;;;; 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") #| The CommonLoops evaluator is meta-circular. Most of the code in PCL is methods on generic functions, including most of the code that actually implements generic functions and method lookup. So, we have a classic bootstrapping problem. The solution to this is to first get a cheap implementation of generic functions running, these are called early generic functions. These early generic functions and the corresponding early methods and early method lookup are used to get enough of the system running that it is possible to create real generic functions and methods and implement real method lookup. At that point (done in the file FIXUP) the function fix-early-generic-functions is called to convert all the early generic functions to real generic functions. The cheap generic functions are built using the same funcallable-instance objects real generic-functions are made out of. This means that as PCL is being bootstrapped, the cheap generic function objects which are being created are the same objects which will later be real generic functions. This is good because: - we don't cons garbage structure, and - we can keep pointers to the cheap generic function objects during booting because those pointers will still point to the right object after the generic functions are all fixed up. This file defines the defmethod macro and the mechanism used to expand it. This includes the mechanism for processing the body of a method. DEFMETHOD basically expands into a call to LOAD-DEFMETHOD, which basically calls ADD-METHOD to add the method to the generic-function. These expansions can be loaded either during bootstrapping or when PCL is fully up and running. An important effect of this arrangement is it means we can compile files with defmethod forms in them in a completely running PCL, but then load those files back in during bootstrapping. This makes development easier. It also means there is only one set of code for processing defmethod. Bootstrapping works by being sure to have load-method be careful to call only primitives which work during bootstrapping. |# ;;; FIXME: SB-KERNEL::PCL-CHECK-WRAPPER-VALIDITY-HOOK shouldn't be a ;;; separate function. Instead, we should define a simple placeholder ;;; version of SB-PCL:CHECK-WRAPPER-VALIDITY where ;;; SB-KERNEL::PCL-CHECK-WRAPPER-VALIDITY is defined now, then just ;;; let the later real PCL DEFUN of SB-PCL:CHECK-WRAPPER-VALIDITY ;;; overwrite it. (setf (symbol-function 'sb-kernel::pcl-check-wrapper-validity-hook) #'check-wrapper-validity) (declaim (notinline make-a-method add-named-method ensure-generic-function-using-class add-method remove-method)) (defvar *early-functions* '((make-a-method early-make-a-method real-make-a-method) (add-named-method early-add-named-method real-add-named-method) )) ;;; For each of the early functions, arrange to have it point to its early ;;; definition. Do this in a way that makes sure that if we redefine one ;;; of the early definitions the redefinition will take effect. This makes ;;; development easier. ;;; ;;; The function which generates the redirection closure is pulled out into ;;; a separate piece of code because of a bug in ExCL which causes this not ;;; to work if it is inlined. ;;; FIXME: We no longer need to worry about ExCL now, so we could unscrew this. (eval-when (:load-toplevel :execute) (defun redirect-early-function-internal (real early) (setf (gdefinition real) (set-function-name #'(lambda (&rest args) (apply (the function (symbol-function early)) args)) real))) (dolist (fns *early-functions*) (let ((name (car fns)) (early-name (cadr fns))) (redirect-early-function-internal name early-name))) ) ; EVAL-WHEN ;;; *GENERIC-FUNCTION-FIXUPS* is used by fix-early-generic-functions to ;;; convert the few functions in the bootstrap which are supposed to be ;;; generic functions but can't be early on. (defvar *generic-function-fixups* '((add-method ((generic-function method) ;lambda-list (standard-generic-function method) ;specializers real-add-method)) ;method-function (remove-method ((generic-function method) (standard-generic-function method) real-remove-method)) (get-method ((generic-function qualifiers specializers &optional (errorp t)) (standard-generic-function t t) real-get-method)) (ensure-generic-function-using-class ((generic-function function-name &key generic-function-class environment &allow-other-keys) (generic-function t) real-ensure-gf-using-class--generic-function) ((generic-function function-name &key generic-function-class environment &allow-other-keys) (null t) real-ensure-gf-using-class--null)) (make-method-lambda ((proto-generic-function proto-method lambda-expression environment) (standard-generic-function standard-method t t) real-make-method-lambda)) (make-method-initargs-form ((proto-generic-function proto-method lambda-expression lambda-list environment) (standard-generic-function standard-method t t t) real-make-method-initargs-form)) (compute-effective-method ((generic-function combin applicable-methods) (generic-function standard-method-combination t) standard-compute-effective-method)))) (defmacro defgeneric (function-name lambda-list &body options) (expand-defgeneric function-name lambda-list options)) (defun expand-defgeneric (function-name lambda-list options) (when (listp function-name) (do-standard-defsetf-1 (sb-int:function-name-block-name function-name))) (let ((initargs ()) (methods ())) (flet ((duplicate-option (name) (error 'sb-kernel:simple-program-error :format-control "The option ~S appears more than once." :format-arguments (list name))) (expand-method-definition (qab) ; QAB = qualifiers, arglist, body (let* ((arglist-pos (position-if #'listp qab)) (arglist (elt qab arglist-pos)) (qualifiers (subseq qab 0 arglist-pos)) (body (nthcdr (1+ arglist-pos) qab))) (when (not (equal (cadr (getf initargs :method-combination)) qualifiers)) (error "bad method specification in DEFGENERIC ~A~%~ -- qualifier mismatch for lambda list ~A" function-name arglist)) `(defmethod ,function-name ,@qualifiers ,arglist ,@body)))) (macrolet ((initarg (key) `(getf initargs ,key))) (dolist (option options) (let ((car-option (car option))) (case car-option (declare (push (cdr option) (initarg :declarations))) ((:argument-precedence-order :method-combination) (if (initarg car-option) (duplicate-option car-option) (setf (initarg car-option) `',(cdr option)))) ((:documentation :generic-function-class :method-class) (unless (sb-int:proper-list-of-length-p option 2) (error "bad list length for ~S" option)) (if (initarg car-option) (duplicate-option car-option) (setf (initarg car-option) `',(cadr option)))) (:method (push (cdr option) methods)) (t ;; ANSI requires that unsupported things must get a ;; PROGRAM-ERROR. (error 'sb-kernel:simple-program-error :format-control "unsupported option ~S" :format-arguments (list option)))))) (when (initarg :declarations) (setf (initarg :declarations) `',(initarg :declarations)))) `(progn (eval-when (:compile-toplevel :load-toplevel :execute) (compile-or-load-defgeneric ',function-name)) ,(make-top-level-form `(defgeneric ,function-name) *defgeneric-times* `(load-defgeneric ',function-name ',lambda-list ,@initargs)) ,@(mapcar #'expand-method-definition methods) `,(function ,function-name))))) (defun compile-or-load-defgeneric (function-name) (sb-kernel:proclaim-as-function-name function-name) (sb-kernel:note-name-defined function-name :function) (unless (eq (sb-int:info :function :where-from function-name) :declared) (setf (sb-int:info :function :where-from function-name) :defined) (setf (sb-int:info :function :type function-name) (sb-kernel:specifier-type 'function)))) (defun load-defgeneric (function-name lambda-list &rest initargs) (when (listp function-name) (do-standard-defsetf-1 (cadr function-name))) (when (fboundp function-name) (sb-kernel::style-warn "redefining ~S in DEFGENERIC" function-name)) (apply #'ensure-generic-function function-name :lambda-list lambda-list :definition-source `((defgeneric ,function-name) ,*load-truename*) initargs)) (defmacro defmethod (&rest args &environment env) (declare (arglist name {method-qualifier}* specialized-lambda-list &body body)) (multiple-value-bind (name qualifiers lambda-list body) (parse-defmethod args) (multiple-value-bind (proto-gf proto-method) (prototypes-for-make-method-lambda name) (expand-defmethod name proto-gf proto-method qualifiers lambda-list body env)))) (defun prototypes-for-make-method-lambda (name) (if (not (eq *boot-state* 'complete)) (values nil nil) (let ((gf? (and (gboundp name) (gdefinition name)))) (if (or (null gf?) (not (generic-function-p gf?))) (values (class-prototype (find-class 'standard-generic-function)) (class-prototype (find-class 'standard-method))) (values gf? (class-prototype (or (generic-function-method-class gf?) (find-class 'standard-method)))))))) ;;; takes a name