516 lines
15 KiB
Scheme
516 lines
15 KiB
Scheme
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; Copyright (c) 1993-1999 by Richard Kelsey and Jonathan Rees. See file COPYING.
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; Generic procedure package
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; This is written in fairly portable Scheme. It needs:
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; Scheme 48 low-level macros (explicit renaming), in one small place.
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; (CALL-ERROR message proc arg ...) - signal an error.
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; Record package and DEFINE-RECORD-TYPES macro.
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; An object :RECORD-TYPE which is the record type descriptor for
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; record type descriptors (records are assumed to be records).
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; This wouldn't be difficult to change.
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; A RECORD? predicate (not essential - only for defining a DISCLOSE
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; method for records).
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; --------------------
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; Simple types.
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; More specific types have higher priorities. The priorities are used
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; to establish the ordinary in which type predicates are called.
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(define-record-type simple-type :simple-type
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(really-make-simple-type supers predicate priority id)
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simple-type?
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(supers simple-type-superiors)
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(predicate simple-type-predicate)
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(priority simple-type-priority)
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(id simple-type-id)
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(more)) ;if needed later
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(define-record-discloser :simple-type
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(lambda (c) `(simple-type ,(simple-type-id c))))
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(define (make-simple-type supers predicate id)
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(make-immutable!
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(really-make-simple-type supers
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predicate
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(compute-priority supers)
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id)))
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(define (compute-priority supers)
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(if (null? supers)
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0
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(+ (apply max (map %type-priority supers))
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*increment*)))
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(define *increment* 10)
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; These two procedures will become generic later, but must exist early
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; in order to be able to bootstrap the method definition mechanism.
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(define (%type-priority type)
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(cond ((simple-type? type)
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(simple-type-priority type))
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((record-type? type)
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(record-type-priority type))
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(else (type-priority type)))) ;generic
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(define (%type-predicate type)
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(cond ((simple-type? type)
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(simple-type-predicate type))
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((record-type? type)
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(record-predicate type))
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(else (type-predicate type)))) ;generic
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(define (%same-type? t1 t2)
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(or (eq? t1 t2)
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(if (simple-type? t1)
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#f
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(if (record-type? t1)
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#f
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(same-type? t1 t2)))))
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(define-syntax define-simple-type
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(syntax-rules ()
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((define-simple-type ?name (?super ...) ?pred)
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(define ?name (make-simple-type (list ?super ...) ?pred '?name)))))
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; --------------------
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; Built-in Scheme types
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(define-simple-type :syntax () #f)
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(define-simple-type :values () #f) ;any number of values
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(define (value? x) #t)
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(define-simple-type :value (:values) value?)
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(define-simple-type :zero (:values) (lambda (x) #f))
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(define-simple-type :number (:value) number?)
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(define-simple-type :complex (:number) complex?)
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(define-simple-type :real (:complex) real?)
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(define-simple-type :rational (:real) rational?)
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(define-simple-type :integer (:rational) integer?)
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(define-simple-type :exact-integer (:integer)
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(lambda (n) (and (integer? n) (exact? n))))
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(define-simple-type :boolean (:value) boolean?)
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(define-simple-type :symbol (:value) symbol?)
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(define-simple-type :char (:value) char?)
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(define-simple-type :null (:value) null?)
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(define-simple-type :pair (:value) pair?)
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(define-simple-type :vector (:value) vector?)
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(define-simple-type :string (:value) string?)
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(define-simple-type :procedure (:value) procedure?)
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(define-simple-type :input-port (:value) input-port?)
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(define-simple-type :output-port (:value) output-port?)
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(define-simple-type :eof-object (:value) eof-object?)
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; If there is no RECORD? predicate, do
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; (define-simple-type :record (:value) value?)
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; and change the DISCLOSE method for records to
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; (or (disclose-record obj) (next-method)).
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(define-simple-type :record (:value) record?)
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; If record types are not records, un-comment the following line.
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; (define-simple-type :record-type (:value) record-type?)
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; Given a record type, RECORD-TYPE-PRIORITY returns its priority.
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; Here we establish that every record type is a direct subtype of the
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; :RECORD type.
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(define record-type-priority
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(let ((r-priority
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(simple-type-priority (make-simple-type (list :record) #f #f))))
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(lambda (rt) r-priority)))
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; --------------------
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; Method-info records are triples <type-list, n-ary?, proc>.
