src/core/SkScalerContext.h - skia - Git at Google

 /*
  * Copyright 2006 The Android Open Source Project
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkScalerContext_DEFINED
 #define SkScalerContext_DEFINED

 #include "SkMask.h"
 #include "SkMaskGamma.h"
 #include "SkMatrix.h"
 #include "SkPaint.h"
 #include "SkTypeface.h"

 class SkGlyph;
 class SkDescriptor;
 class SkMaskFilter;
 class SkPathEffect;
 class SkRasterizer;

 /*
  *  To allow this to be forward-declared, it must be its own typename, rather
  *  than a nested struct inside SkScalerContext (where it started).
  */
 struct SkScalerContextRec {
     uint32_t    fFontID;
     SkScalar    fTextSize, fPreScaleX, fPreSkewX;
     SkScalar    fPost2x2[2][2];
     SkScalar    fFrameWidth, fMiterLimit;

     //These describe the parameters to create (uniquely identify) the pre-blend.
     uint32_t    fLumBits;
     uint8_t     fDeviceGamma; //2.6, (0.0, 4.0) gamma, 0.0 for sRGB
     uint8_t     fPaintGamma;  //2.6, (0.0, 4.0) gamma, 0.0 for sRGB
     uint8_t     fContrast;    //0.8+1, [0.0, 1.0] artificial contrast
     uint8_t     fReservedAlign;

     SkScalar getDeviceGamma() const {
         return SkIntToScalar(fDeviceGamma) / (1 << 6);
     }
     void setDeviceGamma(SkScalar dg) {
         SkASSERT(0 <= dg && dg < SkIntToScalar(4));
         fDeviceGamma = SkScalarFloorToInt(dg * (1 << 6));
     }

     SkScalar getPaintGamma() const {
         return SkIntToScalar(fPaintGamma) / (1 << 6);
     }
     void setPaintGamma(SkScalar pg) {
         SkASSERT(0 <= pg && pg < SkIntToScalar(4));
         fPaintGamma = SkScalarFloorToInt(pg * (1 << 6));
     }

     SkScalar getContrast() const {
         return SkIntToScalar(fContrast) / ((1 << 8) - 1);
     }
     void setContrast(SkScalar c) {
         SkASSERT(0 <= c && c <= SK_Scalar1);
         fContrast = SkScalarRoundToInt(c * ((1 << 8) - 1));
     }

     /**
      *  Causes the luminance color and contrast to be ignored, and the
      *  paint and device gamma to be effectively 1.0.
      */
     void ignorePreBlend() {
         setLuminanceColor(SK_ColorTRANSPARENT);
         setPaintGamma(SK_Scalar1);
         setDeviceGamma(SK_Scalar1);
         setContrast(0);
     }

     uint8_t     fMaskFormat;
     uint8_t     fStrokeJoin;
     uint16_t    fFlags;
     // Warning: when adding members note that the size of this structure
     // must be a multiple of 4. SkDescriptor requires that its arguments be
     // multiples of four and this structure is put in an SkDescriptor in
     // SkPaint::MakeRec.

     void    getMatrixFrom2x2(SkMatrix*) const;
     void    getLocalMatrix(SkMatrix*) const;
     void    getSingleMatrix(SkMatrix*) const;

