dust3d/thirdparty/cgal/CGAL-5.1/include/CGAL/constructions/kernel_ftC2.h

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// Copyright (c) 2000
// Utrecht University (The Netherlands),
// ETH Zurich (Switzerland),
// INRIA Sophia-Antipolis (France),
// Max-Planck-Institute Saarbruecken (Germany),
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// and Tel-Aviv University (Israel). All rights reserved.
//
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// This file is part of CGAL (www.cgal.org)
//
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// $URL: https://github.com/CGAL/cgal/blob/v5.1/Cartesian_kernel/include/CGAL/constructions/kernel_ftC2.h $
// $Id: kernel_ftC2.h 5c41857 2020-04-08T13:03:50+02:00 Maxime Gimeno
// SPDX-License-Identifier: LGPL-3.0-or-later OR LicenseRef-Commercial
//
//
// Author(s) : Sven Schoenherr, Herve Bronnimann, Sylvain Pion
#ifndef CGAL_CONSTRUCTIONS_KERNEL_FTC2_H
#define CGAL_CONSTRUCTIONS_KERNEL_FTC2_H
#include <CGAL/determinant.h>
#include <CGAL/number_utils.h>
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#include <boost/type_traits/is_integral.hpp>
namespace CGAL {
template < class FT >
CGAL_KERNEL_INLINE
void
midpointC2( const FT &px, const FT &py,
const FT &qx, const FT &qy,
FT &x, FT &y )
{
x = (px+qx) / 2;
y = (py+qy) / 2;
}
template < class FT >
CGAL_KERNEL_LARGE_INLINE
void
circumcenter_translateC2(const FT &dqx, const FT &dqy,
const FT &drx, const FT &dry,
FT &dcx, FT &dcy)
{
// Given 3 points P, Q, R, this function takes as input:
// qx-px, qy-py, rx-px, ry-py. And returns cx-px, cy-py,
// where (cx, cy) are the coordinates of the circumcenter C.
// What we do is intersect the bisectors.
FT r2 = CGAL_NTS square(drx) + CGAL_NTS square(dry);
FT q2 = CGAL_NTS square(dqx) + CGAL_NTS square(dqy);
FT den = 2 * determinant(dqx, dqy, drx, dry);
// The 3 points aren't collinear.
// Hopefully, this is already checked at the upper level.
CGAL_kernel_assertion ( ! CGAL_NTS is_zero(den) );
// One possible optimization here is to precompute 1/den, to avoid one
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// division. However, we lose precision, and it's maybe not worth it (?).
dcx = determinant (dry, dqy, r2, q2) / den;
dcy = - determinant (drx, dqx, r2, q2) / den;
}
template < class FT >
CGAL_KERNEL_MEDIUM_INLINE
void
circumcenterC2( const FT &px, const FT &py,
const FT &qx, const FT &qy,
const FT &rx, const FT &ry,
FT &x, FT &y )
{
circumcenter_translateC2<FT>(qx-px, qy-py, rx-px, ry-py, x, y);
x += px;
y += py;
}
template < class FT >
void
barycenterC2(const FT &p1x, const FT &p1y, const FT &w1,
const FT &p2x, const FT &p2y,
FT &x, FT &y)
{
FT w2 = 1 - w1;
x = w1 * p1x + w2 * p2x;
y = w1 * p1y + w2 * p2y;
}
template < class FT >
void
barycenterC2(const FT &p1x, const FT &p1y, const FT &w1,
const FT &p2x, const FT &p2y, const FT &w2,
FT &x, FT &y)
{
FT sum = w1 + w2;
CGAL_kernel_assertion(sum != 0);
x = (w1 * p1x + w2 * p2x) / sum;
y = (w1 * p1y + w2 * p2y) / sum;
}
template < class FT >
void
barycenterC2(const FT &p1x, const FT &p1y, const FT &w1,
const FT &p2x, const FT &p2y, const FT &w2,
const FT &p3x, const FT &p3y,
FT &x, FT &y)
