Resource Management
A resource is a field in the widget record with a corresponding
resource entry in the resources list of the widget or any of its
superclasses.
This means that the field is
settable by
(by naming the field in the argument list), by an
entry in a resource file (by using either the name or class), and by
.
In addition, it is readable by
.
Not all fields in a widget record are resources.
Some are for bookkeeping use by the
generic routines (like managed and being_destroyed).
Others can be for local bookkeeping,
and still others are derived from resources
(many graphics contexts and pixmaps).
Widgets typically need to obtain a large set of resources at widget
creation time.
Some of the resources come from the argument list supplied in the call to
,
some from the resource database,
and some from the internal defaults specified by the widget.
Resources are obtained first from the argument list,
then from the resource database for all resources not specified
in the argument list,
and last, from the internal default, if needed.
Resource Lists
A resource entry specifies a field in the widget,
the textual name and class of the field that argument lists
and external resource files use to refer to the field,
and a default value that the field should get if no value is specified.
The declaration for the
XtResource
structure is
typedef struct {
String resource_name;
String resource_class;
String resource_type;
Cardinal resource_size;
Cardinal resource_offset;
String default_type;
XtPointer default_addr;
} XtResource, *XtResourceList;
When the resource list is specified as the
CoreClassPart,
ObjectClassPart,
RectObjClassPart,
or
ConstraintClassPart
resources field, the strings pointed to by resource_name,
resource_class, resource_type, and default_type must
be permanently allocated prior to or during the execution of the class
initialization procedure and must not be subsequently deallocated.
The resource_name field contains the name used by clients to access the field
in the widget.
By convention, it starts with a lowercase letter
and is spelled exactly like the field name,
except all underscores (_) are deleted and the next letter is replaced by its
uppercase counterpart.
For example, the resource name for background_pixel becomes backgroundPixel.
Resource names beginning with the two-character
sequence “xt”, and resource classes beginning with the two-character
sequence “Xt” are reserved to the Intrinsics for future standard and
implementation-dependent uses.
Widget header files typically contain a symbolic name for each resource name.
All resource names, classes, and types used by the Intrinsics are named in
.
The Intrinsics's symbolic resource names begin with
“XtN”
and are followed by the string name (for example, XtNbackgroundPixel
for backgroundPixel).
The resource_class field contains the class string used in resource
specification files to identify the field.
A resource class provides two functions:
It isolates an application from different representations that widgets
can use for a similar resource.
It lets you specify values for several actual resources with a single name.
A resource class should be chosen to span a group of closely related fields.
For example,
a widget can have several pixel resources: background, foreground,
border, block cursor, pointer cursor, and so on.
Typically, the background defaults to white
and everything else to black.
The resource class for each of these resources in the resource list
should be chosen so that it takes the minimal number of entries
in the resource database to make the background ivory
and everything else darkblue.
In this case, the background pixel should have a resource class of
“Background”
and all the other pixel entries a resource class of
“Foreground”.
Then, the resource file needs only two lines to
change all pixels to ivory or darkblue:
*Background: ivory
*Foreground: darkblue
Similarly, a widget may have several font resources (such as normal and bold),
but all fonts should have the class Font.
Thus, changing all fonts simply requires only a single line in the
default resource file:
*Font: 6x13
By convention,
resource classes are always spelled starting with a capital letter
to distinguish them from resource names.
Their symbolic names are preceded with
“XtC”
(for example, XtCBackground).
The resource_type field gives the physical representation type of the resource
and also encodes information about the specific usage of the field.
By convention, it starts with an uppercase letter and is
spelled identically to the type name of the field.
The resource type is used when resources are fetched to
convert from the resource database format (usually
String)
or the format of the resource default value
(almost anything, but often
String)
to the desired
physical representation (see ).
The Intrinsics define the following resource types:
Resource Type
Structure or Field Type
XtRAcceleratorTable
XtAccelerators
XtRAtom
Atom
XtRBitmap
Pixmap, depth=1
XtRBoolean
Boolean
XtRBool
Bool
XtRCallback
XtCallbackList
XtRCardinal
Cardinal
XtRColor
XColor
XtRColormap
Colormap
XtRCommandArgArray
String*
XtRCursor
Cursor
XtRDimension
Dimension
XtRDirectoryString
String
XtRDisplay
Display*
XtREnum
XtEnum
XtREnvironmentArray
String*
XtRFile
FILE*
XtRFloat
float
XtRFont
Font
XtRFontSet
XFontSet
XtRFontStruct
XFontStruct*
XtRFunction
(*)(Widget)
XtRGeometry
char*, format as defined by
XParseGeometry
XtRGravity
int
XtRInitialState
int
XtRInt
int
XtRLongBoolean
long
XtRObject
Object
XtRPixel
Pixel
XtRPixmap
Pixmap
XtRPointer
XtPointer
XtRPosition
Position
XtRRestartStyle
unsigned char
XtRScreen
Screen*
XtRShort
short
XtRSmcConn
XtPointer
XtRString
String
XtRStringArray
String*
XtRStringTable
String*
XtRTranslationTable
XtTranslations
XtRUnsignedChar
unsigned char
XtRVisual
Visual*
XtRWidget
Widget
XtRWidgetClass
WidgetClass
XtRWidgetList
WidgetList
XtRWindow
Window
also defines the following resource types as a
convenience for widgets, although they do not have any corresponding
data type assigned:
XtREditMode,
XtRJustify,
and
XtROrientation.
The resource_size field is the size of the physical representation in bytes;
you should specify it as
sizeof(type) so that the
compiler fills in the value.
The resource_offset field is the offset in bytes of the field
within the widget.
You should use the
macro to retrieve this value.
The default_type field is the representation type of the default
resource value.
If default_type is different from resource_type and the default value
is needed,
the resource manager invokes a conversion procedure from default_type
to resource_type.
Whenever possible,
the default type should be identical to the resource type in order
to minimize widget creation time.
However, there are sometimes no values of the type that the program
can easily specify.
In this case,
it should be a value for which the converter is guaranteed to work (for example,
XtDefaultForeground
for a pixel resource).
The default_addr field specifies the address of the default resource value.
As a special case, if default_type is
XtRString,
then the value in the default_addr field is the pointer to
the string rather than a pointer to the pointer.
The default is used if a resource is not specified in the argument list
or in the resource database or if the conversion from the representation
type stored in the resource database fails,
which can happen for various reasons (for example, a misspelled entry in a
resource file).
Two special representation types
(XtRImmediate
and
XtRCallProc)
are usable only as default resource types.
XtRImmediate
indicates that the value in the default_addr field is the actual value of
the resource rather than the address of the value.
The value must be in the correct representation type for the resource,
coerced to an
XtPointer.
No conversion is possible, since there is no source representation type.
XtRCallProc
indicates that the value in the default_addr field is a procedure
pointer.
This procedure is automatically invoked with the widget,
resource_offset, and a pointer to an
XrmValue
in which to store the result.
XtRCallProc
procedure pointers are of type
.
typedef void (*XtResourceDefaultProc)
Widget w
int offset
XrmValue *value
w
Specifies the widget whose resource value is to be obtained.
offset
Specifies the offset of the field in the widget record.
value
Specifies the resource value descriptor to return.
The
procedure should fill in the value->addr field with a pointer
to the resource value in its correct representation type.