     /** The kind of scale which will be applied by the underlying port (pre-matrix). */
     enum PreMatrixScale {
         kFull_PreMatrixScale,  // The underlying port can apply both x and y scale.
         kVertical_PreMatrixScale,  // The underlying port can only apply a y scale.
         kVerticalInteger_PreMatrixScale  // The underlying port can only apply an integer y scale.
     };
     /**
      *  Compute useful matrices for use with sizing in underlying libraries.
      *
      *  There are two kinds of text size, a 'requested/logical size' which is like asking for size
      *  '12' and a 'real' size which is the size after the matrix is applied. The matrices produced
      *  by this method are based on the 'real' size. This method effectively finds the total device
      *  matrix and decomposes it in various ways.
      *
      *  The most useful decomposition is into 'scale' and 'remaining'. The 'scale' is applied first
      *  and then the 'remaining' to fully apply the total matrix. This decomposition is useful when
      *  the text size ('scale') may have meaning apart from the total matrix. This is true when
      *  hinting, and sometimes true for other properties as well.
      *
      *  The second (optional) decomposition is of 'remaining' into a non-rotational part
      *  'remainingWithoutRotation' and a rotational part 'remainingRotation'. The 'scale' is applied
      *  first, then 'remainingWithoutRotation', then 'remainingRotation' to fully apply the total
      *  matrix. This decomposition is helpful when only horizontal metrics can be trusted, so the
      *  'scale' and 'remainingWithoutRotation' will be handled by the underlying library, but
      *  the final rotation 'remainingRotation' will be handled manually.
      *
      *  The 'total' matrix is also (optionally) available. This is useful in cases where the
      *  underlying library will not be used, often when working directly with font data.
      *
      *  The parameters 'scale' and 'remaining' are required, the other pointers may be NULL.
      *
      *  @param preMatrixScale the kind of scale to extract from the total matrix.
      *  @param scale the scale extracted from the total matrix (both values positive).
      *  @param remaining apply after scale to apply the total matrix.
      *  @param remainingWithoutRotation apply after scale to apply the total matrix sans rotation.
      *  @param remainingRotation apply after remainingWithoutRotation to apply the total matrix.
      *  @param total the total matrix.
      */
     void computeMatrices(PreMatrixScale preMatrixScale,
                          SkVector* scale, SkMatrix* remaining,
                          SkMatrix* remainingWithoutRotation = NULL,
                          SkMatrix* remainingRotation = NULL,
                          SkMatrix* total = NULL);

     inline SkPaint::Hinting getHinting() const;
     inline void setHinting(SkPaint::Hinting);

     SkMask::Format getFormat() const {
         return static_cast<SkMask::Format>(fMaskFormat);
     }

     SkColor getLuminanceColor() const {
         return fLumBits;
     }

     void setLuminanceColor(SkColor c) {
         fLumBits = c;
     }
 };

 //The following typedef hides from the rest of the implementation the number of
 //most significant bits to consider when creating mask gamma tables. Two bits
 //per channel was chosen as a balance between fidelity (more bits) and cache
 //sizes (fewer bits). Three bits per channel was chosen when #303942; (used by
 //the Chrome UI) turned out too green.
 typedef SkTMaskGamma<3, 3, 3> SkMaskGamma;

 class SkScalerContext {
 public:
     typedef SkScalerContextRec Rec;

     enum Flags {
         kFrameAndFill_Flag        = 0x0001,
         kDevKernText_Flag         = 0x0002,
         kEmbeddedBitmapText_Flag  = 0x0004,
         kEmbolden_Flag            = 0x0008,
         kSubpixelPositioning_Flag = 0x0010,
         kForceAutohinting_Flag    = 0x0020,  // Use auto instead of bytcode hinting if hinting.
         kVertical_Flag            = 0x0040,

         // together, these two flags resulting in a two bit value which matches
         // up with the SkPaint::Hinting enum.
         kHinting_Shift            = 7, // to shift into the other flags above
         kHintingBit1_Flag         = 0x0080,
         kHintingBit2_Flag         = 0x0100,

         // Pixel geometry information.
         // only meaningful if fMaskFormat is kLCD16
         kLCD_Vertical_Flag        = 0x0200,    // else Horizontal
         kLCD_BGROrder_Flag        = 0x0400,    // else RGB order

         // Generate A8 from LCD source (for GDI and CoreGraphics).
         // only meaningful if fMaskFormat is kA8
         kGenA8FromLCD_Flag        = 0x0800, // could be 0x200 (bit meaning dependent on fMaskFormat)
     };

     // computed values
     enum {
         kHinting_Mask   = kHintingBit1_Flag | kHintingBit2_Flag,
     };


     SkScalerContext(SkTypeface*, const SkDescriptor*);
     virtual ~SkScalerContext();

     SkTypeface* getTypeface() const { return fTypeface.get(); }

     SkMask::Format getMaskFormat() const {
         return (SkMask::Format)fRec.fMaskFormat;
     }

     bool isSubpixel() const {
         return SkToBool(fRec.fFlags & kSubpixelPositioning_Flag);
     }

     bool isVertical() const {
         return SkToBool(fRec.fFlags & kVertical_Flag);
     }

     /** Return the corresponding glyph for the specified unichar. Since contexts
         may be chained (under the hood), the glyphID that is returned may in
         fact correspond to a different font/context. In that case, we use the
         base-glyph-count to know how to translate back into local glyph space.
      */
     uint16_t charToGlyphID(SkUnichar uni) {
         return generateCharToGlyph(uni);
     }

