Widget Instantiation
A hierarchy of widget instances constitutes a widget tree.
The shell widget returned by
is the root of the widget tree instance.
The widgets with one or more children are the intermediate nodes of that tree,
and the widgets with no children of any kind are the leaves of the widget tree.
With the exception of pop-up children (see ),
this widget tree instance defines the associated X Window tree.
Widgets can be either composite or primitive.
Both kinds of widgets can contain children,
but the Intrinsics provide a set of management mechanisms for constructing
and interfacing between composite widgets, their children, and
other clients.
Composite widgets, that is, members of the class
compositeWidgetClass,
are containers for an arbitrary,
but widget implementation-defined, collection of children,
which may be instantiated by the composite widget itself,
by other clients, or by a combination of the two.
Composite widgets also contain methods for managing the geometry (layout)
of any child widget.
Under unusual circumstances,
a composite widget may have zero children,
but it usually has at least one.
By contrast,
primitive widgets that contain children typically instantiate
specific children of known classes themselves and do not expect external
clients to do so.
Primitive widgets also do not have general geometry management methods.
In addition,
the Intrinsics recursively perform many operations
(for example, realization and destruction)
on composite widgets and all their children.
Primitive widgets that have children must be prepared
to perform the recursive operations themselves on behalf of their children.
A widget tree is manipulated by several Intrinsics functions.
For example,
traverses the tree downward and recursively realizes all
pop-up widgets and children of composite widgets.
traverses the tree downward and destroys all pop-up widgets
and children of composite widgets.
The functions that fetch and modify resources traverse the tree upward
and determine the inheritance of resources from a widget's ancestors.
traverses the tree up one level and calls the geometry manager
that is responsible for a widget child's geometry.
To facilitate upward traversal of the widget tree,
each widget has a pointer to its parent widget.
The
Shell
widget that
returns has a parent pointer of NULL.
To facilitate downward traversal of the widget tree,
the children field of
each composite widget is a pointer to an array of child widgets,
which includes all normal children created,
not just the subset of children that are managed by the composite widget's
geometry manager.
Primitive widgets
that instantiate children are entirely responsible for all operations
that require downward traversal below themselves.
In addition,
every widget has a pointer to an array of pop-up children.
Initializing the X Toolkit
Before an application can call any Intrinsics function
other than
XtSetLanguageProc
and
,
it must initialize the Intrinsics by using
,
which initializes the Intrinsics internals
,
which initializes the per-application state
or
,
which initializes the per-display state
,
which creates the root of a widget tree
Or an application can call the convenience procedure
,
which combines the functions of the preceding procedures.
An application wishing to use the ANSI C locale mechanism should call
XtSetLanguageProc
prior to calling
,
,
,
or
.
Multiple instances of X Toolkit applications may be implemented
in a single address space.
Each instance needs to be able to read
input and dispatch events independently of any other instance.
Further, an application instance may need multiple display connections
to have widgets on multiple displays.
From the application's point of view, multiple display connections
usually are treated together as a single unit
for purposes of event dispatching.
To accommodate both requirements,
the Intrinsics define application contexts,
each of which provides the information needed to distinguish one application
instance from another.
The major component of an application context is a list of one or more X
Display
pointers for that application.
The Intrinsics handle all display connections within a single application
context simultaneously, handling input in a round-robin fashion.
The application context type
XtAppContext
is opaque to clients.
To initialize the Intrinsics internals, use
.
void XtToolkitInitialize
void
If
was previously called, it returns immediately.
When
is called before
,
the latter is protected against
simultaneous activation by multiple threads.
To create an application context, use
.
XtAppContext XtCreateApplicationContext
void
The
function returns an application context,
which is an opaque type.
Every application must have at least one application context.
To destroy an application context and close any
remaining display connections in it, use
.
void XtDestroyApplicationContext
XtAppContext app_context
app_context
Specifies the application context.
The
function destroys the specified application context.
If called from within an event dispatch (for example, in a callback procedure),
does not destroy the application context until the dispatch is complete.
To get the application context in which a given widget was created, use
.
XtAppContext XtWidgetToApplicationContext
Widget w
w
Specifies the widget for which you want the application context. Must be of class Object or any subclass thereof.
The
function returns the application context for the specified widget.
To initialize a display and add it to an application context, use
.
void XtDisplayInitialize
XtAppContext app_context
Display * display
const char * application_name
const char * application_class
XrmOptionDescRec * options
Cardinal num_options
int * argc
char ** argv
app_context
Specifies the application context.
display
Specifies a previously opened display connection. Note that a single
display connection can be in at most one application context.
application_name
Specifies the name of the application instance.
application_class
Specifies the class name of this application,
which is usually the generic name for all instances of this application.
options
Specifies how to parse the command line for any application-specific resources.
The options argument is passed as a parameter to
XrmParseCommand.
For further information,
see Parsing Command Line Options in Xlib — C Language X Interface and of this specification.
num_options
Specifies the number of entries in the options list.
argc
Specifies a pointer to the number of command line parameters.
argv
Specifies the list of command line parameters.
The
function retrieves the language string to be
used for the specified display (see ),
calls the language procedure (if set) with that language string,
builds the resource database for the default screen, calls the Xlib
XrmParseCommand
function to parse the command line,
and performs other per-display initialization.
After
XrmParseCommand
has been called,
argc and argv contain only those parameters that
were not in the standard option table or in the table specified by the
options argument.
If the modified argc is not zero,
most applications simply print out the modified argv along with a message
listing the allowable options.
On POSIX-based systems,
the application name is usually the final component of argv[0].
If the synchronous resource is
True,
calls the Xlib
XSynchronize
function to put Xlib into synchronous mode for this display connection
and any others currently open in the application context.
See
and
for details on the application_name,
application_class, options, and num_options arguments.
calls
XrmSetDatabase
to associate the resource database of the default screen with the
display before returning.
To open a display, initialize it, and then
add it to an application context, use
.
Display *XtOpenDisplay
XtAppContext app_context
const char * display_string
const char * application_name
const char * application_class
XrmOptionDescRec * options
Cardinal num_options
int * argc
char ** argv
app_context
Specifies the application context.
display_string
Specifies the display string, or NULL.
application_name
Specifies the name of the application instance, or NULL.
application_class
Specifies the class name of this application,
which is usually the generic name for all instances of this application.
options
Specifies how to parse the command line for any application-specific resources.
The options argument is passed as a parameter to
XrmParseCommand.
num_options
Specifies the number of entries in the options list.
argc
Specifies a pointer to the number of command line parameters.
argv
Specifies the list of command line parameters.
The
function calls
XOpenDisplay
with the specified display_string.
If display_string is NULL,
uses the current value of the -display option specified in argv.
If no display is specified in argv,
the user's default display is retrieved from the environment.
On POSIX-based systems,
this is the value of the
DISPLAY
environment variable.
If this succeeds,
then calls
and passes it the opened display and
the value of the -name option specified in argv as the application name.
If no -name option is specified
and application_name is
non-NULL, application_name is passed to
.
If application_name is NULL and if the environment variable
RESOURCE_NAME
is set, the value of
RESOURCE_NAME
is used. Otherwise, the application
name is the name used to invoke the program. On implementations that
conform to ANSI C Hosted Environment support, the application name will
be argv[0] less any directory and file type components, that is, the
final component of argv[0], if specified. If argv[0] does not exist or
is the empty string, the application name is “main”.
returns the newly opened display or NULL if it failed.
See
for information regarding the use of
in multiple threads.
To close a display and remove it from an application context, use
.
void XtCloseDisplay
Display * display
display
Specifies the display.
