REF CLOS John Williams, May 1995 COPYRIGHT University of Sussex 1995. All Rights Reserved. >>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> <<<<<<<<<<<<<<<<<<<<< >>>>>>>>>>>>>>>>>>>>>> <<<<<<<<<<<<<<<<<<<<< THE COMMON LISP OBJECT >>>>>>>>>>>>>>>>>>>>>> <<<<<<<<<<<<<<<<<<<<< SYSTEM >>>>>>>>>>>>>>>>>>>>>> <<<<<<<<<<<<<<<<<<<<< >>>>>>>>>>>>>>>>>>>>>> <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< This file briefly describes the functions, macros and variables documented in Chapter 29 of the standard Common Lisp guide, which is: Common Lisp: The Language, 2nd Edition (Guy L. Steele, Digital Press, 1990). Please note that the text below is directly adapted from the said work (which Digital Press have kindly placed in the public domain). --------------------------------------------- 1 Listing of Variables, Functions and Macros --------------------------------------------- (add-method generic-function method) [generic function] (add-method (generic-function standard-generic-function) [method] (method method)) The generic function add-method adds a method to a generic function. It destructively modifies the generic function and returns the modified generic function as its result. The lambda-list of the method function must be congruent with the lambda-list of the generic function, or an error is signaled. If the given method agrees with an existing method of the generic-function on parameter specializers and qualifiers, the existing method is replaced. If the method object is a method object of another generic function, an error is signaled. (call-method method next-method-list) [macro] The macro call-method is used in method combination. This macro hides the implementation-dependent details of how methods are called. It can be used only within an effective method form, for the name call-method is defined only within the lexical scope of such a form. The macro call-method invokes the specified method, supplying it with arguments and with definitions for call-next-method and for next-method-p. The arguments are the arguments that were supplied to the effective method form containing the invocation of call-method. The definitions of call-next-method and next-method-p rely on the list of method objects given as the second argument to call-method. The call-next-method function available to the method that is the first subform will call the first method in the list that is the second subform. The call-next-method function available in that method, in turn, will call the second method in the list that is the second subform, and so on, until the list of next methods is exhausted. The method argument is a method object; the next-method-list argument is a list of method objects. A list whose first element is the symbol make-method and whose second element is a Lisp form can be used instead of a method object as the first subform of call-method or as an element of the second subform of call-method. Such a list specifies a method object whose method function has a body that is the given form. The result of call-method is the value or values returned by the method invocation. (call-next-method &rest args) [function] The function call-next-method can be used within the body of a method defined by a method-defining form to call the next method. The function call-next-method returns the value or values returned by the method it calls. If there is no next method, the generic function no-next-method is called. The type of method combination used determines which methods can invoke call-next-method. The standard method combination type allows call-next-method to be used within primary methods and :around methods. The standard method combination type defines the next method according to the following rules: # If call-next-method is used in an :around method, the next method is the next most specific :around method, if one is applicable. # If there are no :around methods at all or if call-next-method is called by the least specific :around method, other methods are called as follows: # All the :before methods are called, in most-specific-first order. The function call-next-method cannot be used in :before methods. # The most specific primary method is called. Inside the body of a primary method, call-next-method may be used to pass control to the next most specific primary method. The generic function no-next-method is called if call-next-method is used and there are no more primary methods. # All the :after methods are called in most-specific-last order. The function call-next-method cannot be used in :after methods. When call-next-method is called with no arguments, it passes the current method's original arguments to the next method. Neither argument defaulting, nor using setq, nor rebinding variables with the same names as parameters of the method affects the values call-next-method passes to the method it calls. When call-next-method is called with arguments, the next method is called with those arguments. When providing arguments to call-next-method, the following rule must be satisfied or an error is signaled: The ordered set of methods applicable for a changed set of arguments for call-next-method must be the same as the ordered set of applicable methods for the original arguments to the generic function. The function call-next-method returns the value or values returned by the method it calls. The definition of the function call-next-method has lexical scope (for it is defined only within the body of a method defined by a method-defining form) and indefinite extent. For generic functions using a type of method combination defined by the short form of define-method-combination, call-next-method can be used in :around methods only. The function next-method-p can be used to test whether or not there is a next method. If call-next-method is used in methods that do not support it, an error is signaled. (change-class instance new-class) [generic function] (change-class (instance standard-object) [method] (new-class standard-class)) (change-class (instance t) [method] (new-class symbol)) The generic function change-class changes the class of an instance to a new class. It destructively modifies and returns the instance. If in the old class there is any slot of the same name as a local slot in the new class, the value of that slot is retained. This means that if the slot has a value, the value returned by slot-value after change-class is invoked is eql to the value returned by slot-value before change-class is invoked. Similarly, if the slot was unbound, it remains unbound. The other slots are initialized as described in Steele 1990 section 28.1.11. The instance argument is a Lisp object. The new-class argument is a class object or a symbol that names a class. If the second of the preceding methods is selected, that method invokes change-class on instance and (find-class new-class). After completing all other actions, change-class invokes the generic function update-instance-for-different-class. The generic function update-instance-for-different-class can be used to assign values to slots in the transformed instance. (class-name class) [generic function] (class-name (class class)) [method] The generic function class-name takes a class object and returns its name. The name of an anonymous class is nil. The generic function (setf class-name) takes a class object and sets its name. (class-of object) [function] The function class-of returns the class of which the given object is an instance. (compute-applicable-methods generic-function arguments) [function] Given a generic function and a set of arguments, the function compute-applicable-methods returns the set of methods that are applicable for those arguments. The methods are sorted according to precedence order. (defclass class-name [macro] ({superclass-name}*) ({slot-specifier}*) [[?class-option]]) class-name ::= symbol superclass-name ::= symbol slot-specifier ::= slot-name | (slot-name [[?slot-option]]) slot-name ::= symbol slot-option ::= {:reader reader-function-name}* | {:writer writer-function-name}* | {:accessor reader-function-name}* | {:allocation allocation-type}* | {:initarg initarg-name}* | {:initform form}* | {:type type-specifier}* | {:documentation string}* reader-function-name ::= symbol writer-function-name ::= function-name function-name ::= {symbol | (setf symbol)} initarg-name ::= symbol allocation-type ::= :instance | :class class-option ::= (:default-initargs initarg-list) | (:documentation string) | (:metaclass class-name) initarg-list ::= {initarg-name default-initial-value-form}* The macro defclass defines a new named class. It returns the new class object as its result. The class-name argument is a non-nil symbol. It becomes the proper name of the new class. If a class with the same proper name already exists and that class is an instance of standard-class, and if the defclass form for the definition of the new class specifies a class of class standard-class, the definition of the existing class is replaced. Each superclass-name argument is a non-nil symbol that specifies a direct superclass of the new class. The new class will inherit slots and methods from each of its direct superclasses, from their direct superclasses, and so on. Each slot-specifier argument is the name of the slot or a list consisting of the slot name followed by zero or more slot options. The slot-name argument is a symbol that is syntactically valid for use as a variable name. If there are any duplicate slot names, an error is signaled. The following slot options are available: # The :reader slot option specifies that an unqualified method is to be defined on the generic function named reader-function-name to read the value of the given slot. The reader-function-name argument is a non-nil symbol. The :reader slot option may be specified more than once for a given slot. # The :writer slot option specifies that an unqualified method is to be defined on the generic function named writer-function-name to write the value of the slot. The writer-function-name argument is a function-name. The :writer slot option may be specified more than once for a given slot. # The :accessor slot option specifies that an unqualified method is to be defined on the generic function named reader-function-name to read the value of the given slot and that an unqualified method is to be defined on the generic function named (setf reader-function-name) to be used with setf to modify the value of the slot. The reader-function-name argument is a non-nil symbol. The :accessor slot option may be specified more than once for a given slot. # The :allocation slot option is used to specify where storage is to be allocated for the given slot. Storage for a slot may be located in each instance or in the class object itself, for example. The value of the allocation-type argument can be either the keyword :instance or the keyword :class. The :allocation slot option may be specified at most once for a given slot. If the :allocation slot option is not specified, the effect is the same as specifying :allocation :instance. # If allocation-type is :instance, a local slot of the given name is allocated in each instance of the class. # If allocation-type is :class, a shared slot of the given name is allocated. The value of the slot is shared by all instances of the class. If a class C defines such a shared slot, any subclass C of C will share this single slot unless the defclass form for C specifies a slot of the same name or there is a superclass of C that precedes C in the class precedence list of C and that defines a slot of the same name. # The :initform slot option is used to provide a default initial value form to be used in the initialization of the slot. The :initform slot option may be specified at most once for a given slot. This form is evaluated every time it is used to initialize the slot. The lexical environment in which this form is evaluated is the lexical environment in which the defclass form was evaluated. Note that the lexical environment refers both to variables and to functions. For local slots, the dynamic environment is the dynamic environment in which make-instance was called; for shared slots, the dynamic environment is the dynamic environment in which the defclass form was evaluated. # The :initarg slot option declares an initialization argument named initarg-name and specifies that this initialization argument initializes the given slot. If the initialization argument has a value in the call to initialize-instance, the value will be stored into the given slot, and the slot's :initform slot option, if any, is not evaluated. If none of the initialization arguments specified for a given slot has a value, the slot is initialized according to the :initform slot option, if specified. The :initarg slot option can be specified more than once for a given slot. The initarg-name argument can be any symbol. # The :type slot option specifies that the contents of the slot will always be of the specified data type. It effectively declares the result type of the reader generic function when applied to an object of this class. The result of attempting to store in a slot a value that does not satisfy the type of the slot is undefined. The :type slot option may be specified at most once for a given slot. # The :documentation slot option provides a documentation string for the slot. Each class option is an option that refers to the class as a whole or to all class slots. The following class options are available: # The :default-initargs class option is followed by a list of alternating initialization argument names and default initial value forms. If any of these initialization arguments does not appear in the initialization argument list supplied to make-instance, the corresponding default initial value form is evaluated, and the initialization argument name and the form's value are added to the end of the initialization argument list before the instance is created. The default initial value form is evaluated each time it is used. The lexical environment in which this form is evaluated is the lexical environment in which the defclass form was evaluated. The dynamic environment is the dynamic environment in which make-instance was called. If an initialization argument name appears more than once in a :default-initargs class option, an error is signaled. The :default-initargs class option may be specified at most once. # The :documentation class option causes a documentation string to be attached to the class name. The documentation type for this string is type. The form (documentation class-name 'type) may be used to retrieve the documentation string. The :documentation class option may be specified at most once. # The :metaclass class option is used to specify that instances of the class being defined are to have a different metaclass than the default provided by the system (the class standard-class). The class-name argument is the name of the desired metaclass. The :metaclass class option may be specified at most once. If a class with the same proper name already exists and that class is an instance of standard-class, and if the defclass form for the definition of the new class specifies a class of class standard-class, the existing class is redefined, and instances of it (and its subclasses) are updated to the new definition at the time that they are next accessed. Note the following rules of defclass for standard classes: # It is not required that the superclasses of a class be defined before the defclass form for that class is evaluated. # All the superclasses of a class must be defined before an instance of the class can be made. # A class must be defined before it can be used as a parameter specializer in a defmethod form. Some slot options are inherited by a class from its superclasses, and some can be shadowed or altered by providing a local slot description. No class options except :default-initargs are inherited. It is valid to specify more than one reader, writer, accessor, or initialization argument for a slot. No other slot option may appear more than once in a single slot description, or an error is signaled. If no reader, writer, or accessor is specified for a slot, the slot can be accessed only by the function slot-value. (defgeneric function-name lambda-list [macro] [[?option | {method-description}*]]) function-name ::= {symbol | (setf symbol)} lambda-list ::= ({var}* [&optional {var | (var)}*] [&rest var] [&key {keyword-parameter}* [&allow-other-keys]]) keyword-parameter ::= var | ({var | (keyword var)}) option ::= (:argument-precedence-order {parameter-name}+) | (declare {declaration}+) | (:documentation string) | (:method-combination symbol {arg}*) | (:generic-function-class class-name) | (:method-class class-name) method-description ::= (:method {method-qualifier}* specialized-lambda-list [[ {declaration}* | documentation ]] {form}*) method-qualifier ::= non-nil-atom specialized-lambda-list ::= ({var | (var parameter-specializer-name)}* [&optional {var | (var [initform [supplied-p-parameter]])}*] [&rest var] [&key {specialized-keyword-parameter}* [&allow-other-keys]] [&aux {var | (var [initform])}*]) specialized-keyword-parameter ::= var | ({var | (keyword var)} [initform [supplied-p-parameter]]) parameter-specializer-name ::= symbol | (eql eql-specializer-form) The macro defgeneric is used to define a generic function or to specify options and declarations that pertain to a generic function as a whole. If (fboundp function-name) is nil, a new generic function is created. If (fdefinition function-specifier) is a generic function, that generic function is modified. If function-name names a non-generic function, a macro, or a special form, an error is signaled. Each method-description defines a method on the generic function. The lambda-list of each method must be congruent with the lambda-list specified by the lambda-list option. If this condition does not hold, an error is signaled. See section 28.1.6.4 for a definition of congruence in this context. The macro defgeneric returns the generic function object as its result. The function-name argument is a non-nil symbol or a list of the form (setf symbol). The lambda-list argument is an ordinary function lambda-list with the following exceptions: # The use of &aux is not allowed. # Optional and keyword arguments may not have default initial value forms nor use supplied-p parameters. The generic function passes to the method all the argument values passed to it, and only those; default values are not supported. Note that optional and keyword arguments in method definitions, however, can have default initial value forms and can use supplied-p parameters. The following options are provided. A given option may occur only once, or an error is signaled. # The :argument-precedence-order option is used to specify the order in which the required arguments in a call to the generic function are tested for specificity when selecting a particular method. Each required argument, as specified in the lambda-list argument, must be included exactly once as a parameter-name so that the full and unambiguous precedence order is supplied. If this condition is not met, an error is signaled. # The declare option is used to specify declarations that pertain to the generic function. The following standard Common Lisp declaration is allowed: # An optimize declaration specifies whether method selection should be optimized for speed or space, but it has no effect on methods. To control how a method is optimized, an optimize declaration must be placed directly in the defmethod form or method description. The optimization qualities speed and space are the only qualities this standard requires, but an implementation can extend the Common Lisp Object System to recognize other qualities. A simple implementation that has only one method selection technique and ignores the optimize declaration is valid. The special, ftype, function, inline, notinline, and declaration declarations are not permitted. Individual implementations can extend the declare option to support additional declarations. If an implementation notices a declaration that it does not support and that has not been proclaimed as a non-standard declaration name in a declaration proclamation, it should issue a warning. # The :documentation argument associates a documentation string with the generic function. # The :generic-function-class option may be used to specify that the generic function is to have a different class than the default provided by the system (the class standard-generic-function). The class-name argument is the name of a class that can be the class of a generic function. If function-name specifies an existing generic function that has a different value for the :generic-function-class argument and the new generic function class is compatible with the old, change-class is called to change the class of the generic function; otherwise an error is signaled. # The :method-class option is used to specify that all methods on this generic function are to have a different class from the default provided by the system (the class standard-method). The class-name argument is the name of a class that is capable of being the class of a method. # The :method-combination option is followed by a symbol that names a type of method combination. The arguments (if any) that follow that symbol depend on the type of method combination. Note that the standard method combination type does not support any arguments. However, all types of method combination defined by the short form of define-method-combination accept an optional argument named order, defaulting to :most-specific-first, where a value of :most-specific-last reverses the order of the primary methods without affecting the order of the auxiliary methods. The method-description arguments define methods that will be associated with the generic function. The method-qualifier and specialized-lambda-list arguments in a method description are the same as for defmethod. The form arguments specify the method body. The body of the method is enclosed in an implicit block. If function-name is a symbol, this block bears the same name as the generic function. If function-name is a list of the form (setf symbol), the name of the block is symbol. The effect of the defgeneric macro is as if the following three steps were performed: first, methods defined by previous defgeneric forms are removed; second, ensure-generic-function is called; and finally, methods specified by the current defgeneric form are added to the generic function. If no method descriptions are specified and a generic function of the same name does not already exist, a generic function with no methods is created. The lambda-list argument of defgeneric specifies the shape of lambda-lists for the methods on this generic function. All methods on the resulting generic function must have lambda-lists that are congruent with this shape. If a defgeneric form is evaluated and some methods for that generic function have lambda-lists that are not congruent with that given in the defgeneric form, an error is signaled. (define-method-combination name [[?short-form-option]]) [macro] (define-method-combination name lambda-list [macro] ({method-group-specifier}*) [(:arguments . lambda-list)] [(:generic-function generic-fn-symbol)] [[{declaration}* | doc-string]] {form}*) short-form-option ::= :documentation string | :identity-with-one-argument boolean | :operator operator method-group-specifier ::= (variable {{qualifier-pattern}+ | predicate} [[?long-form-option]]) long-form-option ::= :description format-string | :order order | :required boolean The macro define-method-combination is used to define new types of method combination. There are two forms of define-method-combination. The short form is a simple facility for the cases that are expected to be most commonly needed. The long form is more powerful but more verbose. It resembles defmacro in that the body is an expression, usually using backquote, that computes a Lisp form. Thus arbitrary control structures can be implemented. The long form also allows arbitrary processing of method qualifiers. In both the short and long forms, name is a symbol. By convention, non-keyword, non-nil symbols are usually used. The short-form syntax of define-method-combination is recognized when the second subform is a non-nil symbol or is not present. When the short form is used, name is defined as a type of method combination that produces a Lisp form ( operator method-call method-call ... ). The operator is a symbol that can be the name of a function, macro, or special form. The operator can be specified by a keyword option; it defaults to name. Keyword options for the short form are the following: # The :documentation option is used to document the method-combination type. # The :identity-with-one-argument option enables an optimization when boolean is true (the default is false). If there is exactly one applicable method and it is a primary method, that method serves as the effective method and operator is not called. This optimization avoids the need to create a new effective method and avoids the overhead of a function call. This option is designed to be used