net.miginfocom.layout.CC Maven / Gradle / Ivy
package net.miginfocom.layout;
import java.io.*;
import java.util.ArrayList;
/*
* License (BSD):
* ==============
*
* Copyright (c) 2004, Mikael Grev, MiG InfoCom AB. (miglayout (at) miginfocom (dot) com)
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without modification,
* are permitted provided that the following conditions are met:
* Redistributions of source code must retain the above copyright notice, this list
* of conditions and the following disclaimer.
* 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.
* Neither the name of the MiG InfoCom AB 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, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
* OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY
* OF SUCH DAMAGE.
*
* @version 1.0
* @author Mikael Grev, MiG InfoCom AB
* Date: 2006-sep-08
*/
/** A simple value holder for one component's constraint.
*/
public class CC implements Externalizable
{
private static final BoundSize DEF_GAP = BoundSize.NULL_SIZE; // Only used to denote default wrap/newline gap.
static final String[] DOCK_SIDES = {"north", "west", "south", "east"};
// See the getters and setters for information about the properties below.
private int dock = -1;
private UnitValue[] pos = null; // [x1, y1, x2, y2]
private UnitValue[] padding = null; // top, left, bottom, right
private UnitValue[] visualPadding = null; // top, left, bottom, right
private Boolean flowX = null;
private int skip = 0;
private int split = 1;
private int spanX = 1, spanY = 1;
private int cellX = -1, cellY = 0; // If cellX is -1 then cellY is also considered -1. cellY is never negative.
private String tag = null;
private String id = null;
private int hideMode = -1;
private DimConstraint hor = new DimConstraint();
private DimConstraint ver = new DimConstraint();
private BoundSize newline = null;
private BoundSize wrap = null;
private boolean boundsInGrid = true;
private boolean external = false;
private Float pushX = null, pushY = null;
private AnimSpec animSpec = AnimSpec.DEF;
// ***** Tmp cache field
private static final String[] EMPTY_ARR = new String[0];
private transient String[] linkTargets = null;
/** Empty constructor.
*/
public CC()
{
}
String[] getLinkTargets()
{
if (linkTargets == null) {
final ArrayList targets = new ArrayList(2);
if (pos != null) {
for (int i = 0; i < pos.length ; i++)
addLinkTargetIDs(targets, pos[i]);
}
linkTargets = targets.size() == 0 ? EMPTY_ARR : targets.toArray(new String[targets.size()]);
}
return linkTargets;
}
private void addLinkTargetIDs(ArrayList targets, UnitValue uv)
{
if (uv != null) {
String linkId = uv.getLinkTargetId();
if (linkId != null) {
targets.add(linkId);
} else {
for (int i = uv.getSubUnitCount() - 1; i >= 0; i--) {
UnitValue subUv = uv.getSubUnitValue(i);
if (subUv.isLinkedDeep())
addLinkTargetIDs(targets, subUv);
}
}
}
}
// **********************************************************
// Chaining constraint setters
// **********************************************************
/** Specifies that the component should be put in the end group s
and will thus share the same ending
* coordinate as them within the group.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param s A name to associate on the group that should be the same for other rows/columns in the same group.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC endGroupX(String s)
{
hor.setEndGroup(s);
return this;
}
/** Specifies that the component should be put in the size group s
and will thus share the same size
* as them within the group.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param s A name to associate on the group that should be the same for other rows/columns in the same group.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC sizeGroupX(String s)
{
hor.setSizeGroup(s);
return this;
}
/** The minimum size for the component. The value will override any value that is set on the component itself.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param size The size expressed as a UnitValue
. E.g. "100px" or "200mm".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC minWidth(String size)
{
hor.setSize(LayoutUtil.derive(hor.getSize(), ConstraintParser.parseUnitValue(size, true), null, null));
return this;
}
/** The size for the component as a min and/or preferred and/or maximum size. The value will override any value that is set on
* the component itself.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param size The size expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC width(String size)
{
hor.setSize(ConstraintParser.parseBoundSize(size, false, true));
return this;
}
/** The maximum size for the component. The value will override any value that is set on the component itself.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param size The size expressed as a UnitValue
. E.g. "100px" or "200mm".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC maxWidth(String size)
{
hor.setSize(LayoutUtil.derive(hor.getSize(), null, null, ConstraintParser.parseUnitValue(size, true)));
return this;
}
/** The horizontal gap before and/or after the component. The gap is towards cell bounds and/or other component bounds.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param before The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @param after The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC gapX(String before, String after)
{
if (before != null)
hor.setGapBefore(ConstraintParser.parseBoundSize(before, true, true));
if (after != null)
hor.setGapAfter(ConstraintParser.parseBoundSize(after, true, true));
return this;
}
/** Same functionality as getHorizontal().setAlign(ConstraintParser.parseUnitValue(unitValue, true))
only this method
* returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param align The align keyword or for instance "100px". E.g "left", "right", "leading" or "trailing".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC alignX(String align)
{
hor.setAlign(ConstraintParser.parseUnitValueOrAlign(align, true, null));
return this;
}
/**
* Strongly typed API for most common usages
*
* @see #alignX(String)
*
* @param align
* @return this
so it is possible to chain calls.
