Composite Widgets and Their Children
Composite widgets (widgets whose class is a subclass of
compositeWidgetClass)
can have an arbitrary number of children.
Consequently, they are responsible for much more than primitive widgets.
Their responsibilities (either implemented directly by the widget class
or indirectly by Intrinsics functions) include:
Overall management of children from creation to destruction.
Destruction of descendants when the composite widget is destroyed.
Physical arrangement (geometry management) of a displayable subset of
children (that is, the managed children).
Mapping and unmapping of a subset of the managed children.
Overall management is handled by the generic procedures
and
.
adds children to their parent by calling the parent's insert_child
procedure.
removes children from their parent by calling the parent's delete_child
procedure and ensures that all children of a destroyed composite widget
also get destroyed.
Only a subset of the total number of children is actually managed by
the geometry manager and hence possibly visible.
For example, a composite editor widget
supporting multiple editing buffers might allocate one child
widget for each file buffer,
but it might display only a small number of the existing buffers.
Widgets that are in this displayable subset are called managed widgets
and enter into geometry manager calculations.
The other children are called unmanaged widgets
and, by definition, are not mapped by the Intrinsics.
Children are added to and removed from their parent's managed set by using
,
,
,
,
and
,
which notify the parent to recalculate the physical layout of its children
by calling the parent's change_managed procedure.
The
convenience function calls
and
on the result.
Most managed children are mapped,
but some widgets can be in a state where they take up physical space
but do not show anything.
Managed widgets are not mapped automatically
if their map_when_managed field is
False.
The default is
True
and is changed by using
.
Each composite widget class declares a geometry manager,
which is responsible for figuring out where the managed children
should appear within the composite widget's window.
Geometry management techniques fall into four classes:
Fixed boxes
Fixed boxes have a fixed number of children created by the parent.
All these children are managed,
and none ever makes geometry manager requests.
Homogeneous boxes
Homogeneous boxes treat all children equally and apply the same geometry
constraints to each child.
Many clients insert and delete widgets freely.
Heterogeneous boxes
Heterogeneous boxes have a specific location where each child is placed.
This location usually is not specified in pixels,
because the window may be resized, but is expressed rather
in terms of the relationship between a child
and the parent or between the child and other specific children.
The class of heterogeneous boxes is usually a subclass of
Constraint.
Shell boxes
Shell boxes typically have only one child,
and the child's size is usually
exactly the size of the shell.
The geometry manager must communicate with the window manager, if it exists,
and the box must also accept
ConfigureNotify
events when the window size is changed by the window manager.
Addition of Children to a Composite Widget: The insert_child Procedure
To add a child to
the parent's list of children, the
function calls the parent's class routine insert_child.
The insert_child procedure pointer in a composite widget is of type
.
typedef void (*XtWidgetProc)
Widget w
w
Passes the newly created child.
Most composite widgets inherit their superclass's operation.
The insert_child routine in
CompositeWidgetClass calls the insert_position procedure
and inserts the child at the specified position
in the children list, expanding it if necessary.
Some composite widgets define their own insert_child routine
so that they can order their children in some convenient way,
create companion controller widgets for a new widget,
or limit the number or class of their child widgets.
A composite widget class that wishes
to allow nonwidget children (see ) must specify a
CompositeClassExtension
extension record as described
in
and set the accepts_objects field in this record to
True.
If the
CompositeClassExtension
record is not specified or the
accepts_objects field is
False,
the composite widget can assume that all its children are of a subclass of Core
without an explicit subclass test in the insert_child procedure.
If there is not enough room to insert a new child in the children array
(that is, num_children is equal to num_slots),
the insert_child procedure must first reallocate the array
and update num_slots.
The insert_child procedure then places the child at the appropriate position
in the array and increments the num_children field.
Insertion Order of Children: The insert_position Procedure
Instances of composite widgets sometimes need to specify more about the order in which
their children are kept.
For example,
an application may want a set of command buttons in some logical order
grouped by function,
and it may want buttons that represent file names to be kept
in alphabetical order without constraining the order in which the
buttons are created.
An application controls the presentation order of a set of children by
supplying an
XtNinsertPosition
resource.
The insert_position procedure pointer in a composite widget instance is of type
.
typedef Cardinal (*XtOrderProc)
Widget w
w
Passes the newly created widget.
Composite widgets that allow clients to order their children (usually
homogeneous boxes) can call their widget instance's insert_position
procedure from the class's insert_child procedure to determine where a new
child should go in its children array.
Thus, a client using a composite class can apply different sorting criteria
to widget instances of the class, passing in a different insert_position
procedure resource when it creates each composite widget instance.
