package net.miginfocom.layout;
import java.io.*;
/*
* 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
*/
/** Contains the constraints for an instance of the {@link LC} layout manager.
*/
public final class LC implements Externalizable
{
// See the corresponding set/get method for documentation of the property!
private int wrapAfter = LayoutUtil.INF;
private Boolean leftToRight = null;
private UnitValue[] insets = null; // Never null elememts but if unset array is null
private UnitValue alignX = null, alignY = null;
private BoundSize gridGapX = null, gridGapY = null;
private BoundSize width = BoundSize.NULL_SIZE, height = BoundSize.NULL_SIZE;
private BoundSize packW = BoundSize.NULL_SIZE, packH = BoundSize.NULL_SIZE;
private float pwAlign = 0.5f, phAlign = 1.0f;
private int debugMillis = 0;
private int hideMode = 0;
private boolean noCache = false;
private boolean flowX = true;
private boolean fillX = false, fillY = false;
private boolean topToBottom = true;
private boolean noGrid = false;
private boolean visualPadding = true;
/** Empty constructor.
*/
public LC()
{
}
// ************************************************************************
// * JavaBean get/set methods.
// ************************************************************************
/** If components have sizes or positions linked to the bounds of the parent in some way (as for instance the <code>"%"</code> unit has) the cache
* must be turned off for the panel. If components does not get the correct or expected size or position try to set this property to <code>true</code>.
* @return <code>true</code> means no cache and slightly slower layout.
*/
public boolean isNoCache()
{
return noCache;
}
/** If components have sizes or positions linked to the bounds of the parent in some way (as for instance the <code>"%"</code> unit has) the cache
* must be turned off for the panel. If components does not get the correct or expected size or position try to set this property to <code>true</code>.
* @param b <code>true</code> means no cache and slightly slower layout.
*/
public void setNoCache(boolean b)
{
this.noCache = b;
}
/** If the laid out components' bounds in total is less than the final size of the container these align values will be used to align the components
* in the parent. <code>null</code> is default and that means top/left alignment. The relative distances between the components will not be affected
* by this property.
* @return The current alignment.
*/
public final UnitValue getAlignX()
{
return alignX;
}
/** If the laid out components' bounds in total is less than the final size of the container these align values will be used to align the components
* in the parent. <code>null</code> is default and that means top/left alignment. The relative distances between the components will not be affected
* by this property.
* @param uv The new alignment. Use {@link ConstraintParser#parseAlignKeywords(String, boolean)} to create the {@link UnitValue}. May be <code>null</code>.
*/
public final void setAlignX(UnitValue uv)
{
this.alignX = uv;
}
/** If the laid out components' bounds in total is less than the final size of the container these align values will be used to align the components
* in the parent. <code>null</code> is default and that means top/left alignment. The relative distances between the components will not be affected
* by this property.
* @return The current alignment.
*/
public final UnitValue getAlignY()
{
return alignY;
}
/** If the laid out components' bounds in total is less than the final size of the container these align values will be used to align the components
* in the parent. <code>null</code> is default and that means top/left alignment. The relative distances between the components will not be affected
* by this property.
* @param uv The new alignment. Use {@link ConstraintParser#parseAlignKeywords(String, boolean)} to create the {@link UnitValue}. May be <code>null</code>.
*/
public final void setAlignY(UnitValue uv)
{
this.alignY = uv;
}
/** If <code>> 0</code> the debug decorations will be repainted every <code>millis</code>. No debug information if <code><= 0</code> (default).
* @return The current debug repaint interval.
*/
public final int getDebugMillis()
{
return debugMillis;
}
/** If <code>> 0</code> the debug decorations will be repainted every <code>millis</code>. No debug information if <code><= 0</code> (default).
* @param millis The new debug repaint interval.
*/
public final void setDebugMillis(int millis)
{
this.debugMillis = millis;
}
/** If the layout should always claim the whole bounds of the laid out container even if the preferred size is smaller.
