void StraussShader::AffectReflection(ShadeContext &sc, IllumParams &ip, Color &rClr )
{
float opac = ip.channels[ S_TR ].r;
float g = ip.channels[ S_GL ].r;
float m = ip.channels[ S_MT ].r;
Color Cd = ip.channels[ S_DI ];
float rn = opac - (1.0f - g * g * g) * opac;
// the reflection of the reflection vector is just the view vector
// so dot(v, r) is 1, to any power is still 1
float a, b;
// NB: this has been transformed for existing in-pointing v
float NV = Dot( sc.V(), sc.Normal() );
Point3 R = sc.V() - 2.0f * NV * sc.Normal();
float NR = Dot( sc.Normal(), R );
a = (float)acos( NR ) * OneOverHalfPi;
b = (float)acos( NV ) * OneOverHalfPi;
float fa = F( a );
float j = fa * G( a ) * G( b );
float rj = Bound( rn + (rn+kj)*j );
Color white( 1.0f, 1.0f, 1.0f );
Color Cs = white + m * (1.0f - fa) * (Cd - white);
rClr *= Cs * rj * REFL_BRIGHTNESS_ADJUST;
}
float BerconGradient::getGradientValueNormal(ShadeContext& sc) {
switch (p_normalType) {
case 0: { // View
return -DotProd(sc.Normal(), sc.V());
}
case 1: { // Local X
return (sc.VectorTo(sc.Normal(), REF_OBJECT)).x;
}
case 2: { // Local Y
return (sc.VectorTo(sc.Normal(), REF_OBJECT)).y;
}
case 3: { // Local Z
return (sc.VectorTo(sc.Normal(), REF_OBJECT)).z;
}
case 4: { // World X
return (sc.VectorTo(sc.Normal(), REF_WORLD)).x;
}
case 5: { // World Y
return (sc.VectorTo(sc.Normal(), REF_WORLD)).y;
}
case 6: { // World Z
return (sc.VectorTo(sc.Normal(), REF_WORLD)).z;
}
case 7: { // Camera X
return sc.Normal().x; //(sc.VectorTo(sc.Normal(), REF_CAMERA)).x;
}
case 8: { // Camera Y
return sc.Normal().y; //(sc.VectorTo(sc.Normal(), REF_CAMERA)).y;
}
case 9: { // Camera Z
return sc.Normal().z; //(sc.VectorTo(sc.Normal(), REF_CAMERA)).z;
}
case 10: { // To Object
if (sc.InMtlEditor() || !p_node)
return -DotProd(sc.Normal(), sc.V());
return DotProd(sc.Normal(), FNormalize(sc.PointFrom((p_node->GetNodeTM(sc.CurTime())).GetTrans(),REF_WORLD) - sc.P()));
}
case 11: { // Object Z
if (sc.InMtlEditor() || !p_node)
return -DotProd(sc.Normal(), sc.V());
return DotProd(sc.Normal(), FNormalize(sc.VectorFrom(p_node->GetNodeTM(sc.CurTime()).GetRow(2),REF_WORLD)));
}
}
return 0.f;
}
void plPassMtl::ShadeWithBackground(ShadeContext &sc, Color background, bool useVtxAlpha /* = true */)
{
#if 1
// old
#if 0
Color lightCol,rescol, diffIllum0;
RGBA mval;
Point3 N0,P;
BOOL bumped = FALSE;
int i;
if (gbufID)
sc.SetGBufferID(gbufID);
if (sc.mode == SCMODE_SHADOW) {
float opac = 0.0;
for (i=0; i < NumSubTexmaps(); i++) {
if (SubTexmapOn(i)) {
hsMaxLayerBase *hsmLay = (hsMaxLayerBase *)GetSubTexmap(i);
opac += hsmLay->GetOpacity(t);
}
}
float f = 1.0f - opac;
sc.out.t = Color(f,f,f);
return;
}
N0 = sc.Normal();
P = sc.P();
#endif
TimeValue t = sc.CurTime();
Color color(0, 0, 0);
float alpha = 0.0;
// Evaluate Base layer
Texmap *map = fLayersPB->GetTexmap(kPassLayBase);
if (map && ( map->ClassID() == LAYER_TEX_CLASS_ID
|| map->ClassID() == STATIC_ENV_LAYER_CLASS_ID ) )
{
plLayerTex *layer = (plLayerTex*)map;