To get the resource list structure for a particular class, use
.
void XtGetResourceList
WidgetClass class
XtResourceList *resources_return
Cardinal *num_resources_return
class
Specifies the object class to be queried. It must be
objectClass
or any subclass thereof.
resources_return
Returns the resource list.
num_resources_return
Returns the number of entries in the resource list.
If
is called before the class is initialized,
it returns the resource list as specified in the class record.
If it is called after the class has been initialized,
returns a merged resource list that includes the resources
for all superclasses.
The list returned by
should be freed using
when it is no longer needed.
To get the constraint resource list structure for a particular widget
class, use
.
void XtGetConstraintResourceList
WidgetClass class
XtResourceList *resources_return
Cardinal *num_resources_return
class
Specifies the object class to be queried. It must be
objectClass
or any subclass thereof.
resources_return
Returns the constraint resource list.
num_resources_return
Returns the number of entries in the constraint resource list.
If
is called before the widget class is
initialized, the resource list as specified in the widget
class Constraint part is returned. If
is called after the widget class has been initialized, the merged
resource list for the class and all Constraint superclasses is
returned. If the
specified class is not a subclass of
constraintWidgetClass,
*resources_return is set to NULL
and *num_resources_return is set to zero.
The list returned by
should be freed using
when it is no longer needed.
The routines
and
also use the resource list to set and get widget state;
see and
.
Here is an abbreviated version of a possible resource list for a Label widget:
/* Resources specific to Label */
static XtResource resources[] = {
{XtNforeground, XtCForeground, XtRPixel, sizeof(Pixel),
XtOffsetOf(LabelRec, label.foreground), XtRString, XtDefaultForeground},
{XtNfont, XtCFont, XtRFontStruct, sizeof(XFontStruct*),
XtOffsetOf(LabelRec, label.font), XtRString, XtDefaultFont},
{XtNlabel, XtCLabel, XtRString, sizeof(String),
XtOffsetOf(LabelRec, label.label), XtRString, NULL},
.
.
.
}
The complete resource name for a field of a widget instance is the
concatenation of the application shell name (from
XtAppCreateShell),
the instance names of all the widget's parents up to the
top of the widget tree,
the instance name of the widget itself,
and the resource name of the specified field of the widget.
Similarly,
the full resource class of a field of a widget instance is the
concatenation of the application class (from
XtAppCreateShell),
the widget class names of all the widget's parents up to the
top of the widget tree,
the widget class name of the widget itself,
and the resource class of the specified field of the widget.
Byte Offset Calculations
To determine the byte offset of a field within a structure type, use
.
Cardinal XtOffsetOf
Type structure_type
Field field_name
structure_type
Specifies a type that is declared as a structure.
field_name
Specifies the name of a member within the structure.
The
macro expands to a constant expression that gives the
offset in bytes to the specified structure member from the beginning
of the structure. It is normally used to statically initialize
resource lists and is more portable than
,
which serves the same function.
To determine the byte offset of a field within a structure pointer type, use
.
Cardinal XtOffset
Type pointer_type
Field field_name
pointer_type
Specifies a type that is declared as a pointer to a structure.
field_name
Specifies the name of a member within the structure.
The
macro expands to a constant expression that gives the
offset in bytes to the specified structure member from the beginning
of the structure. It may be used to statically initialize
resource lists.
is less portable than
.
Superclass-to-Subclass Chaining of Resource Lists
The
function gets resources as a superclass-to-subclass chained operation.
That is, the resources specified in the
objectClass
resource list are fetched,
then those in
rectObjClass,
and so on down to the resources specified
for this widget's class. Within a class, resources are fetched in the order
they are declared.
In general, if a widget resource field is declared in a superclass,
that field is included in the superclass's resource list and need not be
included in the subclass's resource list.
For example, the
Core
class contains a resource entry for background_pixel.
Consequently,
the implementation of Label need not also have a resource entry
for background_pixel.
However, a subclass,
by specifying a resource entry for that field in its own resource list,
can override the resource entry for any field declared in a superclass.
This is most often done to override the defaults provided in the
superclass with new ones.
At class initialization time,
resource lists for that class are scanned from the superclass down
to the class to look for resources with the same offset.
A matching resource in a subclass will be reordered to override
the superclass entry.
If reordering is necessary, a copy of the superclass resource list is made to
avoid affecting other subclasses of the superclass.
Also at class initialization time, the Intrinsics produce an
internal representation of the resource list to optimize access time
when creating widgets. In order to save memory, the Intrinsics may
overwrite the storage allocated for the resource list in the class
record; therefore, widgets must allocate resource lists in writable
storage and must not access the list contents directly after the
class_initialize procedure has returned.
Subresources
A widget does not do anything to retrieve its own resources;
instead,
does this automatically before calling the class initialize procedure.
Some widgets have subparts that are not widgets but for which the widget
would like to fetch resources.
Such widgets call
to accomplish this.
void XtGetSubresources
Widget w
XtPointer base
const char * name
const char * class
XtResourceList resources
Cardinal num_resources
ArgList args
Cardinal num_args
w
Specifies the object used to qualify the subpart resource name and
class. Must be of class Object or any subclass thereof.
base
Specifies the base address of the subpart data structure into which the
resources will be written.
name
Specifies the name of the subpart.
class
Specifies the class of the subpart.
resources
Specifies the resource list for the subpart.
num_resources
Specifies the number of entries in the resource list.
args
Specifies the argument list to override any other resource specifications.
num_args
Specifies the number of entries in the argument list.
The
function constructs a name and class list from the application name and class,
the names and classes of all the object's ancestors, and the object itself.
Then it appends to this list the name and class pair passed in.
The resources are fetched from the argument list, the resource database,
or the default values in the resource list.
Then they are copied into the subpart record.
If args is NULL,
num_args must be zero.
However, if num_args is zero,
the argument list is not referenced.
may overwrite the specified resource list with an
equivalent representation in an internal format, which optimizes access
time if the list is used repeatedly. The resource list must be
allocated in writable storage, and the caller must not modify the list
contents after the call if the same list is to be used again.
Resources fetched by
are reference-counted as
if they were referenced by the specified object. Subresources might
therefore be freed from the conversion cache and destroyed
when the object is destroyed, but not before then.
To fetch resources for widget subparts using varargs lists, use
.
void XtVaGetSubresources
Widget w
XtPointer base
const char * name
const char * class
XtResourceList resources
Cardinal num_resources
...
w
Specifies the object used to qualify the subpart resource name and
class. Must be of class Object or any subclass thereof.
base
Specifies the base address of the subpart data structure into which the
resources will be written.
name
Specifies the name of the subpart.
class
Specifies the class of the subpart.
resources
Specifies the resource list for the subpart.
num_resources
Specifies the number of entries in the resource list.
...
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.
Obtaining Application Resources
To retrieve resources that are not specific to a widget
but apply to the overall application, use
.
void XtGetApplicationResources
Widget w
XtPointer base
XtResourceList resources
Cardinal num_resources
ArgList args
Cardinal num_args
w
Specifies the object that identifies the resource database to search
(the database is that associated with the display for this object). Must be of class Object or any subclass thereof.
base
Specifies the base address into which
the resource values will be written.
resources
Specifies the resource list.
num_resources
Specifies the number of entries in the resource list.
args
Specifies the argument list to override any other resource specifications.
num_args
Specifies the number of entries in the argument list.