* @return <code>true</code> means fill. <code>false</code> is default.
*/
public final boolean isFillX()
{
return fillX;
}
/** If the layout should always claim the whole bounds of the laid out container even if the preferred size is smaller.
* @param b <code>true</code> means fill. <code>false</code> is default.
*/
public final void setFillX(boolean b)
{
this.fillX = b;
}
/** If the layout should always claim the whole bounds of the laid out container even if the preferred size is smaller.
* @return <code>true</code> means fill. <code>false</code> is default.
*/
public final boolean isFillY()
{
return fillY;
}
/** If the layout should always claim the whole bounds of the laid out container even if the preferred size is smaller.
* @param b <code>true</code> means fill. <code>false</code> is default.
*/
public final void setFillY(boolean b)
{
this.fillY = b;
}
/** The default flow direction. Normally (which is <code>true</code>) this is horizontal and that means that the "next" component
* will be put in the cell to the right (or to the left if left-to-right is false).
* @return <code>true</code> is the default flow horizontally.
* @see #setLeftToRight(Boolean)
*/
public final boolean isFlowX()
{
return flowX;
}
/** The default flow direction. Normally (which is <code>true</code>) this is horizontal and that means that the "next" component
* will be put in the cell to the right (or to the left if left-to-right is false).
* @param b <code>true</code> is the default flow horizontally.
* @see #setLeftToRight(Boolean)
*/
public final void setFlowX(boolean b)
{
this.flowX = b;
}
/** If non-<code>null</code> (<code>null</code> is default) these value will be used as the default gaps between the columns in the grid.
* @return The default grid gap between columns in the grid. <code>null</code> if the platform default is used.
*/
public final BoundSize getGridGapX()
{
return gridGapX;
}
/** If non-<code>null</code> (<code>null</code> is default) these value will be used as the default gaps between the columns in the grid.
* @param x The default grid gap between columns in the grid. If <code>null</code> the platform default is used.
*/
public final void setGridGapX(BoundSize x)
{
this.gridGapX = x;
}
/** If non-<code>null</code> (<code>null</code> is default) these value will be used as the default gaps between the rows in the grid.
* @return The default grid gap between rows in the grid. <code>null</code> if the platform default is used.
*/
public final BoundSize getGridGapY()
{
return gridGapY;
}
/** If non-<code>null</code> (<code>null</code> is default) these value will be used as the default gaps between the rows in the grid.
* @param y The default grid gap between rows in the grid. If <code>null</code> the platform default is used.
*/
public final void setGridGapY(BoundSize y)
{
this.gridGapY = y;
}
/** How a component that is hidden (not visible) should be treated by default.
* @return The mode:<br>
* 0 == Normal. Bounds will be caclulated as if the component was visible.<br>
* 1 == If hidden the size will be 0, 0 but the gaps remain.<br>
* 2 == If hidden the size will be 0, 0 and gaps set to zero.<br>
* 3 == If hidden the component will be disregarded completely and not take up a cell in the grid..
*/
public final int getHideMode()
{
return hideMode;
}
/** How a component that is hidden (not visible) should be treated.
* @param mode The mode:<br>
* 0 == Normal. Bounds will be caclulated as if the component was visible.<br>
* 1 == If hidden the size will be 0, 0 but the gaps remain.<br>
* 2 == If hidden the size will be 0, 0 and gaps set to zero.<br>
* 3 == If hidden the component will be disregarded completely and not take up a cell in the grid..
*/
public final void setHideMode(int mode)
{
if (mode < 0 || mode > 3)
throw new IllegalArgumentException("Wrong hideMode: " + mode);
this.hideMode = mode;
}
/** The insets for the layed out panel. The insets will be an empty space around the components in the panel. <code>null</code> values
* means that the default panel insets for the platform is used. See {@link PlatformDefaults#setDialogInsets(net.miginfocom.layout.UnitValue, net.miginfocom.layout.UnitValue, net.miginfocom.layout.UnitValue, net.miginfocom.layout.UnitValue)}.
