- (warn-about-possible-float-info-loss ()
- (warn-possible-cross-type-float-info-loss
- `(cross-typep ,host-object ,target-type))))
- (cond (;; Handle various SBCL-specific types which can't exist on the
- ;; ANSI cross-compilation host. KLUDGE: This code will need to be
- ;; tweaked by hand if the names of these types ever change, ugh!
- (if (consp target-type)
- (member (car target-type)
- '(sb!alien:alien))
- (member target-type
- '(system-area-pointer
- funcallable-instance
- sb!alien-internals:alien-value)))
- (values nil t))
- ((typep target-type 'sb!xc::structure-class)
- ;; SBCL-specific types which have an analogue specially created
- ;; on the host system
- (if (sb!xc:subtypep (sb!xc:class-name target-type)
- 'sb!kernel::structure!object)
- (values (typep host-object (sb!xc:class-name target-type)) t)
- (values nil t)))
- ((and (symbolp target-type)
- (find-class target-type nil)
- (subtypep target-type 'sb!kernel::structure!object))
- (values (typep host-object target-type) t))
- ((and (symbolp target-type)
- (sb!xc:find-class target-type nil)
- (sb!xc:subtypep target-type 'cl:structure-object)
- (typep host-object '(or symbol number list character)))
- (values nil t))
- ((and (not (unknown-type-p (values-specifier-type target-type)))
- (sb!xc:subtypep target-type 'cl:array))
- (if (arrayp host-object)
- (warn-and-give-up) ; general case of arrays being way too hard
- (values nil t))) ; but "obviously not an array" being easy
- ((consp target-type)
- (let ((first (first target-type))
- (rest (rest target-type)))
- (case first
- ;; Many complex types are guaranteed to correspond exactly
- ;; between any host ANSI Common Lisp and the target SBCL.
- ((integer member mod rational real signed-byte unsigned-byte)
- (values (typep host-object target-type) t))
- ;; Floating point types are guaranteed to correspond, too, but
- ;; less exactly.
- ((single-float double-float)
- (cond ((floatp host-object)
- (warn-about-possible-float-info-loss)
- (values (typep host-object target-type) t))
- (t
- (values nil t))))
- ;; Some complex types have translations that are less trivial.
- (and
- ;; Note: This could be implemented as a real test, just the way
- ;; that OR is; I just haven't bothered. -- WHN 19990706
- (warn-and-give-up))
- (or (let ((opinion nil)
- (certain-p t))
- (dolist (i rest)
- (multiple-value-bind (sub-opinion sub-certain-p)
- (cross-typep host-object i)
- (cond (sub-opinion (setf opinion t
- certain-p t)
- (return))
- ((not sub-certain-p) (setf certain-p nil))))
- (if certain-p
- (values opinion t)
- (warn-and-give-up)))))
- ;; Some complex types are too hard to handle in the positive
- ;; case, but at least we can be confident in a large fraction of
- ;; the negative cases..
- ((base-string simple-base-string simple-string)
- (if (stringp host-object)
- (warn-and-give-up)
- (values nil t)))
- ((array simple-array simple-vector vector)
- (if (arrayp host-object)
- (warn-and-give-up)
- (values nil t)))
- (function
- (if (functionp host-object)
- (warn-and-give-up)
- (values nil t)))
- ;; And the Common Lisp type system is complicated, and we don't
- ;; try to implement everything.
- (otherwise (warn-and-give-up)))))
- (t
- (case target-type
- ((*)
- ;; KLUDGE: SBCL has * as an explicit wild type. While this is
- ;; sort of logical (because (e.g. (ARRAY * 1)) is a valid type)
- ;; it's not ANSI: looking at the ANSI definitions of complex
- ;; types like like ARRAY shows that they consider * different
- ;; from other type names. Someday we should probably get rid of
- ;; this non-ANSIism in base SBCL, but until we do, we might as
- ;; well here in the cross compiler. And in order to make sure
- ;; that we don't continue doing it after we someday patch SBCL's
- ;; type system so that * is no longer a type, we make this
- ;; assertion:
- (assert (typep (specifier-type '*) 'named-type))
- (values t t))
- ;; Many simple types are guaranteed to correspond exactly between
- ;; any host ANSI Common Lisp and the target Common Lisp.
- ((array bit character complex cons float function integer list
- nil null number rational real signed-byte string symbol t
- unsigned-byte vector)
- (values (typep host-object target-type) t))
- ;; Floating point types are guaranteed to correspond, too, but
- ;; less exactly.
- ((single-float double-float)
- (cond ((floatp host-object)
- (warn-about-possible-float-info-loss)
- (values (typep host-object target-type) t))
- (t
- (values nil t))))
- ;; Some types require translation between the cross-compilation
- ;; host Common Lisp and the target SBCL.
- (sb!xc:class (values (typep host-object 'sb!xc:class) t))
- (fixnum (values (target-fixnump host-object) t))
- ;; Some types are too hard to handle in the positive case, but at
- ;; least we can be confident in a large fraction of the negative
- ;; cases..
