dust3d/thirdparty/cgal/CGAL-4.13/include/CGAL/Homogeneous/predicates_on_pointsH2.h

// Copyright (c) 1999,2016
// Utrecht University (The Netherlands),
// ETH Zurich (Switzerland),
// INRIA Sophia-Antipolis (France),
// Max-Planck-Institute Saarbruecken (Germany),
// and Tel-Aviv University (Israel).  All rights reserved. 
//
// This file is part of CGAL (www.cgal.org); you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public License as
// published by the Free Software Foundation; either version 3 of the License,
// or (at your option) any later version.
//
// Licensees holding a valid commercial license may use this file in
// accordance with the commercial license agreement provided with the software.
//
// This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
// WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
//
// $URL$
// $Id$
// SPDX-License-Identifier: LGPL-3.0+
// 
//
// Author(s)     : Stefan Schirra, Olivier Devillers, Mariette Yvinec
 

#ifndef CGAL_PREDICATES_ON_POINTSH2_H
#define CGAL_PREDICATES_ON_POINTSH2_H

#include <CGAL/Homogeneous/PointH2.h>

namespace CGAL {

template < class R>
CGAL_KERNEL_INLINE
bool
equal_xy(const PointH2<R>& p,
         const PointH2<R>& q)
{
  typedef typename R::RT RT;

  // Using these references allows to spare calls to [pq].hw().
  const RT& phw = p.hw();
  const RT& qhw = q.hw();

  return (p.hx()*qhw == q.hx()*phw) && (p.hy()*qhw == q.hy()*phw);
}

template <class R>
CGAL_KERNEL_MEDIUM_INLINE
Oriented_side
_where_wrt_L_wedge( const PointH2<R>& p, const PointH2<R>& q )
{
  Sign xs = CGAL_NTS sign( q.hx()*p.hw() - p.hx()*q.hw() );  // sign( qx - px )
  Sign ys = CGAL_NTS sign( q.hy()*p.hw() - p.hy()*q.hw() );  // sign( qy - py )

  if (( xs == NEGATIVE ) || ( ys == NEGATIVE ))
      return ON_NEGATIVE_SIDE;
  if (( xs == POSITIVE ) && ( ys == POSITIVE ))
      return ON_POSITIVE_SIDE;
  return ON_ORIENTED_BOUNDARY;
}

template <class RT>
Comparison_result
compare_power_distanceH2(const RT& phx, const RT& phy, const RT& phw,
			 const Quotient<RT>& pwt,
			 const RT& qhx, const RT& qhy, const RT& qhw,
			 const Quotient<RT>& qwt,
			 const RT& rhx, const RT& rhy, const RT& rhw)
{
  // returns SMALLER if r is closer to p w.r.t. the power metric
  RT dphx = rhx * phw - phx * rhw;
  RT dphy = rhy * phw - phy * rhw;
  RT dqhx = rhx * qhw - qhx * rhw;
  RT dqhy = rhy * qhw - qhy * rhw;
  RT dphw = CGAL_NTS square(phw);
  RT dqhw = CGAL_NTS square(qhw);
  RT drhw = CGAL_NTS square(rhw);

  RT npwt = pwt.numerator();
  RT dpwt = pwt.denominator();
  RT nqwt = qwt.numerator();
  RT dqwt = qwt.denominator();


  RT dh1 = (CGAL_NTS square(dphx) + CGAL_NTS square(dphy))*dpwt - npwt * dphw * drhw;
  RT dh2 = (CGAL_NTS square(dqhx) + CGAL_NTS square(dqhy))*dqwt - nqwt * dqhw * drhw;
  return CGAL_NTS compare(dh1 * dqhw * dqwt, dh2 * dphw * dpwt );
}


template <class RT>
Oriented_side
power_testH2( const RT &phx, const RT &phy, const RT &phw, const Quotient<RT> &pwt,
              const RT &qhx, const RT &qhy, const RT &qhw, const Quotient<RT> &qwt,
              const RT &rhx, const RT &rhy, const RT &rhw, const Quotient<RT> &rwt,
              const RT &thx, const RT &thy, const RT &thw, const Quotient<RT> &twt)
{
    RT npwt = pwt.numerator();
    RT dpwt = pwt.denominator();
    RT nqwt = qwt.numerator();
    RT dqwt = qwt.denominator();
    RT nrwt = rwt.numerator();
    RT drwt = rwt.denominator();
    RT ntwt = twt.numerator();
    RT dtwt = twt.denominator();

