src/gpu/GrOptDrawState.h - skia - Git at Google

 /*
  * Copyright 2014 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrOptDrawState_DEFINED
 #define GrOptDrawState_DEFINED

 #include "GrColor.h"
 #include "GrGpu.h"
 #include "GrProcessorStage.h"
 #include "GrProgramDesc.h"
 #include "GrStencil.h"
 #include "GrTypesPriv.h"
 #include "SkMatrix.h"
 #include "SkRefCnt.h"

 class GrDeviceCoordTexture;
 class GrDrawState;

 /**
  * Class that holds an optimized version of a GrDrawState. It is meant to be an immutable class,
  * and contains all data needed to set the state for a gpu draw.
  */
 class GrOptDrawState : public SkRefCnt {
 public:
     /**
      * Returns a snapshot of the current optimized state. If the current drawState has a valid
      * cached optimiezed state it will simply return a pointer to it otherwise it will create a new
      * GrOptDrawState. In all cases the GrOptDrawState is reffed and ownership is given to the
      * caller.
      */
     static GrOptDrawState* Create(const GrDrawState& drawState, GrGpu*,
                                   const GrDeviceCoordTexture* dstCopy, GrGpu::DrawType drawType);

     bool operator== (const GrOptDrawState& that) const;

     ///////////////////////////////////////////////////////////////////////////
     /// @name Vertex Attributes
     ////

     enum {
         kMaxVertexAttribCnt = kLast_GrVertexAttribBinding + 4,
     };

     const GrVertexAttrib* getVertexAttribs() const { return fVAPtr; }
     int getVertexAttribCount() const { return fVACount; }

     size_t getVertexStride() const { return fVAStride; }

     /// @}

     ///////////////////////////////////////////////////////////////////////////
     /// @name Color
     ////

     GrColor getColor() const { return fColor; }

     /// @}

     ///////////////////////////////////////////////////////////////////////////
     /// @name Coverage
     ////

     uint8_t getCoverage() const { return fCoverage; }

     GrColor getCoverageColor() const {
         return GrColorPackRGBA(fCoverage, fCoverage, fCoverage, fCoverage);
     }

     /// @}

     ///////////////////////////////////////////////////////////////////////////
     /// @name Effect Stages
     /// Each stage hosts a GrProcessor. The effect produces an output color or coverage in the
     /// fragment shader. Its inputs are the output from the previous stage as well as some variables
     /// available to it in the fragment and vertex shader (e.g. the vertex position, the dst color,
     /// the fragment position, local coordinates).
     ///
     /// The stages are divided into two sets, color-computing and coverage-computing. The final
     /// color stage produces the final pixel color. The coverage-computing stages function exactly
     /// as the color-computing but the output of the final coverage stage is treated as a fractional
     /// pixel coverage rather than as input to the src/dst color blend step.
     ///
     /// The input color to the first color-stage is either the constant color or interpolated
     /// per-vertex colors. The input to the first coverage stage is either a constant coverage
     /// (usually full-coverage) or interpolated per-vertex coverage.
     ///
     /// See the documentation of kCoverageDrawing_StateBit for information about disabling the
     /// the color / coverage distinction.
     ////

     int numColorStages() const { return fNumColorStages; }
     int numCoverageStages() const { return fFragmentStages.count() - fNumColorStages; }
     int numFragmentStages() const { return fFragmentStages.count(); }
     int numTotalStages() const {
          return this->numFragmentStages() + (this->hasGeometryProcessor() ? 1 : 0);
     }

     bool hasGeometryProcessor() const { return SkToBool(fGeometryProcessor.get()); }
     const GrGeometryProcessor* getGeometryProcessor() const { return fGeometryProcessor.get(); }
     const GrFragmentStage& getColorStage(int idx) const {
         SkASSERT(idx < this->numColorStages());
         return fFragmentStages[idx];
     }
     const GrFragmentStage& getCoverageStage(int idx) const {
         SkASSERT(idx < this->numCoverageStages());
         return fFragmentStages[fNumColorStages + idx];
     }
     const GrFragmentStage& getFragmentStage(int idx) const { return fFragmentStages[idx]; }