* @return The insets. Of length 4 (top, left, bottom, right) or <code>null</code>. The elements (1 to 4) may be <code>null</code>. The array is a copy and can be used freely.
* @see net.miginfocom.layout.ConstraintParser#parseInsets(String, boolean)
*/
public final UnitValue[] getInsets()
{
return insets != null ? new UnitValue[] {insets[0], insets[1], insets[2], insets[3]} : null;
}
/** The insets for the layed out panel. The insets will be an empty space around the components in the panel. <code>null</code> values
* means that the default panel insets for the platform is used. See {@link PlatformDefaults#setDialogInsets(net.miginfocom.layout.UnitValue, net.miginfocom.layout.UnitValue, net.miginfocom.layout.UnitValue, net.miginfocom.layout.UnitValue)}.
* @param ins The new insets. Must be of length 4 (top, left, bottom, right) or <code>null</code>. The elements (1 to 4) may be <code>null</code> to use
* the platform default for that side. The array is copied for storage.
* @see net.miginfocom.layout.ConstraintParser#parseInsets(String, boolean)
*/
public final void setInsets(UnitValue[] ins)
{
this.insets = ins != null ? new UnitValue[] {ins[0], ins[1], ins[2], ins[3]} : null;
}
/** If the layout should be forced to be left-to-right or right-to-left. A value of <code>null</code> is default and
* means that this will be picked up from the {@link java.util.Locale} that the container being layed out is reporting.
* @return <code>Boolean.TRUE</code> if force left-to-right. <code>Boolean.FALSE</code> if force tight-to-left. <code>null</code>
* for the default "let the current Locale decide".
*/
public final Boolean getLeftToRight()
{
return leftToRight;
}
/** If the layout should be forced to be left-to-right or right-to-left. A value of <code>null</code> is default and
* means that this will be picked up from the {@link java.util.Locale} that the container being layed out is reporting.
* @param b <code>Boolean.TRUE</code> to force left-to-right. <code>Boolean.FALSE</code> to force tight-to-left. <code>null</code>
* for the default "let the current Locale decide".
*/
public final void setLeftToRight(Boolean b)
{
this.leftToRight = b;
}
/** If the whole layout should be non grid based. It is the same as setting the "nogrid" property on every row/column in the grid.
* @return <code>true</code> means not grid based. <code>false</code> is default.
*/
public final boolean isNoGrid()
{
return noGrid;
}
/** If the whole layout should be non grid based. It is the same as setting the "nogrid" property on every row/column in the grid.
* @param b <code>true</code> means no grid. <code>false</code> is default.
*/
public final void setNoGrid(boolean b)
{
this.noGrid = b;
}
/** If the layout should go from the default top-to-bottom in the grid instead of the optinal bottom-to-top.
* @return <code>true</code> for the default top-to-bottom.
*/
public final boolean isTopToBottom()
{
return topToBottom;
}
/** If the layout should go from the default top-to-bottom in the grid instead of the optinal bottom-to-top.
* @param b <code>true</code> for the default top-to-bottom.
*/
public final void setTopToBottom(boolean b)
{
this.topToBottom = b;
}
/** If visual padding should be automatically used and compensated for by this layout instance.
* @return <code>true</code> if visual padding.
*/
public final boolean isVisualPadding()
{
return visualPadding;
}
/** If visual padding should be automatically used and compensated for by this layout instance.
* @param b <code>true</code> turns on visual padding.
*/
public final void setVisualPadding(boolean b)
{
this.visualPadding = b;
}
/** Returns after what cell the grid should always auto wrap.
* @return After what cell the grid should always auto wrap. If <code>0</code> the number of columns/rows in the
* {@link net.miginfocom.layout.AC} is used. <code>LayoutUtil.INF</code> is used for no auto wrap.
*/
public final int getWrapAfter()
{
return wrapAfter;
}
/** Sets after what cell the grid should always auto wrap.