*/
public final CC alignX(AlignX align) {
return alignX(align == null ? null : align.code());
}
/** The grow priority compared to other components in the same cell.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param p The grow priority.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC growPrioX(int p)
{
hor.setGrowPriority(p);
return this;
}
/** Grow priority for the component horizontally and optionally vertically.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param widthHeight The new shrink weight and height. 1-2 arguments, never null.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC growPrio(int ... widthHeight)
{
switch (widthHeight.length) {
default:
throw new IllegalArgumentException("Illegal argument count: " + widthHeight.length);
case 2:
growPrioY(widthHeight[1]);
case 1:
growPrioX(widthHeight[0]);
}
return this;
}
/** Grow weight for the component horizontally. It default to weight 100
.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #growX(float)
*/
public final CC growX()
{
hor.setGrow(ResizeConstraint.WEIGHT_100);
return this;
}
/** Grow weight for the component horizontally.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param w The new grow weight.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC growX(float w)
{
hor.setGrow(w);
return this;
}
/** grow weight for the component horizontally and optionally vertically.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param widthHeight The new shrink weight and height. 1-2 arguments, never null.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC grow(float ... widthHeight)
{
switch (widthHeight.length) {
default:
throw new IllegalArgumentException("Illegal argument count: " + widthHeight.length);
case 2:
growY(widthHeight[1]);
case 1:
growX(widthHeight[0]);
}
return this;
}
/** The shrink priority compared to other components in the same cell.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param p The shrink priority.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC shrinkPrioX(int p)
{
hor.setShrinkPriority(p);
return this;
}
/** Shrink priority for the component horizontally and optionally vertically.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param widthHeight The new shrink weight and height. 1-2 arguments, never null.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC shrinkPrio(int ... widthHeight)
{
switch (widthHeight.length) {
default:
throw new IllegalArgumentException("Illegal argument count: " + widthHeight.length);
case 2:
shrinkPrioY(widthHeight[1]);
case 1:
shrinkPrioX(widthHeight[0]);
}
return this;
}
/** Shrink weight for the component horizontally.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param w The new shrink weight.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC shrinkX(float w)
{
hor.setShrink(w);
return this;
}
/** Shrink weight for the component horizontally and optionally vertically.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param widthHeight The new shrink weight and height. 1-2 arguments, never null.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC shrink(float ... widthHeight)
{
switch (widthHeight.length) {
default:
throw new IllegalArgumentException("Illegal argument count: " + widthHeight.length);
case 2:
shrinkY(widthHeight[1]);
case 1:
shrinkX(widthHeight[0]);
}
return this;
}
/** The end group that this component should be placed in.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param s The name of the group. If null
that means no group (default)
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC endGroupY(String s)
{
ver.setEndGroup(s);
return this;
}
/** The end group(s) that this component should be placed in.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param xy The end group for x and y respectively. 1-2 arguments, not null.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC endGroup(String ... xy)
{
switch (xy.length) {
default:
throw new IllegalArgumentException("Illegal argument count: " + xy.length);
case 2:
endGroupY(xy[1]);
case 1:
endGroupX(xy[0]);
}
return this;
}
/** The size group that this component should be placed in.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param s The name of the group. If null
that means no group (default)
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC sizeGroupY(String s)
{
ver.setSizeGroup(s);
return this;
}
/** The size group(s) that this component should be placed in.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param xy The size group for x and y respectively. 1-2 arguments, not null.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC sizeGroup(String ... xy)
{
switch (xy.length) {
default:
throw new IllegalArgumentException("Illegal argument count: " + xy.length);
case 2:
sizeGroupY(xy[1]);
case 1:
sizeGroupX(xy[0]);
}
return this;
}
/** The minimum size for the component. The value will override any value that is set on the component itself.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param size The size expressed as a UnitValue
. E.g. "100px" or "200mm".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC minHeight(String size)
{
ver.setSize(LayoutUtil.derive(ver.getSize(), ConstraintParser.parseUnitValue(size, false), null, null));
return this;
}
/** The size for the component as a min and/or preferred and/or maximum size. The value will override any value that is set on
* the component itself.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param size The size expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC height(String size)
{
ver.setSize(ConstraintParser.parseBoundSize(size, false, false));
return this;
}
/** The maximum size for the component. The value will override any value that is set on the component itself.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param size The size expressed as a UnitValue
. E.g. "100px" or "200mm".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC maxHeight(String size)
{
ver.setSize(LayoutUtil.derive(ver.getSize(), null, null, ConstraintParser.parseUnitValue(size, false)));
return this;
}
/** The vertical gap before (normally above) and/or after (normally below) the component. The gap is towards cell bounds and/or other component bounds.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param before The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @param after The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC gapY(String before, String after)
{
if (before != null)
ver.setGapBefore(ConstraintParser.parseBoundSize(before, true, false));
if (after != null)
ver.setGapAfter(ConstraintParser.parseBoundSize(after, true, false));
return this;
}
/** Same functionality as getVertical().setAlign(ConstraintParser.parseUnitValue(unitValue, true))
only this method
* returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param align The align keyword or for instance "100px". E.g "top" or "bottom".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC alignY(String align)
{
ver.setAlign(ConstraintParser.parseUnitValueOrAlign(align, false, null));
return this;
}
/**
* Strongly typed API for most common usages
*
* @see #alignY(String)
*
* @param align
* @return this
so it is possible to chain calls.
*/
public final CC alignY(AlignY align)
{
return alignY(align == null ? null : align.code());
}
/** The grow priority compared to other components in the same cell.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param p The grow priority.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC growPrioY(int p)
{
ver.setGrowPriority(p);
return this;
}
/** Grow weight for the component vertically. Defaults to 100
.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #growY(Float)
*/
public final CC growY()
{
ver.setGrow(ResizeConstraint.WEIGHT_100);
return this;
}
/** Grow weight for the component vertically.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param w The new grow weight.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC growY(float w)
{
ver.setGrow(w);
return this;
}
/** Grow weight for the component vertically.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param w The new grow weight.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
@Deprecated
public final CC growY(Float w)
{
ver.setGrow(w);
return this;
}
/** The shrink priority compared to other components in the same cell.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param p The shrink priority.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC shrinkPrioY(int p)
{
ver.setShrinkPriority(p);
return this;
}
/** Shrink weight for the component horizontally.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param w The new shrink weight.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC shrinkY(float w)
{
ver.setShrink(w);
return this;
}
/** How this component, if hidden (not visible), should be treated.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param mode The mode. Default to the mode in the {@link net.miginfocom.layout.LC}.
