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greg |
2.1 |
/* Copyright (c) 1992 Regents of the University of California */ |
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#ifndef lint |
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static char SCCSid[] = "$SunId$ LBL"; |
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#endif |
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/* |
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* Shading functions for anisotropic materials. |
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*/ |
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#include "ray.h" |
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#include "otypes.h" |
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#include "func.h" |
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#include "random.h" |
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greg |
2.4 |
extern double specthresh; /* specular sampling threshold */ |
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extern double specjitter; /* specular sampling jitter */ |
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greg |
2.1 |
/* |
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* This anisotropic reflection model uses a variant on the |
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* exponential Gaussian used in normal.c. |
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* We orient the surface towards the incoming ray, so a single |
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* surface can be used to represent an infinitely thin object. |
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* |
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* Arguments for MAT_PLASTIC2 and MAT_METAL2 are: |
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* 4+ ux uy uz funcfile [transform...] |
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* 0 |
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* 6 red grn blu specular-frac. u-facet-slope v-facet-slope |
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* |
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* Real arguments for MAT_TRANS2 are: |
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* 8 red grn blu rspec u-rough v-rough trans tspec |
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*/ |
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greg |
2.14 |
#define BSPEC(m) (6.0) /* specularity parameter b */ |
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greg |
2.1 |
/* specularity flags */ |
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#define SP_REFL 01 /* has reflected specular component */ |
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#define SP_TRAN 02 /* has transmitted specular */ |
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greg |
2.10 |
#define SP_FLAT 04 /* reflecting surface is flat */ |
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#define SP_RBLT 010 /* reflection below sample threshold */ |
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#define SP_TBLT 020 /* transmission below threshold */ |
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#define SP_BADU 040 /* bad u direction calculation */ |
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greg |
2.1 |
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typedef struct { |
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greg |
2.2 |
OBJREC *mp; /* material pointer */ |
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greg |
2.1 |
RAY *rp; /* ray pointer */ |
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short specfl; /* specularity flags, defined above */ |
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COLOR mcolor; /* color of this material */ |
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COLOR scolor; /* color of specular component */ |
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greg |
2.6 |
FVECT vrefl; /* vector in reflected direction */ |
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greg |
2.1 |
FVECT prdir; /* vector in transmitted direction */ |
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FVECT u, v; /* u and v vectors orienting anisotropy */ |
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double u_alpha; /* u roughness */ |
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double v_alpha; /* v roughness */ |
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double rdiff, rspec; /* reflected specular, diffuse */ |
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double trans; /* transmissivity */ |
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double tdiff, tspec; /* transmitted specular, diffuse */ |
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FVECT pnorm; /* perturbed surface normal */ |
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double pdot; /* perturbed dot product */ |
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} ANISODAT; /* anisotropic material data */ |
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diraniso(cval, np, ldir, omega) /* compute source contribution */ |
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COLOR cval; /* returned coefficient */ |
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register ANISODAT *np; /* material data */ |
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FVECT ldir; /* light source direction */ |
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double omega; /* light source size */ |
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{ |
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double ldot; |
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double dtmp, dtmp2; |
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FVECT h; |
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double au2, av2; |
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COLOR ctmp; |
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setcolor(cval, 0.0, 0.0, 0.0); |
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ldot = DOT(np->pnorm, ldir); |
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if (ldot < 0.0 ? np->trans <= FTINY : np->trans >= 1.0-FTINY) |
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return; /* wrong side */ |
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if (ldot > FTINY && np->rdiff > FTINY) { |
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/* |
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* Compute and add diffuse reflected component to returned |
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* color. The diffuse reflected component will always be |
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* modified by the color of the material. |
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*/ |
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copycolor(ctmp, np->mcolor); |
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dtmp = ldot * omega * np->rdiff / PI; |
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scalecolor(ctmp, dtmp); |
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addcolor(cval, ctmp); |
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} |
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greg |
