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/*
 * Copyright (c) 2002-2013 JGoodies Software GmbH. All Rights Reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions are met:
 *
 *  o Redistributions of source code must retain the above copyright notice,
 *    this list of conditions and the following disclaimer.
 *
 *  o Redistributions in binary form must reproduce the above copyright notice,
 *    this list of conditions and the following disclaimer in the documentation
 *    and/or other materials provided with the distribution.
 *
 *  o Neither the name of JGoodies Software GmbH nor the names of
 *    its contributors may be used to endorse or promote products derived
 *    from this software without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "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 THE COPYRIGHT OWNER OR
 * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
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package com.privatejgoodies.forms.layout;

import static com.privatejgoodies.common.base.Preconditions.checkNotNull;
import static com.privatejgoodies.common.base.Preconditions.checkState;

import java.awt.Component;
import java.awt.Container;
import java.awt.Dimension;
import java.awt.Insets;
import java.awt.LayoutManager2;
import java.awt.Rectangle;
import java.io.IOException;
import java.io.ObjectOutputStream;
import java.io.Serializable;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import java.util.Set;

import javax.swing.JComponent;

import com.privatejgoodies.common.base.Objects;

/**
 * FormLayout is a powerful, flexible and precise general purpose layout manager. It aligns
 * components vertically and horizontally in a dynamic rectangular grid of cells, with each
 * component occupying one or more cells. A
 * whitepaper
 * about the FormLayout ships with the product documentation and is available
 * online.

* * To use FormLayout you first define the grid by specifying the columns and rows. In a second step * you add components to the grid. You can specify columns and rows via human-readable String * descriptions or via arrays of {@link ColumnSpec} and {@link RowSpec} instances.

* * Each component managed by a FormLayout is associated with an instance of {@link CellConstraints}. * The constraints object specifies where a component should be located on the form's grid and how * the component should be positioned. In addition to its constraints object the {@code FormLayout} * also considers each component's minimum and preferred sizes in order to determine a component's * size.

* * FormLayout has been designed to work with non-visual builders that help you specify the layout * and fill the grid. For example, the com.privatejgoodies.forms.builder.ButtonBarBuilder assists * you in building button bars; it creates a standardized FormLayout and provides a minimal API that * specializes in adding buttons and Actions. Other builders can create frequently used panel * design, for example a form that consists of rows of label-component pairs.

* * FormLayout has been prepared to work with different types of sizes as defined by the {@link Size} * interface.

* * Example 1 (Plain FormLayout):
* The following example creates a panel with 3 data columns and 3 data rows; the columns and rows * are specified before components are added to the form. *

 * FormLayout layout = new FormLayout(
 *      "right:pref, 6dlu, 50dlu, 4dlu, default",  // columns
 *      "pref, 3dlu, pref, 3dlu, pref");           // rows
 *
 * JPanel panel = new JPanel(layout);
 * panel.add(new JLabel("Label1"),   CC.xy  (1, 1));
 * panel.add(new JTextField(),       CC.xywh(3, 1, 3, 1));
 * panel.add(new JLabel("Label2"),   CC.xy  (1, 3));
 * panel.add(new JTextField(),       CC.xy  (3, 3));
 * panel.add(new JLabel("Label3"),   CC.xy  (1, 5));
 * panel.add(new JTextField(),       CC.xy  (3, 5));
 * panel.add(new JButton("/u2026"),  CC.xy  (5, 5));
 * return panel;
 * 

* * Example 2 (Using PanelBuilder):
* This example creates the same panel as above using the PanelBuilder to add components to the * form. *

 * FormLayout layout = new FormLayout(
 *      "right:pref, 6dlu, 50dlu, 4dlu, default",  // columns
 *      "pref, 3dlu, pref, 3dlu, pref");           // rows
 *
 * PanelBuilder builder = new PanelBuilder(layout);
 * builder.addLabel("Label1",         CC.xy  (1, 1));
 * builder.add(new JTextField(),      CC.xywh(3, 1, 3, 1));
 * builder.addLabel("Label2",         CC.xy  (1, 3));
 * builder.add(new JTextField(),      CC.xy  (3, 3));
 * builder.addLabel("Label3",         CC.xy  (1, 5));
 * builder.add(new JTextField(),      CC.xy  (3, 5));
 * builder.add(new JButton("/u2026"), CC.xy  (5, 5));
 * return builder.getPanel();
 * 

* * Example 3 (Using DefaultFormBuilder):
* This example utilizes the com.privatejgoodies.forms.builder.DefaultFormBuilder that ships with * the source distribution. *

 * FormLayout layout = new FormLayout(
 *      "right:pref, 6dlu, 50dlu, 4dlu, default"); // 5 columns; add rows later
 *
 * DefaultFormBuilder builder = new DefaultFormBuilder(layout);
 * builder.append("Label1", new JTextField(), 3);
 * builder.append("Label2", new JTextField());
 * builder.append("Label3", new JTextField());
 * builder.append(new JButton("/u2026"));
 * return builder.getPanel();
 * 
* * @author Karsten Lentzsch * @version $Revision: 1.30 $ * * @see ColumnSpec * @see RowSpec * @see CellConstraints see com.privatejgoodies.forms.builder.AbstractFormBuilder * @see com.privatejgoodies.forms.layout.FormSpecs * @see Size * @see Sizes See com.privatejgoodies.forms.builder.DefaultFormBuilder */ public final class FormLayout implements LayoutManager2, Serializable { // Instance Fields ******************************************************** /** * Holds the column specifications. * * @see ColumnSpec * @see #getColumnCount() * @see #getColumnSpec(int) * @see #appendColumn(ColumnSpec) * @see #insertColumn(int, ColumnSpec) * @see #removeColumn(int) */ private final List colSpecs; /** * Holds the row specifications. * * @see RowSpec * @see #getRowCount() * @see #getRowSpec(int) * @see #appendRow(RowSpec) * @see #insertRow(int, RowSpec) * @see #removeRow(int) */ private final List rowSpecs; /** * Holds the column groups as an array of arrays of column indices. * * @see #getColumnGroups() * @see #setColumnGroups(int[][]) * @see #addGroupedColumn(int) */ private int[][] colGroupIndices; /** * Holds the row groups as an array of arrays of row indices. * * @see #getRowGroups() * @see #setRowGroups(int[][]) * @see #addGroupedRow(int) */ private int[][] rowGroupIndices; /** * Maps components to their associated {@code CellConstraints}. * * @see CellConstraints * @see #getConstraints(Component) * @see #setConstraints(Component, CellConstraints) */ private final Map constraintMap; private boolean honorsVisibility = true; // Fields used by the Layout Algorithm ************************************ /** * Holds the components that occupy exactly one column. For each column we keep a list of these * components. */ private transient List[] colComponents; /** * Holds the components that occupy exactly one row. For each row we keep a list of these * components. */ private transient List[] rowComponents; /** * Caches component minimum and preferred sizes. All requests for component sizes shall be * directed to the cache. */ private final ComponentSizeCache componentSizeCache; /** * These functional objects are used to measure component sizes. They abstract from horizontal * and vertical orientation and so, allow to implement the layout algorithm for both * orientations with a single set of methods. */ private final Measure minimumWidthMeasure; private final Measure minimumHeightMeasure; private final Measure preferredWidthMeasure; private final Measure preferredHeightMeasure; // Instance Creation **************************************************** /** * Constructs an empty FormLayout. Columns and rows must be added before components can be added * to the layout container.