{
FT w3 = 1 - w1 - w2;
x = w1 * p1x + w2 * p2x + w3 * p3x;
y = w1 * p1y + w2 * p2y + w3 * p3y;
}
template < class FT >
void
barycenterC2(const FT &p1x, const FT &p1y, const FT &w1,
const FT &p2x, const FT &p2y, const FT &w2,
const FT &p3x, const FT &p3y, const FT &w3,
FT &x, FT &y)
{
FT sum = w1 + w2 + w3;
CGAL_kernel_assertion(sum != 0);
x = (w1 * p1x + w2 * p2x + w3 * p3x) / sum;
y = (w1 * p1y + w2 * p2y + w3 * p3y) / sum;
}
template < class FT >
void
barycenterC2(const FT &p1x, const FT &p1y, const FT &w1,
const FT &p2x, const FT &p2y, const FT &w2,
const FT &p3x, const FT &p3y, const FT &w3,
const FT &p4x, const FT &p4y,
FT &x, FT &y)
{
FT w4 = 1 - w1 - w2 - w3;
x = w1 * p1x + w2 * p2x + w3 * p3x + w4 * p4x;
y = w1 * p1y + w2 * p2y + w3 * p3y + w4 * p4y;
}
template < class FT >
void
barycenterC2(const FT &p1x, const FT &p1y, const FT &w1,
const FT &p2x, const FT &p2y, const FT &w2,
const FT &p3x, const FT &p3y, const FT &w3,
const FT &p4x, const FT &p4y, const FT &w4,
FT &x, FT &y)
{
FT sum = w1 + w2 + w3 + w4;
CGAL_kernel_assertion(sum != 0);
x = (w1 * p1x + w2 * p2x + w3 * p3x + w4 * p4x) / sum;
y = (w1 * p1y + w2 * p2y + w3 * p3y + w4 * p4y) / sum;
}
template < class FT >
CGAL_KERNEL_MEDIUM_INLINE
void
centroidC2( const FT &px, const FT &py,
const FT &qx, const FT &qy,
const FT &rx, const FT &ry,
FT &x, FT &y)
{
x = (px + qx + rx) / 3;
y = (py + qy + ry) / 3;
}
template < class FT >
CGAL_KERNEL_MEDIUM_INLINE
void
centroidC2( const FT &px, const FT &py,
const FT &qx, const FT &qy,
const FT &rx, const FT &ry,
const FT &sx, const FT &sy,
FT &x, FT &y)
{
x = (px + qx + rx + sx) / 4;
y = (py + qy + ry + sy) / 4;
}
template < class FT >
inline
void
line_from_pointsC2(const FT &px, const FT &py,
const FT &qx, const FT &qy,
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FT &a, FT &b, FT &c)
{
// The horizontal and vertical line get a special treatment
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// in order to make the intersection code robust for doubles
if(py == qy){
a = 0 ;
if(qx > px){
b = 1;
c = -py;
} else if(qx == px){
b = 0;
c = 0;
}else{
b = -1;
c = py;
}
} else if(qx == px){
b = 0;
if(qy > py){
a = -1;
c = px;
} else if (qy == py){
a = 0;
c = 0;
} else {
a = 1;
c = -px;
}
} else {
a = py - qy;
b = qx - px;
c = -px*a - py*b;
}
}
template < class FT >
inline
void
line_from_point_directionC2(const FT &px, const FT &py,
const FT &dx, const FT &dy,
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FT &a, FT &b, FT &c)
{
a = - dy;
b = dx;
c = px*dy - py*dx;
}
template < class FT >
CGAL_KERNEL_INLINE
void
bisector_of_pointsC2(const FT &px, const FT &py,
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const FT &qx, const FT &qy,
FT &a, FT &b, FT& c )
{
a = 2 * (px - qx);
b = 2 * (py - qy);
c = CGAL_NTS square(qx) + CGAL_NTS square(qy) -
CGAL_NTS square(px) - CGAL_NTS square(py);
}
template < class FT >
CGAL_KERNEL_INLINE
void
bisector_of_linesC2(const FT &pa, const FT &pb, const FT &pc,
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const FT &qa, const FT &qb, const FT &qc,
FT &a, FT &b, FT &c)
{
// We normalize the equations of the 2 lines, and we then add them.
