;;;; This file contains macro-like source transformations which
;;;; convert uses of certain functions into the canonical form desired
-;;;; within the compiler. ### and other IR1 transforms and stuff.
+;;;; within the compiler. FIXME: and other IR1 transforms and stuff.
;;;; This software is part of the SBCL system. See the README file for
;;;; more information.
(define-source-transform identity (x) `(prog1 ,x))
(define-source-transform values (x) `(prog1 ,x))
-;;; Bind the values and make a closure that returns them.
+;;; Bind the value and make a closure that returns it.
(define-source-transform constantly (value)
- (let ((rest (gensym "CONSTANTLY-REST-")))
- `(lambda (&rest ,rest)
- (declare (ignore ,rest))
- ,value)))
+ (with-unique-names (rest n-value)
+ `(let ((,n-value ,value))
+ (lambda (&rest ,rest)
+ (declare (ignore ,rest))
+ ,n-value))))
;;; If the function has a known number of arguments, then return a
;;; lambda with the appropriate fixed number of args. If the
;;; Apply the function F to a bound X. If X is an open bound, then
;;; the result will be open. IF X is NIL, the result is NIL.
(defun bound-func (f x)
+ (declare (type function f))
(and x
(with-float-traps-masked (:underflow :overflow :inexact :divide-by-zero)
;; With these traps masked, we might get things like infinity
;;; result makes sense. It will if F is monotonic increasing (or
;;; non-decreasing).
(defun interval-func (f x)
- (declare (type interval x))
+ (declare (type function f)
+ (type interval x))
(let ((lo (bound-func f (interval-low x)))
(hi (bound-func f (interval-high x))))
(make-interval :low lo :high hi)))
;;; are equal to an intermediate convention for which they are
;;; considered different which is more natural for some of the
;;; optimisers.
-#!-negative-zero-is-not-zero
(defun convert-numeric-type (type)
(declare (type numeric-type type))
;;; Only convert real float interval delimiters types.
:low (if lo-float-zero-p
(if (consp lo)
(list (float 0.0 lo-val))
- (float -0.0 lo-val))
+ (float (load-time-value (make-unportable-float :single-float-negative-zero)) lo-val))
lo)
:high (if hi-float-zero-p
(if (consp hi)
- (list (float -0.0 hi-val))
+ (list (float (load-time-value (make-unportable-float :single-float-negative-zero)) hi-val))
(float 0.0 hi-val))
hi))
type))
;;; Convert back from the intermediate convention for which -0.0 and
;;; 0.0 are considered different to the standard type convention for
;;; which and equal.
-#!-negative-zero-is-not-zero
(defun convert-back-numeric-type (type)
(declare (type numeric-type type))
;;; Only convert real float interval delimiters types.
type))
;;; Convert back a possible list of numeric types.
-#!-negative-zero-is-not-zero
(defun convert-back-numeric-type-list (type-list)
(typecase type-list
(list
;;; FIXME: MAKE-CANONICAL-UNION-TYPE and CONVERT-MEMBER-TYPE probably
;;; belong in the kernel's type logic, invoked always, instead of in
-;;; the compiler, invoked only during some type optimizations.
+;;; the compiler, invoked only during some type optimizations. (In
+;;; fact, as of 0.pre8.100 or so they probably are, under
+;;; MAKE-MEMBER-TYPE, so probably this code can be deleted)
;;; Take a list of types and return a canonical type specifier,
;;; combining any MEMBER types together. If both positive and negative
(setf members (union members (member-type-members type)))
(push type misc-types)))
#!+long-float
- (when (null (set-difference '(-0l0 0l0) members))
- #!-negative-zero-is-not-zero
- (push (specifier-type '(long-float 0l0 0l0)) misc-types)
- #!+negative-zero-is-not-zero
- (push (specifier-type '(long-float -0l0 0l0)) misc-types)
- (setf members (set-difference members '(-0l0 0l0))))
- (when (null (set-difference '(-0d0 0d0) members))
- #!-negative-zero-is-not-zero
- (push (specifier-type '(double-float 0d0 0d0)) misc-types)
- #!+negative-zero-is-not-zero
- (push (specifier-type '(double-float -0d0 0d0)) misc-types)
- (setf members (set-difference members '(-0d0 0d0))))
- (when (null (set-difference '(-0f0 0f0) members))
- #!-negative-zero-is-not-zero
- (push (specifier-type '(single-float 0f0 0f0)) misc-types)
- #!+negative-zero-is-not-zero
- (push (specifier-type '(single-float -0f0 0f0)) misc-types)
- (setf members (set-difference members '(-0f0 0f0))))
+ (when (null (set-difference `(,(load-time-value (make-unportable-float :long-float-negative-zero)) 0.0l0) members))
+ (push (specifier-type '(long-float 0.0l0 0.0l0)) misc-types)
+ (setf members (set-difference members `(,(load-time-value (make-unportable-float :long-float-negative-zero)) 0.0l0))))
+ (when (null (set-difference `(,(load-time-value (make-unportable-float :double-float-negative-zero)) 0.0d0) members))
+ (push (specifier-type '(double-float 0.0d0 0.0d0)) misc-types)
+ (setf members (set-difference members `(,(load-time-value (make-unportable-float :double-float-negative-zero)) 0.0d0))))
+ (when (null (set-difference `(,(load-time-value (make-unportable-float :single-float-negative-zero)) 0.0f0) members))
+ (push (specifier-type '(single-float 0.0f0 0.0f0)) misc-types)
+ (setf members (set-difference members `(,(load-time-value (make-unportable-float :single-float-negative-zero)) 0.0f0))))
(if members
(apply #'type-union (make-member-type :members members) misc-types)
(apply #'type-union misc-types))))
(defun one-arg-derive-type (arg derive-fcn member-fcn
&optional (convert-type t))
(declare (type function derive-fcn)
- (type (or null function) member-fcn)
- #!+negative-zero-is-not-zero (ignore convert-type))
+ (type (or null function) member-fcn))
(let ((arg-list (prepare-arg-for-derive-type (continuation-type arg))))
(when arg-list
(flet ((deriver (x)
;; Otherwise convert to a numeric type.
