/***** * runpath3.in * * Runtime functions for path3 operations. * *****/ pair => primPair() triple => primTriple() path3 => primPath3() boolarray* => booleanArray() realarray* => realArray() realarray2* => realArray2() triplearray* => tripleArray() triplearray2* => tripleArray2() #include "path3.h" #include "array.h" #include "drawsurface.h" using namespace camp; using namespace vm; typedef array boolarray; typedef array realarray; typedef array realarray2; typedef array triplearray; typedef array triplearray2; using types::booleanArray; using types::realArray; using types::realArray2; using types::tripleArray; using types::tripleArray2; // Autogenerated routines: path3 path3(triplearray *pre, triplearray *point, triplearray *post, boolarray *straight, bool cyclic) { size_t n=checkArrays(pre,point); checkEqual(n,checkArray(post)); checkEqual(n,checkArray(straight)); mem::vector nodes(n); for(size_t i=0; i < n; ++i) { nodes[i].pre=read(pre,i); nodes[i].point=read(point,i); nodes[i].post=read(post,i); nodes[i].straight=read(straight,i); } return path3(nodes,(Int) n,cyclic); } path3 :nullPath3() { return nullpath3; } bool ==(path3 a, path3 b) { return a == b; } bool !=(path3 a, path3 b) { return !(a == b); } triple point(path3 p, Int t) { return p.point((Int) t); } triple point(path3 p, real t) { return p.point(t); } triple precontrol(path3 p, Int t) { return p.precontrol((Int) t); } triple precontrol(path3 p, real t) { return p.precontrol(t); } triple postcontrol(path3 p, Int t) { return p.postcontrol((Int) t); } triple postcontrol(path3 p, real t) { return p.postcontrol(t); } triple dir(path3 p, Int t, Int sign=0, bool normalize=true) { return p.dir(t,sign,normalize); } triple dir(path3 p, real t, bool normalize=true) { return p.dir(t,normalize); } triple accel(path3 p, Int t, Int sign=0) { return p.accel(t,sign); } triple accel(path3 p, real t) { return p.accel(t); } real radius(path3 p, real t) { triple v=p.dir(t,false); triple a=p.accel(t); real d=dot(a,v); real v2=v.abs2(); real a2=a.abs2(); real denom=v2*a2-d*d; real r=v2*sqrt(v2); return denom > 0 ? r/sqrt(denom) : 0.0; } real radius(triple z0, triple c0, triple c1, triple z1, real t) { triple v=(3.0*(z1-z0)+9.0*(c0-c1))*t*t+(6.0*(z0+c1)-12.0*c0)*t+3.0*(c0-z0); triple a=6.0*(z1-z0+3.0*(c0-c1))*t+6.0*(z0+c1)-12.0*c0; real d=dot(a,v); real v2=v.abs2(); real a2=a.abs2(); real denom=v2*a2-d*d; real r=v2*sqrt(v2); return denom > 0 ? r/sqrt(denom) : 0.0; } path3 reverse(path3 p) { return p.reverse(); } path3 subpath(path3 p, Int a, Int b) { return p.subpath((Int) a, (Int) b); } path3 subpath(path3 p, real a, real b) { return p.subpath(a,b); } Int length(path3 p) { return p.length(); } bool cyclic(path3 p) { return p.cyclic(); } bool straight(path3 p, Int t) { return p.straight(t); } path3 unstraighten(path3 p) { return p.unstraighten(); } // Return the maximum perpendicular deviation of segment i of path3 g // from a straight line. real straightness(path3 p, Int t) { if(p.straight(t)) return 0; triple z0=p.point(t); triple u=unit(p.point(t+1)-z0); return ::max(length(perp(p.postcontrol(t)-z0,u)), length(perp(p.precontrol(t+1)-z0,u))); } // Return the maximum perpendicular deviation of z0..controls c0 and c1..z1 // from a straight line. real straightness(triple z0, triple c0, triple c1, triple z1) { triple u=unit(z1-z0); return ::max(length(perp(c0-z0,u)),length(perp(c1-z0,u))); } bool piecewisestraight(path3 p) { return p.piecewisestraight(); } real arclength(path3 p) { return p.arclength(); } real arctime(path3 p, real dval) { return p.arctime(dval); } realarray* intersect(path3 p, path3 q, real fuzz=-1) { bool exact=fuzz <= 0.0; if(fuzz < 0) fuzz=BigFuzz*::max(::max(length(p.max()),length(p.min())), ::max(length(q.max()),length(q.min()))); std::vector S,T; real s,t; if(intersections(s,t,S,T,p,q,fuzz,true,exact)) { array *V=new array(2); (*V)[0]=s; (*V)[1]=t; return V; } else return new array(0); } realarray2* intersections(path3 p, path3 q, real fuzz=-1) { bool exact=fuzz <= 0.0; if(fuzz < 0) fuzz=BigFuzz*::max(::max(length(p.max()),length(p.min())), ::max(length(q.max()),length(q.min()))); bool single=!exact; real s,t; std::vector S,T; bool found=intersections(s,t,S,T,p,q,fuzz,single,exact); if(!found) return new array(0); array *V; if(single) { V=new array(1); array *Vi=new array(2); (*V)[0]=Vi; (*Vi)[0]=s; (*Vi)[1]=t; } else { size_t n=S.size(); V=new array(n); for(size_t i=0; i < n; ++i) { array *Vi=new array(2); (*V)[i]=Vi; (*Vi)[0]=S[i]; (*Vi)[1]=T[i]; } } stable_sort(V->begin(),V->end(),run::compare2()); return V; } realarray2* intersections(path3 p, triplearray2 *P, real fuzz=-1) { triple *A=copyTripleArray2C(P,true,4); if(fuzz <= 0) fuzz=BigFuzz*::max(::max(length(p.max()),length(p.min())), norm(A,16)); std::vector T,U,V; intersections(T,U,V,p,A,fuzz); delete[] A; size_t n=T.size(); array *W=new array(n); for(size_t i=0; i < n; ++i) { array *Wi=new array(3); (*W)[i]=Wi; (*Wi)[0]=T[i]; (*Wi)[1]=U[i]; (*Wi)[2]=V[i]; } return W; // Sorting will done in asy. } Int size(path3 p) { return p.size(); } path3 &(path3 p, path3 q) { return camp::concat(p,q); } triple min(path3 p) { return p.min(); } triple max(path3 p) { return p.max(); } realarray *mintimes(path3 p) { array *V=new array(3); triple v=p.mintimes(); (*V)[0]=v.getx(); (*V)[1]=v.gety(); (*V)[2]=v.getz(); return V; } realarray *maxtimes(path3 p) { array *V=new array(3); triple v=p.maxtimes(); (*V)[0]=v.getx(); (*V)[1]=v.gety(); (*V)[2]=v.getz(); return V; } path3 Operator *(realarray2 *t, path3 g) { return transformed(*t,g); } pair minratio(path3 g) { return g.ratio(::min); } pair maxratio(path3 g) { return g.ratio(::max); }