with operators such as progn, and, +, and max. # The :operator option specifies the name of the operator. The operator argument is a symbol that can be the name of a function, macro, or special form. By convention, name and operator are often the same symbol. This is the default, but it is not required. None of the subforms is evaluated. These types of method combination require exactly one qualifier per method. An error is signaled if there are applicable methods with no qualifiers or with qualifiers that are not supported by the method combination type. A method combination procedure defined in this way recognizes two roles for methods. A method whose one qualifier is the symbol naming this type of method combination is defined to be a primary method. At least one primary method must be applicable or an error is signaled. A method with :around as its one qualifier is an auxiliary method that behaves the same as an :around method in standard method combination. The function call-next-method can be used only in :around methods; it cannot be used in primary methods defined by the short form of the define-method-combination macro. A method combination procedure defined in this way accepts an optional argument named order, which defaults to :most-specific-first. A value of :most-specific-last reverses the order of the primary methods without affecting the order of the auxiliary methods. The short form automatically includes error checking and support for :around methods. The long-form syntax of define-method-combination is recognized when the second subform is a list. The lambda-list argument is an ordinary lambda-list. It receives any arguments provided after the name of the method combination type in the :method-combination option to defgeneric. A list of method group specifiers follows. Each specifier selects a subset of the applicable methods to play a particular role, either by matching their qualifiers against some patterns or by testing their qualifiers with a predicate. These method group specifiers define all method qualifiers that can be used with this type of method combination. If an applicable method does not fall into any method group, the system signals the error that the method is invalid for the kind of method combination in use. Each method group specifier names a variable. During the execution of the forms in the body of define-method-combination, this variable is bound to a list of the methods in the method group. The methods in this list occur in most-specific-first order. A qualifier pattern is a list or the symbol *. A method matches a qualifier pattern if the method's list of qualifiers is equal to the qualifier pattern (except that the symbol * in a qualifier pattern matches anything). Thus a qualifier pattern can be one of the following: the empty list (), which matches unqualified methods; the symbol *, which matches all methods; a true list, which matches methods with the same number of qualifiers as the length of the list when each qualifier matches the corresponding list element; or a dotted list that ends in the symbol * (the * matches any number of additional qualifiers). Each applicable method is tested against the qualifier patterns and predicates in left-to-right order. As soon as a qualifier pattern matches or a predicate returns true, the method becomes a member of the corresponding method group and no further tests are made. Thus if a method could be a member of more than one method group, it joins only the first such group. If a method group has more than one qualifier pattern, a method need only satisfy one of the qualifier patterns to be a member of the group. The name of a predicate function can appear instead of qualifier patterns in a method group specifier. The predicate is called for each method that has not been assigned to an earlier method group; it is called with one argument, the method's qualifier list. The predicate should return true if the method is to be a member of the method group. A predicate can be distinguished from a qualifier pattern because it is a symbol other than nil or *. If there is an applicable method whose qualifiers are not valid for the method combination type, the function invalid-method-error is called. Method group specifiers can have keyword options following the qualifier patterns or predicate. Keyword options can be distinguished from additional qualifier patterns because they are neither lists nor the symbol *. The keyword options are: # The :description option is used to provide a description of the role of methods in the method group. Programming environment tools use: (apply #'format stream format-string (method-qualifiers method)) to print this description, which is expected to be concise. This keyword option allows the description of a method qualifier to be defined in the same module that defines the meaning of the method qualifier. In most cases, format-string will not contain any format directives, but they are available for generality. If :description is not specified, a default description is generated based on the variable name and the qualifier patterns and on whether this method group includes the unqualified methods. The argument format-string is not evaluated. # The :order option specifies the order of methods. The order argument is a form that evaluates to :most-specific-first or :most-specific-last. If it evaluates to any other value, an error is signaled. This keyword option is a convenience and does not add any expressive power. If :order is not specified, it defaults to :most-specific-first. # The :required option specifies whether at least one method in this method group is required. If the boolean argument is non-nil and the method group is empty (that is, no applicable methods match the qualifier patterns or satisfy the predicate), an error is signaled. This keyword option is a convenience and does not add any expressive power. If :required is not specified, it defaults to nil. The boolean argument is not evaluated. The use of method group specifiers provides a convenient syntax to select methods, to divide them among the possible roles, and to perform the necessary error checking. It is possible to perform further filtering of methods in the body forms by using normal list-processing operations and the functions method-qualifiers and invalid-method-error. It is permissible to use setq on the variables named in the method group specifiers and to bind additional variables. It is also possible to bypass the method group specifier mechanism and do everything in the body forms. This is accomplished by writing a single method group with * as its only qualifier pattern; the variable is then bound to a list of all of the applicable methods, in most-specific-first order. The body forms compute and return the Lisp form that specifies how the methods are combined, that is, the effective method. The effective method uses the macro call-method. The definition of this macro has lexical scope and is available only in an effective method form. Given a method object in one of the lists produced by the method group specifiers and a list of next methods, the macro call-method will invoke the method so that call-next-method will have available the next methods. When an effective method has no effect other than to call a single method, some implementations employ an optimization that uses the single method directly as the effective method, thus avoiding the need to create a new effective method. This optimization is active when the effective method form consists entirely of an invocation of the call-method macro whose first subform is a method object and whose second subform is nil. Each define-method-combination body is responsible for stripping off redundant invocations of progn, and, multiple-value-prog1, and the like, if this optimization is desired. The list (:arguments . lambda-list) can appear before any declaration or documentation string. This form is useful when the method combination type performs some specific behavior as part of the combined method and that behavior needs access to the arguments to the generic function. Each parameter variable defined by lambda-list is bound to a form that can be inserted into the effective method. When this form is evaluated during execution of the effective method, its value is the corresponding argument to the generic function. If lambda-list is not congruent to the