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Groovy: A powerful, dynamic language for the JVM
/*
* $Id: TableSorter.java 6817 2007-07-04 04:42:13Z paulk $
*
* Copyright 2003-2007 the original author or authors.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package groovy.inspect.swingui;
/**
* A sorter for TableModels. The sorter has a model (conforming to TableModel)
* and itself implements TableModel. TableSorter does not store or copy
* the data in the TableModel, instead it maintains an array of
* integers which it keeps the same size as the number of rows in its
* model. When the model changes it notifies the sorter that something
* has changed eg. "rowsAdded" so that its internal array of integers
* can be reallocated. As requests are made of the sorter (like
* getValueAt(row, col) it redirects them to its model via the mapping
* array. That way the TableSorter appears to hold another copy of the table
* with the rows in a different order. The sorting algorthm used is stable
* which means that it does not move around rows when its comparison
* function returns 0 to denote that they are equivalent.
*
* @version 1.12 01/23/03
* @author Philip Milne
* @author Minimal adjustments by Dierk Koenig, June 2005
*/
import javax.swing.*;
import javax.swing.event.TableModelEvent;
import javax.swing.table.JTableHeader;
import javax.swing.table.TableColumnModel;
import javax.swing.table.TableModel;
import java.awt.event.MouseAdapter;
import java.awt.event.MouseEvent;
import java.util.Date;
import java.util.Vector;
public class TableSorter extends TableMap {
int indexes[];
Vector sortingColumns = new Vector();
boolean ascending = true;
int lastSortedColumn = -1;
public TableSorter() {
indexes = new int[0]; // For consistency.
}
public TableSorter(TableModel model) {
setModel(model);
}
public void setModel(TableModel model) {
super.setModel(model);
reallocateIndexes();
}
public int compareRowsByColumn(int row1, int row2, int column) {
Class type = model.getColumnClass(column);
TableModel data = model;
// Check for nulls
Object o1 = data.getValueAt(row1, column);
Object o2 = data.getValueAt(row2, column);
// If both values are null return 0
if (o1 == null && o2 == null) {
return 0;
} else if (o1 == null) { // Define null less than everything.
return -1;
} else if (o2 == null) {
return 1;
}
/* We copy all returned values from the getValue call in case
an optimised model is reusing one object to return many values.
The Number subclasses in the JDK are immutable and so will not be used in
this way but other subclasses of Number might want to do this to save
space and avoid unnecessary heap allocation.
*/
if (type.getSuperclass() == java.lang.Number.class) {
return compareNumbers(data, row1, column, row2);
}
if (type == java.util.Date.class) {
return compareDates(data, row1, column, row2);
}
if (type == String.class) {
return compareStrings(data, row1, column, row2);
}
if (type == Boolean.class) {
return compareBooleans(data, row1, column, row2);
}
return compareObjects(data, row1, column, row2);
}
private int compareObjects(TableModel data, int row1, int column, int row2) {
Object v1 = data.getValueAt(row1, column);
String s1 = v1.toString();
Object v2 = data.getValueAt(row2, column);
String s2 = v2.toString();
int result = s1.compareTo(s2);
if (result < 0)
return -1;
if (result > 0)
return 1;
return 0;
}
private int compareBooleans(TableModel data, int row1, int column, int row2) {
Boolean bool1 = (Boolean) data.getValueAt(row1, column);
boolean b1 = bool1.booleanValue();
Boolean bool2 = (Boolean) data.getValueAt(row2, column);
boolean b2 = bool2.booleanValue();
if (b1 == b2)
return 0;
if (b1) // Define false < true
return 1;
return -1;
}
private int compareStrings(TableModel data, int row1, int column, int row2) {
String s1 = (String) data.getValueAt(row1, column);
String s2 = (String) data.getValueAt(row2, column);
int result = s1.compareTo(s2);
if (result < 0)
return -1;
if (result > 0)
return 1;
return 0;
}
private int compareDates(TableModel data, int row1, int column, int row2) {
Date d1 = (Date) data.getValueAt(row1, column);
long n1 = d1.getTime();
Date d2 = (Date) data.getValueAt(row2, column);
long n2 = d2.getTime();
if (n1 < n2)
return -1;
if (n1 > n2)
return 1;
return 0;
}
private int compareNumbers(TableModel data, int row1, int column, int row2) {
Number n1 = (Number) data.getValueAt(row1, column);
double d1 = n1.doubleValue();
Number n2 = (Number) data.getValueAt(row2, column);
double d2 = n2.doubleValue();
if (d1 < d2)
return -1;
if (d1 > d2)
return 1;
return 0;
}
public int compare(int row1, int row2) {
for (int level = 0; level < sortingColumns.size(); level++) {
Integer column = (Integer) sortingColumns.elementAt(level);
int result = compareRowsByColumn(row1, row2, column.intValue());
if (result != 0)
return ascending ? result : -result;
}
return 0;
}
public void reallocateIndexes() {
int rowCount = model.getRowCount();
// Set up a new array of indexes with the right number of elements
// for the new data model.
