(ltn-annotate nil :type (or function null))
;; If true, the special-case IR2 conversion method for this
;; function. This deals with funny functions, and anything else that
- ;; can't be handled using the template mechanism. The Combination
+ ;; can't be handled using the template mechanism. The COMBINATION
;; node and the IR2-BLOCK are passed as arguments.
(ir2-convert nil :type (or function null))
+ ;; If true, the function can stack-allocate the result. The
+ ;; COMBINATION node is passed as an argument.
+ (stack-allocate-result nil :type (or function null))
;; all the templates that could be used to translate this function
;; into IR2, sorted by increasing cost.
(templates nil :type list)
;;; Grab the FUN-INFO and enter the function, replacing any old
;;; one with the same type and note.
(declaim (ftype (function (t list function &optional (or string null)
- (member t nil))
- *)
- %deftransform))
+ (member t nil))
+ *)
+ %deftransform))
(defun %deftransform (name type fun &optional note important)
(let* ((ctype (specifier-type type))
- (note (or note "optimize"))
- (info (fun-info-or-lose name))
- (old (find-if (lambda (x)
- (and (type= (transform-type x) ctype)
- (string-equal (transform-note x) note)
- (eq (transform-important x) important)))
- (fun-info-transforms info))))
+ (note (or note "optimize"))
+ (info (fun-info-or-lose name))
+ (old (find-if (lambda (x)
+ (and (type= (transform-type x) ctype)
+ (string-equal (transform-note x) note)
+ (eq (transform-important x) important)))
+ (fun-info-transforms info))))
(cond (old
(style-warn "Overwriting ~S" old)
(setf (transform-function old) fun
;;; Make a FUN-INFO structure with the specified type, attributes
;;; and optimizers.
(declaim (ftype (function (list list attributes &key
- (:derive-type (or function null))
- (:optimizer (or function null)))
- *)
- %defknown))
+ (:derive-type (or function null))
+ (:optimizer (or function null)))
+ *)
+ %defknown))
(defun %defknown (names type attributes &key derive-type optimizer)
(let ((ctype (specifier-type type))
- (info (make-fun-info :attributes attributes
+ (info (make-fun-info :attributes attributes
:derive-type derive-type
:optimizer optimizer))
- (target-env *info-environment*))
+ (target-env *info-environment*))
(dolist (name names)
(let ((old-fun-info (info :function :info name)))
- (when old-fun-info
- ;; This is handled as an error because it's generally a bad
- ;; thing to blow away all the old optimization stuff. It's
- ;; also a potential source of sneaky bugs:
- ;; DEFKNOWN FOO
- ;; DEFTRANSFORM FOO
- ;; DEFKNOWN FOO ; possibly hidden inside some macroexpansion
- ;; ; Now the DEFTRANSFORM doesn't exist in the target Lisp.
- ;; However, it's continuable because it might be useful to do
- ;; it when testing new optimization stuff interactively.
- (cerror "Go ahead, overwrite it."
- "~@<overwriting old FUN-INFO ~2I~_~S ~I~_for ~S~:>"
- old-fun-info name)))
+ (when old-fun-info
+ ;; This is handled as an error because it's generally a bad
+ ;; thing to blow away all the old optimization stuff. It's
+ ;; also a potential source of sneaky bugs:
+ ;; DEFKNOWN FOO
+ ;; DEFTRANSFORM FOO
+ ;; DEFKNOWN FOO ; possibly hidden inside some macroexpansion
+ ;; ; Now the DEFTRANSFORM doesn't exist in the target Lisp.
+ ;; However, it's continuable because it might be useful to do
+ ;; it when testing new optimization stuff interactively.
+ (cerror "Go ahead, overwrite it."
+ "~@<overwriting old FUN-INFO ~2I~_~S ~I~_for ~S~:>"
+ old-fun-info name)))
(setf (info :function :type name target-env) ctype)
(setf (info :function :where-from name target-env) :declared)
(setf (info :function :kind name target-env) :function)
(declaim (ftype (sfunction (t) fun-info) fun-info-or-lose))
(defun fun-info-or-lose (name)
(let (;; FIXME: Do we need this rebinding here? It's a literal
- ;; translation of the old CMU CL rebinding to
- ;; (OR *BACKEND-INFO-ENVIRONMENT* *INFO-ENVIRONMENT*),
- ;; and it's not obvious whether the rebinding to itself is
- ;; needed that SBCL doesn't need *BACKEND-INFO-ENVIRONMENT*.