(let ((result-type-list
(funcall derive-fcn (convert-member-type x))))
- #!-negative-zero-is-not-zero
(if convert-type
(convert-back-numeric-type-list result-type-list)
- result-type-list)
- #!+negative-zero-is-not-zero
- result-type-list)))
+ result-type-list))))
(numeric-type
- #!-negative-zero-is-not-zero
(if convert-type
(convert-back-numeric-type-list
(funcall derive-fcn (convert-numeric-type x)))
- (funcall derive-fcn x))
- #!+negative-zero-is-not-zero
- (funcall derive-fcn x))
+ (funcall derive-fcn x)))
(t
*universal-type*))))
;; Run down the list of args and derive the type of each one,
;;; positive. If we didn't do this, we wouldn't be able to tell.
(defun two-arg-derive-type (arg1 arg2 derive-fcn fcn
&optional (convert-type t))
- #!+negative-zero-is-not-zero
- (declare (ignore convert-type))
- (flet (#!-negative-zero-is-not-zero
- (deriver (x y same-arg)
+ (declare (type function derive-fcn fcn))
+ (flet ((deriver (x y same-arg)
(cond ((and (member-type-p x) (member-type-p y))
(let* ((x (first (member-type-members x)))
(y (first (member-type-members y)))
(convert-back-numeric-type-list result)
result)))
(t
- *universal-type*)))
- #!+negative-zero-is-not-zero
- (deriver (x y same-arg)
- (cond ((and (member-type-p x) (member-type-p y))
- (let* ((x (first (member-type-members x)))
- (y (first (member-type-members y)))
- (result (with-float-traps-masked
- (:underflow :overflow :divide-by-zero)
- (funcall fcn x y))))
- (if result
- (make-member-type :members (list result)))))
- ((and (member-type-p x) (numeric-type-p y))
- (let ((x (convert-member-type x)))
- (funcall derive-fcn x y same-arg)))
- ((and (numeric-type-p x) (member-type-p y))
- (let ((y (convert-member-type y)))
- (funcall derive-fcn x y same-arg)))
- ((and (numeric-type-p x) (numeric-type-p y))
- (funcall derive-fcn x y same-arg))
- (t
*universal-type*))))
(let ((same-arg (same-leaf-ref-p arg1 arg2))
(a1 (prepare-arg-for-derive-type (continuation-type arg1)))
) ; PROGN
-
-;;; KLUDGE: All this ASH optimization is suppressed under CMU CL
-;;; because as of version 2.4.6 for Debian, CMU CL blows up on (ASH
-;;; 1000000000 -100000000000) (i.e. ASH of two bignums yielding zero)
-;;; and it's hard to avoid that calculation in here.
-#-(and cmu sb-xc-host)
-(progn
-
(defun ash-derive-type-aux (n-type shift same-arg)
(declare (ignore same-arg))
+ ;; KLUDGE: All this ASH optimization is suppressed under CMU CL for
+ ;; some bignum cases because as of version 2.4.6 for Debian and 18d,
+ ;; CMU CL blows up on (ASH 1000000000 -100000000000) (i.e. ASH of
+ ;; two bignums yielding zero) and it's hard to avoid that
+ ;; calculation in here.
+ #+(and cmu sb-xc-host)
+ (when (and (or (typep (numeric-type-low n-type) 'bignum)
+ (typep (numeric-type-high n-type) 'bignum))
+ (or (typep (numeric-type-low shift) 'bignum)
+ (typep (numeric-type-high shift) 'bignum)))
+ (return-from ash-derive-type-aux *universal-type*))
(flet ((ash-outer (n s)
(when (and (fixnump s)
(<= s 64)
(defoptimizer (ash derive-type) ((n shift))
(two-arg-derive-type n shift #'ash-derive-type-aux #'ash))
-) ; PROGN
#+sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
(macrolet ((frob (fun)
(specifier-type 'base-char))
(defoptimizer (values derive-type) ((&rest values))
- (values-specifier-type
- `(values ,@(mapcar (lambda (x)
- (type-specifier (continuation-type x)))
- values))))
+ (make-values-type :required (mapcar #'continuation-type values)))
\f
;;;; byte operations
;;;;
(logior (logand new mask)
(logand int (lognot mask)))))
\f
+;;; Modular functions
+
+;;; (ldb (byte s 0) (foo x y ...)) =
+;;; (ldb (byte s 0) (foo (ldb (byte s 0) x) y ...))
+;;;
+;;; and similar for other arguments.
+
+;;; Try to recursively cut all uses of the continuation CONT to WIDTH
+;;; bits.
+;;;
+;;; For good functions, we just recursively cut arguments; their
+;;; "goodness" means that the result will not increase (in the
+;;; (unsigned-byte +infinity) sense). An ordinary modular function is
+;;; replaced with the version, cutting its result to WIDTH or more
+;;; bits. If we have changed anything, we need to flush old derived
+;;; types, because they have nothing in common with the new code.