* * This constructor is intended to be used in environments that add columns and rows * dynamically. */ public FormLayout() { this(new ColumnSpec[0], new RowSpec[0]); } /** * Constructs a FormLayout using the given encoded column specifications. The constructed layout * has no rows; these must be added before components can be added to the layout container. The * string decoding uses the default LayoutMap.

* * This constructor is intended to be used with builder classes that add rows dynamically, such * as the {@code DefaultFormBuilder} * .

* * Examples:

     * // Label, gap, component
     * FormLayout layout = new FormLayout(
     *      "pref, 4dlu, pref");
     *
     * // Right-aligned label, gap, component, gap, component
     * FormLayout layout = new FormLayout(
     *      "right:pref, 4dlu, 50dlu, 4dlu, 50dlu");
     *
     * // Left-aligned labels, gap, components, gap, components
     * FormLayout layout = new FormLayout(
     *      "left:pref, 4dlu, pref, 4dlu, pref");
     * 
See the class comment for more examples. * * @param encodedColumnSpecs comma separated encoded column specifications * * @throws NullPointerException if encodedColumnSpecs is {@code null} * * @see LayoutMap#getRoot() */ public FormLayout(String encodedColumnSpecs) { this(encodedColumnSpecs, LayoutMap.getRoot()); } /** * Constructs a FormLayout using the given encoded column specifications and LayoutMap. The * constructed layout has no rows; these must be added before components can be added to the * layout container.

* * This constructor is intended to be used with builder classes that add rows dynamically, such * as the {@code DefaultFormBuilder} * .

* * Examples:

     * // Label, gap, component
     * FormLayout layout = new FormLayout(
     *      "pref, 4dlu, pref",
     *      myLayoutMap);
     *
     * // Right-aligned label, gap, component, gap, component
     * FormLayout layout = new FormLayout(
     *      "right:pref, @lcgap, 50dlu, 4dlu, 50dlu",
     *      myLayoutMap);
     *
     * // Left-aligned labels, gap, components, gap, components
     * FormLayout layout = new FormLayout(
     *      "left:pref, @lcgap, pref, @myGap, pref",
     *      myLayoutMap);
     * 
See the class comment for more examples. * * @param encodedColumnSpecs comma separated encoded column specifications * @param layoutMap expands layout column and row variables * * @throws NullPointerException if {@code encodedColumnSpecs} or {@code layoutMap} is * {@code null} * * @see LayoutMap#getRoot() * * @since 1.2 */ public FormLayout(String encodedColumnSpecs, LayoutMap layoutMap) { this(ColumnSpec.decodeSpecs(encodedColumnSpecs, layoutMap), new RowSpec[0]); } /** * Constructs a FormLayout using the given encoded column and row specifications and the default * LayoutMap.

* * This constructor is recommended for most hand-coded layouts.

* * Examples:

     * FormLayout layout = new FormLayout(
     *      "pref, 4dlu, pref",               // columns
     *      "p, 3dlu, p");                    // rows
     *
     * FormLayout layout = new FormLayout(
     *      "right:pref, 4dlu, pref",         // columns
     *      "p, 3dlu, p, 3dlu, fill:p:grow"); // rows
     *
     * FormLayout layout = new FormLayout(
     *      "left:pref, 4dlu, 50dlu",         // columns
     *      "p, 2px, p, 3dlu, p, 9dlu, p");   // rows
     *
     * FormLayout layout = new FormLayout(
     *      "max(75dlu;pref), 4dlu, default", // columns
     *      "p, 3dlu, p, 3dlu, p, 3dlu, p");  // rows
     * 
See the class comment for more examples. * * @param encodedColumnSpecs comma separated encoded column specifications * @param encodedRowSpecs comma separated encoded row specifications * * @throws NullPointerException if encodedColumnSpecs or encodedRowSpecs is {@code null} * * @see LayoutMap#getRoot() */ public FormLayout(String encodedColumnSpecs, String encodedRowSpecs) { this(encodedColumnSpecs, encodedRowSpecs, LayoutMap.getRoot()); } /** * Constructs a FormLayout using the given encoded column and row specifications and the given * LayoutMap.

* * Examples:

     * FormLayout layout = new FormLayout(
     *      "pref, 4dlu, pref",               // columns
     *      "p, 3dlu, p",                     // rows
     *      myLayoutMap);                     // custom LayoutMap
     *
     * FormLayout layout = new FormLayout(
     *      "right:pref, 4dlu, pref",         // columns
     *      "p, @lgap, p, @lgap, fill:p:grow",// rows
     *      myLayoutMap);                     // custom LayoutMap
     *
     * FormLayout layout = new FormLayout(
     *      "left:pref, 4dlu, 50dlu",         // columns
     *      "p, 2px, p, 3dlu, p, 9dlu, p",    // rows
     *      myLayoutMap);                     // custom LayoutMap
     *
     * FormLayout layout = new FormLayout(
     *      "max(75dlu;pref), 4dlu, default", // columns
     *      "p, 3dlu, p, 3dlu, p, 3dlu, p",   // rows
     *      myLayoutMap);                     // custom LayoutMap
     * 
See the class comment for more examples. * * @param encodedColumnSpecs comma separated encoded column specifications * @param encodedRowSpecs comma separated encoded row specifications * @param layoutMap expands layout column and row variables * * @throws NullPointerException if {@code encodedColumnSpecs}, {@code encodedRowSpecs}, or * {@code layoutMap} is {@code null} * * @since 1.2 */ public FormLayout( String encodedColumnSpecs, String encodedRowSpecs, LayoutMap layoutMap) { this(ColumnSpec.decodeSpecs(encodedColumnSpecs, layoutMap), RowSpec.decodeSpecs(encodedRowSpecs, layoutMap)); } /** * Constructs a FormLayout using the given column specifications. The constructed layout has no * rows; these must be added before components can be added to the layout container. * * @param colSpecs an array of column specifications. * @throws NullPointerException if {@code colSpecs} is {@code null} * * @since 1.1 */ public FormLayout(ColumnSpec[] colSpecs) { this(colSpecs, new RowSpec[]{}); } /** * Constructs a FormLayout using the given column and row specifications. * * @param colSpecs an array of column specifications. * @param rowSpecs an array of row specifications. * @throws NullPointerException if {@code colSpecs} or {@code rowSpecs} is {@code null} */ public FormLayout(ColumnSpec[] colSpecs, RowSpec[] rowSpecs) { checkNotNull(colSpecs, "The column specifications must not be null."); checkNotNull(rowSpecs, "The row specifications must not be null."); this.colSpecs = new ArrayList(Arrays.asList(colSpecs)); this.rowSpecs = new ArrayList(Arrays.asList(rowSpecs)); colGroupIndices = new int[][]{}; rowGroupIndices = new int[][]{}; int initialCapacity = colSpecs.length * rowSpecs.length / 4; constraintMap = new HashMap(initialCapacity); componentSizeCache = new ComponentSizeCache(initialCapacity); minimumWidthMeasure = new MinimumWidthMeasure(componentSizeCache); minimumHeightMeasure = new MinimumHeightMeasure(componentSizeCache); preferredWidthMeasure = new PreferredWidthMeasure(componentSizeCache); preferredHeightMeasure = new PreferredHeightMeasure(componentSizeCache); } // Accessing the Column and Row Specifications ************************** /** * Returns the number of columns in this layout. * * @return the number of columns */ public int getColumnCount() { return colSpecs.size(); } /** * Returns the {@code ColumnSpec} at the specified column index. * * @param columnIndex the column index of the requested {@code ColumnSpec} * @return the {@code ColumnSpec} at the specified column * @throws IndexOutOfBoundsException if the column index is out of range */ public ColumnSpec getColumnSpec(int columnIndex) { return colSpecs.get(columnIndex - 1); } /** * Sets the ColumnSpec at the specified column index. * * @param columnIndex the index of the column to be changed * @param columnSpec the ColumnSpec to be set * @throws NullPointerException if {@code columnSpec} is {@code null} * @throws IndexOutOfBoundsException if the column index is out of range */ public void setColumnSpec(int columnIndex, ColumnSpec columnSpec) { checkNotNull(columnSpec, "The column spec must not be null."); colSpecs.set(columnIndex - 1, columnSpec); } /** * Appends the given column specification to the right hand side of all columns. * * @param columnSpec the column specification to be added * @throws NullPointerException if {@code columnSpec} is {@code null} */ public void appendColumn(ColumnSpec columnSpec) { checkNotNull(columnSpec, "The column spec must not be null."); colSpecs.add(columnSpec); } /** * Inserts the specified column at the specified position. Shifts components that intersect the * new column to the right hand side and readjusts column groups.

