void CopyNcVarAttributes(
	NcVar * varIn,
	NcVar * varOut
) {
	for (int a = 0; a < varIn->num_atts(); a++) {
		NcAtt * att = varIn->get_att(a);
		long num_vals = att->num_vals();

		NcValues * pValues = att->values();

		if (att->type() == ncByte) {
			varOut->add_att(att->name(), num_vals,
				(const ncbyte*)(pValues->base()));

		} else if (att->type() == ncChar) {
			varOut->add_att(att->name(), num_vals,
				(const char*)(pValues->base()));

		} else if (att->type() == ncShort) {
			varOut->add_att(att->name(), num_vals,
				(const short*)(pValues->base()));

		} else if (att->type() == ncInt) {
			varOut->add_att(att->name(), num_vals,
				(const int*)(pValues->base()));

		} else if (att->type() == ncFloat) {
			varOut->add_att(att->name(), num_vals,
				(const float*)(pValues->base()));

		} else if (att->type() == ncDouble) {
			varOut->add_att(att->name(), num_vals,
				(const double*)(pValues->base()));

		} else {
			_EXCEPTIONT("Invalid attribute type");
		}

		delete pValues;
	}
}
Exemplo n.º 2
0
bool
RemapWidget::getVolumeInfo(QString volfile,
			   int &skipheaderbytes,
			   uchar &voxelType,
			   int &voxelUnit,
			   float &vx, float &vy, float &vz,
			   QString &description,
			   QList<float> &rawMap,
			   QList<uchar> &pvlMap,
			   int &depth,
			   int &width,
			   int &height)
{
  NcError err(NcError::verbose_nonfatal);

  NcFile pvlFile(volfile.toAscii().data(), NcFile::ReadOnly);

  if (!pvlFile.is_valid())
    {
      QMessageBox::information(0, "Error",
       QString("%1 is not a valid preprocessed volume file").arg(volfile));
      return false;
    }

  int i;
  NcAtt *att;
  char *attval;
  QString pvalue;

  att = pvlFile.get_att("description");
  if (att)
    {
      attval = att->as_string(0);
      description = attval;
      delete [] attval;
    }

  att = pvlFile.get_att("voxeltype");
  if (att)
    {
      attval = att->as_string(0);
      pvalue = attval;
      if (pvalue == "unsigned char")
	voxelType = Raw2Pvl::_UChar;
      if (pvalue == "char")
	voxelType = Raw2Pvl::_Char;
      if (pvalue == "unsigned short")
	voxelType = Raw2Pvl::_UShort;
      if (pvalue == "short")
	voxelType = Raw2Pvl::_Short;
      if (pvalue == "int")
	voxelType = Raw2Pvl::_Int;
      if (pvalue == "float")
	voxelType = Raw2Pvl::_Float;
      delete [] attval;
    }


  att = pvlFile.get_att("voxelunit");
  if (att)
    { 
      attval = att->as_string(0);
      pvalue = attval;
      voxelUnit = Raw2Pvl::_Nounit;
      if (pvalue == "angstrom")
	voxelUnit = Raw2Pvl::_Angstrom;
      else if (pvalue == "nanometer")
	voxelUnit = Raw2Pvl::_Nanometer;
      else if (pvalue == "micron")
	voxelUnit = Raw2Pvl::_Micron;
      else if (pvalue == "millimeter")
	voxelUnit = Raw2Pvl::_Millimeter;
      else if (pvalue == "centimeter")
	voxelUnit = Raw2Pvl::_Centimeter;
      else if (pvalue == "meter")
	voxelUnit = Raw2Pvl::_Meter;
      else if (pvalue == "kilometer")
	voxelUnit = Raw2Pvl::_Kilometer;
      else if (pvalue == "parsec")
	voxelUnit = Raw2Pvl::_Parsec;
      else if (pvalue == "kiloparsec")
	voxelUnit = Raw2Pvl::_Kiloparsec;
      delete [] attval;
    }
  
