svn-gvsig-desktop / trunk / org.gvsig.desktop / org.gvsig.desktop.compat.cdc / org.gvsig.fmap.dal / org.gvsig.fmap.dal.file / org.gvsig.fmap.dal.file.dbf / src / main / java / org / gvsig / fmap / dal / store / dbf / utils / DbaseFileWriter.java @ 43461
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/**
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* gvSIG. Desktop Geographic Information System.
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*
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* Copyright (C) 2007-2013 gvSIG Association.
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 3
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* of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
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* MA 02110-1301, USA.
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*
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* For any additional information, do not hesitate to contact us
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* at info AT gvsig.com, or visit our website www.gvsig.com.
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*/
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package org.gvsig.fmap.dal.store.dbf.utils; |
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import java.io.IOException; |
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import java.nio.BufferOverflowException; |
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import java.nio.ByteBuffer; |
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import java.nio.MappedByteBuffer; |
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import java.nio.channels.FileChannel; |
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import java.nio.charset.Charset; |
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import java.text.FieldPosition; |
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import java.text.NumberFormat; |
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import java.util.Arrays; |
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import java.util.Calendar; |
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import java.util.Date; |
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import java.util.Iterator; |
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import java.util.Locale; |
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import org.apache.commons.lang3.StringUtils; |
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import org.gvsig.fmap.dal.DataTypes; |
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import org.gvsig.fmap.dal.exception.CloseException; |
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import org.gvsig.fmap.dal.exception.InitializeException; |
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import org.gvsig.fmap.dal.exception.UnsupportedEncodingException; |
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import org.gvsig.fmap.dal.exception.WriteException; |
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import org.gvsig.fmap.dal.feature.Feature; |
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import org.gvsig.fmap.dal.feature.FeatureAttributeDescriptor; |
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import org.gvsig.fmap.dal.feature.FeatureType; |
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/**
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* A DbaseFileReader is used to read a dbase III format file. The general use of
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* this class is: <CODE><PRE>
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* DbaseFileHeader header = ...
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* WritableFileChannel out = new FileOutputStream("thefile.dbf").getChannel();
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* DbaseFileWriter w = new DbaseFileWriter(header,out);
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* while ( moreRecords ) {
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* w.write( getMyRecord() );
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* }
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* w.close();
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* </PRE></CODE> You must supply the <CODE>moreRecords</CODE> and
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* <CODE>getMyRecord()</CODE> logic...
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*
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* @author Ian Schneider
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*/
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public class DbaseFileWriter { |
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private DbaseFileHeader header;
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private DbaseFileWriter.FieldFormatter formatter =
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new DbaseFileWriter.FieldFormatter();
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FileChannel channel;
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private ByteBuffer buffer; |
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private boolean headDrity = false; |
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private ByteBuffer blank; |
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private int blankSize; |
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//private Charset charset = Charset.forName("ISO-8859-1");
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private Charset charset; |
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/**
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* Create a DbaseFileWriter using the specified header and writing to the
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* given channel.
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*
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* @param header
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* The DbaseFileHeader to write.
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* @param out
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* The Channel to write to.
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*
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*
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* @throws InitializeWriterException
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* @throws IOException
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* If errors occur while initializing.
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*/
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public DbaseFileWriter(DbaseFileHeader header, FileChannel out, |
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boolean isNew) throws InitializeException { |
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this.header = header;
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this.channel = out;
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this.headDrity = isNew;
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this.setCharset(Charset.forName(header.mappingEncoding(header.getCharsetName()))); |
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init(); |
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} |
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private void init() throws InitializeException { |
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try {
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if (this.channel.size() < this.header.getHeaderLength()) { |
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this.writeHeader();
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} |
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buffer = ByteBuffer.allocateDirect(header.getRecordLength());
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} catch (Exception e) { |
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throw new InitializeException("DBF Writer", e); |
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} |
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} |
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private void write() throws WriteException { |
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buffer.position(0);
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int r = buffer.remaining();
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try {
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while ((r -= channel.write(buffer)) > 0) { |
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; // do nothing
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} |
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} catch (IOException e) { |
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throw new WriteException("DBF Writer", e); |
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} |
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} |
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private void writeHeader() throws WriteException { |
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try {
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channel.position(0);
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header.writeHeader(channel); |
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} catch (IOException e) { |
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throw new WriteException("DBF Writer", e); |
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} |
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} |
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/**
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* Write a single dbase record.