The return value of the insert_position procedure
indicates how many children should go before the widget.
Returning zero indicates that the widget should go before all other children,
and returning num_children indicates that it should go after all other children.
The default insert_position function returns num_children
and can be overridden by a specific composite widget's resource list
or by the argument list provided when the composite widget is created.
Deletion of Children: The delete_child Procedure
To remove the child from the parent's children list, the
function eventually causes a call to the Composite parent's class delete_child
procedure.
The delete_child procedure pointer is of type
.
typedef void (*XtWidgetProc)
Widget w
w
Passes the child being deleted.
Most widgets inherit the delete_child procedure from their superclass.
Composite widgets that create companion widgets define their own
delete_child procedure to remove these companion widgets.
Adding and Removing Children from the Managed Set
The Intrinsics provide a set of generic routines to permit the addition of
widgets to or the removal of widgets from a composite widget's managed set.
These generic routines eventually call the composite widget's change_managed
procedure if the procedure pointer is non-NULL.
The change_managed procedure pointer is of type
.
The widget argument specifies the composite widget whose managed child
set has been modified.
Managing Children
To add a list of widgets to the geometry-managed (and hence displayable)
subset of their Composite parent, use
.
typedef Widget *WidgetList;
void XtManageChildren
WidgetList children
Cardinal num_children
children
Specifies a list of child widgets. Each child must be of class
RectObj or any subclass thereof.
num_children
Specifies the number of children in the list.
The
function performs the following:
Issues an error if the children do not all have the same parent or
if the parent's class is not a subclass of
compositeWidgetClass.
Returns immediately if the common parent is being destroyed;
otherwise, for each unique child on the list,
ignores the child if it already is managed or is being destroyed,
and marks it if not.
If the parent is realized and after all children have been marked,
it makes some of the newly managed children viewable:
Calls the change_managed routine of the widgets' parent.
Calls
on each previously unmanaged child that is unrealized.
Maps each previously unmanaged child that has map_when_managed
True.
Managing children is independent of the ordering of children and
independent of creating and deleting children.
The layout routine of the parent
should consider children whose managed field is
True
and should ignore all other children.
Note that some composite widgets, especially fixed boxes, call
from their insert_child procedure.
If the parent widget is realized,
its change_managed procedure is called to notify it
that its set of managed children has changed.
The parent can reposition and resize any of its children.
It moves each child as needed by calling
,
which first updates the x and y fields and which then calls
XMoveWindow.
If the composite widget wishes to change the size or border width of any of
its children, it calls
,
which first updates the
width, height, and border_width
fields and then calls
XConfigureWindow.
Simultaneous repositioning and resizing may be done with
;
see .
To add a single child to its parent widget's set of managed children, use
.
void XtManageChild
Widget child
child
Specifies the child. Must be of class RectObj or any subclass thereof.
The
function constructs a
WidgetList
of length 1 and calls
.
To create and manage a child widget in a single procedure, use
or
.
Widget XtCreateManagedWidget
const char * name
WidgetClass widget_class
Widget parent
ArgList args
Cardinal num_args
name
Specifies the resource instance name for the created widget.
widget_class
Specifies the widget class pointer for the created widget. (rC
parent
Specifies the parent widget. Must be of class Composite or any
subclass thereof.
args
Specifies the argument list to override any other resource specifications.
num_args
Specifies the number of entries in the argument list.
The
function is a convenience routine that calls
and
.
Widget XtVaCreateManagedWidget
const char * name
WidgetClass widget_class
Widget parent
...
name
Specifies the resource instance name for the created widget.
widget_class
Specifies the widget class pointer for the created widget. (rC
parent
Specifies the parent widget. Must be of class Composite or any
subclass thereof.
...
Specifies the variable argument list to override any other
resource specifications.
is identical in function to
with the args and num_args parameters replaced
by a varargs list, as described in Section 2.5.1.
Unmanaging Children
To remove a list of children from a parent widget's managed list, use
.
void XtUnmanageChildren
WidgetList children
Cardinal num_children
children
Specifies a list of child widgets. Each child must be of class
RectObj or any subclass thereof.
num_children
Specifies the number of children.
The
function performs the following:
Returns immediately if the common parent is being destroyed.
Issues an error if the children do not all have the same parent
or if the parent is not a subclass of
compositeWidgetClass.
For each unique child on the list,
ignores the child if it is unmanaged; otherwise it performs the following:
Marks the child as unmanaged.
If the child is realized and the map_when_managed field is
True,
it is unmapped.
