virtualx-engine/thirdparty/embree/kernels/geometry/cylinder.h

// Copyright 2009-2021 Intel Corporation
// SPDX-License-Identifier: Apache-2.0

#pragma once

#include "../common/ray.h"

namespace embree
{
  namespace isa
  {
    struct Cylinder
    {
      const Vec3fa p0;  //!< start location
      const Vec3fa p1;  //!< end position
      const float rr;   //!< squared radius of cylinder

      __forceinline Cylinder(const Vec3fa& p0, const Vec3fa& p1, const float r) 
        : p0(p0), p1(p1), rr(sqr(r)) {}

      __forceinline Cylinder(const Vec3fa& p0, const Vec3fa& p1, const float rr, bool) 
        : p0(p0), p1(p1), rr(rr) {}

      __forceinline bool intersect(const Vec3fa& org,
                                   const Vec3fa& dir, 
                                   BBox1f& t_o, 
                                   float& u0_o, Vec3fa& Ng0_o,
                                   float& u1_o, Vec3fa& Ng1_o) const
      {
        /* calculate quadratic equation to solve */
        const float rl = rcp_length(p1-p0);
        const Vec3fa P0 = p0, dP = (p1-p0)*rl;
        const Vec3fa O = org-P0, dO = dir;
        
        const float dOdO = dot(dO,dO);
        const float OdO = dot(dO,O);
        const float OO = dot(O,O);
        const float dOz = dot(dP,dO);
        const float Oz = dot(dP,O);
        
        const float A = dOdO - sqr(dOz);
        const float B = 2.0f * (OdO - dOz*Oz);
        const float C = OO - sqr(Oz) - rr;
        
        /* we miss the cylinder if determinant is smaller than zero */
        const float D = B*B - 4.0f*A*C;
        if (D < 0.0f) {
          t_o = BBox1f(pos_inf,neg_inf);
          return false;
        }
        
        /* special case for rays that are parallel to the cylinder */
        const float eps = 16.0f*float(ulp)*max(abs(dOdO),abs(sqr(dOz)));
        if (abs(A) < eps) 
        {
          if (C <= 0.0f) {
            t_o = BBox1f(neg_inf,pos_inf);
            return true;
          } else {
            t_o = BBox1f(pos_inf,neg_inf);
            return false;
          }
        }
        
        /* standard case for rays that are not parallel to the cylinder */
        const float Q = sqrt(D);
        const float rcp_2A = rcp(2.0f*A);
        const float t0 = (-B-Q)*rcp_2A;
        const float t1 = (-B+Q)*rcp_2A;
        
        /* calculates u and Ng for near hit */
        {
          u0_o = madd(t0,dOz,Oz)*rl;
          const Vec3fa Pr = t0*dir;
          const Vec3fa Pl = madd(u0_o,p1-p0,p0);
          Ng0_o = Pr-Pl;
        }

        /* calculates u and Ng for far hit */
        {
          u1_o = madd(t1,dOz,Oz)*rl;
          const Vec3fa Pr = t1*dir;
          const Vec3fa Pl = madd(u1_o,p1-p0,p0);
          Ng1_o = Pr-Pl;
        }

        t_o.lower = t0;
        t_o.upper = t1;
        return true;
      }

      __forceinline bool intersect(const Vec3fa& org_i, const Vec3fa& dir, BBox1f& t_o) const
      {
        float u0_o; Vec3fa Ng0_o;
        float u1_o; Vec3fa Ng1_o;
        return intersect(org_i,dir,t_o,u0_o,Ng0_o,u1_o,Ng1_o);
      }

      static bool verify(const size_t id, const Cylinder& cylinder, const RayHit& ray, bool shouldhit, const float t0, const float t1)
      {
        float eps = 0.001f;
        BBox1f t; bool hit;
        hit = cylinder.intersect(ray.org,ray.dir,t);

        bool failed = hit != shouldhit;
        if (shouldhit) failed |= std::isinf(t0) ? t0 != t.lower : abs(t0-t.lower) > eps;
        if (shouldhit) failed |= std::isinf(t1) ? t1 != t.upper : abs(t1-t.upper) > eps;
        if (!failed) return true;
        embree_cout << "Cylinder test " << id << " failed: cylinder = " << cylinder << ", ray = " << ray << ", hit = " << hit << ", t = " << t << embree_endl; 
        return false;
      }