The
function first uses the passed object,
which is usually an application shell widget,
to construct a resource name and class list.
The full name and class of the specified object (that is, including its
ancestors, if any) is logically added to the
front of each resource name and class.
Then it retrieves the resources from the argument list,
the resource database, or the resource list default values.
After adding base to each address,
copies the resources into the addresses
obtained by adding base to each offset in the resource list.
If args is NULL,
num_args must be zero.
However, if num_args is zero,
the argument list is not referenced.
The portable way to specify application resources is to declare them
as members of a structure and pass the address of the structure
as the base argument.
may overwrite the specified resource list
with an equivalent representation in an internal format, which
optimizes access time if the list is used repeatedly. The resource
list must be allocated in writable storage, and the caller must not
modify the list contents after the call if the same list is to be
used again. Any per-display resources fetched by
will not be freed from the resource cache until the display is closed.
To retrieve resources for the overall application using varargs lists, use
.
void XtVaGetApplicationResources
Widget w
XtPointer base
XtResourceList resources
Cardinal num_resources
...
w
Specifies the object that identifies the resource database to search
(the database is that associated with the display for this object). Must be of class Object or any subclass thereof.
base
Specifies the base address into which
the resource values will be written.
resources
Specifies the resource list for the subpart.
num_resources
Specifies the number of entries in the resource list.
...
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.
Resource Conversions
The Intrinsics provide a mechanism for registering representation converters that
are automatically invoked by the resource-fetching routines.
The Intrinsics additionally provide and register several commonly used converters.
This resource conversion mechanism serves several purposes:
It permits user and application resource files to contain textual
representations of nontextual values.
It allows textual or other representations of default resource values that
are dependent on the display, screen, or colormap, and thus must be
computed at runtime.
It caches conversion source and result data.
Conversions that require much computation or space
(for example, string-to-translation-table)
or that require round-trips to the server
(for example, string-to-font or string-to-color) are performed only once.
Predefined Resource Converters
The Intrinsics define all the representations used in the
Object,
RectObj,
Core,
Composite,
Constraint,
and
Shell
widget classes.
The Intrinsics register the following resource converters that accept
input values of representation type
XtRString.
Target Representation
Converter Name
Additional Args
XtRAcceleratorTable
XtCvtStringToAcceleratorTable
XtRAtom
XtCvtStringToAtom
Display*
XtRBoolean
XtCvtStringToBoolean
XtRBool
XtCvtStringToBool
XtRCommandArgArray
XtCvtStringToCommandArgArray
XtRCursor
XtCvtStringToCursor
Display*
XtRDimension
XtCvtStringToDimension
XtRDirectoryString
XtCvtStringToDirectoryString
XtRDisplay
XtCvtStringToDisplay
XtRFile
XtCvtStringToFile
XtRFloat
XtCvtStringToFloat
XtRFont
XtCvtStringToFont
Display*
XtRFontSet
XtCvtStringToFontSet
Display*, String locale
XtRFontStruct
XtCvtStringToFontStruct
Display*
XtRGravity
XtCvtStringToGravity
XtRInitialState
XtCvtStringToInitialState
XtRInt
XtCvtStringToInt
XtRPixel
XtCvtStringToPixel
colorConvertArgs
XtRPosition
XtCvtStringToPosition
XtRRestartStyle
XtCvtStringToRestartStyle
XtRShort
XtCvtStringToShort
XtRTranslationTable
XtCvtStringToTranslationTable
XtRUnsignedChar
XtCvtStringToUnsignedChar
XtRVisual
XtCvtStringToVisual
Screen*, Cardinal depth
The String-to-Pixel conversion has two predefined constants that are
guaranteed to work and contrast with each other:
XtDefaultForeground
and
XtDefaultBackground.
They evaluate to the black and white pixel values of the widget's screen,
respectively.
If the application resource reverseVideo is
True,
they evaluate to the white and black pixel values of the widget's screen,
respectively.
Similarly, the String-to-Font and String-to-FontStruct converters recognize
the constant
XtDefaultFont
and evaluate this in the following manner:
Query the resource database for the resource whose full name
is “xtDefaultFont”, class “XtDefaultFont” (that is, no widget
name/class prefixes), and use a type
XtRString
value returned as the font name or a type
XtRFont
or
XtRFontStruct
value directly as the resource value.
If the resource database does not contain a value for xtDefaultFont,
class XtDefaultFont, or if the returned font name cannot be
successfully opened, an implementation-defined font in ISO8859-1
character set encoding is opened. (One possible algorithm is to
perform an
XListFonts
using a wildcard font name and use the first
font in the list. This wildcard font name should be as broad as
possible to maximize the probability of locating a usable font;
for example, “-*-*-*-R-*-*-*-120-*-*-*-*-ISO8859-1
”.)
If no suitable ISO8859-1 font can be found, issue a warning message
and return
False.
The String-to-FontSet converter recognizes the constant
XtDefaultFontSet
and evaluate this in the following manner:
Query the resource database for the resource whose full name
is “xtDefaultFontSet”, class “XtDefaultFontSet” (that is, no widget
name/class prefixes), and use a type
XtRString
value returned as the base font name list or a type
XtRFontSet
value directly as the resource value.
If the resource database does not contain a value for xtDefaultFontSet,
class XtDefaultFontSet, or if a font set cannot be
successfully created from this resource,
an implementation-defined font set is created.
(One possible algorithm is to
perform an
XCreateFontSet
using a wildcard base font name.
This wildcard base font name should be as broad as
possible to maximize the probability of locating a usable font;
for example, “-*-*-*-R-*-*-*-120-*-*-*-*
”.)
If no suitable font set can be created, issue a warning message
and return
False.
If a font set is created but missing_charset_list is not
empty, a warning is issued and the partial font set is returned.
The Intrinsics register the String-to-FontSet converter with
a conversion argument list that extracts the current process
locale at the time the converter is invoked. This ensures
that the converter is invoked again if the same conversion
is required in a different locale.
The String-to-Gravity conversion accepts string values that are the
names of window and bit gravities and their numerical equivalents,
as defined in Xlib — C Language X Interface:
ForgetGravity,
UnmapGravity,
NorthWestGravity,
NorthGravity,
NorthEastGravity,
WestGravity,
CenterGravity,
EastGravity,
SouthWestGravity,
SouthGravity,
SouthEastGravity,
and
StaticGravity.
Alphabetic case is not significant in the conversion.
The String-to-CommandArgArray conversion parses a String into an
array of strings.
White space characters separate elements of the command line.
The converter recognizes the backslash character “\” as an escape
character to allow the following white space character to be part of the
array element.
The String-to-DirectoryString conversion recognizes the
string “XtCurrentDirectory” and returns the result of a call
to the operating system to get the current directory.
The String-to-RestartStyle conversion accepts the values
RestartIfRunning,
RestartAnyway,
RestartImmediately,
and
RestartNever
as defined by the X Session Management Protocol.
The String-to-InitialState conversion accepts the values
NormalState
or
IconicState
as defined by the Inter-Client Communication Conventions Manual.
The String-to-Visual conversion calls
XMatchVisualInfo
using the
screen and depth fields from the core part and returns the first
matching Visual on the list. The widget resource list must be certain
to specify any resource of type
XtRVisual
after the depth resource.
