/* * Copyright 2010 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef GrClip_DEFINED #define GrClip_DEFINED #include "GrClipIterator.h" #include "GrRect.h" #include "SkPath.h" #include "SkTArray.h" class GrSurface; class GrClip { public: GrClip(); GrClip(const GrClip& src); /** * The conservativeBounds parameter already takes (tx,ty) into account. */ GrClip(GrClipIterator* iter, GrScalar tx, GrScalar ty, const GrRect& conservativeBounds); explicit GrClip(const GrIRect& rect); explicit GrClip(const GrRect& rect); ~GrClip(); GrClip& operator=(const GrClip& src); const GrRect& getConservativeBounds() const { GrAssert(fConservativeBoundsValid); return fConservativeBounds; } bool requiresAA() const { return fRequiresAA; } class Iter { public: enum IterStart { kBottom_IterStart, kTop_IterStart }; /** * Creates an uninitialized iterator. Must be reset() */ Iter(); Iter(const GrClip& stack, IterStart startLoc); struct Clip { Clip() : fRect(NULL), fPath(NULL), fOp(SkRegion::kIntersect_Op), fDoAA(false) {} const SkRect* fRect; // if non-null, this is a rect clip const SkPath* fPath; // if non-null, this is a path clip SkRegion::Op fOp; bool fDoAA; }; /** * Return the clip for this element in the iterator. If next() returns * NULL, then the iterator is done. The type of clip is determined by * the pointers fRect and fPath: * * fRect==NULL fPath!=NULL path clip * fRect!=NULL fPath==NULL rect clip * fRect==NULL fPath==NULL empty clip */ const Clip* next(); const Clip* prev(); /** * Moves the iterator to the topmost clip with the specified RegionOp * and returns that clip. If no clip with that op is found, * returns NULL. */ const Clip* skipToTopmost(SkRegion::Op op); /** * Restarts the iterator on a clip stack. */ void reset(const GrClip& stack, IterStart startLoc); private: const GrClip* fStack; Clip fClip; int fCurIndex; /** * updateClip updates fClip to represent the clip in the index slot of * GrClip's list. * It unifies functionality needed by both next() and * prev(). */ const Clip* updateClip(int index); }; private: int getElementCount() const { return fList.count(); } GrClipType getElementType(int i) const { return fList[i].fType; } const SkPath& getPath(int i) const { GrAssert(kPath_ClipType == fList[i].fType); return fList[i].fPath; } GrPathFill getPathFill(int i) const { GrAssert(kPath_ClipType == fList[i].fType); return fList[i].fPathFill; } const GrRect& getRect(int i) const { GrAssert(kRect_ClipType == fList[i].fType); return fList[i].fRect; } SkRegion::Op getOp(int i) const { return fList[i].fOp; } bool getDoAA(int i) const { return fList[i].fDoAA; } public: bool isRect() const { if (1 == fList.count() && kRect_ClipType == fList[0].fType && (SkRegion::kIntersect_Op == fList[0].fOp || SkRegion::kReplace_Op == fList[0].fOp)) { // if we determined that the clip is a single rect // we ought to have also used that rect as the bounds. GrAssert(fConservativeBoundsValid); GrAssert(fConservativeBounds == fList[0].fRect); return true; } else { return false; } } // FIXME: This word "empty" is confusing. It means that the clip has no // elements (it is the infinite plane) not that it has no area. bool isEmpty() const { return 0 == fList.count(); } /** * Resets this clip to be empty */ void setEmpty(); /** * If specified, the bounds parameter already takes (tx,ty) into account. */ void setFromIterator(GrClipIterator* iter, GrScalar tx, GrScalar ty, const GrRect& conservativeBounds); void setFromRect(const GrRect& rect); void setFromIRect(const GrIRect& rect); friend bool operator==(const GrClip& a, const GrClip& b) { if (a.fList.count() != b.fList.count()) { return false; } int count = a.fList.count(); for (int i = 0; i < count; ++i) { if (a.fList[i] != b.fList[i]) { return false; } } return true; } friend bool operator!=(const GrClip& a, const GrClip& b) { return !(a == b); } private: struct Element { GrClipType fType; GrRect fRect; SkPath fPath; GrPathFill fPathFill; SkRegion::Op fOp; bool fDoAA; bool operator ==(const Element& e) const { if (e.fType != fType || e.fOp != fOp || e.fDoAA != fDoAA) { return false; } switch (fType) { case kRect_ClipType: return fRect == e.fRect; case kPath_ClipType: return fPath == e.fPath; default: GrCrash("Unknown clip element type."); return false; // suppress warning } } bool operator !=(const Element& e) const { return !(*this == e); } }; GrRect fConservativeBounds; bool fConservativeBoundsValid; bool fRequiresAA; enum { kPreAllocElements = 4, }; SkSTArray fList; }; /** * GrClipData encapsulates the information required to construct the clip * masks. 'fOrigin' is only non-zero when saveLayer has been called * with an offset bounding box. The clips in 'fClipStack' are in * device coordinates (i.e., they have been translated by -fOrigin w.r.t. * the canvas' device coordinates). */ class GrClipData : public SkNoncopyable { public: const GrClip* fClipStack; SkIPoint fOrigin; GrClipData() : fClipStack(NULL) { fOrigin.setZero(); } bool operator==(const GrClipData& other) const { if (fOrigin != other.fOrigin) { return false; } if (NULL != fClipStack && NULL != other.fClipStack) { return *fClipStack == *other.fClipStack; } return fClipStack == other.fClipStack; } bool operator!=(const GrClipData& other) const { return !(*this == other); } void getConservativeBounds(const GrSurface* surface, GrIRect* result, bool* isIntersectionOfRects = NULL) const; }; #endif