Java example source code file (GridBagLayout.java)
The GridBagLayout.java Java example source code/*
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package java.awt;
import java.util.Hashtable;
import java.util.Arrays;
/**
* The <code>GridBagLayout class is a flexible layout
* manager that aligns components vertically, horizontally or along their
* baseline without requiring that the components be of the same size.
* Each <code>GridBagLayout object maintains a dynamic,
* rectangular grid of cells, with each component occupying
* one or more cells, called its <em>display area.
* <p>
* Each component managed by a <code>GridBagLayout is associated with
* an instance of {@link GridBagConstraints}. The constraints object
* specifies where a component's display area should be located on the grid
* and how the component should be positioned within its display area. In
* addition to its constraints object, the <code>GridBagLayout also
* considers each component's minimum and preferred sizes in order to
* determine a component's size.
* <p>
* The overall orientation of the grid depends on the container's
* {@link ComponentOrientation} property. For horizontal left-to-right
* orientations, grid coordinate (0,0) is in the upper left corner of the
* container with x increasing to the right and y increasing downward. For
* horizontal right-to-left orientations, grid coordinate (0,0) is in the upper
* right corner of the container with x increasing to the left and y
* increasing downward.
* <p>
* To use a grid bag layout effectively, you must customize one or more
* of the <code>GridBagConstraints objects that are associated
* with its components. You customize a <code>GridBagConstraints
* object by setting one or more of its instance variables:
*
* <dl>
* <dt>{@link GridBagConstraints#gridx},
* {@link GridBagConstraints#gridy}
* <dd>Specifies the cell containing the leading corner of the component's
* display area, where the cell at the origin of the grid has address
* <code>gridx = 0,
* <code>gridy = 0. For horizontal left-to-right layout,
* a component's leading corner is its upper left. For horizontal
* right-to-left layout, a component's leading corner is its upper right.
* Use <code>GridBagConstraints.RELATIVE (the default value)
* to specify that the component be placed immediately following
* (along the x axis for <code>gridx or the y axis for
* <code>gridy) the component that was added to the container
* just before this component was added.
* <dt>{@link GridBagConstraints#gridwidth},
* {@link GridBagConstraints#gridheight}
* <dd>Specifies the number of cells in a row (for BASELINE.
* </ul>
* Because the second button and the panel share the same prevailing row,
* they are both aligned along their baseline.
* <p>
* Components positioned using one of the baseline-relative values resize
* differently than when positioned using an absolute or orientation-relative
* value. How components change is dictated by how the baseline of the
* prevailing row changes. The baseline is anchored to the
* bottom of the display area if any components with the same prevailing row
* have a baseline-resize behavior of <code>CONSTANT_DESCENT,
* otherwise the baseline is anchored to the top of the display area.
* The following rules dictate the resize behavior:
* <ul>
* <li>Resizable components positioned above the baseline can only
* grow as tall as the baseline. For example, if the baseline is at 100
* and anchored at the top, a resizable component positioned above the
* baseline can never grow more than 100 units.
* <li>Similarly, resizable components positioned below the baseline can
* only grow as high as the difference between the display height and the
* baseline.
* <li>Resizable components positioned on the baseline with a
* baseline-resize behavior of <code>OTHER are only resized if
* the baseline at the resized size fits within the display area. If
* the baseline is such that it does not fit within the display area
* the component is not resized.
* <li>Components positioned on the baseline that do not have a
* baseline-resize behavior of <code>OTHER
* can only grow as tall as {@code display height - baseline + baseline of component}.
* </ul>
* If you position a component along the baseline, but the
* component does not have a valid baseline, it will be vertically centered
* in its space. Similarly if you have positioned a component relative
* to the baseline and none of the components in the row have a valid
* baseline the component is vertically centered.
* <p>
* The following figures show ten components (all buttons)
* managed by a grid bag layout. Figure 2 shows the layout for a horizontal,
* left-to-right container and Figure 3 shows the layout for a horizontal,
* right-to-left container.
*
* <center>weightx = 1.0
* <li>Button4: weightx = 1.0,
* <code>gridwidth = GridBagConstraints.REMAINDER
* <li>Button5: gridwidth = GridBagConstraints.REMAINDER
* <li>Button6: gridwidth = GridBagConstraints.RELATIVE
* <li>Button7: gridwidth = GridBagConstraints.REMAINDER
* <li>Button8: gridheight = 2,
* <code>weighty = 1.0
* <li>Button9, Button 10:
* <code>gridwidth = GridBagConstraints.REMAINDER
* </ul>
* <p>
* Here is the code that implements the example shown above:
*
* <hr>* <p> * @author Doug Stein * @author Bill Spitzak (orignial NeWS & OLIT implementation) * @see java.awt.GridBagConstraints * @see java.awt.GridBagLayoutInfo * @see java.awt.ComponentOrientation * @since JDK1.0 */ public class GridBagLayout implements LayoutManager2, java.io.Serializable { static final int EMPIRICMULTIPLIER = 2; /** * This field is no longer used to reserve arrays and kept for backward * compatibility. Previously, this was * the maximum number of grid positions (both horizontal and * vertical) that could be laid out by the grid bag layout. * Current implementation doesn't impose any limits * on the size of a grid. */ protected static final int MAXGRIDSIZE = 512; /** * The smallest grid that can be laid out by the grid bag layout. */ protected static final int MINSIZE = 1; /** * The preferred grid size that can be laid out by the grid bag layout. */ protected static final int PREFERREDSIZE = 2; /** * This hashtable maintains the association between * a component and its gridbag constraints. * The Keys in <code>comptable are the components and the * values are the instances of <code>GridBagConstraints. * * @serial * @see java.awt.GridBagConstraints */ protected Hashtable<Component,GridBagConstraints> comptable; /** * This field holds a gridbag constraints instance * containing the default values, so if a component * does not have gridbag constraints associated with * it, then the component will be assigned a * copy of the <code>defaultConstraints. * * @serial * @see #getConstraints(Component) * @see #setConstraints(Component, GridBagConstraints) * @see #lookupConstraints(Component) */ protected GridBagConstraints defaultConstraints; /** * This field holds the layout information * for the gridbag. The information in this field * is based on the most recent validation of the * gridbag. * If <code>layoutInfo is null
* this indicates that there are no components in
* the gridbag or if there are components, they have
* not yet been validated.
*
* @serial
* @see #getLayoutInfo(Container, int)
*/
protected GridBagLayoutInfo layoutInfo;
/**
* This field holds the overrides to the column minimum
* width. If this field is non-<code>null the values are
* applied to the gridbag after all of the minimum columns
* widths have been calculated.
* If columnWidths has more elements than the number of
* columns, columns are added to the gridbag to match
* the number of elements in columnWidth.
*
* @serial
* @see #getLayoutDimensions()
*/
public int columnWidths[];
/**
* This field holds the overrides to the row minimum
* heights. If this field is non-<code>null the values are
* applied to the gridbag after all of the minimum row
* heights have been calculated.
* If <code>rowHeights has more elements than the number of
* rows, rows are added to the gridbag to match
* the number of elements in <code>rowHeights.
*
* @serial
* @see #getLayoutDimensions()
*/
public int rowHeights[];
/**
* This field holds the overrides to the column weights.
* If this field is non-<code>null the values are
* applied to the gridbag after all of the columns
* weights have been calculated.
* If <code>columnWeights[i] > weight for column i, then
* column i is assigned the weight in <code>columnWeights[i].
