include/core/SkClipStack.h - platform/external/skia - 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 SkClipStack_DEFINED
 #define SkClipStack_DEFINED

 #include "SkDeque.h"
 #include "SkRegion.h"
 #include "SkTDArray.h"

 struct SkRect;
 class SkPath;

 // Because a single save/restore state can have multiple clips, this class
 // stores the stack depth (fSaveCount) and clips (fDeque) separately.
 // Each clip in fDeque stores the stack state to which it belongs
 // (i.e., the fSaveCount in force when it was added). Restores are thus
 // implemented by removing clips from fDeque that have an fSaveCount larger
 // then the freshly decremented count.
 class SK_API SkClipStack {
 public:
     SkClipStack();
     SkClipStack(const SkClipStack& b);
     explicit SkClipStack(const SkRect& r);
     explicit SkClipStack(const SkIRect& r);
     ~SkClipStack();

     SkClipStack& operator=(const SkClipStack& b);
     bool operator==(const SkClipStack& b) const;
     bool operator!=(const SkClipStack& b) const { return !(*this == b); }

     void reset();

     int getSaveCount() const { return fSaveCount; }
     void save();
     void restore();

     enum BoundsType {
         // The bounding box contains all the pixels that can be written to
         kNormal_BoundsType,
         // The bounding box contains all the pixels that cannot be written to.
         // The real bound extends out to infinity and all the pixels outside
         // of the bound can be written to. Note that some of the pixels inside
         // the bound may also be writeable but all pixels that cannot be
         // written to are guaranteed to be inside.
         kInsideOut_BoundsType
     };

     /**
      * getBounds places the current finite bound in its first parameter. In its
      * second, it indicates which kind of bound is being returned. If
      * 'canvFiniteBound' is a normal bounding box then it encloses all writeable
      * pixels. If 'canvFiniteBound' is an inside out bounding box then it
      * encloses all the un-writeable pixels and the true/normal bound is the
      * infinite plane. isIntersectionOfRects is an optional parameter
      * that is true if 'canvFiniteBound' resulted from an intersection of rects.
      */
     void getBounds(SkRect* canvFiniteBound,
                    BoundsType* boundType,
                    bool* isIntersectionOfRects = NULL) const;

     /**
      * Takes an input rect in device space and conservatively clips it to the
      * clip-stack. If false is returned then the rect does not intersect the
      * clip and is unmodified.
      */
     bool intersectRectWithClip(SkRect* devRect) const;

     void clipDevRect(const SkIRect& ir, SkRegion::Op op) {
         SkRect r;
         r.set(ir);
         this->clipDevRect(r, op, false);
     }
     void clipDevRect(const SkRect&, SkRegion::Op, bool doAA);
     void clipDevPath(const SkPath&, SkRegion::Op, bool doAA);
     // An optimized version of clipDevRect(emptyRect, kIntersect, ...)
     void clipEmpty();

     /**
      * isWideOpen returns true if the clip state corresponds to the infinite
      * plane (i.e., draws are not limited at all)
      */
     bool isWideOpen() const;

     /**
      * Add a callback function that will be called whenever a clip state
      * is no longer viable. This will occur whenever restore
      * is called or when a clipDevRect or clipDevPath call updates the
      * clip within an existing save/restore state. Each clip state is
      * represented by a unique generation ID.
      */
     typedef void (*PFPurgeClipCB)(int genID, void* data);
     void addPurgeClipCallback(PFPurgeClipCB callback, void* data) const;

     /**
      * Remove a callback added earlier via addPurgeClipCallback
      */
     void removePurgeClipCallback(PFPurgeClipCB callback, void* data) const;

     /**
      * The generation ID has three reserved values to indicate special
      * (potentially ignoreable) cases
      */
     static const int32_t kInvalidGenID = 0;
     static const int32_t kEmptyGenID = 1;       // no pixels writeable
     static const int32_t kWideOpenGenID = 2;    // all pixels writeable

     int32_t getTopmostGenID() const;

 private:
     struct Rec;

 public:
     class Iter {
     public:
         enum IterStart {
             kBottom_IterStart = SkDeque::Iter::kFront_IterStart,
             kTop_IterStart = SkDeque::Iter::kBack_IterStart
         };

         /**
          * Creates an uninitialized iterator. Must be reset()
          */
         Iter();

         Iter(const SkClipStack& stack, IterStart startLoc);

         struct Clip {
             Clip() : fRect(NULL), fPath(NULL), fOp(SkRegion::kIntersect_Op),
                      fDoAA(false) {}
             friend bool operator==(const Clip& a, const Clip& b);
             friend bool operator!=(const Clip& a, const Clip& b);
             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;
             int32_t         fGenID;
         };

         /**
          *  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 SkClipStack& stack, IterStart startLoc);

     private:
         const SkClipStack* fStack;
         Clip               fClip;
         SkDeque::Iter      fIter;

         /**
          * updateClip updates fClip to the current state of fIter. It unifies
          * functionality needed by both next() and prev().
          */
         const Clip* updateClip(const SkClipStack::Rec* rec);
     };

