Next: Splicing into Lists, Previous: Simple Types, Up: Customization Types [Contents][Index]
When none of the simple types is appropriate, you can use composite types, which build new types from other types or from specified data. The specified types or data are called the arguments of the composite type. The composite type normally looks like this:
(constructor arguments…)
but you can also add keyword-value pairs before the arguments, like this:
(constructor {keyword value}… arguments…)
Here is a table of constructors and how to use them to write composite types:
(cons car-type cdr-type)
The value must be a cons cell, its CAR must fit car-type, and
its CDR must fit cdr-type. For example, (cons string
symbol)
is a customization type which matches values such as
("foo" . foo)
.
In the customization buffer, the CAR and CDR are displayed and edited separately, each according to their specified type.
(list element-types…)
The value must be a list with exactly as many elements as the element-types given; and each element must fit the corresponding element-type.
For example, (list integer string function)
describes a list of
three elements; the first element must be an integer, the second a
string, and the third a function.
In the customization buffer, each element is displayed and edited separately, according to the type specified for it.
(group element-types…)
This works like list
except for the formatting
of text in the Custom buffer. list
labels each
element value with its tag; group
does not.
(vector element-types…)
Like list
except that the value must be a vector instead of a
list. The elements work the same as in list
.
(alist :key-type key-type :value-type value-type)
The value must be a list of cons-cells, the CAR of each cell representing a key of customization type key-type, and the CDR of the same cell representing a value of customization type value-type. The user can add and delete key/value pairs, and edit both the key and the value of each pair.
If omitted, key-type and value-type default to
sexp
.
The user can add any key matching the specified key type, but you can
give some keys a preferential treatment by specifying them with the
:options
(see Variable Definitions). The specified keys
will always be shown in the customize buffer (together with a suitable
value), with a checkbox to include or exclude or disable the key/value
pair from the alist. The user will not be able to edit the keys
specified by the :options
keyword argument.
The argument to the :options
keywords should be a list of
specifications for reasonable keys in the alist. Ordinarily, they are
simply atoms, which stand for themselves. For example:
:options '("foo" "bar" "baz")
specifies that there are three “known” keys, namely "foo"
,
"bar"
and "baz"
, which will always be shown first.
You may want to restrict the value type for specific keys, for
example, the value associated with the "bar"
key can only be an
integer. You can specify this by using a list instead of an atom in
the list. The first element will specify the key, like before, while
the second element will specify the value type. For example:
:options '("foo" ("bar" integer) "baz")
Finally, you may want to change how the key is presented. By default,
the key is simply shown as a const
, since the user cannot change
the special keys specified with the :options
keyword. However,
you may want to use a more specialized type for presenting the key, like
function-item
if you know it is a symbol with a function binding.
This is done by using a customization type specification instead of a
symbol for the key.
:options '("foo" ((function-item some-function) integer) "baz")
Many alists use lists with two elements, instead of cons cells. For example,
(defcustom list-alist '(("foo" 1) ("bar" 2) ("baz" 3)) "Each element is a list of the form (KEY VALUE).")
instead of
(defcustom cons-alist '(("foo" . 1) ("bar" . 2) ("baz" . 3)) "Each element is a cons-cell (KEY . VALUE).")
Because of the way lists are implemented on top of cons cells, you can
treat list-alist
in the example above as a cons cell alist, where
the value type is a list with a single element containing the real
value.
(defcustom list-alist '(("foo" 1) ("bar" 2) ("baz" 3)) "Each element is a list of the form (KEY VALUE)." :type '(alist :value-type (group integer)))
The group
widget is used here instead of list
only because
the formatting is better suited for the purpose.
Similarly, you can have alists with more values associated with each key, using variations of this trick:
(defcustom person-data '(("brian" 50 t) ("dorith" 55 nil) ("ken" 52 t)) "Alist of basic info about people. Each element has the form (NAME AGE MALE-FLAG)." :type '(alist :value-type (group integer boolean)))
(plist :key-type key-type :value-type value-type)
This customization type is similar to alist
(see above), except
that (i) the information is stored as a property list,
(see Property Lists), and (ii) key-type, if omitted,
defaults to symbol
rather than sexp
.
(choice alternative-types…)
The value must fit one of alternative-types. For example,
(choice integer string)
allows either an integer or a string.
In the customization buffer, the user selects an alternative using a menu, and can then edit the value in the usual way for that alternative.