* If <code>columnWeights has more elements than the number
* of columns, the excess elements are ignored - they do
* not cause more columns to be created.
*
* @serial
*/
public double columnWeights[];
/**
* This field holds the overrides to the row weights.
* If this field is non-<code>null the values are
* applied to the gridbag after all of the rows
* weights have been calculated.
* If <code>rowWeights[i] > weight for row i, then
* row i is assigned the weight in <code>rowWeights[i].
* If <code>rowWeights has more elements than the number
* of rows, the excess elements are ignored - they do
* not cause more rows to be created.
*
* @serial
*/
public double rowWeights[];
/**
* The component being positioned. This is set before calling into
* <code>adjustForGravity.
*/
private Component componentAdjusting;
/**
* Creates a grid bag layout manager.
*/
public GridBagLayout () {
comptable = new Hashtable<Component,GridBagConstraints>();
defaultConstraints = new GridBagConstraints();
}
/**
* Sets the constraints for the specified component in this layout.
* @param comp the component to be modified
* @param constraints the constraints to be applied
*/
public void setConstraints(Component comp, GridBagConstraints constraints) {
comptable.put(comp, (GridBagConstraints)constraints.clone());
}
/**
* Gets the constraints for the specified component. A copy of
* the actual <code>GridBagConstraints object is returned.
* @param comp the component to be queried
* @return the constraint for the specified component in this
* grid bag layout; a copy of the actual constraint
* object is returned
*/
public GridBagConstraints getConstraints(Component comp) {
GridBagConstraints constraints = comptable.get(comp);
if (constraints == null) {
setConstraints(comp, defaultConstraints);
constraints = comptable.get(comp);
}
return (GridBagConstraints)constraints.clone();
}
/**
* Retrieves the constraints for the specified component.
* The return value is not a copy, but is the actual
* <code>GridBagConstraints object used by the layout mechanism.
* <p>
* If <code>comp is not in the GridBagLayout,
* a set of default <code>GridBagConstraints are returned.
* A <code>comp value of null is invalid
* and returns <code>null.
*
* @param comp the component to be queried
* @return the constraints for the specified component
*/
protected GridBagConstraints lookupConstraints(Component comp) {
GridBagConstraints constraints = comptable.get(comp);
if (constraints == null) {
setConstraints(comp, defaultConstraints);
constraints = comptable.get(comp);
}
return constraints;
}
/**
* Removes the constraints for the specified component in this layout
* @param comp the component to be modified
*/
private void removeConstraints(Component comp) {
comptable.remove(comp);
}
/**
* Determines the origin of the layout area, in the graphics coordinate
* space of the target container. This value represents the pixel
* coordinates of the top-left corner of the layout area regardless of
* the <code>ComponentOrientation value of the container. This
* is distinct from the grid origin given by the cell coordinates (0,0).
* Most applications do not call this method directly.
* @return the graphics origin of the cell in the top-left
* corner of the layout grid
* @see java.awt.ComponentOrientation
* @since JDK1.1
*/
public Point getLayoutOrigin () {
Point origin = new Point(0,0);
if (layoutInfo != null) {
origin.x = layoutInfo.startx;
origin.y = layoutInfo.starty;
}
return origin;
}
/**
* Determines column widths and row heights for the layout grid.
* <p>
* Most applications do not call this method directly.
* @return an array of two arrays, containing the widths
* of the layout columns and
* the heights of the layout rows
* @since JDK1.1
*/
public int [][] getLayoutDimensions () {
if (layoutInfo == null)
return new int[2][0];
int dim[][] = new int [2][];
dim[0] = new int[layoutInfo.width];
dim[1] = new int[layoutInfo.height];
System.arraycopy(layoutInfo.minWidth, 0, dim[0], 0, layoutInfo.width);
System.arraycopy(layoutInfo.minHeight, 0, dim[1], 0, layoutInfo.height);
return dim;
}
/**
* Determines the weights of the layout grid's columns and rows.
* Weights are used to calculate how much a given column or row
* stretches beyond its preferred size, if the layout has extra
* room to fill.
* <p>
* Most applications do not call this method directly.
* @return an array of two arrays, representing the
* horizontal weights of the layout columns
* and the vertical weights of the layout rows
* @since JDK1.1
*/
public double [][] getLayoutWeights () {
if (layoutInfo == null)
return new double[2][0];
double weights[][] = new double [2][];
weights[0] = new double[layoutInfo.width];
weights[1] = new double[layoutInfo.height];
System.arraycopy(layoutInfo.weightX, 0, weights[0], 0, layoutInfo.width);
System.arraycopy(layoutInfo.weightY, 0, weights[1], 0, layoutInfo.height);
return weights;
}
/**
* Determines which cell in the layout grid contains the point
* specified by <code>(x, y). Each cell is identified
* by its column index (ranging from 0 to the number of columns
* minus 1) and its row index (ranging from 0 to the number of
* rows minus 1).
* <p>
* If the <code>(x, y) point lies
* outside the grid, the following rules are used.
* The column index is returned as zero if <code>x lies to the
* left of the layout for a left-to-right container or to the right of
* the layout for a right-to-left container. The column index is returned
* as the number of columns if <code>x lies
* to the right of the layout in a left-to-right container or to the left
* in a right-to-left container.
* The row index is returned as zero if <code>y lies above the
* layout, and as the number of rows if <code>y lies
* below the layout. The orientation of a container is determined by its
* <code>ComponentOrientation property.
* @param x the <i>x coordinate of a point
* @param y the <i>y coordinate of a point
* @return an ordered pair of indexes that indicate which cell
* in the layout grid contains the point
* (<i>x, y).
* @see java.awt.ComponentOrientation
* @since JDK1.1
*/
public Point location(int x, int y) {
Point loc = new Point(0,0);
int i, d;
if (layoutInfo == null)
return loc;
d = layoutInfo.startx;
if (!rightToLeft) {
for (i=0; i<layoutInfo.width; i++) {
d += layoutInfo.minWidth[i];
if (d > x)
break;
}
} else {
for (i=layoutInfo.width-1; i>=0; i--) {
if (d > x)
break;
d += layoutInfo.minWidth[i];
}
i++;
}
loc.x = i;
d = layoutInfo.starty;
for (i=0; i<layoutInfo.height; i++) {
d += layoutInfo.minHeight[i];
if (d > y)
break;
}
loc.y = i;
return loc;
}
/**
* Has no effect, since this layout manager does not use a per-component string.
*/
public void addLayoutComponent(String name, Component comp) {
}
/**
* Adds the specified component to the layout, using the specified
* <code>constraints object. Note that constraints
* are mutable and are, therefore, cloned when cached.
*
* @param comp the component to be added
* @param constraints an object that determines how
* the component is added to the layout
* @exception IllegalArgumentException if <code>constraints
* is not a <code>GridBagConstraint
*/
public void addLayoutComponent(Component comp, Object constraints) {
if (constraints instanceof GridBagConstraints) {
setConstraints(comp, (GridBagConstraints)constraints);
} else if (constraints != null) {
throw new IllegalArgumentException("cannot add to layout: constraints must be a GridBagConstraint");
}
}
/**
* Removes the specified component from this layout.
* <p>
* Most applications do not call this method directly.
* @param comp the component to be removed.
* @see java.awt.Container#remove(java.awt.Component)
* @see java.awt.Container#removeAll()
*/
public void removeLayoutComponent(Component comp) {
removeConstraints(comp);
}
/**
* Determines the preferred size of the <code>parent
* container using this grid bag layout.