AColor evalColor = layer->EvalColor(sc);
color = evalColor;
alpha = evalColor.a;
}
// Evaluate Top layer, if it's on
if (fLayersPB->GetInt(kPassLayTopOn))
{
Texmap *map = fLayersPB->GetTexmap(kPassLayTop);
if (map && ( map->ClassID() == LAYER_TEX_CLASS_ID
|| map->ClassID() == STATIC_ENV_LAYER_CLASS_ID
|| map->ClassID() == ANGLE_ATTEN_LAYER_CLASS_ID) )
{
plPlasmaMAXLayer *layer = (plPlasmaMAXLayer*)map;
AColor evalColor = layer->EvalColor(sc);
// Blend layers
if( !layer->DiscardColor() )
{
int blendType = fLayersPB->GetInt(kPassLayBlend);
switch (blendType)
{
case kBlendAdd:
color += evalColor * evalColor.a;
break;
case kBlendAlpha:
color = (1.0f - evalColor.a) * color + evalColor.a * evalColor;
break;
case kBlendMult:
color *= evalColor;
break;
default: // No blend...
color = evalColor;
break;
}
}
if( !layer->DiscardAlpha() )
{
int alphaType = fLayersPB->GetInt(kPassLayOutputBlend);
switch( alphaType )
{
case kAlphaMultiply:
alpha *= evalColor.a;
break;
case kAlphaAdd:
alpha += evalColor.a;
break;
case kAlphaDiscard:
default:
break;
}
}
}
}
#if 1
AColor black;
black.Black();
AColor white;
white.White();
SIllumParams ip;
if (fBasicPB->GetInt(kPassBasEmissive))
{
// Emissive objects don't get shaded
ip.diffIllum = fBasicPB->GetColor(kPassBasColorAmb, t) * color;
ip.diffIllum.ClampMinMax();
ip.specIllum = black;
}
else
{
//
// Shading setup
//
// Setup the parameters for the shader
ip.amb = fBasicPB->GetColor(kPassBasColorAmb, t);
ip.diff = fBasicPB->GetColor(kPassBasColor, t) * color;
ip.diffIllum = black;
ip.specIllum = black;
ip.N = sc.Normal();
ip.V = sc.V();
//
// Specularity
//
if (fBasicPB->GetInt(kPassBasUseSpec, t))
{
ip.sh_str = 1.f;
ip.spec = fBasicPB->GetColor( kPassBasSpecColor, t );
ip.ph_exp = (float)pow(2.0f,float(fBasicPB->GetInt(kPassBasShine, t)) / 10.0f);
ip.shine = float(fBasicPB->GetInt(kPassBasShine, t)) / 100.0f;
}
else
{
ip.spec = black;
ip.sh_str = 0;
ip.ph_exp = 0;
ip.shine = 0;
}
ip.softThresh = 0;
//
// Do the shading
Shader *myShader = GetShader(SHADER_BLINN);
myShader->Illum(sc, ip);
// Override shader parameters
if (fAdvPB->GetInt(kPBAdvNoShade))
{
ip.diffIllum = black;
ip.specIllum = black;
}
if (fAdvPB->GetInt(kPBAdvWhite))
{
ip.diffIllum = white;
ip.specIllum = black;
}
ip.specIllum.ClampMinMax();
ip.diffIllum = ip.amb * sc.ambientLight + ip.diff * ip.diffIllum;
ip.diffIllum.ClampMinMax();
}
// AColor returnColor = AColor(opac * ip.diffIllum + ip.specIllum, opac)
#endif
// Get opacity and combine with alpha
float opac = float(fBasicPB->GetInt(kPassBasOpacity, t)) / 100.0f;
alpha *= opac;
float vtxAlpha = 1.0f;
if (useVtxAlpha && GetOutputBlend() == plPassMtlBase::kBlendAlpha)
{
Point3 p;
GetInterpVtxValue(MAP_ALPHA, sc, p);
vtxAlpha = p.x;
}
alpha *= vtxAlpha;
// MAX will do the additive/alpha/no blending for us based on what Requirements()
// we tell it. However, since MAX's formula is bgnd*sc.out.t + sc.out.c,
// we have to multiply our output color by the alpha.
