the correct input coords are present
      * in r,g MatrixRec::apply() must be called (unless the shader doesn't require it's input
      * coords). The default impl creates shadercontext and calls that (not very efficient).
      */
     virtual bool appendStages(const SkStageRec&, const SkShaders::MatrixRec&) const = 0;

     virtual SkImage* onIsAImage(SkMatrix*, SkTileMode[2]) const {
         return nullptr;
     }

     virtual SkRuntimeEffect* asRuntimeEffect() const { return nullptr; }

     static Type GetFlattenableType() { return kSkShader_Type; }
     Type getFlattenableType() const override { return GetFlattenableType(); }

     static sk_sp<SkShaderBase> Deserialize(const void* data, size_t size,
                                              const SkDeserialProcs* procs = nullptr) {
         return sk_sp<SkShaderBase>(static_cast<SkShaderBase*>(
                 SkFlattenable::Deserialize(GetFlattenableType(), data, size, procs).release()));
     }
     static void RegisterFlattenables();

     /** DEPRECATED. skbug.com/8941
      *  If this shader can be represented by another shader + a localMatrix, return that shader and
      *  the localMatrix. If not, return nullptr and ignore the localMatrix parameter.
      */
     virtual sk_sp<SkShader> makeAsALocalMatrixShader(SkMatrix* localMatrix) const;

     static SkMatrix ConcatLocalMatrices(const SkMatrix& parentLM, const SkMatrix& childLM) {
 #if defined(SK_BUILD_FOR_ANDROID_FRAMEWORK)  // b/256873449
         return SkMatrix::Concat(childLM, parentLM);
 #endif
         return SkMatrix::Concat(parentLM, childLM);
     }

 protected:
     SkShaderBase();

     void flatten(SkWriteBuffer&) const override;

 #ifdef SK_ENABLE_LEGACY_SHADERCONTEXT
     /**
      * Specialize creating a SkShader context using the supplied allocator.
      * @return pointer to context owned by the arena allocator.
      */
     virtual Context* onMakeContext(const ContextRec&, SkArenaAlloc*) const {
         return nullptr;
     }
 #endif

     virtual bool onAsLuminanceColor(SkColor4f*) const {
         return false;
     }

     friend class SkShaders::MatrixRec;
 };
 inline SkShaderBase* as_SB(SkShader* shader) {
     return static_cast<SkShaderBase*>(shader);
 }

 inline const SkShaderBase* as_SB(const SkShader* shader) {
     return static_cast<const SkShaderBase*>(shader);
 }

 inline const SkShaderBase* as_SB(const sk_sp<SkShader>& shader) {
     return static_cast<SkShaderBase*>(shader.get());
 }

 void SkRegisterBlendShaderFlattenable();
 void SkRegisterColor4ShaderFlattenable();
 void SkRegisterColorShaderFlattenable();
 void SkRegisterCoordClampShaderFlattenable();
 void SkRegisterEmptyShaderFlattenable();
 void SkRegisterPerlinNoiseShaderFlattenable();
 void SkRegisterWorkingColorSpaceShaderFlattenable();

 #endif // SkShaderBase_DEFINED
	/*
	* Copyright 2017 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkShaderBase_DEFINED
	#define SkShaderBase_DEFINED

	#include "include/core/SkColor.h"
	#include "include/core/SkFlattenable.h"
	#include "include/core/SkMatrix.h"
	#include "include/core/SkPoint.h"
	#include "include/core/SkRefCnt.h"
	#include "include/core/SkScalar.h"
	#include "include/core/SkShader.h"
	#include "include/core/SkSurfaceProps.h"
	#include "include/core/SkTypes.h"
	#include "include/private/base/SkNoncopyable.h"