     /** Map the glyphID to its glyph index, and then to its char code. Unmapped
         glyphs return zero.
     */
     SkUnichar glyphIDToChar(uint16_t glyphID) {
         return (glyphID < getGlyphCount()) ? generateGlyphToChar(glyphID) : 0;
     }

     unsigned    getGlyphCount() { return this->generateGlyphCount(); }
     void        getAdvance(SkGlyph*);
     void        getMetrics(SkGlyph*);
     void        getImage(const SkGlyph&);
     void        getPath(const SkGlyph&, SkPath*);
     void        getFontMetrics(SkPaint::FontMetrics*);

     /** Return the size in bytes of the associated gamma lookup table
      */
     static size_t GetGammaLUTSize(SkScalar contrast, SkScalar paintGamma, SkScalar deviceGamma,
                                   int* width, int* height);

     /** Get the associated gamma lookup table. The 'data' pointer must point to pre-allocated
         memory, with size in bytes greater than or equal to the return value of getGammaLUTSize().
      */
     static void   GetGammaLUTData(SkScalar contrast, SkScalar paintGamma, SkScalar deviceGamma,
                                   void* data);

     static void MakeRec(const SkPaint&, const SkDeviceProperties* deviceProperties,
                         const SkMatrix*, Rec* rec);
     static inline void PostMakeRec(const SkPaint&, Rec*);

     static SkMaskGamma::PreBlend GetMaskPreBlend(const Rec& rec);

     const Rec& getRec() const { return fRec; }

 protected:
     Rec         fRec;

     /** Generates the contents of glyph.fAdvanceX and glyph.fAdvanceY.
      *  May call getMetrics if that would be just as fast.
      */
     virtual void generateAdvance(SkGlyph* glyph) = 0;

     /** Generates the contents of glyph.fWidth, fHeight, fTop, fLeft,
      *  as well as fAdvanceX and fAdvanceY if not already set.
      *
      *  TODO: fMaskFormat is set by getMetrics later; cannot be set here.
      */
     virtual void generateMetrics(SkGlyph* glyph) = 0;

     /** Generates the contents of glyph.fImage.
      *  When called, glyph.fImage will be pointing to a pre-allocated,
      *  uninitialized region of memory of size glyph.computeImageSize().
      *  This method may change glyph.fMaskFormat if the new image size is
      *  less than or equal to the old image size.
      *
      *  Because glyph.computeImageSize() will determine the size of fImage,
      *  generateMetrics will be called before generateImage.
      */
     virtual void generateImage(const SkGlyph& glyph) = 0;

     /** Sets the passed path to the glyph outline.
      *  If this cannot be done the path is set to empty;
      *  this is indistinguishable from a glyph with an empty path.
      *  This does not set glyph.fPath.
      *
      *  TODO: path is always glyph.fPath, no reason to pass separately.
      */
     virtual void generatePath(const SkGlyph& glyph, SkPath* path) = 0;

     /** Retrieves font metrics. */
     virtual void generateFontMetrics(SkPaint::FontMetrics*) = 0;

     /** Returns the number of glyphs in the font. */
     virtual unsigned generateGlyphCount() = 0;

     /** Returns the glyph id for the given unichar.
      *  If there is no 1:1 mapping from the unichar to a glyph id, returns 0.
      */
     virtual uint16_t generateCharToGlyph(SkUnichar unichar) = 0;

     /** Returns the unichar for the given glyph id.
      *  If there is no 1:1 mapping from the glyph id to a unichar, returns 0.
      *  The default implementation always returns 0, indicating failure.
      */
     virtual SkUnichar generateGlyphToChar(uint16_t glyphId);

     void forceGenerateImageFromPath() { fGenerateImageFromPath = true; }

     void forceOffGenerateImageFromPath() { fGenerateImageFromPath = false; }

 private:
     // never null
     SkAutoTUnref<SkTypeface> fTypeface;

     // optional object, which may be null
     SkPathEffect*   fPathEffect;
     SkMaskFilter*   fMaskFilter;
     SkRasterizer*   fRasterizer;