+(defun cut-to-width (cont width)
+ (declare (type continuation cont) (type (integer 0) width))
+ (labels ((reoptimize-node (node name)
+ (setf (node-derived-type node)
+ (fun-type-returns
+ (info :function :type name)))
+ (setf (continuation-%derived-type (node-cont node)) nil)
+ (setf (node-reoptimize node) t)
+ (setf (block-reoptimize (node-block node)) t)
+ (setf (component-reoptimize (node-component node)) t))
+ (cut-node (node &aux did-something)
+ (when (and (combination-p node)
+ (fun-info-p (basic-combination-kind node)))
+ (let* ((fun-ref (continuation-use (combination-fun node)))
+ (fun-name (leaf-source-name (ref-leaf fun-ref)))
+ (modular-fun (find-modular-version fun-name width))
+ (name (and (modular-fun-info-p modular-fun)
+ (modular-fun-info-name modular-fun))))
+ (when (and modular-fun
+ (not (and (eq name 'logand)
+ (csubtypep
+ (single-value-type (node-derived-type node))
+ (specifier-type `(unsigned-byte ,width))))))
+ (unless (eq modular-fun :good)
+ (setq did-something t)
+ (change-ref-leaf
+ fun-ref
+ (find-free-fun name "in a strange place"))
+ (setf (combination-kind node) :full))
+ (dolist (arg (basic-combination-args node))
+ (when (cut-continuation arg)
+ (setq did-something t)))
+ (when did-something
+ (reoptimize-node node fun-name))
+ did-something))))
+ (cut-continuation (cont &aux did-something)
+ (do-uses (node cont)
+ (when (cut-node node)
+ (setq did-something t)))
+ did-something))
+ (cut-continuation cont)))
+
+(defoptimizer (logand optimizer) ((x y) node)
+ (let ((result-type (single-value-type (node-derived-type node))))
+ (when (numeric-type-p result-type)
+ (let ((low (numeric-type-low result-type))
+ (high (numeric-type-high result-type)))
+ (when (and (numberp low)
+ (numberp high)
+ (>= low 0))
+ (let ((width (integer-length high)))
+ (when (some (lambda (x) (<= width x))
+ *modular-funs-widths*)
+ ;; FIXME: This should be (CUT-TO-WIDTH NODE WIDTH).
+ (cut-to-width x width)
+ (cut-to-width y width)
+ nil ; After fixing above, replace with T.
+ )))))))
+\f
;;; miscellanous numeric transforms
;;; If a constant appears as the first arg, swap the args.
(or result 0)))
;;; If arg is a constant power of two, turn FLOOR into a shift and
-;;; mask. If CEILING, add in (1- (ABS Y)) and then do FLOOR.
+;;; mask. If CEILING, add in (1- (ABS Y)), do FLOOR and correct a
+;;; remainder.
(flet ((frob (y ceil-p)
(unless (constant-continuation-p y)
(give-up-ir1-transform))
(unless (= y-abs (ash 1 len))
(give-up-ir1-transform))
(let ((shift (- len))
- (mask (1- y-abs)))
- `(let ,(when ceil-p `((x (+ x ,(1- y-abs)))))
+ (mask (1- y-abs))
+ (delta (if ceil-p (* (signum y) (1- y-abs)) 0)))
+ `(let ((x (+ x ,delta)))
,(if (minusp y)
`(values (ash (- x) ,shift)
- (- (logand (- x) ,mask)))
+ (- (- (logand (- x) ,mask)) ,delta))
`(values (ash x ,shift)
- (logand x ,mask))))))))
+ (- (logand x ,mask) ,delta))))))))
(deftransform floor ((x y) (integer integer) *)
"convert division by 2^k to shift"
(frob y nil))
(def logxor -1 (lognot x))
(def logxor 0 x))
+(deftransform logand ((x y) (* (constant-arg t)) *)
+ "fold identity operation"
+ (let ((y (continuation-value y)))
+ (unless (and (plusp y)
+ (= y (1- (ash 1 (integer-length y)))))
+ (give-up-ir1-transform))
+ (unless (csubtypep (continuation-type x)
+ (specifier-type `(integer 0 ,y)))
+ (give-up-ir1-transform))
+ 'x))
+
;;; These are restricted to rationals, because (- 0 0.0) is 0.0, not -0.0, and
;;; (* 0 -4.0) is -0.0.
(deftransform - ((x y) ((constant-arg (member 0)) rational) *)
;;; change.
(defun same-leaf-ref-p (x y)
(declare (type continuation x y))
- (let ((x-use (continuation-use x))
- (y-use (continuation-use y)))
+ (let ((x-use (principal-continuation-use x))
+ (y-use (principal-continuation-use y)))
(and (ref-p x-use)
(ref-p y-use)
(eq (ref-leaf x-use) (ref-leaf y-use))
#-sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
(deftransform > ((x y) (float float) *)
(ir1-transform-< y x x y '<))
+
+(defun ir1-transform-char< (x y first second inverse)
+ (cond
+ ((same-leaf-ref-p x y) nil)
+ ;; If we had interval representation of character types, as we
+ ;; might eventually have to to support 2^21 characters, then here
+ ;; we could do some compile-time computation as in IR1-TRANSFORM-<
+ ;; above. -- CSR, 2003-07-01
+ ((and (constant-continuation-p first)
+ (not (constant-continuation-p second)))
+ `(,inverse y x))
+ (t (give-up-ir1-transform))))
+
+(deftransform char< ((x y) (character character) *)
+ (ir1-transform-char< x y x y 'char>))
+
+(deftransform char> ((x y) (character character) *)
+ (ir1-transform-char< y x x y 'char<))
\f
;;;; converting N-arg comparisons
;;;;
;;; negated test as appropriate. If it is a degenerate one-arg call,
;;; then we transform to code that returns true. Otherwise, we bind
;;; all the arguments and expand into a bunch of IFs.