      /* verify cylinder class */
      static bool verify()
      {
        bool passed = true;
        const Cylinder cylinder(Vec3fa(0.0f,0.0f,0.0f),Vec3fa(1.0f,0.0f,0.0f),1.0f);
        passed &= verify(0,cylinder,RayHit(Vec3fa(-2.0f,1.0f,0.0f),Vec3fa( 0.0f,-1.0f,+0.0f),0.0f,float(inf)),true,0.0f,2.0f);
        passed &= verify(1,cylinder,RayHit(Vec3fa(+2.0f,1.0f,0.0f),Vec3fa( 0.0f,-1.0f,+0.0f),0.0f,float(inf)),true,0.0f,2.0f);
        passed &= verify(2,cylinder,RayHit(Vec3fa(+2.0f,1.0f,2.0f),Vec3fa( 0.0f,-1.0f,+0.0f),0.0f,float(inf)),false,0.0f,0.0f);
        passed &= verify(3,cylinder,RayHit(Vec3fa(+0.0f,0.0f,0.0f),Vec3fa( 1.0f, 0.0f,+0.0f),0.0f,float(inf)),true,neg_inf,pos_inf);
        passed &= verify(4,cylinder,RayHit(Vec3fa(+0.0f,0.0f,0.0f),Vec3fa(-1.0f, 0.0f,+0.0f),0.0f,float(inf)),true,neg_inf,pos_inf);
        passed &= verify(5,cylinder,RayHit(Vec3fa(+0.0f,2.0f,0.0f),Vec3fa( 1.0f, 0.0f,+0.0f),0.0f,float(inf)),false,pos_inf,neg_inf);
        passed &= verify(6,cylinder,RayHit(Vec3fa(+0.0f,2.0f,0.0f),Vec3fa(-1.0f, 0.0f,+0.0f),0.0f,float(inf)),false,pos_inf,neg_inf);
        return passed;
      }

      /*! output operator */
      friend __forceinline embree_ostream operator<<(embree_ostream cout, const Cylinder& c) {
        return cout << "Cylinder { p0 = " << c.p0 << ", p1 = " << c.p1 << ", r = " << sqrtf(c.rr) << "}";
      }
    };

    template<int N>
      struct CylinderN
    { 
      const Vec3vf<N> p0;     //!< start location
      const Vec3vf<N> p1;     //!< end position
      const vfloat<N> rr;   //!< squared radius of cylinder

      __forceinline CylinderN(const Vec3vf<N>& p0, const Vec3vf<N>& p1, const vfloat<N>& r)
        : p0(p0), p1(p1), rr(sqr(r)) {}

      __forceinline CylinderN(const Vec3vf<N>& p0, const Vec3vf<N>& p1, const vfloat<N>& rr, bool)
        : p0(p0), p1(p1), rr(rr) {}

     
      __forceinline vbool<N> intersect(const Vec3fa& org, const Vec3fa& dir, 
                                       BBox<vfloat<N>>& t_o, 
                                       vfloat<N>& u0_o, Vec3vf<N>& Ng0_o,
                                       vfloat<N>& u1_o, Vec3vf<N>& Ng1_o) const
      {
        /* calculate quadratic equation to solve */
        const vfloat<N> rl = rcp_length(p1-p0);
        const Vec3vf<N> P0 = p0, dP = (p1-p0)*rl;
        const Vec3vf<N> O = Vec3vf<N>(org)-P0, dO = dir;
        
        const vfloat<N> dOdO = dot(dO,dO);
        const vfloat<N> OdO = dot(dO,O);
        const vfloat<N> OO = dot(O,O);
        const vfloat<N> dOz = dot(dP,dO);
        const vfloat<N> Oz = dot(dP,O);
        
        const vfloat<N> A = dOdO - sqr(dOz);
        const vfloat<N> B = 2.0f * (OdO - dOz*Oz);
        const vfloat<N> C = OO - sqr(Oz) - rr;
        
        /* we miss the cylinder if determinant is smaller than zero */
        const vfloat<N> D = B*B - 4.0f*A*C;
        vbool<N> valid = D >= 0.0f;
        if (none(valid)) {
          t_o = BBox<vfloat<N>>(empty);
          return valid;
        }

        /* standard case for rays that are not parallel to the cylinder */
        const vfloat<N> Q = sqrt(D);
        const vfloat<N> rcp_2A = rcp(2.0f*A);
        const vfloat<N> t0 = (-B-Q)*rcp_2A;
        const vfloat<N> t1 = (-B+Q)*rcp_2A;
        
        /* calculates u and Ng for near hit */
        {
          u0_o = madd(t0,dOz,Oz)*rl;
          const Vec3vf<N> Pr = t0*Vec3vf<N>(dir);
          const Vec3vf<N> Pl = madd(u0_o,p1-p0,p0);
          Ng0_o = Pr-Pl;
        }
        