* @param count After what cell the grid should always auto wrap. If <code>0</code> the number of columns/rows in the
* {@link net.miginfocom.layout.AC} is used. <code>LayoutUtil.INF</code> is used for no auto wrap.
*/
public final void setWrapAfter(int count)
{
this.wrapAfter = count;
}
/** Returns the "pack width" for the <b>window</b> that this container is located in. When the size of this container changes
* the size of the window will be corrected to be within this BoundsSize. It can be used to set the minimum and/or maximum size of the window
* as well as the size window should optimally get. This optimal size is normaly its "preferred" size which is why "preferred"
* is the normal value to set here.
* <p>
* ":push" can be appended to the bound size to only push the size bigger and never shrink it if the preferred size gets smaller.
* <p>
* E.g. "pref", "100:pref", "pref:700", "300::700", "pref:push"
* @return The current value. Never <code>null</code>. Check if not set with <code>.isUnset()</code>.
* @since 3.5
*/
public final BoundSize getPackWidth()
{
return packW;
}
/** Sets the "pack width" for the <b>window</b> that this container is located in. When the size of this container changes
* the size of the window will be corrected to be within this BoundsSize. It can be used to set the minimum and/or maximum size of the window
* as well as the size window should optimally get. This optimal size is normaly its "preferred" size which is why "preferred"
* is the normal value to set here.
* <p>
* ":push" can be appended to the bound size to only push the size bigger and never shrink it if the preferred size gets smaller.
* <p>
* E.g. "pref", "100:pref", "pref:700", "300::700", "pref:push"
* @param size The new pack size. If <code>null</code> it will be corrected to an "unset" BoundSize.
* @since 3.5
*/
public final void setPackWidth(BoundSize size)
{
packW = size != null ? size : BoundSize.NULL_SIZE;
}
/** Returns the "pack height" for the <b>window</b> that this container is located in. When the size of this container changes
* the size of the window will be corrected to be within this BoundsSize. It can be used to set the minimum and/or maximum size of the window
* as well as the size window should optimally get. This optimal size is normaly its "preferred" size which is why "preferred"
* is the normal value to set here.
* <p>
* ":push" can be appended to the bound size to only push the size bigger and never shrink it if the preferred size gets smaller.
* <p>
* E.g. "pref", "100:pref", "pref:700", "300::700", "pref:push"
* @return The current value. Never <code>null</code>. Check if not set with <code>.isUnset()</code>.
* @since 3.5
*/
public final BoundSize getPackHeight()
{
return packH;
}
/** Sets the "pack height" for the <b>window</b> that this container is located in. When the size of this container changes
* the size of the window will be corrected to be within this BoundsSize. It can be used to set the minimum and/or maximum size of the window
* as well as the size window should optimally get. This optimal size is normaly its "preferred" size which is why "preferred"
* is the normal value to set here.
* <p>
* ":push" can be appended to the bound size to only push the size bigger and never shrink it if the preferred size gets smaller.
* <p>
* E.g. "pref", "100:pref", "pref:700", "300::700", "pref:push"
* @param size The new pack size. If <code>null</code> it will be corrected to an "unset" BoundSize.
* @since 3.5
*/
public final void setPackHeight(BoundSize size)
{
packH = size != null ? size : BoundSize.NULL_SIZE;
}
/** If there is a resize of the window due to packing (see {@link #setPackHeight(BoundSize)} this value, which is between 0f and 1f,
* decides where the extra/surpurflous size is placed. 0f means that the window will resize so that the upper part moves up and the
* lower side stays in the same place. 0.5f will expand/reduce the window equally upwards and downwards. 1f will do the opposite of 0f
* of course.
* @return The pack alignment. Always between 0f and 1f, inclusive.
* @since 3.5
*/
public final float getPackHeightAlign()
{
return phAlign;
}
/** If there is a resize of the window due to packing (see {@link #setPackHeight(BoundSize)} this value, which is between 0f and 1f,
* decides where the extra/surpurflous size is placed. 0f means that the window will resize so that the upper part moves up and the
* lower side stays in the same place. 0.5f will expand/reduce the window equally upwards and downwards. 1f will do the opposite of 0f
* of course.