The allowed string values are the visual class names defined in X Window System Protocol,
Section 8;
StaticGray,
StaticColor,
TrueColor,
GrayScale,
PseudoColor,
and
DirectColor.
The Intrinsics register the following resource converter that accepts
an input value of representation type
XtRColor.
Target Representation
Converter Name
Additional Args
XtRPixel
XtCvtColorToPixel
The Intrinsics register the following resource converters that accept
input values of representation type
XtRInt.
Target Representation
Converter Name
Additional Args
XtRBoolean
XtCvtIntToBoolean
XtRBool
XtCvtIntToBool
XtRColor
XtCvtIntToColor
colorConvertArgs
XtRDimension
XtCvtIntToDimension
XtRFloat
XtCvtIntToFloat
XtRFont
XtCvtIntToFont
XtRPixel
XtCvtIntToPixel
XtRPixmap
XtCvtIntToPixmap
XtRPosition
XtCvtIntToPosition
XtRShort
XtCvtIntToShort
XtRUnsignedChar
XtCvtIntToUnsignedChar
The Intrinsics register the following resource converter that accepts
an input value of representation type
XtRPixel.
Target Representation
Converter Name
Additional Args
XtRColor
XtCvtPixelToColor
New Resource Converters
Type converters use pointers to
XrmValue
structures (defined in
see Section 15.4 in
Xlib — C Language X Interface)
for input and output values.
typedef struct {
unsigned int size;
XPointer addr;
} XrmValue, *XrmValuePtr;
The addr field specifies the address of the data, and the size
field gives the total number of significant bytes in the data.
For values of type
String,
addr is the address of the first character and size
includes the NULL-terminating byte.
A resource converter procedure pointer is of type
.
typedef Boolean (*XtTypeConverter)
Display *display
XrmValue *args
Cardinal *num_args
XrmValue *from
XrmValue *to
XtPointer *converter_data
display
Specifies the display connection with which this conversion is associated.
args
Specifies a list of additional
XrmValue
arguments to the converter if additional context is needed
to perform the conversion, or NULL.
For example, the String-to-Font converter needs the widget's display,
and the String-to-Pixel converter needs the widget's screen and colormap.
num_args
Specifies the number of entries in args.
from
Specifies the value to convert.
to
Specifies a descriptor for a location into which to store the converted value.
converter_data
Specifies a location into which the converter may
store converter-specific data associated
with this conversion.
The display argument is normally used only when generating error
messages, to identify the application context (with the function
XtDisplayToApplicationContext ).
The to argument specifies the size and location into which the
converter should store the converted value. If the addr field is NULL,
the converter should allocate appropriate storage and store the size
and location into the to descriptor. If the type converter allocates
the storage, it remains under the ownership of the converter and must
not be modified by the caller. The type converter is permitted to use
static storage for this purpose, and therefore the caller must
immediately copy the data upon return from the converter. If the
addr field is not NULL, the converter must check the size field to
ensure that sufficient space has been allocated before storing the
converted value. If insufficient space is specified, the converter
should update the size field with the number of bytes required and
return
False
without modifying the data at the specified location.
If sufficient space was allocated by the caller, the converter should
update the size field with the number of bytes actually occupied by the
converted value. For converted values of type
XtRString,
the size should
include the NULL-terminating byte, if any.
The converter may store any value in the location specified
in converter_data; this value will be passed to the destructor, if any,
when the resource is freed by the Intrinsics.
The converter must return
True
if the conversion was successful and
False
otherwise. If the conversion cannot be performed because of an
improper source value, a warning message should also be issued with
.
Most type converters just take the data described by the specified from
argument and return data by writing into the location specified in
the to argument.
A few need other information, which is available in args.
A type converter can invoke another type converter,
which allows differing sources that may convert into a common intermediate
result to make maximum use of the type converter cache.
Note that if an address is written into to->addr, it cannot be that
of a local variable of the converter because the data will not be
valid after the converter returns. Static variables may be used,
as in the following example.
If the converter modifies the resource database,
the changes affect any in-progress widget creation,
,
or
in an implementation-defined manner; however, insertion of new entries
or changes to existing entries is allowed and will not directly cause
an error.
The following is an example of a converter that takes a
string
and converts it to a
Pixel.
Note that the display parameter is
used only to generate error messages; the
Screen
conversion argument is
still required to inform the Intrinsics that the converted value is
a function of the particular display (and colormap).
#define done(type, value) \
{ \
if (toVal->addr != NULL) { \
if (toVal->size < sizeof(type)) { \
toVal->size = sizeof(type); \
return False; \
} \
*(type*)(toVal->addr) = (value); \
} \
else { \
static type static_val; \
static_val = (value); \
toVal->addr = (XPointer)&static_val; \
} \
toVal->size = sizeof(type); \
return True; \
}
static Boolean CvtStringToPixel(
Display *dpy,
XrmValue *args,
Cardinal *num_args,
XrmValue *fromVal,
XrmValue *toVal,
XtPointer *converter_data)
{
static XColor screenColor;
XColor exactColor;
Screen *screen;
Colormap colormap;
Status status;
if (*num_args != 2)
XtAppWarningMsg(XtDisplayToApplicationContext(dpy),
"wrongParameters", "cvtStringToPixel", "XtToolkitError",
"String to pixel conversion needs screen and colormap arguments",
(String *)NULL, (Cardinal *)NULL);
screen = *((Screen**) args[0].addr);
colormap = *((Colormap *) args[1].addr);
if (CompareISOLatin1(str, XtDefaultBackground) == 0) {
*closure_ret = False;
done(Pixel, WhitePixelOfScreen(screen));
}
if (CompareISOLatin1(str, XtDefaultForeground) == 0) {
*closure_ret = False;
done(Pixel, BlackPixelOfScreen(screen));
}
status = XAllocNamedColor(DisplayOfScreen(screen),
colormap, (char*)fromVal->addr,
&screenColor, &exactColor);
if (status == 0) {
String params[1];
Cardinal num_params = 1;
params[0] = (String)fromVal->addr;
XtAppWarningMsg(XtDisplayToApplicationContext(dpy),
"noColormap",
"cvtStringToPixel",
"XtToolkitError",
"Cannot allocate colormap entry for \"%s\"",
params, &num_params);
*converter_data = (char *) False;
return False;
} else {
*converter_data = (char *) True;
done(Pixel, &screenColor.pixel);
}
}
All type converters should define some set of conversion values for which they
are guaranteed to succeed so these can be used in the resource defaults.
This issue arises only with conversions, such as fonts and colors,
where there is no string representation that all server implementations
will necessarily recognize.
For resources like these,
the converter should define a symbolic constant
in the same manner as
XtDefaultForeground,
XtDefaultBackground,
and
XtDefaultFont.
To allow the Intrinsics to deallocate resources produced by type
converters, a resource destructor procedure may also be provided.
A resource destructor procedure pointer is of type
.
typedef void (*XtDestructor)
XtAppContext app
XrmValue *to
XtPointer converter_data
XrmValue *args
Cardinal *num_args
app
Specifies an application context in which the resource is being freed.
to
Specifies a descriptor for the resource produced by the type converter.
converter_data
Specifies the converter-specific data returned by the type converter.
args
Specifies the additional converter arguments as passed
to the type converter when the conversion was performed.
num_args
Specifies the number of entries in args.
