/* * 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 "SkImageInfo.h" #include "SkMask.h" #include "SkMatrix.h" #include "SkPaint.h" #include "../gpu/GrColor.h" class SkColorFilter; class SkColorSpace; class SkPath; class SkPicture; class SkXfermode; class GrContext; class GrFragmentProcessor; /** \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: SkShader(const SkMatrix* localMatrix = NULL); virtual ~SkShader(); /** * Returns the local matrix. * * FIXME: This can be incorrect for a Shader with its own local matrix * that is also wrapped via CreateLocalMatrixShader. */ const SkMatrix& getLocalMatrix() const { return fLocalMatrix; } 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 }; enum { kTileModeCount = kMirror_TileMode + 1 }; // override these in your subclass enum Flags { //!< set if all of the colors will be opaque kOpaqueAlpha_Flag = 1 << 0, /** set 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 = 1 << 1, /** hint for the blitter that 4f is the preferred shading mode. */ kPrefers4f_Flag = 1 << 2, }; /** * 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. */ virtual bool isOpaque() const { return false; } /** * ContextRec acts as a parameter bundle for creating Contexts. */ struct ContextRec { enum DstType { kPMColor_DstType, // clients prefer shading into PMColor dest kPM4f_DstType, // clients prefer shading into PM4f dest }; ContextRec(const SkPaint& paint, const SkMatrix& matrix, const SkMatrix* localM, DstType dstType) : fPaint(&paint) , fMatrix(&matrix) , fLocalMatrix(localM) , fPreferredDstType(dstType) {} const SkPaint* fPaint; // the current paint associated with the draw const SkMatrix* fMatrix; // the current matrix in the canvas const SkMatrix* fLocalMatrix; // optional local matrix const DstType fPreferredDstType; // the "natural" client dest type }; class Context : public ::SkNoncopyable { public: Context(const SkShader& shader, const ContextRec&); virtual ~Context(); /** * 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() const { return 0; } /** * 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; virtual void shadeSpan4f(int x, int y, SkPM4f[], int count); struct BlitState; typedef void (*BlitBW)(BlitState*, int x, int y, const SkPixmap&, int count); typedef void (*BlitAA)(BlitState*, int x, int y, const SkPixmap&, int count, const SkAlpha[]); struct BlitState { // inputs Context* fCtx; SkXfermode* fXfer; // outputs enum { N = 2 }; void* fStorage[N]; BlitBW fBlitBW; BlitAA fBlitAA; }; // Returns true if one or more of the blitprocs are set in the BlitState bool chooseBlitProcs(const SkImageInfo& info, BlitState* state) { state->fBlitBW = nullptr; state->fBlitAA = nullptr; if (this->onChooseBlitProcs(info, state)) { SkASSERT(state->fBlitBW || state->fBlitAA); return true; } return false; } /** * The const void* ctx is only const because all the implementations are const. * This can be changed to non-const if a new shade proc needs to change the ctx. */ typedef void (*ShadeProc)(const void* ctx, int x, int y, SkPMColor[], int count); virtual ShadeProc asAShadeProc(void** ctx); /** * 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); // Notification from blitter::blitMask in case we need to see the non-alpha channels virtual void set3DMask(const SkMask*) {} protected: // Reference to shader, so we don't have to dupe information. const SkShader& fShader; 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&); uint8_t getPaintAlpha() const { return fPaintAlpha; } const SkMatrix& getTotalInverse() const { return fTotalInverse; } MatrixClass getInverseClass() const { return (MatrixClass)fTotalInverseClass; } const SkMatrix& getCTM() const { return fCTM; } virtual bool onChooseBlitProcs(const SkImageInfo&, BlitState*) { return false; } private: SkMatrix fCTM; SkMatrix fTotalInverse; uint8_t fPaintAlpha; uint8_t fTotalInverseClass; typedef SkNoncopyable INHERITED; }; /** * Create the actual object that does the shading. * Size of storage must be >= contextSize. */ Context* createContext(const ContextRec&, void* storage) const; /** * Return the size of a Context returned by createContext. */ size_t contextSize(const ContextRec&) const; /** * Returns true if this shader is just a bitmap, and if not null, returns the bitmap, * localMatrix, and tilemodes. If this is not a bitmap, returns false and ignores the * out-parameters. */ bool isABitmap(SkBitmap* outTexture, SkMatrix* outMatrix, TileMode xy[2]) const { return this->onIsABitmap(outTexture, outMatrix, xy); } bool isABitmap() const { return this->isABitmap(nullptr, nullptr, nullptr); } /** * 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 * Conical: * 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, 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. uint32_t fGradientFlags; //!< see SkGradientShader::Flags }; virtual GradientType asAGradient(GradientInfo* info) const; /** * If the shader subclass is composed of two shaders, return true, and if rec is not NULL, * fill it out with info about the shader. * * These are bare pointers; the ownership and reference count are unchanged. */ struct ComposeRec { const SkShader* fShaderA; const SkShader* fShaderB; const SkXfermode* fMode; }; virtual bool asACompose(ComposeRec*) const { return false; } #if SK_SUPPORT_GPU /** * Returns a GrFragmentProcessor that implements the shader for the GPU backend. NULL is * returned if there is no GPU implementation. * * The GPU device does not call SkShader::createContext(), instead we pass the view matrix, * local matrix, and filter quality directly. * * The GrContext may be used by the to create textures that are required by the returned * processor. * * The returned GrFragmentProcessor should expect an unpremultiplied input color and * produce a premultiplied output. */ virtual sk_sp asFragmentProcessor(GrContext*, const SkMatrix& viewMatrix, const SkMatrix* localMatrix, SkFilterQuality, SkSourceGammaTreatment) const; #endif /** * If the shader can