;;; The CLASS structure is a supertype of all class types. A CLASS is
;;; also a CTYPE structure as recognized by the type system.
-(def!struct (;; FIXME: Yes, these #+SB-XC/#-SB-XC conditionals are
- ;; pretty hairy. I'm considering cleaner ways to rewrite
- ;; the whole build system to avoid these (and other hacks
- ;; too, e.g. UNCROSS) but I'm not sure yet that I've got
- ;; it figured out. -- WHN 19990729
- #-sb-xc sb!xc:class
- #+sb-xc cl:class
- (:make-load-form-fun class-make-load-form-fun)
+(def!struct (classoid
+ (:make-load-form-fun classoid-make-load-form-fun)
(:include ctype
- (:class-info (type-class-or-lose #-sb-xc 'sb!xc:class
- #+sb-xc 'cl:class)))
+ (class-info (type-class-or-lose 'classoid)))
(:constructor nil)
#-no-ansi-print-object
(:print-object
(lambda (class stream)
- (let ((name (sb!xc:class-name class)))
+ (let ((name (classoid-name class)))
(print-unreadable-object (class stream
:type t
:identity (not name))
;; reasonably for anonymous classes.
"~:[anonymous~;~:*~S~]~@[ (~(~A~))~]"
name
- (class-state class))))))
+ (classoid-state class))))))
#-sb-xc-host (:pure nil))
- ;; the value to be returned by CLASS-NAME. (CMU CL used the raw slot
- ;; accessor for this slot directly as the definition of
- ;; CL:CLASS-NAME, but that was slightly wrong, because ANSI says
- ;; that CL:CLASS-NAME is a generic function.)
- (%name nil :type symbol)
+ ;; the value to be returned by CLASSOID-NAME.
+ (name nil :type symbol)
;; the current layout for this class, or NIL if none assigned yet
- (layout nil :type (or sb!kernel::layout null))
+ (layout nil :type (or layout null))
;; How sure are we that this class won't be redefined?
;; :READ-ONLY = We are committed to not changing the effective
;; slots or superclasses.
;; the PCL class object for this class, or NIL if none assigned yet
(pcl-class nil))
-;;; KLUDGE: ANSI says this is a generic function, but we need it for
-;;; bootstrapping before CLOS exists, so we define it as an ordinary
-;;; function and let CLOS code overwrite it later. -- WHN ca. 19990815
-(defun sb!xc:class-name (class)
- (class-%name class))
-
-(defun class-make-load-form-fun (class)
- (/show "entering CLASS-MAKE-LOAD-FORM-FUN" class)
- (let ((name (sb!xc:class-name class)))
- (unless (and name (eq (sb!xc:find-class name nil) class))
+(defun classoid-make-load-form-fun (class)
+ (/show "entering %CLASSOID-MAKE-LOAD-FORM-FUN" class)
+ (let ((name (classoid-name class)))
+ (unless (and name (eq (find-classoid name nil) class))
(/show "anonymous/undefined class case")
(error "can't use anonymous or undefined class as constant:~% ~S"
class))
;; names which creates fast but non-cold-loadable, non-compact
;; code. In this context, we'd rather have compact,
;; cold-loadable code. -- WHN 19990928
- (declare (notinline sb!xc:find-class))
- (sb!xc:find-class ',name))))
+ (declare (notinline find-classoid))
+ (find-classoid ',name))))
\f
;;;; basic LAYOUT stuff
;;; Note: This bound is set somewhat less than MOST-POSITIVE-FIXNUM
;;; in order to guarantee that several hash values can be added without
;;; overflowing into a bignum.
-(defconstant layout-clos-hash-max (ash most-positive-fixnum -3)
+(def!constant layout-clos-hash-max (ash most-positive-fixnum -3)
#!+sb-doc
"the inclusive upper bound on LAYOUT-CLOS-HASH values")
(clos-hash-6 (random-layout-clos-hash) :type index)
(clos-hash-7 (random-layout-clos-hash) :type index)
;; the class that this is a layout for
- (class (required-argument)
- ;; FIXME: Do we really know this is a CL:CLASS? Mightn't it
- ;; be a SB-PCL:CLASS under some circumstances? What goes here
- ;; when the LAYOUT is in fact a PCL::WRAPPER?
- :type #-sb-xc sb!xc:class #+sb-xc cl:class)
- ;; The value of this slot can be
+ (classoid (missing-arg) :type classoid)
+ ;; The value of this slot can be:
;; * :UNINITIALIZED if not initialized yet;
;; * NIL if this is the up-to-date layout for a class; or
;; * T if this layout has been invalidated (by being replaced by
;; * something else (probably a list) if the class is a PCL wrapper
;; and PCL has made it invalid and made a note to itself about it
(invalid :uninitialized :type (or cons (member nil t :uninitialized)))
- ;; The layouts for all classes we inherit. If hierarchical these are
- ;; in order from most general down to (but not including) this
- ;; class.
+ ;; the layouts for all classes we inherit. If hierarchical, i.e. if
+ ;; DEPTHOID >= 0, then these are ordered by ORDER-LAYOUT-INHERITS,
+ ;; so that each inherited layout appears at its expected depth,
+ ;; i.e. at its LAYOUT-DEPTHOID value.
;;
- ;; FIXME: Couldn't this be (SIMPLE-ARRAY LAYOUT 1) instead of
- ;; SIMPLE-VECTOR?
+ ;; Remaining elements are filled by the non-hierarchical layouts or,
+ ;; if they would otherwise be empty, by copies of succeeding layouts.
(inherits #() :type simple-vector)
- ;; If inheritance is hierarchical, this is -1. If inheritance is not
+ ;; If inheritance is not hierarchical, this is -1. If inheritance is
;; hierarchical, this is the inheritance depth, i.e. (LENGTH INHERITS).
;; Note:
;; (1) This turns out to be a handy encoding for arithmetically
;; renamed because some of us find it confusing to call something
;; a depth when it isn't quite.
(depthoid -1 :type layout-depthoid)
- ;; The number of top-level descriptor cells in each instance.
+ ;; the number of top level descriptor cells in each instance
(length 0 :type index)
;; If this layout has some kind of compiler meta-info, then this is
;; it. If a structure, then we store the DEFSTRUCT-DESCRIPTION here.
(eval-when (:compile-toplevel :load-toplevel :execute)
(defun layout-proper-name (layout)
- (class-proper-name (layout-class layout))))
+ (classoid-proper-name (layout-classoid layout))))
\f
;;;; support for the hash values used by CLOS when working with LAYOUTs
-(defconstant layout-clos-hash-length 8)
+(def!constant layout-clos-hash-length 8)
#!-sb-fluid (declaim (inline layout-clos-hash))
(defun layout-clos-hash (layout i)
;; FIXME: Either this I should be declared to be `(MOD
;;; been split off into INIT-OR-CHECK-LAYOUT.
