core/SkImageFilter.h - platform/external/chromium_org/third_party/skia/include - Git at Google

 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkImageFilter_DEFINED
 #define SkImageFilter_DEFINED

 #include "SkFlattenable.h"
 #include "SkRect.h"

 class SkBitmap;
 class SkColorFilter;
 class SkBaseDevice;
 class SkMatrix;
 struct SkIPoint;
 class SkShader;
 class GrEffectRef;
 class GrTexture;

 /**
  *  Base class for image filters. If one is installed in the paint, then
  *  all drawing occurs as usual, but it is as if the drawing happened into an
  *  offscreen (before the xfermode is applied). This offscreen bitmap will
  *  then be handed to the imagefilter, who in turn creates a new bitmap which
  *  is what will finally be drawn to the device (using the original xfermode).
  */
 class SK_API SkImageFilter : public SkFlattenable {
 public:
     SK_DECLARE_INST_COUNT(SkImageFilter)

     class CropRect {
     public:
         enum CropEdge {
             kHasLeft_CropEdge   = 0x01,
             kHasTop_CropEdge    = 0x02,
             kHasRight_CropEdge  = 0x04,
             kHasBottom_CropEdge = 0x08,
             kHasAll_CropEdge    = 0x0F,
         };
         CropRect() {}
         explicit CropRect(const SkRect& rect, uint32_t flags = kHasAll_CropEdge) : fRect(rect), fFlags(flags) {}
         uint32_t flags() const { return fFlags; }
         const SkRect& rect() const { return fRect; }
     private:
         SkRect fRect;
         uint32_t fFlags;
     };

     class Proxy {
     public:
         virtual ~Proxy() {};

         virtual SkBaseDevice* createDevice(int width, int height) = 0;
         // returns true if the proxy can handle this filter natively
         virtual bool canHandleImageFilter(SkImageFilter*) = 0;
         // returns true if the proxy handled the filter itself. if this returns
         // false then the filter's code will be called.
         virtual bool filterImage(SkImageFilter*, const SkBitmap& src,
                                  const SkMatrix& ctm,
                                  SkBitmap* result, SkIPoint* offset) = 0;
     };

     /**
      *  Request a new (result) image to be created from the src image.
      *  If the src has no pixels (isNull()) then the request just wants to
      *  receive the config and width/height of the result.
      *
      *  The matrix is the current matrix on the canvas.
      *
      *  Offset is the amount to translate the resulting image relative to the
      *  src when it is drawn.
      *
      *  If the result image cannot be created, return false, in which case both
      *  the result and offset parameters will be ignored by the caller.
      */
     bool filterImage(Proxy*, const SkBitmap& src, const SkMatrix& ctm,
                      SkBitmap* result, SkIPoint* offset);

     /**
      *  Given the src bounds of an image, this returns the bounds of the result
      *  image after the filter has been applied.
      */
     bool filterBounds(const SkIRect& src, const SkMatrix& ctm, SkIRect* dst);

     /**
      *  Returns true if the filter can be processed on the GPU.  This is most
      *  often used for multi-pass effects, where intermediate results must be
      *  rendered to textures.  For single-pass effects, use asNewEffect().
      *  The default implementation returns asNewEffect(NULL, NULL, SkMatrix::I(),
      *  SkIRect()).
      */
     virtual bool canFilterImageGPU() const;

     /**
      *  Process this image filter on the GPU.  This is most often used for
      *  multi-pass effects, where intermediate results must be rendered to
      *  textures.  For single-pass effects, use asNewEffect().  src is the
      *  source image for processing, as a texture-backed bitmap.  result is
      *  the destination bitmap, which should contain a texture-backed pixelref
      *  on success.  offset is the amount to translate the resulting image
      *  relative to the src when it is drawn. The default implementation does
      *  single-pass processing using asNewEffect().
      */
     virtual bool filterImageGPU(Proxy*, const SkBitmap& src, const SkMatrix& ctm,
                                 SkBitmap* result, SkIPoint* offset);