* @param align The pack alignment. Always between 0f and 1f, inclusive. Values outside this will be truncated.
* @since 3.5
*/
public final void setPackHeightAlign(float align)
{
phAlign = Math.max(0f, Math.min(1f, align));
}
/** If there is a resize of the window due to packing (see {@link #setPackHeight(BoundSize)} this value, which is between 0f and 1f,
* decides where the extra/surpurflous size is placed. 0f means that the window will resize so that the left part moves left and the
* right side stays in the same place. 0.5f will expand/reduce the window equally to the right and lefts. 1f will do the opposite of 0f
* of course.
* @return The pack alignment. Always between 0f and 1f, inclusive.
* @since 3.5
*/
public final float getPackWidthAlign()
{
return pwAlign;
}
/** If there is a resize of the window due to packing (see {@link #setPackHeight(BoundSize)} this value, which is between 0f and 1f,
* decides where the extra/surpurflous size is placed. 0f means that the window will resize so that the left part moves left and the
* right side stays in the same place. 0.5f will expand/reduce the window equally to the right and lefts. 1f will do the opposite of 0f
* of course.
* @param align The pack alignment. Always between 0f and 1f, inclusive. Values outside this will be truncated.
* @since 3.5
*/
public final void setPackWidthAlign(float align)
{
pwAlign = Math.max(0f, Math.min(1f, align));
}
/** Returns the minimum/preferred/maximum size for the container that this layout constraint is set for. Any of these
* sizes that is not <code>null</code> will be returned directly instead of determining the correspondig size through
* asking the components in this container.
* @return The width for the container that this layout constraint is set for. Not <code>null</code> but
* all sizes can be <code>null</code>.
* @since 3.5
*/
public final BoundSize getWidth()
{
return width;
}
/** Sets the minimum/preferred/maximum size for the container that this layout constraint is set for. Any of these
* sizes that is not <code>null</code> will be returned directly instead of determining the correspondig size through
* asking the components in this container.
* @param size The width for the container that this layout constraint is set for. <code>null</code> is translated to
* a bound size containing only null sizes.
* @since 3.5
*/
public final void setWidth(BoundSize size)
{
this.width = size != null ? size : BoundSize.NULL_SIZE;
}
/** Returns the minimum/preferred/maximum size for the container that this layout constraint is set for. Any of these
* sizes that is not <code>null</code> will be returned directly instead of determining the correspondig size through
* asking the components in this container.
* @return The height for the container that this layout constraint is set for. Not <code>null</code> but
* all sizes can be <code>null</code>.
* @since 3.5
*/
public final BoundSize getHeight()
{
return height;
}
/** Sets the minimum/preferred/maximum size for the container that this layout constraint is set for. Any of these
* sizes that is not <code>null</code> will be returned directly instead of determining the correspondig size through
* asking the components in this container.
* @param size The height for the container that this layout constraint is set for. <code>null</code> is translated to
* a bound size containing only null sizes.
* @since 3.5
*/
public final void setHeight(BoundSize size)
{
this.height = size != null ? size : BoundSize.NULL_SIZE;
}
// ************************************************************************
// * Builder methods.
// ************************************************************************
/** Short for, and thus same as, <code>.pack("pref", "pref")</code>.
* <p>
* Same functionality as {@link #setPackHeight(BoundSize)} and {@link #setPackWidth(net.miginfocom.layout.BoundSize)}
* only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @since 3.5
*/
public final LC pack()
{
return pack("pref", "pref");
}
/** Sets the pack width and height.
* <p>
* Same functionality as {@link #setPackHeight(BoundSize)} and {@link #setPackWidth(net.miginfocom.layout.BoundSize)}
* only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param width The pack width. May be <code>null</code>.
