include/effects/SkPerlinNoiseShader.h - platform/external/skqp - Gitiles

 /*
  * Copyright 2013 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkPerlinNoiseShader_DEFINED
 #define SkPerlinNoiseShader_DEFINED

 #include "SkShader.h"

 /** \class SkPerlinNoiseShader

     SkPerlinNoiseShader creates an image using the Perlin turbulence function.

     It can produce tileable noise if asked to stitch tiles and provided a tile size.
     In order to fill a large area with repeating noise, set the stitchTiles flag to
     true, and render exactly a single tile of noise. Without this flag, the result
     will contain visible seams between tiles.

     The algorithm used is described here :
     http://www.w3.org/TR/SVG/filters.html#feTurbulenceElement
 */
 class SK_API SkPerlinNoiseShader : public SkShader {
     struct PaintingData;
 public:
     struct StitchData;

     /**
      *  About the noise types : the difference between the 2 is just minor tweaks to the algorithm,
      *  they're not 2 entirely different noises. The output looks different, but once the noise is
      *  generated in the [1, -1] range, the output is brought back in the [0, 1] range by doing :
      *  kFractalNoise_Type : noise * 0.5 + 0.5
      *  kTurbulence_Type   : abs(noise)
      *  Very little differences between the 2 types, although you can tell the difference visually.
      */
     enum Type {
         kFractalNoise_Type,
         kTurbulence_Type,
         kFirstType = kFractalNoise_Type,
         kLastType = kTurbulence_Type
     };
     /**
      *  This will construct Perlin noise of the given type (Fractal Noise or Turbulence).
      *
      *  Both base frequencies (X and Y) have a usual range of (0..1).
      *
      *  The number of octaves provided should be fairly small, although no limit is enforced.
      *  Each octave doubles the frequency, so 10 octaves would produce noise from
      *  baseFrequency * 1, * 2, * 4, ..., * 512, which quickly yields insignificantly small
      *  periods and resembles regular unstructured noise rather than Perlin noise.
      *
      *  If tileSize isn't NULL or an empty size, the tileSize parameter will be used to modify
      *  the frequencies so that the noise will be tileable for the given tile size. If tileSize
      *  is NULL or an empty size, the frequencies will be used as is without modification.
      */
     static SkShader* CreateFractalNoise(SkScalar baseFrequencyX, SkScalar baseFrequencyY,
                                         int numOctaves, SkScalar seed,
                                         const SkISize* tileSize = NULL);
     static SkShader* CreateTubulence(SkScalar baseFrequencyX, SkScalar baseFrequencyY,
                                      int numOctaves, SkScalar seed,
                                      const SkISize* tileSize = NULL);

     virtual bool setContext(const SkBitmap& device, const SkPaint& paint,
                             const SkMatrix& matrix);
     virtual void shadeSpan(int x, int y, SkPMColor[], int count) SK_OVERRIDE;
     virtual void shadeSpan16(int x, int y, uint16_t[], int count) SK_OVERRIDE;

     virtual GrEffectRef* asNewEffect(GrContext* context, const SkPaint&) const SK_OVERRIDE;

     SK_DEVELOPER_TO_STRING()
     SK_DECLARE_PUBLIC_FLATTENABLE_DESERIALIZATION_PROCS(SkPerlinNoiseShader)

 protected:
     SkPerlinNoiseShader(SkReadBuffer&);
     virtual void flatten(SkWriteBuffer&) const SK_OVERRIDE;

 private:
     SkPerlinNoiseShader(SkPerlinNoiseShader::Type type, SkScalar baseFrequencyX,
                         SkScalar baseFrequencyY, int numOctaves, SkScalar seed,
                         const SkISize* tileSize = NULL);
     virtual ~SkPerlinNoiseShader();

     void setTileSize(const SkISize&);

     void initPaint(PaintingData& paintingData);

     SkScalar noise2D(int channel, const PaintingData& paintingData,
                      const StitchData& stitchData, const SkPoint& noiseVector);

     SkScalar calculateTurbulenceValueForPoint(int channel, const PaintingData& paintingData,
                                               StitchData& stitchData, const SkPoint& point);

     SkPMColor shade(const SkPoint& point, StitchData& stitchData);

     SkPerlinNoiseShader::Type fType;
     SkScalar fBaseFrequencyX;
     SkScalar fBaseFrequencyY;
     int fNumOctaves;
     SkScalar fSeed;
     SkISize fTileSize;
     bool fStitchTiles;
     SkMatrix fMatrix;

     PaintingData* fPaintingData;

     typedef SkShader INHERITED;
 };

 #endif
	/*
	* Copyright 2013 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkPerlinNoiseShader_DEFINED
	#define SkPerlinNoiseShader_DEFINED

	#include "SkShader.h"

	/** \class SkPerlinNoiseShader

	SkPerlinNoiseShader creates an image using the Perlin turbulence function.