If the parent is realized and if any children have become unmanaged,
calls the change_managed routine of the widgets' parent.
does not destroy the child widgets.
Removing widgets from a parent's managed set is often a temporary banishment,
and some time later the client may manage the children again.
To destroy widgets entirely,
should be called instead;
see .
To remove a single child from its parent widget's managed set, use
.
void XtUnmanageChild
Widget child
child
Specifies the child. Must be of class RectObj or any subclass thereof.
The
function constructs a widget list
of length 1 and calls
.
These functions are low-level routines that are used by generic
composite widget building routines.
In addition, composite widgets can provide widget-specific,
high-level convenience procedures.
Bundling Changes to the Managed Set
A client may simultaneously unmanage and manage children
with a single call to the Intrinsics. In this same call the
client may provide a callback procedure that can modify the
geometries of one or more children. The composite widget class
defines whether this single client call results in separate invocations
of the change_managed method, one to unmanage and the other to
manage, or in just a single invocation.
To simultaneously remove from and add to the geometry-managed
set of children of a composite parent, use
.
void XtChangeManagedSet
WidgetList unmanage_children
Cardinal num_unmanage_children
XtDoChangeProc do_change_proc
XtPointer client_data
WidgetList manage_children
Cardinal num_manage_children
unmanage_children
Specifies the list of widget children to initially remove from the managed set.
num_unmanage_children
Specifies the number of entries in the unmanage_children list.
do_change_proc
Specifies a procedure to invoke between unmanaging
and managing the children, or NULL.
client_data
Specifies client data to be passed to the do_change_proc.
manage_children
Specifies the list of widget children to finally add to the managed set.
num_manage_children
Specifies the number of entries in the manage_children list.
The
function performs the following:
Returns immediately if num_unmanage_children and
num_manage_children are both 0.
Issues a warning and returns if the widgets specified in the
manage_children and
the unmanage_children lists do not all have the same parent or if
that parent is not a subclass of
compositeWidgetClass.
Returns immediately if the common parent is being destroyed.
If do_change_proc is not NULL and the parent's
CompositeClassExtension
allows_change_managed_set field is
False,
then
performs the following:
Calls
(unmanage_children, num_unmanage_children).
Calls the do_change_proc.
Calls
(manage_children, num_manage_children).
Otherwise, the following is performed:
For each child on the unmanage_children list; if the child is
already unmanaged it is ignored, otherwise it is marked as unmanaged,
and if it is realized and its map_when_managed field is
True,
it is unmapped.
If do_change_proc is non-NULL, the procedure is invoked.
For each child on the manage_children list; if the child is already
managed or is being destroyed, it is ignored; otherwise it is
marked as managed.
If the parent is realized and after all children have been marked,
the change_managed method of the parent is invoked, and subsequently
some of the newly managed children are made viewable by calling
on each previously unmanaged child that is unrealized and
mapping each previously unmanaged child that has map_when_managed
True.
If no
CompositeClassExtension
record is found in the parent's composite class part extension field
with record type
NULLQUARK
and version greater than 1, and if
XtInheritChangeManaged
was specified in the parent's class record during class initialization,
the value of the allows_change_managed_set
field is inherited from the superclass. The value inherited from
compositeWidgetClass
for the allows_change_managed_set field is
False.
It is not an error to include a child in both the unmanage_children
and the manage_children lists. The effect of such a call is that
the child remains managed following the call, but the do_change_proc is
able to affect the child while it is in an unmanaged state.
The do_change_proc is of type
.
typedef void *XtDoChangeProc
Widget composite_parent
WidgetList unmange_children
Cardinal *num_unmanage_children
WidgetList manage_children
Cardinal *num_manage_children
XtPointer client_data
composite_parent
Passes the composite parent whose managed set is being altered.
unmanage_children
Passes the list of children just removed from the managed set.
num_unmanage_children
Passes the number of entries in the unmanage_children list.
manage_children
Passes the list of children about to be added to the managed set.
num_manage_children
Passes the number of entries in the manage_children list.
client_data
Passes the client data passed to
.
The do_change_proc procedure is used by the caller of
to make changes to one or more children at the point when the
managed set contains the fewest entries. These changes may
involve geometry requests, and in this case the caller of
may take advantage of the fact that the Intrinsics internally grant
geometry requests made by unmanaged children without invoking
the parent's geometry manager. To achieve this advantage, if
the do_change_proc procedure
changes the geometry of a child or of a descendant of a child, then
that child should be included in the unmanage_children and
manage_children lists.
Determining if a Widget Is Managed
To determine the managed state of a given child widget, use
.