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*
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* @param record
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* The entries to write.
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* @throws UnsupportedEncodingException
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* @throws WriteException
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*/
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public void append(Feature feature) throws WriteException, |
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UnsupportedEncodingException {
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this.fillBuffer(feature);
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try {
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this.moveToEOF();
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} catch (IOException e) { |
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throw new WriteException("DbaseFileWriter", e); |
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} |
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this.header.setNumRecords(this.header.getNumRecords() + 1); |
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write(); |
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this.headDrity = true; |
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} |
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private void fillBuffer(Feature feature) |
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throws UnsupportedEncodingException, WriteException { |
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FeatureType featureType = feature.getType(); |
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try {
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buffer.position(0);
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// put the 'not-deleted' marker
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buffer.put((byte) ' '); |
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@SuppressWarnings("unchecked") |
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Iterator<FeatureAttributeDescriptor> iterator =
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featureType.iterator(); |
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while (iterator.hasNext()) {
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FeatureAttributeDescriptor fad = iterator.next(); |
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if (fad.getName().length() > DbaseFile.MAX_FIELD_NAME_LENGTH) {
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throw new FieldNameTooLongException( |
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"DBF file", fad.getName());
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} |
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int type = fad.getType();
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if (type == DataTypes.GEOMETRY) {
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continue;
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} |
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encodeField(fad, feature); |
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} |
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} catch (Exception e) { |
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throw new WriteException("DbaseFileWriter", e); |
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} |
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} |
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private void moveToEOF() throws IOException { |
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this.moveTo(this.header.getNumRecords()); |
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} |
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private void moveTo(long numReg) throws IOException { |
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// if (!(channel instanceof FileChannel)) {
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// throw new IOException(
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// "DbaseFileWriterNIO: channel is not a FileChannel. Cannot position properly");
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// }
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long newPos =
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header.getHeaderLength() + numReg * header.getRecordLength(); |
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if (this.channel.position() != newPos) { |
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this.channel.position(newPos);
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} |
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} |
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/**
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* Write a single dbase record. Useful to update a dbf.
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*
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* @param record
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* The entries to write.
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* @throws WriteException
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* @throws UnsupportedEncodingException
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*/
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public void update(Feature feature, long numReg) throws WriteException, |
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UnsupportedEncodingException {
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this.fillBuffer(feature);
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try {
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this.moveTo(numReg);
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} catch (IOException e) { |
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throw new WriteException("DbaseFileWriter", e); |
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} |
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write(); |
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} |
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private String fieldString(FeatureAttributeDescriptor attr, Feature feature) throws java.io.UnsupportedEncodingException { |
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int type = attr.getType();
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int dbfFieldIndex = this.header.getFieldIndex(attr.getName()); |
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final int fieldLen = header.getFieldLength(dbfFieldIndex); |
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String fieldString = ""; |
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if (DataTypes.BOOLEAN == type) {
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boolean b = feature.getBoolean(attr.getIndex());
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if (b) {
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fieldString = "T";
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} else {
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fieldString = "F";
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} |
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} else
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if (DataTypes.BYTE == type) {
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fieldString = String.valueOf(feature.getByte(attr.getIndex()));
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} else
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if (DataTypes.DATE == type) {
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Date date = feature.getDate(attr.getIndex());
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fieldString = formatter.getFieldString(date); |
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} else
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if (DataTypes.DOUBLE == type) {
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double d = feature.getDouble(attr.getIndex());
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fieldString = |
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formatter.getFieldString(fieldLen, |
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header.getFieldDecimalCount(dbfFieldIndex), d); |
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} else
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if (DataTypes.FLOAT == type) {
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float f = feature.getFloat(attr.getIndex());
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fieldString = |
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formatter.getFieldString(fieldLen, |
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header.getFieldDecimalCount(dbfFieldIndex), |
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f); |
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} else
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if (DataTypes.INT == type) {
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int integer = feature.getInt(attr.getIndex());
