403 lines
11 KiB
C++
403 lines
11 KiB
C++
/*
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* This program source code file is part of KiCad, a free EDA CAD application.
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*
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* Copyright (C) 2015-2017 Mario Luzeiro <mrluzeiro@ua.pt>
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* Copyright (C) 1992-2017 KiCad Developers, see AUTHORS.txt for contributors.
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, you may find one here:
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* http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
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* or you may search the http://www.gnu.org website for the version 2 license,
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* or you may write to the Free Software Foundation, Inc.,
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* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
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*/
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/**
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* @file ray.cpp
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* @brief
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*/
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#include "ray.h"
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#include "../../3d_fastmath.h"
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#include <cstdio>
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#include <wx/debug.h>
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#include <cmath>
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//static unsigned int gs_next_rayID = 0;
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void RAY::Init( const SFVEC3F& o, const SFVEC3F& d )
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{
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m_Origin = o;
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m_Dir = d;
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m_InvDir = 1.0f / d;
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//rayID = gs_next_rayID;
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//gs_next_rayID++;
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// An Efficient and Robust Ray–Box Intersection Algorithm
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// Amy Williams Steve Barrus R. Keith Morley Peter Shirley
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// University of Utah
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// http://people.csail.mit.edu/amy/papers/box-jgt.pdf
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m_dirIsNeg[0] = m_Dir.x < 0.0f;
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m_dirIsNeg[1] = m_Dir.y < 0.0f;
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m_dirIsNeg[2] = m_Dir.z < 0.0f;
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// ray slope
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// "Fast Ray / Axis-Aligned Bounding Box Overlap Tests using Ray Slopes"
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// by Martin Eisemann, Thorsten Grosch, Stefan Müller and Marcus Magnor
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// Computer Graphics Lab, TU Braunschweig, Germany and
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// University of Koblenz-Landau, Germany
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// Licence: "This source code is public domain, but please mention us if you use it."
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//
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// https://github.com/rjw57/mcvoxel/tree/master/third-party/rayslope
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// https://github.com/rjw57/mcvoxel/blob/master/third-party/rayslope/ray.cpp
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ibyj = m_Dir.x * m_InvDir.y;
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jbyi = m_Dir.y * m_InvDir.x;
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jbyk = m_Dir.y * m_InvDir.z;
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kbyj = m_Dir.z * m_InvDir.y;
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ibyk = m_Dir.x * m_InvDir.z;
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kbyi = m_Dir.z * m_InvDir.x;
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c_xy = m_Origin.y - jbyi * m_Origin.x;
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c_xz = m_Origin.z - kbyi * m_Origin.x;
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c_yx = m_Origin.x - ibyj * m_Origin.y;
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c_yz = m_Origin.z - kbyj * m_Origin.y;
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c_zx = m_Origin.x - ibyk * m_Origin.z;
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c_zy = m_Origin.y - jbyk * m_Origin.z;
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// ray slope classification
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if( m_Dir.x < 0 )
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{
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if( m_Dir.y < 0 )
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{
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if( m_Dir.z < 0 )
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{
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m_Classification = MMM;
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}
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else if( m_Dir.z > 0 ){
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m_Classification = MMP;
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}
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else//( m_Dir.z >= 0 )
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{
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m_Classification = MMO;
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}
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}
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else//( m_Dir.y >= 0 )
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{
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if( m_Dir.z < 0 )
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{
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m_Classification = MPM;
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if( m_Dir.y == 0 )
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m_Classification = MOM;
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}
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else//( m_Dir.z >= 0 )
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{
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if( ( m_Dir.y == 0 ) && ( m_Dir.z == 0 ) )
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m_Classification = MOO;
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else if( m_Dir.z == 0 )
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m_Classification = MPO;
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else if( m_Dir.y == 0 )
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m_Classification = MOP;
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else
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m_Classification = MPP;
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}
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}
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}
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else//( m_Dir.x >= 0 )
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{
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if( m_Dir.y < 0 )
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{
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if( m_Dir.z < 0 )
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{
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m_Classification = PMM;
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if( m_Dir.x == 0 )
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m_Classification = OMM;
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}
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else//( m_Dir.z >= 0 )
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{