(declaim (ftype (function (symbol) layout) find-layout))
(defun find-layout (name)
- (let ((class (sb!xc:find-class name nil)))
- (or (and class (class-layout class))
+ (let ((classoid (find-classoid name nil)))
+ (or (and classoid (classoid-layout classoid))
(gethash name *forward-referenced-layouts*)
(setf (gethash name *forward-referenced-layouts*)
- (make-layout :class (or class (make-undefined-class name)))))))
+ (make-layout :classoid (or classoid
+ (make-undefined-classoid name)))))))
;;; If LAYOUT is uninitialized, initialize it with CLASS, LENGTH,
;;; INHERITS, and DEPTHOID, otherwise require that it be consistent
;;; preexisting class slot value is OK, and if it's not initialized,
;;; its class slot value is set to an UNDEFINED-CLASS. -- FIXME: This
;;; is no longer true, :UNINITIALIZED used instead.
-(declaim (ftype (function (layout sb!xc:class index simple-vector layout-depthoid) layout)
+(declaim (ftype (function (layout classoid index simple-vector layout-depthoid)
+ layout)
init-or-check-layout))
-(defun init-or-check-layout (layout class length inherits depthoid)
+(defun init-or-check-layout (layout classoid length inherits depthoid)
(cond ((eq (layout-invalid layout) :uninitialized)
;; There was no layout before, we just created one which
;; we'll now initialize with our information.
(setf (layout-length layout) length
(layout-inherits layout) inherits
(layout-depthoid layout) depthoid
- (layout-class layout) class
+ (layout-classoid layout) classoid
(layout-invalid layout) nil))
;; FIXME: Now that LAYOUTs are born :UNINITIALIZED, maybe this
;; clause is not needed?
((not *type-system-initialized*)
- (setf (layout-class layout) class))
+ (setf (layout-classoid layout) classoid))
(t
;; There was an old layout already initialized with old
;; information, and we'll now check that old information
;; which was known with certainty is consistent with current
;; information which is known with certainty.
- (check-layout layout class length inherits depthoid)))
+ (check-layout layout classoid length inherits depthoid)))
layout)
;;; In code for the target Lisp, we don't use dump LAYOUTs using the
(declare (ignore env))
(when (layout-invalid layout)
(compiler-error "can't dump reference to obsolete class: ~S"
- (layout-class layout)))
- (let ((name (sb!xc:class-name (layout-class layout))))
+ (layout-classoid layout)))
+ (let ((name (classoid-name (layout-classoid layout))))
(unless name
(compiler-error "can't dump anonymous LAYOUT: ~S" layout))
;; Since LAYOUT refers to a class which refers back to the LAYOUT,
;; "initialization" form (which actually doesn't initialize
;; preexisting LAYOUTs, just checks that they're consistent).
`(init-or-check-layout ',layout
- ',(layout-class layout)
+ ',(layout-classoid layout)
',(layout-length layout)
',(layout-inherits layout)
',(layout-depthoid layout)))))
(let ((old-length (layout-length old-layout)))
(unless (= old-length length)
(warn "change in instance length of class ~S:~% ~
- ~A length: ~D~% ~
- ~A length: ~D"
+ ~A length: ~W~% ~
+ ~A length: ~W"
name
old-context old-length
context length)
;;; Require that LAYOUT data be consistent with CLASS, LENGTH,
;;; INHERITS, and DEPTHOID.
-(declaim (ftype (function (layout sb!xc:class index simple-vector layout-depthoid))
+(declaim (ftype (function
+ (layout classoid index simple-vector layout-depthoid))
check-layout))
-(defun check-layout (layout class length inherits depthoid)
- (assert (eq (layout-class layout) class))
+(defun check-layout (layout classoid length inherits depthoid)
+ (aver (eq (layout-classoid layout) classoid))
(when (redefine-layout-warning "current" layout
"compile time" length inherits depthoid)
;; Classic CMU CL had more options here. There are several reasons
(declaim (ftype (function (symbol index simple-vector layout-depthoid) layout)
find-and-init-or-check-layout))
(defun find-and-init-or-check-layout (name length inherits depthoid)
- (/show0 "entering FIND-AND-INIT-OR-CHECK-LAYOUT")
(let ((layout (find-layout name)))
(init-or-check-layout layout
- (or (sb!xc:find-class name nil)
- (make-undefined-class name))
+ (or (find-classoid name nil)
+ (make-undefined-classoid name))
length
inherits
depthoid)))
(eval-when (#-sb-xc :compile-toplevel :load-toplevel :execute)
(defun register-layout (layout &key (invalidate t) destruct-layout)
(declare (type layout layout) (type (or layout null) destruct-layout))
- (let* ((class (layout-class layout))
- (class-layout (class-layout class))
- (subclasses (class-subclasses class)))
+ (let* ((classoid (layout-classoid layout))
+ (classoid-layout (classoid-layout classoid))
+ (subclasses (classoid-subclasses classoid)))
;; Attempting to register ourselves with a temporary undefined
;; class placeholder is almost certainly a programmer error. (I
;; should know, I did it.) -- WHN 19990927
- (assert (not (undefined-class-p class)))
+ (aver (not (undefined-classoid-p classoid)))
;; This assertion dates from classic CMU CL. The rationale is
;; probably that calling REGISTER-LAYOUT more than once for the
;; same LAYOUT is almost certainly a programmer error.
- (assert (not (eq class-layout layout)))
+ (aver (not (eq classoid-layout layout)))
;; Figure out what classes are affected by the change, and issue
;; appropriate warnings and invalidations.