The
function calls
XCloseDisplay
with the specified display as soon as it is safe to do so.
If called from within an event dispatch (for example, a callback procedure),
does not close the display until the dispatch is complete.
Note that applications need only call
if they are to continue executing after closing the display;
otherwise, they should call
.
See
for information regarding the use of
in multiple threads.
Establishing the Locale
Resource databases are specified to be created in the current process
locale. During display initialization prior to creating the
per-screen resource database, the Intrinsics will call out to a specified
application procedure to set the locale according to options found on
the command line or in the per-display resource specifications.
The callout procedure provided by the application is of type
XtLanguageProc.
typedef String (*XtLanguageProc)
Display display
String language
XtPointer client_data
display
Passes the display.
language
Passes the initial language value obtained from the command line
or server per-display resource specifications.
client_data
Passes the additional client data specified in the call to
XtSetLanguageProc.
The language procedure allows an application to set the locale to
the value of the language resource determined by
.
The function returns a new language string that
will be subsequently used by
to establish the path for loading resource files. The returned
string will be copied by the Intrinsics into new memory.
Initially, no language procedure is set by the Intrinsics.
To set the language procedure for use by
,
use
XtSetLanguageProc.
XtLanguageProc XtSetLanguageProc
XtAppContext app_context
XtLanguageProc proc
XtPointer client_data
app_context
Specifies the application context in which the language procedure is
to be used, or NULL.
proc
Specifies the language procedure.
client_data
Specifies additional client data to be passed to the language
procedure when it is called.
XtSetLanguageProc
sets the language procedure that will be called from
for all subsequent Displays initialized in the specified application
context. If app_context is NULL, the specified language
procedure is registered in all application contexts created by the
calling process, including any future application contexts that may
be created. If proc is NULL, a default language procedure is
registered.
XtSetLanguageProc
returns the previously registered language procedure.
If a language procedure has not yet been registered, the return value
is unspecified, but if this return value is used in a subsequent call to
XtSetLanguageProc,
it will cause the default language procedure to be registered.
The default language procedure does the following:
Sets the locale according to the environment. On ANSI C-based
systems this is done by calling
setlocale(
LC_ALL,
language ).
If an error is encountered, a warning message is issued with
.
Calls
XSupportsLocale
to verify that the current locale is supported.
If the locale is not supported, a warning message is issued with
and the locale is set to “C”.
Calls
XSetLocaleModifiers
specifying the empty string.
Returns the value of the current locale. On ANSI C-based systems this
is the return value from a final call to
setlocale(
LC_ALL,
NULL ).
A client wishing to use this mechanism to establish locale can do so
by calling
XtSetLanguageProc
prior to
,
as in the following example.
Widget top;
XtSetLanguageProc(NULL, NULL, NULL);
top = XtOpenApplication(...);
...
Loading the Resource Database
The
function first determines the language
string to be used for the specified display. It then
creates a resource database for the default screen of the display by
combining the following sources in order, with the entries in the
first named source having highest precedence:
Application command line (argc, argv).
Per-host user environment resource file on the local host.
Per-screen resource specifications from the server.
Per-display resource specifications from the server or from
the user preference file on the local host.
Application-specific user resource file on the local host.
Application-specific class resource file on the local host.
When the resource database for a particular screen on the display
is needed (either internally, or when
is called),
it is created in the following manner using the sources listed
above in the same order:
A temporary database, the “server resource database”, is
created from the string returned by
XResourceManagerString
or, if
XResourceManagerString
returns NULL, the contents of a resource file in the user's home
directory. On POSIX-based systems, the usual name for this user
preference resource file is $HOME/.Xdefaults.
If a language procedure has been set,
first searches the command line for the option “-xnlLanguage”, or
for a -xrm option that specifies the xnlLanguage/XnlLanguage resource,
as specified by Section 2.4.
If such a resource is found, the value is assumed to be
entirely in XPCS, the X Portable Character Set. If neither option is
specified on the command line,
queries the server resource database (which is assumed to be entirely
in XPCS) for the resource
name.xnlLanguage, class Class.XnlLanguage
where name
and Class are the application_name and
application_class specified to
.
The language procedure is then invoked with
the resource value if found, else the empty string. The
string returned from the language procedure is saved for all future
references in the Intrinsics that require the per-display language string.
The screen resource database is initialized by parsing the command
line in the manner specified by Section 2.4.
If a language procedure has not been set,
the initial database is then queried for the resource
name.xnlLanguage, class Class.XnlLanguage
as specified above.
If this database query fails, the server resource database is
queried; if this query also fails, the language is determined from
the environment; on POSIX-based systems, this is done by retrieving the
value of the
LANG
environment variable. If no language string is
found, the empty string is used.
This language string is saved for all future references in the Intrinsics
that require the per-display language string.
After determining the language string, the user's environment resource
file is then merged into the initial resource database if the file exists.
This file is user-, host-, and process-specific and is expected to
contain user preferences that are to override those specifications in
the per-display and per-screen resources.
On POSIX-based systems, the user's environment resource file name is
specified by the value of the
XENVIRONMENT
environment variable.
If this environment variable does not exist, the user's home directory
is searched for a file named
.Xdefaults-host,
where host is the host name of the machine on which the
application is running.
The per-screen resource specifications are then merged into the screen
resource database, if they exist. These specifications are the string
returned by
XScreenResourceString
for the respective screen and are owned entirely by the user.
Next, the server resource database created earlier is merged into the
screen resource database. The server property, and corresponding user
preference file, are owned and constructed entirely by the user.
The application-specific user resource file from the local host is
then merged into the screen resource database.
This file contains user customizations and is stored
in a directory owned by the user.
Either the user or the application or both can store resource specifications
in the file. Each should be prepared to find and respect entries made
by the other.
The file name is found by calling
XrmSetDatabase
with the current screen resource database, after preserving the
original display-associated database, then calling
with the parameters
(display, NULL, NULL, NULL, path, NULL, 0, NULL),
where path is defined in an operating-system-specific way.
On POSIX-based systems, path is defined to be the value
of the environment variable
XUSERFILESEARCHPATH
if this is defined. If
XUSERFILESEARCHPATH
is not defined, an implementation-dependent default value is used.
This default value is constrained in the following manner:
If the environment variable
XAPPLRESDIR
is not defined, the default
XUSERFILESEARCHPATH
must contain at least six entries. These entries must contain
$HOME as the directory prefix, plus the following substitutions:
1. %C, %N, %L or %C, %N, %l, %t, %c
2. %C, %N, %l
3. %C, %N
4. %N, %L or %N, %l, %t, %c
5. %N, %l
6. %N
The order of these six entries within the path must be as given above.
The order and use of substitutions within a given entry are
implementation-dependent.
If
XAPPLRESDIR
is defined, the default
XUSERFILESEARCHPATH
must contain at least seven entries. These entries must contain the
following directory prefixes and substitutions:
1. $XAPPLRESDIR with %C, %N, %L or %C, %N, %l, %t, %c
2. $XAPPLRESDIR with %C, %N, %l
3. $XAPPLRESDIR with %C, %N
4. $XAPPLRESDIR with %N, %L or %N, %l, %t, %c
5. $XAPPLRESDIR with %N, %l
6. $XAPPLRESDIR with %N
7. $HOME with %N
The order of these seven entries within the path must be as given above.
The order and use of substitutions within a given entry are
implementation-dependent.
Last, the application-specific class resource file from the local
host is merged into the screen resource database.
This file is owned by the application and is usually installed in
a system directory when the application is installed.
It may contain sitewide customizations specified by the system manager.
