/*
******** tenGradientJitter
**
** moves all gradients by amount dist on tangent plane, in a random
** direction, and then renormalizes. The distance is a fraction
** of the ideal edge length (via tenGradientIdealEdge)
*/
int
tenGradientJitter(Nrrd *nout, const Nrrd *nin, double dist) {
static const char me[]="tenGradientJitter";
double *grad, perp0[3], perp1[3], len, theta, cc, ss, edge;
unsigned int gi, num;
if (nrrdConvert(nout, nin, nrrdTypeDouble)) {
biffMovef(TEN, NRRD, "%s: trouble converting input to double", me);
return 1;
}
if (tenGradientCheck(nout, nrrdTypeDouble, 3)) {
biffAddf(TEN, "%s: didn't get valid gradients", me);
return 1;
}
grad = AIR_CAST(double*, nout->data);
num = AIR_UINT(nout->axis[1].size);
/* HEY: possible confusion between single and not */
edge = tenGradientIdealEdge(num, AIR_FALSE);
for (gi=0; gi<num; gi++) {
ELL_3V_NORM(grad, grad, len);
ell_3v_perp_d(perp0, grad);
ELL_3V_CROSS(perp1, perp0, grad);
theta = AIR_AFFINE(0, airDrandMT(), 1, 0, 2*AIR_PI);
cc = dist*edge*cos(theta);
ss = dist*edge*sin(theta);
ELL_3V_SCALE_ADD3(grad, 1.0, grad, cc, perp0, ss, perp1);
ELL_3V_NORM(grad, grad, len);
grad += 3;
}
return 0;
}
void
_tenFiberStep_TensorLine(tenFiberContext *tfx, double step[3]) {
double cl, evec0[3], vout[3], vin[3], len;
ELL_3V_COPY(evec0, tfx->evec + 3*0);
_tenFiberAlign(tfx, evec0);
if (tfx->lastDirSet) {
ELL_3V_COPY(vin, tfx->lastDir);
TEN_T3V_MUL(vout, tfx->dten, tfx->lastDir);
ELL_3V_NORM(vout, vout, len);
_tenFiberAlign(tfx, vout); /* HEY: is this needed? */
} else {
ELL_3V_COPY(vin, evec0);
ELL_3V_COPY(vout, evec0);
}
cl = (tfx->eval[0] - tfx->eval[1])/(tfx->eval[0] + 0.00001);
ELL_3V_SCALE_ADD3(step,
cl, evec0,
(1-cl)*(1-tfx->wPunct), vin,
(1-cl)*tfx->wPunct, vout);
/* _tenFiberAlign(tfx, step); */
ELL_3V_NORM(step, step, len);
if (tfx->anisoSpeedType) {
_tenFiberAnisoSpeed(step, *(tfx->anisoSpeed),
tfx->anisoSpeedFunc);
}
}
void
_ra2t(Nrrd *nten, double rad, double angle,
double mRI[9], double mRF[9], double hack) {
double x, y, xyz[3], XX[3], YY[3], CC[3], EE[3], VV[3], tmp, mD[9], mT[9];
float *tdata;
int xi, yi, sx, sy;
sx = nten->axis[1].size;
sy = nten->axis[2].size;
x = rad*sin(AIR_PI*angle/180);
y = rad*cos(AIR_PI*angle/180);
xi = airIndexClamp(0.0, x, sqrt(3.0)/2.0, sx);
yi = airIndexClamp(0.0, y, 0.5, sy);
ELL_3V_SET(VV, 0, 3, 0);
ELL_3V_SET(EE, 1.5, 1.5, 0);
ELL_3V_SET(CC, 1, 1, 1);
ELL_3V_SUB(YY, EE, CC);
ELL_3V_SUB(XX, VV, EE);
ELL_3V_NORM(XX, XX, tmp);
ELL_3V_NORM(YY, YY, tmp);
ELL_3V_SCALE_ADD3(xyz, 1.0, CC, hack*x, XX, hack*y, YY);
ELL_3M_IDENTITY_SET(mD);
ELL_3M_DIAG_SET(mD, xyz[0], xyz[1], xyz[2]);
ELL_3M_IDENTITY_SET(mT);
ell_3m_post_mul_d(mT, mRI);
ell_3m_post_mul_d(mT, mD);
ell_3m_post_mul_d(mT, mRF);
tdata = (float*)(nten->data) + 7*(xi + sx*(yi + 1*sy));
tdata[0] = 1.0;
TEN_M2T(tdata, mT);
