;;;; and runs the same rule.
(defclass short-method-combination (standard-method-combination)
- ((operator
- :reader short-combination-operator
- :initarg :operator)
- (identity-with-one-argument
- :reader short-combination-identity-with-one-argument
- :initarg :identity-with-one-argument))
+ ((operator
+ :reader short-combination-operator
+ :initarg :operator)
+ (identity-with-one-argument
+ :reader short-combination-identity-with-one-argument
+ :initarg :identity-with-one-argument))
(:predicate-name short-method-combination-p))
(defun expand-short-defcombin (whole)
',type ',operator ',identity-with-one-arg ',documentation)))
(defun load-short-defcombin (type operator ioa doc)
- (let* ((truename *load-truename*)
+ (let* ((pathname *load-pathname*)
(specializers
(list (find-class 'generic-function)
(intern-eql-specializer type)
(short-combine-methods
type options operator ioa new-method doc))
args))
- :definition-source `((define-method-combination ,type) ,truename)))
+ :definition-source `((define-method-combination ,type) ,pathname)))
(when old-method
(remove-method #'find-method-combination old-method))
- (add-method #'find-method-combination new-method)))
+ (add-method #'find-method-combination new-method)
+ (setf (random-documentation type 'method-combination) doc)
+ type))
(defun short-combine-methods (type options operator ioa method doc)
(cond ((null options) (setq options '(:most-specific-first)))
(order (car (method-combination-options combin)))
(around ())
(primary ()))
- (dolist (m applicable-methods)
- (let ((qualifiers (method-qualifiers m)))
- (flet ((lose (method why)
- (invalid-method-error
- method
- "The method ~S ~A.~%~
- The method combination type ~S was defined with the~%~
- short form of DEFINE-METHOD-COMBINATION and so requires~%~
- all methods have either the single qualifier ~S or the~%~
- single qualifier :AROUND."
- method why type type)))
- (cond ((null qualifiers)
- (lose m "has no qualifiers"))
- ((cdr qualifiers)
- (lose m "has more than one qualifier"))
+ (flet ((invalid (gf combin m)
+ (if *in-precompute-effective-methods-p*
+ (return-from compute-effective-method
+ `(%invalid-qualifiers ',gf ',combin ',m))
+ (invalid-qualifiers gf combin m))))
+ (dolist (m applicable-methods)
+ (let ((qualifiers (method-qualifiers m)))
+ (cond ((null qualifiers) (invalid generic-function combin m))
+ ((cdr qualifiers) (invalid generic-function combin m))
((eq (car qualifiers) :around)
(push m around))
((eq (car qualifiers) type)
(push m primary))
- (t
- (lose m "has an illegal qualifier"))))))
+ (t (invalid generic-function combin m))))))
(setq around (nreverse around))
(ecase order
(:most-specific-last) ; nothing to be done, already in correct order
`(,operator ,@(mapcar (lambda (m) `(call-method ,m ()))
primary)))))
(cond ((null primary)
- `(error "No ~S methods for the generic function ~S."
- ',type ',generic-function))
+ ;; As of sbcl-0.8.0.80 we don't seem to need to need
+ ;; to do anything messy like
+ ;; `(APPLY (FUNCTION (IF AROUND
+ ;; 'NO-PRIMARY-METHOD
+ ;; 'NO-APPLICABLE-METHOD)
+ ;; ',GENERIC-FUNCTION
+ ;; .ARGS.)
+ ;; here because (for reasons I don't understand at the
+ ;; moment -- WHN) control will never reach here if there
+ ;; are no applicable methods, but instead end up
+ ;; in NO-APPLICABLE-METHODS first.
+ ;;
+ ;; FIXME: The way that we arrange for .ARGS. to be bound
+ ;; here seems weird. We rely on EXPAND-EFFECTIVE-METHOD-FUNCTION
+ ;; recognizing any form whose operator is %NO-PRIMARY-METHOD
+ ;; as magical, and carefully surrounding it with a
+ ;; LAMBDA form which binds .ARGS. But...
+ ;; 1. That seems fragile, because the magicalness of
+ ;; %NO-PRIMARY-METHOD forms is scattered around
+ ;; the system. So it could easily be broken by
+ ;; locally-plausible maintenance changes like,
+ ;; e.g., using the APPLY expression above.
+ ;; 2. That seems buggy w.r.t. to MOPpish tricks in
+ ;; user code, e.g.
+ ;; (DEFMETHOD COMPUTE-EFFECTIVE-METHOD :AROUND (...)
+ ;; `(PROGN ,(CALL-NEXT-METHOD) (INCF *MY-CTR*)))
+ `(%no-primary-method ',generic-function .args.))
