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The NetCDF-Java Library is a Java interface to NetCDF files,
as well as to many other types of scientific data formats.
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/*
* Copyright (c) 1998 - 2010. University Corporation for Atmospheric Research/Unidata
* Portions of this software were developed by the Unidata Program at the
* University Corporation for Atmospheric Research.
*
* Access and use of this software shall impose the following obligations
* and understandings on the user. The user is granted the right, without
* any fee or cost, to use, copy, modify, alter, enhance and distribute
* this software, and any derivative works thereof, and its supporting
* documentation for any purpose whatsoever, provided that this entire
* notice appears in all copies of the software, derivative works and
* supporting documentation. Further, UCAR requests that the user credit
* UCAR/Unidata in any publications that result from the use of this
* software or in any product that includes this software. The names UCAR
* and/or Unidata, however, may not be used in any advertising or publicity
* to endorse or promote any products or commercial entity unless specific
* written permission is obtained from UCAR/Unidata. The user also
* understands that UCAR/Unidata is not obligated to provide the user with
* any support, consulting, training or assistance of any kind with regard
* to the use, operation and performance of this software nor to provide
* the user with any updates, revisions, new versions or "bug fixes."
*
* THIS SOFTWARE IS PROVIDED BY UCAR/UNIDATA "AS IS" AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL UCAR/UNIDATA BE LIABLE FOR ANY SPECIAL,
* INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING
* FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT,
* NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION
* WITH THE ACCESS, USE OR PERFORMANCE OF THIS SOFTWARE.
*/
package ucar.nc2.iosp.nowrad;
//~--- non-JDK imports --------------------------------------------------------
import ucar.ma2.Array;
import ucar.ma2.DataType;
import ucar.nc2.Attribute;
import ucar.nc2.Dimension;
import ucar.nc2.Variable;
import ucar.nc2.constants.AxisType;
import ucar.nc2.constants.CDM;
import ucar.nc2.constants.FeatureType;
import ucar.nc2.constants._Coordinate;
import ucar.nc2.units.DateFormatter;
import ucar.unidata.geoloc.LatLonPointImpl;
import ucar.unidata.geoloc.ProjectionImpl;
import ucar.unidata.geoloc.ProjectionPointImpl;
import ucar.unidata.geoloc.projection.LambertConformal;
import ucar.unidata.util.Parameter;
import ucar.unidata.util.StringUtil2;
import java.io.IOException;
import java.text.SimpleDateFormat;
import java.util.ArrayList;
import java.util.Date;
import java.util.List;
import java.util.TimeZone;
/**
* Created by IntelliJ IDEA.
* User: yuanho
* Date: Feb 10, 2010
* Time: 11:21:19 AM
* To change this template use File | Settings | File Templates.
*/
public class NOWRadheader {
final static int NEXET = 2; // Echo Tops Composite
final static int NEXLH = 5; // Layer Reflectivity - High
final static int NEXLL = 3; // Layer Reflectivity - Low
final static int NEXLM = 4; // Layer Reflectivity - Mid
final static int NEXVI = 6; // Vert. Integrated Liquid Water
final static int NOWRADHF = 0; // 2km Base Reflectivity
final static int USRADHF = 1; // 8km Base Reflectivity
static public String mons[] = {
"JAN", "FEB", "MAR", "APR", "MAY", "JUN", "JUL", "AUG", "SEP", "OCT", "NOV", "DEC"
