XrmGetResource(3) XLIB FUNCTIONS XrmGetResource(3)
XrmGetResource, XrmQGetResource, XrmQGetSearchList, XrmQGetSearchResource - retrieve database resources and search lists
Bool XrmGetResource(XrmDatabase database, char *str_name, char *str_class, char **str_type_return, XrmValue *value_return);
Bool XrmQGetResource(XrmDatabase database, XrmNameList quark_name, XrmClassList quark_class, XrmRepresentation *quark_type_return, XrmValue
typedef XrmHashTable *XrmSearchList;
Bool XrmQGetSearchList(XrmDatabase database, XrmNameList names, XrmClassList classes, XrmSearchList list_return, int list_length);
Bool XrmQGetSearchResource(XrmSearchList list, XrmName name, XrmClass class, XrmRepresentation *type_return, XrmValue *value_return);
class Specifies the resource class.
classes Specifies a list of resource classes.
database Specifies the database that is to be used.
list Specifies the search list returned by XrmQGetSearchList.
Specifies the number of entries (not the byte size) allocated for list_return.
Returns a search list for further use.
name Specifies the resource name.
names Specifies a list of resource names.
Specifies the fully qualified class of the value being retrieved (as a quark).
Specifies the fully qualified name of the value being retrieved (as a quark).
Returns the representation type of the destination (as a quark).
str_class Specifies the fully qualified class of the value being retrieved (as a string).
str_name Specifies the fully qualified name of the value being retrieved (as a string).
Returns the representation type of the destination (as a string).
Returns data representation type.
Returns the value in the database.
The XrmGetResource and XrmQGetResource functions retrieve a resource from the specified database. Both take a fully qualified name/class
pair, a destination resource representation, and the address of a value (size/address pair). The value and returned type point into data-
base memory; therefore, you must not modify the data.
The database only frees or overwrites entries on XrmPutResource, XrmQPutResource, or XrmMergeDatabases. A client that is not storing new
values into the database or is not merging the database should be safe using the address passed back at any time until it exits. If a
resource was found, both XrmGetResource and XrmQGetResource return True; otherwise, they return False.
The XrmQGetSearchList function takes a list of names and classes and returns a list of database levels where a match might occur. The
returned list is in best-to-worst order and uses the same algorithm as XrmGetResource for determining precedence. If list_return was large
enough for the search list, XrmQGetSearchList returns True; otherwise, it returns False.
The size of the search list that the caller must allocate is dependent upon the number of levels and wildcards in the resource specifiers
that are stored in the database. The worst case length is %3 sup n%, where n is the number of name or class components in names or
When using XrmQGetSearchList followed by multiple probes for resources with a common name and class prefix, only the common prefix should
be specified in the name and class list to XrmQGetSearchList.
The XrmQGetSearchResource function searches the specified database levels for the resource that is fully identified by the specified name
and class. The search stops with the first match. XrmQGetSearchResource returns True if the resource was found; otherwise, it returns
A call to XrmQGetSearchList with a name and class list containing all but the last component of a resource name followed by a call to
XrmQGetSearchResource with the last component name and class returns the same database entry as XrmGetResource and XrmQGetResource with the
fully qualified name and class.
The algorithm for determining which resource database entry matches a given query is the heart of the resource manager. All queries must
fully specify the name and class of the desired resource (use of the characters ``*'' and ``?'' are not permitted). The library supports
up to 100 components in a full name or class. Resources are stored in the database with only partially specified names and classes, using
pattern matching constructs. An asterisk (*) is a loose binding and is used to represent any number of intervening components, including
none. A period (.) is a tight binding and is used to separate immediately adjacent components. A question mark (?) is used to match any
single component name or class. A database entry cannot end in a loose binding; the final component (which cannot be the character ``?'')
must be specified. The lookup algorithm searches the database for the entry that most closely matches (is most specific for) the full name
and class being queried. When more than one database entry matches the full name and class, precedence rules are used to select just one.
The full name and class are scanned from left to right (from highest level in the hierarchy to lowest), one component at a time. At each
level, the corresponding component and/or binding of each matching entry is determined, and these matching components and bindings are com-
pared according to precedence rules. Each of the rules is applied at each level before moving to the next level, until a rule selects a
single entry over all others. The rules, in order of precedence, are:
1. An entry that contains a matching component (whether name, class, or the character ``?'') takes precedence over entries that elide
the level (that is, entries that match the level in a loose binding).
2. An entry with a matching name takes precedence over both entries with a matching class and entries that match using the character
``?''. An entry with a matching class takes precedence over entries that match using the character ``?''.
3. An entry preceded by a tight binding takes precedence over entries preceded by a loose binding.
XrmInitialize(3X11), XrmMergeDatabases(3X11), XrmPutResource(3X11), XrmUniqueQuark(3X11)
Xlib - C Language X Interface
X Version 11 libX11 1.2.1 XrmGetResource(3)