src/core/SkRectPriv.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 SkRectPriv_DEFINED
 #define SkRectPriv_DEFINED

 #include "include/core/SkRect.h"
 #include "src/base/SkMathPriv.h"
 #include "src/base/SkVx.h"

 class SkM44;
 class SkMatrix;

 class SkRectPriv {
 public:
     // Returns an irect that is very large, and can be safely round-trip with SkRect and still
     // be considered non-empty (i.e. width/height > 0) even if we round-out the SkRect.
     static SkIRect MakeILarge() {
         // SK_MaxS32 >> 1 seemed better, but it did not survive round-trip with SkRect and rounding.
         // Also, 1 << 29 can be perfectly represented in float, while SK_MaxS32 >> 1 cannot.
         const int32_t large = 1 << 29;
         return { -large, -large, large, large };
     }

     static SkIRect MakeILargestInverted() {
         return { SK_MaxS32, SK_MaxS32, SK_MinS32, SK_MinS32 };
     }

     static SkRect MakeLargeS32() {
         SkRect r;
         r.set(MakeILarge());
         return r;
     }

     static SkRect MakeLargest() {
         return { SK_ScalarMin, SK_ScalarMin, SK_ScalarMax, SK_ScalarMax };
     }

     static constexpr SkRect MakeLargestInverted() {
         return { SK_ScalarMax, SK_ScalarMax, SK_ScalarMin, SK_ScalarMin };
     }

     static void GrowToInclude(SkRect* r, const SkPoint& pt) {
         r->fLeft  =  std::min(pt.fX, r->fLeft);
         r->fRight =  std::max(pt.fX, r->fRight);
         r->fTop    = std::min(pt.fY, r->fTop);
         r->fBottom = std::max(pt.fY, r->fBottom);
     }

     // Conservative check if r can be expressed in fixed-point.
     // Will return false for very large values that might have fit
     static bool FitsInFixed(const SkRect& r) {
         return SkFitsInFixed(r.fLeft) && SkFitsInFixed(r.fTop) &&
                SkFitsInFixed(r.fRight) && SkFitsInFixed(r.fBottom);
     }

     // Returns r.width()/2 but divides first to avoid width() overflowing.
     static constexpr float HalfWidth(const SkRect& r) {
         return sk_float_midpoint(-r.fLeft, r.fRight);
     }
     // Returns r.height()/2 but divides first to avoid height() overflowing.
     static constexpr float HalfHeight(const SkRect& r) {
         return sk_float_midpoint(-r.fTop, r.fBottom);
     }

     // Evaluate A-B. If the difference shape cannot be represented as a rectangle then false is
     // returned and 'out' is set to the largest rectangle contained in said shape. If true is
     // returned then A-B is representable as a rectangle, which is stored in 'out'.
     static bool Subtract(const SkRect& a, const SkRect& b, SkRect* out);
     static bool Subtract(const SkIRect& a, const SkIRect& b, SkIRect* out);

     // Evaluate A-B, and return the largest rectangle contained in that shape (since the difference
     // may not be representable as rectangle). The returned rectangle will not intersect B.
     static SkRect Subtract(const SkRect& a, const SkRect& b) {
         SkRect diff;
         Subtract(a, b, &diff);
         return diff;
     }
     static SkIRect Subtract(const SkIRect& a, const SkIRect& b) {
         SkIRect diff;
         Subtract(a, b, &diff);
         return diff;
     }

     // Returns true if the quadrilateral formed by transforming the four corners of 'a' contains 'b'
     // 'tol' is in the same coordinate space as 'b', to treat 'b' as 'tol' units inset.
     static bool QuadContainsRect(const SkMatrix& m,
                                  const SkIRect& a,
                                  const SkIRect& b,
                                  float tol=0.f);
     static bool QuadContainsRect(const SkM44& m, const SkRect& a, const SkRect& b, float tol=0.f);
     // Like QuadContainsRect() but returns the edge test masks ordered T, R, B, L.
     static skvx::int4 QuadContainsRectMask(const SkM44& m, const SkRect& a, const SkRect& b,
                                            float tol=0.f);

     // Assuming 'src' does not intersect 'dst', returns the edge or corner of 'src' that is closest
     // to 'dst', e.g. the pixels that would be sampled from 'src' when clamp-tiled into 'dst'.
     //
     // The returned rectangle will not be empty if 'src' is not empty and 'dst' is not empty.
     // At least one of its width or height will be equal to 1 (possibly both if a corner is closest)
     //
     // Returns src.intersect(dst) if they do actually intersect.
     static SkIRect ClosestDisjointEdge(const SkIRect& src, const SkIRect& dst);
 };