// If we ever need a more complicated blending function, you can request the
// background color via Requirements() (otherwise it's just black) and then do
// the blending yourself; however, if the transparency isn't set, the shadows
// will be opaque, so be careful.
Color outC = ip.diffIllum + ip.specIllum;
sc.out.c = ( outC * alpha );
sc.out.t = Color( 1.f - alpha, 1.f - alpha, 1.f - alpha );
#endif
}
RGBA Plate::EvalColor(ShadeContext& sc) {
BMM_Color_64 c;
IPoint2 s;
int id = sc.NodeID();
PlateMap *pmap = FindMap(id);
if (gbufID) sc.SetGBufferID(gbufID);
if (pmap) {
s = sc.ScreenCoord();
int w = pmap->bm->Width();
int h = pmap->bm->Height();
Point3 view = sc.OrigView();
Point3 v2 = sc.V();
Point3 p = sc.P();
Point3 dV,dvf;
Point3 N0 = sc.OrigNormal();
Point3 vf = RefractVector(sc, N0, view, sc.GetIOR());
RenderGlobalContext *gc = sc.globContext;
if (gc==NULL) return blackrgba;
// total deflection due to refraction
dV = view-v2;
// deflection due to flat refracton (no bumps)
dvf = view-vf;
dV = refrAmt*(dV-dvf) + thick*dvf;
// compute screen deflection: This is really a cheat, and the
// scale factor is arbitrary. Infact it depends on the distance
// between to the point on the glass plate and to the point being
// seen behind it, which we don't know.
// these should be multiplied by the factor (Zbehind-Zcur)/Zcur
// This assumes that the factor is .1
float dsx,dsy;
if (gc->projType==0) {
// perspective
dsx = dV.x*0.1f*gc->xscale;
dsy = dV.y*0.1f*gc->yscale;
}
else {
// parallel projection
dsx = -dV.x*gc->xscale*10.0f;
dsy = -dV.y*gc->yscale*10.0f;
}
if (gc->fieldRender) dsy *= 2.0f;
int x = s.x - (pmap->org.x+gc->devWidth/2);
int y = s.y - (pmap->org.y+gc->devHeight/2);
if (applyBlur) {
float du = 1.0f/float(w);
float dv = 1.0f/float(h);
float u = (float(x)+dsx)*du;
float v = (float(y)+dsy)*dv;
if (u<0.0f||u>1.0f||v<0.0f||v>1.0f) {
if (useEnvMap) {
return sc.EvalGlobalEnvironMap(view-dvf);
}
else
return blackrgba;
}
else
pmap->bm->GetFiltered(u,v, du*blur, dv*blur,&c);
}
else {
int ix = x + int(dsx);
int iy = y + int(dsy);
if (ix<0||ix>=w||iy<0||iy>=h) {
if (useEnvMap)
return sc.EvalGlobalEnvironMap(view-dvf);
else
return blackrgba;
}
else
pmap->bm->GetLinearPixels(ix,iy,1,&c);
}
return c;
}
else
return blackrgba;
}
void plParticleMtl::ShadeWithBackground(ShadeContext &sc, Color background)
{
#if 1
TimeValue t = sc.CurTime();
Color color(0, 0, 0);
float alpha = 0.0;
// Evaluate Base layer
Texmap *map = fBasicPB->GetTexmap(kTexmap);
if (map && map->ClassID() == LAYER_TEX_CLASS_ID)
{