}
/*
** leaves v+3*0 untouched, but makes sure that v+3*0, v+3*1, and v+3*2
** are mutually orthogonal. Also leaves the magnitudes of all
** vectors unchanged.
*/
void
_ell_3m_enforce_orthogonality(double v[9]) {
double d00, d10, d11, d20, d21, d22, scl, tv[3];
d00 = ELL_3V_DOT(v+3*0, v+3*0);
d10 = ELL_3V_DOT(v+3*1, v+3*0);
d11 = ELL_3V_DOT(v+3*1, v+3*1);
ELL_3V_SCALE_ADD2(tv, 1, v+3*1, -d10/d00, v+3*0);
scl = sqrt(d11/ELL_3V_DOT(tv, tv));
ELL_3V_SCALE(v+3*1, scl, tv);
d20 = ELL_3V_DOT(v+3*2, v+3*0);
d21 = ELL_3V_DOT(v+3*2, v+3*1);
d22 = ELL_3V_DOT(v+3*2, v+3*2);
ELL_3V_SCALE_ADD3(tv, 1, v+3*2, -d20/d00, v+3*0, -d21/d00, v+3*1);
scl = sqrt(d22/ELL_3V_DOT(tv, tv));
ELL_3V_SCALE(v+3*2, scl, tv);
return;
}
/*
******* echoLightPosition()
**
** sets "pos" to xyz position for current sample of given light
*/
void
echoLightPosition(echoPos_t pos[3], echoObject *light,
echoThreadState *tstate) {
char me[]="echoLightPos";
echoPos_t x, y;
echoRectangle *rectLight;
x = tstate->jitt[0 + 2*echoJittableLight] + 0.5;
y = tstate->jitt[1 + 2*echoJittableLight] + 0.5;
switch(light->type) {
case echoTypeRectangle:
rectLight = RECTANGLE(light);
ELL_3V_SCALE_ADD3(pos, 1, rectLight->origin,
x, rectLight->edge0,
y, rectLight->edge1);
break;
default:
fprintf(stderr, "%s: currently only support echoTypeRectangle lights", me);
break;
}
return;
}
int
tenGlyphGen(limnObject *glyphsLimn, echoScene *glyphsEcho,
tenGlyphParm *parm,
const Nrrd *nten, const Nrrd *npos, const Nrrd *nslc) {
static const char me[]="tenGlyphGen";
gageShape *shape;
airArray *mop;
float *tdata, eval[3], evec[9], *cvec, rotEvec[9], mA_f[16],
absEval[3], glyphScl[3];
double pI[3], pW[3], cl, cp, sRot[16], mA[16], mB[16], msFr[9], tmpvec[3],
R, G, B, qA, qB, qC, glyphAniso, sliceGray;
unsigned int duh;
int slcCoord[3], idx, glyphIdx, axis, numGlyphs,
svRGBAfl=AIR_FALSE;
limnLook *look; int lookIdx;
echoObject *eglyph, *inst, *list=NULL, *split, *esquare;
echoPos_t eM[16], originOffset[3], edge0[3], edge1[3];
char stmp[AIR_STRLEN_SMALL];
/*
int eret;
double tmp1[3], tmp2[3];
*/
if (!( (glyphsLimn || glyphsEcho) && nten && parm)) {
biffAddf(TEN, "%s: got NULL pointer", me);
return 1;
}
mop = airMopNew();
shape = gageShapeNew();
shape->defaultCenter = nrrdCenterCell;
airMopAdd(mop, shape, (airMopper)gageShapeNix, airMopAlways);
if (npos) {
if (!( 2 == nten->dim && 7 == nten->axis[0].size )) {
biffAddf(TEN, "%s: nten isn't 2-D 7-by-N array", me);
airMopError(mop); return 1;
}
if (!( 2 == npos->dim && 3 == npos->axis[0].size
&& nten->axis[1].size == npos->axis[1].size )) {
biffAddf(TEN, "%s: npos isn't 2-D 3-by-%s array", me,
airSprintSize_t(stmp, nten->axis[1].size));
airMopError(mop); return 1;
}
if (!( nrrdTypeFloat == nten->type && nrrdTypeFloat == npos->type )) {
biffAddf(TEN, "%s: nten and npos must be %s, not %s and %s", me,
airEnumStr(nrrdType, nrrdTypeFloat),
airEnumStr(nrrdType, nten->type),
airEnumStr(nrrdType, npos->type));
airMopError(mop); return 1;
