(print-unreadable-object (x stream :type t)
(prin1 (type-class-name x) stream)))))
;; the name of this type class (used to resolve references at load time)
- (name nil :type symbol) ; FIXME: should perhaps be REQUIRED-ARGUMENT?
+ (name nil :type symbol) ; FIXME: should perhaps be (MISSING-ARG) default?
;; Dyadic type methods. If the classes of the two types are EQ, then
;; we call the SIMPLE-xxx method. If the classes are not EQ, and
;; either type's class has a COMPLEX-xxx method, then we call it.
(complex-intersection2 nil :type (or function null))
(simple-= #'must-supply-this :type function)
(complex-= nil :type (or function null))
+ ;; monadic functions
+ (negate #'must-supply-this :type function)
;; a function which returns a Common Lisp type specifier
;; representing this type
(unparse #'must-supply-this :type function)
;; supplying both.
(unary-typep nil :type (or symbol null))
(typep nil :type (or symbol null))
- ;; Like TYPEP, UNARY-TYPEP except these functions coerce objects to this
- ;; type.
+ ;; These are like TYPEP and UNARY-TYPEP except they coerce objects to
+ ;; the type.
(unary-coerce nil :type (or symbol null))
(coerce :type (or symbol null))
|#
(:complex-intersection2 . type-class-complex-intersection2)
(:simple-= . type-class-simple-=)
(:complex-= . type-class-complex-=)
+ (:negate . type-class-negate)
(:unparse . type-class-unparse))))
-(eval-when (:compile-toplevel :load-toplevel :execute)
-
+(declaim (ftype (function (type-class) type-class) copy-type-class-coldly))
+(eval-when (#-sb-xc :compile-toplevel :load-toplevel :execute)
;;; Copy TYPE-CLASS object X, using only operations which will work
;;; early in cold load. (COPY-STRUCTURE won't work early in cold load,
;;; because it needs RAW-INDEX and RAW-LENGTH information from
;;; the positive effect of removing indirection could be cancelled by
;;; the negative effect of imposing an unnecessary GC write barrier on
;;; raw data which doesn't actually affect GC.)
-(declaim (ftype (function (type-class) type-class) copy-type-class-coldly))
(defun copy-type-class-coldly (x)
;; KLUDGE: If the slots of TYPE-CLASS ever change in a way not
;; reflected in *TYPE-CLASS-FUN-SLOTS*, the slots here will
;; have to be hand-tweaked to match. -- WHN 2001-03-19
- (make-type-class :name (type-class-name x)
+ (make-type-class :name (type-class-name x)
. #.(mapcan (lambda (type-class-fun-slot)
(destructuring-bind (keyword . slot-accessor)
type-class-fun-slot
(%invoke-type-method ',(class-fun-slot-or-lose simple)
',(class-fun-slot-or-lose
(if complex-arg1-p
- complex-arg1
- complex-arg2))
+ complex-arg1
+ complex-arg2))
',(class-fun-slot-or-lose complex-arg2)
,complex-arg1-p
,type1
,type2)
(if valid-p
- (values result-a result-b)
- ,default)))
+ (values result-a result-b)
+ ,default)))
;;; most of the implementation of !INVOKE-TYPE-METHOD
;;;
(let ((class1 (type-class-info type1))
(class2 (type-class-info type2)))
(if (eq class1 class2)
- (funcall (funcall simple class1) type1 type2)
- (let ((complex2 (funcall cslot2 class2)))
- (if complex2
- (funcall complex2 type1 type2)
- (let ((complex1 (funcall cslot1 class1)))
- (if complex1
- (if complex-arg1-p
- (funcall complex1 type1 type2)
- (funcall complex1 type2 type1))
- ;; No meaningful result was found: the caller should
- ;; use the default value instead.
- (return-from %invoke-type-method (values nil nil nil))))))))
+ (funcall (the function (funcall simple class1)) type1 type2)
+ (let ((complex2 (funcall cslot2 class2)))
+ (declare (type (or function null) complex2))
+ (if complex2
+ (funcall complex2 type1 type2)
+ (let ((complex1 (funcall cslot1 class1)))
+ (declare (type (or function null) complex1))
+ (if complex1
+ (if complex-arg1-p
+ (funcall complex1 type1 type2)
+ (funcall complex1 type2 type1))
+ ;; No meaningful result was found: the caller
+ ;; should use the default value instead.
+ (return-from %invoke-type-method
+ (values nil nil nil))))))))
;; If we get to here (without breaking out by calling RETURN-FROM)
;; then a meaningful result was found, and we return it.
(values result-a result-b t)))
+;;; This is a very specialized implementation of CLOS-style
+;;; CALL-NEXT-METHOD within our twisty little type class object
+;;; system, which works given that it's called from within a
+;;; COMPLEX-SUBTYPEP-ARG2 method. (We're particularly motivated to
+;;; implement CALL-NEXT-METHOD in that case, because ANSI imposes some
+;;; strict limits on when SUBTYPEP is allowed to return (VALUES NIL NIL),
+;;; so instead of just complacently returning (VALUES NIL NIL) from a
+;;; COMPLEX-SUBTYPEP-ARG2 method we usually need to CALL-NEXT-METHOD.)
+;;;
+;;; KLUDGE: In CLOS, this could just be CALL-NEXT-METHOD and
+;;; everything would Just Work without us having to think about it. In
+;;; our goofy type dispatch system, it's messier to express. It's also
+;;; more fragile, since (0) there's no check that it's called from
+;;; within a COMPLEX-SUBTYPEP-ARG2 method as it should be, and (1) we
+;;; rely on our global knowledge that the next (and only) relevant
+;;; method is COMPLEX-SUBTYPEP-ARG1, and (2) we rely on our global
+;;; knowledge of the appropriate default for the CSUBTYPEP function
+;;; when no next method exists. -- WHN 2002-04-07
+;;;
+;;; (We miss CLOS! -- CSR and WHN)
+(defun invoke-complex-subtypep-arg1-method (type1 type2 &optional subtypep win)
+ (let* ((type-class (type-class-info type1))
+ (method-fun (type-class-complex-subtypep-arg1 type-class)))
+ (if method-fun
+ (funcall (the function method-fun) type1 type2)
+ (values subtypep win))))
+
+;;; KLUDGE: This function is dangerous, as its overuse could easily
+;;; cause stack exhaustion through unbounded recursion. We only use
+;;; it in one place; maybe it ought not to be a function at all?
+(defun invoke-complex-=-other-method (type1 type2)
+ (let* ((type-class (type-class-info type1))
+ (method-fun (type-class-complex-= type-class)))
+ (if method-fun
+ (funcall (the function method-fun) type2 type1)
+ (values nil t))))
+
(!defun-from-collected-cold-init-forms !type-class-cold-init)