-(declaim (ftype (function (symbol list boolean) *) multi-compare))
-(defun multi-compare (predicate args not-p)
+(declaim (ftype (function (symbol list boolean t) *) multi-compare))
+(defun multi-compare (predicate args not-p type)
(let ((nargs (length args)))
(cond ((< nargs 1) (values nil t))
- ((= nargs 1) `(progn ,@args t))
+ ((= nargs 1) `(progn (the ,type ,@args) t))
((= nargs 2)
(if not-p
`(if (,predicate ,(first args) ,(second args)) nil t)
`(if (,predicate ,current ,last)
,result nil))))
((zerop i)
- `((lambda ,vars ,result) . ,args)))))))
-
-(define-source-transform = (&rest args) (multi-compare '= args nil))
-(define-source-transform < (&rest args) (multi-compare '< args nil))
-(define-source-transform > (&rest args) (multi-compare '> args nil))
-(define-source-transform <= (&rest args) (multi-compare '> args t))
-(define-source-transform >= (&rest args) (multi-compare '< args t))
-
-(define-source-transform char= (&rest args) (multi-compare 'char= args nil))
-(define-source-transform char< (&rest args) (multi-compare 'char< args nil))
-(define-source-transform char> (&rest args) (multi-compare 'char> args nil))
-(define-source-transform char<= (&rest args) (multi-compare 'char> args t))
-(define-source-transform char>= (&rest args) (multi-compare 'char< args t))
+ `((lambda ,vars (declare (type ,type ,@vars)) ,result)
+ ,@args)))))))
+
+(define-source-transform = (&rest args) (multi-compare '= args nil 'number))
+(define-source-transform < (&rest args) (multi-compare '< args nil 'real))
+(define-source-transform > (&rest args) (multi-compare '> args nil 'real))
+(define-source-transform <= (&rest args) (multi-compare '> args t 'real))
+(define-source-transform >= (&rest args) (multi-compare '< args t 'real))
+
+(define-source-transform char= (&rest args) (multi-compare 'char= args nil
+ 'character))
+(define-source-transform char< (&rest args) (multi-compare 'char< args nil
+ 'character))
+(define-source-transform char> (&rest args) (multi-compare 'char> args nil
+ 'character))
+(define-source-transform char<= (&rest args) (multi-compare 'char> args t
+ 'character))
+(define-source-transform char>= (&rest args) (multi-compare 'char< args t
+ 'character))
(define-source-transform char-equal (&rest args)
- (multi-compare 'char-equal args nil))
+ (multi-compare 'char-equal args nil 'character))
(define-source-transform char-lessp (&rest args)
- (multi-compare 'char-lessp args nil))
+ (multi-compare 'char-lessp args nil 'character))
(define-source-transform char-greaterp (&rest args)
- (multi-compare 'char-greaterp args nil))
+ (multi-compare 'char-greaterp args nil 'character))
(define-source-transform char-not-greaterp (&rest args)
- (multi-compare 'char-greaterp args t))
+ (multi-compare 'char-greaterp args t 'character))
(define-source-transform char-not-lessp (&rest args)
- (multi-compare 'char-lessp args t))
+ (multi-compare 'char-lessp args t 'character))
;;; This function does source transformation of N-arg inequality
;;; functions such as /=. This is similar to MULTI-COMPARE in the <3
;;; arg cases. If there are more than two args, then we expand into
;;; the appropriate n^2 comparisons only when speed is important.
-(declaim (ftype (function (symbol list) *) multi-not-equal))
-(defun multi-not-equal (predicate args)
+(declaim (ftype (function (symbol list t) *) multi-not-equal))
+(defun multi-not-equal (predicate args type)
(let ((nargs (length args)))
(cond ((< nargs 1) (values nil t))
- ((= nargs 1) `(progn ,@args t))
+ ((= nargs 1) `(progn (the ,type ,@args) t))
((= nargs 2)
`(if (,predicate ,(first args) ,(second args)) nil t))
((not (policy *lexenv*
(next (cdr vars) (cdr next))
(result t))
((null next)
- `((lambda ,vars ,result) . ,args))
+ `((lambda ,vars (declare (type ,type ,@vars)) ,result)
+ ,@args))
(let ((v1 (first var)))
(dolist (v2 next)
(setq result `(if (,predicate ,v1 ,v2) nil ,result))))))))))
-(define-source-transform /= (&rest args) (multi-not-equal '= args))
-(define-source-transform char/= (&rest args) (multi-not-equal 'char= args))
+(define-source-transform /= (&rest args)
+ (multi-not-equal '= args 'number))
+(define-source-transform char/= (&rest args)
+ (multi-not-equal 'char= args 'character))
(define-source-transform char-not-equal (&rest args)
- (multi-not-equal 'char-equal args))
+ (multi-not-equal 'char-equal args 'character))
;;; Expand MAX and MIN into the obvious comparisons.