The destructor procedure is responsible for freeing the resource
specified by the to argument, including any auxiliary storage
associated with that resource, but not the memory directly addressed
by the size and location in the to argument or the memory specified
by args.
Issuing Conversion Warnings
The
procedure is a convenience routine for resource type converters
that convert from string values.
void XtDisplayStringConversionWarning
Display *display
const char * from_value
const char * to_type
display
Specifies the display connection with which the conversion is associated.
from_value
Specifies the string that could not be converted.
to_type
Specifies the target representation type requested.
The
procedure issues a warning message using
with name “conversionError”,
type “string”, class “XtToolkitError”, and the default message
“Cannot convert "from_value" to type to_type”.
To issue other types of warning or error messages, the type converter
should use
or
.
To retrieve the application context associated with a given
display connection, use
.
XtAppContext XtDisplayToApplicationContext
Display *display
display
Specifies an open and initialized display connection.
The
function returns the application
context in which the specified display was initialized. If the
display is not known to the Intrinsics, an error message is issued.
Registering a New Resource Converter
When registering a resource converter, the client must specify the
manner in which the conversion cache is to be used when there are multiple
calls to the converter. Conversion cache control is specified
via an XtCacheType
argument.
typedef int XtCacheType;
An XtCacheType
field may contain one of the following values:
XtCacheNone
Specifies that the results of a previous conversion
may not be reused to satisfy any other resource
requests; the specified converter will be called
each time the converted value is required.
XtCacheAll
Specifies that the results of a previous conversion
should be reused for any resource request that depends
upon the same source value and conversion arguments.
XtCacheByDisplay
Specifies that the results of a previous conversion
should be used as for
XtCacheAll
but the destructor will be called, if specified, if
is called
for the display connection associated with the converted value, and
the value will be removed from the conversion cache.
The qualifier
XtCacheRefCount
may be ORed with any of the above values. If
XtCacheRefCount
is specified, calls to
,
,
,
and
that use the converted value will be counted. When a widget using the
converted value is destroyed, the count is decremented, and, if the
count reaches zero, the destructor procedure will be called and the
converted value will be removed from the conversion cache.
To register a type converter for all application contexts in a
process, use
,
and to register a type converter in a single application context, use
.
void XtSetTypeConverter
const char * from_type
const char * to_type
XtTypeConverter converter
XtConvertArgList convert_args
Cardinal num_args
XtCacheType cache_type
XtDestructor destructor
from_type
Specifies the source type.
to_type
Specifies the destination type.
converter
Specifies the resource type converter procedure.
convert_args
Specifies additional conversion arguments, or NULL.
num_args
Specifies the number of entries in convert_args.
cache_type
Specifies whether or not resources produced by this
converter are shareable or display-specific and when
they should be freed.
destructor
Specifies a destroy procedure for resources produced by
this conversion, or NULL if no additional action is
required to deallocate resources produced by the converter.
void XtAppSetTypeConverter
XtAppContext app_context
const char * from_type
const char * to_type
XtTypeConverter converter
XtConvertArgList convert_args
Cardinal num_args
XtCacheType cache_type
XtDestructor destructor
app_context
Specifies the application context.
from_type
Specifies the source type.
to_type
Specifies the destination type.
converter
Specifies the resource type converter procedure.
convert_args
Specifies additional conversion arguments, or NULL.
num_args
Specifies the number of entries in convert_args.
cache_type
Specifies whether or not resources produced by this
converter are shareable or display-specific and when
they should be freed.
destructor
Specifies a destroy procedure for resources produced by
this conversion, or NULL if no additional action is
required to deallocate resources produced by the converter.
registers the specified type converter and
destructor in all application contexts created by the calling process,
including any future application contexts that may be created.
registers the specified type converter in the
single application context specified. If the same from_type and
to_type are specified in multiple calls to either function, the most
recent overrides the previous ones.
For the few type converters that need additional arguments,
the Intrinsics conversion mechanism provides a method of specifying
how these arguments should be computed.
The enumerated type
XtAddressMode
and the structure
XtConvertArgRec
specify how each argument is derived.
These are defined in
.
typedef enum {
/* address mode parameter representation */
XtAddress, /* address */
XtBaseOffset, /* offset */
XtImmediate, /* constant */
XtResourceString, /* resource name string */
XtResourceQuark, /* resource name quark */
XtWidgetBaseOffset, /* offset */
XtProcedureArg /* procedure to call */
} XtAddressMode;
typedef struct {
XtAddressMode address_mode;
XtPointer address_id;
Cardinal size;
} XtConvertArgRec, *XtConvertArgList;
The size field specifies the length of the data in bytes.
The address_mode field specifies how the address_id field should be
interpreted.
XtAddress
causes address_id to be interpreted as the address of the data.
XtBaseOffset
causes address_id to be interpreted as the offset from the widget base.
XtImmediate
causes address_id to be interpreted as a constant.
XtResourceString
causes address_id to be interpreted as the name of a resource
that is to be converted into an offset from the widget base.
XtResourceQuark
causes address_id to be interpreted as the result of an
XrmStringToQuark
conversion on the name of a resource,
which is to be converted into an offset from the widget base.
XtWidgetBaseOffset
is similar to
XtBaseOffset
except that it
searches for the closest windowed ancestor if the object is not
of a subclass of
Core
(see ).
XtProcedureArg
specifies that address_id is a pointer to a procedure to
be invoked to return the conversion argument. If
XtProcedureArg
is specified, address_id must contain
the address of a function of type
.
typedef void (*XtConvertArgProc)
Widget object
Cardinal *size
XrmValue *value
object
Passes the object for which the resource is being
converted, or NULL if the converter was invoked by
or
.
size
Passes a pointer to the size field from the XtConvertArgRec.
value
Passes a pointer to a descriptor into which the procedure must store the
conversion argument.
When invoked, the XtConvertArgProc procedure must derive a
conversion argument and store the address and size of the
argument in the location pointed to by value.
In order to permit reentrancy, the XtConvertArgProc should
return the address of storage whose lifetime is no shorter
than the lifetime of object.
If object is NULL,
the lifetime of the conversion argument must be no shorter than the
lifetime of the resource with which the conversion argument
is associated. The Intrinsics do not guarantee to copy this
storage but do guarantee not to reference it if the resource
is removed from the conversion cache.
The following example illustrates how to register the
CvtStringToPixel
routine given earlier:
static XtConvertArgRec colorConvertArgs[] = {
{XtWidgetBaseOffset,
(XtPointer)XtOffset(Widget, core.screen),
sizeof(Screen*)},
{XtWidgetBaseOffset,
(XtPointer)XtOffset(Widget, core.colormap),
sizeof(Colormap)}
};
XtSetTypeConverter(XtRString,
XtRPixel,
CvtStringToPixel,
colorConvertArgs,
XtNumber(colorConvertArgs),
XtCacheByDisplay, NULL);
The conversion argument descriptors colorConvertArgs and
screenConvertArg are predefined by the Intrinsics. Both
take the values from the closest windowed ancestor if the
object is not of a subclass of Core. The screenConvertArg
descriptor puts the widget’s screen field into args[0]. The
colorConvertArgs descriptor puts the widget’s screen field
into args[0], and the widget’s colormap field into args[1].