* 0 == Normal. Bounds will be calculated as if the component was visible.
* 1 == If hidden the size will be 0, 0 but the gaps remain.
* 2 == If hidden the size will be 0, 0 and gaps set to zero.
* 3 == If hidden the component will be disregarded completely and not take up a cell in the grid..
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC hideMode(int mode)
{
setHideMode(mode);
return this;
}
/** The id used to reference this component in some constraints.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param s The id or null
. May consist of a groupID and an componentID which are separated by a dot: ".". E.g. "grp1.id1".
* The dot should never be first or last if present.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
*/
public final CC id(String s)
{
setId(s);
return this;
}
/** Same functionality as {@link #setTag(String tag)} only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param tag The new tag. May be null
.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setTag(String)
*/
public final CC tag(String tag)
{
setTag(tag);
return this;
}
/** Set the cell(s) that the component should occupy in the grid. Same functionality as {@link #setCellX(int col)} and
* {@link #setCellY(int row)} together with {@link #setSpanX(int width)} and {@link #setSpanY(int height)}. This method
* returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param colRowWidthHeight cellX, cellY, spanX, spanY respectively. 1-4 arguments, not null.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setCellX(int)
* @see #setCellY(int)
* @see #setSpanX(int)
* @see #setSpanY(int)
* @since 3.7.2. Replacing cell(int, int) and cell(int, int, int, int)
*/
public final CC cell(int ... colRowWidthHeight)
{
switch (colRowWidthHeight.length) {
default:
throw new IllegalArgumentException("Illegal argument count: " + colRowWidthHeight.length);
case 4:
setSpanY(colRowWidthHeight[3]);
case 3:
setSpanX(colRowWidthHeight[2]);
case 2:
setCellY(colRowWidthHeight[1]);
case 1:
setCellX(colRowWidthHeight[0]);
}
return this;
}
/** Same functionality as spanX(cellsX).spanY(cellsY)
which means this cell will span cells in both x and y.
* This method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* Since 3.7.2 this takes an array/vararg whereas it previously only took two specific values, xSpan and ySpan.
* @param cells spanX and spanY, when present, and in that order.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setSpanY(int)
* @see #setSpanX(int)
* @see #spanY()
* @see #spanX()
* @since 3.7.2 Replaces span(int, int).
*/
public final CC span(int ... cells)
{
if (cells == null || cells.length == 0) {
setSpanX(LayoutUtil.INF);
setSpanY(1);
} else if (cells.length == 1) {
setSpanX(cells[0]);
setSpanY(1);
} else {
setSpanX(cells[0]);
setSpanY(cells[1]);
}
return this;
}
/** Corresponds exactly to the "gap left right top bottom" keyword.
* @param args Same as for the "gap" keyword. Length 1-4, never null buf elements can be null.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC gap(String ... args)
{
switch (args.length) {
default:
throw new IllegalArgumentException("Illegal argument count: " + args.length);
case 4:
gapBottom(args[3]);
case 3:
gapTop(args[2]);
case 2:
gapRight(args[1]);
case 1:
gapLeft(args[0]);
}
return this;
}
/** Sets the horizontal gap before the component.
*
* Note! This is currently same as gapLeft(). This might change in 4.x.
* @param boundsSize The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC gapBefore(String boundsSize)
{
hor.setGapBefore(ConstraintParser.parseBoundSize(boundsSize, true, true));
return this;
}
/** Sets the horizontal gap after the component.
*
* Note! This is currently same as gapRight(). This might change in 4.x.
* @param boundsSize The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC gapAfter(String boundsSize)
{
hor.setGapAfter(ConstraintParser.parseBoundSize(boundsSize, true, true));
return this;
}
/** Sets the gap above the component.
* @param boundsSize The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC gapTop(String boundsSize)
{
ver.setGapBefore(ConstraintParser.parseBoundSize(boundsSize, true, false));
return this;
}
/** Sets the gap to the left the component.
* @param boundsSize The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC gapLeft(String boundsSize)
{
hor.setGapBefore(ConstraintParser.parseBoundSize(boundsSize, true, true));
return this;
}
/** Sets the gap below the component.
* @param boundsSize The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC gapBottom(String boundsSize)
{
ver.setGapAfter(ConstraintParser.parseBoundSize(boundsSize, true, false));
return this;
}
/** Sets the gap to the right of the component.
* @param boundsSize The size of the gap expressed as a BoundSize
. E.g. "50:100px:200mm" or "100px!".
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @since 3.7.2
*/
public final CC gapRight(String boundsSize)
{
hor.setGapAfter(ConstraintParser.parseBoundSize(boundsSize, true, true));
return this;
}
/** Same functionality as calling {@link #setSpanY(int)} with LayoutUtil.INF
which means this cell will span the rest of the column.
* This method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setSpanY(int)
* @see #spanY()
*/
public final CC spanY()
{
return spanY(LayoutUtil.INF);
}
/** Same functionality as {@link #setSpanY(int)} only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param cells The number of cells to span (i.e. merge).
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setSpanY(int)
*/
public final CC spanY(int cells)
{
setSpanY(cells);
return this;
}
/** Same functionality as {@link #setSpanX(int)} which means this cell will span the rest of the row.
