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guile-bootstrap / guile /module /oop /goops.scm

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	;;;; goops.scm -- The Guile Object-Oriented Programming System
	;;;;
	;;;; Copyright (C) 1998-2003,2006,2009-2011,2013-2015,2017-2018,2021
	;;;; Free Software Foundation, Inc.
	;;;; Copyright (C) 1993-1998 Erick Gallesio - I3S-CNRS/ESSI <[email protected]>
	;;;;
	;;;; This library is free software; you can redistribute it and/or
	;;;; modify it under the terms of the GNU Lesser General Public
	;;;; License as published by the Free Software Foundation; either
	;;;; version 3 of the License, or (at your option) any later version.
	;;;;
	;;;; This library is distributed in the hope that it will be useful,
	;;;; but WITHOUT ANY WARRANTY; without even the implied warranty of
	;;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	;;;; Lesser General Public License for more details.
	;;;;
	;;;; You should have received a copy of the GNU Lesser General Public
	;;;; License along with this library; if not, write to the Free Software
	;;;; Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
	;;;;


	;;;;
	;;;; This file was based upon stklos.stk from the STk distribution
	;;;; version 4.0.1 by Erick Gallesio <[email protected]>.
	;;;;

	(define-module (oop goops)
	#:use-module (srfi srfi-1)
	#:use-module (ice-9 match)
	#:use-module ((ice-9 control) #:select (let/ec))
	#:use-module (ice-9 threads)
	#:use-module ((language tree-il primitives)
	:select (add-interesting-primitive!))
	#:export-syntax (define-class class standard-define-class
	define-generic define-accessor define-method
	define-extended-generic define-extended-generics
	method)
	#:export ( ;; The root of everything.
	<top>
	<class> <object>

	;; Slot types.
	<slot>
	<foreign-slot> <protected-slot> <hidden-slot> <opaque-slot>
	<read-only-slot> <protected-opaque-slot>
	<protected-hidden-slot> <protected-read-only-slot>
	<scm-slot>

	;; Redefinable classes.
	<redefinable-class>

	;; Methods are implementations of generic functions.
	<method> <accessor-method>

	;; Applicable objects, either procedures or applicable structs.
	<procedure-class> <applicable>
	<procedure> <primitive-generic>

	;; Applicable structs.
	<applicable-struct-class> <applicable-struct-with-setter-class>
	<applicable-struct> <applicable-struct-with-setter>
	<generic> <extended-generic>
	<generic-with-setter> <extended-generic-with-setter>
	<accessor> <extended-accessor>

	;; Types with their own allocated typecodes.
	<boolean> <char> <list> <pair> <null> <string> <symbol>
	<vector> <bytevector> <uvec> <foreign> <hashtable>
	<fluid> <dynamic-state> <frame> <vm> <vm-continuation>
	<keyword> <syntax> <atomic-box>

	;; Numbers.
	<number> <complex> <real> <integer> <fraction>

	;; Unknown.
	<unknown>

	;; Particular SMOB data types. All SMOB types have
	;; corresponding classes, which may be obtained via class-of,
	;; once you have an instance. Perhaps FIXME to provide a
	;; smob-type-name->class procedure.
	<promise> <thread> <mutex> <condition-variable>
	<regexp> <hook> <bitvector> <random-state>
	<directory> <array> <character-set>
	<dynamic-object> <guardian> <macro>

	;; Modules.
	<module>

	;; Ports.
	<port> <input-port> <output-port> <input-output-port>

	;; Like SMOB types, all port types have their own classes,
	;; which can be accessed via `class-of' once you have an
	;; instance. Here we export bindings just for file ports.
	<file-port>
	<file-input-port> <file-output-port> <file-input-output-port>

	is-a? class-of
	ensure-metaclass ensure-metaclass-with-supers
	make-class
	make-generic ensure-generic
	make-extended-generic
	make-accessor ensure-accessor
	add-method!
	class-slot-ref class-slot-set! slot-unbound slot-missing
	slot-definition-name slot-definition-options
	slot-definition-allocation

	slot-definition-getter slot-definition-setter
	slot-definition-accessor
	slot-definition-init-value slot-definition-init-form
	slot-definition-init-thunk slot-definition-init-keyword
	slot-init-function class-slot-definition
	method-source
	compute-cpl compute-std-cpl compute-get-n-set compute-slots
	compute-getter-method compute-setter-method
	allocate-instance initialize make-instance make
	no-next-method no-applicable-method no-method
	change-class update-instance-for-different-class
	shallow-clone deep-clone
	class-redefinition
	apply-generic apply-method apply-methods
	compute-applicable-methods %compute-applicable-methods
	method-more-specific? sort-applicable-methods
	class-subclasses class-methods
	goops-error
	min-fixnum max-fixnum

	instance?
	slot-ref slot-set! slot-bound? slot-exists?
	class-name class-direct-supers class-direct-subclasses
	class-direct-methods class-direct-slots class-precedence-list
	class-slots
	generic-function-name
	generic-function-methods method-generic-function
	method-specializers method-formals
	primitive-generic-generic enable-primitive-generic!
	method-procedure accessor-method-slot-definition
	make find-method get-keyword))


	;;;
	;;; Booting GOOPS is a tortuous process. We begin by loading a small
	;;; set of primitives from C.
	;;;
	(eval-when (expand load eval)
	(load-extension (string-append "libguile-" (effective-version))
	"scm_init_goops_builtins")
	(add-interesting-primitive! 'class-of))




	;;;
	;;; We then define the slots that must appear in all classes (<class>
	;;; objects) and slot definitions (<slot> objects). These slots must
	;;; appear in order. We'll use this list to statically compute offsets
	;;; for the various fields, to compute the struct layout for <class>
	;;; instances, and to compute the slot definition lists for <class>.
	;;; Because the list is needed at expansion-time, we define it as a
	;;; macro.
	;;;
	(define-syntax macro-fold-left
	(syntax-rules ()
	((_ folder seed ()) seed)
	((_ folder seed (head . tail))
	(macro-fold-left folder (folder head seed) tail))))

	(define-syntax macro-fold-right
	(syntax-rules ()
	((_ folder seed ()) seed)
	((_ folder seed (head . tail))
	(folder head (macro-fold-right folder seed tail)))))

	(define-syntax-rule (define-macro-folder macro-folder value ...)
	(define-syntax macro-folder
	(lambda (x)
	(syntax-case x ()
	((_ fold visit seed)
	;; The datum->syntax makes it as if each `value' were present
	;; in the initial form, which allows them to be used as
	;; (components of) introduced identifiers.
	#`(fold visit seed #,(datum->syntax #'visit '(value ...))))))))

	(define-macro-folder fold-class-slots
	(layout #:class <protected-read-only-slot>)
	(flags #:class <hidden-slot>)
	(instance-finalizer #:class <hidden-slot>)
	(print)
	(name #:class <protected-hidden-slot>)
	(nfields #:class <hidden-slot>)
	(%reserved-6 #:class <hidden-slot>)
	(%reserved-7 #:class <hidden-slot>)
	(direct-supers)
	(direct-slots)
	(direct-subclasses)
	(direct-methods)
	(cpl)
	(slots))

	(define-macro-folder fold-slot-slots
	(name #:init-keyword #:name)
	(allocation #:init-keyword #:allocation #:init-value #:instance)
	(init-keyword #:init-keyword #:init-keyword #:init-value #f)
	(init-form #:init-keyword #:init-form)
	(init-value #:init-keyword #:init-value)
	(init-thunk #:init-keyword #:init-thunk #:init-value #f)
	(options)
	(getter #:init-keyword #:getter #:init-value #f)
	(setter #:init-keyword #:setter #:init-value #f)
	(accessor #:init-keyword #:accessor #:init-value #f)
	;; These last don't have #:init-keyword because they are meant to be
	;; set by `allocate-slots', not in compute-effective-slot-definition.
	(slot-ref/raw #:init-value #f)
	(slot-ref #:init-value #f)
	(slot-set! #:init-value #f)
	(index #:init-value #f)
	(size #:init-value #f))

	;;;
	;;; Statically define variables for slot offsets: `class-index-layout'
	;;; will be 0, `class-index-flags' will be 1, and so on, and the same
	;;; for `slot-index-name' and such for <slot>.
	;;;
	(let-syntax ((define-slot-indexer
	(syntax-rules ()
	((_ define-index prefix)
	(define-syntax define-index
	(lambda (x)
	(define (id-append ctx a b)
	(datum->syntax ctx (symbol-append (syntax->datum a)
	(syntax->datum b))))
	(define (tail-length tail)
	(syntax-case tail ()
	((begin) 0)
	((visit head tail) (1+ (tail-length #'tail)))))
	(syntax-case x ()
	((_ (name . _) tail)
	#`(begin
	(define-syntax #,(id-append #'name #'prefix #'name)
	(identifier-syntax #,(tail-length #'tail)))
	tail)))))))))
	(define-slot-indexer define-class-index class-index-)
	(define-slot-indexer define-slot-index slot-index-)
	(fold-class-slots macro-fold-left define-class-index (begin))
	(fold-slot-slots macro-fold-left define-slot-index (begin)))

	;;;
	;;; Structs that are vtables have a "flags" slot, which corresponds to
	;;; class-index-flags. `vtable-flag-vtable' indicates that instances of
	;;; a vtable are themselves vtables, and `vtable-flag-validated'
	;;; indicates that the struct's layout has been validated. goops.c
	;;; defines a few additional flags: one to indicate that a vtable is
	;;; actually a class, one to indicate that instances of a class are slot
	;;; definition objects (<slot> instances), one to indicate that this
	;;; class has "static slot allocation" (meaning that its slots must
	;;; always be allocated to the same indices in all subclasses), and two
	;;; more flags used for redefinable classes (more below).
	;;;
	(define vtable-flag-goops-metaclass
	(logior vtable-flag-vtable vtable-flag-goops-class))

	(define-inlinable (class-add-flags! class flags)
	(struct-set!/unboxed
	class
	class-index-flags
	(logior flags (struct-ref/unboxed class class-index-flags))))

	(define-inlinable (class-clear-flags! class flags)
	(struct-set!/unboxed
	class
	class-index-flags
	(logand (lognot flags) (struct-ref/unboxed class class-index-flags))))

	(define-inlinable (class-has-flags? class flags)
	(eqv? flags
	(logand (struct-ref/unboxed class class-index-flags) flags)))

	(define-inlinable (class? obj)
	(class-has-flags? (struct-vtable obj) vtable-flag-goops-metaclass))

	(define-inlinable (slot? obj)
	(and (struct? obj)
	(class-has-flags? (struct-vtable obj) vtable-flag-goops-slot)))

	(define-inlinable (instance? obj)
	(and (struct? obj)
	(class-has-flags? (struct-vtable obj) vtable-flag-goops-class)))

	(define (class-has-statically-allocated-slots? class)
	(class-has-flags? class vtable-flag-goops-static-slot-allocation))

	(define (class-has-indirect-instances? class)
	(class-has-flags? class vtable-flag-goops-indirect))

	(define (indirect-slots-need-migration? slots)
	(class-has-flags? (struct-vtable slots) vtable-flag-goops-needs-migration))

	;;;
	;;; Now that we know the slots that must be present in classes, and
	;;; their offsets, we can create the root of the class hierarchy.
	;;;
	;;; Note that the `direct-supers', `direct-slots', `cpl', and `slots'
	;;; fields will be updated later, once we can create slot definition
	;;; objects and once we have definitions for <top> and <object>.
	;;;
	(define <class>
	(let-syntax ((cons-layout
	;; A simple way to compute class layout for the concrete
	;; types used in <class>.
	(syntax-rules (<protected-read-only-slot>
	<hidden-slot>
	<protected-hidden-slot>)
	((_ (name) tail)
	(string-append "pw" tail))
	((_ (name #:class <protected-read-only-slot>) tail)
	(string-append "pw" tail))
	((_ (name #:class <hidden-slot>) tail)
	(string-append "uh" tail))
	((_ (name #:class <protected-hidden-slot>) tail)
	(string-append "ph" tail)))))
	(let* ((layout (fold-class-slots macro-fold-right cons-layout ""))
	(nfields (/ (string-length layout) 2))
	(<class> (%make-vtable-vtable layout)))
	(class-add-flags! <class> vtable-flag-goops-class)
	(struct-set! <class> class-index-name '<class>)
	(struct-set!/unboxed <class> class-index-nfields nfields)
	(struct-set! <class> class-index-direct-supers '())
	(struct-set! <class> class-index-direct-slots '())
	(struct-set! <class> class-index-direct-subclasses '())
	(struct-set! <class> class-index-direct-methods '())
	(struct-set! <class> class-index-cpl '())
	(struct-set! <class> class-index-slots '())
	<class>)))

	;;;
	;;; Accessors to fields of <class>.
	;;;
	(define-syntax-rule (define-class-accessor name docstring field)
	(define (name obj)
	docstring
	(let ((val obj))
	(unless (class? val)
	(scm-error 'wrong-type-arg #f "Not a class: ~S"
	(list val) #f))
	(struct-ref val field))))

	(define-class-accessor class-name
	"Return the class name of @var{obj}."
	class-index-name)
	(define-class-accessor class-direct-supers
	"Return the direct superclasses of the class @var{obj}."
	class-index-direct-supers)
	(define-class-accessor class-direct-slots
	"Return the direct slots of the class @var{obj}."
	class-index-direct-slots)
	(define-class-accessor class-direct-subclasses
	"Return the direct subclasses of the class @var{obj}."
	class-index-direct-subclasses)
	(define-class-accessor class-direct-methods
	"Return the direct methods of the class @var{obj}."
	class-index-direct-methods)
	(define-class-accessor class-precedence-list
	"Return the class precedence list of the class @var{obj}."
	class-index-cpl)
	(define-class-accessor class-slots
	"Return the slot list of the class @var{obj}."
	class-index-slots)

	(define (class-subclasses c)
	"Compute a list of all subclasses of @var{c}, direct and indirect."
	(define (all-subclasses c)
	(cons c (append-map all-subclasses
	(class-direct-subclasses c))))
	(delete-duplicates (cdr (all-subclasses c)) eq?))

	(define (class-methods c)
	"Compute a list of all methods that specialize on @var{c} or
	subclasses of @var{c}."
	(delete-duplicates (append-map class-direct-methods
	(cons c (class-subclasses c)))
	eq?))