plLayerTex *layer = (plLayerTex*)map;
AColor evalColor = layer->EvalColor(sc);
color = evalColor;
alpha = evalColor.a;
}
#if 1
AColor black;
black.Black();
AColor white;
white.White();
SIllumParams ip;
if( fBasicPB->GetInt( kNormal ) == kEmissive )
{
// Emissive objects don't get shaded
ip.diffIllum = fBasicPB->GetColor(kColorAmb, t) * color;
ip.diffIllum.ClampMinMax();
ip.specIllum = black;
}
else
{
//
// Shading setup
//
// Setup the parameters for the shader
ip.amb = black;
ip.diff = fBasicPB->GetColor(kColor, t) * color;
ip.spec = white;
ip.diffIllum = black;
ip.specIllum = black;
ip.N = sc.Normal();
ip.V = sc.V();
//
// Specularity
//
ip.sh_str = 0;
ip.ph_exp = 0;
ip.shine = 0;
ip.softThresh = 0;
// Do the shading
Shader *myShader = GetShader(SHADER_BLINN);
myShader->Illum(sc, ip);
ip.diffIllum.ClampMinMax();
ip.specIllum.ClampMinMax();
ip.diffIllum = ip.amb * sc.ambientLight + ip.diff * ip.diffIllum;
}
// AColor returnColor = AColor(opac * ip.diffIllum + ip.specIllum, opac)
#endif
// Get opacity and combine with alpha
float opac = float(fBasicPB->GetInt(kOpacity, t)) / 100.0f;
//float opac = 1.0f;
alpha *= opac;
// MAX will do the additive/alpha/no blending for us based on what Requirements()
// we tell it. However, since MAX's formula is bgnd*sc.out.t + sc.out.c,
// we have to multiply our output color by the alpha.
// If we ever need a more complicated blending function, you can request the
// background color via Requirements() (otherwise it's just black) and then do
// the blending yourself; however, if the transparency isn't set, the shadows
// will be opaque, so be careful.
Color outC = ip.diffIllum + ip.specIllum;
sc.out.c = ( outC * alpha );
sc.out.t = Color( 1.f - alpha, 1.f - alpha, 1.f - alpha );
#endif
}
void OrenNayarBlinnShader::Illum(ShadeContext &sc, IllumParams &ip)
{
LightDesc *l;
Color lightCol;
#ifdef _DEBUG
IPoint2 sp = sc.ScreenCoord();
if ( sp.x == stopX && sp.y == stopY )
sp.x = stopX;
#endif
// Blinn style phong
BOOL isShiny= (ip.channels[ID_SS].r > 0.0f) ? 1 : 0;
double phExp = 0.0;
if (isShiny)
phExp = pow(2.0, ip.channels[ID_SH].r * 10.0) * 4.0;
for (int i=0; i<sc.nLights; i++) {
l = sc.Light(i);
float NL, kL;
Point3 L;
if (l->Illuminate( sc, sc.Normal(), lightCol, L, NL, kL)) {
if (l->ambientOnly) {
ip.ambIllumOut += lightCol;
continue;
}
if (NL<=0.0f)
continue;
// specular
Color spec( 0.0f, 0.0f, 0.0f );
if (isShiny && l->affectSpecular) {
Point3 H = Normalize(L-sc.V() ); // (L + -V)/2
float c = DotProd(sc.Normal(), H);
if (c>0.0f) {
if (softThresh != 0.0 && kL < softThresh) {
