src/gpu/GrPathRendering.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 GrPathRendering_DEFINED
 #define GrPathRendering_DEFINED

 #include "SkPath.h"
 #include "GrGpu.h"
 #include "GrPathRange.h"
 #include "GrPipeline.h"

 class SkDescriptor;
 class SkTypeface;
 class GrPath;
 class GrStencilSettings;
 class GrStyle;

 /**
  * Abstract class wrapping HW path rendering API.
  *
  * The subclasses of this class use the possible HW API to render paths (as opposed to path
  * rendering implemented in Skia on top of a "3d" HW API).
  * The subclasses hold the global state needed to render paths, including shadow of the global HW
  * API state. Similar to GrGpu.
  *
  * It is expected that the lifetimes of GrGpuXX and GrXXPathRendering are the same. The call context
  * interface (eg.  * the concrete instance of GrGpu subclass) should be provided to the instance
  * during construction.
  */
 class GrPathRendering {
 public:
     virtual ~GrPathRendering() { }

     typedef GrPathRange::PathIndexType PathIndexType;

     enum PathTransformType {
         kNone_PathTransformType,        //!< []
         kTranslateX_PathTransformType,  //!< [kMTransX]
         kTranslateY_PathTransformType,  //!< [kMTransY]
         kTranslate_PathTransformType,   //!< [kMTransX, kMTransY]
         kAffine_PathTransformType,      //!< [kMScaleX, kMSkewX, kMTransX, kMSkewY, kMScaleY, kMTransY]

         kLast_PathTransformType = kAffine_PathTransformType
     };

     static inline int PathTransformSize(PathTransformType type) {
         switch (type) {
             case kNone_PathTransformType:
                 return 0;
             case kTranslateX_PathTransformType:
             case kTranslateY_PathTransformType:
                 return 1;
             case kTranslate_PathTransformType:
                 return 2;
             case kAffine_PathTransformType:
                 return 6;

             default:
                 SkFAIL("Unknown path transform type");
                 return 0;
         }
     }

     // No native support for inverse at this time
     enum FillType {
         /** Specifies that "inside" is computed by a non-zero sum of signed
             edge crossings
         */
         kWinding_FillType,
         /** Specifies that "inside" is computed by an odd number of edge
             crossings
         */
         kEvenOdd_FillType,
     };

     static const GrUserStencilSettings& GetStencilPassSettings(FillType);

     /**
      * Creates a new gpu path, based on the specified path and stroke and returns it.
      * The caller owns a ref on the returned path which must be balanced by a call to unref.
      *
      * @param SkPath    the geometry.
      * @param GrStyle   the style applied to the path. Styles with non-dash path effects are not
      *                  allowed.
      * @return a new GPU path object.
      */
     virtual GrPath* createPath(const SkPath&, const GrStyle&) = 0;

     /**
      * Creates a range of gpu paths with a common style. The caller owns a ref on the
      * returned path range which must be balanced by a call to unref.
      *
      * @param PathGenerator class that generates SkPath objects for each path in the range.
      * @param GrStyle   the common style applied to each path in the range. Styles with non-dash
      *                  path effects are not allowed.
      * @return a new path range.
      */
     virtual GrPathRange* createPathRange(GrPathRange::PathGenerator*, const GrStyle&) = 0;

     /**
      * Creates a range of glyph paths, indexed by glyph id. The glyphs will have an
      * inverted y-direction in order to match the raw font path data. The caller owns
      * a ref on the returned path range which must be balanced by a call to unref.
      *
      * @param SkTypeface   Typeface that defines the glyphs.
      *                     If null, the default typeface will be used.
      *
      * @param SkDescriptor Additional font configuration that specifies the font's size,
      *                     stroke, and other flags. This will generally come from an
      *                     SkGlyphCache.
      *
      *                     It is recommended to leave this value null when possible, in
      *                     which case the glyphs will be loaded directly from the font's
      *                     raw path data and sized at SkPaint::kCanonicalTextSizeForPaths.
      *                     This will result in less memory usage and more efficient paths.
      *
      *                     If non-null, the glyph paths will match the font descriptor,
      *                     including with the stroke information baked directly into
      *                     the outlines.
      *
      * @param GrStyle      Common style that the GPU will apply to every path. Note that
      *                     if the glyph outlines contain baked-in styles from the font
      *                     descriptor, the GPU style will be applied on top of those
      *                     outlines.
      *
      * @return a new path range populated with glyphs.
      */
     GrPathRange* createGlyphs(const SkTypeface*, const SkScalerContextEffects&,
                               const SkDescriptor*, const GrStyle&);