     /**
      *  Returns whether this image filter is a color filter and puts the color filter into the
      *  "filterPtr" parameter if it can. Does nothing otherwise.
      *  If this returns false, then the filterPtr is unchanged.
      *  If this returns true, then if filterPtr is not null, it must be set to a ref'd colorfitler
      *  (i.e. it may not be set to NULL).
      */
     virtual bool asColorFilter(SkColorFilter** filterPtr) const;

     /**
      *  Returns the number of inputs this filter will accept (some inputs can
      *  be NULL).
      */
     int countInputs() const { return fInputCount; }

     /**
      *  Returns the input filter at a given index, or NULL if no input is
      *  connected.  The indices used are filter-specific.
      */
     SkImageFilter* getInput(int i) const {
         SkASSERT(i < fInputCount);
         return fInputs[i];
     }

     /**
      *  Returns whether any edges of the crop rect have been set. The crop
      *  rect is set at construction time, and determines which pixels from the
      *  input image will be processed. The size of the crop rect should be
      *  used as the size of the destination image. The origin of this rect
      *  should be used to offset access to the input images, and should also
      *  be added to the "offset" parameter in onFilterImage and
      *  filterImageGPU(). (The latter ensures that the resulting buffer is
      *  drawn in the correct location.)
      */
     bool cropRectIsSet() const { return fCropRect.flags() != 0x0; }

     SK_DEFINE_FLATTENABLE_TYPE(SkImageFilter)

 protected:
     SkImageFilter(int inputCount, SkImageFilter** inputs, const CropRect* cropRect = NULL);

     // Convenience constructor for 1-input filters.
     explicit SkImageFilter(SkImageFilter* input, const CropRect* cropRect = NULL);

     // Convenience constructor for 2-input filters.
     SkImageFilter(SkImageFilter* input1, SkImageFilter* input2, const CropRect* cropRect = NULL);

     virtual ~SkImageFilter();

     /**
      *  Constructs a new SkImageFilter read from an SkFlattenableReadBuffer object.
      *
      *  @param inputCount    The exact number of inputs expected for this SkImageFilter object.
      *                       -1 can be used if the filter accepts any number of inputs.
      *  @param rb            SkFlattenableReadBuffer object from which the SkImageFilter is read.
      */
     explicit SkImageFilter(int inputCount, SkFlattenableReadBuffer& rb);

     virtual void flatten(SkFlattenableWriteBuffer& wb) const SK_OVERRIDE;

     // Default impl returns false
     virtual bool onFilterImage(Proxy*, const SkBitmap& src, const SkMatrix&,
                                SkBitmap* result, SkIPoint* offset);
     // Default impl copies src into dst and returns true
     virtual bool onFilterBounds(const SkIRect&, const SkMatrix&, SkIRect*);

     // Applies "matrix" to the crop rect, and sets "rect" to the intersection of
     // "rect" and the transformed crop rect. If there is no overlap, returns
     // false and leaves "rect" unchanged.
     bool applyCropRect(SkIRect* rect, const SkMatrix& matrix) const;

     /**
      *  Returns true if the filter can be expressed a single-pass
      *  GrEffect, used to process this filter on the GPU, or false if
      *  not.
      *
      *  If effect is non-NULL, a new GrEffect instance is stored
      *  in it.  The caller assumes ownership of the stage, and it is up to the
      *  caller to unref it.
      *
      *  The effect can assume its vertexCoords space maps 1-to-1 with texels
      *  in the texture.  "matrix" is a transformation to apply to filter
      *  parameters before they are used in the effect. Note that this function
      *  will be called with (NULL, NULL, SkMatrix::I()) to query for support,
      *  so returning "true" indicates support for all possible matrices.
      */
     virtual bool asNewEffect(GrEffectRef** effect,
                              GrTexture*,
                              const SkMatrix& matrix,
                              const SkIRect& bounds) const;

 private:
     typedef SkFlattenable INHERITED;
     int fInputCount;
     SkImageFilter** fInputs;
     CropRect fCropRect;
 };