The name of the application class resource file is found by calling
with the parameters
(display, “app-defaults”, NULL, NULL, NULL, NULL, 0, NULL).
This file is expected to be provided by the developer of the application
and may be required for the application to function properly.
A simple application that wants to be assured of having a minimal
set of resources in the absence of its class resource file can declare
fallback resource specifications with
.
Note that the customization substitution string is retrieved
dynamically by
so that the resolved file name of the application class resource file
can be affected by any of the earlier sources for the screen resource
database, even though the contents of the class resource file have
lowest precedence. After calling
,
the original display-associated database is restored.
To obtain the resource database for a particular screen, use
.
XrmDatabase XtScreenDatabase
Screen * screen
screen
Specifies the screen whose resource database is to be returned.
The
function returns the fully merged resource database as specified above,
associated with the specified screen. If the specified screen
does not belong to a
Display
initialized by
,
the results are undefined.
To obtain the default resource database associated with a particular display, use
.
XrmDatabase XtDatabase
Display * display
display
Specifies the display.
The
function is equivalent to
XrmGetDatabase.
It returns the database associated with the specified display, or
NULL if a database has not been set.
To specify a default set of resource values that will be used to
initialize the resource database if no application-specific class
resource file is found (the last of the six sources listed above),
use
.
void XtAppSetFallbackResources
XtAppContext app_context
String * specification_list
app_context
Specifies the application context in which
the fallback specifications will be used.
specification_list
Specifies a NULL-terminated list of
resource specifications to preload
the database, or NULL.
Each entry in specification_list points to a string in the format of
XrmPutLineResource.
Following a call to
,
when a resource database is being created for a particular screen and
the Intrinsics are not able
to find or read an application-specific class resource file according to the
rules given above and if specification_list is not NULL, the
resource specifications in specification_list will be merged
into the screen resource database in place of the application-specific
class resource file.
is not
required to copy specification_list; the caller must ensure that the
contents of the list and of the strings addressed by the list remain
valid until all displays are initialized or until
is called again. The value NULL for
specification_list removes any previous fallback resource specification
for the application context. The intended use for fallback resources
is to provide a minimal
number of resources that will make the application usable (or at
least terminate with helpful diagnostic messages) when some problem
exists in finding and loading the application defaults file.
Parsing the Command Line
The
function first parses the command line for the following options:
-display
Specifies the display name for
XOpenDisplay.
-name
Sets the resource name prefix,
which overrides the application name passed to
.
-xnllanguage
Specifies the initial language string for establishing locale
and for finding application class resource files.
has a table of standard command line options that are passed to
XrmParseCommand
for adding resources to the resource database,
and it takes as a parameter additional
application-specific resource abbreviations.
The format of this table is described in Section 15.9 in Xlib — C Language X Interface.
typedef enum {
XrmoptionNoArg, /* Value is specified in OptionDescRec.value */
XrmoptionIsArg, /* Value is the option string itself */
XrmoptionStickyArg, /* Value is characters immediately following option */
XrmoptionSepArg, /* Value is next argument in argv */
XrmoptionResArg, /* Use the next argument as input to XrmPutLineResource*/
XrmoptionSkipArg, /* Ignore this option and the next argument in argv */
XrmoptionSkipNArgs, /* Ignore this option and the next */
/* OptionDescRec.value arguments in argv */
XrmoptionSkipLine /* Ignore this option and the rest of argv */
} XrmOptionKind;
typedef struct {
char *option; /* Option name in argv */
char *specifier; /* Resource name (without application name) */
XrmOptionKind argKind; /* Location of the resource value */
XPointer value; /* Value to provide if XrmoptionNoArg */
} XrmOptionDescRec, *XrmOptionDescList;
The standard table contains the following entries:
Option String
Resource Name
Argument Kind
Resource Value
-background
*background
SepArg
next argument
-bd
*borderColor
SepArg
next argument
-bg
*background
SepArg
next argument
-borderwidth
.borderWidth
SepArg
next argument
-bordercolor
*borderColor
SepArg
next argument
-bw
.borderWidth
SepArg
next argument
-display
.display
SepArg
next argument
-fg
*foreground
SepArg
next argument
-fn
*font
SepArg
next argument
-font
*font
SepArg
next argument
-foreground
*foreground
SepArg
next argument
-geometry
.geometry
SepArg
next argument
-iconic
.iconic
NoArg
"true"
-name
.name
SepArg
next argument
-reverse
.reverseVideo
NoArg
"on"
-rv
.reverseVideo
NoArg
"on"
+rv
.reverseVideo
NoArg
"off"
-selectionTimeout
.selectionTimeout
SepArg
next argument
-synchronous
.synchronous
NoArg
"on"
+synchronous
.synchronous
NoArg
"off"
-title
.title
SepArg
next argument
-xnllanguage
.xnlLanguage
SepArg
next argument
-xrm
next argument
ResArg
next argument
-xtsessionID
.sessionID
SepArg
next argument
Note that any unique abbreviation for an option name in the standard table
or in the application table is accepted.
If reverseVideo is
True,
the values of
XtDefaultForeground
and
XtDefaultBackground
are exchanged for all screens on the Display.
The value of the synchronous resource specifies whether or not
Xlib is put into synchronous mode. If a value is found in the resource
database during display initialization,
makes a call to
XSynchronize
for all display
connections currently open in the application context. Therefore,
when multiple displays are initialized in the same application
context, the most recent value specified for the synchronous resource
is used for all displays in the application context.
The value of the selectionTimeout resource applies to all displays
opened in the same application context. When multiple displays are
initialized in the same application context, the most recent value
specified is used for all displays in the application context.
The -xrm option provides a method of setting any resource in an application.
The next argument should be a quoted string identical in format to a line in
the user resource file.
For example,
to give a red background to all command buttons in an application named
xmh,
you can start it up as
xmh -xrm 'xmh*Command.background: red'
When it parses the command line,
merges the application option table with the standard option table
before calling the Xlib
XrmParseCommand
function.
An entry in the application table with the same name as an entry
in the standard table overrides the standard table entry.
If an option name is a prefix of another option name,
both names are kept in the merged table.
The Intrinsics reserve all option names
beginning with the characters “-xt” for future standard uses.
Creating Widgets
The creation of widget instances is a three-phase process:
The widgets are allocated and initialized with resources
and are optionally added to the managed subset of their parent.
All composite widgets are notified of their managed children
in a bottom-up traversal of the widget tree.
The widgets create X windows, which then are mapped.
To start the first phase,
the application calls
for all its widgets and adds some (usually, most or all) of its widgets
to their respective parents' managed set by calling
.
To avoid an O(n2) creation process where each composite widget
lays itself out each time a widget is created and managed,
parent widgets are not notified of changes in their managed set
during this phase.
After all widgets have been created,
the application calls
with the top-level widget to execute the second and third phases.
first recursively traverses the widget tree in a postorder (bottom-up)
traversal and then notifies each composite widget with one
or more managed children by means of its change_managed procedure.
Notifying a parent about its managed set involves geometry layout and
possibly geometry negotiation.
A parent deals with constraints on its size imposed from above
(for example, when a user specifies the application window size)
and suggestions made from below (for example,
when a primitive child computes its preferred size).
One difference between the two can cause geometry changes to ripple
in both directions through the widget tree.
The parent may force some of its children to change size and position
and may issue geometry requests to its own parent in order to better
accommodate all its children.
You cannot predict where anything will go on the screen
until this process finishes.
Consequently, in the first and second phases,
no X windows are actually created, because it is likely
that they will get moved around after creation.
This avoids unnecessary requests to the X server.