     /** None of these params are optional, pointers used just to avoid making copies. */
     struct StencilPathArgs {
         StencilPathArgs(bool useHWAA,
                         GrRenderTarget* renderTarget,
                         const SkMatrix* viewMatrix,
                         const GrScissorState* scissor,
                         const GrStencilSettings* stencil)
             : fUseHWAA(useHWAA)
             , fRenderTarget(renderTarget)
             , fViewMatrix(viewMatrix)
             , fScissor(scissor)
             , fStencil(stencil) {
         }
         bool fUseHWAA;
         GrRenderTarget* fRenderTarget;
         const SkMatrix* fViewMatrix;
         const GrScissorState* fScissor;
         const GrStencilSettings* fStencil;
     };

     void stencilPath(const StencilPathArgs& args, const GrPath* path) {
         fGpu->handleDirtyContext();
         this->onStencilPath(args, path);
     }

     void drawPath(const GrPipeline& pipeline,
                   const GrPrimitiveProcessor& primProc,
                   const GrStencilSettings& stencilPassSettings, // Cover pass settings in pipeline.
                   const GrPath* path) {
         fGpu->handleDirtyContext();
         if (GrXferBarrierType barrierType = pipeline.xferBarrierType(*fGpu->caps())) {
             fGpu->xferBarrier(pipeline.getRenderTarget(), barrierType);
         }
         this->onDrawPath(pipeline, primProc, stencilPassSettings, path);
     }

     void drawPaths(const GrPipeline& pipeline,
                    const GrPrimitiveProcessor& primProc,
                    const GrStencilSettings& stencilPassSettings, // Cover pass settings in pipeline.
                    const GrPathRange* pathRange,
                    const void* indices,
                    PathIndexType indexType,
                    const float transformValues[],
                    PathTransformType transformType,
                    int count) {
         fGpu->handleDirtyContext();
         if (GrXferBarrierType barrierType = pipeline.xferBarrierType(*fGpu->caps())) {
             fGpu->xferBarrier(pipeline.getRenderTarget(), barrierType);
         }
 #ifdef SK_DEBUG
         pathRange->assertPathsLoaded(indices, indexType, count);
 #endif
         this->onDrawPaths(pipeline, primProc, stencilPassSettings, pathRange, indices, indexType,
                           transformValues, transformType, count);
     }

 protected:
     GrPathRendering(GrGpu* gpu)
         : fGpu(gpu) {
     }
     virtual void onStencilPath(const StencilPathArgs&, const GrPath*) = 0;
     virtual void onDrawPath(const GrPipeline&,
                             const GrPrimitiveProcessor&,
                             const GrStencilSettings&,
                             const GrPath*) = 0;
     virtual void onDrawPaths(const GrPipeline&,
                              const GrPrimitiveProcessor&,
                              const GrStencilSettings&,
                              const GrPathRange*,
                              const void* indices,
                              PathIndexType,
                              const float transformValues[],
                              PathTransformType,
                              int count) = 0;

     GrGpu* fGpu;
 private:
     GrPathRendering& operator=(const GrPathRendering&);
 };

 #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 GrPathRendering_DEFINED
	#define GrPathRendering_DEFINED

	#include "SkPath.h"
	#include "GrGpu.h"
	#include "GrPathRange.h"
	#include "GrPipeline.h"

	class SkDescriptor;
	class SkTypeface;
	class GrPath;
	class GrStencilSettings;
	class GrStyle;

	/**
	* Abstract class wrapping HW path rendering API.
	*
	* The subclasses of this class use the possible HW API to render paths (as opposed to path
	* rendering implemented in Skia on top of a "3d" HW API).
	* The subclasses hold the global state needed to render paths, including shadow of the global HW
	* API state. Similar to GrGpu.
	*
	* It is expected that the lifetimes of GrGpuXX and GrXXPathRendering are the same. The call context
	* interface (eg. * the concrete instance of GrGpu subclass) should be provided to the instance
	* during construction.
	*/
	class GrPathRendering {
	public:
	virtual ~GrPathRendering() { }

	typedef GrPathRange::PathIndexType PathIndexType;

	enum PathTransformType {
	kNone_PathTransformType, //!< []
	kTranslateX_PathTransformType, //!< [kMTransX]
	kTranslateY_PathTransformType, //!< [kMTransY]
	kTranslate_PathTransformType, //!< [kMTransX, kMTransY]
	kAffine_PathTransformType, //!< [kMScaleX, kMSkewX, kMTransX, kMSkewY, kMScaleY, kMTransY]

	kLast_PathTransformType = kAffine_PathTransformType
	};

	static inline int PathTransformSize(PathTransformType type) {
	switch (type) {
	case kNone_PathTransformType:
	return 0;
	case kTranslateX_PathTransformType:
	case kTranslateY_PathTransformType:
	return 1;
	case kTranslate_PathTransformType:
	return 2;
	case kAffine_PathTransformType:
	return 6;

	default:
	SkFAIL("Unknown path transform type");
	return 0;
	}
	}

	// No native support for inverse at this time
	enum FillType {
	/** Specifies that "inside" is computed by a non-zero sum of signed
	edge crossings
	*/
	kWinding_FillType,
	/** Specifies that "inside" is computed by an odd number of edge
	crossings
	*/
	kEvenOdd_FillType,
	};

	static const GrUserStencilSettings& GetStencilPassSettings(FillType);