        /* calculates u and Ng for far hit */
        {
          u1_o = madd(t1,dOz,Oz)*rl;
          const Vec3vf<N> Pr = t1*Vec3vf<N>(dir);
          const Vec3vf<N> Pl = madd(u1_o,p1-p0,p0);
          Ng1_o = Pr-Pl;
        }

        t_o.lower = select(valid, t0, vfloat<N>(pos_inf));
        t_o.upper = select(valid, t1, vfloat<N>(neg_inf));

        /* special case for rays that are parallel to the cylinder */
        const vfloat<N> eps = 16.0f*float(ulp)*max(abs(dOdO),abs(sqr(dOz)));
        vbool<N> validt = valid & (abs(A) < eps); 
        if (unlikely(any(validt))) 
        {
          vbool<N> inside = C <= 0.0f;
          t_o.lower = select(validt,select(inside,vfloat<N>(neg_inf),vfloat<N>(pos_inf)),t_o.lower);
          t_o.upper = select(validt,select(inside,vfloat<N>(pos_inf),vfloat<N>(neg_inf)),t_o.upper);
          valid &= !validt | inside;
        }
        return valid;
      }

      __forceinline vbool<N> intersect(const Vec3fa& org_i, const Vec3fa& dir, BBox<vfloat<N>>& t_o) const
      {
        vfloat<N> u0_o; Vec3vf<N> Ng0_o;
        vfloat<N> u1_o; Vec3vf<N> Ng1_o;
        return intersect(org_i,dir,t_o,u0_o,Ng0_o,u1_o,Ng1_o);
      }
    };
  }
}
Upgrade Embree to the latest official release. Since Embree v3.13.0 supports AARCH64, switch back to the official repo instead of using Embree-aarch64. `thirdparty/embree/patches/godot-changes.patch` should now contain an accurate diff of the changes done to the library. (cherry picked from commit 767e374dced69b45db0afb30ca2ccf0bbbeef672) 2021-05-20 12:49:33 +02:00			`// Copyright 2009-2021 Intel Corporation`
Add Embree thirdparty library 2020-12-19 14:50:20 +01:00			`// SPDX-License-Identifier: Apache-2.0`

			`#pragma once`

			`#include "../common/ray.h"`

			`namespace embree`
			`{`
			`namespace isa`
			`{`
			`struct Cylinder`
			`{`
			`const Vec3fa p0; //!< start location`
			`const Vec3fa p1; //!< end position`
			`const float rr; //!< squared radius of cylinder`

			`__forceinline Cylinder(const Vec3fa& p0, const Vec3fa& p1, const float r)`
			`: p0(p0), p1(p1), rr(sqr(r)) {}`

			`__forceinline Cylinder(const Vec3fa& p0, const Vec3fa& p1, const float rr, bool)`
			`: p0(p0), p1(p1), rr(rr) {}`

			`__forceinline bool intersect(const Vec3fa& org,`
			`const Vec3fa& dir,`
			`BBox1f& t_o,`
			`float& u0_o, Vec3fa& Ng0_o,`
			`float& u1_o, Vec3fa& Ng1_o) const`
			`{`
			`/* calculate quadratic equation to solve */`
			`const float rl = rcp_length(p1-p0);`
			`const Vec3fa P0 = p0, dP = (p1-p0)*rl;`
			`const Vec3fa O = org-P0, dO = dir;`

			`const float dOdO = dot(dO,dO);`
			`const float OdO = dot(dO,O);`
			`const float OO = dot(O,O);`
			`const float dOz = dot(dP,dO);`
			`const float Oz = dot(dP,O);`

			`const float A = dOdO - sqr(dOz);`
			`const float B = 2.0f * (OdO - dOz*Oz);`
			`const float C = OO - sqr(Oz) - rr;`

			`/* we miss the cylinder if determinant is smaller than zero */`
			`const float D = BB - 4.0fA*C;`
			`if (D < 0.0f) {`
			`t_o = BBox1f(pos_inf,neg_inf);`
			`return false;`
			`}`

			`/* special case for rays that are parallel to the cylinder */`
			`const float eps = 16.0ffloat(ulp)max(abs(dOdO),abs(sqr(dOz)));`
			`if (abs(A) < eps)`
			`{`
			`if (C <= 0.0f) {`
			`t_o = BBox1f(neg_inf,pos_inf);`
			`return true;`
			`} else {`
			`t_o = BBox1f(pos_inf,neg_inf);`
			`return false;`
			`}`
			`}`

