0.7.13.pcl-class.1

[sbcl.git] / src / pcl / methods.lisp

;;;; This software is part of the SBCL system. See the README file for
;;;; more information.

;;;; This software is derived from software originally released by Xerox
;;;; Corporation. Copyright and release statements follow. Later modifications
;;;; to the software are in the public domain and are provided with
;;;; absolutely no warranty. See the COPYING and CREDITS files for more
;;;; information.

;;;; copyright information from original PCL sources:
;;;;
;;;; Copyright (c) 1985, 1986, 1987, 1988, 1989, 1990 Xerox Corporation.
;;;; All rights reserved.
;;;;
;;;; Use and copying of this software and preparation of derivative works based
;;;; upon this software are permitted. Any distribution of this software or
;;;; derivative works must comply with all applicable United States export
;;;; control laws.
;;;;
;;;; This software is made available AS IS, and Xerox Corporation makes no
;;;; warranty about the software, its performance or its conformity to any
;;;; specification.

(in-package "SB-PCL")
\f

;;; methods
;;;
;;; Methods themselves are simple inanimate objects. Most properties of
;;; methods are immutable, methods cannot be reinitialized. The following
;;; properties of methods can be changed:
;;;   METHOD-GENERIC-FUNCTION
;;;   METHOD-FUNCTION       ??

(defmethod method-function ((method standard-method))
  (or (slot-value method 'function)
      (let ((fmf (slot-value method 'fast-function)))
        (unless fmf ; The :BEFORE SHARED-INITIALIZE method prevents this.
          (error "~S doesn't seem to have a METHOD-FUNCTION." method))
        (setf (slot-value method 'function)
              (method-function-from-fast-function fmf)))))

(defmethod accessor-method-class ((method standard-accessor-method))
  (car (slot-value method 'specializers)))

(defmethod accessor-method-class ((method standard-writer-method))
  (cadr (slot-value method 'specializers)))

;;; initialization
;;;
;;; Error checking is done in before methods. Because of the simplicity of
;;; standard method objects the standard primary method can fill the slots.
;;;
;;; Methods are not reinitializable.

(defmethod reinitialize-instance ((method standard-method) &rest initargs)
  (declare (ignore initargs))
  (error "An attempt was made to reinitialize the method ~S.~%~
          Method objects cannot be reinitialized."
         method))

(defmethod legal-documentation-p ((object standard-method) x)
  (if (or (null x) (stringp x))
      t
      "a string or NULL"))

(defmethod legal-lambda-list-p ((object standard-method) x)
  (declare (ignore x))
  t)

(defmethod legal-method-function-p ((object standard-method) x)
  (if (functionp x)
      t
      "a function"))

(defmethod legal-qualifiers-p ((object standard-method) x)
  (flet ((improper-list ()
           (return-from legal-qualifiers-p "Is not a proper list.")))
    (dolist-carefully (q x improper-list)
      (let ((ok (legal-qualifier-p object q)))
        (unless (eq ok t)
          (return-from legal-qualifiers-p
            (format nil "Contains ~S which ~A" q ok)))))
    t))

(defmethod legal-qualifier-p ((object standard-method) x)
  (if (and x (atom x))
      t
      "is not a non-null atom"))

(defmethod legal-slot-name-p ((object standard-method) x)
  (cond ((not (symbolp x)) "is not a symbol and so cannot be bound")
        ((keywordp x)      "is a keyword and so cannot be bound")
        ((memq x '(t nil)) "cannot be bound")
        ((constantp x)     "is a constant and so cannot be bound")
        (t t)))

(defmethod legal-specializers-p ((object standard-method) x)
  (flet ((improper-list ()
           (return-from legal-specializers-p "Is not a proper list.")))
    (dolist-carefully (s x improper-list)
      (let ((ok (legal-specializer-p object s)))
        (unless (eq ok t)
          (return-from legal-specializers-p
            (format nil "Contains ~S which ~A" s ok)))))
    t))

(defvar *allow-experimental-specializers-p* nil)

(defmethod legal-specializer-p ((object standard-method) x)
  (if (if *allow-experimental-specializers-p*
          (specializerp x)
          (or (classp x)
              (eql-specializer-p x)))
      t
      "is neither a class object nor an EQL specializer"))

(defmethod shared-initialize :before ((method standard-method)
                                      slot-names
                                      &key qualifiers
                                           lambda-list
                                           specializers
                                           function
                                           fast-function
                                           documentation)
  (declare (ignore slot-names))
  (flet ((lose (initarg value string)
           (error "when initializing the method ~S:~%~
                   The ~S initialization argument was: ~S.~%~
                   which ~A."
                  method initarg value string)))
    (let ((check-qualifiers    (legal-qualifiers-p method qualifiers))
          (check-lambda-list   (legal-lambda-list-p method lambda-list))
          (check-specializers  (legal-specializers-p method specializers))
          (check-fun (legal-method-function-p method
                                              (or function
                                                  fast-function)))
          (check-documentation (legal-documentation-p method documentation)))
      (unless (eq check-qualifiers t)
        (lose :qualifiers qualifiers check-qualifiers))
      (unless (eq check-lambda-list t)
        (lose :lambda-list lambda-list check-lambda-list))
      (unless (eq check-specializers t)
        (lose :specializers specializers check-specializers))
      (unless (eq check-fun t)
        (lose :function function check-fun))
      (unless (eq check-documentation t)
        (lose :documentation documentation check-documentation)))))

(defmethod shared-initialize :before ((method standard-accessor-method)
                                      slot-names
                                      &key slot-name slot-definition)
  (declare (ignore slot-names))
  (unless slot-definition
    (let ((legalp (legal-slot-name-p method slot-name)))
      ;; FIXME: nasty convention; should be renamed to ILLEGAL-SLOT-NAME-P and
      ;; ILLEGALP, and the convention redone to be less twisty
      (unless (eq legalp t)
        (error "The value of the :SLOT-NAME initarg ~A." legalp)))))

(defmethod shared-initialize :after ((method standard-method) slot-names
                                     &rest initargs
                                     &key qualifiers method-spec plist)
  (declare (ignore slot-names method-spec plist))
  (initialize-method-function initargs nil method)
  (setf (plist-value method 'qualifiers) qualifiers)
  #+ignore
  (setf (slot-value method 'closure-generator)
        (method-function-closure-generator (slot-value method 'function))))

(defmethod shared-initialize :after ((method standard-accessor-method)
                                     slot-names
                                     &key)
  (declare (ignore slot-names))
  (with-slots (slot-name slot-definition)
    method
    (unless slot-definition
      (let ((class (accessor-method-class method)))
        (when (slot-class-p class)
          (setq slot-definition (find slot-name (class-direct-slots class)
                                      :key #'slot-definition-name)))))
    (when (and slot-definition (null slot-name))
      (setq slot-name (slot-definition-name slot-definition)))))

(defmethod method-qualifiers ((method standard-method))
  (plist-value method 'qualifiers))
\f
(defvar *the-class-generic-function*
  (find-class 'generic-function))
(defvar *the-class-standard-generic-function*
  (find-class 'standard-generic-function))
\f
(defmethod shared-initialize :before
           ((generic-function standard-generic-function)
            slot-names
            &key (name nil namep)
                 (lambda-list () lambda-list-p)
                 argument-precedence-order
                 declarations
                 documentation
                 (method-class nil method-class-supplied-p)
                 (method-combination nil method-combination-supplied-p))
  (declare (ignore slot-names
                   declarations argument-precedence-order documentation
                   lambda-list lambda-list-p))