Finally,
starts the third phase by making a preorder (top-down) traversal
of the widget tree, allocates an X window to each widget by means of
its realize procedure, and finally maps the widgets that are managed.
Creating and Merging Argument Lists
Many Intrinsics functions may be passed pairs of resource names and
values.
These are passed as an arglist, a pointer to an array of
Arg
structures, which contains
typedef struct {
String name;
XtArgVal value;
} Arg, *ArgList;
where
XtArgVal
is as defined in Section 1.5.
If the size of the resource is less than or equal to the size of an
XtArgVal,
the resource value is stored directly in value;
otherwise, a pointer to it is stored in value.
To set values in an
ArgList,
use
.
void XtSetArg
Arg arg
String name
XtArgVal value
arg
Specifies the name/value pair to set.
name
Specifies the name of the resource.
value
Specifies the value of the resource if it will fit in an
XtArgVal,
else the address.
The
function is usually used in a highly stylized manner to
minimize the probability of making a mistake; for example:
Arg args[20];
int n;
n = 0;
XtSetArg(args[n], XtNheight, 100); n++;
XtSetArg(args[n], XtNwidth, 200); n++;
XtSetValues(widget, args, n);
Alternatively, an application can statically declare the argument list
and use
:
static Args args[] = {
{XtNheight, (XtArgVal) 100},
{XtNwidth, (XtArgVal) 200},
};
XtSetValues(Widget, args, XtNumber(args));
Note that you should not use expressions with side effects such as
auto-increment or auto-decrement
within the first argument to
.
can be implemented as a macro that evaluates the first argument twice.
To merge two
arglist arrays, use
.
ArgList XtMergeArgLists
ArgList args1
Cardinal num_args1
ArgList args2
Cardinal num_args2
args1
Specifies the first argument list.
num_args1
Specifies the number of entries in the first argument list.
args2
Specifies the second argument list.
num_args2
Specifies the number of entries in the second argument list.
The
function allocates enough storage to hold the combined
arglist arrays and copies them into it.
Note that it does not check for duplicate entries.
The length of the returned list is the sum of the lengths of the
specified lists.
When it is no longer needed,
free the returned storage by using
.
All Intrinsics interfaces that require
ArgList
arguments have analogs
conforming to the ANSI C variable argument list
(traditionally called “varargs”)
calling convention. The name of the analog is formed by prefixing
“Va” to the name of the corresponding
ArgList
procedure; e.g.,
.
Each procedure named XtVasomething takes as its
last arguments, in place of the corresponding
ArgList/
Cardinal
parameters, a variable parameter list of resource name and
value pairs where each name is of type
String
and each value is of type
XtArgVal.
The end of the list is identified by a name entry
containing NULL. Developers writing in the C language wishing to pass
resource name and value pairs to any of these interfaces may use the
ArgList
and varargs forms interchangeably.
Two special names are defined for use only in varargs lists:
XtVaTypedArg
and
XtVaNestedList.
#define XtVaTypedArg "XtVaTypedArg"
If the name
XtVaTypedArg
is specified in place of a resource
name, then the following four arguments are interpreted as a
name/type/value/size tuple where name is of type
String,
type is of type
String,
value is of type
XtArgVal,
and size is of type int. When a varargs list containing
XtVaTypedArg
is processed, a resource type
conversion (see ) is performed if necessary to convert the
value into the format required by the associated resource. If type is
XtRString, then value contains a pointer to the string and size
contains the number of bytes allocated, including the trailing null
byte. If type is not XtRString, then if size is
less than or equal to
sizeof(XtArgVal), the value should be the data cast to the type
XtArgVal,
otherwise value is a pointer to the data. If the type
conversion fails for any reason, a warning message is issued and the
list entry is skipped.
#define XtVaNestedList "XtVaNestedList"
If the name
XtVaNestedList
is specified in place of a resource name,
then the following argument is interpreted as an
XtVarArgsList
value, which specifies another
varargs list that is logically inserted into the original list at the
point of declaration. The end of the nested list is identified with a
name entry containing NULL. Varargs lists may nest to any depth.
To dynamically allocate a varargs list for use with
XtVaNestedList
in multiple calls, use
.
typedef XtPointer XtVarArgsList;
XtVarArgsList XtVaCreateArgsList
XtPointer unused
...
unused
This argument is not currently used and must be specified as NULL.
...
Specifies a variable parameter list of resource
name and value pairs.
The
function allocates memory and copies its arguments into a
single list pointer, which may be used with
XtVaNestedList.
The end of
both lists is identified by a name entry containing NULL. Any entries
of type
XtVaTypedArg
are copied as specified without applying
conversions. Data passed by reference (including Strings) are not
copied, only the pointers themselves; the caller must ensure that the
data remain valid for the lifetime of the created varargs list. The
list should be freed using
when no longer needed.
Use of resource files and of the resource database is generally
encouraged over lengthy arglist or varargs lists whenever possible in
order to permit modification without recompilation.
Creating a Widget Instance
To create an instance of a widget, use
.
Widget XtCreateWidget
const char * name
WidgetClass object_class
Widget parent
ArgList args
Cardinal num_args
name
Specifies the resource instance name for the created widget,
which is used for retrieving resources
and, for that reason, should not be the same as any other widget
that is a child of the same parent.
object_class
Specifies the widget class pointer for the created object. Must be objectClass or any subclass thereof.
parent
Specifies the parent widget. Must be of class Object 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 performs all the boilerplate operations of widget
creation, doing the following in order:
Checks to see if the class_initialize procedure has been called for this class
and for all superclasses and, if not, calls those necessary in a
superclass-to-subclass order.
If the specified class is not
coreWidgetClass
or a subclass thereof,
and the parent's class is a subclass of
compositeWidgetClass
and either no extension record in
the parent's composite class part extension field exists with the
record_type
NULLQUARK
or the accepts_objects field in the extension
record is
False,
issues a fatal error; see and .
If the specified class contains an extension record in the object class
part extension field with record_type
NULLQUARK
and the allocate field is not NULL,
the procedure is invoked to allocate memory
for the widget instance. If the parent is a member of the class
constraintWidgetClass,
the procedure also allocates memory for the
parent's constraints and stores the address of this memory into the
constraints field. If no allocate procedure is found, the Intrinsics
allocate memory for the widget and, when applicable, the constraints,
and initializes the constraints field.
Initializes the Core nonresource data fields
self, parent, widget_class, being_destroyed,
name, managed, window, visible,
popup_list, and num_popups.
Initializes the resource fields (for example, background_pixel)
by using the
CoreClassPart
resource lists specified for this class and all superclasses.
If the parent is a member of the class
constraintWidgetClass,
initializes the resource fields of the constraints record
by using the
ConstraintClassPart
resource lists specified for the parent's class
and all superclasses up to
constraintWidgetClass.
Calls the initialize procedures for the widget starting at the
Object
initialize procedure on down to the widget's initialize procedure.
If the parent is a member of the class
constraintWidgetClass,
calls the
ConstraintClassPart
initialize procedures,
starting at
constraintWidgetClass
on down to the parent's
ConstraintClassPart
initialize procedure.
If the parent is a member of the class
compositeWidgetClass,
puts the widget into its parent's children list by calling its parent's
insert_child procedure.
For further information,
see .
To create an instance of a widget using varargs lists, use
.
Widget XtVaCreateWidget
const char * name
WidgetClass object_class
Widget parent
...
name
Specifies the resource name for the created widget.
object_class
Specifies the widget class pointer for the created object. Must be objectClass or any subclass thereof.
parent
Specifies the parent widget. Must be of class Object or any subclass thereof.