-(define-source-transform max (arg &rest more-args)
- (if (null more-args)
- `(values ,arg)
- (once-only ((arg1 arg)
- (arg2 `(max ,@more-args)))
- `(if (> ,arg1 ,arg2)
- ,arg1 ,arg2))))
-(define-source-transform min (arg &rest more-args)
- (if (null more-args)
- `(values ,arg)
- (once-only ((arg1 arg)
- (arg2 `(min ,@more-args)))
- `(if (< ,arg1 ,arg2)
- ,arg1 ,arg2))))
+(define-source-transform max (arg0 &rest rest)
+ (once-only ((arg0 arg0))
+ (if (null rest)
+ `(values (the real ,arg0))
+ `(let ((maxrest (max ,@rest)))
+ (if (> ,arg0 maxrest) ,arg0 maxrest)))))
+(define-source-transform min (arg0 &rest rest)
+ (once-only ((arg0 arg0))
+ (if (null rest)
+ `(values (the real ,arg0))
+ `(let ((minrest (min ,@rest)))
+ (if (< ,arg0 minrest) ,arg0 minrest)))))
\f
;;;; converting N-arg arithmetic functions
;;;;
;;; Do source transformations for transitive functions such as +.
;;; One-arg cases are replaced with the arg and zero arg cases with
-;;; the identity. If LEAF-FUN is true, then replace two-arg calls with
-;;; a call to that function.
-(defun source-transform-transitive (fun args identity &optional leaf-fun)
+;;; the identity. ONE-ARG-RESULT-TYPE is, if non-NIL, the type to
+;;; ensure (with THE) that the argument in one-argument calls is.
+(defun source-transform-transitive (fun args identity
+ &optional one-arg-result-type)
(declare (symbol fun leaf-fun) (list args))
(case (length args)
(0 identity)
- (1 `(values ,(first args)))
- (2 (if leaf-fun
- `(,leaf-fun ,(first args) ,(second args))
- (values nil t)))
+ (1 (if one-arg-result-type
+ `(values (the ,one-arg-result-type ,(first args)))
+ `(values ,(first args))))
+ (2 (values nil t))
(t
(associate-args fun (first args) (rest args)))))
(define-source-transform + (&rest args)
- (source-transform-transitive '+ args 0))
+ (source-transform-transitive '+ args 0 'number))
(define-source-transform * (&rest args)
- (source-transform-transitive '* args 1))
+ (source-transform-transitive '* args 1 'number))
(define-source-transform logior (&rest args)
- (source-transform-transitive 'logior args 0))
+ (source-transform-transitive 'logior args 0 'integer))
(define-source-transform logxor (&rest args)
- (source-transform-transitive 'logxor args 0))
+ (source-transform-transitive 'logxor args 0 'integer))
(define-source-transform logand (&rest args)
- (source-transform-transitive 'logand args -1))
+ (source-transform-transitive 'logand args -1 'integer))
(define-source-transform logeqv (&rest args)
(if (evenp (length args))
;;; Do source transformations for intransitive n-arg functions such as
;;; /. With one arg, we form the inverse. With two args we pass.
;;; Otherwise we associate into two-arg calls.
-(declaim (ftype (function (symbol list t) list) source-transform-intransitive))
+(declaim (ftype (function (symbol list t)
+ (values list &optional (member nil t)))
+ source-transform-intransitive))
(defun source-transform-intransitive (function args inverse)
(case (length args)
((0 2) (values nil t))
;;;; or T and the control string is a function (i.e. FORMATTER), then
;;;; convert the call to FORMAT to just a FUNCALL of that function.
+;;; for compile-time argument count checking.
+;;;
+;;; FIXME I: this is currently called from DEFTRANSFORMs, the vast
+;;; majority of which are not going to transform the code, but instead
+;;; are going to GIVE-UP-IR1-TRANSFORM unconditionally. It would be
+;;; nice to make this explicit, maybe by implementing a new
+;;; "optimizer" (say, DEFOPTIMIZER CONSISTENCY-CHECK).
+;;;
+;;; FIXME II: In some cases, type information could be correlated; for
+;;; instance, ~{ ... ~} requires a list argument, so if the
+;;; continuation-type of a corresponding argument is known and does
+;;; not intersect the list type, a warning could be signalled.
+(defun check-format-args (string args fun)
+ (declare (type string string))
+ (unless (typep string 'simple-string)
+ (setq string (coerce string 'simple-string)))
+ (multiple-value-bind (min max)
+ (handler-case (sb!format:%compiler-walk-format-string string args)
+ (sb!format:format-error (c)
+ (compiler-warn "~A" c)))
+ (when min
+ (let ((nargs (length args)))
+ (cond
+ ((< nargs min)
+ (compiler-warn "Too few arguments (~D) to ~S ~S: ~
+ requires at least ~D."
+ nargs fun string min))
+ ((> nargs max)
+ (;; to get warned about probably bogus code at
+ ;; cross-compile time.
+ #+sb-xc-host compiler-warn
+ ;; ANSI saith that too many arguments doesn't cause a
+ ;; run-time error.
+ #-sb-xc-host compiler-style-warn
+ "Too many arguments (~D) to ~S ~S: uses at most ~D."
+ nargs fun string max)))))))
+
(deftransform format ((dest control &rest args) (t simple-string &rest t) *
- :policy (> speed space))
- (unless (constant-continuation-p control)
- (give-up-ir1-transform "The control string is not a constant."))
- (let ((arg-names (make-gensym-list (length args))))
- `(lambda (dest control ,@arg-names)
- (declare (ignore control))
- (format dest (formatter ,(continuation-value control)) ,@arg-names))))
+ :node node)
+
+ (cond
+ ((policy node (> speed space))
+ (unless (constant-continuation-p control)
+ (give-up-ir1-transform "The control string is not a constant."))