  (when namep
    (set-fun-name generic-function name))

  (flet ((initarg-error (initarg value string)
           (error "when initializing the generic function ~S:~%~
                   The ~S initialization argument was: ~A.~%~
                   It must be ~A."
                  generic-function initarg value string)))
    (cond (method-class-supplied-p
           (when (symbolp method-class)
             (setq method-class (find-class method-class)))
           (unless (and (classp method-class)
                        (*subtypep (class-eq-specializer method-class)
                                   *the-class-method*))
             (initarg-error :method-class
                            method-class
                            "a subclass of the class METHOD"))
           (setf (slot-value generic-function 'method-class) method-class))
          ((slot-boundp generic-function 'method-class))
          (t
           (initarg-error :method-class
                          "not supplied"
                          "a subclass of the class METHOD")))
    (cond (method-combination-supplied-p
           (unless (method-combination-p method-combination)
             (initarg-error :method-combination
                            method-combination
                            "a method combination object")))
          ((slot-boundp generic-function 'method-combination))
          (t
           (initarg-error :method-combination
                          "not supplied"
                          "a method combination object")))))

#||
(defmethod reinitialize-instance ((generic-function standard-generic-function)
                                  &rest initargs
                                  &key name
                                       lambda-list
                                       argument-precedence-order
                                       declarations
                                       documentation
                                       method-class
                                       method-combination)
  (declare (ignore documentation declarations argument-precedence-order
                   lambda-list name method-class method-combination))
  (macrolet ((add-initarg (check name slot-name)
               `(unless ,check
                  (push (slot-value generic-function ,slot-name) initargs)
                  (push ,name initargs))))
;   (add-initarg name :name 'name)
;   (add-initarg lambda-list :lambda-list 'lambda-list)
;   (add-initarg argument-precedence-order
;                :argument-precedence-order
;                'argument-precedence-order)
;   (add-initarg declarations :declarations 'declarations)
;   (add-initarg documentation :documentation 'documentation)
;   (add-initarg method-class :method-class 'method-class)
;   (add-initarg method-combination :method-combination 'method-combination)
    (apply #'call-next-method generic-function initargs)))
||#
\f
;;; These three are scheduled for demolition.

(defmethod remove-named-method (generic-function-name argument-specifiers
                                                      &optional extra)
  (let ((generic-function ())
        (method ()))
    (cond ((or (null (fboundp generic-function-name))
               (not (generic-function-p
                      (setq generic-function
                            (fdefinition generic-function-name)))))
           (error "~S does not name a generic function."
                  generic-function-name))
          ((null (setq method (get-method generic-function
                                          extra
                                          (parse-specializers
                                            argument-specifiers)
                                          nil)))
           (error "There is no method for the generic function ~S~%~
                   which matches the ARGUMENT-SPECIFIERS ~S."
                  generic-function
                  argument-specifiers))
          (t
           (remove-method generic-function method)))))

(defun real-add-named-method (generic-function-name
                              qualifiers
                              specializers
                              lambda-list
                              &rest other-initargs)
  (unless (and (fboundp generic-function-name)
               (typep (fdefinition generic-function-name) 'generic-function))
    (sb-kernel::style-warn "implicitly creating new generic function ~S"
                           generic-function-name))
  ;; XXX What about changing the class of the generic function if
  ;; there is one? Whose job is that, anyway? Do we need something
  ;; kind of like CLASS-FOR-REDEFINITION?
  (let* ((generic-function
           (ensure-generic-function generic-function-name))
         (specs (parse-specializers specializers))
         (proto (method-prototype-for-gf generic-function-name))
         (new (apply #'make-instance (class-of proto)
                                     :qualifiers qualifiers
                                     :specializers specs
                                     :lambda-list lambda-list
                                     other-initargs)))
    (add-method generic-function new)))

(defun real-get-method (generic-function qualifiers specializers
                                         &optional (errorp t))
  (let ((hit 
          (dolist (method (generic-function-methods generic-function))
            (let ((mspecializers (method-specializers method)))
              (when (and (equal qualifiers (method-qualifiers method))
                         (= (length specializers) (length mspecializers))
                         (every #'same-specializer-p specializers
                                (method-specializers method)))
                (return method))))))
    (cond (hit hit)
          ((null errorp) nil)
          (t
           (error "no method on ~S with qualifiers ~:S and specializers ~:S"
                  generic-function qualifiers specializers)))))
\f
(defmethod find-method ((generic-function standard-generic-function)
                        qualifiers specializers &optional (errorp t))
  (real-get-method generic-function qualifiers
                   (parse-specializers specializers) errorp))
\f
;;; Compute various information about a generic-function's arglist by looking
;;; at the argument lists of the methods. The hair for trying not to use
;;; &REST arguments lives here.
;;;  The values returned are:
;;;    number-of-required-arguments
;;;       the number of required arguments to this generic-function's
;;;       discriminating function
;;;    &rest-argument-p
;;;       whether or not this generic-function's discriminating
;;;       function takes an &rest argument.
;;;    specialized-argument-positions
;;;       a list of the positions of the arguments this generic-function
;;;       specializes (e.g. for a classical generic-function this is the
;;;       list: (1)).
(defmethod compute-discriminating-function-arglist-info
           ((generic-function standard-generic-function))
  ;;(declare (values number-of-required-arguments &rest-argument-p
  ;;             specialized-argument-postions))
  (let ((number-required nil)
        (restp nil)
        (specialized-positions ())
        (methods (generic-function-methods generic-function)))
    (dolist (method methods)
      (multiple-value-setq (number-required restp specialized-positions)
        (compute-discriminating-function-arglist-info-internal
         generic-function method number-required restp specialized-positions)))
    (values number-required restp (sort specialized-positions #'<))))

(defun compute-discriminating-function-arglist-info-internal
       (generic-function method number-of-requireds restp
        specialized-argument-positions)
  (declare (ignore generic-function)
           (type (or null fixnum) number-of-requireds))
  (let ((requireds 0))
    (declare (fixnum requireds))
    ;; Go through this methods arguments seeing how many are required,
    ;; and whether there is an &rest argument.
    (dolist (arg (method-lambda-list method))
      (cond ((eq arg '&aux) (return))
            ((memq arg '(&optional &rest &key))
             (return (setq restp t)))
            ((memq arg lambda-list-keywords))
            (t (incf requireds))))
    ;; Now go through this method's type specifiers to see which
    ;; argument positions are type specified. Treat T specially
    ;; in the usual sort of way. For efficiency don't bother to
    ;; keep specialized-argument-positions sorted, rather depend
    ;; on our caller to do that.
    (let ((pos 0))
      (dolist (type-spec (method-specializers method))
        (unless (eq type-spec *the-class-t*)
          (pushnew pos specialized-argument-positions))
        (incf pos)))
    ;; Finally merge the values for this method into the values
    ;; for the exisiting methods and return them. Note that if
    ;; num-of-requireds is NIL it means this is the first method
    ;; and we depend on that.
    (values (min (or number-of-requireds requireds) requireds)
            (or restp
                (and number-of-requireds (/= number-of-requireds requireds)))
            specialized-argument-positions)))