	(define (is-a? obj class)
	"Return @code{#t} if @var{obj} is an instance of @var{class}, or
	@code{#f} otherwise."
	(and (memq class (class-precedence-list (class-of obj))) #t))




	;;;
	;;; At this point, <class> is missing slot definitions, but we can't
	;;; create slot definitions until we have a slot definition class.
	;;; Continue with manual object creation until we're able to bootstrap
	;;; more of the protocol. Again, the CPL and class hierarchy slots
	;;; remain uninitialized.
	;;;
	(define* (get-keyword key l #:optional default)
	"Determine an associated value for the keyword @var{key} from the list
	@var{l}. The list @var{l} has to consist of an even number of elements,
	where, starting with the first, every second element is a keyword,
	followed by its associated value. If @var{l} does not hold a value for
	@var{key}, the value @var{default} is returned."
	(unless (keyword? key)
	(scm-error 'wrong-type-arg #f "Not a keyword: ~S" (list key) #f))
	(let lp ((l l))
	(match l
	(() default)
	((kw arg . l)
	(unless (keyword? kw)
	(scm-error 'wrong-type-arg #f "Not a keyword: ~S" (list kw) #f))
	(if (eq? kw key) arg (lp l))))))

	(define unbound (list 'unbound))

	(define-inlinable (unbound? x)
	(eq? x unbound))

	(define (%allocate-instance class)
	(let ((obj (allocate-struct class
	(struct-ref/unboxed class class-index-nfields))))
	(%clear-fields! obj unbound)
	obj))

	(define <slot>
	(let-syntax ((cons-layout
	;; All slots are "pw" in <slot>.
	(syntax-rules ()
	((_ _ tail) (string-append "pw" tail)))))
	(let* ((layout (fold-slot-slots macro-fold-right cons-layout ""))
	(nfields (/ (string-length layout) 2))
	(<slot> (make-struct/no-tail <class> (make-struct-layout layout))))
	(class-add-flags! <slot> (logior vtable-flag-goops-class
	vtable-flag-goops-slot))
	(struct-set! <slot> class-index-name '<slot>)
	(struct-set!/unboxed <slot> class-index-nfields nfields)
	(struct-set! <slot> class-index-direct-supers '())
	(struct-set! <slot> class-index-direct-slots '())
	(struct-set! <slot> class-index-direct-subclasses '())
	(struct-set! <slot> class-index-direct-methods '())
	(struct-set! <slot> class-index-cpl (list <slot>))
	(struct-set! <slot> class-index-slots '())
	<slot>)))

	;;; Access to slot objects is performance-sensitive for slot-ref, so in
	;;; addition to the type-checking accessors that we export, we also
	;;; define some internal inlined helpers that just do an unchecked
	;;; struct-ref in cases where we know the object must be a slot, as
	;;; when accessing class-slots.
	;;;
	(define-syntax-rule (define-slot-accessor name docstring %name field)
	(begin
	(define-syntax-rule (%name obj)
	(struct-ref obj field))
	(define (name obj)
	docstring
	(unless (slot? obj)
	(scm-error 'wrong-type-arg #f "Not a slot: ~S"
	(list obj) #f))
	(%name obj))))

	(define-slot-accessor slot-definition-name
	"Return the name of @var{obj}."
	%slot-definition-name slot-index-name)
	(define-slot-accessor slot-definition-allocation
	"Return the allocation of the slot @var{obj}."
	%slot-definition-allocation slot-index-allocation)
	(define-slot-accessor slot-definition-init-keyword
	"Return the init keyword of the slot @var{obj}, or @code{#f}."
	%slot-definition-init-keyword slot-index-init-keyword)
	(define-slot-accessor slot-definition-init-form
	"Return the init form of the slot @var{obj}, or the unbound value"
	%slot-definition-init-form slot-index-init-form)
	(define-slot-accessor slot-definition-init-value
	"Return the init value of the slot @var{obj}, or the unbound value."
	%slot-definition-init-value slot-index-init-value)
	(define-slot-accessor slot-definition-init-thunk
	"Return the init thunk of the slot @var{obj}, or @code{#f}."
	%slot-definition-init-thunk slot-index-init-thunk)
	(define-slot-accessor slot-definition-options
	"Return the initargs given when creating the slot @var{obj}."
	%slot-definition-options slot-index-options)
	(define-slot-accessor slot-definition-getter
	"Return the getter of the slot @var{obj}, or @code{#f}."
	%slot-definition-getter slot-index-getter)
	(define-slot-accessor slot-definition-setter
	"Return the setter of the slot @var{obj}, or @code{#f}."
	%slot-definition-setter slot-index-setter)
	(define-slot-accessor slot-definition-accessor
	"Return the accessor of the slot @var{obj}, or @code{#f}."
	%slot-definition-accessor slot-index-accessor)
	(define-slot-accessor slot-definition-slot-ref/raw
	"Return the raw slot-ref procedure of the slot @var{obj}."
	%slot-definition-slot-ref/raw slot-index-slot-ref/raw)
	(define-slot-accessor slot-definition-slot-ref
	"Return the slot-ref procedure of the slot @var{obj}."
	%slot-definition-slot-ref slot-index-slot-ref)
	(define-slot-accessor slot-definition-slot-set!
	"Return the slot-set! procedure of the slot @var{obj}."
	%slot-definition-slot-set! slot-index-slot-set!)
	(define-slot-accessor slot-definition-index
	"Return the allocated struct offset of the slot @var{obj}, or @code{#f}."
	%slot-definition-index slot-index-index)
	(define-slot-accessor slot-definition-size
	"Return the number fields used by the slot @var{obj}, or @code{#f}."
	%slot-definition-size slot-index-size)

	;; Boot definition.
	(define (direct-slot-definition-class class initargs)
	(get-keyword #:class initargs <slot>))

	;; Boot definition.
	(define (make-slot class initargs)
	(let ((slot (make-struct/no-tail class)))
	(define-syntax-rule (init-slot offset kw default)
	(struct-set! slot offset (get-keyword kw initargs default)))
	(init-slot slot-index-name #:name #f)
	(init-slot slot-index-allocation #:allocation #:instance)
	(init-slot slot-index-init-keyword #:init-keyword #f)
	(init-slot slot-index-init-form #:init-form unbound)
	(init-slot slot-index-init-value #:init-value unbound)
	(struct-set! slot slot-index-init-thunk
	(or (get-keyword #:init-thunk initargs #f)
	(let ((val (%slot-definition-init-value slot)))
	(if (unbound? val)
	#f
	(lambda () val)))))
	(struct-set! slot slot-index-options initargs)
	(init-slot slot-index-getter #:getter #f)
	(init-slot slot-index-setter #:setter #f)
	(init-slot slot-index-accessor #:accessor #f)
	(struct-set! slot slot-index-slot-ref/raw #f)
	(struct-set! slot slot-index-slot-ref #f)
	(struct-set! slot slot-index-slot-set! #f)
	(struct-set! slot slot-index-index #f)
	(struct-set! slot slot-index-size #f)
	slot))

	;; Boot definition.
	(define (make class . args)
	(unless (memq <slot> (class-precedence-list class))
	(error (format #f "Unsupported class: ~S" class)))
	(make-slot class args))

	;; Boot definition.
	(define (compute-direct-slot-definition class initargs)
	(apply make (direct-slot-definition-class class initargs) initargs))

	(define (compute-direct-slot-definition-initargs class slot-spec)
	(match slot-spec
	((? symbol? name) (list #:name name))
	(((? symbol? name) . initargs)
	(cons* #:name name
	;; If there is an #:init-form, the `class' macro will have
	;; already added an #:init-thunk. Still, if there isn't an
	;; #:init-thunk already but we do have an #:init-value,
	;; synthesize an #:init-thunk initarg. This will ensure
	;; that the #:init-thunk gets passed on to the effective
	;; slot definition too.
	(if (get-keyword #:init-thunk initargs)
	initargs
	(let ((value (get-keyword #:init-value initargs unbound)))
	(if (unbound? value)
	initargs
	(cons* #:init-thunk (lambda () value) initargs))))))))

	(let ()
	(define-syntax cons-slot
	(syntax-rules ()
	((_ (name #:class class) tail)
	;; Special case to avoid referencing specialized <slot> kinds,
	;; which are not defined yet.
	(cons (list 'name) tail))
	((_ (name . initargs) tail)
	(cons (list 'name . initargs) tail))))
	(define-syntax-rule (initialize-direct-slots! class fold-slots)
	(let ((specs (fold-slots macro-fold-right cons-slot '())))
	(define (make-direct-slot-definition spec)
	(let ((initargs (compute-direct-slot-definition-initargs class spec)))
	(compute-direct-slot-definition class initargs)))
	(struct-set! class class-index-direct-slots
	(map make-direct-slot-definition specs))))

	(initialize-direct-slots! <class> fold-class-slots)
	(initialize-direct-slots! <slot> fold-slot-slots))




	;;;
	;;; OK, at this point we have initialized `direct-slots' on both <class>
	;;; and <slot>. We need to define a standard way to make subclasses:
	;;; how to compute the precedence list of subclasses, how to compute the
	;;; list of slots in a subclass, and what layout to use for instances of
	;;; those classes.
	;;;
	(define (compute-std-cpl c get-direct-supers)
	"The standard class precedence list computation algorithm."
	(define (only-non-null lst)
	(filter (lambda (l) (not (null? l))) lst))

	(define (merge-lists reversed-partial-result inputs)
	(cond
	((every null? inputs)
	(reverse! reversed-partial-result))
	(else
	(let* ((candidate (lambda (c)
	(and (not (any (lambda (l)
	(memq c (cdr l)))
	inputs))
	c)))
	(candidate-car (lambda (l)
	(and (not (null? l))
	(candidate (car l)))))
	(next (any candidate-car inputs)))
	(unless next
	(goops-error "merge-lists: Inconsistent precedence graph"))
	(let ((remove-next (lambda (l)
	(if (eq? (car l) next)
	(cdr l)
	l))))
	(merge-lists (cons next reversed-partial-result)
	(only-non-null (map remove-next inputs))))))))
	(let ((c-direct-supers (get-direct-supers c)))
	(merge-lists (list c)
	(only-non-null (append (map class-precedence-list
	c-direct-supers)
	(list c-direct-supers))))))

	;; This version of compute-cpl is replaced with a generic function once
	;; GOOPS has booted.
	(define (compute-cpl class)
	(compute-std-cpl class class-direct-supers))

	(define (effective-slot-definition-class class slot)
	(class-of slot))

	(define (compute-effective-slot-definition class slot)
	;; FIXME: Support slot being a list of slots, as in CLOS.
	(apply make
	(effective-slot-definition-class class slot)
	(slot-definition-options slot)))

	(define (build-slots-list dslots cpl)
	(define (slot-memq slot slots)
	(let ((name (%slot-definition-name slot)))
	(let lp ((slots slots))
	(match slots
	(() #f)
	((slot . slots)
	(or (eq? (%slot-definition-name slot) name) (lp slots)))))))
	(define (check-cpl slots static-slots)
	(match static-slots
	(() #t)
	((static-slot . static-slots)
	(when (slot-memq static-slot slots)
	(scm-error 'misc-error #f
	"statically allocated inherited field cannot be redefined: ~a"
	(list (%slot-definition-name static-slot)) '()))
	(check-cpl slots static-slots))))
	(define (remove-duplicate-slots slots)
	(let lp ((slots (reverse slots)) (res '()) (seen '()))
	(match slots
	(() res)
	((slot . slots)
	(let ((name (%slot-definition-name slot)))
	(if (memq name seen)
	(lp slots res seen)
	(lp slots (cons slot res) (cons name seen))))))))
	;; For subclases of <class> and <slot>, we need to ensure that the
	;; <class> or <slot> slots come first.
	(let ((static-slots
	(match (filter class-has-statically-allocated-slots? (cdr cpl))
	(() #f)
	((class) (struct-ref class class-index-direct-slots))
	(classes
	(error "can't subtype multiple classes with static slot allocation"
	classes)))))
	(when static-slots
	(check-cpl dslots static-slots))
	(let lp ((cpl (cdr cpl)) (res dslots) (static-slots '()))
	(match cpl
	(() (remove-duplicate-slots (append static-slots res)))
	((head . cpl)
	(let ((new-slots (struct-ref head class-index-direct-slots)))
	(cond
	((not static-slots)
	(lp cpl (append new-slots res) static-slots))
	((class-has-statically-allocated-slots? head)
	;; Move static slots to the head of the list.
	(lp cpl res new-slots))
	(else
	(check-cpl new-slots static-slots)
	(lp cpl (append new-slots res) static-slots)))))))))

	;; Boot definition.
	(define (compute-get-n-set class slot)
	(let ((index (struct-ref/unboxed class class-index-nfields)))
	(struct-set!/unboxed class class-index-nfields (1+ index))
	index))

	;;; Pre-generate getters and setters for the first 20 slots.
	(define-syntax define-standard-accessor-method
	(lambda (stx)
	(define num-standard-pre-cache 20)
	(syntax-case stx ()
	((_ ((proc n) arg ...) body)
	#`(define proc
	(let ((cache (vector #,@(map (lambda (n*)
	#`(lambda (arg ...)
	(let ((n #,n*))
	body)))
	(iota num-standard-pre-cache)))))
	(lambda (n)
	(if (< n #,num-standard-pre-cache)
	(vector-ref cache n)
	(lambda (arg ...) body)))))))))

	(define-standard-accessor-method ((bound-check-get n) o)
	(let ((x (struct-ref o n)))
	(if (unbound? x)
	(slot-unbound o)
	x)))

	(define-standard-accessor-method ((standard-get n) o)
	(struct-ref o n))

	(define-standard-accessor-method ((standard-set n) o v)
	(struct-set! o n v))

	(define-standard-accessor-method ((unboxed-get n) o)
	(struct-ref/unboxed o n))

	(define-standard-accessor-method ((unboxed-set n) o v)
	(struct-set!/unboxed o n v))

	;; Boot definitions.
	(define (opaque-slot? slot) #f)
	(define (read-only-slot? slot) #f)
	(define (unboxed-slot? slot)
	(memq (%slot-definition-name slot)
	'(flags instance-finalizer nfields %reserved-6 %reserved-7)))