generic function's lambda-list, additional ignored parameters are automatically inserted until it is congruent. Thus it is permissible for lambda-list to receive fewer arguments than the number that the generic function expects. Erroneous conditions detected by the body should be reported with method-combination-error or invalid-method-error; these functions add any necessary contextual information to the error message and will signal the appropriate error. The body forms are evaluated inside the bindings created by the lambda-list and method group specifiers. Declarations at the head of the body are positioned directly inside bindings created by the lambda-list and outside the bindings of the method group variables. Thus method group variables cannot be declared. Within the body forms, generic-function-symbol is bound to the generic function object. If a doc-string argument is present, it provides the documentation for the method combination type. The functions method-combination-error and invalid-method-error can be called from the body forms or from functions called by the body forms. The actions of these two functions can depend on implementation-dependent dynamic variables automatically bound before the generic function compute-effective-method is called. The value returned by the define-method-combination macro is the new method combination object. (defmethod function-name {method-qualifier}* [macro] specialized-lambda-list [[ {declaration}* | doc-string]] {form}*) function-name ::= {symbol | (setf symbol)} method-qualifier ::= non-nil-atom parameter-specializer-name ::= symbol | (eql eql-specializer-form) The macro defmethod defines a method on a generic function. If (fboundp function-name) is nil, a generic function is created with default values for the argument precedence order (each argument is more specific than the arguments to its right in the argument list), for the generic function class (the class standard-generic-function), for the method class (the class standard-method), and for the method combination type (the standard method combination type). The lambda-list of the generic function is congruent with the lambda-list of the method being defined; if the defmethod form mentions keyword arguments, the lambda-list of the generic function will mention &key (but no keyword arguments). If function-name names a non-generic function, a macro, or a special form, an error is signaled. If a generic function is currently named by function-name, where function-name is a symbol or a list of the form (setf symbol), the lambda-list of the method must be congruent with the lambda-list of the generic function. If this condition does not hold, an error is signaled. The function-name argument is a non-nil symbol or a list of the form (setf symbol). It names the generic function on which the method is defined. Each method-qualifier argument is an object that is used by method combination to identify the given method. A method qualifier is a non-nil atom. The method combination type may further restrict what a method qualifier may be. The standard method combination type allows for unqualified methods or methods whose sole qualifier is the keyword :before, the keyword :after, or the keyword :around. A specialized-lambda-list is like an ordinary function lambda-list except that the name of a required parameter can be replaced by a specialized parameter, a list of the form (variable-name parameter-specializer-name). Only required parameters may be specialized. A parameter specializer name is a symbol that names a class or (eql eql-specializer-form). The parameter specializer name (eql eql-specializer-form) indicates that the corresponding argument must be eql to the object that is the value of eql-specializer-form for the method to be applicable. If no parameter specializer name is specified for a given required parameter, the parameter specializer defaults to the class named t. The form arguments specify the method body. The body of the method is enclosed in an implicit block. If function-name is a symbol, this block bears the same name as the generic function. If function-name is a list of the form (setf symbol), the name of the block is symbol. The result of defmethod is the method object. The class of the method object that is created is that given by the method class option of the generic function on which the method is defined. If the generic function already has a method that agrees with the method being defined on parameter specializers and qualifiers, defmethod replaces the existing method with the one now being defined. (documentation x &optional doc-type) [generic function] (documentation (method standard-method) &optional doc-type) [method] (documentation (generic-function standard-generic-function) [method] &optional doc-type) (documentation (class standard-class) &optional doc-type) [method] (documentation (method-combination method-combination) [method] &optional doc-type) (documentation (symbol symbol) &optional doc-type) [method] (documentation (list list) &optional doc-type) [method] The ordinary function documentation is replaced by a generic function. The generic function documentation returns the documentation string associated with the given object if it is available; otherwise documentation returns nil. The first argument of documentation is a symbol, a function-name list of the form (setf symbol), a method object, a class object, a generic function object, a method combination object, or a slot description object. Whether a second argument should be supplied depends on the type of the first argument. # If the first argument is a method object, a class object, a generic function object, a method combination object, or a slot description object, the second argument must not be supplied, or an error is signaled. # If the first argument is a symbol or a list of the form (setf symbol), the second argument must be supplied. # The forms (documentation symbol 'function) and (documentation '(setf symbol) 'function) return the documentation string of the function, generic function, special form, or macro named by the symbol or list. # The form (documentation symbol 'variable) returns the documentation string of the special variable or constant named by the symbol. # The form (documentation symbol 'structure) returns the documentation string of the defstruct structure named by the symbol. # The form (documentation symbol 'type) returns the documentation string of the class object named by the symbol, if there is such a class. If there is no such class, it returns the documentation string of the type specifier named by the symbol. # The form (documentation symbol 'setf) returns the documentation string of the defsetf or define-setf-method definition associated with the symbol. # The form (documentation symbol 'method-combination) returns the documentation string of the method combination type named by the symbol. The documentation string associated with the given object is returned unless none is available, in which case documentation returns nil. The generic function (setf documentation) is used to update the documentation. (ensure-generic-function function-name [function] &key :lambda-list :argument-precedence-order :declare :documentation :generic-function-class :method-combination :method-class :environment) function-name ::= {symbol | (setf symbol)} The function ensure-generic-function is used to define a globally named generic function with no methods or to specify or modify options and declarations that pertain to a globally named generic function as a whole. If (fboundp function-name) is nil, a new generic function is created. If (fdefinition function-name) is a non-generic function, a macro, or a special form, an error is signaled. If function-name specifies a generic function that has a different value for any of the following arguments, the generic function is modified to have the new value: :argument-precedence-order, :declare, :documentation, and :method-combination. If function-name specifies a generic function that has a different value for the :lambda-list argument, and the new value is congruent with the lambda-lists of all existing methods or there are no methods, the value is changed; otherwise an error is signaled. If function-name specifies a generic function that has a different value for the :generic-function-class argument and if the new generic function class is