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fieldString = |
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formatter.getFieldString(fieldLen, header |
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.getFieldDecimalCount(dbfFieldIndex), |
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integer); |
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} else
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if (DataTypes.LONG == type) {
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long l = feature.getLong(attr.getIndex());
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fieldString = |
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formatter |
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.getFieldString( |
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fieldLen, |
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header |
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.getFieldDecimalCount(dbfFieldIndex), |
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l); |
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} else
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if (DataTypes.STRING == type) {
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String s =
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feature.getString(attr.getIndex()); |
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return s;
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} |
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return fieldString;
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} |
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private void encodeField(FeatureAttributeDescriptor attr, Feature feature) throws java.io.UnsupportedEncodingException, UnsupportedEncodingException { |
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int type = attr.getType();
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int dbfFieldIndex = this.header.getFieldIndex(attr.getName()); |
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final int fieldLen = header.getFieldLength(dbfFieldIndex); |
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String fieldString = ""; |
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if( DataTypes.BOOLEAN == type ) {
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boolean b = feature.getBoolean(attr.getIndex());
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if( b ) {
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safeEncode("T", 1, true); |
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} else {
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safeEncode("F", 1, true); |
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} |
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} else if( DataTypes.BYTE == type ) { |
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fieldString = String.valueOf(feature.getByte(attr.getIndex()));
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safeEncode(fieldString, 8, false); |
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} else if( DataTypes.DATE == type ) { |
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Date date = feature.getDate(attr.getIndex());
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fieldString = formatter.getFieldString(date); |
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safeEncode(fieldString, 8, false); |
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} else if( DataTypes.DOUBLE == type ) { |
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double d = feature.getDouble(attr.getIndex());
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fieldString = formatter.getFieldString( |
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fieldLen, header.getFieldDecimalCount(dbfFieldIndex), d |
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); |
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safeEncode(fieldString, fieldLen, false);
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} else if( DataTypes.FLOAT == type ) { |
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float f = feature.getFloat(attr.getIndex());
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fieldString = formatter.getFieldString( |
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fieldLen, header.getFieldDecimalCount(dbfFieldIndex), f |
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); |
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safeEncode(fieldString, fieldLen, false);
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} else if( DataTypes.INT == type ) { |
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int integer = feature.getInt(attr.getIndex());
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fieldString = formatter.getFieldString( |
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fieldLen, header.getFieldDecimalCount(dbfFieldIndex), integer |
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); |
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safeEncode(fieldString, fieldLen, false);
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} else if( DataTypes.LONG == type ) { |
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long l = feature.getLong(attr.getIndex());
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fieldString = formatter.getFieldString( |
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fieldLen, header.getFieldDecimalCount(dbfFieldIndex),l |
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); |
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safeEncode(fieldString, fieldLen, false);
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} else if( DataTypes.STRING == type ) { |
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String s = feature.getString(attr.getIndex());
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safeEncode(StringUtils.defaultIfEmpty(s, ""), fieldLen, true); |
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} else {
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// Si no conocemos el tipo intentamos guardarlo como un string
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String s = feature.getString(attr.getIndex());
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safeEncode(StringUtils.defaultIfEmpty(s, ""), fieldLen, true); |
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} |
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} |
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/**
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* Returns a safely padded (and potentially truncated) string
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*
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* This may truncate some record, but it is required to ensure
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* that the field limit is not overflowed when using
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* variable-length charsets such as UTF-8.
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* @throws UnsupportedEncodingException
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*/
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private void safeEncode(String in, int limit, boolean rightPadding) throws UnsupportedEncodingException { |
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try {
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byte[] encodedString = in.getBytes(this.charset); |
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if (encodedString.length>limit) {
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// too long, truncating
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/*
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* The block code bellow is equivalent to this simple code
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* fragment:
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if (rightPadding) {
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in = in.substring(0, in.length()-1);
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encodedString = in.getBytes(charset);
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}
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else {
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in.substring(1, in.length());
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encodedString = in.getBytes(charset);
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}
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However, the implemented algorithm has a much better performance
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for the average and worst cases (when the input string has a lot
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of multibyte characters), while keeping a good performance
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for the best case (when all the characters in the input string
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can be represented as single bytes using the selected charset).