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(define-record-type method-info :method-info
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(really-make-method-info types n-ary? proc)
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method-info?
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(types method-info-types)
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(n-ary? method-info-n-ary?)
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(proc method-info-proc))
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(define (make-method-info types n-ary? proc)
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(make-immutable! (really-make-method-info types n-ary? proc)))
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(define-record-discloser :method-info
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(lambda (info)
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`(method-info ,(method-info-types info) ,(method-info-n-ary? info))))
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; --------------------
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; Method lists
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; A method list is a list of method-info records, sorted in order from
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; most specific to least specific.
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(define (empty-method-list) '())
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; insert-method inserts an entry into a method list so that the most
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; specific methods come earliest in the list. The last method should
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; be a default method or error signal(l)er.
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(define (insert-method info ms)
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(let recur ((ms ms))
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(if (null? ms)
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(cons info ms)
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(if (more-specific? (car ms) info)
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(cons (car ms) (recur (cdr ms)))
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(cons info
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(if (same-applicability? (car ms) info)
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(cdr ms)
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ms))))))
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; Replace an existing method with identical domain.
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(define (same-applicability? info1 info2)
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(and (every2 %same-type?
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(method-info-types info1)
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(method-info-types info2))
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(eq? (method-info-n-ary? info1) (method-info-n-ary? info2))))
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(define (every2 pred l1 l2)
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(if (null? l1)
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(null? l2)
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(if (null? l2)
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#f
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(and (pred (car l1) (car l2)) (every2 pred (cdr l1) (cdr l2))))))
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; This interacts with methods->perform, below.
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; In this version, it's supposed to be a total order.
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(define (more-specific? info1 info2)
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(let ((t1 (method-info-types info1))
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(t2 (method-info-types info2)))
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(let ((l1 (length t1))
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(l2 (length t2))
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(foo? (and (not (method-info-n-ary? info1))
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(method-info-n-ary? info2))))
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(if (= l1 l2)
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(or foo?
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(let loop ((l1 t1)
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(l2 t2))
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(if (null? l2)
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#f
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(or (more-specific-type? (car l1) (car l2))
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(and (%same-type? (car l1) (car l2))
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(loop (cdr l1) (cdr l2)))))))
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(and (> l1 l2)
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foo?)))))
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(define (more-specific-type? t1 t2)
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(> (%type-priority t1) (%type-priority t2)))
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; --------------------
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; A method table is a cell that contains a method list.
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; Note that the method table is not reachable from the generic
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; procedure. This means good things for the GC.
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(define-record-type method-table :method-table
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(really-make-method-table methods prototype
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generic get-perform set-perform! id)
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method-table?
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(methods method-table-methods set-method-table-methods!)
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(prototype method-table-prototype)
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(generic make-generic)
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(get-perform method-table-get-perform)
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(set-perform! method-table-set-perform!)
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(id method-table-id))
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(define-record-discloser :method-table
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(lambda (t) `(method-table ,(method-table-id t))))
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(define (make-method-table id . option)
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(let* ((prototype (if (null? option)
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(make-method-info '() #t #f)
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(car option)))
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(mtable (call-with-values make-cell-for-generic
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(lambda (generic get-perform set-perform!)
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(really-make-method-table '()
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prototype
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generic
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get-perform
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set-perform!
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id)))))
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(set-final-method!
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mtable
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(lambda (next-method . args)
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(apply call-error "invalid or unimplemented operation"
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id args)))
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mtable))
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(define (make-cell-for-generic)
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(let ((perform #f))
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;; PERFORM always caches (METHODS->PERFORM method-list prototype).
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(values (lambda args (perform args)) ;Generic proc
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(lambda () perform)
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(lambda (new) (set! perform new)))))
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(define (add-to-method-table! mtable info)
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(let ((l (insert-method info (method-table-methods mtable))))
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(set-method-table-methods! mtable l)
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((method-table-set-perform! mtable)
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(methods->perform l (method-table-prototype mtable)))))
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(define (set-final-method! mtable proc)
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(add-to-method-table! mtable
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(make-method-info '()
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#t
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proc)))
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(define (apply-generic mtable args)
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;; (apply (make-generic mtable) args)
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(((method-table-get-perform mtable)) args)) ;+++
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; DEFINE-GENERIC
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(define-syntax define-generic
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(syntax-rules ()
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((define-generic ?name ?mtable-name)
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(begin (define ?mtable-name (make-method-table '?name))
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(define ?name (make-generic ?mtable-name))))
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((define-generic ?name ?mtable-name (?spec . ?specs))
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(begin (define ?mtable-name
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(make-method-table '?name
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(method-info ?name ("next" next-method
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?spec . ?specs)
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(next-method))))
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(define ?name (make-generic ?mtable-name))))))
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; --------------------
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; Method combination.