- (when class-layout
- (modify-class class)
+ (when classoid-layout
+ (modify-classoid classoid)
(when subclasses
(dohash (subclass subclass-layout subclasses)
- (modify-class subclass)
+ (modify-classoid subclass)
(when invalidate
(invalidate-layout subclass-layout))))
(when invalidate
- (invalidate-layout class-layout)
- (setf (class-subclasses class) nil)))
+ (invalidate-layout classoid-layout)
+ (setf (classoid-subclasses classoid) nil)))
(if destruct-layout
(setf (layout-invalid destruct-layout) nil
(layout-depthoid destruct-layout)(layout-depthoid layout)
(layout-length destruct-layout) (layout-length layout)
(layout-info destruct-layout) (layout-info layout)
- (class-layout class) destruct-layout)
+ (classoid-layout classoid) destruct-layout)
(setf (layout-invalid layout) nil
- (class-layout class) layout))
+ (classoid-layout classoid) layout))
(let ((inherits (layout-inherits layout)))
(dotimes (i (length inherits)) ; FIXME: should be DOVECTOR
- (let* ((super (layout-class (svref inherits i)))
- (subclasses (or (class-subclasses super)
- (setf (class-subclasses super)
+ (let* ((super (layout-classoid (svref inherits i)))
+ (subclasses (or (classoid-subclasses super)
+ (setf (classoid-subclasses super)
(make-hash-table :test 'eq)))))
- (when (and (eq (class-state super) :sealed)
- (not (gethash class subclasses)))
+ (when (and (eq (classoid-state super) :sealed)
+ (not (gethash classoid subclasses)))
(warn "unsealing sealed class ~S in order to subclass it"
- (sb!xc:class-name super))
- (setf (class-state super) :read-only))
- (setf (gethash class subclasses)
+ (classoid-name super))
+ (setf (classoid-state super) :read-only))
+ (setf (gethash classoid subclasses)
(or destruct-layout layout))))))
(values))
); EVAL-WHEN
+
+;;; Arrange the inherited layouts to appear at their expected depth,
+;;; ensuring that hierarchical type tests succeed. Layouts with
+;;; DEPTHOID >= 0 (i.e. hierarchical classes) are placed first,
+;;; at exactly that index in the INHERITS vector. Then, non-hierarchical
+;;; layouts are placed in remaining elements. Then, any still-empty
+;;; elements are filled with their successors, ensuring that each
+;;; element contains a valid layout.
+;;;
+;;; This reordering may destroy CPL ordering, so the inherits should
+;;; not be read as being in CPL order.
+(defun order-layout-inherits (layouts)
+ (declare (simple-vector layouts))
+ (let ((length (length layouts))
+ (max-depth -1))
+ (dotimes (i length)
+ (let ((depth (layout-depthoid (svref layouts i))))
+ (when (> depth max-depth)
+ (setf max-depth depth))))
+ (let* ((new-length (max (1+ max-depth) length))
+ (inherits (make-array new-length)))
+ (dotimes (i length)
+ (let* ((layout (svref layouts i))
+ (depth (layout-depthoid layout)))
+ (unless (eql depth -1)
+ (let ((old-layout (svref inherits depth)))
+ (unless (or (eql old-layout 0) (eq old-layout layout))
+ (error "layout depth conflict: ~S~%" layouts)))
+ (setf (svref inherits depth) layout))))
+ (do ((i 0 (1+ i))
+ (j 0))
+ ((>= i length))
+ (declare (type index i j))
+ (let* ((layout (svref layouts i))
+ (depth (layout-depthoid layout)))
+ (when (eql depth -1)
+ (loop (when (eql (svref inherits j) 0)
+ (return))
+ (incf j))
+ (setf (svref inherits j) layout))))
+ (do ((i (1- new-length) (1- i)))
+ ((< i 0))
+ (declare (type fixnum i))
+ (when (eql (svref inherits i) 0)
+ (setf (svref inherits i) (svref inherits (1+ i)))))
+ inherits)))
+\f
+;;;; class precedence lists
+
+;;; Topologically sort the list of objects to meet a set of ordering
+;;; constraints given by pairs (A . B) constraining A to precede B.
+;;; When there are multiple objects to choose, the tie-breaker
+;;; function is called with both the list of object to choose from and
+;;; the reverse ordering built so far.
+(defun topological-sort (objects constraints tie-breaker)
+ (declare (list objects constraints)
+ (function tie-breaker))
+ (let ((obj-info (make-hash-table :size (length objects)))
+ (free-objs nil)
+ (result nil))
+ (dolist (constraint constraints)
+ (let ((obj1 (car constraint))
+ (obj2 (cdr constraint)))
+ (let ((info2 (gethash obj2 obj-info)))
+ (if info2
+ (incf (first info2))
+ (setf (gethash obj2 obj-info) (list 1))))
+ (let ((info1 (gethash obj1 obj-info)))
+ (if info1
+ (push obj2 (rest info1))
+ (setf (gethash obj1 obj-info) (list 0 obj2))))))
+ (dolist (obj objects)
+ (let ((info (gethash obj obj-info)))
+ (when (or (not info) (zerop (first info)))
+ (push obj free-objs))))
+ (loop
+ (flet ((next-result (obj)
+ (push obj result)
+ (dolist (successor (rest (gethash obj obj-info)))
+ (let* ((successor-info (gethash successor obj-info))
+ (count (1- (first successor-info))))
+ (setf (first successor-info) count)
+ (when (zerop count)
+ (push successor free-objs))))))
+ (cond ((endp free-objs)
+ (dohash (obj info obj-info)
+ (unless (zerop (first info))
+ (error "Topological sort failed due to constraint on ~S."
+ obj)))
+ (return (nreverse result)))
+ ((endp (rest free-objs))
+ (next-result (pop free-objs)))
+ (t
+ (let ((obj (funcall tie-breaker free-objs result)))
+ (setf free-objs (remove obj free-objs))
+ (next-result obj))))))))
+
+
+;;; standard class precedence list computation
+(defun std-compute-class-precedence-list (class)
+ (let ((classes nil)
+ (constraints nil))
+ (labels ((note-class (class)
+ (unless (member class classes)
+ (push class classes)
+ (let ((superclasses (classoid-direct-superclasses class)))
+ (do ((prev class)
+ (rest superclasses (rest rest)))
+ ((endp rest))
+ (let ((next (first rest)))
+ (push (cons prev next) constraints)
+ (setf prev next)))
+ (dolist (class superclasses)
+ (note-class class)))))
+ (std-cpl-tie-breaker (free-classes rev-cpl)
+ (dolist (class rev-cpl (first free-classes))
+ (let* ((superclasses (classoid-direct-superclasses class))
+ (intersection (intersection free-classes
+ superclasses)))
+ (when intersection
+ (return (first intersection)))))))
+ (note-class class)
+ (topological-sort classes constraints #'std-cpl-tie-breaker))))
\f
-;;; An UNDEFINED-CLASS is a cookie we make up to stick in forward
+;;;; object types to represent classes
+
+;;; An UNDEFINED-CLASSOID is a cookie we make up to stick in forward
;;; referenced layouts. Users should never see them.
-(def!struct (undefined-class (:include #-sb-xc sb!xc:class
- #+sb-xc cl:class)
- (:constructor make-undefined-class (%name))))
+(def!struct (undefined-classoid
+ (:include classoid)
+ (:constructor make-undefined-classoid (name))))
;;; BUILT-IN-CLASS is used to represent the standard classes that
;;; aren't defined with DEFSTRUCT and other specially implemented
;;; This translation is done when type specifiers are parsed. Type
;;; system operations (union, subtypep, etc.) should never encounter
;;; translated classes, only their translation.