(defun make-discriminating-function-arglist (number-required-arguments restp)
  (nconc (let ((args nil))
           (dotimes (i number-required-arguments)
             (push (intern (format nil "Discriminating Function Arg ~D" i))
                   args))
           (nreverse args))
         (when restp
               `(&rest ,(intern "Discriminating Function &rest Arg")))))
\f
(defmethod generic-function-argument-precedence-order
    ((gf standard-generic-function))
  (aver (eq *boot-state* 'complete))
  (loop with arg-info = (gf-arg-info gf)
        with lambda-list = (arg-info-lambda-list arg-info)
        for argument-position in (arg-info-precedence arg-info)
        collect (nth argument-position lambda-list)))

(defmethod generic-function-lambda-list ((gf generic-function))
  (gf-lambda-list gf))

(defmethod gf-fast-method-function-p ((gf standard-generic-function))
  (gf-info-fast-mf-p (slot-value gf 'arg-info)))

(defmethod initialize-instance :after ((gf standard-generic-function)
                                       &key (lambda-list nil lambda-list-p)
                                       argument-precedence-order)
  (with-slots (arg-info)
    gf
    (if lambda-list-p
        (set-arg-info gf
                      :lambda-list lambda-list
                      :argument-precedence-order argument-precedence-order)
        (set-arg-info gf))
    (when (arg-info-valid-p arg-info)
      (update-dfun gf))))

(defmethod reinitialize-instance :after ((gf standard-generic-function)
                                         &rest args
                                         &key (lambda-list nil lambda-list-p)
                                         (argument-precedence-order
                                          nil argument-precedence-order-p))
  (with-slots (arg-info)
    gf
    (if lambda-list-p
        (if argument-precedence-order-p
            (set-arg-info gf
                          :lambda-list lambda-list
                          :argument-precedence-order argument-precedence-order)
            (set-arg-info gf
                          :lambda-list lambda-list))
        (set-arg-info gf))
    (when (and (arg-info-valid-p arg-info)
               args
               (or lambda-list-p (cddr args)))
      (update-dfun gf))))

(declaim (special *lazy-dfun-compute-p*))

(defun set-methods (gf methods)
  (setf (generic-function-methods gf) nil)
  (loop (when (null methods) (return gf))
        (real-add-method gf (pop methods) methods)))

(defun real-add-method (generic-function method &optional skip-dfun-update-p)
  (when (method-generic-function method)
    (error "The method ~S is already part of the generic~@
            function ~S. It can't be added to another generic~@
            function until it is removed from the first one."
           method (method-generic-function method)))
  (flet ((similar-lambda-lists-p (method-a method-b)
           (multiple-value-bind (a-nreq a-nopt a-keyp a-restp)
               (analyze-lambda-list (method-lambda-list method-a))
             (multiple-value-bind (b-nreq b-nopt b-keyp b-restp)
                 (analyze-lambda-list (method-lambda-list method-b))
               (and (= a-nreq b-nreq)
                    (= a-nopt b-nopt)
                    (eq (or a-keyp a-restp)
                        (or b-keyp b-restp)))))))
      (let* ((name (generic-function-name generic-function))
             (qualifiers (method-qualifiers method))
             (specializers (method-specializers method))
             (existing (get-method generic-function
                                   qualifiers
                                   specializers
                                   nil)))

        ;; If there is already a method like this one then we must get
        ;; rid of it before proceeding.  Note that we call the generic
        ;; function REMOVE-METHOD to remove it rather than doing it in
        ;; some internal way.
        (when (and existing (similar-lambda-lists-p existing method))
          (remove-method generic-function existing))

        (setf (method-generic-function method) generic-function)
        (pushnew method (generic-function-methods generic-function))
        (dolist (specializer specializers)
          (add-direct-method specializer method))

        ;; KLUDGE: SET-ARG-INFO contains the error-detecting logic for
        ;; detecting attempts to add methods with incongruent lambda
        ;; lists.  However, according to Gerd Moellmann on cmucl-imp,
        ;; it also depends on the new method already having been added
        ;; to the generic function.  Therefore, we need to remove it
        ;; again on error:
        (let ((remove-again-p t))
          (unwind-protect
               (progn
                 (set-arg-info generic-function :new-method method)
                 (setq remove-again-p nil))
            (when remove-again-p
              (remove-method generic-function method))))
        (unless skip-dfun-update-p
          (update-ctors 'add-method
                        :generic-function generic-function
                        :method method)
          (update-dfun generic-function))
        method)))

(defun real-remove-method (generic-function method)
  ;; Note: Error check prohibited by ANSI spec removed.
  (when  (eq generic-function (method-generic-function method))
    (let* ((name         (generic-function-name generic-function))
           (specializers (method-specializers method))
           (methods      (generic-function-methods generic-function))
           (new-methods  (remove method methods)))
      (setf (method-generic-function method) nil)
      (setf (generic-function-methods generic-function) new-methods)
      (dolist (specializer (method-specializers method))
        (remove-direct-method specializer method))
      (set-arg-info generic-function)
      (update-ctors 'remove-method
                    :generic-function generic-function
                    :method method)
      (update-dfun generic-function)
      generic-function)))
\f
(defun compute-applicable-methods-function (generic-function arguments)
  (values (compute-applicable-methods-using-types
           generic-function
           (types-from-args generic-function arguments 'eql))))

(defmethod compute-applicable-methods
    ((generic-function generic-function) arguments)
  (values (compute-applicable-methods-using-types
           generic-function
           (types-from-args generic-function arguments 'eql))))

(defmethod compute-applicable-methods-using-classes
    ((generic-function generic-function) classes)
  (compute-applicable-methods-using-types
   generic-function
   (types-from-args generic-function classes 'class-eq)))

(defun proclaim-incompatible-superclasses (classes)
  (setq classes (mapcar (lambda (class)
                          (if (symbolp class)
                              (find-class class)
                              class))
                        classes))
  (dolist (class classes)
    (dolist (other-class classes)
      (unless (eq class other-class)
        (pushnew other-class (class-incompatible-superclass-list class))))))

(defun superclasses-compatible-p (class1 class2)
  (let ((cpl1 (class-precedence-list class1))
        (cpl2 (class-precedence-list class2)))
    (dolist (sc1 cpl1 t)
      (dolist (ic (class-incompatible-superclass-list sc1))
        (when (memq ic cpl2)
          (return-from superclasses-compatible-p nil))))))

(mapc
 #'proclaim-incompatible-superclasses
 '(;; superclass class
   (built-in-class std-class structure-class) ; direct subclasses of pcl-class
   (standard-class funcallable-standard-class)
   ;; superclass metaobject
   (class eql-specializer class-eq-specializer method method-combination
    generic-function slot-definition)
   ;; metaclass built-in-class
   (number sequence character           ; direct subclasses of t, but not array
    standard-object structure-object)   ;                        or symbol
   (number array character symbol       ; direct subclasses of t, but not
    standard-object structure-object)   ;                        sequence
   (complex float rational)             ; direct subclasses of number
   (integer ratio)                      ; direct subclasses of rational
   (list vector)                        ; direct subclasses of sequence
   (cons null)                          ; direct subclasses of list
   (string bit-vector)                  ; direct subclasses of vector
   ))
\f
(defmethod same-specializer-p ((specl1 specializer) (specl2 specializer))
  nil)