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; Here is the specification:
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;(define (apply-generic mtable args)
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; (let loop ((ms (method-table-methods mtable)))
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; (let ((next-method (lambda () (loop (cdr ms)))))
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; (if (let test ((ts (method-info-types (car ms)))
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; (args args))
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; (if (null? ts)
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; (or (null? args)
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; (method-info-n-ary? (car ms)))
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; (and ((%type-predicate (car ts)) (car args))
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; (test (cdr ts) (cdr args)))))
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; (apply (method-info-proc (car ms))
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; next-method
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; args)
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; (next-method)))))
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; (perform arg-list)
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; (apply proc next-method-thunk arg-list)
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; This version of METHODS->PERFORM simply marches through all the
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; methods, looking for one that handles the operation.
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; The prototype is currently ignored, but it could be put to good use.
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(define (methods->perform l prototype)
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(let recur ((l l))
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(let* ((info (car l))
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(proc (method-info-proc info)))
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(if (null? (cdr l))
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(last-action proc)
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(one-action (argument-sequence-predicate info)
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proc
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(recur (cdr l)))))))
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(define (last-action proc)
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(lambda (args)
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(apply proc #f args)))
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(define (one-action pred proc perform-next)
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(lambda (args)
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(if (pred args)
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(apply proc
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(lambda () (perform-next args)) ; next-method
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args)
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(perform-next args))))
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(define (argument-sequence-predicate info)
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(let recur ((types (method-info-types info)))
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(if (null? types)
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(if (method-info-n-ary? info) value? null?)
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(let ((pred (%type-predicate (car types)))
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(check-rest (recur (cdr types))))
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(if (eq? pred value?)
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(check-for-next check-rest) ;+++
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(check-next pred check-rest))))))
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(define (check-for-next check-rest)
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(lambda (args)
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(if (null? args)
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#f
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(check-rest (cdr args)))))
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(define (check-next pred check-rest)
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(lambda (args)
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(if (null? args)
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#f
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(if (pred (car args))
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(check-rest (cdr args))
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#f))))
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; --------------------
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; METHOD-INFO macro.
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; Returns a method-info record.
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; You can specify the name of the next-method parameter by saying
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; (method-info my-name (x y "next" n) body ...)
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; Otherwise, the next-method parameter will be named next-method.
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; Just pretend it's Dylan and that #next reads as "next".
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(define-syntax method-info
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(syntax-rules ()
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((method-info ?id ?formals ?body ...)
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(method-internal ?formals () () #f ?id ?body ...))))
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(define-syntax method-internal
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(syntax-rules ()
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((method-internal ((?formal1 ?type1) . ?specs)
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(?formal ...) (?type ...) ?next
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. ?rest)
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(method-internal ?specs
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(?formal ... ?formal1) (?type ... ?type1) ?next
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. ?rest))
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((method-internal ("next" ?next . ?specs)
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(?formal ...) (?type ...) ?ignore
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. ?rest)
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(method-internal ?specs
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(?formal ...) (?type ...) ?next
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. ?rest))
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((method-internal (?spec . ?specs)
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(?formal ...) (?type ...) ?next
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. ?rest)
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(method-internal ?specs
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(?formal ... ?spec) (?type ... :value) ?next
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. ?rest))
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((method-internal ?rest
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(?formal ...) (?type ...) ?next
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?id ?body ...)
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(make-method-info (list ?type ...)
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(not (null? '?rest))
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(let ((?id (with-next-method ?next (?formal ... . ?rest)
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?body ...)))
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;; The (let ...) is a hack for the Scheme 48
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;; byte code compiler, which will remember
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;; ?id as the procedure's name. This should
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;; aid debugging a little bit since the name
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;; shows up in backtraces and the inspector.