* <p>
* Most applications do not call this method directly.
*
* @param parent the container in which to do the layout
* @see java.awt.Container#getPreferredSize
* @return the preferred size of the <code>parent
* container
*/
public Dimension preferredLayoutSize(Container parent) {
GridBagLayoutInfo info = getLayoutInfo(parent, PREFERREDSIZE);
return getMinSize(parent, info);
}
/**
* Determines the minimum size of the <code>parent container
* using this grid bag layout.
* <p>
* Most applications do not call this method directly.
* @param parent the container in which to do the layout
* @see java.awt.Container#doLayout
* @return the minimum size of the <code>parent container
*/
public Dimension minimumLayoutSize(Container parent) {
GridBagLayoutInfo info = getLayoutInfo(parent, MINSIZE);
return getMinSize(parent, info);
}
/**
* Returns the maximum dimensions for this layout given the components
* in the specified target container.
* @param target the container which needs to be laid out
* @see Container
* @see #minimumLayoutSize(Container)
* @see #preferredLayoutSize(Container)
* @return the maximum dimensions for this layout
*/
public Dimension maximumLayoutSize(Container target) {
return new Dimension(Integer.MAX_VALUE, Integer.MAX_VALUE);
}
/**
* Returns the alignment along the x axis. This specifies how
* the component would like to be aligned relative to other
* components. The value should be a number between 0 and 1
* where 0 represents alignment along the origin, 1 is aligned
* the furthest away from the origin, 0.5 is centered, etc.
* <p>
* @return the value <code>0.5f to indicate centered
*/
public float getLayoutAlignmentX(Container parent) {
return 0.5f;
}
/**
* Returns the alignment along the y axis. This specifies how
* the component would like to be aligned relative to other
* components. The value should be a number between 0 and 1
* where 0 represents alignment along the origin, 1 is aligned
* the furthest away from the origin, 0.5 is centered, etc.
* <p>
* @return the value <code>0.5f to indicate centered
*/
public float getLayoutAlignmentY(Container parent) {
return 0.5f;
}
/**
* Invalidates the layout, indicating that if the layout manager
* has cached information it should be discarded.
*/
public void invalidateLayout(Container target) {
}
/**
* Lays out the specified container using this grid bag layout.
* This method reshapes components in the specified container in
* order to satisfy the constraints of this <code>GridBagLayout
* object.
* <p>
* Most applications do not call this method directly.
* @param parent the container in which to do the layout
* @see java.awt.Container
* @see java.awt.Container#doLayout
*/
public void layoutContainer(Container parent) {
arrangeGrid(parent);
}
/**
* Returns a string representation of this grid bag layout's values.
* @return a string representation of this grid bag layout.
*/
public String toString() {
return getClass().getName();
}
/**
* Print the layout information. Useful for debugging.
*/
/* DEBUG
*
* protected void dumpLayoutInfo(GridBagLayoutInfo s) {
* int x;
*
* System.out.println("Col\tWidth\tWeight");
* for (x=0; x<s.width; x++) {
* System.out.println(x + "\t" +
* s.minWidth[x] + "\t" +
* s.weightX[x]);
* }
* System.out.println("Row\tHeight\tWeight");
* for (x=0; x<s.height; x++) {
* System.out.println(x + "\t" +
* s.minHeight[x] + "\t" +
* s.weightY[x]);
* }
* }
*/
/**
* Print the layout constraints. Useful for debugging.
*/
/* DEBUG
*
* protected void dumpConstraints(GridBagConstraints constraints) {
* System.out.println(
* "wt " +
* constraints.weightx +
* " " +
* constraints.weighty +
* ", " +
*
* "box " +
* constraints.gridx +
* " " +
* constraints.gridy +
* " " +
* constraints.gridwidth +
* " " +
* constraints.gridheight +
* ", " +
*
* "min " +
* constraints.minWidth +
* " " +
* constraints.minHeight +
* ", " +
*
* "pad " +
* constraints.insets.bottom +
* " " +
* constraints.insets.left +
* " " +
* constraints.insets.right +
* " " +
* constraints.insets.top +
* " " +
* constraints.ipadx +
* " " +
* constraints.ipady);
* }
*/
/**
* Fills in an instance of <code>GridBagLayoutInfo for the
* current set of managed children. This requires three passes through the
* set of children:
*
* <ol>
* <li>Figure out the dimensions of the layout grid.
* <li>Determine which cells the components occupy.
* <li>Distribute the weights and min sizes among the rows/columns.
* </ol>
*
* This also caches the minsizes for all the children when they are
* first encountered (so subsequent loops don't need to ask again).
* <p>
* This method should only be used internally by
* <code>GridBagLayout.
*
* @param parent the layout container
* @param sizeflag either <code>PREFERREDSIZE or
* <code>MINSIZE
* @return the <code>GridBagLayoutInfo for the set of children
* @since 1.4
*/
protected GridBagLayoutInfo getLayoutInfo(Container parent, int sizeflag) {
return GetLayoutInfo(parent, sizeflag);
}
/*
* Calculate maximum array sizes to allocate arrays without ensureCapacity
* we may use preCalculated sizes in whole class because of upper estimation of
* maximumArrayXIndex and maximumArrayYIndex.
*/
private long[] preInitMaximumArraySizes(Container parent){
Component components[] = parent.getComponents();
Component comp;
GridBagConstraints constraints;
int curX, curY;
int curWidth, curHeight;
int preMaximumArrayXIndex = 0;
int preMaximumArrayYIndex = 0;
long [] returnArray = new long[2];
for (int compId = 0 ; compId < components.length ; compId++) {
comp = components[compId];
if (!comp.isVisible()) {
continue;
}
constraints = lookupConstraints(comp);
curX = constraints.gridx;
curY = constraints.gridy;
curWidth = constraints.gridwidth;
curHeight = constraints.gridheight;
// -1==RELATIVE, means that column|row equals to previously added component,
// since each next Component with gridx|gridy == RELATIVE starts from
// previous position, so we should start from previous component which
// already used in maximumArray[X|Y]Index calculation. We could just increase
// maximum by 1 to handle situation when component with gridx=-1 was added.
if (curX < 0){
curX = ++preMaximumArrayYIndex;
}
if (curY < 0){
curY = ++preMaximumArrayXIndex;
}
// gridwidth|gridheight may be equal to RELATIVE (-1) or REMAINDER (0)
// in any case using 1 instead of 0 or -1 should be sufficient to for
// correct maximumArraySizes calculation
if (curWidth <= 0){
curWidth = 1;
}
if (curHeight <= 0){
curHeight = 1;
}
preMaximumArrayXIndex = Math.max(curY + curHeight, preMaximumArrayXIndex);
preMaximumArrayYIndex = Math.max(curX + curWidth, preMaximumArrayYIndex);
} //for (components) loop
// Must specify index++ to allocate well-working arrays.
/* fix for 4623196.
* now return long array instead of Point
*/
returnArray[0] = preMaximumArrayXIndex;
returnArray[1] = preMaximumArrayYIndex;
return returnArray;
} //PreInitMaximumSizes
/**
* This method is obsolete and supplied for backwards
* compatibility only; new code should call {@link
* #getLayoutInfo(java.awt.Container, int) getLayoutInfo} instead.
* This method is the same as <code>getLayoutInfo;
* refer to <code>getLayoutInfo for details on parameters
* and return value.