- ((base-string simple-base-string simple-string)
- (if (stringp host-object)
- (warn-and-give-up)
- (values nil t)))
- ((character base-char)
- (cond ((typep host-object 'standard-char)
- (values t t))
- ((not (characterp host-object))
- (values nil t))
- (t
- (warn-and-give-up))))
- ((stream instance)
- ;; Neither target CL:STREAM nor target SB!KERNEL:INSTANCE is
- ;; implemented as a STRUCTURE-OBJECT, so they'll fall through the
- ;; tests above. We don't want to assume too much about them here,
- ;; but at least we know enough about them to say that neither T
- ;; nor NIL nor indeed any other symbol in the cross-compilation
- ;; host is one. That knowledge suffices to answer so many of the
- ;; questions that the cross-compiler asks that it's well worth
- ;; special-casing it here.
- (if (symbolp host-object)
- (values nil t)
- (warn-and-give-up)))
- ;; And the Common Lisp type system is complicated, and we don't
- ;; try to implement everything.
- (otherwise (warn-and-give-up)))))))
+ (warn-about-possible-float-info-loss ()
+ (warn-possible-cross-type-float-info-loss
+ `(cross-typep ,host-object ,raw-target-type)))
+ ;; a convenient idiom for making more matches to special cases:
+ ;; Test both forms of target type for membership in LIST.
+ ;;
+ ;; (In order to avoid having to use too much deep knowledge
+ ;; of types, it's sometimes convenient to test RAW-TARGET-TYPE
+ ;; as well as the expanded type, since we can get matches with
+ ;; just EQL. E.g. SIMPLE-STRING can be matched with EQL, while
+ ;; safely matching its expansion,
+ ;; (OR (SIMPLE-ARRAY CHARACTER (*)) (SIMPLE-BASE-STRING *))
+ ;; would require logic clever enough to know that, e.g., OR is
+ ;; commutative.)
+ (target-type-is-in (list)
+ (or (member raw-target-type list)
+ (member target-type list))))
+ (cond (;; Handle various SBCL-specific types which can't exist on
+ ;; the ANSI cross-compilation host. KLUDGE: This code will
+ ;; need to be tweaked by hand if the names of these types
+ ;; ever change, ugh!
+ (if (consp target-type)
+ (member (car target-type)
+ '(sb!alien:alien))
+ (member target-type
+ '(system-area-pointer
+ funcallable-instance
+ sb!alien-internals:alien-value)))
+ (values nil t))
+ (;; special case when TARGET-TYPE isn't a type spec, but
+ ;; instead a CLASS object.
+ (typep target-type 'class)
+ (bug "We don't support CROSS-TYPEP of CLASS type specifiers"))
+ ((and (symbolp target-type)
+ (find-classoid target-type nil)
+ (sb!xc:subtypep target-type 'cl:structure-object)
+ (typep host-object '(or symbol number list character)))
+ (values nil t))
+ ((and (symbolp target-type)
+ (find-class target-type nil)
+ (subtypep target-type 'sb!kernel::structure!object))
+ (values (typep host-object target-type) t))
+ (;; easy cases of arrays and vectors
+ (target-type-is-in
+ '(array simple-string simple-vector string vector))
+ (values (typep host-object target-type) t))
+ (;; general cases of vectors
+ (and (not (unknown-type-p (values-specifier-type target-type)))
+ (sb!xc:subtypep target-type 'cl:vector))
+ (if (vectorp host-object)
+ (warn-and-give-up) ; general-case vectors being way too hard
+ (values nil t))) ; but "obviously not a vector" being easy
+ (;; general cases of arrays
+ (and (not (unknown-type-p (values-specifier-type target-type)))
+ (sb!xc:subtypep target-type 'cl:array))
+ (if (arrayp host-object)
+ (warn-and-give-up) ; general-case arrays being way too hard
+ (values nil t))) ; but "obviously not an array" being easy
+ ((target-type-is-in '(*))
+ ;; KLUDGE: SBCL has * as an explicit wild type. While
+ ;; this is sort of logical (because (e.g. (ARRAY * 1)) is
+ ;; a valid type) it's not ANSI: looking at the ANSI
+ ;; definitions of complex types like like ARRAY shows
+ ;; that they consider * different from other type names.
+ ;; Someday we should probably get rid of this non-ANSIism
+ ;; in base SBCL, but until we do, we might as well here
+ ;; in the cross compiler. And in order to make sure that
+ ;; we don't continue doing it after we someday patch
+ ;; SBCL's type system so that * is no longer a type, we
+ ;; make this assertion. -- WHN 2001-08-08
+ (aver (typep (values-specifier-type '*) 'named-type))
+ (values t t))
+ (;; Many simple types are guaranteed to correspond exactly
+ ;; between any host ANSI Common Lisp and the target
+ ;; Common Lisp. (Some array types are too, but they
+ ;; were picked off earlier.)
+ (target-type-is-in
+ '(atom bit character complex cons float function integer keyword
+ list nil null number rational real signed-byte symbol t
+ unsigned-byte))
+ (values (typep host-object target-type) t))
+ (;; Floating point types are guaranteed to correspond,
+ ;; too, but less exactly.