	(define (allocate-slots class slots)
	"Transform the computed list of direct slot definitions @var{slots}
	into a corresponding list of effective slot definitions, allocating
	slots as we go."
	(define (make-effective-slot-definition slot)
	;; `compute-get-n-set' is expected to mutate `nfields' if it
	;; allocates a field to the object. Pretty strange, but we preserve
	;; the behavior for backward compatibility.
	(let* ((slot (compute-effective-slot-definition class slot))
	(name (%slot-definition-name slot))
	(index (struct-ref/unboxed class class-index-nfields))
	(g-n-s (compute-get-n-set class slot))
	(size (- (struct-ref/unboxed class class-index-nfields) index)))
	(call-with-values
	(lambda ()
	(match g-n-s
	((? integer?)
	(unless (= size 1)
	(error "unexpected return from compute-get-n-set"))
	(cond
	((unboxed-slot? slot)
	(let ((get (unboxed-get g-n-s)))
	(values get get (unboxed-set g-n-s))))
	(else
	(values (standard-get g-n-s)
	(if (slot-definition-init-thunk slot)
	(standard-get g-n-s)
	(bound-check-get g-n-s))
	(standard-set g-n-s)))))
	(((? procedure? get) (? procedure? set))
	(values get
	(lambda (o)
	(let ((value (get o)))
	(if (unbound? value)
	(slot-unbound class o name)
	value)))
	set))))
	(lambda (get/raw get set)
	(let ((get (if (opaque-slot? slot)
	(lambda (o)
	(error "Slot is opaque" name))
	get))
	(set (cond
	((opaque-slot? slot)
	(lambda (o v)
	(error "Slot is opaque" name)))
	((read-only-slot? slot)
	(if (unboxed-slot? slot)
	(lambda (o v)
	(let ((v* (get/raw o)))
	(if (zero? v*)
	;; Allow initialization.
	(set o v)
	(error "Slot is read-only" name))))
	(lambda (o v)
	(let ((v* (get/raw o)))
	(if (unbound? v*)
	;; Allow initialization.
	(set o v)
	(error "Slot is read-only" name))))))
	(else set))))
	(struct-set! slot slot-index-slot-ref/raw get/raw)
	(struct-set! slot slot-index-slot-ref get)
	(struct-set! slot slot-index-slot-set! set)
	(struct-set! slot slot-index-index index)
	(struct-set! slot slot-index-size size))))
	slot))
	(struct-set!/unboxed class class-index-nfields 0)
	(map-in-order make-effective-slot-definition slots))

	(define (%compute-layout slots nfields is-class?)
	(define (slot-protection-and-kind slot)
	(define (subclass? class parent)
	(memq parent (class-precedence-list class)))
	(let ((type (get-keyword #:class (%slot-definition-options slot))))
	(if (and type (subclass? type <foreign-slot>))
	(values (cond
	((subclass? type <protected-slot>) #\p)
	(else #\u))
	(cond
	((subclass? type <hidden-slot>) #\h)
	(else #\w)))
	(values #\p #\w))))
	(let ((layout (make-string (* nfields 2))))
	(let lp ((n 0) (slots slots))
	(match slots
	(()
	(unless (= n nfields) (error "bad nfields"))
	(when is-class?
	(let ((class-layout (struct-ref <class> class-index-layout)))
	(unless (string-prefix? (symbol->string class-layout) layout)
	(error "bad layout for class"))))
	layout)
	((slot . slots)
	(unless (= n (%slot-definition-index slot)) (error "bad allocation"))
	(call-with-values (lambda () (slot-protection-and-kind slot))
	(lambda (protection kind)
	(let init ((n n) (size (%slot-definition-size slot)))
	(cond
	((zero? size) (lp n slots))
	(else
	(unless (< n nfields) (error "bad nfields"))
	(string-set! layout (* n 2) protection)
	(string-set! layout (1+ (* n 2)) kind)
	(init (1+ n) (1- size))))))))))))




	;;;
	;;; With all of this, we are now able to define subclasses of <class>.
	;;;
	(define (%prep-layout! class)
	(let* ((is-class? (and (memq <class> (struct-ref class class-index-cpl)) #t))
	(layout (%compute-layout (struct-ref class class-index-slots)
	(struct-ref/unboxed class class-index-nfields)
	is-class?)))
	(%init-layout! class layout)))

	(define (make-standard-class class name dsupers dslots)
	(let ((z (make-struct/no-tail class)))
	(define (make-direct-slot-definition dslot)
	(let ((initargs (compute-direct-slot-definition-initargs z dslot)))
	(compute-direct-slot-definition z initargs)))

	(struct-set! z class-index-name name)
	(struct-set!/unboxed z class-index-nfields 0)
	(struct-set! z class-index-direct-supers dsupers)
	(struct-set! z class-index-direct-subclasses '())
	(struct-set! z class-index-direct-methods '())
	(let ((cpl (compute-cpl z)))
	(struct-set! z class-index-cpl cpl)
	(when (memq <slot> cpl)
	(class-add-flags! z vtable-flag-goops-slot))
	(let* ((dslots (map make-direct-slot-definition dslots))
	(slots (allocate-slots z (build-slots-list dslots cpl))))
	(struct-set! z class-index-direct-slots dslots)
	(struct-set! z class-index-slots slots)))
	(for-each
	(lambda (super)
	(let ((subclasses (struct-ref super class-index-direct-subclasses)))
	(struct-set! super class-index-direct-subclasses
	(cons z subclasses))))
	dsupers)
	(%prep-layout! z)
	z))

	(define-syntax define-standard-class
	(syntax-rules ()
	((define-standard-class name (super ...) #:metaclass meta slot ...)
	(define name
	(make-standard-class meta 'name (list super ...) '(slot ...))))
	((define-standard-class name (super ...) slot ...)
	(define-standard-class name (super ...) #:metaclass <class> slot ...))))




	;;;
	;;; Sweet! Now we can define <top> and <object>, and finish
	;;; initializing the `direct-subclasses', `direct-supers', and `cpl'
	;;; slots of <class>.
	;;;
	(define-standard-class <top> ())
	(define-standard-class <object> (<top>))

	;; The inheritance links for <top>, <object>, <class>, and <slot> were
	;; partially initialized. Correct them here.
	(struct-set! <object> class-index-direct-subclasses (list <slot> <class>))
	(struct-set! <class> class-index-direct-supers (list <object>))
	(struct-set! <slot> class-index-direct-supers (list <object>))
	(struct-set! <class> class-index-cpl (list <class> <object> <top>))
	(struct-set! <slot> class-index-cpl (list <slot> <object> <top>))




	;;;
	;;; We can also define the various slot types, and finish initializing
	;;; `direct-slots' and `slots' on <class> and <slot>.
	;;;
	(define-standard-class <foreign-slot> (<slot>))
	(define-standard-class <protected-slot> (<foreign-slot>))
	(define-standard-class <hidden-slot> (<foreign-slot>))
	(define-standard-class <opaque-slot> (<foreign-slot>))
	(define-standard-class <read-only-slot> (<foreign-slot>))
	(define-standard-class <protected-opaque-slot> (<protected-slot>
	<opaque-slot>))
	(define-standard-class <protected-hidden-slot> (<protected-slot>
	<hidden-slot>))
	(define-standard-class <protected-read-only-slot> (<protected-slot>
	<read-only-slot>))
	(define-standard-class <scm-slot> (<protected-slot>))

	(define (opaque-slot? slot) (is-a? slot <opaque-slot>))
	(define (read-only-slot? slot) (is-a? slot <read-only-slot>))
	(define (unboxed-slot? slot)
	(and (is-a? slot <foreign-slot>)
	(not (is-a? slot <protected-slot>))))



	;;;
	;;; Finally! Initialize `direct-slots' and `slots' on <class>, and
	;;; `slots' on <slot>.
	;;;
	(let ()
	(define-syntax-rule (cons-slot (name . initargs) tail)
	(cons (list 'name . initargs) tail))
	(define-syntax-rule (initialize-direct-slots! class fold-slots)
	(let ((specs (fold-slots macro-fold-right cons-slot '())))
	(define (make-direct-slot-definition spec)
	(let ((initargs (compute-direct-slot-definition-initargs class spec)))
	(compute-direct-slot-definition class initargs)))
	(struct-set! class class-index-direct-slots
	(map make-direct-slot-definition specs))))
	;; Boot definition that avoids munging nfields.
	(define (allocate-slots class slots)
	(define (make-effective-slot-definition slot index)
	(let* ((slot (compute-effective-slot-definition class slot))
	(get/raw (standard-get index))
	(set/raw (standard-set index)))
	(struct-set! slot slot-index-slot-ref/raw (standard-get index))
	(struct-set! slot slot-index-slot-ref
	(if (slot-definition-init-thunk slot)
	get/raw
	(bound-check-get index)))
	(struct-set! slot slot-index-slot-set!
	(if (read-only-slot? slot)
	(lambda (o v)
	(let ((v* (get/raw o)))
	(if (unbound? v*)
	;; Allow initialization.
	(set/raw o v)
	(error "Slot is read-only" slot))))
	set/raw))
	(struct-set! slot slot-index-index index)
	(struct-set! slot slot-index-size 1)
	slot))
	(map make-effective-slot-definition slots (iota (length slots))))
	(define (initialize-slots! class)
	(let ((slots (build-slots-list (class-direct-slots class)
	(class-precedence-list class))))
	(struct-set! class class-index-slots (allocate-slots class slots))))

	;; Finish initializing <class> with the specialized slot kinds.
	(initialize-direct-slots! <class> fold-class-slots)

	(initialize-slots! <class>)
	(initialize-slots! <slot>)

	;; Now that we're all done with that, mark <class> and <slot> as
	;; static.
	(class-add-flags! <class> vtable-flag-goops-static-slot-allocation)
	(class-add-flags! <slot> vtable-flag-goops-static-slot-allocation))




	;;;
	;;; Now, to build out the class hierarchy.
	;;;

	(define-standard-class <procedure-class> (<class>))

	(define-standard-class <applicable-struct-class>
	(<procedure-class>))
	(class-add-flags! <applicable-struct-class>
	vtable-flag-applicable-vtable)

	(define-standard-class <applicable-struct-with-setter-class>
	(<applicable-struct-class>))
	(class-add-flags! <applicable-struct-with-setter-class>
	vtable-flag-setter-vtable)

	(define-standard-class <applicable> (<top>))
	(define-standard-class <applicable-struct> (<object> <applicable>)
	#:metaclass <applicable-struct-class>
	procedure)
	(define-standard-class <applicable-struct-with-setter> (<applicable-struct>)
	#:metaclass <applicable-struct-with-setter-class>
	setter)
	(define-standard-class <generic> (<applicable-struct>)
	#:metaclass <applicable-struct-class>
	methods
	(n-specialized #:init-value 0)
	(extended-by #:init-value ())
	effective-methods)
	(define-standard-class <extended-generic> (<generic>)
	#:metaclass <applicable-struct-class>
	(extends #:init-value ()))
	(define-standard-class <generic-with-setter> (<generic>
	<applicable-struct-with-setter>)
	#:metaclass <applicable-struct-with-setter-class>)
	(define-standard-class <accessor> (<generic-with-setter>)
	#:metaclass <applicable-struct-with-setter-class>)
	(define-standard-class <extended-generic-with-setter> (<extended-generic>
	<generic-with-setter>)
	#:metaclass <applicable-struct-with-setter-class>)
	(define-standard-class <extended-accessor> (<accessor>
	<extended-generic-with-setter>)
	#:metaclass <applicable-struct-with-setter-class>)

	(define-standard-class <method> (<object>)
	generic-function
	specializers
	procedure
	formals
	body
	make-procedure)
	(define-standard-class <accessor-method> (<method>)
	(slot-definition #:init-keyword #:slot-definition))

	(define-standard-class <boolean> (<top>))
	(define-standard-class <char> (<top>))
	(define-standard-class <list> (<top>))
	;; Not all pairs are lists, but there is code out there that relies on
	;; (is-a? '(1 2 3) <list>) to work. Terrible. How to fix?
	(define-standard-class <pair> (<list>))
	(define-standard-class <null> (<list>))
	(define-standard-class <string> (<top>))
	(define-standard-class <symbol> (<top>))
	(define-standard-class <vector> (<top>))
	(define-standard-class <foreign> (<top>))
	(define-standard-class <hashtable> (<top>))
	(define-standard-class <fluid> (<top>))
	(define-standard-class <dynamic-state> (<top>))
	(define-standard-class <frame> (<top>))
	(define-standard-class <vm-continuation> (<top>))
	(define-standard-class <bytevector> (<top>))
	(define-standard-class <uvec> (<bytevector>))
	(define-standard-class <array> (<top>))
	(define-standard-class <bitvector> (<top>))
	(define-standard-class <number> (<top>))
	(define-standard-class <complex> (<number>))
	(define-standard-class <real> (<complex>))
	(define-standard-class <integer> (<real>))
	(define-standard-class <fraction> (<real>))
	(define-standard-class <keyword> (<top>))
	(define-standard-class <syntax> (<top>))
	(define-standard-class <atomic-box> (<top>))
	(define-standard-class <unknown> (<top>))
	(define-standard-class <procedure> (<applicable>)
	#:metaclass <procedure-class>)
	(define-standard-class <primitive-generic> (<procedure>)
	#:metaclass <procedure-class>)
	(define-standard-class <port> (<top>))
	(define-standard-class <input-port> (<port>))
	(define-standard-class <output-port> (<port>))
	(define-standard-class <input-output-port> (<input-port> <output-port>))

	(define (inherit-applicable! class)
	"An internal routine to redefine a SMOB class that was added after
	GOOPS was loaded, and on which scm_set_smob_apply installed an apply
	function."
	(unless (memq <applicable> (class-precedence-list class))
	(unless (null? (class-slots class))
	(error "SMOB object has slots?"))
	(for-each
	(lambda (super)
	(let ((subclasses (struct-ref super class-index-direct-subclasses)))
	(struct-set! super class-index-direct-subclasses
	(delq class subclasses))))
	(struct-ref class class-index-direct-supers))
	(struct-set! class class-index-direct-supers (list <applicable>))
	(struct-set! class class-index-cpl (compute-cpl class))
	(let ((subclasses (struct-ref <applicable> class-index-direct-subclasses)))
	(struct-set! <applicable> class-index-direct-subclasses
	(cons class subclasses)))))




	;;;
	;;; At this point we have defined the class hierarchy, and it's time to
	;;; move on to instance allocation and generics. Once we have generics,
	;;; we'll fill out the metaobject protocol.
	;;;
	;;; Here we define a limited version of `make', so that we can allocate
	;;; instances of specific classes. This definition will be replaced
	;;; later.
	;;;
	(define (%invalidate-method-cache! gf)
	(slot-set! gf 'effective-methods '())
	(recompute-generic-function-dispatch-procedure! gf))

	;; Boot definition.
	(define (invalidate-method-cache! gf)
	(%invalidate-method-cache! gf))

	(define (make class . args)
	(cond
	((or (eq? class <generic>) (eq? class <accessor>))
	(let ((z (make-struct/no-tail class #f '() 0 '())))
	(set-procedure-property! z 'name (get-keyword #:name args #f))
	(invalidate-method-cache! z)
	(when (eq? class <accessor>)
	(let ((setter (get-keyword #:setter args #f)))
	(when setter
	(slot-set! z 'setter setter))))
	z))
	(else
	(let ((z (%allocate-instance class)))
	(cond
	((or (eq? class <method>) (eq? class <accessor-method>))
	(for-each (match-lambda
	((kw slot default)
	(slot-set! z slot (get-keyword kw args default))))
	'((#:generic-function generic-function #f)
	(#:specializers specializers ())
	(#:procedure procedure #f)
	(#:formals formals ())
	(#:body body ())
	(#:make-procedure make-procedure #f))))
	((memq <class> (class-precedence-list class))
	(class-add-flags! z vtable-flag-goops-class)
	(for-each (match-lambda
	((kw slot default)
	(slot-set! z slot (get-keyword kw args default))))
	'((#:name name ???)
	(#:dsupers direct-supers ())
	(#:slots direct-slots ()))))
	(else
	(error "boot `make' does not support this class" class)))
	z))))