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if( ( m_Dir.x == 0 ) && ( m_Dir.z == 0 ) )
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m_Classification = OMO;
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else if( m_Dir.z == 0 )
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m_Classification = PMO;
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else if( m_Dir.x == 0 )
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m_Classification = OMP;
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else
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m_Classification = PMP;
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}
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}
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else//( m_Dir.y >= 0 )
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{
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if( m_Dir.z < 0 )
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{
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if( ( m_Dir.x == 0 ) && ( m_Dir.y == 0 ) )
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m_Classification = OOM;
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else if( m_Dir.x == 0 )
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m_Classification = OPM;
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else if( m_Dir.y == 0 )
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m_Classification = POM;
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else
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m_Classification = PPM;
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}
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else//( m_Dir.z > 0 )
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{
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if( m_Dir.x == 0 )
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{
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if( m_Dir.y == 0 )
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m_Classification = OOP;
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else if( m_Dir.z == 0 )
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m_Classification = OPO;
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else
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m_Classification = OPP;
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}
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else
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{
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if( ( m_Dir.y == 0 ) && ( m_Dir.z == 0 ) )
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m_Classification = POO;
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else if( m_Dir.y == 0 )
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m_Classification = POP;
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else if( m_Dir.z == 0 )
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m_Classification = PPO;
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else
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m_Classification = PPP;
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}
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}
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}
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}
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}
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bool IntersectSegment( const SFVEC2F &aStartA, const SFVEC2F &aEnd_minus_startA,
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const SFVEC2F &aStartB, const SFVEC2F &aEnd_minus_startB )
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{
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float rxs = aEnd_minus_startA.x *
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aEnd_minus_startB.y - aEnd_minus_startA.y *
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aEnd_minus_startB.x;
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if( std::abs( rxs ) > glm::epsilon<float>() )
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{
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float inv_rxs = 1.0f / rxs;
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SFVEC2F pq = aStartB - aStartA;
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float t = (pq.x * aEnd_minus_startB.y - pq.y * aEnd_minus_startB.x) * inv_rxs;
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if( (t < 0.0f) || (t > 1.0f) )
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return false;
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float u = (pq.x * aEnd_minus_startA.y - pq.y * aEnd_minus_startA.x) * inv_rxs;
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if( (u < 0.0f) || (u > 1.0f) )
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return false;
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return true;
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}
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return false;
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}
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// !TODO: not tested
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bool RAY::IntersectSphere( const SFVEC3F &aCenter, float aRadius, float &aOutT0, float &aOutT1 ) const
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{
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/*
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// Ray-sphere intersection: algebraic
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SFVEC3F CO = m_Origin - aCenter;
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float a = glm::dot( m_Dir, m_Dir );
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float b = 2.0f * glm::dot( CO, m_Dir );
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float c = glm::dot( CO, CO ) - aRadius*aRadius;
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float discriminant = b * b - 4.0f * a * c;
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if( discriminant < 0.0f )
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return false;
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aOutT0 = (-b - sqrtf(discriminant)) / (2.0f * a);
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aOutT1 = (-b + sqrtf(discriminant)) / (2.0f * a);
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if( aOutT0 > aOutT1 )
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{
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float temp = aOutT0;
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aOutT0 = aOutT1;
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aOutT1 = temp;
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}
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return true;
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*/
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// Ray-sphere intersection: geometric
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SFVEC3F OC = aCenter - m_Origin;
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float p_dot_d = glm::dot( OC, m_Dir );
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if( p_dot_d < 0.0f )
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return 0.0f;
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float p_dot_p = glm::dot( OC, OC );
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float discriminant = p_dot_p - p_dot_d * p_dot_d;
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if( discriminant > aRadius*aRadius )
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return false;
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discriminant = sqrtf( aRadius*aRadius - discriminant );
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aOutT0 = p_dot_d - discriminant;
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aOutT1 = p_dot_d + discriminant;
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if( aOutT0 > aOutT1 )
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{
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float temp = aOutT0;
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aOutT0 = aOutT1;
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aOutT1 = temp;
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}