 #endif
	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkImageFilter_DEFINED
	#define SkImageFilter_DEFINED

	#include "SkFlattenable.h"
	#include "SkRect.h"

	class SkBitmap;
	class SkColorFilter;
	class SkBaseDevice;
	class SkMatrix;
	struct SkIPoint;
	class SkShader;
	class GrEffectRef;
	class GrTexture;

	/**
	* Base class for image filters. If one is installed in the paint, then
	* all drawing occurs as usual, but it is as if the drawing happened into an
	* offscreen (before the xfermode is applied). This offscreen bitmap will
	* then be handed to the imagefilter, who in turn creates a new bitmap which
	* is what will finally be drawn to the device (using the original xfermode).
	*/
	class SK_API SkImageFilter : public SkFlattenable {
	public:
	SK_DECLARE_INST_COUNT(SkImageFilter)

	class CropRect {
	public:
	enum CropEdge {
	kHasLeft_CropEdge = 0x01,
	kHasTop_CropEdge = 0x02,
	kHasRight_CropEdge = 0x04,
	kHasBottom_CropEdge = 0x08,
	kHasAll_CropEdge = 0x0F,
	};
	CropRect() {}
	explicit CropRect(const SkRect& rect, uint32_t flags = kHasAll_CropEdge) : fRect(rect), fFlags(flags) {}
	uint32_t flags() const { return fFlags; }
	const SkRect& rect() const { return fRect; }
	private:
	SkRect fRect;
	uint32_t fFlags;
	};

	class Proxy {
	public:
	virtual ~Proxy() {};

	virtual SkBaseDevice* createDevice(int width, int height) = 0;
	// returns true if the proxy can handle this filter natively
	virtual bool canHandleImageFilter(SkImageFilter*) = 0;
	// returns true if the proxy handled the filter itself. if this returns
	// false then the filter's code will be called.
	virtual bool filterImage(SkImageFilter*, const SkBitmap& src,
	const SkMatrix& ctm,
	SkBitmap* result, SkIPoint* offset) = 0;
	};

	/**
	* Request a new (result) image to be created from the src image.
	* If the src has no pixels (isNull()) then the request just wants to
	* receive the config and width/height of the result.
	*
	* The matrix is the current matrix on the canvas.
	*
	* Offset is the amount to translate the resulting image relative to the
	* src when it is drawn.
	*
	* If the result image cannot be created, return false, in which case both
	* the result and offset parameters will be ignored by the caller.
	*/
	bool filterImage(Proxy*, const SkBitmap& src, const SkMatrix& ctm,
	SkBitmap* result, SkIPoint* offset);

	/**
	* Given the src bounds of an image, this returns the bounds of the result
	* image after the filter has been applied.
	*/
	bool filterBounds(const SkIRect& src, const SkMatrix& ctm, SkIRect* dst);

	/**
	* Returns true if the filter can be processed on the GPU. This is most
	* often used for multi-pass effects, where intermediate results must be
	* rendered to textures. For single-pass effects, use asNewEffect().
	* The default implementation returns asNewEffect(NULL, NULL, SkMatrix::I(),
	* SkIRect()).
	*/
	virtual bool canFilterImageGPU() const;

	/**
	* Process this image filter on the GPU. This is most often used for
	* multi-pass effects, where intermediate results must be rendered to
	* textures. For single-pass effects, use asNewEffect(). src is the
	* source image for processing, as a texture-backed bitmap. result is
	* the destination bitmap, which should contain a texture-backed pixelref
	* on success. offset is the amount to translate the resulting image
	* relative to the src when it is drawn. The default implementation does
	* single-pass processing using asNewEffect().
	*/
	virtual bool filterImageGPU(Proxy*, const SkBitmap& src, const SkMatrix& ctm,
	SkBitmap* result, SkIPoint* offset);