	It can produce tileable noise if asked to stitch tiles and provided a tile size.
	In order to fill a large area with repeating noise, set the stitchTiles flag to
	true, and render exactly a single tile of noise. Without this flag, the result
	will contain visible seams between tiles.

	The algorithm used is described here :
	http://www.w3.org/TR/SVG/filters.html#feTurbulenceElement
	*/
	class SK_API SkPerlinNoiseShader : public SkShader {
	struct PaintingData;
	public:
	struct StitchData;

	/**
	* About the noise types : the difference between the 2 is just minor tweaks to the algorithm,
	* they're not 2 entirely different noises. The output looks different, but once the noise is
	* generated in the [1, -1] range, the output is brought back in the [0, 1] range by doing :
	* kFractalNoise_Type : noise * 0.5 + 0.5
	* kTurbulence_Type : abs(noise)
	* Very little differences between the 2 types, although you can tell the difference visually.
	*/
	enum Type {
	kFractalNoise_Type,
	kTurbulence_Type,
	kFirstType = kFractalNoise_Type,
	kLastType = kTurbulence_Type
	};
	/**
	* This will construct Perlin noise of the given type (Fractal Noise or Turbulence).
	*
	* Both base frequencies (X and Y) have a usual range of (0..1).
	*
	* The number of octaves provided should be fairly small, although no limit is enforced.
	* Each octave doubles the frequency, so 10 octaves would produce noise from
	* baseFrequency * 1, * 2, * 4, ..., * 512, which quickly yields insignificantly small
	* periods and resembles regular unstructured noise rather than Perlin noise.
	*
	* If tileSize isn't NULL or an empty size, the tileSize parameter will be used to modify
	* the frequencies so that the noise will be tileable for the given tile size. If tileSize
	* is NULL or an empty size, the frequencies will be used as is without modification.
	*/
	static SkShader* CreateFractalNoise(SkScalar baseFrequencyX, SkScalar baseFrequencyY,
	int numOctaves, SkScalar seed,
	const SkISize* tileSize = NULL);
	static SkShader* CreateTubulence(SkScalar baseFrequencyX, SkScalar baseFrequencyY,
	int numOctaves, SkScalar seed,
	const SkISize* tileSize = NULL);

	virtual bool setContext(const SkBitmap& device, const SkPaint& paint,
	const SkMatrix& matrix);
	virtual void shadeSpan(int x, int y, SkPMColor[], int count) SK_OVERRIDE;
	virtual void shadeSpan16(int x, int y, uint16_t[], int count) SK_OVERRIDE;

	virtual GrEffectRef* asNewEffect(GrContext* context, const SkPaint&) const SK_OVERRIDE;

	SK_DEVELOPER_TO_STRING()
	SK_DECLARE_PUBLIC_FLATTENABLE_DESERIALIZATION_PROCS(SkPerlinNoiseShader)

	protected:
	SkPerlinNoiseShader(SkReadBuffer&);
	virtual void flatten(SkWriteBuffer&) const SK_OVERRIDE;

	private:
	SkPerlinNoiseShader(SkPerlinNoiseShader::Type type, SkScalar baseFrequencyX,
	SkScalar baseFrequencyY, int numOctaves, SkScalar seed,
	const SkISize* tileSize = NULL);
	virtual ~SkPerlinNoiseShader();

	void setTileSize(const SkISize&);

	void initPaint(PaintingData& paintingData);

	SkScalar noise2D(int channel, const PaintingData& paintingData,
	const StitchData& stitchData, const SkPoint& noiseVector);

	SkScalar calculateTurbulenceValueForPoint(int channel, const PaintingData& paintingData,
	StitchData& stitchData, const SkPoint& point);

	SkPMColor shade(const SkPoint& point, StitchData& stitchData);

	SkPerlinNoiseShader::Type fType;
	SkScalar fBaseFrequencyX;
	SkScalar fBaseFrequencyY;
	int fNumOctaves;
	SkScalar fSeed;
	SkISize fTileSize;
	bool fStitchTiles;
	SkMatrix fMatrix;

	PaintingData* fPaintingData;

	typedef SkShader INHERITED;
	};

	#endif