src/core/SkMaskGamma.h - platform/external/skia - Git at Google

 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkMaskGamma_DEFINED
 #define SkMaskGamma_DEFINED

 #include "SkTypes.h"
 #include "SkColor.h"
 #include "SkColorPriv.h"
 #include "SkRefCnt.h"

 /**
  * SkColorSpaceLuminance is used to convert luminances to and from linear and
  * perceptual color spaces.
  *
  * Luma is used to specify a linear luminance value [0.0, 1.0].
  * Luminance is used to specify a luminance value in an arbitrary color space [0.0, 1.0].
  */
 class SkColorSpaceLuminance : SkNoncopyable {
 public:
     virtual ~SkColorSpaceLuminance() { }

     /** Converts a color component luminance in the color space to a linear luma. */
     virtual SkScalar toLuma(SkScalar gamma, SkScalar luminance) const = 0;
     /** Converts a linear luma to a color component luminance in the color space. */
     virtual SkScalar fromLuma(SkScalar gamma, SkScalar luma) const = 0;

     /** Converts a color to a luminance value. */
     static U8CPU computeLuminance(SkScalar gamma, SkColor c) {
         const SkColorSpaceLuminance& luminance = Fetch(gamma);
         SkScalar r = luminance.toLuma(gamma, SkIntToScalar(SkColorGetR(c)) / 255);
         SkScalar g = luminance.toLuma(gamma, SkIntToScalar(SkColorGetG(c)) / 255);
         SkScalar b = luminance.toLuma(gamma, SkIntToScalar(SkColorGetB(c)) / 255);
         SkScalar luma = r * SkFloatToScalar(SK_LUM_COEFF_R) +
                         g * SkFloatToScalar(SK_LUM_COEFF_G) +
                         b * SkFloatToScalar(SK_LUM_COEFF_B);
         SkASSERT(luma <= SK_Scalar1);
         return SkScalarRoundToInt(luminance.fromLuma(gamma, luma) * 255);
     }

     /** Retrieves the SkColorSpaceLuminance for the given gamma. */
     static const SkColorSpaceLuminance& Fetch(SkScalar gamma);
 };

 ///@{
 /**
  * Scales base <= 2^N-1 to 2^8-1
  * @param N [1, 8] the number of bits used by base.
  * @param base the number to be scaled to [0, 255].
  */
 template<U8CPU N> static inline U8CPU sk_t_scale255(U8CPU base) {
     base <<= (8 - N);
     U8CPU lum = base;
     for (unsigned int i = N; i < 8; i += N) {
         lum |= base >> i;
     }
     return lum;
 }
 template<> /*static*/ inline U8CPU sk_t_scale255<1>(U8CPU base) {
     return base * 0xFF;
 }
 template<> /*static*/ inline U8CPU sk_t_scale255<2>(U8CPU base) {
     return base * 0x55;
 }
 template<> /*static*/ inline U8CPU sk_t_scale255<4>(U8CPU base) {
     return base * 0x11;
 }
 template<> /*static*/ inline U8CPU sk_t_scale255<8>(U8CPU base) {
     return base;
 }
 ///@}

 template <int R_LUM_BITS, int G_LUM_BITS, int B_LUM_BITS> class SkTMaskPreBlend;

 void SkTMaskGamma_build_correcting_lut(uint8_t table[256], U8CPU srcI, SkScalar contrast,
                                        const SkColorSpaceLuminance& srcConvert, SkScalar srcGamma,
                                        const SkColorSpaceLuminance& dstConvert, SkScalar dstGamma);

 /**
  * A regular mask contains linear alpha values. A gamma correcting mask
  * contains non-linear alpha values in an attempt to create gamma correct blits
  * in the presence of a gamma incorrect (linear) blend in the blitter.
  *
  * SkMaskGamma creates and maintains tables which convert linear alpha values
  * to gamma correcting alpha values.
  * @param R The number of luminance bits to use [1, 8] from the red channel.
  * @param G The number of luminance bits to use [1, 8] from the green channel.
  * @param B The number of luminance bits to use [1, 8] from the blue channel.
  */
 template <int R_LUM_BITS, int G_LUM_BITS, int B_LUM_BITS> class SkTMaskGamma : public SkRefCnt {
 public:
     SK_DECLARE_INST_COUNT_TEMPLATE(SkTMaskGamma)