Normally the strings in this menu are determined automatically from the
choices; however, you can specify different strings for the menu by
including the :tag
keyword in the alternatives. For example, if
an integer stands for a number of spaces, while a string is text to use
verbatim, you might write the customization type this way,
(choice (integer :tag "Number of spaces") (string :tag "Literal text"))
so that the menu offers ‘Number of spaces’ and ‘Literal text’.
In any alternative for which nil
is not a valid value, other than
a const
, you should specify a valid default for that alternative
using the :value
keyword. See Type Keywords.
If some values are covered by more than one of the alternatives, customize will choose the first alternative that the value fits. This means you should always list the most specific types first, and the most general last. Here’s an example of proper usage:
(choice (const :tag "Off" nil) symbol (sexp :tag "Other"))
This way, the special value nil
is not treated like other
symbols, and symbols are not treated like other Lisp expressions.
(radio element-types…)
This is similar to choice
, except that the choices are displayed
using ‘radio buttons’ rather than a menu. This has the advantage of
displaying documentation for the choices when applicable and so is often
a good choice for a choice between constant functions
(function-item
customization types).
(const value)
The value must be value—nothing else is allowed.
The main use of const
is inside of choice
. For example,
(choice integer (const nil))
allows either an integer or
nil
.
:tag
is often used with const
, inside of choice
.
For example,
(choice (const :tag "Yes" t) (const :tag "No" nil) (const :tag "Ask" foo))
describes a variable for which t
means yes, nil
means no,
and foo
means “ask”.
(other value)
This alternative can match any Lisp value, but if the user chooses this alternative, that selects the value value.
The main use of other
is as the last element of choice
.
For example,
(choice (const :tag "Yes" t) (const :tag "No" nil) (other :tag "Ask" foo))
describes a variable for which t
means yes, nil
means no,
and anything else means “ask”. If the user chooses ‘Ask’ from
the menu of alternatives, that specifies the value foo
; but any
other value (not t
, nil
or foo
) displays as
‘Ask’, just like foo
.
(function-item function)
Like const
, but used for values which are functions. This
displays the documentation string as well as the function name.
The documentation string is either the one you specify with
:doc
, or function’s own documentation string.
(variable-item variable)
Like const
, but used for values which are variable names. This
displays the documentation string as well as the variable name. The
documentation string is either the one you specify with :doc
, or
variable’s own documentation string.
(set types…)
The value must be a list, and each element of the list must match one of the types specified.
This appears in the customization buffer as a checklist, so that each of
types may have either one corresponding element or none. It is
not possible to specify two different elements that match the same one
of types. For example, (set integer symbol)
allows one
integer and/or one symbol in the list; it does not allow multiple
integers or multiple symbols. As a result, it is rare to use
nonspecific types such as integer
in a set
.
Most often, the types in a set
are const
types, as
shown here:
(set (const :bold) (const :italic))
Sometimes they describe possible elements in an alist:
(set (cons :tag "Height" (const height) integer) (cons :tag "Width" (const width) integer))
That lets the user specify a height value optionally and a width value optionally.
(repeat element-type)
The value must be a list and each element of the list must fit the type element-type. This appears in the customization buffer as a list of elements, with ‘[INS]’ and ‘[DEL]’ buttons for adding more elements or removing elements.
(restricted-sexp :match-alternatives criteria)
This is the most general composite type construct. The value may be any Lisp object that satisfies one of criteria. criteria should be a list, and each element should be one of these possibilities:
nil
or non-nil
according to
the argument. Using a predicate in the list says that objects for which
the predicate returns non-nil
are acceptable.
'object
. This sort of element
in the list says that object itself is an acceptable value.
For example,
(restricted-sexp :match-alternatives (integerp 't 'nil))
allows integers, t
and nil
as legitimate values.
The customization buffer shows all legitimate values using their read syntax, and the user edits them textually.
Here is a table of the keywords you can use in keyword-value pairs in a composite type:
:tag tag
Use tag as the name of this alternative, for user communication
purposes. This is useful for a type that appears inside of a
choice
.
:match-alternatives criteria
Use criteria to match possible values. This is used only in
restricted-sexp
.
:args argument-list
Use the elements of argument-list as the arguments of the type
construct. For instance, (const :args (foo))
is equivalent to
(const foo)
. You rarely need to write :args
explicitly,
because normally the arguments are recognized automatically as
whatever follows the last keyword-value pair.
Next: Splicing into Lists, Previous: Simple Types, Up: Customization Types [Contents][Index]