*/
protected GridBagLayoutInfo GetLayoutInfo(Container parent, int sizeflag) {
synchronized (parent.getTreeLock()) {
GridBagLayoutInfo r;
Component comp;
GridBagConstraints constraints;
Dimension d;
Component components[] = parent.getComponents();
// Code below will address index curX+curWidth in the case of yMaxArray, weightY
// ( respectively curY+curHeight for xMaxArray, weightX ) where
// curX in 0 to preInitMaximumArraySizes.y
// Thus, the maximum index that could
// be calculated in the following code is curX+curX.
// EmpericMultier equals 2 because of this.
int layoutWidth, layoutHeight;
int []xMaxArray;
int []yMaxArray;
int compindex, i, k, px, py, pixels_diff, nextSize;
int curX = 0; // constraints.gridx
int curY = 0; // constraints.gridy
int curWidth = 1; // constraints.gridwidth
int curHeight = 1; // constraints.gridheight
int curRow, curCol;
double weight_diff, weight;
int maximumArrayXIndex = 0;
int maximumArrayYIndex = 0;
int anchor;
/*
* Pass #1
*
* Figure out the dimensions of the layout grid (use a value of 1 for
* zero or negative widths and heights).
*/
layoutWidth = layoutHeight = 0;
curRow = curCol = -1;
long [] arraySizes = preInitMaximumArraySizes(parent);
/* fix for 4623196.
* If user try to create a very big grid we can
* get NegativeArraySizeException because of integer value
* overflow (EMPIRICMULTIPLIER*gridSize might be more then Integer.MAX_VALUE).
* We need to detect this situation and try to create a
* grid with Integer.MAX_VALUE size instead.
*/
maximumArrayXIndex = (EMPIRICMULTIPLIER * arraySizes[0] > Integer.MAX_VALUE )? Integer.MAX_VALUE : EMPIRICMULTIPLIER*(int)arraySizes[0];
maximumArrayYIndex = (EMPIRICMULTIPLIER * arraySizes[1] > Integer.MAX_VALUE )? Integer.MAX_VALUE : EMPIRICMULTIPLIER*(int)arraySizes[1];
if (rowHeights != null){
maximumArrayXIndex = Math.max(maximumArrayXIndex, rowHeights.length);
}
if (columnWidths != null){
maximumArrayYIndex = Math.max(maximumArrayYIndex, columnWidths.length);
}
xMaxArray = new int[maximumArrayXIndex];
yMaxArray = new int[maximumArrayYIndex];
boolean hasBaseline = false;
for (compindex = 0 ; compindex < components.length ; compindex++) {
comp = components[compindex];
if (!comp.isVisible())
continue;
constraints = lookupConstraints(comp);
curX = constraints.gridx;
curY = constraints.gridy;
curWidth = constraints.gridwidth;
if (curWidth <= 0)
curWidth = 1;
curHeight = constraints.gridheight;
if (curHeight <= 0)
curHeight = 1;
/* If x or y is negative, then use relative positioning: */
if (curX < 0 && curY < 0) {
if (curRow >= 0)
curY = curRow;
else if (curCol >= 0)
curX = curCol;
else
curY = 0;
}
if (curX < 0) {
px = 0;
for (i = curY; i < (curY + curHeight); i++) {
px = Math.max(px, xMaxArray[i]);
}
curX = px - curX - 1;
if(curX < 0)
curX = 0;
}
else if (curY < 0) {
py = 0;
for (i = curX; i < (curX + curWidth); i++) {
py = Math.max(py, yMaxArray[i]);
}
curY = py - curY - 1;
if(curY < 0)
curY = 0;
}
/* Adjust the grid width and height
* fix for 5005945: unneccessary loops removed
*/
px = curX + curWidth;
if (layoutWidth < px) {
layoutWidth = px;
}
py = curY + curHeight;
if (layoutHeight < py) {
layoutHeight = py;
}
/* Adjust xMaxArray and yMaxArray */
for (i = curX; i < (curX + curWidth); i++) {
yMaxArray[i] =py;
}
for (i = curY; i < (curY + curHeight); i++) {
xMaxArray[i] = px;
}
/* Cache the current slave's size. */
if (sizeflag == PREFERREDSIZE)
d = comp.getPreferredSize();
else
d = comp.getMinimumSize();
constraints.minWidth = d.width;
constraints.minHeight = d.height;
if (calculateBaseline(comp, constraints, d)) {
hasBaseline = true;
}
/* Zero width and height must mean that this is the last item (or
* else something is wrong). */
if (constraints.gridheight == 0 && constraints.gridwidth == 0)
curRow = curCol = -1;
/* Zero width starts a new row */
if (constraints.gridheight == 0 && curRow < 0)
curCol = curX + curWidth;
/* Zero height starts a new column */
else if (constraints.gridwidth == 0 && curCol < 0)
curRow = curY + curHeight;
} //for (components) loop
/*
* Apply minimum row/column dimensions
*/
if (columnWidths != null && layoutWidth < columnWidths.length)
layoutWidth = columnWidths.length;
if (rowHeights != null && layoutHeight < rowHeights.length)
layoutHeight = rowHeights.length;
r = new GridBagLayoutInfo(layoutWidth, layoutHeight);
/*
* Pass #2
*
* Negative values for gridX are filled in with the current x value.
* Negative values for gridY are filled in with the current y value.
* Negative or zero values for gridWidth and gridHeight end the current
* row or column, respectively.
*/
curRow = curCol = -1;
Arrays.fill(xMaxArray, 0);
Arrays.fill(yMaxArray, 0);
int[] maxAscent = null;
int[] maxDescent = null;
short[] baselineType = null;
if (hasBaseline) {
r.maxAscent = maxAscent = new int[layoutHeight];
r.maxDescent = maxDescent = new int[layoutHeight];
r.baselineType = baselineType = new short[layoutHeight];
r.hasBaseline = true;
}
for (compindex = 0 ; compindex < components.length ; compindex++) {
comp = components[compindex];
if (!comp.isVisible())
continue;
constraints = lookupConstraints(comp);
curX = constraints.gridx;
curY = constraints.gridy;
curWidth = constraints.gridwidth;
curHeight = constraints.gridheight;
/* If x or y is negative, then use relative positioning: */
if (curX < 0 && curY < 0) {
if(curRow >= 0)
curY = curRow;
else if(curCol >= 0)
curX = curCol;
else
curY = 0;
}
if (curX < 0) {
if (curHeight <= 0) {
curHeight += r.height - curY;
if (curHeight < 1)
curHeight = 1;
}
px = 0;
for (i = curY; i < (curY + curHeight); i++)
px = Math.max(px, xMaxArray[i]);
curX = px - curX - 1;
if(curX < 0)
curX = 0;
}
else if (curY < 0) {
if (curWidth <= 0) {
curWidth += r.width - curX;
if (curWidth < 1)
curWidth = 1;
}
py = 0;
for (i = curX; i < (curX + curWidth); i++){
py = Math.max(py, yMaxArray[i]);
}
curY = py - curY - 1;
if(curY < 0)
curY = 0;
}
if (curWidth <= 0) {
curWidth += r.width - curX;
if (curWidth < 1)
curWidth = 1;
}
if (curHeight <= 0) {
curHeight += r.height - curY;
if (curHeight < 1)
curHeight = 1;
}
px = curX + curWidth;
py = curY + curHeight;
for (i = curX; i < (curX + curWidth); i++) { yMaxArray[i] = py; }
for (i = curY; i < (curY + curHeight); i++) { xMaxArray[i] = px; }
/* Make negative sizes start a new row/column */
if (constraints.gridheight == 0 && constraints.gridwidth == 0)
curRow = curCol = -1;
if (constraints.gridheight == 0 && curRow < 0)
curCol = curX + curWidth;
else if (constraints.gridwidth == 0 && curCol < 0)
curRow = curY + curHeight;
/* Assign the new values to the gridbag slave */
constraints.tempX = curX;
constraints.tempY = curY;
constraints.tempWidth = curWidth;
constraints.tempHeight = curHeight;
anchor = constraints.anchor;
if (hasBaseline) {
switch(anchor) {
case GridBagConstraints.BASELINE:
case GridBagConstraints.BASELINE_LEADING:
case GridBagConstraints.BASELINE_TRAILING:
if (constraints.ascent >= 0) {
if (curHeight == 1) {
maxAscent[curY] =
Math.max(maxAscent[curY],
constraints.ascent);
maxDescent[curY] =
Math.max(maxDescent[curY],
constraints.descent);
}
else {
if (constraints.baselineResizeBehavior ==
Component.BaselineResizeBehavior.