+ (target-type-is-in
+ '(single-float double-float))
+ (cond ((floatp host-object)
+ (warn-about-possible-float-info-loss)
+ (values (typep host-object target-type) t))
+ (t
+ (values nil t))))
+ (;; Complexes suffer the same kind of problems as arrays
+ (and (not (unknown-type-p (values-specifier-type target-type)))
+ (sb!xc:subtypep target-type 'cl:complex))
+ (if (complexp host-object)
+ (warn-and-give-up) ; general-case complexes being way too hard
+ (values nil t))) ; but "obviously not a complex" being easy
+ ;; Some types require translation between the cross-compilation
+ ;; host Common Lisp and the target SBCL.
+ ((target-type-is-in '(classoid))
+ (values (typep host-object 'classoid) t))
+ ((target-type-is-in '(fixnum))
+ (values (fixnump host-object) t))
+ ;; Some types are too hard to handle in the positive
+ ;; case, but at least we can be confident in a large
+ ;; fraction of the negative cases..
+ ((target-type-is-in
+ '(base-string simple-base-string simple-string))
+ (if (stringp host-object)
+ (warn-and-give-up)
+ (values nil t)))
+ ((target-type-is-in '(character base-char))
+ (cond ((typep host-object 'standard-char)
+ (values t t))
+ ((not (characterp host-object))
+ (values nil t))
+ (t
+ (warn-and-give-up))))
+ ((target-type-is-in '(stream instance))
+ ;; Neither target CL:STREAM nor target SB!KERNEL:INSTANCE
+ ;; is implemented as a STRUCTURE-OBJECT, so they'll fall
+ ;; through the tests above. We don't want to assume too
+ ;; much about them here, but at least we know enough
+ ;; about them to say that neither T nor NIL nor indeed
+ ;; any other symbol in the cross-compilation host is one.
+ ;; That knowledge suffices to answer so many of the
+ ;; questions that the cross-compiler asks that it's well
+ ;; worth special-casing it here.
+ (if (symbolp host-object)
+ (values nil t)
+ (warn-and-give-up)))
+ ;; various hacks for composite types..
+ ((consp target-type)
+ (let ((first (first target-type))
+ (rest (rest target-type)))
+ (case first
+ ;; Many complex types are guaranteed to correspond exactly
+ ;; between any host ANSI Common Lisp and the target SBCL.
+ ((integer member mod rational real signed-byte unsigned-byte)
+ (values (typep host-object target-type) t))
+ ;; Floating point types are guaranteed to correspond,
+ ;; too, but less exactly.
+ ((single-float double-float)
+ (cond ((floatp host-object)
+ (warn-about-possible-float-info-loss)
+ (values (typep host-object target-type) t))
+ (t
+ (values nil t))))
+ ;; Some complex types have translations that are less
+ ;; trivial.
+ (and (every/type #'cross-typep host-object rest))
+ (or (any/type #'cross-typep host-object rest))
+ ;; If we want to work with the KEYWORD type, we need
+ ;; to grok (SATISFIES KEYWORDP).
+ (satisfies
+ (destructuring-bind (predicate-name) rest
+ (if (and (in-cl-package-p predicate-name)
+ (fboundp predicate-name))
+ ;; Many predicates like KEYWORDP, ODDP, PACKAGEP,
+ ;; and NULL correspond between host and target.
+ ;; But we still need to handle errors, because
+ ;; the code which calls us may not understand
+ ;; that a type is unreachable. (E.g. when compiling
+ ;; (AND STRING (SATISFIES ARRAY-HAS-FILL-POINTER-P))
+ ;; CTYPEP may be called on the SATISFIES expression
+ ;; even for non-STRINGs.)
+ (multiple-value-bind (result error?)
+ (ignore-errors (funcall predicate-name
+ host-object))
+ (if error?
+ (values nil nil)
+ (values result t)))
+ ;; For symbols not in the CL package, it's not
+ ;; in general clear how things correspond
+ ;; between host and target, so we punt.
+ (warn-and-give-up))))
+ ;; Some complex types are too hard to handle in the
+ ;; positive case, but at least we can be confident in
+ ;; a large fraction of the negative cases..
+ ((base-string simple-base-string simple-string)
+ (if (stringp host-object)
+ (warn-and-give-up)
+ (values nil t)))
+ ((vector simple-vector)
+ (if (vectorp host-object)
+ (warn-and-give-up)
+ (values nil t)))
+ ((array simple-array)
+ (if (arrayp host-object)
+ (warn-and-give-up)
+ (values nil t)))
+ (function
+ (if (functionp host-object)
+ (warn-and-give-up)
+ (values nil t)))
+ ;; And the Common Lisp type system is complicated,
+ ;; and we don't try to implement everything.
+ (otherwise (warn-and-give-up)))))
+ ;; And the Common Lisp type system is complicated, and
+ ;; we don't try to implement everything.
+ (t
+ (warn-and-give-up))))))