}
} else {
if (tenTensorCheck(nten, nrrdTypeFloat, AIR_TRUE, AIR_TRUE)) {
biffAddf(TEN, "%s: didn't get a valid DT volume", me);
airMopError(mop); return 1;
}
}
if (tenGlyphParmCheck(parm, nten, npos, nslc)) {
biffAddf(TEN, "%s: trouble", me);
airMopError(mop); return 1;
}
if (!npos) {
if (gageShapeSet(shape, nten, tenGageKind->baseDim)) {
biffMovef(TEN, GAGE, "%s: trouble", me);
airMopError(mop); return 1;
}
}
if (parm->doSlice) {
ELL_3V_COPY(edge0, shape->spacing);
ELL_3V_COPY(edge1, shape->spacing);
edge0[parm->sliceAxis] = edge1[parm->sliceAxis] = 0.0;
switch(parm->sliceAxis) {
case 0:
edge0[1] = edge1[2] = 0;
ELL_4M_ROTATE_Y_SET(sRot, AIR_PI/2);
break;
case 1:
edge0[0] = edge1[2] = 0;
ELL_4M_ROTATE_X_SET(sRot, AIR_PI/2);
break;
case 2: default:
edge0[0] = edge1[1] = 0;
ELL_4M_IDENTITY_SET(sRot);
break;
}
ELL_3V_COPY(originOffset, shape->spacing);
ELL_3V_SCALE(originOffset, -0.5, originOffset);
originOffset[parm->sliceAxis] *= -2*parm->sliceOffset;
}
if (glyphsLimn) {
/* create limnLooks for diffuse and ambient-only shading */
/* ??? */
/* hack: save old value of setVertexRGBAFromLook, and set to true */
svRGBAfl = glyphsLimn->setVertexRGBAFromLook;
glyphsLimn->setVertexRGBAFromLook = AIR_TRUE;
}
if (glyphsEcho) {
list = echoObjectNew(glyphsEcho, echoTypeList);
}
if (npos) {
numGlyphs = AIR_UINT(nten->axis[1].size);
} else {
numGlyphs = shape->size[0] * shape->size[1] * shape->size[2];
}
/* find measurement frame transform */
if (3 == nten->spaceDim
&& AIR_EXISTS(nten->measurementFrame[0][0])) {
/* msFr nten->measurementFrame
** 0 1 2 [0][0] [1][0] [2][0]
** 3 4 5 [0][1] [1][1] [2][1]
** 6 7 8 [0][2] [1][2] [2][2]
*/
msFr[0] = nten->measurementFrame[0][0];
msFr[3] = nten->measurementFrame[0][1];
msFr[6] = nten->measurementFrame[0][2];
msFr[1] = nten->measurementFrame[1][0];
msFr[4] = nten->measurementFrame[1][1];
msFr[7] = nten->measurementFrame[1][2];
msFr[2] = nten->measurementFrame[2][0];
msFr[5] = nten->measurementFrame[2][1];
msFr[8] = nten->measurementFrame[2][2];
} else {
ELL_3M_IDENTITY_SET(msFr);
}
for (idx=0; idx<numGlyphs; idx++) {
tdata = (float*)(nten->data) + 7*idx;
if (parm->verbose >= 2) {
fprintf(stderr, "%s: glyph %d/%d: hello %g %g %g %g %g %g %g\n",
me, idx, numGlyphs, tdata[0],
tdata[1], tdata[2], tdata[3],
tdata[4], tdata[5], tdata[6]);
}
if (!( TEN_T_EXISTS(tdata) )) {
/* there's nothing we can do here */
if (parm->verbose >= 2) {
fprintf(stderr, "%s: glyph %d/%d: non-existent data\n",
me, idx, numGlyphs);
}
continue;
}
if (npos) {
ELL_3V_COPY(pW, (float*)(npos->data) + 3*idx);
if (!( AIR_EXISTS(pW[0]) && AIR_EXISTS(pW[1]) && AIR_EXISTS(pW[2]) )) {
/* position doesn't exist- perhaps because its from the push
library, which might kill points by setting coords to nan */
continue;
}
} else {
NRRD_COORD_GEN(pI, shape->size, 3, idx);
/* this does take into account full orientation */
gageShapeItoW(shape, pW, pI);
if (parm->nmask) {
if (!( nrrdFLookup[parm->nmask->type](parm->nmask->data, idx)