CONSTANT_DESCENT) {
maxDescent[curY + curHeight - 1] =
Math.max(maxDescent[curY + curHeight
- 1],
constraints.descent);
}
else {
maxAscent[curY] = Math.max(maxAscent[curY],
constraints.ascent);
}
}
if (constraints.baselineResizeBehavior ==
Component.BaselineResizeBehavior.CONSTANT_DESCENT) {
baselineType[curY + curHeight - 1] |=
(1 << constraints.
baselineResizeBehavior.ordinal());
}
else {
baselineType[curY] |= (1 << constraints.
baselineResizeBehavior.ordinal());
}
}
break;
case GridBagConstraints.ABOVE_BASELINE:
case GridBagConstraints.ABOVE_BASELINE_LEADING:
case GridBagConstraints.ABOVE_BASELINE_TRAILING:
// Component positioned above the baseline.
// To make the bottom edge of the component aligned
// with the baseline the bottom inset is
// added to the descent, the rest to the ascent.
pixels_diff = constraints.minHeight +
constraints.insets.top +
constraints.ipady;
maxAscent[curY] = Math.max(maxAscent[curY],
pixels_diff);
maxDescent[curY] = Math.max(maxDescent[curY],
constraints.insets.bottom);
break;
case GridBagConstraints.BELOW_BASELINE:
case GridBagConstraints.BELOW_BASELINE_LEADING:
case GridBagConstraints.BELOW_BASELINE_TRAILING:
// Component positioned below the baseline.
// To make the top edge of the component aligned
// with the baseline the top inset is
// added to the ascent, the rest to the descent.
pixels_diff = constraints.minHeight +
constraints.insets.bottom + constraints.ipady;
maxDescent[curY] = Math.max(maxDescent[curY],
pixels_diff);
maxAscent[curY] = Math.max(maxAscent[curY],
constraints.insets.top);
break;
}
}
}
r.weightX = new double[maximumArrayYIndex];
r.weightY = new double[maximumArrayXIndex];
r.minWidth = new int[maximumArrayYIndex];
r.minHeight = new int[maximumArrayXIndex];
/*
* Apply minimum row/column dimensions and weights
*/
if (columnWidths != null)
System.arraycopy(columnWidths, 0, r.minWidth, 0, columnWidths.length);
if (rowHeights != null)
System.arraycopy(rowHeights, 0, r.minHeight, 0, rowHeights.length);
if (columnWeights != null)
System.arraycopy(columnWeights, 0, r.weightX, 0, Math.min(r.weightX.length, columnWeights.length));
if (rowWeights != null)
System.arraycopy(rowWeights, 0, r.weightY, 0, Math.min(r.weightY.length, rowWeights.length));
/*
* Pass #3
*
* Distribute the minimun widths and weights:
*/
nextSize = Integer.MAX_VALUE;
for (i = 1;
i != Integer.MAX_VALUE;
i = nextSize, nextSize = Integer.MAX_VALUE) {
for (compindex = 0 ; compindex < components.length ; compindex++) {
comp = components[compindex];
if (!comp.isVisible())
continue;
constraints = lookupConstraints(comp);
if (constraints.tempWidth == i) {
px = constraints.tempX + constraints.tempWidth; /* right column */
/*
* Figure out if we should use this slave\'s weight. If the weight
* is less than the total weight spanned by the width of the cell,
* then discard the weight. Otherwise split the difference
* according to the existing weights.
*/
weight_diff = constraints.weightx;
for (k = constraints.tempX; k < px; k++)
weight_diff -= r.weightX[k];
if (weight_diff > 0.0) {
weight = 0.0;
for (k = constraints.tempX; k < px; k++)
weight += r.weightX[k];
for (k = constraints.tempX; weight > 0.0 && k < px; k++) {
double wt = r.weightX[k];
double dx = (wt * weight_diff) / weight;
r.weightX[k] += dx;
weight_diff -= dx;
weight -= wt;
}
/* Assign the remainder to the rightmost cell */
r.weightX[px-1] += weight_diff;
}
/*
* Calculate the minWidth array values.
* First, figure out how wide the current slave needs to be.
* Then, see if it will fit within the current minWidth values.
* If it will not fit, add the difference according to the
* weightX array.
*/
pixels_diff =
constraints.minWidth + constraints.ipadx +
constraints.insets.left + constraints.insets.right;
for (k = constraints.tempX; k < px; k++)
pixels_diff -= r.minWidth[k];
if (pixels_diff > 0) {
weight = 0.0;
for (k = constraints.tempX; k < px; k++)
weight += r.weightX[k];
for (k = constraints.tempX; weight > 0.0 && k < px; k++) {
double wt = r.weightX[k];
int dx = (int)((wt * ((double)pixels_diff)) / weight);
r.minWidth[k] += dx;
pixels_diff -= dx;
weight -= wt;
}
/* Any leftovers go into the rightmost cell */
r.minWidth[px-1] += pixels_diff;
}
}
else if (constraints.tempWidth > i && constraints.tempWidth < nextSize)
nextSize = constraints.tempWidth;
if (constraints.tempHeight == i) {
py = constraints.tempY + constraints.tempHeight; /* bottom row */
/*
* Figure out if we should use this slave's weight. If the weight
* is less than the total weight spanned by the height of the cell,
* then discard the weight. Otherwise split it the difference
* according to the existing weights.
*/
weight_diff = constraints.weighty;
for (k = constraints.tempY; k < py; k++)
weight_diff -= r.weightY[k];
if (weight_diff > 0.0) {
weight = 0.0;
for (k = constraints.tempY; k < py; k++)
weight += r.weightY[k];
for (k = constraints.tempY; weight > 0.0 && k < py; k++) {
double wt = r.weightY[k];
double dy = (wt * weight_diff) / weight;
r.weightY[k] += dy;
weight_diff -= dy;
weight -= wt;
}
/* Assign the remainder to the bottom cell */
r.weightY[py-1] += weight_diff;
}
/*
* Calculate the minHeight array values.
* First, figure out how tall the current slave needs to be.
* Then, see if it will fit within the current minHeight values.
* If it will not fit, add the difference according to the
* weightY array.