c *= Soften(kL/softThresh);
}
c = (float)pow((double)c, phExp); // could use table lookup for speed
spec = c * ip.channels[ID_SS].r * lightCol;
ip.specIllumOut += spec;
}
}
// diffuse
if (l->affectDiffuse){
float diffIntens;
Color d = OrenNayarIllum( sc.Normal(), L, sc.V(), ip.channels[ID_DIFF_ROUGH].r * Pi*0.5f, ip.channels[ID_DI], &diffIntens, NL );
d = d * ip.channels[ID_DIFF_LEV].r;
ip.diffIllumOut += kL * d * lightCol;
ip.diffIllumIntens += kL * diffIntens * Intens(lightCol);
}
}
} // for each light
// Apply mono self illumination
if ( ! selfIllumClrOn ){
float si = 0.3333333f * (ip.channels[ID_SI].r + ip.channels[ID_SI].g + ip.channels[ID_SI].b);
// float si = ip.channels[ID_SI].r; //DS: 4/23/99
if ( si > 0.0f ) {
si = Bound( si );
ip.selfIllumOut = si * ip.channels[ID_DI];
ip.diffIllumOut *= (1.0f - si);
// fade the ambient down on si: 5/27/99 ke
ip.ambIllumOut *= 1.0f-si;
}
}
else {
// colored self illum,
ip.selfIllumOut += ip.channels[ID_SI];
}
// get the diffuse intensity...unscramble the wavelength dependence
// float rho, diffIntens;
// rho = ip.channels[ID_DI].r == 0.0f ? 1.0f : 1.0f / ip.channels[ID_DI].r;
// diffIntens = ip.diffIllumOut.r * rho;
// rho = ip.channels[ID_DI].g == 0.0f ? 1.0f : 1.0f / ip.channels[ID_DI].g;
// diffIntens += ip.diffIllumOut.g * rho;
// rho = ip.channels[ID_DI].b == 0.0f ? 1.0f : 1.0f / ip.channels[ID_DI].b;
// diffIntens += ip.diffIllumOut.b * rho;
// ip.diffIllumIntens = diffIntens * 0.5f;
// now we can multiply by the clrs
ip.specIllumOut *= ip.channels[ID_SP];
ip.ambIllumOut *= ip.channels[ID_AM];
int chan = ip.stdIDToChannel[ ID_RR ];
ShadeTransmission(sc, ip, ip.channels[chan], ip.refractAmt);
chan = ip.stdIDToChannel[ ID_RL ];
ShadeReflection( sc, ip, ip.channels[chan] );
if (sc.globContext != NULL && sc.globContext->pToneOp != NULL) {
if (isInvertSelfIllum())
sc.globContext->pToneOp->RGBToScaled(ip.selfIllumOut);
if (isInvertReflect() && (ip.hasComponents & HAS_REFLECT))
sc.globContext->pToneOp->RGBToScaled(ip.reflIllumOut);
if (isInvertRefract() && (ip.hasComponents & HAS_REFRACT))
sc.globContext->pToneOp->RGBToScaled(ip.transIllumOut);
}
CombineComponents( sc, ip );
}
void StraussShader::Illum(ShadeContext &sc, IllumParams &ip)
{
LightDesc *l;
Color lightClr;
#ifdef _DEBUG
IPoint2 sp = sc.ScreenCoord();
if ( sp.x == stopX && sp.y == stopY )
sp.x = stopX;
#endif
float opac = ip.channels[ S_TR ].r;
float g = ip.channels[ S_GL ].r;
float m = ip.channels[ S_MT ].r;
Color Cd = ip.channels[ S_DI ];
// BOOL dimDiffuse = ip.hasComponents & HAS_REFLECT;