};
static private org.slf4j.Logger log = org.slf4j.LoggerFactory.getLogger(NOWRadheader.class);
DateFormatter formatter = new DateFormatter();
// private PrintStream out = System.out;
// private Vinfo myInfo;
private String cmemo, ctilt, ctitle, cunit, cname;
private ucar.nc2.NetcdfFile ncfile;
// message header block
// production dessciption block
private int numX;
private int numY;
private ucar.unidata.io.RandomAccessFile raf;
/**
* check if this file is a nids / tdwr file
* @param raf input file
* @return true if valid
*/
public boolean isValidFile(ucar.unidata.io.RandomAccessFile raf) {
try {
long t = raf.length();
if (t == 0) {
throw new IOException("zero length file ");
}
} catch (IOException e) {
return (false);
}
try {
int p = this.readTop(raf);
if (p == 0) {
return false;
}
} catch (IOException e) {
return (false);
}
return true;
}
/**
* read the header of input file and parsing the NOWRAD part
* @param raf input file
* @return 1 if checking passing
* @throws IOException
*/
int readTop(ucar.unidata.io.RandomAccessFile raf) throws IOException {
int pos = 0;
// long actualSize = 0;
raf.seek(pos);
int readLen = 35;
// Read in the contents of the NEXRAD Level III product head
byte[] b = new byte[readLen];
int rc = raf.read(b);
if (rc != readLen) {
return 0;
}
// check
if ((convertunsignedByte2Short(b[0]) != 0x00) || (convertunsignedByte2Short(b[1]) != 0xF0)
|| (convertunsignedByte2Short(b[2]) != 0x09)) {
return 0;
}
String pidd = new String(b, 15, 5, CDM.utf8Charset);
if (pidd.contains("NOWRA") || pidd.contains("USRAD") || pidd.contains("NEX")) {
return 1;
} else {
return 0;
}
}
public byte[] getData(int offset) throws IOException {
int readLen = (int) raf.length();
byte[] b = new byte[readLen];
int pos = 0;
raf.seek(pos);
raf.readFully(b);
return b;
}
// ////////////////////////////////////////////////////////////////////////////////
public void setProperty(String name, String value) {}
/**
* read and parse the header of the nids/tdwr file
* @param raf input file
* @param ncfile output file
* @throws IOException
*/
void read(ucar.unidata.io.RandomAccessFile raf, ucar.nc2.NetcdfFile ncfile) throws Exception {
this.raf = raf;
int rc; /* function return status */
int hoffset;
int readLen = 250;
this.ncfile = ncfile;
int pos = 0;
raf.seek(pos);
byte[] b = new byte[readLen];
rc = raf.read(b);
if (rc != readLen) {
log.warn(" error reading nids product header " + raf.getLocation());
}
int hsize = b[3];
String product = new String(b, 15, 8, CDM.utf8Charset);
// image lines
//byte[] bt = new byte[] { (byte) 0xF0, (byte) 0x0A };
int t1 = 0 ;
int ii = 0;
for(int i = 0; i < readLen; i++ ){
if(convertunsignedByte2Short(b[i+hsize]) == 0xF0 &&
convertunsignedByte2Short(b[i+1+hsize]) == 0x0A ){
t1 = i + hsize;
ii = i;
break;
}
}
if(t1 == 0)
return;
// if(convertunsignedByte2Short(b[6+hsize]) != 0xF0 ||
// convertunsignedByte2Short(b[7+hsize]) != 0x0A )
// return;
String lstr = trim(new String(b, t1 + 2, 4, CDM.utf8Charset));
numY = Integer.parseInt(lstr);
String estr = trim(new String(b, t1 + 6, 5, CDM.utf8Charset));
numX = Integer.parseInt(estr);
//bt = new byte[] { (byte) 0xF0, (byte) 0x03 };
t1 = 0;
for(int i = ii; i < readLen; i++ ){
if(convertunsignedByte2Short(b[i+hsize]) == 0xF0 &&
convertunsignedByte2Short(b[i+1+hsize]) == 0x03 ){
t1 = i + hsize;
ii = i;
break;
}
}
if(t1 == 0)
return;
// if((lstr.length()+estr.length() < 8))
// hsize = hsize -2;
// if(convertunsignedByte2Short(b[18+hsize]) != 0xF0 ||
