src/core/SkRRectPriv.h - skia - Git at Google

 /*
  * Copyright 2018 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkRRectPriv_DEFINED
 #define SkRRectPriv_DEFINED

 #include "include/core/SkRRect.h"

 class SkRBuffer;
 class SkWBuffer;

 class SkRRectPriv {
 public:
     static bool IsCircle(const SkRRect& rr) {
         return rr.isOval() && SkScalarNearlyEqual(rr.fRadii[0].fX, rr.fRadii[0].fY);
     }

     static SkVector GetSimpleRadii(const SkRRect& rr) {
         SkASSERT(!rr.isComplex());
         return rr.fRadii[0];
     }

     static bool IsSimpleCircular(const SkRRect& rr) {
         return rr.isSimple() && SkScalarNearlyEqual(rr.fRadii[0].fX, rr.fRadii[0].fY);
     }

     // Looser version of IsSimpleCircular, where the x & y values of the radii
     // only have to be nearly equal instead of strictly equal.
     static bool IsNearlySimpleCircular(const SkRRect& rr, SkScalar tolerance = SK_ScalarNearlyZero);

     static bool EqualRadii(const SkRRect& rr) {
         return rr.isRect() || SkRRectPriv::IsCircle(rr)  || SkRRectPriv::IsSimpleCircular(rr);
     }

     static const SkVector* GetRadiiArray(const SkRRect& rr) { return rr.fRadii; }

     static bool AllCornersCircular(const SkRRect& rr, SkScalar tolerance = SK_ScalarNearlyZero);

     static bool ReadFromBuffer(SkRBuffer* buffer, SkRRect* rr);

     static void WriteToBuffer(const SkRRect& rr, SkWBuffer* buffer);

     // Test if a point is in the rrect, if it were a closed set.
     static bool ContainsPoint(const SkRRect& rr, const SkPoint& p) {
         return rr.getBounds().contains(p.fX, p.fY) && rr.checkCornerContainment(p.fX, p.fY);
     }

     // Compute an approximate largest inscribed bounding box of the rounded rect. For empty,
     // rect, oval, and simple types this will be the largest inscribed rectangle. Otherwise it may
     // not be the global maximum, but will be non-empty, touch at least one edge and be contained
     // in the round rect.
     static SkRect InnerBounds(const SkRRect& rr);

     // Attempt to compute the intersection of two round rects. The intersection is not necessarily
     // a round rect. This returns intersections only when the shape is representable as a new
     // round rect (or rect). Empty is returned if 'a' and 'b' do not intersect or if the
     // intersection is too complicated. This is conservative, it may not always detect that an
     // intersection could be represented as a round rect. However, when it does return a round rect
     // that intersection will be exact (i.e. it is NOT just a subset of the actual intersection).
     static SkRRect ConservativeIntersect(const SkRRect& a, const SkRRect& b);
 };

 #endif
	/*
	* Copyright 2018 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkRRectPriv_DEFINED
	#define SkRRectPriv_DEFINED

	#include "include/core/SkRRect.h"

	class SkRBuffer;
	class SkWBuffer;

	class SkRRectPriv {
	public:
	static bool IsCircle(const SkRRect& rr) {
	return rr.isOval() && SkScalarNearlyEqual(rr.fRadii[0].fX, rr.fRadii[0].fY);
	}

	static SkVector GetSimpleRadii(const SkRRect& rr) {
	SkASSERT(!rr.isComplex());
	return rr.fRadii[0];
	}

	static bool IsSimpleCircular(const SkRRect& rr) {
	return rr.isSimple() && SkScalarNearlyEqual(rr.fRadii[0].fX, rr.fRadii[0].fY);
	}

	// Looser version of IsSimpleCircular, where the x & y values of the radii
	// only have to be nearly equal instead of strictly equal.
	static bool IsNearlySimpleCircular(const SkRRect& rr, SkScalar tolerance = SK_ScalarNearlyZero);

	static bool EqualRadii(const SkRRect& rr) {
	return rr.isRect() \|\| SkRRectPriv::IsCircle(rr) \|\| SkRRectPriv::IsSimpleCircular(rr);
	}

	static const SkVector* GetRadiiArray(const SkRRect& rr) { return rr.fRadii; }

	static bool AllCornersCircular(const SkRRect& rr, SkScalar tolerance = SK_ScalarNearlyZero);

	static bool ReadFromBuffer(SkRBuffer* buffer, SkRRect* rr);

	static void WriteToBuffer(const SkRRect& rr, SkWBuffer* buffer);

	// Test if a point is in the rrect, if it were a closed set.
	static bool ContainsPoint(const SkRRect& rr, const SkPoint& p) {
	return rr.getBounds().contains(p.fX, p.fY) && rr.checkCornerContainment(p.fX, p.fY);
	}

	// Compute an approximate largest inscribed bounding box of the rounded rect. For empty,
	// rect, oval, and simple types this will be the largest inscribed rectangle. Otherwise it may
	// not be the global maximum, but will be non-empty, touch at least one edge and be contained
	// in the round rect.
	static SkRect InnerBounds(const SkRRect& rr);

	// Attempt to compute the intersection of two round rects. The intersection is not necessarily
	// a round rect. This returns intersections only when the shape is representable as a new
	// round rect (or rect). Empty is returned if 'a' and 'b' do not intersect or if the
	// intersection is too complicated. This is conservative, it may not always detect that an
	// intersection could be represented as a round rect. However, when it does return a round rect
	// that intersection will be exact (i.e. it is NOT just a subset of the actual intersection).
	static SkRRect ConservativeIntersect(const SkRRect& a, const SkRRect& b);
	};

	#endif