(defmethod same-specializer-p ((specl1 class) (specl2 class))
  (eq specl1 specl2))

(defmethod specializer-class ((specializer class))
  specializer)

(defmethod same-specializer-p ((specl1 class-eq-specializer)
                               (specl2 class-eq-specializer))
  (eq (specializer-class specl1) (specializer-class specl2)))

(defmethod same-specializer-p ((specl1 eql-specializer)
                               (specl2 eql-specializer))
  (eq (specializer-object specl1) (specializer-object specl2)))

(defmethod specializer-class ((specializer eql-specializer))
  (class-of (slot-value specializer 'object)))

(defvar *in-gf-arg-info-p* nil)
(setf (gdefinition 'arg-info-reader)
      (let ((mf (initialize-method-function
                 (make-internal-reader-method-function
                  'standard-generic-function 'arg-info)
                 t)))
        (lambda (&rest args) (funcall mf args nil))))


(defun error-need-at-least-n-args (function n)
  (error "~@<The function ~2I~_~S ~I~_requires at least ~W argument~:P.~:>"
         function
         n))

(defun types-from-args (generic-function arguments &optional type-modifier)
  (multiple-value-bind (nreq applyp metatypes nkeys arg-info)
      (get-generic-fun-info generic-function)
    (declare (ignore applyp metatypes nkeys))
    (let ((types-rev nil))
      (dotimes-fixnum (i nreq)
        i
        (unless arguments
          (error-need-at-least-n-args (generic-function-name generic-function)
                                      nreq))
        (let ((arg (pop arguments)))
          (push (if type-modifier `(,type-modifier ,arg) arg) types-rev)))
      (values (nreverse types-rev) arg-info))))

(defun get-wrappers-from-classes (nkeys wrappers classes metatypes)
  (let* ((w wrappers) (w-tail w) (mt-tail metatypes))
    (dolist (class (if (listp classes) classes (list classes)))
      (unless (eq t (car mt-tail))
        (let ((c-w (class-wrapper class)))
          (unless c-w (return-from get-wrappers-from-classes nil))
          (if (eql nkeys 1)
              (setq w c-w)
              (setf (car w-tail) c-w
                    w-tail (cdr w-tail)))))
      (setq mt-tail (cdr mt-tail)))
    w))

(defun sdfun-for-caching (gf classes)
  (let ((types (mapcar #'class-eq-type classes)))
    (multiple-value-bind (methods all-applicable-and-sorted-p)
        (compute-applicable-methods-using-types gf types)
      (function-funcall (get-secondary-dispatch-function1
                         gf methods types nil t all-applicable-and-sorted-p)
                        nil (mapcar #'class-wrapper classes)))))

(defun value-for-caching (gf classes)
  (let ((methods (compute-applicable-methods-using-types
                   gf (mapcar #'class-eq-type classes))))
    (method-function-get (or (method-fast-function (car methods))
                             (method-function (car methods)))
                         :constant-value)))

(defun default-secondary-dispatch-function (generic-function)
  (lambda (&rest args)
    (let ((methods (compute-applicable-methods generic-function args)))
      (if methods
          (let ((emf (get-effective-method-function generic-function
                                                    methods)))
            (invoke-emf emf args))
          (apply #'no-applicable-method generic-function args)))))

(defun list-eq (x y)
  (loop (when (atom x) (return (eq x y)))
        (when (atom y) (return nil))
        (unless (eq (car x) (car y)) (return nil))
        (setq x (cdr x)  y (cdr y))))

(defvar *std-cam-methods* nil)

(defun compute-applicable-methods-emf (generic-function)
  (if (eq *boot-state* 'complete)
      (let* ((cam (gdefinition 'compute-applicable-methods))
             (cam-methods (compute-applicable-methods-using-types
                           cam (list `(eql ,generic-function) t))))
        (values (get-effective-method-function cam cam-methods)
                (list-eq cam-methods
                         (or *std-cam-methods*
                             (setq *std-cam-methods*
                                   (compute-applicable-methods-using-types
                                    cam (list `(eql ,cam) t)))))))
      (values #'compute-applicable-methods-function t)))

(defun compute-applicable-methods-emf-std-p (gf)
  (gf-info-c-a-m-emf-std-p (gf-arg-info gf)))

(defvar *old-c-a-m-gf-methods* nil)

(defun update-all-c-a-m-gf-info (c-a-m-gf)
  (let ((methods (generic-function-methods c-a-m-gf)))
    (if (and *old-c-a-m-gf-methods*
             (every (lambda (old-method)
                      (member old-method methods))
                    *old-c-a-m-gf-methods*))
        (let ((gfs-to-do nil)
              (gf-classes-to-do nil))
          (dolist (method methods)
            (unless (member method *old-c-a-m-gf-methods*)
              (let ((specl (car (method-specializers method))))
                (if (eql-specializer-p specl)
                    (pushnew (specializer-object specl) gfs-to-do)
                    (pushnew (specializer-class specl) gf-classes-to-do)))))
          (map-all-generic-functions
           (lambda (gf)
             (when (or (member gf gfs-to-do)
                       (dolist (class gf-classes-to-do nil)
                         (member class
                                 (class-precedence-list (class-of gf)))))
               (update-c-a-m-gf-info gf)))))
        (map-all-generic-functions #'update-c-a-m-gf-info))
    (setq *old-c-a-m-gf-methods* methods)))

(defun update-gf-info (gf)
  (update-c-a-m-gf-info gf)
  (update-gf-simple-accessor-type gf))

(defun update-c-a-m-gf-info (gf)
  (unless (early-gf-p gf)
    (multiple-value-bind (c-a-m-emf std-p)
        (compute-applicable-methods-emf gf)
      (let ((arg-info (gf-arg-info gf)))
        (setf (gf-info-static-c-a-m-emf arg-info) c-a-m-emf)
        (setf (gf-info-c-a-m-emf-std-p arg-info) std-p)))))

(defun update-gf-simple-accessor-type (gf)
  (let ((arg-info (gf-arg-info gf)))
    (setf (gf-info-simple-accessor-type arg-info)
          (let* ((methods (generic-function-methods gf))
                 (class (and methods (class-of (car methods))))
                 (type (and class
                            (cond ((eq class
                                       *the-class-standard-reader-method*)
                                   'reader)
                                  ((eq class
                                       *the-class-standard-writer-method*)
                                   'writer)
                                  ((eq class
                                       *the-class-standard-boundp-method*)
                                   'boundp)))))
            (when (and (gf-info-c-a-m-emf-std-p arg-info)
                       type
                       (dolist (method (cdr methods) t)
                         (unless (eq class (class-of method)) (return nil)))
                       (eq (generic-function-method-combination gf)
                           *standard-method-combination*))
              type)))))