2.10 |
if (ldot > FTINY && (np->specfl&(SP_REFL|SP_BADU)) == SP_REFL) { |
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greg |
2.1 |
/* |
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* Compute specular reflection coefficient using |
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* anisotropic gaussian distribution model. |
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*/ |
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greg |
2.2 |
/* add source width if flat */ |
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if (np->specfl & SP_FLAT) |
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au2 = av2 = omega/(4.0*PI); |
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else |
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au2 = av2 = 0.0; |
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greg |
2.1 |
au2 += np->u_alpha * np->u_alpha; |
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av2 += np->v_alpha * np->v_alpha; |
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/* half vector */ |
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h[0] = ldir[0] - np->rp->rdir[0]; |
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h[1] = ldir[1] - np->rp->rdir[1]; |
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h[2] = ldir[2] - np->rp->rdir[2]; |
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normalize(h); |
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/* ellipse */ |
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dtmp = DOT(np->u, h); |
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dtmp *= dtmp / au2; |
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dtmp2 = DOT(np->v, h); |
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dtmp2 *= dtmp2 / av2; |
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/* gaussian */ |
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dtmp = (dtmp + dtmp2) / (1.0 + DOT(np->pnorm, h)); |
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dtmp = exp(-2.0*dtmp) / (4.0*PI * sqrt(au2*av2)); |
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/* worth using? */ |
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if (dtmp > FTINY) { |
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copycolor(ctmp, np->scolor); |
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greg |
2.13 |
dtmp *= omega * sqrt(ldot/np->pdot); |
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greg |
2.1 |
scalecolor(ctmp, dtmp); |
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addcolor(cval, ctmp); |
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} |
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} |
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if (ldot < -FTINY && np->tdiff > FTINY) { |
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/* |
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* Compute diffuse transmission. |
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*/ |
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copycolor(ctmp, np->mcolor); |
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dtmp = -ldot * omega * np->tdiff / PI; |
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scalecolor(ctmp, dtmp); |
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addcolor(cval, ctmp); |
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} |
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greg |
2.10 |
if (ldot < -FTINY && (np->specfl&(SP_TRAN|SP_BADU)) == SP_TRAN) { |
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greg |
2.1 |
/* |
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* Compute specular transmission. Specular transmission |
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* is always modified by material color. |
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*/ |
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/* roughness + source */ |
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/* gaussian */ |
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dtmp = 0.0; |
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/* worth using? */ |
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if (dtmp > FTINY) { |
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copycolor(ctmp, np->mcolor); |
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greg |
2.13 |
dtmp *= np->tspec * omega * sqrt(ldot/np->pdot); |
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greg |
2.1 |
scalecolor(ctmp, dtmp); |
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addcolor(cval, ctmp); |
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} |
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} |
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} |
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m_aniso(m, r) /* shade ray that hit something anisotropic */ |
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register OBJREC *m; |
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register RAY *r; |
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{ |
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ANISODAT nd; |
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double dtmp; |
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COLOR ctmp; |
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register int i; |
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/* easy shadow test */ |
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greg |
2.10 |
if (r->crtype & SHADOW) |
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greg |
2.1 |
return; |
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if (m->oargs.nfargs != (m->otype == MAT_TRANS2 ? 8 : 6)) |
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objerror(m, USER, "bad number of real arguments"); |
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greg |
2.2 |
nd.mp = m; |
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greg |
2.1 |
nd.rp = r; |
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/* get material color */ |
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setcolor(nd.mcolor, m->oargs.farg[0], |
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m->oargs.farg[1], |
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m->oargs.farg[2]); |
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/* get roughness */ |
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nd.specfl = 0; |
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nd.u_alpha = m->oargs.farg[4]; |
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nd.v_alpha = m->oargs.farg[5]; |
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greg |
2.10 |
if (nd.u_alpha < 1e-6 || nd.v_alpha <= 1e-6) |
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objerror(m, USER, "roughness too small"); |
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greg |
2.1 |
/* reorient if necessary */ |
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if (r->rod < 0.0) |
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flipsurface(r); |
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/* get modifiers */ |
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raytexture(r, m->omod); |