     /**
      * The B2TIter iterates from the bottom of the stack to the top.
      * It inherits privately from Iter to prevent access to reverse iteration.
      */
     class B2TIter : private Iter {
     public:
         B2TIter() {}

         /**
          * Wrap Iter's 2 parameter ctor to force initialization to the
          * beginning of the deque/bottom of the stack
          */
         B2TIter(const SkClipStack& stack)
         : INHERITED(stack, kBottom_IterStart) {
         }

         using Iter::Clip;
         using Iter::next;

         /**
          * Wrap Iter::reset to force initialization to the
          * beginning of the deque/bottom of the stack
          */
         void reset(const SkClipStack& stack) {
             this->INHERITED::reset(stack, kBottom_IterStart);
         }

     private:

         typedef Iter INHERITED;
     };

     /**
      * GetConservativeBounds returns a conservative bound of the current clip.
      * Since this could be the infinite plane (if inverse fills were involved) the
      * maxWidth and maxHeight parameters can be used to limit the returned bound
      * to the expected drawing area. Similarly, the offsetX and offsetY parameters
      * allow the caller to offset the returned bound to account for translated
      * drawing areas (i.e., those resulting from a saveLayer). For finite bounds,
      * the translation (+offsetX, +offsetY) is applied before the clamp to the
      * maximum rectangle: [0,maxWidth) x [0,maxHeight).
      * isIntersectionOfRects is an optional parameter that is true when
      * 'devBounds' is the result of an intersection of rects. In this case
      * 'devBounds' is the exact answer/clip.
      */
     void getConservativeBounds(int offsetX,
                                int offsetY,
                                int maxWidth,
                                int maxHeight,
                                SkRect* devBounds,
                                bool* isIntersectionOfRects = NULL) const;

 private:
     friend class Iter;

     SkDeque fDeque;
     int     fSaveCount;

     // Generation ID for the clip stack. This is incremented for each
     // clipDevRect and clipDevPath call. 0 is reserved to indicate an
     // invalid ID.
     static int32_t     gGenID;

     struct ClipCallbackData {
         PFPurgeClipCB   fCallback;
         void*           fData;

         friend bool operator==(const ClipCallbackData& a,
                                const ClipCallbackData& b) {
             return a.fCallback == b.fCallback && a.fData == b.fData;
         }
     };

     mutable SkTDArray<ClipCallbackData> fCallbackData;

     /**
      * Invoke all the purge callbacks passing in rec's generation ID.
      */
     void purgeClip(Rec* rec);

     /**
      * Return the next unique generation ID.
      */
     static int32_t GetNextGenID();
 };

 #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 SkClipStack_DEFINED
	#define SkClipStack_DEFINED

	#include "SkDeque.h"
	#include "SkRegion.h"
	#include "SkTDArray.h"

	struct SkRect;
	class SkPath;

	// Because a single save/restore state can have multiple clips, this class
	// stores the stack depth (fSaveCount) and clips (fDeque) separately.
	// Each clip in fDeque stores the stack state to which it belongs
	// (i.e., the fSaveCount in force when it was added). Restores are thus
	// implemented by removing clips from fDeque that have an fSaveCount larger
	// then the freshly decremented count.
	class SK_API SkClipStack {
	public:
	SkClipStack();
	SkClipStack(const SkClipStack& b);
	explicit SkClipStack(const SkRect& r);
	explicit SkClipStack(const SkIRect& r);
	~SkClipStack();

	SkClipStack& operator=(const SkClipStack& b);
	bool operator==(const SkClipStack& b) const;
	bool operator!=(const SkClipStack& b) const { return !(*this == b); }

	void reset();

	int getSaveCount() const { return fSaveCount; }
	void save();
	void restore();

	enum BoundsType {
	// The bounding box contains all the pixels that can be written to
	kNormal_BoundsType,
	// The bounding box contains all the pixels that cannot be written to.
	// The real bound extends out to infinity and all the pixels outside
	// of the bound can be written to. Note that some of the pixels inside
	// the bound may also be writeable but all pixels that cannot be
	// written to are guaranteed to be inside.
	kInsideOut_BoundsType
	};

	/**
	* getBounds places the current finite bound in its first parameter. In its
	* second, it indicates which kind of bound is being returned. If
	* 'canvFiniteBound' is a normal bounding box then it encloses all writeable
	* pixels. If 'canvFiniteBound' is an inside out bounding box then it
	* encloses all the un-writeable pixels and the true/normal bound is the
	* infinite plane. isIntersectionOfRects is an optional parameter
	* that is true if 'canvFiniteBound' resulted from an intersection of rects.
	*/
	void getBounds(SkRect* canvFiniteBound,
	BoundsType* boundType,
	bool* isIntersectionOfRects = NULL) const;

	/**
	* Takes an input rect in device space and conservatively clips it to the
	* clip-stack. If false is returned then the rect does not intersect the
	* clip and is unmodified.
	*/
	bool intersectRectWithClip(SkRect* devRect) const;

	void clipDevRect(const SkIRect& ir, SkRegion::Op op) {
	SkRect r;
	r.set(ir);
	this->clipDevRect(r, op, false);
	}
	void clipDevRect(const SkRect&, SkRegion::Op, bool doAA);
	void clipDevPath(const SkPath&, SkRegion::Op, bool doAA);
	// An optimized version of clipDevRect(emptyRect, kIntersect, ...)
	void clipEmpty();

