int main(int argc, char** argv)
{
if (argc < 3) {
cerr << "Usage: " << argv[0]
<< " inputfile outputfile [max_coefs_u max_coefs_v]" << endl;
return 1;
}
ifstream in(argv[1]);
ofstream out(argv[2]);
if (!in || !out) {
cout << "Bad file(s) or filename(s)." << endl;
return 1;
}
ObjectHeader oh;
SplineSurface sf;
in >> oh >> sf;
int m = sf.numCoefs_v() - sf.order_v() + 1;
int n = sf.numCoefs_u() - sf.order_u() + 1;
if (argc >= 5) {
// Note the weird order (v then u)
m = min(atoi(argv[4])-sf.numCoefs_v(), m);
n = min(atoi(argv[3])-sf.numCoefs_u(), n);
}
int i;
vector<double> newknots_v;
vector<double> newknots_u;
for (i = 0; i < m; ++i) {
vector<double>::const_iterator it = sf.basis_v().begin();
double newknot = 0.5*it[sf.order_v()+i-1] + 0.5*it[sf.order_v()+i];
newknots_v.push_back(newknot);
}
for (i = 0; i < n; ++i) {
vector<double>::const_iterator it = sf.basis_u().begin();
double newknot = 0.5*it[sf.order_u()+i-1] + 0.5*it[sf.order_u()+i];
newknots_u.push_back(newknot);
}
sf.insertKnot_v(newknots_v);
sf.insertKnot_u(newknots_u);
out << oh << sf;
return 0;
}
//===========================================================================
SplineSurface*
LoftSurfaceCreator::loftSurfaceFromUnifiedCurves(vector<shared_ptr<SplineCurve> >::iterator
first_curve,
vector<double>::iterator first_param,
int nmb_crvs)
//===========================================================================
{
SplineSurface* surf = loftNonrationalSurface(first_curve, first_param, nmb_crvs);
if (first_curve[0]->rational())
{
int n = surf->numCoefs_u() * surf->numCoefs_v();
int kdim = surf->dimension() + 1;
bool all_positive = true;
vector<double>::const_iterator it = surf->rcoefs_begin();
it += (kdim - 1);
for (int i = 0; i < n; ++i)
if (it[kdim * i] <= 0.0)
{
all_positive = false;
break;
}
if (!all_positive)
{
delete surf;
surf = loftRationalSurface(first_curve, first_param, nmb_crvs);
}
}
return surf;
}
//==========================================================================
void GeometryTools::splitSurfaceIntoPatches(const SplineSurface& sf,
vector<SplineSurface>& pat)
//==========================================================================
{
SplineSurface orig = sf;
orig.makeBernsteinKnotsU();
orig.makeBernsteinKnotsV();
int num_u = orig.numCoefs_u();
int num_v = orig.numCoefs_v();
int order_u = orig.order_u();
int order_v = orig.order_v();
int numpat_u = num_u / order_u;
int numpat_v = num_v / order_v;
pat.resize(numpat_u * numpat_v);
typedef vector<double>::const_iterator const_iter;
const_iter itu = orig.basis_u().begin();
const_iter itv;
for (int i = 0; i < numpat_u; ++i) {
itv = orig.basis_v().begin();
for (int j = 0; j < numpat_v; ++j) {
shared_ptr<SplineSurface>
new_sf(orig.subSurface(*itu, *itv,
*(itu+order_u), *(itv+order_v)));
pat[numpat_u*j + i] = *new_sf;
itv += order_v;
}
itu += order_u;
}
return;
}
//==========================================================================
void GeometryTools::findDominant(const SplineSurface& surface,
Vector3D& dominant_u, Vector3D& dominant_v)
//==========================================================================
{
int nu = surface.numCoefs_u();
int nv = surface.numCoefs_v();
vector<double>::const_iterator start = surface.coefs_begin();