     /// @}

     ///////////////////////////////////////////////////////////////////////////
     /// @name Blending
     ////

     GrBlendCoeff getSrcBlendCoeff() const { return fSrcBlend; }
     GrBlendCoeff getDstBlendCoeff() const { return fDstBlend; }

     /**
      * Retrieves the last value set by setBlendConstant()
      * @return the blending constant value
      */
     GrColor getBlendConstant() const { return fBlendConstant; }

     /// @}

     ///////////////////////////////////////////////////////////////////////////
     /// @name View Matrix
     ////

     /**
      * Retrieves the current view matrix
      * @return the current view matrix.
      */
     const SkMatrix& getViewMatrix() const { return fViewMatrix; }

     /**
      *  Retrieves the inverse of the current view matrix.
      *
      *  If the current view matrix is invertible, return true, and if matrix
      *  is non-null, copy the inverse into it. If the current view matrix is
      *  non-invertible, return false and ignore the matrix parameter.
      *
      * @param matrix if not null, will receive a copy of the current inverse.
      */
     bool getViewInverse(SkMatrix* matrix) const {
         SkMatrix inverse;
         if (fViewMatrix.invert(&inverse)) {
             if (matrix) {
                 *matrix = inverse;
             }
             return true;
         }
         return false;
     }

     /// @}

     ///////////////////////////////////////////////////////////////////////////
     /// @name Render Target
     ////

     /**
      * Retrieves the currently set render-target.
      *
      * @return    The currently set render target.
      */
     GrRenderTarget* getRenderTarget() const { return fRenderTarget.get(); }

     /// @}

     ///////////////////////////////////////////////////////////////////////////
     /// @name Stencil
     ////

     const GrStencilSettings& getStencil() const { return fStencilSettings; }

     /// @}

     ///////////////////////////////////////////////////////////////////////////
     /// @name State Flags
     ////

     /**
      *  Flags that affect rendering. Controlled using enable/disableState(). All
      *  default to disabled.
      */
     enum StateBits {
         /**
          * Perform dithering. TODO: Re-evaluate whether we need this bit
          */
         kDither_StateBit        = 0x01,
         /**
          * Perform HW anti-aliasing. This means either HW FSAA, if supported by the render target,
          * or smooth-line rendering if a line primitive is drawn and line smoothing is supported by
          * the 3D API.
          */
         kHWAntialias_StateBit   = 0x02,
         /**
          * Draws will respect the clip, otherwise the clip is ignored.
          */
         kClip_StateBit          = 0x04,
         /**
          * Disables writing to the color buffer. Useful when performing stencil
          * operations.
          */
         kNoColorWrites_StateBit = 0x08,

         /**
          * Usually coverage is applied after color blending. The color is blended using the coeffs
          * specified by setBlendFunc(). The blended color is then combined with dst using coeffs
          * of src_coverage, 1-src_coverage. Sometimes we are explicitly drawing a coverage mask. In
          * this case there is no distinction between coverage and color and the caller needs direct
          * control over the blend coeffs. When set, there will be a single blend step controlled by
          * setBlendFunc() which will use coverage*color as the src color.
          */
          kCoverageDrawing_StateBit = 0x10,

         // Users of the class may add additional bits to the vector
         kDummyStateBit,
         kLastPublicStateBit = kDummyStateBit-1,
     };

     bool isStateFlagEnabled(uint32_t stateBit) const { return 0 != (stateBit & fFlagBits); }

     bool isDitherState() const { return 0 != (fFlagBits & kDither_StateBit); }
     bool isHWAntialiasState() const { return 0 != (fFlagBits & kHWAntialias_StateBit); }
     bool isClipState() const { return 0 != (fFlagBits & kClip_StateBit); }
     bool isColorWriteDisabled() const { return 0 != (fFlagBits & kNoColorWrites_StateBit); }
     bool isCoverageDrawing() const { return 0 != (fFlagBits & kCoverageDrawing_StateBit); }