// convertunsignedByte2Short(b[19+hsize]) != 0x03 )
// return;
int off = 0;
if (product.contains("USRADHF")) {
off = 3;
}
// Image time, HHMMSS. The time will be in the form HH:MM, so look :
String ts = new String(b, t1 + 22 + off, 2, CDM.utf8Charset);
int hr = Integer.parseInt(ts);
ts = new String(b, t1 + 25 + off, 2, CDM.utf8Charset);
int min = Integer.parseInt(ts);
ts = new String(b, t1 + 28 + off, 2, CDM.utf8Charset);
int dd = Integer.parseInt(ts);
ts = new String(b, t1 + 31 + off, 3, CDM.utf8Charset);
String mon = ts;
int month = getMonth(mon);
ts = new String(b, t1 + 35 + off, 2, CDM.utf8Charset);
int year = Integer.parseInt(ts);
SimpleDateFormat sdf = new SimpleDateFormat();
sdf.setTimeZone(TimeZone.getTimeZone("GMT"));
sdf.applyPattern("yyyy/MM/dd HH:mm");
Date date = sdf.parse(year + "/" + month + "/" + dd + " " + hr + ":" + min);
//bt = new byte[] { (byte) 0xF0, (byte) 0x0b };
t1 = 0;
for(int i = ii; i < readLen; i++ ){
if(convertunsignedByte2Short(b[i+hsize]) == 0xF0 &&
convertunsignedByte2Short(b[i+1+hsize]) == 0x0b ) {
t1 = i + hsize;
break;
}
}
if(t1 == 0)
return;
// if( convertunsignedByte2Short(b[101 + hsize]) != 0xF0 ||
// convertunsignedByte2Short(b[102 + hsize]) != 0x0b )
// return;
if (product.contains("NOWRAD")) {
String ot = new String(b, t1 + 2, 68, CDM.utf8Charset);
//List toks = StringUtil.split(ot, " ", true, true);
String[] toks = StringUtil2.splitString(ot);
double nav1 = Math.toDegrees(Double.parseDouble(toks[1])); // lon
double nav2 = Math.toDegrees(Double.parseDouble(toks[2])); // lat
double nav3 = Math.toDegrees(Double.parseDouble(toks[3]));
double nav4 = Math.toDegrees(Double.parseDouble(toks[4])); // lat sp
double nav5 = Math.toDegrees(Double.parseDouble(toks[5])); // lon sp
// lower left and upper right corner
float rlat1;
float rlon1;
float rlat2;
float rlon2;
rlat1 = (float) (nav2 - (numY - 1) * nav4);
rlon1 = (float) (nav1 + nav3);
rlat2 = (float) nav2;
rlon2 = (float) (nav1 - nav3);
hoffset = t1 + 71; // 172 + hsize;
// start of the image sequence
if ((convertunsignedByte2Short(b[172 + hsize]) != 0xF0)
|| (convertunsignedByte2Short(b[173 + hsize]) != 0x0c)) {
return;
}
// hoffset = 174 + hsize;
// Set product-dependent information
setProductInfo(product, date);
// data struct
nowrad(hoffset, rlat1, rlon1, rlat2, rlon2, (float) nav4, (float) nav5, date);
} else if (product.contains("USRADHF")) {
String ot = new String(b, t1 + 2, 107, CDM.utf8Charset);
String[] toks = StringUtil2.splitString(ot);
double nav1 = Math.toDegrees(Double.parseDouble(toks[1])); // standard lat 1
double nav2 = Math.toDegrees(Double.parseDouble(toks[2])); // standard lat 2
double nav3 = Math.toDegrees(Double.parseDouble(toks[3])); // lat. center of proj
double nav4 = Math.toDegrees(Double.parseDouble(toks[4])); // lon. center of proj
double nav5 = Math.toDegrees(Double.parseDouble(toks[5])); // upper left lat
double nav6 = Math.toDegrees(Double.parseDouble(toks[6])); // upper left lon
/* List toks = StringUtil.split(ot, " ", true, true);
String pj = toks.get(0);
double nav1 = Math.toDegrees(Double.parseDouble(toks.get(1))); // standard lat 1
double nav2 = Math.toDegrees(Double.parseDouble(toks.get(2))); // standard lat 2
double nav3 = Math.toDegrees(Double.parseDouble(toks.get(3))); // lat. center of proj
double nav4 = Math.toDegrees(Double.parseDouble(toks.get(4))); // lon. center of proj
double nav5 = Math.toDegrees(Double.parseDouble(toks.get(5))); // upper left lat