* @param height The pack height. May be <code>null</code>.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @since 3.5
*/
public final LC pack(String width, String height)
{
setPackWidth(width != null ? ConstraintParser.parseBoundSize(width, false, false) : BoundSize.NULL_SIZE);
setPackHeight(height != null ? ConstraintParser.parseBoundSize(height, false, false) : BoundSize.NULL_SIZE);
return this;
}
/** Sets the pack width and height alignment.
* <p>
* Same functionality as {@link #setPackHeightAlign(float)} and {@link #setPackWidthAlign(float)}
* only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param alignX The pack width alignment. 0.5f is default.
* @param alignY The pack height alignment. 0.5f is default.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @since 3.5
*/
public final LC packAlign(float alignX, float alignY)
{
setPackWidthAlign(alignX);
setPackHeightAlign(alignY);
return this;
}
/** Sets a wrap after the number of columns/rows that is defined in the {@link net.miginfocom.layout.AC}.
* <p>
* Same functionality as {@link #setWrapAfter(int 0)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC wrap()
{
setWrapAfter(0);
return this;
}
/** Same functionality as {@link #setWrapAfter(int)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param count After what cell the grid should always auto wrap. If <code>0</code> the number of columns/rows in the
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC wrapAfter(int count)
{
setWrapAfter(count);
return this;
}
/** Same functionality as {@link #setNoCache(boolean true)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC noCache()
{
setNoCache(true);
return this;
}
/** Same functionality as {@link #setFlowX(boolean false)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC flowY()
{
setFlowX(false);
return this;
}
/** Same functionality as {@link #setFlowX(boolean true)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC flowX()
{
setFlowX(true);
return this;
}
/** Same functionality as {@link #setFillX(boolean true)} and {@link #setFillY(boolean true)} conmbined.T his method returns
* <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC fill()
{
setFillX(true);
setFillY(true);
return this;
}
/** Same functionality as {@link #setFillX(boolean true)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC fillX()
{
setFillX(true);
return this;
}
/** Same functionality as {@link #setFillY(boolean true)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC fillY()
{
setFillY(true);
return this;
}
/** Same functionality as {@link #setLeftToRight(Boolean)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param b <code>true</code> for forcing left-to-right. <code>false</code> for forcing right-to-left.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC leftToRight(boolean b)
{
setLeftToRight(b ? Boolean.TRUE : Boolean.FALSE);
return this;
}
/** Same functionality as setLeftToRight(false) only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @since 3.7.2
*/
public final LC rightToLeft()
{
setLeftToRight(Boolean.FALSE);
return this;
}
/** Same functionality as {@link #setTopToBottom(boolean false)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC bottomToTop()
{
setTopToBottom(false);
return this;
}
/** Same functionality as {@link #setTopToBottom(boolean true)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @since 3.7.2
*/
public final LC topToBottom()
{
setTopToBottom(true);
return this;
}
/** Same functionality as {@link #setNoGrid(boolean true)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC noGrid()
{
setNoGrid(true);
return this;
}
/** Same functionality as {@link #setVisualPadding(boolean false)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC noVisualPadding()
{
setVisualPadding(false);
return this;
}
/** Sets the same inset (expressed as a <code>UnitValue</code>, e.g. "10px" or "20mm") all around.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param allSides The unit value to set for all sides. May be <code>null</code> which means that the default panel insets
* for the platform is used.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #setInsets(UnitValue[])
*/
public final LC insetsAll(String allSides)
{
UnitValue insH = ConstraintParser.parseUnitValue(allSides, true);
UnitValue insV = ConstraintParser.parseUnitValue(allSides, false);
insets = new UnitValue[] {insV, insH, insV, insH}; // No setter to avoid copy again
return this;
}
/** Same functionality as <code>setInsets(ConstraintParser.parseInsets(s, true))</code>. This method returns <code>this</code>
* for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param s 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 <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #setInsets(UnitValue[])
*/
public final LC insets(String s)
{
insets = ConstraintParser.parseInsets(s, true);
return this;
}
/** Sets the different insets (expressed as a <code>UnitValue</code>s, e.g. "10px" or "20mm") for the corresponding sides.