compatible with the old, change-class is called to change the class of the generic function; otherwise an error is signaled. If function-name specifies a generic function that has a different :method-class value, the value is changed but any existing methods are not changed. The function-name argument is a symbol or a list of the form (setf symbol). The keyword arguments correspond to the option arguments of defgeneric, except that the :method-class and :generic-function-class arguments can be class objects as well as names. The :environment argument is the same as the &environment argument to macro expansion functions. It is typically used to distinguish between compile-time and run-time environments. The :method-combination argument is a method combination object. The generic function object is returned. (find-class symbol &optional errorp environment) [function] The function find-class returns the class object named by the given symbol in the given environment. If there is no such class and the errorp argument is not supplied or is non-nil, find-class signals an error. If there is no such class and the errorp argument is nil, find-class returns nil. The default value of errorp is t. The optional environment argument is the same as the &environment argument to macro expansion functions. It is typically used to distinguish between compile-time and run-time environments. (find-method generic-function method-qualifiers [generic function] specializers &optional errorp) (find-method (generic-function standard-generic-function) [method] method-qualifiers specializers &optional errorp) The generic function find-method takes a generic function and returns the method object that agrees on method qualifiers and parameter specializers with the method-qualifiers and specializers arguments. The method-qualifiers argument is a list of the method qualifiers for the method. The order of the method qualifiers is significant. The specializers argument is a list of the parameter specializers for the method. It must correspond in length to the number of required arguments of the generic function, or an error is signaled. This means that to obtain the default method on a given generic function, a list whose elements are the class named t must be given. If there is no such method and the errorp argument is not supplied or is non-nil, find-method signals an error. If there is no such method and the errorp argument is nil, find-method returns nil. The default value of errorp is t. The result of find-method is the method object with the given method qualifiers and parameter specializers. (function-keywords method) [generic function] (function-keywords (method standard-method)) [method] The generic function function-keywords is used to return the keyword parameter specifiers for a given method. The generic function function-keywords returns two values: a list of the explicitly named keywords and a boolean that states whether &allow-other-keys had been specified in the method definition. (generic-function lambda-list [macro] [[?option | {method-description}*]]) option ::= (:argument-precedence-order {parameter-name}+) | (declare {declaration}+) | (:documentation string) | (:method-combination symbol {arg}*) | (:generic-function-class class-name) | (:method-class class-name) method-description ::= (:method {method-qualifier}* specialized-lambda-list {declaration | documentation}* {form}*) The generic-function macro creates an anonymous generic function. The generic function is created with the set of methods specified by its method descriptions. The option, method-qualifier, and specialized-lambda-list arguments are the same as for defgeneric. The generic function object is returned as the result. If no method descriptions are specified, an anonymous generic function with no methods is created. (initialize-instance instance &rest initargs) [generic function] (initialize-instance (instance standard-object) &rest initargs) [method] The generic function initialize-instance is called by make-instance to initialize a newly created instance. The generic function initialize-instance is called with the new instance and the defaulted initialization arguments. The system-supplied primary method on initialize-instance initializes the slots of the instance with values according to the initialization arguments and the :initform forms of the slots. It does this by calling the generic function shared-initialize with the following arguments: the instance, t (this indicates that all slots for which no initialization arguments are provided should be initialized according to their :initform forms) and the defaulted initialization arguments. The instance argument is the object to be initialized. The initargs argument consists of alternating initialization argument names and values. The modified instance is returned as the result. Programmers can define methods for initialize-instance to specify actions to be taken when an instance is initialized. If only :after methods are defined, they will be run after the system-supplied primary method for initialization and therefore will not interfere with the default behavior of initialize-instance. (invalid-method-error method format-string &rest args) [function] The function invalid-method-error is used to signal an error when there is an applicable method whose qualifiers are not valid for the method combination type. The error message is constructed by using a format string and any arguments to it. Because an implementation may need to add additional contextual information to the error message, invalid-method-error should be called only within the dynamic extent of a method combination function. The function invalid-method-error is called automatically when a method fails to satisfy every qualifier pattern and predicate in a define-method-combination form. A method combination function that imposes additional restrictions should call invalid-method-error explicitly if it encounters a method it cannot accept. The method argument is the invalid method object. The format-string argument is a control string that can be given to format, and args are any arguments required by that string. Whether invalid-method-error returns to its caller or exits via throw is implementation-dependent. (make-instance class &rest initargs) [generic function] (make-instance (class standard-class) &rest initargs) [method] (make-instance (class symbol) &rest initargs) [method] The generic function make-instance creates a new instance of the given class. The class argument is a class object or a symbol that names a class. The remaining arguments form a list of alternating initialization argument names and values. If the second of the preceding methods is selected, that method invokes make-instance on the arguments (find-class class) and initargs. (make-instances-obsolete class) [generic function] (make-instances-obsolete (class standard-class)) [method] (make-instances-obsolete (class symbol)) [method] The generic function make-instances-obsolete is invoked automatically by the system when defclass has been used to redefine an existing standard class and the set of local slots accessible in an instance is changed or the order of slots in storage is changed. It can also be explicitly invoked by the user. The function make-instances-obsolete has the effect of initiating the process of updating the instances of the class. During updating, the generic function update-instance-for- -redefined-class will be invoked. The class argument is a class object symbol that names the class whose instances are to be made obsolete. If the second of the preceding methods is selected, that method invokes make-instances-obsolete on (find-class class). The modified class is returned. The result of make-instances- -obsolete is eq to the class argument supplied to the first of the preceding methods. (method-combination-error format-string &rest args) [function] The function method-combination-error is used to signal an error in method combination. The error message is constructed by using a format string and any arguments to it. Because an implementation may need to add additional contextual information to the error message, method-combination-error should be called only within the dynamic extent of a method combination function. The format-string argument is a control string that can be given to format, and args are any arguments required by that