*/
pixels_diff = -1;
if (hasBaseline) {
switch(constraints.anchor) {
case GridBagConstraints.BASELINE:
case GridBagConstraints.BASELINE_LEADING:
case GridBagConstraints.BASELINE_TRAILING:
if (constraints.ascent >= 0) {
if (constraints.tempHeight == 1) {
pixels_diff =
maxAscent[constraints.tempY] +
maxDescent[constraints.tempY];
}
else if (constraints.baselineResizeBehavior !=
Component.BaselineResizeBehavior.
CONSTANT_DESCENT) {
pixels_diff =
maxAscent[constraints.tempY] +
constraints.descent;
}
else {
pixels_diff = constraints.ascent +
maxDescent[constraints.tempY +
constraints.tempHeight - 1];
}
}
break;
case GridBagConstraints.ABOVE_BASELINE:
case GridBagConstraints.ABOVE_BASELINE_LEADING:
case GridBagConstraints.ABOVE_BASELINE_TRAILING:
pixels_diff = constraints.insets.top +
constraints.minHeight +
constraints.ipady +
maxDescent[constraints.tempY];
break;
case GridBagConstraints.BELOW_BASELINE:
case GridBagConstraints.BELOW_BASELINE_LEADING:
case GridBagConstraints.BELOW_BASELINE_TRAILING:
pixels_diff = maxAscent[constraints.tempY] +
constraints.minHeight +
constraints.insets.bottom +
constraints.ipady;
break;
}
}
if (pixels_diff == -1) {
pixels_diff =
constraints.minHeight + constraints.ipady +
constraints.insets.top +
constraints.insets.bottom;
}
for (k = constraints.tempY; k < py; k++)
pixels_diff -= r.minHeight[k];
if (pixels_diff > 0) {
weight = 0.0;
for (k = constraints.tempY; k < py; k++)
weight += r.weightY[k];
for (k = constraints.tempY; weight > 0.0 && k < py; k++) {
double wt = r.weightY[k];
int dy = (int)((wt * ((double)pixels_diff)) / weight);
r.minHeight[k] += dy;
pixels_diff -= dy;
weight -= wt;
}
/* Any leftovers go into the bottom cell */
r.minHeight[py-1] += pixels_diff;
}
}
else if (constraints.tempHeight > i &&
constraints.tempHeight < nextSize)
nextSize = constraints.tempHeight;
}
}
return r;
}
} //getLayoutInfo()
/**
* Calculate the baseline for the specified component.
* If {@code c} is positioned along it's baseline, the baseline is
* obtained and the {@code constraints} ascent, descent and
* baseline resize behavior are set from the component; and true is
* returned. Otherwise false is returned.
*/
private boolean calculateBaseline(Component c,
GridBagConstraints constraints,
Dimension size) {
int anchor = constraints.anchor;
if (anchor == GridBagConstraints.BASELINE ||
anchor == GridBagConstraints.BASELINE_LEADING ||
anchor == GridBagConstraints.BASELINE_TRAILING) {
// Apply the padding to the component, then ask for the baseline.
int w = size.width + constraints.ipadx;
int h = size.height + constraints.ipady;
constraints.ascent = c.getBaseline(w, h);
if (constraints.ascent >= 0) {
// Component has a baseline
int baseline = constraints.ascent;
// Adjust the ascent and descent to include the insets.
constraints.descent = h - constraints.ascent +
constraints.insets.bottom;
constraints.ascent += constraints.insets.top;
constraints.baselineResizeBehavior =
c.getBaselineResizeBehavior();
constraints.centerPadding = 0;
if (constraints.baselineResizeBehavior == Component.
BaselineResizeBehavior.CENTER_OFFSET) {
// Component has a baseline resize behavior of
// CENTER_OFFSET, calculate centerPadding and
// centerOffset (see the description of
// CENTER_OFFSET in the enum for detais on this
// algorithm).
int nextBaseline = c.getBaseline(w, h + 1);
constraints.centerOffset = baseline - h / 2;
if (h % 2 == 0) {
if (baseline != nextBaseline) {
constraints.centerPadding = 1;
}
}
else if (baseline == nextBaseline){
constraints.centerOffset--;
constraints.centerPadding = 1;
}
}
}
return true;
}
else {
constraints.ascent = -1;
return false;
}
}
/**
* Adjusts the x, y, width, and height fields to the correct
* values depending on the constraint geometry and pads.
* This method should only be used internally by
* <code>GridBagLayout.
*
* @param constraints the constraints to be applied
* @param r the <code>Rectangle to be adjusted
* @since 1.4
*/
protected void adjustForGravity(GridBagConstraints constraints,
Rectangle r) {
AdjustForGravity(constraints, r);
}
/**
* This method is obsolete and supplied for backwards
* compatibility only; new code should call {@link
* #adjustForGravity(java.awt.GridBagConstraints, java.awt.Rectangle)
* adjustForGravity} instead.
* This method is the same as <code>adjustForGravity;
* refer to <code>adjustForGravity for details
* on parameters.
*/
protected void AdjustForGravity(GridBagConstraints constraints,
Rectangle r) {
int diffx, diffy;
int cellY = r.y;
int cellHeight = r.height;
if (!rightToLeft) {
r.x += constraints.insets.left;
} else {
r.x -= r.width - constraints.insets.right;
}
r.width -= (constraints.insets.left + constraints.insets.right);
r.y += constraints.insets.top;
r.height -= (constraints.insets.top + constraints.insets.bottom);
diffx = 0;
if ((constraints.fill != GridBagConstraints.HORIZONTAL &&
constraints.fill != GridBagConstraints.BOTH)
&& (r.width > (constraints.minWidth + constraints.ipadx))) {
diffx = r.width - (constraints.minWidth + constraints.ipadx);
r.width = constraints.minWidth + constraints.ipadx;
}
diffy = 0;
if ((constraints.fill != GridBagConstraints.VERTICAL &&
constraints.fill != GridBagConstraints.BOTH)
&& (r.height > (constraints.minHeight + constraints.ipady))) {
diffy = r.height - (constraints.minHeight + constraints.ipady);
r.height = constraints.minHeight + constraints.ipady;
}
switch (constraints.anchor) {
case GridBagConstraints.BASELINE:
r.x += diffx/2;
alignOnBaseline(constraints, r, cellY, cellHeight);
break;
case GridBagConstraints.BASELINE_LEADING:
if (rightToLeft) {
r.x += diffx;
}
alignOnBaseline(constraints, r, cellY, cellHeight);
break;
case GridBagConstraints.BASELINE_TRAILING:
if (!rightToLeft) {
r.x += diffx;
}
alignOnBaseline(constraints, r, cellY, cellHeight);
break;
case GridBagConstraints.ABOVE_BASELINE:
r.x += diffx/2;
alignAboveBaseline(constraints, r, cellY, cellHeight);
break;
case GridBagConstraints.ABOVE_BASELINE_LEADING:
if (rightToLeft) {
r.x += diffx;
}
alignAboveBaseline(constraints, r, cellY, cellHeight);
break;
case GridBagConstraints.ABOVE_BASELINE_TRAILING:
if (!rightToLeft) {
r.x += diffx;
}
alignAboveBaseline(constraints, r, cellY, cellHeight);
break;
case GridBagConstraints.BELOW_BASELINE:
r.x += diffx/2;
alignBelowBaseline(constraints, r, cellY, cellHeight);
break;
case GridBagConstraints.BELOW_BASELINE_LEADING:
if (rightToLeft) {
r.x += diffx;
}
alignBelowBaseline(constraints, r, cellY, cellHeight);
break;
case GridBagConstraints.BELOW_BASELINE_TRAILING:
if (!rightToLeft) {
r.x += diffx;
}
alignBelowBaseline(constraints, r, cellY, cellHeight);
break;
case GridBagConstraints.CENTER:
r.x += diffx/2;
r.y += diffy/2;
break;
case GridBagConstraints.PAGE_START:
case GridBagConstraints.NORTH:
r.x += diffx/2;
break;
case GridBagConstraints.NORTHEAST:
r.x += diffx;
break;
case GridBagConstraints.EAST:
r.x += diffx;
r.y += diffy/2;
break;
case GridBagConstraints.SOUTHEAST:
r.x += diffx;
r.y += diffy;
break;
case GridBagConstraints.PAGE_END:
case GridBagConstraints.SOUTH:
r.x += diffx/2;
r.y += diffy;
break;
case GridBagConstraints.SOUTHWEST:
r.y += diffy;
break;
case GridBagConstraints.WEST:
r.y += diffy/2;
break;
case GridBagConstraints.NORTHWEST:
break;
case GridBagConstraints.LINE_START:
if (rightToLeft) {
r.x += diffx;
}
r.y += diffy/2;
break;
case GridBagConstraints.LINE_END:
if (!rightToLeft) {
r.x += diffx;
}
r.y += diffy/2;
break;
case GridBagConstraints.FIRST_LINE_START:
if (rightToLeft) {
r.x += diffx;
}
break;
case GridBagConstraints.FIRST_LINE_END:
if (!rightToLeft) {
r.x += diffx;
}
break;
case GridBagConstraints.LAST_LINE_START:
if (rightToLeft) {
r.x += diffx;
}
r.y += diffy;
break;
case GridBagConstraints.LAST_LINE_END:
if (!rightToLeft) {
r.x += diffx;
}
r.y += diffy;
break;
default:
throw new IllegalArgumentException("illegal anchor value");
}
}
/**
* Positions on the baseline.