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nd.pdot = raynormal(nd.pnorm, r); /* perturb normal */ |
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if (nd.pdot < .001) |
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nd.pdot = .001; /* non-zero for diraniso() */ |
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multcolor(nd.mcolor, r->pcol); /* modify material color */ |
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/* get specular component */ |
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if ((nd.rspec = m->oargs.farg[3]) > FTINY) { |
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nd.specfl |= SP_REFL; |
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/* compute specular color */ |
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if (m->otype == MAT_METAL2) |
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copycolor(nd.scolor, nd.mcolor); |
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else |
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setcolor(nd.scolor, 1.0, 1.0, 1.0); |
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scalecolor(nd.scolor, nd.rspec); |
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greg |
2.14 |
/* improved model */ |
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dtmp = exp(-BSPEC(m)*nd.pdot); |
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for (i = 0; i < 3; i++) |
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colval(nd.scolor,i) += (1.0-colval(nd.scolor,i))*dtmp; |
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nd.rspec += (1.0-nd.rspec)*dtmp; |
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greg |
2.4 |
/* check threshold */ |
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greg |
2.5 |
if (specthresh > FTINY && |
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greg |
2.12 |
(specthresh >= 1.-FTINY || |
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greg |
2.15 |
specthresh + .05 - .1*frandom() > nd.rspec)) |
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greg |
2.4 |
nd.specfl |= SP_RBLT; |
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greg |
2.6 |
/* compute refl. direction */ |
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for (i = 0; i < 3; i++) |
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nd.vrefl[i] = r->rdir[i] + 2.0*nd.pdot*nd.pnorm[i]; |
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if (DOT(nd.vrefl, r->ron) <= FTINY) /* penetration? */ |
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for (i = 0; i < 3; i++) /* safety measure */ |
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nd.vrefl[i] = r->rdir[i] + 2.*r->rod*r->ron[i]; |
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greg |
2.1 |
} |
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/* compute transmission */ |
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if (m->otype == MAT_TRANS) { |
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nd.trans = m->oargs.farg[6]*(1.0 - nd.rspec); |
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nd.tspec = nd.trans * m->oargs.farg[7]; |
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nd.tdiff = nd.trans - nd.tspec; |
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if (nd.tspec > FTINY) { |
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nd.specfl |= SP_TRAN; |
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greg |
2.4 |
/* check threshold */ |
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greg |
2.5 |
if (specthresh > FTINY && |
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greg |
2.12 |
(specthresh >= 1.-FTINY || |
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greg |
2.15 |
specthresh + .05 - .1*frandom() > nd.tspec)) |
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greg |
2.4 |
nd.specfl |= SP_TBLT; |
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greg |
2.10 |
if (DOT(r->pert,r->pert) <= FTINY*FTINY) { |
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greg |
2.1 |
VCOPY(nd.prdir, r->rdir); |
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} else { |
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for (i = 0; i < 3; i++) /* perturb */ |
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nd.prdir[i] = r->rdir[i] - |
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greg |
2.7 |
0.5*r->pert[i]; |
236 |
greg |
2.6 |
if (DOT(nd.prdir, r->ron) < -FTINY) |
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normalize(nd.prdir); /* OK */ |
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else |
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VCOPY(nd.prdir, r->rdir); |
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greg |
2.1 |
} |
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} |
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} else |
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nd.tdiff = nd.tspec = nd.trans = 0.0; |
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/* diffuse reflection */ |
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nd.rdiff = 1.0 - nd.trans - nd.rspec; |
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greg |
2.11 |
if (r->ro != NULL && (r->ro->otype == OBJ_FACE || |
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r->ro->otype == OBJ_RING)) |
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greg |
2.4 |
nd.specfl |= SP_FLAT; |
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greg |
2.1 |
getacoords(r, &nd); /* set up coordinates */ |
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254 |
greg |
2.10 |
if (nd.specfl & (SP_REFL|SP_TRAN) && !(nd.specfl & SP_BADU)) |
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greg |
2.1 |
agaussamp(r, &nd); |
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if (nd.rdiff > FTINY) { /* ambient from this side */ |
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ambient(ctmp, r); |
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greg |
2.4 |
if (nd.specfl & SP_RBLT) |
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scalecolor(ctmp, 1.0-nd.trans); |
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else |
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scalecolor(ctmp, nd.rdiff); |
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greg |
2.1 |
multcolor(ctmp, nd.mcolor); /* modified by material color */ |
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addcolor(r->rcol, ctmp); /* add to returned color */ |
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} |
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if (nd.tdiff > FTINY) { /* ambient from other side */ |
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flipsurface(r); |
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ambient(ctmp, r); |
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greg |
2.4 |
if (nd.specfl & SP_TBLT) |
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scalecolor(ctmp, nd.trans); |
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else |
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scalecolor(ctmp, nd.tdiff); |
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greg |
2.1 |
multcolor(ctmp, nd.mcolor); /* modified by color */ |
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addcolor(r->rcol, ctmp); |