* * The component shift works as follows: components that were located on the right hand side of * the inserted column are shifted one column to the right; component column span is increased * by one if it intersects the new column.

* * Column group indices that are greater or equal than the given column index will be increased * by one. * * @param columnIndex index of the column to be inserted * @param columnSpec specification of the column to be inserted * @throws IndexOutOfBoundsException if the column index is out of range */ public void insertColumn(int columnIndex, ColumnSpec columnSpec) { if (columnIndex < 1 || columnIndex > getColumnCount()) { throw new IndexOutOfBoundsException( "The column index " + columnIndex + "must be in the range [1, " + getColumnCount() + "]."); } colSpecs.add(columnIndex - 1, columnSpec); shiftComponentsHorizontally(columnIndex, false); adjustGroupIndices(colGroupIndices, columnIndex, false); } /** * Removes the column with the given column index from the layout. Components will be rearranged * and column groups will be readjusted. Therefore, the column must not contain components and * must not be part of a column group.

* * The component shift works as follows: components that were located on the right hand side of * the removed column are moved one column to the left; component column span is decreased by * one if it intersects the removed column.

* * Column group indices that are greater than the column index will be decreased by one.

* * Note: If one of the constraints mentioned above is violated, this layout's * state becomes illegal and it is unsafe to work with this layout. A typical layout * implementation can ensure that these constraints are not violated. However, in some cases you * may need to check these conditions before you invoke this method. The Forms extras contain * source code for class {@code FormLayoutUtils} that provides the required test methods:
* {@code #columnContainsComponents(Container, int)} and
* {@code #isGroupedColumn(FormLayout, int)}. * * @param columnIndex index of the column to remove * @throws IndexOutOfBoundsException if the column index is out of range * @throws IllegalStateException if the column contains components or if the column is already * grouped * * see com.jgoodies.forms.extras.FormLayoutUtils#columnContainsComponent(Container, int) see * com.jgoodies.forms.extras.FormLayoutUtils#isGroupedColumn(FormLayout, int) */ public void removeColumn(int columnIndex) { if (columnIndex < 1 || columnIndex > getColumnCount()) { throw new IndexOutOfBoundsException( "The column index " + columnIndex + " must be in the range [1, " + getColumnCount() + "]."); } colSpecs.remove(columnIndex - 1); shiftComponentsHorizontally(columnIndex, true); adjustGroupIndices(colGroupIndices, columnIndex, true); } /** * Returns the number of rows in this layout. * * @return the number of rows */ public int getRowCount() { return rowSpecs.size(); } /** * Returns the {@code RowSpec} at the specified row index. * * @param rowIndex the row index of the requested {@code RowSpec} * @return the {@code RowSpec} at the specified row * @throws IndexOutOfBoundsException if the row index is out of range */ public RowSpec getRowSpec(int rowIndex) { return rowSpecs.get(rowIndex - 1); } /** * Sets the RowSpec at the specified row index. * * @param rowIndex the index of the row to be changed * @param rowSpec the RowSpec to be set * @throws NullPointerException if {@code rowSpec} is {@code null} * @throws IndexOutOfBoundsException if the row index is out of range */ public void setRowSpec(int rowIndex, RowSpec rowSpec) { checkNotNull(rowSpec, "The row spec must not be null."); rowSpecs.set(rowIndex - 1, rowSpec); } /** * Appends the given row specification to the bottom of all rows. * * @param rowSpec the row specification to be added to the form layout * @throws NullPointerException if {@code rowSpec} is {@code null} */ public void appendRow(RowSpec rowSpec) { checkNotNull(rowSpec, "The row spec must not be null."); rowSpecs.add(rowSpec); } /** * Inserts the specified column at the specified position. Shifts components that intersect the * new column to the right and readjusts column groups.

* * The component shift works as follows: components that were located on the right hand side of * the inserted column are shifted one column to the right; component column span is increased * by one if it intersects the new column.

* * Column group indices that are greater or equal than the given column index will be increased * by one. * * @param rowIndex index of the row to be inserted * @param rowSpec specification of the row to be inserted * @throws IndexOutOfBoundsException if the row index is out of range */ public void insertRow(int rowIndex, RowSpec rowSpec) { if (rowIndex < 1 || rowIndex > getRowCount()) { throw new IndexOutOfBoundsException( "The row index " + rowIndex + " must be in the range [1, " + getRowCount() + "]."); } rowSpecs.add(rowIndex - 1, rowSpec); shiftComponentsVertically(rowIndex, false); adjustGroupIndices(rowGroupIndices, rowIndex, false); } /** * Removes the row with the given row index from the layout. Components will be rearranged and * row groups will be readjusted. Therefore, the row must not contain components and must not be * part of a row group.

* * The component shift works as follows: components that were located below the removed row are * moved up one row; component row span is decreased by one if it intersects the removed row.

* * Row group indices that are greater than the row index will be decreased by one.