     /// @}

     ///////////////////////////////////////////////////////////////////////////
     /// @name Face Culling
     ////

     enum DrawFace {
         kInvalid_DrawFace = -1,

         kBoth_DrawFace,
         kCCW_DrawFace,
         kCW_DrawFace,
     };

     /**
      * Gets whether the target is drawing clockwise, counterclockwise,
      * or both faces.
      * @return the current draw face(s).
      */
     DrawFace getDrawFace() const { return fDrawFace; }

     /// @}

     ///////////////////////////////////////////////////////////////////////////

     /** Return type for CombineIfPossible. */
     enum CombinedState {
         /** The GrDrawStates cannot be combined. */
         kIncompatible_CombinedState,
         /** Either draw state can be used in place of the other. */
         kAOrB_CombinedState,
         /** Use the first draw state. */
         kA_CombinedState,
         /** Use the second draw state. */
         kB_CombinedState,
     };

     /// @}

     const GrProgramDesc& programDesc() const { return fDesc; }

 private:
     /**
      * Optimizations for blending / coverage to that can be applied based on the current state.
      */
     enum BlendOptFlags {
         /**
          * No optimization
          */
         kNone_BlendOpt                  = 0,
         /**
          * Don't draw at all
          */
         kSkipDraw_BlendOptFlag          = 0x1,
         /**
          * The coverage value does not have to be computed separately from alpha, the the output
          * color can be the modulation of the two.
          */
         kCoverageAsAlpha_BlendOptFlag   = 0x2,
         /**
          * Instead of emitting a src color, emit coverage in the alpha channel and r,g,b are
          * "don't cares".
          */
         kEmitCoverage_BlendOptFlag      = 0x4,
         /**
          * Emit transparent black instead of the src color, no need to compute coverage.
          */
         kEmitTransBlack_BlendOptFlag    = 0x8,
     };
     GR_DECL_BITFIELD_OPS_FRIENDS(BlendOptFlags);

     /**
      * Constructs and optimized drawState out of a GrRODrawState.
      */
     GrOptDrawState(const GrDrawState& drawState, BlendOptFlags blendOptFlags,
                    GrBlendCoeff optSrcCoeff, GrBlendCoeff optDstCoeff,
                    GrGpu*, const GrDeviceCoordTexture* dstCopy, GrGpu::DrawType);

     /**
      * Loops through all the color stage effects to check if the stage will ignore color input or
      * always output a constant color. In the ignore color input case we can ignore all previous
      * stages. In the constant color case, we can ignore all previous stages and
      * the current one and set the state color to the constant color.
      */
     void computeEffectiveColorStages(const GrDrawState& ds, GrProgramDesc::DescInfo*,
                                      int* firstColorStageIdx, uint8_t* fixFunctionVAToRemove);

     /**
      * Loops through all the coverage stage effects to check if the stage will ignore color input.
      * If a coverage stage will ignore input, then we can ignore all coverage stages before it. We
      * loop to determine the first effective coverage stage.
      */
     void computeEffectiveCoverageStages(const GrDrawState& ds, GrProgramDesc::DescInfo* descInfo,
                                         int* firstCoverageStageIdx);

     /**
      * This function takes in a flag and removes the corresponding fixed function vertex attributes.
      * The flags are in the same order as GrVertexAttribBinding array. If bit i of removeVAFlags is
      * set, then vertex attributes with binding (GrVertexAttribute)i will be removed.
      */
     void removeFixedFunctionVertexAttribs(uint8_t removeVAFlags, GrProgramDesc::DescInfo*);

     /**
      * Alter the OptDrawState (adjusting stages, vertex attribs, flags, etc.) based on the
      * BlendOptFlags.
      */
     void adjustFromBlendOpts(const GrDrawState& ds, GrProgramDesc::DescInfo*,
                              int* firstColorStageIdx, int* firstCoverageStageIdx,
                              uint8_t* fixedFunctionVAToRemove);