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flipsurface(r); |
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} |
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/* add direct component */ |
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direct(r, diraniso, &nd); |
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} |
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282 |
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static |
283 |
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getacoords(r, np) /* set up coordinate system */ |
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RAY *r; |
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register ANISODAT *np; |
286 |
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{ |
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register MFUNC *mf; |
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register int i; |
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mf = getfunc(np->mp, 3, 0x7, 1); |
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setfunc(np->mp, r); |
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errno = 0; |
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for (i = 0; i < 3; i++) |
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np->u[i] = evalue(mf->ep[i]); |
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if (errno) { |
296 |
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objerror(np->mp, WARNING, "compute error"); |
297 |
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np->specfl |= SP_BADU; |
298 |
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return; |
299 |
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} |
300 |
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multv3(np->u, np->u, mf->f->xfm); |
301 |
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fcross(np->v, np->pnorm, np->u); |
302 |
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if (normalize(np->v) == 0.0) { |
303 |
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objerror(np->mp, WARNING, "illegal orientation vector"); |
304 |
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np->specfl |= SP_BADU; |
305 |
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return; |
306 |
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} |
307 |
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fcross(np->u, np->v, np->pnorm); |
308 |
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} |
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310 |
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311 |
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static |
312 |
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agaussamp(r, np) /* sample anisotropic gaussian specular */ |
313 |
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RAY *r; |
314 |
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register ANISODAT *np; |
315 |
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{ |
316 |
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RAY sr; |
317 |
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FVECT h; |
318 |
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double rv[2]; |
319 |
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double d, sinp, cosp; |
320 |
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register int i; |
321 |
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/* compute reflection */ |
322 |
greg |
2.4 |
if ((np->specfl & (SP_REFL|SP_RBLT)) == SP_REFL && |
323 |
greg |
2.1 |
rayorigin(&sr, r, SPECULAR, np->rspec) == 0) { |
324 |
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dimlist[ndims++] = (int)np->mp; |
325 |
greg |
2.6 |
d = urand(ilhash(dimlist,ndims)+samplendx); |
326 |
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multisamp(rv, 2, d); |
327 |
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d = 2.0*PI * rv[0]; |
328 |
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cosp = np->u_alpha * cos(d); |
329 |
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sinp = np->v_alpha * sin(d); |
330 |
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d = sqrt(cosp*cosp + sinp*sinp); |
331 |
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cosp /= d; |
332 |
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sinp /= d; |
333 |
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rv[1] = 1.0 - specjitter*rv[1]; |
334 |
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if (rv[1] <= FTINY) |
335 |
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d = 1.0; |
336 |
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else |
337 |
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d = sqrt(-log(rv[1]) / |
338 |
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(cosp*cosp/(np->u_alpha*np->u_alpha) + |
339 |
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sinp*sinp/(np->v_alpha*np->v_alpha))); |
340 |
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for (i = 0; i < 3; i++) |
341 |
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h[i] = np->pnorm[i] + |
342 |
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d*(cosp*np->u[i] + sinp*np->v[i]); |
343 |
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d = -2.0 * DOT(h, r->rdir) / (1.0 + d*d); |
344 |
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for (i = 0; i < 3; i++) |
345 |
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sr.rdir[i] = r->rdir[i] + d*h[i]; |
346 |
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if (DOT(sr.rdir, r->ron) <= FTINY) /* penetration? */ |
347 |
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VCOPY(sr.rdir, np->vrefl); /* jitter no good */ |
348 |
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rayvalue(&sr); |
349 |
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multcolor(sr.rcol, np->scolor); |
350 |
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addcolor(r->rcol, sr.rcol); |
351 |
greg |
2.1 |
ndims--; |
352 |
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} |
353 |
|
|
/* compute transmission */ |
354 |
greg |
2.7 |
if ((np->specfl & (SP_TRAN|SP_TBLT)) == SP_TRAN && |
355 |
|
|
rayorigin(&sr, r, SPECULAR, np->tspec) == 0) { |
356 |
|
|
dimlist[ndims++] = (int)np->mp; |
357 |
|
|
d = urand(ilhash(dimlist,ndims)+1823+samplendx); |
358 |
|
|
multisamp(rv, 2, d); |
359 |
|
|
d = 2.0*PI * rv[0]; |
360 |
|
|
cosp = cos(d); |
361 |
|
|
sinp = sin(d); |
362 |
|
|
rv[1] = 1.0 - specjitter*rv[1]; |
363 |
|
|
if (rv[1] <= FTINY) |
364 |
|
|
d = 1.0; |
365 |
|
|
else |
366 |
|
|
d = sqrt(-log(rv[1]) / |
367 |
|
|
(cosp*cosp*4./(np->u_alpha*np->u_alpha) + |
368 |
|
|
sinp*sinp*4./(np->v_alpha*np->v_alpha))); |
369 |
|
|
for (i = 0; i < 3; i++) |
370 |
|
|
sr.rdir[i] = np->prdir[i] + |
371 |
|
|
d*(cosp*np->u[i] + sinp*np->v[i]); |
372 |
|
|
if (DOT(sr.rdir, r->ron) < -FTINY) |
373 |
|
|
normalize(sr.rdir); /* OK, normalize */ |
374 |
|
|
else |
375 |
|
|
VCOPY(sr.rdir, np->prdir); /* else no jitter */ |
376 |
|
|
rayvalue(&sr); |
377 |
greg |
2.10 |
scalecolor(sr.rcol, np->tspec); |
378 |
|
|
multcolor(sr.rcol, np->mcolor); /* modify by color */ |
379 |
greg |
2.7 |
addcolor(r->rcol, sr.rcol); |
380 |
|
|
ndims--; |
381 |
|
|
} |
382 |
greg |
2.1 |
} |