kicad/libs/kimath/include/math/vector2d.h

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/*
* This program source code file is part of KICAD, a free EDA CAD application.
*
* Copyright (C) 2010 Virtenio GmbH, Torsten Hueter, torsten.hueter <at> virtenio.de
* Copyright (C) 2012 SoftPLC Corporation, Dick Hollenbeck <dick@softplc.com>
* Copyright (C) 2012-2021 KiCad Developers, see AUTHORS.txt for contributors.
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* Copyright (C) 2013 CERN
* @author Tomasz Wlostowski <tomasz.wlostowski@cern.ch>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, you may find one here:
* http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
* or you may search the http://www.gnu.org website for the version 2 license,
* or you may write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
*/
#ifndef VECTOR2D_H_
#define VECTOR2D_H_
#include <limits>
#include <iostream>
#include <sstream>
#include <type_traits>
#include <math/util.h>
#ifdef WX_COMPATIBILITY
#include <wx/gdicmn.h>
#endif
/**
* Traits class for VECTOR2.
*/
template <class T>
struct VECTOR2_TRAITS
{
///< extended range/precision types used by operations involving multiple
///< multiplications to prevent overflow.
typedef T extended_type;
};
template <>
struct VECTOR2_TRAITS<int>
{
typedef int64_t extended_type;
};
// Forward declarations for template friends
template <class T>
class VECTOR2;
template <class T>
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std::ostream& operator<<( std::ostream& aStream, const VECTOR2<T>& aVector );
/**
* Define a general 2D-vector/point.
*
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* This class uses templates to be universal. Several operators are provided to help
* easy implementing of linear algebra equations.
*
*/
template <class T = int>
class VECTOR2
{
public:
typedef typename VECTOR2_TRAITS<T>::extended_type extended_type;
typedef T coord_type;
static constexpr extended_type ECOORD_MAX = std::numeric_limits<extended_type>::max();
static constexpr extended_type ECOORD_MIN = std::numeric_limits<extended_type>::min();
T x, y;
/// Construct a 2D-vector with x, y = 0
VECTOR2();
#ifdef WX_COMPATIBILITY
/// Constructor with a wxPoint as argument
VECTOR2( const wxPoint& aPoint );
/// Constructor with a wxSize as argument
VECTOR2( const wxSize& aSize );
#endif
/// Construct a vector with given components x, y
VECTOR2( T x, T y );
/// Initializes a vector from another specialization. Beware of rounding issues.
template <typename CastingType>
VECTOR2( const VECTOR2<CastingType>& aVec )
{
x = (T) aVec.x;
y = (T) aVec.y;
}
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/// Copy a vector
VECTOR2( const VECTOR2<T>& aVec )
{
x = aVec.x;
y = aVec.y;
}
/// Cast a vector to another specialized subclass. Beware of rounding issues.
template <typename CastedType>
VECTOR2<CastedType> operator()() const
{
return VECTOR2<CastedType>( (CastedType) x, (CastedType) y );
}
/**
* Implement the cast to wxPoint.
*
* @return the vector cast to wxPoint.
*/
explicit operator wxPoint() const
{
return wxPoint( x, y );
}
// virtual ~VECTOR2();
/**
* Compute the Euclidean norm of the vector, which is defined as sqrt(x ** 2 + y ** 2).
*
* It is used to calculate the length of the vector.
*
* @return Scalar, the euclidean norm
*/
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T EuclideanNorm() const;
/**
* Compute the squared euclidean norm of the vector, which is defined as (x ** 2 + y ** 2).
*
* It is used to calculate the length of the vector.
*
* @return Scalar, the euclidean norm
*/
extended_type SquaredEuclideanNorm() const;
/**
* Compute the perpendicular vector.
*
* @return Perpendicular vector
*/
VECTOR2<T> Perpendicular() const;
/**
* Return a vector of the same direction, but length specified in \a aNewLength.
*
* @param aNewLength is the length of the rescaled vector.
* @return the rescaled vector.
*/
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VECTOR2<T> Resize( T aNewLength ) const;
/**
* Compute the angle of the vector.