* <p>
* 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 inset. E.g. "10px" or "10mm" or "related". May be <code>null</code> in which case the default inset for this
* side for the platform will be used.
* @param left The left inset. E.g. "10px" or "10mm" or "related". May be <code>null</code> in which case the default inset for this
* side for the platform will be used.
* @param bottom The bottom inset. E.g. "10px" or "10mm" or "related". May be <code>null</code> in which case the default inset for this
* side for the platform will be used.
* @param right The right inset. E.g. "10px" or "10mm" or "related". May be <code>null</code> in which case the default inset for this
* side for the platform will be used.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #setInsets(UnitValue[])
*/
public final LC insets(String top, String left, String bottom, String right)
{
insets = new UnitValue[] { // No setter to avoid copy again
ConstraintParser.parseUnitValue(top, false),
ConstraintParser.parseUnitValue(left, true),
ConstraintParser.parseUnitValue(bottom, false),
ConstraintParser.parseUnitValue(right, true)};
return this;
}
/** Same functionality as <code>setAlignX(ConstraintParser.parseUnitValueOrAlign(unitValue, true))</code> only this method returns <code>this</code>
* for chaining multiple calls.
* <p>
* 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 <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #setAlignX(UnitValue)
*/
public final LC alignX(String align)
{
setAlignX(ConstraintParser.parseUnitValueOrAlign(align, true, null));
return this;
}
/** Same functionality as <code>setAlignY(ConstraintParser.parseUnitValueOrAlign(align, false))</code> only this method returns <code>this</code> for chaining multiple calls.
* <p>
* 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 <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #setAlignY(UnitValue)
*/
public final LC alignY(String align)
{
setAlignY(ConstraintParser.parseUnitValueOrAlign(align, false, null));
return this;
}
/** Sets both the alignX and alignY as the same time.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param ax The align keyword or for instance "100px". E.g "left", "right", "leading" or "trailing".
* @param ay The align keyword or for instance "100px". E.g "top" or "bottom".
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #alignX(String)
* @see #alignY(String)
*/
public final LC align(String ax, String ay)
{
if (ax != null)
alignX(ax);
if (ay != null)
alignY(ay);
return this;
}
/** Same functionality as <code>setGridGapX(ConstraintParser.parseBoundSize(boundsSize, true, true))</code> only this method
* returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param boundsSize The <code>BoundSize</code> of the gap. This is a minimum and/or preferred and/or maximum size. E.g.
* <code>"50:100:200"</code> or <code>"100px"</code>.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #setGridGapX(BoundSize)
*/
public final LC gridGapX(String boundsSize)
{
setGridGapX(ConstraintParser.parseBoundSize(boundsSize, true, true));
return this;
}
/** Same functionality as <code>setGridGapY(ConstraintParser.parseBoundSize(boundsSize, true, false))</code> only this method
* returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param boundsSize The <code>BoundSize</code> of the gap. This is a minimum and/or preferred and/or maximum size. E.g.
* <code>"50:100:200"</code> or <code>"100px"</code>.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #setGridGapY(BoundSize)
*/
public final LC gridGapY(String boundsSize)
{
setGridGapY(ConstraintParser.parseBoundSize(boundsSize, true, false));
return this;
}
/** Sets both grid gaps at the same time. see {@link #gridGapX(String)} and {@link #gridGapY(String)}.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param gapx The <code>BoundSize</code> of the gap. This is a minimum and/or preferred and/or maximum size. E.g.
* <code>"50:100:200"</code> or <code>"100px"</code>.
* @param gapy The <code>BoundSize</code> of the gap. This is a minimum and/or preferred and/or maximum size. E.g.
* <code>"50:100:200"</code> or <code>"100px"</code>.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #gridGapX(String)
* @see #gridGapY(String)
*/
public final LC gridGap(String gapx, String gapy)
{
if (gapx != null)
gridGapX(gapx);
if (gapy != null)
gridGapY(gapy);
return this;
}
/** Same functionality as {@link #setDebugMillis(int repaintMillis)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcomponents.com.