Conversion routines should not just put a descriptor for the
address of the base of the widget into args[0], and use that
in the routine. They should pass in the actual values on
which the conversion depends. By keeping the dependencies
of the conversion procedure specific, it is more likely that
subsequent conversions will find what they need in the conversion cache.
This way the cache is smaller and has fewer
and more widely applicable entries.
If any conversion arguments of type
XtBaseOffset,
XtResourceString,
XtResourceQuark,
and
XtWidgetBaseOffset
are
specified for conversions performed by
XtGetApplicationResources,
XtGetSubresources,
XtVaGetApplicationResources,
or
XtVaGetSubresources,
the arguments are computed with respect
to the specified widget, not the base address or resource
list specified in the call.
If the XtConvertArgProc modifies the resource database, the
changes affect any in-progress widget creation,
,
or
in an implementation-defined manner;
however, insertion of new entries or changes
to existing entries are allowed and will not directly cause
an error.
Resource Converter Invocation
All resource-fetching routines (for example,
,
,
and so on) call resource converters if the resource database or
varargs list specifies a value
that has a different representation from the desired representation or if the
widget's default resource value representation is different from the desired
representation.
To invoke explicit resource conversions, use
or
.
typedef XtPointer XtCacheRef;
Boolean XtCallConverter
Display* display
XtTypeConverter converter
XrmValuePtr conversion_args
Cardinal num_args
XrmValuePtr from
XrmValuePtr to_in_out
XtCacheRef *cache_ref_return
display
Specifies the display with which the conversion is to be associated.
converter
Specifies the conversion procedure to be called.
conversion_args
Specifies the additional conversion arguments needed
to perform the conversion, or NULL.
num_args
Specifies the number of entries in conversion_args.
from
Specifies a descriptor for the source value.
to_in_out
Returns the converted value.
cache_ref_return
Returns a conversion cache id.
The
function looks up the
specified type converter in the application context associated with
the display and, if the converter was not registered or was registered
with cache type
XtCacheAll
or
XtCacheByDisplay,
looks in the conversion cache to see if this conversion procedure
has been called with the specified conversion arguments. If so, it
checks the success status of the prior call, and if
the conversion failed,
returns
False
immediately;
otherwise it checks the size specified in the to argument, and, if it is
greater than or equal to the size stored in the cache, copies the
information stored in the cache into the location specified by
to->addr, stores the cache size into to->size, and returns
True.
If the size specified in the to argument is smaller than the size stored
in the cache,
copies the cache size into to->size and returns
False.
If the converter was registered with cache type
XtCacheNone
or no value was found in the conversion cache,
calls the converter, and if it was not registered with cache type
XtCacheNone,
enters the result in the cache.
then returns what the converter returned.
The cache_ref_return field specifies storage allocated by the caller in which
an opaque value will be stored. If the type converter has been
registered with the
XtCacheRefCount
modifier and if the value returned
in cache_ref_return is non-NULL, then the caller should store the
cache_ref_return value in order to decrement the reference count when
the converted value is no longer required. The cache_ref_return
argument should be
NULL if the caller is unwilling or unable to store the
value.
To explicitly decrement the reference counts for resources obtained
from
,
use
.
void XtAppReleaseCacheRefs
XtAppContext app_context
XtCacheRef *refs
app_context
Specifies the application context.
refs
Specifies the list of cache references to be released.
decrements the reference count for the
conversion entries identified by the refs argument.
This argument is a
pointer to a NULL-terminated list of
XtCacheRef
values. If any reference
count reaches zero, the destructor, if any, will be called and
the resource removed from the conversion cache.
As a convenience to clients needing to explicitly decrement reference
counts via a callback function, the Intrinsics define two callback
procedures,
and
.
void XtCallbackReleaseCacheRef
Widget object
XtPointer client_data
XtPointer call_data
object
Specifies the object with which the resource is associated.
client_data
Specifies the conversion cache entry to be released.
call_data
Is ignored.
This callback procedure may be added to a callback list to release a
previously returned
XtCacheRef
value. When adding the callback, the
callback client_data argument must be specified as the value of the
XtCacheRef
data cast to type
XtPointer.
void XtCallbackReleaseCacheRefList
Widget object
XtPointer client_data
XtPointer call_data
object
Specifies the object with which the resources are associated.
client_data
Specifies the conversion cache entries to be released.
call_data
Is ignored.
This callback procedure may be added to a callback list to release a
list of previously returned
XtCacheRef
values. When adding the
callback, the callback client_data argument must be specified as a
pointer to a NULL-terminated list of
XtCacheRef
values.
To lookup and call a resource converter, copy the resulting value,
and free a cached resource when a widget is destroyed, use
.
Boolean XtConvertAndStore
Widget object
const char * from_type
XrmValuePtr from
const char * to_type
XrmValuePtr to_in_out
object
Specifies the object to use for additional arguments, if any are needed,
and the destroy callback list. Must be of class Object or any subclass thereof.
from_type
Specifies the source type.
from
Specifies the value to be converted.
to_type
Specifies the destination type.
to_in_out
Specifies a descriptor for storage into which the converted value
will be returned.
The
function looks up the type converter registered
to convert from_type to to_type, computes any additional arguments
needed, and then calls
(or
if an old-style converter was registered with
or
;
see Appendix C) with the from and to_in_out arguments. The
to_in_out argument specifies the size and location into which the
converted value will be stored and is passed directly to the
converter. If the location is specified as NULL, it will be replaced
with a pointer to private storage and the size will be returned in the
descriptor. The caller is expected to copy this private storage
immediately and must not modify it in any way. If a non-NULL location
is specified, the caller must allocate sufficient storage to hold the
converted value and must also specify the size of that storage in the
descriptor.
The size field will be modified on return to indicate the actual
size of the converted data.
If the conversion succeeds,
returns
True;
otherwise, it returns
False.
adds
to the destroyCallback list of the specified object if the conversion
returns an
XtCacheRef
value. The resulting resource should not be referenced
after the object has been destroyed.
performs processing equivalent to
when initializing the object instance. Because there is extra memory
overhead required to implement reference counting, clients may
distinguish those objects that are never destroyed before the
application exits from those that may be destroyed and whose
resources should be deallocated.
To specify whether reference counting is to be enabled for the
resources of a particular object when the object is created, the
client can specify a value for the
Boolean
resource
XtNinitialResourcesPersistent,
class
XtCInitialResourcesPersistent.
When
is called, if this resource is not specified as
False
in either the arglist or the resource database, then the
resources referenced by this object are not reference-counted, regardless of
how the type converter may have been registered. The effective
default value is
True;
thus clients that expect to destroy one or
more objects and want resources deallocated must explicitly specify
False
for
XtNinitialResourcesPersistent.
The resources are still freed and destructors called when
is called if the conversion was registered as
XtCacheByDisplay.
Reading and Writing Widget State
Any resource field in a widget can be read or written by a client.
On a write operation,
the widget decides what changes it will actually allow and updates all
derived fields appropriately.
Obtaining Widget State
To retrieve the current values of resources associated with a
widget instance, use
.
void XtGetValues
Widget object
ArgList args
Cardinal num_args
object
Specifies the object whose resource values are to be returned. Must be of class Object or any subclass thereof.
args
Specifies the argument list of name/address pairs that contain the
resource names and the addresses into which the resource values are to
be stored.
The resource names are widget-dependent.
num_args
Specifies the number of entries in the argument list.