string. Whether method-combination-error returns to its caller or exits via throw is implementation-dependent. (method-qualifiers method) [generic function] (method-qualifiers (method standard-method)) [method] The generic function method-qualifiers returns a list of the qualifiers of the given method. (next-method-p) [function] The locally defined function next-method-p can be used within the body of a method defined by a method-defining form to determine whether a next method exists. The function next-method-p returns true or false. Like call-next-method, the function next-method-p has lexical scope (for it is defined only within the body of a method defined by a method-defining form) and indefinite extent. (no-applicable-method generic-function [generic function] &rest fn-arguments) (no-applicable-method (generic-function t) [method] &rest fn-arguments) The generic function no-applicable-method is called when a generic function of the class standard-generic-function is invoked and no method on that generic function is applicable. The default method signals an error. The generic function no-applicable-method is not intended to be called by programmers. Programmers may write methods for it. The generic-function argument of no-applicable-method is the generic function object on which no applicable method was found. The fn-arguments argument is a list of the arguments to that generic function. (no-next-method generic-function method &rest args) [generic function] (no-next-method (generic-function standard-generic-function) [method] (method standard-method) &rest args) The generic function no-next-method is called by call-next-method when there is no next method. The system-supplied method on no-next-method signals an error. The generic function no-next-method is not intended to be called by programmers. Programmers may write methods for it. The generic-function argument is the generic function object to which the method that is the second argument belongs. The method argument is the method that contains the call to call-next-method for which there is no next method. The args argument is a list of the arguments to call-next-method. (print-object object stream) [generic function] (print-object (object standard-object) stream) [method] The generic function print-object writes the printed representation of an object to a stream. The function print-object is called by the print system; it should not be called by the user. Each implementation must provide a method on the class standard-object and methods on enough other classes so as to ensure that there is always an applicable method. Implementations are free to add methods for other classes. Users can write methods for print-object for their own classes if they do not wish to inherit an implementation-supplied method. The first argument is any Lisp object. The second argument is a stream; it cannot be t or nil. The function print-object returns its first argument, the object. (reinitialize-instance instance &rest initargs) [generic function] (reinitialize-instance (instance standard-object) [method] &rest initargs) The generic function reinitialize-instance can be used to change the values of local slots according to initialization arguments. The system-supplied primary method for reinitialize-instance checks the validity of initialization arguments and signals an error if an initialization argument is supplied that is not declared valid. The method then calls the generic function shared-initialize with the following arguments: the instance, nil (which means no slots should be initialized according to their :initform forms) and the initialization arguments it received. The instance argument is the object to be initialized. The initargs argument consists of alternating initialization argument names and values. The modified instance is returned as the result. Initialization arguments are declared valid by using the :initarg option to defclass, or by defining methods for reinitialize-instance or shared-initialize. The keyword name of each keyword parameter specifier in the lambda-list of any method defined on reinitialize-instance or shared-initialize is declared a valid initialization argument name for all classes for which that method is applicable. (remove-method generic-function method) [generic function] (remove-method (generic-function standard-generic-function) [method] method) The generic function remove-method removes a method from a generic function. It destructively modifies the specified generic function and returns the modified generic function as its result. The generic-function argument is a generic function object. The method argument is a method object. The function remove-method does not signal an error if the method is not one of the methods on the generic function. (shared-initialize instance slot-names [generic function] &rest initargs) (shared-initialize (instance standard-object) [method] slot-names &rest initargs) The generic function shared-initialize is used to fill the slots of an instance using initialization arguments and :initform forms. It is called when an instance is created, when an instance is re-initialized, when an instance is updated to conform to a redefined class, and when an instance is updated to conform to a different class. The generic function shared-initialize is called by the system-supplied primary method for initialize-instance, reinitialize-instance, update- -instance-for-redefined-class and update-instance-for-different- -class. The generic function shared-initialize takes the following arguments: the instance to be initialized, a specification of a set of names of slots accessible in that instance, and any number of initialization arguments. The arguments after the first two must form an initialization argument list. The system-supplied primary method on shared-initialize initializes the slots with values according to the initialization arguments and specified :initform forms. The second argument indicates which slots should be initialized according to their :initform forms if no initialization arguments are provided for those slots. The system-supplied primary method behaves as follows, regardless of whether the slots are local or shared: # If an initialization argument in the initialization argument list specifies a value for that slot, that value is stored into the slot, even if a value has already been stored in the slot before the method is run. # Any slots indicated by the second argument that are still unbound at this point are initialized according to their :initform forms. For any such slot that has an :initform form, that form is evaluated in the lexical environment of its defining defclass form and the result is stored into the slot. For example, if a :before method stores a value in the slot, the :initform form will not be used to supply a value for the slot. The instance argument is the object to be initialized. The slot-names argument specifies the slots that are to be initialized according to their :initform forms if no initialization arguments apply. It is supplied in one of three forms as follows: # It can be a list of slot names, which specifies the set of those slot names. # It can be nil, which specifies the empty set of slot names. # It can be the symbol t, which specifies the set of all of the slots. The initargs argument consists of alternating initialization argument names and values. The modified instance is returned as the result. (slot-boundp instance slot-name) [function] The function slot-boundp tests whether a specific slot in an instance is bound. If no slot of the given name exists in the instance, slot-missing is called as follows: (slot-missing (class-of instance) instance slot-name 'slot-boundp) (slot-exists-p object slot-name) [function] The function slot-exists-p tests whether the specified object has a slot of the given name. (slot-makunbound instance slot-name) [function] The function slot-makunbound restores a slot in an instance to the unbound state. The instance is returned as the result. If no slot of the given name exists in the instance, slot-missing is called as follows: (slot-missing (class-of instance) instance slot-name 'slot-makunbound) (slot-missing class object slot-name operation [generic function] &optional new-value) (slot-missing (class t) object slot-name operation [method] &optional new-value) The generic function slot-missing is invoked when an attempt