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|
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The general strategy is to compute the deviation from the
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required maximum number of bytes (limit) and the actual number
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of bytes of the encoded String.
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Then, we use this deviation to estimate the amount of characters
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to truncate, based on the average factor of bytes per char in the
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input string.
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We truncate the string using this approach until the deviation
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gets stable.
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|
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Finally, as we should be close enough to the right truncation position,
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we increment/decrement the truncated string by only 1 character, to
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ensure we truncate in the exact position.
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*/
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String str = in;
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int estimatedDiff, deviation;
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int deviationPrev;
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double ratio;
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byte[] encodedChar; |
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int truncatePos = 0; |
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deviation = encodedString.length - limit; |
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deviationPrev = deviation - 1;
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while(Math.abs(deviation)>Math.abs(deviationPrev) && str.length()>0) { |
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ratio = ((double)encodedString.length) / ((double)str.length()); |
406 |
// apply the estimated diff, ensuring it is at least >= 1.0 in absolute value
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estimatedDiff = Math.max((int)(((double)deviation)/ratio), (int)(Math.signum(deviation)*1)); |
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// too long, truncating
|
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if (rightPadding) {
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truncatePos = Math.max(str.length()-estimatedDiff, 0); |
411 |
str = in.substring(0, truncatePos);
|
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} |
413 |
else {
|
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truncatePos = Math.max(truncatePos + estimatedDiff, 0); |
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str = in.substring(truncatePos); |
416 |
} |
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encodedString = str.getBytes(charset); |
418 |
deviationPrev = deviation; |
419 |
deviation = encodedString.length - limit; |
420 |
} |
421 |
// now we are close enough, get the exact position for truncating
|
422 |
while (encodedString.length>limit) {
|
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// too long, truncating
|
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// System.out.println("truncating");
|
425 |
if (rightPadding) {
|
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str = in.substring(0, str.length()-1); |
427 |
} |
428 |
else {
|
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truncatePos = truncatePos + 1;
|
430 |
str = in.substring(truncatePos); |
431 |
} |
432 |
encodedString = str.getBytes(charset); |
433 |
} |
434 |
while (encodedString.length<limit && str.length()<in.length()) {
|
435 |
// Extend if necessary:
|
436 |
// 1 - Get the length in bytes of the next char
|
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// 2 - Add the char to the substring if we are still within the limits
|
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// System.out.println("extending");
|
439 |
if (rightPadding) {
|
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encodedChar = in.substring(str.length(), str.length()+1).getBytes(charset);
|
441 |
} |
442 |
else {
|
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encodedChar = in.substring(truncatePos-1, truncatePos).getBytes(charset);
|
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// System.out.println(encodedChar);
|
445 |
// System.out.println(encodedChar.length);
|
446 |
// System.out.println(testStrings[i].substring(truncatePos-1, truncatePos));
|
447 |
} |
448 |
// System.out.println(testStrings[i].substring(in.length(), in.length()+1));
|
449 |
if ((encodedString.length + encodedChar.length)>limit) {
|
450 |
// one more char would overflow the limit
|
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break;
|
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} |
453 |
// too short, extending
|
454 |
if (rightPadding) {
|
455 |
str = in.substring(0, str.length()+1); |
456 |
} |
457 |
else {
|
458 |
truncatePos = truncatePos - 1;
|
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str = in.substring(truncatePos); |
460 |
} |
461 |
encodedString = str.getBytes(charset); |
462 |
} |
463 |
} |
464 |
if (rightPadding) {
|
465 |
buffer.put(encodedString); |
466 |
} |
467 |
if (encodedString.length<limit) {
|
468 |
// too short, padding
|
469 |
int i = encodedString.length;
|
470 |
while (i<limit) {
|
471 |
blank.position(0);
|
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buffer.put(blank); |
473 |
i=i+blankSize; |
474 |
} |
475 |
if (i>limit) {
|
476 |
// Might happen for instance if charset is UTF16 and the
|
477 |
// limit of characters in the field is an odd number
|
478 |
throw new UnsupportedEncodingException(new Exception("Impossible to encode this DBF using the selected charset")); |
479 |
} |
480 |
} |
481 |
if (!rightPadding) {
|
482 |
buffer.put(encodedString); |
483 |
} |
484 |
} |
485 |
catch(BufferOverflowException exc) { |
486 |
// Might happen for instance if charset is UTF16 and the
|
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// limit of characters in the field is an odd number
|
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throw new UnsupportedEncodingException(exc); |
489 |
} |
490 |
} |
491 |
|
492 |
/**
|
493 |
* Returns a safely padded (and potentially truncated) string
|
494 |
*
|
495 |
* This may truncate some record, but it is required to ensure
|
496 |
* that the field limit is not overflowed when using
|
497 |
* variable-length charsets such as UTF-8.