	;;;
	;;; Slot access.
	;;;
	(define-inlinable (%class-slot-definition class slot-name kt kf)
	(let lp ((slots (struct-ref class class-index-slots)))
	(match slots
	((slot . slots)
	(if (eq? (%slot-definition-name slot) slot-name)
	(kt slot)
	(lp slots)))
	(_ (kf)))))

	(define (class-slot-definition class slot-name)
	(unless (class? class)
	(scm-error 'wrong-type-arg #f "Not a class: ~S" (list class) #f))
	(%class-slot-definition class slot-name
	(lambda (slot) slot)
	(lambda () #f)))

	(define (slot-ref obj slot-name)
	"Return the value from @var{obj}'s slot with the nam var{slot_name}."
	(let ((class (class-of obj)))
	(define (have-slot slot)
	((%slot-definition-slot-ref slot) obj))
	(define (no-slot)
	(unless (symbol? slot-name)
	(scm-error 'wrong-type-arg #f "Not a symbol: ~S"
	(list slot-name) #f))
	(let ((val (slot-missing class obj slot-name)))
	(if (unbound? val)
	(slot-unbound class obj slot-name)
	val)))
	(%class-slot-definition class slot-name have-slot no-slot)))

	(define (slot-set! obj slot-name value)
	"Set the slot named @var{slot_name} of @var{obj} to @var{value}."
	(let ((class (class-of obj)))
	(define (have-slot slot)
	((%slot-definition-slot-set! slot) obj value))
	(define (no-slot)
	(unless (symbol? slot-name)
	(scm-error 'wrong-type-arg #f "Not a symbol: ~S"
	(list slot-name) #f))
	(slot-missing class obj slot-name value))

	(%class-slot-definition class slot-name have-slot no-slot)))

	(define (slot-bound? obj slot-name)
	"Return the value from @var{obj}'s slot with the nam var{slot_name}."
	(let ((class (class-of obj)))
	(define (have-slot slot)
	(not (unbound? ((%slot-definition-slot-ref/raw slot) obj))))
	(define (no-slot)
	(unless (symbol? slot-name)
	(scm-error 'wrong-type-arg #f "Not a symbol: ~S"
	(list slot-name) #f))
	(not (unbound? (slot-missing class obj slot-name))))
	(%class-slot-definition class slot-name have-slot no-slot)))

	(define (slot-exists? obj slot-name)
	"Return @code{#t} if @var{obj} has a slot named @var{slot_name}."
	(define (have-slot slot) #t)
	(define (no-slot)
	(unless (symbol? slot-name)
	(scm-error 'wrong-type-arg #f "Not a symbol: ~S"
	(list slot-name) #f))
	#f)
	(%class-slot-definition (class-of obj) slot-name have-slot no-slot))




	;;;
	;;; Method accessors.
	;;;
	(define (method-generic-function obj)
	"Return the generic function for the method @var{obj}."
	(unless (is-a? obj <method>)
	(scm-error 'wrong-type-arg #f "Not a method: ~S"
	(list obj) #f))
	(slot-ref obj 'generic-function))

	(define (method-specializers obj)
	"Return specializers of the method @var{obj}."
	(unless (is-a? obj <method>)
	(scm-error 'wrong-type-arg #f "Not a method: ~S"
	(list obj) #f))
	(slot-ref obj 'specializers))

	(define (method-procedure obj)
	"Return the procedure of the method @var{obj}."
	(unless (is-a? obj <method>)
	(scm-error 'wrong-type-arg #f "Not a method: ~S"
	(list obj) #f))
	(slot-ref obj 'procedure))




	;;;
	;;; Generic functions!
	;;;
	;;; Generic functions have an applicable-methods cache associated with
	;;; them. Every distinct set of types that is dispatched through a
	;;; generic adds an entry to the cache. A composite dispatch procedure
	;;; is recomputed every time an entry gets added to the cache, or when
	;;; the cache is invalidated.
	;;;
	;;; In steady-state, this dispatch procedure is never regenerated; but
	;;; during warm-up there is some churn.
	;;;
	;;; So what is the deal if warm-up happens in a multithreaded context?
	;;; There is indeed a window between missing the cache for a certain set
	;;; of arguments, and then updating the cache with the newly computed
	;;; applicable methods. One of the updaters is liable to lose their new
	;;; entry.
	;;;
	;;; This is actually OK though, because a subsequent cache miss for the
	;;; race loser will just cause memoization to try again. The cache will
	;;; eventually be consistent. We're not mutating the old part of the
	;;; cache, just consing on the new entry.
	;;;
	;;; It doesn't even matter if the dispatch procedure and the cache are
	;;; inconsistent -- most likely the type-set that lost the dispatch
	;;; procedure race will simply re-trigger a memoization, but since the
	;;; winner isn't in the effective-methods cache, it will likely also
	;;; re-trigger a memoization, and the cache will finally be consistent.
	;;; As you can see there is a possibility for ping-pong effects, but
	;;; it's unlikely given the shortness of the window between slot-set!
	;;; invocations.
	;;;
	;;; We probably do need to use atomic access primitives to correctly
	;;; handle concurrency, but that's a more general Guile concern.
	;;;

	(define-syntax arity-case
	(lambda (x)
	(syntax-case x ()
	;; (arity-case n 2 foo bar)
	;; => (case n
	;; ((0) (foo))
	;; ((1) (foo a))
	;; ((2) (foo a b))
	;; (else bar))
	((arity-case n max form alternate)
	(let ((max (syntax->datum #'max)))
	#`(case n
	#,@(let lp ((n 0))
	(let ((ids (map (lambda (n)
	(let* ((n (+ (char->integer #\a) n))
	(c (integer->char n)))
	(datum->syntax #'here (symbol c))))
	(iota n))))
	#`(((#,n) (form #,@ids))
	. #,(if (< n max)
	(lp (1+ n))
	#'()))))
	(else alternate)))))))

	;;;
	;;; These dispatchers are set as the "procedure" field of <generic>
	;;; instances. Unlike CLOS, in GOOPS a generic function can have
	;;; multiple arities.
	;;;
	;;; We pre-generate fast dispatchers for applications of up to 20
	;;; arguments. More arguments than that will go through slower generic
	;;; routines that cons arguments into a rest list.
	;;;
	(define (multiple-arity-dispatcher fv miss)
	(define-syntax dispatch
	(lambda (x)
	(define (build-clauses args)
	(let ((len (length (syntax->datum args))))
	#`((#,args ((vector-ref fv #,len) . #,args))
	. #,(syntax-case args ()
	(() #'())
	((arg ... _) (build-clauses #'(arg ...)))))))
	(syntax-case x ()
	((dispatch arg ...)
	#`(case-lambda
	#,@(build-clauses #'(arg ...))
	(args (apply miss args)))))))
	(arity-case (1- (vector-length fv)) 20 dispatch
	(lambda args
	(let ((nargs (length args)))
	(if (< nargs (vector-length fv))
	(apply (vector-ref fv nargs) args)
	(apply miss args))))))

	;;;
	;;; The above multiple-arity-dispatcher is entirely sufficient, and
	;;; should be fast enough. Still, for no good reason we also have an
	;;; arity dispatcher for generics that are only called with one arity.
	;;;
	(define (single-arity-dispatcher f nargs miss)
	(define-syntax-rule (dispatch arg ...)
	(case-lambda
	((arg ...) (f arg ...))
	(args (apply miss args))))
	(arity-case nargs 20 dispatch
	(lambda args
	(if (eqv? (length args) nargs)
	(apply f args)
	(apply miss args)))))

	;;;
	;;; The guts of generic function dispatch are here. Once we've selected
	;;; an arity, we need to map from arguments to effective method. Until
	;;; we have `eqv?' specializers, this map is entirely a function of the
	;;; types (classes) of the arguments. So, we look in the cache to see
	;;; if we have seen this set of concrete types, and if so we apply the
	;;; previously computed effective method. Otherwise we miss the cache,
	;;; so we'll have to compute the right answer for this set of types, add
	;;; the mapping to the cache, and apply the newly computed method.
	;;;
	;;; The cached mapping is invalidated whenever a new method is defined
	;;; on this generic, or whenever the class hierarchy of any method
	;;; specializer changes.
	;;;
	(define (single-arity-cache-dispatch cache nargs cache-miss)
	(match cache
	(() cache-miss)
	(((typev . cmethod) . cache)
	(cond
	((eqv? nargs (vector-length typev))
	(let ((cache-miss (single-arity-cache-dispatch cache nargs cache-miss)))
	(define (type-ref n)
	(and (< n nargs) (vector-ref typev n)))
	(define-syntax args-match?
	(syntax-rules ()
	((args-match?) #t)
	((args-match? (arg type) (arg* type*) ...)
	;; Check that the arg has the exact type that we saw. It
	;; could be that `type' is #f, which indicates the end of
	;; the specializers list. Once all specializers have been
	;; examined, we don't need to look at any more arguments
	;; to know that this is a cache hit.
	(or (not type)
	(and (eq? (class-of arg) type)
	(args-match? (arg* type*) ...))))))
	(define-syntax dispatch
	(lambda (x)
	(define (bind-types types k)
	(let lp ((types types) (n 0))
	(syntax-case types ()
	(() (k))
	((type . types)
	#`(let ((type (type-ref #,n)))
	#,(lp #'types (1+ n)))))))
	(syntax-case x ()
	((dispatch arg ...)
	(with-syntax (((type ...) (generate-temporaries #'(arg ...))))
	(bind-types
	#'(type ...)
	(lambda ()
	#'(lambda (arg ...)
	(if (args-match? (arg type) ...)
	(cmethod arg ...)
	(cache-miss arg ...))))))))))
	(arity-case nargs 20 dispatch
	(lambda args
	(define (args-match? args)
	(let lp ((args args) (n 0))
	(match args
	((arg . args)
	(or (not (vector-ref typev n))
	(and (eq? (vector-ref typev n) (class-of arg))
	(lp args (1+ n)))))
	(_ #t))))
	(if (args-match? args)
	(apply cmethod args)
	(apply cache-miss args))))))
	(else
	(single-arity-cache-dispatch cache nargs cache-miss))))))

	(define (compute-generic-function-dispatch-procedure gf)
	(define (seen-arities cache)
	(let lp ((arities 0) (cache cache))
	(match cache
	(() arities)
	(((typev . cmethod) . cache)
	(lp (logior arities (ash 1 (vector-length typev)))
	cache)))))
	(define (cache-miss . args)
	(memoize-generic-function-application! gf args)
	(apply gf args))
	(let* ((cache (slot-ref gf 'effective-methods))
	(arities (seen-arities cache))
	(max-arity (let lp ((max -1))
	(if (< arities (ash 1 (1+ max)))
	max
	(lp (1+ max))))))
	(cond
	((= max-arity -1)
	;; Nothing in the cache.
	cache-miss)
	((= arities (ash 1 max-arity))
	;; Only one arity in the cache.
	(let* ((nargs max-arity)
	(f (single-arity-cache-dispatch cache nargs cache-miss)))
	(single-arity-dispatcher f nargs cache-miss)))
	(else
	;; Multiple arities.
	(let ((fv (make-vector (1+ max-arity) #f)))
	(let lp ((n 0))
	(when (<= n max-arity)
	(let ((f (single-arity-cache-dispatch cache n cache-miss)))
	(vector-set! fv n f)
	(lp (1+ n)))))
	(multiple-arity-dispatcher fv cache-miss))))))

	(define (recompute-generic-function-dispatch-procedure! gf)
	(slot-set! gf 'procedure
	(compute-generic-function-dispatch-procedure gf)))

	(define (memoize-effective-method! gf args applicable)
	(define (record-types args)
	(let ((typev (make-vector (length args) #f)))
	(let lp ((n 0) (args args))
	(when (and (< n (slot-ref gf 'n-specialized))
	(pair? args))
	(match args
	((arg . args)
	(vector-set! typev n (class-of arg))
	(lp (1+ n) args)))))
	typev))
	(let* ((typev (record-types args))
	(compute-effective-method (if (eq? (class-of gf) <generic>)
	%compute-effective-method
	compute-effective-method))
	(cmethod (compute-effective-method gf applicable typev))
	(cache (acons typev cmethod (slot-ref gf 'effective-methods))))
	(slot-set! gf 'effective-methods cache)
	(recompute-generic-function-dispatch-procedure! gf)
	cmethod))

	;;;
	;;; If a method refers to `next-method' in its body, that method will be
	;;; able to dispatch to the next most specific method. The exact
	;;; `next-method' implementation is only known at runtime, as it is a
	;;; function of which precise argument types are being dispatched, which
	;;; might be subclasses of the method's declared specializers.
	;;;
	;;; Guile implements `next-method' by binding it as a closure variable.
	;;; An effective method is bound to a specific `next-method' by the
	;;; `make-procedure' slot of a <method>, which returns the new closure.
	;;;
	(define (%compute-specialized-effective-method gf method types next-method)
	(match (slot-ref method 'make-procedure)
	(#f (method-procedure method))
	(make-procedure (make-procedure next-method))))

	(define (compute-specialized-effective-method gf method types next-method)
	(%compute-specialized-effective-method gf method types next-method))

	(define (%compute-effective-method gf methods types)
	(match methods
	((method . methods)
	(let ((compute-specialized-effective-method
	(if (and (eq? (class-of gf) <generic>)
	(eq? (class-of method) <method>))
	%compute-specialized-effective-method
	compute-specialized-effective-method)))
	(compute-specialized-effective-method
	gf method types
	(match methods
	(()
	(lambda args
	(no-next-method gf args)))
	(methods
	(let ((compute-effective-method (if (eq? (class-of gf) <generic>)
	%compute-effective-method
	compute-effective-method)))
	(compute-effective-method gf methods types)))))))))

	;; Boot definition; overrided with a generic later.
	(define (compute-effective-method gf methods types)
	(%compute-effective-method gf methods types))

	;;;
	;;; Memoization
	;;;

	(define (memoize-generic-function-application! gf args)
	(let ((applicable ((if (eq? (class-of gf) <generic>)
	%compute-applicable-methods
	compute-applicable-methods)
	gf args)))
	(cond (applicable
	(memoize-effective-method! gf args applicable))
	(else
	(no-applicable-method gf args)))))

	(define no-applicable-method
	(make <generic> #:name 'no-applicable-method))

	(%goops-early-init)

	;; Then load the rest of GOOPS


	;; FIXME: deprecate.
	(define min-fixnum (- (expt 2 29)))
	(define max-fixnum (- (expt 2 29) 1))