...
Specifies the variable argument list to override any other
resource specifications.
The
procedure is identical in function to
with the args and num_args parameters replaced by a varargs list,
as described
in Section 2.5.1.
Creating an Application Shell Instance
An application can have multiple top-level widgets, each of which
specifies a unique widget tree
that can potentially be on different screens or displays.
An application uses
to create independent widget trees.
Widget XtAppCreateShell
const char * name
const char * application_class
WidgetClass widget_class
Display * display
ArgList args
Cardinal num_args
name
Specifies the instance name of the shell widget.
If name is NULL,
the application name passed to
is used.
application_class
Specifies the resource class string to be used in
place of the widget class_name string when
widget_class is
applicationShellWidgetClass
or a subclass thereof.
widget_class
Specifies the widget class for the top-level widget (e.g.,
applicationShellWidgetClass ).
display
Specifies the display for the default screen
and for the resource database used to retrieve
the shell widget resources.
args
Specifies the argument list to override any other resource specifications.
num_args
Specifies the number of entries in the argument list.
The
function
creates a new shell widget instance as the root of a widget tree.
The screen resource for this widget is determined by first scanning
args for the XtNscreen argument. If no XtNscreen argument is
found, the resource database associated with the default screen of
the specified display is queried for the resource name.screen,
class Class.Screen where Class is the specified
application_class if widget_class is
applicationShellWidgetClass
or a subclass thereof. If widget_class is not
applicationShellWidgetClass
or a subclass, Class is the class_name
field from the
CoreClassPart
of the specified widget_class.
If this query fails, the default
screen of the specified display is used. Once the screen is determined,
the resource database associated with that screen is used to retrieve
all remaining resources for the shell widget not specified in
args. The widget name and Class as determined above are
used as the leftmost (i.e., root) components in all fully qualified
resource names for objects within this widget tree.
If the specified widget class is a subclass of WMShell, the name and
Class as determined above will be stored into the
WM_CLASS
property on the widget's window when it becomes realized.
If the specified widget_class is
applicationShellWidgetClass
or a subclass thereof, the
WM_COMMAND
property will also be set from the values of the XtNargv and
XtNargc resources.
To create multiple top-level shells within a single (logical)
application,
you can use one of two methods:
Designate one shell as the real top-level shell and
create the others as pop-up children of it by using
.
Have all shells as pop-up children of an unrealized top-level shell.
The first method,
which is best used when there is a clear choice for what is the main window,
leads to resource specifications like the following:
xmail.geometry:... (the main window)
xmail.read.geometry:... (the read window)
xmail.compose.geometry:... (the compose window)
The second method,
which is best if there is no main window,
leads to resource specifications like the following:
xmail.headers.geometry:... (the headers window)
xmail.read.geometry:... (the read window)
xmail.compose.geometry:... (the compose window)
To create a top-level widget that is the root of a widget tree using
varargs lists, use
.
Widget XtVaAppCreateShell
const char * name
const char * application_class
WidgetClass widget_class
Display * display
...
name
Specifies the instance name of the shell widget.
If name is NULL,
the application name passed to
is used.
application_class
Specifies the resource class string to be used in
place of the widget class_name string when
widget_class is
applicationShellWidgetClass
or a subclass thereof.
widget_class
Specifies the widget class for the top-level widget.
display
Specifies the display for the default screen
and for the resource database used to retrieve
the shell widget resources.
...
Specifies the variable argument list to override any other
resource specifications.
The
procedure is identical in function to
with the args and num_args parameters replaced by a varargs list, as
described in Section 2.5.1.
Convenience Procedure to Initialize an Application
To initialize the Intrinsics internals, create an application context,
open and initialize a display, and create the initial root shell
instance, an application may use
or
.
Widget XtOpenApplication
XtAppContext * app_context_return
const char * application_class
XrmOptionDescList options
Cardinal num_options
int * argc_in_out
char ** argv_in_out
String * fallback_resources
WidgetClass widget_class
ArgList args
Cardinal num_args
app_context_return
Returns the application context, if non-NULL.
application_class
Specifies the class name of the application.
options
Specifies the command line options table.
num_options
Specifies the number of entries in options.
argc_in_out
Specifies a pointer to the number of command line arguments.
argv_in_out
Specifies a pointer to the command line arguments.
fallback_resources
Specifies resource values to be used if the application class resource
file cannot be opened or read, or NULL.
widget_class
Specifies the class of the widget to be created. Must be shellWidgetClass
or a subclass.
args
Specifies the argument list to override any
other resource specifications for the created shell widget.
num_args
Specifies the number of entries in the argument list.
The
function calls
followed by
,
then calls
with display_string NULL and
application_name NULL, and finally calls
with name NULL, the specified widget_class,
an argument list and count,
and returns the created shell.
The recommended widget_class is
sessionShellWidgetClass.
The argument list and count are created by merging
the specified args and num_args with a list
containing the specified argc and argv.
The modified argc and argv returned by
are returned in argc_in_out and argv_in_out. If
app_context_return is not NULL, the created application context is
also returned. If the display specified by the command line cannot be
opened, an error message is issued and
terminates the application. If fallback_resources is non-NULL,
is called with the value prior to calling
.
Widget XtVaOpenApplication
XtAppContext * app_context_return
const char * application_class
XrmOptionDescList options
Cardinal num_options
int * argc_in_out
char ** argv_in_out
String * fallback_resources
WidgetClass widget_class
...
app_context_return
Returns the application context, if non-NULL.
application_class
Specifies the class name of the application.
options
Specifies the command line options table.
num_options
Specifies the number of entries in options.
argc_in_out
Specifies a pointer to the number of command line arguments.
argv_in_out
Specifies the command line arguments array.
fallback_resources
Specifies resource values to be used if the application class
resource file cannot be opened, or NULL.
widget_class
Specifies the class of the widget to be created. Must be shellWidgetClass
or a subclass.
...
Specifies the variable argument list to override any other
resource specifications for the created shell.
The
procedure is identical in function to
with the args and num_args parameters replaced by a varargs list,
as described
in Section 2.5.1.
Widget Instance Allocation: The allocate Procedure
A widget class may optionally provide an instance allocation procedure
in the
ObjectClassExtension
record.
When the call to create a widget includes a varargs list containing
XtVaTypedArg,
these arguments will be passed to the allocation procedure in an
XtTypedArgList.
typedef struct {
String name;
String type;
XtArgVal value;
int size;
} XtTypedArg, *XtTypedArgList;
The allocate procedure pointer in the
ObjectClassExtension
record is of type
.
typedef void (*XtAllocateProc)
WidgetClass widget_class
Cardinal* constraint_size
Cardinal* more_bytes
ArgList args
Cardinal* num_args
XtTypedArgList typed_args
Cardinal* num_typed_args
Widget* new_return
XtPointer* more_bytes_return
widget_class
Specifies the widget class of the instance to allocate.
constraint_size
Specifies the size of the constraint record to allocate, or 0.
more_bytes
Specifies the number of auxiliary bytes of memory to allocate.
args
Specifies the argument list as given in the call to create the widget.
num_args
Specifies the number of arguments.
typed_args
Specifies the list of typed arguments given in the call to create the widget.
num_typed_args
Specifies the number of typed arguments.
new_return
Returns a pointer to the newly allocated instance, or NULL in case of error.
more_bytes_return
Returns the auxiliary memory if it was requested, or NULL
if requested and an error occurred; otherwise, unchanged.