|
498 |
*
|
499 |
* This implementation is not used but it is kept here for reference.
|
500 |
* It is fully equivalent to the {@link #safeEncode(String, int, boolean)}
|
501 |
* method and easier to understand, but this implementation is much
|
502 |
* slower for any multibyte charset (such as UTF-8).
|
503 |
*
|
504 |
* @throws UnsupportedEncodingException
|
505 |
*/
|
506 |
private void safeEncodeSlow(String in, int limit, boolean rightPadding) throws UnsupportedEncodingException { |
507 |
try {
|
508 |
byte[] encodedString = in.getBytes(this.charset); |
509 |
while (encodedString.length>limit) {
|
510 |
// too long, truncating
|
511 |
if (rightPadding) {
|
512 |
in = in.substring(0, in.length()-1); |
513 |
encodedString = in.getBytes(charset); |
514 |
} |
515 |
else {
|
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in.substring(1, in.length());
|
517 |
encodedString = in.getBytes(charset); |
518 |
} |
519 |
} |
520 |
if (rightPadding) {
|
521 |
buffer.put(encodedString); |
522 |
} |
523 |
if (encodedString.length<limit) {
|
524 |
// too short, padding
|
525 |
int i = encodedString.length;
|
526 |
while (i<limit) {
|
527 |
blank.position(0);
|
528 |
buffer.put(blank); |
529 |
i=i+blankSize; |
530 |
} |
531 |
if (i>limit) {
|
532 |
throw new UnsupportedEncodingException(new Exception("Impossible to encode this DBF using the selected charset")); |
533 |
} |
534 |
} |
535 |
if (!rightPadding) {
|
536 |
buffer.put(encodedString); |
537 |
} |
538 |
} |
539 |
catch(BufferOverflowException exc) { |
540 |
// Might happen for instance if charset is UTF16 and the
|
541 |
// limit of characters in the field is an odd number
|
542 |
throw new UnsupportedEncodingException(exc); |
543 |
} |
544 |
} |
545 |
|
546 |
|
547 |
/**
|
548 |
* Release resources associated with this writer. <B>Highly recommended</B>
|
549 |
*
|
550 |
* @throws CloseException
|
551 |
* @throws IOException
|
552 |
* If errors occur.
|
553 |
*/
|
554 |
public void close() throws CloseException { |
555 |
// IANS - GEOT 193, bogus 0x00 written. According to dbf spec, optional
|
556 |
// eof 0x1a marker is, well, optional. Since the original code wrote a
|
557 |
// 0x00 (which is wrong anyway) lets just do away with this :)
|
558 |
// - produced dbf works in OpenOffice and ArcExplorer java, so it must
|
559 |
// be okay.