     /** Creates a linear SkTMaskGamma. */
     SkTMaskGamma() : fIsLinear(true) { }

     /**
      * Creates tables to convert linear alpha values to gamma correcting alpha
      * values.
      *
      * @param contrast A value in the range [0.0, 1.0] which indicates the
      *                 amount of artificial contrast to add.
      * @param paint The color space in which the paint color was chosen.
      * @param device The color space of the target device.
      */
     SkTMaskGamma(SkScalar contrast, SkScalar paintGamma, SkScalar deviceGamma) : fIsLinear(false) {
         const SkColorSpaceLuminance& paintConvert = SkColorSpaceLuminance::Fetch(paintGamma);
         const SkColorSpaceLuminance& deviceConvert = SkColorSpaceLuminance::Fetch(deviceGamma);
         for (U8CPU i = 0; i < (1 << MAX_LUM_BITS); ++i) {
             U8CPU lum = sk_t_scale255<MAX_LUM_BITS>(i);
             SkTMaskGamma_build_correcting_lut(fGammaTables[i], lum, contrast,
                                               paintConvert, paintGamma,
                                               deviceConvert, deviceGamma);
         }
     }

     /** Given a color, returns the closest canonical color. */
     static SkColor CanonicalColor(SkColor color) {
         return SkColorSetRGB(
                    sk_t_scale255<R_LUM_BITS>(SkColorGetR(color) >> (8 - R_LUM_BITS)),
                    sk_t_scale255<G_LUM_BITS>(SkColorGetG(color) >> (8 - G_LUM_BITS)),
                    sk_t_scale255<B_LUM_BITS>(SkColorGetB(color) >> (8 - B_LUM_BITS)));
     }

     /** The type of the mask pre-blend which will be returned from preBlend(SkColor). */
     typedef SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS> PreBlend;

     /**
      * Provides access to the tables appropriate for converting linear alpha
      * values into gamma correcting alpha values when drawing the given color
      * through the mask. The destination color will be approximated.
      */
     PreBlend preBlend(SkColor color) const;

 private:
     static const int MAX_LUM_BITS =
           B_LUM_BITS > (R_LUM_BITS > G_LUM_BITS ? R_LUM_BITS : G_LUM_BITS)
         ? B_LUM_BITS : (R_LUM_BITS > G_LUM_BITS ? R_LUM_BITS : G_LUM_BITS);
     uint8_t fGammaTables[1 << MAX_LUM_BITS][256];
     bool fIsLinear;

     typedef SkRefCnt INHERITED;
 };


 #define MacroComma ,
 SK_DEFINE_INST_COUNT_TEMPLATE(
     template <int R_LUM_BITS MacroComma int G_LUM_BITS MacroComma int B_LUM_BITS>,
     SkTMaskGamma<R_LUM_BITS MacroComma G_LUM_BITS MacroComma B_LUM_BITS>);

 /**
  * SkTMaskPreBlend is a tear-off of SkTMaskGamma. It provides the tables to
  * convert a linear alpha value for a given channel to a gamma correcting alpha
  * value for that channel. This class is immutable.
  *
  * If fR, fG, or fB is NULL, all of them will be. This indicates that no mask
  * pre blend should be applied. SkTMaskPreBlend::isApplicable() is provided as
  * a convenience function to test for the absence of this case.
  */
 template <int R_LUM_BITS, int G_LUM_BITS, int B_LUM_BITS> class SkTMaskPreBlend {
 private:
     SkTMaskPreBlend(const SkTMaskGamma<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>* parent,
                     const uint8_t* r, const uint8_t* g, const uint8_t* b)
     : fParent(SkSafeRef(parent)), fR(r), fG(g), fB(b) { }