-(def!struct (sb!xc:built-in-class (:include #-sb-xc sb!xc:class
- #+sb-xc cl:class)
- (:constructor bare-make-built-in-class))
+(def!struct (built-in-classoid (:include classoid)
+ (:constructor make-built-in-classoid))
;; the type we translate to on parsing. If NIL, then this class
;; stands on its own; or it can be set to :INITIALIZING for a period
;; during cold-load.
(translation nil :type (or ctype (member nil :initializing))))
-(defun make-built-in-class (&rest rest)
- (apply #'bare-make-built-in-class
- (rename-key-args '((:name :%name)) rest)))
;;; FIXME: In CMU CL, this was a class with a print function, but not
;;; necessarily a structure class (e.g. CONDITIONs). In SBCL,
;;; we let CLOS handle our print functions, so that is no longer needed.
;;; Is there any need for this class any more?
-(def!struct (slot-class (:include #-sb-xc sb!xc:class #+sb-xc cl:class)
- (:constructor nil)))
+(def!struct (slot-classoid (:include classoid)
+ (:constructor nil)))
;;; STRUCTURE-CLASS represents what we need to know about structure
;;; classes. Non-structure "typed" defstructs are a special case, and
;;; don't have a corresponding class.
-(def!struct (basic-structure-class (:include slot-class)
- (:constructor nil)))
+(def!struct (basic-structure-classoid (:include slot-classoid)
+ (:constructor nil)))
-(def!struct (sb!xc:structure-class (:include basic-structure-class)
- (:constructor bare-make-structure-class))
+(def!struct (structure-classoid (:include basic-structure-classoid)
+ (:constructor make-structure-classoid))
;; If true, a default keyword constructor for this structure.
(constructor nil :type (or function null)))
-(defun make-structure-class (&rest rest)
- (apply #'bare-make-structure-class
- (rename-key-args '((:name :%name)) rest)))
;;; FUNCALLABLE-STRUCTURE-CLASS is used to represent funcallable
;;; structures, which are used to implement generic functions.
-(def!struct (funcallable-structure-class (:include basic-structure-class)
- (:constructor bare-make-funcallable-structure-class)))
-(defun make-funcallable-structure-class (&rest rest)
- (apply #'bare-make-funcallable-structure-class
- (rename-key-args '((:name :%name)) rest)))
+(def!struct (funcallable-structure-classoid
+ (:include basic-structure-classoid)
+ (:constructor make-funcallable-structure-classoid)))
\f
-;;;; class namespace
+;;;; classoid namespace
;;; We use an indirection to allow forward referencing of class
;;; definitions with load-time resolution.
-(def!struct (class-cell
- (:constructor make-class-cell (name &optional class))
+(def!struct (classoid-cell
+ (:constructor make-classoid-cell (name &optional classoid))
(:make-load-form-fun (lambda (c)
- `(find-class-cell ',(class-cell-name c))))
+ `(find-classoid-cell
+ ',(classoid-cell-name c))))
#-no-ansi-print-object
(:print-object (lambda (s stream)
(print-unreadable-object (s stream :type t)
- (prin1 (class-cell-name s) stream)))))
+ (prin1 (classoid-cell-name s) stream)))))
;; Name of class we expect to find.
(name nil :type symbol :read-only t)
;; Class or NIL if not yet defined.
- (class nil :type (or #-sb-xc sb!xc:class #+sb-xc cl:class
- null)))
-(defun find-class-cell (name)
- (or (info :type :class name)
- (setf (info :type :class name)
- (make-class-cell name))))
+ (classoid nil :type (or classoid null)))
+(defun find-classoid-cell (name)
+ (or (info :type :classoid name)
+ (setf (info :type :classoid name)
+ (make-classoid-cell name))))
;;; FIXME: When the system is stable, this DECLAIM FTYPE should
;;; probably go away in favor of the DEFKNOWN for FIND-CLASS.
-(declaim (ftype (function (symbol &optional t (or null sb!c::lexenv))) sb!xc:find-class))
+(declaim (ftype (function (symbol &optional t (or null sb!c::lexenv)))
+ find-classoid))
(eval-when (#-sb-xc :compile-toplevel :load-toplevel :execute)
-(defun sb!xc:find-class (name &optional (errorp t) environment)
+(defun find-classoid (name &optional (errorp t) environment)
#!+sb-doc
"Return the class with the specified NAME. If ERRORP is false, then NIL is
returned when no such class exists."
(declare (type symbol name) (ignore environment))
- (let ((res (class-cell-class (find-class-cell name))))
+ (let ((res (classoid-cell-classoid (find-classoid-cell name))))
(if (or res (not errorp))
res
(error "class not yet defined:~% ~S" name))))
-(defun (setf sb!xc:find-class) (new-value name)
- #-sb-xc (declare (type sb!xc:class new-value))
+(defun (setf find-classoid) (new-value name)
+ #-sb-xc (declare (type classoid new-value))
(ecase (info :type :kind name)
((nil))
+ (:forthcoming-defclass-type
+ ;; XXX Currently, nothing needs to be done in this case. Later, when
+ ;; PCL is integrated tighter into SBCL, this might need more work.
+ nil)
(:instance
- (let ((old (class-of (sb!xc:find-class name)))
- (new (class-of new-value)))
+ #-sb-xc-host ; FIXME
+ (let ((old (classoid-of (find-classoid name)))
+ (new (classoid-of new-value)))
(unless (eq old new)
(warn "changing meta-class of ~S from ~S to ~S"
name
- (class-name old)
- (class-name new)))))
+ (classoid-name old)
+ (classoid-name new)))))
(:primitive
(error "illegal to redefine standard type ~S" name))
(:defined
(remhash name *forward-referenced-layouts*)
(%note-type-defined name)
(setf (info :type :kind name) :instance)
- (setf (class-cell-class (find-class-cell name)) new-value)
+ (setf (classoid-cell-classoid (find-classoid-cell name)) new-value)
(unless (eq (info :type :compiler-layout name)
- (class-layout new-value))
- (setf (info :type :compiler-layout name) (class-layout new-value)))
+ (classoid-layout new-value))
+ (setf (info :type :compiler-layout name) (classoid-layout new-value)))
new-value)
) ; EVAL-WHEN
;;; predicate (such as a meta-class type test.) The first result is
;;; always of the desired class. The second result is any existing
;;; LAYOUT for this name.
