include/core/SkPoint3.h - skia - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkPoint3_DEFINED
 #define SkPoint3_DEFINED

 #include "include/core/SkPoint.h"

 struct SK_API SkPoint3 {
     SkScalar fX, fY, fZ;

     static SkPoint3 Make(SkScalar x, SkScalar y, SkScalar z) {
         SkPoint3 pt;
         pt.set(x, y, z);
         return pt;
     }

     SkScalar x() const { return fX; }
     SkScalar y() const { return fY; }
     SkScalar z() const { return fZ; }

     void set(SkScalar x, SkScalar y, SkScalar z) { fX = x; fY = y; fZ = z; }

     friend bool operator==(const SkPoint3& a, const SkPoint3& b) {
         return a.fX == b.fX && a.fY == b.fY && a.fZ == b.fZ;
     }

     friend bool operator!=(const SkPoint3& a, const SkPoint3& b) {
         return !(a == b);
     }

     /** Returns the Euclidian distance from (0,0,0) to (x,y,z)
     */
     static SkScalar Length(SkScalar x, SkScalar y, SkScalar z);

     /** Return the Euclidian distance from (0,0,0) to the point
     */
     SkScalar length() const { return SkPoint3::Length(fX, fY, fZ); }

     /** Set the point (vector) to be unit-length in the same direction as it
         already points.  If the point has a degenerate length (i.e., nearly 0)
         then set it to (0,0,0) and return false; otherwise return true.
     */
     bool normalize();

     /** Return a new point whose X, Y and Z coordinates are scaled.
     */
     SkPoint3 makeScale(SkScalar scale) const {
         SkPoint3 p;
         p.set(scale * fX, scale * fY, scale * fZ);
         return p;
     }

     /** Scale the point's coordinates by scale.
     */
     void scale(SkScalar value) {
         fX *= value;
         fY *= value;
         fZ *= value;
     }

     /** Return a new point whose X, Y and Z coordinates are the negative of the
         original point's
     */
     SkPoint3 operator-() const {
         SkPoint3 neg;
         neg.fX = -fX;
         neg.fY = -fY;
         neg.fZ = -fZ;
         return neg;
     }

     /** Returns a new point whose coordinates are the difference between
         a and b (i.e., a - b)
     */
     friend SkPoint3 operator-(const SkPoint3& a, const SkPoint3& b) {
         return { a.fX - b.fX, a.fY - b.fY, a.fZ - b.fZ };
     }

     /** Returns a new point whose coordinates are the sum of a and b (a + b)
     */
     friend SkPoint3 operator+(const SkPoint3& a, const SkPoint3& b) {
         return { a.fX + b.fX, a.fY + b.fY, a.fZ + b.fZ };
     }

     /** Add v's coordinates to the point's
     */
     void operator+=(const SkPoint3& v) {
         fX += v.fX;
         fY += v.fY;
         fZ += v.fZ;
     }

     /** Subtract v's coordinates from the point's
     */
     void operator-=(const SkPoint3& v) {
         fX -= v.fX;
         fY -= v.fY;
         fZ -= v.fZ;
     }

     friend SkPoint3 operator*(SkScalar t, SkPoint3 p) {
         return { t * p.fX, t * p.fY, t * p.fZ };
     }

     /** Returns true if fX, fY, and fZ are measurable values.

      @return  true for values other than infinities and NaN
      */
     bool isFinite() const {
         SkScalar accum = 0;
         accum *= fX;
         accum *= fY;
         accum *= fZ;

         // accum is either NaN or it is finite (zero).
         SkASSERT(0 == accum || SkScalarIsNaN(accum));

         // value==value will be true iff value is not NaN
         // TODO: is it faster to say !accum or accum==accum?
         return !SkScalarIsNaN(accum);
     }

     /** Returns the dot product of a and b, treating them as 3D vectors
     */
     static SkScalar DotProduct(const SkPoint3& a, const SkPoint3& b) {
         return a.fX * b.fX + a.fY * b.fY + a.fZ * b.fZ;
     }

     SkScalar dot(const SkPoint3& vec) const {
         return DotProduct(*this, vec);
     }

     /** Returns the cross product of a and b, treating them as 3D vectors
     */
     static SkPoint3 CrossProduct(const SkPoint3& a, const SkPoint3& b) {
         SkPoint3 result;
         result.fX = a.fY*b.fZ - a.fZ*b.fY;
         result.fY = a.fZ*b.fX - a.fX*b.fZ;
         result.fZ = a.fX*b.fY - a.fY*b.fX;

         return result;
     }

     SkPoint3 cross(const SkPoint3& vec) const {
         return CrossProduct(*this, vec);
     }
 };

 typedef SkPoint3 SkVector3;
 typedef SkPoint3 SkColor3f;