     /**
      * Loop over the effect stages to determine various info like what data they will read and what
      * shaders they require.
      */
     void getStageStats(const GrDrawState& ds, int firstColorStageIdx, int firstCoverageStageIdx,
                        GrProgramDesc::DescInfo*);

     /**
      * Calculates the primary and secondary output types of the shader. For certain output types
      * the function may adjust the blend coefficients. After this function is called the src and dst
      * blend coeffs will represent those used by backend API.
      */
     void setOutputStateInfo(const GrDrawState& ds, const GrDrawTargetCaps&,
                             int firstCoverageStageIdx, GrProgramDesc::DescInfo*,
                             bool* separateCoverageFromColor);

     bool isEqual(const GrOptDrawState& that) const;

     // These fields are roughly sorted by decreasing likelihood of being different in op==
     typedef GrTGpuResourceRef<GrRenderTarget> ProgramRenderTarget;
     ProgramRenderTarget                 fRenderTarget;
     GrColor                             fColor;
     SkMatrix                            fViewMatrix;
     GrColor                             fBlendConstant;
     uint32_t                            fFlagBits;
     const GrVertexAttrib*               fVAPtr;
     int                                 fVACount;
     size_t                              fVAStride;
     GrStencilSettings                   fStencilSettings;
     uint8_t                             fCoverage;
     DrawFace                            fDrawFace;
     GrBlendCoeff                        fSrcBlend;
     GrBlendCoeff                        fDstBlend;

     typedef SkSTArray<8, GrFragmentStage> FragmentStageArray;
     typedef GrProgramElementRef<const GrGeometryProcessor> ProgramGeometryProcessor;
     ProgramGeometryProcessor            fGeometryProcessor;
     FragmentStageArray                  fFragmentStages;

     // This function is equivalent to the offset into fFragmentStages where coverage stages begin.
     int                                 fNumColorStages;

     SkAutoSTArray<4, GrVertexAttrib> fOptVA;

     BlendOptFlags   fBlendOptFlags;

     GrProgramDesc fDesc;

     typedef SkRefCnt INHERITED;
 };

 GR_MAKE_BITFIELD_OPS(GrOptDrawState::BlendOptFlags);

 #endif
	/*
	* Copyright 2014 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrOptDrawState_DEFINED
	#define GrOptDrawState_DEFINED

	#include "GrColor.h"
	#include "GrGpu.h"
	#include "GrProcessorStage.h"
	#include "GrProgramDesc.h"
	#include "GrStencil.h"
	#include "GrTypesPriv.h"
	#include "SkMatrix.h"
	#include "SkRefCnt.h"

	class GrDeviceCoordTexture;
	class GrDrawState;

	/**
	* Class that holds an optimized version of a GrDrawState. It is meant to be an immutable class,
	* and contains all data needed to set the state for a gpu draw.
	*/
	class GrOptDrawState : public SkRefCnt {
	public:
	/**
	* Returns a snapshot of the current optimized state. If the current drawState has a valid
	* cached optimiezed state it will simply return a pointer to it otherwise it will create a new
	* GrOptDrawState. In all cases the GrOptDrawState is reffed and ownership is given to the
	* caller.
	*/
	static GrOptDrawState* Create(const GrDrawState& drawState, GrGpu*,
	const GrDeviceCoordTexture* dstCopy, GrGpu::DrawType drawType);

	bool operator== (const GrOptDrawState& that) const;

	///////////////////////////////////////////////////////////////////////////
	/// @name Vertex Attributes
	////

	enum {
	kMaxVertexAttribCnt = kLast_GrVertexAttribBinding + 4,
	};

	const GrVertexAttrib* getVertexAttribs() const { return fVAPtr; }
	int getVertexAttribCount() const { return fVACount; }

	size_t getVertexStride() const { return fVAStride; }

	/// @}

	///////////////////////////////////////////////////////////////////////////
	/// @name Color
	////

	GrColor getColor() const { return fColor; }

	/// @}

	///////////////////////////////////////////////////////////////////////////
	/// @name Coverage
	////

	uint8_t getCoverage() const { return fCoverage; }

	GrColor getCoverageColor() const {
	return GrColorPackRGBA(fCoverage, fCoverage, fCoverage, fCoverage);
	}

