Functions defined using
defun have a hard-coded set of
assumptions about the types and expected values of their arguments.
For example, a function that was designed to handle values of its
argument that are either numbers or lists of numbers will fail or
signal an error if called with a value of any other type, such as a
vector or a string. This happens because the implementation of the
function is not prepared to deal with types other than those assumed
during the design.
By contrast, object-oriented programs use polymorphic functions: a set of specialized functions having the same name, each one of which was written for a certain specific set of argument types. Which of the functions is actually called is decided at run time based on the types of the actual arguments.
Emacs provides support for polymorphism. Like other Lisp environments, notably Common Lisp and its Common Lisp Object System (CLOS), this support is based on generic functions. The Emacs generic functions closely follow CLOS, including use of similar names, so if you have experience with CLOS, the rest of this section will sound very familiar.
A generic function specifies an abstract operation, by defining its
name and list of arguments, but (usually) no implementation. The
actual implementation for several specific classes of arguments is
provided by methods, which should be defined separately. Each
method that implements a generic function has the same name as the
generic function, but the method’s definition indicates what kinds of
arguments it can handle by specializing the arguments defined by
the generic function. These argument specializers can be more
or less specific; for example, a
string type is more specific
than a more general type, such as
Note that, unlike in message-based OO languages, such as C++ and Simula, methods that implement generic functions don’t belong to a class, they belong to the generic function they implement.
When a generic function is invoked, it selects the applicable methods by comparing the actual arguments passed by the caller with the argument specializers of each method. A method is applicable if the actual arguments of the call are compatible with the method’s specializers. If more than one method is applicable, they are combined using certain rules, described below, and the combination then handles the call.
cl-defgenericname arguments [documentation] [options-and-methods…] &rest body
This macro defines a generic function with the specified name
and arguments. If body is present, it provides the
default implementation. If documentation is present (it should
always be), it specifies the documentation string for the generic
function, in the form
(:documentation docstring). The
optional options-and-methods can be one of the following forms:
A declare form, as described in Declare Form.
(:argument-precedence-order &rest args)
This form affects the sorting order for combining applicable methods. Normally, when two methods are compared during combination, method arguments are examined left to right, and the first method whose argument specializer is more specific will come before the other one. The order defined by this form overrides that, and the arguments are examined according to their order in this form, and not left to right.
(:method [qualifiers…] args &rest body)
This form defines a method like
cl-defmethodname [qualifier] arguments &rest [docstring] body
This macro defines a particular implementation for the generic
function called name. The implementation code is given by
body. If present, docstring is the documentation string
for the method. The arguments list, which must be identical in
all the methods that implement a generic function, and must match the
argument list of that function, provides argument specializers of the
(arg spec), where arg is the argument
name as specified in the
cl-defgeneric call, and spec is
one of the following specializer forms:
This specializer requires the argument to be of the given type, one of the types from the type hierarchy described below.
This specializer requires the argument be
eql to the given
The argument must be a cons cell whose
The argument must be an instance of a class named struct-tag
cl-defstruct (see Structures in Common Lisp
Extensions for GNU Emacs Lisp), or of one of its parent classes.
Alternatively, the argument specializer can be of the form
&context (expr spec), in which case the value of
expr must be compatible with the specializer provided by
spec; spec can be any of the forms described above. In
other words, this form of specializer uses the value of expr
instead of arguments for the decision whether the method is
applicable. For example,
&context (overwrite-mode (eql t))
will make the method compatible only when
The type specializer,
(arg type), can specify one
of the system types in the following list. When a parent type
is specified, an argument whose type is any of its more specific child
types, as well as grand-children, grand-grand-children, etc. will also
The optional qualifier allows combining several applicable methods. If it is not present, the defined method is a primary method, responsible for providing the primary implementation of the generic function for the specialized arguments. You can also define auxiliary methods, by using one of the following values as qualifier:
This auxiliary method will run before the primary method. More
accurately, all the
:before methods will run before the
primary, in the most-specific-first order.
This auxiliary method will run after the primary method. More accurately, all such methods will run after the primary, in the most-specific-last order.
This auxiliary method will run instead of the primary method.
The most specific of such methods will be run before any other method.
Such methods normally use
cl-call-next-method, described below,
to invoke the other auxiliary or primary methods.
This allows you to add more methods, distinguished by string, for the same specializers and qualifiers.
Each time a generic function is called, it builds the effective method which will handle this invocation by combining the applicable methods defined for the function. The process of finding the applicable methods and producing the effective method is called dispatch. The applicable methods are those all of whose specializers are compatible with the actual arguments of the call. Since all of the arguments must be compatible with the specializers, they all determine whether a method is applicable. Methods that explicitly specialize more than one argument are called multiple-dispatch methods.
The applicable methods are sorted into the order in which they will be
combined. The method whose left-most argument specializer is the most
specific one will come first in the order. (Specifying
:argument-precedence-order as part of
overrides that, as described above.) If the method body calls
cl-call-next-method, the next most-specific method will run.
If there are applicable
:around methods, the most-specific of
them will run first; it should call
cl-call-next-method to run
any of the less specific
:around methods. Next, the
:before methods run in the order of their specificity, followed
by the primary method, and lastly the
:after methods in the
reverse order of their specificity.
When invoked from within the lexical body of a primary or an
:around auxiliary method, call the next applicable method for
the same generic function. Normally, it is called with no arguments,
which means to call the next applicable method with the same arguments
that the calling method was invoked. Otherwise, the specified
arguments are used instead.
This function, when called from within the lexical body of a primary
:around auxiliary method, returns non-
nil if there
is a next method to call.