* * Note: If one of the constraints mentioned above is violated, this layout's * state becomes illegal and it is unsafe to work with this layout. A typical layout * implementation can ensure that these constraints are not violated. However, in some cases you * may need to check these conditions before you invoke this method. The Forms extras contain * source code for class {@code FormLayoutUtils} that provides the required test methods:
* {@code #rowContainsComponents(Container, int)} and
* {@code #isGroupedRow(FormLayout, int)}. * * @param rowIndex index of the row to remove * @throws IndexOutOfBoundsException if the row index is out of range * @throws IllegalStateException if the row contains components or if the row is already grouped * * see com.jgoodies.forms.extras.FormLayoutUtils#rowContainsComponent(Container, int) see * com.jgoodies.forms.extras.FormLayoutUtils#isGroupedRow(FormLayout, int) */ public void removeRow(int rowIndex) { if (rowIndex < 1 || rowIndex > getRowCount()) { throw new IndexOutOfBoundsException( "The row index " + rowIndex + "must be in the range [1, " + getRowCount() + "]."); } rowSpecs.remove(rowIndex - 1); shiftComponentsVertically(rowIndex, true); adjustGroupIndices(rowGroupIndices, rowIndex, true); } /** * Shifts components horizontally, either to the right if a column has been inserted or to the * left if a column has been removed. * * @param columnIndex index of the column to remove * @param remove true for remove, false for insert * @throws IllegalStateException if a removed column contains components */ private void shiftComponentsHorizontally(int columnIndex, boolean remove) { final int offset = remove ? -1 : 1; for (Object element : constraintMap.entrySet()) { Map.Entry entry = (Map.Entry) element; CellConstraints constraints = (CellConstraints) entry.getValue(); int x1 = constraints.gridX; int w = constraints.gridWidth; int x2 = x1 + w - 1; if (x1 == columnIndex && remove) { throw new IllegalStateException( "The removed column " + columnIndex + " must not contain component origins.\n" + "Illegal component=" + entry.getKey()); } else if (x1 >= columnIndex) { constraints.gridX += offset; } else if (x2 >= columnIndex) { constraints.gridWidth += offset; } } } /** * Shifts components vertically, either to the bottom if a row has been inserted or to the top * if a row has been removed. * * @param rowIndex index of the row to remove * @param remove true for remove, false for insert * @throws IllegalStateException if a removed column contains components */ private void shiftComponentsVertically(int rowIndex, boolean remove) { final int offset = remove ? -1 : 1; for (Object element : constraintMap.entrySet()) { Map.Entry entry = (Map.Entry) element; CellConstraints constraints = (CellConstraints) entry.getValue(); int y1 = constraints.gridY; int h = constraints.gridHeight; int y2 = y1 + h - 1; if (y1 == rowIndex && remove) { throw new IllegalStateException( "The removed row " + rowIndex + " must not contain component origins.\n" + "Illegal component=" + entry.getKey()); } else if (y1 >= rowIndex) { constraints.gridY += offset; } else if (y2 >= rowIndex) { constraints.gridHeight += offset; } } } /** * Adjusts group indices. Shifts the given groups to left, right, up, down according to the * specified remove or add flag. * * @param allGroupIndices the groups to be adjusted * @param modifiedIndex the modified column or row index * @param remove true for remove, false for add * @throws IllegalStateException if we remove and the index is grouped */ private static void adjustGroupIndices(int[][] allGroupIndices, int modifiedIndex, boolean remove) { final int offset = remove ? -1 : +1; for (int[] allGroupIndice : allGroupIndices) { int[] groupIndices = allGroupIndice; for (int i = 0; i < groupIndices.length; i++) { int index = groupIndices[i]; if (index == modifiedIndex && remove) { throw new IllegalStateException( "The removed index " + modifiedIndex + " must not be grouped."); } else if (index >= modifiedIndex) { groupIndices[i] += offset; } } } } // Accessing Constraints ************************************************ /** * Looks up and returns the constraints for the specified component. A copy of the * actualCellConstraints object is returned. * * @param component the component to be queried * @return the CellConstraints for the specified component * @throws NullPointerException if {@code component} is {@code null} * @throws IllegalStateException if {@code component} has not been added to the container */ public CellConstraints getConstraints(Component component) { return (CellConstraints) getConstraints0(component).clone(); } private CellConstraints getConstraints0(Component component) { checkNotNull(component, "The component must not be null."); CellConstraints constraints = constraintMap.get(component); checkState(constraints != null, "The component has not been added to the container."); return constraints; } /** * Sets the constraints for the specified component in this layout. * * @param component the component to be modified * @param constraints the constraints to be applied * @throws NullPointerException if {@code component} or {@code constraints} is {@code null} */ public void setConstraints(Component component, CellConstraints constraints) { checkNotNull(component, "The component must not be null."); checkNotNull(constraints, "The constraints must not be null."); constraints.ensureValidGridBounds(getColumnCount(), getRowCount()); constraintMap.put(component, (CellConstraints) constraints.clone()); } /** * Removes the constraints for the specified component in this layout. * * @param component the component to be modified */ private void removeConstraints(Component component) { constraintMap.remove(component); componentSizeCache.removeEntry(component); } // Accessing Column and Row Groups ************************************** /** * Returns a deep copy of the column groups. * * @return the column groups as two-dimensional int array */ public int[][] getColumnGroups() { return deepClone(colGroupIndices); } /** * Sets the column groups, where each column in a group gets the same group wide width. Each * group is described by an array of integers that are interpreted as column indices. The * parameter is an array of such group descriptions.

* * Examples:

     * // Group columns 1, 3 and 4.
     * setColumnGroups(new int[][]{ {1, 3, 4}});
     *
     * // Group columns 1, 3, 4, and group columns 7 and 9
     * setColumnGroups(new int[][]{ {1, 3, 4}, {7, 9}});
     * 
* * @param colGroupIndices a two-dimensional array of column groups indices * @throws IndexOutOfBoundsException if an index is outside the grid * @throws IllegalArgumentException if a column index is used twice */ public void setColumnGroups(int[][] colGroupIndices) { int maxColumn = getColumnCount(); boolean[] usedIndices = new boolean[maxColumn + 1]; for (int group = 0; group < colGroupIndices.length; group++) { for (int j = 0; j < colGroupIndices[group].length; j++) { int colIndex = colGroupIndices[group][j]; if (colIndex < 1 || colIndex > maxColumn) { throw new IndexOutOfBoundsException( "Invalid column group index " + colIndex + " in group " + (group + 1)); } if (usedIndices[colIndex]) { throw new IllegalArgumentException( "Column index " + colIndex + " must not be used in multiple column groups."); } usedIndices[colIndex] = true; } } this.colGroupIndices = deepClone(colGroupIndices); } /** * Adds the specified column index to the last column group. In case there are no groups, a new * group will be created. * * @param columnIndex the column index to be set grouped */ public void addGroupedColumn(int columnIndex) { int[][] newColGroups = getColumnGroups(); // Create a group if none exists. if (newColGroups.length == 0) { newColGroups = new int[][]{{columnIndex}}; } else { int lastGroupIndex = newColGroups.length - 1; int[] lastGroup = newColGroups[lastGroupIndex]; int groupSize = lastGroup.length; int[] newLastGroup = new int[groupSize + 1]; System.arraycopy(lastGroup, 0, newLastGroup, 0, groupSize); newLastGroup[groupSize] = columnIndex; newColGroups[lastGroupIndex] = newLastGroup; } setColumnGroups(newColGroups); } /** * Returns a deep copy of the row groups. * * @return the row groups as two-dimensional int array */ public int[][] getRowGroups() { return deepClone(rowGroupIndices); } /** * Sets the row groups, where each row in such a group gets the same group wide height. Each * group is described by an array of integers that are interpreted as row indices. The parameter * is an array of such group descriptions.

* * Examples:

     * // Group rows 1 and 2.
     * setRowGroups(new int[][]{ {1, 2}});
     *
     * // Group rows 1 and 2, and group rows 5, 7, and 9.
     * setRowGroups(new int[][]{ {1, 2}, {5, 7, 9}});
     * 
* * @param rowGroupIndices a two-dimensional array of row group indices. * @throws IndexOutOfBoundsException if an index is outside the grid */ public void setRowGroups(int[][] rowGroupIndices) { int rowCount = getRowCount(); boolean[] usedIndices = new boolean[rowCount + 1]; for (int i = 0; i < rowGroupIndices.length; i++) { for (int j = 0; j < rowGroupIndices[i].length; j++) { int rowIndex = rowGroupIndices[i][j]; if (rowIndex < 1 || rowIndex > rowCount) { throw new IndexOutOfBoundsException( "Invalid row group index " + rowIndex + " in group " + (i + 1)); } if (usedIndices[rowIndex]) { throw new IllegalArgumentException( "Row index " + rowIndex + " must not be used in multiple row groups."); } usedIndices[rowIndex] = true; } } this.rowGroupIndices = deepClone(rowGroupIndices); } /** * Adds the specified row index to the last row group. In case there are no groups, a new group * will be created. * * @param rowIndex the index of the row that should be grouped */ public void addGroupedRow(int rowIndex) { int[][] newRowGroups = getRowGroups(); // Create a group if none exists. if (newRowGroups.length == 0) { newRowGroups = new int[][]{{rowIndex}}; } else { int lastGroupIndex = newRowGroups.length - 1; int[] lastGroup = newRowGroups[lastGroupIndex]; int groupSize = lastGroup.length; int[] newLastGroup = new int[groupSize + 1]; System.arraycopy(lastGroup, 0, newLastGroup, 0, groupSize); newLastGroup[groupSize] = rowIndex; newRowGroups[lastGroupIndex] = newLastGroup; } setRowGroups(newRowGroups); } // Other Accessors ******************************************************** /** * Returns whether invisible components shall be taken into account by this layout. This * container-wide setting can be overridden per component. See * {@link #setHonorsVisibility(boolean)} for details. * * @return {@code true} if the component visibility is honored by this FormLayout, {@code false} * if it is ignored. This setting can be overridden for individual CellConstraints using * {@link #setHonorsVisibility(Component, Boolean)}. * * @since 1.2 */ public boolean getHonorsVisibility() { return honorsVisibility; } /** * Specifies whether invisible components shall be taken into account by this layout for * computing the layout size and setting component bounds. If set to {@code true} invisible * components will be ignored by the layout. If set to {@code false} components will be taken * into account regardless of their visibility. Visible components are always used for sizing * and positioning.