Vector3D temp;
// Dominant in u-direction
dominant_u = Vector3D(0.0, 0.0, 0.0);
for (int j = 0; j < nv; ++j) {
for (int dd = 0; dd < 3; ++dd) {
temp[dd] = *(start + 3*(nu*j + (nu-1)) + dd)
- *(start + 3*(nu*j) + dd);
}
dominant_u += temp;
}
// Dominant in v-direction
dominant_v = Vector3D(0.0, 0.0, 0.0);
for (int i = 0; i < nu; ++i) {
for (int dd = 0; dd < 3; ++dd) {
temp[dd] = *(start + 3*(nu*(nv-1) + i) + dd)
- *(start + 3*i + dd);
}
dominant_v += temp;
}
return;
}
//===========================================================================
vector<shared_ptr<SplineSurface> >
SurfaceCreators::separateRationalParts(const SplineSurface& sf)
//===========================================================================
{
bool rat = sf.rational();
ASSERT(rat);
int dim= sf.dimension();
int rdim = dim + 1;
vector<shared_ptr<SplineSurface> > sep_sfs;
vector<double> coefs(sf.coefs_begin(), sf.coefs_end());
int nmb1 = sf.numCoefs_u();
int nmb2 = sf.numCoefs_v();
vector<double> rcoefs;
int num_coefs = nmb1*nmb2;
vector<double>::const_iterator rcoef_iter = sf.rcoefs_begin();
for (int ki = 0; ki < num_coefs; ++ki) {
rcoefs.push_back(rcoef_iter[ki*rdim+1]);
for (int kj = 0; kj < dim; ++kj) {
coefs[ki*dim+kj] /= (rcoefs.back());
}
}
sep_sfs.push_back(shared_ptr<SplineSurface>
(new SplineSurface(nmb1, nmb2, sf.order_u(), sf.order_v(),
sf.basis_u().begin(), sf.basis_v().begin(),
coefs.begin(), dim)));
sep_sfs.push_back(shared_ptr<SplineSurface>
(new SplineSurface(nmb1, nmb2, sf.order_u(), sf.order_v(),
sf.basis_u().begin(), sf.basis_v().begin(),
rcoefs.begin(), 1)));
return sep_sfs;
}
int main()
{
ObjectHeader header;
SplineSurface surf;
cin >> header >> surf;
PointCloud<3> cloud(surf.coefs_begin(),
surf.numCoefs_u()*surf.numCoefs_v());
cloud.writeStandardHeader(cout);
cout << cloud;
}
//==========================================================================
bool GeometryTools::negativeProj(const SplineSurface& surface,
const Array<Vector3D, 2>& refvector,
const double eps)
//==========================================================================
{
int num_u = surface.numCoefs_u();
int num_v = surface.numCoefs_v();
Vector3D temp;
int i = 0, j = 0;
while (i < num_u-1) {
j = 0;
while (j < num_v) {
temp[0] = *(surface.coefs_begin() + 3*(num_u*j + i+1))
- *(surface.coefs_begin() + 3*(num_u*j + i));
temp[1] = *(surface.coefs_begin() + 3*(num_u*j + i+1) + 1)
- *(surface.coefs_begin() + 3*(num_u*j + i) + 1);
temp[2] = *(surface.coefs_begin() + 3*(num_u*j + i+1) + 2)
- *(surface.coefs_begin() + 3*(num_u*j + i) + 2);
// Positive tolerance means that there must be a small
// _nonzero_ negative projection before it is reported as
// negative!
if (temp * refvector[0] < -eps)
return true;
++j;
}
++i;
}
i = 0;
while (i < num_u) {
j = 0;
while (j < num_v-1) {
temp[0] = *(surface.coefs_begin() + 3*(num_u*(j+1) + i))
- *(surface.coefs_begin() + 3*(num_u*j + i));
temp[1] = *(surface.coefs_begin() + 3*(num_u*(j+1) + i) + 1)
- *(surface.coefs_begin() + 3*(num_u*j + i) +1);
temp[2] = *(surface.coefs_begin() + 3*(num_u*(j+1) + i) + 2)
- *(surface.coefs_begin() + 3*(num_u*j + i) + 2);
// Positive tolerance means that there must be a small
// _nonzero_ negative projection before it is reported as
// negative!