* This method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setSpanX(int)
* @see #spanX()
*/
public final CC spanX()
{
return spanX(LayoutUtil.INF);
}
/** Same functionality as {@link #setSpanX(int)} only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param cells The number of cells to span (i.e. merge).
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setSpanY(int)
*/
public final CC spanX(int cells)
{
setSpanX(cells);
return this;
}
/** Same functionality as pushX().pushY()
which means this cell will push in both x and y dimensions.
* This method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setPushX(Float)
* @see #setPushX(Float)
* @see #pushY()
* @see #pushX()
*/
public final CC push()
{
return pushX().pushY();
}
/** Same functionality as pushX(weightX).pushY(weightY)
which means this cell will push in both x and y dimensions.
* This method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param weightX The weight used in the push.
* @param weightY The weight used in the push.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setPushY(Float)
* @see #setPushX(Float)
* @see #pushY()
* @see #pushX()
*/
public final CC push(Float weightX, Float weightY)
{
return pushX(weightX).pushY(weightY);
}
/** Same functionality as {@link #setPushY(Float)} which means this cell will push the rest of the column.
* This method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setPushY(Float)
*/
public final CC pushY()
{
return pushY(ResizeConstraint.WEIGHT_100);
}
/** Same functionality as {@link #setPushY(Float weight)} only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param weight The weight used in the push.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setPushY(Float)
*/
public final CC pushY(Float weight)
{
setPushY(weight);
return this;
}
/** Same functionality as {@link #setPushX(Float)} which means this cell will push the rest of the row.
* This method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setPushX(Float)
*/
public final CC pushX()
{
return pushX(ResizeConstraint.WEIGHT_100);
}
/** Same functionality as {@link #setPushX(Float weight)} only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param weight The weight used in the push.
* @return this
so it is possible to chain calls. E.g. new LayoutConstraint().noGrid().gap().fill()
.
* @see #setPushY(Float)
*/
public final CC pushX(Float weight)
{
setPushX(weight);
return this;
}
/** Same functionality as {@link #setSplit(int parts)} only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param parts The number of parts (i.e. component slots) the cell should be divided into.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setSplit(int)
*/
public final CC split(int parts)
{
setSplit(parts);
return this;
}
/** Same functionality as split(LayoutUtil.INF), which means split until one of the keywords that breaks the split is found for
* a component after this one (e.g. wrap, newline and skip).
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setSplit(int)
* @since 3.7.2
*/
public final CC split()
{
setSplit(LayoutUtil.INF);
return this;
}
/** Same functionality as {@link #setSkip(int)} only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param cells How many cells in the grid that should be skipped before the component that this constraint belongs to
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setSkip(int)
*/
public final CC skip(int cells)
{
setSkip(cells);
return this;
}
/** Same functionality as skip(1).
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setSkip(int)
* @since 3.7.2
*/
public final CC skip()
{
setSkip(1);
return this;
}
/** Same functionality as calling {@link #setExternal(boolean)} with true
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setExternal(boolean)
*/
public final CC external()
{
setExternal(true);
return this;
}
/** Same functionality as calling {@link #setFlowX(Boolean)} with Boolean.TRUE
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setFlowX(Boolean)
*/
public final CC flowX()
{
setFlowX(Boolean.TRUE);
return this;
}
/** Same functionality as calling {@link #setFlowX(Boolean)} with Boolean.FALSE
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setFlowX(Boolean)
*/
public final CC flowY()
{
setFlowX(Boolean.FALSE);
return this;
}
/** Same functionality as {@link #growX()} and {@link #growY()}.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #growX()
* @see #growY()
*/
public final CC grow()
{
growX();
growY();
return this;
}
/** Same functionality as calling {@link #setNewline(boolean)} with true
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setNewline(boolean)
*/
public final CC newline()
{
setNewline(true);
return this;
}
/** Same functionality as {@link #setNewlineGapSize(BoundSize)} only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param gapSize The gap size that will override the gap size in the row/column constraints if != null
. E.g. "5px" or "unrel".
* If null
or ""
the newline size will be set to the default size and turned on. This is different compared to
* {@link #setNewlineGapSize(BoundSize)}.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setNewlineGapSize(BoundSize)
*/
public final CC newline(String gapSize)
{
BoundSize bs = ConstraintParser.parseBoundSize(gapSize, true, (flowX != null && flowX == false));
if (bs != null) {
setNewlineGapSize(bs);
} else {
setNewline(true);
}
return this;
}
/** Same functionality as calling {@link #setWrap(boolean)} with true
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setWrap(boolean)
*/
public final CC wrap()
{
setWrap(true);
return this;
}
/** Same functionality as {@link #setWrapGapSize(BoundSize)} only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param gapSize The gap size that will override the gap size in the row/column constraints if != null
. E.g. "5px" or "unrel".