	;;
	;; goops-error
	;;
	(define (goops-error format-string . args)
	(scm-error 'goops-error #f format-string args '()))

	;;;
	;;; {Meta classes}
	;;;

	(define ensure-metaclass-with-supers
	(let ((table-of-metas '()))
	(lambda (meta-supers)
	(let ((entry (assoc meta-supers table-of-metas)))
	(if entry
	;; Found a previously created metaclass
	(cdr entry)
	;; Create a new meta-class which inherit from "meta-supers"
	(let ((new (make <class> #:dsupers meta-supers
	#:slots '()
	#:name (gensym "metaclass"))))
	(set! table-of-metas (cons (cons meta-supers new) table-of-metas))
	new))))))

	(define (ensure-metaclass supers)
	(if (null? supers)
	<class>
	(let* ((all-metas (map (lambda (x) (class-of x)) supers))
	(all-cpls (append-map (lambda (m)
	(cdr (class-precedence-list m)))
	all-metas))
	(needed-metas '()))
	;; Find the most specific metaclasses. The new metaclass will be
	;; a subclass of these.
	(for-each
	(lambda (meta)
	(when (and (not (member meta all-cpls))
	(not (member meta needed-metas)))
	(set! needed-metas (append needed-metas (list meta)))))
	all-metas)
	;; Now return a subclass of the metaclasses we found.
	(if (null? (cdr needed-metas))
	(car needed-metas) ; If there's only one, just use it.
	(ensure-metaclass-with-supers needed-metas)))))

	;;;
	;;; {Classes}
	;;;

	;;; (define-class NAME (SUPER ...) SLOT-DEFINITION ... OPTION ...)
	;;;
	;;; SLOT-DEFINITION ::= INSTANCE-OF-<SLOT> \| (SLOT-NAME OPTION ...)
	;;; OPTION ::= KEYWORD VALUE
	;;;

	(define (make-class supers slots . options)
	(define (find-duplicate l)
	(match l
	(() #f)
	((head . tail)
	(if (memq head tail)
	head
	(find-duplicate tail)))))
	(define (slot-spec->name slot-spec)
	(match slot-spec
	(((? symbol? name) . args) name)
	;; We can get here when redefining classes.
	((? slot? slot) (%slot-definition-name slot))))

	(let* ((name (get-keyword #:name options unbound))
	(supers (if (not (or-map (lambda (class)
	(memq <object>
	(class-precedence-list class)))
	supers))
	(append supers (list <object>))
	supers))
	(metaclass (or (get-keyword #:metaclass options #f)
	(ensure-metaclass supers))))

	;; Verify that all direct slots are different and that we don't inherit
	;; several time from the same class
	(let ((tmp1 (find-duplicate supers))
	(tmp2 (find-duplicate (map slot-spec->name slots))))
	(if tmp1
	(goops-error "make-class: super class ~S is duplicate in class ~S"
	tmp1 name))
	(if tmp2
	(goops-error "make-class: slot ~S is duplicate in class ~S"
	tmp2 name)))

	;; Everything seems correct, build the class
	(apply make metaclass
	#:dsupers supers
	#:slots slots
	#:name name
	options)))

	;;; (class (SUPER ...) SLOT-DEFINITION ... OPTION ...)
	;;;
	;;; SLOT-DEFINITION ::= SLOT-NAME \| (SLOT-NAME OPTION ...)
	;;; OPTION ::= KEYWORD VALUE
	;;;
	(define-syntax class
	(lambda (x)
	(define (parse-options options)
	(syntax-case options ()
	(() #'())
	((kw arg . options) (keyword? (syntax->datum #'kw))
	(with-syntax ((options (parse-options #'options)))
	(syntax-case #'kw ()
	(#:init-form
	#'(kw 'arg #:init-thunk (lambda () arg) . options))
	(_
	#'(kw arg . options)))))))
	(define (check-valid-kwargs args)
	(syntax-case args ()
	(() #'())
	((kw arg . args) (keyword? (syntax->datum #'kw))
	#`(kw arg . #,(check-valid-kwargs #'args)))))
	(define (parse-slots-and-kwargs args)
	(syntax-case args ()
	(()
	#'(() ()))
	((kw . _) (keyword? (syntax->datum #'kw))
	#`(() #,(check-valid-kwargs args)))
	(((name option ...) args ...)
	(with-syntax (((slots kwargs) (parse-slots-and-kwargs #'(args ...)))
	((option ...) (parse-options #'(option ...))))
	#'(((list 'name option ...) . slots) kwargs)))
	((name args ...) (symbol? (syntax->datum #'name))
	(with-syntax (((slots kwargs) (parse-slots-and-kwargs #'(args ...))))
	#'(('(name) . slots) kwargs)))))
	(syntax-case x ()
	((class (super ...) arg ...)
	(with-syntax ((((slot-def ...) (option ...))
	(parse-slots-and-kwargs #'(arg ...))))
	#'(make-class (list super ...)
	(list slot-def ...)
	option ...))))))

	(define-syntax define-class-pre-definition
	(lambda (x)
	(syntax-case x ()
	((_ (k arg rest ...) out ...)
	(keyword? (syntax->datum #'k))
	(case (syntax->datum #'k)
	((#:getter #:setter)
	#'(define-class-pre-definition (rest ...)
	out ...
	(when (or (not (defined? 'arg))
	(not (is-a? arg <generic>)))
	(toplevel-define!
	'arg
	(ensure-generic (if (defined? 'arg) arg #f) 'arg)))))
	((#:accessor)
	#'(define-class-pre-definition (rest ...)
	out ...
	(when (or (not (defined? 'arg))
	(not (is-a? arg <accessor>)))
	(toplevel-define!
	'arg
	(ensure-accessor (if (defined? 'arg) arg #f) 'arg)))))
	(else
	#'(define-class-pre-definition (rest ...) out ...))))
	((_ () out ...)
	#'(begin out ...)))))

	;; Some slot options require extra definitions to be made. In
	;; particular, we want to make sure that the generic function objects
	;; which represent accessors exist before `make-class' tries to add
	;; methods to them.
	(define-syntax define-class-pre-definitions
	(lambda (x)
	(syntax-case x ()
	((_ () out ...)
	#'(begin out ...))
	((_ (slot rest ...) out ...)
	(keyword? (syntax->datum #'slot))
	#'(begin out ...))
	((_ (slot rest ...) out ...)
	(identifier? #'slot)
	#'(define-class-pre-definitions (rest ...)
	out ...))
	((_ ((slotname slotopt ...) rest ...) out ...)
	#'(define-class-pre-definitions (rest ...)
	out ... (define-class-pre-definition (slotopt ...)))))))

	(define-syntax-rule (define-class name supers slot ...)
	(begin
	(define-class-pre-definitions (slot ...))
	(let ((cls (class supers slot ... #:name 'name)))
	(toplevel-define!
	'name
	(if (defined? 'name)
	(class-redefinition name cls)
	cls)))))

	(define-syntax-rule (standard-define-class arg ...)
	(define-class arg ...))

	;;;
	;;; {Generic functions and accessors}
	;;;

	;; Apparently the desired semantics are that we extend previous
	;; procedural definitions, but that if `name' was already a generic, we
	;; overwrite its definition.
	(define-syntax define-generic
	(lambda (x)
	(syntax-case x ()
	((define-generic name) (symbol? (syntax->datum #'name))
	#'(define name
	(if (and (defined? 'name) (is-a? name <generic>))
	(make <generic> #:name 'name)
	(ensure-generic (if (defined? 'name) name #f) 'name)))))))

	(define-syntax define-extended-generic
	(lambda (x)
	(syntax-case x ()
	((define-extended-generic name val) (symbol? (syntax->datum #'name))
	#'(define name (make-extended-generic val 'name))))))

	(define-syntax define-extended-generics
	(lambda (x)
	(define (id-append ctx a b)
	(datum->syntax ctx (symbol-append (syntax->datum a) (syntax->datum b))))
	(syntax-case x ()
	((define-extended-generic (name ...) #:prefix (prefix ...))
	(and (and-map symbol? (syntax->datum #'(name ...)))
	(and-map symbol? (syntax->datum #'(prefix ...))))
	(with-syntax ((((val ...)) (map (lambda (name)
	(map (lambda (prefix)
	(id-append name prefix name))
	#'(prefix ...)))
	#'(name ...))))
	#'(begin
	(define-extended-generic name (list val ...))
	...))))))

	(define* (make-generic #:optional name)
	(make <generic> #:name name))

	(define* (make-extended-generic gfs #:optional name)
	(let* ((gfs (if (list? gfs) gfs (list gfs)))
	(gws? (any (lambda (gf) (is-a? gf <generic-with-setter>)) gfs)))
	(let ((ans (if gws?
	(let* ((sname (and name (make-setter-name name)))
	(setters
	(append-map (lambda (gf)
	(if (is-a? gf <generic-with-setter>)
	(list (ensure-generic (setter gf)
	sname))
	'()))
	gfs))
	(es (make <extended-generic-with-setter>
	#:name name
	#:extends gfs
	#:setter (make <extended-generic>
	#:name sname
	#:extends setters))))
	(extended-by! setters (setter es))
	es)
	(make <extended-generic>
	#:name name
	#:extends gfs))))
	(extended-by! gfs ans)
	ans)))

	(define (extended-by! gfs eg)
	(for-each (lambda (gf)
	(slot-set! gf 'extended-by
	(cons eg (slot-ref gf 'extended-by))))
	gfs)
	(invalidate-method-cache! eg))

	(define (not-extended-by! gfs eg)
	(for-each (lambda (gf)
	(slot-set! gf 'extended-by
	(delq! eg (slot-ref gf 'extended-by))))
	gfs)
	(invalidate-method-cache! eg))

	(define* (ensure-generic old-definition #:optional name)
	(cond ((is-a? old-definition <generic>) old-definition)
	((procedure-with-setter? old-definition)
	(make <generic-with-setter>
	#:name name
	#:default (procedure old-definition)
	#:setter (setter old-definition)))
	((procedure? old-definition)
	(if (generic-capability? old-definition) old-definition
	(make <generic> #:name name #:default old-definition)))
	(else (make <generic> #:name name))))

	;; same semantics as <generic>
	(define-syntax-rule (define-accessor name)
	(define name
	(cond ((not (defined? 'name)) (ensure-accessor #f 'name))
	((is-a? name <accessor>) (make <accessor> #:name 'name))
	(else (ensure-accessor name 'name)))))

	(define (make-setter-name name)
	(string->symbol (string-append "setter:" (symbol->string name))))

	(define* (make-accessor #:optional name)
	(make <accessor>
	#:name name
	#:setter (make <generic>
	#:name (and name (make-setter-name name)))))

	(define* (ensure-accessor proc #:optional name)
	(cond ((and (is-a? proc <accessor>)
	(is-a? (setter proc) <generic>))
	proc)
	((is-a? proc <generic-with-setter>)
	(upgrade-accessor proc (setter proc)))
	((is-a? proc <generic>)
	(upgrade-accessor proc (make-generic name)))
	((procedure-with-setter? proc)
	(make <accessor>
	#:name name
	#:default (procedure proc)
	#:setter (ensure-generic (setter proc) name)))
	((procedure? proc)
	(ensure-accessor (if (generic-capability? proc)
	(make <generic> #:name name #:default proc)
	(ensure-generic proc name))
	name))
	(else
	(make-accessor name))))

	(define (upgrade-accessor generic setter)
	(let ((methods (slot-ref generic 'methods))
	(gws (make (if (is-a? generic <extended-generic>)
	<extended-generic-with-setter>
	<accessor>)
	#:name (generic-function-name generic)
	#:extended-by (slot-ref generic 'extended-by)
	#:setter setter)))
	(when (is-a? generic <extended-generic>)
	(let ((gfs (slot-ref generic 'extends)))
	(not-extended-by! gfs generic)
	(slot-set! gws 'extends gfs)
	(extended-by! gfs gws)))
	;; Steal old methods
	(for-each (lambda (method)
	(slot-set! method 'generic-function gws))
	methods)
	(slot-set! gws 'methods methods)
	(invalidate-method-cache! gws)
	gws))

	;;;
	;;; {Methods}
	;;;

	;; Note: `a' and `b' can have unequal lengths (i.e. one can be one
	;; element longer than the other when we have a dotted parameter
	;; list). For instance, with the call
	;;
	;; (M 1)
	;;
	;; with
	;;
	;; (define-method M (a . l) ....)
	;; (define-method M (a) ....)
	;;
	;; we consider that the second method is more specific.
	;;
	;; Precondition: `a' and `b' are methods and are applicable to `types'.
	(define (%method-more-specific? a b types)
	(let lp ((a-specializers (method-specializers a))
	(b-specializers (method-specializers b))
	(types types))
	(cond
	;; (a) less specific than (a b ...) or (a . b)
	((null? a-specializers) #t)
	;; (a b ...) or (a . b) less specific than (a)
	((null? b-specializers) #f)
	;; (a . b) less specific than (a b ...)
	((not (pair? a-specializers)) #f)
	;; (a b ...) more specific than (a . b)
	((not (pair? b-specializers)) #t)
	(else
	(let ((a-specializer (car a-specializers))
	(b-specializer (car b-specializers))
	(a-specializers (cdr a-specializers))
	(b-specializers (cdr b-specializers))
	(type (car types))
	(types (cdr types)))
	(if (eq? a-specializer b-specializer)
	(lp a-specializers b-specializers types)
	(let lp ((cpl (class-precedence-list type)))
	(let ((elt (car cpl)))
	(cond
	((eq? a-specializer elt) #t)
	((eq? b-specializer elt) #f)
	(else (lp (cdr cpl))))))))))))

	(define (%sort-applicable-methods methods types)
	(sort methods (lambda (a b) (%method-more-specific? a b types))))

	(define (generic-function-methods obj)
	"Return the methods of the generic function @var{obj}."
	(define (fold-upward method-lists gf)
	(cond
	((is-a? gf <extended-generic>)
	(let lp ((method-lists method-lists) (gfs (slot-ref gf 'extends)))
	(match gfs
	(() method-lists)
	((gf . gfs)
	(lp (fold-upward (cons (slot-ref gf 'methods) method-lists) gf)
	gfs)))))
	(else method-lists)))
	(define (fold-downward method-lists gf)
	(let lp ((method-lists (cons (slot-ref gf 'methods) method-lists))
	(gfs (slot-ref gf 'extended-by)))
	(match gfs
	(() method-lists)
	((gf . gfs)
	(lp (fold-downward method-lists gf) gfs)))))
	(unless (is-a? obj <generic>)
	(scm-error 'wrong-type-arg #f "Not a generic: ~S"
	(list obj) #f))
	(concatenate (fold-downward (fold-upward '() obj) obj)))

	(define (%compute-applicable-methods gf args)
	(define (method-applicable? m types)
	(let ((specs (method-specializers m)))
	(cond
	((and (is-a? m <accessor-method>)
	(or (null? specs) (null? types)
	(not (eq? (car specs) (car types)))))
	;; Slot accessor methods are added to each subclass with the
	;; slot. They only apply to that specific concrete class, which
	;; appears as the first argument.
	#f)
	(else
	(let lp ((specs specs) (types types))
	(cond
	((null? specs) (null? types))
	((not (pair? specs)) #t)
	((null? types) #f)
	(else
	(and (memq (car specs) (class-precedence-list (car types)))
	(lp (cdr specs) (cdr types))))))))))
	(let ((n (length args))
	(types (map class-of args)))
	(let lp ((methods (generic-function-methods gf))
	(applicable '()))
	(if (null? methods)
	(and (not (null? applicable))
	(%sort-applicable-methods applicable types))
	(let ((m (car methods)))
	(lp (cdr methods)
	(if (method-applicable? m types)
	(cons m applicable)
	applicable)))))))

	(define compute-applicable-methods %compute-applicable-methods)

	(define (toplevel-define! name val)
	(module-define! (current-module) name val))

	(define-syntax define-method
	(syntax-rules (setter)
	((_ ((setter name) . args) body ...)
	(begin
	(when (or (not (defined? 'name))
	(not (is-a? name <accessor>)))
	(toplevel-define! 'name
	(ensure-accessor
	(if (defined? 'name) name #f) 'name)))
	(add-method! (setter name) (method args body ...))))
	((_ (name . args) body ...)
	(begin
	;; FIXME: this code is how it always was, but it's quite cracky:
	;; it will only define the generic function if it was undefined
	;; before (ok), or was defined to #f. The latter is crack. But
	;; there are bootstrap issues about fixing this -- change it to
	;; (is-a? name <generic>) and see.
	(when (or (not (defined? 'name))
	(not name))
	(toplevel-define! 'name (make <generic> #:name 'name)))
	(add-method! name (method args body ...))))))