*
* @param cellY the location of the row, does not include insets
* @param cellHeight the height of the row, does not take into account
* insets
* @param r available bounds for the component, is padded by insets and
* ipady
*/
private void alignOnBaseline(GridBagConstraints cons, Rectangle r,
int cellY, int cellHeight) {
if (cons.ascent >= 0) {
if (cons.baselineResizeBehavior == Component.
BaselineResizeBehavior.CONSTANT_DESCENT) {
// Anchor to the bottom.
// Baseline is at (cellY + cellHeight - maxDescent).
// Bottom of component (maxY) is at baseline + descent
// of component. We need to subtract the bottom inset here
// as the descent in the constraints object includes the
// bottom inset.
int maxY = cellY + cellHeight -
layoutInfo.maxDescent[cons.tempY + cons.tempHeight - 1] +
cons.descent - cons.insets.bottom;
if (!cons.isVerticallyResizable()) {
// Component not resizable, calculate y location
// from maxY - height.
r.y = maxY - cons.minHeight;
r.height = cons.minHeight;
} else {
// Component is resizable. As brb is constant descent,
// can expand component to fill region above baseline.
// Subtract out the top inset so that components insets
// are honored.
r.height = maxY - cellY - cons.insets.top;
}
}
else {
// BRB is not constant_descent
int baseline; // baseline for the row, relative to cellY
// Component baseline, includes insets.top
int ascent = cons.ascent;
if (layoutInfo.hasConstantDescent(cons.tempY)) {
// Mixed ascent/descent in same row, calculate position
// off maxDescent
baseline = cellHeight - layoutInfo.maxDescent[cons.tempY];
}
else {
// Only ascents/unknown in this row, anchor to top
baseline = layoutInfo.maxAscent[cons.tempY];
}
if (cons.baselineResizeBehavior == Component.
BaselineResizeBehavior.OTHER) {
// BRB is other, which means we can only determine
// the baseline by asking for it again giving the
// size we plan on using for the component.
boolean fits = false;
ascent = componentAdjusting.getBaseline(r.width, r.height);
if (ascent >= 0) {
// Component has a baseline, pad with top inset
// (this follows from calculateBaseline which
// does the same).
ascent += cons.insets.top;
}
if (ascent >= 0 && ascent <= baseline) {
// Components baseline fits within rows baseline.
// Make sure the descent fits within the space as well.
if (baseline + (r.height - ascent - cons.insets.top) <=
cellHeight - cons.insets.bottom) {
// It fits, we're good.
fits = true;
}
else if (cons.isVerticallyResizable()) {
// Doesn't fit, but it's resizable. Try
// again assuming we'll get ascent again.
int ascent2 = componentAdjusting.getBaseline(
r.width, cellHeight - cons.insets.bottom -
baseline + ascent);
if (ascent2 >= 0) {
ascent2 += cons.insets.top;
}
if (ascent2 >= 0 && ascent2 <= ascent) {
// It'll fit
r.height = cellHeight - cons.insets.bottom -
baseline + ascent;
ascent = ascent2;
fits = true;
}
}
}
if (!fits) {
// Doesn't fit, use min size and original ascent
ascent = cons.ascent;
r.width = cons.minWidth;
r.height = cons.minHeight;
}
}
// Reset the components y location based on
// components ascent and baseline for row. Because ascent
// includes the baseline
r.y = cellY + baseline - ascent + cons.insets.top;
if (cons.isVerticallyResizable()) {
switch(cons.baselineResizeBehavior) {
case CONSTANT_ASCENT:
r.height = Math.max(cons.minHeight,cellY + cellHeight -
r.y - cons.insets.bottom);
break;
case CENTER_OFFSET:
{
int upper = r.y - cellY - cons.insets.top;
int lower = cellY + cellHeight - r.y -
cons.minHeight - cons.insets.bottom;
int delta = Math.min(upper, lower);
delta += delta;
if (delta > 0 &&
(cons.minHeight + cons.centerPadding +
delta) / 2 + cons.centerOffset != baseline) {
// Off by 1
delta--;
}
r.height = cons.minHeight + delta;
r.y = cellY + baseline -
(r.height + cons.centerPadding) / 2 -
cons.centerOffset;
}
break;
case OTHER:
// Handled above
break;
default:
break;
}
}
}
}
else {
centerVertically(cons, r, cellHeight);
}
}
/**
* Positions the specified component above the baseline. That is
* the bottom edge of the component will be aligned along the baseline.
* If the row does not have a baseline, this centers the component.
*/
private void alignAboveBaseline(GridBagConstraints cons, Rectangle r,
int cellY, int cellHeight) {
if (layoutInfo.hasBaseline(cons.tempY)) {
int maxY; // Baseline for the row
if (layoutInfo.hasConstantDescent(cons.tempY)) {
// Prefer descent
maxY = cellY + cellHeight - layoutInfo.maxDescent[cons.tempY];
}
else {
// Prefer ascent
maxY = cellY + layoutInfo.maxAscent[cons.tempY];
}
if (cons.isVerticallyResizable()) {
// Component is resizable. Top edge is offset by top
// inset, bottom edge on baseline.
r.y = cellY + cons.insets.top;
r.height = maxY - r.y;
}
else {
// Not resizable.
r.height = cons.minHeight + cons.ipady;
r.y = maxY - r.height;
}
}
else {
centerVertically(cons, r, cellHeight);
}
}
/**
* Positions below the baseline.