+ (check-format-args (continuation-value control) args 'format)
+ (let ((arg-names (make-gensym-list (length args))))
+ `(lambda (dest control ,@arg-names)
+ (declare (ignore control))
+ (format dest (formatter ,(continuation-value control)) ,@arg-names))))
+ (t (when (constant-continuation-p control)
+ (check-format-args (continuation-value control) args 'format))
+ (give-up-ir1-transform))))
(deftransform format ((stream control &rest args) (stream function &rest t) *
:policy (> speed space))
(funcall control *standard-output* ,@arg-names)
nil)))
+(macrolet
+ ((def (name)
+ `(deftransform ,name
+ ((control &rest args) (simple-string &rest t) *)
+ (when (constant-continuation-p control)
+ (check-format-args (continuation-value control) args ',name))
+ (give-up-ir1-transform))))
+ (def error)
+ (def warn)
+ #+sb-xc-host ; Only we should be using these
+ (progn
+ (def style-warn)
+ (def compiler-abort)
+ (def compiler-error)
+ (def compiler-warn)
+ (def compiler-style-warn)
+ (def compiler-notify)
+ (def maybe-compiler-notify)
+ (def bug)))
+
+(deftransform cerror ((report control &rest args)
+ (simple-string simple-string &rest t) *)
+ (unless (and (constant-continuation-p control)
+ (constant-continuation-p report))
+ (give-up-ir1-transform))
+ (multiple-value-bind (min1 max1)
+ (handler-case (sb!format:%compiler-walk-format-string
+ (continuation-value control) args)
+ (sb!format:format-error (c)
+ (compiler-warn "~A" c)))
+ (when min1
+ (multiple-value-bind (min2 max2)
+ (handler-case (sb!format:%compiler-walk-format-string
+ (continuation-value report) args)
+ (sb!format:format-error (c)
+ (compiler-warn "~A" c)))
+ (when min2
+ (let ((nargs (length args)))
+ (cond
+ ((< nargs (min min1 min2))
+ (compiler-warn "Too few arguments (~D) to ~S ~S ~S: ~
+ requires at least ~D."
+ nargs 'cerror report control (min min1 min2)))
+ ((> nargs (max max1 max2))
+ (;; to get warned about probably bogus code at
+ ;; cross-compile time.
+ #+sb-xc-host compiler-warn
+ ;; ANSI saith that too many arguments doesn't cause a
+ ;; run-time error.
+ #-sb-xc-host compiler-style-warn
+ "Too many arguments (~D) to ~S ~S ~S: uses at most ~D."
+ nargs 'cerror report control (max max1 max2)))))))))
+ (give-up-ir1-transform))
+
(defoptimizer (coerce derive-type) ((value type))
- (let ((value-type (continuation-type value))
- (type-type (continuation-type type)))
- (labels
- ((good-cons-type-p (cons-type)
- ;; Make sure the cons-type we're looking at is something
- ;; we're prepared to handle which is basically something
- ;; that array-element-type can return.
- (or (and (member-type-p cons-type)
- (null (rest (member-type-members cons-type)))
- (null (first (member-type-members cons-type))))
- (let ((car-type (cons-type-car-type cons-type)))
- (and (member-type-p car-type)
- (null (rest (member-type-members car-type)))
- (or (symbolp (first (member-type-members car-type)))
- (numberp (first (member-type-members car-type)))
- (and (listp (first (member-type-members car-type)))
- (numberp (first (first (member-type-members
- car-type))))))
- (good-cons-type-p (cons-type-cdr-type cons-type))))))
- (unconsify-type (good-cons-type)
- ;; Convert the "printed" respresentation of a cons
- ;; specifier into a type specifier. That is, the specifier
- ;; (cons (eql signed-byte) (cons (eql 16) null)) is
- ;; converted to (signed-byte 16).
- (cond ((or (null good-cons-type)
- (eq good-cons-type 'null))
- nil)
- ((and (eq (first good-cons-type) 'cons)
- (eq (first (second good-cons-type)) 'member))
- `(,(second (second good-cons-type))
- ,@(unconsify-type (caddr good-cons-type))))))
- (coerceable-p (c-type)
- ;; Can the value be coerced to the given type? Coerce is
- ;; complicated, so we don't handle every possible case
- ;; here---just the most common and easiest cases:
- ;;
- ;; o Any real can be coerced to a float type.
- ;; o Any number can be coerced to a complex single/double-float.
- ;; o An integer can be coerced to an integer.
- (let ((coerced-type c-type))
- (or (and (subtypep coerced-type 'float)
- (csubtypep value-type (specifier-type 'real)))
- (and (subtypep coerced-type
- '(or (complex single-float)
- (complex double-float)))
- (csubtypep value-type (specifier-type 'number)))
- (and (subtypep coerced-type 'integer)
- (csubtypep value-type (specifier-type 'integer))))))
- (process-types (type)
- ;; FIXME:
- ;; This needs some work because we should be able to derive
- ;; the resulting type better than just the type arg of
- ;; coerce. That is, if x is (integer 10 20), the (coerce x
- ;; 'double-float) should say (double-float 10d0 20d0)
- ;; instead of just double-float.
- (cond ((member-type-p type)
- (let ((members (member-type-members type)))
- (if (every #'coerceable-p members)
- (specifier-type `(or ,@members))
- *universal-type*)))
- ((and (cons-type-p type)
- (good-cons-type-p type))
- (let ((c-type (unconsify-type (type-specifier type))))
- (if (coerceable-p c-type)
- (specifier-type c-type)
- *universal-type*)))
- (t
- *universal-type*))))
- (cond ((union-type-p type-type)
- (apply #'type-union (mapcar #'process-types
- (union-type-types type-type))))
- ((or (member-type-p type-type)
- (cons-type-p type-type))
- (process-types type-type))
- (t
- *universal-type*)))))
+ (cond
+ ((constant-continuation-p type)
+ ;; This branch is essentially (RESULT-TYPE-SPECIFIER-NTH-ARG 2),
+ ;; but dealing with the niggle that complex canonicalization gets
+ ;; in the way: (COERCE 1 'COMPLEX) returns 1, which is not of
+ ;; type COMPLEX.