double nav6 = Math.toDegrees(Double.parseDouble(toks.get(6))); // upper left lon
double nav7 = Math.toDegrees(Double.parseDouble(toks.get(7))); // lat sp
double nav8 = Math.toDegrees(Double.parseDouble(toks.get(8))); // lon sp */
// lower left and upper right corner
// int offh = 39;
hoffset = t1 + 110; // 172 + hsize+ offh;
// start of the image sequence
if ((convertunsignedByte2Short(b[t1 + 110]) != 0xF0) || (convertunsignedByte2Short(b[t1 + 111]) != 0x0c)) {
return;
}
// Set product-dependent information
setProductInfo(product, date);
// data struct
nowradL(hoffset, (float) nav1, (float) nav2, (float) nav3, (float) nav4, (float) nav5, (float) nav6, date);
}
ncfile.finish();
}
String trim(String str) {
int len = str.length();
StringBuilder ostr = new StringBuilder();
for (int i = 0; i < len; i++) {
char sc = str.charAt(i);
if (Character.isDigit(sc)) {
ostr.append(sc);
}
}
return ostr.toString();
}
int getMonth(String m) {
int i = 0;
while (i < 12) {
if (m.equalsIgnoreCase(mons[i])) {
return i + 1;
} else {
i++;
}
}
return 0;
}
ProjectionImpl nowradL(int hoff, float lat1, float lat2, float clat, float clon, float lat, float lon, Date dd) {
List dims = new ArrayList<>();
Dimension dimT = new Dimension("time", 1, true, false, false);
ncfile.addDimension(null, dimT);
String timeCoordName = "time";
Variable taxis = new Variable(ncfile, null, null, timeCoordName);
taxis.setDataType(DataType.DOUBLE);
taxis.setDimensions("time");
taxis.addAttribute(new Attribute(CDM.LONG_NAME, "time since base date"));
taxis.addAttribute(new Attribute(_Coordinate.AxisType, AxisType.Time.toString()));
double[] tdata = new double[1];
tdata[0] = dd.getTime();
Array dataT = Array.factory(DataType.DOUBLE.getPrimitiveClassType(), new int[] { 1 }, tdata);
taxis.setCachedData(dataT, false);
DateFormatter formatter = new DateFormatter();
taxis.addAttribute(new Attribute(CDM.UNITS, "msecs since " + formatter.toDateTimeStringISO(new Date(0))));
ncfile.addVariable(null, taxis);
dims.add(dimT);
Dimension jDim = new Dimension("y", numY, true, false, false);
Dimension iDim = new Dimension("x", numX, true, false, false);
dims.add(jDim);
dims.add(iDim);
ncfile.addDimension(null, iDim);
ncfile.addDimension(null, jDim);
ncfile.addAttribute(null, new Attribute("cdm_data_type", FeatureType.GRID.toString()));
String coordinates = "time y x";
Variable v = new Variable(ncfile, null, null, cname);
v.setDataType(DataType.BYTE);
v.setDimensions(dims);
ncfile.addVariable(null, v);
v.addAttribute(new Attribute(CDM.LONG_NAME, ctitle));
v.addAttribute(new Attribute(CDM.UNITS, cunit));
v.addAttribute(new Attribute(CDM.SCALE_FACTOR, 5.0f));
v.addAttribute(new Attribute(CDM.MISSING_VALUE, 0));
v.setSPobject(new Vinfo(numX, numY, hoff));
v.addAttribute(new Attribute(_Coordinate.Axes, coordinates));
// create coordinate variables
Variable xaxis = new Variable(ncfile, null, null, "x");
xaxis.setDataType(DataType.DOUBLE);
xaxis.setDimensions("x");
xaxis.addAttribute(new Attribute("standard_name", "projection x coordinate"));
xaxis.addAttribute(new Attribute(CDM.UNITS, "km"));
xaxis.addAttribute(new Attribute(_Coordinate.AxisType, "GeoX"));
double[] data1 = new double[numX];
ProjectionImpl projection = new LambertConformal(clat, clon, lat1, lat2);
double ullat = 51.8294;
double ullon = -135.8736;
double lrlat = 17.2454;
double lrlon = -70.1154;
ProjectionPointImpl ptul = (ProjectionPointImpl) projection.latLonToProj(new LatLonPointImpl(ullat, ullon));