-(defun insured-find-class (name predicate constructor)
+(defun insured-find-classoid (name predicate constructor)
(declare (type function predicate constructor))
- (let* ((old (sb!xc:find-class name nil))
+ (let* ((old (find-classoid name nil))
(res (if (and old (funcall predicate old))
old
(funcall constructor :name name)))
(found (or (gethash name *forward-referenced-layouts*)
- (when old (class-layout old)))))
+ (when old (classoid-layout old)))))
(when found
- (setf (layout-class found) res))
+ (setf (layout-classoid found) res))
(values res found)))
;;; If the class has a proper name, return the name, otherwise return
;;; the class.
-(defun class-proper-name (class)
- #-sb-xc (declare (type sb!xc:class class))
- (let ((name (sb!xc:class-name class)))
- (if (and name (eq (sb!xc:find-class name nil) class))
+(defun classoid-proper-name (class)
+ #-sb-xc (declare (type classoid class))
+ (let ((name (classoid-name class)))
+ (if (and name (eq (find-classoid name nil) class))
name
class)))
\f
;;;; CLASS type operations
-(!define-type-class sb!xc:class)
+(!define-type-class classoid)
;;; Simple methods for TYPE= and SUBTYPEP should never be called when
;;; the two classes are equal, since there are EQ checks in those
;;; operations.
-(!define-type-method (sb!xc:class :simple-=) (type1 type2)
- (assert (not (eq type1 type2)))
+(!define-type-method (classoid :simple-=) (type1 type2)
+ (aver (not (eq type1 type2)))
(values nil t))
-(!define-type-method (sb!xc:class :simple-subtypep) (class1 class2)
- (assert (not (eq class1 class2)))
- (let ((subclasses (class-subclasses class2)))
+(!define-type-method (classoid :simple-subtypep) (class1 class2)
+ (aver (not (eq class1 class2)))
+ (let ((subclasses (classoid-subclasses class2)))
(if (and subclasses (gethash class1 subclasses))
(values t t)
(values nil t))))
;;; class (not hierarchically related) the intersection is the union
;;; of the currently shared subclasses.
(defun sealed-class-intersection2 (sealed other)
- (declare (type sb!xc:class sealed other))
- (let ((s-sub (class-subclasses sealed))
- (o-sub (class-subclasses other)))
+ (declare (type classoid sealed other))
+ (let ((s-sub (classoid-subclasses sealed))
+ (o-sub (classoid-subclasses other)))
(if (and s-sub o-sub)
(collect ((res *empty-type* type-union))
(dohash (subclass layout s-sub)
(res))
*empty-type*)))
-(!define-type-method (sb!xc:class :simple-intersection2) (class1 class2)
- (declare (type sb!xc:class class1 class2))
+(!define-type-method (classoid :simple-intersection2) (class1 class2)
+ (declare (type classoid class1 class2))
(cond ((eq class1 class2)
class1)
;; If one is a subclass of the other, then that is the
;; intersection.
- ((let ((subclasses (class-subclasses class2)))
+ ((let ((subclasses (classoid-subclasses class2)))
(and subclasses (gethash class1 subclasses)))
class1)
- ((let ((subclasses (class-subclasses class1)))
+ ((let ((subclasses (classoid-subclasses class1)))
(and subclasses (gethash class2 subclasses)))
class2)
;; Otherwise, we can't in general be sure that the
;; intersection is empty, since a subclass of both might be
;; defined. But we can eliminate it for some special cases.
- ((or (basic-structure-class-p class1)
- (basic-structure-class-p class2))
+ ((or (basic-structure-classoid-p class1)
+ (basic-structure-classoid-p class2))
;; No subclass of both can be defined.
*empty-type*)
- ((eq (class-state class1) :sealed)
+ ((eq (classoid-state class1) :sealed)
;; checking whether a subclass of both can be defined:
(sealed-class-intersection2 class1 class2))
- ((eq (class-state class2) :sealed)
+ ((eq (classoid-state class2) :sealed)
;; checking whether a subclass of both can be defined:
(sealed-class-intersection2 class2 class1))
(t
;; uncertain, since a subclass of both might be defined
nil)))
-(!define-type-method (sb!xc:class :unparse) (type)
- (class-proper-name type))
+;;; KLUDGE: we need this because of the need to represent
+;;; intersections of two classes, even when empty at a given time, as
+;;; uncanonicalized intersections because of the possibility of later
+;;; defining a subclass of both classes. The necessity for changing
+;;; the default return value from SUBTYPEP to NIL, T if no alternate
+;;; method is present comes about because, unlike the other places we
+;;; use INVOKE-COMPLEX-SUBTYPEP-ARG1-METHOD, in HAIRY methods and the
+;;; like, classes are in their own hierarchy with no possibility of
+;;; mixtures with other type classes.
+(!define-type-method (classoid :complex-subtypep-arg2) (type1 class2)
+ (if (and (intersection-type-p type1)
+ (> (count-if #'classoid-p (intersection-type-types type1)) 1))
+ (values nil nil)
+ (invoke-complex-subtypep-arg1-method type1 class2 nil t)))
+
+(!define-type-method (classoid :unparse) (type)
+ (classoid-proper-name type))
\f
;;;; PCL stuff
-(def!struct (std-class (:include sb!xc:class)
- (:constructor nil)))
-(def!struct (sb!xc:standard-class (:include std-class)
- (:constructor bare-make-standard-class)))
-(def!struct (random-pcl-class (:include std-class)
- (:constructor bare-make-random-pcl-class)))
-(defun make-standard-class (&rest rest)
- (apply #'bare-make-standard-class
- (rename-key-args '((:name :%name)) rest)))
-(defun make-random-pcl-class (&rest rest)
- (apply #'bare-make-random-pcl-class
- (rename-key-args '((:name :%name)) rest)))
+(def!struct (std-classoid (:include classoid)
+ (:constructor nil)))
+(def!struct (standard-classoid (:include std-classoid)
+ (:constructor make-standard-classoid)))
+(def!struct (random-pcl-classoid (:include std-classoid)
+ (:constructor make-random-pcl-classoid)))
\f
;;;; built-in classes
(character :enumerable t :translation base-char)
(base-char :enumerable t
:inherits (character)
- :codes (#.sb!vm:base-char-type))
- (symbol :codes (#.sb!vm:symbol-header-type))
+ :codes (#.sb!vm:base-char-widetag))
+ (symbol :codes (#.sb!vm:symbol-header-widetag))
(instance :state :read-only)
- (system-area-pointer :codes (#.sb!vm:sap-type))
- (weak-pointer :codes (#.sb!vm:weak-pointer-type))
- (code-component :codes (#.sb!vm:code-header-type))
- #!-gengc (lra :codes (#.sb!vm:return-pc-header-type))
- (fdefn :codes (#.sb!vm:fdefn-type))
+ (system-area-pointer :codes (#.sb!vm:sap-widetag))
+ (weak-pointer :codes (#.sb!vm:weak-pointer-widetag))
+ (code-component :codes (#.sb!vm:code-header-widetag))
+ (lra :codes (#.sb!vm:return-pc-header-widetag))
+ (fdefn :codes (#.sb!vm:fdefn-widetag))
(random-class) ; used for unknown type codes
(function
- :codes (#.sb!vm:byte-code-closure-type
- #.sb!vm:byte-code-function-type
- #.sb!vm:closure-header-type
- #.sb!vm:function-header-type)
+ :codes (#.sb!vm:closure-header-widetag
+ #.sb!vm:simple-fun-header-widetag)
:state :read-only)
(funcallable-instance
:inherits (function)
:state :read-only)
- ;; FIXME: Are COLLECTION and MUTABLE-COLLECTION used for anything
- ;; any more? COLLECTION is not defined in ANSI Common Lisp..