* * The default value for this setting is {@code true}. It is useful to set the value to * {@code false} (in other words to ignore the visibility) if you switch the component * visibility dynamically and want the container to retain the size and component positions.

* * This container-wide default setting can be overridden per component using {@link #setHonorsVisibility(Component, Boolean)} * .

* * Components are taken into account, if

    *
  1. they are visible, or *
  2. they have no individual setting and the container-wide settings ignores the visibility * (honorsVisibility set to {@code false}), or *
  3. the individual component ignores the visibility. *
* * @param b {@code true} to honor the visibility, i.e. to exclude invisible components from the * sizing and positioning, {@code false} to ignore the visibility, in other words to layout * visible and invisible components * * @since 1.2 */ public void setHonorsVisibility(boolean b) { boolean oldHonorsVisibility = getHonorsVisibility(); if (oldHonorsVisibility == b) { return; } honorsVisibility = b; Set componentSet = constraintMap.keySet(); if (componentSet.isEmpty()) { return; } Component firstComponent = (Component) componentSet.iterator().next(); Container container = firstComponent.getParent(); invalidateAndRepaint(container); } /** * Specifies whether the given component shall be taken into account for sizing and positioning. * This setting overrides the container-wide default. See {@link #setHonorsVisibility(boolean)} * for details. * * @param component the component that shall get an individual setting * @param b {@code Boolean.TRUE} to override the container default and honor the visibility for * the given component, {@code Boolean.FALSE} to override the container default and ignore the * visibility for the given component, {@code null} to use the container default value as * specified by {@link #getHonorsVisibility()}. * * @since 1.2 */ public void setHonorsVisibility(Component component, Boolean b) { CellConstraints constraints = getConstraints0(component); if (Objects.equals(b, constraints.honorsVisibility)) { return; } constraints.honorsVisibility = b; invalidateAndRepaint(component.getParent()); } // Implementing the LayoutManager and LayoutManager2 Interfaces ********* /** * Throws an {@code UnsupportedOperationException}. Does not add the specified component with * the specified name to the layout. * * @param name indicates entry's position and anchor * @param component component to add * @throws UnsupportedOperationException always */ @Override public void addLayoutComponent(String name, Component component) { throw new UnsupportedOperationException( "Use #addLayoutComponent(Component, Object) instead."); } /** * Adds the specified component to the layout, using the specified {@code constraints} object. * Note that constraints are mutable and are, therefore, cloned when cached. * * @param comp the component to be added * @param constraints the component's cell constraints * @throws NullPointerException if {@code constraints} is {@code null} * @throws IllegalArgumentException if {@code constraints} is neither a String, nor a * CellConstraints object, or a String that is rejected by the CellConstraints construction */ @Override public void addLayoutComponent(Component comp, Object constraints) { checkNotNull(constraints, "The constraints must not be null."); if (constraints instanceof String) { setConstraints(comp, new CellConstraints((String) constraints)); } else if (constraints instanceof CellConstraints) { setConstraints(comp, (CellConstraints) constraints); } else { throw new IllegalArgumentException("Illegal constraint type " + constraints.getClass()); } } /** * Removes the specified component from this layout.

* * Most applications do not call this method directly. * * @param comp the component to be removed. * @see Container#remove(java.awt.Component) * @see Container#removeAll() */ @Override public void removeLayoutComponent(Component comp) { removeConstraints(comp); } // Layout Requests ****************************************************** /** * Determines the minimum size of the {@code parent} container using this form layout.

* * Most applications do not call this method directly. * * @param parent the container in which to do the layout * @return the minimum size of the {@code parent} container * * @see Container#doLayout() */ @Override public Dimension minimumLayoutSize(Container parent) { return computeLayoutSize(parent, minimumWidthMeasure, minimumHeightMeasure); } /** * Determines the preferred size of the {@code parent} container using this form layout.

* * Most applications do not call this method directly. * * @param parent the container in which to do the layout * @return the preferred size of the {@code parent} container * * @see Container#getPreferredSize() */ @Override public Dimension preferredLayoutSize(Container parent) { return computeLayoutSize(parent, preferredWidthMeasure, preferredHeightMeasure); } /** * Returns the maximum dimensions for this layout given the components in the specified target * container. * * @param target the container which needs to be laid out * @see Container * @see #minimumLayoutSize(Container) * @see #preferredLayoutSize(Container) * @return the maximum dimensions for this layout */ @Override public Dimension maximumLayoutSize(Container target) { return new Dimension(Integer.MAX_VALUE, Integer.MAX_VALUE); } /** * Returns the alignment along the x axis. This specifies how the component would like to be * aligned relative to other components. The value should be a number between 0 and 1 where 0 * represents alignment along the origin, 1 is aligned the farthest away from the origin, 0.5 is * centered, etc. * * @param parent the parent container * @return the value {@code 0.5f} to indicate center alignment */ @Override public float getLayoutAlignmentX(Container parent) { return 0.5f; } /** * Returns the alignment along the y axis. This specifies how the component would like to be * aligned relative to other components. The value should be a number between 0 and 1 where 0 * represents alignment along the origin, 1 is aligned the farthest away from the origin, 0.5 is * centered, etc. * * @param parent the parent container * @return the value {@code 0.5f} to indicate center alignment */ @Override public float getLayoutAlignmentY(Container parent) { return 0.5f; } /** * Invalidates the layout, indicating that if the layout manager has cached information it * should be discarded. * * @param target the container that holds the layout to be invalidated */ @Override public void invalidateLayout(Container target) { invalidateCaches(); } /** * Lays out the specified container using this form layout. This method reshapes components in * the specified container in order to satisfy the constraints of this {@code FormLayout} * object.

* * Most applications do not call this method directly.

* * The form layout performs the following steps: *

    *
  1. find components that occupy exactly one column or row *
  2. compute minimum widths and heights *
  3. compute preferred widths and heights *
  4. give cols and row equal size if they share a group *
  5. compress default columns and rows if total is less than pref size *
  6. give cols and row equal size if they share a group *
  7. distribute free space *
  8. set components bounds *
* * @param parent the container in which to do the layout * @see Container * @see Container#doLayout() */ @Override public void layoutContainer(Container parent) { synchronized (parent.getTreeLock()) { initializeColAndRowComponentLists(); Dimension size = parent.getSize(); Insets insets = parent.getInsets(); int totalWidth = size.width - insets.left - insets.right; int totalHeight = size.height - insets.top - insets.bottom; int[] x = computeGridOrigins(parent, totalWidth, insets.left, colSpecs, colComponents, colGroupIndices, minimumWidthMeasure, preferredWidthMeasure ); int[] y = computeGridOrigins(parent, totalHeight, insets.top, rowSpecs, rowComponents, rowGroupIndices, minimumHeightMeasure, preferredHeightMeasure ); layoutComponents(x, y); } } // Layout Algorithm ***************************************************** /** * Initializes two lists for columns and rows that hold a column's or row's components that span * only this column or row.