	/**
	* Returns whether this image filter is a color filter and puts the color filter into the
	* "filterPtr" parameter if it can. Does nothing otherwise.
	* If this returns false, then the filterPtr is unchanged.
	* If this returns true, then if filterPtr is not null, it must be set to a ref'd colorfitler
	* (i.e. it may not be set to NULL).
	*/
	virtual bool asColorFilter(SkColorFilter** filterPtr) const;

	/**
	* Returns the number of inputs this filter will accept (some inputs can
	* be NULL).
	*/
	int countInputs() const { return fInputCount; }

	/**
	* Returns the input filter at a given index, or NULL if no input is
	* connected. The indices used are filter-specific.
	*/
	SkImageFilter* getInput(int i) const {
	SkASSERT(i < fInputCount);
	return fInputs[i];
	}

	/**
	* Returns whether any edges of the crop rect have been set. The crop
	* rect is set at construction time, and determines which pixels from the
	* input image will be processed. The size of the crop rect should be
	* used as the size of the destination image. The origin of this rect
	* should be used to offset access to the input images, and should also
	* be added to the "offset" parameter in onFilterImage and
	* filterImageGPU(). (The latter ensures that the resulting buffer is
	* drawn in the correct location.)
	*/
	bool cropRectIsSet() const { return fCropRect.flags() != 0x0; }

	SK_DEFINE_FLATTENABLE_TYPE(SkImageFilter)

	protected:
	SkImageFilter(int inputCount, SkImageFilter** inputs, const CropRect* cropRect = NULL);

	// Convenience constructor for 1-input filters.
	explicit SkImageFilter(SkImageFilter* input, const CropRect* cropRect = NULL);

	// Convenience constructor for 2-input filters.
	SkImageFilter(SkImageFilter* input1, SkImageFilter* input2, const CropRect* cropRect = NULL);

	virtual ~SkImageFilter();

	/**
	* Constructs a new SkImageFilter read from an SkFlattenableReadBuffer object.
	*
	* @param inputCount The exact number of inputs expected for this SkImageFilter object.
	* -1 can be used if the filter accepts any number of inputs.
	* @param rb SkFlattenableReadBuffer object from which the SkImageFilter is read.
	*/
	explicit SkImageFilter(int inputCount, SkFlattenableReadBuffer& rb);

	virtual void flatten(SkFlattenableWriteBuffer& wb) const SK_OVERRIDE;

	// Default impl returns false
	virtual bool onFilterImage(Proxy*, const SkBitmap& src, const SkMatrix&,
	SkBitmap* result, SkIPoint* offset);
	// Default impl copies src into dst and returns true
	virtual bool onFilterBounds(const SkIRect&, const SkMatrix&, SkIRect*);

	// Applies "matrix" to the crop rect, and sets "rect" to the intersection of
	// "rect" and the transformed crop rect. If there is no overlap, returns
	// false and leaves "rect" unchanged.
	bool applyCropRect(SkIRect* rect, const SkMatrix& matrix) const;

	/**
	* Returns true if the filter can be expressed a single-pass
	* GrEffect, used to process this filter on the GPU, or false if
	* not.
	*
	* If effect is non-NULL, a new GrEffect instance is stored
	* in it. The caller assumes ownership of the stage, and it is up to the
	* caller to unref it.
	*
	* The effect can assume its vertexCoords space maps 1-to-1 with texels
	* in the texture. "matrix" is a transformation to apply to filter
	* parameters before they are used in the effect. Note that this function
	* will be called with (NULL, NULL, SkMatrix::I()) to query for support,
	* so returning "true" indicates support for all possible matrices.
	*/
	virtual bool asNewEffect(GrEffectRef** effect,
	GrTexture*,
	const SkMatrix& matrix,
	const SkIRect& bounds) const;

	private:
	typedef SkFlattenable INHERITED;
	int fInputCount;
	SkImageFilter** fInputs;
	CropRect fCropRect;
	};

	#endif