*
* @return the vector angle in radians.
*/
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double Angle() const;
/**
* Rotate the vector by a given angle.
*
* @param aAngle rotation angle in radians
* @return rotated vector
*/
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VECTOR2<T> Rotate( double aAngle ) const;
/**
* Return the vector formatted as a string.
*
* @return the formatted string
*/
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const std::string Format() const;
/**
* Compute cross product of self with \a aVector.
*/
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extended_type Cross( const VECTOR2<T>& aVector ) const;
/**
* Compute dot product of self with \a aVector.
*/
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extended_type Dot( const VECTOR2<T>& aVector ) const;
// Operators
/// Assignment operator
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VECTOR2<T>& operator=( const VECTOR2<T>& aVector );
/// Vector addition operator
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VECTOR2<T> operator+( const VECTOR2<T>& aVector ) const;
/// Scalar addition operator
VECTOR2<T> operator+( const T& aScalar ) const;
/// Compound assignment operator
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VECTOR2<T>& operator+=( const VECTOR2<T>& aVector );
/// Compound assignment operator
VECTOR2<T>& operator+=( const T& aScalar );
/// Vector subtraction operator
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VECTOR2<T> operator-( const VECTOR2<T>& aVector ) const;
/// Scalar subtraction operator
VECTOR2<T> operator-( const T& aScalar ) const;
/// Compound assignment operator
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VECTOR2<T>& operator-=( const VECTOR2<T>& aVector );
/// Compound assignment operator
VECTOR2<T>& operator-=( const T& aScalar );
/// Negate Vector operator
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VECTOR2<T> operator-();
/// Scalar product operator
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extended_type operator*( const VECTOR2<T>& aVector ) const;
/// Multiplication with a factor
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VECTOR2<T> operator*( const T& aFactor ) const;
/// Division with a factor
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VECTOR2<T> operator/( const T& aFactor ) const;
/// Equality operator
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bool operator==( const VECTOR2<T>& aVector ) const;
/// Not equality operator
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bool operator!=( const VECTOR2<T>& aVector ) const;
/// Smaller than operator
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bool operator<( const VECTOR2<T>& aVector ) const;
bool operator<=( const VECTOR2<T>& aVector ) const;
/// Greater than operator
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bool operator>( const VECTOR2<T>& aVector ) const;
bool operator>=( const VECTOR2<T>& aVector ) const;
};
// ----------------------
// --- Implementation ---
// ----------------------
template <class T>
VECTOR2<T>::VECTOR2()
{
x = y = 0.0;
}
#ifdef WX_COMPATIBILITY
template <class T>
VECTOR2<T>::VECTOR2( const wxPoint& aPoint )
{
x = T( aPoint.x );
y = T( aPoint.y );
}
template <class T>
VECTOR2<T>::VECTOR2( const wxSize& aSize )
{
x = T( aSize.x );
y = T( aSize.y );
}
#endif
template <class T>
VECTOR2<T>::VECTOR2( T aX, T aY )
{
x = aX;
y = aY;
}
template <class T>
T VECTOR2<T>::EuclideanNorm() const
{
return sqrt( (extended_type) x * x + (extended_type) y * y );
}
template <class T>
typename VECTOR2<T>::extended_type VECTOR2<T>::SquaredEuclideanNorm() const
{
return (extended_type) x * x + (extended_type) y * y;
}
template <class T>
double VECTOR2<T>::Angle() const
{
return atan2( (double) y, (double) x );
}
template <class T>
VECTOR2<T> VECTOR2<T>::Perpendicular() const
{
VECTOR2<T> perpendicular( -y, x );
return perpendicular;
}
template <class T>
VECTOR2<T>& VECTOR2<T>::operator=( const VECTOR2<T>& aVector )
{
x = aVector.x;
y = aVector.y;
return *this;
}
template <class T>
VECTOR2<T>& VECTOR2<T>::operator+=( const VECTOR2<T>& aVector )
{
x += aVector.x;
y += aVector.y;
return *this;
}
template <class T>
VECTOR2<T>& VECTOR2<T>::operator+=( const T& aScalar )
{
x += aScalar;
y += aScalar;
return *this;
}
template <class T>
VECTOR2<T>& VECTOR2<T>::operator-=( const VECTOR2<T>& aVector )
{
x -= aVector.x;
y -= aVector.y;
return *this;
}
template <class T>
VECTOR2<T>& VECTOR2<T>::operator-=( const T& aScalar )
{
x -= aScalar;
y -= aScalar;
return *this;
}
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/**
* Rotate a VECTOR2 by aAngle.