	(define-syntax method
	(lambda (x)
	(define (parse-args args)
	(let lp ((ls args) (formals '()) (specializers '()))
	(syntax-case ls ()
	(((f s) . rest)
	(and (identifier? #'f) (identifier? #'s))
	(lp #'rest
	(cons #'f formals)
	(cons #'s specializers)))
	((f . rest)
	(identifier? #'f)
	(lp #'rest
	(cons #'f formals)
	(cons #'<top> specializers)))
	(()
	(list (reverse formals)
	(reverse (cons #''() specializers))))
	(tail
	(identifier? #'tail)
	(list (append (reverse formals) #'tail)
	(reverse (cons #'<top> specializers)))))))

	(define (find-free-id exp referent)
	(syntax-case exp ()
	((x . y)
	(or (find-free-id #'x referent)
	(find-free-id #'y referent)))
	(x
	(identifier? #'x)
	(let ((id (datum->syntax #'x referent)))
	(and (free-identifier=? #'x id) id)))
	(_ #f)))

	(define (compute-procedure formals body)
	(syntax-case body ()
	((body0 ...)
	(with-syntax ((formals formals))
	#'(lambda formals body0 ...)))))

	(define (->proper args)
	(let lp ((ls args) (out '()))
	(syntax-case ls ()
	((x . xs) (lp #'xs (cons #'x out)))
	(() (reverse out))
	(tail (reverse (cons #'tail out))))))

	(define (compute-make-procedure formals body next-method)
	(syntax-case body ()
	((body ...)
	(with-syntax ((next-method next-method))
	(syntax-case formals ()
	((formal ...)
	#'(lambda (real-next-method)
	(lambda (formal ...)
	(let ((next-method (lambda args
	(if (null? args)
	(real-next-method formal ...)
	(apply real-next-method args)))))
	body ...))))
	(formals
	(with-syntax (((formal ...) (->proper #'formals)))
	#'(lambda (real-next-method)
	(lambda formals
	(let ((next-method (lambda args
	(if (null? args)
	(apply real-next-method formal ...)
	(apply real-next-method args)))))
	body ...))))))))))

	(define (compute-procedures formals body)
	;; So, our use of this is broken, because it operates on the
	;; pre-expansion source code. It's equivalent to just searching
	;; for referent in the datums. Ah well.
	(let ((id (find-free-id body 'next-method)))
	(if id
	;; return a make-procedure
	(values #'#f
	(compute-make-procedure formals body id))
	(values (compute-procedure formals body)
	#'#f))))

	(syntax-case x ()
	((_ args) #'(method args (if #f #f)))
	((_ args body0 body1 ...)
	(with-syntax (((formals (specializer ...)) (parse-args #'args)))
	(call-with-values
	(lambda ()
	(compute-procedures #'formals #'(body0 body1 ...)))
	(lambda (procedure make-procedure)
	(with-syntax ((procedure procedure)
	(make-procedure make-procedure))
	#'(make <method>
	#:specializers (cons* specializer ...)
	#:formals 'formals
	#:body '(body0 body1 ...)
	#:make-procedure make-procedure
	#:procedure procedure)))))))))

	;;;
	;;; {Utilities}
	;;;
	;;; These are useful when dealing with method specializers, which might
	;;; have a rest argument.
	;;;

	(define (map* fn . l) ; A map which accepts dotted lists (arg lists
	(cond ; must be "isomorph"
	((null? (car l)) '())
	((pair? (car l)) (cons (apply fn (map car l))
	(apply map* fn (map cdr l))))
	(else (apply fn l))))

	(define (for-each* fn . l) ; A for-each which accepts dotted lists (arg lists
	(cond ; must be "isomorph"
	((null? (car l)) '())
	((pair? (car l)) (apply fn (map car l)) (apply for-each* fn (map cdr l)))
	(else (apply fn l))))

	(define (length* ls)
	(do ((n 0 (+ 1 n))
	(ls ls (cdr ls)))
	((not (pair? ls)) n)))

	;;;
	;;; {add-method!}
	;;;

	(define (add-method-in-classes! m)
	;; Add method in all the classes which appears in its specializers list
	(for-each* (lambda (x)
	(let ((dm (class-direct-methods x)))
	(unless (memq m dm)
	(struct-set! x class-index-direct-methods (cons m dm)))))
	(method-specializers m)))

	(define (remove-method-in-classes! m)
	;; Remove method in all the classes which appears in its specializers list
	(for-each* (lambda (x)
	(struct-set! x
	class-index-direct-methods
	(delv! m (class-direct-methods x))))
	(method-specializers m)))

	(define (compute-new-list-of-methods gf new)
	(let ((new-spec (method-specializers new))
	(methods (slot-ref gf 'methods)))
	(let loop ((l methods))
	(if (null? l)
	(cons new methods)
	(if (equal? (method-specializers (car l)) new-spec)
	(begin
	;; This spec. list already exists. Remove old method from dependents
	(remove-method-in-classes! (car l))
	(set-car! l new)
	methods)
	(loop (cdr l)))))))

	(define (method-n-specializers m)
	(length* (slot-ref m 'specializers)))

	(define (calculate-n-specialized gf)
	(fold (lambda (m n) (max n (method-n-specializers m)))
	0
	(generic-function-methods gf)))

	(define (invalidate-method-cache! gf)
	(slot-set! gf 'n-specialized (calculate-n-specialized gf))
	(%invalidate-method-cache! gf)
	(for-each (lambda (gf) (invalidate-method-cache! gf))
	(slot-ref gf 'extended-by)))

	(define internal-add-method!
	(method ((gf <generic>) (m <method>))
	(slot-set! m 'generic-function gf)
	(slot-set! gf 'methods (compute-new-list-of-methods gf m))
	(invalidate-method-cache! gf)
	(add-method-in-classes! m)
	unspecified))

	(define-generic add-method!)

	((method-procedure internal-add-method!) add-method! internal-add-method!)

	(define-method (add-method! (proc <procedure>) (m <method>))
	(if (generic-capability? proc)
	(begin
	(enable-primitive-generic! proc)
	(add-method! proc m))
	(next-method)))

	(define-method (add-method! (pg <primitive-generic>) (m <method>))
	(add-method! (primitive-generic-generic pg) m))

	(define-method (add-method! obj (m <method>))
	(goops-error "~S is not a valid generic function" obj))

	;;;
	;;; {Access to meta objects}
	;;;

	;;;
	;;; Methods
	;;;
	(define-method (method-source (m <method>))
	(let* ((spec (map* class-name (slot-ref m 'specializers)))
	(src (procedure-source (slot-ref m 'procedure))))
	(and src
	(let ((args (cadr src))
	(body (cddr src)))
	(cons 'method
	(cons (map* list args spec)
	body))))))

	(define-method (method-formals (m <method>))
	(slot-ref m 'formals))

	;;;
	;;; Slots
	;;;
	(define (slot-init-function class slot-name)
	(%slot-definition-init-thunk (or (class-slot-definition class slot-name)
	(error "slot not found" slot-name))))

	(define (accessor-method-slot-definition obj)
	"Return the slot definition of the accessor @var{obj}."
	(slot-ref obj 'slot-definition))


	;;;
	;;; {Standard methods used by the C runtime}
	;;;

	;;; Methods to compare objects
	;;;

	;; Have to do this in a strange order because equal? is used in the
	;; add-method! implementation; we need to make sure that when the
	;; primitive is extended, that the generic has a method. =
	(define g-equal? (make-generic 'equal?))
	;; When this generic gets called, we will have already checked eq? and
	;; eqv? -- the purpose of this generic is to extend equality. So by
	;; default, there is no extension, thus the #f return.
	(add-method! g-equal? (method (x y) #f))
	(set-primitive-generic! equal? g-equal?)

	;;;
	;;; methods to display/write an object
	;;;

	; Code for writing objects must test that the slots they use are
	; bound. Otherwise a slot-unbound method will be called and will
	; conduct to an infinite loop.

	;; Write
	(define (display-address o file)
	(display (number->string (object-address o) 16) file))

	(define-method (write o file)
	(display "#<instance " file)
	(display-address o file)
	(display #\> file))

	(define write-object (primitive-generic-generic write))

	(define-method (write (o <object>) file)
	(let ((class (class-of o)))
	(if (slot-bound? class 'name)
	(begin
	(display "#<" file)
	(display (class-name class) file)
	(display #\space file)
	(display-address o file)
	(display #\> file))
	(next-method))))

	(define-method (write (slot <slot>) file)
	(let ((class (class-of slot)))
	(if (and (slot-bound? class 'name)
	(slot-bound? slot 'name))
	(begin
	(display "#<" file)
	(display (class-name class) file)
	(display #\space file)
	(display (%slot-definition-name slot) file)
	(display #\space file)
	(display-address slot file)
	(display #\> file))
	(next-method))))

	(define-method (write (class <class>) file)
	(let ((meta (class-of class)))
	(if (and (slot-bound? class 'name)
	(slot-bound? meta 'name))
	(begin
	(display "#<" file)
	(display (class-name meta) file)
	(display #\space file)
	(display (class-name class) file)
	(display #\space file)
	(display-address class file)
	(display #\> file))
	(next-method))))

	(define-method (write (gf <generic>) file)
	(let ((meta (class-of gf)))
	(if (and (slot-bound? meta 'name)
	(slot-bound? gf 'methods))
	(begin
	(display "#<" file)
	(display (class-name meta) file)
	(let ((name (generic-function-name gf)))
	(if name
	(begin
	(display #\space file)
	(display name file))))
	(display " (" file)
	(display (length (generic-function-methods gf)) file)
	(display ")>" file))
	(next-method))))

	(define-method (write (o <method>) file)
	(let ((meta (class-of o)))
	(if (and (slot-bound? meta 'name)
	(slot-bound? o 'specializers))
	(begin
	(display "#<" file)
	(display (class-name meta) file)
	(display #\space file)
	(display (map* (lambda (spec)
	(if (slot-bound? spec 'name)
	(slot-ref spec 'name)
	spec))
	(method-specializers o))
	file)
	(display #\space file)
	(display-address o file)
	(display #\> file))
	(next-method))))

	;; Display (do the same thing as write by default)
	(define-method (display o file)
	(write-object o file))

	;;;
	;;; Handling of duplicate bindings in the module system
	;;;

	(define (find-subclass super name)
	(let lp ((classes (class-direct-subclasses super)))
	(cond
	((null? classes)
	(error "class not found" name))
	((and (slot-bound? (car classes) 'name)
	(eq? (class-name (car classes)) name))
	(car classes))
	(else
	(lp (cdr classes))))))

	;; A record type.
	(define <module> (find-subclass <top> '<module>))

	(define-method (merge-generics (module <module>)
	(name <symbol>)
	(int1 <module>)
	(val1 <top>)
	(int2 <module>)
	(val2 <top>)
	(var <top>)
	(val <top>))
	#f)

	(define-method (merge-generics (module <module>)
	(name <symbol>)
	(int1 <module>)
	(val1 <generic>)
	(int2 <module>)
	(val2 <generic>)
	(var <top>)
	(val <boolean>))
	(and (not (eq? val1 val2))
	(make-variable (make-extended-generic (list val2 val1) name))))

	(define-method (merge-generics (module <module>)
	(name <symbol>)
	(int1 <module>)
	(val1 <generic>)
	(int2 <module>)
	(val2 <generic>)
	(var <top>)
	(gf <extended-generic>))
	(and (not (memq val2 (slot-ref gf 'extends)))
	(begin
	(slot-set! gf
	'extends
	(cons val2 (delq! val2 (slot-ref gf 'extends))))
	(slot-set! val2
	'extended-by
	(cons gf (delq! gf (slot-ref val2 'extended-by))))
	(invalidate-method-cache! gf)
	var)))

	(module-define! duplicate-handlers 'merge-generics merge-generics)

	(define-method (merge-accessors (module <module>)
	(name <symbol>)
	(int1 <module>)
	(val1 <top>)
	(int2 <module>)
	(val2 <top>)
	(var <top>)
	(val <top>))
	#f)

	(define-method (merge-accessors (module <module>)
	(name <symbol>)
	(int1 <module>)
	(val1 <accessor>)
	(int2 <module>)
	(val2 <accessor>)
	(var <top>)
	(val <top>))
	(merge-generics module name int1 val1 int2 val2 var val))

	(module-define! duplicate-handlers 'merge-accessors merge-accessors)

	;;;
	;;; slot access
	;;;

	(define (class-slot-ref class slot-name)
	(let ((slot (class-slot-definition class slot-name)))
	(unless (memq (%slot-definition-allocation slot) '(#:class #:each-subclass))
	(slot-missing class slot-name))
	(let ((x ((%slot-definition-slot-ref/raw slot) #f)))
	(if (unbound? x)
	(slot-unbound class slot-name)
	x))))

	(define (class-slot-set! class slot-name value)
	(let ((slot (class-slot-definition class slot-name)))
	(unless (memq (%slot-definition-allocation slot) '(#:class #:each-subclass))
	(slot-missing class slot-name))
	((%slot-definition-slot-set! slot) #f value)))