ProjectionPointImpl ptlr = (ProjectionPointImpl) projection.latLonToProj(new LatLonPointImpl(lrlat, lrlon));
double startX = ptul.getX();
double startY = ptlr.getY();
double dx = (ptlr.getX() - ptul.getX())/(numX-1);
for (int i = 0; i < numX; i++) {
data1[i] = startX + i*dx;
}
Array dataA = Array.factory(DataType.DOUBLE.getPrimitiveClassType(), new int[] { numX }, data1);
xaxis.setCachedData(dataA, false);
ncfile.addVariable(null, xaxis);
Variable yaxis = new Variable(ncfile, null, null, "y");
yaxis.setDataType(DataType.DOUBLE);
yaxis.setDimensions("y");
yaxis.addAttribute(new Attribute("standard_name", "projection y coordinate"));
yaxis.addAttribute(new Attribute(CDM.UNITS, "km"));
yaxis.addAttribute(new Attribute(_Coordinate.AxisType, "GeoY"));
data1 = new double[numY];
double dy = (ptul.getY() - ptlr.getY())/(numY-1);
for (int i = 0; i < numY; i++) {
data1[i] = startY + i*dy;
}
dataA = Array.factory(DataType.DOUBLE.getPrimitiveClassType(), new int[] { numY }, data1);
yaxis.setCachedData(dataA, false);
ncfile.addVariable(null, yaxis);
// projection
// lower left and upper right corner lat/lons
// modified cylind. equidistant or CED with lat/lon ration != 1
Variable ct = new Variable(ncfile, null, null, projection.getClassName());
ct.setDataType(DataType.CHAR);
ct.setDimensions("");
List params = projection.getProjectionParameters();
for (Parameter p : params) {
ct.addAttribute(new Attribute(p));
}
ct.addAttribute(new Attribute(_Coordinate.TransformType, "Projection"));
//ct.addAttribute(new Attribute(_Coordinate.Axes, "lat lon"));
ct.addAttribute( new Attribute(_Coordinate.Axes, "x y "));
// fake data
dataA = Array.factory(DataType.CHAR.getPrimitiveClassType(), new int[] {});
dataA.setChar(dataA.getIndex(), ' ');
ct.setCachedData(dataA, false);
ncfile.addVariable(null, ct);
return projection;
}
/**
* construct a raster dataset for NIDS raster products;
*
* @return soff -- not used
*/
ProjectionImpl nowrad(int hoff, float rlat1, float rlon1, float rlat2, float rlon2, float dlat, float dlon, Date dd) {
List dims = new ArrayList<>();
Dimension dimT = new Dimension("time", 1, true, false, false);
ncfile.addDimension(null, dimT);
String timeCoordName = "time";
Variable taxis = new Variable(ncfile, null, null, timeCoordName);
taxis.setDataType(DataType.DOUBLE);
taxis.setDimensions("time");
taxis.addAttribute(new Attribute(CDM.LONG_NAME, "time since base date"));
taxis.addAttribute(new Attribute(_Coordinate.AxisType, AxisType.Time.toString()));
double[] tdata = new double[1];
tdata[0] = dd.getTime();
Array dataT = Array.factory(DataType.DOUBLE.getPrimitiveClassType(), new int[] { 1 }, tdata);
taxis.setCachedData(dataT, false);
DateFormatter formatter = new DateFormatter();
taxis.addAttribute(new Attribute(CDM.UNITS, "msecs since " + formatter.toDateTimeStringISO(new Date(0))));
ncfile.addVariable(null, taxis);
dims.add(dimT);
Dimension jDim = new Dimension("lat", numY, true, false, false);
Dimension iDim = new Dimension("lon", numX, true, false, false);
dims.add(jDim);
dims.add(iDim);
ncfile.addDimension(null, iDim);
ncfile.addDimension(null, jDim);
ncfile.addAttribute(null, new Attribute("cdm_data_type", FeatureType.GRID.toString()));
String coordinates = "time lat lon";
Variable v = new Variable(ncfile, null, null, cname);
v.setDataType(DataType.BYTE);
v.setDimensions(dims);
ncfile.addVariable(null, v);
v.addAttribute(new Attribute(CDM.LONG_NAME, ctitle));
v.addAttribute(new Attribute(CDM.SCALE_FACTOR, 5.0f));
v.addAttribute(new Attribute(CDM.MISSING_VALUE, 0));