>= parm->maskThresh )) {
if (parm->verbose >= 2) {
fprintf(stderr, "%s: glyph %d/%d: doesn't meet mask thresh\n",
me, idx, numGlyphs);
}
continue;
}
}
}
tenEigensolve_f(eval, evec, tdata);
/* transform eigenvectors by measurement frame */
ELL_3MV_MUL(tmpvec, msFr, evec + 0);
ELL_3V_COPY_TT(evec + 0, float, tmpvec);
ELL_3MV_MUL(tmpvec, msFr, evec + 3);
ELL_3V_COPY_TT(evec + 3, float, tmpvec);
ELL_3MV_MUL(tmpvec, msFr, evec + 6);
ELL_3V_COPY_TT(evec + 6, float, tmpvec);
ELL_3V_CROSS(tmpvec, evec + 0, evec + 3);
if (0 > ELL_3V_DOT(tmpvec, evec + 6)) {
ELL_3V_SCALE(evec + 6, -1, evec + 6);
}
ELL_3M_TRANSPOSE(rotEvec, evec);
if (parm->doSlice
&& pI[parm->sliceAxis] == parm->slicePos) {
/* set sliceGray */
if (nslc) {
/* we aren't masked by confidence, as anisotropy slice is */
for (duh=0; duh<parm->sliceAxis; duh++) {
slcCoord[duh] = (int)(pI[duh]);
}
for (duh=duh<parm->sliceAxis; duh<2; duh++) {
slcCoord[duh] = (int)(pI[duh+1]);
}
/* HEY: GLK has no idea what's going here */
slcCoord[0] = (int)(pI[0]);
slcCoord[1] = (int)(pI[1]);
slcCoord[2] = (int)(pI[2]);
sliceGray =
nrrdFLookup[nslc->type](nslc->data, slcCoord[0]
+ nslc->axis[0].size*slcCoord[1]);
} else {
if (!( tdata[0] >= parm->confThresh )) {
if (parm->verbose >= 2) {
fprintf(stderr, "%s: glyph %d/%d (slice): conf %g < thresh %g\n",
me, idx, numGlyphs, tdata[0], parm->confThresh);
}
continue;
}
sliceGray = tenAnisoEval_f(eval, parm->sliceAnisoType);
}
if (parm->sliceGamma > 0) {
sliceGray = AIR_AFFINE(0, sliceGray, 1, parm->sliceBias, 1);
sliceGray = pow(sliceGray, 1.0/parm->sliceGamma);
} else {
sliceGray = AIR_AFFINE(0, sliceGray, 1, 0, 1-parm->sliceBias);
sliceGray = 1.0 - pow(sliceGray, -1.0/parm->sliceGamma);
}
/* make slice contribution */
/* HEY: this is *NOT* aware of shape->fromOrientation */
if (glyphsLimn) {
lookIdx = limnObjectLookAdd(glyphsLimn);
look = glyphsLimn->look + lookIdx;
ELL_4V_SET_TT(look->rgba, float, sliceGray, sliceGray, sliceGray, 1);
ELL_3V_SET(look->kads, 1, 0, 0);
look->spow = 0;
glyphIdx = limnObjectSquareAdd(glyphsLimn, lookIdx);
ELL_4M_IDENTITY_SET(mA);
ell_4m_post_mul_d(mA, sRot);
if (!npos) {
ELL_4M_SCALE_SET(mB,
shape->spacing[0],
shape->spacing[1],
shape->spacing[2]);
}
ell_4m_post_mul_d(mA, mB);
ELL_4M_TRANSLATE_SET(mB, pW[0], pW[1], pW[2]);
ell_4m_post_mul_d(mA, mB);
ELL_4M_TRANSLATE_SET(mB,
originOffset[0],
originOffset[1],
originOffset[2]);
ell_4m_post_mul_d(mA, mB);
ELL_4M_COPY_TT(mA_f, float, mA);
limnObjectPartTransform(glyphsLimn, glyphIdx, mA_f);
}
if (glyphsEcho) {
esquare = echoObjectNew(glyphsEcho,echoTypeRectangle);
ELL_3V_ADD2(((echoRectangle*)esquare)->origin, pW, originOffset);
ELL_3V_COPY(((echoRectangle*)esquare)->edge0, edge0);
ELL_3V_COPY(((echoRectangle*)esquare)->edge1, edge1);
echoColorSet(esquare,
AIR_CAST(echoCol_t, sliceGray),
AIR_CAST(echoCol_t, sliceGray),
AIR_CAST(echoCol_t, sliceGray), 1);
/* this is pretty arbitrary- but I want shadows to have some effect.