The
function starts with the resources specified for the Object class
and proceeds down the subclass chain to the class of the object.
The value field of a passed argument list must contain the
address into which to copy the contents of the corresponding
object instance field. If the field is a pointer type, the lifetime
of the pointed-to data is defined by the object class. For the
Intrinsics-defined resources, the following lifetimes apply:
Not valid following any operation that modifies the resource:
XtNchildren resource of composite widgets.
All resources of representation type XtRCallback.
Remain valid at least until the widget is destroyed:
XtNaccelerators, XtNtranslations.
Remain valid until the Display is closed:
XtNscreen.
It is the caller's responsibility
to allocate and deallocate storage for the copied data
according to the size of the
resource representation type used within the object.
If the class of the object's parent is a subclass of
constraintWidgetClass,
then fetches the values for any constraint resources requested.
It starts with the constraint resources specified for
constraintWidgetClass
and proceeds down the subclass chain to the parent's constraint resources.
If the argument list contains a resource name that is not found in any of the
resource lists searched,
the value at the corresponding address is not modified.
If any get_values_hook procedures in the
object's class or superclass records are non-NULL,
they are called in superclass-to-subclass order after
all the resource values have been fetched by
.
Finally, if the object's parent is a
subclass of
constraintWidgetClass,
and if any of the parent's class or
superclass records have declared
ConstraintClassExtension
records in
the Constraint class part extension field with a record type of
NULLQUARK,
and if the get_values_hook field in the extension record is non-NULL,
calls the get_values_hook procedures in superclass-to-subclass order.
This permits a Constraint parent to provide
nonresource data via
.
Get_values_hook procedures may modify the data stored at the
location addressed by the value field, including (but not
limited to) making a copy of data whose resource representation is a
pointer. None of the Intrinsics-defined object classes copy
data in this manner. Any operation that modifies the queried
object resource may invalidate the pointed-to data.
To retrieve the current values of resources associated with a widget
instance using varargs lists, use
.
void XtVaGetValues
Widget object
...
object
Specifies the object whose resource values are to be returned. Must be of class Object or any subclass thereof.
...
Specifies the variable argument list for the resources to
be returned.
is identical in function to
with the args
and num_args parameters replaced by a varargs list, as described in
Section 2.5.1. All value entries in the list must specify pointers to
storage allocated by the caller to which the resource value will be
copied. It is the caller's responsibility to ensure that sufficient
storage is allocated. If
XtVaTypedArg
is specified, the type argument
specifies the representation desired by the caller and the size argument
specifies the number of bytes allocated to store the result of the
conversion. If the size is insufficient, a warning message is issued
and the list entry is skipped.
Widget Subpart Resource Data: The get_values_hook Procedure
Widgets that have subparts can return resource values from them through
by supplying a get_values_hook procedure.
The get_values_hook procedure pointer is of type
.
typedef void (*XtArgsProc)
Widget w
ArgList args
Cardinal *num_args
w
Specifies the widget whose subpart resource values are to be retrieved.
args
Specifies the argument list that was passed to
or the transformed varargs list passed to
.
num_args
Specifies the number of entries in the argument list.
The widget with subpart resources should call
in the get_values_hook procedure
and pass in its subresource list and the args and num_args parameters.
Widget Subpart State
To retrieve the current values of subpart resource data associated with a
widget instance, use
.
For a discussion of subpart resources,
see .
void XtGetSubvalues
XtPointer base
XtResourceList resources
Cardinal num_resources
ArgList args
Cardinal num_args
base
Specifies the base address of the subpart data structure for which the
resources should be retrieved.
resources
Specifies the subpart resource list.
num_resources
Specifies the number of entries in the resource list.
args
Specifies the argument list of name/address pairs that contain the
resource names and the addresses into which the resource values are to
be stored.
num_args
Specifies the number of entries in the argument list.
The
function obtains resource values from the structure identified by base.
The value field in each argument entry must contain the address into
which to store the corresponding resource value. It is the caller's
responsibility to allocate and deallocate this storage according to
the size of the resource representation type used within the subpart.
If the argument list contains a resource name that is not found in the
resource list, the value at the corresponding address is not modified.
To retrieve the current values of subpart resources associated with
a widget instance using varargs lists, use
.
void XtVaGetSubvalues
XtPointer base
XtResourceList resources
Cardinal num_resources
...
base
Specifies the base address of the subpart data structure for which the
resources should be retrieved.
resources
Specifies the subpart resource list.
num_resources
Specifies the number of entries in the resource list.
...
Specifies a variable argument list of name/address pairs that
contain the resource names and the addresses into which the resource
values are to be stored.
is identical in function to
with the
args and num_args parameters replaced by a varargs list, as described
in Section 2.5.1.
XtVaTypedArg
is not supported for
.
If
XtVaTypedArg
is specified in the list, a warning message is issued
and the entry is then ignored.
Setting Widget State
To modify the current values of resources associated with a widget
instance, use
.
void XtSetValues
Widget object
ArgList args
Cardinal num_args
object
Specifies the object whose resources are to be modified. Must be of class Object or any subclass thereof.
args
Specifies the argument list of name/value pairs that contain the
resources to be modified and their new values.
num_args
Specifies the number of entries in the argument list.
The
function starts with the resources specified for the
Object
class fields and proceeds down the subclass chain to the object.
At each stage, it replaces the object resource fields with any values
specified in the argument list.
then calls the set_values procedures for the object in superclass-to-subclass
order.
If the object has any non-NULL set_values_hook fields,
these are called immediately after the
corresponding set_values procedure.
This procedure permits subclasses to set subpart data via
.
If the class of the object's parent is a subclass of
constraintWidgetClass,
also updates the object's constraints.
It starts with the constraint resources specified for
constraintWidgetClass
and proceeds down the subclass chain to the parent's class.
At each stage, it replaces the constraint resource fields with any
values specified in the argument list.
It then calls the constraint set_values procedures from
constraintWidgetClass
down to the parent's class.
The constraint set_values procedures are called with widget arguments,
as for all set_values procedures, not just the constraint records,
so that they can make adjustments to the desired values based
on full information about the widget. Any arguments specified that
do not match a resource list entry are silently ignored.
If the object is of a subclass of
RectObj,
determines if a geometry request is needed by comparing the old object to
the new object.
If any geometry changes are required,
restores the original geometry and makes the request on behalf of the widget.
If the geometry manager returns
XtGeometryYes,
calls the object's resize procedure.
If the geometry manager returns
XtGeometryDone,
continues, as the object's resize procedure should have been called
by the geometry manager.
If the geometry manager returns
XtGeometryNo,
ignores the geometry request and continues.
If the geometry manager returns
XtGeometryAlmost,
calls the set_values_almost procedure,
which determines what should be done.
then repeats this process,
deciding once more whether the geometry manager should be called.
Finally, if any of the set_values procedures returned
True,
and the widget is realized,
causes the widget's expose procedure to be invoked by calling
XClearArea
on the widget's window.
To modify the current values of resources associated with a widget
instance using varargs lists, use
.
void XtVaSetValues
Widget object
...
object
Specifies the object whose resources are to be modified. Must be of class Object or any subclass thereof.
...
Specifies the variable argument list of name/value pairs that
contain the resources to be modified and their new values.