	/**
	* Creates a new gpu path, based on the specified path and stroke and returns it.
	* The caller owns a ref on the returned path which must be balanced by a call to unref.
	*
	* @param SkPath the geometry.
	* @param GrStyle the style applied to the path. Styles with non-dash path effects are not
	* allowed.
	* @return a new GPU path object.
	*/
	virtual GrPath* createPath(const SkPath&, const GrStyle&) = 0;

	/**
	* Creates a range of gpu paths with a common style. The caller owns a ref on the
	* returned path range which must be balanced by a call to unref.
	*
	* @param PathGenerator class that generates SkPath objects for each path in the range.
	* @param GrStyle the common style applied to each path in the range. Styles with non-dash
	* path effects are not allowed.
	* @return a new path range.
	*/
	virtual GrPathRange* createPathRange(GrPathRange::PathGenerator*, const GrStyle&) = 0;

	/**
	* Creates a range of glyph paths, indexed by glyph id. The glyphs will have an
	* inverted y-direction in order to match the raw font path data. The caller owns
	* a ref on the returned path range which must be balanced by a call to unref.
	*
	* @param SkTypeface Typeface that defines the glyphs.
	* If null, the default typeface will be used.
	*
	* @param SkDescriptor Additional font configuration that specifies the font's size,
	* stroke, and other flags. This will generally come from an
	* SkGlyphCache.
	*
	* It is recommended to leave this value null when possible, in
	* which case the glyphs will be loaded directly from the font's
	* raw path data and sized at SkPaint::kCanonicalTextSizeForPaths.
	* This will result in less memory usage and more efficient paths.
	*
	* If non-null, the glyph paths will match the font descriptor,
	* including with the stroke information baked directly into
	* the outlines.
	*
	* @param GrStyle Common style that the GPU will apply to every path. Note that
	* if the glyph outlines contain baked-in styles from the font
	* descriptor, the GPU style will be applied on top of those
	* outlines.
	*
	* @return a new path range populated with glyphs.
	*/
	GrPathRange* createGlyphs(const SkTypeface*, const SkScalerContextEffects&,
	const SkDescriptor*, const GrStyle&);

	/** None of these params are optional, pointers used just to avoid making copies. */
	struct StencilPathArgs {
	StencilPathArgs(bool useHWAA,
	GrRenderTarget* renderTarget,
	const SkMatrix* viewMatrix,
	const GrScissorState* scissor,
	const GrStencilSettings* stencil)
	: fUseHWAA(useHWAA)
	, fRenderTarget(renderTarget)
	, fViewMatrix(viewMatrix)
	, fScissor(scissor)
	, fStencil(stencil) {
	}
	bool fUseHWAA;
	GrRenderTarget* fRenderTarget;
	const SkMatrix* fViewMatrix;
	const GrScissorState* fScissor;
	const GrStencilSettings* fStencil;
	};

	void stencilPath(const StencilPathArgs& args, const GrPath* path) {
	fGpu->handleDirtyContext();
	this->onStencilPath(args, path);
	}

	void drawPath(const GrPipeline& pipeline,
	const GrPrimitiveProcessor& primProc,
	const GrStencilSettings& stencilPassSettings, // Cover pass settings in pipeline.
	const GrPath* path) {
	fGpu->handleDirtyContext();
	if (GrXferBarrierType barrierType = pipeline.xferBarrierType(*fGpu->caps())) {
	fGpu->xferBarrier(pipeline.getRenderTarget(), barrierType);
	}
	this->onDrawPath(pipeline, primProc, stencilPassSettings, path);
	}

	void drawPaths(const GrPipeline& pipeline,
	const GrPrimitiveProcessor& primProc,
	const GrStencilSettings& stencilPassSettings, // Cover pass settings in pipeline.
	const GrPathRange* pathRange,
	const void* indices,
	PathIndexType indexType,
	const float transformValues[],
	PathTransformType transformType,
	int count) {
	fGpu->handleDirtyContext();
	if (GrXferBarrierType barrierType = pipeline.xferBarrierType(*fGpu->caps())) {
	fGpu->xferBarrier(pipeline.getRenderTarget(), barrierType);
	}
	#ifdef SK_DEBUG
	pathRange->assertPathsLoaded(indices, indexType, count);
	#endif
	this->onDrawPaths(pipeline, primProc, stencilPassSettings, pathRange, indices, indexType,
	transformValues, transformType, count);
	}

	protected:
	GrPathRendering(GrGpu* gpu)
	: fGpu(gpu) {
	}
	virtual void onStencilPath(const StencilPathArgs&, const GrPath*) = 0;
	virtual void onDrawPath(const GrPipeline&,
	const GrPrimitiveProcessor&,
	const GrStencilSettings&,
	const GrPath*) = 0;
	virtual void onDrawPaths(const GrPipeline&,
	const GrPrimitiveProcessor&,
	const GrStencilSettings&,
	const GrPathRange*,
	const void* indices,
	PathIndexType,
	const float transformValues[],
	PathTransformType,
	int count) = 0;

	GrGpu* fGpu;
	private:
	GrPathRendering& operator=(const GrPathRendering&);
	};

	#endif