* If null
or ""
the wrap size will be set to the default size and turned on. This is different compared to
* {@link #setWrapGapSize(BoundSize)}.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setWrapGapSize(BoundSize)
*/
public final CC wrap(String gapSize)
{
BoundSize bs = ConstraintParser.parseBoundSize(gapSize, true, (flowX != null && flowX == false));
if (bs != null) {
setWrapGapSize(bs);
} else {
setWrap(true);
}
return this;
}
/** Same functionality as calling {@link #setDockSide(int)} with 0
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setDockSide(int)
*/
public final CC dockNorth()
{
setDockSide(0);
return this;
}
/** Same functionality as calling {@link #setDockSide(int)} with 1
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setDockSide(int)
*/
public final CC dockWest()
{
setDockSide(1);
return this;
}
/** Same functionality as calling {@link #setDockSide(int)} with 2
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setDockSide(int)
*/
public final CC dockSouth()
{
setDockSide(2);
return this;
}
/** Same functionality as calling {@link #setDockSide(int)} with 3
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setDockSide(int)
*/
public final CC dockEast()
{
setDockSide(3);
return this;
}
/** Sets the x-coordinate for the component. This is used to set the x coordinate position to a specific value. The component
* bounds is still precalculated to the grid cell and this method should be seen as a way to correct the x position.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param x The x position as a UnitValue. E.g. "10" or "40mm" or "container.x+10".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setPos(UnitValue[])
* @see #setBoundsInGrid(boolean)
*/
public final CC x(String x)
{
return corrPos(x, 0);
}
/** Sets the y-coordinate for the component. This is used to set the y coordinate position to a specific value. The component
* bounds is still precalculated to the grid cell and this method should be seen as a way to correct the y position.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param y The y position as a UnitValue. E.g. "10" or "40mm" or "container.x+10".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setPos(UnitValue[])
* @see #setBoundsInGrid(boolean)
*/
public final CC y(String y)
{
return corrPos(y, 1);
}
/** Sets the x2-coordinate for the component (right side). This is used to set the x2 coordinate position to a specific value. The component
* bounds is still precalculated to the grid cell and this method should be seen as a way to correct the x position.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param x2 The x2 side's position as a UnitValue. E.g. "10" or "40mm" or "container.x2 - 10".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setPos(UnitValue[])
* @see #setBoundsInGrid(boolean)
*/
public final CC x2(String x2)
{
return corrPos(x2, 2);
}
/** Sets the y2-coordinate for the component (bottom side). This is used to set the y2 coordinate position to a specific value. The component
* bounds is still precalculated to the grid cell and this method should be seen as a way to correct the y position.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param y2 The y2 side's position as a UnitValue. E.g. "10" or "40mm" or "container.x2 - 10".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setPos(UnitValue[])
* @see #setBoundsInGrid(boolean)
*/
public final CC y2(String y2)
{
return corrPos(y2, 3);
}
private final CC corrPos(String uv, int ix)
{
UnitValue[] b = getPos();
if (b == null)
b = new UnitValue[4];
b[ix] = ConstraintParser.parseUnitValue(uv, (ix % 2 == 0));
setPos(b);
setBoundsInGrid(true);
return this;
}
/** Same functionality as {@link #x(String x)} and {@link #y(String y)} together.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param x The x position as a UnitValue. E.g. "10" or "40mm" or "container.x+10".
* @param y The y position as a UnitValue. E.g. "10" or "40mm" or "container.x+10".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setPos(UnitValue[])
*/
public final CC pos(String x, String y)
{
UnitValue[] b = getPos();
if (b == null)
b = new UnitValue[4];
b[0] = ConstraintParser.parseUnitValue(x, true);
b[1] = ConstraintParser.parseUnitValue(y, false);
setPos(b);
setBoundsInGrid(false);
return this;
}
/** Same functionality as {@link #x(String x)}, {@link #y(String y)}, {@link #y2(String y)} and {@link #y2(String y)} together.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param x The x position as a UnitValue. E.g. "10" or "40mm" or "container.x+10".
* @param y The y position as a UnitValue. E.g. "10" or "40mm" or "container.x+10".
* @param x2 The x2 side's position as a UnitValue. E.g. "10" or "40mm" or "container.x2 - 10".
* @param y2 The y2 side's position as a UnitValue. E.g. "10" or "40mm" or "container.x2 - 10".
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setPos(UnitValue[])
*/
public final CC pos(String x, String y, String x2, String y2)
{
setPos(new UnitValue[] {
ConstraintParser.parseUnitValue(x, true),
ConstraintParser.parseUnitValue(y, false),
ConstraintParser.parseUnitValue(x2, true),
ConstraintParser.parseUnitValue(y2, false),
});
setBoundsInGrid(false);
return this;
}
/** Same functionality as {@link #setPadding(UnitValue[])} but the unit values as absolute pixels. This method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param top The top padding that will be added to the y coordinate at the last stage in the layout.
* @param left The top padding that will be added to the x coordinate at the last stage in the layout.
* @param bottom The top padding that will be added to the y2 coordinate at the last stage in the layout.
* @param right The top padding that will be added to the x2 coordinate at the last stage in the layout.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setTag(String)
*/
public final CC pad(int top, int left, int bottom, int right)
{
setPadding(new UnitValue[] {
new UnitValue(top), new UnitValue(left), new UnitValue(bottom), new UnitValue(right)
});
return this;
}
/** Same functionality as setPadding(ConstraintParser.parseInsets(pad, false))}
only this method returns this
for chaining multiple calls.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param pad The string to parse. E.g. "10 10 10 10" or "20". If less than 4 groups the last will be used for the missing.
* @return this
so it is possible to chain calls. E.g. new ComponentConstraint().noGrid().gap().fill()
.
* @see #setTag(String)
*/
public final CC pad(String pad)
{
setPadding(pad != null ? ConstraintParser.parseInsets(pad, false) : null);
return this;
}
// **********************************************************
// Bean properties
// **********************************************************
/** Returns the horizontal dimension constraint for this component constraint. It has constraints for the horizontal size
* and grow/shrink priorities and weights.
*
* Note! If any changes is to be made it must be made direct when the object is returned. It is not allowed to save the
* constraint for later use.
* @return The current dimension constraint. Never null
.
*/
public DimConstraint getHorizontal()
{
return hor;
}
/** Sets the horizontal dimension constraint for this component constraint. It has constraints for the horizontal size
* and grow/shrink priorities and weights.
