/*************************************************************************/ /* gjk_epa.cpp */ /*************************************************************************/ /* This file is part of: */ /* GODOT ENGINE */ /* http://www.godotengine.org */ /*************************************************************************/ /* Copyright (c) 2007-2017 Juan Linietsky, Ariel Manzur. */ /* */ /* Permission is hereby granted, free of charge, to any person obtaining */ /* a copy of this software and associated documentation files (the */ /* "Software"), to deal in the Software without restriction, including */ /* without limitation the rights to use, copy, modify, merge, publish, */ /* distribute, sublicense, and/or sell copies of the Software, and to */ /* permit persons to whom the Software is furnished to do so, subject to */ /* the following conditions: */ /* */ /* The above copyright notice and this permission notice shall be */ /* included in all copies or substantial portions of the Software. */ /* */ /* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */ /* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */ /* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/ /* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */ /* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */ /* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */ /* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /*************************************************************************/ #include "gjk_epa.h" /*************** Bullet's GJK-EPA2 IMPLEMENTATION *******************/ // Config /* GJK */ #define GJK_MAX_ITERATIONS 128 #define GJK_ACCURARY ((real_t)0.0001) #define GJK_MIN_DISTANCE ((real_t)0.0001) #define GJK_DUPLICATED_EPS ((real_t)0.0001) #define GJK_SIMPLEX2_EPS ((real_t)0.0) #define GJK_SIMPLEX3_EPS ((real_t)0.0) #define GJK_SIMPLEX4_EPS ((real_t)0.0) /* EPA */ #define EPA_MAX_VERTICES 64 #define EPA_MAX_FACES (EPA_MAX_VERTICES*2) #define EPA_MAX_ITERATIONS 255 #define EPA_ACCURACY ((real_t)0.0001) #define EPA_FALLBACK (10*EPA_ACCURACY) #define EPA_PLANE_EPS ((real_t)0.00001) #define EPA_INSIDE_EPS ((real_t)0.01) namespace GjkEpa2 { struct sResults { enum eStatus { Separated, /* Shapes doesnt penetrate */ Penetrating, /* Shapes are penetrating */ GJK_Failed, /* GJK phase fail, no big issue, shapes are probably just 'touching' */ EPA_Failed /* EPA phase fail, bigger problem, need to save parameters, and debug */ } status; Vector3 witnesses[2]; Vector3 normal; real_t distance; }; // Shorthands typedef unsigned int U; typedef unsigned char U1; // MinkowskiDiff struct MinkowskiDiff { const ShapeSW* m_shapes[2]; Transform transform_A; Transform transform_B; // i wonder how this could be sped up... if it can _FORCE_INLINE_ Vector3 Support0 ( const Vector3& d ) const { return transform_A.xform( m_shapes[0]->get_support( transform_A.basis.xform_inv(d).normalized() ) ); } _FORCE_INLINE_ Vector3 Support1 ( const Vector3& d ) const { return transform_B.xform( m_shapes[1]->get_support( transform_B.basis.xform_inv(d).normalized() ) ); } _FORCE_INLINE_ Vector3 Support ( const Vector3& d ) const { return ( Support0 ( d )-Support1 ( -d ) ); } _FORCE_INLINE_ Vector3 Support ( const Vector3& d,U index ) const { if ( index ) return ( Support1 ( d ) ); else return ( Support0 ( d ) ); } }; typedef MinkowskiDiff tShape; // GJK struct GJK { /* Types */ struct sSV { Vector3 d,w; }; struct sSimplex { sSV* c[4]; real_t p[4]; U rank; }; struct eStatus { enum _ { Valid, Inside, Failed };}; /* Fields */ tShape m_shape; Vector3 m_ray; real_t m_distance; sSimplex m_simplices[2]; sSV m_store[4]; sSV* m_free[4]; U m_nfree; U m_current; sSimplex* m_simplex; eStatus::_ m_status; /* Methods */ GJK() { Initialize(); } void Initialize() { m_ray = Vector3(0,0,0); m_nfree = 0; m_status = eStatus::Failed; m_current = 0; m_distance = 0; } eStatus::_ Evaluate(const tShape& shapearg,const Vector3& guess) { U iterations=0; real_t sqdist=0; real_t alpha=0; Vector3 lastw[4]; U clastw=0; /* Initialize solver */ m_free[0] = &m_store[0]; m_free[1] = &m_store[1]; m_free[2] = &m_store[2]; m_free[3] = &m_store[3]; m_nfree = 4; m_current = 0; m_status = eStatus::Valid; m_shape = shapearg; m_distance = 0; /* Initialize simplex */ m_simplices[0].rank = 0; m_ray = guess; const real_t sqrl= m_ray.length_squared(); appendvertice(m_simplices[0],sqrl>0?-m_ray:Vector3(1,0,0)); m_simplices[0].p[0] = 1; m_ray = m_simplices[0].c[0]->w; sqdist = sqrl; lastw[0] = lastw[1] = lastw[2] = lastw[3] = m_ray; /* Loop */ do { const U next=1-m_current; sSimplex& cs=m_simplices[m_current]; sSimplex& ns=m_simplices[next]; /* Check zero */ const real_t rl=m_ray.length(); if(rlw; bool found=false; for(U i=0;i<4;++i) { if((w-lastw[i]).length_squared()w, cs.c[1]->w, weights,mask);break; case 3: sqdist=projectorigin( cs.c[0]->w, cs.c[1]->w, cs.c[2]->w, weights,mask);break; case 4: sqdist=projectorigin( cs.c[0]->w, cs.c[1]->w, cs.c[2]->w, cs.c[3]->w, weights,mask);break; } if(sqdist>=0) {/* Valid */ ns.rank = 0; m_ray = Vector3(0,0,0); m_current = next; for(U i=0,ni=cs.rank;iw*weights[i]; } else { m_free[m_nfree++] = cs.c[i]; } } if(mask==15) m_status=eStatus::Inside; } else {/* Return old simplex */ removevertice(m_simplices[m_current]); break; } m_status=((++iterations)rank) { case 1: { for(U i=0;i<3;++i) { Vector3 axis=Vector3(0,0,0); axis[i]=1; appendvertice(*m_simplex, axis); if(EncloseOrigin()) return(true); removevertice(*m_simplex); appendvertice(*m_simplex,-axis); if(EncloseOrigin()) return(true); removevertice(*m_simplex); } } break; case 2: { const Vector3 d=m_simplex->c[1]->w-m_simplex->c[0]->w; for(U i=0;i<3;++i) { Vector3 axis=Vector3(0,0,0); axis[i]=1; const Vector3 p=vec3_cross(d,axis); if(p.length_squared()>0) { appendvertice(*m_simplex, p); if(EncloseOrigin()) return(true); removevertice(*m_simplex); appendvertice(*m_simplex,-p); if(EncloseOrigin()) return(true); removevertice(*m_simplex); } } } break; case 3: { const Vector3 n=vec3_cross(m_simplex->c[1]->w-m_simplex->c[0]->w, m_simplex->c[2]->w-m_simplex->c[0]->w); if(n.length_squared()>0) { appendvertice(*m_simplex,n); if(EncloseOrigin()) return(true); removevertice(*m_simplex); appendvertice(*m_simplex,-n); if(EncloseOrigin()) return(true); removevertice(*m_simplex); } } break; case 4: { if(Math::abs(det( m_simplex->c[0]->w-m_simplex->c[3]->w, m_simplex->c[1]->w-m_simplex->c[3]->w, m_simplex->c[2]->w-m_simplex->c[3]->w))>0) return(true); } break; } return(false); } /* Internals */ void