     // if this is set, we draw the image from a path, rather than
     // calling generateImage.
     bool fGenerateImageFromPath;

     void internalGetPath(const SkGlyph& glyph, SkPath* fillPath,
                          SkPath* devPath, SkMatrix* fillToDevMatrix);

     // returns the right context from our link-list for this char. If no match
     // is found it returns NULL. If a match is found then the glyphID param is
     // set to the glyphID that maps to the provided char.
     SkScalerContext* getContextFromChar(SkUnichar uni, uint16_t* glyphID);

     // SkMaskGamma::PreBlend converts linear masks to gamma correcting masks.
 protected:
     // Visible to subclasses so that generateImage can apply the pre-blend directly.
     const SkMaskGamma::PreBlend fPreBlend;
 private:
     // When there is a filter, previous steps must create a linear mask
     // and the pre-blend applied as a final step.
     const SkMaskGamma::PreBlend fPreBlendForFilter;

     friend class SkRandomScalerContext; // For debugging
 };

 #define kRec_SkDescriptorTag            SkSetFourByteTag('s', 'r', 'e', 'c')
 #define kPathEffect_SkDescriptorTag     SkSetFourByteTag('p', 't', 'h', 'e')
 #define kMaskFilter_SkDescriptorTag     SkSetFourByteTag('m', 's', 'k', 'f')
 #define kRasterizer_SkDescriptorTag     SkSetFourByteTag('r', 'a', 's', 't')

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

 enum SkAxisAlignment {
     kNone_SkAxisAlignment,
     kX_SkAxisAlignment,
     kY_SkAxisAlignment
 };

 /**
  *  Return the axis (if any) that the baseline for horizontal text will land on
  *  after running through the specified matrix.
  *
  *  As an example, the identity matrix will return kX_SkAxisAlignment
  */
 SkAxisAlignment SkComputeAxisAlignmentForHText(const SkMatrix& matrix);

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

 SkPaint::Hinting SkScalerContextRec::getHinting() const {
     unsigned hint = (fFlags & SkScalerContext::kHinting_Mask) >>
                                             SkScalerContext::kHinting_Shift;
     return static_cast<SkPaint::Hinting>(hint);
 }

 void SkScalerContextRec::setHinting(SkPaint::Hinting hinting) {
     fFlags = (fFlags & ~SkScalerContext::kHinting_Mask) |
                                 (hinting << SkScalerContext::kHinting_Shift);
 }


 #endif
	/*
	* Copyright 2006 The Android Open Source Project
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkScalerContext_DEFINED
	#define SkScalerContext_DEFINED

	#include "SkMask.h"
	#include "SkMaskGamma.h"
	#include "SkMatrix.h"
	#include "SkPaint.h"
	#include "SkTypeface.h"

	class SkGlyph;
	class SkDescriptor;
	class SkMaskFilter;
	class SkPathEffect;
	class SkRasterizer;

	/*
	* To allow this to be forward-declared, it must be its own typename, rather
	* than a nested struct inside SkScalerContext (where it started).
	*/
	struct SkScalerContextRec {
	uint32_t fFontID;
	SkScalar fTextSize, fPreScaleX, fPreSkewX;
	SkScalar fPost2x2[2][2];
	SkScalar fFrameWidth, fMiterLimit;

	//These describe the parameters to create (uniquely identify) the pre-blend.
	uint32_t fLumBits;
	uint8_t fDeviceGamma; //2.6, (0.0, 4.0) gamma, 0.0 for sRGB
	uint8_t fPaintGamma; //2.6, (0.0, 4.0) gamma, 0.0 for sRGB
	uint8_t fContrast; //0.8+1, [0.0, 1.0] artificial contrast
	uint8_t fReservedAlign;

	SkScalar getDeviceGamma() const {
	return SkIntToScalar(fDeviceGamma) / (1 << 6);
	}
	void setDeviceGamma(SkScalar dg) {
	SkASSERT(0 <= dg && dg < SkIntToScalar(4));
	fDeviceGamma = SkScalarFloorToInt(dg * (1 << 6));
	}

	SkScalar getPaintGamma() const {
	return SkIntToScalar(fPaintGamma) / (1 << 6);
	}
	void setPaintGamma(SkScalar pg) {
	SkASSERT(0 <= pg && pg < SkIntToScalar(4));
	fPaintGamma = SkScalarFloorToInt(pg * (1 << 6));
	}