At widget allocation time, if an extension record with record_type
equal to
NULLQUARK
is located through the object class part extension field
and the allocate field is not NULL, the
will be invoked to allocate memory for the widget. If no ObjectClassPart
extension record is declared with record_type equal to
NULLQUARK,
then
XtInheritAllocate
and
XtInheritDeallocate
are assumed.
If no
is found, the Intrinsics will allocate memory for the widget.
An
must perform the following:
Allocate memory for the widget instance and return it in new_return.
The memory must be at least wc->core_class.widget_size bytes in length,
double-word aligned.
Initialize the core.constraints field in the instance record to NULL
or to point to a constraint record. If constraint_size
is not 0, the procedure must allocate memory for the constraint record.
The memory must be double-word aligned.
If more_bytes is not 0, then the address of a block of memory
at least more_bytes in size, double-word aligned, must be
returned in the more_bytes_return parameter,
or NULL to indicate an error.
A class allocation procedure that envelops the allocation procedure of a
superclass must rely on the enveloped procedure to perform the instance
and constraint allocation.
Allocation procedures should refrain from initializing fields in the
widget record except to store pointers to newly allocated additional memory.
Under no circumstances should an allocation procedure that envelopes
its superclass allocation procedure modify fields in the
instance part of any superclass.
Widget Instance Initialization: The initialize Procedure
The initialize procedure pointer in a widget class is of type
.
typedef void (*XtInitProc)
Widget request
Widget new
ArgList args
Cardinal * num_args
request
Specifies a copy of the widget with resource values as requested by the
argument list, the resource database, and the widget defaults.
new
Specifies the widget with the new values, both resource and nonresource,
that are actually allowed.
args
Specifies the argument list passed by the client, for
computing derived resource values.
If the client created the widget using a varargs form, any resources
specified via
XtVaTypedArg
are converted to the widget representation and the list is transformed
into the
ArgList
format.
num_args
Specifies the number of entries in the argument list.
An initialization procedure performs the following:
Allocates space for and copies any resources referenced by address
that the client is allowed to free or modify
after the widget has been created.
For example,
if a widget has a field that is a
String,
it may choose not to
depend on the characters at that address remaining constant
but dynamically allocate space for the string and copy it to the new space.
Widgets that do not copy one or more resources referenced
by address should clearly so state in their user documentation.
It is not necessary to allocate space for or to copy callback lists.
Computes values for unspecified resource fields.
For example, if width and height are zero,
the widget should compute an appropriate width and height
based on its other resources.
A widget may directly assign only
its own width and height within the initialize, initialize_hook,
set_values, and
set_values_hook procedures; see .
Computes values for uninitialized nonresource fields that are derived from
resource fields.
For example, graphics contexts (GCs) that the widget uses are derived from
resources like background, foreground, and font.
An initialization procedure also can check certain fields for
internal consistency.
For example, it makes no sense to specify a colormap for a depth
that does not support that colormap.
Initialization procedures are called in superclass-to-subclass order
after all fields specified in the resource lists have been
initialized. The initialize procedure does not need to examine
args and num_args
if all public resources are declared in the resource list.
Most of the initialization code for a specific widget class deals with fields
defined in that class and not with fields defined in its superclasses.
If a subclass does not need an initialization procedure
because it does not need to perform any of the above operations,
it can specify NULL for the initialize field in the class record.
Sometimes a subclass may want to overwrite values filled in by its
superclass.
In particular, size calculations of a superclass often are
incorrect for a subclass, and in this case,
the subclass must modify or recalculate fields declared
and computed by its superclass.
As an example,
a subclass can visually surround its superclass display.
In this case, the width and height calculated by the superclass initialize
procedure are too small and need to be incremented by the size of the surround.
The subclass needs to know if its superclass's size was calculated by the
superclass or was specified explicitly.
All widgets must place themselves into whatever size is explicitly given,
but they should compute a reasonable size if no size is requested.
The request and new arguments provide the necessary information for
a subclass to determine the difference between an explicitly specified field
and a field computed by a superclass.
The request widget is a copy of the widget as initialized by the
arglist and resource database.
The new widget starts with the values in the request,
but it has been updated by all superclass initialization procedures called
so far.
A subclass initialize procedure can compare these two to resolve
any potential conflicts.
In the above example,
the subclass with the visual surround can see
if the width and height in the request widget are zero.
If so,
it adds its surround size to the width and height
fields in the new widget.
If not, it must make do with the size originally specified.
The new widget will become the actual widget instance record.
Therefore,
the initialization procedure should do all its work on the new widget;
the request widget should never be modified.
If the initialize procedure
needs to call any routines that operate on a widget,
it should specify new as the widget instance.
Constraint Instance Initialization: The ConstraintClassPart initialize Procedure
The constraint initialization procedure pointer, found in the
ConstraintClassPart
initialize field of the widget class record, is of type
.
The values passed to the parent constraint initialization procedures
are the same as those passed to the child's class widget initialization
procedures.
The constraints field of the request widget points to a copy of the
constraints record as initialized by the arglist and resource database.
The constraint initialization procedure should compute any constraint fields
derived from constraint resources.
It can make further changes to the new widget to make the widget
and any other constraint fields
conform to the specified constraints, for example,
changing the widget's size or position.
If a constraint class does not need a constraint initialization procedure,
it can specify NULL for the initialize field of the
ConstraintClassPart
in the class record.
Nonwidget Data Initialization: The initialize_hook Procedure
The initialize_hook procedure is obsolete, as the same information
is now available to the initialize procedure. The procedure has been
retained for those widgets that used it in previous releases.
The initialize_hook procedure pointer is of type
:
typedef void (*XtArgsProc)
Widget w
ArgList args
Cardinal * num_args
w
Specifies the widget.
args
Specifies the argument list passed by the client.
If the client created the widget using a varargs form, any resources
specified via
XtVaTypedArg
are converted to the widget representation and the list is transformed
into the
ArgList
format.
num_args
Specifies the number of entries in the argument list.
If this procedure is not NULL,
it is called immediately after the corresponding initialize
procedure or in its place if the initialize field is NULL.
The initialize_hook procedure allows a widget instance to initialize
nonresource data using information from the specified argument list
as if it were a resource.
Realizing Widgets
To realize a widget instance, use
.
void XtRealizeWidget
Widget w
w
Specifies the widget. Must be of class Core or any subclass thereof.
If the widget is already realized,
simply returns.
Otherwise it performs the following:
Binds all action names in the widget's
translation table to procedures (see ).
Makes a postorder traversal of the widget tree rooted
at the specified widget and calls each non-NULL change_managed procedure
of all composite widgets that have one or more managed children.
Constructs an
XSetWindowAttributes
structure filled in with information derived from the
Core
widget fields and calls the realize procedure for the widget,
which adds any widget-specific attributes and creates the X window.
If the widget is
not a subclass of
compositeWidgetClass,
returns; otherwise it continues and performs the following:
Descends recursively to each of the widget's
managed children and calls the realize procedures.
Primitive widgets that instantiate children are responsible for realizing
those children themselves.
Maps all of the managed children windows that have mapped_when_managed
True.
If a widget is managed but mapped_when_managed is
False,
the widget is allocated visual space but is not displayed.
If the widget is a top-level shell widget (that is, it has no parent), and
mapped_when_managed is
True,
maps the widget window.
,
,
,
,
XtUnmanageChildren,
,
,
and
XtDestroyWidget
maintain the following invariants:
If a composite widget is realized, then all its managed children are realized.
If a composite widget is realized, then all its managed children that have
mapped_when_managed
True
are mapped.
All Intrinsics functions and all widget routines should accept
either realized or unrealized widgets.