* @param h The new dimension constraint. If null
it will be reset to new DimConstraint();
*/
public void setHorizontal(DimConstraint h)
{
hor = h != null ? h : new DimConstraint();
}
/** Returns the vertical dimension constraint for this component constraint. It has constraints for the vertical size
* and grow/shrink priorities and weights.
*
* Note! If any changes is to be made it must be made direct when the object is returned. It is not allowed to save the
* constraint for later use.
* @return The current dimension constraint. Never null
.
*/
public DimConstraint getVertical()
{
return ver;
}
/** Sets the vertical dimension constraint for this component constraint. It has constraints for the vertical size
* and grow/shrink priorities and weights.
* @param v The new dimension constraint. If null
it will be reset to new DimConstraint();
*/
public void setVertical(DimConstraint v)
{
ver = v != null ? v : new DimConstraint();
}
/** Returns the vertical or horizontal dim constraint.
*
* Note! If any changes is to be made it must be made direct when the object is returned. It is not allowed to save the
* constraint for later use.
* @param isHor If the horizontal constraint should be returned.
* @return The dim constraint. Never null
.
*/
public DimConstraint getDimConstraint(boolean isHor)
{
return isHor ? hor : ver;
}
/** Returns the absolute positioning of one or more of the edges. This will be applied last in the layout cycle and will not
* affect the flow or grid positions. The positioning is relative to the parent and can not (as padding) be used
* to adjust the edges relative to the old value. May be null
and elements may be null
.
* null
value(s) for the x2 and y2 will be interpreted as to keep the preferred size and thus the x1
* and x2 will just absolutely positions the component.
*
* Note that {@link #setBoundsInGrid(boolean)} changes the interpretation of this property slightly.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value as a new array, free to modify.
*/
public UnitValue[] getPos()
{
return pos != null ? new UnitValue[] {pos[0], pos[1], pos[2], pos[3]} : null;
}
/** Sets absolute positioning of one or more of the edges. This will be applied last in the layout cycle and will not
* affect the flow or grid positions. The positioning is relative to the parent and can not (as padding) be used
* to adjust the edges relative to the old value. May be null
and elements may be null
.
* null
value(s) for the x2 and y2 will be interpreted as to keep the preferred size and thus the x1
* and x2 will just absolutely positions the component.
*
* Note that {@link #setBoundsInGrid(boolean)} changes the interpretation of this property slightly.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param pos UnitValue[] {x, y, x2, y2}
. Must be null
or of length 4. Elements can be null
.
*/
public void setPos(UnitValue[] pos)
{
this.pos = pos != null ? new UnitValue[] {pos[0], pos[1], pos[2], pos[3]} : null;
linkTargets = null;
}
/** Returns if the absolute pos
value should be corrections to the component that is in a normal cell. If false
* the value of pos
is truly absolute in that it will not affect the grid or have a default bounds in the grid.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
* @see #getPos()
*/
public boolean isBoundsInGrid()
{
return boundsInGrid;
}
/** Sets if the absolute pos
value should be corrections to the component that is in a normal cell. If false
* the value of pos
is truly absolute in that it will not affect the grid or have a default bounds in the grid.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param b true
for bounds taken from the grid position. false
is default.
* @see #setPos(UnitValue[])
*/
public void setBoundsInGrid(boolean b)
{
this.boundsInGrid = b;
}
/** Returns the absolute cell position in the grid or -1
if cell positioning is not used.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
*/
public int getCellX()
{
return cellX;
}
/** Set an absolute cell x-position in the grid. If >= 0 this point points to the absolute cell that this constaint's component should occupy.
* If there's already a component in that cell they will split the cell. The flow will then continue after this cell.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param x The x-position or -1
to disable cell positioning.
*/
public void setCellX(int x)
{
cellX = x;
}
/** Returns the absolute cell position in the grid or -1
if cell positioning is not used.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
*/
public int getCellY()
{
return cellX < 0 ? -1 : cellY;
}
/** Set an absolute cell x-position in the grid. If >= 0 this point points to the absolute cell that this constaint's component should occupy.
* If there's already a component in that cell they will split the cell. The flow will then continue after this cell.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param y The y-position or -1
to disable cell positioning.
*/
public void setCellY(int y)
{
if (y < 0)
cellX = -1;
cellY = Math.max(y, 0);
}
/** Sets the docking side. -1 means no docking.
* Valid sides are: north = 0, west = 1, south = 2, east = 3
.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current side.
*/
public int getDockSide()
{
return dock;
}
/** Sets the docking side. -1 means no docking.
* Valid sides are: north = 0, west = 1, south = 2, east = 3
.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param side -1 or 0-3.
*/
public void setDockSide(int side)
{
if (side < -1 || side > 3)
throw new IllegalArgumentException("Illegal dock side: " + side);
dock = side;
}
/** Returns if this component should have its bounds handled by an external source and not this layout manager.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
*/
public boolean isExternal()
{
return external;
}
/** If this boolean is true this component is not handled in any way by the layout manager and the component can have its bounds set by an external
* handler which is normally by the use of some component.setBounds(x, y, width, height)
directly (for Swing).
*
* The bounds will not affect the minimum and preferred size of the container.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param b true
means that the bounds are not changed.
*/
public void setExternal(boolean b)
{
this.external = b;
}
/** Returns if the flow in the cell is in the horizontal dimension. Vertical if false
. Only the first
* component is a cell can set the flow.
*
* If null
the flow direction is inherited by from the {@link net.miginfocom.layout.LC}.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
*/
public Boolean getFlowX()
{
return flowX;
}
/** Sets if the flow in the cell is in the horizontal dimension. Vertical if false
. Only the first
* component is a cell can set the flow.
