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/*
* 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 SkShader_DEFINED
#define SkShader_DEFINED
#include "SkBitmap.h"
#include "SkFlattenable.h"
#include "SkMask.h"
#include "SkMatrix.h"
#include "SkPaint.h"
class SkPath;
class GrContext;
class GrCustomStage;
class GrSamplerState;
/** \class SkShader
*
* Shaders specify the source color(s) for what is being drawn. If a paint
* has no shader, then the paint's color is used. If the paint has a
* shader, then the shader's color(s) are use instead, but they are
* modulated by the paint's alpha. This makes it easy to create a shader
* once (e.g. bitmap tiling or gradient) and then change its transparency
* w/o having to modify the original shader... only the paint's alpha needs
* to be modified.
*/
class SK_API SkShader : public SkFlattenable {
public:
SK_DECLARE_INST_COUNT(SkShader)
SkShader();
virtual ~SkShader();
/**
* Return true if the shader has a non-identity local matrix.
* @param localM Optional: If not null, return the shader's local matrix
* @return true if the shader has a non-identity local matrix.
*/
bool getLocalMatrix(SkMatrix* localM) const;
/**
* Set the shader's local matrix.
* @param localM The shader's new local matrix.
*/
void setLocalMatrix(const SkMatrix& localM);
/**
* Reset the shader's local matrix to identity.
*/
void resetLocalMatrix();
enum TileMode {
/** replicate the edge color if the shader draws outside of its
* original bounds
*/
kClamp_TileMode,
/** repeat the shader's image horizontally and vertically */
kRepeat_TileMode,
/** repeat the shader's image horizontally and vertically, alternating
* mirror images so that adjacent images always seam
*/
kMirror_TileMode,
#if 0
/** only draw within the original domain, return 0 everywhere else */
kDecal_TileMode,
#endif
kTileModeCount
};
// override these in your subclass
enum Flags {
//!< set if all of the colors will be opaque
kOpaqueAlpha_Flag = 0x01,
//! set if this shader's shadeSpan16() method can be called
kHasSpan16_Flag = 0x02,
/** Set this bit if the shader's native data type is instrinsically 16
bit, meaning that calling the 32bit shadeSpan() entry point will
mean the the impl has to up-sample 16bit data into 32bit. Used as a
a means of clearing a dither request if the it will have no effect
*/
kIntrinsicly16_Flag = 0x04,
/** set (after setContext) if the spans only vary in X (const in Y).
e.g. an Nx1 bitmap that is being tiled in Y, or a linear-gradient
that varies from left-to-right. This flag specifies this for
shadeSpan().
*/
kConstInY32_Flag = 0x08,
/** same as kConstInY32_Flag, but is set if this is true for shadeSpan16
which may not always be the case, since shadeSpan16 may be
predithered, which would mean it was not const in Y, even though
the 32bit shadeSpan() would be const.
*/
kConstInY16_Flag = 0x10
};
/**
* Called sometimes before drawing with this shader. Return the type of
* alpha your shader will return. The default implementation returns 0.
* Your subclass should override if it can (even sometimes) report a
* non-zero value, since that will enable various blitters to perform
* faster.
*/
virtual uint32_t getFlags() { return 0; }
/**
* Returns true if the shader is guaranteed to produce only opaque
* colors, subject to the SkPaint using the shader to apply an opaque
* alpha value. Subclasses should override this to allow some
* optimizations. isOpaque() can be called at any time, unlike getFlags,
* which only works properly when the context is set.
*/
virtual bool isOpaque() const { return false; }
/**
* Return the alpha associated with the data returned by shadeSpan16(). If
* kHasSpan16_Flag is not set, this value is meaningless.
*/
virtual uint8_t getSpan16Alpha() const { return fPaintAlpha; }
/**
* Called once before drawing, with the current paint and device matrix.
* Return true if your shader supports these parameters, or false if not.
* If false is returned, nothing will be drawn.
*/
virtual bool setContext(const SkBitmap& device, const SkPaint& paint,
const SkMatrix& matrix);
/**
* Called for each span of the object being drawn. Your subclass should
* set the appropriate colors (with premultiplied alpha) that correspond
* to the specified device coordinates.