which is either a generic function name or a list specifying ;;; a setf generic function (like: (SETF )). Returns ;;; the prototype instance of the method-class for that generic function. ;;; ;;; If there is no generic function by that name, this returns the default ;;; value, the prototype instance of the class STANDARD-METHOD. This default ;;; value is also returned if the spec names an ordinary function or even a ;;; macro. In effect, this leaves the signalling of the appropriate error ;;; until load time. ;;; ;;; Note: During bootstrapping, this function is allowed to return NIL. (defun method-prototype-for-gf (name) (let ((gf? (and (gboundp name) (gdefinition name)))) (cond ((neq *boot-state* 'complete) nil) ((or (null gf?) (not (generic-function-p gf?))) ; Someone else MIGHT ; error at load time. (class-prototype (find-class 'standard-method))) (t (class-prototype (or (generic-function-method-class gf?) (find-class 'standard-method))))))) (defvar *optimize-asv-funcall-p* nil) (defvar *asv-readers*) (defvar *asv-writers*) (defvar *asv-boundps*) (defun expand-defmethod (name proto-gf proto-method qualifiers lambda-list body env) (when (listp name) (do-standard-defsetf-1 (cadr name))) (let ((*make-instance-function-keys* nil) (*optimize-asv-funcall-p* t) (*asv-readers* nil) (*asv-writers* nil) (*asv-boundps* nil)) (declare (special *make-instance-function-keys*)) (multiple-value-bind (method-lambda unspecialized-lambda-list specializers) (add-method-declarations name qualifiers lambda-list body env) (multiple-value-bind (method-function-lambda initargs) (make-method-lambda proto-gf proto-method method-lambda env) (let ((initargs-form (make-method-initargs-form proto-gf proto-method method-function-lambda initargs env))) `(progn ;; Note: We could DECLAIM the type of the generic ;; function here, since ANSI specifies that we create it ;; if it does not exist. However, I chose not to, because ;; I think it's more useful to support a style of ;; programming where every generic function has an ;; explicit DEFGENERIC and any typos in DEFMETHODs are ;; warned about. Otherwise ;; (DEFGENERIC FOO-BAR-BLETCH ((X T))) ;; (DEFMETHOD FOO-BAR-BLETCH ((X HASH-TABLE)) ..) ;; (DEFMETHOD FOO-BRA-BLETCH ((X SIMPLE-VECTOR)) ..) ;; (DEFMETHOD FOO-BAR-BLETCH ((X VECTOR)) ..) ;; (DEFMETHOD FOO-BAR-BLETCH ((X ARRAY)) ..) ;; (DEFMETHOD FOO-BAR-BLETCH ((X LIST)) ..) ;; compiles without raising an error and runs without ;; raising an error (since SIMPLE-VECTOR cases fall ;; through to VECTOR) but still doesn't do what was ;; intended. I hate that kind of bug (code which silently ;; gives the wrong answer), so we don't do a DECLAIM ;; here. -- WHN 20000229 ,@(when *make-instance-function-keys* `((get-make-instance-functions ',*make-instance-function-keys*))) ,@(when (or *asv-readers* *asv-writers* *asv-boundps*) `((initialize-internal-slot-gfs* ',*asv-readers* ',*asv-writers* ',*asv-boundps*))) ,(make-defmethod-form name qualifiers specializers unspecialized-lambda-list (if proto-method (class-name (class-of proto-method)) 'standard-method) initargs-form (getf (getf initargs ':plist) ':pv-table-symbol)))))))) (defun interned-symbol-p (x) (and (symbolp x) (symbol-package x))) (defun make-defmethod-form (name qualifiers specializers unspecialized-lambda-list method-class-name initargs-form &optional pv-table-symbol) (let (fn fn-lambda) (if (and (interned-symbol-p (sb-int:function-name-block-name name)) (every #'interned-symbol-p qualifiers) (every #'(lambda (s) (if (consp s) (and (eq (car s) 'eql) (constantp (cadr s)) (let ((sv (eval (cadr s)))) (or (interned-symbol-p sv) (integerp sv) (and (characterp sv) (standard-char-p sv))))) (interned-symbol-p s))) specializers) (consp initargs-form) (eq (car initargs-form) 'list*) (memq (cadr initargs-form) '(:function :fast-function)) (consp (setq fn (caddr initargs-form))) (eq (car fn) 'function) (consp (setq fn-lambda (cadr fn))) (eq (car fn-lambda) 'lambda)) (let* ((specls (mapcar (lambda (specl) (if (consp specl) `(,(car specl) ,(eval (cadr specl))) specl)) specializers)) (mname `(,(if (eq (cadr initargs-form) ':function) 'method 'fast-method) ,name ,@qualifiers ,specls)) (mname-sym (intern (let ((*print-pretty* nil)) (format nil "~S" mname))))) `(eval-when ,*defmethod-times* (defun ,mname-sym ,(cadr fn-lambda) ,@(cddr fn-lambda)) ,(make-defmethod-form-internal name qualifiers `',specls unspecialized-lambda-list method-class-name `(list* ,(cadr initargs-form) #',mname-sym ,@(cdddr initargs-form)) pv-table-symbol))) (make-top-level-form `(defmethod ,name ,@qualifiers ,specializers) *defmethod-times* (make-defmethod-form-internal name qualifiers `(list ,@(mapcar #'(lambda (specializer) (if (consp specializer) ``(,',(car specializer) ,,(cadr specializer)) `',specializer)) specializers)) unspecialized-lambda-list method-class-name initargs-form pv-table-symbol))))) (defun make-defmethod-form-internal (name qualifiers specializers-form unspecialized-lambda-list method-class-name initargs-form &optional pv-table-symbol) `(load-defmethod ',method-class-name ',name ',qualifiers ,specializers-form ',unspecialized-lambda-list ,initargs-form ;; Paper over a bug in KCL by passing the cache-symbol here in addition to ;; in the list. FIXME: We should no longer need to do this. ',pv-table-symbol)) (defmacro make-method-function (method-lambda &environment env) (make-method-function-internal method-lambda env)) (defun make-method-function-internal (method-lambda &optional env) (multiple-value-bind (proto-gf proto-method) (prototypes-for-make-method-lambda nil) (multiple-value-bind (method-function-lambda initargs) (make-method-lambda proto-gf proto-method method-lambda env) (make-method-initargs-form proto-gf proto-method method-function-lambda initargs env)))) (defun add-method-declarations (name qualifiers lambda-list body env) (multiple-value-bind (parameters unspecialized-lambda-list specializers) (parse-specialized-lambda-list lambda-list) (declare (ignore parameters)) (multiple-value-bind (documentation declarations real-body) (extract-declarations body env) (values `(lambda ,unspecialized-lambda-list ,@(when documentation `(,documentation)) (declare (method-name ,(list name qualifiers specializers))) (declare (method-lambda-list ,@lambda-list)) ,@declarations ,@real-body) unspecialized-lambda-list specializers)))) (defun real-make-method-initargs-form (proto-gf proto-method method-lambda initargs env) (declare (ignore proto-gf proto-method)) (unless (and (consp method-lambda) (eq (car method-lambda) 'lambda)) (error "The METHOD-LAMBDA argument to MAKE-METHOD-FUNCTION, ~S,~ is not a lambda form." method-lambda)) (make-method-initargs-form-internal method-lambda initargs env)) (unless (fboundp 'make-method-initargs-form) (setf (gdefinition 'make-method-initargs-form) (symbol-function 'real-make-method-initargs-form))) (defun real-make-method-lambda (proto-gf proto-method method-lambda env) (declare (ignore proto-gf proto-method)) (make-method-lambda-internal method-lambda env)) (defun make-method-lambda-internal (method-lambda &optional env) (unless (and (consp method-lambda) (eq (car method-lambda) 'lambda)) (error "The METHOD-LAMBDA argument to MAKE-METHOD-LAMBDA, ~S,~ is not a lambda form." method-lambda)) (multiple-value-bind (documentation declarations real-body) (extract-declarations (cddr method-lambda) env) (let* ((name-decl (get-declaration 'method-name declarations)) (sll-decl (get-declaration 'method-lambda-list declarations)) (method-name (when (consp name-decl) (car name-decl))) (generic-function-name (when method-name (car method-name))) (specialized-lambda-list (or sll-decl (cadr method-lambda)))) (multiple-value-bind (parameters lambda-list specializers) (parse-specialized-lambda-list specialized-lambda-list) (let* ((required-parameters (mapcar #'(lambda (r s) (declare (ignore s)) r) parameters specializers)) (slots (mapcar #'list required-parameters)) (calls (list nil)) (parameters-to-reference (make-parameter-references specialized-lambda-list required-parameters declarations method-name specializers)) (class-declarations `(declare ;; FIXME: Are these (DECLARE (SB-PCL::CLASS FOO BAR)) ;; declarations used for anything any more? ,@(remove nil (mapcar (lambda (a s) (and (symbolp s) (neq s 't) `(class ,a ,s))) parameters specializers)) ;; These TYPE declarations weren't in the original ;; PCL code, but Python likes them a lot. (We're ;; telling the compiler about our knowledge of ;; specialized argument types so that it can avoid ;; run-time type overhead, which can be a big win ;; for Python.) ,@(mapcar (lambda (a s) (cond ((and (consp s) (eql (car s) 'eql)) ;; KLUDGE: ANSI, in its wisdom, says ;; that EQL-SPECIALIZER-FORMs in EQL ;; specializers are evaluated at ;; DEFMETHOD expansion time. Thus, ;; although one might think that in ;; (DEFMETHOD FOO ((X PACKAGE) ;; (Y (EQL 12)) ;; ..)) ;; the PACKAGE and (EQL 