	SkScalar getContrast() const {
	return SkIntToScalar(fContrast) / ((1 << 8) - 1);
	}
	void setContrast(SkScalar c) {
	SkASSERT(0 <= c && c <= SK_Scalar1);
	fContrast = SkScalarRoundToInt(c * ((1 << 8) - 1));
	}

	/**
	* Causes the luminance color and contrast to be ignored, and the
	* paint and device gamma to be effectively 1.0.
	*/
	void ignorePreBlend() {
	setLuminanceColor(SK_ColorTRANSPARENT);
	setPaintGamma(SK_Scalar1);
	setDeviceGamma(SK_Scalar1);
	setContrast(0);
	}

	uint8_t fMaskFormat;
	uint8_t fStrokeJoin;
	uint16_t fFlags;
	// Warning: when adding members note that the size of this structure
	// must be a multiple of 4. SkDescriptor requires that its arguments be
	// multiples of four and this structure is put in an SkDescriptor in
	// SkPaint::MakeRec.

	void getMatrixFrom2x2(SkMatrix*) const;
	void getLocalMatrix(SkMatrix*) const;
	void getSingleMatrix(SkMatrix*) const;

	/** The kind of scale which will be applied by the underlying port (pre-matrix). */
	enum PreMatrixScale {
	kFull_PreMatrixScale, // The underlying port can apply both x and y scale.
	kVertical_PreMatrixScale, // The underlying port can only apply a y scale.
	kVerticalInteger_PreMatrixScale // The underlying port can only apply an integer y scale.
	};
	/**
	* Compute useful matrices for use with sizing in underlying libraries.
	*
	* There are two kinds of text size, a 'requested/logical size' which is like asking for size
	* '12' and a 'real' size which is the size after the matrix is applied. The matrices produced
	* by this method are based on the 'real' size. This method effectively finds the total device
	* matrix and decomposes it in various ways.
	*
	* The most useful decomposition is into 'scale' and 'remaining'. The 'scale' is applied first
	* and then the 'remaining' to fully apply the total matrix. This decomposition is useful when
	* the text size ('scale') may have meaning apart from the total matrix. This is true when
	* hinting, and sometimes true for other properties as well.
	*
	* The second (optional) decomposition is of 'remaining' into a non-rotational part
	* 'remainingWithoutRotation' and a rotational part 'remainingRotation'. The 'scale' is applied
	* first, then 'remainingWithoutRotation', then 'remainingRotation' to fully apply the total
	* matrix. This decomposition is helpful when only horizontal metrics can be trusted, so the
	* 'scale' and 'remainingWithoutRotation' will be handled by the underlying library, but
	* the final rotation 'remainingRotation' will be handled manually.
	*
	* The 'total' matrix is also (optionally) available. This is useful in cases where the
	* underlying library will not be used, often when working directly with font data.
	*
	* The parameters 'scale' and 'remaining' are required, the other pointers may be NULL.
	*
	* @param preMatrixScale the kind of scale to extract from the total matrix.
	* @param scale the scale extracted from the total matrix (both values positive).
	* @param remaining apply after scale to apply the total matrix.
	* @param remainingWithoutRotation apply after scale to apply the total matrix sans rotation.
	* @param remainingRotation apply after remainingWithoutRotation to apply the total matrix.
	* @param total the total matrix.
	*/
	void computeMatrices(PreMatrixScale preMatrixScale,
	SkVector* scale, SkMatrix* remaining,
	SkMatrix* remainingWithoutRotation = NULL,
	SkMatrix* remainingRotation = NULL,
	SkMatrix* total = NULL);

	inline SkPaint::Hinting getHinting() const;
	inline void setHinting(SkPaint::Hinting);

	SkMask::Format getFormat() const {
	return static_cast<SkMask::Format>(fMaskFormat);
	}

	SkColor getLuminanceColor() const {
	return fLumBits;
	}

	void setLuminanceColor(SkColor c) {
	fLumBits = c;
	}
	};