if (temp * refvector[1] < -eps)
return true;
++j;
}
++i;
}
return false;
}
//==========================================================================
void cart_to_bary(const SplineSurface& sf, const BaryCoordSystem3D& bc,
SplineSurface& sf_bc)
//==========================================================================
{
ALWAYS_ERROR_IF(sf.dimension() != 3, "Dimension must be 3.");
int nu = sf.numCoefs_u();
int nv = sf.numCoefs_v();
Vector3D cart;
Vector4D bary;
vector<double> new_coefs;
if (!sf.rational()) {
new_coefs.resize(4 * nu * nv);
for (int iv = 0; iv < nv; ++iv) {
for (int iu = 0; iu < nu; ++iu) {
int offset = nu * iv + iu;
cart = Vector3D(sf.coefs_begin() + 3 * offset);
bary = bc.cartToBary(cart);
for (int j = 0; j < 4; ++j) {
new_coefs[4*offset + j] = bary[j];
}
}
}
} else {
new_coefs.resize(5 * nu * nv);
for (int iv = 0; iv < nv; ++iv) {
for (int iu = 0; iu < nu; ++iu) {
int offset = nu * iv + iu;
cart = Vector3D(sf.coefs_begin() + 3 * offset);
bary = bc.cartToBary(cart);
double w = sf.rcoefs_begin()[4*offset + 3];
for (int j = 0; j < 4; ++j) {
new_coefs[5*offset + j] = bary[j] * w;
}
new_coefs[5*offset + 4] = w;
}
}
}
sf_bc = SplineSurface(nu, nv, sf.order_u(), sf.order_v(),
sf.basis_u().begin(), sf.basis_v().begin(),
new_coefs.begin(), 4, sf.rational());
return;
}
int main(int argc, char** argv)
{
if (argc != 6)
{
cout << "Usage: " << argv[0] << " surfaceinfile surface3doutfile points3doutfile num_u num_v" << endl;
exit(-1);
}
ifstream filein(argv[1]);
ALWAYS_ERROR_IF(filein.bad(), "Bad or no curvee input filename");
ObjectHeader head;
filein >> head;
if (head.classType() != SplineSurface::classType()) {
THROW("Not a spline surface");
}
SplineSurface sf;
filein >> sf;
ofstream fileoutsurf(argv[2]);
ALWAYS_ERROR_IF(fileoutsurf.bad(), "Bad surface output filename");
ofstream fileoutpts(argv[3]);
ALWAYS_ERROR_IF(fileoutpts.bad(), "Bad points output filename");
int num_u = atoi(argv[4]);
int num_v = atoi(argv[5]);
vector<double> pts, param_u, param_v;
sf.gridEvaluator(num_u, num_v, pts, param_u, param_v);
vector<double> coefs3d;
vector<Point> pts3d;
int dim = sf.dimension();
bool rational = sf.rational();
int ctrl_pts = sf.numCoefs_u() * sf.numCoefs_v();
vector<double>::const_iterator it = sf.ctrl_begin();
for (int i = 0; i < ctrl_pts; ++i)
{
if (dim <= 3)
for (int j = 0; j < 3; ++j)
{
if (j>=dim)
coefs3d.push_back(0.0);
else
{
coefs3d.push_back(*it);
++it;
}
}
else
{
for (int j = 0; j < 3; ++j, ++it)
coefs3d.push_back(*it);
it += (dim-3);
}
if (rational)
{
coefs3d.push_back(*it);
++it;
}
}
int pts_pos = 0;
for (int i = 0; i < num_u*num_v; ++i)
{
double x, y, z;
if (dim == 0)
x = 0.0;
else
x = pts[pts_pos];
if (dim <= 1)
y = 0.0;
else
y = pts[pts_pos+1];
if (dim <= 2)
z = 0.0;
else
z = pts[pts_pos+2];
pts_pos += dim;
pts3d.push_back(Point(x, y, z));
}
SplineSurface sf3d(sf.basis_u(), sf.basis_v(), coefs3d.begin(), 3, rational);
sf3d.writeStandardHeader(fileoutsurf);
sf3d.write(fileoutsurf);
fileoutpts << "400 1 0 4 255 255 0 255" << endl;
fileoutpts << pts3d.size() << endl;
for (int i = 0; i < (int)pts3d.size(); ++i)
fileoutpts << pts3d[i] << endl;
}
//===========================================================================
void SplineUtils::refinedBezierCoefsCubic(SplineSurface& spline_sf,
int ind_u_min, int ind_v_min,
vector<double>& bez_coefs)
//===========================================================================
{
assert(!spline_sf.rational());
if (bez_coefs.size() != 48)
bez_coefs.resize(48);
std::fill(bez_coefs.begin(), bez_coefs.end(), 0.0);
// Values for inpute spline surface.