BOOL dimDiffuse = ip.hasComponents & HAS_REFLECT_MAP;
float rd;
float g3 = Cube( g );
if ( dimDiffuse )
rd = (1.0f - g3) * opac;
else
rd = (1.0f - m * g3) * opac; //ke 10/28/98
float rn = opac - (1.0f - g3) * opac;
float h = (g == 1.0f ) ? 600.0f : 3.0f / (1.0f - g );
float d = 1.0f - m * g;
for (int i=0; i<sc.nLights; i++) {
l = sc.Light(i);
float NL, Kl;
Point3 L;
if (l->Illuminate( sc, sc.Normal(), lightClr, L, NL, Kl)) {
if (l->ambientOnly) {
ip.ambIllumOut += lightClr;
continue;
}
if (NL<=0.0f)
continue;
// diffuse
if (l->affectDiffuse){
ip.diffIllumOut += Kl * d * rd * lightClr;
}
// specular
if (l->affectSpecular) {
// strauss uses the reflected LIGHT vector
Point3 R = L - 2.0f * NL * sc.Normal();
R = Normalize( R );
float RV = -Dot(R, sc.V() );
float s;
if (RV < 0.0f) {
// soften
if ( NL < softThresh )
RV *= SoftSpline2( NL / softThresh );
// specular function
s = SpecBoost * (float)pow( -RV, h);
} else
continue;
float a, b;
a = (float)acos( NL ) * OneOverHalfPi;
b = (float)acos( -Dot(sc.Normal(), sc.V()) ) * OneOverHalfPi;
float fa = F( a );
float j = fa * G( a ) * G( b );
float rj = rn > 0.0f ? Bound( rn + (rn+kj)*j ) : rn;
Color Cl = lightClr;
// normalize the light color in case it's really bright
float I = NormClr( Cl );
Color Cs = Cl + m * (1.0f - fa) * (Cd - Cl);
ip.specIllumOut += s * rj * I * Cs;
} // end, if specular
} // end, illuminate
} // for each light
// now we can multiply by the clrs, except specular, which is already done
ip.ambIllumOut *= 0.5f * rd * Cd;
ip.diffIllumIntens = Intens(ip.diffIllumOut);
ip.diffIllumOut *= Cd;
// next due reflection
if ( ip.hasComponents & HAS_REFLECT ){
Color rc = ip.channels[ ip.stdIDToChannel[ ID_RL ] ];
AffectReflection(sc, ip, rc);
ip.reflIllumOut = rc * ip.reflectAmt;
}
// last do refraction/ opacity
if ( (ip.hasComponents & HAS_REFRACT) ){
// Set up attenuation opacity for Refraction map. dim diffuse & spec by this
ip.finalAttenuation = ip.finalOpac * (1.0f - ip.refractAmt);
// Make more opaque where specular hilite occurs:
float max = Max(ip.specIllumOut);
if (max > 1.0f) max = 1.0f;
float newOpac = ip.finalAttenuation + max - ip.finalAttenuation * max;
// Evaluate refraction map, filtered by filter color.
// Color tClr = ((StdMat2*)(ip.pMtl))->TranspColor( newOpac, ip.channels[filtChan], ip.channels[diffChan]);
Color tClr = transpColor( TRANSP_FILTER, newOpac, Cd, Cd );
ip.transIllumOut = ip.channels[ ip.stdIDToChannel[ ID_RR ] ] * tClr;
// no transparency when doing refraction
ip.finalT.Black();
} else {
// no refraction, transparent?