When calling the realize or change_managed
procedures for children of a composite
widget,
calls the procedures in reverse order of
appearance in the
CompositePart
children list. By default, this
ordering of the realize procedures will
result in the stacking order of any newly created subwindows being
top-to-bottom in the order of appearance on the list, and the most
recently created child will be at the bottom.
To check whether or not a widget has been realized, use
.
Boolean XtIsRealized
Widget w
w
Specifies the widget. Must be of class Object or any subclass thereof.
The
function returns
True
if the widget has been realized,
that is, if the widget has a nonzero window ID.
If the specified object is not a widget, the state of the nearest
widget ancestor is returned.
Some widget procedures (for example, set_values) might wish to
operate differently
after the widget has been realized.
Widget Instance Window Creation: The realize Procedure
The realize procedure pointer in a widget class is of type
.
typedef void (*XtRealizeProc)
Widget w
XtValueMask value_mask
XSetWindowAttributes attributes
w
Specifies the widget.
value_mask
Specifies which fields in the attributes structure are used.
attributes
Specifies the window attributes to use in the
XCreateWindow
call.
The realize procedure must create the widget's window.
Before calling the class realize procedure, the generic
function fills in a mask and a corresponding
XSetWindowAttributes
structure.
It sets the following fields in attributes and
corresponding bits in value_mask
based on information in the widget
core
structure:
The background_pixmap (or background_pixel if background_pixmap is
XtUnspecifiedPixmap)
is filled in from the corresponding field.
The border_pixmap (or border_pixel if border_pixmap is
XtUnspecifiedPixmap)
is filled in from the corresponding field.
The colormap is filled in from the corresponding field.
The event_mask is filled in based on the event handlers registered,
the event translations specified, whether the expose field is non-NULL,
and whether visible_interest is
True.
The bit_gravity is set to
NorthWestGravity
if the expose field is NULL.
These or any other fields in attributes and the corresponding bits in
value_mask can be set by the realize procedure.
Note that because realize is not a chained operation,
the widget class realize procedure must update the
XSetWindowAttributes
structure with all the appropriate fields from
non-Core
superclasses.
A widget class can inherit its realize procedure from its superclass
during class initialization.
The realize procedure defined for
coreWidgetClass
calls
with the passed value_mask and attributes
and with window_class and visual set to
CopyFromParent.
Both
compositeWidgetClass
and
constraintWidgetClass
inherit this realize procedure, and most new widget subclasses
can do the same (see ).
The most common noninherited realize procedures set bit_gravity in the mask
and attributes to the appropriate value and then create the window.
For example, depending on its justification, Label might set bit_gravity to
WestGravity,
CenterGravity,
or
EastGravity.
Consequently, shrinking it would just move the bits appropriately,
and no
exposure
event is needed for repainting.
If a composite widget's children should be realized in an order other
than that specified
(to control the stacking order, for example),
it should call
on its children itself in the appropriate order from within its own
realize procedure.
Widgets that have children and whose class is not a subclass of
compositeWidgetClass
are responsible for calling
on their children, usually from within the realize procedure.
Realize procedures cannot manage or unmanage their descendants.
Window Creation Convenience Routine
Rather than call the Xlib
XCreateWindow
function explicitly, a realize procedure should normally call the Intrinsics analog
,
which simplifies the creation of windows for widgets.
void XtCreateWindow
Widget w
unsigned int window_class
Visual * visual
XtValueMask value_mask
XSetWindowAttributes * attributes
w
Specifies the widget that defines the additional window attributed. Must be of class Core or any subclass thereof.
window_class
Specifies the Xlib window class (for example,
InputOutput,
InputOnly,
or
CopyFromParent ).
visual
Specifies the visual type (usually
CopyFromParent ).
value_mask
Specifies which fields in the attributes structure are used.
attributes
Specifies the window attributes to use in the
XCreateWindow
call.
The
function calls the Xlib
XCreateWindow
function with values from the widget structure and the passed parameters.
Then, it assigns the created window to the widget's window field.
evaluates the following fields of the widget core
structure: depth, screen, parent->core.window, x,
y, width, height, and
border_width.
Obtaining Window Information from a Widget
The
Core
widget class definition contains the screen and window ids.
The window field may be NULL for a while
(see and ).
The display pointer, the parent widget, screen pointer,
and window of a widget are available to the widget writer by means of macros
and to the application writer by means of functions.
Display * XtDisplay
Widget w
w
Specifies the widget. Must be of class Core or any subclass thereof.
XtDisplay
returns the display pointer for the specified widget.
Widget XtParent
Widget w
w
Specifies the widget. Must be of class Object or any subclass thereof.
XtParent
returns the parent object for the specified widget. The returned object
will be of class Object or a subclass.
Screen *XtScreen
Widget w
w
Specifies the widget. Must be of class Core or any subclass thereof.
returns the screen pointer for the specified widget.
Window XtWindow
Widget w
w
Specifies the widget. Must be of class Core or any subclass thereof.
returns the window of the specified widget.
The display pointer, screen pointer, and window of a widget or
of the closest widget ancestor of a nonwidget object are available
by means of
,
,
and
.
Display *XtDisplayOfObject
Widget w
object
Specifies the object. Must be of class Object or any subclass thereof.
is identical in function to
XtDisplay
if the object is a widget; otherwise
returns the display
pointer for the nearest ancestor of object that is of class
Widget or a subclass thereof.
Screen *XtScreenOfObject
Widget object
object
Specifies the object. Must be of class Object or any subclass thereof.
is identical in function to
if the object is a widget; otherwise
returns the screen pointer
for the nearest ancestor of object that is of class
Widget or a subclass thereof.
Window XtWindowOfObject
Widget object
object
Specifies the object. Must be of class Object or any subclass thereof.
is identical in function to
if the object is a widget; otherwise
returns the window for the nearest ancestor of object that is of class
Widget or a subclass thereof.
To retrieve the instance name of an object, use
.
String XtName
Widget object
object
Specifies the object whose name is desired. Must be of class Object or any subclass thereof.
returns a pointer to the instance name of the specified object.
The storage is owned by the Intrinsics and must not be modified. The
name is not qualified by the names of any of the object's ancestors.
Several window attributes are locally cached in the widget instance.
Thus, they can be set by the resource manager and
as well as used by routines that derive structures from these values
(for example, depth for deriving pixmaps,
background_pixel for deriving GCs, and so on) or in the
call.
The x, y, width, height, and border_width
window attributes are available to
geometry managers.
These fields are maintained synchronously inside the Intrinsics.
When an
XConfigureWindow
is issued by the Intrinsics on the widget's window (on request of its parent),
these values are updated immediately rather than some time later
when the server generates a
ConfigureNotify
event.
(In fact, most widgets do not select
SubstructureNotify
events.)
This ensures that all geometry calculations are based on the internally
consistent toolkit world rather than on either
an inconsistent world updated by asynchronous
ConfigureNotify
events or a consistent, but slow, world in which geometry managers
ask the server
for window sizes whenever they need to lay out their managed children
(see ).
Unrealizing Widgets
To destroy the windows associated with a widget and its
non-pop-up descendants, use
.
void XtUnrealizeWidget
Widget w
w
Specifies the widget. Must be of class Core or any subclass thereof.
If the widget is currently unrealized,
simply returns. Otherwise it performs the following:
Unmanages the widget if the widget is managed.
Makes a postorder (child-to-parent) traversal of the widget tree
rooted at the specified widget and, for each widget that has
declared a callback list resource named “unrealizeCallback”, executes the
procedures on the
XtNunrealizeCallback
list.
Destroys the widget's window and any subwindows by calling
XDestroyWindow
with the specified widget's window field.