int dim = spline_sf.dimension();
int order_u = spline_sf.order_u();
int order_v = spline_sf.order_u();
int num_coefs_u = spline_sf.numCoefs_u();
int num_coefs_v = spline_sf.numCoefs_v();
// Checking that input index is within range.
assert(ind_u_min >= order_u - 1 && ind_u_min < num_coefs_u);
assert(ind_v_min >= order_v - 1 && ind_v_min < num_coefs_v);
BsplineBasis& basis_u = spline_sf.basis_u();
BsplineBasis& basis_v = spline_sf.basis_v();
double* knot_u = &basis_u.begin()[0];
double* knot_v = &basis_v.begin()[0];
// We expect the knot index to refer to the last occurence.
assert(knot_u[ind_u_min] != knot_u[ind_u_min+1]);
assert(knot_v[ind_v_min] != knot_v[ind_v_min+1]);
// We expect knot mult to be 1 or 4.
int knot_mult_umin = (knot_u[ind_u_min-1] == knot_u[ind_u_min]) ? 4 : 1;
int knot_mult_umax = (knot_u[ind_u_min+1] == knot_u[ind_u_min+2]) ? 4 : 1;
int knot_mult_vmin = (knot_v[ind_v_min-1] == knot_v[ind_v_min]) ? 4 : 1;
int knot_mult_vmax = (knot_v[ind_v_min+1] == knot_v[ind_v_min+2]) ? 4 : 1;
bool kreg_at_ustart = (knot_mult_umin == 4);
bool kreg_at_uend = (knot_mult_umax == 4);
vector<double> transf_mat_u(16, 0.0);
// if (!kreg_at_ustart && !kreg_at_uend)
splineToBezierTransfMat(knot_u + ind_u_min - 3,
transf_mat_u);
#ifndef NDEBUG
std::cout << "\ntransf_mat_u=" << std::endl;
for (size_t kj = 0; kj < 4; ++kj)
{
for (size_t ki = 0; ki < 4; ++ki)
std::cout << transf_mat_u[kj*4+ki] << " ";
std::cout << std::endl;
}
std::cout << std::endl;
#endif // NDEBUG
// else
// cubicTransfMat(knot_u + ind_u_min - 3,
// kreg_at_ustart, kreg_at_uend,
// transf_mat_u);
bool kreg_at_vstart = (knot_mult_vmin == 4);
bool kreg_at_vend = (knot_mult_vmax == 4);
vector<double> transf_mat_v(16, 0.0);
// if (!kreg_at_ustart && !kreg_at_uend)
splineToBezierTransfMat(knot_v + ind_v_min - 3,
transf_mat_v);
#ifndef NDEBUG
std::cout << "\ntransf_mat_v=" << std::endl;
for (size_t kj = 0; kj < 4; ++kj)
{
for (size_t ki = 0; ki < 4; ++ki)
std::cout << transf_mat_v[kj*4+ki] << " ";
std::cout << std::endl;
}
std::cout << std::endl;
#endif // NDEBUG
extractBezierCoefs(&spline_sf.coefs_begin()[0],
num_coefs_u, num_coefs_v,
ind_u_min, ind_v_min,
transf_mat_u, transf_mat_v,
bez_coefs);
return;
}