((null around) main-method)
(t
`(call-method ,(car around)
(,@(cdr around) (make-method ,main-method))))))))
+
+(defmethod invalid-qualifiers ((gf generic-function)
+ (combin short-method-combination)
+ method)
+ (let ((qualifiers (method-qualifiers method))
+ (type (method-combination-type combin)))
+ (let ((why (cond
+ ((null qualifiers) "has no qualifiers")
+ ((cdr qualifiers) "has too many qualifiers")
+ (t (aver (and (neq (car qualifiers) type)
+ (neq (car qualifiers) :around)))
+ "has an invalid qualifier"))))
+ (invalid-method-error
+ method
+ "The method ~S on ~S ~A.~%~
+ The method combination type ~S was defined with the~%~
+ short form of DEFINE-METHOD-COMBINATION and so requires~%~
+ all methods have either the single qualifier ~S or the~%~
+ single qualifier :AROUND."
+ method gf why type type))))
\f
;;;; long method combinations
-(defclass long-method-combination (standard-method-combination)
- ((function :initarg :function
- :reader long-method-combination-function)))
-
(defun expand-long-defcombin (form)
(let ((type (cadr form))
(lambda-list (caddr form))
(make-long-method-combination-function
type lambda-list method-group-specifiers args-option gf-var
body)
- `(load-long-defcombin ',type ',documentation #',function))))
+ `(load-long-defcombin ',type ',documentation #',function
+ ',args-option))))
(defvar *long-method-combination-functions* (make-hash-table :test 'eq))
-(defun load-long-defcombin (type doc function)
+(defun load-long-defcombin (type doc function args-lambda-list)
(let* ((specializers
(list (find-class 'generic-function)
(intern-eql-specializer type)
(make-instance 'long-method-combination
:type type
:options options
+ :args-lambda-list args-lambda-list
:documentation doc))
args))
:definition-source `((define-method-combination ,type)
- ,*load-truename*))))
+ ,*load-pathname*))))
(setf (gethash type *long-method-combination-functions*) function)
(when old-method (remove-method #'find-method-combination old-method))
- (add-method #'find-method-combination new-method)))
+ (add-method #'find-method-combination new-method)
+ (setf (random-documentation type 'method-combination) doc)
+ type))
(defmethod compute-effective-method ((generic-function generic-function)
(combin long-method-combination)
(defun make-long-method-combination-function
(type ll method-group-specifiers args-option gf-var body)
- ;;(declare (values documentation function))
(declare (ignore type))
- (multiple-value-bind (documentation declarations real-body)
- (extract-declarations body)
-
+ (multiple-value-bind (real-body declarations documentation)
+ (parse-body body)
(let ((wrapped-body
(wrap-method-group-specifier-bindings method-group-specifiers
declarations
(values
documentation
`(lambda (.generic-function. .method-combination. .applicable-methods.)
- (progn .generic-function. .method-combination. .applicable-methods.)
+ (declare (ignorable .generic-function.
+ .method-combination. .applicable-methods.))
(block .long-method-combination-function. ,wrapped-body))))))
;; parse-method-group-specifiers parse the method-group-specifiers
(push name names)
(push specializer-cache specializer-caches)
(push `((or ,@tests)
- (if (equal ,specializer-cache .specializers.)
- (return-from .long-method-combination-function.
- '(error "More than one method of type ~S ~
+ (if (and (equal ,specializer-cache .specializers.)
+ (not (null .specializers.)))
+ (return-from .long-method-combination-function.
+ '(error "More than one method of type ~S ~
with the same specializers."
- ',name))
- (setq ,specializer-cache .specializers.))
- (push .method. ,name))
- cond-clauses)
+ ',name))
+ (setq ,specializer-cache .specializers.))
+ (push .method. ,name))
+ cond-clauses)
(when required
(push `(when (null ,name)
(return-from .long-method-combination-function.
(dolist (.method. .applicable-methods.)
(let ((.qualifiers. (method-qualifiers .method.))
(.specializers. (method-specializers .method.)))
- (progn .qualifiers. .specializers.)
+ (declare (ignorable .qualifiers. .specializers.))
(cond ,@(nreverse cond-clauses))))
,@(nreverse required-checks)
,@(nreverse order-cleanups)
;;;
;;; At compute-effective-method time, the symbols in the :arguments
;;; option are bound to the symbols in the intercept lambda list.
-(defun deal-with-args-option (wrapped-body args-option)
- (let* ((intercept-lambda-list
- (let (collect)
- (dolist (arg args-option)
- (if (memq arg lambda-list-keywords)
- (push arg collect)
- (push (gensym) collect)))
- (nreverse collect)))
- (intercept-rebindings
- (loop for arg in args-option
- for int in intercept-lambda-list
- unless (memq arg lambda-list-keywords)
- collect `(,arg ',int))))
- (setf (cadr wrapped-body)
- (append intercept-rebindings (cadr wrapped-body)))
+(defun deal-with-args-option (wrapped-body args-lambda-list)
+ (let ((intercept-rebindings
+ (let (rebindings)
+ (dolist (arg args-lambda-list (nreverse rebindings))
+ (unless (member arg lambda-list-keywords)
+ (push `(,arg ',arg) rebindings)))))
+ (nreq 0)
+ (nopt 0)
+ (whole nil))
+ ;; Count the number of required and optional parameters in
+ ;; ARGS-LAMBDA-LIST into NREQ and NOPT, and set WHOLE to the
+ ;; name of a &WHOLE parameter, if any.