+ (let* ((specifier (continuation-value type))
+ (result-typeoid (careful-specifier-type specifier)))
+ (cond
+ ((null result-typeoid) nil)
+ ((csubtypep result-typeoid (specifier-type 'number))
+ ;; the difficult case: we have to cope with ANSI 12.1.5.3
+ ;; Rule of Canonical Representation for Complex Rationals,
+ ;; which is a truly nasty delivery to field.
+ (cond
+ ((csubtypep result-typeoid (specifier-type 'real))
+ ;; cleverness required here: it would be nice to deduce
+ ;; that something of type (INTEGER 2 3) coerced to type
+ ;; DOUBLE-FLOAT should return (DOUBLE-FLOAT 2.0d0 3.0d0).
+ ;; FLOAT gets its own clause because it's implemented as
+ ;; a UNION-TYPE, so we don't catch it in the NUMERIC-TYPE
+ ;; logic below.
+ result-typeoid)
+ ((and (numeric-type-p result-typeoid)
+ (eq (numeric-type-complexp result-typeoid) :real))
+ ;; FIXME: is this clause (a) necessary or (b) useful?
+ result-typeoid)
+ ((or (csubtypep result-typeoid
+ (specifier-type '(complex single-float)))
+ (csubtypep result-typeoid
+ (specifier-type '(complex double-float)))
+ #!+long-float
+ (csubtypep result-typeoid
+ (specifier-type '(complex long-float))))
+ ;; float complex types are never canonicalized.
+ result-typeoid)
+ (t
+ ;; if it's not a REAL, or a COMPLEX FLOAToid, it's
+ ;; probably just a COMPLEX or equivalent. So, in that
+ ;; case, we will return a complex or an object of the
+ ;; provided type if it's rational:
+ (type-union result-typeoid
+ (type-intersection (continuation-type value)
+ (specifier-type 'rational))))))
+ (t result-typeoid))))
+ (t
+ ;; OK, the result-type argument isn't constant. However, there
+ ;; are common uses where we can still do better than just
+ ;; *UNIVERSAL-TYPE*: e.g. (COERCE X (ARRAY-ELEMENT-TYPE Y)),
+ ;; where Y is of a known type. See messages on cmucl-imp
+ ;; 2001-02-14 and sbcl-devel 2002-12-12. We only worry here
+ ;; about types that can be returned by (ARRAY-ELEMENT-TYPE Y), on
+ ;; the basis that it's unlikely that other uses are both
+ ;; time-critical and get to this branch of the COND (non-constant
+ ;; second argument to COERCE). -- CSR, 2002-12-16
+ (let ((value-type (continuation-type value))
+ (type-type (continuation-type type)))
+ (labels
+ ((good-cons-type-p (cons-type)
+ ;; Make sure the cons-type we're looking at is something
+ ;; we're prepared to handle which is basically something
+ ;; that array-element-type can return.
+ (or (and (member-type-p cons-type)
+ (null (rest (member-type-members cons-type)))
+ (null (first (member-type-members cons-type))))
+ (let ((car-type (cons-type-car-type cons-type)))
+ (and (member-type-p car-type)
+ (null (rest (member-type-members car-type)))
+ (or (symbolp (first (member-type-members car-type)))
+ (numberp (first (member-type-members car-type)))
+ (and (listp (first (member-type-members
+ car-type)))
+ (numberp (first (first (member-type-members
+ car-type))))))
+ (good-cons-type-p (cons-type-cdr-type cons-type))))))
+ (unconsify-type (good-cons-type)
+ ;; Convert the "printed" respresentation of a cons
+ ;; specifier into a type specifier. That is, the
+ ;; specifier (CONS (EQL SIGNED-BYTE) (CONS (EQL 16)
+ ;; NULL)) is converted to (SIGNED-BYTE 16).
+ (cond ((or (null good-cons-type)
+ (eq good-cons-type 'null))
+ nil)
+ ((and (eq (first good-cons-type) 'cons)
+ (eq (first (second good-cons-type)) 'member))
+ `(,(second (second good-cons-type))
+ ,@(unconsify-type (caddr good-cons-type))))))
+ (coerceable-p (c-type)
+ ;; Can the value be coerced to the given type? Coerce is
+ ;; complicated, so we don't handle every possible case
+ ;; here---just the most common and easiest cases:
+ ;;
+ ;; * Any REAL can be coerced to a FLOAT type.
+ ;; * Any NUMBER can be coerced to a (COMPLEX
+ ;; SINGLE/DOUBLE-FLOAT).
+ ;;
+ ;; FIXME I: we should also be able to deal with characters
+ ;; here.
+ ;;
+ ;; FIXME II: I'm not sure that anything is necessary
+ ;; here, at least while COMPLEX is not a specialized
+ ;; array element type in the system. Reasoning: if
+ ;; something cannot be coerced to the requested type, an
+ ;; error will be raised (and so any downstream compiled
+ ;; code on the assumption of the returned type is
+ ;; unreachable). If something can, then it will be of
+ ;; the requested type, because (by assumption) COMPLEX
+ ;; (and other difficult types like (COMPLEX INTEGER)
+ ;; aren't specialized types.