*/
virtual void shadeSpan(int x, int y, SkPMColor[], int count) = 0;
/**
* Called only for 16bit devices when getFlags() returns
* kOpaqueAlphaFlag | kHasSpan16_Flag
*/
virtual void shadeSpan16(int x, int y, uint16_t[], int count);
/**
* Similar to shadeSpan, but only returns the alpha-channel for a span.
* The default implementation calls shadeSpan() and then extracts the alpha
* values from the returned colors.
*/
virtual void shadeSpanAlpha(int x, int y, uint8_t alpha[], int count);
/**
* Helper function that returns true if this shader's shadeSpan16() method
* can be called.
*/
bool canCallShadeSpan16() {
return SkShader::CanCallShadeSpan16(this->getFlags());
}
/**
* Helper to check the flags to know if it is legal to call shadeSpan16()
*/
static bool CanCallShadeSpan16(uint32_t flags) {
return (flags & kHasSpan16_Flag) != 0;
}
/**
* Called before a session using the shader begins. Some shaders override
* this to defer some of their work (like calling bitmap.lockPixels()).
* Must be balanced by a call to endSession.
*/
virtual void beginSession();
virtual void endSession();
/**
Gives method bitmap should be read to implement a shader.
Also determines number and interpretation of "extra" parameters returned
by asABitmap
*/
enum BitmapType {
kNone_BitmapType, //<! Shader is not represented as a bitmap
kDefault_BitmapType,//<! Access bitmap using local coords transformed
// by matrix. No extras
kRadial_BitmapType, //<! Access bitmap by transforming local coordinates
// by the matrix and taking the distance of result
// from (0,0) as bitmap column. Bitmap is 1 pixel
// tall. No extras
kSweep_BitmapType, //<! Access bitmap by transforming local coordinates
// by the matrix and taking the angle of result
// to (0,0) as bitmap x coord, where angle = 0 is
// bitmap left edge of bitmap = 2pi is the
// right edge. Bitmap is 1 pixel tall. No extras
kTwoPointRadial_BitmapType,
//<! Matrix transforms to space where (0,0) is
// the center of the starting circle. The second
// circle will be centered (x, 0) where x may be
// 0. The post-matrix space is normalized such
// that 1 is the second radius - first radius.
// Three extra parameters are returned:
// 0: x-offset of second circle center
// to first.
// 1: radius of first circle in post-matrix
// space
// 2: the second radius minus the first radius
// in pre-transformed space.
kTwoPointConical_BitmapType,
//<! Matrix transforms to space where (0,0) is
// the center of the starting circle. The second
// circle will be centered (x, 0) where x may be
// 0.
// Three extra parameters are returned:
// 0: x-offset of second circle center
// to first.
// 1: radius of first circle
// 2: the second radius minus the first radius
kLinear_BitmapType, //<! Access bitmap using local coords transformed
// by matrix. No extras
kLast_BitmapType = kLinear_BitmapType
};
/** Optional methods for shaders that can pretend to be a bitmap/texture
to play along with opengl. Default just returns kNone_BitmapType and
ignores the out parameters.
@param outTexture if non-NULL will be the bitmap representing the shader
after return.
@param outMatrix if non-NULL will be the matrix to apply to vertices
to access the bitmap after return.
@param xy if non-NULL will be the tile modes that should be
used to access the bitmap after return.
@param twoPointRadialParams Two extra return values needed for two point
radial bitmaps. The first is the x-offset of
the second point and the second is the radius
about the first point.
*/
virtual BitmapType asABitmap(SkBitmap* outTexture, SkMatrix* outMatrix,
TileMode xy[2]) const;
/**
* If the shader subclass can be represented as a gradient, asAGradient
* returns the matching GradientType enum (or kNone_GradientType if it
* cannot). Also, if info is not null, asAGradient populates info with
* the relevant (see below) parameters for the gradient. fColorCount
* is both an input and output parameter. On input, it indicates how
* many entries in fColors and fColorOffsets can be used, if they are
* non-NULL. After asAGradient has run, fColorCount indicates how
* many color-offset pairs there are in the gradient. If there is
* insufficient space to store all of the color-offset pairs, fColors
* and fColorOffsets will not be altered. fColorOffsets specifies
* where on the range of 0 to 1 to transition to the given color.