	/// @}

	///////////////////////////////////////////////////////////////////////////
	/// @name Effect Stages
	/// Each stage hosts a GrProcessor. The effect produces an output color or coverage in the
	/// fragment shader. Its inputs are the output from the previous stage as well as some variables
	/// available to it in the fragment and vertex shader (e.g. the vertex position, the dst color,
	/// the fragment position, local coordinates).
	///
	/// The stages are divided into two sets, color-computing and coverage-computing. The final
	/// color stage produces the final pixel color. The coverage-computing stages function exactly
	/// as the color-computing but the output of the final coverage stage is treated as a fractional
	/// pixel coverage rather than as input to the src/dst color blend step.
	///
	/// The input color to the first color-stage is either the constant color or interpolated
	/// per-vertex colors. The input to the first coverage stage is either a constant coverage
	/// (usually full-coverage) or interpolated per-vertex coverage.
	///
	/// See the documentation of kCoverageDrawing_StateBit for information about disabling the
	/// the color / coverage distinction.
	////

	int numColorStages() const { return fNumColorStages; }
	int numCoverageStages() const { return fFragmentStages.count() - fNumColorStages; }
	int numFragmentStages() const { return fFragmentStages.count(); }
	int numTotalStages() const {
	return this->numFragmentStages() + (this->hasGeometryProcessor() ? 1 : 0);
	}

	bool hasGeometryProcessor() const { return SkToBool(fGeometryProcessor.get()); }
	const GrGeometryProcessor* getGeometryProcessor() const { return fGeometryProcessor.get(); }
	const GrFragmentStage& getColorStage(int idx) const {
	SkASSERT(idx < this->numColorStages());
	return fFragmentStages[idx];
	}
	const GrFragmentStage& getCoverageStage(int idx) const {
	SkASSERT(idx < this->numCoverageStages());
	return fFragmentStages[fNumColorStages + idx];
	}
	const GrFragmentStage& getFragmentStage(int idx) const { return fFragmentStages[idx]; }

	/// @}

	///////////////////////////////////////////////////////////////////////////
	/// @name Blending
	////

	GrBlendCoeff getSrcBlendCoeff() const { return fSrcBlend; }
	GrBlendCoeff getDstBlendCoeff() const { return fDstBlend; }

	/**
	* Retrieves the last value set by setBlendConstant()
	* @return the blending constant value
	*/
	GrColor getBlendConstant() const { return fBlendConstant; }

	/// @}

	///////////////////////////////////////////////////////////////////////////
	/// @name View Matrix
	////

	/**
	* Retrieves the current view matrix
	* @return the current view matrix.
	*/
	const SkMatrix& getViewMatrix() const { return fViewMatrix; }

	/**
	* Retrieves the inverse of the current view matrix.
	*
	* If the current view matrix is invertible, return true, and if matrix
	* is non-null, copy the inverse into it. If the current view matrix is
	* non-invertible, return false and ignore the matrix parameter.
	*
	* @param matrix if not null, will receive a copy of the current inverse.
	*/
	bool getViewInverse(SkMatrix* matrix) const {
	SkMatrix inverse;
	if (fViewMatrix.invert(&inverse)) {
	if (matrix) {
	*matrix = inverse;
	}
	return true;
	}
	return false;
	}

	/// @}

	///////////////////////////////////////////////////////////////////////////
	/// @name Render Target
	////

	/**
	* Retrieves the currently set render-target.
	*
	* @return The currently set render target.
	*/
	GrRenderTarget* getRenderTarget() const { return fRenderTarget.get(); }

	/// @}

	///////////////////////////////////////////////////////////////////////////
	/// @name Stencil
	////

	const GrStencilSettings& getStencil() const { return fStencilSettings; }

	/// @}

	///////////////////////////////////////////////////////////////////////////
	/// @name State Flags
	////