Previously, the material was all ambient: (A,D,S) = (1,0,0),
which avoided all shadow effects. */
echoMatterPhongSet(glyphsEcho, esquare, 0.4f, 0.6f, 0, 40);
echoListAdd(list, esquare);
}
}
if (parm->onlyPositive) {
if (eval[2] < 0) {
/* didn't have all positive eigenvalues, its outta here */
if (parm->verbose >= 2) {
fprintf(stderr, "%s: glyph %d/%d: not all evals %g %g %g > 0\n",
me, idx, numGlyphs, eval[0], eval[1], eval[2]);
}
continue;
}
}
if (!( tdata[0] >= parm->confThresh )) {
if (parm->verbose >= 2) {
fprintf(stderr, "%s: glyph %d/%d: conf %g < thresh %g\n",
me, idx, numGlyphs, tdata[0], parm->confThresh);
}
continue;
}
if (!( tenAnisoEval_f(eval, parm->anisoType) >= parm->anisoThresh )) {
if (parm->verbose >= 2) {
fprintf(stderr, "%s: glyph %d/%d: aniso[%d] %g < thresh %g\n",
me, idx, numGlyphs, parm->anisoType,
tenAnisoEval_f(eval, parm->anisoType), parm->anisoThresh);
}
continue;
}
glyphAniso = tenAnisoEval_f(eval, parm->colAnisoType);
/*
fprintf(stderr, "%s: eret = %d; evals = %g %g %g\n", me,
eret, eval[0], eval[1], eval[2]);
ELL_3V_CROSS(tmp1, evec+0, evec+3); tmp2[0] = ELL_3V_LEN(tmp1);
ELL_3V_CROSS(tmp1, evec+0, evec+6); tmp2[1] = ELL_3V_LEN(tmp1);
ELL_3V_CROSS(tmp1, evec+3, evec+6); tmp2[2] = ELL_3V_LEN(tmp1);
fprintf(stderr, "%s: crosses = %g %g %g\n", me,
tmp2[0], tmp2[1], tmp2[2]);
*/
/* set transform (in mA) */
ELL_3V_ABS(absEval, eval);
ELL_4M_IDENTITY_SET(mA); /* reset */
ELL_3V_SCALE(glyphScl, parm->glyphScale, absEval); /* scale by evals */
ELL_4M_SCALE_SET(mB, glyphScl[0], glyphScl[1], glyphScl[2]);
ell_4m_post_mul_d(mA, mB);
ELL_43M_INSET(mB, rotEvec); /* rotate by evecs */
ell_4m_post_mul_d(mA, mB);
ELL_4M_TRANSLATE_SET(mB, pW[0], pW[1], pW[2]); /* translate */
ell_4m_post_mul_d(mA, mB);
/* set color (in R,G,B) */
cvec = evec + 3*(AIR_CLAMP(0, parm->colEvec, 2));
R = AIR_ABS(cvec[0]); /* standard mapping */
G = AIR_ABS(cvec[1]);
B = AIR_ABS(cvec[2]);
/* desaturate by colMaxSat */
R = AIR_AFFINE(0.0, parm->colMaxSat, 1.0, parm->colIsoGray, R);
G = AIR_AFFINE(0.0, parm->colMaxSat, 1.0, parm->colIsoGray, G);
B = AIR_AFFINE(0.0, parm->colMaxSat, 1.0, parm->colIsoGray, B);
/* desaturate some by anisotropy */
R = AIR_AFFINE(0.0, parm->colAnisoModulate, 1.0,
R, AIR_AFFINE(0.0, glyphAniso, 1.0, parm->colIsoGray, R));
G = AIR_AFFINE(0.0, parm->colAnisoModulate, 1.0,
G, AIR_AFFINE(0.0, glyphAniso, 1.0, parm->colIsoGray, G));
B = AIR_AFFINE(0.0, parm->colAnisoModulate, 1.0,
B, AIR_AFFINE(0.0, glyphAniso, 1.0, parm->colIsoGray, B));