	#include <cstddef>
	#include <cstdint>
	#include <optional>
	#include <tuple>

	class SkArenaAlloc;
	class SkColorSpace;
	class SkImage;
	class SkRuntimeEffect;
	class SkWriteBuffer;
	enum SkColorType : int;
	enum class SkTileMode;
	struct SkDeserialProcs;
	struct SkStageRec;

	namespace SkShaders {
	/**
	* This is used to accumulate matrices, starting with the CTM, when building up
	* SkRasterPipeline or GrFragmentProcessor by walking the SkShader tree. It avoids
	* adding a matrix multiply for each individual matrix. It also handles the reverse matrix
	* concatenation order required by Android Framework, see b/256873449.
	*
	* This also tracks the dubious concept of a "total matrix", in the legacy Context/shadeSpan system.
	* That includes all the matrices encountered during traversal to the current shader, including ones
	* that have already been applied. The total matrix represents the transformation from the current
	* shader's coordinate space to device space. It is dubious because it doesn't account for SkShaders
	* that manipulate the coordinates passed to their children, which may not even be representable by
	* a matrix.
	*
	* The total matrix is used for mipmap level selection and a filter downgrade optimizations in
	* SkImageShader and sizing of the SkImage created by SkPictureShader. If we can remove usages
	* of the "total matrix" and if Android Framework could be updated to not use backwards local
	* matrix concatenation this could just be replaced by a simple SkMatrix or SkM44 passed down
	* during traversal.
	*/
	class MatrixRec {
	public:
	MatrixRec() = default;

	explicit MatrixRec(const SkMatrix& ctm);

	/**
	* Returns a new MatrixRec that represents the existing total and pending matrix
	* pre-concat'ed with m.
	*/
	[[nodiscard]] MatrixRec concat(const SkMatrix& m) const;

	/**
	* Appends a mul by the inverse of the pending local matrix to the pipeline. 'postInv' is an
	* additional matrix to post-apply to the inverted pending matrix. If the pending matrix is
	* not invertible the std::optional result won't have a value and the pipeline will be
	* unmodified.
	*/
	[[nodiscard]] std::optional<MatrixRec> apply(const SkStageRec& rec,
	const SkMatrix& postInv = {}) const;

	/**
	* FP matrices work differently than SkRasterPipeline. The starting coordinates provided to the
	* root SkShader's FP are already in local space. So we never apply the inverse CTM. This
	* returns the inverted pending local matrix with the provided postInv matrix applied after it.
	* If the pending local matrix cannot be inverted, the boolean is false.
	*/
	std::tuple<SkMatrix, bool> applyForFragmentProcessor(const SkMatrix& postInv) const;

	/**
	* A parent FP may need to create a FP for its child by calling
	* SkShaderBase::asFragmentProcessor() and then pass the result to the apply() above.
	* This comes up when the parent needs to ensure pending matrices are applied before the
	* child because the parent is going to manipulate the coordinates after any pending
	* matrix and pass the resulting coords to the child. This function gets a MatrixRec that
	* reflects the state after this MatrixRec has bee applied but it does not apply it!
	* Example:
	* auto childFP = fChild->asFragmentProcessor(args, mrec.applied());
	* childFP = MakeAWrappingFPThatModifiesChildsCoords(std::move(childFP));
	* auto [success, parentFP] = mrec.apply(std::move(childFP));
	*/
	MatrixRec applied() const;

	/** Call to indicate that the mapping from shader to device space is not known. */
	void markTotalMatrixInvalid() { fTotalMatrixIsValid = false; }

	/** Marks the CTM as already applied; can avoid re-seeding the shader unnecessarily. */
	void markCTMApplied() { fCTMApplied = true; }

	/**
	* Indicates whether the total matrix of a MatrixRec passed to a SkShader actually
	* represents the full transform between that shader's coordinate space and device space.
	*/
	bool totalMatrixIsValid() const { return fTotalMatrixIsValid; }