* @param aAngle = rotation angle in radians
*/
template <class T>
VECTOR2<T> VECTOR2<T>::Rotate( double aAngle ) const
{
// Avoid common radian rotations that may allow for angular error
if( aAngle == 0.0 || aAngle == 2 * M_PI )
return VECTOR2<T> ( T( x ), T( y ) );
if( aAngle == M_PI_2 )
return VECTOR2<T>( -T( y ), T( x ) );
if( aAngle == M_PI )
return VECTOR2<T>( -T(x), -T( y ) );
if( aAngle == 3 * M_PI_2 )
return VECTOR2<T>( T( y ), -T( x ) );
double sa = sin( aAngle );
double ca = cos( aAngle );
if( std::is_integral<T>::value )
{
return VECTOR2<T> ( KiROUND( (double) x * ca - (double) y * sa ),
KiROUND( (double) x * sa + (double) y * ca ) );
}
else
{
return VECTOR2<T> ( T( (double) x * ca - (double) y * sa ),
T( (double) x * sa + (double) y * ca ) );
}
}
template <class T>
VECTOR2<T> VECTOR2<T>::Resize( T aNewLength ) const
{
if( x == 0 && y == 0 )
return VECTOR2<T> ( 0, 0 );
extended_type l_sq_current = (extended_type) x * x + (extended_type) y * y;
extended_type l_sq_new = (extended_type) aNewLength * aNewLength;
if( std::is_integral<T>::value )
{
return VECTOR2<T> (
( x < 0 ? -1 : 1 ) *
KiROUND( std::sqrt( rescale( l_sq_new, (extended_type) x * x, l_sq_current ) ) ),
( y < 0 ? -1 : 1 ) *
KiROUND( std::sqrt( rescale( l_sq_new, (extended_type) y * y, l_sq_current ) ) ) )
* sign( aNewLength );
}
else
{
return VECTOR2<T> (
( x < 0 ? -1 : 1 ) *
std::sqrt( rescale( l_sq_new, (extended_type) x * x, l_sq_current ) ),
( y < 0 ? -1 : 1 ) *
std::sqrt( rescale( l_sq_new, (extended_type) y * y, l_sq_current ) ) )
* sign( aNewLength );
}
}
template <class T>
const std::string VECTOR2<T>::Format() const
{
std::stringstream ss;
ss << "( xy " << x << " " << y << " )";
return ss.str();
}
template <class T>
VECTOR2<T> VECTOR2<T>::operator+( const VECTOR2<T>& aVector ) const
{
return VECTOR2<T> ( x + aVector.x, y + aVector.y );
}
template <class T>
VECTOR2<T> VECTOR2<T>::operator+( const T& aScalar ) const
{
return VECTOR2<T> ( x + aScalar, y + aScalar );
}
template <class T>
VECTOR2<T> VECTOR2<T>::operator-( const VECTOR2<T>& aVector ) const
{
return VECTOR2<T> ( x - aVector.x, y - aVector.y );
}
template <class T>
VECTOR2<T> VECTOR2<T>::operator-( const T& aScalar ) const
{
return VECTOR2<T> ( x - aScalar, y - aScalar );
}
template <class T>
VECTOR2<T> VECTOR2<T>::operator-()
{
return VECTOR2<T> ( -x, -y );
}
template <class T>
typename VECTOR2<T>::extended_type VECTOR2<T>::operator*( const VECTOR2<T>& aVector ) const
{
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return (extended_type)aVector.x * x + (extended_type)aVector.y * y;
}
template <class T>
VECTOR2<T> VECTOR2<T>::operator*( const T& aFactor ) const
{
VECTOR2<T> vector( x * aFactor, y * aFactor );
return vector;
}
template <class T>
VECTOR2<T> VECTOR2<T>::operator/( const T& aFactor ) const
{
if( std::is_integral<T>::value )
return VECTOR2<T>( KiROUND( x / aFactor ), KiROUND( y / aFactor ) );
else
return VECTOR2<T>( x / aFactor, y / aFactor );
}
template <class T>
VECTOR2<T> operator*( const T& aFactor, const VECTOR2<T>& aVector )
{