* * Iterates over all components and their associated constraints; every component that has a * column span or row span of 1 is put into the column's or row's component list. */ private void initializeColAndRowComponentLists() { colComponents = new List[getColumnCount()]; for (int i = 0; i < getColumnCount(); i++) { colComponents[i] = new ArrayList(); } rowComponents = new List[getRowCount()]; for (int i = 0; i < getRowCount(); i++) { rowComponents[i] = new ArrayList(); } for (Object element : constraintMap.entrySet()) { Map.Entry entry = (Map.Entry) element; Component component = (Component) entry.getKey(); CellConstraints constraints = (CellConstraints) entry.getValue(); if (takeIntoAccount(component, constraints)) { if (constraints.gridWidth == 1) { colComponents[constraints.gridX - 1].add(component); } if (constraints.gridHeight == 1) { rowComponents[constraints.gridY - 1].add(component); } } } } /** * Computes and returns the layout size of the given {@code parent} container using the * specified measures. * * @param parent the container in which to do the layout * @param defaultWidthMeasure the measure used to compute the default width * @param defaultHeightMeasure the measure used to compute the default height * @return the layout size of the {@code parent} container */ private Dimension computeLayoutSize(Container parent, Measure defaultWidthMeasure, Measure defaultHeightMeasure) { synchronized (parent.getTreeLock()) { initializeColAndRowComponentLists(); int[] colWidths = maximumSizes(parent, colSpecs, colComponents, minimumWidthMeasure, preferredWidthMeasure, defaultWidthMeasure); int[] rowHeights = maximumSizes(parent, rowSpecs, rowComponents, minimumHeightMeasure, preferredHeightMeasure, defaultHeightMeasure); int[] groupedWidths = groupedSizes(colGroupIndices, colWidths); int[] groupedHeights = groupedSizes(rowGroupIndices, rowHeights); // Convert sizes to origins. int[] xOrigins = computeOrigins(groupedWidths, 0); int[] yOrigins = computeOrigins(groupedHeights, 0); int width1 = sum(groupedWidths); int height1 = sum(groupedHeights); int maxWidth = width1; int maxHeight = height1; /* * Take components that span multiple columns or rows into account. * This shall be done if and only if a component spans an interval * that can grow. */ // First computes the maximum number of cols/rows a component // can span without spanning a growing column. int[] maxFixedSizeColsTable = computeMaximumFixedSpanTable(colSpecs); int[] maxFixedSizeRowsTable = computeMaximumFixedSpanTable(rowSpecs); for (Object element : constraintMap.entrySet()) { Map.Entry entry = (Map.Entry) element; Component component = (Component) entry.getKey(); CellConstraints constraints = (CellConstraints) entry.getValue(); if (!takeIntoAccount(component, constraints)) { continue; } if (constraints.gridWidth > 1 && constraints.gridWidth > maxFixedSizeColsTable[constraints.gridX - 1]) { //int compWidth = minimumWidthMeasure.sizeOf(component); int compWidth = defaultWidthMeasure.sizeOf(component); //int compWidth = preferredWidthMeasure.sizeOf(component); int gridX1 = constraints.gridX - 1; int gridX2 = gridX1 + constraints.gridWidth; int lead = xOrigins[gridX1]; int trail = width1 - xOrigins[gridX2]; int myWidth = lead + compWidth + trail; if (myWidth > maxWidth) { maxWidth = myWidth; } } if (constraints.gridHeight > 1 && constraints.gridHeight > maxFixedSizeRowsTable[constraints.gridY - 1]) { //int compHeight = minimumHeightMeasure.sizeOf(component); int compHeight = defaultHeightMeasure.sizeOf(component); //int compHeight = preferredHeightMeasure.sizeOf(component); int gridY1 = constraints.gridY - 1; int gridY2 = gridY1 + constraints.gridHeight; int lead = yOrigins[gridY1]; int trail = height1 - yOrigins[gridY2]; int myHeight = lead + compHeight + trail; if (myHeight > maxHeight) { maxHeight = myHeight; } } } Insets insets = parent.getInsets(); int width = maxWidth + insets.left + insets.right; int height = maxHeight + insets.top + insets.bottom; return new Dimension(width, height); } } /** * Computes and returns the grid's origins. * * @param container the layout container * @param totalSize the total size to assign * @param offset the offset from left or top margin * @param formSpecs the column or row specs, resp. * @param componentLists the components list for each col/row * @param minMeasure the measure used to determine min sizes * @param prefMeasure the measure used to determine pre sizes * @param groupIndices the group specification * @return an int array with the origins */ private static int[] computeGridOrigins(Container container, int totalSize, int offset, List formSpecs, List[] componentLists, int[][] groupIndices, Measure minMeasure, Measure prefMeasure) { /* For each spec compute the minimum and preferred size that is * the maximum of all component minimum and preferred sizes resp. */ int[] minSizes = maximumSizes(container, formSpecs, componentLists, minMeasure, prefMeasure, minMeasure); int[] prefSizes = maximumSizes(container, formSpecs, componentLists, minMeasure, prefMeasure, prefMeasure); int[] groupedMinSizes = groupedSizes(groupIndices, minSizes); int[] groupedPrefSizes = groupedSizes(groupIndices, prefSizes); int totalMinSize = sum(groupedMinSizes); int totalPrefSize = sum(groupedPrefSizes); int[] compressedSizes = compressedSizes(formSpecs, totalSize, totalMinSize, totalPrefSize, groupedMinSizes, prefSizes); int[] groupedSizes = groupedSizes(groupIndices, compressedSizes); int totalGroupedSize = sum(groupedSizes); int[] sizes = distributedSizes(formSpecs, totalSize, totalGroupedSize, groupedSizes); return computeOrigins(sizes, offset); } /** * Computes origins from sizes taking the specified offset into account. * * @param sizes the array of sizes * @param offset an offset for the first origin * @return an array of origins */ private static int[] computeOrigins(int[] sizes, int offset) { int count = sizes.length; int[] origins = new int[count + 1]; origins[0] = offset; for (int i = 1; i <= count; i++) { origins[i] = origins[i - 1] + sizes[i - 1]; } return origins; } /** * Lays out the components using the given x and y origins, the column and row specifications, * and the component constraints.