	/**
	* Gets the total transform from the current shader's space to device space. This may or
	* may not be valid. Shaders should avoid making decisions based on this matrix if
	* totalMatrixIsValid() is false.
	*/
	SkMatrix totalMatrix() const { return SkMatrix::Concat(fCTM, fTotalLocalMatrix); }

	/** Gets the inverse of totalMatrix(), if invertible. */
	[[nodiscard]] bool totalInverse(SkMatrix* out) const {
	return this->totalMatrix().invert(out);
	}

	/** Is there a transform that has not yet been applied by a parent shader? */
	bool hasPendingMatrix() const {
	return (!fCTMApplied && !fCTM.isIdentity()) \|\| !fPendingLocalMatrix.isIdentity();
	}

	/** When generating raster pipeline, have the device coordinates been seeded? */
	bool rasterPipelineCoordsAreSeeded() const { return fCTMApplied; }

	private:
	MatrixRec(const SkMatrix& ctm,
	const SkMatrix& totalLocalMatrix,
	const SkMatrix& pendingLocalMatrix,
	bool totalIsValid,
	bool ctmApplied)
	: fCTM(ctm)
	, fTotalLocalMatrix(totalLocalMatrix)
	, fPendingLocalMatrix(pendingLocalMatrix)
	, fTotalMatrixIsValid(totalIsValid)
	, fCTMApplied(ctmApplied) {}

	const SkMatrix fCTM;

	// Concatenation of all local matrices, including those already applied.
	const SkMatrix fTotalLocalMatrix;

	// The accumulated local matrices from walking down the shader hierarchy that have NOT yet
	// been incorporated into the SkRasterPipeline.
	const SkMatrix fPendingLocalMatrix;

	bool fTotalMatrixIsValid = true;

	// Tracks whether the CTM has already been applied (and in raster pipeline whether the
	// device coords have been seeded.)
	bool fCTMApplied = false;
	};

	} // namespace SkShaders

	#define SK_ALL_SHADERS(M) \
	M(Blend) \
	M(CTM) \
	M(Color) \
	M(Color4) \
	M(ColorFilter) \
	M(CoordClamp) \
	M(Empty) \
	M(GradientBase) \
	M(Image) \
	M(LocalMatrix) \
	M(PerlinNoise) \
	M(Picture) \
	M(Runtime) \
	M(Transform) \
	M(TriColor) \
	M(WorkingColorSpace)

	#define SK_ALL_GRADIENTS(M) \
	M(Conical) \
	M(Linear) \
	M(Radial) \
	M(Sweep)

	class SkShaderBase : public SkShader {
	public:
	~SkShaderBase() override;

	sk_sp<SkShader> makeInvertAlpha() const;
	sk_sp<SkShader> makeWithCTM(const SkMatrix&) const; // owns its own ctm

	/**
	* Returns true if the shader is guaranteed to produce only a single color.
	* Subclasses can override this to allow loop-hoisting optimization.
	*/
	virtual bool isConstant() const { return false; }

	enum class ShaderType {
	#define M(type) k##type,
	SK_ALL_SHADERS(M)
	#undef M
	};

	virtual ShaderType type() const = 0;

	enum class GradientType {
	kNone,
	#define M(type) k##type,
	SK_ALL_GRADIENTS(M)
	#undef M
	};