12) forms are ;; both parallel type names, they're ;; not, as is made clear when you do ;; (DEFMETHOD FOO ((X PACKAGE) ;; (Y (EQL 'BAR))) ;; ..) ;; where Y needs to be a symbol ;; named "BAR", not some cons made by ;; (CONS 'QUOTE 'BAR). I.e. when ;; the EQL-SPECIALIZER-FORM is (EQL 'X), ;; it requires an argument to be of ;; type (EQL X). It'd be easy to transform ;; one to the other, but it'd be somewhat ;; messier to do so while ensuring that ;; the EQL-SPECIALIZER-FORM is only ;; EVAL'd once. (The new code wouldn't ;; be messy, but it'd require a big ;; transformation of the old code.) ;; So instead we punt. -- WHN 20000610 '(ignorable)) ((not (eq *boot-state* 'complete)) ;; KLUDGE: PCL, in its wisdom, ;; sometimes calls methods with ;; types which don't match their ;; specializers. (Specifically, it calls ;; ENSURE-CLASS-USING-CLASS (T NULL) ;; with a non-NULL second argument.) ;; Hopefully it only does this kind ;; of weirdness when bootstrapping.. ;; -- WHN 20000610 '(ignorable)) (t ;; Otherwise, we can make Python ;; very happy. `(type ,s ,a)))) parameters specializers))) (method-lambda ;; Remove the documentation string and insert the ;; appropriate class declarations. The documentation ;; string is removed to make it easy for us to insert ;; new declarations later, they will just go after the ;; cadr of the method lambda. The class declarations ;; are inserted to communicate the class of the method's ;; arguments to the code walk. `(lambda ,lambda-list ,class-declarations ,@declarations (declare (ignorable ,@parameters-to-reference)) ;; FIXME: should become FUNCTION-NAME-BLOCK-NAME (block ,(if (listp generic-function-name) (cadr generic-function-name) generic-function-name) ,@real-body))) (constant-value-p (and (null (cdr real-body)) (constantp (car real-body)))) (constant-value (and constant-value-p (eval (car real-body)))) ;; FIXME: This can become a bare AND (no IF), just like ;; the expression for CONSTANT-VALUE just above. (plist (if (and constant-value-p (or (typep constant-value '(or number character)) (and (symbolp constant-value) (symbol-package constant-value)))) (list :constant-value constant-value) ())) (applyp (dolist (p lambda-list nil) (cond ((memq p '(&optional &rest &key)) (return t)) ((eq p '&aux) (return nil)))))) (multiple-value-bind (walked-lambda call-next-method-p closurep next-method-p-p) (walk-method-lambda method-lambda required-parameters env slots calls) (multiple-value-bind (ignore walked-declarations walked-lambda-body) (extract-declarations (cddr walked-lambda)) (declare (ignore ignore)) (when (or next-method-p-p call-next-method-p) (setq plist (list* :needs-next-methods-p 't plist))) (when (some #'cdr slots) (multiple-value-bind (slot-name-lists call-list) (slot-name-lists-from-slots slots calls) (let ((pv-table-symbol (make-symbol "pv-table"))) (setq plist `(,@(when slot-name-lists `(:slot-name-lists ,slot-name-lists)) ,@(when call-list `(:call-list ,call-list)) :pv-table-symbol ,pv-table-symbol ,@plist)) (setq walked-lambda-body `((pv-binding (,required-parameters ,slot-name-lists ,pv-table-symbol) ,@walked-lambda-body)))))) (when (and (memq '&key lambda-list) (not (memq '&allow-other-keys lambda-list))) (let ((aux (memq '&aux lambda-list))) (setq lambda-list (nconc (ldiff lambda-list aux) (list '&allow-other-keys) aux)))) (values `(lambda (.method-args. .next-methods.) (simple-lexical-method-functions (,lambda-list .method-args. .next-methods. :call-next-method-p ,call-next-method-p :next-method-p-p ,next-method-p-p :closurep ,closurep :applyp ,applyp) ,@walked-declarations ,@walked-lambda-body)) `(,@(when plist `(:plist ,plist)) ,@(when documentation `(:documentation ,documentation))))))))))) (unless (fboundp 'make-method-lambda) (setf (gdefinition 'make-method-lambda) (symbol-function 'real-make-method-lambda))) (defmacro simple-lexical-method-functions ((lambda-list method-args next-methods &rest lmf-options) &body body) `(progn ,method-args ,next-methods (bind-simple-lexical-method-macros (,method-args ,next-methods) (bind-lexical-method-functions (,@lmf-options) (bind-args (,lambda-list ,method-args) ,@body))))) (defmacro fast-lexical-method-functions ((lambda-list next-method-call args rest-arg &rest lmf-options) &body body) `(bind-fast-lexical-method-macros (,args ,rest-arg ,next-method-call) (bind-lexical-method-functions (,@lmf-options) (bind-args (,(nthcdr (length args) lambda-list) ,rest-arg) ,@body)))) (defmacro bind-simple-lexical-method-macros ((method-args next-methods) &body body) `(macrolet ((call-next-method-bind (&body body) `(let ((.next-method. (car ,',next-methods)) (,',next-methods (cdr ,',next-methods))) .next-method. ,',next-methods ,@body)) (call-next-method-body (cnm-args) `(if .next-method. (funcall (if (std-instance-p .next-method.) (method-function .next-method.) .next-method.) ; for early methods (or ,cnm-args ,',method-args) ,',next-methods) (error "no next method"))) (next-method-p-body () `(not (null .next-method.)))) ,@body)) (defstruct method-call (function #'identity :type function) call-method-args) #-sb-fluid (declaim (sb-ext:freeze-type method-call)) (defmacro invoke-method-call1 (function args cm-args) `(let ((.function. ,function) (.args. ,args) (.cm-args. ,cm-args)) (if (and .cm-args. (null (cdr .cm-args.))) (funcall .function. .args. (car .cm-args.)) (apply .function. .args. .cm-args.)))) (defmacro invoke-method-call (method-call restp &rest required-args+rest-arg) `(invoke-method-call1 (method-call-function ,method-call) ,(if restp `(list* ,@required-args+rest-arg) `(list ,@required-args+rest-arg)) (method-call-call-method-args ,method-call))) (defstruct fast-method-call (function #'identity :type function) pv-cell next-method-call arg-info) #-sb-fluid (declaim (sb-ext:freeze-type fast-method-call)) (defmacro fmc-funcall (fn pv-cell next-method-call &rest args) `(funcall ,fn ,pv-cell ,next-method-call ,@args)) (defmacro invoke-fast-method-call (method-call &rest required-args+rest-arg) `(fmc-funcall (fast-method-call-function ,method-call) (fast-method-call-pv-cell ,method-call) (fast-method-call-next-method-call ,method-call) ,@required-args+rest-arg)) (defstruct fast-instance-boundp (index 0 :type fixnum)) #-sb-fluid (declaim (sb-ext:freeze-type fast-instance-boundp)) (eval-when (:compile-toplevel :load-toplevel :execute) (defvar *allow-emf-call-tracing-p* nil) (defvar *enable-emf-call-tracing-p* #-testing nil #+testing t) ) ; EVAL-WHEN ;;;; effective method functions (defvar *emf-call-trace-size* 200) (defvar *emf-call-trace* nil) (defvar *emf-call-trace-index* 0) ;;; This function was in the CMU CL version of PCL (ca Debian 2.4.8) ;;; without explanation. It appears to be intended for debugging, so ;;; it might be useful someday, so I haven't deleted it. ;;; But it isn't documented and isn't used for anything now, so ;;; I've conditionalized it out of the base system. -- WHN 19991213 #+sb-show (defun show-emf-call-trace () (when *emf-call-trace* (let ((j *emf-call-trace-index*) (*enable-emf-call-tracing-p* nil)) (format t "~&(The oldest entries are printed first)~%") (dotimes-fixnum (i *emf-call-trace-size*) (let ((ct (aref *emf-call-trace* j))) (when ct (print ct))) (incf j) (when (= j *emf-call-trace-size*) (setq j 0)))))) (defun trace-emf-call-internal (emf format args) (unless *emf-call-trace* (setq *emf-call-trace* (make-array *emf-call-trace-size*))) (setf (aref *emf-call-trace* *emf-call-trace-index*) (list* emf format args)) (incf *emf-call-trace-index*) (when (= *emf-call-trace-index* *emf-call-trace-size*) (setq *emf-call-trace-index* 0))) (defmacro trace-emf-call (emf format args) (when *allow-emf-call-tracing-p* `(when *enable-emf-call-tracing-p* (trace-emf-call-internal ,emf ,format ,args)))) (defmacro invoke-effective-method-function-fast (emf restp &rest required-args+rest-arg) `(progn (trace-emf-call ,emf ,restp (list ,@required-args+rest-arg)) (invoke-fast-method-call ,emf ,@required-args+rest-arg))) (defmacro invoke-effective-method-function (emf restp &rest required-args+rest-arg) (unless (constantp restp) (error "The RESTP argument is not constant.")) (setq restp (eval restp)) `(progn (trace-emf-call ,emf ,restp (list ,@required-args+rest-arg)) (cond ((typep ,emf 'fast-method-call) (invoke-fast-method-call ,emf ,@required-args+rest-arg)) ,@(when (and (null restp) (= 1 (length required-args+rest-arg))) `(((typep ,emf 'fixnum) (let* ((.slots. (get-slots-or-nil ,(car required-args+rest-arg))) (value (when .slots. (%instance-ref .slots. ,emf)))) (if (eq value ',*slot-unbound*) (slot-unbound-internal ,(car required-args+rest-arg) ,emf) value))))) ,@(when (and (null restp) (= 2 (length required-args+rest-arg))) `(((typep ,emf 'fixnum) (let ((.new-value. ,(car required-args+rest-arg)) (.slots. (get-slots-or-nil ,(car required-args+rest-arg)))) (when .slots. ; just to avoid compiler warnings (setf (%instance-ref .slots. ,emf) .new-value.)))))) #|| ,@(when (and (null restp) (= 1 (length required-args+rest-arg))) `(((typep ,emf 'fast-instance-boundp) (let ((.slots. (get-slots-or-nil ,(car required-args+rest-arg)))) (and .slots. (not (eq (%instance-ref .slots. (fast-instance-boundp-index ,emf)) ',*slot-unbound*))))))) ||# (t (etypecase ,emf (method-call (invoke-method-call ,emf ,restp ,@required-args+rest-arg)) (function ,(if restp `(apply (the function ,emf) ,@required-args+rest-arg) `(funcall (the function ,emf) ,@required-args+rest-arg)))))))) (defun invoke-emf (emf args) (trace-emf-call emf t args) (etypecase emf (fast-method-call (let* ((arg-info (fast-method-call-arg-info emf)) (restp (cdr arg-info)) (nreq (car arg-info))) (if restp (let* ((rest-args (nthcdr nreq args)) (req-args (ldiff args rest-args))) (apply (fast-method-call-function emf) (fast-method-call-pv-cell emf) (fast-method-call-next-method-call emf) (nconc req-args (list rest-args)))) (cond ((null args) (if (eql nreq 0) (invoke-fast-method-call emf) (error "wrong number of args"))) ((null (cdr args)) (if (eql nreq 1) (invoke-fast-method-call emf (car args)) (error "wrong number of args"))) ((null (cddr args)) (if (eql nreq 2) (invoke-fast-method-call emf (car args) (cadr args)) (error "wrong number of args"))) (t (apply (fast-method-call-function emf) (fast-method-call-pv-cell emf) (fast-method-call-next-method-call emf) args)))))) (method-call (apply (method-call-function emf) args (method-call-call-method-args emf))) (fixnum (cond ((null args) (error "1 or 2 args were expected.")) ((null (cdr args)) (let ((value (%instance-ref (get-slots (car args)) emf))) (if (eq value *slot-unbound*) (slot-unbound-internal (car args) emf) value))) ((null (cddr args)) (setf (%instance-ref (get-slots (cadr args)) emf) (car args))) (t (error "1 or 2 args were expected.")))) (fast-instance-boundp (if (or (null args) (cdr args)) (error "1 arg was expected.") (not (eq (%instance-ref (get-slots (car args)) (fast-instance-boundp-index emf)) *slot-unbound*)))) (function (apply emf args)))) ;; KLUDGE: A comment from the original PCL said "This can be improved alot." (defun gf-make-function-from-emf (gf emf) (etypecase emf (fast-method-call (let* ((arg-info (gf-arg-info gf)) (nreq (arg-info-number-required arg-info)) (restp (arg-info-applyp arg-info))) #'(lambda (&rest args) (trace-emf-call emf t args) (apply (fast-method-call-function emf) (fast-method-call-pv-cell emf) (fast-method-call-next-method-call emf) (if restp (let* ((rest-args (nthcdr nreq args)) (req-args (ldiff args rest-args))) (nconc req-args rest-args)) args))))) (method-call #'(lambda (&rest args) (trace-emf-call emf t args) (apply (method-call-function emf) args (method-call-call-method-args emf)))) (function emf))) (defmacro bind-fast-lexical-method-macros ((args rest-arg next-method-call) &body body) `(macrolet ((call-next-method-bind (&body body) `(let () ,@body)) (call-next-method-body (cnm-args) `(if ,',next-method-call ,(if (and (null ',rest-arg) (consp cnm-args) (eq (car cnm-args) 'list)) `(invoke-effective-method-function ,',next-method-call nil ,@(cdr cnm-args)) (let ((call `(invoke-effective-method-function ,',next-method-call ,',(not (null rest-arg)) ,@',args ,@',(when rest-arg `(,rest-arg))))) `(if ,cnm-args (bind-args ((,@',args ,@',(when rest-arg `(&rest ,rest-arg))) ,cnm-args) ,call) ,call))) (error "no next method"))) (next-method-p-body () `(not (null ,',next-method-call)))) ,@body)) (defmacro bind-lexical-method-functions ((&key call-next-method-p next-method-p-p closurep applyp) &body body) (cond ((and (null call-next-method-p) (null next-method-p-p) (null closurep) (null applyp)) `(let () ,@body)) ((and (null closurep) (null applyp)) ;; OK to use MACROLET, and all args are mandatory ;; (else APPLYP would be true). `(call-next-method-bind (macrolet ((call-next-method (&rest cnm-args) `(call-next-method-body ,(when cnm-args `(list ,@cnm-args)))) (next-method-p () `(next-method-p-body))) ,@body))) (t `(call-next-method-bind (flet (,@(and call-next-method-p '((call-next-method (&rest cnm-args) (call-next-method-body cnm-args)))) ,@(and next-method-p-p '((next-method-p () (next-method-p-body))))) ,@body))))) (defmacro bind-args ((lambda-list args) &body body) (let ((args-tail '.args-tail.) (key '.key.) (state 'required)) (flet ((process-var (var) (if (memq var lambda-list-keywords) (progn (case var (&optional (setq state 'optional)) (&key (setq state 'key)) (&allow-other-keys) (&rest (setq state 'rest)) (&aux (setq state 'aux)) (otherwise (error "encountered the non-standard lambda list keyword ~S" var))) nil) (case state (required `((,var (pop ,args-tail)))) (optional (cond ((not (consp var)) `((,var (when ,args-tail (pop ,args-tail))))) ((null (cddr var)) `((,(car var) (if ,args-tail (pop ,args-tail) ,(cadr var))))) (t `((,(caddr var) ,args-tail) (,(car var) (if ,args-tail (pop ,args-tail) ,(cadr var))))))) (rest `((,var ,args-tail))) (key (cond ((not (consp var)) `((,var (get-key-arg ,(make-keyword var) ,args-tail)))) ((null (cddr var)) (multiple-value-bind (keyword variable) (if (consp (car var)) (values (caar var) (cadar var)) (values (make-keyword (car var)) (car var))) `((,key (get-key-arg1 ,keyword ,args-tail)) (,variable (if (consp ,key) (car ,key) ,(cadr var)))))) (t (multiple-value-bind (keyword variable) (if (consp (car var)) (values (caar var) (cadar var)) (values (make-keyword (car var)) (car var))) `((,key (get-key-arg1 ,keyword ,args-tail)) (,(caddr var) ,key) (,variable (if (consp ,key) (car ,key) ,(cadr var)))))))) (aux `(,var)))))) (let ((bindings (mapcan #'process-var lambda-list))) `(let* ((,args-tail ,args) ,@bindings) (declare (ignorable ,args-tail)) ,@body))))) (defun get-key-arg (keyword list) (loop (when (atom list) (return nil)) (when (eq (car list) keyword) (return (cadr list))) (setq list (cddr list)))) (defun get-key-arg1 (keyword list) (loop (when (atom list) (return nil)) (when (eq (car list) keyword) (return (cdr list))) (setq list (cddr list)))) (defun walk-method-lambda (method-lambda required-parameters env slots calls) (let ((call-next-method-p nil) ; flag indicating that CALL-NEXT-METHOD ; should be in the method definition (closurep nil) ; flag indicating that #'CALL-NEXT-METHOD ; was seen in the body of a method (next-method-p-p nil)) ; flag indicating that NEXT-METHOD-P ; should be in the method definition (flet ((walk-function (form context env) (cond ((not (eq context ':eval)) form) ;; FIXME: Jumping to a conclusion from the way it's used ;; above, perhaps CONTEXT should be called SITUATION ;; (after the term used in the ANSI specification of ;; EVAL-WHEN) and given modern ANSI keyword values ;; like :LOAD-TOPLEVEL. ((not (listp form)) form) ((eq (car form) 'call-next-method) (setq call-next-method-p 't) form) ((eq (car form) 'next-method-p) (setq next-method-p-p 't) form) ((and (eq (car form) 'function) (cond ((eq (cadr form) 'call-next-method) (setq call-next-method-p 't) (setq closurep t) form) ((eq (cadr form) 'next-method-p) (setq next-method-p-p 't) (setq closurep t) form) (t nil)))) (;; FIXME: should be MEMQ or FIND :TEST #'EQ (and (or (eq (car form) 'slot-value) (eq (car form) 'set-slot-value) (eq (car form) 'slot-boundp)) (constantp (caddr form))) (let ((parameter (can-optimize-access form required-parameters env))) ;; FIXME: could be ;; (LET ((FUN (ECASE (CAR FORM) ..))) ;; (FUNCALL FUN SLOTS PARAMETER FORM)) (ecase (car form) (slot-value (optimize-slot-value slots parameter form)) (set-slot-value (optimize-set-slot-value slots parameter form)) (slot-boundp (optimize-slot-boundp slots parameter form))))) ((and (eq (car form) 'apply) (consp (cadr form)) (eq (car (cadr form)) 'function) (generic-function-name-p (cadr (cadr form)))) (optimize-generic-function-call form required-parameters env slots calls)) ((generic-function-name-p (car form)) (optimize-generic-function-call form required-parameters env slots calls)) ((and (eq (car form) 'asv-funcall) *optimize-asv-funcall-p*) (case (fourth form) (reader (push (third form) *asv-readers*)) (writer (push (third form) *asv-writers*)) (boundp (push (third form) *asv-boundps*))) `(,(second form) ,@(cddddr form))) (t form)))) (let ((walked-lambda (walk-form method-lambda env #'walk-function))) (values walked-lambda call-next-method-p closurep next-method-p-p))))) (defun generic-function-name-p (name) (and (sb-int:legal-function-name-p name) (gboundp name) (if (eq *boot-state* 'complete) (standard-generic-function-p (gdefinition name)) (funcallable-instance-p (gdefinition name))))) (defun make-parameter-references (specialized-lambda-list required-parameters declarations method-name specializers) (flet ((ignoredp (symbol) (dolist (decl (cdar declarations)) (when (and (eq (car decl) 'ignore) (memq symbol (cdr decl))) (return t))))) (gathering ((references (collecting))) (iterate ((s (list-elements specialized-lambda-list)) (p (list-elements required-parameters))) (progn