- (collection :hierarchical-p nil :state :read-only)
- (mutable-collection :state :read-only
- :inherits (collection))
- (generic-sequence :state :read-only
- :inherits (collection))
- (mutable-sequence :state :read-only
- :direct-superclasses (mutable-collection
- generic-sequence)
- :inherits (mutable-collection
- generic-sequence
- collection))
- (generic-array :state :read-only
- :inherits (mutable-sequence
- mutable-collection
- generic-sequence
- collection))
- (generic-vector :state :read-only
- :inherits (generic-array
- mutable-sequence mutable-collection
- generic-sequence collection))
- (array :translation array :codes (#.sb!vm:complex-array-type)
- :inherits (generic-array mutable-sequence mutable-collection
- generic-sequence collection))
+ (array :translation array :codes (#.sb!vm:complex-array-widetag)
+ :hierarchical-p nil)
(simple-array
- :translation simple-array :codes (#.sb!vm:simple-array-type)
- :inherits (array generic-array mutable-sequence mutable-collection
- generic-sequence collection))
+ :translation simple-array :codes (#.sb!vm:simple-array-widetag)
+ :inherits (array))
(sequence
- :translation (or cons (member nil) vector)
- :inherits (mutable-sequence mutable-collection generic-sequence
- collection))
+ :translation (or cons (member nil) vector))
(vector
- :translation vector :codes (#.sb!vm:complex-vector-type)
- :direct-superclasses (array sequence generic-vector)
- :inherits (array sequence generic-vector generic-array
- mutable-sequence mutable-collection generic-sequence
- collection))
+ :translation vector :codes (#.sb!vm:complex-vector-widetag)
+ :direct-superclasses (array sequence)
+ :inherits (array sequence))
(simple-vector
- :translation simple-vector :codes (#.sb!vm:simple-vector-type)
+ :translation simple-vector :codes (#.sb!vm:simple-vector-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array
- sequence generic-vector generic-array
- mutable-sequence mutable-collection
- generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(bit-vector
- :translation bit-vector :codes (#.sb!vm:complex-bit-vector-type)
- :inherits (vector array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :translation bit-vector :codes (#.sb!vm:complex-bit-vector-widetag)
+ :inherits (vector array sequence))
(simple-bit-vector
- :translation simple-bit-vector :codes (#.sb!vm:simple-bit-vector-type)
+ :translation simple-bit-vector :codes (#.sb!vm:simple-bit-vector-widetag)
:direct-superclasses (bit-vector simple-array)
:inherits (bit-vector vector simple-array
- array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ array sequence))
(simple-array-unsigned-byte-2
:translation (simple-array (unsigned-byte 2) (*))
- :codes (#.sb!vm:simple-array-unsigned-byte-2-type)
+ :codes (#.sb!vm:simple-array-unsigned-byte-2-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-unsigned-byte-4
:translation (simple-array (unsigned-byte 4) (*))
- :codes (#.sb!vm:simple-array-unsigned-byte-4-type)
+ :codes (#.sb!vm:simple-array-unsigned-byte-4-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-unsigned-byte-8
:translation (simple-array (unsigned-byte 8) (*))
- :codes (#.sb!vm:simple-array-unsigned-byte-8-type)
+ :codes (#.sb!vm:simple-array-unsigned-byte-8-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-unsigned-byte-16
:translation (simple-array (unsigned-byte 16) (*))
- :codes (#.sb!vm:simple-array-unsigned-byte-16-type)
+ :codes (#.sb!vm:simple-array-unsigned-byte-16-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-unsigned-byte-32
:translation (simple-array (unsigned-byte 32) (*))
- :codes (#.sb!vm:simple-array-unsigned-byte-32-type)
+ :codes (#.sb!vm:simple-array-unsigned-byte-32-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-signed-byte-8
:translation (simple-array (signed-byte 8) (*))
- :codes (#.sb!vm:simple-array-signed-byte-8-type)
+ :codes (#.sb!vm:simple-array-signed-byte-8-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-signed-byte-16
:translation (simple-array (signed-byte 16) (*))
- :codes (#.sb!vm:simple-array-signed-byte-16-type)
+ :codes (#.sb!vm:simple-array-signed-byte-16-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-signed-byte-30
:translation (simple-array (signed-byte 30) (*))
- :codes (#.sb!vm:simple-array-signed-byte-30-type)
+ :codes (#.sb!vm:simple-array-signed-byte-30-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-signed-byte-32
:translation (simple-array (signed-byte 32) (*))
- :codes (#.sb!vm:simple-array-signed-byte-32-type)
+ :codes (#.sb!vm:simple-array-signed-byte-32-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-single-float
:translation (simple-array single-float (*))
- :codes (#.sb!vm:simple-array-single-float-type)
+ :codes (#.sb!vm:simple-array-single-float-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-double-float
:translation (simple-array double-float (*))
- :codes (#.sb!vm:simple-array-double-float-type)
+ :codes (#.sb!vm:simple-array-double-float-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
#!+long-float
(simple-array-long-float
:translation (simple-array long-float (*))
- :codes (#.sb!vm:simple-array-long-float-type)
+ :codes (#.sb!vm:simple-array-long-float-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-complex-single-float
:translation (simple-array (complex single-float) (*))
- :codes (#.sb!vm:simple-array-complex-single-float-type)
+ :codes (#.sb!vm:simple-array-complex-single-float-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
(simple-array-complex-double-float
:translation (simple-array (complex double-float) (*))
- :codes (#.sb!vm:simple-array-complex-double-float-type)
+ :codes (#.sb!vm:simple-array-complex-double-float-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ :inherits (vector simple-array array sequence))
#!+long-float
(simple-array-complex-long-float
:translation (simple-array (complex long-float) (*))
- :codes (#.sb!vm:simple-array-complex-long-float-type)
+ :codes (#.sb!vm:simple-array-complex-long-float-widetag)
:direct-superclasses (vector simple-array)
- :inherits (vector simple-array array sequence
- generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
- (generic-string