     SkAutoTUnref<const SkTMaskGamma<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS> > fParent;
     friend class SkTMaskGamma<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>;
 public:
     /** Creates a non applicable SkTMaskPreBlend. */
     SkTMaskPreBlend() : fParent(), fR(NULL), fG(NULL), fB(NULL) { }

     /**
      * This copy contructor exists for correctness, but should never be called
      * when return value optimization is enabled.
      */
     SkTMaskPreBlend(const SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>& that)
     : fParent(SkSafeRef(that.fParent.get())), fR(that.fR), fG(that.fG), fB(that.fB) { }

     ~SkTMaskPreBlend() { }

     /** True if this PreBlend should be applied. When false, fR, fG, and fB are NULL. */
     bool isApplicable() const {
         return NULL != this->fG;
     }

     const uint8_t* fR;
     const uint8_t* fG;
     const uint8_t* fB;
 };

 template <int R_LUM_BITS, int G_LUM_BITS, int B_LUM_BITS>
 SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>
 SkTMaskGamma<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>::preBlend(SkColor color) const {
     return fIsLinear ? SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>()
                      : SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>(this,
                          fGammaTables[SkColorGetR(color) >> (8 - MAX_LUM_BITS)],
                          fGammaTables[SkColorGetG(color) >> (8 - MAX_LUM_BITS)],
                          fGammaTables[SkColorGetB(color) >> (8 - MAX_LUM_BITS)]);
 }

 ///@{
 /**
  *  If APPLY_LUT is false, returns component unchanged.
  *  If APPLY_LUT is true, returns lut[component].
  *  @param APPLY_LUT whether or not the look-up table should be applied to component.
  *  @component the initial component.
  *  @lut a look-up table which transforms the component.
  */
 template<bool APPLY_LUT> static inline U8CPU sk_apply_lut_if(U8CPU component, const uint8_t*) {
     return component;
 }
 template<> /*static*/ inline U8CPU sk_apply_lut_if<true>(U8CPU component, const uint8_t* lut) {
     return lut[component];
 }
 ///@}

 #endif
	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkMaskGamma_DEFINED
	#define SkMaskGamma_DEFINED

	#include "SkTypes.h"
	#include "SkColor.h"
	#include "SkColorPriv.h"
	#include "SkRefCnt.h"

	/**
	* SkColorSpaceLuminance is used to convert luminances to and from linear and
	* perceptual color spaces.
	*
	* Luma is used to specify a linear luminance value [0.0, 1.0].
	* Luminance is used to specify a luminance value in an arbitrary color space [0.0, 1.0].
	*/
	class SkColorSpaceLuminance : SkNoncopyable {
	public:
	virtual ~SkColorSpaceLuminance() { }

	/** Converts a color component luminance in the color space to a linear luma. */
	virtual SkScalar toLuma(SkScalar gamma, SkScalar luminance) const = 0;
	/** Converts a linear luma to a color component luminance in the color space. */
	virtual SkScalar fromLuma(SkScalar gamma, SkScalar luma) const = 0;

	/** Converts a color to a luminance value. */
	static U8CPU computeLuminance(SkScalar gamma, SkColor c) {
	const SkColorSpaceLuminance& luminance = Fetch(gamma);
	SkScalar r = luminance.toLuma(gamma, SkIntToScalar(SkColorGetR(c)) / 255);
	SkScalar g = luminance.toLuma(gamma, SkIntToScalar(SkColorGetG(c)) / 255);
	SkScalar b = luminance.toLuma(gamma, SkIntToScalar(SkColorGetB(c)) / 255);
	SkScalar luma = r * SkFloatToScalar(SK_LUM_COEFF_R) +
	g * SkFloatToScalar(SK_LUM_COEFF_G) +
	b * SkFloatToScalar(SK_LUM_COEFF_B);
	SkASSERT(luma <= SK_Scalar1);
	return SkScalarRoundToInt(luminance.fromLuma(gamma, luma) * 255);
	}

	/** Retrieves the SkColorSpaceLuminance for the given gamma. */
	static const SkColorSpaceLuminance& Fetch(SkScalar gamma);
	};