	(define-method (slot-unbound (c <class>) (o <object>) s)
	(goops-error "Slot `~S' is unbound in object ~S" s o))

	(define-method (slot-unbound (c <class>) s)
	(goops-error "Slot `~S' is unbound in class ~S" s c))

	(define-method (slot-unbound (o <object>))
	(goops-error "Unbound slot in object ~S" o))

	(define-method (slot-missing (c <class>) (o <object>) s)
	(goops-error "No slot with name `~S' in object ~S" s o))

	(define-method (slot-missing (c <class>) s)
	(goops-error "No class slot with name `~S' in class ~S" s c))


	(define-method (slot-missing (c <class>) (o <object>) s value)
	(slot-missing c o s))

	;;; Methods for the possible error we can encounter when calling a gf

	(define-method (no-next-method (gf <generic>) args)
	(goops-error "No next method when calling ~S\nwith arguments ~S" gf args))

	(define-method (no-applicable-method (gf <generic>) args)
	(goops-error "No applicable method for ~S in call ~S"
	gf (cons (generic-function-name gf) args)))

	(define-method (no-method (gf <generic>) args)
	(goops-error "No method defined for ~S" gf))

	;;;
	;;; {Cloning functions (from [email protected])}
	;;;

	(define-method (shallow-clone (self <object>))
	(let* ((class (class-of self))
	(clone (%allocate-instance class))
	(slots (map slot-definition-name (class-slots class))))
	(for-each (lambda (slot)
	(when (slot-bound? self slot)
	(slot-set! clone slot (slot-ref self slot))))
	slots)
	clone))

	(define-method (deep-clone (self <object>))
	(let* ((class (class-of self))
	(clone (%allocate-instance class))
	(slots (map slot-definition-name (class-slots class))))
	(for-each (lambda (slot)
	(when (slot-bound? self slot)
	(slot-set! clone slot
	(let ((value (slot-ref self slot)))
	(if (instance? value)
	(deep-clone value)
	value)))))
	slots)
	clone))

	;;;
	;;; {Utilities for INITIALIZE methods}
	;;;

	;;; compute-slot-accessors
	;;;
	(define (compute-slot-accessors class slots)
	(for-each
	(lambda (slot)
	(let ((getter (%slot-definition-getter slot))
	(setter (%slot-definition-setter slot))
	(accessor-setter setter)
	(accessor (%slot-definition-accessor slot)))
	(when getter
	(add-method! getter (compute-getter-method class slot)))
	(when setter
	(add-method! setter (compute-setter-method class slot)))
	(when accessor
	(add-method! accessor (compute-getter-method class slot))
	(add-method! (accessor-setter accessor)
	(compute-setter-method class slot)))))
	slots))

	(define-method (compute-getter-method (class <class>) slot)
	(make <accessor-method>
	#:specializers (list class)
	#:procedure (slot-definition-slot-ref slot)
	#:slot-definition slot))

	(define-method (compute-setter-method (class <class>) slot)
	(make <accessor-method>
	#:specializers (list class <top>)
	#:procedure (slot-definition-slot-set! slot)
	#:slot-definition slot))

	(define (make-generic-bound-check-getter proc)
	(lambda (o)
	(let ((val (proc o)))
	(if (unbound? val)
	(slot-unbound o)
	val))))

	;;; compute-cpl
	;;;

	;; Replace the bootstrap compute-cpl with this definition.
	(define compute-cpl
	(make <generic> #:name 'compute-cpl))

	(define-method (compute-cpl (class <class>))
	(compute-std-cpl class class-direct-supers))

	;;; compute-get-n-set
	;;;
	(define compute-get-n-set
	(make <generic> #:name 'compute-get-n-set))

	(define-method (compute-get-n-set (class <class>) s)
	(define (class-slot-init-value)
	(let ((thunk (slot-definition-init-thunk s)))
	(if thunk
	(thunk)
	(slot-definition-init-value s))))

	(define (make-closure-variable class value)
	(list (lambda (o) value)
	(lambda (o v) (set! value v))))

	(case (slot-definition-allocation s)
	((#:instance) ;; Instance slot
	;; get-n-set is just its offset
	(let ((already-allocated (struct-ref/unboxed class class-index-nfields)))
	(struct-set!/unboxed class class-index-nfields (+ already-allocated 1))
	already-allocated))

	((#:class) ;; Class slot
	;; Class-slots accessors are implemented as 2 closures around
	;; a Scheme variable. As instance slots, class slots must be
	;; unbound at init time.
	(let ((name (slot-definition-name s)))
	(if (memq name (map slot-definition-name (class-direct-slots class)))
	;; This slot is direct; create a new shared variable
	(make-closure-variable class (class-slot-init-value))
	;; Slot is inherited. Find its definition in superclass
	(let lp ((cpl (cdr (class-precedence-list class))))
	(match cpl
	((super . cpl)
	(let ((s (class-slot-definition super name)))
	(if s
	(list (slot-definition-slot-ref s)
	(slot-definition-slot-set! s))
	;; Multiple inheritance means that we might have
	;; to look deeper in the CPL.
	(lp cpl)))))))))

	((#:each-subclass) ;; slot shared by instances of direct subclass.
	;; (Thomas Buerger, April 1998)
	(make-closure-variable class (class-slot-init-value)))

	((#:virtual) ;; No allocation
	;; slot-ref and slot-set! function must be given by the user
	(let ((get (get-keyword #:slot-ref (slot-definition-options s) #f))
	(set (get-keyword #:slot-set! (slot-definition-options s) #f)))
	(unless (and get set)
	(goops-error "You must supply a #:slot-ref and a #:slot-set! in ~S" s))
	(list get set)))
	(else (next-method))))

	(define-method (compute-get-n-set (o <object>) s)
	(goops-error "Allocation \"~S\" is unknown" (slot-definition-allocation s)))

	(define-method (compute-slots (class <class>))
	(build-slots-list (class-direct-slots class)
	(class-precedence-list class)))

	;;;
	;;; {Initialize}
	;;;

	;; FIXME: This could be much more efficient.
	(define (%initialize-object obj initargs)
	"Initialize the object @var{obj} with the given arguments
	var{initargs}."
	(define (valid-initargs? initargs)
	(match initargs
	(() #t)
	(((? keyword?) _ . initargs) (valid-initargs? initargs))
	(_ #f)))
	(unless (instance? obj)
	(scm-error 'wrong-type-arg #f "Not an object: ~S"
	(list obj) #f))
	(unless (valid-initargs? initargs)
	(scm-error 'wrong-type-arg #f "Invalid initargs: ~S"
	(list initargs) #f))
	(let ((class (class-of obj)))
	(define (get-initarg kw)
	(if kw
	;; Inlined get-keyword to avoid checking initargs for validity
	;; each time.
	(let lp ((initargs initargs))
	(match initargs
	((kw* val . initargs)
	(if (eq? kw* kw)
	val
	(lp initargs)))
	(_ unbound)))
	unbound))
	(let lp ((slots (struct-ref class class-index-slots)))
	(match slots
	(() obj)
	((slot . slots)
	(define (initialize-slot! value)
	((%slot-definition-slot-set! slot) obj value))
	(let ((initarg (get-initarg (%slot-definition-init-keyword slot))))
	(cond
	((not (unbound? initarg))
	(initialize-slot! initarg))
	((%slot-definition-init-thunk slot)
	=> (lambda (init-thunk)
	(unless (memq (slot-definition-allocation slot)
	'(#:class #:each-subclass))
	(initialize-slot! (init-thunk)))))))
	(lp slots))))))

	(define-method (initialize (object <object>) initargs)
	(%initialize-object object initargs))

	(define-method (initialize (slot <slot>) initargs)
	(next-method)
	(struct-set! slot slot-index-options initargs)
	(let ((init-thunk (%slot-definition-init-thunk slot)))
	(when init-thunk
	(unless (thunk? init-thunk)
	(goops-error "Bad init-thunk for slot `~S': ~S"
	(%slot-definition-name slot) init-thunk)))))

	(define-method (initialize (class <class>) initargs)
	(define (make-direct-slot-definition dslot)
	(let ((initargs (compute-direct-slot-definition-initargs class dslot)))
	(compute-direct-slot-definition class initargs)))

	(next-method)
	(class-add-flags! class vtable-flag-goops-class)
	(struct-set! class class-index-name (get-keyword #:name initargs '???))
	(struct-set!/unboxed class class-index-nfields 0)
	(struct-set! class class-index-direct-supers
	(get-keyword #:dsupers initargs '()))
	(struct-set! class class-index-direct-subclasses '())
	(struct-set! class class-index-direct-methods '())
	(struct-set! class class-index-cpl (compute-cpl class))
	(when (get-keyword #:static-slot-allocation? initargs #f)
	(match (filter class-has-statically-allocated-slots?
	(class-precedence-list class))
	(()
	(class-add-flags! class vtable-flag-goops-static-slot-allocation))
	(classes
	(error "Class has superclasses with static slot allocation" classes))))
	(struct-set! class class-index-direct-slots
	(map (lambda (slot)
	(if (slot? slot)
	slot
	(make-direct-slot-definition slot)))
	(get-keyword #:slots initargs '())))
	(struct-set! class class-index-slots
	(allocate-slots class (compute-slots class)))

	;; This is a hack.
	(when (memq <slot> (struct-ref class class-index-cpl))
	(class-add-flags! class vtable-flag-goops-slot))

	;; Build getters - setters - accessors
	(compute-slot-accessors class (struct-ref class class-index-slots))

	;; Update the "direct-subclasses" of each inherited classes
	(for-each (lambda (x)
	(let ((dsubs (struct-ref x class-index-direct-subclasses)))
	(struct-set! x class-index-direct-subclasses
	(cons class dsubs))))
	(struct-ref class class-index-direct-supers))

	;; Compute struct layout of instances, set the `layout' slot, and
	;; update class flags.
	(%prep-layout! class))

	(define (initialize-object-procedure object initargs)
	(let ((proc (get-keyword #:procedure initargs #f)))
	(cond ((not proc))
	((pair? proc)
	(apply slot-set! object 'procedure proc))
	(else
	(slot-set! object 'procedure proc)))))

	(define-method (initialize (applicable-struct <applicable-struct>) initargs)
	(next-method)
	(initialize-object-procedure applicable-struct initargs))

	(define-method (initialize (applicable-struct <applicable-struct-with-setter>)
	initargs)
	(next-method)
	(slot-set! applicable-struct 'setter (get-keyword #:setter initargs #f)))

	(define-method (initialize (generic <generic>) initargs)
	(let ((previous-definition (get-keyword #:default initargs #f))
	(name (get-keyword #:name initargs #f)))
	(next-method)
	(slot-set! generic 'methods (if (is-a? previous-definition <procedure>)
	(list (method args
	(apply previous-definition args)))
	'()))
	(if name
	(set-procedure-property! generic 'name name))
	(invalidate-method-cache! generic)))

	(define-method (initialize (eg <extended-generic>) initargs)
	(next-method)
	(slot-set! eg 'extends (get-keyword #:extends initargs '())))

	(define dummy-procedure (lambda args unspecified))

	(define-method (initialize (method <method>) initargs)
	(next-method)
	(slot-set! method 'generic-function (get-keyword #:generic-function initargs #f))
	(slot-set! method 'specializers (get-keyword #:specializers initargs '()))
	(slot-set! method 'procedure
	(get-keyword #:procedure initargs #f))
	(slot-set! method 'formals (get-keyword #:formals initargs '()))
	(slot-set! method 'body (get-keyword #:body initargs '()))
	(slot-set! method 'make-procedure (get-keyword #:make-procedure initargs #f)))


	;;;
	;;; {make}
	;;;
	;;; A new definition which overwrites the previous one which was built-in
	;;;

	(define-method (allocate-instance (class <class>) initargs)
	(%allocate-instance class))

	(define-method (make-instance (class <class>) . initargs)
	(let ((instance (allocate-instance class initargs)))
	(initialize instance initargs)
	instance))

	(define make make-instance)

	;;;
	;;; {apply-generic}
	;;;
	;;; Protocol for calling generic functions, intended to be used when
	;;; applying subclasses of <generic> and <generic-with-setter>. The
	;;; code below is similar to the first MOP described in AMOP.
	;;;
	;;; Note that standard generic functions dispatch only on the classes of
	;;; the arguments, and the result of such dispatch can be memoized. The
	;;; `dispatch-generic-function-application-from-cache' routine
	;;; implements this. `apply-generic' isn't called currently; the
	;;; generic function MOP was never fully implemented in GOOPS. However
	;;; now that GOOPS is implemented entirely in Scheme (2015) it's much
	;;; easier to complete this work. Contributions gladly accepted!
	;;; Please read the AMOP first though :)
	;;;
	;;; The protocol is:
	;;;
	;;; + apply-generic (gf args)
	;;; + compute-applicable-methods (gf args ...)
	;;; + sort-applicable-methods (gf methods args)
	;;; + apply-methods (gf methods args)
	;;;
	;;; apply-methods calls make-next-method to build the "continuation" of
	;;; a method. Applying a next-method will call apply-next-method which
	;;; in turn will call apply again to call effectively the following
	;;; method. (This paragraph is out of date but is kept so that maybe it
	;;; illuminates some future hack.)
	;;;

	(define-method (apply-generic (gf <generic>) args)
	(when (null? (slot-ref gf 'methods))
	(no-method gf args))
	(let ((methods (compute-applicable-methods gf args)))
	(if methods
	(apply-methods gf (sort-applicable-methods gf methods args) args)
	(no-applicable-method gf args))))

	;; compute-applicable-methods is bound to %compute-applicable-methods.
	(define compute-applicable-methods
	(let ((gf (make <generic> #:name 'compute-applicable-methods)))
	(add-method! gf (method ((gf <generic>) args)
	(%compute-applicable-methods gf args)))
	gf))

	(define-method (sort-applicable-methods (gf <generic>) methods args)
	(%sort-applicable-methods methods (map class-of args)))

	(define-method (method-more-specific? (m1 <method>) (m2 <method>) targs)
	(%method-more-specific? m1 m2 targs))

	(define compute-effective-method
	(let ((gf (make <generic> #:name 'compute-effective-method)))
	(add-method! gf (method ((gf <generic>) methods typev)
	(%compute-effective-method gf methods typev)))
	gf))

	(define compute-specialized-effective-method
	(let ((gf (make <generic> #:name 'compute-specialized-effective-method)))
	(add-method!
	gf
	(method ((gf <generic>) (method <method>) typev next)
	(%compute-specialized-effective-method gf method typev next)))
	gf))