- :state :read-only
- :inherits (mutable-sequence mutable-collection generic-sequence
- collection))
+ :inherits (vector simple-array array sequence))
(string
:translation string
- :codes (#.sb!vm:complex-string-type)
- :direct-superclasses (vector generic-string)
- :inherits (vector array sequence
- generic-vector generic-array generic-string
- mutable-sequence mutable-collection
- generic-sequence collection))
+ :codes (#.sb!vm:complex-string-widetag)
+ :direct-superclasses (vector)
+ :inherits (vector array sequence))
(simple-string
:translation simple-string
- :codes (#.sb!vm:simple-string-type)
+ :codes (#.sb!vm:simple-string-widetag)
:direct-superclasses (string simple-array)
:inherits (string vector simple-array
- array sequence
- generic-string generic-vector generic-array mutable-sequence
- mutable-collection generic-sequence collection))
+ array sequence))
(list
:translation (or cons (member nil))
- :inherits (sequence mutable-sequence mutable-collection
- generic-sequence collection))
+ :inherits (sequence))
(cons
- :codes (#.sb!vm:list-pointer-type)
+ :codes (#.sb!vm:list-pointer-lowtag)
:translation cons
- :inherits (list sequence
- mutable-sequence mutable-collection
- generic-sequence collection))
+ :inherits (list sequence))
(null
:translation (member nil)
- :inherits (list sequence
- mutable-sequence mutable-collection
- generic-sequence collection symbol)
- :direct-superclasses (list symbol))
- (generic-number :state :read-only)
- (number :translation number :inherits (generic-number))
+ :inherits (symbol list sequence)
+ :direct-superclasses (symbol list))
+ (number :translation number)
(complex
:translation complex
- :inherits (number generic-number)
- :codes (#.sb!vm:complex-type))
+ :inherits (number)
+ :codes (#.sb!vm:complex-widetag))
(complex-single-float
:translation (complex single-float)
- :inherits (complex number generic-number)
- :codes (#.sb!vm:complex-single-float-type))
+ :inherits (complex number)
+ :codes (#.sb!vm:complex-single-float-widetag))
(complex-double-float
:translation (complex double-float)
- :inherits (complex number generic-number)
- :codes (#.sb!vm:complex-double-float-type))
+ :inherits (complex number)
+ :codes (#.sb!vm:complex-double-float-widetag))
#!+long-float
(complex-long-float
:translation (complex long-float)
- :inherits (complex number generic-number)
- :codes (#.sb!vm:complex-long-float-type))
- (real :translation real :inherits (number generic-number))
+ :inherits (complex number)
+ :codes (#.sb!vm:complex-long-float-widetag))
+ (real :translation real :inherits (number))
(float
:translation float
- :inherits (real number generic-number))
+ :inherits (real number))
(single-float
:translation single-float
- :inherits (float real number generic-number)
- :codes (#.sb!vm:single-float-type))
+ :inherits (float real number)
+ :codes (#.sb!vm:single-float-widetag))
(double-float
:translation double-float
- :inherits (float real number generic-number)
- :codes (#.sb!vm:double-float-type))
+ :inherits (float real number)
+ :codes (#.sb!vm:double-float-widetag))
#!+long-float
(long-float
:translation long-float
- :inherits (float real number generic-number)
- :codes (#.sb!vm:long-float-type))
+ :inherits (float real number)
+ :codes (#.sb!vm:long-float-widetag))
(rational
:translation rational
- :inherits (real number generic-number))
+ :inherits (real number))
(ratio
:translation (and rational (not integer))
- :inherits (rational real number generic-number)
- :codes (#.sb!vm:ratio-type))
+ :inherits (rational real number)
+ :codes (#.sb!vm:ratio-widetag))
(integer
:translation integer
- :inherits (rational real number generic-number))
+ :inherits (rational real number))
(fixnum
- :translation (integer #.sb!vm:*target-most-negative-fixnum*
- #.sb!vm:*target-most-positive-fixnum*)
- :inherits (integer rational real number
- generic-number)
- :codes (#.sb!vm:even-fixnum-type #.sb!vm:odd-fixnum-type))
+ :translation (integer #.sb!xc:most-negative-fixnum
+ #.sb!xc:most-positive-fixnum)
+ :inherits (integer rational real number)
+ :codes (#.sb!vm:even-fixnum-lowtag #.sb!vm:odd-fixnum-lowtag))
(bignum
:translation (and integer (not fixnum))
- :inherits (integer rational real number
- generic-number)
- :codes (#.sb!vm:bignum-type))
+ :inherits (integer rational real number)
+ :codes (#.sb!vm:bignum-widetag))
(stream
- :hierarchical-p nil
:state :read-only
- :inherits (instance t)))))
+ :depth 3
+ :inherits (instance)))))
;;; comment from CMU CL:
;;; See also type-init.lisp where we finish setting up the
codes
enumerable
state
+ depth
(hierarchical-p t) ; might be modified below
(direct-superclasses (if inherits
(list (car inherits))
'(t))))
x
(declare (ignore codes state translation))
- (let ((inherits-list (if (eq name 't)
- ()
- (cons 't (reverse inherits))))
- (class (make-built-in-class
- :enumerable enumerable
- :name name
- :translation (if trans-p :initializing nil)
- :direct-superclasses
- (if (eq name 't)
- nil
- (mapcar #'sb!xc:find-class direct-superclasses)))))
- (setf (info :type :kind name) :primitive
- (class-cell-class (find-class-cell name)) class)
+ (let ((inherits-list (if (eq name t)
+ ()
+ (cons t (reverse inherits))))
+ (classoid (make-built-in-classoid
+ :enumerable enumerable
+ :name name
+ :translation (if trans-p :initializing nil)
+ :direct-superclasses
+ (if (eq name t)
+ nil
+ (mapcar #'find-classoid direct-superclasses)))))
+ (setf (info :type :kind name) #+sb-xc-host :defined #-sb-xc-host :primitive
+ (classoid-cell-classoid (find-classoid-cell name)) classoid)
(unless trans-p
- (setf (info :type :builtin name) class))
+ (setf (info :type :builtin name) classoid))
(let* ((inherits-vector
- (map 'vector
+ (map 'simple-vector
(lambda (x)
(let ((super-layout
- (class-layout (sb!xc:find-class x))))
+ (classoid-layout (find-classoid x))))
(when (minusp (layout-depthoid super-layout))
(setf hierarchical-p nil))
super-layout))
inherits-list))
- (depthoid (if hierarchical-p (length inherits-vector) -1)))
+ (depthoid (if hierarchical-p
+ (or depth (length inherits-vector))
+ -1)))
(register-layout
(find-and-init-or-check-layout name
0
;;; is loaded and the class defined.