represent its "average" luminance in a single color, return true and * if color is not NULL, return that color. If it cannot, return false and ignore the color * parameter. * * Note: if this returns true, the returned color will always be opaque, as only the RGB * components are used to compute luminance. */ bool asLuminanceColor(SkColor*) const; #ifdef SK_BUILD_FOR_ANDROID_FRAMEWORK /** * If the shader is a custom shader which has data the caller might want, call this function * to get that data. */ virtual bool asACustomShader(void** /* customData */) const { return false; } #endif ////////////////////////////////////////////////////////////////////////// // Methods to create combinations or variants of shaders /** * Return a shader that will apply the specified localMatrix to this shader. * The specified matrix will be applied before any matrix associated with this shader. */ sk_sp makeWithLocalMatrix(const SkMatrix&) const; /** * Create a new shader that produces the same colors as invoking this shader and then applying * the colorfilter. */ sk_sp makeWithColorFilter(sk_sp) const; ////////////////////////////////////////////////////////////////////////// // Factory methods for stock shaders /** * Call this to create a new "empty" shader, that will not draw anything. */ static sk_sp MakeEmptyShader(); /** * Call this to create a new shader that just draws the specified color. This should always * draw the same as a paint with this color (and no shader). */ static sk_sp MakeColorShader(SkColor); /** * Create a shader that draws the specified color (in the specified colorspace). * * This works around the limitation that SkPaint::setColor() only takes byte values, and does * not support specific colorspaces. */ static sk_sp MakeColorShader(const SkColor4f&, sk_sp); static sk_sp MakeComposeShader(sk_sp dst, sk_sp src, SkXfermode::Mode); #ifdef SK_SUPPORT_LEGACY_CREATESHADER_PTR static SkShader* CreateEmptyShader() { return MakeEmptyShader().release(); } static SkShader* CreateColorShader(SkColor c) { return MakeColorShader(c).release(); } static SkShader* CreateBitmapShader(const SkBitmap& src, TileMode tmx, TileMode tmy, const SkMatrix* localMatrix = nullptr) { return MakeBitmapShader(src, tmx, tmy, localMatrix).release(); } static SkShader* CreateComposeShader(SkShader* dst, SkShader* src, SkXfermode::Mode mode); static SkShader* CreateComposeShader(SkShader* dst, SkShader* src, SkXfermode* xfer); static SkShader* CreatePictureShader(const SkPicture* src, TileMode tmx, TileMode tmy, const SkMatrix* localMatrix, const SkRect* tile); SkShader* newWithLocalMatrix(const SkMatrix& matrix) const { return this->makeWithLocalMatrix(matrix).release(); } SkShader* newWithColorFilter(SkColorFilter* filter) const; #endif /** * Create a new compose shader, given shaders dst, src, and a combining xfermode mode. * The xfermode is called with the output of the two shaders, and its output is returned. * If xfer is null, SkXfermode::kSrcOver_Mode is assumed. * * The caller is responsible for managing its reference-count for the xfer (if not null). */ static sk_sp MakeComposeShader(sk_sp dst, sk_sp src, sk_sp xfer); #ifdef SK_SUPPORT_LEGACY_XFERMODE_PTR static sk_sp MakeComposeShader(sk_sp dst, sk_sp src, SkXfermode* xfer); #endif /** 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. * * If the src is kA8_Config then that mask will be colorized using the color on * the paint. * * @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 sk_sp MakeBitmapShader(const SkBitmap& src, TileMode tmx, TileMode tmy, const SkMatrix* localMatrix = nullptr); // NOTE: You can create an SkImage Shader with SkImage::newShader(). /** Call this to create a new shader that will draw with the specified picture. * * @param src The picture to use inside the shader (if not NULL, its ref count * is incremented). The SkPicture must not be changed after * successfully creating a picture 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. * @param tile The tile rectangle in picture coordinates: this represents the subset * (or superset) of the picture used when building a tile. It is not * affected by localMatrix and does not imply scaling (only translation * and cropping). If null, the tile rect is considered equal to the picture * bounds. * @return Returns a new shader object. Note: this function never returns null. */ static sk_sp MakePictureShader(sk_sp src, TileMode tmx, TileMode tmy, const SkMatrix* localMatrix, const SkRect* tile); /** * If this shader can be represented by another shader + a localMatrix, return that shader * and, if not NULL, the localMatrix. If not, return NULL and ignore the localMatrix parameter. * * Note: the returned shader (if not NULL) will have been ref'd, and it is the responsibility * of the caller to balance that with unref() when they are done. */ virtual SkShader* refAsALocalMatrixShader(SkMatrix* localMatrix) const; SK_TO_STRING_VIRT() SK_DEFINE_FLATTENABLE_TYPE(SkShader) protected: void flatten(SkWriteBuffer&) const override; bool computeTotalInverse(const ContextRec&, SkMatrix* totalInverse) const; /** * Your subclass must also override contextSize() if it overrides onCreateContext(). * Base class impl returns NULL. */ virtual Context* onCreateContext(const ContextRec&, void* storage) const; /** * Override this if your subclass overrides createContext, to return the correct size of * your subclass' context. */ virtual size_t onContextSize(const ContextRec&) const; virtual bool onAsLuminanceColor(SkColor*) const { return false; } virtual bool onIsABitmap(SkBitmap*, SkMatrix*, TileMode[2]) const { return false; } private: // This is essentially const, but not officially so it can be modified in // constructors. SkMatrix fLocalMatrix; // So the SkLocalMatrixShader can whack fLocalMatrix in its SkReadBuffer constructor. friend class SkLocalMatrixShader; friend class SkBitmapProcShader; // for computeTotalInverse() typedef SkFlattenable INHERITED; }; #endif