  
  att = pvlFile.get_att("gridsize");
  if (att)
    {
      depth = att->as_int(0);
      width = att->as_int(1);
      height = att->as_int(2);
    }

  att = pvlFile.get_att("voxelsize");
  if (att)
    {
      vx = att->as_float(0);
      vy = att->as_float(1);
      vz = att->as_float(2);
    }

  att = pvlFile.get_att("skipheaderbytes");
  if (att)
    skipheaderbytes = att->as_int(0);
  
  att = pvlFile.get_att("mapraw");
  if (att)
    {
      for(i=0; i<att->num_vals(); i++)
	rawMap.append(att->as_float(i));
  
      att = pvlFile.get_att("mappvl");
      for(i=0; i<att->num_vals(); i++)
	pvlMap.append(att->as_ncbyte(i));
    }

  pvlFile.close();
  return true;
}
Exemplo n.º 3
0
eavlNetCDFImporter::eavlNetCDFImporter(const string &filename)
{
    file = new NcFile(filename.c_str(), NcFile::ReadOnly);
     
    if (!file->is_valid())
    {
        THROW(eavlException,"Couldn't open file!\n");
    }

    if (debugoutput) cerr << "num_dims="<<file->num_dims()<<endl;
    if (debugoutput) cerr << "num_vars="<<file->num_vars()<<endl;
    if (debugoutput) cerr << "num_atts="<<file->num_atts()<<endl;

    for (int i=0; i<file->num_dims(); i++)
    {
        NcDim *d = file->get_dim(i);
        if (debugoutput) cerr << "  dim["<<i<<"]: name="<<d->name()<<" size="<<d->size()<<endl;
    }

    for (int i=0; i<file->num_atts(); i++)
    {
        NcAtt *a = file->get_att(i);
        if (debugoutput) cerr << "  att["<<i<<"]: name="<<a->name()<<" numvals="<<a->num_vals()<<endl;
    }

    bool found_grid = false;

    for (int i=0; i<file->num_vars(); i++)
    {
        NcVar *v = file->get_var(i);
        if (debugoutput) 
        {
            cerr << "  var["<<i<<"]: name="<<v->name();
            cerr << "  ndims="<<v->num_dims();
            cerr << "  dims = ";
            for (int j=0; j<v->num_dims(); j++)
            {
                cerr << v->get_dim(j)->name();
                if (j<v->num_dims()-1)
                    cerr << "*";
            }
            cerr << endl;
        }

        // Here's the condition for what we're going to use;
        // we only support one mesh for the moment, so we're picking one.
        // Also, the netcdf files we have have the time dim size as "1"
        if (v->num_dims() == 4 && string(v->get_dim(0)->name())=="time")
        {
            if (!found_grid)
            {
                dims.push_back(v->get_dim(1));
                dims.push_back(v->get_dim(2));
                dims.push_back(v->get_dim(3));
                found_grid = true;
                vars.push_back(v);
                if (debugoutput) cerr << "     * using as first real var\n";
            }
            else
            {
                if (string(v->get_dim(1)->name()) == dims[0]->name() &&
                    string(v->get_dim(2)->name()) == dims[1]->name() &&
                    string(v->get_dim(3)->name()) == dims[2]->name())
                {
                    vars.push_back(v);
                    if (debugoutput) cerr << "     * using as another var; matches the first real one's dims\n";
                }
            }
        }

    }
}
void
avtS3DFileFormat::PopulateDatabaseMetaData(avtDatabaseMetaData *md,
                                           int timeState)
{
    debug5 << "avtS3DFileFormat::PopulateDatabaseMetaData" << endl;
    // Get the metadata from the log file first.
    OpenLogFile();