	/**
	* Flags that affect rendering. Controlled using enable/disableState(). All
	* default to disabled.
	*/
	enum StateBits {
	/**
	* Perform dithering. TODO: Re-evaluate whether we need this bit
	*/
	kDither_StateBit = 0x01,
	/**
	* Perform HW anti-aliasing. This means either HW FSAA, if supported by the render target,
	* or smooth-line rendering if a line primitive is drawn and line smoothing is supported by
	* the 3D API.
	*/
	kHWAntialias_StateBit = 0x02,
	/**
	* Draws will respect the clip, otherwise the clip is ignored.
	*/
	kClip_StateBit = 0x04,
	/**
	* Disables writing to the color buffer. Useful when performing stencil
	* operations.
	*/
	kNoColorWrites_StateBit = 0x08,

	/**
	* Usually coverage is applied after color blending. The color is blended using the coeffs
	* specified by setBlendFunc(). The blended color is then combined with dst using coeffs
	* of src_coverage, 1-src_coverage. Sometimes we are explicitly drawing a coverage mask. In
	* this case there is no distinction between coverage and color and the caller needs direct
	* control over the blend coeffs. When set, there will be a single blend step controlled by
	* setBlendFunc() which will use coverage*color as the src color.
	*/
	kCoverageDrawing_StateBit = 0x10,

	// Users of the class may add additional bits to the vector
	kDummyStateBit,
	kLastPublicStateBit = kDummyStateBit-1,
	};

	bool isStateFlagEnabled(uint32_t stateBit) const { return 0 != (stateBit & fFlagBits); }

	bool isDitherState() const { return 0 != (fFlagBits & kDither_StateBit); }
	bool isHWAntialiasState() const { return 0 != (fFlagBits & kHWAntialias_StateBit); }
	bool isClipState() const { return 0 != (fFlagBits & kClip_StateBit); }
	bool isColorWriteDisabled() const { return 0 != (fFlagBits & kNoColorWrites_StateBit); }
	bool isCoverageDrawing() const { return 0 != (fFlagBits & kCoverageDrawing_StateBit); }

	/// @}

	///////////////////////////////////////////////////////////////////////////
	/// @name Face Culling
	////

	enum DrawFace {
	kInvalid_DrawFace = -1,

	kBoth_DrawFace,
	kCCW_DrawFace,
	kCW_DrawFace,
	};

	/**
	* Gets whether the target is drawing clockwise, counterclockwise,
	* or both faces.
	* @return the current draw face(s).
	*/
	DrawFace getDrawFace() const { return fDrawFace; }

	/// @}

	///////////////////////////////////////////////////////////////////////////

	/** Return type for CombineIfPossible. */
	enum CombinedState {
	/** The GrDrawStates cannot be combined. */
	kIncompatible_CombinedState,
	/** Either draw state can be used in place of the other. */
	kAOrB_CombinedState,
	/** Use the first draw state. */
	kA_CombinedState,
	/** Use the second draw state. */
	kB_CombinedState,
	};

	/// @}

	const GrProgramDesc& programDesc() const { return fDesc; }

	private:
	/**
	* Optimizations for blending / coverage to that can be applied based on the current state.
	*/
	enum BlendOptFlags {
	/**
	* No optimization
	*/
	kNone_BlendOpt = 0,
	/**
	* Don't draw at all
	*/
	kSkipDraw_BlendOptFlag = 0x1,
	/**
	* The coverage value does not have to be computed separately from alpha, the the output
	* color can be the modulation of the two.
	*/
	kCoverageAsAlpha_BlendOptFlag = 0x2,
	/**
	* Instead of emitting a src color, emit coverage in the alpha channel and r,g,b are
	* "don't cares".
	*/
	kEmitCoverage_BlendOptFlag = 0x4,
	/**
	* Emit transparent black instead of the src color, no need to compute coverage.
	*/
	kEmitTransBlack_BlendOptFlag = 0x8,
	};
	GR_DECL_BITFIELD_OPS_FRIENDS(BlendOptFlags);

