src/gpu/GrProcOptInfo.h - platform/external/skia - Gitiles

 /*
  * 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 GrProcOptInfo_DEFINED
 #define GrProcOptInfo_DEFINED

 #include "GrColor.h"
 #include "GrInvariantOutput.h"

 class GrBatch;
 class GrFragmentStage;
 class GrFragmentProcessor;
 class GrPrimitiveProcessor;
 class GrProcessor;

 /**
  * GrProcOptInfo gathers invariant data from a set of processor stages.It is used to recognize
  * optimizations related to eliminating stages and vertex attributes that aren't necessary for a
  * draw.
  */
 class GrProcOptInfo {
 public:
     GrProcOptInfo()
         : fInOut(0, static_cast<GrColorComponentFlags>(0), false)
         , fFirstEffectStageIndex(0)
         , fInputColorIsUsed(true)
         , fInputColor(0)
         , fReadsFragPosition(false) {}

     void calcWithInitialValues(const GrFragmentStage*, int stageCount, GrColor startColor,
                                GrColorComponentFlags flags, bool areCoverageStages);

     void calcColorWithBatch(const GrBatch*, const GrFragmentStage*, int stagecount);
     void calcCoverageWithBatch(const GrBatch*, const GrFragmentStage*, int stagecount);

     // TODO delete these when batch is everywhere
     void calcColorWithPrimProc(const GrPrimitiveProcessor*, const GrFragmentStage*, int stagecount);
     void calcCoverageWithPrimProc(const GrPrimitiveProcessor*, const GrFragmentStage*,
                                   int stagecount);

     bool isSolidWhite() const { return fInOut.isSolidWhite(); }
     bool isOpaque() const { return fInOut.isOpaque(); }
     bool isSingleComponent() const { return fInOut.isSingleComponent(); }
     bool allStagesMultiplyInput() const { return fInOut.allStagesMulInput(); }

     // TODO: Once texture pixel configs quaries are updated, we no longer need this function.
     // For now this function will correctly tell us if we are using LCD text or not and should only
     // be called when looking at the coverage output.
     bool isFourChannelOutput() const { return !fInOut.isSingleComponent() &&
                                                fInOut.isLCDCoverage(); }

     GrColor color() const { return fInOut.color(); }
     uint8_t validFlags() const { return fInOut.validFlags(); }

     /**
      * Returns the index of the first effective color stage. If an intermediate stage doesn't read
      * its input or has a known output, then we can ignore all earlier stages since they will not
      * affect the final output. Thus the first effective stage index is the index to the first stage
      * that will have an effect on the final output.
      *
      * If stages before the firstEffectiveStageIndex are removed, corresponding values from
      * inputColorIsUsed(), inputColorToEffectiveStage(), removeVertexAttribs(), and readsDst() must
      * be used when setting up the draw to ensure correct drawing.
      */
     int firstEffectiveStageIndex() const { return fFirstEffectStageIndex; }

     /**
      * True if the first effective stage reads its input, false otherwise.
      */
     bool inputColorIsUsed() const { return fInputColorIsUsed; }

     /**
      * If input color is used and per-vertex colors are not used, this is the input color to the
      * first effective stage.
      */
     GrColor inputColorToEffectiveStage() const { return fInputColor; }

     /**
      * Returns true if any of the stages preserved by GrProcOptInfo read the frag position.
      */
     bool readsFragPosition() const { return fReadsFragPosition; }

 private:
     void internalCalc(const GrFragmentStage*, int stagecount, bool initWillReadFragPosition);

     GrInvariantOutput fInOut;
     int fFirstEffectStageIndex;
     bool fInputColorIsUsed;
     GrColor fInputColor;
     bool fReadsFragPosition;
 };

 #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 GrProcOptInfo_DEFINED
	#define GrProcOptInfo_DEFINED

	#include "GrColor.h"
	#include "GrInvariantOutput.h"

	class GrBatch;
	class GrFragmentStage;
	class GrFragmentProcessor;
	class GrPrimitiveProcessor;
	class GrProcessor;

	/**
	* GrProcOptInfo gathers invariant data from a set of processor stages.It is used to recognize
	* optimizations related to eliminating stages and vertex attributes that aren't necessary for a
	* draw.
	*/
	class GrProcOptInfo {
	public:
	GrProcOptInfo()
	: fInOut(0, static_cast<GrColorComponentFlags>(0), false)
	, fFirstEffectStageIndex(0)
	, fInputColorIsUsed(true)
	, fInputColor(0)
	, fReadsFragPosition(false) {}

	void calcWithInitialValues(const GrFragmentStage*, int stageCount, GrColor startColor,
	GrColorComponentFlags flags, bool areCoverageStages);

	void calcColorWithBatch(const GrBatch, const GrFragmentStage, int stagecount);
	void calcCoverageWithBatch(const GrBatch, const GrFragmentStage, int stagecount);

	// TODO delete these when batch is everywhere
	void calcColorWithPrimProc(const GrPrimitiveProcessor, const GrFragmentStage, int stagecount);
	void calcCoverageWithPrimProc(const GrPrimitiveProcessor, const GrFragmentStage,
	int stagecount);

	bool isSolidWhite() const { return fInOut.isSolidWhite(); }
	bool isOpaque() const { return fInOut.isOpaque(); }
	bool isSingleComponent() const { return fInOut.isSingleComponent(); }
	bool allStagesMultiplyInput() const { return fInOut.allStagesMulInput(); }

	// TODO: Once texture pixel configs quaries are updated, we no longer need this function.
	// For now this function will correctly tell us if we are using LCD text or not and should only
	// be called when looking at the coverage output.
	bool isFourChannelOutput() const { return !fInOut.isSingleComponent() &&
	fInOut.isLCDCoverage(); }

	GrColor color() const { return fInOut.color(); }
	uint8_t validFlags() const { return fInOut.validFlags(); }

	/**
	* Returns the index of the first effective color stage. If an intermediate stage doesn't read
	* its input or has a known output, then we can ignore all earlier stages since they will not
	* affect the final output. Thus the first effective stage index is the index to the first stage
	* that will have an effect on the final output.
	*
	* If stages before the firstEffectiveStageIndex are removed, corresponding values from
	* inputColorIsUsed(), inputColorToEffectiveStage(), removeVertexAttribs(), and readsDst() must
	* be used when setting up the draw to ensure correct drawing.
	*/
	int firstEffectiveStageIndex() const { return fFirstEffectStageIndex; }

	/**
	* True if the first effective stage reads its input, false otherwise.
	*/
	bool inputColorIsUsed() const { return fInputColorIsUsed; }

	/**
	* If input color is used and per-vertex colors are not used, this is the input color to the
	* first effective stage.
	*/
	GrColor inputColorToEffectiveStage() const { return fInputColor; }

	/**
	* Returns true if any of the stages preserved by GrProcOptInfo read the frag position.
	*/
	bool readsFragPosition() const { return fReadsFragPosition; }

	private:
	void internalCalc(const GrFragmentStage*, int stagecount, bool initWillReadFragPosition);

	GrInvariantOutput fInOut;
	int fFirstEffectStageIndex;
	bool fInputColorIsUsed;
	GrColor fInputColor;
	bool fReadsFragPosition;
	};

	#endif