	/**
	* isWideOpen returns true if the clip state corresponds to the infinite
	* plane (i.e., draws are not limited at all)
	*/
	bool isWideOpen() const;

	/**
	* Add a callback function that will be called whenever a clip state
	* is no longer viable. This will occur whenever restore
	* is called or when a clipDevRect or clipDevPath call updates the
	* clip within an existing save/restore state. Each clip state is
	* represented by a unique generation ID.
	*/
	typedef void (PFPurgeClipCB)(int genID, void data);
	void addPurgeClipCallback(PFPurgeClipCB callback, void* data) const;

	/**
	* Remove a callback added earlier via addPurgeClipCallback
	*/
	void removePurgeClipCallback(PFPurgeClipCB callback, void* data) const;

	/**
	* The generation ID has three reserved values to indicate special
	* (potentially ignoreable) cases
	*/
	static const int32_t kInvalidGenID = 0;
	static const int32_t kEmptyGenID = 1; // no pixels writeable
	static const int32_t kWideOpenGenID = 2; // all pixels writeable

	int32_t getTopmostGenID() const;

	private:
	struct Rec;

	public:
	class Iter {
	public:
	enum IterStart {
	kBottom_IterStart = SkDeque::Iter::kFront_IterStart,
	kTop_IterStart = SkDeque::Iter::kBack_IterStart
	};

	/**
	* Creates an uninitialized iterator. Must be reset()
	*/
	Iter();

	Iter(const SkClipStack& stack, IterStart startLoc);

	struct Clip {
	Clip() : fRect(NULL), fPath(NULL), fOp(SkRegion::kIntersect_Op),
	fDoAA(false) {}
	friend bool operator==(const Clip& a, const Clip& b);
	friend bool operator!=(const Clip& a, const Clip& b);
	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;
	int32_t fGenID;
	};

	/**
	* 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 SkClipStack& stack, IterStart startLoc);

	private:
	const SkClipStack* fStack;
	Clip fClip;
	SkDeque::Iter fIter;

	/**
	* updateClip updates fClip to the current state of fIter. It unifies
	* functionality needed by both next() and prev().
	*/
	const Clip* updateClip(const SkClipStack::Rec* rec);
	};

	/**
	* The B2TIter iterates from the bottom of the stack to the top.
	* It inherits privately from Iter to prevent access to reverse iteration.
	*/
	class B2TIter : private Iter {
	public:
	B2TIter() {}

	/**
	* Wrap Iter's 2 parameter ctor to force initialization to the
	* beginning of the deque/bottom of the stack
	*/
	B2TIter(const SkClipStack& stack)
	: INHERITED(stack, kBottom_IterStart) {
	}

	using Iter::Clip;
	using Iter::next;

	/**
	* Wrap Iter::reset to force initialization to the
	* beginning of the deque/bottom of the stack
	*/
	void reset(const SkClipStack& stack) {
	this->INHERITED::reset(stack, kBottom_IterStart);
	}

	private:

	typedef Iter INHERITED;
	};

	/**
	* GetConservativeBounds returns a conservative bound of the current clip.
	* Since this could be the infinite plane (if inverse fills were involved) the
	* maxWidth and maxHeight parameters can be used to limit the returned bound
	* to the expected drawing area. Similarly, the offsetX and offsetY parameters
	* allow the caller to offset the returned bound to account for translated
	* drawing areas (i.e., those resulting from a saveLayer). For finite bounds,
	* the translation (+offsetX, +offsetY) is applied before the clamp to the
	* maximum rectangle: [0,maxWidth) x [0,maxHeight).
	* isIntersectionOfRects is an optional parameter that is true when
	* 'devBounds' is the result of an intersection of rects. In this case
	* 'devBounds' is the exact answer/clip.
	*/
	void getConservativeBounds(int offsetX,
	int offsetY,
	int maxWidth,
	int maxHeight,
	SkRect* devBounds,
	bool* isIntersectionOfRects = NULL) const;

	private:
	friend class Iter;

	SkDeque fDeque;
	int fSaveCount;

	// Generation ID for the clip stack. This is incremented for each
	// clipDevRect and clipDevPath call. 0 is reserved to indicate an
	// invalid ID.
	static int32_t gGenID;

	struct ClipCallbackData {
	PFPurgeClipCB fCallback;
	void* fData;

	friend bool operator==(const ClipCallbackData& a,
	const ClipCallbackData& b) {
	return a.fCallback == b.fCallback && a.fData == b.fData;
	}
	};

	mutable SkTDArray<ClipCallbackData> fCallbackData;

	/**
	* Invoke all the purge callbacks passing in rec's generation ID.
	*/
	void purgeClip(Rec* rec);

	/**
	* Return the next unique generation ID.
	*/
	static int32_t GetNextGenID();
	};

	#endif