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return true;
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}
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RAYSEG2D::RAYSEG2D( const SFVEC2F& s, const SFVEC2F& e )
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{
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m_Start = s;
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m_End = e;
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m_End_minus_start = e - s;
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m_Length = glm::length( m_End_minus_start );
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m_Dir = glm::normalize( m_End_minus_start );
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m_InvDir = (1.0f / m_Dir);
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if( fabs(m_Dir.x) < FLT_EPSILON )
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m_InvDir.x = NextFloatDown(FLT_MAX);
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if( fabs(m_Dir.y) < FLT_EPSILON )
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m_InvDir.y = NextFloatDown(FLT_MAX);
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m_DOT_End_minus_start = glm::dot( m_End_minus_start, m_End_minus_start );
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}
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bool RAYSEG2D::IntersectSegment( const SFVEC2F &aStart,
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const SFVEC2F &aEnd_minus_start,
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float *aOutT ) const
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{
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float rxs = m_End_minus_start.x *
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aEnd_minus_start.y - m_End_minus_start.y *
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aEnd_minus_start.x;
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if( std::abs( rxs ) > glm::epsilon<float>() )
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{
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const float inv_rxs = 1.0f / rxs;
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const SFVEC2F pq = aStart - m_Start;
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const float t = (pq.x * aEnd_minus_start.y - pq.y * aEnd_minus_start.x) * inv_rxs;
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if( (t < 0.0f) || (t > 1.0f) )
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return false;
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float u = (pq.x * m_End_minus_start.y - pq.y * m_End_minus_start.x) * inv_rxs;
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if( (u < 0.0f) || (u > 1.0f) )
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return false;
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*aOutT = t;
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return true;
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}
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return false;
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}
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// http://geomalgorithms.com/a02-_lines.html
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float RAYSEG2D::DistanceToPointSquared( const SFVEC2F &aPoint ) const
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{
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SFVEC2F p = aPoint - m_Start;
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const float c1 = glm::dot( p, m_End_minus_start );
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if( c1 < FLT_EPSILON )
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return glm::dot( p, p );
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if( m_DOT_End_minus_start <= c1 )
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p = aPoint - m_End;
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else
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{
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const float b = c1 / m_DOT_End_minus_start;
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const SFVEC2F pb = m_Start + m_End_minus_start * b;
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p = aPoint - pb;
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}
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return glm::dot( p, p );
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}
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bool RAYSEG2D::IntersectCircle( const SFVEC2F &aCenter,
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float aRadius,
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float *aOutT0,
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float *aOutT1,
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SFVEC2F *aOutNormalT0,
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SFVEC2F *aOutNormalT1 ) const
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{
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// This code used directly from Steve Marschner's CS667 framework
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// http://cs665pd.googlecode.com/svn/trunk/photon/sphere.cpp
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// Compute some factors used in computation
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const float qx = m_Start.x - aCenter.x;
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const float qy = m_Start.y - aCenter.y;
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const float qd = qx * m_Dir.x + qy * m_Dir.y;
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const float qq = qx * qx + qy * qy;
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// solving the quadratic equation for t at the pts of intersection
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// dd*t^2 + (2*qd)*t + (qq-r^2) = 0
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const float discriminantsqr = (qd * qd - (qq - aRadius * aRadius));
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// If the discriminant is less than zero, there is no intersection
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if( discriminantsqr < FLT_EPSILON )
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return false;
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// Otherwise check and make sure that the intersections occur on the ray (t
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// > 0) and return the closer one
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const float discriminant = std::sqrt( discriminantsqr );
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const float t1 = (-qd - discriminant);
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const float t2 = (-qd + discriminant);
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if( (( t1 < 0.0f ) || ( t1 > m_Length ) ) &&
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(( t2 < 0.0f ) || ( t2 > m_Length ) ) )
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return false;// Neither intersection was in the ray's half line.
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// Convert the intersection to a normalized
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*aOutT0 = t1 / m_Length;
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*aOutT1 = t2 / m_Length;
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SFVEC2F hitPointT1 = at( t1 );
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SFVEC2F hitPointT2 = at( t2 );
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*aOutNormalT0 = (hitPointT1 - aCenter) / aRadius;
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*aOutNormalT1 = (hitPointT2 - aCenter) / aRadius;
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return true;
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}
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void RAY::debug() const
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{
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printf("O(%f, %f, %f) D(%f, %f, %f)\n", m_Origin.x, m_Origin.y, m_Origin.z,
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m_Dir.x, m_Dir.y, m_Dir.z );
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}
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