* @param repaintMillis The new debug repaint interval.
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #setDebugMillis(int)
*/
public final LC debug(int repaintMillis)
{
setDebugMillis(repaintMillis);
return this;
}
/** Same functionality as {@link #setHideMode(int mode)} only this method returns <code>this</code> for chaining multiple calls.
* <p>
* 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:<br>
* 0 == Normal. Bounds will be calculated as if the component was visible.<br>
* 1 == If hidden the size will be 0, 0 but the gaps remain.<br>
* 2 == If hidden the size will be 0, 0 and gaps set to zero.<br>
* 3 == If hidden the component will be disregarded completely and not take up a cell in the grid..
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
* @see #setHideMode(int)
*/
public final LC hideMode(int mode)
{
setHideMode(mode);
return this;
}
/** The minimum width for the container. The value will override any value that is set on the container itself.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or Cheat Sheet at www.migcontainers.com.
* @param width The width expressed as a <code>UnitValue</code>. E.g. "100px" or "200mm".
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC minWidth(String width)
{
setWidth(LayoutUtil.derive(getWidth(), ConstraintParser.parseUnitValue(width, true), null, null));
return this;
}
/** The width for the container as a min and/or preferred and/or maximum width. The value will override any value that is set on
* the container itself.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or Cheat Sheet at www.migcontainers.com.
* @param width The width expressed as a <code>BoundSize</code>. E.g. "50:100px:200mm" or "100px".
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC width(String width)
{
setWidth(ConstraintParser.parseBoundSize(width, false, true));
return this;
}
/** The maximum width for the container. The value will override any value that is set on the container itself.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or Cheat Sheet at www.migcontainers.com.
* @param width The width expressed as a <code>UnitValue</code>. E.g. "100px" or "200mm".
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC maxWidth(String width)
{
setWidth(LayoutUtil.derive(getWidth(), null, null, ConstraintParser.parseUnitValue(width, true)));
return this;
}
/** The minimum height for the container. The value will override any value that is set on the container itself.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or Cheat Sheet at www.migcontainers.com.
* @param height The height expressed as a <code>UnitValue</code>. E.g. "100px" or "200mm".
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC minHeight(String height)
{
setHeight(LayoutUtil.derive(getHeight(), ConstraintParser.parseUnitValue(height, false), null, null));
return this;
}
/** The height for the container as a min and/or preferred and/or maximum height. The value will override any value that is set on
* the container itself.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcontainers.com.
* @param height The height expressed as a <code>BoundSize</code>. E.g. "50:100px:200mm" or "100px".
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC height(String height)
{
setHeight(ConstraintParser.parseBoundSize(height, false, false));
return this;
}
/** The maximum height for the container. The value will override any value that is set on the container itself.
* <p>
* For a more thorough explanation of what this constraint does see the white paper or cheat Sheet at www.migcontainers.com.
* @param height The height expressed as a <code>UnitValue</code>. E.g. "100px" or "200mm".
* @return <code>this</code> so it is possible to chain calls. E.g. <code>new LayoutConstraint().noGrid().gap().fill()</code>.
*/
public final LC maxHeight(String height)
{
setHeight(LayoutUtil.derive(getHeight(), null, null, ConstraintParser.parseUnitValue(height, false)));
return this;
}
// ************************************************
// Persistence Delegate and Serializable combined.
// ************************************************
private Object readResolve() throws ObjectStreamException
{
return LayoutUtil.getSerializedObject(this);
}
public void readExternal(ObjectInput in) throws IOException, ClassNotFoundException
{
LayoutUtil.setSerializedObject(this, LayoutUtil.readAsXML(in));
}
public void writeExternal(ObjectOutput out) throws IOException
{
if (getClass() == LC.class)
LayoutUtil.writeAsXML(out, this);
}
}