|
560 |
// buffer.position(0);
|
561 |
// buffer.put((byte) 0).position(0).limit(1);
|
562 |
// write();
|
563 |
|
564 |
if (headDrity) {
|
565 |
try {
|
566 |
this.writeHeader();
|
567 |
} catch (WriteException e) {
|
568 |
throw new CloseException("DbaseFileWriter", e); |
569 |
} |
570 |
} |
571 |
|
572 |
try {
|
573 |
channel.close(); |
574 |
} catch (IOException e) { |
575 |
throw new CloseException("DBF Writer", e); |
576 |
} |
577 |
if (buffer instanceof MappedByteBuffer) { |
578 |
// NIOUtilities.clean(buffer);
|
579 |
} |
580 |
|
581 |
buffer = null;
|
582 |
channel = null;
|
583 |
formatter = null;
|
584 |
} |
585 |
|
586 |
/** Utility for formatting Dbase fields. */
|
587 |
public static class FieldFormatter { |
588 |
|
589 |
private StringBuffer buffer = new StringBuffer(255); |
590 |
private NumberFormat numFormat = NumberFormat |
591 |
.getNumberInstance(Locale.US);
|
592 |
private Calendar calendar = Calendar.getInstance(Locale.US); |
593 |
private String emtpyString; |
594 |
private static final int MAXCHARS = 255; |
595 |
|
596 |
public FieldFormatter() {
|
597 |
// Avoid grouping on number format
|
598 |
numFormat.setGroupingUsed(false);
|
599 |
|
600 |
// build a 255 white spaces string
|
601 |
StringBuffer sb = new StringBuffer(MAXCHARS); |
602 |
sb.setLength(MAXCHARS); |
603 |
for (int i = 0; i < MAXCHARS; i++) { |
604 |
sb.setCharAt(i, ' ');
|
605 |
} |
606 |
|
607 |
emtpyString = sb.toString(); |
608 |
} |
609 |
|
610 |
public String getFieldString(int size, String s) { |
611 |
buffer.replace(0, size, emtpyString);
|
612 |
buffer.setLength(size); |
613 |
|
614 |
if (s != null) { |
615 |
buffer.replace(0, size, s);
|
616 |
if (s.length() <= size) {
|
617 |
for (int i = s.length(); i < size; i++) { |
618 |
buffer.append(' ');
|
619 |
} |
620 |
} |
621 |
} |
622 |
|
623 |
buffer.setLength(size); |
624 |
return buffer.toString();
|
625 |
} |
626 |
|
627 |
public String getFieldString(Date d) { |
628 |
|
629 |
if (d != null) { |
630 |
buffer.delete(0, buffer.length());
|
631 |
|
632 |
calendar.setTime(d); |
633 |
int year = calendar.get(Calendar.YEAR); |
634 |
int month = calendar.get(Calendar.MONTH) + 1; // returns 0 based |
635 |
// month?
|
636 |
int day = calendar.get(Calendar.DAY_OF_MONTH); |
637 |
|
638 |
if (year < 1000) { |
639 |
if (year >= 100) { |
640 |
buffer.append("0");
|
641 |
} else
|
642 |
if (year >= 10) { |
643 |
buffer.append("00");
|
644 |
} else {
|
645 |
buffer.append("000");
|
646 |
} |
647 |
} |
648 |
buffer.append(year); |
649 |
|
650 |
if (month < 10) { |
651 |
buffer.append("0");
|
652 |
} |
653 |
buffer.append(month); |
654 |
|
655 |
if (day < 10) { |
656 |
buffer.append("0");
|
657 |
} |
658 |
buffer.append(day); |
659 |
} else {
|
660 |
buffer.setLength(8);
|
661 |
buffer.replace(0, 8, emtpyString); |
662 |
} |
663 |
|
664 |
buffer.setLength(8);
|
665 |
return buffer.toString();
|
666 |
} |
667 |
|
668 |
public String getFieldString(int size, int decimalPlaces, double n) { |
669 |
buffer.delete(0, buffer.length());
|
670 |
|
671 |
numFormat.setMaximumFractionDigits(decimalPlaces); |
672 |
numFormat.setMinimumFractionDigits(decimalPlaces); |
673 |
numFormat.format(n, buffer, new FieldPosition( |
674 |
NumberFormat.INTEGER_FIELD));
|
675 |
return buffer.toString();
|
676 |
} |
677 |
} |
678 |
|
679 |
public void setCharset(Charset charset) { |
680 |
this.charset = charset;
|
681 |
blank = charset.encode(" ");
|
682 |
blankSize = blank.limit(); |
683 |
} |
684 |
|
685 |
} |