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 State: The set_values Procedure
The set_values procedure pointer in a widget class is of type
.
typedef Boolean (*XtSetValuesFunc)
Widget current
Widget request
Widget new
ArgList args
Cardinal *num_args
current
Specifies a copy of the widget as it was before the
call.
request
Specifies a copy of the widget with all values changed as asked for by the
call before any class set_values procedures have been called.
new
Specifies the widget with the new values that are actually allowed.
args
Specifies the argument list passed to
or the transformed argument list passed to
.
num_args
Specifies the number of entries in the argument list.
The set_values procedure should recompute any field
derived from resources that are changed
(for example, many GCs depend on foreground and background pixels).
If no recomputation is necessary, and if none of the resources specific to a
subclass require the window to be redisplayed when their values are changed,
you can specify NULL for the set_values field in the class record.
Like the initialize procedure,
set_values mostly deals only with the fields defined in the subclass,
but it has to resolve conflicts with its superclass,
especially conflicts over width and height.
Sometimes a subclass may want to overwrite values filled in by its
superclass.
In particular, size calculations of a superclass are often
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 set_values
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.
How does a subclass know the difference between a specified size
and a size computed by a superclass?
The request and new parameters provide the necessary information.
The request widget is a copy of the widget, updated as originally requested.
The new widget starts with the values in the request,
but it has additionally been updated by all superclass set_values
procedures called so far.
A subclass set_values procedure can compare these two to resolve
any potential conflicts.
The set_values procedure need not refer to the request widget
unless it must resolve conflicts between the current and new widgets.
Any changes the widget needs to make, including geometry changes,
should be made in the new widget.
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.
In this case, zero is a special value defined by the class to permit
the application to invoke this behavior.
The new widget is the actual widget instance record.
Therefore,
the set_values procedure should do all its work on the new widget;
the request widget should never be modified.
If the set_values procedure needs to call any routines that operate on
a widget, it should specify new as the widget instance.
Before calling the set_values procedures, the Intrinsics modify the
resources of the request widget according to the contents of the arglist;
if the widget names all its resources in the class resource list, it is
never necessary to examine the contents of args.
Finally, the set_values procedure must return a Boolean that indicates whether
the widget needs to be redisplayed.
Note that a change in the geometry fields alone does not require
the set_values procedure to return
True;
the X server will eventually generate an
Expose
event, if necessary.
After calling all the set_values procedures,
forces a redisplay by calling
XClearArea
if any of the set_values procedures returned
True.
Therefore, a set_values procedure should not try to do its own redisplaying.
Set_values procedures should not do any work in response to changes in
geometry because
eventually will perform a geometry request, and that request might be denied.
If the widget actually changes size in response to a
call to
,
its resize procedure is called.
Widgets should do any geometry-related work in their resize procedure.
Note that it is permissible to call
before a widget is realized.
Therefore, the set_values procedure must not assume that the widget is realized.
Widget State: The set_values_almost Procedure
The set_values_almost procedure pointer in the widget class record is of type
.
typedef void (*XtAlmostProc)
Widget old
Widget new
XtWidgetGeometry *request
XtWidgetGeometry *reply
old
Specifies a copy of the object as it was before the
call.
new
Specifies the object instance record.
request
Specifies the original geometry request that was sent to the geometry
manager that caused
XtGeometryAlmost
to be returned.
reply
Specifies the compromise geometry that was returned by the geometry
manager with
XtGeometryAlmost.
Most classes inherit the set_values_almost procedure from their superclass by
specifying
XtInheritSetValuesAlmost
in the class initialization.
The
set_values_almost procedure in
rectObjClass
accepts the compromise suggested.
The set_values_almost procedure is called when a client tries to set a widget's
geometry by means of a call to
and the geometry manager cannot
satisfy the request but instead returns
XtGeometryNo
or
XtGeometryAlmost
and a compromise geometry.
The new object is the actual instance record. The x, y,
width, height,
and border_width fields contain the original values as they were
before the
call, and all other fields contain the new
values. The request parameter contains the new geometry request that
was made to the parent. The reply parameter contains
reply->request_mode equal to zero if the parent returned
XtGeometryNo
and contains the parent's compromise geometry otherwise. The
set_values_almost procedure takes the original geometry and the
compromise geometry and determines if the compromise is
acceptable or whether
to try a different compromise.
It returns its results in the request parameter,
which is then sent back to the geometry manager for another try.
To accept the compromise, the procedure must copy the contents
of the reply geometry into the request geometry; to attempt an
alternative geometry, the procedure may modify any part of the request
argument; to terminate the geometry negotiation and retain the
original geometry, the procedure must set request->request_mode to
zero. The geometry fields of the old and new instances must not be modified
directly.
Widget State: The ConstraintClassPart set_values Procedure
The constraint set_values procedure pointer is of type
.
The values passed to the parent's constraint set_values procedure
are the same as those passed to the child's class
set_values procedure.
A class can specify NULL for the set_values field of the
ConstraintPart
if it need not compute anything.
The constraint set_values procedure should recompute any constraint fields
derived from constraint resources that are changed.
Furthermore, it may modify other widget fields as appropriate.
For example, if a constraint for the maximum height of a widget is changed
to a value smaller than the widget's current height,
the constraint set_values procedure may reset the height field in the
widget.
Widget Subpart State
To set the current values of subpart resources associated with a
widget instance, use
.
For a discussion of subpart resources,
see .
void XtSetSubvalues
XtPointer base
XtResourceList resources
Cardinal num_resources
ArgList args
Cardinal num_args
base
Specifies the base address of the subpart data structure into which the
resources should be written.
resources
Specifies the subpart resource list.
num_resources
Specifies the number of entries in the resource list.
args
Specifies the argument list of name/value pairs that contain the
resources to be modified and their new values.
num_args
Specifies the number of entries in the argument list.
The
function updates the resource fields of the structure identified by
base. Any specified arguments that do not match an entry in the
resource list are silently ignored.
To set the current values of subpart resources associated with
a widget instance using varargs lists, use
.
void XtVaSetSubvalues
XtPointer base
XtResourceList resources
Cardinal num_resources
...
base
Specifies the base address of the subpart data structure into which the
resources should be written.
resources
Specifies the subpart resource list.
num_resources
Specifies the number of entries in the resource list.
...
Specifies the variable argument list of name/value pairs that
contain the resources to be modified and their new values.
is identical in function to
with the args and num_args parameters replaced by a varargs list, as
described in Section 2.5.1.
XtVaTypedArg
is not supported for
.
If an entry containing
XtVaTypedArg
is specified in the list, a warning message is issued
and the entry is ignored.
Widget Subpart Resource Data: The set_values_hook Procedure
The set_values_hook procedure is obsolete, as the same information
is now available to the set_values procedure. The procedure has been
retained for those widgets that used it in versions prior to Release 4.
Widgets that have a subpart can set the subpart resource values through
by supplying a set_values_hook procedure.
The set_values_hook procedure pointer in a widget class is of type
.
typedef Boolean (*XtArgsFunc)
Widget w
Arglist args
Cardinal *num_args
w
Specifies the widget whose subpart resource values are to be changed.
args
Specifies the argument list that was passed to
or the transformed varargs list passed to
.
num_args
Specifies the number of entries in the argument list.
The widget with subpart resources may call
from the set_values_hook procedure
and pass in its subresource list and the
args and num_args parameters.