v.addAttribute(new Attribute(CDM.UNITS, cunit));
v.setSPobject(new Vinfo(numX, numY, hoff));
v.addAttribute(new Attribute(_Coordinate.Axes, coordinates));
// create coordinate variables
Variable xaxis = new Variable(ncfile, null, null, "lon");
xaxis.setDataType(DataType.DOUBLE);
xaxis.setDimensions("lon");
xaxis.addAttribute(new Attribute(CDM.LONG_NAME, "longitude"));
xaxis.addAttribute(new Attribute(CDM.UNITS, "degree"));
xaxis.addAttribute(new Attribute(_Coordinate.AxisType, "Lon"));
double[] data1 = new double[numX];
for (int i = 0; i < numX; i++) {
data1[i] = (double) (rlon1 + i * dlon);
}
Array dataA = Array.factory(DataType.DOUBLE.getPrimitiveClassType(), new int[] { numX }, data1);
xaxis.setCachedData(dataA, false);
ncfile.addVariable(null, xaxis);
Variable yaxis = new Variable(ncfile, null, null, "lat");
yaxis.setDataType(DataType.DOUBLE);
yaxis.setDimensions("lat");
yaxis.addAttribute(new Attribute(CDM.LONG_NAME, "latitude"));
yaxis.addAttribute(new Attribute(CDM.UNITS, "degree"));
yaxis.addAttribute(new Attribute(_Coordinate.AxisType, "Lat"));
data1 = new double[numY];
for (int i = 0; i < numY; i++) {
data1[i] = rlat1 + i * dlat;
}
dataA = Array.factory(DataType.DOUBLE.getPrimitiveClassType(), new int[] { numY }, data1);
yaxis.setCachedData(dataA, false);
ncfile.addVariable(null, yaxis);
// projection
// lower left and upper right corner lat/lons
// modified cylind. equidistant or CED with lat/lon ration != 1
/* LatLonProjection llproj = new LatLonProjection("LatitudeLongitudeProjection",
new ProjectionRect(rlat1, rlon1, rlat2, rlon2));
Variable ct = new Variable(ncfile, null, null, llproj.getClassName());
ct.setDataType(DataType.CHAR);
ct.setDimensions("");
List params = llproj.getProjectionParameters();
for (int i = 0; i < params.size(); i++) {
Parameter p = (Parameter) params.get(i);
ct.addAttribute(new Attribute(p));
}
ct.addAttribute(new Attribute(_Coordinate.TransformType, "Projection"));
ct.addAttribute(new Attribute(_Coordinate.Axes, "lat lon"));
// fake data
dataA = Array.factory(DataType.CHAR.getPrimitiveClassType(), new int[] {});
dataA.setChar(dataA.getIndex(), ' ');
ct.setCachedData(dataA, false);
ncfile.addVariable(null, ct);
*/
return null;
}
/**
* parsing the product information into netcdf dataset
*/
void setProductInfo(String prod, Date dd) {
String summary = null;
if (prod.contains("NOWRADHF")) {
cmemo = "NOWRAD Base Reflectivity at Tilt 1";
ctitle = "BREF: Base Reflectivity [dBZ]";
cunit = "dBZ";
cname = "Reflectivity";
summary = "NOWRAD Product";
} else if (prod.contains("USRADHF")) {
cmemo = "NOWRAD Base Reflectivity at Tilt 1";
ctitle = "BREF: Base Reflectivity [dBZ]";
cunit = "dBZ";
cname = "Reflectivity";
summary = "NOWRAD Product";
} else if (prod.contains("NEXET")) {
cmemo = "NOWRAD Echo Tops";
ctitle = "Echo Tops Composite";
cunit = "K FT";
cname = "EchoTopsComposite";
summary = "NOWRAD Product";
} else if (prod.contains("NEXLL")) {
cmemo = "NOWRAD Layer Comp. Reflectivity - Low";
ctitle = "LayerReflectivityLow";
cunit = "dBZ";
cname = "Reflectivity";
summary = "NOWRAD Product";
} else if (prod.contains("NEXLM")) {
cmemo = "NOWRAD Layer Comp. Reflectivity - Mid";
ctitle = "LayerReflectivityMid";
cunit = "dBZ";
cname = "Reflectivity";
summary = "NOWRAD Product";
} else if (prod.contains("NEXLH")) {
cmemo = "NOWRAD Layer Comp. Reflectivity - High";
ctitle = "LayerReflectivityHigh";
cunit = "dBZ";
cname = "ReflectivityHigh";
summary = "NOWRAD Product";