    RT dphx = phx*phw;
    RT dphy = phy*phw;
    RT dphw = CGAL_NTS square(phw);
    RT dpz = (CGAL_NTS square(phx) + CGAL_NTS square(phy))*dpwt  - npwt*dphw;

    RT dqhx = qhx*qhw;
    RT dqhy = qhy*qhw;
    RT dqhw = CGAL_NTS square(qhw);
    RT dqz = (CGAL_NTS square(qhx) + CGAL_NTS square(qhy))*dqwt - nqwt*dqhw;

    RT drhx = rhx*rhw;
    RT drhy = rhy*rhw;
    RT drhw = CGAL_NTS square(rhw);
    RT drz = (CGAL_NTS square(rhx) + CGAL_NTS square(rhy)) *drwt - nrwt*drhw;

    RT dthx = thx*thw;
    RT dthy = thy*thw;
    RT dthw = CGAL_NTS square(thw);
    RT dtz = (CGAL_NTS square(thx) + CGAL_NTS square(thy))*dtwt - ntwt*dthw;

    dthx *= dtwt;
    dthy *= dtwt;
    dthw *= dtwt;

    return sign_of_determinant(dphx, dphy, dpz, dphw,
	                       dqhx, dqhy, dqz, dqhw,
	                       drhx, drhy, drz, drhw,
	                       dthx, dthy, dtz, dthw);
}


template <class RT>
Oriented_side
power_testH2( const RT &phx, const RT &phy, const RT &phw, const Quotient<RT> &pwt,
              const RT &qhx, const RT &qhy, const RT &qhw, const Quotient<RT> &qwt,
              const RT &thx, const RT &thy, const RT &thw, const Quotient<RT> &twt)
{
    RT npwt = pwt.numerator();
    RT dpwt = pwt.denominator();
    RT nqwt = qwt.numerator();
    RT dqwt = qwt.denominator();
    RT ntwt = twt.numerator();
    RT dtwt = twt.denominator();

    // Test if we can project on the (x) axis.  If not, then on the
    // (y) axis
    RT pa, qa, ta;

    if (phx * qhw != qhx * phw )
    {
	pa = phx*phw;
	qa = qhx*qhw;
	ta = thx*thw;
    }
    else
    {   
	pa = phy*phw;
	qa = qhy*qhw;
	ta = thy*thw;
    }

    RT dphw = CGAL_NTS square(phw);
    RT dpz = (CGAL_NTS square(phx) + CGAL_NTS square(phy))*dpwt - npwt*dphw;

    RT dqhw = CGAL_NTS square(qhw);
    RT dqz = (CGAL_NTS square(qhx) + CGAL_NTS square(qhy))*dqwt - nqwt*dqhw;

    RT dthw = CGAL_NTS square(thw);
    RT dtz = (CGAL_NTS square(thx) + CGAL_NTS square(thy))*dtwt - ntwt*dthw;

    pa *= dtwt;
    qa *= dtwt;
    ta *= dtwt;

    return CGAL_NTS compare(pa, qa) * sign_of_determinant(pa, dpz, dphw,
				                          qa, dqz, dqhw,
				                          ta, dtz, dthw);
}

#if 0
// Unused, undocumented, un-functorized.
template < class R >
CGAL_KERNEL_MEDIUM_INLINE
Comparison_result
compare_deltax_deltay(const PointH2<R>& p,
                      const PointH2<R>& q,
                      const PointH2<R>& r,
                      const PointH2<R>& s)
{
  return CGAL_NTS compare(
                  CGAL_NTS abs(p.hx()*q.hw() - q.hx()*p.hw()) * r.hw()*s.hw(),
                  CGAL_NTS abs(r.hy()*s.hw() - s.hy()*r.hw()) * p.hw()*q.hw());
}
#endif