FT n1 = CGAL_NTS sqrt(CGAL_NTS square(pa) + CGAL_NTS square(pb));
FT n2 = CGAL_NTS sqrt(CGAL_NTS square(qa) + CGAL_NTS square(qb));
a = n2 * pa + n1 * qa;
b = n2 * pb + n1 * qb;
c = n2 * pc + n1 * qc;
// Care must be taken for the case when this produces a degenerate line.
if (a == 0 && b == 0) {
a = n2 * pa - n1 * qa;
b = n2 * pb - n1 * qb;
c = n2 * pc - n1 * qc;
}
}
template < class FT >
inline
FT
line_y_at_xC2(const FT &a, const FT &b, const FT &c, const FT &x)
{
return (-a*x-c) / b;
}
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// Silence a warning for MSVC 2017
// > include\cgal\constructions\kernel_ftc2.h(287) :
// > warning C4723: potential divide by 0
#if defined(BOOST_MSVC)
#pragma warning(push)
#pragma warning(disable:4723)
#endif
template < class FT >
inline
void
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line_get_pointC2(const FT &a, const FT &b, const FT &c, const FT &i,
FT &x, FT &y)
{
if (CGAL_NTS is_zero(b))
{
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x = -c/a;
y = 1 - i * a;
}
else
{
x = 1 + i * b;
y = -(a+c)/b - i * a;
}
}
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#if defined(BOOST_MSVC)
#pragma warning(pop)
#endif
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template < class FT >
inline
void
perpendicular_through_pointC2(const FT &la, const FT &lb,
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const FT &px, const FT &py,
FT &a, FT &b, FT &c)
{
a = -lb;
b = la;
c = lb * px - la * py;
}
template < class FT >
CGAL_KERNEL_MEDIUM_INLINE
void
line_project_pointC2(const FT &la, const FT &lb, const FT &lc,
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const FT &px, const FT &py,
FT &x, FT &y)
{
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if (certainly(is_zero(la))) // horizontal line
{
x = px;
y = -lc/lb;
}
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else if (certainly(is_zero(lb))) // vertical line
{
x = -lc/la;
y = py;
}
else
{
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FT a2 = CGAL_NTS square(la);
FT b2 = CGAL_NTS square(lb);
FT d = a2 + b2;
x = (b2*px - la*lb*py - la*lc) / d;
y = (-la*lb*px + a2*py - lb*lc) / d;
}
}
template < class FT >
CGAL_KERNEL_MEDIUM_INLINE
FT
squared_radiusC2(const FT &px, const FT &py,
const FT &qx, const FT &qy,
const FT &rx, const FT &ry,
FT &x, FT &y )
{
circumcenter_translateC2(qx-px, qy-py, rx-px, ry-py, x, y);
FT r2 = CGAL_NTS square(x) + CGAL_NTS square(y);
x += px;
y += py;
return r2;
}
template < class FT >
CGAL_KERNEL_MEDIUM_INLINE
FT
squared_radiusC2(const FT &px, const FT &py,
const FT &qx, const FT &qy,
const FT &rx, const FT &ry)
{
FT x, y;
circumcenter_translateC2<FT>(qx-px, qy-py, rx-px, ry-py, x, y);
return CGAL_NTS square(x) + CGAL_NTS square(y);
}
template < class FT >
inline
FT
squared_distanceC2( const FT &px, const FT &py,
const FT &qx, const FT &qy)
{
return CGAL_NTS square(px-qx) + CGAL_NTS square(py-qy);
}
template < class FT >
inline
FT
squared_radiusC2(const FT &px, const FT &py,
const FT &qx, const FT &qy)
{
return squared_distanceC2(px, py,qx, qy) / 4;
}
template < class FT >
CGAL_KERNEL_INLINE
FT
scaled_distance_to_lineC2( const FT &la, const FT &lb, const FT &lc,
const FT &px, const FT &py)
{
// for comparisons, use distance_to_directionsC2 instead
// since lc is irrelevant
return la*px + lb*py + lc;
}
template < class FT >
CGAL_KERNEL_INLINE
FT
scaled_distance_to_directionC2( const FT &la, const FT &lb,
const FT &px, const FT &py)
{
// scalar product with direction
return la*px + lb*py;
}
template < class FT >
CGAL_KERNEL_MEDIUM_INLINE
FT
scaled_distance_to_lineC2( const FT &px, const FT &py,
const FT &qx, const FT &qy,
const FT &rx, const FT &ry)
{
return determinant<FT>(px-rx, py-ry, qx-rx, qy-ry);
}
template < class RT >
void
weighted_circumcenter_translateC2(const RT &dqx, const RT &dqy, const RT &dqw,
const RT &drx, const RT &dry, const RT &drw,
RT &dcx, RT &dcy)
{
// Given 3 points P, Q, R, this function takes as input:
// qx-px, qy-py,qw-pw, rx-px, ry-py, rw-pw. And returns cx-px, cy-py,
// where (cx, cy) are the coordinates of the circumcenter C.