indexes = new int[rowCount];
// Initialise with the identity mapping.
for (int row = 0; row < rowCount; row++)
indexes[row] = row;
}
public void tableChanged(TableModelEvent e) {
System.out.println("Sorter: tableChanged");
reallocateIndexes();
super.tableChanged(e);
}
public void checkModel() {
if (indexes.length != model.getRowCount()) {
System.err.println("Sorter not informed of a change in model.");
}
}
public void sort(Object sender) {
checkModel();
shuttlesort((int[]) indexes.clone(), indexes, 0, indexes.length);
}
public void n2sort() {
for (int i = 0; i < getRowCount(); i++) {
for (int j = i + 1; j < getRowCount(); j++) {
if (compare(indexes[i], indexes[j]) == -1) {
swap(i, j);
}
}
}
}
// This is a home-grown implementation which we have not had time
// to research - it may perform poorly in some circumstances. It
// requires twice the space of an in-place algorithm and makes
// NlogN assigments shuttling the values between the two
// arrays. The number of compares appears to vary between N-1 and
// NlogN depending on the initial order but the main reason for
// using it here is that, unlike qsort, it is stable.
public void shuttlesort(int from[], int to[], int low, int high) {
if (high - low < 2) {
return;
}
int middle = (low + high) / 2;
shuttlesort(to, from, low, middle);
shuttlesort(to, from, middle, high);
int p = low;
int q = middle;
/* This is an optional short-cut; at each recursive call,
check to see if the elements in this subset are already
ordered. If so, no further comparisons are needed; the
sub-array can just be copied. The array must be copied rather
than assigned otherwise sister calls in the recursion might
get out of sinc. When the number of elements is three they
are partitioned so that the first set, [low, mid), has one
element and and the second, [mid, high), has two. We skip the
optimisation when the number of elements is three or less as
the first compare in the normal merge will produce the same
sequence of steps. This optimisation seems to be worthwhile
for partially ordered lists but some analysis is needed to
find out how the performance drops to Nlog(N) as the initial
order diminishes - it may drop very quickly. */
if (high - low >= 4 && compare(from[middle - 1], from[middle]) <= 0) {
System.arraycopy(from, low, to, low, high - low);
return;
}
// A normal merge.
for (int i = low; i < high; i++) {
if (q >= high || (p < middle && compare(from[p], from[q]) <= 0)) {
to[i] = from[p++];
} else {
to[i] = from[q++];
}
}
}
public void swap(int i, int j) {
int tmp = indexes[i];
indexes[i] = indexes[j];
indexes[j] = tmp;
}
// The mapping only affects the contents of the data rows.
// Pass all requests to these rows through the mapping array: "indexes".
public Object getValueAt(int aRow, int aColumn) {
checkModel();
return model.getValueAt(indexes[aRow], aColumn);
}
public void setValueAt(Object aValue, int aRow, int aColumn) {
checkModel();
model.setValueAt(aValue, indexes[aRow], aColumn);
}
public void sortByColumn(int column) {
sortByColumn(column, true);
}
public void sortByColumn(int column, boolean ascending) {
this.ascending = ascending;
sortingColumns.removeAllElements();
sortingColumns.addElement(new Integer(column));
sort(this);
super.tableChanged(new TableModelEvent(this));
}
// There is no-where else to put this.
// Add a mouse listener to the Table to trigger a table sort
// when a column heading is clicked in the JTable.
public void addMouseListenerToHeaderInTable(JTable table) {
final TableSorter sorter = this;
final JTable tableView = table;
tableView.setColumnSelectionAllowed(false);
MouseAdapter listMouseListener = new MouseAdapter() {
public void mouseClicked(MouseEvent e) {
TableColumnModel columnModel = tableView.getColumnModel();
int viewColumn = columnModel.getColumnIndexAtX(e.getX());
int column = tableView.convertColumnIndexToModel(viewColumn);
if (e.getClickCount() == 1 && column != -1) {
if (lastSortedColumn == column) ascending = !ascending;
sorter.sortByColumn(column, ascending);
lastSortedColumn = column;
}
}
};
JTableHeader th = tableView.getTableHeader();
th.addMouseListener(listMouseListener);
}
}