	//The following typedef hides from the rest of the implementation the number of
	//most significant bits to consider when creating mask gamma tables. Two bits
	//per channel was chosen as a balance between fidelity (more bits) and cache
	//sizes (fewer bits). Three bits per channel was chosen when #303942; (used by
	//the Chrome UI) turned out too green.
	typedef SkTMaskGamma<3, 3, 3> SkMaskGamma;

	class SkScalerContext {
	public:
	typedef SkScalerContextRec Rec;

	enum Flags {
	kFrameAndFill_Flag = 0x0001,
	kDevKernText_Flag = 0x0002,
	kEmbeddedBitmapText_Flag = 0x0004,
	kEmbolden_Flag = 0x0008,
	kSubpixelPositioning_Flag = 0x0010,
	kForceAutohinting_Flag = 0x0020, // Use auto instead of bytcode hinting if hinting.
	kVertical_Flag = 0x0040,

	// together, these two flags resulting in a two bit value which matches
	// up with the SkPaint::Hinting enum.
	kHinting_Shift = 7, // to shift into the other flags above
	kHintingBit1_Flag = 0x0080,
	kHintingBit2_Flag = 0x0100,

	// Pixel geometry information.
	// only meaningful if fMaskFormat is kLCD16
	kLCD_Vertical_Flag = 0x0200, // else Horizontal
	kLCD_BGROrder_Flag = 0x0400, // else RGB order

	// Generate A8 from LCD source (for GDI and CoreGraphics).
	// only meaningful if fMaskFormat is kA8
	kGenA8FromLCD_Flag = 0x0800, // could be 0x200 (bit meaning dependent on fMaskFormat)
	};

	// computed values
	enum {
	kHinting_Mask = kHintingBit1_Flag \| kHintingBit2_Flag,
	};


	SkScalerContext(SkTypeface, const SkDescriptor);
	virtual ~SkScalerContext();

	SkTypeface* getTypeface() const { return fTypeface.get(); }

	SkMask::Format getMaskFormat() const {
	return (SkMask::Format)fRec.fMaskFormat;
	}

	bool isSubpixel() const {
	return SkToBool(fRec.fFlags & kSubpixelPositioning_Flag);
	}

	bool isVertical() const {
	return SkToBool(fRec.fFlags & kVertical_Flag);
	}

	/** Return the corresponding glyph for the specified unichar. Since contexts
	may be chained (under the hood), the glyphID that is returned may in
	fact correspond to a different font/context. In that case, we use the
	base-glyph-count to know how to translate back into local glyph space.
	*/
	uint16_t charToGlyphID(SkUnichar uni) {
	return generateCharToGlyph(uni);
	}

	/** Map the glyphID to its glyph index, and then to its char code. Unmapped
	glyphs return zero.
	*/
	SkUnichar glyphIDToChar(uint16_t glyphID) {
	return (glyphID < getGlyphCount()) ? generateGlyphToChar(glyphID) : 0;
	}

	unsigned getGlyphCount() { return this->generateGlyphCount(); }
	void getAdvance(SkGlyph*);
	void getMetrics(SkGlyph*);
	void getImage(const SkGlyph&);
	void getPath(const SkGlyph&, SkPath*);
	void getFontMetrics(SkPaint::FontMetrics*);

	/** Return the size in bytes of the associated gamma lookup table
	*/
	static size_t GetGammaLUTSize(SkScalar contrast, SkScalar paintGamma, SkScalar deviceGamma,
	int* width, int* height);

	/** Get the associated gamma lookup table. The 'data' pointer must point to pre-allocated
	memory, with size in bytes greater than or equal to the return value of getGammaLUTSize().
	*/
	static void GetGammaLUTData(SkScalar contrast, SkScalar paintGamma, SkScalar deviceGamma,
	void* data);

	static void MakeRec(const SkPaint&, const SkDeviceProperties* deviceProperties,
	const SkMatrix, Rec rec);
	static inline void PostMakeRec(const SkPaint&, Rec*);

	static SkMaskGamma::PreBlend GetMaskPreBlend(const Rec& rec);

	const Rec& getRec() const { return fRec; }

	protected:
	Rec fRec;

	/** Generates the contents of glyph.fAdvanceX and glyph.fAdvanceY.
	* May call getMetrics if that would be just as fast.
	*/
	virtual void generateAdvance(SkGlyph* glyph) = 0;

	/** Generates the contents of glyph.fWidth, fHeight, fTop, fLeft,
	* as well as fAdvanceX and fAdvanceY if not already set.
	*
	* TODO: fMaskFormat is set by getMetrics later; cannot be set here.
	*/
	virtual void generateMetrics(SkGlyph* glyph) = 0;