+ (let ((coerced-type c-type))
+ (or (and (subtypep coerced-type 'float)
+ (csubtypep value-type (specifier-type 'real)))
+ (and (subtypep coerced-type
+ '(or (complex single-float)
+ (complex double-float)))
+ (csubtypep value-type (specifier-type 'number))))))
+ (process-types (type)
+ ;; FIXME: This needs some work because we should be able
+ ;; to derive the resulting type better than just the
+ ;; type arg of coerce. That is, if X is (INTEGER 10
+ ;; 20), then (COERCE X 'DOUBLE-FLOAT) should say
+ ;; (DOUBLE-FLOAT 10d0 20d0) instead of just
+ ;; double-float.
+ (cond ((member-type-p type)
+ (let ((members (member-type-members type)))
+ (if (every #'coerceable-p members)
+ (specifier-type `(or ,@members))
+ *universal-type*)))
+ ((and (cons-type-p type)
+ (good-cons-type-p type))
+ (let ((c-type (unconsify-type (type-specifier type))))
+ (if (coerceable-p c-type)
+ (specifier-type c-type)
+ *universal-type*)))
+ (t
+ *universal-type*))))
+ (cond ((union-type-p type-type)
+ (apply #'type-union (mapcar #'process-types
+ (union-type-types type-type))))
+ ((or (member-type-p type-type)
+ (cons-type-p type-type))
+ (process-types type-type))
+ (t
+ *universal-type*)))))))
+(defoptimizer (compile derive-type) ((nameoid function))
+ (when (csubtypep (continuation-type nameoid)
+ (specifier-type 'null))
+ (values-specifier-type '(values function boolean boolean))))
+
+;;; FIXME: Maybe also STREAM-ELEMENT-TYPE should be given some loving
+;;; treatment along these lines? (See discussion in COERCE DERIVE-TYPE
+;;; optimizer, above).
(defoptimizer (array-element-type derive-type) ((array))
- (let* ((array-type (continuation-type array)))
+ (let ((array-type (continuation-type array)))
(labels ((consify (list)
(if (endp list)
'(eql nil)
(error "can't understand type ~S~%" element-type))))))
(cond ((array-type-p array-type)
(get-element-type array-type))
- ((union-type-p array-type)
+ ((union-type-p array-type)
(apply #'type-union
(mapcar #'get-element-type (union-type-types array-type))))
(t
*universal-type*)))))
+
+(define-source-transform sb!impl::sort-vector (vector start end predicate key)
+ `(macrolet ((%index (x) `(truly-the index ,x))
+ (%parent (i) `(ash ,i -1))
+ (%left (i) `(%index (ash ,i 1)))
+ (%right (i) `(%index (1+ (ash ,i 1))))
+ (%heapify (i)
+ `(do* ((i ,i)
+ (left (%left i) (%left i)))
+ ((> left current-heap-size))
+ (declare (type index i left))
+ (let* ((i-elt (%elt i))
+ (i-key (funcall keyfun i-elt))
+ (left-elt (%elt left))
+ (left-key (funcall keyfun left-elt)))
+ (multiple-value-bind (large large-elt large-key)
+ (if (funcall ,',predicate i-key left-key)
+ (values left left-elt left-key)
+ (values i i-elt i-key))
+ (let ((right (%right i)))
+ (multiple-value-bind (largest largest-elt)
+ (if (> right current-heap-size)
+ (values large large-elt)
+ (let* ((right-elt (%elt right))
+ (right-key (funcall keyfun right-elt)))
+ (if (funcall ,',predicate large-key right-key)
+ (values right right-elt)
+ (values large large-elt))))
+ (cond ((= largest i)
+ (return))
+ (t
+ (setf (%elt i) largest-elt
+ (%elt largest) i-elt
+ i largest)))))))))
+ (%sort-vector (keyfun &optional (vtype 'vector))
+ `(macrolet (;; KLUDGE: In SBCL ca. 0.6.10, I had trouble getting
+ ;; type inference to propagate all the way
+ ;; through this tangled mess of
+ ;; inlining. The TRULY-THE here works
+ ;; around that. -- WHN
+ (%elt (i)
+ `(aref (truly-the ,',vtype ,',',vector)
+ (%index (+ (%index ,i) start-1)))))
+ (let ((start-1 (1- ,',start)) ; Heaps prefer 1-based addressing.
+ (current-heap-size (- ,',end ,',start))
+ (keyfun ,keyfun))
+ (declare (type (integer -1 #.(1- most-positive-fixnum))
+ start-1))
+ (declare (type index current-heap-size))
+ (declare (type function keyfun))
+ (loop for i of-type index
+ from (ash current-heap-size -1) downto 1 do
+ (%heapify i))
+ (loop
+ (when (< current-heap-size 2)
+ (return))
+ (rotatef (%elt 1) (%elt current-heap-size))
+ (decf current-heap-size)
+ (%heapify 1))))))
+ (if (typep ,vector 'simple-vector)
+ ;; (VECTOR T) is worth optimizing for, and SIMPLE-VECTOR is
+ ;; what we get from (VECTOR T) inside WITH-ARRAY-DATA.
+ (if (null ,key)
+ ;; Special-casing the KEY=NIL case lets us avoid some
+ ;; function calls.
+ (%sort-vector #'identity simple-vector)
+ (%sort-vector ,key simple-vector))
+ ;; It's hard to anticipate many speed-critical applications for
+ ;; sorting vector types other than (VECTOR T), so we just lump
+ ;; them all together in one slow dynamically typed mess.
+ (locally
+ (declare (optimize (speed 2) (space 2) (inhibit-warnings 3)))
+ (%sort-vector (or ,key #'identity))))))
\f
;;;; debuggers' little helpers