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// Copyright (c) 1995-1999 Matra Datavision
// Copyright (c) 1999-2014 OPEN CASCADE SAS
//
// This file is part of Open CASCADE Technology software library.
//
// This library is free software; you can redistribute it and/or modify it under
// the terms of the GNU Lesser General Public License version 2.1 as published
// by the Free Software Foundation, with special exception defined in the file
// OCCT_LGPL_EXCEPTION.txt. Consult the file LICENSE_LGPL_21.txt included in OCCT
// distribution for complete text of the license and disclaimer of any warranty.
//
// Alternatively, this file may be used under the terms of Open CASCADE
// commercial license or contractual agreement.

// LPA et JCV 07/92 

#include <Standard_OutOfRange.hxx>
#include <Standard_ConstructionError.hxx>
#include <gp.hxx>
#include <gp_Mat2d.hxx>

inline gp_XY::gp_XY () : x(0.), y(0.) { } 

inline gp_XY::gp_XY (const Standard_Real X,
		     const Standard_Real Y) :  x (X),  y (Y) { }

inline void gp_XY::SetCoord (const Standard_Integer i,
			     const Standard_Real X)
{
  Standard_OutOfRange_Raise_if( i < 1 || i > 2,NULL);
  (&x)[i-1] = X;
}

inline void gp_XY::SetCoord (const Standard_Real X,
			     const Standard_Real Y)
{ x = X;  y = Y; }

inline void gp_XY::SetX (const Standard_Real X)
{ x = X; }

inline void gp_XY::SetY (const Standard_Real Y)
{ y = Y; }

inline Standard_Real gp_XY::Coord (const Standard_Integer i) const
{
  Standard_OutOfRange_Raise_if( i < 1 || i > 2,NULL);
  return (&x)[i-1];
}

inline Standard_Real& gp_XY::ChangeCoord (const Standard_Integer theIndex)
{
  Standard_OutOfRange_Raise_if(theIndex < 1 || theIndex > 2,NULL);
  return (&x)[theIndex - 1];
}

inline void gp_XY::Coord (Standard_Real& X,
			  Standard_Real& Y) const
{ X = x;  Y = y; }

inline Standard_Real gp_XY::X () const
{ return x; }

inline Standard_Real gp_XY::Y () const
{ return y; }

inline Standard_Real gp_XY::Modulus () const
{ 
  return sqrt (x * x + y * y);
}

inline Standard_Real gp_XY::SquareModulus () const
{
  return x * x + y * y;
}

inline void gp_XY::Add (const gp_XY& Other) {
  x += Other.x;
  y += Other.y;
}

inline gp_XY gp_XY::Added (const gp_XY& Other) const {
  return gp_XY(x + Other.X(),y + Other.Y());
}

inline Standard_Real gp_XY::Crossed (const gp_XY& Right) const {
  return x * Right.y - y * Right.x;
}

inline Standard_Real gp_XY::CrossMagnitude (const gp_XY& Right) const
{
  Standard_Real val = x * Right.y - y * Right.x;
  if (val < 0) val = - val;
  return val;
}

inline Standard_Real gp_XY::CrossSquareMagnitude (const gp_XY& Right) const {
  Standard_Real Zresult =  x * Right.y - y * Right.x;
  return Zresult * Zresult;
}

inline void gp_XY::Divide (const Standard_Real Scalar)
{
  x /= Scalar;
  y /= Scalar;
}

inline gp_XY gp_XY::Divided (const Standard_Real Scalar) const {
  return gp_XY(x / Scalar,y / Scalar);
}

inline Standard_Real gp_XY::Dot (const gp_XY& Other) const
{
  return x * Other.x + y * Other.y;
}

inline void gp_XY::Multiply (const Standard_Real Scalar)
{
  x *= Scalar;
  y *= Scalar;
}

inline void gp_XY::Multiply (const gp_XY& Other)
{
  x *= Other.x;
  y *= Other.y;
}

inline void gp_XY::Multiply (const gp_Mat2d& Matrix)
{
  Standard_Real Xresult = Matrix.matrix[0][0] * x + Matrix.matrix[0][1] * y;
  y                     = Matrix.matrix[1][0] * x + Matrix.matrix[1][1] * y;
  x                     = Xresult;
}

inline gp_XY gp_XY::Multiplied (const Standard_Real Scalar) const {
  return gp_XY(x * Scalar,y * Scalar);
}

inline gp_XY gp_XY::Multiplied (const gp_XY& Other) const {
  return(gp_XY(x * Other.X(),y * Other.Y()));
}

inline gp_XY gp_XY::Multiplied (const gp_Mat2d& Matrix) const
{
  return gp_XY (Matrix.matrix[0][0] * x + Matrix.matrix[0][1] * y,
		Matrix.matrix[1][0] * x + Matrix.matrix[1][1] * y);
}

inline void gp_XY::Normalize ()
{
  Standard_Real D = Modulus();
  Standard_ConstructionError_Raise_if (D <= gp::Resolution(), "");
  x = x / D;   y = y / D;
}

inline gp_XY gp_XY::Normalized () const
{
  Standard_Real D = Modulus();
  Standard_ConstructionError_Raise_if (D <= gp::Resolution(), "");
  return gp_XY (x / D, y / D);
}

inline void gp_XY::Reverse ()
{  x = - x;    y = - y;  }

inline gp_XY gp_XY::Reversed () const
{
  gp_XY Coord2D = *this;
  Coord2D.Reverse();
  return Coord2D;
}

inline void gp_XY::SetLinearForm (const Standard_Real L,
				  const gp_XY& Left,
				  const Standard_Real R,
				  const gp_XY& Right) {
  x = L * Left.x + R * Right.x;
  y = L * Left.y + R * Right.y;
}

inline void gp_XY::SetLinearForm (const Standard_Real L,
				  const gp_XY& Left,
				  const gp_XY& Right) {
  x = L * Left.x + Right.x;
  y = L * Left.y + Right.y;
}

inline void gp_XY::SetLinearForm (const gp_XY& Left,
				  const gp_XY& Right) {
  x = Left.x + Right.x;
  y = Left.y + Right.y;
}

inline void gp_XY::SetLinearForm (const Standard_Real A1,
				  const gp_XY& XY1,
				  const Standard_Real A2,
				  const gp_XY& XY2,
				  const gp_XY& XY3) {
  x = A1 * XY1.x + A2 * XY2.x + XY3.x;
  y = A1 * XY1.y + A2 * XY2.y + XY3.y;
}

inline void gp_XY::Subtract (const gp_XY& Right)
{
  x -= Right.x;
  y -= Right.y;
}

inline gp_XY gp_XY::Subtracted (const gp_XY& Right) const
{
  gp_XY Coord2D = *this;
  Coord2D.Subtract(Right);
  return Coord2D;
}

inline gp_XY operator* (const gp_Mat2d& Matrix,
			const gp_XY& Coord1) {
  return Coord1.Multiplied(Matrix);
}

inline gp_XY operator* (const Standard_Real Scalar,
			const gp_XY& Coord1) {
  return Coord1.Multiplied(Scalar);
}