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ModularImageAnalysis (MIA) is an ImageJ plugin which provides a modular framework for assembling image and object analysis workflows. Detected objects can be transformed, filtered, measured and related. Analysis workflows are batch-enabled by default, allowing easy processing of high-content datasets.
/*
* "Concave" hulls by Glenn Hudson and Matt Duckham
*
* Source code downloaded from https://archive.md/l3Un5#selection-571.0-587.218 on 3rd November 2021.
*
* - This software is Copyright (C) 2008 Glenn Hudson released under Gnu Public License (GPL). Under
* GPL you are free to use, modify, and redistribute the software. Please acknowledge Glenn Hudson
* and Matt Duckham as the source of this software if you do use or adapt the code in further research
* or other work. For full details of GPL see http://www.gnu.org/licenses/gpl-3.0.txt.
* - This software comes with no warranty of any kind, expressed or implied.
*
* A paper with full details of the characteristic hulls algorithm is published in Pattern Recognition.
* Duckham, M., Kulik, L., Worboys, M.F., Galton, A. (2008) Efficient generation of simple polygons for
* characterizing the shape of a set of points in the plane. Pattern Recognition v41, 3224-3236
*
* The software was developed by Glenn Hudson while working with me as an RA. The characteristic shapes
* algorithm is collaborative work between Matt Duckham, Lars Kulik, Antony Galton, and Mike Worboys.
*
*/
package signalprocesser.voronoi.tools;
import java.awt.Rectangle;
import java.io.BufferedReader;
import java.io.FileNotFoundException;
import java.io.IOException;
import java.io.InputStream;
import java.io.InputStreamReader;
import java.net.URISyntaxException;
import java.util.ArrayList;
import java.util.Iterator;
import java.util.regex.Matcher;
import java.util.regex.Pattern;
import signalprocesser.voronoi.VPoint;
public class CountryData {
public static final String PATH_TO_COUNTRYDATA = "countrydata";
public static final String INDEX_FILE = PATH_TO_COUNTRYDATA + "/fileindex.dat";
public static final Pattern PATTERN_COORDLINE = Pattern.compile("^[ ]*([0-9E.-]*)[ ]*,[ ]*([0-9E.-]*)[ ]*$");
public static void main(String args[]) throws IOException, URISyntaxException {
// Call country data generation to generate mapping data
//CountryDataGeneration.main(args);
}
public static ArrayList getCountryList() throws IOException {
// Open the index file
InputStream stream = CountryData.class.getResourceAsStream(INDEX_FILE);
if ( stream==null ) {
throw new FileNotFoundException("The resource \"" + INDEX_FILE + "\" was not found relative to CountryData.class" );
}
BufferedReader reader = new BufferedReader(new InputStreamReader(stream));
// Read the country files available
String line;
ArrayList countrylist = new ArrayList();
while ( (line=reader.readLine())!=null ) {
countrylist.add(line);
}
// Return the generated list
return countrylist;
}
public static ArrayList getCountryData(String countryfile, Rectangle bounds) throws IOException {
// Open country file requested
String resourcename = PATH_TO_COUNTRYDATA + "/" + countryfile;
InputStream stream = CountryData.class.getResourceAsStream(resourcename);
if ( stream==null ) {
stream = CountryData.class.getResourceAsStream(resourcename + ".txt");
if ( stream==null ) {
throw new FileNotFoundException("The resource \"" + resourcename + "\" (also tried with \".txt\" extension) was not found relative to CountryData.class");
}
}
BufferedReader reader = new BufferedReader(new InputStreamReader(stream));
// Parse content in file
String line;
int linenumber=0;
boolean isfirst = true;
ArrayList points = new ArrayList();
int min_x = -1, max_x = -1;
int min_y = -1, max_y = -1;
while ( (line=reader.readLine())!=null ) {
// Increment line number
linenumber++;
// Attempt to match line
Matcher matcher = PATTERN_COORDLINE.matcher(line);
if ( matcher.matches()==false ) {
throw new IOException("(line " + linenumber + ") Line doesn't match expected format - \"" + line + "\"");
}
// Get coordinates on line
int x = (int) Double.parseDouble(matcher.group(1));
int y = (int) Double.parseDouble(matcher.group(2));
// Determine if min/max
if ( isfirst ) {
isfirst = false;
min_x = x; max_x = x;
min_y = y; max_y = y;
} else {
// Determine if min/max x value
if ( xmax_x ) max_x = x;
// Determine if min/max y value
if ( ymax_y ) max_y = y;
}
// Add to array
points.add( new VPoint(x, y) );
}
// Scale so as within bounds requested
double scaleby;
int margin_top, margin_left;
if ( (double)(max_x-min_x)/(double)(bounds.width) >
(double)(max_y-min_y)/(double)(bounds.height) ) {
scaleby = (double)(bounds.width) / (double)(max_x-min_x);
margin_top = (int)( ((double)(bounds.height)-(double)(max_y-min_y)*scaleby) / 2.0 );
margin_left = 0;
} else {
scaleby = (double)(bounds.height) / (double)(max_y-min_y);
margin_top = 0;
margin_left = (int)( ((double)(bounds.width)-(double)(max_x-min_x)*scaleby) / 2.0 );
}
// Scale all points appropriately
Iterator iter = points.iterator();
VPoint prevpoint = null;
while ( iter.hasNext() ) {
VPoint point = iter.next();
point.x = bounds.x + margin_left + (int)( (double)(point.x - min_x) * scaleby );
point.y = bounds.y + margin_top + (int)( (double)(point.y - min_y) * scaleby );
// Remove this point if the same as the previous one
if ( prevpoint!=null && point.x==prevpoint.x && point.y==prevpoint.y ) {
iter.remove();
} else {
prevpoint = point;
}
}
// Close the shape if it is not closed
if ( points.size()>=1 ) {
VPoint first = points.get(0);
if (!( first.x==prevpoint.x && first.y==prevpoint.y )) {
points.add( first );
}
}
// Return these points
return points;
}
}