* The meaning of fPoint and fRadius is dependant on the type of gradient.
*
* None:
* info is ignored.
* Color:
* fColorOffsets[0] is meaningless.
* Linear:
* fPoint[0] and fPoint[1] are the end-points of the gradient
* Radial:
* fPoint[0] and fRadius[0] are the center and radius
* Radial2:
* fPoint[0] and fRadius[0] are the center and radius of the 1st circle
* fPoint[1] and fRadius[1] are the center and radius of the 2nd circle
* Sweep:
* fPoint[0] is the center of the sweep.
*/
enum GradientType {
kNone_GradientType,
kColor_GradientType,
kLinear_GradientType,
kRadial_GradientType,
kRadial2_GradientType,
kSweep_GradientType,
kConical_GradientType,
kLast_GradientType = kConical_GradientType
};
struct GradientInfo {
int fColorCount; //!< In-out parameter, specifies passed size
// of fColors/fColorOffsets on input, and
// actual number of colors/offsets on
// output.
SkColor* fColors; //!< The colors in the gradient.
SkScalar* fColorOffsets; //!< The unit offset for color transitions.
SkPoint fPoint[2]; //!< Type specific, see above.
SkScalar fRadius[2]; //!< Type specific, see above.
TileMode fTileMode; //!< The tile mode used.
};
virtual GradientType asAGradient(GradientInfo* info) const;
/**
* If the shader subclass has a GrCustomStage implementation, this returns
* a new custom stage (the caller assumes ownership, and will need to
* unref it). A GrContext pointer is required since custom stages may
* need to create textures. The sampler parameter is necessary to set
* up matrix/tile modes/etc, and will eventually be removed.
*/
virtual GrCustomStage* asNewCustomStage(GrContext* context,
GrSamplerState* sampler) const;
//////////////////////////////////////////////////////////////////////////
// Factory methods for stock shaders
/** Call this to create a new shader that will draw with the specified bitmap.
*
* If the bitmap cannot be used (e.g. has no pixels, or its dimensions
* exceed implementation limits (currently at 64K - 1)) then SkEmptyShader
* may be returned.
*
* @param src The bitmap to use inside the shader
* @param tmx The tiling mode to use when sampling the bitmap in the x-direction.
* @param tmy The tiling mode to use when sampling the bitmap in the y-direction.
* @return Returns a new shader object. Note: this function never returns null.
*/
static SkShader* CreateBitmapShader(const SkBitmap& src,
TileMode tmx, TileMode tmy);
protected:
enum MatrixClass {
kLinear_MatrixClass, // no perspective
kFixedStepInX_MatrixClass, // fast perspective, need to call fixedStepInX() each scanline
kPerspective_MatrixClass // slow perspective, need to mappoints each pixel
};
static MatrixClass ComputeMatrixClass(const SkMatrix&);
// These can be called by your subclass after setContext() has been called
uint8_t getPaintAlpha() const { return fPaintAlpha; }
SkBitmap::Config getDeviceConfig() const { return (SkBitmap::Config)fDeviceConfig; }
const SkMatrix& getTotalInverse() const { return fTotalInverse; }
MatrixClass getInverseClass() const { return (MatrixClass)fTotalInverseClass; }
SkShader(SkFlattenableReadBuffer& );
virtual void flatten(SkFlattenableWriteBuffer&) const SK_OVERRIDE;
private:
SkMatrix* fLocalMatrix;
SkMatrix fTotalInverse;
uint8_t fPaintAlpha;
uint8_t fDeviceConfig;
uint8_t fTotalInverseClass;
SkDEBUGCODE(SkBool8 fInSession;)
static SkShader* CreateBitmapShader(const SkBitmap& src,
TileMode, TileMode,
void* storage, size_t storageSize);
friend class SkAutoBitmapShaderInstall;
typedef SkFlattenable INHERITED;
};
#endif
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