	/**
	* Constructs and optimized drawState out of a GrRODrawState.
	*/
	GrOptDrawState(const GrDrawState& drawState, BlendOptFlags blendOptFlags,
	GrBlendCoeff optSrcCoeff, GrBlendCoeff optDstCoeff,
	GrGpu, const GrDeviceCoordTexture dstCopy, GrGpu::DrawType);

	/**
	* Loops through all the color stage effects to check if the stage will ignore color input or
	* always output a constant color. In the ignore color input case we can ignore all previous
	* stages. In the constant color case, we can ignore all previous stages and
	* the current one and set the state color to the constant color.
	*/
	void computeEffectiveColorStages(const GrDrawState& ds, GrProgramDesc::DescInfo*,
	int* firstColorStageIdx, uint8_t* fixFunctionVAToRemove);

	/**
	* Loops through all the coverage stage effects to check if the stage will ignore color input.
	* If a coverage stage will ignore input, then we can ignore all coverage stages before it. We
	* loop to determine the first effective coverage stage.
	*/
	void computeEffectiveCoverageStages(const GrDrawState& ds, GrProgramDesc::DescInfo* descInfo,
	int* firstCoverageStageIdx);

	/**
	* This function takes in a flag and removes the corresponding fixed function vertex attributes.
	* The flags are in the same order as GrVertexAttribBinding array. If bit i of removeVAFlags is
	* set, then vertex attributes with binding (GrVertexAttribute)i will be removed.
	*/
	void removeFixedFunctionVertexAttribs(uint8_t removeVAFlags, GrProgramDesc::DescInfo*);

	/**
	* Alter the OptDrawState (adjusting stages, vertex attribs, flags, etc.) based on the
	* BlendOptFlags.
	*/
	void adjustFromBlendOpts(const GrDrawState& ds, GrProgramDesc::DescInfo*,
	int* firstColorStageIdx, int* firstCoverageStageIdx,
	uint8_t* fixedFunctionVAToRemove);

	/**
	* Loop over the effect stages to determine various info like what data they will read and what
	* shaders they require.
	*/
	void getStageStats(const GrDrawState& ds, int firstColorStageIdx, int firstCoverageStageIdx,
	GrProgramDesc::DescInfo*);

	/**
	* Calculates the primary and secondary output types of the shader. For certain output types
	* the function may adjust the blend coefficients. After this function is called the src and dst
	* blend coeffs will represent those used by backend API.
	*/
	void setOutputStateInfo(const GrDrawState& ds, const GrDrawTargetCaps&,
	int firstCoverageStageIdx, GrProgramDesc::DescInfo*,
	bool* separateCoverageFromColor);

	bool isEqual(const GrOptDrawState& that) const;

	// These fields are roughly sorted by decreasing likelihood of being different in op==
	typedef GrTGpuResourceRef<GrRenderTarget> ProgramRenderTarget;
	ProgramRenderTarget fRenderTarget;
	GrColor fColor;
	SkMatrix fViewMatrix;
	GrColor fBlendConstant;
	uint32_t fFlagBits;
	const GrVertexAttrib* fVAPtr;
	int fVACount;
	size_t fVAStride;
	GrStencilSettings fStencilSettings;
	uint8_t fCoverage;
	DrawFace fDrawFace;
	GrBlendCoeff fSrcBlend;
	GrBlendCoeff fDstBlend;

	typedef SkSTArray<8, GrFragmentStage> FragmentStageArray;
	typedef GrProgramElementRef<const GrGeometryProcessor> ProgramGeometryProcessor;
	ProgramGeometryProcessor fGeometryProcessor;
	FragmentStageArray fFragmentStages;

	// This function is equivalent to the offset into fFragmentStages where coverage stages begin.
	int fNumColorStages;

	SkAutoSTArray<4, GrVertexAttrib> fOptVA;

	BlendOptFlags fBlendOptFlags;

	GrProgramDesc fDesc;

	typedef SkRefCnt INHERITED;
	};

	GR_MAKE_BITFIELD_OPS(GrOptDrawState::BlendOptFlags);

	#endif