p) (cond ((not (listp s))) ((ignoredp (car s)) (warn "In DEFMETHOD ~S, there is a~%~ redundant IGNORE declaration for the parameter ~S." method-name specializers (car s))) (t (gather (car s) references))))))) (defvar *method-function-plist* (make-hash-table :test 'eq)) (defvar *mf1* nil) (defvar *mf1p* nil) (defvar *mf1cp* nil) (defvar *mf2* nil) (defvar *mf2p* nil) (defvar *mf2cp* nil) (defun method-function-plist (method-function) (unless (eq method-function *mf1*) (rotatef *mf1* *mf2*) (rotatef *mf1p* *mf2p*) (rotatef *mf1cp* *mf2cp*)) (unless (or (eq method-function *mf1*) (null *mf1cp*)) (setf (gethash *mf1* *method-function-plist*) *mf1p*)) (unless (eq method-function *mf1*) (setf *mf1* method-function *mf1cp* nil *mf1p* (gethash method-function *method-function-plist*))) *mf1p*) (defun #-setf SETF\ SB-PCL\ METHOD-FUNCTION-PLIST #+setf (setf method-function-plist) (val method-function) (unless (eq method-function *mf1*) (rotatef *mf1* *mf2*) (rotatef *mf1cp* *mf2cp*) (rotatef *mf1p* *mf2p*)) (unless (or (eq method-function *mf1*) (null *mf1cp*)) (setf (gethash *mf1* *method-function-plist*) *mf1p*)) (setf *mf1* method-function *mf1cp* t *mf1p* val)) (defun method-function-get (method-function key &optional default) (getf (method-function-plist method-function) key default)) (defun #-setf SETF\ SB-PCL\ METHOD-FUNCTION-GET #+setf (setf method-function-get) (val method-function key) (setf (getf (method-function-plist method-function) key) val)) (defun method-function-pv-table (method-function) (method-function-get method-function :pv-table)) (defun method-function-method (method-function) (method-function-get method-function :method)) (defun method-function-needs-next-methods-p (method-function) (method-function-get method-function :needs-next-methods-p t)) (defmacro method-function-closure-generator (method-function) `(method-function-get ,method-function 'closure-generator)) (defun load-defmethod (class name quals specls ll initargs &optional pv-table-symbol) (when (listp name) (do-standard-defsetf-1 (cadr name))) (setq initargs (copy-tree initargs)) (let ((method-spec (or (getf initargs ':method-spec) (make-method-spec name quals specls)))) (setf (getf initargs ':method-spec) method-spec) (record-definition 'method method-spec) (load-defmethod-internal class name quals specls ll initargs pv-table-symbol))) (defun load-defmethod-internal (method-class gf-spec qualifiers specializers lambda-list initargs pv-table-symbol) (when (listp gf-spec) (do-standard-defsetf-1 (cadr gf-spec))) (when pv-table-symbol (setf (getf (getf initargs ':plist) :pv-table-symbol) pv-table-symbol)) ;; FIXME: It seems as though I should be able to get this to work. ;; But it keeps on screwing up PCL bootstrapping. #+nil (when (and (eq *boot-state* 'complete) (fboundp gf-spec)) (let* ((gf (symbol-function gf-spec)) (method (and (generic-function-p gf) (find-method gf qualifiers (mapcar #'find-class specializers) nil)))) (when method (sb-kernel::style-warn "redefining ~S~{ ~S~} ~S in DEFMETHOD" gf-spec qualifiers specializers)))) (let ((method (apply #'add-named-method gf-spec qualifiers specializers lambda-list :definition-source `((defmethod ,gf-spec ,@qualifiers ,specializers) ,*load-truename*) initargs))) (unless (or (eq method-class 'standard-method) (eq (find-class method-class nil) (class-of method))) ;; FIXME: should be STYLE-WARNING? (format *error-output* "~&At the time the method with qualifiers ~:S and~%~ specializers ~:S on the generic function ~S~%~ was compiled, the method-class for that generic function was~%~ ~S. But, the method class is now ~S, this~%~ may mean that this method was compiled improperly.~%" qualifiers specializers gf-spec method-class (class-name (class-of method)))) method)) (defun make-method-spec (gf-spec qualifiers unparsed-specializers) `(method ,gf-spec ,@qualifiers ,unparsed-specializers)) (defun initialize-method-function (initargs &optional return-function-p method) (let* ((mf (getf initargs ':function)) (method-spec (getf initargs ':method-spec)) (plist (getf initargs ':plist)) (pv-table-symbol (getf plist ':pv-table-symbol)) (pv-table nil) (mff (getf initargs ':fast-function))) (flet ((set-mf-property (p v) (when mf (setf (method-function-get mf p) v)) (when mff (setf (method-function-get mff p) v)))) (when method-spec (when mf (setq mf (set-function-name mf method-spec))) (when mff (let ((name `(,(or (get (car method-spec) 'fast-sym) (setf (get (car method-spec) 'fast-sym) ;; KLUDGE: If we're going to be ;; interning private symbols in our ;; a this way, it would be cleanest ;; to use a separate package ;; %PCL-PRIVATE or something, and ;; failing that, to use a special ;; symbol prefix denoting privateness. ;; -- WHN 19991201 (intern (format nil "FAST-~A" (car method-spec)) *pcl-package*))) ,@(cdr method-spec)))) (set-function-name mff name) (unless mf (set-mf-property :name name))))) (when plist (let ((snl (getf plist :slot-name-lists)) (cl (getf plist :call-list))) (when (or snl cl) (setq pv-table (intern-pv-table :slot-name-lists snl :call-list cl)) (when pv-table (set pv-table-symbol pv-table)) (set-mf-property :pv-table pv-table))) (loop (when (null plist) (return nil)) (set-mf-property (pop plist) (pop plist))) (when method (set-mf-property :method method)) (when return-function-p (or mf (method-function-from-fast-function mff))))))) (defun analyze-lambda-list (lambda-list) ;;(declare (values nrequired noptional keysp restp allow-other-keys-p ;; keywords keyword-parameters)) (flet ((parse-keyword-argument (arg) (if (listp arg) (if (listp (car arg)) (caar arg) (make-keyword (car arg))) (make-keyword arg)))) (let ((nrequired 0) (noptional 0) (keysp nil) (restp nil) (allow-other-keys-p nil) (keywords ()) (keyword-parameters ()) (state 'required)) (dolist (x lambda-list) (if (memq x lambda-list-keywords) (case x (&optional (setq state 'optional)) (&key (setq keysp 't state 'key)) (&allow-other-keys (setq allow-other-keys-p 't)) (&rest (setq restp 't state 'rest)) (&aux (return t)) (otherwise (error "encountered the non-standard lambda list keyword ~S" x))) (ecase state (required (incf nrequired)) (optional (incf noptional)) (key (push (parse-keyword-argument x) keywords) (push x keyword-parameters)) (rest ())))) (values nrequired noptional keysp restp allow-other-keys-p (reverse keywords) (reverse keyword-parameters))))) (defun keyword-spec-name (x) (let ((key (if (atom x) x (car x)))) (if (atom key) (intern (symbol-name key) *keyword-package*) (car key)))) (defun ftype-declaration-from-lambda-list (lambda-list name) (multiple-value-bind (nrequired noptional keysp restp allow-other-keys-p keywords keyword-parameters) (analyze-lambda-list lambda-list) (declare (ignore keyword-parameters)) (let* ((old (sb-c::info :function :type name)) ;FIXME:FDOCUMENTATION instead? (old-ftype (if (sb-c::function-type-p old) old nil)) (old-restp (and old-ftype (sb-c::function-type-rest old-ftype))) (old-keys (and old-ftype (mapcar #'sb-c::key-info-name (sb-c::function-type-keywords old-ftype)))) (old-keysp (and old-ftype (sb-c::function-type-keyp old-ftype))) (old-allowp (and old-ftype (sb-c::function-type-allowp old-ftype))) (keywords (union old-keys (mapcar #'keyword-spec-name keywords)))) `(function ,(append (make-list nrequired :initial-element 't) (when (plusp noptional) (append '(&optional) (make-list noptional :initial-element 't))) (when (or restp old-restp) '(&rest t)) (when (or keysp old-keysp) (append '(&key) (mapcar #'(lambda (key) `(,key t)) keywords) (when (or allow-other-keys-p old-allowp) '(&allow-other-keys))))) *)))) (defun defgeneric-declaration (spec lambda-list) (when (consp spec) (setq spec (get-setf-function-name (cadr spec)))) `(ftype ,(ftype-declaration-from-lambda-list lambda-list spec) ,spec)) ;;;; early generic function support (defvar *early-generic-functions* ()) (defun ensure-generic-function (function-name &rest all-keys &key environment &allow-other-keys) (declare (ignore environment)) (let ((existing (and (gboundp function-name) (gdefinition function-name)))) (if (and existing (eq *boot-state* 'complete) (null (generic-function-p existing))) (generic-clobbers-function function-name) (apply #'ensure-generic-function-using-class existing function-name all-keys)))) (defun generic-clobbers-function (function-name) (error 'sb-kernel:simple-program-error :format-control "~S already names an ordinary function or a macro." :format-arguments (list function-name))) (defvar *sgf-wrapper* (boot-make-wrapper (early-class-size 'standard-generic-function) 'standard-generic-function)) (defvar *sgf-slots-init* (mapcar #'(lambda (canonical-slot) (if (memq (getf canonical-slot :name) '(arg-info source)) *slot-unbound* (let ((initfunction (getf canonical-slot :initfunction))) (if initfunction (funcall initfunction) *slot-unbound*)))) (early-collect-inheritance 'standard-generic-function))) (defvar *sgf-method-class-index* (bootstrap-slot-index 'standard-generic-function 'method-class)) (defun early-gf-p (x) (and (fsc-instance-p x) (eq (instance-ref (get-slots x) *sgf-method-class-index*) *slot-unbound*))) (defvar *sgf-methods-index* (bootstrap-slot-index 'standard-generic-function 'methods)) (defmacro early-gf-methods (gf) `(instance-ref (get-slots ,gf) *sgf-methods-index*)) (defvar *sgf-arg-info-index* (bootstrap-slot-index 'standard-generic-function 'arg-info)) (defmacro early-gf-arg-info (gf) `(instance-ref (get-slots ,gf) *sgf-arg-info-index*)) (defvar *sgf-dfun-state-index* (bootstrap-slot-index 'standard-generic-function 'dfun-state)) (defstruct (arg-info (:conc-name nil) (:constructor make-arg-info ())) (arg-info-lambda-list :no-lambda-list) arg-info-precedence arg-info-metatypes arg-info-number-optional arg-info-key/rest-p arg-info-keywords ;nil no keyword or rest allowed ;(k1 k2 ..) each method must accept these keyword arguments ;T must have &key or &rest gf-info-simple-accessor-type ; nil, reader, writer, boundp (gf-precompute-dfun-and-emf-p nil) ; set by set-arg-info gf-info-static-c-a-m-emf (gf-info-c-a-m-emf-std-p t) gf-info-fast-mf-p) #-sb-fluid (declaim (sb-ext:freeze-type arg-info)) (defun arg-info-valid-p (arg-info) (not (null (arg-info-number-optional arg-info)))) (defun arg-info-applyp (arg-info) (or (plusp (arg-info-number-optional arg-info)) (arg-info-key/rest-p arg-info))) (defun arg-info-number-required (arg-info) (length (arg-info-metatypes arg-info))) (defun arg-info-nkeys (arg-info) (count-if #'(lambda (x) (neq x 't)) (arg-info-metatypes arg-info))) ;;; Keep pages clean by not setting if the value is already the same. (defmacro esetf (pos val) (let ((valsym (gensym "value"))) `(let ((,valsym ,val)) (unless (equal ,pos ,valsym) (setf ,pos ,valsym))))) (defun set-arg-info (gf &key new-method (lambda-list nil lambda-list-p) argument-precedence-order) (let* ((arg-info (if (eq *boot-state* 'complete) (gf-arg-info gf) (early-gf-arg-info gf))) (methods (if (eq *boot-state* 'complete) (generic-function-methods gf) (early-gf-methods gf))) (was-valid-p (integerp (arg-info-number-optional arg-info))) (first-p (and new-method (null (cdr methods))))) (when (and (not lambda-list-p) methods) (setq lambda-list (gf-lambda-list gf))) (when (or lambda-list-p (and first-p (eq (arg-info-lambda-list arg-info) ':no-lambda-list))) (multiple-value-bind (nreq nopt keysp restp allow-other-keys-p keywords) (analyze-lambda-list lambda-list) (when (and methods (not first-p)) (let ((gf-nreq (arg-info-number-required arg-info)) (gf-nopt (arg-info-number-optional arg-info)) (gf-key/rest-p (arg-info-key/rest-p arg-info))) (unless (and (= nreq gf-nreq) (= nopt gf-nopt) (eq (or keysp restp) gf-key/rest-p)) (error "The lambda-list ~S is incompatible with ~ existing methods of ~S." lambda-list gf)))) (when lambda-list-p (esetf (arg-info-lambda-list arg-info) lambda-list)) (when (or lambda-list-p argument-precedence-order (null (arg-info-precedence arg-info))) (esetf (arg-info-precedence arg-info) (compute-precedence lambda-list nreq argument-precedence-order))) (esetf (arg-info-metatypes arg-info) (make-list nreq)) (esetf (arg-info-number-optional arg-info) nopt) (esetf (arg-info-key/rest-p arg-info) (not (null (or keysp restp)))) (esetf (arg-info-keywords arg-info) (if lambda-list-p (if allow-other-keys-p t keywords) (arg-info-key/rest-p arg-info))))) (when new-method (check-method-arg-info gf arg-info new-method)) (set-arg-info1 gf arg-info new-method methods was-valid-p first-p) arg-info)) (defun check-method-arg-info (gf arg-info 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))) (flet ((lose (string &rest args) (error "attempt to add the method ~S to the generic function ~S.~%~ But ~A" method gf (apply #'format nil string args))) (compare (x y) (if (> x y) "more" "fewer"))) (let ((gf-nreq (arg-info-number-required arg-info)) (gf-nopt (arg-info-number-optional arg-info)) (gf-key/rest-p (arg-info-key/rest-p arg-info)) (gf-keywords (arg-info-keywords arg-info))) (unless (= nreq gf-nreq) (lose "the method has ~A required arguments than the generic function." (compare nreq gf-nreq))) (unless (= nopt gf-nopt) (lose "the method has ~S optional arguments than the generic function." (compare nopt gf-nopt))) (unless (eq (or keysp restp) gf-key/rest-p) (error "The method and generic function differ in whether they accept~%~ &REST or &KEY arguments.")) (when (consp gf-keywords) (unless (or (and restp (not keysp)) allow-other-keys-p (every #'(lambda (k) (memq k keywords)) gf-keywords)) (lose "the method does not accept each of the keyword arguments~%~ ~S." gf-keywords))))))) (defun set-arg-info1 (gf arg-info new-method methods was-valid-p first-p) (let* ((existing-p (and methods (cdr methods) new-method)) (nreq (length (arg-info-metatypes arg-info))) (metatypes (if existing-p (arg-info-metatypes arg-info) (make-list nreq))) (type (if existing-p (gf-info-simple-accessor-type arg-info) nil))) (when (arg-info-valid-p arg-info) (dolist (method (if new-method (list new-method) methods)) (let* ((specializers (if (or (eq *boot-state* 'complete) (not (consp method))) (method-specializers method) (early-method-specializers method t))) (class (if (or (eq *boot-state* 'complete) (not (consp method))) (class-of method) (early-method-class method))) (new-type (when (and class (or (not (eq *boot-state* 'complete)) (eq (generic-function-method-combination gf) *standard-method-combination*))) (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))))) (setq metatypes (mapcar #'raise-metatype metatypes specializers)) (setq type (cond ((null type) new-type) ((eq type new-type) type) (t nil))))) (esetf (arg-info-metatypes arg-info) metatypes) (esetf (gf-info-simple-accessor-type arg-info) type))) (when (or (not was-valid-p) first-p) (multiple-value-bind (c-a-m-emf std-p) (if (early-gf-p gf) (values t t) (compute-applicable-methods-emf gf)) (esetf (gf-info-static-c-a-m-emf arg-info) c-a-m-emf) (esetf (gf-info-c-a-m-emf-std-p arg-info) std-p) (unless (gf-info-c-a-m-emf-std-p arg-info) (esetf (gf-info-simple-accessor-type arg-info) t)))) (unless was-valid-p (let ((name (if (eq *boot-state* 'complete) (generic-function-name gf) (early-gf-name gf)))) (esetf (gf-precompute-dfun-and-emf-p arg-info) (let* ((sym (if (atom name) name (cadr name))) (pkg-list (cons *pcl-package* (package-use-list *pcl-package*)))) (and sym (symbolp sym) (not (null (memq (symbol-package sym) pkg-list))) (not (find #\space (symbol-name sym)))))))) (esetf (gf-info-fast-mf-p arg-info) (or (not (eq *boot-state* 'complete)) (let* ((method-class (generic-function-method-class gf)) (methods (compute-applicable-methods #'make-method-lambda (list gf (class-prototype method-class) '(lambda) nil)))) (and methods (null (cdr methods)) (let ((specls (method-specializers (car methods)))) (and (classp (car specls)) (eq 'standard-generic-function (class-name (car specls))) (classp (cadr specls)) (eq 'standard-method (class-name (cadr specls))))))))) arg-info) ;;; This is the early definition of ensure-generic-function-using-class. ;;; ;;; The static-slots field of the funcallable instances used as early generic ;;; functions is used to store the early methods and early discriminator code ;;; for the early generic function. The static slots field of the fins ;;; contains a list whose: ;;; CAR - a list of the early methods on this early gf ;;; CADR - the early discriminator code for this method (defun ensure-generic-function-using-class (existing spec &rest keys &key (lambda-list nil lambda-list-p) &allow-other-keys) (declare (ignore keys)) (cond ((and existing (early-gf-p existing)) existing) ((assoc spec *generic-function-fixups* :test #'equal) (if existing (make-early-gf spec lambda-list lambda-list-p existing) (error "The function ~S is not already defined." spec))) (existing (error "~S should be on the list ~S." spec '*generic-function-fixups*)) (t (pushnew spec *early-generic-functions* :test #'equal) (make-early-gf spec lambda-list lambda-list-p)))) (defun make-early-gf (spec &optional lambda-list lambda-list-p function) (let ((fin (allocate-funcallable-instance *sgf-wrapper* *sgf-slots-init*))) (set-funcallable-instance-function fin (or function (if (eq spec 'print-object) #'(sb-kernel:instance-lambda (instance stream) (print-unreadable-object (instance stream :identity t) (format stream "std-instance"))) #'(sb-kernel:instance-lambda (&rest args) (declare (ignore args)) (error "The function of the funcallable-instance ~S~ has not been set." fin))))) (setf (gdefinition spec) fin) (bootstrap-set-slot 'standard-generic-function fin 'name spec) (bootstrap-set-slot 'standard-generic-function fin 'source *load-truename*) (set-function-name fin spec) (let ((arg-info (make-arg-info))) (setf (early-gf-arg-info fin) arg-info) (when lambda-list-p (proclaim (defgeneric-declaration spec lambda-list)) (set-arg-info fin :lambda-list