+ (when (member '&whole (rest args-lambda-list))
+ (error 'simple-program-error
+ :format-control "~@<The value of the :ARGUMENTS option of ~
+ DEFINE-METHOD-COMBINATION is~2I~_~S,~I~_but &WHOLE may ~
+ only appear first in the lambda list.~:>"
+ :format-arguments (list args-lambda-list)))
+ (loop with state = 'required
+ for arg in args-lambda-list do
+ (if (memq arg lambda-list-keywords)
+ (setq state arg)
+ (case state
+ (required (incf nreq))
+ (&optional (incf nopt))
+ (&whole (setq whole arg state 'required)))))
+ ;; This assumes that the head of WRAPPED-BODY is a let, and it
+ ;; injects let-bindings of the form (ARG 'SYM) for all variables
+ ;; of the argument-lambda-list; SYM is a gensym.
+ (aver (memq (first wrapped-body) '(let let*)))
+ (setf (second wrapped-body)
+ (append intercept-rebindings (second wrapped-body)))
+ ;; Be sure to fill out the args lambda list so that it can be too
+ ;; short if it wants to.
+ (unless (or (memq '&rest args-lambda-list)
+ (memq '&allow-other-keys args-lambda-list))
+ (let ((aux (memq '&aux args-lambda-list)))
+ (setq args-lambda-list
+ (append (ldiff args-lambda-list aux)
+ (if (memq '&key args-lambda-list)
+ '(&allow-other-keys)
+ '(&rest .ignore.))
+ aux))))
+ ;; .GENERIC-FUNCTION. is bound to the generic function in the
+ ;; method combination function, and .GF-ARGS* is bound to the
+ ;; generic function arguments in effective method functions
+ ;; created for generic functions having a method combination that
+ ;; uses :ARGUMENTS.
+ ;;
+ ;; The DESTRUCTURING-BIND binds the parameters of the
+ ;; ARGS-LAMBDA-LIST to actual generic function arguments. Because
+ ;; ARGS-LAMBDA-LIST may be shorter or longer than the generic
+ ;; function's lambda list, which is only known at run time, this
+ ;; destructuring has to be done on a slighly modified list of
+ ;; actual arguments, from which values might be stripped or added.
+ ;;
+ ;; Using one of the variable names in the body inserts a symbol
+ ;; into the effective method, and running the effective method
+ ;; produces the value of actual argument that is bound to the
+ ;; symbol.
+ `(let ((inner-result. ,wrapped-body)
+ (gf-lambda-list (generic-function-lambda-list .generic-function.)))
+ `(destructuring-bind ,',args-lambda-list
+ (frob-combined-method-args
+ .gf-args. ',gf-lambda-list
+ ,',nreq ,',nopt)
+ ,,(when (memq '.ignore. args-lambda-list)
+ ''(declare (ignore .ignore.)))
+ ;; If there is a &WHOLE in the args-lambda-list, let
+ ;; it result in the actual arguments of the generic-function
+ ;; not the frobbed list.
+ ,,(when whole
+ ``(setq ,',whole .gf-args.))
+ ,inner-result.))))
- ;; Be sure to fill out the intercept lambda list so that it can
- ;; be too short if it wants to.
- (cond ((memq '&rest intercept-lambda-list))
- ((memq '&allow-other-keys intercept-lambda-list))
- ((memq '&key intercept-lambda-list)
- (setq intercept-lambda-list
- (append intercept-lambda-list '(&allow-other-keys))))
- (t
- (setq intercept-lambda-list
- (append intercept-lambda-list '(&rest .ignore.)))))
+;;; Partition VALUES into three sections: required, optional, and the
+;;; rest, according to required, optional, and other parameters in
+;;; LAMBDA-LIST. Make the required and optional sections NREQ and
+;;; NOPT elements long by discarding values or adding NILs. Value is
+;;; the concatenated list of required and optional sections, and what
+;;; is left as rest from VALUES.
+(defun frob-combined-method-args (values lambda-list nreq nopt)
+ (loop with section = 'required
+ for arg in lambda-list
+ if (memq arg lambda-list-keywords) do
+ (setq section arg)
+ (unless (eq section '&optional)
+ (loop-finish))
+ else if (eq section 'required)
+ count t into nr
+ and collect (pop values) into required
+ else if (eq section '&optional)
+ count t into no
+ and collect (pop values) into optional
+ finally
+ (flet ((frob (list n m)
+ (cond ((> n m) (butlast list (- n m)))
+ ((< n m) (nconc list (make-list (- m n))))
+ (t list))))
+ (return (nconc (frob required nr nreq)
+ (frob optional no nopt)
+ values)))))
- `(let ((inner-result. ,wrapped-body))
- `(apply #'(lambda ,',intercept-lambda-list
- ,,(when (memq '.ignore. intercept-lambda-list)
- ''(declare (ignore .ignore.)))
- ,inner-result.)
- .combined-method-args.))))