ip.finalAttenuation = opac;
if (ip.hasComponents & HAS_OPACITY) {
// ip.finalT = Cd * (1.0f-opac);
Cd = greyVal * Color( 1.0f, 1.0f, 1.0f ) + clrVal * Cd;
ip.finalT = transpColor( TRANSP_FILTER, opac, Cd, Cd );
}
}
if (sc.globContext != NULL && sc.globContext->pToneOp != NULL) {
if (isInvertSelfIllum())
sc.globContext->pToneOp->RGBToScaled(ip.selfIllumOut);
if (isInvertReflect() && (ip.hasComponents & HAS_REFLECT))
sc.globContext->pToneOp->RGBToScaled(ip.reflIllumOut);
if (isInvertRefract() && (ip.hasComponents & HAS_REFRACT))
sc.globContext->pToneOp->RGBToScaled(ip.transIllumOut);
}
CombineComponents( sc, ip );
}
void WardShader::Illum(ShadeContext &sc, IllumParams &ip) {
LightDesc *l;
Color lightCol;
#ifdef _DEBUG
IPoint2 sp = sc.ScreenCoord();
if ( sp.x == stopX && sp.y == stopY )
sp.x = stopX;
#endif
BOOL isShiny= (ip.channels[W_SL].r > 0.0f) ? 1 : 0;
for (int i=0; i<sc.nLights; i++) {
l = sc.Light(i);
float NL, Kl;
Point3 L;
if (l->Illuminate( sc, sc.Normal(), lightCol, L, NL, Kl)) {
if (l->ambientOnly) {
ip.ambIllumOut += lightCol;
continue;
}
if (NL<=0.0f)
continue;
// diffuse
if (l->affectDiffuse){
ip.diffIllumOut += Kl / Pi * ip.channels[W_DL].r * lightCol;
}
// specular
if (isShiny && l->affectSpecular) {
float gx = ip.channels[W_GX].r;
float gy = ip.channels[W_GY].r;
assert( gx >= 0.0f && gy >= 0.0f );
Point3 H = Normalize(L - sc.V() ); // (L + -V)/2
float NH = DotProd(sc.Normal(), H);
if (NH > 0.0f) {
float g2 = normalizeOn ? gx * gy : DEFAULT_GLOSS2;
float norm = 1.0f / (4.0f * PI * g2);
float NV = -DotProd(sc.Normal(), sc.V() );
if ( NV <= 0.001f)
NV = 0.001f;
float g = 1.0f / (float)sqrt( NL * NV );
if ( g > 6.0f ) g = 6.0f;
//Point3 basisVecs[ 3 ];
//sc.DPdUVW( basisVecs, uvChan ); // 0 is vtxclr, 1..n is uv channels, max_meshmaps in mesh.h
//basisVecs[0] = Normalize( basisVecs[0] );
// This is the new preferred method for getting bump basis vectors -- DS 5/22/00
Point3 basisVecs[2];
sc.BumpBasisVectors(basisVecs, 0, uvChan);
// the line between the tip of vec[0] and its projection on N is tangent
Point3 T = basisVecs[0] - sc.Normal() * Dot( basisVecs[0], sc.Normal() );
Point3 B = CrossProd( sc.Normal(), T );
float x = DotProd( H, T ) / gx;
float y = DotProd( H, B ) / gy;
float e = (float)exp( -2.0 * (x*x + y*y) / (1.0+NH) );
ip.specIllumOut += Kl * ip.channels[W_SL].r * norm * g * e * lightCol;
}
}
}
} // for each light
// now we can multiply by the clrs,
ip.ambIllumOut *= ip.channels[W_AM];
ip.diffIllumIntens = Intens(ip.diffIllumOut);
ip.diffIllumOut *= ip.channels[W_DI];
ip.specIllumOut *= ip.channels[W_SP];
int chan = ip.stdIDToChannel[ ID_RR ];
ShadeTransmission(sc, ip, ip.channels[chan], ip.refractAmt);
chan = ip.stdIDToChannel[ ID_RL ];
ShadeReflection( sc, ip, ip.channels[chan] );
if (sc.globContext != NULL && sc.globContext->pToneOp != NULL) {
if (isInvertSelfIllum())
sc.globContext->pToneOp->RGBToScaled(ip.selfIllumOut);
if (isInvertReflect() && (ip.hasComponents & HAS_REFLECT))
sc.globContext->pToneOp->RGBToScaled(ip.reflIllumOut);
if (isInvertRefract() && (ip.hasComponents & HAS_REFRACT))
sc.globContext->pToneOp->RGBToScaled(ip.transIllumOut);
}
CombineComponents( sc, ip );
}