(defun get-accessor-method-function (gf type class slotd)
  (let* ((std-method (standard-svuc-method type))
         (str-method (structure-svuc-method type))
         (types1 `((eql ,class) (class-eq ,class) (eql ,slotd)))
         (types (if (eq type 'writer) `(t ,@types1) types1))
         (methods (compute-applicable-methods-using-types gf types))
         (std-p (null (cdr methods))))
    (values
     (if std-p
         (get-optimized-std-accessor-method-function class slotd type)
         (get-accessor-from-svuc-method-function
          class slotd
          (get-secondary-dispatch-function
           gf methods types
           `((,(car (or (member std-method methods)
                        (member str-method methods)
                        (error "error in get-accessor-method-function")))
              ,(get-optimized-std-slot-value-using-class-method-function
                class slotd type)))
           (unless (and (eq type 'writer)
                        (dolist (method methods t)
                          (unless (eq (car (method-specializers method))
                                      *the-class-t*)
                            (return nil))))
             (let ((wrappers (list (wrapper-of class)
                                   (class-wrapper class)
                                   (wrapper-of slotd))))
               (if (eq type 'writer)
                   (cons (class-wrapper *the-class-t*) wrappers)
                   wrappers))))
          type))
     std-p)))

;;; used by OPTIMIZE-SLOT-VALUE-BY-CLASS-P (vector.lisp)
(defun update-slot-value-gf-info (gf type)
  (unless *new-class*
    (update-std-or-str-methods gf type))
  (when (and (standard-svuc-method type) (structure-svuc-method type))
    (flet ((update-class (class)
             (when (class-finalized-p class)
               (dolist (slotd (class-slots class))
                 (compute-slot-accessor-info slotd type gf)))))
      (if *new-class*
          (update-class *new-class*)
          (map-all-classes #'update-class 'slot-object)))))

(defvar *standard-slot-value-using-class-method* nil)
(defvar *standard-setf-slot-value-using-class-method* nil)
(defvar *standard-slot-boundp-using-class-method* nil)
(defvar *structure-slot-value-using-class-method* nil)
(defvar *structure-setf-slot-value-using-class-method* nil)
(defvar *structure-slot-boundp-using-class-method* nil)

(defun standard-svuc-method (type)
  (case type
    (reader *standard-slot-value-using-class-method*)
    (writer *standard-setf-slot-value-using-class-method*)
    (boundp *standard-slot-boundp-using-class-method*)))

(defun set-standard-svuc-method (type method)
  (case type
    (reader (setq *standard-slot-value-using-class-method* method))
    (writer (setq *standard-setf-slot-value-using-class-method* method))
    (boundp (setq *standard-slot-boundp-using-class-method* method))))

(defun structure-svuc-method (type)
  (case type
    (reader *structure-slot-value-using-class-method*)
    (writer *structure-setf-slot-value-using-class-method*)
    (boundp *structure-slot-boundp-using-class-method*)))

(defun set-structure-svuc-method (type method)
  (case type
    (reader (setq *structure-slot-value-using-class-method* method))
    (writer (setq *structure-setf-slot-value-using-class-method* method))
    (boundp (setq *structure-slot-boundp-using-class-method* method))))

(defun update-std-or-str-methods (gf type)
  (dolist (method (generic-function-methods gf))
    (let ((specls (method-specializers method)))
      (when (and (or (not (eq type 'writer))
                     (eq (pop specls) *the-class-t*))
                 (every #'classp specls))
        (cond ((and (eq (class-name (car specls))
                        'std-class)
                    (eq (class-name (cadr specls))
                        'std-object)
                    (eq (class-name (caddr specls))
                        'standard-effective-slot-definition))
               (set-standard-svuc-method type method))
              ((and (eq (class-name (car specls))
                        'structure-class)
                    (eq (class-name (cadr specls))
                        'structure-object)
                    (eq (class-name (caddr specls))
                        'structure-effective-slot-definition))
               (set-structure-svuc-method type method)))))))

(defun mec-all-classes-internal (spec precompute-p)
  (cons (specializer-class spec)
        (and (classp spec)
             precompute-p
             (not (or (eq spec *the-class-t*)
                      (eq spec *the-class-slot-object*)
                      (eq spec *the-class-std-object*)
                      (eq spec *the-class-standard-object*)
                      (eq spec *the-class-structure-object*)))
             (let ((sc (class-direct-subclasses spec)))
               (when sc
                 (mapcan (lambda (class)
                           (mec-all-classes-internal class precompute-p))
                         sc))))))

(defun mec-all-classes (spec precompute-p)
  (let ((classes (mec-all-classes-internal spec precompute-p)))
    (if (null (cdr classes))
        classes
        (let* ((a-classes (cons nil classes))
               (tail classes))
          (loop (when (null (cdr tail))
                  (return (cdr a-classes)))
                (let ((class (cadr tail))
                      (ttail (cddr tail)))
                  (if (dolist (c ttail nil)
                        (when (eq class c) (return t)))
                      (setf (cdr tail) (cddr tail))
                      (setf tail (cdr tail)))))))))

(defun mec-all-class-lists (spec-list precompute-p)
  (if (null spec-list)
      (list nil)
      (let* ((car-all-classes (mec-all-classes (car spec-list)
                                               precompute-p))
             (all-class-lists (mec-all-class-lists (cdr spec-list)
                                                   precompute-p)))
        (mapcan (lambda (list)
                  (mapcar (lambda (c) (cons c list)) car-all-classes))
                all-class-lists))))

(defun make-emf-cache (generic-function valuep cache classes-list new-class)
  (let* ((arg-info (gf-arg-info generic-function))
         (nkeys (arg-info-nkeys arg-info))
         (metatypes (arg-info-metatypes arg-info))
         (wrappers (unless (eq nkeys 1) (make-list nkeys)))
         (precompute-p (gf-precompute-dfun-and-emf-p arg-info))
         (default '(default)))
    (flet ((add-class-list (classes)
             (when (or (null new-class) (memq new-class classes))
               (let ((wrappers (get-wrappers-from-classes
                                nkeys wrappers classes metatypes)))
                 (when (and wrappers
                            (eq default (probe-cache cache wrappers default)))
                   (let ((value (cond ((eq valuep t)
                                       (sdfun-for-caching generic-function
                                                          classes))
                                      ((eq valuep :constant-value)
                                       (value-for-caching generic-function
                                                          classes)))))
                     (setq cache (fill-cache cache wrappers value t))))))))
      (if classes-list
          (mapc #'add-class-list classes-list)
          (dolist (method (generic-function-methods generic-function))
            (mapc #'add-class-list
                  (mec-all-class-lists (method-specializers method)
                                       precompute-p))))
      cache)))

(defmacro class-test (arg class)
  (cond ((eq class *the-class-t*)
         t)
        ((eq class *the-class-slot-object*)
         `(not (typep (sb-kernel:classoid-of ,arg)
                      'sb-kernel:built-in-classoid)))
        ((eq class *the-class-std-object*)
         `(or (std-instance-p ,arg) (fsc-instance-p ,arg)))
        ((eq class *the-class-standard-object*)
         `(std-instance-p ,arg))
        ((eq class *the-class-funcallable-standard-object*)
         `(fsc-instance-p ,arg))
        (t
         `(typep ,arg ',(class-name class)))))

(defmacro class-eq-test (arg class)
  `(eq (class-of ,arg) ',class))

(defmacro eql-test (arg object)
  `(eql ,arg ',object))

(defun dnet-methods-p (form)
  (and (consp form)
       (or (eq (car form) 'methods)
           (eq (car form) 'unordered-methods))))