getsupport(const Vector3& d,sSV& sv) const { sv.d = d/d.length(); sv.w = m_shape.Support(sv.d); } void removevertice(sSimplex& simplex) { m_free[m_nfree++]=simplex.c[--simplex.rank]; } void appendvertice(sSimplex& simplex,const Vector3& v) { simplex.p[simplex.rank]=0; simplex.c[simplex.rank]=m_free[--m_nfree]; getsupport(v,*simplex.c[simplex.rank++]); } static real_t det(const Vector3& a,const Vector3& b,const Vector3& c) { return( a.y*b.z*c.x+a.z*b.x*c.y- a.x*b.z*c.y-a.y*b.x*c.z+ a.x*b.y*c.z-a.z*b.y*c.x); } static real_t projectorigin( const Vector3& a, const Vector3& b, real_t* w,U& m) { const Vector3 d=b-a; const real_t l=d.length_squared(); if(l>GJK_SIMPLEX2_EPS) { const real_t t(l>0?-vec3_dot(a,d)/l:0); if(t>=1) { w[0]=0;w[1]=1;m=2;return(b.length_squared()); } else if(t<=0) { w[0]=1;w[1]=0;m=1;return(a.length_squared()); } else { w[0]=1-(w[1]=t);m=3;return((a+d*t).length_squared()); } } return(-1); } static real_t projectorigin( const Vector3& a, const Vector3& b, const Vector3& c, real_t* w,U& m) { static const U imd3[]={1,2,0}; const Vector3* vt[]={&a,&b,&c}; const Vector3 dl[]={a-b,b-c,c-a}; const Vector3 n=vec3_cross(dl[0],dl[1]); const real_t l=n.length_squared(); if(l>GJK_SIMPLEX3_EPS) { real_t mindist=-1; real_t subw[2]; U subm; for(U i=0;i<3;++i) { if(vec3_dot(*vt[i],vec3_cross(dl[i],n))>0) { const U j=imd3[i]; const real_t subd(projectorigin(*vt[i],*vt[j],subw,subm)); if((mindist<0)||(subd(((subm&1)?1<GJK_SIMPLEX4_EPS)) { real_t mindist=-1; real_t subw[3]; U subm; for(U i=0;i<3;++i) { const U j=imd3[i]; const real_t s=vl*vec3_dot(d,vec3_cross(dl[i],dl[j])); if(s>0) { const real_t subd=projectorigin(*vt[i],*vt[j],d,subw,subm); if((mindist<0)||(subd((subm&1?1<e[ea]=(U1)eb;fa->f[ea]=fb; fb->e[eb]=(U1)ea;fb->f[eb]=fa; } static inline void append(sList& list,sFace* face) { face->l[0] = 0; face->l[1] = list.root; if(list.root) list.root->l[0]=face; list.root = face; ++list.count; } static inline void remove(sList& list,sFace* face) { if(face->l[1]) face->l[1]->l[0]=face->l[0]; if(face->l[0]) face->l[0]->l[1]=face->l[1]; if(face==list.root) list.root=face->l[1]; --list.count; } void Initialize() { m_status = eStatus::Failed; m_normal = Vector3(0,0,0); m_depth = 0; m_nextsv = 0; for(U i=0;i1)&&gjk.EncloseOrigin()) { /* Clean up */ while(m_hull.root) { sFace* f = m_hull.root; remove(m_hull,f); append(m_stock,f); } m_status = eStatus::Valid; m_nextsv = 0; /* Orient simplex */ if(gjk.det( simplex.c[0]->w-simplex.c[3]->w, simplex.c[1]->w-simplex.c[3]->w, simplex.c[2]->w-simplex.c[3]->w)<0) { SWAP(simplex.c[0],simplex.c[1]); SWAP(simplex.p[0],simplex.p[1]); } /* Build initial hull */ sFace* tetra[]={newface(simplex.c[0],simplex.c[1],simplex.c[2],true), newface(simplex.c[1],simplex.c[0],simplex.c[3],true), newface(simplex.c[2],simplex.c[1],simplex.c[3],true), newface(simplex.c[0],simplex.c[2],simplex.c[3],true)}; if(m_hull.count==4) { sFace* best=findbest(); sFace outer=*best; U pass=0; U iterations=0; bind(tetra[0],0,tetra[1],0); bind(tetra[0],1,tetra[2],0); bind(tetra[0],2,tetra[3],0); bind(tetra[1],1,tetra[3],2); bind(tetra[1],2,tetra[2],1); bind(tetra[2],2,tetra[3],1); m_status=eStatus::Valid; for(;iterationspass = (U1)(++pass); gjk.getsupport(best->n,*w); const real_t