Boolean XtIsManaged
Widget w
w
Specifies the widget. Must be of class Object or any subclass thereof.
The
function returns
True
if the specified widget is of class RectObj or any subclass thereof
and is managed, or
False
otherwise.
Controlling When Widgets Get Mapped
A widget is normally mapped if it is managed.
However,
this behavior can be overridden by setting the XtNmappedWhenManaged resource
for the widget when it is created
or by setting the map_when_managed field to
False.
To change the value of a given widget's map_when_managed field, use
.
void XtSetMappedWhenManaged
Widget w
Boolean map_when_managed
w
Specifies the widget. Must be of class Core or any subclass thereof.
map_when_managed
Specifies a Boolean value that indicates the new value
that is stored into the widget's map_when_managed
field.
If the widget is realized and managed,
and if map_when_managed is
True,
maps the window.
If the widget is realized and managed,
and if map_when_managed is
False,
it unmaps the window.
is a convenience function that is equivalent to (but slightly faster than)
calling
and setting the new value for the XtNmappedWhenManaged resource
then mapping the widget as appropriate.
As an alternative to using
to control mapping,
a client may set mapped_when_managed to
False
and use
and
explicitly.
To map a widget explicitly, use
.
void XtMapWidget
Widget w
w
Specifies the widget. Must be of class Core or any subclass thereof.
To unmap a widget explicitly, use
.
void XtUnmapWidget
Widget w
w
Specifies the widget. Must be of class Core or any subclass thereof.
Constrained Composite Widgets
The Constraint
widget class is a subclass of
compositeWidgetClass.
The name is derived from the fact that constraint widgets
may manage the geometry
of their children based on constraints associated with each child.
These constraints can be as simple as the maximum width and height
the parent will allow the child to occupy or can be as complicated as
how other children should change if this child is moved or resized.
Constraint
widgets let a parent define constraints as resources that are supplied for their children.
For example, if the
Constraint
parent defines the maximum sizes for its children,
these new size resources are retrieved for each child as if they were
resources that were defined by the child widget's class.
Accordingly,
constraint resources may be included in the argument list or resource file just
like any other resource for the child.
Constraint
widgets have all the responsibilities of normal composite widgets
and, in addition, must process and act upon the constraint information
associated with each of their children.
To make it easy for widgets and the Intrinsics to keep track of the
constraints associated with a child,
every widget has a constraints field,
which is the address of a parent-specific structure that contains
constraint information about the child.
If a child's parent does not belong to a subclass of
constraintWidgetClass,
then the child's constraints field is NULL.
Subclasses of
Constraint
can add constraint data to the constraint record defined by their superclass.
To allow this, widget writers should define the constraint
records in their private .h file by using the same conventions as used for
widget records.
For example, a widget class that needs to maintain a maximum
width and height for each child might define its constraint record as
follows:
typedef struct {
Dimension max_width, max_height;
} MaxConstraintPart;
typedef struct {
MaxConstraintPart max;
} MaxConstraintRecord, *MaxConstraint;
A subclass of this widget class that also needs to maintain a minimum size would
define its constraint record as follows:
typedef struct {
Dimension min_width, min_height;
} MinConstraintPart;
typedef struct {
MaxConstraintPart max;
MinConstraintPart min;
} MaxMinConstraintRecord, *MaxMinConstraint;
Constraints are allocated, initialized, deallocated, and otherwise maintained
insofar as possible by the Intrinsics.
The Constraint class record part has several entries that facilitate this.
All entries in
ConstraintClassPart
are fields and procedures that are defined and implemented by the parent,
but they are called whenever actions are performed on the parent's children.
The
function uses the constraint_size field in the parent's class record
to allocate a constraint record when a child is created.
also uses the constraint resources to fill in resource fields in the
constraint record associated with a child.
It then calls the constraint initialize procedure so that the parent
can compute constraint fields that are derived from constraint resources
and can possibly move or resize the child to conform to the given constraints.
When the
and
functions are executed
on a child, they use the constraint resources to get the values or
set the values of constraints associated with that child.
then calls the constraint set_values procedures so that the parent can
recompute derived constraint fields and move or resize the child
as appropriate.
If a
Constraint
widget class or any of its superclasses have declared a
ConstraintClassExtension
record in the
ConstraintClassPart
extension
fields with a record type of
NULLQUARK
and the get_values_hook field in
the extension record is non-NULL,
calls the get_values_hook
procedure(s) to allow the parent to return derived constraint fields.
The
function calls the constraint destroy procedure to deallocate any
dynamic storage associated with a constraint record.
The constraint record itself must not be deallocated by the constraint
destroy procedure;
does this automatically.