;;; This is CASE, but without gensyms.
(defmacro scase (arg &rest clauses)
  `(let ((.case-arg. ,arg))
     (cond ,@(mapcar (lambda (clause)
                       (list* (cond ((null (car clause))
                                     nil)
                                    ((consp (car clause))
                                     (if (null (cdar clause))
                                         `(eql .case-arg.
                                               ',(caar clause))
                                         `(member .case-arg.
                                                  ',(car clause))))
                                    ((member (car clause) '(t otherwise))
                                     `t)
                                    (t
                                     `(eql .case-arg. ',(car clause))))
                              nil
                              (cdr clause)))
                     clauses))))

(defmacro mcase (arg &rest clauses) `(scase ,arg ,@clauses))

(defun generate-discrimination-net (generic-function methods types sorted-p)
  (let* ((arg-info (gf-arg-info generic-function))
         (precedence (arg-info-precedence arg-info)))
    (generate-discrimination-net-internal
     generic-function methods types
     (lambda (methods known-types)
       (if (or sorted-p
               (block one-order-p
                 (let ((sorted-methods nil))
                   (map-all-orders
                    (copy-list methods) precedence
                    (lambda (methods)
                      (when sorted-methods (return-from one-order-p nil))
                      (setq sorted-methods methods)))
                   (setq methods sorted-methods))
                 t))
           `(methods ,methods ,known-types)
           `(unordered-methods ,methods ,known-types)))
     (lambda (position type true-value false-value)
       (let ((arg (dfun-arg-symbol position)))
         (if (eq (car type) 'eql)
             (let* ((false-case-p (and (consp false-value)
                                       (or (eq (car false-value) 'scase)
                                           (eq (car false-value) 'mcase))
                                       (eq arg (cadr false-value))))
                    (false-clauses (if false-case-p
                                       (cddr false-value)
                                       `((t ,false-value))))
                    (case-sym (if (and (dnet-methods-p true-value)
                                       (if false-case-p
                                           (eq (car false-value) 'mcase)
                                           (dnet-methods-p false-value)))
                                  'mcase
                                  'scase))
                    (type-sym `(,(cadr type))))
               `(,case-sym ,arg
                           (,type-sym ,true-value)
                           ,@false-clauses))
             `(if ,(let ((arg (dfun-arg-symbol position)))
                     (case (car type)
                       (class    `(class-test    ,arg ,(cadr type)))
                       (class-eq `(class-eq-test ,arg ,(cadr type)))))
                  ,true-value
                  ,false-value))))
     #'identity)))

(defun class-from-type (type)
  (if (or (atom type) (eq (car type) t))
      *the-class-t*
      (case (car type)
        (and (dolist (type (cdr type) *the-class-t*)
               (when (and (consp type) (not (eq (car type) 'not)))
                 (return (class-from-type type)))))
        (not *the-class-t*)
        (eql (class-of (cadr type)))
        (class-eq (cadr type))
        (class (cadr type)))))

(defun precompute-effective-methods (gf caching-p &optional classes-list-p)
  (let* ((arg-info (gf-arg-info gf))
         (methods (generic-function-methods gf))
         (precedence (arg-info-precedence arg-info))
         (*in-precompute-effective-methods-p* t)
         (classes-list nil))
    (generate-discrimination-net-internal
     gf methods nil
     (lambda (methods known-types)
       (when methods
         (when classes-list-p
           (push (mapcar #'class-from-type known-types) classes-list))
         (let ((no-eql-specls-p (not (methods-contain-eql-specializer-p
                                      methods))))
           (map-all-orders
            methods precedence
            (lambda (methods)
              (get-secondary-dispatch-function1
               gf methods known-types
               nil caching-p no-eql-specls-p))))))
     (lambda (position type true-value false-value)
       (declare (ignore position type true-value false-value))
       nil)
     (lambda (type)
       (if (and (consp type) (eq (car type) 'eql))
           `(class-eq ,(class-of (cadr type)))
           type)))
    classes-list))

;;; We know that known-type implies neither new-type nor `(not ,new-type).
(defun augment-type (new-type known-type)
  (if (or (eq known-type t)
          (eq (car new-type) 'eql))
      new-type
      (let ((so-far (if (and (consp known-type) (eq (car known-type) 'and))
                        (cdr known-type)
                        (list known-type))))
        (unless (eq (car new-type) 'not)
          (setq so-far
                (mapcan (lambda (type)
                          (unless (*subtypep new-type type)
                            (list type)))
                        so-far)))
        (if (null so-far)
            new-type
            `(and ,new-type ,@so-far)))))

(defun generate-discrimination-net-internal
    (gf methods types methods-function test-fun type-function)
  (let* ((arg-info (gf-arg-info gf))
         (precedence (arg-info-precedence arg-info))
         (nreq (arg-info-number-required arg-info))
         (metatypes (arg-info-metatypes arg-info)))
    (labels ((do-column (p-tail contenders known-types)
               (if p-tail
                   (let* ((position (car p-tail))
                          (known-type (or (nth position types) t)))
                     (if (eq (nth position metatypes) t)
                         (do-column (cdr p-tail) contenders
                                    (cons (cons position known-type)
                                          known-types))
                         (do-methods p-tail contenders
                                     known-type () known-types)))
                   (funcall methods-function contenders
                            (let ((k-t (make-list nreq)))
                              (dolist (index+type known-types)
                                (setf (nth (car index+type) k-t)
                                      (cdr index+type)))
                              k-t))))
             (do-methods (p-tail contenders known-type winners known-types)
               ;; CONTENDERS
               ;;   is a (sorted) list of methods that must be discriminated.
               ;; KNOWN-TYPE
               ;;   is the type of this argument, constructed from tests
               ;;   already made.
               ;; WINNERS
               ;;   is a (sorted) list of methods that are potentially
               ;;   applicable after the discrimination has been made.
               (if (null contenders)
                   (do-column (cdr p-tail)
                              winners
                              (cons (cons (car p-tail) known-type)
                                    known-types))
                   (let* ((position (car p-tail))
                          (method (car contenders))
                          (specl (nth position (method-specializers method)))
                          (type (funcall type-function
                                         (type-from-specializer specl))))
                     (multiple-value-bind (app-p maybe-app-p)
                         (specializer-applicable-using-type-p type known-type)
                       (flet ((determined-to-be (truth-value)
                                (if truth-value app-p (not maybe-app-p)))
                              (do-if (truth &optional implied)
                                (let ((ntype (if truth type `(not ,type))))
                                  (do-methods p-tail
                                    (cdr contenders)
                                    (if implied
                                        known-type
                                        (augment-type ntype known-type))
                                    (if truth
                                        (append winners `(,method))
                                        winners)
                                    known-types))))
                         (cond ((determined-to-be nil) (do-if nil t))
                               ((determined-to-be t)   (do-if t   t))
                               (t (funcall test-fun position type
                                           (do-if t) (do-if nil))))))))))
      (do-column precedence methods ()))))

(defun compute-secondary-dispatch-function (generic-function net &optional
                                            method-alist wrappers)
  (function-funcall (compute-secondary-dispatch-function1 generic-function net)
                    method-alist wrappers))

(defvar *eq-case-table-limit* 15)
(defvar *case-table-limit* 10)