	///@{
	/**
	* Scales base <= 2^N-1 to 2^8-1
	* @param N [1, 8] the number of bits used by base.
	* @param base the number to be scaled to [0, 255].
	*/
	template<U8CPU N> static inline U8CPU sk_t_scale255(U8CPU base) {
	base <<= (8 - N);
	U8CPU lum = base;
	for (unsigned int i = N; i < 8; i += N) {
	lum \|= base >> i;
	}
	return lum;
	}
	template<> /static/ inline U8CPU sk_t_scale255<1>(U8CPU base) {
	return base * 0xFF;
	}
	template<> /static/ inline U8CPU sk_t_scale255<2>(U8CPU base) {
	return base * 0x55;
	}
	template<> /static/ inline U8CPU sk_t_scale255<4>(U8CPU base) {
	return base * 0x11;
	}
	template<> /static/ inline U8CPU sk_t_scale255<8>(U8CPU base) {
	return base;
	}
	///@}

	template <int R_LUM_BITS, int G_LUM_BITS, int B_LUM_BITS> class SkTMaskPreBlend;

	void SkTMaskGamma_build_correcting_lut(uint8_t table[256], U8CPU srcI, SkScalar contrast,
	const SkColorSpaceLuminance& srcConvert, SkScalar srcGamma,
	const SkColorSpaceLuminance& dstConvert, SkScalar dstGamma);

	/**
	* A regular mask contains linear alpha values. A gamma correcting mask
	* contains non-linear alpha values in an attempt to create gamma correct blits
	* in the presence of a gamma incorrect (linear) blend in the blitter.
	*
	* SkMaskGamma creates and maintains tables which convert linear alpha values
	* to gamma correcting alpha values.
	* @param R The number of luminance bits to use [1, 8] from the red channel.
	* @param G The number of luminance bits to use [1, 8] from the green channel.
	* @param B The number of luminance bits to use [1, 8] from the blue channel.
	*/
	template <int R_LUM_BITS, int G_LUM_BITS, int B_LUM_BITS> class SkTMaskGamma : public SkRefCnt {
	public:
	SK_DECLARE_INST_COUNT_TEMPLATE(SkTMaskGamma)

	/** Creates a linear SkTMaskGamma. */
	SkTMaskGamma() : fIsLinear(true) { }

	/**
	* Creates tables to convert linear alpha values to gamma correcting alpha
	* values.
	*
	* @param contrast A value in the range [0.0, 1.0] which indicates the
	* amount of artificial contrast to add.
	* @param paint The color space in which the paint color was chosen.
	* @param device The color space of the target device.
	*/
	SkTMaskGamma(SkScalar contrast, SkScalar paintGamma, SkScalar deviceGamma) : fIsLinear(false) {
	const SkColorSpaceLuminance& paintConvert = SkColorSpaceLuminance::Fetch(paintGamma);
	const SkColorSpaceLuminance& deviceConvert = SkColorSpaceLuminance::Fetch(deviceGamma);
	for (U8CPU i = 0; i < (1 << MAX_LUM_BITS); ++i) {
	U8CPU lum = sk_t_scale255<MAX_LUM_BITS>(i);
	SkTMaskGamma_build_correcting_lut(fGammaTables[i], lum, contrast,
	paintConvert, paintGamma,
	deviceConvert, deviceGamma);
	}
	}

	/** Given a color, returns the closest canonical color. */
	static SkColor CanonicalColor(SkColor color) {
	return SkColorSetRGB(
	sk_t_scale255<R_LUM_BITS>(SkColorGetR(color) >> (8 - R_LUM_BITS)),
	sk_t_scale255<G_LUM_BITS>(SkColorGetG(color) >> (8 - G_LUM_BITS)),
	sk_t_scale255<B_LUM_BITS>(SkColorGetB(color) >> (8 - B_LUM_BITS)));
	}

	/** The type of the mask pre-blend which will be returned from preBlend(SkColor). */
	typedef SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS> PreBlend;