} //namespace CGAL

#endif // CGAL_PREDICATES_ON_POINTSH2_H
Integrate Instant-Meshes 1. Drop windows 32bit support Add windows 64bit support. 2. Remove Script(quickjs) support The current integrated quickjs is a very old version which doesn’t support windows 64bit system. In the future, (TODO)WebAssembly should be integrate as plugin system. 3. Integrate Instant-Meshes Instant-Meshes take less than 1 second on all three platforms. 4. Remove QuadriFlow Current implementation of QuadriFlow is too slow (take about 5 seconds on the example model) to do realtime remeshing. 2020-01-04 10:29:10 +00:00			`// Copyright (c) 1999,2016`
			`// Utrecht University (The Netherlands),`
			`// ETH Zurich (Switzerland),`
			`// INRIA Sophia-Antipolis (France),`
			`// Max-Planck-Institute Saarbruecken (Germany),`
			`// and Tel-Aviv University (Israel). All rights reserved.`
			`//`
			`// This file is part of CGAL (www.cgal.org); you can redistribute it and/or`
			`// modify it under the terms of the GNU Lesser General Public License as`
			`// published by the Free Software Foundation; either version 3 of the License,`
			`// or (at your option) any later version.`
			`//`
			`// Licensees holding a valid commercial license may use this file in`
			`// accordance with the commercial license agreement provided with the software.`
			`//`
			`// This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE`
			`// WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.`
			`//`
			`// $URL$`
			`// $Id$`
			`// SPDX-License-Identifier: LGPL-3.0+`
			`//`
			`//`
			`// Author(s) : Stefan Schirra, Olivier Devillers, Mariette Yvinec`


			`#ifndef CGAL_PREDICATES_ON_POINTSH2_H`
			`#define CGAL_PREDICATES_ON_POINTSH2_H`

			`#include <CGAL/Homogeneous/PointH2.h>`

			`namespace CGAL {`

			`template < class R>`
			`CGAL_KERNEL_INLINE`
			`bool`
			`equal_xy(const PointH2<R>& p,`
			`const PointH2<R>& q)`
			`{`
			`typedef typename R::RT RT;`

			`// Using these references allows to spare calls to [pq].hw().`
			`const RT& phw = p.hw();`
			`const RT& qhw = q.hw();`

			`return (p.hx()qhw == q.hx()phw) && (p.hy()qhw == q.hy()phw);`
			`}`

			`template <class R>`
			`CGAL_KERNEL_MEDIUM_INLINE`
			`Oriented_side`
			`_where_wrt_L_wedge( const PointH2<R>& p, const PointH2<R>& q )`
			`{`
			`Sign xs = CGAL_NTS sign( q.hx()p.hw() - p.hx()q.hw() ); // sign( qx - px )`
			`Sign ys = CGAL_NTS sign( q.hy()p.hw() - p.hy()q.hw() ); // sign( qy - py )`

			`if (( xs == NEGATIVE ) \|\| ( ys == NEGATIVE ))`
			`return ON_NEGATIVE_SIDE;`
			`if (( xs == POSITIVE ) && ( ys == POSITIVE ))`
			`return ON_POSITIVE_SIDE;`
			`return ON_ORIENTED_BOUNDARY;`
			`}`

			`template <class RT>`
			`Comparison_result`
			`compare_power_distanceH2(const RT& phx, const RT& phy, const RT& phw,`
			`const Quotient<RT>& pwt,`
			`const RT& qhx, const RT& qhy, const RT& qhw,`
			`const Quotient<RT>& qwt,`
			`const RT& rhx, const RT& rhy, const RT& rhw)`
			`{`
			`// returns SMALLER if r is closer to p w.r.t. the power metric`
			`RT dphx = rhx * phw - phx * rhw;`
			`RT dphy = rhy * phw - phy * rhw;`
			`RT dqhx = rhx * qhw - qhx * rhw;`
			`RT dqhy = rhy * qhw - qhy * rhw;`
			`RT dphw = CGAL_NTS square(phw);`
			`RT dqhw = CGAL_NTS square(qhw);`
			`RT drhw = CGAL_NTS square(rhw);`

			`RT npwt = pwt.numerator();`
			`RT dpwt = pwt.denominator();`
			`RT nqwt = qwt.numerator();`
			`RT dqwt = qwt.denominator();`


			`RT dh1 = (CGAL_NTS square(dphx) + CGAL_NTS square(dphy))dpwt - npwt dphw * drhw;`
			`RT dh2 = (CGAL_NTS square(dqhx) + CGAL_NTS square(dqhy))dqwt - nqwt dqhw * drhw;`
			`return CGAL_NTS compare(dh1 * dqhw * dqwt, dh2 * dphw * dpwt );`
			`}`


			`template <class RT>`
			`Oriented_side`
			`power_testH2( const RT &phx, const RT &phy, const RT &phw, const Quotient<RT> &pwt,`
			`const RT &qhx, const RT &qhy, const RT &qhw, const Quotient<RT> &qwt,`
			`const RT &rhx, const RT &rhy, const RT &rhw, const Quotient<RT> &rwt,`
			`const RT &thx, const RT &thy, const RT &thw, const Quotient<RT> &twt)`
			`{`
			`RT npwt = pwt.numerator();`
			`RT dpwt = pwt.denominator();`
			`RT nqwt = qwt.numerator();`
			`RT dqwt = qwt.denominator();`
			`RT nrwt = rwt.numerator();`
			`RT drwt = rwt.denominator();`
			`RT ntwt = twt.numerator();`
			`RT dtwt = twt.denominator();`