 #endif
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkPoint3_DEFINED
	#define SkPoint3_DEFINED

	#include "include/core/SkPoint.h"

	struct SK_API SkPoint3 {
	SkScalar fX, fY, fZ;

	static SkPoint3 Make(SkScalar x, SkScalar y, SkScalar z) {
	SkPoint3 pt;
	pt.set(x, y, z);
	return pt;
	}

	SkScalar x() const { return fX; }
	SkScalar y() const { return fY; }
	SkScalar z() const { return fZ; }

	void set(SkScalar x, SkScalar y, SkScalar z) { fX = x; fY = y; fZ = z; }

	friend bool operator==(const SkPoint3& a, const SkPoint3& b) {
	return a.fX == b.fX && a.fY == b.fY && a.fZ == b.fZ;
	}

	friend bool operator!=(const SkPoint3& a, const SkPoint3& b) {
	return !(a == b);
	}

	/** Returns the Euclidian distance from (0,0,0) to (x,y,z)
	*/
	static SkScalar Length(SkScalar x, SkScalar y, SkScalar z);

	/** Return the Euclidian distance from (0,0,0) to the point
	*/
	SkScalar length() const { return SkPoint3::Length(fX, fY, fZ); }

	/** Set the point (vector) to be unit-length in the same direction as it
	already points. If the point has a degenerate length (i.e., nearly 0)
	then set it to (0,0,0) and return false; otherwise return true.
	*/
	bool normalize();

	/** Return a new point whose X, Y and Z coordinates are scaled.
	*/
	SkPoint3 makeScale(SkScalar scale) const {
	SkPoint3 p;
	p.set(scale * fX, scale * fY, scale * fZ);
	return p;
	}

	/** Scale the point's coordinates by scale.
	*/
	void scale(SkScalar value) {
	fX *= value;
	fY *= value;
	fZ *= value;
	}

	/** Return a new point whose X, Y and Z coordinates are the negative of the
	original point's
	*/
	SkPoint3 operator-() const {
	SkPoint3 neg;
	neg.fX = -fX;
	neg.fY = -fY;
	neg.fZ = -fZ;
	return neg;
	}

	/** Returns a new point whose coordinates are the difference between
	a and b (i.e., a - b)
	*/
	friend SkPoint3 operator-(const SkPoint3& a, const SkPoint3& b) {
	return { a.fX - b.fX, a.fY - b.fY, a.fZ - b.fZ };
	}

	/** Returns a new point whose coordinates are the sum of a and b (a + b)
	*/
	friend SkPoint3 operator+(const SkPoint3& a, const SkPoint3& b) {
	return { a.fX + b.fX, a.fY + b.fY, a.fZ + b.fZ };
	}

	/** Add v's coordinates to the point's
	*/
	void operator+=(const SkPoint3& v) {
	fX += v.fX;
	fY += v.fY;
	fZ += v.fZ;
	}

	/** Subtract v's coordinates from the point's
	*/
	void operator-=(const SkPoint3& v) {
	fX -= v.fX;
	fY -= v.fY;
	fZ -= v.fZ;
	}

	friend SkPoint3 operator*(SkScalar t, SkPoint3 p) {
	return { t * p.fX, t * p.fY, t * p.fZ };
	}

	/** Returns true if fX, fY, and fZ are measurable values.

	@return true for values other than infinities and NaN
	*/
	bool isFinite() const {
	SkScalar accum = 0;
	accum *= fX;
	accum *= fY;
	accum *= fZ;

	// accum is either NaN or it is finite (zero).
	SkASSERT(0 == accum \|\| SkScalarIsNaN(accum));

	// value==value will be true iff value is not NaN
	// TODO: is it faster to say !accum or accum==accum?
	return !SkScalarIsNaN(accum);
	}

	/** Returns the dot product of a and b, treating them as 3D vectors
	*/
	static SkScalar DotProduct(const SkPoint3& a, const SkPoint3& b) {
	return a.fX * b.fX + a.fY * b.fY + a.fZ * b.fZ;
	}

	SkScalar dot(const SkPoint3& vec) const {
	return DotProduct(*this, vec);
	}

	/** Returns the cross product of a and b, treating them as 3D vectors
	*/
	static SkPoint3 CrossProduct(const SkPoint3& a, const SkPoint3& b) {
	SkPoint3 result;
	result.fX = a.fYb.fZ - a.fZb.fY;
	result.fY = a.fZb.fX - a.fXb.fZ;
	result.fZ = a.fXb.fY - a.fYb.fX;

	return result;
	}

	SkPoint3 cross(const SkPoint3& vec) const {
	return CrossProduct(*this, vec);
	}
	};

	typedef SkPoint3 SkVector3;
	typedef SkPoint3 SkColor3f;

	#endif