/* clamp and do gamma */
R = AIR_CLAMP(0.0, R, 1.0);
G = AIR_CLAMP(0.0, G, 1.0);
B = AIR_CLAMP(0.0, B, 1.0);
R = pow(R, parm->colGamma);
G = pow(G, parm->colGamma);
B = pow(B, parm->colGamma);
/* find axis, and superquad exponents qA and qB */
if (eval[2] > 0) {
/* all evals positive */
cl = AIR_MIN(0.99, tenAnisoEval_f(eval, tenAniso_Cl1));
cp = AIR_MIN(0.99, tenAnisoEval_f(eval, tenAniso_Cp1));
if (cl > cp) {
axis = 0;
qA = pow(1-cp, parm->sqdSharp);
qB = pow(1-cl, parm->sqdSharp);
} else {
axis = 2;
qA = pow(1-cl, parm->sqdSharp);
qB = pow(1-cp, parm->sqdSharp);
}
qC = qB;
} else if (eval[0] < 0) {
/* all evals negative */
float aef[3];
aef[0] = absEval[2];
aef[1] = absEval[1];
aef[2] = absEval[0];
cl = AIR_MIN(0.99, tenAnisoEval_f(aef, tenAniso_Cl1));
cp = AIR_MIN(0.99, tenAnisoEval_f(aef, tenAniso_Cp1));
if (cl > cp) {
axis = 2;
qA = pow(1-cp, parm->sqdSharp);
qB = pow(1-cl, parm->sqdSharp);
} else {
axis = 0;
qA = pow(1-cl, parm->sqdSharp);
qB = pow(1-cp, parm->sqdSharp);
}
qC = qB;
} else {
#define OOSQRT2 0.70710678118654752440
#define OOSQRT3 0.57735026918962576451
/* double poleA[3]={OOSQRT3, OOSQRT3, OOSQRT3}; */
double poleB[3]={1, 0, 0};
double poleC[3]={OOSQRT2, OOSQRT2, 0};
double poleD[3]={OOSQRT3, -OOSQRT3, -OOSQRT3};
double poleE[3]={OOSQRT2, 0, -OOSQRT2};
double poleF[3]={OOSQRT3, OOSQRT3, -OOSQRT3};
double poleG[3]={0, -OOSQRT2, -OOSQRT2};
double poleH[3]={0, 0, -1};
/* double poleI[3]={-OOSQRT3, -OOSQRT3, -OOSQRT3}; */
double funk[3]={0,4,2}, thrn[3]={1,4,4};
double octa[3]={0,2,2}, cone[3]={1,2,2};
double evalN[3], tmp, bary[3];
double qq[3];
ELL_3V_NORM(evalN, eval, tmp);
if (eval[1] >= -eval[2]) {
/* inside B-F-C */
ell_3v_barycentric_spherical_d(bary, poleB, poleF, poleC, evalN);
ELL_3V_SCALE_ADD3(qq, bary[0], octa, bary[1], thrn, bary[2], cone);
axis = 2;
} else if (eval[0] >= -eval[2]) {
/* inside B-D-F */
if (eval[1] >= 0) {
/* inside B-E-F */
ell_3v_barycentric_spherical_d(bary, poleB, poleE, poleF, evalN);
ELL_3V_SCALE_ADD3(qq, bary[0], octa, bary[1], funk, bary[2], thrn);
axis = 2;
} else {
/* inside B-D-E */
ell_3v_barycentric_spherical_d(bary, poleB, poleD, poleE, evalN);
ELL_3V_SCALE_ADD3(qq, bary[0], cone, bary[1], thrn, bary[2], funk);
axis = 0;
}
} else if (eval[0] < -eval[1]) {
/* inside D-G-H */
ell_3v_barycentric_spherical_d(bary, poleD, poleG, poleH, evalN);
ELL_3V_SCALE_ADD3(qq, bary[0], thrn, bary[1], cone, bary[2], octa);
axis = 0;
} else if (eval[1] < 0) {