			`/* standard case for rays that are not parallel to the cylinder */`
			`const float Q = sqrt(D);`
			`const float rcp_2A = rcp(2.0f*A);`
			`const float t0 = (-B-Q)*rcp_2A;`
			`const float t1 = (-B+Q)*rcp_2A;`

			`/* calculates u and Ng for near hit */`
			`{`
			`u0_o = madd(t0,dOz,Oz)*rl;`
			`const Vec3fa Pr = t0*dir;`
			`const Vec3fa Pl = madd(u0_o,p1-p0,p0);`
			`Ng0_o = Pr-Pl;`
			`}`

			`/* calculates u and Ng for far hit */`
			`{`
			`u1_o = madd(t1,dOz,Oz)*rl;`
			`const Vec3fa Pr = t1*dir;`
			`const Vec3fa Pl = madd(u1_o,p1-p0,p0);`
			`Ng1_o = Pr-Pl;`
			`}`

			`t_o.lower = t0;`
			`t_o.upper = t1;`
			`return true;`
			`}`

			`__forceinline bool intersect(const Vec3fa& org_i, const Vec3fa& dir, BBox1f& t_o) const`
			`{`
			`float u0_o; Vec3fa Ng0_o;`
			`float u1_o; Vec3fa Ng1_o;`
			`return intersect(org_i,dir,t_o,u0_o,Ng0_o,u1_o,Ng1_o);`
			`}`

			`static bool verify(const size_t id, const Cylinder& cylinder, const RayHit& ray, bool shouldhit, const float t0, const float t1)`
			`{`
			`float eps = 0.001f;`
			`BBox1f t; bool hit;`
			`hit = cylinder.intersect(ray.org,ray.dir,t);`

			`bool failed = hit != shouldhit;`
			`if (shouldhit) failed \|= std::isinf(t0) ? t0 != t.lower : abs(t0-t.lower) > eps;`
			`if (shouldhit) failed \|= std::isinf(t1) ? t1 != t.upper : abs(t1-t.upper) > eps;`
			`if (!failed) return true;`
			`embree_cout << "Cylinder test " << id << " failed: cylinder = " << cylinder << ", ray = " << ray << ", hit = " << hit << ", t = " << t << embree_endl;`
			`return false;`
			`}`

			`/* verify cylinder class */`
			`static bool verify()`
			`{`
			`bool passed = true;`
			`const Cylinder cylinder(Vec3fa(0.0f,0.0f,0.0f),Vec3fa(1.0f,0.0f,0.0f),1.0f);`
			`passed &= verify(0,cylinder,RayHit(Vec3fa(-2.0f,1.0f,0.0f),Vec3fa( 0.0f,-1.0f,+0.0f),0.0f,float(inf)),true,0.0f,2.0f);`
			`passed &= verify(1,cylinder,RayHit(Vec3fa(+2.0f,1.0f,0.0f),Vec3fa( 0.0f,-1.0f,+0.0f),0.0f,float(inf)),true,0.0f,2.0f);`
			`passed &= verify(2,cylinder,RayHit(Vec3fa(+2.0f,1.0f,2.0f),Vec3fa( 0.0f,-1.0f,+0.0f),0.0f,float(inf)),false,0.0f,0.0f);`
			`passed &= verify(3,cylinder,RayHit(Vec3fa(+0.0f,0.0f,0.0f),Vec3fa( 1.0f, 0.0f,+0.0f),0.0f,float(inf)),true,neg_inf,pos_inf);`
			`passed &= verify(4,cylinder,RayHit(Vec3fa(+0.0f,0.0f,0.0f),Vec3fa(-1.0f, 0.0f,+0.0f),0.0f,float(inf)),true,neg_inf,pos_inf);`
			`passed &= verify(5,cylinder,RayHit(Vec3fa(+0.0f,2.0f,0.0f),Vec3fa( 1.0f, 0.0f,+0.0f),0.0f,float(inf)),false,pos_inf,neg_inf);`
			`passed &= verify(6,cylinder,RayHit(Vec3fa(+0.0f,2.0f,0.0f),Vec3fa(-1.0f, 0.0f,+0.0f),0.0f,float(inf)),false,pos_inf,neg_inf);`
			`return passed;`
			`}`

			`/! output operator /`
			`friend __forceinline embree_ostream operator<<(embree_ostream cout, const Cylinder& c) {`
			`return cout << "Cylinder { p0 = " << c.p0 << ", p1 = " << c.p1 << ", r = " << sqrtf(c.rr) << "}";`
			`}`
			`};`