} else if (prod.contains("NEXVI")) {
cmemo = "NOWRAD ";
ctitle = "Vert. Integrated Liquid Water";
cunit = "Knots";
cname = "VILwater";
summary = "NOWRAD ";
} else {
ctilt = "error";
ctitle = "error";
cunit = "error";
cname = "error";
}
/* add geo global att */
ncfile.addAttribute(null, new Attribute("summary", "NOWRAD radar composite products." + summary));
ncfile.addAttribute(null, new Attribute("title", "NOWRAD"));
ncfile.addAttribute(null, new Attribute("keywords", "NOWRAD"));
ncfile.addAttribute(null, new Attribute("creator_name", "NOAA/NWS"));
ncfile.addAttribute(null, new Attribute("creator_url", "http://www.ncdc.noaa.gov/oa/radar/radarproducts.html"));
ncfile.addAttribute(null, new Attribute("naming_authority", "NOAA/NCDC"));
ncfile.addAttribute(null, new Attribute("base_date", formatter.toDateOnlyString(dd)));
ncfile.addAttribute(null, new Attribute("conventions", _Coordinate.Convention));
ncfile.addAttribute(null, new Attribute("cdm_data_type", FeatureType.GRID.toString()));
}
/* thredds global att */
/**
* convert two short into a integer
* @param s1 short one
* @param s2 short two
* @param swapBytes if swap bytes
* @return integer
*/
public static int shortsToInt(short s1, short s2, boolean swapBytes) {
byte[] b = new byte[4];
b[0] = (byte) (s1 >>> 8);
b[1] = (byte) (s1 >>> 0);
b[2] = (byte) (s2 >>> 8);
b[3] = (byte) (s2 >>> 0);
return bytesToInt(b, false);
}
/**
* convert bytes into integer
* @param bytes bytes array
* @param swapBytes if need to swap
* @return integer
*/
public static int bytesToInt(byte[] bytes, boolean swapBytes) {
byte a = bytes[0];
byte b = bytes[1];
byte c = bytes[2];
byte d = bytes[3];
if (swapBytes) {
return ((a & 0xff)) + ((b & 0xff) << 8) + ((c & 0xff) << 16) + ((d & 0xff) << 24);
} else {
return ((a & 0xff) << 24) + ((b & 0xff) << 16) + ((c & 0xff) << 8) + ((d & 0xff));
}
}
/**
* Concatenate two bytes to a 32-bit int value. a is the high order
* byte in the resulting int representation, unless swapBytes is true, in
* which b is the high order byte.
* @param a high order byte
* @param b low order byte
* @param swapBytes byte order swap flag
* @return 32-bit integer
*/
public static int bytesToInt(byte a, byte b, boolean swapBytes) {
// again, high order bit is expressed left into 32-bit form
if (swapBytes) {
return (a & 0xff) + ((int) b << 8);
} else {
return ((int) a << 8) + (b & 0xff);
}
}
/**
* convert unsigned byte to short
* @param b convert this unsigned byte
* @return unsigned short
*/
public short convertunsignedByte2Short(byte b) {
return (short) ((b < 0)
? (short) b + 256
: (short) b);
}
/**
* convert short to unsigned integer
* @param b convert this short
* @return unsigned integer
*/
public int convertShort2unsignedInt(short b) {
return (b < 0)
? (-1) * b + 32768
: b;
}
/**
* get jave date
* @param julianDays
* @param msecs
* @return java date
*/
static public java.util.Date getDate(int julianDays, int msecs) {
long total = ((long) (julianDays - 1)) * 24 * 3600 * 1000 + msecs;
return new Date(total);
}
/**
* Flush all data buffers to disk.
* @throws IOException
*/
public void flush() throws IOException {
raf.flush();
}
/**
* Close the file.
* @throws IOException
*/
public void close() throws IOException {
if (raf != null) {
raf.close();
}
}
// variable info for reading/writing
static class Vinfo {
long hoff; // header offset
int xt;
int yt;
Vinfo(int xt, int yt, long hoff) {
this.xt = xt;
this.yt = yt;
this.hoff = hoff;
}
}
}
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