 #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 SkRectPriv_DEFINED
	#define SkRectPriv_DEFINED

	#include "include/core/SkRect.h"
	#include "src/base/SkMathPriv.h"
	#include "src/base/SkVx.h"

	class SkM44;
	class SkMatrix;

	class SkRectPriv {
	public:
	// Returns an irect that is very large, and can be safely round-trip with SkRect and still
	// be considered non-empty (i.e. width/height > 0) even if we round-out the SkRect.
	static SkIRect MakeILarge() {
	// SK_MaxS32 >> 1 seemed better, but it did not survive round-trip with SkRect and rounding.
	// Also, 1 << 29 can be perfectly represented in float, while SK_MaxS32 >> 1 cannot.
	const int32_t large = 1 << 29;
	return { -large, -large, large, large };
	}

	static SkIRect MakeILargestInverted() {
	return { SK_MaxS32, SK_MaxS32, SK_MinS32, SK_MinS32 };
	}

	static SkRect MakeLargeS32() {
	SkRect r;
	r.set(MakeILarge());
	return r;
	}

	static SkRect MakeLargest() {
	return { SK_ScalarMin, SK_ScalarMin, SK_ScalarMax, SK_ScalarMax };
	}

	static constexpr SkRect MakeLargestInverted() {
	return { SK_ScalarMax, SK_ScalarMax, SK_ScalarMin, SK_ScalarMin };
	}

	static void GrowToInclude(SkRect* r, const SkPoint& pt) {
	r->fLeft = std::min(pt.fX, r->fLeft);
	r->fRight = std::max(pt.fX, r->fRight);
	r->fTop = std::min(pt.fY, r->fTop);
	r->fBottom = std::max(pt.fY, r->fBottom);
	}

	// Conservative check if r can be expressed in fixed-point.
	// Will return false for very large values that might have fit
	static bool FitsInFixed(const SkRect& r) {
	return SkFitsInFixed(r.fLeft) && SkFitsInFixed(r.fTop) &&
	SkFitsInFixed(r.fRight) && SkFitsInFixed(r.fBottom);
	}

	// Returns r.width()/2 but divides first to avoid width() overflowing.
	static constexpr float HalfWidth(const SkRect& r) {
	return sk_float_midpoint(-r.fLeft, r.fRight);
	}
	// Returns r.height()/2 but divides first to avoid height() overflowing.
	static constexpr float HalfHeight(const SkRect& r) {
	return sk_float_midpoint(-r.fTop, r.fBottom);
	}

	// Evaluate A-B. If the difference shape cannot be represented as a rectangle then false is
	// returned and 'out' is set to the largest rectangle contained in said shape. If true is
	// returned then A-B is representable as a rectangle, which is stored in 'out'.
	static bool Subtract(const SkRect& a, const SkRect& b, SkRect* out);
	static bool Subtract(const SkIRect& a, const SkIRect& b, SkIRect* out);

	// Evaluate A-B, and return the largest rectangle contained in that shape (since the difference
	// may not be representable as rectangle). The returned rectangle will not intersect B.
	static SkRect Subtract(const SkRect& a, const SkRect& b) {
	SkRect diff;
	Subtract(a, b, &diff);
	return diff;
	}
	static SkIRect Subtract(const SkIRect& a, const SkIRect& b) {
	SkIRect diff;
	Subtract(a, b, &diff);
	return diff;
	}

	// Returns true if the quadrilateral formed by transforming the four corners of 'a' contains 'b'
	// 'tol' is in the same coordinate space as 'b', to treat 'b' as 'tol' units inset.
	static bool QuadContainsRect(const SkMatrix& m,
	const SkIRect& a,
	const SkIRect& b,
	float tol=0.f);
	static bool QuadContainsRect(const SkM44& m, const SkRect& a, const SkRect& b, float tol=0.f);
	// Like QuadContainsRect() but returns the edge test masks ordered T, R, B, L.
	static skvx::int4 QuadContainsRectMask(const SkM44& m, const SkRect& a, const SkRect& b,
	float tol=0.f);

	// Assuming 'src' does not intersect 'dst', returns the edge or corner of 'src' that is closest
	// to 'dst', e.g. the pixels that would be sampled from 'src' when clamp-tiled into 'dst'.
	//
	// The returned rectangle will not be empty if 'src' is not empty and 'dst' is not empty.
	// At least one of its width or height will be equal to 1 (possibly both if a corner is closest)
	//
	// Returns src.intersect(dst) if they do actually intersect.
	static SkIRect ClosestDisjointEdge(const SkIRect& src, const SkIRect& dst);
	};


	#endif