*
* If null
the flow direction is inherited by from the {@link net.miginfocom.layout.LC}.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param b Boolean.TRUE
means horizontal flow in the cell.
*/
public void setFlowX(Boolean b)
{
this.flowX = b;
}
/** Sets how a component that is hidden (not visible) should be treated by default.
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The mode:
* 0 == Normal. Bounds will be calculated as if the component was visible.
* 1 == If hidden the size will be 0, 0 but the gaps remain.
* 2 == If hidden the size will be 0, 0 and gaps set to zero.
* 3 == If hidden the component will be disregarded completely and not take up a cell in the grid..
*/
public int getHideMode()
{
return hideMode;
}
/** Sets how a component that is hidden (not visible) should be treated by default.
* @param mode The mode:
* 0 == Normal. Bounds will be calculated as if the component was visible.
* 1 == If hidden the size will be 0, 0 but the gaps remain.
* 2 == If hidden the size will be 0, 0 and gaps set to zero.
* 3 == If hidden the component will be disregarded completely and not take up a cell in the grid..
*/
public void setHideMode(int mode)
{
if (mode < -1 || mode > 3)
throw new IllegalArgumentException("Wrong hideMode: " + mode);
hideMode = mode;
}
/** Returns the id used to reference this component in some constraints.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The id or null
. May consist of a groupID and an componentID which are separated by a dot: ".". E.g. "grp1.id1".
* The dot should never be first or last if present.
*/
public String getId()
{
return id;
}
/** Sets the id used to reference this component in some constraints.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param id The id or null
. May consist of a groupID and an componentID which are separated by a dot: ".". E.g. "grp1.id1".
* The dot should never be first or last if present.
*/
public void setId(String id)
{
this.id = id;
}
/** Returns the absolute resizing in the last stage of the layout cycle. May be null
and elements may be null
.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value. null
or of length 4.
*/
public UnitValue[] getPadding()
{
return padding != null ? new UnitValue[] {padding[0], padding[1], padding[2], padding[3]} : null;
}
/** Sets the absolute resizing in the last stage of the layout cycle. These values are added to the edges and can thus for
* instance be used to grow or reduce the size or move the component an absolute number of pixels. May be null
* and elements may be null
.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param sides top, left, bottom right. Must be null
or of length 4.
*/
public void setPadding(UnitValue[] sides)
{
this.padding = sides != null ? new UnitValue[] {sides[0], sides[1], sides[2], sides[3]} : null;
}
/** Returns the visual padding used when laying out this Component. May be null
and elements may be null
.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value. null
or of length 4.
*/
public UnitValue[] getVisualPadding()
{
return visualPadding != null ? new UnitValue[] {visualPadding[0], visualPadding[1], visualPadding[2], visualPadding[3]} : null;
}
/** Sets the visual padding used when laying out this Component.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param sides top, left, bottom right. Must be null
or of length 4.
*/
public void setVisualPadding(UnitValue[] sides)
{
this.visualPadding = sides != null ? new UnitValue[] {sides[0], sides[1], sides[2], sides[3]} : null;
}
/** Returns how many cells in the grid that should be skipped before the component that this constraint belongs to.
*
* Note that only the first component will be checked for this property.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value. 0 if no skip.
*/
public int getSkip()
{
return skip;
}
/** Sets how many cells in the grid that should be skipped before the component that this constraint belongs to.
*
* Note that only the first component will be checked for this property.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param cells How many cells in the grid that should be skipped before the component that this constraint belongs to
*/
public void setSkip(int cells)
{
this.skip = cells;
}
/** Returns the number of cells the cell that this constraint's component will span in the indicated dimension. 1
is default and
* means that it only spans the current cell. LayoutUtil.INF
is used to indicate a span to the end of the column/row.
*
* Note that only the first component will be checked for this property.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
*/
public int getSpanX()
{
return spanX;
}
/** Sets the number of cells the cell that this constraint's component will span in the indicated dimension. 1
is default and
* means that it only spans the current cell. LayoutUtil.INF
is used to indicate a span to the end of the column/row.
*
* Note that only the first component will be checked for this property.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param cells The number of cells to span (i.e. merge).
*/
public void setSpanX(int cells)
{
this.spanX = cells;
}
/** Returns the number of cells the cell that this constraint's component will span in the indicated dimension. 1
is default and
* means that it only spans the current cell. LayoutUtil.INF
is used to indicate a span to the end of the column/row.
*
* Note that only the first component will be checked for this property.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
*/
public int getSpanY()
{
return spanY;
}
/** Sets the number of cells the cell that this constraint's component will span in the indicated dimension. 1
is default and
* means that it only spans the current cell. LayoutUtil.INF
is used to indicate a span to the end of the column/row.
*
* Note that only the first component will be checked for this property.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param cells The number of cells to span (i.e. merge).
*/
public void setSpanY(int cells)
{
this.spanY = cells;
}
/** "pushx" indicates that the column that this component is in (this first if the component spans) should default to growing.
* If any other column has been set to grow this push value on the component does nothing as the column's explicit grow weight
* will take precedence. Push is normally used when the grid has not been defined in the layout.
*
* If multiple components in a column has push weights set the largest one will be used for the column.
* @return The current push value. Default is null
.
*/
public Float getPushX()
{
return pushX;
}
/** "pushx" indicates that the column that this component is in (this first if the component spans) should default to growing.
* If any other column has been set to grow this push value on the component does nothing as the column's explicit grow weight
* will take precedence. Push is normally used when the grid has not been defined in the layout.
*
* If multiple components in a column has push weights set the largest one will be used for the column.
* @param weight The new push value. Default is null
.