- (*info-environment* *info-environment*))
+ ;; translation of the old CMU CL rebinding to
+ ;; (OR *BACKEND-INFO-ENVIRONMENT* *INFO-ENVIRONMENT*),
+ ;; and it's not obvious whether the rebinding to itself is
+ ;; needed that SBCL doesn't need *BACKEND-INFO-ENVIRONMENT*.
+ (*info-environment* *info-environment*))
(let ((old (info :function :info name)))
(unless old (error "~S is not a known function." name))
(setf (info :function :info name) (copy-fun-info old)))))
(defun result-type-float-contagion (call)
(declare (type combination call))
(reduce #'numeric-contagion (combination-args call)
- :key #'lvar-type
- :initial-value (specifier-type 'single-float)))
+ :key #'lvar-type
+ :initial-value (specifier-type 'single-float)))
;;; Return a closure usable as a derive-type method for accessing the
;;; N'th argument. If arg is a list, result is a list. If arg is a
(declare (type combination call))
(let ((lvar (nth (1- n) (combination-args call))))
(when lvar
- (let ((type (lvar-type lvar)))
- (if (array-type-p type)
- (specifier-type
- `(vector ,(type-specifier (array-type-element-type type))))
- (let ((ltype (specifier-type 'list)))
- (when (csubtypep type ltype)
- ltype))))))))
+ (let ((type (lvar-type lvar)))
+ (if (array-type-p type)
+ (specifier-type
+ `(vector ,(type-specifier (array-type-element-type type))))
+ (let ((ltype (specifier-type 'list)))
+ (when (csubtypep type ltype)
+ ltype))))))))
;;; Derive the type to be the type specifier which is the Nth arg.
(defun result-type-specifier-nth-arg (n)
(declare (type combination call))
(let ((lvar (nth (1- n) (combination-args call))))
(when (and lvar (constant-lvar-p lvar))
- (careful-specifier-type (lvar-value lvar))))))
+ (careful-specifier-type (lvar-value lvar))))))
;;; Derive the type to be the type specifier which is the Nth arg,
;;; with the additional restriptions noted in the CLHS for STRING and
(declare (type combination call))
(let ((lvar (nth (1- n) (combination-args call))))
(when (and lvar (constant-lvar-p lvar))
- (let* ((specifier (lvar-value lvar))
- (lspecifier (if (atom specifier) (list specifier) specifier)))
- (cond
- ((eq (car lspecifier) 'string)
- (destructuring-bind (string &rest size)
- lspecifier
- (declare (ignore string))
- (careful-specifier-type
- `(vector character ,@(when size size)))))
- ((eq (car lspecifier) 'simple-string)
- (destructuring-bind (simple-string &rest size)
- lspecifier
- (declare (ignore simple-string))
- (careful-specifier-type
- `(simple-array character ,@(if size (list size) '((*)))))))
- (t
- (let ((ctype (careful-specifier-type specifier)))
- (if (and (array-type-p ctype)
- (eq (array-type-specialized-element-type ctype)
- *wild-type*))
- ;; I don't think I'm allowed to modify what I get
- ;; back from SPECIFIER-TYPE; it is, after all,
- ;; cached. Better copy it, then.
- (let ((real-ctype (copy-structure ctype)))
- (setf (array-type-element-type real-ctype)
- *universal-type*
- (array-type-specialized-element-type real-ctype)
- *universal-type*)
- real-ctype)
- ctype)))))))))
+ (let* ((specifier (lvar-value lvar))
+ (lspecifier (if (atom specifier) (list specifier) specifier)))
+ (cond
+ ((eq (car lspecifier) 'string)
+ (destructuring-bind (string &rest size)
+ lspecifier
+ (declare (ignore string))
+ (careful-specifier-type
+ `(vector character ,@(when size size)))))
+ ((eq (car lspecifier) 'simple-string)
+ (destructuring-bind (simple-string &rest size)
+ lspecifier
+ (declare (ignore simple-string))
+ (careful-specifier-type
+ `(simple-array character ,@(if size (list size) '((*)))))))
+ (t
+ (let ((ctype (careful-specifier-type specifier)))
+ (if (and (array-type-p ctype)
+ (eq (array-type-specialized-element-type ctype)
+ *wild-type*))
+ ;; I don't think I'm allowed to modify what I get
+ ;; back from SPECIFIER-TYPE; it is, after all,
+ ;; cached. Better copy it, then.
+ (let ((real-ctype (copy-structure ctype)))
+ (setf (array-type-element-type real-ctype)
+ *universal-type*
+ (array-type-specialized-element-type real-ctype)
+ *universal-type*)
+ real-ctype)
+ ctype)))))))))
(/show0 "knownfun.lisp end of file")