*/
private void alignBelowBaseline(GridBagConstraints cons, Rectangle r,
int cellY, int cellHeight) {
if (layoutInfo.hasBaseline(cons.tempY)) {
if (layoutInfo.hasConstantDescent(cons.tempY)) {
// Prefer descent
r.y = cellY + cellHeight - layoutInfo.maxDescent[cons.tempY];
}
else {
// Prefer ascent
r.y = cellY + layoutInfo.maxAscent[cons.tempY];
}
if (cons.isVerticallyResizable()) {
r.height = cellY + cellHeight - r.y - cons.insets.bottom;
}
}
else {
centerVertically(cons, r, cellHeight);
}
}
private void centerVertically(GridBagConstraints cons, Rectangle r,
int cellHeight) {
if (!cons.isVerticallyResizable()) {
r.y += Math.max(0, (cellHeight - cons.insets.top -
cons.insets.bottom - cons.minHeight -
cons.ipady) / 2);
}
}
/**
* Figures out the minimum size of the
* master based on the information from <code>getLayoutInfo.
* This method should only be used internally by
* <code>GridBagLayout.
*
* @param parent the layout container
* @param info the layout info for this parent
* @return a <code>Dimension object containing the
* minimum size
* @since 1.4
*/
protected Dimension getMinSize(Container parent, GridBagLayoutInfo info) {
return GetMinSize(parent, info);
}
/**
* This method is obsolete and supplied for backwards
* compatibility only; new code should call {@link
* #getMinSize(java.awt.Container, GridBagLayoutInfo) getMinSize} instead.
* This method is the same as <code>getMinSize;
* refer to <code>getMinSize for details on parameters
* and return value.
*/
protected Dimension GetMinSize(Container parent, GridBagLayoutInfo info) {
Dimension d = new Dimension();
int i, t;
Insets insets = parent.getInsets();
t = 0;
for(i = 0; i < info.width; i++)
t += info.minWidth[i];
d.width = t + insets.left + insets.right;
t = 0;
for(i = 0; i < info.height; i++)
t += info.minHeight[i];
d.height = t + insets.top + insets.bottom;
return d;
}
transient boolean rightToLeft = false;
/**
* Lays out the grid.
* This method should only be used internally by
* <code>GridBagLayout.
*
* @param parent the layout container
* @since 1.4
*/
protected void arrangeGrid(Container parent) {
ArrangeGrid(parent);
}
/**
* This method is obsolete and supplied for backwards
* compatibility only; new code should call {@link
* #arrangeGrid(Container) arrangeGrid} instead.
* This method is the same as <code>arrangeGrid;
* refer to <code>arrangeGrid for details on the
* parameter.
*/
protected void ArrangeGrid(Container parent) {
Component comp;
int compindex;
GridBagConstraints constraints;
Insets insets = parent.getInsets();
Component components[] = parent.getComponents();
Dimension d;
Rectangle r = new Rectangle();
int i, diffw, diffh;
double weight;
GridBagLayoutInfo info;
rightToLeft = !parent.getComponentOrientation().isLeftToRight();
/*
* If the parent has no slaves anymore, then don't do anything
* at all: just leave the parent's size as-is.
*/
if (components.length == 0 &&
(columnWidths == null || columnWidths.length == 0) &&
(rowHeights == null || rowHeights.length == 0)) {
return;
}
/*
* Pass #1: scan all the slaves to figure out the total amount
* of space needed.
*/
info = getLayoutInfo(parent, PREFERREDSIZE);
d = getMinSize(parent, info);
if (parent.width < d.width || parent.height < d.height) {
info = getLayoutInfo(parent, MINSIZE);
d = getMinSize(parent, info);
}
layoutInfo = info;
r.width = d.width;
r.height = d.height;
/*
* DEBUG
*
* DumpLayoutInfo(info);
* for (compindex = 0 ; compindex < components.length ; compindex++) {
* comp = components[compindex];
* if (!comp.isVisible())
* continue;
* constraints = lookupConstraints(comp);
* DumpConstraints(constraints);
* }
* System.out.println("minSize " + r.width + " " + r.height);
*/
/*
* If the current dimensions of the window don't match the desired
* dimensions, then adjust the minWidth and minHeight arrays
* according to the weights.
*/
diffw = parent.width - r.width;
if (diffw != 0) {
weight = 0.0;
for (i = 0; i < info.width; i++)
weight += info.weightX[i];
if (weight > 0.0) {
for (i = 0; i < info.width; i++) {
int dx = (int)(( ((double)diffw) * info.weightX[i]) / weight);
info.minWidth[i] += dx;
r.width += dx;
if (info.minWidth[i] < 0) {
r.width -= info.minWidth[i];
info.minWidth[i] = 0;
}
}
}
diffw = parent.width - r.width;
}
else {
diffw = 0;
}
diffh = parent.height - r.height;
if (diffh != 0) {
weight = 0.0;
for (i = 0; i < info.height; i++)
weight += info.weightY[i];
if (weight > 0.0) {
for (i = 0; i < info.height; i++) {
int dy = (int)(( ((double)diffh) * info.weightY[i]) / weight);
info.minHeight[i] += dy;
r.height += dy;
if (info.minHeight[i] < 0) {
r.height -= info.minHeight[i];
info.minHeight[i] = 0;
}
}
}
diffh = parent.height - r.height;
}
else {
diffh = 0;
}
/*
* DEBUG
*
* System.out.println("Re-adjusted:");
* DumpLayoutInfo(info);
*/
/*
* Now do the actual layout of the slaves using the layout information
* that has been collected.
*/
info.startx = diffw/2 + insets.left;
info.starty = diffh/2 + insets.top;
for (compindex = 0 ; compindex < components.length ; compindex++) {
comp = components[compindex];
if (!comp.isVisible()){
continue;
}
constraints = lookupConstraints(comp);
if (!rightToLeft) {
r.x = info.startx;
for(i = 0; i < constraints.tempX; i++)
r.x += info.minWidth[i];
} else {
r.x = parent.width - (diffw/2 + insets.right);
for(i = 0; i < constraints.tempX; i++)
r.x -= info.minWidth[i];
}
r.y = info.starty;
for(i = 0; i < constraints.tempY; i++)
r.y += info.minHeight[i];
r.width = 0;
for(i = constraints.tempX;
i < (constraints.tempX + constraints.tempWidth);
i++) {
r.width += info.minWidth[i];
}
r.height = 0;
for(i = constraints.tempY;
i < (constraints.tempY + constraints.tempHeight);
i++) {
r.height += info.minHeight[i];
}
componentAdjusting = comp;
adjustForGravity(constraints, r);
/* fix for 4408108 - components were being created outside of the container */
/* fix for 4969409 "-" replaced by "+" */
if (r.x < 0) {
r.width += r.x;
r.x = 0;
}
if (r.y < 0) {
r.height += r.y;
r.y = 0;
}
/*
* If the window is too small to be interesting then
* unmap it. Otherwise configure it and then make sure
* it's mapped.
*/
if ((r.width <= 0) || (r.height <= 0)) {
comp.setBounds(0, 0, 0, 0);
}
else {
if (comp.x != r.x || comp.y != r.y ||
comp.width != r.width || comp.height != r.height) {
comp.setBounds(r.x, r.y, r.width, r.height);
}
}
}
}
// Added for serial backwards compatibility (4348425)
static final long serialVersionUID = 8838754796412211005L;
}
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