*/
public void setPushX(Float weight)
{
this.pushX = weight;
}
/** "pushx" indicates that the row that this component is in (this first if the component spans) should default to growing.
* If any other row has been set to grow this push value on the component does nothing as the row's explicit grow weight
* will take precedence. Push is normally used when the grid has not been defined in the layout.
*
* If multiple components in a row has push weights set the largest one will be used for the row.
* @return The current push value. Default is null
.
*/
public Float getPushY()
{
return pushY;
}
/** "pushx" indicates that the row that this component is in (this first if the component spans) should default to growing.
* If any other row has been set to grow this push value on the component does nothing as the row's explicit grow weight
* will take precedence. Push is normally used when the grid has not been defined in the layout.
*
* If multiple components in a row has push weights set the largest one will be used for the row.
* @param weight The new push value. Default is null
.
*/
public void setPushY(Float weight)
{
this.pushY = weight;
}
/** Returns in how many parts the current cell (that this constraint's component will be in) should be split in. If for instance
* it is split in two, the next component will also share the same cell. Note that the cell can also span a number of
* cells, which means that you can for instance span three cells and split that big cell for two components. Split can be
* set to a very high value to make all components in the same row/column share the same cell (e.g. LayoutUtil.INF
).
*
* Note that only the first component will be checked for this property.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
*/
public int getSplit()
{
return split;
}
/** Sets in how many parts the current cell (that this constraint's component will be in) should be split in. If for instance
* it is split in two, the next component will also share the same cell. Note that the cell can also span a number of
* cells, which means that you can for instance span three cells and split that big cell for two components. Split can be
* set to a very high value to make all components in the same row/column share the same cell (e.g. LayoutUtil.INF
).
*
* Note that only the first component will be checked for this property.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param parts The number of parts (i.e. component slots) the cell should be divided into.
*/
public void setSplit(int parts)
{
this.split = parts;
}
/** Tags the component with metadata. Currently only used to tag buttons with for instance "cancel" or "ok" to make them
* show up in the correct order depending on platform. See {@link PlatformDefaults#setButtonOrder(String)} for information.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value. May be null
.
*/
public String getTag()
{
return tag;
}
/** Optional tag that gives more context to this constraint's component. It is for instance used to tag buttons in a
* button bar with the button type such as "ok", "help" or "cancel".
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param tag The new tag. May be null
.
*/
public void setTag(String tag)
{
this.tag = tag;
}
/** Returns if the flow should wrap to the next line/column after the component that this constraint belongs to.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
*/
public boolean isWrap()
{
return wrap != null;
}
/** Sets if the flow should wrap to the next line/column after the component that this constraint belongs to.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param b true
means wrap after.
*/
public void setWrap(boolean b)
{
wrap = b ? (wrap == null ? DEF_GAP : wrap) : null;
}
/** Returns the wrap size if it is a custom size. If wrap was set to true with {@link #setWrap(boolean)} then this method will
* return null
since that means that the gap size should be the default one as defined in the rows spec.
* @return The custom gap size. NOTE! Will return null
for both no wrap and default wrap.
* @see #isWrap()
* @see #setWrap(boolean)
* @since 2.4.2
*/
public BoundSize getWrapGapSize()
{
return wrap == DEF_GAP ? null : wrap;
}
/** Set the wrap size and turns wrap on if != null
.
* @param s The custom gap size. NOTE! null
will not turn on or off wrap, it will only set the wrap gap size to "default".
* A non-null value will turn on wrap though.
* @see #isWrap()
* @see #setWrap(boolean)
* @since 2.4.2
*/
public void setWrapGapSize(BoundSize s)
{
wrap = s == null ? (wrap != null ? DEF_GAP : null) : s;
}
/** Returns if the flow should wrap to the next line/column before the component that this constraint belongs to.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return The current value.
*/
public boolean isNewline()
{
return newline != null;
}
/** Sets if the flow should wrap to the next line/column before the component that this constraint belongs to.
*
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param b true
means wrap before.
*/
public void setNewline(boolean b)
{
newline = b ? (newline == null ? DEF_GAP : newline) : null;
}
/** Returns the newline size if it is a custom size. If newline was set to true with {@link #setNewline(boolean)} then this method will
* return null
since that means that the gap size should be the default one as defined in the rows spec.
* @return The custom gap size. NOTE! Will return null
for both no newline and default newline.
* @see #isNewline()
* @see #setNewline(boolean)
* @since 2.4.2
*/
public BoundSize getNewlineGapSize()
{
return newline == DEF_GAP ? null : newline;
}
/** Set the newline size and turns newline on if != null
.
* @param s The custom gap size. NOTE! null
will not turn on or off newline, it will only set the newline gap size to "default".
* A non-null value will turn on newline though.
* @see #isNewline()
* @see #setNewline(boolean)
* @since 2.4.2
*/
public void setNewlineGapSize(BoundSize s)
{
newline = s == null ? (newline != null ? DEF_GAP : null) : s;
}
/** Returns the animation spec. Default is a spec where animation is off (prio 0).
* @return Never null.
*/
public AnimSpec getAnimSpec()
{
return animSpec;
}
// ************************************************
// Persistence Delegate and Serializable combined.
// ************************************************
private Object readResolve() throws ObjectStreamException
{
return LayoutUtil.getSerializedObject(this);
}
@Override
public void readExternal(ObjectInput in) throws IOException, ClassNotFoundException
{
LayoutUtil.setSerializedObject(this, LayoutUtil.readAsXML(in));
}
@Override
public void writeExternal(ObjectOutput out) throws IOException
{
if (getClass() == CC.class)
LayoutUtil.writeAsXML(out, this);
}
}