* * The actual computation is done by each component's form constraint object. We just compute * the cell, the cell bounds and then hand over the component, cell bounds, and measure to the * form constraints. This will allow potential subclasses of {@code CellConstraints} to do * special micro-layout corrections. For example, such a subclass could map JComponent classes * to visual layout bounds that may lead to a slightly different bounds. * * @param x an int array of the horizontal origins * @param y an int array of the vertical origins */ private void layoutComponents(int[] x, int[] y) { Rectangle cellBounds = new Rectangle(); for (Object element : constraintMap.entrySet()) { Map.Entry entry = (Map.Entry) element; Component component = (Component) entry.getKey(); CellConstraints constraints = (CellConstraints) entry.getValue(); int gridX = constraints.gridX - 1; int gridY = constraints.gridY - 1; int gridWidth = constraints.gridWidth; int gridHeight = constraints.gridHeight; cellBounds.x = x[gridX]; cellBounds.y = y[gridY]; cellBounds.width = x[gridX + gridWidth] - cellBounds.x; cellBounds.height = y[gridY + gridHeight] - cellBounds.y; constraints.setBounds(component, this, cellBounds, minimumWidthMeasure, minimumHeightMeasure, preferredWidthMeasure, preferredHeightMeasure); } } /** * Invalidates the component size caches. */ private void invalidateCaches() { componentSizeCache.invalidate(); } /** * Computes and returns the sizes for the given form specs, component lists and measures for * minimum, preferred, and default size. * * @param container the layout container * @param formSpecs the column or row specs, resp. * @param componentLists the components list for each col/row * @param minMeasure the measure used to determine min sizes * @param prefMeasure the measure used to determine pre sizes * @param defaultMeasure the measure used to determine default sizes * @return the column or row sizes */ private static int[] maximumSizes(Container container, List formSpecs, List[] componentLists, Measure minMeasure, Measure prefMeasure, Measure defaultMeasure) { FormSpec formSpec; int size = formSpecs.size(); int[] result = new int[size]; for (int i = 0; i < size; i++) { formSpec = (FormSpec) formSpecs.get(i); result[i] = formSpec.maximumSize(container, componentLists[i], minMeasure, prefMeasure, defaultMeasure); } return result; } /** * Computes and returns the compressed sizes. Compresses space for columns and rows iff the * available space is less than the total preferred size but more than the total minimum * size.

* * Only columns and rows that are specified to be compressible will be affected. You can specify * a column and row as compressible by giving it the component size default. * * @param formSpecs the column or row specs to use * @param totalSize the total available size * @param totalMinSize the sum of all minimum sizes * @param totalPrefSize the sum of all preferred sizes * @param minSizes an int array of column/row minimum sizes * @param prefSizes an int array of column/row preferred sizes * @return an int array of compressed column/row sizes */ private static int[] compressedSizes(List formSpecs, int totalSize, int totalMinSize, int totalPrefSize, int[] minSizes, int[] prefSizes) { // If we have less space than the total min size, answer the min sizes. if (totalSize < totalMinSize) { return minSizes; } // If we have more space than the total pref size, answer the pref sizes. if (totalSize >= totalPrefSize) { return prefSizes; } int count = formSpecs.size(); int[] sizes = new int[count]; double totalCompressionSpace = totalPrefSize - totalSize; double maxCompressionSpace = totalPrefSize - totalMinSize; double compressionFactor = totalCompressionSpace / maxCompressionSpace; // System.out.println("Total compression space=" + totalCompressionSpace); // System.out.println("Max compression space =" + maxCompressionSpace); // System.out.println("Compression factor =" + compressionFactor); for (int i = 0; i < count; i++) { FormSpec formSpec = (FormSpec) formSpecs.get(i); sizes[i] = prefSizes[i]; if (formSpec.getSize().compressible()) { sizes[i] -= (int) Math.round((prefSizes[i] - minSizes[i]) * compressionFactor); } } return sizes; } /** * Computes and returns the grouped sizes. Gives grouped columns and rows the same size. * * @param groups the group specification * @param rawSizes the raw sizes before the grouping * @return the grouped sizes */ private static int[] groupedSizes(int[][] groups, int[] rawSizes) { // Return the compressed sizes if there are no groups. if (groups == null || groups.length == 0) { return rawSizes; } // Initialize the result with the given compressed sizes. int[] sizes = new int[rawSizes.length]; for (int i = 0; i < sizes.length; i++) { sizes[i] = rawSizes[i]; } // For each group equalize the sizes. for (int[] groupIndices : groups) { int groupMaxSize = 0; // Compute the group's maximum size. for (int groupIndice : groupIndices) { int index = groupIndice - 1; groupMaxSize = Math.max(groupMaxSize, sizes[index]); } // Set all sizes of this group to the group's maximum size. for (int groupIndice : groupIndices) { int index = groupIndice - 1; sizes[index] = groupMaxSize; } } return sizes; } /** * Distributes free space over columns and rows and returns the sizes after this distribution * process. * * @param formSpecs the column/row specifications to work with * @param totalSize the total available size * @param totalPrefSize the sum of all preferred sizes * @param inputSizes the input sizes * @return the distributed sizes */ private static int[] distributedSizes(List formSpecs, int totalSize, int totalPrefSize, int[] inputSizes) { double totalFreeSpace = totalSize - totalPrefSize; // Do nothing if there's no free space. if (totalFreeSpace < 0) { return inputSizes; } // Compute the total weight. int count = formSpecs.size(); double totalWeight = 0.0; for (int i = 0; i < count; i++) { FormSpec formSpec = (FormSpec) formSpecs.get(i); totalWeight += formSpec.getResizeWeight(); } // Do nothing if there's no resizing column. if (totalWeight == 0.0) { return inputSizes; } int[] sizes = new int[count]; double restSpace = totalFreeSpace; int roundedRestSpace = (int) totalFreeSpace; for (int i = 0; i < count; i++) { FormSpec formSpec = (FormSpec) formSpecs.get(i); double weight = formSpec.getResizeWeight(); if (weight == FormSpec.NO_GROW) { sizes[i] = inputSizes[i]; } else { double roundingCorrection = restSpace - roundedRestSpace; double extraSpace = totalFreeSpace * weight / totalWeight; double correctedExtraSpace = extraSpace - roundingCorrection; int roundedExtraSpace = (int) Math.round(correctedExtraSpace); sizes[i] = inputSizes[i] + roundedExtraSpace; restSpace -= extraSpace; roundedRestSpace -= roundedExtraSpace; } } return sizes; } /** * Computes and returns a table that maps a column/row index to the maximum number of * columns/rows that a component can span without spanning a growing column.

* * Iterates over the specs from right to left/bottom to top, sets the table value to zero if a * spec can grow, otherwise increases the span by one.

* * Examples:

     * "pref, 4dlu, pref, 2dlu, p:grow, 2dlu,      pref" ->
     * [4,    3,    2,    1,    0,      MAX_VALUE, MAX_VALUE]
     *
     * "p:grow, 4dlu, p:grow, 9dlu,      pref" ->
     * [0,      1,    0,      MAX_VALUE, MAX_VALUE]
     *
     * "p, 4dlu, p, 2dlu, 0:grow" ->
     * [4, 3,    2, 1,    0]
     * 
* * @param formSpecs the column specs or row specs * @return a table that maps a spec index to the maximum span for fixed size specs */ private static int[] computeMaximumFixedSpanTable(List formSpecs) { int size = formSpecs.size(); int[] table = new int[size]; int maximumFixedSpan = Integer.MAX_VALUE; // Could be 1 for (int i = size - 1; i >= 0; i--) { FormSpec spec = (FormSpec) formSpecs.get(i); // ArrayList access if (spec.canGrow()) { maximumFixedSpan = 0; } table[i] = maximumFixedSpan; if (maximumFixedSpan < Integer.MAX_VALUE) { maximumFixedSpan++; } } return table; } // Helper Code ************************************************************ /** * Computes and returns the sum of integers in the given array of ints. * * @param sizes an array of ints to sum up * @return the sum of ints in the array */ private static int sum(final int[] sizes) { int sum = 0; for (int i = sizes.length - 1; i >= 0; i--) { sum += sizes[i]; } return sum; } private static void invalidateAndRepaint(Container container) { if (container == null) { return; } if (container instanceof JComponent) { ((JComponent) container).revalidate(); } else { container.invalidate(); } container.repaint(); } /** * Checks and answers whether the given component with the specified CellConstraints shall be * taken into account for the layout. * * @param component the component to test * @param cc the component's associated CellConstraints * @return {@code true} if a) {@code component} is visible, or b) {@code component} has no * individual setting and the container-wide settings ignores the visibility, or c) {@code cc} * indicates that this individual component ignores the visibility. */ private boolean takeIntoAccount(Component component, CellConstraints cc) { return component.isVisible() || cc.honorsVisibility == null && !getHonorsVisibility() || Boolean.FALSE.equals(cc.honorsVisibility); } // Measuring Component Sizes ******************************************** /** * An interface that describes how to measure a {@code Component}. Used to abstract from * horizontal and vertical dimensions as well as minimum and preferred sizes. * * @since 1.1 */ public static interface Measure { /** * Computes and returns the size of the given {@code Component}. * * @param component the component to measure * @return the component's size */ int sizeOf(Component component); } /** * An abstract implementation of the {@code Measure} interface that caches component sizes. */ private abstract static class CachingMeasure implements Measure, Serializable { /** * Holds previously requested component sizes. Used to minimize size requests to * subcomponents. */ protected final ComponentSizeCache cache; private CachingMeasure(ComponentSizeCache cache) { this.cache = cache; } } /** * Measures a component by computing its minimum width. */ private static final class MinimumWidthMeasure extends CachingMeasure { private MinimumWidthMeasure(ComponentSizeCache cache) { super(cache); } @Override public int sizeOf(Component c) { return cache.getMinimumSize(c).width; } } /** * Measures a component by computing its minimum height. */ private static final class MinimumHeightMeasure extends CachingMeasure { private MinimumHeightMeasure(ComponentSizeCache cache) { super(cache); } @Override public int sizeOf(Component c) { return cache.getMinimumSize(c).height; } } /** * Measures a component by computing its preferred width. */ private static final class PreferredWidthMeasure extends CachingMeasure { private PreferredWidthMeasure(ComponentSizeCache cache) { super(cache); } @Override public int sizeOf(Component c) { return cache.getPreferredSize(c).width; } } /** * Measures a component by computing its preferred height. */ private static final class PreferredHeightMeasure extends CachingMeasure { private PreferredHeightMeasure(ComponentSizeCache cache) { super(cache); } @Override public int sizeOf(Component c) { return cache.getPreferredSize(c).height; } } // Caching Component Sizes ********************************************** /** * A cache for component minimum and preferred sizes. Used to reduce the requests to determine a * component's size. */ private static final class ComponentSizeCache implements Serializable { /** * Maps components to their minimum sizes. */ private final Map minimumSizes; /** * Maps components to their preferred sizes. */ private final Map preferredSizes; /** * Constructs a {@code ComponentSizeCache}. * * @param initialCapacity the initial cache capacity */ private ComponentSizeCache(int initialCapacity) { minimumSizes = new HashMap(initialCapacity); preferredSizes = new HashMap(initialCapacity); } /** * Invalidates the cache. Clears all stored size information. */ void invalidate() { minimumSizes.clear(); preferredSizes.clear(); } /** * Returns the minimum size for the given component. Tries to look up the value from the * cache; lazily creates the value if it has not been requested before. * * @param component the component to compute the minimum size * @return the component's minimum size */ Dimension getMinimumSize(Component component) { Dimension size = minimumSizes.get(component); if (size == null) { size = component.getMinimumSize(); minimumSizes.put(component, size); } return size; } /** * Returns the preferred size for the given component. Tries to look up the value from the * cache; lazily creates the value if it has not been requested before. * * @param component the component to compute the preferred size * @return the component's preferred size */ Dimension getPreferredSize(Component component) { Dimension size = preferredSizes.get(component); if (size == null) { size = component.getPreferredSize(); preferredSizes.put(component, size); } return size; } void removeEntry(Component component) { minimumSizes.remove(component); preferredSizes.remove(component); } } // Exposing the Layout Information ************************************** /** * Computes and returns the horizontal and vertical grid origins. Performs the same layout * process as {@code #layoutContainer} but does not layout the components.

* * This method has been added only to make it easier to debug the form layout. You must * not call this method directly; It may be removed in a future release or the visibility may be * reduced. * * @param parent the {@code Container} to inspect * @return an object that comprises the grid x and y origins */ public LayoutInfo getLayoutInfo(Container parent) { synchronized (parent.getTreeLock()) { initializeColAndRowComponentLists(); Dimension size = parent.getSize(); Insets insets = parent.getInsets(); int totalWidth = size.width - insets.left - insets.right; int totalHeight = size.height - insets.top - insets.bottom; int[] x = computeGridOrigins(parent, totalWidth, insets.left, colSpecs, colComponents, colGroupIndices, minimumWidthMeasure, preferredWidthMeasure ); int[] y = computeGridOrigins(parent, totalHeight, insets.top, rowSpecs, rowComponents, rowGroupIndices, minimumHeightMeasure, preferredHeightMeasure ); return new LayoutInfo(x, y); } } /** * Stores column and row origins. */ public static final class LayoutInfo { /** * Holds the origins of the columns. */ public final int[] columnOrigins; /** * Holds the origins of the rows. */ public final int[] rowOrigins; private LayoutInfo(int[] xOrigins, int[] yOrigins) { this.columnOrigins = xOrigins; this.rowOrigins = yOrigins; } /** * Returns the layout's horizontal origin, the origin of the first column. * * @return the layout's horizontal origin, the origin of the first column. */ public int getX() { return columnOrigins[0]; } /** * Returns the layout's vertical origin, the origin of the first row. * * @return the layout's vertical origin, the origin of the first row. */ public int getY() { return rowOrigins[0]; } /** * Returns the layout's width, the size between the first and the last column origin. * * @return the layout's width. */ public int getWidth() { return columnOrigins[columnOrigins.length - 1] - columnOrigins[0]; } /** * Returns the layout's height, the size between the first and last row. * * @return the layout's height. */ public int getHeight() { return rowOrigins[rowOrigins.length - 1] - rowOrigins[0]; } } // Helper Code ********************************************************** /** * Creates and returns a deep copy of the given array. Unlike {@code #clone} that performs a * shallow copy, this method copies both array levels. * * @param array the array to clone * @return a deep copy of the given array * * @see Object#clone() */ private static int[][] deepClone(int[][] array) { int[][] result = new int[array.length][]; for (int i = 0; i < result.length; i++) { result[i] = array[i].clone(); } return result; } // Serialization ******************************************************** /** * In addition to the default serialization mechanism this class invalidates the component size * cache. The cache will be populated again after the deserialization. Also, the fields * {@code colComponents} and {@code rowComponents} have been marked as transient to exclude them * from the serialization. */ private void writeObject(ObjectOutputStream out) throws IOException { invalidateCaches(); out.defaultWriteObject(); } // Debug Helper Code **************************************************** /* // Prints the given column widths and row heights. private void printSizes(String title, int[] colWidths, int[] rowHeights) { System.out.println(); System.out.println(title); int totalWidth = 0; System.out.print("Column widths: "); for (int i=0; i < getColumnCount(); i++) { int width = colWidths[i]; totalWidth += width; System.out.print(width + ", "); } System.out.println(" Total=" + totalWidth); int totalHeight = 0; System.out.print("Row heights: "); for (int i=0; i < getRowCount(); i++) { int height = rowHeights[i]; totalHeight += height; System.out.print(height + ", "); } System.out.println(" Total=" + totalHeight); System.out.println(); } */ }





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