Any events in the queue or which arrive following a call to
will be dispatched as if the window(s) of the
unrealized widget(s) had never existed.
Destroying Widgets
The Intrinsics provide support
To destroy all the pop-up children of the widget being destroyed
and destroy all children of composite widgets.
To remove (and unmap) the widget from its parent.
To call the callback procedures that have been registered to trigger
when the widget is destroyed.
To minimize the number of things a widget has to deallocate when destroyed.
To minimize the number of
XDestroyWindow
calls when destroying a widget tree.
To destroy a widget instance, use
.
void XtDestroyWidget
Widget w
w
Specifies the widget. Must be of class Object or any subclass thereof.
The
function provides the only method of destroying a widget,
including widgets that need to destroy themselves.
It can be called at any time,
including from an application callback routine of the widget being destroyed.
This requires a two-phase destroy process in order to avoid dangling
references to destroyed widgets.
In phase 1,
performs the following:
If the being_destroyed field of the widget is
True,
it returns immediately.
Recursively descends the widget tree and
sets the being_destroyed field to
True
for the widget and all normal and pop-up children.
Adds the widget to a list of widgets (the destroy list) that should be
destroyed when it is safe to do so.
Entries on the destroy list satisfy the invariant that
if w2 occurs after w1 on the destroy list, then w2 is not a descendent,
either normal or pop-up, of w1.
Phase 2 occurs when all procedures that should execute as a result of
the current event have been called, including all procedures registered with
the event and translation managers,
that is, when the current invocation of
is about to return, or immediately if not in
.
In phase 2,
performs the following on each entry in the destroy list in the order
specified:
If the widget is not a pop-up child and the widget's parent is a subclass of
compositeWidgetClass,
and if the parent is not being destroyed,
it calls
on the widget and then calls the widget's parent's delete_child procedure
(see ).
Calls the destroy callback procedures registered on the widget
and all normal and pop-up descendants in postorder (it calls child
callbacks before parent callbacks).
The
function then makes second traversal of the widget and all normal
and pop-up descendants to perform the following three items on each
widget in postorder:
If the widget is not a pop-up child and the widget's parent is a subclass of
constraintWidgetClass,
it calls the
ConstraintClassPart
destroy procedure for the parent,
then for the parent's superclass,
until finally it calls the
ConstraintClassPart
destroy procedure for
constraintWidgetClass.
Calls the
CoreClassPart
destroy procedure declared in the widget class,
then the destroy procedure declared in its superclass,
until finally it calls the destroy procedure declared in the Object
class record. Callback lists are deallocated.
If the widget class object class part contains an
ObjectClassExtension
record with the record_type
NULLQUARK
and the deallocate field is not NULL,
calls the deallocate procedure to deallocate the instance and if one
exists, the constraint record. Otherwise, the Intrinsics will deallocate
the widget instance record and if one exists, the constraint record.
Calls
XDestroyWindow
if the specified widget is realized (that is, has an X window).
The server recursively destroys all normal descendant windows.
(Windows of realized pop-up Shell children, and their
descendants, are destroyed by a shell class destroy procedure.)
Adding and Removing Destroy Callbacks
When an application needs to perform additional processing during the
destruction of a widget,
it should register a destroy callback procedure for the widget.
The destroy callback procedures use the mechanism described in
.
The destroy callback list is identified by the resource name
XtNdestroyCallback.
For example, the following adds an application-supplied destroy callback
procedure ClientDestroy with client data to a widget by calling
.
XtAddCallback(w, XtNdestroyCallback, ClientDestroy, client_data)
Similarly, the following removes the application-supplied destroy callback
procedure ClientDestroy by calling
.
XtRemoveCallback(w, XtNdestroyCallback, ClientDestroy, client_data)
The ClientDestroy argument is of type
;
see .
Dynamic Data Deallocation: The destroy Procedure
The destroy procedure pointers in the
ObjectClassPart,
RectObjClassPart,
and
CoreClassPart
structures are of type
.
typedef void XtWidgetProc
Widget w
w
Specifies the widget being destroyed.
The destroy procedures are called in subclass-to-superclass order.
Therefore, a widget's destroy procedure should deallocate only storage
that is specific to the subclass and should ignore the storage
allocated by any of its superclasses.
The destroy procedure should deallocate only resources that have been
explicitly created by the subclass.
Any resource that was obtained from the resource database
or passed in an argument list was not created by the widget
and therefore should not be destroyed by it.
If a widget does not need to deallocate any storage,
the destroy procedure entry in its class record can be NULL.
Deallocating storage includes, but is not limited to,
the following steps:
Calling
on dynamic storage allocated with
,
,
and so on.
Calling
XFreePixmap
on pixmaps created with direct X calls.
Calling
on GCs allocated with
.
Calling
XFreeGC
on GCs allocated with direct X calls.
Calling
on event handlers added to other widgets.
Calling
on timers created with
.
Calling
for each child if the widget has children
and is not a subclass of
compositeWidgetClass.
During destroy phase 2 for each widget, the Intrinsics remove the widget
from the modal cascade, unregister all event handlers, remove all key,
keyboard, button, and pointer grabs and remove all callback procedures
registered on the widget. Any outstanding selection transfers will time out.
Dynamic Constraint Data Deallocation: The ConstraintClassPart destroy Procedure
The constraint destroy procedure identified in the
ConstraintClassPart
constraintWidgetClass.
This constraint destroy procedure pointer is of type
.
The constraint destroy procedures are called in subclass-to-superclass order,
starting at the class of the widget's parent and ending at
constraintWidgetClass.
Therefore, a parent's constraint destroy procedure should deallocate only
storage that is specific to the constraint subclass
and not storage allocated by any of its superclasses.
If a parent does not need to deallocate any constraint storage,
the constraint destroy procedure entry
in its class record can be NULL.
Widget Instance Deallocation: The deallocate Procedure
The deallocate procedure pointer in the
ObjectClassExtension
record is of type
XtDeallocateProc.
typedef void (*XtDeallocateProc)
Widget widget
XtPointer more_bytes
widget
Specifies the widget being destroyed.
more_bytes
Specifies the auxiliary memory received from the corresponding allocator
along with the widget, or NULL.
When a widget is destroyed, if an
ObjectClassExtension
record exists in the object class part extension field
with record_type
NULLQUARK
and the deallocate field is not NULL, the
XtDeallocateProc
will be called.
If no ObjectClassPart extension record is declared with record_type
equal to
NULLQUARK,
then
XtInheritAllocate
and
XtInheritDeallocate
are assumed.
The responsibilities of the deallocate procedure are to deallocate the
memory specified by more_bytes if it is not NULL,
to deallocate the constraints record as specified by the
widget's core.constraints field if it is
not NULL, and to deallocate the widget instance itself.
If no
XtDeallocateProc
is found, it is assumed that the Intrinsics
originally allocated the memory and is responsible for freeing it.
Exiting from an Application
All X Toolkit applications should terminate
by calling
and then exiting
using the
standard method for their operating system (typically, by calling
exit
for POSIX-based systems).
The quickest way to make the windows disappear while exiting is to call
on each top-level shell widget.
The Intrinsics have no resources beyond those in the program image,
and the X server will free its resources when its connection
to the application is broken.
Depending upon the widget set in use, it may be necessary to explicitly
destroy individual widgets or widget trees with
before calling
in order to ensure that any
required widget cleanup is properly executed. The application developer
must refer to the widget documentation to learn if a widget needs to
perform cleanup beyond that performed automatically by the
operating system. If the client is a session participant
(see ), then the client may wish to resign from the session
before exiting. See for details.