	/** Generates the contents of glyph.fImage.
	* When called, glyph.fImage will be pointing to a pre-allocated,
	* uninitialized region of memory of size glyph.computeImageSize().
	* This method may change glyph.fMaskFormat if the new image size is
	* less than or equal to the old image size.
	*
	* Because glyph.computeImageSize() will determine the size of fImage,
	* generateMetrics will be called before generateImage.
	*/
	virtual void generateImage(const SkGlyph& glyph) = 0;

	/** Sets the passed path to the glyph outline.
	* If this cannot be done the path is set to empty;
	* this is indistinguishable from a glyph with an empty path.
	* This does not set glyph.fPath.
	*
	* TODO: path is always glyph.fPath, no reason to pass separately.
	*/
	virtual void generatePath(const SkGlyph& glyph, SkPath* path) = 0;

	/** Retrieves font metrics. */
	virtual void generateFontMetrics(SkPaint::FontMetrics*) = 0;

	/** Returns the number of glyphs in the font. */
	virtual unsigned generateGlyphCount() = 0;

	/** Returns the glyph id for the given unichar.
	* If there is no 1:1 mapping from the unichar to a glyph id, returns 0.
	*/
	virtual uint16_t generateCharToGlyph(SkUnichar unichar) = 0;

	/** Returns the unichar for the given glyph id.
	* If there is no 1:1 mapping from the glyph id to a unichar, returns 0.
	* The default implementation always returns 0, indicating failure.
	*/
	virtual SkUnichar generateGlyphToChar(uint16_t glyphId);

	void forceGenerateImageFromPath() { fGenerateImageFromPath = true; }

	void forceOffGenerateImageFromPath() { fGenerateImageFromPath = false; }

	private:
	// never null
	SkAutoTUnref<SkTypeface> fTypeface;

	// optional object, which may be null
	SkPathEffect* fPathEffect;
	SkMaskFilter* fMaskFilter;
	SkRasterizer* fRasterizer;

	// if this is set, we draw the image from a path, rather than
	// calling generateImage.
	bool fGenerateImageFromPath;

	void internalGetPath(const SkGlyph& glyph, SkPath* fillPath,
	SkPath* devPath, SkMatrix* fillToDevMatrix);

	// returns the right context from our link-list for this char. If no match
	// is found it returns NULL. If a match is found then the glyphID param is
	// set to the glyphID that maps to the provided char.
	SkScalerContext* getContextFromChar(SkUnichar uni, uint16_t* glyphID);

	// SkMaskGamma::PreBlend converts linear masks to gamma correcting masks.
	protected:
	// Visible to subclasses so that generateImage can apply the pre-blend directly.
	const SkMaskGamma::PreBlend fPreBlend;
	private:
	// When there is a filter, previous steps must create a linear mask
	// and the pre-blend applied as a final step.
	const SkMaskGamma::PreBlend fPreBlendForFilter;

	friend class SkRandomScalerContext; // For debugging
	};

	#define kRec_SkDescriptorTag SkSetFourByteTag('s', 'r', 'e', 'c')
	#define kPathEffect_SkDescriptorTag SkSetFourByteTag('p', 't', 'h', 'e')
	#define kMaskFilter_SkDescriptorTag SkSetFourByteTag('m', 's', 'k', 'f')
	#define kRasterizer_SkDescriptorTag SkSetFourByteTag('r', 'a', 's', 't')

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

	enum SkAxisAlignment {
	kNone_SkAxisAlignment,
	kX_SkAxisAlignment,
	kY_SkAxisAlignment
	};

	/**
	* Return the axis (if any) that the baseline for horizontal text will land on
	* after running through the specified matrix.
	*
	* As an example, the identity matrix will return kX_SkAxisAlignment
	*/
	SkAxisAlignment SkComputeAxisAlignmentForHText(const SkMatrix& matrix);

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

	SkPaint::Hinting SkScalerContextRec::getHinting() const {
	unsigned hint = (fFlags & SkScalerContext::kHinting_Mask) >>
	SkScalerContext::kHinting_Shift;
	return static_cast<SkPaint::Hinting>(hint);
	}

	void SkScalerContextRec::setHinting(SkPaint::Hinting hinting) {
	fFlags = (fFlags & ~SkScalerContext::kHinting_Mask) \|
	(hinting << SkScalerContext::kHinting_Shift);
	}


	#endif