	/**
	* If the shader subclass can be represented as a gradient, asGradient
	* returns the matching GradientType enum (or GradientType::kNone if it
	* cannot). Also, if info is not null, asGradient populates info with
	* the relevant (see below) parameters for the gradient. fColorCount
	* is both an input and output parameter. On input, it indicates how
	* many entries in fColors and fColorOffsets can be used, if they are
	* non-NULL. After asGradient has run, fColorCount indicates how
	* many color-offset pairs there are in the gradient. If there is
	* insufficient space to store all of the color-offset pairs, fColors
	* and fColorOffsets will not be altered. fColorOffsets specifies
	* where on the range of 0 to 1 to transition to the given color.
	* The meaning of fPoint and fRadius is dependent on the type of gradient.
	*
	* None:
	* info is ignored.
	* Color:
	* fColorOffsets[0] is meaningless.
	* Linear:
	* fPoint[0] and fPoint[1] are the end-points of the gradient
	* Radial:
	* fPoint[0] and fRadius[0] are the center and radius
	* Conical:
	* fPoint[0] and fRadius[0] are the center and radius of the 1st circle
	* fPoint[1] and fRadius[1] are the center and radius of the 2nd circle
	* Sweep:
	* fPoint[0] is the center of the sweep.
	*/
	struct GradientInfo {
	int fColorCount = 0; //!< In-out parameter, specifies passed size
	// of fColors/fColorOffsets on input, and
	// actual number of colors/offsets on
	// output.
	SkColor* fColors = nullptr; //!< The colors in the gradient.
	SkScalar* fColorOffsets = nullptr; //!< The unit offset for color transitions.
	SkPoint fPoint[2]; //!< Type specific, see above.
	SkScalar fRadius[2]; //!< Type specific, see above.
	SkTileMode fTileMode;
	uint32_t fGradientFlags = 0; //!< see SkGradientShader::Flags
	};

	virtual GradientType asGradient(GradientInfo* info = nullptr,
	SkMatrix* localMatrix = nullptr) const {
	return GradientType::kNone;
	}

	enum Flags {
	//!< set if all of the colors will be opaque
	kOpaqueAlpha_Flag = 1 << 0,
	};

	/**
	* ContextRec acts as a parameter bundle for creating Contexts.
	*/
	struct ContextRec {
	ContextRec(SkAlpha paintAlpha,
	const SkShaders::MatrixRec& matrixRec,
	SkColorType dstColorType,
	SkColorSpace* dstColorSpace,
	const SkSurfaceProps& props)
	: fMatrixRec(matrixRec)
	, fDstColorType(dstColorType)
	, fDstColorSpace(dstColorSpace)
	, fProps(props)
	, fPaintAlpha(paintAlpha) {}

	static ContextRec Concat(const ContextRec& parentRec, const SkMatrix& localM) {
	return {parentRec.fPaintAlpha,
	parentRec.fMatrixRec.concat(localM),
	parentRec.fDstColorType,
	parentRec.fDstColorSpace,
	parentRec.fProps};
	}

	const SkShaders::MatrixRec fMatrixRec;
	SkColorType fDstColorType; // the color type of the dest surface
	SkColorSpace* fDstColorSpace; // the color space of the dest surface (if any)
	SkSurfaceProps fProps; // props of the dest surface
	SkAlpha fPaintAlpha;

	bool isLegacyCompatible(SkColorSpace* shadersColorSpace) const;
	};

	class Context : public ::SkNoncopyable {
	public:
	Context(const SkShaderBase& shader, const ContextRec&);

	virtual ~Context();

	/**
	* Called sometimes before drawing with this shader. Return the type of
	* alpha your shader will return. The default implementation returns 0.
	* Your subclass should override if it can (even sometimes) report a
	* non-zero value, since that will enable various blitters to perform
	* faster.
	*/
	virtual uint32_t getFlags() const { return 0; }

	/**
	* Called for each span of the object being drawn. Your subclass should
	* set the appropriate colors (with premultiplied alpha) that correspond
	* to the specified device coordinates.
	*/
	virtual void shadeSpan(int x, int y, SkPMColor[], int count) = 0;

	protected:
	// Reference to shader, so we don't have to dupe information.
	const SkShaderBase& fShader;

	uint8_t getPaintAlpha() const { return fPaintAlpha; }
	const SkMatrix& getTotalInverse() const { return fTotalInverse; }

	private:
	SkMatrix fTotalInverse;
	uint8_t fPaintAlpha;
	};

	/**
	* Make a context using the memory provided by the arena.
	*
	* @return pointer to context or nullptr if can't be created
	*/
	Context* makeContext(const ContextRec&, SkArenaAlloc*) const;