    // Mesh
    avtMeshMetaData *mesh = new avtMeshMetaData;
    mesh->name = "mesh";
    mesh->meshType = AVT_RECTILINEAR_MESH;
    mesh->numBlocks = procs[0] * procs[1] * procs[2];
    mesh->blockOrigin = 1;
    mesh->cellOrigin = 0;
    mesh->spatialDimension = 3;
    mesh->topologicalDimension = 3;
    mesh->blockTitle = "blocks";
    mesh->blockPieceName = "block";
    mesh->hasSpatialExtents = false;
    mesh->xUnits = "mm";
    mesh->yUnits = "mm";
    mesh->zUnits = "mm";
    md->Add(mesh);

    //
    // Look in the NetCDF file for the first block for the list of variables.
    //

    // Calculate the timestep directory that the data lives in.
    char *pathcopy = strdup(mainFilename);
    string dir = parse_dirname(pathcopy);
    string timestepDir = CreateStringFromDouble(fileTimes[timeState]);

    char path[256];
    SNPRINTF(path,256,"%s%s%s%sfield.00000",dir.c_str(),VISIT_SLASH_STRING, timestepDir.c_str(), VISIT_SLASH_STRING);

    NcError err(NcError::verbose_nonfatal);
 
    NcFile nf(path);
    if (!nf.is_valid())
    {
        EXCEPTION1(InvalidFilesException, path);
    }
    debug5 << "avtS3DFileFormat::PopulateDatabaseMetaData: Got valid file" << endl;

    int nvars = nf.num_vars();
    debug5 << "avtS3DFileFormat::PopulateDatabaseMetaData: Found " << nvars << " variables" << endl;
    for (int i=0 ; i<nvars; i++)
    {
        NcVar *v = nf.get_var(i);
        if (!v)
            continue;
        debug4 << "Found variable " << v->name() << endl;

        // Check dimensionality
        int nvals = v->num_vals();
        if (nvals != 1) // Single scalars are useless.
        {
            avtScalarMetaData *scalar = new avtScalarMetaData();
            scalar->name = v->name();
            scalar->meshName = "mesh";
            scalar->centering = AVT_NODECENT;
            scalar->hasDataExtents = false;
            scalar->treatAsASCII = false;

            NcAtt *units = v->get_att(NcToken("units"));
            if (units)
            {
                long nv = units->num_vals();
                if (nv == 0)
                {
                    scalar->hasUnits = false;
                } else {
                    char *unitString = units->as_string(0);
                    scalar->units = unitString;
                    scalar->hasUnits = true;
                }
            } else
                scalar->hasUnits = false;

            md->Add(scalar);
        } else {
            debug4 << "Unable to process variable " << v->name() <<
                      " since it is a single scalar" << endl;

        }
    }

#if 0
    // Expressions
    Expression tempGradient_expr;
    tempGradient_expr.SetName("Temperature_gradient");
    tempGradient_expr.SetDefinition("gradient(Temperature)");
    tempGradient_expr.SetType(Expression::VectorMeshVar);
    tempGradient_expr.SetHidden(true);
    md->AddExpression(&tempGradient_expr);

    Expression tempUnit_expr;
    tempUnit_expr.SetName("Temperature_grad_unit");
    //tempUnit_expr.SetDefinition("(Temperature_gradient + {1e-6,0,0})/(magnitude(Temperature_gradient) + 1e-6)");
    //tempUnit_expr.SetDefinition("Temperature_gradient/(magnitude(Temperature_gradient) + 1e-6)");
    tempUnit_expr.SetDefinition("normalize(Temperature_gradient)");
    tempUnit_expr.SetType(Expression::VectorMeshVar);
    tempUnit_expr.SetHidden(true);
    md->AddExpression(&tempUnit_expr);

    Expression tempCurv_expr;
    tempCurv_expr.SetName("Temperature_curvature");
    tempCurv_expr.SetDefinition("divergence(Temperature_grad_unit)");
    tempCurv_expr.SetType(Expression::ScalarMeshVar);
    tempUnit_expr.SetHidden(false);
    md->AddExpression(&tempCurv_expr);
#endif
}