// What we do is intersect the radical axis
RT r2 = CGAL_NTS square(drx) + CGAL_NTS square(dry) - drw;
RT q2 = CGAL_NTS square(dqx) + CGAL_NTS square(dqy) - dqw;
RT den = RT(2) * determinant(dqx, dqy, drx, dry);
// The 3 points aren't collinear.
// Hopefully, this is already checked at the upper level.
CGAL_assertion ( den != RT(0) );
// One possible optimization here is to precompute 1/den, to avoid one
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// division. However, we lose precision, and it's maybe not worth it (?).
dcx = determinant (dry, dqy, r2, q2) / den;
dcy = - determinant (drx, dqx, r2, q2) / den;
}
//template < class RT >
template < class RT, class We>
void
weighted_circumcenterC2( const RT &px, const RT &py, const We &pw,
const RT &qx, const RT &qy, const We &qw,
const RT &rx, const RT &ry, const We &rw,
RT &x, RT &y )
{
RT dqw = RT(qw-pw);
RT drw = RT(rw-pw);
weighted_circumcenter_translateC2<RT>(qx-px, qy-py, dqw,rx-px, ry-py,drw,x, y);
x += px;
y += py;
}
template< class FT >
FT
power_productC2(const FT &px, const FT &py, const FT &pw,
const FT &qx, const FT &qy, const FT &qw)
{
// computes the power product of two weighted points
FT qpx = qx - px;
FT qpy = qy - py;
FT qp2 = CGAL_NTS square(qpx) + CGAL_NTS square(qpy);
return qp2 - pw - qw;
}
template < class RT , class We>
void
radical_axisC2(const RT &px, const RT &py, const We &pw,
const RT &qx, const RT &qy, const We &qw,
RT &a, RT &b, RT& c )
{
a = RT(2)*(px - qx);
b = RT(2)*(py - qy);
c = - CGAL_NTS square(px) - CGAL_NTS square(py)
+ CGAL_NTS square(qx) + CGAL_NTS square(qy)
+ RT(pw) - RT(qw);
}
template< class FT >
CGAL_KERNEL_MEDIUM_INLINE
FT
squared_radius_orthogonal_circleC2(const FT &px, const FT &py, const FT &pw,
const FT &qx, const FT &qy, const FT &qw,
const FT &rx, const FT &ry, const FT &rw)
{
FT FT4(4);
FT dpx = px - rx;
FT dpy = py - ry;
FT dqx = qx - rx;
FT dqy = qy - ry;
FT dpp = CGAL_NTS square(dpx) + CGAL_NTS square(dpy) - pw + rw;
FT dqq = CGAL_NTS square(dqx) + CGAL_NTS square(dqy) - qw + rw;
FT det0 = determinant(dpx, dpy, dqx, dqy);
FT det1 = determinant(dpp, dpy, dqq, dqy);
FT det2 = determinant(dpx, dpp, dqx, dqq);
return (CGAL_NTS square(det1) + CGAL_NTS square(det2)) /
(FT4 * CGAL_NTS square(det0)) - rw;
}
template< class FT >
CGAL_KERNEL_MEDIUM_INLINE
FT
squared_radius_smallest_orthogonal_circleC2(const FT &px, const FT &py, const FT &pw,
const FT &qx, const FT &qy, const FT &qw)
{
FT FT4(4);
FT dpz = CGAL_NTS square(px - qx) + CGAL_NTS square(py - qy);
return (CGAL_NTS square(dpz - pw + qw) / (FT4 * dpz) - qw);
}
} //namespace CGAL
#endif // CGAL_CONSTRUCTIONS_KERNEL_FTC2_H