(!cold-init-forms
(/show0 "about to define temporary STANDARD-CLASSes")
- (dolist (x '((fundamental-stream (t instance stream))))
+ (dolist (x '(;; Why is STREAM duplicated in this list? Because, when
+ ;; the inherits-vector of FUNDAMENTAL-STREAM is set up,
+ ;; a vector containing the elements of the list below,
+ ;; i.e. '(T INSTANCE STREAM STREAM), is created, and
+ ;; this is what the function ORDER-LAYOUT-INHERITS
+ ;; would do, too.
+ ;;
+ ;; So, the purpose is to guarantee a valid layout for
+ ;; the FUNDAMENTAL-STREAM class, matching what
+ ;; ORDER-LAYOUT-INHERITS would do.
+ ;; ORDER-LAYOUT-INHERITS would place STREAM at index 3
+ ;; in the INHERITS(-VECTOR). Index 2 would not be
+ ;; filled, so STREAM is duplicated there (as
+ ;; ORDER-LAYOUTS-INHERITS would do). Maybe the
+ ;; duplicate definition could be removed (removing a
+ ;; STREAM element), because FUNDAMENTAL-STREAM is
+ ;; redefined after PCL is set up, anyway. But to play
+ ;; it safely, we define the class with a valid INHERITS
+ ;; vector.
+ (fundamental-stream (t instance stream stream))))
(/show0 "defining temporary STANDARD-CLASS")
(let* ((name (first x))
(inherits-list (second x))
- (class (make-standard-class :name name))
- (class-cell (find-class-cell name)))
- (setf (class-cell-class class-cell) class
- (info :type :class name) class-cell
+ (classoid (make-standard-classoid :name name))
+ (classoid-cell (find-classoid-cell name)))
+ ;; Needed to open-code the MAP, below
+ (declare (type list inherits-list))
+ (setf (classoid-cell-classoid classoid-cell) classoid
+ (info :type :classoid name) classoid-cell
(info :type :kind name) :instance)
- (let ((inherits (map 'vector
+ (let ((inherits (map 'simple-vector
(lambda (x)
- (class-layout (sb!xc:find-class x)))
+ (classoid-layout (find-classoid x)))
inherits-list)))
#-sb-xc-host (/show0 "INHERITS=..") #-sb-xc-host (/hexstr inherits)
(register-layout (find-and-init-or-check-layout name 0 inherits -1)
(!cold-init-forms
(dolist (x *built-in-classes*)
(destructuring-bind (name &key (state :sealed) &allow-other-keys) x
- (setf (class-state (sb!xc:find-class name)) state))))
+ (setf (classoid-state (find-classoid name)) state))))
\f
;;;; class definition/redefinition
;;; This is to be called whenever we are altering a class.
-(defun modify-class (class)
+(defun modify-classoid (classoid)
(clear-type-caches)
- (when (member (class-state class) '(:read-only :frozen))
+ (when (member (classoid-state classoid) '(:read-only :frozen))
;; FIXME: This should probably be CERROR.
(warn "making ~(~A~) class ~S writable"
- (class-state class)
- (sb!xc:class-name class))
- (setf (class-state class) nil)))
+ (classoid-state classoid)
+ (classoid-name classoid))
+ (setf (classoid-state classoid) nil)))
;;; Mark LAYOUT as invalid. Setting DEPTHOID -1 helps cause unsafe
;;; structure type tests to fail. Remove class from all superclasses
(setf (layout-invalid layout) t
(layout-depthoid layout) -1)
(let ((inherits (layout-inherits layout))
- (class (layout-class layout)))
- (modify-class class)
+ (classoid (layout-classoid layout)))
+ (modify-classoid classoid)
(dotimes (i (length inherits)) ; FIXME: DOVECTOR
(let* ((super (svref inherits i))
- (subs (class-subclasses (layout-class super))))
+ (subs (classoid-subclasses (layout-classoid super))))
(when subs
- (remhash class subs)))))
+ (remhash classoid subs)))))
(values))
\f
;;;; cold loading initializations
;;; FIXME: It would be good to arrange for this to be called when the
;;; cross-compiler is being built, not just when the target Lisp is
;;; being cold loaded. Perhaps this could be moved to its own file
-;;; late in the stems-and-flags.lisp-expr sequence, and be put in
+;;; late in the build-order.lisp-expr sequence, and be put in
;;; !COLD-INIT-FORMS there?
(defun !class-finalize ()
(dohash (name layout *forward-referenced-layouts*)
- (let ((class (sb!xc:find-class name nil)))
+ (let ((class (find-classoid name nil)))
(cond ((not class)
- (setf (layout-class layout) (make-undefined-class name)))
- ((eq (class-layout class) layout)
+ (setf (layout-classoid layout) (make-undefined-classoid name)))
+ ((eq (classoid-layout class) layout)
(remhash name *forward-referenced-layouts*))
(t
;; FIXME: ERROR?
(setq *built-in-class-codes*
(let* ((initial-element
(locally
- ;; KLUDGE: There's a FIND-CLASS DEFTRANSFORM for
+ ;; KLUDGE: There's a FIND-CLASSOID DEFTRANSFORM for
;; constant class names which creates fast but
;; non-cold-loadable, non-compact code. In this
;; context, we'd rather have compact, cold-loadable
;; code. -- WHN 19990928
- (declare (notinline sb!xc:find-class))
- (class-layout (sb!xc:find-class 'random-class))))
+ (declare (notinline find-classoid))
+ (classoid-layout (find-classoid 'random-class))))
(res (make-array 256 :initial-element initial-element)))
(dolist (x *built-in-classes* res)
(destructuring-bind (name &key codes &allow-other-keys)
x
- (let ((layout (class-layout (sb!xc:find-class name))))
+ (let ((layout (classoid-layout (find-classoid name))))
(dolist (code codes)
(setf (svref res code) layout)))))))
#-sb-xc-host (/show0 "done setting *BUILT-IN-CLASS-CODES*"))