(defun compute-mcase-parameters (case-list)
  (unless (eq t (caar (last case-list)))
    (error "The key for the last case arg to mcase was not T"))
  (let* ((eq-p (dolist (case case-list t)
                 (unless (or (eq (car case) t)
                             (symbolp (caar case)))
                   (return nil))))
         (len (1- (length case-list)))
         (type (cond ((= len 1)
                      :simple)
                     ((<= len
                          (if eq-p
                              *eq-case-table-limit*
                              *case-table-limit*))
                      :assoc)
                     (t
                      :hash-table))))
    (list eq-p type)))

(defmacro mlookup (key info default &optional eq-p type)
  (unless (or (eq eq-p t) (null eq-p))
    (error "Invalid eq-p argument"))
  (ecase type
    (:simple
     `(if (,(if eq-p 'eq 'eql) ,key (car ,info))
          (cdr ,info)
          ,default))
    (:assoc
     `(dolist (e ,info ,default)
        (when (,(if eq-p 'eq 'eql) (car e) ,key)
          (return (cdr e)))))
    (:hash-table
     `(gethash ,key ,info ,default))))

(defun net-test-converter (form)
  (if (atom form)
      (default-test-converter form)
      (case (car form)
        ((invoke-effective-method-function invoke-fast-method-call)
         '.call.)
        (methods
         '.methods.)
        (unordered-methods
         '.umethods.)
        (mcase
         `(mlookup ,(cadr form)
                   nil
                   nil
                   ,@(compute-mcase-parameters (cddr form))))
        (t (default-test-converter form)))))

(defun net-code-converter (form)
  (if (atom form)
      (default-code-converter form)
      (case (car form)
        ((methods unordered-methods)
         (let ((gensym (gensym)))
           (values gensym
                   (list gensym))))
        (mcase
         (let ((mp (compute-mcase-parameters (cddr form)))
               (gensym (gensym)) (default (gensym)))
           (values `(mlookup ,(cadr form) ,gensym ,default ,@mp)
                   (list gensym default))))
        (t
         (default-code-converter form)))))

(defun net-constant-converter (form generic-function)
  (or (let ((c (methods-converter form generic-function)))
        (when c (list c)))
      (if (atom form)
          (default-constant-converter form)
          (case (car form)
            (mcase
             (let* ((mp (compute-mcase-parameters (cddr form)))
                    (list (mapcar (lambda (clause)
                                    (let ((key (car clause))
                                          (meth (cadr clause)))
                                      (cons (if (consp key) (car key) key)
                                            (methods-converter
                                             meth generic-function))))
                                  (cddr form)))
                    (default (car (last list))))
               (list (list* :mcase mp (nbutlast list))
                     (cdr default))))
            (t
             (default-constant-converter form))))))

(defun methods-converter (form generic-function)
  (cond ((and (consp form) (eq (car form) 'methods))
         (cons '.methods.
               (get-effective-method-function1 generic-function (cadr form))))
        ((and (consp form) (eq (car form) 'unordered-methods))
         (default-secondary-dispatch-function generic-function))))

(defun convert-methods (constant method-alist wrappers)
  (if (and (consp constant)
           (eq (car constant) '.methods.))
      (funcall (cdr constant) method-alist wrappers)
      constant))

(defun convert-table (constant method-alist wrappers)
  (cond ((and (consp constant)
              (eq (car constant) :mcase))
         (let ((alist (mapcar (lambda (k+m)
                                (cons (car k+m)
                                      (convert-methods (cdr k+m)
                                                       method-alist
                                                       wrappers)))
                              (cddr constant)))
               (mp (cadr constant)))
           (ecase (cadr mp)
             (:simple
              (car alist))
             (:assoc
              alist)
             (:hash-table
              (let ((table (make-hash-table :test (if (car mp) 'eq 'eql))))
                (dolist (k+m alist)
                  (setf (gethash (car k+m) table) (cdr k+m)))
                table)))))))

(defun compute-secondary-dispatch-function1 (generic-function net
                                             &optional function-p)
  (cond
   ((and (eq (car net) 'methods) (not function-p))
    (get-effective-method-function1 generic-function (cadr net)))
   (t
    (let* ((name (generic-function-name generic-function))
           (arg-info (gf-arg-info generic-function))
           (metatypes (arg-info-metatypes arg-info))
           (applyp (arg-info-applyp arg-info))
           (fmc-arg-info (cons (length metatypes) applyp))
           (arglist (if function-p
                        (make-dfun-lambda-list metatypes applyp)
                        (make-fast-method-call-lambda-list metatypes applyp))))
      (multiple-value-bind (cfunction constants)
          (get-fun1 `(,(if function-p
                           'sb-kernel:instance-lambda
                           'lambda)
                      ,arglist
                      ,@(unless function-p
                          `((declare (ignore .pv-cell.
                                             .next-method-call.))))
                      (locally (declare #.*optimize-speed*)
                               (let ((emf ,net))
                                 ,(make-emf-call metatypes applyp 'emf))))
                    #'net-test-converter
                    #'net-code-converter
                    (lambda (form)
                      (net-constant-converter form generic-function)))
        (lambda (method-alist wrappers)
          (let* ((alist (list nil))
                 (alist-tail alist))
            (dolist (constant constants)
              (let* ((a (or (dolist (a alist nil)
                              (when (eq (car a) constant)
                                (return a)))
                            (cons constant
                                  (or (convert-table
                                       constant method-alist wrappers)
                                      (convert-methods
                                       constant method-alist wrappers)))))
                     (new (list a)))
                (setf (cdr alist-tail) new)
                (setf alist-tail new)))
            (let ((function (apply cfunction (mapcar #'cdr (cdr alist)))))
              (if function-p
                  function
                  (make-fast-method-call
                   :function (set-fun-name function `(sdfun-method ,name))
                   :arg-info fmc-arg-info))))))))))

(defvar *show-make-unordered-methods-emf-calls* nil)