lambda-list))) fin)) (defun set-dfun (gf &optional dfun cache info) (when cache (setf (cache-owner cache) gf)) (let ((new-state (if (and dfun (or cache info)) (list* dfun cache info) dfun))) (if (eq *boot-state* 'complete) (setf (gf-dfun-state gf) new-state) (setf (instance-ref (get-slots gf) *sgf-dfun-state-index*) new-state))) dfun) (defun gf-dfun-cache (gf) (let ((state (if (eq *boot-state* 'complete) (gf-dfun-state gf) (instance-ref (get-slots gf) *sgf-dfun-state-index*)))) (typecase state (function nil) (cons (cadr state))))) (defun gf-dfun-info (gf) (let ((state (if (eq *boot-state* 'complete) (gf-dfun-state gf) (instance-ref (get-slots gf) *sgf-dfun-state-index*)))) (typecase state (function nil) (cons (cddr state))))) (defvar *sgf-name-index* (bootstrap-slot-index 'standard-generic-function 'name)) (defun early-gf-name (gf) (instance-ref (get-slots gf) *sgf-name-index*)) (defun gf-lambda-list (gf) (let ((arg-info (if (eq *boot-state* 'complete) (gf-arg-info gf) (early-gf-arg-info gf)))) (if (eq ':no-lambda-list (arg-info-lambda-list arg-info)) (let ((methods (if (eq *boot-state* 'complete) (generic-function-methods gf) (early-gf-methods gf)))) (if (null methods) (progn (warn "no way to determine the lambda list for ~S" gf) nil) (let* ((method (car (last methods))) (ll (if (consp method) (early-method-lambda-list method) (method-lambda-list method))) (k (member '&key ll))) (if k (append (ldiff ll (cdr k)) '(&allow-other-keys)) ll)))) (arg-info-lambda-list arg-info)))) (defmacro real-ensure-gf-internal (gf-class all-keys env) `(progn (cond ((symbolp ,gf-class) (setq ,gf-class (find-class ,gf-class t ,env))) ((classp ,gf-class)) (t (error "The :GENERIC-FUNCTION-CLASS argument (~S) was neither a~%~ class nor a symbol that names a class." ,gf-class))) (remf ,all-keys :generic-function-class) (remf ,all-keys :environment) (let ((combin (getf ,all-keys :method-combination '.shes-not-there.))) (unless (eq combin '.shes-not-there.) (setf (getf ,all-keys :method-combination) (find-method-combination (class-prototype ,gf-class) (car combin) (cdr combin))))))) (defun real-ensure-gf-using-class--generic-function (existing function-name &rest all-keys &key environment (lambda-list nil lambda-list-p) (generic-function-class 'standard-generic-function gf-class-p) &allow-other-keys) (real-ensure-gf-internal generic-function-class all-keys environment) (unless (or (null gf-class-p) (eq (class-of existing) generic-function-class)) (change-class existing generic-function-class)) (prog1 (apply #'reinitialize-instance existing all-keys) (when lambda-list-p (proclaim (defgeneric-declaration function-name lambda-list))))) (defun real-ensure-gf-using-class--null (existing function-name &rest all-keys &key environment (lambda-list nil lambda-list-p) (generic-function-class 'standard-generic-function) &allow-other-keys) (declare (ignore existing)) (real-ensure-gf-internal generic-function-class all-keys environment) (prog1 (setf (gdefinition function-name) (apply #'make-instance generic-function-class :name function-name all-keys)) (when lambda-list-p (proclaim (defgeneric-declaration function-name lambda-list))))) (defun get-generic-function-info (gf) ;; values nreq applyp metatypes nkeys arg-info (multiple-value-bind (applyp metatypes arg-info) (let* ((arg-info (if (early-gf-p gf) (early-gf-arg-info gf) (gf-arg-info gf))) (metatypes (arg-info-metatypes arg-info))) (values (arg-info-applyp arg-info) metatypes arg-info)) (values (length metatypes) applyp metatypes (count-if #'(lambda (x) (neq x 't)) metatypes) arg-info))) (defun early-make-a-method (class qualifiers arglist specializers initargs doc &optional slot-name) (initialize-method-function initargs) (let ((parsed ()) (unparsed ())) ;; Figure out whether we got class objects or class names as the ;; specializers and set parsed and unparsed appropriately. If we ;; got class objects, then we can compute unparsed, but if we got ;; class names we don't try to compute parsed. ;; ;; Note that the use of not symbolp in this call to every should be ;; read as 'classp' we can't use classp itself because it doesn't ;; exist yet. (if (every #'(lambda (s) (not (symbolp s))) specializers) (setq parsed specializers unparsed (mapcar #'(lambda (s) (if (eq s 't) 't (class-name s))) specializers)) (setq unparsed specializers parsed ())) (list :early-method ;This is an early method dammit! (getf initargs ':function) (getf initargs ':fast-function) parsed ;The parsed specializers. This is used ;by early-method-specializers to cache ;the parse. Note that this only comes ;into play when there is more than one ;early method on an early gf. (list class ;A list to which real-make-a-method qualifiers ;can be applied to make a real method arglist ;corresponding to this early one. unparsed initargs doc slot-name)))) (defun real-make-a-method (class qualifiers lambda-list specializers initargs doc &optional slot-name) (setq specializers (parse-specializers specializers)) (apply #'make-instance class :qualifiers qualifiers :lambda-list lambda-list :specializers specializers :documentation doc :slot-name slot-name :allow-other-keys t initargs)) (defun early-method-function (early-method) (values (cadr early-method) (caddr early-method))) (defun early-method-class (early-method) (find-class (car (fifth early-method)))) (defun early-method-standard-accessor-p (early-method) (let ((class (first (fifth early-method)))) (or (eq class 'standard-reader-method) (eq class 'standard-writer-method) (eq class 'standard-boundp-method)))) (defun early-method-standard-accessor-slot-name (early-method) (seventh (fifth early-method))) ;;; Fetch the specializers of an early method. This is basically just a ;;; simple accessor except that when the second argument is t, this converts ;;; the specializers from symbols into class objects. The class objects ;;; are cached in the early method, this makes bootstrapping faster because ;;; the class objects only have to be computed once. ;;; NOTE: ;;; the second argument should only be passed as T by early-lookup-method. ;;; this is to implement the rule that only when there is more than one ;;; early method on a generic function is the conversion from class names ;;; to class objects done. ;;; the corresponds to the fact that we are only allowed to have one method ;;; on any generic function up until the time classes exist. (defun early-method-specializers (early-method &optional objectsp) (if (and (listp early-method) (eq (car early-method) :early-method)) (cond ((eq objectsp 't) (or (fourth early-method) (setf (fourth early-method) (mapcar #'find-class (cadddr (fifth early-method)))))) (t (cadddr (fifth early-method)))) (error "~S is not an early-method." early-method))) (defun early-method-qualifiers (early-method) (cadr (fifth early-method))) (defun early-method-lambda-list (early-method) (caddr (fifth early-method))) (defun early-add-named-method (generic-function-name qualifiers specializers arglist &rest initargs) (let* ((gf (ensure-generic-function generic-function-name)) (existing (dolist (m (early-gf-methods gf)) (when (and (equal (early-method-specializers m) specializers) (equal (early-method-qualifiers m) qualifiers)) (return m)))) (new (make-a-method 'standard-method qualifiers arglist specializers initargs ()))) (when existing (remove-method gf existing)) (add-method gf new))) ;;; This is the early version of add-method. Later this will become a ;;; generic function. See fix-early-generic-functions which has special ;;; knowledge about add-method. (defun add-method (generic-function method) (when (not (fsc-instance-p generic-function)) (error "Early add-method didn't get a funcallable instance.")) (when (not (and (listp method) (eq (car method) :early-method))) (error "Early add-method didn't get an early method.")) (push method (early-gf-methods generic-function)) (set-arg-info generic-function :new-method method) (unless (assoc (early-gf-name generic-function) *generic-function-fixups* :test #'equal) (update-dfun generic-function))) ;;; This is the early version of REMOVE-METHOD.. (defun remove-method (generic-function method) (when (not (fsc-instance-p generic-function)) (error "An early remove-method didn't get a funcallable instance.")) (when (not (and (listp method) (eq (car method) :early-method))) (error "An early remove-method didn't get an early method.")) (setf (early-gf-methods generic-function) (remove method (early-gf-methods generic-function))) (set-arg-info generic-function) (unless (assoc (early-gf-name generic-function) *generic-function-fixups* :test #'equal) (update-dfun generic-function))) ;;; ..and the early version of GET-METHOD. (defun get-method (generic-function qualifiers specializers &optional (errorp t)) (if (early-gf-p generic-function) (or (dolist (m (early-gf-methods generic-function)) (when (and (or (equal (early-method-specializers m nil) specializers) (equal (early-method-specializers m 't) specializers)) (equal (early-method-qualifiers m) qualifiers)) (return m))) (if errorp (error "can't get early method") nil)) (real-get-method generic-function qualifiers specializers errorp))) (defvar *fegf-debug-p* nil) (defun fix-early-generic-functions (&optional (noisyp *fegf-debug-p*)) (let ((accessors nil)) ;; Rearrange *EARLY-GENERIC-FUNCTIONS* to speed up ;; FIX-EARLY-GENERIC-FUNCTIONS. (dolist (early-gf-spec *early-generic-functions*) (when (every #'early-method-standard-accessor-p (early-gf-methods (gdefinition early-gf-spec))) (push early-gf-spec accessors))) (dolist (spec (nconc accessors '(accessor-method-slot-name generic-function-methods method-specializers specializerp specializer-type specializer-class slot-definition-location slot-definition-name class-slots gf-arg-info class-precedence-list slot-boundp-using-class (setf slot-value-using-class) slot-value-using-class structure-class-p standard-class-p funcallable-standard-class-p specializerp))) (setq *early-generic-functions* (cons spec (delete spec *early-generic-functions* :test #'equal)))) (dolist (early-gf-spec *early-generic-functions*) (when noisyp (format t "~&~S..." early-gf-spec)) (let* ((gf (gdefinition early-gf-spec)) (methods (mapcar #'(lambda (early-method) (let ((args (copy-list (fifth early-method)))) (setf (fourth args) (early-method-specializers early-method t)) (apply #'real-make-a-method args))) (early-gf-methods gf)))) (setf (generic-function-method-class gf) *the-class-standard-method*) (setf (generic-function-method-combination gf) *standard-method-combination*) (set-methods gf methods))) (dolist (fns *early-functions*) (setf (gdefinition (car fns)) (symbol-function (caddr fns)))) (dolist (fixup *generic-function-fixups*) (let* ((fspec (car fixup)) (gf (gdefinition fspec)) (methods (mapcar #'(lambda (method) (let* ((lambda-list (first method)) (specializers (second method)) (method-fn-name (third method)) (fn-name (or method-fn-name fspec)) (fn (symbol-function fn-name)) (initargs (list :function (set-function-name #'(lambda (args next-methods) (declare (ignore next-methods)) (apply fn args)) `(call ,fn-name))))) (declare (type function fn)) (make-a-method 'standard-method () lambda-list specializers initargs nil))) (cdr fixup)))) (setf (generic-function-method-class gf) *the-class-standard-method*) (setf (generic-function-method-combination gf) *standard-method-combination*) (set-methods gf methods))))) ;;; PARSE-DEFMETHOD is used by DEFMETHOD to parse the &REST argument into ;;; the 'real' arguments. This is where the syntax of DEFMETHOD is really ;;; implemented. (defun parse-defmethod (cdr-of-form) ;;(declare (values name qualifiers specialized-lambda-list body)) (let ((name (pop cdr-of-form)) (qualifiers ()) (spec-ll ())) (loop (if (and (car cdr-of-form) (atom (car cdr-of-form))) (push (pop cdr-of-form) qualifiers) (return (setq qualifiers (nreverse qualifiers))))) (setq spec-ll (pop cdr-of-form)) (values name qualifiers spec-ll cdr-of-form))) (defun parse-specializers (specializers) (flet ((parse (spec) (let ((result (specializer-from-type spec))) (if (specializerp result) result (if (symbolp spec) (error "~S was used as a specializer,~%~ but is not the name of a class." spec) (error "~S is not a legal specializer." spec)))))) (mapcar #'parse specializers))) (defun unparse-specializers (specializers-or-method) (if (listp specializers-or-method) (flet ((unparse (spec) (if (specializerp spec) (let ((type (specializer-type spec))) (if (and (consp type) (eq (car type) 'class)) (let* ((class (cadr type)) (class-name (class-name class))) (if (eq class (find-class class-name nil)) class-name type)) type)) (error "~S is not a legal specializer." spec)))) (mapcar #'unparse specializers-or-method)) (unparse-specializers (method-specializers specializers-or-method)))) (defun parse-method-or-spec (spec &optional (errorp t)) ;;(declare (values generic-function method method-name)) (let (gf method name temp) (if (method-p spec) (setq method spec gf (method-generic-function method) temp (and gf (generic-function-name gf)) name (if temp (intern-function-name (make-method-spec temp (method-qualifiers method) (unparse-specializers (method-specializers method)))) (make-symbol (format nil "~S" method)))) (multiple-value-bind (gf-spec quals specls) (parse-defmethod spec) (and (setq gf (and (or errorp (gboundp gf-spec)) (gdefinition gf-spec))) (let ((nreq (compute-discriminating-function-arglist-info gf))) (setq specls (append (parse-specializers specls) (make-list (- nreq (length specls)) :initial-element *the-class-t*))) (and (setq method (get-method gf quals specls errorp)) (setq name (intern-function-name (make-method-spec gf-spec quals specls)))))))) (values gf method name))) (defun extract-parameters (specialized-lambda-list) (multiple-value-bind (parameters ignore1 ignore2) (parse-specialized-lambda-list specialized-lambda-list) (declare (ignore ignore1 ignore2)) parameters)) (defun extract-lambda-list (specialized-lambda-list) (multiple-value-bind (ignore1 lambda-list ignore2) (parse-specialized-lambda-list specialized-lambda-list) (declare (ignore ignore1 ignore2)) lambda-list)) (defun extract-specializer-names (specialized-lambda-list) (multiple-value-bind (ignore1 ignore2 specializers) (parse-specialized-lambda-list specialized-lambda-list) (declare (ignore ignore1 ignore2)) specializers)) (defun extract-required-parameters (specialized-lambda-list) (multiple-value-bind (ignore1 ignore2 ignore3 required-parameters) (parse-specialized-lambda-list specialized-lambda-list) (declare (ignore ignore1 ignore2 ignore3)) required-parameters)) (defun parse-specialized-lambda-list (arglist &optional post-keyword) ;;(declare (values parameters lambda-list specializers required-parameters)) (let ((arg (car arglist))) (cond ((null arglist) (values nil nil nil nil)) ((eq arg '&aux) (values nil arglist nil)) ((memq arg lambda-list-keywords) (unless (memq arg '(&optional &rest &key &allow-other-keys &aux)) ;; Warn about non-standard lambda-list-keywords, but then ;; go on to treat them like a standard lambda-list-keyword ;; what with the warning its probably ok. ;; ;; FIXME: This shouldn't happen now that this is maintained ;; as part of SBCL, should it? Perhaps this is now ;; "internal error: unrecognized lambda-list keyword ~S"? (warn "Unrecognized lambda-list keyword ~S in arglist.~%~ Assuming that the symbols following it are parameters,~%~ and not allowing any parameter specializers to follow~%~ to follow it." arg)) ;; When we are at a lambda-list keyword, the parameters don't ;; include the lambda-list keyword; the lambda-list does include ;; the lambda-list keyword; and no specializers are allowed to ;; follow the lambda-list keywords (at least for now). (multiple-value-bind (parameters lambda-list) (parse-specialized-lambda-list (cdr arglist) t) (values parameters (cons arg lambda-list) () ()))) (post-keyword ;; After a lambda-list keyword there can be no specializers. (multiple-value-bind (parameters lambda-list) (parse-specialized-lambda-list (cdr arglist) t) (values (cons (if (listp arg) (car arg) arg) parameters) (cons arg lambda-list) () ()))) (t (multiple-value-bind (parameters lambda-list specializers required) (parse-specialized-lambda-list (cdr arglist)) (values (cons (if (listp arg) (car arg) arg) parameters) (cons (if (listp arg) (car arg) arg) lambda-list) (cons (if (listp arg) (cadr arg) 't) specializers) (cons (if (listp arg) (car arg) arg) required))))))) (eval-when (:load-toplevel :execute) (setq *boot-state* 'early)) ;;; FIXME: In here there was a #-CMU definition of SYMBOL-MACROLET which used ;;; %WALKER stuff. That suggests to me that maybe the code walker stuff was ;;; only used for implementing stuff like that; maybe it's not needed any more? ;;; Hunt down what it was used for and see. (defmacro with-slots (slots instance &body body) (let ((in (gensym))) `(let ((,in ,instance)) (declare (ignorable ,in)) ,@(let ((instance (if (and (consp instance) (eq (car instance) 'the)) (third instance) instance))) (and (symbolp instance) `((declare (variable-rebinding ,in ,instance))))) ,in (symbol-macrolet ,(mapcar #'(lambda (slot-entry) (let ((variable-name (if (symbolp slot-entry) slot-entry (car slot-entry))) (slot-name (if (symbolp slot-entry) slot-entry (cadr slot-entry)))) `(,variable-name (slot-value ,in ',slot-name)))) slots) ,@body)))) (defmacro with-accessors (slots instance &body body) (let ((in (gensym))) `(let ((,in ,instance)) (declare (ignorable ,in)) ,@(let ((instance (if (and (consp instance) (eq (car instance) 'the)) (third instance) instance))) (and (symbolp instance) `((declare (variable-rebinding ,in ,instance))))) ,in (symbol-macrolet ,(mapcar #'(lambda (slot-entry) (let ((variable-name (car slot-entry)) (accessor-name (cadr slot-entry))) `(,variable-name (,accessor-name ,in)))) slots) ,@body))))