	/**
	* Provides access to the tables appropriate for converting linear alpha
	* values into gamma correcting alpha values when drawing the given color
	* through the mask. The destination color will be approximated.
	*/
	PreBlend preBlend(SkColor color) const;

	private:
	static const int MAX_LUM_BITS =
	B_LUM_BITS > (R_LUM_BITS > G_LUM_BITS ? R_LUM_BITS : G_LUM_BITS)
	? B_LUM_BITS : (R_LUM_BITS > G_LUM_BITS ? R_LUM_BITS : G_LUM_BITS);
	uint8_t fGammaTables[1 << MAX_LUM_BITS][256];
	bool fIsLinear;

	typedef SkRefCnt INHERITED;
	};


	#define MacroComma ,
	SK_DEFINE_INST_COUNT_TEMPLATE(
	template <int R_LUM_BITS MacroComma int G_LUM_BITS MacroComma int B_LUM_BITS>,
	SkTMaskGamma<R_LUM_BITS MacroComma G_LUM_BITS MacroComma B_LUM_BITS>);

	/**
	* SkTMaskPreBlend is a tear-off of SkTMaskGamma. It provides the tables to
	* convert a linear alpha value for a given channel to a gamma correcting alpha
	* value for that channel. This class is immutable.
	*
	* If fR, fG, or fB is NULL, all of them will be. This indicates that no mask
	* pre blend should be applied. SkTMaskPreBlend::isApplicable() is provided as
	* a convenience function to test for the absence of this case.
	*/
	template <int R_LUM_BITS, int G_LUM_BITS, int B_LUM_BITS> class SkTMaskPreBlend {
	private:
	SkTMaskPreBlend(const SkTMaskGamma<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>* parent,
	const uint8_t* r, const uint8_t* g, const uint8_t* b)
	: fParent(SkSafeRef(parent)), fR(r), fG(g), fB(b) { }

	SkAutoTUnref<const SkTMaskGamma<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS> > fParent;
	friend class SkTMaskGamma<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>;
	public:
	/** Creates a non applicable SkTMaskPreBlend. */
	SkTMaskPreBlend() : fParent(), fR(NULL), fG(NULL), fB(NULL) { }

	/**
	* This copy contructor exists for correctness, but should never be called
	* when return value optimization is enabled.
	*/
	SkTMaskPreBlend(const SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>& that)
	: fParent(SkSafeRef(that.fParent.get())), fR(that.fR), fG(that.fG), fB(that.fB) { }

	~SkTMaskPreBlend() { }

	/** True if this PreBlend should be applied. When false, fR, fG, and fB are NULL. */
	bool isApplicable() const {
	return NULL != this->fG;
	}

	const uint8_t* fR;
	const uint8_t* fG;
	const uint8_t* fB;
	};

	template <int R_LUM_BITS, int G_LUM_BITS, int B_LUM_BITS>
	SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>
	SkTMaskGamma<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>::preBlend(SkColor color) const {
	return fIsLinear ? SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>()
	: SkTMaskPreBlend<R_LUM_BITS, G_LUM_BITS, B_LUM_BITS>(this,
	fGammaTables[SkColorGetR(color) >> (8 - MAX_LUM_BITS)],
	fGammaTables[SkColorGetG(color) >> (8 - MAX_LUM_BITS)],
	fGammaTables[SkColorGetB(color) >> (8 - MAX_LUM_BITS)]);
	}

	///@{
	/**
	* If APPLY_LUT is false, returns component unchanged.
	* If APPLY_LUT is true, returns lut[component].
	* @param APPLY_LUT whether or not the look-up table should be applied to component.
	* @component the initial component.
	* @lut a look-up table which transforms the component.
	*/
	template<bool APPLY_LUT> static inline U8CPU sk_apply_lut_if(U8CPU component, const uint8_t*) {
	return component;
	}
	template<> /static/ inline U8CPU sk_apply_lut_if<true>(U8CPU component, const uint8_t* lut) {
	return lut[component];
	}
	///@}

	#endif