	(define-method (compute-specialized-effective-method (gf <generic>)
	(m <accessor-method>)
	typev
	next)
	(let ((name (slot-definition-name (accessor-method-slot-definition m))))
	(match typev
	(#(class)
	(slot-definition-slot-ref (class-slot-definition class name)))
	(#(class _)
	(slot-definition-slot-set! (class-slot-definition class name)))
	(_
	(next-method)))))

	(define-method (apply-method (gf <generic>) methods build-next args)
	(apply (method-procedure (car methods))
	(build-next (cdr methods) args)
	args))

	(define-method (apply-methods (gf <generic>) (l <list>) args)
	(letrec ((next (lambda (procs args)
	(lambda new-args
	(let ((a (if (null? new-args) args new-args)))
	(if (null? procs)
	(no-next-method gf a)
	(apply-method gf procs next a)))))))
	(apply-method gf l next args)))

	;; We don't want the following procedure to turn up in backtraces:
	(for-each (lambda (proc)
	(set-procedure-property! proc 'system-procedure #t))
	(list slot-unbound
	slot-missing
	no-next-method
	no-applicable-method
	no-method
	))



	;;;
	;;; Class redefinition
	;;;

	;;; GOOPS has a facility to allow a user to change the definition of
	;;; class. This will cause instances of that class to lazily migrate
	;;; over to the new definition. Implementing this is tricky because
	;;; identity is a fundamental part of object-oriented programming; you
	;;; can't just make a new class and start using it, just like that. In
	;;; GOOPS, classes are objects too and need to be addressable by
	;;; identity (by `eq?'). Classes need the ability to change their
	;;; definition "in place". The same goes for instances; redefining a
	;;; class might change the amount of storage associated with each
	;;; instance, and yet we need to update the instances in place, and
	;;; without having classes maintain a list of all of their instances.
	;;;
	;;; The way that we implement this is by adding an indirection. An
	;;; instance of a redefinable class becomes a small object containing
	;;; only a single field, a reference to an external "slots" objects that
	;;; holds the actual slots. There is an exception however for objects
	;;; that have statically allocated slots, most importantly classes -- in
	;;; that case the indirected slots are allocated "directly" in the
	;;; object.
	;;;
	;;; Instances update by checking the class of their their indirected
	;;; slots object. In addition to describing the slots of the indirected
	;;; slots object, that slots class (which is a direct class) has a
	;;; "redefined" slot. If the indirect slots object is current, this
	;;; value is #f. Otherwise it points to the old class definition
	;;; corresponding to its instances.
	;;;
	;;; To try to clarify things, here is a diagram of the "normal" state of
	;;; affairs. The redefinable class has an associated slots class. When
	;;; it makes instances, the instances have a pointer to the indirect
	;;; "slots" object. The class of the indirect slots object is the slots
	;;; class associated with the instance's class. The "V" arrows indicate
	;;; a vtable (class-of) relationship. Dashed arrows indicate a reference
	;;; from a struct slot to an object.
	;;;
	;;; Initial state.
	;;; +-------------+ +------------------------------+
	;;; \| class ----> slots class, redefined: #f \|
	;;; +-V-----------+ +-V----------------------------+
	;;; V V
	;;; +-V-----------+ +-V----------------------------+
	;;; \| instance ----> slots ... \|
	;;; +-------------+ +------------------------------+
	;;;
	;;; When a class is redefined, it is updated in place. However existing
	;;; instances are only migrated lazily. So after a class has been
	;;; redefined but before the instance has been updated, the state looks
	;;; like this:
	;;;
	;;; Redefined state.
	;;; ,-------------------------------------------.
	;;; \| \|
	;;; +-v-----------+ +----------------------------\|-+
	;;; \| old class ----> old slots class, redefined:' VVV
	;;; +-------------+ +------------------------------+ V
	;;; V
	;;; +-------------+ +------------------------------+ V
	;;; \| new class ----> new slots class, redefined:#f\| V
	;;; +-V-----------+ +------------------------------+ V
	;;; V V
	;;; +-V-----------+ +------------------------------+ V
	;;; \| old inst ----> slots ... VVV
	;;; +-------------+ +------------------------------+
	;;;
	;;; That is to say, because the class was updated in place, the old
	;;; instance's vtable is the new class, even though the old instance's
	;;; slots still correspond to the old class. The vtable of the old slots
	;;; has the "redefined" field, which has been set to point to a fresh
	;;; object containing the direct slots of the old class, and a pointer to
	;;; the old slots class -- as if it were the old class, but with a new
	;;; temporary identity. This allows us to then call
	;;;
	;;; (change-object-class obj old-class new-class)
	;;;
	;;; which will allocate a fresh slots object for the old instance
	;;; corresponding to the new class, completing the migration for that
	;;; instance.
	;;;
	;;; Lazy instance migration is triggered by "class-of". Calling
	;;; "class-of" on an indirect instance will check the indirect slots to
	;;; see if they need redefinition. If so, we construct a fresh instance
	;;; of the new class and swap fields with the old instance (including
	;;; the indirect-slots field). Unfortunately there is some
	;;; thread-unsafety here, as retrieving the class is unsynchronized with
	;;; retrieving the indirect slots.
	;;;
	(define-class <indirect-slots-class> (<class>)
	(%redefined #:init-value #f))
	(define-class <redefinable-class> (<class>)
	(indirect-slots-class))

	(define-method (compute-slots (class <redefinable-class>))
	(let* ((slots (next-method))
	;; The base method ensured that at most one superclass has
	;; statically allocated slots.
	(static-slots
	(match (filter class-has-statically-allocated-slots?
	(cdr (class-precedence-list class)))
	(() '())
	((class) (struct-ref class class-index-direct-slots)))))
	(define (simplify-slot-definition s)
	;; Here we take a slot definition and strip it to just be a plain
	;; old name, suitable for use as a slot for the plain-old-data
	;; indirect-slots class.
	(and (eq? (slot-definition-allocation s) #:instance)
	(make (class-of s) #:name (slot-definition-name s))))
	(define (maybe-make-indirect-slot-definition s)
	;; Here we copy over all the frippery of a slot definition
	;; (accessors, init-keywords, and so on), but we change the slot
	;; to have virtual allocation and we provide explicit
	;; slot-ref/slot-set! functions that access the slot value through
	;; the indirect slots object. For slot definitions without
	;; instance allocation though, we just pass them through.
	(cond
	((eq? (slot-definition-allocation s) #:instance)
	(let* ((s* (class-slot-definition (slot-ref class 'indirect-slots-class)
	(slot-definition-name s)))
	(ref (slot-definition-slot-ref/raw s*))
	(set! (slot-definition-slot-set! s*)))
	(apply make (class-of s)
	#:allocation #:virtual
	;; TODO: Make faster.
	#:slot-ref (lambda (o)
	(ref (slot-ref o 'indirect-slots)))
	#:slot-set! (lambda (o v)
	(set! (slot-ref o 'indirect-slots) v))
	(let loop ((options (slot-definition-options s)))
	(match options
	(() '())
	(((or #:allocation #:slot-ref #:slot-set!) _ . rest)
	(loop rest))
	((kw arg . rest)
	(cons* kw arg (loop rest))))))))
	(else s)))
	(unless (equal? (list-head slots (length static-slots))
	static-slots)
	(error "unexpected slots"))
	(let* ((indirect-slots (list-tail slots (length static-slots)))
	(indirect-slots-class
	(make-class '()
	(filter-map simplify-slot-definition
	indirect-slots)
	#:name 'indirect-slots
	#:metaclass <indirect-slots-class>)))
	(slot-set! class 'indirect-slots-class indirect-slots-class)
	(append static-slots
	(cons (make <slot> #:name 'indirect-slots)
	(map maybe-make-indirect-slot-definition
	indirect-slots))))))

	(define-method (initialize (class <redefinable-class>) initargs)
	(next-method)
	(class-add-flags! class vtable-flag-goops-indirect))

	(define-method (allocate-instance (class <redefinable-class>) initargs)
	(let ((instance (next-method))
	(nfields (struct-ref/unboxed class class-index-nfields))
	(indirect-slots-class (slot-ref class 'indirect-slots-class)))
	;; Indirect slots will be last struct field.
	(struct-set! instance (1- nfields) (make indirect-slots-class))
	instance))

	;; Called when redefining an existing binding, and the new binding is a
	;; class. Two arguments: the old value, and the new.
	(define-generic class-redefinition)

	(define-method (class-redefinition (old <top>) (new <class>))
	;; Default class-redefinition method is to just replace old binding
	;; with the class.
	new)

	(define-method (class-redefinition (old <redefinable-class>)
	(new <redefinable-class>))
	;; When redefining a redefinable class with a redefinable class, we
	;; migrate the old definition and its instances to become the new
	;; definition.
	;;
	;; Work on direct methods:
	;; 1. Remove accessor methods from the old class
	;; 2. Patch the occurences of new in the specializers by old
	;; 3. Displace the methods from old to new
	(remove-class-accessors! old) ;; -1-
	(let ((methods (class-direct-methods new)))
	(for-each (lambda (m)
	(update-direct-method! m new old)) ;; -2-
	methods)
	(struct-set! new
	class-index-direct-methods
	(append methods (class-direct-methods old))))

	;; Substitute old for new in new cpl
	(set-car! (struct-ref new class-index-cpl) old)

	;; Remove the old class from the direct-subclasses list of its super classes
	(for-each (lambda (c) (struct-set! c class-index-direct-subclasses
	(delv! old (class-direct-subclasses c))))
	(class-direct-supers old))

	;; Replace the new class with the old in the direct-subclasses of the supers
	(for-each (lambda (c)
	(struct-set! c class-index-direct-subclasses
	(cons old (delv! new (class-direct-subclasses c)))))
	(class-direct-supers new))

	;; Swap object headers
	(%modify-instance old new)

	;; Now old is NEW!

	;; Redefine all the subclasses of old to take into account modification
	(for-each
	(lambda (c)
	(update-direct-subclass! c new old))
	(class-direct-subclasses new))

	;; Invalidate class so that subsequent instance slot accesses invoke
	;; change-object-class
	(let ((slots-class (slot-ref new 'indirect-slots-class)))
	(slot-set! slots-class '%redefined new)
	(class-add-flags! slots-class vtable-flag-goops-needs-migration))

	old)

	(define-method (remove-class-accessors! (c <class>))
	(for-each (lambda (m)
	(when (is-a? m <accessor-method>)
	(let ((gf (slot-ref m 'generic-function)))
	;; remove the method from its GF
	(slot-set! gf 'methods
	(delq1! m (slot-ref gf 'methods)))
	(invalidate-method-cache! gf)
	;; remove the method from its specializers
	(remove-method-in-classes! m))))
	(class-direct-methods c)))

	(define-method (update-direct-method! (m <method>)
	(old <class>)
	(new <class>))
	(let loop ((l (method-specializers m)))
	;; Note: the <top> in dotted list is never used.
	;; So we can work as if we had only proper lists.
	(when (pair? l)
	(when (eqv? (car l) old)
	(set-car! l new))
	(loop (cdr l)))))

	(define-method (update-direct-subclass! (c <class>)
	(old <class>)
	(new <class>))
	(class-redefinition c
	(make-class (class-direct-supers c)
	(class-direct-slots c)
	#:name (class-name c)
	#:metaclass (class-of c))))

	(define (change-object-class old-instance old-class new-class)
	(let ((new-instance (allocate-instance new-class '())))
	;; Initialize the slots of the new instance
	(for-each
	(lambda (slot)
	(unless (eq? slot 'indirect-slots)
	(if (and (slot-exists? old-instance slot)
	(memq (%slot-definition-allocation
	(class-slot-definition old-class slot))
	'(#:instance #:virtual))
	(slot-bound? old-instance slot))
	;; Slot was present and allocated in old instance; copy it
	(slot-set! new-instance slot (slot-ref old-instance slot))
	;; slot was absent; initialize it with its default value
	(let ((init (slot-init-function new-class slot)))
	(when init
	(slot-set! new-instance slot (init)))))))
	(map slot-definition-name (class-slots new-class)))
	;; Exchange old and new instance in place to keep pointers valid
	(%modify-instance old-instance new-instance)
	;; Allow class specific updates of instances (which now are swapped)
	(update-instance-for-different-class new-instance old-instance)
	old-instance))


	(define-method (update-instance-for-different-class (old-instance <object>)
	(new-instance
	<object>))
	;;not really important what we do, we just need a default method
	new-instance)

	(define-method (change-class (old-instance <object>)
	(new-class <redefinable-class>))
	(unless (is-a? (class-of old-instance) <redefinable-class>)
	(error (string-append
	"Default change-class implementation only works on"
	" instances of redefinable classes")))
	(change-object-class old-instance (class-of old-instance) new-class))

	(define class-of-obsolete-indirect-instance
	(let ((lock (make-mutex))
	(stack '()))
	(lambda (instance)
	(let* ((new-class (struct-vtable instance))
	(nfields (struct-ref/unboxed new-class class-index-nfields))
	;; Indirect slots are in last instance slot. For normal
	;; instances last slot is 0 of course.
	(slots (struct-ref instance (1- nfields)))
	(old-class (slot-ref (class-of slots) '%redefined)))
	(let/ec return
	(dynamic-wind
	(lambda ()
	(with-mutex lock
	(if (memv slots stack)
	(return (or old-class new-class))
	(set! stack (cons slots stack)))))
	(lambda ()
	(when old-class
	(change-class instance new-class))
	new-class)
	(lambda ()
	(with-mutex lock
	(set! stack (delq! slots stack))))))))))




	;;;
	;;; {Final initialization}
	;;;

	;; Tell C code that the main bulk of Goops has been loaded
	(%goops-loaded)




	;;;
	;;; {SMOB and port classes}
	;;;

	(define <promise> (find-subclass <top> '<promise>))
	(define <thread> (find-subclass <top> '<thread>))
	(define <mutex> (find-subclass <top> '<mutex>))
	(define <condition-variable> (find-subclass <top> '<condition-variable>))
	(define <regexp> (find-subclass <top> '<regexp>))
	(define <hook> (find-subclass <top> '<hook>))
	(define <bitvector> (find-subclass <top> '<bitvector>))
	(define <random-state> (find-subclass <top> '<random-state>))
	(define <directory> (find-subclass <top> '<directory>))
	(define <array> (find-subclass <top> '<array>))
	(define <character-set> (find-subclass <top> '<character-set>))
	(define <guardian> (find-subclass <applicable> '<guardian>))
	(define <macro> (find-subclass <top> '<macro>))

	;; <dynamic-object> used to be a SMOB type, albeit not exported even to
	;; C. However now it's a record type, though still private. Cross our
	;; fingers that nobody is using it in anger!
	(define <dynamic-object>
	(module-ref (resolve-module '(system foreign-library)) '<foreign-library>))

	(define (define-class-subtree class)
	(define! (class-name class) class)
	(for-each define-class-subtree (class-direct-subclasses class)))

	(define-class-subtree (find-subclass <port> '<file-port>))