	/**
	* If the shader can represent its "average" luminance in a single color, return true and
	* if color is not NULL, return that color. If it cannot, return false and ignore the color
	* parameter.
	*
	* Note: if this returns true, the returned color will always be opaque, as only the RGB
	* components are used to compute luminance.
	*/
	bool asLuminanceColor(SkColor4f*) const;

	/**
	* If this returns false, then we draw nothing (do not fall back to shader context). This should
	* only be called on a root-level effect. It assumes that the initial device coordinates have
	* not yet been seeded.
	*/
	[[nodiscard]] bool appendRootStages(const SkStageRec& rec, const SkMatrix& ctm) const;

	/**
	* Adds stages to implement this shader. To ensure that the correct input coords are present
	* in r,g MatrixRec::apply() must be called (unless the shader doesn't require it's input
	* coords). The default impl creates shadercontext and calls that (not very efficient).
	*/
	virtual bool appendStages(const SkStageRec&, const SkShaders::MatrixRec&) const = 0;

	virtual SkImage* onIsAImage(SkMatrix*, SkTileMode[2]) const {
	return nullptr;
	}

	virtual SkRuntimeEffect* asRuntimeEffect() const { return nullptr; }

	static Type GetFlattenableType() { return kSkShader_Type; }
	Type getFlattenableType() const override { return GetFlattenableType(); }

	static sk_sp<SkShaderBase> Deserialize(const void* data, size_t size,
	const SkDeserialProcs* procs = nullptr) {
	return sk_sp<SkShaderBase>(static_cast<SkShaderBase*>(
	SkFlattenable::Deserialize(GetFlattenableType(), data, size, procs).release()));
	}
	static void RegisterFlattenables();

	/** DEPRECATED. skbug.com/8941
	* If this shader can be represented by another shader + a localMatrix, return that shader and
	* the localMatrix. If not, return nullptr and ignore the localMatrix parameter.
	*/
	virtual sk_sp<SkShader> makeAsALocalMatrixShader(SkMatrix* localMatrix) const;

	static SkMatrix ConcatLocalMatrices(const SkMatrix& parentLM, const SkMatrix& childLM) {
	#if defined(SK_BUILD_FOR_ANDROID_FRAMEWORK) // b/256873449
	return SkMatrix::Concat(childLM, parentLM);
	#endif
	return SkMatrix::Concat(parentLM, childLM);
	}

	protected:
	SkShaderBase();

	void flatten(SkWriteBuffer&) const override;

	#ifdef SK_ENABLE_LEGACY_SHADERCONTEXT
	/**
	* Specialize creating a SkShader context using the supplied allocator.
	* @return pointer to context owned by the arena allocator.
	*/
	virtual Context* onMakeContext(const ContextRec&, SkArenaAlloc*) const {
	return nullptr;
	}
	#endif

	virtual bool onAsLuminanceColor(SkColor4f*) const {
	return false;
	}

	friend class SkShaders::MatrixRec;
	};
	inline SkShaderBase* as_SB(SkShader* shader) {
	return static_cast<SkShaderBase*>(shader);
	}

	inline const SkShaderBase* as_SB(const SkShader* shader) {
	return static_cast<const SkShaderBase*>(shader);
	}

	inline const SkShaderBase* as_SB(const sk_sp<SkShader>& shader) {
	return static_cast<SkShaderBase*>(shader.get());
	}

	void SkRegisterBlendShaderFlattenable();
	void SkRegisterColor4ShaderFlattenable();
	void SkRegisterColorShaderFlattenable();
	void SkRegisterCoordClampShaderFlattenable();
	void SkRegisterEmptyShaderFlattenable();
	void SkRegisterPerlinNoiseShaderFlattenable();
	void SkRegisterWorkingColorSpaceShaderFlattenable();

	#endif // SkShaderBase_DEFINED