			`template<int N>`
			`struct CylinderN`
			`{`
			`const Vec3vf<N> p0; //!< start location`
			`const Vec3vf<N> p1; //!< end position`
			`const vfloat<N> rr; //!< squared radius of cylinder`

			`__forceinline CylinderN(const Vec3vf<N>& p0, const Vec3vf<N>& p1, const vfloat<N>& r)`
			`: p0(p0), p1(p1), rr(sqr(r)) {}`

			`__forceinline CylinderN(const Vec3vf<N>& p0, const Vec3vf<N>& p1, const vfloat<N>& rr, bool)`
			`: p0(p0), p1(p1), rr(rr) {}`


			`__forceinline vbool<N> intersect(const Vec3fa& org, const Vec3fa& dir,`
			`BBox<vfloat<N>>& t_o,`
			`vfloat<N>& u0_o, Vec3vf<N>& Ng0_o,`
			`vfloat<N>& u1_o, Vec3vf<N>& Ng1_o) const`
			`{`
			`/* calculate quadratic equation to solve */`
			`const vfloat<N> rl = rcp_length(p1-p0);`
			`const Vec3vf<N> P0 = p0, dP = (p1-p0)*rl;`
			`const Vec3vf<N> O = Vec3vf<N>(org)-P0, dO = dir;`

			`const vfloat<N> dOdO = dot(dO,dO);`
			`const vfloat<N> OdO = dot(dO,O);`
			`const vfloat<N> OO = dot(O,O);`
			`const vfloat<N> dOz = dot(dP,dO);`
			`const vfloat<N> Oz = dot(dP,O);`

			`const vfloat<N> A = dOdO - sqr(dOz);`
			`const vfloat<N> B = 2.0f * (OdO - dOz*Oz);`
			`const vfloat<N> C = OO - sqr(Oz) - rr;`

			`/* we miss the cylinder if determinant is smaller than zero */`
			`const vfloat<N> D = BB - 4.0fA*C;`
			`vbool<N> valid = D >= 0.0f;`
			`if (none(valid)) {`
			`t_o = BBox<vfloat<N>>(empty);`
			`return valid;`
			`}`

			`/* standard case for rays that are not parallel to the cylinder */`
			`const vfloat<N> Q = sqrt(D);`
			`const vfloat<N> rcp_2A = rcp(2.0f*A);`
			`const vfloat<N> t0 = (-B-Q)*rcp_2A;`
			`const vfloat<N> t1 = (-B+Q)*rcp_2A;`

			`/* calculates u and Ng for near hit */`
			`{`
			`u0_o = madd(t0,dOz,Oz)*rl;`
			`const Vec3vf<N> Pr = t0*Vec3vf<N>(dir);`
			`const Vec3vf<N> Pl = madd(u0_o,p1-p0,p0);`
			`Ng0_o = Pr-Pl;`
			`}`

			`/* calculates u and Ng for far hit */`
			`{`
			`u1_o = madd(t1,dOz,Oz)*rl;`
			`const Vec3vf<N> Pr = t1*Vec3vf<N>(dir);`
			`const Vec3vf<N> Pl = madd(u1_o,p1-p0,p0);`
			`Ng1_o = Pr-Pl;`
			`}`

			`t_o.lower = select(valid, t0, vfloat<N>(pos_inf));`
			`t_o.upper = select(valid, t1, vfloat<N>(neg_inf));`

			`/* special case for rays that are parallel to the cylinder */`
			`const vfloat<N> eps = 16.0ffloat(ulp)max(abs(dOdO),abs(sqr(dOz)));`
			`vbool<N> validt = valid & (abs(A) < eps);`
			`if (unlikely(any(validt)))`
			`{`
			`vbool<N> inside = C <= 0.0f;`
			`t_o.lower = select(validt,select(inside,vfloat<N>(neg_inf),vfloat<N>(pos_inf)),t_o.lower);`
			`t_o.upper = select(validt,select(inside,vfloat<N>(pos_inf),vfloat<N>(neg_inf)),t_o.upper);`
			`valid &= !validt \| inside;`
			`}`
			`return valid;`
			`}`

			`__forceinline vbool<N> intersect(const Vec3fa& org_i, const Vec3fa& dir, BBox<vfloat<N>>& t_o) const`
			`{`
			`vfloat<N> u0_o; Vec3vf<N> Ng0_o;`
			`vfloat<N> u1_o; Vec3vf<N> Ng1_o;`
			`return intersect(org_i,dir,t_o,u0_o,Ng0_o,u1_o,Ng1_o);`
			`}`
			`};`
			`}`
			`}`