			`RT dphx = phx*phw;`
			`RT dphy = phy*phw;`
			`RT dphw = CGAL_NTS square(phw);`
			`RT dpz = (CGAL_NTS square(phx) + CGAL_NTS square(phy))dpwt - npwtdphw;`

			`RT dqhx = qhx*qhw;`
			`RT dqhy = qhy*qhw;`
			`RT dqhw = CGAL_NTS square(qhw);`
			`RT dqz = (CGAL_NTS square(qhx) + CGAL_NTS square(qhy))dqwt - nqwtdqhw;`

			`RT drhx = rhx*rhw;`
			`RT drhy = rhy*rhw;`
			`RT drhw = CGAL_NTS square(rhw);`
			`RT drz = (CGAL_NTS square(rhx) + CGAL_NTS square(rhy)) drwt - nrwtdrhw;`

			`RT dthx = thx*thw;`
			`RT dthy = thy*thw;`
			`RT dthw = CGAL_NTS square(thw);`
			`RT dtz = (CGAL_NTS square(thx) + CGAL_NTS square(thy))dtwt - ntwtdthw;`

			`dthx *= dtwt;`
			`dthy *= dtwt;`
			`dthw *= dtwt;`

			`return sign_of_determinant(dphx, dphy, dpz, dphw,`
			`dqhx, dqhy, dqz, dqhw,`
			`drhx, drhy, drz, drhw,`
			`dthx, dthy, dtz, dthw);`
			`}`


			`template <class RT>`
			`Oriented_side`
			`power_testH2( const RT &phx, const RT &phy, const RT &phw, const Quotient<RT> &pwt,`
			`const RT &qhx, const RT &qhy, const RT &qhw, const Quotient<RT> &qwt,`
			`const RT &thx, const RT &thy, const RT &thw, const Quotient<RT> &twt)`
			`{`
			`RT npwt = pwt.numerator();`
			`RT dpwt = pwt.denominator();`
			`RT nqwt = qwt.numerator();`
			`RT dqwt = qwt.denominator();`
			`RT ntwt = twt.numerator();`
			`RT dtwt = twt.denominator();`

			`// Test if we can project on the (x) axis. If not, then on the`
			`// (y) axis`
			`RT pa, qa, ta;`

			`if (phx * qhw != qhx * phw )`
			`{`
			`pa = phx*phw;`
			`qa = qhx*qhw;`
			`ta = thx*thw;`
			`}`
			`else`
			`{`
			`pa = phy*phw;`
			`qa = qhy*qhw;`
			`ta = thy*thw;`
			`}`

			`RT dphw = CGAL_NTS square(phw);`
			`RT dpz = (CGAL_NTS square(phx) + CGAL_NTS square(phy))dpwt - npwtdphw;`

			`RT dqhw = CGAL_NTS square(qhw);`
			`RT dqz = (CGAL_NTS square(qhx) + CGAL_NTS square(qhy))dqwt - nqwtdqhw;`

			`RT dthw = CGAL_NTS square(thw);`
			`RT dtz = (CGAL_NTS square(thx) + CGAL_NTS square(thy))dtwt - ntwtdthw;`

			`pa *= dtwt;`
			`qa *= dtwt;`
			`ta *= dtwt;`

			`return CGAL_NTS compare(pa, qa) * sign_of_determinant(pa, dpz, dphw,`
			`qa, dqz, dqhw,`
			`ta, dtz, dthw);`
			`}`

			`#if 0`
			`// Unused, undocumented, un-functorized.`
			`template < class R >`
			`CGAL_KERNEL_MEDIUM_INLINE`
			`Comparison_result`
			`compare_deltax_deltay(const PointH2<R>& p,`
			`const PointH2<R>& q,`
			`const PointH2<R>& r,`
			`const PointH2<R>& s)`
			`{`
			`return CGAL_NTS compare(`
			`CGAL_NTS abs(p.hx()q.hw() - q.hx()p.hw()) * r.hw()*s.hw(),`
			`CGAL_NTS abs(r.hy()s.hw() - s.hy()r.hw()) * p.hw()*q.hw());`
			`}`
			`#endif`

			`} //namespace CGAL`

			`#endif // CGAL_PREDICATES_ON_POINTSH2_H`