is made to access a slot in an object whose metaclass is standard-class and the name of the slot provided is not a name of a slot in that class. The default method signals an error. The generic function slot-missing is not intended to be called by programmers. Programmers may write methods for it. The required arguments to slot-missing are the class of the object that is being accessed, the object, the slot name, and a symbol that indicates the operation that caused slot-missing to be invoked. The optional argument to slot-missing is used when the operation is attempting to set the value of the slot. If a method written for slot-missing returns values, these values get returned as the values of the original function invocation. The generic function slot-missing may be called during evaluation of slot-value, (setf slot-value), slot-boundp, and slot-makunbound. For each of these operations the corresponding symbol for the operation argument is slot-value, setf, slot-boundp, and slot-makunbound, respectively. (slot-unbound class instance slot-name) [generic-function] (slot-unbound (class t) instance slot-name) [method] The generic function slot-unbound is called when an unbound slot is read in an instance whose metaclass is standard-class. The default method signals an error. The generic function slot-unbound is not intended to be called by programmers. Programmers may write methods for it. The function slot-unbound is called only by the function slot-value-using-class and thus indirectly by slot-value. The arguments to slot-unbound are the class of the instance whose slot was accessed, the instance itself, and the name of the slot. If a method written for slot-unbound returns values, these values get returned as the values of the original function invocation. An unbound slot may occur if no :initform form was specified for the slot and the slot value has not been set, or if slot-makunbound has been called on the slot. (slot-value object slot-name) [function] The function slot-value returns the value contained in the slot slot-name of the given object. If there is no slot with that name, slot-missing is called. If the slot is unbound, slot-unbound is called. The macro setf can be used with slot-value to change the value of a slot. If an attempt is made to read a slot and no slot of the given name exists in the instance, slot-missing is called as follows: (slot-missing (class-of instance) instance slot-name 'slot-value) If an attempt is made to write a slot and no slot of the given name exists in the instance, slot-missing is called as follows: (slot-missing (class-of instance) instance slot-name 'setf new-value) (update-instance-for-different-class [generic function] previous current &rest initargs) (update-instance-for-different-class (previous standard-object) [method] (current standard-object) &rest initargs) The generic function update-instance-for-different-class is not intended to be called by programmers. Programmers may write methods for it. This function is called only by the function change-class. The system-supplied primary method on update-instance- -for-different-class checks the validity of initialization arguments and signals an error if an initialization argument is supplied that is not declared valid. This method then initializes slots with values according to the initialization arguments and initializes the newly added slots with values according to their :initform forms. It does this by calling the generic function shared-initialize with the following arguments: the instance, a list of names of the newly added slots, and the initialization arguments it received. Newly added slots are those local slots for which no slot of the same name exists in the previous class. Methods for update-instance-for-different-class can be defined to specify actions to be taken when an instance is updated. If only :after methods for update-instance-for-different-class are defined, they will be run after the system-supplied primary method for initialization and therefore will not interfere with the default behavior of update-instance-for-different-class. The arguments to update-instance-for-different-class are computed by change-class. When change-class is invoked on an instance, a copy of that instance is made; change-class then destructively alters the original instance. The first argument to update-instance-for-different-class, previous, is that copy; it holds the old slot values temporarily. This argument has dynamic extent within change-class; if it is referenced in any way once update-instance-for-different-class returns, the results are undefined. The second argument to update-instance-for-different-class, current, is the altered original instance. The intended use of previous is to extract old slot values by using slot-value or with-slots or by invoking a reader generic function, or to run other methods that were applicable to instances of the original class. The initargs argument consists of alternating initialization argument names and values. The value returned by update-instance-for-different-class is ignored by change-class. (update-instance-for-redefined-class [generic function] instance added-slots discarded-slots property-list &rest initargs) (update-instance-for-redefined-class [method] (instance standard-object) added-slots discarded-slots property-list &rest initargs) The generic function update-instance-for-redefined-class is not intended to be called by programmers. Programmers may write methods for it. The generic function update-instance-for- -redefined-class is called by the mechanism activated by make-instances-obsolete. The system-supplied primary method on update-instance-for- -different-class checks the validity of initialization arguments and signals an error if an initialization argument is supplied that is not declared valid. This method then initializes slots with values according to the initialization arguments and initializes the newly added slots with values according to their :initform forms. It does this by calling the generic function shared-initialize with the following arguments: the instance, a list of names of the newly added slots, and the initialization arguments it received. Newly added slots are those local slots for which no slot of the same name exists in the old version of the class. When make-instances-obsolete is invoked or when a class has been redefined and an instance is being updated, a property list is created that captures the slot names and values of all the discarded slots with values in the original instance. The structure of the instance is transformed so that it conforms to the current class definition. The arguments to update-instance-for-redefined-class are this transformed instance, a list of the names of the new slots added to the instance, a list of the names of the old slots discarded from the instance, and the property list containing the slot names and values for slots that were discarded and had values. Included in this list of discarded slots are slots that were local in the old class and are shared in the new class. The initargs argument consists of alternating initialization argument names and values. The value returned by update-instance-for-redefined-class is ignored. (with-accessors ({slot-entry}*) instance-form [macro] {declaration}* {form}*) The macro with-accessors creates a lexical environment in which specified slots are lexically available through their accessors as if they were variables. The macro with-accessors invokes the appropriate accessors to access the specified slots. Both setf and setq can be used to set the value of the slot. The result returned is that obtained by executing the forms specified by the body argument. (with-slots ({slot-entry}*) instance-form [macro] {declaration}* {form}*) slot-entry ::= slot-name | (variable-name slot-name) The macro with-slots creates a lexical context for referring to specified slots as though they were variables. Within such a context the value of the slot can be specified by using its slot name, as if it were a lexically bound variable. Both setf and setq can be used to set the value of the slot. The macro with-slots translates an appearance of the slot name as a variable into a call to slot-value. The result returned is that obtained by executing the forms specified by the body argument. --- C.all/lisp/ref/clos --- Copyright University of Sussex 1995. All rights reserved.