(defun make-unordered-methods-emf (generic-function methods)
  (when *show-make-unordered-methods-emf-calls*
    (format t "~&make-unordered-methods-emf ~S~%"
            (generic-function-name generic-function)))
  (lambda (&rest args)
    (let* ((types (types-from-args generic-function args 'eql))
           (smethods (sort-applicable-methods generic-function
                                              methods
                                              types))
           (emf (get-effective-method-function generic-function smethods)))
      (invoke-emf emf args))))
\f
;;; The value returned by compute-discriminating-function is a function
;;; object. It is called a discriminating function because it is called
;;; when the generic function is called and its role is to discriminate
;;; on the arguments to the generic function and then call appropriate
;;; method functions.
;;;
;;; A discriminating function can only be called when it is installed as
;;; the funcallable instance function of the generic function for which
;;; it was computed.
;;;
;;; More precisely, if compute-discriminating-function is called with an
;;; argument <gf1>, and returns a result <df1>, that result must not be
;;; passed to apply or funcall directly. Rather, <df1> must be stored as
;;; the funcallable instance function of the same generic function <gf1>
;;; (using set-funcallable-instance-fun). Then the generic function
;;; can be passed to funcall or apply.
;;;
;;; An important exception is that methods on this generic function are
;;; permitted to return a function which itself ends up calling the value
;;; returned by a more specific method. This kind of `encapsulation' of
;;; discriminating function is critical to many uses of the MOP.
;;;
;;; As an example, the following canonical case is legal:
;;;
;;;   (defmethod compute-discriminating-function ((gf my-generic-function))
;;;     (let ((std (call-next-method)))
;;;       (lambda (arg)
;;;         (print (list 'call-to-gf gf arg))
;;;         (funcall std arg))))
;;;
;;; Because many discriminating functions would like to use a dynamic
;;; strategy in which the precise discriminating function changes with
;;; time it is important to specify how a discriminating function is
;;; permitted itself to change the funcallable instance function of the
;;; generic function.
;;;
;;; Discriminating functions may set the funcallable instance function
;;; of the generic function, but the new value must be generated by making
;;; a call to COMPUTE-DISCRIMINATING-FUNCTION. This is to ensure that any
;;; more specific methods which may have encapsulated the discriminating
;;; function will get a chance to encapsulate the new, inner discriminating
;;; function.
;;;
;;; This implies that if a discriminating function wants to modify itself
;;; it should first store some information in the generic function proper,
;;; and then call compute-discriminating-function. The appropriate method
;;; on compute-discriminating-function will see the information stored in
;;; the generic function and generate a discriminating function accordingly.
;;;
;;; The following is an example of a discriminating function which modifies
;;; itself in accordance with this protocol:
;;;
;;;   (defmethod compute-discriminating-function ((gf my-generic-function))
;;;     (lambda (arg)
;;;      (cond (<some condition>
;;;             <store some info in the generic function>
;;;             (set-funcallable-instance-fun
;;;               gf
;;;               (compute-discriminating-function gf))
;;;             (funcall gf arg))
;;;            (t
;;;             <call-a-method-of-gf>))))
;;;
;;; Whereas this code would not be legal:
;;;
;;;   (defmethod compute-discriminating-function ((gf my-generic-function))
;;;     (lambda (arg)
;;;      (cond (<some condition>
;;;             (set-funcallable-instance-fun
;;;               gf
;;;               (lambda (a) ..))
;;;             (funcall gf arg))
;;;            (t
;;;             <call-a-method-of-gf>))))
;;;
;;; NOTE:  All the examples above assume that all instances of the class
;;;     my-generic-function accept only one argument.

(defun slot-value-using-class-dfun (class object slotd)
  (declare (ignore class))
  (function-funcall (slot-definition-reader-function slotd) object))

(defun setf-slot-value-using-class-dfun (new-value class object slotd)
  (declare (ignore class))
  (function-funcall (slot-definition-writer-function slotd) new-value object))

(defun slot-boundp-using-class-dfun (class object slotd)
  (declare (ignore class))
  (function-funcall (slot-definition-boundp-function slotd) object))

(defmethod compute-discriminating-function ((gf standard-generic-function))
  (with-slots (dfun-state arg-info) gf
    (typecase dfun-state
      (null (let ((name (generic-function-name gf)))
              (when (eq name 'compute-applicable-methods)
                (update-all-c-a-m-gf-info gf))
              (cond ((eq name 'slot-value-using-class)
                     (update-slot-value-gf-info gf 'reader)
                     #'slot-value-using-class-dfun)
                    ((equal name '(setf slot-value-using-class))
                     (update-slot-value-gf-info gf 'writer)
                     #'setf-slot-value-using-class-dfun)
                    ((eq name 'slot-boundp-using-class)
                     (update-slot-value-gf-info gf 'boundp)
                     #'slot-boundp-using-class-dfun)
                    ((gf-precompute-dfun-and-emf-p arg-info)
                     (make-final-dfun gf))
                    (t
                     (make-initial-dfun gf)))))
      (function dfun-state)
      (cons (car dfun-state)))))

(defmethod update-gf-dfun ((class std-class) gf)
  (let ((*new-class* class)
        #|| (name (generic-function-name gf)) ||#
        (arg-info (gf-arg-info gf)))
    (cond #||
          ((eq name 'slot-value-using-class)
           (update-slot-value-gf-info gf 'reader))
          ((equal name '(setf slot-value-using-class))
           (update-slot-value-gf-info gf 'writer))
          ((eq name 'slot-boundp-using-class)
           (update-slot-value-gf-info gf 'boundp))
          ||#
          ((gf-precompute-dfun-and-emf-p arg-info)
           (multiple-value-bind (dfun cache info)
               (make-final-dfun-internal gf)
             (set-dfun gf dfun cache info) ; lest the cache be freed twice
             (update-dfun gf dfun cache info))))))
\f
(defmethod function-keywords ((method standard-method))
  (multiple-value-bind (nreq nopt keysp restp allow-other-keys-p keywords)
      (analyze-lambda-list (if (consp method)
                               (early-method-lambda-list method)
                               (method-lambda-list method)))
    (declare (ignore nreq nopt keysp restp))
    (values keywords allow-other-keys-p)))

(defun method-ll->generic-function-ll (ll)
  (multiple-value-bind
      (nreq nopt keysp restp allow-other-keys-p keywords keyword-parameters)
      (analyze-lambda-list ll)
    (declare (ignore nreq nopt keysp restp allow-other-keys-p keywords))
    (remove-if (lambda (s)
                 (or (memq s keyword-parameters)
                     (eq s '&allow-other-keys)))
               ll)))
\f
;;; This is based on the rules of method lambda list congruency defined in
;;; the spec. The lambda list it constructs is the pretty union of the
;;; lambda lists of all the methods. It doesn't take method applicability
;;; into account at all yet.
(defmethod generic-function-pretty-arglist
           ((generic-function standard-generic-function))
  (let ((methods (generic-function-methods generic-function)))
    (if methods
      (let ((arglist ()))
        ;; arglist is constructed from the GF's methods - maybe with
        ;; keys and rest stuff added
        (multiple-value-bind (required optional rest key allow-other-keys)
            (method-pretty-arglist (car methods))
          (dolist (m (cdr methods))
            (multiple-value-bind (method-key-keywords
                                  method-allow-other-keys
                                  method-key)
                (function-keywords m)
              ;; we've modified function-keywords to return what we want as
              ;;  the third value, no other change here.
              (declare (ignore method-key-keywords))
              (setq key (union key method-key))
              (setq allow-other-keys (or allow-other-keys
                                         method-allow-other-keys))))
          (when allow-other-keys
            (setq arglist '(&allow-other-keys)))
          (when key
            (setq arglist (nconc (list '&key) key arglist)))
          (when rest
            (setq arglist (nconc (list '&rest rest) arglist)))
          (when optional
            (setq arglist (nconc (list '&optional) optional arglist)))
          (nconc required arglist)))
      ;; otherwise we take the lambda-list from the GF directly, with no
      ;; other 'keys' added ...
      (let ((lambda-list (generic-function-lambda-list generic-function)))
        lambda-list))))

(defmethod method-pretty-arglist ((method standard-method))
  (let ((required ())
        (optional ())
        (rest nil)
        (key ())
        (allow-other-keys nil)
        (state 'required)
        (arglist (method-lambda-list method)))
    (dolist (arg arglist)
      (cond ((eq arg '&optional)         (setq state 'optional))
            ((eq arg '&rest)             (setq state 'rest))
            ((eq arg '&key)              (setq state 'key))
            ((eq arg '&allow-other-keys) (setq allow-other-keys t))
            ((memq arg lambda-list-keywords))
            (t
             (ecase state
               (required (push arg required))
               (optional (push arg optional))
               (key      (push arg key))
               (rest     (setq rest arg))))))
    (values (nreverse required)
            (nreverse optional)
            rest
            (nreverse key)
            allow-other-keys)))