VECTOR2<T> vector( aVector.x * aFactor, aVector.y * aFactor );
return vector;
}
template <class T>
typename VECTOR2<T>::extended_type VECTOR2<T>::Cross( const VECTOR2<T>& aVector ) const
{
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return (extended_type) x * (extended_type) aVector.y -
(extended_type) y * (extended_type) aVector.x;
}
template <class T>
typename VECTOR2<T>::extended_type VECTOR2<T>::Dot( const VECTOR2<T>& aVector ) const
{
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return (extended_type) x * (extended_type) aVector.x +
(extended_type) y * (extended_type) aVector.y;
}
template <class T>
bool VECTOR2<T>::operator<( const VECTOR2<T>& aVector ) const
{
return ( *this * *this ) < ( aVector * aVector );
}
template <class T>
bool VECTOR2<T>::operator<=( const VECTOR2<T>& aVector ) const
{
return ( *this * *this ) <= ( aVector * aVector );
}
template <class T>
bool VECTOR2<T>::operator>( const VECTOR2<T>& aVector ) const
{
return ( *this * *this ) > ( aVector * aVector );
}
template <class T>
bool VECTOR2<T>::operator>=( const VECTOR2<T>& aVector ) const
{
return ( *this * *this ) >= ( aVector * aVector );
}
template <class T>
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bool VECTOR2<T>::operator==( VECTOR2<T> const& aVector ) const
{
return ( aVector.x == x ) && ( aVector.y == y );
}
template <class T>
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bool VECTOR2<T>::operator!=( VECTOR2<T> const& aVector ) const
{
return ( aVector.x != x ) || ( aVector.y != y );
}
template <class T>
const VECTOR2<T> LexicographicalMax( const VECTOR2<T>& aA, const VECTOR2<T>& aB )
{
if( aA.x > aB.x )
return aA;
else if( aA.x == aB.x && aA.y > aB.y )
return aA;
return aB;
}
template <class T>
const VECTOR2<T> LexicographicalMin( const VECTOR2<T>& aA, const VECTOR2<T>& aB )
{
if( aA.x < aB.x )
return aA;
else if( aA.x == aB.x && aA.y < aB.y )
return aA;
return aB;
}
template <class T>
const int LexicographicalCompare( const VECTOR2<T>& aA, const VECTOR2<T>& aB )
{
if( aA.x < aB.x )
return -1;
else if( aA.x > aB.x )
return 1;
else // aA.x == aB.x
{
if( aA.y < aB.y )
return -1;
else if( aA.y > aB.y )
return 1;
else
return 0;
}
}
template <class T>
std::ostream& operator<<( std::ostream& aStream, const VECTOR2<T>& aVector )
{
aStream << "[ " << aVector.x << " | " << aVector.y << " ]";
return aStream;
}
/* Default specializations */
typedef VECTOR2<double> VECTOR2D;
typedef VECTOR2<int> VECTOR2I;
typedef VECTOR2<unsigned int> VECTOR2U;
/* STL specializations */
namespace std
{
// Required to enable correct use in std::map/unordered_map
template <>
struct hash<VECTOR2I>
{
size_t operator()( const VECTOR2I& k ) const;
};
// Required to enable use of std::hash with maps
template <>
struct less<VECTOR2I>
{
bool operator()( const VECTOR2I& aA, const VECTOR2I& aB ) const;
};
}
/* Compatibility typedefs */
// FIXME should be removed to avoid multiple typedefs for the same type
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typedef VECTOR2<double> DPOINT;
typedef DPOINT DSIZE;
#endif // VECTOR2D_H_