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?id)))))
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; Non-hygienic, a la Dylan
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(define-syntax with-next-method
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(cons (lambda (e r c)
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(let ((next (or (cadr e) 'next-method)))
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`(,(r 'lambda) (,next ,@(caddr e))
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,@(cdddr e))))
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'(lambda)))
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; DEFINE-METHOD macro.
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(define-syntax define-method
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(syntax-rules ()
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((define-method ?mtable ?formals ?body ...)
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(add-method! ?mtable
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(method-info ?mtable ?formals ?body ...)))))
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(define-generic add-method! &add-method! (mtable info))
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(let ((info
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(method-info add-method! ((mtable :method-table) (info :method-info))
|
||
|
(add-to-method-table! mtable info))))
|
||
|
(add-to-method-table! &add-method! info))
|
||
|
|
||
|
; --------------------
|
||
|
; Generic functions on types: sort of a meta-object protocol, huh?
|
||
|
|
||
|
(define-generic type-predicate &type-predicate (t))
|
||
|
|
||
|
(define-method &type-predicate ((t :record-type)) (record-predicate t))
|
||
|
(define-method &type-predicate ((t :simple-type)) (simple-type-predicate t))
|
||
|
|
||
|
(define-generic type-priority &type-priority (t))
|
||
|
|
||
|
(define-method &type-priority ((t :record-type)) (record-type-priority t))
|
||
|
(define-method &type-priority ((t :simple-type)) (simple-type-priority t))
|
||
|
|
||
|
(define-generic type-superiors &type-superiors (t))
|
||
|
|
||
|
(define-method &type-superiors ((t :record-type)) (list :record))
|
||
|
(define-method &type-superiors ((t :simple-type)) (simple-type-superiors t))
|
||
|
|
||
|
|
||
|
; Type equivalence
|
||
|
|
||
|
(define-generic same-type? &same-type? (t1 t2))
|
||
|
|
||
|
(define-method &same-type? (t1 t2) (eq? t1 t2))
|
||
|
|
||
|
(define-method &same-type? ((t1 :simple-type) (t2 :simple-type))
|
||
|
(and (eq? (simple-type-predicate t1) (simple-type-predicate t2))
|
||
|
(eq? (simple-type-id t1) (simple-type-id t2)))) ;?
|
||
|
|
||
|
; --------------------
|
||
|
; Singleton types.
|
||
|
|
||
|
(define-record-type singleton :singleton
|
||
|
(singleton value)
|
||
|
(value singleton-value))
|
||
|
|
||
|
(define-record-discloser :singleton
|
||
|
(lambda (s) `(singleton ,(singleton-value s))))
|
||
|
|
||
|
(define (compare-to val)
|
||
|
(lambda (x) (eqv? x val)))
|
||
|
|
||
|
(define-method &type-predicate ((s :singleton))
|
||
|
(compare-to (singleton-value s)))
|
||
|
|
||
|
(define-method &type-priority ((s :singleton)) 1000000)
|
||
|
|
||
|
(define-method &same-type? ((s1 :singleton) (s2 :singleton))
|
||
|
(eqv? (singleton-value s1) (singleton-value s2)))
|
||
|
|
||
|
; --------------------
|
||
|
; DISCLOSE
|
||
|
|
||
|
; A generic procedure for producing printed representations.
|
||
|
; Should return one of
|
||
|
; - A list (symbol info ...), to be printed as #{Symbol info ...}
|
||
|
; - #f, meaning no information available on how to print.
|
||
|
; This is intended to be used not only by write and display, but also by
|
||
|
; the pretty printer.
|
||
|
|
||
|
(define-generic disclose &disclose (x))
|
||
|
|
||
|
(define-method &disclose (obj) #f)
|
||
|
|
||
|
(define-method &disclose ((obj :record))
|
||
|
(or (disclose-record obj)
|
||
|
'(record)))
|
||
|
|
||
|
(define-method &add-method! ((d (singleton &disclose)) info)
|
||
|
(let ((t (car (method-info-types info))))
|
||
|
(if (record-type? t)
|
||
|
(define-record-discloser t (proc->discloser (method-info-proc info)))
|
||
|
(next-method))))
|
||
|
|
||
|
(define (proc->discloser proc)
|
||
|
(lambda (arg)
|
||
|
(proc (lambda () #f) arg)))
|
||
|
|
||
|
;(define-method &disclose ((s :singleton))
|
||
|
; `(singleton ,(singleton-value s)))
|