wdist=vec3_dot(best->n,w->w)-best->d; if(wdist>EPA_ACCURACY) { for(U j=0;(j<3)&&valid;++j) { valid&=expand( pass,w, best->f[j],best->e[j], horizon); } if(valid&&(horizon.nf>=3)) { bind(horizon.cf,1,horizon.ff,2); remove(m_hull,best); append(m_stock,best); best=findbest(); if(best->p>=outer.p) outer=*best; } else { m_status=eStatus::InvalidHull;break; } } else { m_status=eStatus::AccuraryReached;break; } } else { m_status=eStatus::OutOfVertices;break; } } const Vector3 projection=outer.n*outer.d; m_normal = outer.n; m_depth = outer.d; m_result.rank = 3; m_result.c[0] = outer.c[0]; m_result.c[1] = outer.c[1]; m_result.c[2] = outer.c[2]; m_result.p[0] = vec3_cross( outer.c[1]->w-projection, outer.c[2]->w-projection).length(); m_result.p[1] = vec3_cross( outer.c[2]->w-projection, outer.c[0]->w-projection).length(); m_result.p[2] = vec3_cross( outer.c[0]->w-projection, outer.c[1]->w-projection).length(); const real_t sum=m_result.p[0]+m_result.p[1]+m_result.p[2]; m_result.p[0] /= sum; m_result.p[1] /= sum; m_result.p[2] /= sum; return(m_status); } } /* Fallback */ m_status = eStatus::FallBack; m_normal = -guess; const real_t nl=m_normal.length(); if(nl>0) m_normal = m_normal/nl; else m_normal = Vector3(1,0,0); m_depth = 0; m_result.rank=1; m_result.c[0]=simplex.c[0]; m_result.p[0]=1; return(m_status); } sFace* newface(sSV* a,sSV* b,sSV* c,bool forced) { if(m_stock.root) { sFace* face=m_stock.root; remove(m_stock,face); append(m_hull,face); face->pass = 0; face->c[0] = a; face->c[1] = b; face->c[2] = c; face->n = vec3_cross(b->w-a->w,c->w-a->w); const real_t l=face->n.length(); const bool v=l>EPA_ACCURACY; face->p = MIN(MIN( vec3_dot(a->w,vec3_cross(face->n,a->w-b->w)), vec3_dot(b->w,vec3_cross(face->n,b->w-c->w))), vec3_dot(c->w,vec3_cross(face->n,c->w-a->w))) / (v?l:1); face->p = face->p>=-EPA_INSIDE_EPS?0:face->p; if(v) { face->d = vec3_dot(a->w,face->n)/l; face->n /= l; if(forced||(face->d>=-EPA_PLANE_EPS)) { return(face); } else m_status=eStatus::NonConvex; } else m_status=eStatus::Degenerated; remove(m_hull,face); append(m_stock,face); return(0); } m_status=m_stock.root?eStatus::OutOfVertices:eStatus::OutOfFaces; return(0); } sFace* findbest() { sFace* minf=m_hull.root; real_t mind=minf->d*minf->d; real_t maxp=minf->p; for(sFace* f=minf->l[1];f;f=f->l[1]) { const real_t sqd=f->d*f->d; if((f->p>=maxp)&&(sqdp; } } return(minf); } bool expand(U pass,sSV* w,sFace* f,U e,sHorizon& horizon) { static const U i1m3[]={1,2,0}; static const U i2m3[]={2,0,1}; if(f->pass!=pass) { const U e1=i1m3[e]; if((vec3_dot(f->n,w->w)-f->d)<-EPA_PLANE_EPS) { sFace* nf=newface(f->c[e1],f->c[e],w,false); if(nf) { bind(nf,0,f,e); if(horizon.cf) bind(horizon.cf,1,nf,2); else horizon.ff=nf; horizon.cf=nf; ++horizon.nf; return(true); } } else { const U e2=i2m3[e]; f->pass = (U1)pass; if( expand(pass,w,f->f[e1],f->e[e1],horizon)&& expand(pass,w,f->f[e2],f->e[e2],horizon)) { remove(m_hull,f); append(m_stock,f); return(true); } } } return(false); } }; // static void Initialize( const ShapeSW* shape0,const Transform& wtrs0, const ShapeSW* shape1,const Transform& wtrs1, sResults& results, tShape& shape, bool withmargins) { /* Results */ results.witnesses[0] = results.witnesses[1] = Vector3(0,0,0); results.status = sResults::Separated; /* Shape */ shape.m_shapes[0] = shape0; shape.m_shapes[1] = shape1; shape.transform_A = wtrs0; shape.transform_B = wtrs1; } // // Api // // // bool Distance( const ShapeSW* shape0, const Transform& wtrs0, const ShapeSW* shape1, const Transform& wtrs1, const Vector3& guess, sResults& results) { tShape shape; Initialize(shape0,wtrs0,shape1,wtrs1,results,shape,false); GJK gjk; GJK::eStatus::_ gjk_status=gjk.Evaluate(shape,guess); if(gjk_status==GJK::eStatus::Valid) { Vector3 w0=Vector3(0,0,0); Vector3 w1=Vector3(0,0,0); for(U i=0;irank;++i) { const real_t p=gjk.m_simplex->p[i]; w0+=shape.Support( gjk.m_simplex->c[i]->d,0)*p; w1+=shape.Support(-gjk.m_simplex->c[i]->d,1)*p; } results.witnesses[0] = w0; results.witnesses[1] = w1; results.normal = w0-w1; results.distance = results.normal.length(); results.normal /= results.distance>GJK_MIN_DISTANCE?results.distance:1; return(true); } else { results.status = gjk_status==GJK::eStatus::Inside? sResults::Penetrating : sResults::GJK_Failed ; return(false); } } // bool Penetration( const ShapeSW* shape0, const Transform& wtrs0, const ShapeSW* shape1, const Transform& wtrs1, const Vector3& guess, sResults& results ) { tShape shape; Initialize(shape0,wtrs0,shape1,wtrs1,results,shape,false); GJK gjk; GJK::eStatus::_ gjk_status=gjk.Evaluate(shape,-guess); switch(gjk_status) { case GJK::eStatus::Inside: { EPA epa; EPA::eStatus::_ epa_status=epa.Evaluate(gjk,-guess); if(epa_status!=EPA::eStatus::Failed) { Vector3 w0=Vector3(0,0,0); for(U i=0;id,0)*epa.m_result.p[i]; } results.status = sResults::Penetrating; results.witnesses[0] = w0; results.witnesses[1] = w0-epa.m_normal*epa.m_depth; results.normal = -epa.m_normal; results.distance = -epa.m_depth; return(true); } else results.status=sResults::EPA_Failed; } break; case GJK::eStatus::Failed: results.status=sResults::GJK_Failed; break; default: {} } return(false); } /* Symbols cleanup */ #undef GJK_MAX_ITERATIONS #undef GJK_ACCURARY #undef GJK_MIN_DISTANCE #undef GJK_DUPLICATED_EPS #undef GJK_SIMPLEX2_EPS #undef GJK_SIMPLEX3_EPS #undef GJK_SIMPLEX4_EPS #undef EPA_MAX_VERTICES #undef EPA_MAX_FACES #undef EPA_MAX_ITERATIONS #undef EPA_ACCURACY #undef EPA_FALLBACK #undef EPA_PLANE_EPS #undef EPA_INSIDE_EPS } // end of namespace bool gjk_epa_calculate_distance(const ShapeSW *p_shape_A, const Transform& p_transform_A, const ShapeSW *p_shape_B, const Transform& p_transform_B, Vector3& r_result_A, Vector3& r_result_B) { GjkEpa2::sResults res; if (GjkEpa2::Distance(p_shape_A,p_transform_A,p_shape_B,p_transform_B,p_transform_B.origin-p_transform_A.origin,res)) { r_result_A=res.witnesses[0]; r_result_B=res.witnesses[1]; return true; } return false; } bool gjk_epa_calculate_penetration(const ShapeSW *p_shape_A, const Transform& p_transform_A, const ShapeSW *p_shape_B, const Transform& p_transform_B, CollisionSolverSW::CallbackResult p_result_callback,void *p_userdata, bool p_swap ) { GjkEpa2::sResults res; if (GjkEpa2::Penetration(p_shape_A,p_transform_A,p_shape_B,p_transform_B,p_transform_B.origin-p_transform_A.origin,res)) { if (p_result_callback) { if (p_swap) p_result_callback(res.witnesses[1],res.witnesses[0],p_userdata); else p_result_callback(res.witnesses[0],res.witnesses[1],p_userdata); } return true; } return false; }