/* inside E-D-H */
ell_3v_barycentric_spherical_d(bary, poleE, poleD, poleH, evalN);
ELL_3V_SCALE_ADD3(qq, bary[0], funk, bary[1], thrn, bary[2], octa);
axis = 0;
} else {
/* inside F-E-H */
ell_3v_barycentric_spherical_d(bary, poleF, poleE, poleH, evalN);
ELL_3V_SCALE_ADD3(qq, bary[0], thrn, bary[1], funk, bary[2], cone);
axis = 2;
}
qA = qq[0];
qB = qq[1];
qC = qq[2];
#undef OOSQRT2
#undef OOSQRT3
}
/* add the glyph */
if (parm->verbose >= 2) {
fprintf(stderr, "%s: glyph %d/%d: the glyph stays!\n",
me, idx, numGlyphs);
}
if (glyphsLimn) {
lookIdx = limnObjectLookAdd(glyphsLimn);
look = glyphsLimn->look + lookIdx;
ELL_4V_SET_TT(look->rgba, float, R, G, B, 1);
ELL_3V_SET(look->kads, parm->ADSP[0], parm->ADSP[1], parm->ADSP[2]);
look->spow = 0;
switch(parm->glyphType) {
case tenGlyphTypeBox:
glyphIdx = limnObjectCubeAdd(glyphsLimn, lookIdx);
break;
case tenGlyphTypeSphere:
glyphIdx = limnObjectPolarSphereAdd(glyphsLimn, lookIdx, axis,
2*parm->facetRes, parm->facetRes);
break;
case tenGlyphTypeCylinder:
glyphIdx = limnObjectCylinderAdd(glyphsLimn, lookIdx, axis,
parm->facetRes);
break;
case tenGlyphTypeSuperquad:
default:
glyphIdx =
limnObjectPolarSuperquadFancyAdd(glyphsLimn, lookIdx, axis,
AIR_CAST(float, qA),
AIR_CAST(float, qB),
AIR_CAST(float, qC), 0,
2*parm->facetRes,
parm->facetRes);
break;
}
ELL_4M_COPY_TT(mA_f, float, mA);
limnObjectPartTransform(glyphsLimn, glyphIdx, mA_f);
}
if (glyphsEcho) {
switch(parm->glyphType) {
case tenGlyphTypeBox:
eglyph = echoObjectNew(glyphsEcho, echoTypeCube);
/* nothing else to set */
break;
case tenGlyphTypeSphere:
eglyph = echoObjectNew(glyphsEcho, echoTypeSphere);
echoSphereSet(eglyph, 0, 0, 0, 1);
break;
case tenGlyphTypeCylinder:
eglyph = echoObjectNew(glyphsEcho, echoTypeCylinder);
echoCylinderSet(eglyph, axis);
break;
case tenGlyphTypeSuperquad:
default:
eglyph = echoObjectNew(glyphsEcho, echoTypeSuperquad);
echoSuperquadSet(eglyph, axis, qA, qB);
break;
}
echoColorSet(eglyph,
AIR_CAST(echoCol_t, R),
AIR_CAST(echoCol_t, G),
AIR_CAST(echoCol_t, B), 1);
echoMatterPhongSet(glyphsEcho, eglyph,
parm->ADSP[0], parm->ADSP[1],
parm->ADSP[2], parm->ADSP[3]);
inst = echoObjectNew(glyphsEcho, echoTypeInstance);
ELL_4M_COPY(eM, mA);
echoInstanceSet(inst, eM, eglyph);
echoListAdd(list, inst);
}
}
if (glyphsLimn) {
glyphsLimn->setVertexRGBAFromLook = svRGBAfl;
}
if (glyphsEcho) {
split = echoListSplit3(glyphsEcho, list, 10);
echoObjectAdd(glyphsEcho, split);
}
airMopOkay(mop);
return 0;
}
